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The five biggest threats to our natural world … and how we can stop them

From destructive land use to invasive species, scientists have identified the main drivers of biodiversity loss – so that countries can collectively act to tackle them

• Read more on the Cop15 talks to negotiate new UN targets to protect biodiversity in the coming decade
• 1 Changes in land and sea use
• 2 Direct exploitation of natural resources
• 3 The climate crisis
• 4 Pollution
• 5 Invasive species

T he world’s wildlife populations have plummeted by more than two-thirds since 1970 – and there are no signs that this downward trend is slowing. The first phase of Cop15 talks in Kunming this week will lay the groundwork for governments to draw up a global agreement next year to halt the loss of nature. If they are to succeed, they will need to tackle what the IPBES (Intergovernmental Science-Policy Platform on Biodiversity and Ecosystem Services) has identified as the five key drivers of biodiversity loss: changes in land and sea use; direct exploitation of natural resources; climate change; pollution; and invasion of alien species.

Changes in land and sea use

Clearing the US prairies: ‘On a par with tropical deforestation’

“It’s hidden destruction. We’re still losing grasslands in the US at a rate of half a million acres a year or more.”

Tyler Lark, from the University of Wisconsin-Madison, knows what he is talking about. Lark and a team of researchers used satellite data to map the expansion and abandonment of land across the US and discovered that 4m hectares (10m acres) had been destroyed between 2008 and 2016.

Large swathes of the United States’ great prairies continue to be converted into cropland, according to the research, to make way for soya bean, corn and wheat farming.

Changes in land and sea use has been identified as the main driver of “unprecedented” biodiversity and ecosystem change over the past 50 years. ​​ Three-quarters of the land-based environment and about 66% of the marine environment have been significantly altered by human actions.

North America’s grasslands – often referred to as prairies – are a case in point. In the US, about half have been converted since European settlement , and the most fertile land is already being used for agriculture. Areas converted more recently are sub-prime agricultural land, with 70% of yields lower than the national average, which means a lot of biodiversity is being lost for diminishing returns.

“Our findings demonstrate a pervasive pattern of encroachment into areas that are increasingly marginal for production but highly significant for wildlife,” Lark and his team wrote in the paper , published in Nature Communications.

Boggier areas of land, or those with uneven terrain, were traditionally left as grassland, but in the past few decades, this marginal land has also been converted. In the US, 88% of cropland expansion takes place on grassland, and much of this is happening in the Great Plains – known as America’s breadbasket – which used to be the most extensive grassland in the world.

What are the five biggest threats to biodiversity?

According to the UN’s Convention on Biological Diversity there are  five main threats  to biodiversity. In descending order these are: changes in land and sea use; direct exploitation of natural resources; climate change; pollution and invasive species. 

1. For terrestrial and freshwater ecosystems, land-use change has had the largest relative negative impact on nature since 1970.  More than a third of the world’s land surface and nearly 75% of freshwater resources are now devoted to crop or livestock production. Alongside a doubling of urban area since 1992, things such as wetlands, scrubland and woodlands – which wildlife relies on – are ironed out from the landscape. 

2. The direct exploitation of organisms and non-living materials, including logging, hunting and fishing and the extraction of soils and water are all  negatively affecting ecosystems .   In marine environments, overfishing is considered to be the most serious driver of biodiversity loss. One quarter of the world’s commercial fisheries are overexploited, according to a 2005  Millennium Ecosystem Assessment . 

3. The climate crisis is dismantling ecosystems at every level. Extreme weather events such as tropical storms and flooding are destroying habitats. Warmer temperatures are also changing the timing of natural events – such as the availability of insects and when birds hatch their eggs in spring. The distribution of species and their range is also changing. 

4. Many types of pollution are increasing. In marine environments, pollution from agricultural runoff (mainly nitrogen and phosphorus) do huge damage to ecosystems. Agricultural runoff causes toxic algal blooms and even  "dead zones"  in the worst affected areas. Marine plastic pollution has increased tenfold since 1980, affecting at least 267 species.

5. Since the 17th century, invasive species have  contributed to 40%  of all known animal extinctions. Nearly one fifth of the Earth’s surface is at risk of plant and animal invasions. Invasive species change the composition of ecosystems by outcompeting native species. 

Hotspots for this expansion have included wildlife-rich grasslands in the “prairie pothole” region which stretches between Iowa, Dakota, Montana and southern Canada and is home to more than 50% of North American migratory waterfowl, as well as 96 species of songbird. This cropland expansion has wiped out about 138,000 nesting habitats for waterfowl, researchers estimate.

These grasslands are also a rich habitat for the monarch butterfly – a flagship species for pollinator conservation and a key indicator of overall insect biodiversity. More than 200m milkweed plants, the caterpillar’s only food source, were probably destroyed by cropland expansion, making it one of the leading causes for the monarch’s national decline .

The extent of conversion of grassland in the US makes it a larger emission source than the destruction of the Brazilian Cerrado , according to research from 2019 . About 90% of emissions from grassland conversion comes from carbon lost in the soil, which is released when the grassland is ploughed up.

“The rate of clearing that we’re seeing on these grasslands is on par with things like tropical deforestation, but it often receives far less attention,” says Lark.

Food crop production globally has increased by about 300% since 1970 , despite the negative environmental impacts.

Reducing food waste and eating less meat would help cut the amount of land needed for farming, while researchers say improved management of existing croplands and utilising what is already farmed as best as possible would reduce further expansion.

Lark concludes: “I think there’s a huge opportunity to re-envision our landscapes so that they’re not only providing incredible food production but also mitigating climate change and helping reduce the impacts of the biodiversity crisis by increasing habitats on agricultural land.” PW

Direct exploitation of natural resources

Groundwater extraction: ‘People don’t see it’

From hunting, fishing and logging to the extraction of oil, gas, coal and water, humanity’s insatiable appetite for the planet’s resources has devastated large parts of the natural world.

While the impacts of many of these actions can often be seen, unsustainable groundwater extraction could be driving a hidden crisis below our feet, experts have warned, wiping out freshwater biodiversity, threatening global food security and causing rivers to run dry.

Farmers and mining companies are pumping vast underground water stores at an unsustainable rate, according to ecologists and hydrologists. About half the world’s population relies on groundwater for drinking water and it helps sustain 40% of irrigation systems for crops .

The consequences for freshwater ecosystems – among the most degraded on the planet – are under-researched as studies have focused on the depletion of groundwater for agriculture.

But a growing body of research indicates that pumping the world’s most extracted resource – water – is causing significant damage to the planet’s ecosystems. A 2017 study of the Ogallala aquifer – an enormous water source underneath eight states in the US Great Plains – found that more than half a century of pumping has caused streams to run dry and a collapse in large fish populations. In 2019, another study estimated that by 2050 between 42% and 79% of watersheds that pump groundwater globally could pass ecological tipping points, without better management.

“The difficulty with groundwater is that people don’t see it and they don’t understand the fragility of it,” says James Dalton, director of the global water programme at the International Union for Conservation of Nature (IUCN). “Groundwater can be the largest – and sometimes the sole – source in certain types of terrestrial habitats.

“Uganda is luxuriantly green, even during the dry season, but that’s because a lot of it is irrigated with shallow groundwater for agriculture and the ecosystems are reliant on tapping into it.”

According to UPGro (Unlocking the Potential of Groundwater for the Poor), a research programme looking into the management of groundwater in sub-Saharan Africa, 73 of the 98 operational water supply systems in Uganda are dependent on water from below ground. The country shares two transboundary aquifers: the Nile and Lake Victoria basins. At least 592 aquifers are shared across borders around the world.

“Some of the groundwater reserves are huge, so there is time to fix this,” says Dalton. “It’s just there’s no attention to it.”

Inge de Graaf, a hydrologist at Wageningen University, who led the 2019 study into watershed levels, found between 15% to 21% had already passed ecological tipping points, adding that once the effects had become clear for rivers, it was often too late.

“Groundwater is slow because it has to flow through rocks. If you extract water today, it will impact the stream flow maybe in the next five years, in the next 10 years, or in the next decades,” she says. “I think the results of this research and related studies are pretty scary.”

In April, the largest ever assessment of global groundwater wells by researchers from University of California, Santa Barbara, found that up to one in five were at risk of running dry. Scott Jasechko, a hydrologist and lead author on the paper, says that the study focuses on the consequences for humans and more research is needed on biodiversity.

“Millions of wells around the world could run dry with even modest declines in groundwater levels. And that, of course, has cascading implications for livelihoods and access to reliable and convenient water for individuals and ecosystems,” he says. PG

The climate crisis

Climate and biodiversity: ‘Solve both or solve neither’

In 2019, the European heatwave brought 43C heat to Montpellier in France. Great tit chicks in 30 nest boxes starved to death, probably because it was too hot for their parents to catch the food they needed, according to one researcher . Two years later, and 2021’s heatwave appears to have set a European record, pushing temperatures to 48.8C in Sicily in August. Meanwhile, wildfires and heatwaves are stripping the planet of life.

Until now, the destruction of habitats and extraction of resources has had a more significant impact on biodiversity than the climate crisis. This is likely to change over the coming decades as the climate crisis dismantles ecosystems in unpredictable and dramatic ways, according to a review paper published by the Royal Society.

“There are many aspects of ecosystem science where we will not know enough in sufficient time,” the paper says. “Ecosystems are changing so rapidly in response to global change drivers that our research and modelling frameworks are overtaken by empirical, system-altering changes.”

The calls for biodiversity and the climate crisis to be tackled in tandem are growing. “It is clear that we cannot solve [the global biodiversity and climate crises] in isolation – we either solve both or we solve neither,” says Sveinung Rotevatn, Norway’s climate and environment minister, with the launch in June of a report produced by the world’s leading biodiversity and climate experts. Zoological Society of London senior research fellow Dr Nathalie Pettorelli, who led a s tudy on the subject published in the Journal of Applied Ecology in September, says: “The level of interconnectedness between the climate change and biodiversity crises is high and should not be underestimated. This is not just about climate change impacting biodiversity; it is also about the loss of biodiversity deepening the climate crisis.”

Writer Zadie Smith describes every country’s changes as a “local sadness” . Insects no longer fly into the house when the lights are on in the evening, the snowdrops are coming out earlier and some migratory species, such as swallows, are starting to try to stay in the UK for winter. All these individual elements are entwined in a much bigger story of decline.

Our biosphere – the thin film of life on the surface of our planet – is being destabilised by temperature change. On land, rains are altering, extreme weather events are more common, and ecosystems more flammable. Associated changes, including flooding , sea level rise, droughts and storms, are having hugely damaging impacts on biodiversity and its ability to support us.

In the ocean, heatwaves and acidification are stressing organisms and ecosystems already under pressure due to other human activities, such as overfishing and habitat fragmentation.

The latest Intergovernmental Panel on Climate Change (IPCC) landmark report showed that extreme heatwaves that would usually happen every 50 years are already happening every decade. If warming is kept to 1.5C these will happen approximately every five years.

The distributions of almost half (47%) of land-based flightless mammals and almost a quarter of threatened birds, may already have been negatively affected by the climate crisis, the IPBES warns . Five per cent of species are at risk of extinction from 2C warming, climbing to 16% with a 4.3C rise.

Connected, diverse and extensive ecosystems can help stabilise the climate and will have a better chance of thriving in a world permanently altered by rising emissions, say experts. And, as the Royal Society paper says: “Rather than being framed as a victim of climate change, biodiversity can be seen as a key ally in dealing with climate change.” PW

The hidden threat of nitrogen: ‘Slowly eating away at biodiversity’

On the west coast of Scotland, fragments of an ancient rainforest that once stretched along the Atlantic coast of Britain cling on. Its rare mosses, lichens and fungi are perfectly suited to the mild temperatures and steady supply of rainfall, covering the crags, gorges and bark of native woodland. But nitrogen pollution, an invisible menace, threatens the survival of the remaining 30,000 hectares (74,000 acres) of Scottish rainforest, along with invasive rhododendron, conifer plantations and deer.

While marine plastic pollution in particular has increased tenfold since 1980 – affecting 44% of seabirds – air, water and soil pollution are all on the rise in some areas. This has led to pollution being singled out as the fourth biggest driver of biodiversity loss.

In Scotland, nitrogen compounds from intensive farming and fossil fuel combustion are dumped on the Scottish rainforest from the sky, killing off the lichen and bryophytes that absorb water from the air and are highly sensitive to atmospheric conditions.

“The temperate rainforest is far from the sources of pollution, yet because it’s so rainy, we’re getting a kind of acid rain effect,” says Jenny Hawley, policy manager at Plantlife, which has called nitrogen pollution in the air “the elephant in the room” of nature conservation. “The nitrogen-rich rain that’s coming down and depositing nitrogen into those habitats is making it impossible for the lichen, fungi, mosses and wildflowers to survive.”

Environmental destruction caused by nitrogen pollution is not limited to the Scottish rainforest. Algal blooms around the world are often caused by runoff from farming, resulting in vast dead zones in oceans and lakes that kill scores of fish and devastate ecosystems. Nitrogen-rich rainwater degrades the ability of peatlands to sequester carbon, the protection of which is a stated climate goal of several governments. Wildflowers adapted to low-nitrogen soils are squeezed out by aggressive nettles and cow parsley, making them less diverse.

About 80% of nitrogen used by humans – through food production, transport, energy and industrial and wastewater processes – is wasted and enters the environment as pollution.

“Nitrogen pollution might not result in huge floods and apocalyptic droughts but we are slowly eating away at biodiversity as we put more and more nitrogen in ecosystems,” says Carly Stevens, a plant ecologist at Lancaster University. “Across the UK, we have shown that habitats that have lots of nitrogen have fewer species in them. We have shown it across Europe. We have shown it across the US. Now we’re showing it in China. We’re creating more and more damage all the time.”

To decrease the amount of nitrogen pollution causing biodiversity loss, governments will commit to halving nutrient runoff by 2030 as part of an agreement for nature currently being negotiated in Kunming. Halting the waste of vast amounts of nitrogen fertiliser in agriculture is a key part of meeting the target, says Kevin Hicks, a senior research fellow at the Stockholm Environment Institute centre at York.

“One of the biggest problems is the flow of nitrogen from farming into watercourses,” Hicks says. “In terms of a nitrogen footprint, the most intensive thing that you can eat is meat. The more meat you eat, the more nitrogen you’re putting into the environment.”

Mark Sutton, a professor at the UK Centre for Ecology & Hydrology, says reducing nitrogen pollution also makes economic sense.

“Nitrogen in the atmosphere is 78% of every breath we take. It does nothing, it’s very stable and makes the sky blue. Then there are all these other nitrogen compounds: ammonia, nitrates, nitrous oxide. They create air and water pollution,” he says. He argues that if you price every kilo of nitrogen at $1 (an estimated fertiliser price), and multiply it by the amount of nitrogen pollution lost in the world – 200bn tonnes – it amounts to $200bn (£147bn) every year.

“The goal to cut nitrogen waste in half would save you $100bn,” he says. “I think $100bn a year is a worthwhile saving.” PG

• Invasive species

The problem for islands: ‘We have to be very careful’

On Gough Island in the southern Atlantic Ocean, scores of seabird chicks are eaten by mice every year. The rodents were accidentally introduced by sailors in the 19th century and their population has surged, putting the Tristan albatross – one of the largest of its species – at risk of extinction along with dozens of rare seabirds. Although Tristan albatross chicks are 300 times the size of mice, two-thirds did not fledge in 2020 largely because of the injuries they sustained from the rodents, according to the RSPB .

The situation on the remote island, 2,600km from South Africa, is a grisly warning of the consequences of the human-driven impacts of invasive species on biodiversity. An RSPB-led operation to eradicate mice from the British overseas territory has been completed, using poison to help save the critically endangered albatross and other bird species from injuries they sustain from the rodents. It will be two years before researchers can confirm whether or not the plan has worked. But some conservationists want to explore another controversial option whose application is most advanced in the eradication of malaria : gene drives.

Instead of large-scale trapping or poisoning operations, which have limited effectiveness and can harm other species, gene drives involve introducing genetic code into an invasive population that would make them infertile or all one gender over successive generations. The method has so far been used only in a laboratory setting but at September’s IUCN congress in Marseille, members backed a motion to develop a policy on researching its application and other uses of synthetic biology for conservation.

“If a gene drive were proven to be effective and there were safety mechanisms to limit its deployment, you would introduce multiple individuals on an island whose genes would be inherited by other individuals in the population,” says David Will, an innovation programme manager with Island Conservation , a non-profit dedicated to preventing extinctions by removing invasive species from islands. “Eventually, you would have either an entirely all male or entirely all female population and they would no longer be able to reproduce.”

Nearly one-fifth of the Earth’s surface is at risk of plant and animal invasions and although the problem is worldwide, such as feral pigs wreaking havoc in the southern United States and lionfish in the Mediterranean , islands are often worst affected. The global scale of the issue will be revealed in a UN scientific assessment in 2023.

“We have to be very careful,” says Austin Burt, a professor of evolutionary genetics at Imperial College London, who researches how gene drives can be used to eradicate malaria in mosquito populations. “If you’re going after mice, for example, and you’re targeting mice on an island, you’d need to make sure that none of those modified mice got off the island to cause harm to the mainland population.”

In July, scientists announced they had successfully wiped out a population of malaria-transmitting mosquitoes using a gene drive in a laboratory setting, raising the prospect of self-destructing mosquitoes being released into the wild in the next decade.

Kent Redford, chair of the IUCN Task Force on Synthetic Biology who led an assessment of the use of synthetic biology in conservation, said there are clear risks and opportunities in the field but further research is necessary.

“None of these genetic tools are ever going to be a panacea. Ever. Nor do I think they will ever replace the existing tools,” Redford says, adding: “There is a hope – and I stress hope – that engineered gene drives have the potential to effectively decrease the population sizes of alien invasive species with very limited knock-on effects on other species.” PG

Find more age of extinction coverage here , and follow biodiversity reporters Phoebe Weston and Patrick Greenfield on Twitter for all the latest news and features

• Biodiversity
• The road to Cop15
• Endangered species
• Endangered habitats
• Climate crisis
• Conservation

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WWF: These are the biggest threats to the Earth's biodiversity

Climate change was ranked as a 6% risk to Earth's biodiversity. Image:  Unsplash/Sid Balachandran

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Stay up to date:, nature and biodiversity.

• WWF’s Living Planet Report 2020 has ranked the biggest threats to Earth's biodiversity.
• The list includes climate change, changes in land and sea use and pollution.
• The WWF used data from over 4,000 different species.

The biggest threats to Earth’s biodiversity

Biodiversity benefits humanity in many ways.

It helps make the global economy more resilient, it functions as an integral part of our culture and identity, and research has shown it’s even linked to our physical health.

However, despite its importance, Earth’s biodiversity has decreased significantly over the last few decades. In fact, between 1970 and 2016, the population of vertebrate species fell by 68% on average worldwide. What’s causing this global decline?

Today’s graphic uses data from WWF’s Living Planet Report 2020 to illustrate the biggest threats to Earth’s biodiversity, and the impact each threat has had globally.

Measuring the loss of biodiversity

Before looking at biodiversity’s biggest threats, first thing’s first—how exactly has biodiversity changed over the years?

WWF uses the Living Planet Index (LPI) to measure biodiversity worldwide. Using data from over 4,000 different species, LPI tracks the abundance of mammals, birds, fish, reptiles, and amphibians across the globe.

Here’s a look at each region’s average decline between 1970 and 2016:

Latin America & Caribbean has seen the biggest drop in biodiversity at 94% . This region’s drastic decline has been mainly driven by declining reptile, amphibian, and fish populations.

Despite varying rates of loss between regions, it’s clear that overall, biodiversity is on the decline. What main factors are driving this loss, and how do these threats differ from region to region?

Biggest threats to biodiversity, overall

While it’s challenging to create an exhaustive list, WWF has identified five major threats and shown each threats proportional impact, averaged across all regions:

Across the board, changes in land and sea use account for the largest portion of loss, making up 50% of recorded threats to biodiversity on average. This makes sense, considering that approximately one acre of the Earth’s rainforests is disappearing every two seconds .

Species overexploitation is the second biggest threat at 24% on average, while invasive species takes the third spot at 13% .

Biggest threats to biodiversity, by region

When looking at the regional breakdown, the order of threats in terms of biodiversity impact is relatively consistent across all regions—however, there are a few discrepancies:

In Latin America and Caribbean, climate change has been a bigger biodiversity threat than in other regions, and this is possibly linked to an increase in natural disasters. Between 2000 and 2013, the region experienced 613 extreme climate and hydro-meteorological events, from typhoons and hurricanes to flash floods and droughts.

Another notable variation from the mean is species over-exploitation in Africa, which makes up 35% of the region’s threats. This is higher than in other regions, which sit around 18-27%.

While the regional breakdowns differ slightly from place to place, one thing remains constant across the board—all species, no matter how small, play an important role in the maintenance of Earth’s ecosystems.

Will we continue to see a steady decline in Earth’s biodiversity, or will things level out in the near future?

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Biodiversity and Its Conservation: Importance, Threats, Strategies

• Editor Desk
• June 15, 2023
• Biodiversity

Biodiversity , the variety of life on Earth, encompasses all forms of living organisms, including plants, animals, and microorganisms. It is the result of billions of years of evolution and plays a vital role in maintaining the health and balance of ecosystems. However, due to various human activities, biodiversity is facing unprecedented threats, making its conservation crucial for the survival of species and the sustainability of our planet. In this article, we will explore the significance of biodiversity, the current threats it faces, and the strategies and approaches employed in its conservation.

I. Importance of Biodiversity

Biodiversity is essential for the functioning of ecosystems and provides numerous benefits to humanity. It ensures ecological balance by regulating various ecological processes, such as nutrient cycling, water purification, and pollination. Biodiversity also contributes to the production of food, medicines, and raw materials, and supports cultural and aesthetic values. Furthermore, it enhances resilience to environmental changes and helps mitigate the impacts of climate change .

II. Threats to Biodiversity

• Habitat Loss: The destruction, fragmentation, and degradation of habitats due to deforestation, urbanization, and land conversion for agriculture and infrastructure development.
• Climate Change: Rising temperatures, changing precipitation patterns, and extreme weather events disrupt ecosystems, altering species’ distribution and abundance.
• Invasive Species: Non-native species introduced to new environments can outcompete native species, leading to their decline or extinction.
• Pollution: Pollution from various sources, such as industrial activities and agricultural runoff, can contaminate ecosystems, affecting biodiversity.
• Overexploitation: Unsustainable hunting, fishing, and harvesting practices can deplete populations of species, driving them towards extinction.

III. Conservation Strategies

• Protected Areas: Establishing and effectively managing protected areas, such as national parks and wildlife reserves, to safeguard habitats and species.
• Habitat Restoration: Rehabilitating degraded ecosystems by reforesting, wetland restoration, and implementing sustainable land management practices.
• Species Conservation: Implementing measures like captive breeding, habitat protection, and anti-poaching efforts to safeguard endangered species.
• Sustainable Practices: Encouraging sustainable agriculture, fisheries, forestry, and promoting responsible consumption to minimize negative impacts on biodiversity.
• Awareness and Education: Raising public awareness about the value of biodiversity and the need for its conservation through education and outreach programs.

Key Takeaways:

Conserving biodiversity is vital for sustaining life on Earth and ensuring a healthy and prosperous future. By understanding the importance of biodiversity, identifying the threats it faces, and implementing effective conservation strategies, we can work towards preserving our natural heritage and creating a more sustainable planet. It requires collective efforts from individuals, communities, governments, and international organizations to protect and restore biodiversity for the benefit of current and future generations. Let us embrace our responsibility as custodians of Earth’s biodiversity and take action to secure a thriving and diverse planet.

FAQs about Biodiversity and its Conservation:

What is biodiversity.

Biodiversity refers to the variety of life on Earth, including all living organisms, from plants and animals to microorganisms. It encompasses genetic, species, and ecosystem diversity.

Why is biodiversity important?

Biodiversity is crucial for the health and balance of ecosystems. It provides various ecosystem services like nutrient cycling, pollination, and water purification. Biodiversity also contributes to food production , medicine development, and supports cultural and aesthetic values.

What are the main threats to biodiversity?

The main threats to biodiversity include habitat loss due to deforestation and land conversion, climate change, invasive species, pollution, and overexploitation of natural resources.

What are protected areas?

Protected areas are designated regions, such as national parks, wildlife reserves, and marine sanctuaries, created to conserve biodiversity and preserve natural habitats. They often have legal protections to limit human activities that could harm the environment .

What is habitat restoration?

Habitat restoration involves the process of rehabilitating degraded ecosystems by restoring their natural features and functions. It may include activities like reforestation, wetland restoration, and implementing sustainable land management practices.

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• Published: 16 May 2022

Ranking threats to biodiversity and why it doesn’t matter

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• Biodiversity
• Macroecology

Conservation scientists have proposed several rankings of the relative importance of global threats to biodiversity. Here, we argue that relative ranking of biodiversity threats depends on local context and metrics used, and so has little application for conservation.

We are in an unprecedented crisis of biodiversity in human history. All evidence suggests that the current rates of extinctions vastly exceed the estimated background extinction rate. The major difference with the previous mass extinctions is that humans are simultaneously responsible for it, threatened by it, and able to stop it. More than 900 species across all taxa have been documented to go extinct since 1500, with probably as many as 400 bird species alone in prehistoric times 1 . For the scientific community, five main global threats are typically considered responsible of these losses: habitat destruction, over-exploitation, biological invasions, climate change, and pollution 2 , although many more local perturbations and stressors are also important.

Many individual researchers and agencies such as the Intergovernmental Science-Policy Platform on Biodiversity and Ecosystem Services (IPBES), International Union for Conservation of Nature (IUCN), and World Wide Fund for Nature (WWF) have recently ranked these global-threat categories in terms of their estimated contribution to biodiversity loss. For instance, biological invasions are deemed the primary cause of global species’ extinctions for birds, mammals, reptiles, freshwater fish, plants, arthropods, and gastropods, especially on islands 3 . Currently, more than 38,500 species are considered threatened with extinction, first by habitat loss and then overexploitation 4 . Recently, the IPBES published a ranking of these threats, with habitat change identified the most important threat, followed by overexploitation, climate change, pollution, and biological invasions 5 . Consequently, the global exercise of ranking threats at a global scale, although a natural tendency for scientists, has led to differing rankings. However, such a variability can misguide conservation responses depending on which ranking system is favored.

Threat rank is context-specific

The difficulties inherent in ranking global threats are due to them being context-dependent, which result from conditions and the nature of the threats themselves differing among locations, habitats, and taxa (Fig.  1 ). Current high-risk hotspots from habitat loss and overexploitation are primarily located in the tropics, whereas Europe is documented as a threat hotspot for pollution 6 . On islands, biological invasions mainly threaten biodiversity in the Pacific and Atlantic Oceans, while islands in the Indian Ocean and near the coasts of Asia are mostly threatened by overexploitation and agriculture 3 . Climate change affects species more at higher latitudes and altitudes because species are constrained by the physical environment (geographic barriers and mountain tops) to follow their optimal isotherms.

IPBES, WWF, and IUCN established global rankings of the five threats responsible for the current biodiversity crisis (B: central, yellow panel). However, the relative importance of each threat depends on the taxon, system, species’ characteristics, time, and/or the metric considered, resulting in divergences. Global biodiversity threats are represented by colors and symbols, given in the top panel. This figure encapsulates results combined from different studies detailed in Supplementary Table  1 with their associated references.

The relative importance of threats also depends on the taxon considered. At the global scale, vertebrates are primarily threatened by habitat loss, overexploitation, and then biological invasions. But even within the vertebrates rankings differ — birds and mammals are mainly affected by overexploitation, while amphibians have a higher probability of succumbing to habitat loss 6 . Because of species-specific traits and adaptations, some species are likely to respond differently to global threats even within a clade. Large-bodied vertebrates are more likely to be threatened by overexploitation, whereas small-bodied vertebrates are more prone to habitat loss or pollution (Fig.  1 ). Threat ranking also depends on the habitat under consideration. Marine mammals are more threatened by overexploitation and pollution than terrestrial mammals for which habitat loss is the primary threat (Fig.  1 ). On islands, habitat loss is secondary to the pressures of biological invasions in freshwater systems, but the former is more important for terrestrial vertebrates and plants 3 . Another source of uncertainty is that most studies examining threats are based on well-studied taxa such as terrestrial vertebrates, which only represent a small subset of the tree of life. For instance, only 0.2% of fungi, 1.7% of invertebrates, and 10% of described plants are assessed in the IUCN update of 2019 7 , potentially underestimating the intensity of some threats and biasing conservation priorities for these groups. Similarly, there is a bias of research effort towards regions with high-income countries, while research from low or middle-income countries is generally underrepresented 8 . This may give the false impression of absence of threats in some regions of the world.

Likewise, period-specific global threat ranks are subject to the vagaries of temporal dynamics (Fig.  1 ). However, distinguishing past, current, and future threats is essential for current or future conservation interventions. Historically, overexploitation caused most of the Pleistocene megafauna extinctions, likely exacerbated by climate change. As agricultural practices intensified, habitat loss played a major role in extinctions. As humans later colonized islands, biological invasions caused the extinction of hundreds of species worldwide 3 . In contrast, climate change is only predicted to become major in the near future 9 . In fact, the effects of recent threats might be masked by delayed species’ responses, especially in under-studied regions, resulting in a large extinction debt. For instance, the severity of biological invasions often causes native species to decline rapidly to local extinction, while other threats such as habitat loss might affect species more slowly. In both cases, the eventual extinctions are ultimately if similar magnitude.

Threat rank depends on the metric

The inconsistencies among different rankings also arise from the different methodologies applied and metrics used to assess biodiversity losses. The IUCN Classification Threat, one of the most used tools in ecology and conservation, is based on expert assessment and a list of quantitative criteria (i.e., population sizes and area of occupancy) to provide a species’ extinction probability. Adopted by the Convention of Biological Diversity (CBD), the WWF Living Planet Index assesses threats to biodiversity based on population time series of over 4000 vertebrate species. Recently, a new metric based on species’ extinction risk status, anthropogenic pressure, and country-scale mitigation measures has provided an interesting, complementary approach of congruence among species’ extinction risks and their exposure to threats 10 . However, most of the aforementioned metrics rely on species-level data that are often unavailable. Yet, because biodiversity is a multidimensional concept, including genetic, functional, and taxonomic diversities, it is important for threat assessments to consider all dimensions. Attempting to be more integrative, the IPBES proposed a new ranking based on eleven different metrics, from species populations (e.g., Living Planet Index, local species richness) and traits (e.g., mean body length) to ecosystem structure (e.g., mangrove forest, percentage of live coral cover) 5 . Those multiple metrics result in different rankings according to the scale considered. For instance, habitat loss and degradation appear to be important for explaining changes at the population level (i.e., Living Planet and Red List indices), while pollution is among the most important threats of changes of ecosystem structure (e.g., % live coral cover) (Fig.  1 ). Some of these metrics are less appropriate to emphasize certain threats. For example, species traits like mean body length of fish is mostly driven by overexploitation 11 , while biological invasion had little effect on this trait, or on the percentage of live coral cover. Moreover, each threat is in fact multifaceted. For instance, climate change includes sea-level rise, altered precipitation, increase of extreme events, and some of which may even have opposite effects on certain species. For example, some plants may benefit from CO2 increases while suffering from changed in precipitation regime. As a consequence, the definition of threat itself may lead to various rankings.

Conservation implications of ranking threats

The tendency to rank biodiversity threats is not entirely due to the tendency of scientists to ordinate factors or to their relevance to justify studies of the greatest threats. It is also driven by practical considerations. Rankings are in fact commonly applied to establish priorities for conservation interventions, especially by policy makers 12 . For instance, comparative studies have successfully prioritized the conservation of some populations, species, or sites at local scales 12 . Global analyses and rankings can also guide governments and other actors, and offer leverage to implement measures with limited funding. By ranking individual threats independently, scientists implicitly prioritize the top threats and classify others as lower concern. However, ranking global threats by considering each threat independently is likely to underestimate the full consequences to biodiversity worldwide. A recent study showed that the nature of the threat is almost irrelevant when species are exposed to multiple threats simultaneously, as multiple threats exacerbate the loss of resilience in vertebrate populations 13 . Threatened insular species are currently exposed to an average of 2.6 different threats 3 , and according to the IUCN 80% of species are exposed to more than one threat threatened species 4 . In this context, we expect cumulative effects among global change drivers, which may result in unexpected interactions such as synergies or antagonistic interactions. This further weakening the usefulness of independent ranking.

Perspectives and potential opportunities

By over-synthesizing the relative prevalence of threats across juxtaposed contexts, taxa, times, and metrics, these macroecological analyses confuse messages to the public, the media, and policy makers in terms of where and when biodiversity losses occur, and which factors are responsible 14 . Instead, global assessments in conservation should offer synthetic views on how threats operate in combination to threaten biodiversity. New developments in databases and tools could provide advances in conservation evaluation 15 . For instance, network analyses 3 or cumulative-impact approaches 16 can consider multiple threats simultaneously. But exposure to threats alone provides only partial information on conservation needs. New approaches assessing species’ vulnerability to global changes by simultaneously considering exposure to the intensity of the threats, variable sensitivity, and different adaptive capacity are also a valuable change of paradigm 17 .

Because the ultimate objective is to lessen the severity of the biodiversity crisis driven by combination of major threats, we might even need to reconsider the actual usefulness of global threat ranks. Ranking the potential benefits of conservation actions would certainly have more impact that only ranking threats. Providing policy makers with a range of conservation scenarios with their predicted biodiversity outcomes, which consider the multiple sources of stress, different metrics, and variation across taxa, could provide a more realistic description of the state of biodiversity and maximize conservation outcomes. While international biodiversity-conservation instruments derived by the CBD, IPBES, IUCN, and others are exceptional tools to monitor and assess biodiversity, the disparities among rankings create a reductive and oversimplified perspective of the multiple threats underlying the current biodiversity crisis. This could also precipitate unsubstantiated priorities in conservation. Although useful to highlight areas of concern, we argue instead for considering the specificities, complexities, and interactions among threats to tackle this global crisis and for communicating more strategically with policymakers about the limits of global rankings.

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We are grateful for the precious edits and comments provided by Corey Bradshaw and Pol Capdevilla on a previous version of the manuscript.

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Bellard, C., Marino, C. & Courchamp, F. Ranking threats to biodiversity and why it doesn’t matter. Nat Commun 13 , 2616 (2022). https://doi.org/10.1038/s41467-022-30339-y

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How does climate change affect biodiversity?

The environmental changes being driven by climate change are disturbing natural habitats and species in ways that are still only becoming clear. There are signs that rising temperatures are affecting biodiversity, while changing rainfall patterns, extreme weather events, and ocean acidification are putting pressure on species already threatened by other human activities. 

The threat posed by climate change to biodiversity is expected to increase, yet thriving ecosystems also have the capacity to help reduce the impacts of climate change. 

If current rates of warming continue, by 2030 global temperatures could increase by more than 1.5°C (2.7°F) compared to before the industrial revolution. A major impact of  climate change on biodiversity is the increase in the intensity and frequency of fires, storms or periods of drought. In Australia at the end of 2019 and start of 2020, 97,000km2 of forest and surrounding habitats were destroyed by intense fires that are now known to have been made worse by climate change. This adds to the threat to biodiversity which has already been placed under stress by other human activities.  It is thought that the number of threatened species in the area may have increased by 14% as a result of the fires. 

Rising global temperatures also have the potential to alter ecosystems over longer periods by changing what can grow and live within them. There is already evidence to suggest that reductions in water vapour in the atmosphere since the 1990s has resulted in 59% of vegetated areas showing pronounced browning and reduced growth rates worldwide.

Rising temperatures in the oceans affect marine organisms. Corals are particularly vulnerable to rising temperatures and ocean acidification can make it harder for shellfish and corals in the upper ocean to form shells and hard skeletons. We have also seen changes in occurrence of marine algae blooms. Despite the threats posed by climate change to biodiversity, we also know that natural habitats play an important role in regulating climate and can help to absorb and store carbon. Mangroves are significant sinks for carbon and the Amazon is one of the most biologically diverse places on the planet and is an enormous store of carbon – up to 100 billion tons, although a recent study has suggested the Amazon may now be emitting more carbon than it absorbs. Safeguarding these natural carbon sinks from further damage is an important part of limiting climate change.

To find out more: Past and future decline and extinction of species | Royal Society ; Why efforts to address climate change through nature-based solutions must support both biodiversity and people | Royal Society ; Amazonia’s future: Eden or degraded landscapes? | Royal Society ; Evidence & Causes of Climate Change | Royal Society

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10: Threats to Biodiversity

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• Melissa Ha and Rachel Schleiger
• Yuba College & Butte College via ASCCC Open Educational Resources Initiative

Chapter Hook

The northern spotted owl ( Strix occidentalis caurina ) is a western North American owl species that prefers large swaths of pristine old growth forests (that typically take 150-200 years to mature) for nesting. Unfortunately, most western forests have been regularly harvested for timber since around the establishment of the Forest Service in 1905. Thus, this species preferred habitat has been largely destroyed and their populations have plummeted. Habitat destruction is the number one cause for species extinction globally. For some species that are very habitat specific, like the northern spotted owl, there are not as many conservation actions to choose from that can help reverse declining population trends.

Figure \(\PageIndex{a}\) Northern spotted owl perched in a tree. Image by USFS (licensed under CC-BY 2.0 )

Biodiversity loss refers to the reduction of biodiversity due to displacement or extinction of species. The loss of a particular individual species may seem unimportant to some, especially if it is not a charismatic species like the Bengal tiger or the bottlenose dolphin. However, biologists estimate that species extinctions are currently many times higher the normal, or background, rate seen previously in Earth’s history. This translates to the loss of tens of thousands of species within our lifetimes. This is likely to have dramatic effects on human welfare through the collapse of ecosystems. Loss of biodiversity may have reverberating consequences on ecosystems because of the complex interrelations among species. For example, the extinction of one species may cause the extinction of another. To measure biodiversity loss, scientists assess which species are at risk of extinction as well as survey ecosystem decline. 

The core threat to biodiversity on the planet is the combination of human population growth and the resources used by that population. The human population requires resources to survive and grow, and many of those resources are being removed unsustainably from the environment. The five main threats to biodiversity are habitat loss, pollution, overexploitation, invasive species, and climate change. Increased mobility and trade has resulted in the introduction of invasive species while the other threats are direct results of human population growth and resource use.

Attribution

133 Biodiversity Topics & Examples

🔝 top-10 biodiversity topics for presentation, 🏆 best biodiversity project topics, 💡 most interesting biodiversity assignment topics, 📌 simple & easy biodiversity related topics, 👍 good biodiversity title ideas, ❓ biodiversity research topics.

• Biodiversity loss.
• Global biodiversity conservation.
• The Amazon rainforest.
• Animal ecology research.
• Sub Saharan Africa.
• Marine biodiversity.
• Threats to ecosystems.
• Plant ecology.
• Importance of environmental conservation.
• Evolution of animal species.
• Biodiversity Hotspots: The Philippines The International Conservation has classified the Philippines as one of the biodiversity hotspots in the world. Additionally, the country is said to be one of the areas that are endangered in the world.
• Aspects, Importance and Issues of Biodiversity Genetic diversity is a term used to refer to the dissimilitude of organisms of the same species. Species diversity is used to refer to dissimilitude of organisms in a given region.
• Biodiversity Benefits for Ecology This variation of species in the ecosystem is a very important concept and factor that indeed is the basis for sustaining life on our planet. Moreover, the most important supporter of life, which is soil […]
• Habitat Destruction and Biodiversity Extinctions The instance of extinction is by and large regarded as the demise of the very last character of the genus. Habitat obliteration has played a major part in wiping out of species, and it is […]
• How Biodiversity Is Threatened by Human Activity Most of the marine biodiversity is found in the tropics, especially coral reefs that support the growth of organisms. Overexploitation in the oceans is caused by overfishing and fishing practices that cause destruction of biodiversity.
• Biodiversity Conservation: Tropical Rainforest The forest is not a threat to many species and that, therefore, helps in showing that conserving this forest will be of great benefit to many species. The disadvantage of conserving the Mangrove Forest is […]
• Loss of Biodiversity and Extinctions It is estimated that the number of species that have become extinct is greater than the number of species that are currently found on earth.
• Natural Sciences: Biodiversity and Human Civilisation The author in conjunction with a team of other researchers used a modelling study to illustrate the fact approximately 2 percent of global energy is currently being deployed in the generation of wind and solar […]
• How Human Health Depends on Biodiversity The disturbance of the ecosystem has some effects on the dynamics of vectors and infectious diseases. Change of climate is a contributing factor in the emergence of new species and infectious diseases.
• The Importance of Biodiversity in Ecosystem The most urgent problem right now is to maintain the level of biodiversity in this world but it has to begin with a more in-depth understanding of how different species of flora and fauna can […]
• Biodiversity: Aspects Within the Sphere of Biology Finally, living objects consist of cells, which are the basic units of their function and structure. The viruses’ structure depends on which nucleic acid is included, which denotes that there are DNA and RNA viruses.
• Coral Reef and Biodiversity in Ecosystems Coral reefs are formed only in the tropical zone of the ocean; the temperature limits their life – are from +18 to +29oS, and at the slightest deviation from the boundaries of the coral die.
• Biodiversity and the Health of Ecosystems Various opinions are revealed concerning biodiversity, including the human impact, reversal of biodiversity loss, the impact of overpopulation, the future of biodiversity, and the rate of extinction.
• Wild Crops and Biodiversity Threats However, out of millions of existing types of wild crop cultures, the vast majority have been abandoned and eradicated, as the agricultural companies placed major emphasis on the breeding of domesticated cultures that are easy […]
• Biology Lab Report: Biodiversity Study of Lichens As a consequence of these results, the variety of foods found in forest flora that include lichens may be linked to varying optimum conditions for establishment and development.
• Biodiversity, Interdependency: Threatened and Endhangered Species In the above table, humans rely on bees to facilitate pollination among food crops and use their honey as food. Concurrently, lichens break down rocks to provide nutrient-rich soil in the relationship.
• Invasive Processes’ Impact on Ecosystem’s Biodiversity If the invasive ones prove to be more adaptive, this will bring about the oppression of the native species and radical changes in the ecosystem.
• Conserving Biodiversity: The Loggerhead Turtle The loggerhead sea turtle is the species of oceanic turtle which is spread all over the world and belongs to the Cheloniidae family.
• Biodiversity and Dynamics of Mountainous Area Near the House It should be emphasized that the term ecosystem used in this paper is considered a natural community characterized by a constant cycle of energy and resources, the presence of consumers, producers, and decomposers, as well […]
• National Biodiversity Strategy By this decision, the UN seeks to draw the attention of the world community and the leaders of all countries to the protection and rational use of natural resources.
• Rewilding Our Cities: Beauty, Biodiversity and the Biophilic Cities Movement What is the source of your news item? The Guardian.
• Biodiversity and Food Production This paper will analyze the importance of biodiversity in food production and the implications for human existence. Edible organisms are few as compared to the total number of organisms in the ecosystem.
• Restoring the Everglades Wetlands: Biodiversity The Act lays out the functions and roles of the Department of Environmental Protection and the South Florida Water Management District in restoration of the Everglades.
• Biodiversity: Importance and Benefits This is due to the fact that man is evolving from the tendency of valuing long term benefits to a tendency of valuing short terms benefits.
• A Benchmarking Biodiversity Survey of the Inter-Tidal Zone at Goat Island Bay, Leigh Marine Laboratory Within each quadrant, the common species were counted or, in the case of seaweed and moss, proliferation estimated as a percentage of the quadrant occupied.
• Ecological Consequences Due to Changes in Biodiversity The author is an ecologist whose main area of interest is in the field of biodiversity and composition of the ecosystem.
• Biodiversity: Population Versus Ecosystem Diversity by David Tilman How is the variability of the plant species year to year in the community biomass? What is the rate of the plant productivity in the ecosystem?
• Biodiversity Hotspots and Environmental Ethics The magnitude of the problem of losing biodiversity hotspots is too great, to the extend of extinction of various species from the face of the earth.
• Natural Selection and Biodiversity These are featured by the ways in which the inhabiting organisms adapt to them and it is the existence of these organisms on which the ecosystems depend and therefore it is evident that this diversity […]
• Scientific Taxonomy and Earth’s Biodiversity A duck is a domestic bird that is reared for food in most parts of the world. It is associated with food in the household and is smaller than a bee.
• Global Warming: Causes and Impact on Health, Environment and the Biodiversity Global warming is defined in simple terms as the increase in the average temperature of the Earth’s surface including the air and oceans in recent decades and if the causes of global warming are not […]
• Loss of Biodiversity in the Amazon Ecosystem The growth of the human population and the expansion of global economies have contributed to the significant loss of biodiversity despite the initial belief that the increase of resources can halt the adverse consequences of […]
• California’s Coastal Biodiversity Initiative The considered threat to California biodiversity is a relevant topic in the face of climate change. To prevent this outcome, it is necessary to involve the competent authorities and plan a possible mode of operation […]
• Biodiversity: American Museum of Natural History While staying at the museum, I took a chance to visit the Milstein Family Hall of Ocean Life and the Hall of Reptiles and Amphibians.
• Biodiversity and Animal Population in Micronesia This means that in the future, the people living in Micronesia will have to move to other parts of the world when their homes get submerged in the water.
• Urban Plants’ Role in Insects’ Biodiversity The plants provide food, shelter and promote the defensive mechanisms of the insects. The observation was also an instrumental method that was used to assess the behavior and the existence of insects in relation to […]
• Earth’s Biodiversity: Extinction Rates Exaggerated This is because most animals and plants have been projected to be extinct by the end of this century yet the method that is used to forecast this can exaggerate by more than 160%.
• Biodiversity Markets and Bolsa Floresta Program Environmentalists and scholars of the time led by Lord Monboddo put forward the significance of nature conservation which was followed by implementation of conservation policies in the British Indian forests.
• Brazilian Amazonia: Biodiversity and Deforestation Secondly, the mayor persuaded the people to stop deforestation to save the Amazon. Additionally, deforestation leads to displacement of indigenous people living in the Amazonia.
• Defining and Measuring Biodiversity Biodiversity is measured in terms of attributes that explore the quality of nature; richness and evenness of the living organisms within an ecological niche.
• Biodiversity, Its Importance and Benefits Apart from that, the paper is going to speculate on the most and least diverse species in the local area. The biodiversity can be measured in terms of the number of different species in the […]
• Biodiversity, Its Evolutionary and Genetic Reasons The occurrence of natural selection is hinged on the hypothesis that offspring inherit their characteristics from their parents in the form of genes and that members of any particular population must have some inconsiderable disparity […]
• Climate Change’s Negative Impact on Biodiversity This essay’s primary objective is to trace and evaluate the impact of climate change on biological diversity through the lens of transformations in the marine and forest ecosystems and evaluation of the agricultural sector both […]
• Biodiversity Hotspots: Evaluation and Analysis The region also boasts with the endangered freshwater turtle species, which are under a threat of extinction due to over-harvesting and destroyed habitat.
• Marine Biodiversity Conservation and Impure Public Goods The fact that the issue concerning the global marine biodiversity and the effects that impure public goods may possibly have on these rates can lead to the development of a range of externalities that should […]
• Biodiversity and Business Risk In conclusion, biodiversity risk affects businesses since the loss of biodiversity leads to: coastal flooding, desertification and food insecurity, all of which have impacts on business organizations.
• Measurement of Biodiversity It is the “sum total of all biotic variation from the level of genes to ecosystems” according to Andy Purvus and Andy Hector in their article entitled “Getting the Measure of Diversity” which appeared in […]
• Introduced Species and Biodiversity Rhymer and Simberloff explain that the seriousness of the phenomenon may not be very evident from direct observation of the morphological traits of the species.
• Ecosystems: Biodiversity and Habitat Loss The review of the topic shows that the relationship between urban developmental patterns and the dynamics of ecosystem are concepts that are still not clearly understood in the scholarly world as well as in general.
• When Human Diet Costs Too Much: Biodiversity as the Ultimate Answer to the Global Problems Because of the unreasonable use of the natural resources, environmental pollution and inadequate protection, people have led a number of species to extinction; moreover, due to the increasing rates of consumerist approach towards the food […]
• The Impact of Burmese Pythons on Florida’s Native Biodiversity Scientists from the South Florida Natural Resource Center, the Smithsonian institute and the University of Florida have undertaken studies to assess the predation behavior of the Burmese pythons on birds in the area.
• Essentials of Biodiversity At the same time, the knowledge and a more informed understanding of the whole concept of biodiversity gives us the power to intervene in the event that we are faced by the loss of biodiversity, […]
• Threat to Biodiversity Is Just as Important as Climate Change This paper shall articulate the truth of this statement by demonstrating that threats to biodiversity pose significant threat to the sustainability of human life on earth and are therefore the protection of biodiversity is as […]
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Essay on Biodiversity for Students and Children

500+ words essay on biodiversity.

Essay on Biodiversity – Biodiversity is the presence of different species of plants and animals on the earth. Moreover, it is also called biological diversity as it is related to the variety of species of flora and fauna. Biodiversity plays a major role in maintaining the balance of the earth.

Furthermore, everything depends upon the biological diversity of different plants and animals. But due to some reasons, biodiversity is decreasing day by day. If it does not stop then our earth could no longer be a place to live in. Therefore different measures help in increasing the biodiversity of the earth.

Methods to Increase Biodiversity

Building wildlife corridors- This means to build connections between wildlife spaces. In other words, many animals are incapable to cross huge barriers. Therefore they are no able to migrate the barrier and breed. So different engineering techniques can make wildlife corridors. Also, help animals to move from one place to the other.

Set up gardens- Setting up gardens in the houses is the easiest way to increase biodiversity. You can grow different types of plants and animals in the yard or even in the balcony. Further, this would help in increasing the amount of fresh air in the house.

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Protected areas- protected areas like wildlife sanctuaries and zoo conserve biodiversity. For instance, they maintain the natural habitat of plants and animals. Furthermore, these places are away from any human civilization. Therefore the ecosystem is well maintained which makes it a perfect breeding ground for flora and fauna. In our country, their various wildlife sanctuaries are build that is today spread over a vast area. Moreover, these areas are the only reason some of the animal species are not getting extinct. Therefore the protected areas should increase all over the globe.

Re-wilding – Re-wilding is necessary to avert the damage that has been taking place over centuries. Furthermore, the meaning of re-wilding is introducing the endangered species in the areas where it is extinct. Over the past years, by various human activities like hunting and cutting down of trees the biodiversity is in danger. So we must take the necessary steps to conserve our wildlife and different species of plants.

Importance of Biodiversity

Biodiversity is extremely important to maintain the ecological system. Most Noteworthy many species of plants and animals are dependent on each other.

Therefore if one of them gets extinct, the others will start getting endangered too. Moreover, it is important for humans too because our survival depends on plants and animals. For instance, the human needs food to survive which we get from plants. If the earth does not give us a favorable environment then we cannot grow any crops. As a result, it will no longer be possible for us to sustain on this planet.

Biodiversity in flora and fauna is the need of the hour. Therefore we should take various countermeasures to stop the reduction of endangering of species. Furthermore, pollution from vehicles should decrease. So that animals can get fresh air to breathe. Moreover, it will also decrease global warming which is the major cause of the extinction of the species.

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Essay on Biodiversity

List of short and long essays on biodiversity, biodiversity essay for kids and school students, essay on biodiversity – essay 1 (150 words), essay on biodiversity: types, importance and conclusion – essay 2 (250 words), essay on biodiversity: with threats and importance – essay 3 (300 words), essay on biodiversity: introduction, importance, decline and steps – essay 4 (400 words), essay on biodiversity – essay 5 (500 words), biodiversity essay for competitive exam and upsc civil services exam, essay on biodiversity: with conclusion – essay 6 (600 words), essay on biodiversity: facts, importance and preservation – essay 7 (750 words), essay on biodiversity in india – essay 8 (1000 words).

Introduction:

Biodiversity also known as biological diversity is the variables that exist among several species living in the ecosystem. These living organisms include marine, terrestrial and aquatic life. Biodiversity aims to understand the positions these organisms occupy in the broader ecosystem.

Importance of Biodiversity:

When there is biodiversity in our ecosystem it translates to a greener environment. This is because plant life thrives in a balanced ecosystem. This invariably affects humans as we consume plants for our survival. Also, a healthy ecosystem can help to reduce the risk of diseases and the way we respond to them.

Increasing Biodiversity:

Some changes could be encouraged to improve biodiversity in our environment.

Some of them are:

1. Stopping penetration of invasive alien species.

2. Using sustainable agricultural methods.

3. Having protected areas for spices to thrive.

4. Having an organic maintenance culture for fertilizers.

Conclusion:

To make the world a safe place for all organisms, we must maintain good health in all the ecosystems. This is the benefit of paying attention to biodiversity.

Diversity is the hallmark of nature. Things exist in different forms which creates diversity. Biodiversity is a significant and desirable variation in plant and animal existence on the surface of the earth. The variation exists due to genetics, species and the ecosystem or the habitat. Biodiversity is an important aspect in the world because it enables the survival and sustainability of living things on earth.

Types of Biodiversity:

The variation in living things has resulted in different types of biodiversity depending on the certain variables. Genetic diversity is due to the genetic components shared by living organisms. The species that have similar genes diverge and they develop differently thus creating biodiversity. Species diversity occurs when a habitat comprises different kinds of living things. Ecological diversity is through the interaction of living things that share common sources of energy in an ecosystem which contributes to biodiversity.

The existence of living things in an ecosystem and the functioning of the ecosystem contribute to the relevance of biodiversity in nature. Through biodiversity, living organisms are able to acquire food and other important resources to sustain their lives. The climate and environmental changes are regulated because of biodiversity. The culture is enriched through biodiversity as it involves existence of several groups of species and people in one environment.

All the three types of biodiversity are important to the existence of living organisms. The ecosystem is the hallmark of diversity because it helps to sustain the lives of diverse living things.

Biodiversity is the variability or the diversity of the different species of life forms. The planet earth is habitat for a wide variety of flora and fauna like plants, animals and other life forms.

What is Biodiversity?

Biodiversity or Biological diversity refers to the variety and variability of living beings on planet earth and it is the degree of variation of life. It represents the wealth of biological assets available on earth and encompasses microorganism, plants, animals and ecosystems such as coral reefs, forests, rainforests, deserts etc.

Threats to Biodiversity:

The growing population, industrialization, technology, etc., all are impacting biodiversity. The increased human activities have been reducing the natural area for plants, animals and other living things. A number of plants and animals have gone extinct because of increased deforestation and other factors. Growing pollution, causing global warming and climate change, is a big threat to biodiversity. The decline in biodiversity would in turn lead to imbalance in the ecosystem and would become a threat to the human race as well as other living organisms.

Different plants and animals are dependent on others to live and keep the natural surroundings in a balanced state. For example, human beings are dependent on various plants and animals for their food, shelter, safety, clothes etc. Similarly, every living species is dependent on some other species. It is, therefore, important to preserve biodiversity in our planet in order to maintain the ecological balance.

Protecting Biodiversity:

As we know, the biodiversity loss is a serious threat for human race, we all should work for maintaining biodiversity, and find out solutions to reduce the biodiversity decline. Since, air pollution and deforestation are major threats to biodiversity, these are the first things that need to be controlled. Government should frame stricter laws and organizations should sensitize people to be concerned about it and contribute their bit.

Biodiversity, also referred to as the biological diversity refers to the diversified form of plants and animals that exists in our planet . It also denotes each and every aspect of the ecosystem such as micro-organisms, coral reefs, rainforests, deserts, forests etc.,

A good balance in biodiversity supports human race and humans on the other hand must ensure to save biodiversity. This essay is going to talk about the importance of biodiversity and the role of human beings in safeguarding the ecosystem.

There are more than 300,000 species of flora that has been identified and there should be many more unidentified varieties. Similarly there must be infinite variety of other species in our Earth and these together form a perfect natural protection for the human race. Biodiversity supports human race in different ways.

Few of them are listed below:

1. Some of the species capture and stores energy and releases it back in the atmosphere for human consumption.

2. Some biological species help in decomposing organic materials and thus acts as a natural recycling agent.

3. Plants and trees help in reducing pollution and maintain the purity of atmospheric air.

4. It is from the biological resources that humans receive food and shelter.

5. The astonishing beauty of biodiversity is the base for tourism industry to flourish.

Decline in Biodiversity:

The Earth’s biodiversity is undergoing a severe decline and this is a great threat to the human race. There are several factors that lead to the decline in biological species, the most significant one being the behavior of human beings.

1. Human beings destroy forests to build houses and offices. Through deforestation humans are actually destroying the natural habitat of many plants and animals.

2. All new scientific inventions are causing harm to the environment. We cannot even find some species of birds today because of the increase in noise pollution.

3. Global warming is another reason for the decline in biodiversity. Some species require specific climate to survive and when the climatic conditions change continuously these species either migrate or become extinct. Decline in the number of coral reefs are a perfect example.

Steps to Be Taken:

The Government and different voluntary organizations must act upon immediately to create awareness among people on environmental issues and its consequences. It is also the responsibility of every common man to save mother Earth by maintaining a rich biodiversity .

If proper care is not taken, the biodiversity of Earth may become extinct one day and if it happens then, humans have to find another planet to live. It’s better to act now before it gets too late.

Biodiversity can be said to mean the extreme importance of a very wide variety of animals and plants that are resident on the planet earth or in a particular habitat. It is very necessary to maintain the level of biodiversity on the earth so that the environmental harmony can be balanced. Biological diversity is another name for biodiversity and is widely the variability or diversity of all the different species of animals and plants on this planet. Having a very high biodiversity is extremely essential to help maintain the surroundings in a state of harmony. Biodiversity can be loosely defined as a variety of fauna and flora that are available in a specific habitat or the planet earth. Biodiversity is largely originated from the terms – species diversity and species richness.

Biodiversity is mainly a united view of the biological varieties. A lot of other words and terms have been at one time or another used to explain diversity. Some of these terms include taxonomic diversity (this comes from a species diversity point of view), ecological diversity (this comes from an ecosystem diversity point of view), morphological diversity (this comes from a genetic diversity point of view) and functional diversity (this comes from the point of view of the functions of the species). Biodiversity gives quite a uniform view of the above discussed biological varieties.

Biological diversity is quite important because its helps maintain the ecological balance in a system. Different animals and plants depend on one another to fulfill all of their needs. For example, we human beings depend on various animals and plants for our clothes, shelter and food. Other species also do the same and depend on a variety of other species to sustain them and provide them with the basics. Biodiversity and its beautiful richness ensure that the earth is fit enough for the survival of each and every one of the organism living on the earth. However, the ever increasing pollution is negatively affecting biodiversity. Quite a lot of animals and plants have gone into extinction as a result of this pollution and a lot more are going to become extinct if proper care is not taken and the pollution of the environment continues to exponentially and this would cause a sharp decline in the biodiversity.

We human beings have to understand how important the maintenance of the immensely rich biodiversity is. Smokes from vehicles causes a high rate of air pollution and this causes harm to a lot of species. The level of pollution in the atmosphere has to be put under control. Water bodies like seas, oceans and rivers are polluted by the release of industrial wastes into the. These wastes are very harmful to the marine organism and life in the water bodies. There is therefore a need to try as much as possible to dispose industrial wastes through other means and methods that do not harm the environment. The industrial wastes can be primarily treated before being disposed into the water properly and safely.

When you are a biology student biodiversity is one of the most important words you can learn. Not only that but it also becomes your lives calling to maintain it. But let’s not get ahead of ourselves before we can understand why it is important, we need to understand what it is.

This term refers to the many different life forms that inhabit the earth at this moment, this includes bacteria, plants, animals and humans and it also refers to their shared environment. Life has manifested itself in many different forms we do not know why exactly but we are certain that they all exist and depend on each other for survival.

Why is biodiversity important?

The answer to this question is more important than just simply stating what biodiversity is. My personal experience as a student has thought me that I learn best when I have an example so I will give you an example of the importance of biodiversity.

The famous Yellowstone Park is a natural reserve and national park but before it was declared as such it was just another forest that man wanted to hunt in. The geographical region had many wolfs inhabiting its plains, for generations they were hunted until they became extinct in the region. After a while, the coyotes began to reproduce as they hade more space and they started hunting the small mammals, which lead to a decrease in the population of eagles in the area but the most significant change came because of the deer. After fifty years of no wolfs in the park the number of roe deer rose and since they had no natural predators, they no longer feared open grasslands. That’s when they started grazing extensively which depleted the grass on the shore of the Yellow stone river and this, in turn, made the soil loos. The river began to take away a lot of soil and to deposit it in other places flooding certain areas while at the same time causing droughts to happen in other places.

Biologists came to the park with a wish to restore its wolf population and after a decade of planning and working they restored one pack to the park. The pack soon made the deer go back to the forest so they could be harder to hunt, the coyote’s population dropped because they couldn’t compete with the wolf, that led to the increase of small rodents which let to the return of carnivores’ grate birds. But above all the grazing on the river edge stopped and after a few years, the Yellowstone river returned to its natural flow.

This story is completely true and I love to use it as an example of the importance of maintaining biodiversity. There are many regions in the world that have similar problems and if we do not do our best to conserve biodiversity, we could be looking at similar or even worst natural catastrophes.

People tend to mass produce and they do this with most things. They will destroy a forest of many thousands of life forms to make a plantation with one single plant, the same is true of animal farming. With our need to be productive all the time we lose sight of the small things that make the system function as whole. Even though an insignificant thing as a bug or a wolf pack might seem the least important for our daily lives once we take them out of the picture, we see that the balance and wealth biodiversity gives to the planet is not something that can be easily compensated.

The genetic, species and ecosystem variability of flora and fauna on earth are known as Biodiversity. For painting what exactly is Biodiversity, we need a large canvas beyond imagination. Such is the volume of the subject. But, the actual meaning and terms are still not clear.

Keeping it very simple and to the point, the term ‘Biodiversity’ comprises of two words. The first word is Bio, and the other one is Diversity. Bio means the forms of life and Diversity means mixture or variety. So, when both the words combine they form a definition like this ‘Biodiversity means various and mixed forms of life on earth.’ The variety of life forms on earth includes plants and animals and their natural habitat.

Facts about Biodiversity:

Digging into the term ‘Biodiversity’ more generously makes us realize that we have over 10,000 species of birds on earth. The amazing number blows everyone’s mind. Insects have a different counting, and their species are in millions. Plants are also a part of this biological system, and hence there are more than 20,000 species of plants.

Even after so many species of plants, animals and insects have specified there are still over millions of species which are not known by anyone. These species cannot be counted under any head as they don’t pursue an identity. The actual picture says that earth is home to almost 50 million species or even more than that. These facts do not conclude the point because one or the other day there may be many new species evolving.

Biodiversity is essential for survival. The importance of Biodiversity not only related to plants, animals and natural habitat. But it also provides us so many natural products such as fibre and timber and the fresh water to carry out our daily lives. Therefore we need to understand the importance of Biodiversity.

1.   The natural and organic resources:

In the happiness of living our lives, we often forget that Biodiversity is a part of nature. We should protect it no matter whatever be the limitations. Mother Nature has provided us with enough resources which are the Biological Resources. These include wood, medicines, food, etc., which are direct blessings of Biological System or by-product of the Biological Systems. Herbs and plants play a vital role in producing medicines. They may get their final touch from the pharmaceutical companies, but the original source is plants which are again a part of Biodiversity.

2. Biodiversity provides fibres:

It is important to know that wool, jute, palms, etc., use to produce various types of fibres after processing which are again part of the Biological Systems. So, if biodiversity does not persist how people will have access to these fibres? Flax plants use for the production of linen, which is extensively using for making clothes. Similarly, Corchorus plants and Agave plants are using for the production of Jute and sisal respectively. These fibres are no doubt essential for the cloth industry. Therefore it becomes our duty to maintain the Biodiversity.

3. Powerful benefits of Biodiversity:

People may not be aware of the importance, but there are many spiritual benefits of biodiversity. Our folk dances, mythology, and history have a deep link with the Biodiversity in one or the other way. Everyone enjoys or experience the Biodiversity in a different format. Biological diversity also contributes to attracting tourists, especially flora and fauna, which is a rare phenomenon in cities. Therefore it is our ethical duty to preserve Biodiversity.

Preserve Biodiversity:

There are different ways in which we can preserve our Biological environment. Biodiversity should be protected by following these ways.

i. People should stop the process of hunting and poaching the animals. They are a part of Biodiversity.

ii. Protection of endangered species and their surroundings.

iii. We need to curb pollution for protecting Biodiversity.

iv. The explosive growth of population is a threat to Biodiversity. So, to maintain the biological balance, we need to have the population growth under control. Otherwise, people will be exploiting natural resources unethically for survival.

All steps must be taken to protect biodiversity. Things may seem difficult in the initial stages but practicing them will lead to genuine results. Creating awareness on environmental issues and the negative impact of the loss of biodiversity will let people understand the inevitable need for biodiversity conservation.

It is our responsibility to protect the endangered species of plant and animals. If one wants to reach their destination, then it is imperative to take the first step. Without taking a step forward, things will never change on their own. To make a better tomorrow, we need to take steps for preserving our very own Biodiversity.

Biodiversity is a term used to refer the different forms of life on the Earth. It also includes the variety of species in the ecosystem. There is an uneven distribution of the biodiversity on the Earth due to the extreme variation of temperatures in different regions. For instance, it is more in regions near the equator due to warm climatic conditions. However, near the pole, the extreme cold and unfavourable weather conditions do not support a majority of life forms. Additionally, changes in climatic conditions on the Earth over a period of time have also led to the extinction of a number of species.

Biodiversity is often defined at different levels depending upon the category of species. For example, taxonomic diversity is used to measure the species diversity level of different forms of life on the Earth. Ecological diversity is a broader term used for the ecosystem diversity. Similarly, functional diversity is a type used to measure diversity based on their feeding mechanisms along with other functions of species within a population.

Distribution:

There is an uneven distribution of biodiversity on the Earth. In fact, it increases from pole to equator. The climatic conditions of a region decide the presence of different species in an area. Not all species can survive in all weather conditions. Moreover, lower altitudes have a high concentration of species as compared to higher altitudes.

The importance of biodiversity does not only lie in the survival of various species of the earth. There is social, cultural as well as the economic importance of it as well. Biodiversity is of extreme importance to maintain the balance of nature. It is vital to maintaining the food chain as well. One species may be the food for another species and various species are linked to each other through this food chain. Apart from this, there is scientific importance of the biodiversity as well. The research and breeding programmes involve the variety of species. If these species cease to exist then such programmes shall not be possible.

Also, most of the drugs and medicine which are vital for the cure of many diseases are also made from many plants and animals. For instance, penicillin is a fungus through which the penicillin antibiotic is extracted.

Another important importance of biodiversity is that it provides food to all including human beings. All the food we consume is either derived from plants or animals such as fishes and other marine animals. They are also the source of new crops, pesticides and source material for agricultural practices.

Biodiversity is also important for industrial use. We get many products such as fur, honey, leather and pearls from animals. Moreover, we get timber for plants which are the basis of the paper we use in our everyday life. Tea, coffee and other drinks along with dry fruits and our regular fruits and vegetables, all are obtained from the various plants.

There is cultural and religious importance of many species as well. Many plants and animals are worshipped in different cultures and religions such as Ocitnum sanctum (Tulsi) which is a plant worshipped by Hindus.

Biodiversity in India:

India ranks among the top 12 nations which have a rich heritage of biodiversity. There are about 350 different species of mammals along with 12000 different species of birds which are found in India. Additionally, there are around 50000 species of insects which have their habitat in our country. There are a wide variety of domestic animals such as cows and buffaloes along with marine life which is found in India. Moreover, India is a land of 10 different biographical regions which include islands, Trans Himalayas, Desert, Western Ghats, Gangetic Plain, Semi-arid zone, Northeastern zone, Deccan Plateau, Coastal islands and the Western Ghats.

The Gradual Decrease:

Not all species which existed in the ancient times exist today as well. For example, dinosaurs used to exist on our planet in older times. But they were not able to adapt to the changing environmental conditions which led to their extinction from the Earth. Similarly, there are many other species which are on the verge of extinction due to the urbanisation and modernisation of the world. With the increase in population, there has been a constant need to reduce the forest areas and make way for new cities. This has led to the reduction in forests which are the natural habitat for many wild animals and plants. Due to this many wild plants have become extinct and there has been an increase in the man-animal conflict as well. Hence there has been a need to conserve the biodiversity so as to maintain the balance of nature.

Initiatives for the Conservation of Biodiversity:

There have been initiatives by the governments all over the world to conserve the existing biodiversity on the earth. For example, there are dedicated national parks which earmark the area for wild animals and plants and reduce human intervention in their lives. There are various wildlife conservation programmes in place to protect the vulnerable and endangered species. For example, Project Tiger is one such measure in place to increase the population of tigers in our country.

There are also many laws in place which make the hunting of endangered and vulnerable animals a punishable offence. At the international level, UNESCO (United Nations Educational, Scientific and Cultural Organization) and IUCN (International Union for Conservation of Nature and Natural Resources) have also initiated many programmes in order to preserve various species.

It is not possible for the human to live all alone on the Earth. Various other life forms are equally important and play their roles in the mutual survival of the various species on the Earth. Each one of species has its own set of contribution for the environment. Already many species have become extinct as they were not able to survive in the changing weather conditions. Hence it is our duty to ensure that our activities do not affect the other flora and fauna on the planet. Although there are a number of steps taken by the government so as to preserve the various life forms, we should also contribute individually towards this cause. If we do not act today, we may yet again witness the extinction of the vulnerable biodiversity which may further disturb the balance of nature.

Biodiversity , Ecosystem , Environment

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Essay on Biodiversity in 500 Words for Students

• Updated on  
• Dec 7, 2023

Essay on Biodiversity: Biodiversity refers to the variety of animals and plants in the world or a specific area. Even in today’s modern world where so many technological advances have taken place, we still rely on our natural environment and resources to survive, A healthy and vibrant ecosystem is not disturbed by human activities. We humans are the largest consumers of natural resources, and you know what? We are also a real threat to the natural environment? Biodiversity is not just about a variety of animal and plant species, but, also offers us water, climate, disease control, nutrition cycle, oxygen release, etc. According to one report released by the United Nations, around 10 lakh plant and animal species are on the verge of extinction. The worst thing is that this number is almost at a doubling rate.

Also Read: Essay on 5g Technology

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Why is Biodiversity Important?

Biodiversity supports all life forms on earth. To understand the importance of biodiversity, we don’t need to think or act like a biologist. All we need is a holistic understanding. 

• Biodiversity promotes resilience and stability in our ecosystem. If there is any natural disturbance in the environment, a diverse ecosystem will be able to survive and recover better.
• Fields like agriculture, forestry, and medicine completely rely on biodiversity. We get genetic resources from biodiversity, which is essential for agriculture and medicine fields.
• A healthy biodiversity environment means healthy humans. The medicinal drugs we use are derived from plants, animals, and microorganisms.
• In many parts of the world, biodiversity is an integral part of cultural identity. Indigenous tribes are connected with their natural environment and species. 
• Forest areas and oceans play an important role in regulating global temperature and storing carbon dioxide.
• Our environment is constantly changing and the species around it also need to adapt to for to survive. Therefore, genetic diversity within species is also important.
• Natural activities like soil formation, nutrient cycling, water purification, etc, are all dependent on biodiversity.

Also Read: NCERT Solutions Class 9 Natural Vegetation and Wildlife

What is Biodiversity Loss?

Biodiversity loss means the global extinction of various species, resulting in the loss of biological diversity. One of the main factors responsible for biodiversity loss is the conversion of natural habitats into agricultural and urban areas. Cutting down forests and using the land for commercial activities results in destroying the livelihood of all the species in the region. Other factors responsible for biodiversity loss are listed below.

• Overexploitation
• Climate change
• Global trade and transportation
• Emerging diseases
• Pollution 

Also Read: Essay on Save Environment

What is Biodiversity Conservation?

Biodiversity conservation refers to the preservation of species, natural resources, and habitats from the rate of extinction. To achieve the goals of biodiversity conservation, effective management, and sustainable practices are required.

• Biodiversity conservation includes protected areas like biodiversity hotspots, national parks, and wildlife sanctuaries.
• One of the most effective ways to conserve biodiversity is rehabilitation and restoring degraded habitats is crucial.
• Promoting sustainable practices in agriculture, forestry, and other resource-dependent activities is essential for the conservation of biodiversity.
• Encouraging the participation of local and indigenous communities can be one solution to achieving the goals of biodiversity conservation. Indigenous and local knowledge can contribute to effective conservation strategies.

Also Read: Essay on Junk Food

Quotes on Biodiversity

Here are some popular quotes on biodiversity. Feel free to add them to your writing topics related to the natural environment.

• ‘Look closely at nature. Every species is a masterclass, exclusively adapted to the particular environment in which it has survived. Who are we to destroy or even diminish biodiversity?’ – E O Wilson
• ‘Biodiversity is our most valuable but least appreciated resource.’ – E O Wilson
• ‘Biodiversity is the greeted treasure we have. It’s diminishment is to be prevented at all cost.’ – Thomas Eisner
• ‘Animal protection is education to humanity.’ – Albert Schweitzer
• ‘Only beautiful animals or ugly people wear fur.’ – Unknown
• ‘Babies and animals are the mirrors of the nature.’ – Epicurus

Also Read: Essay on Globalization

Ans: Biodiversity refers to the variety of plants and animals in our natural environment or a particular region. Biodiversity supports all life forms on earth. To understand the importance of biodiversity, we don’t need to think or act like a biologist. All we need is a holistic understanding. Biodiversity promotes resilience and stability in our ecosystem. If there is any natural disturbance in the environment, a diverse ecosystem will be able to survive and recover better. Fields like agriculture, forestry, and medicine completely rely on biodiversity. We get genetic resources from biodiversity, which is essential for agriculture and medicine fields.

Ans: Biodiversity conservation refers to the preservation of species, natural resources, and habitats from the rate of extinction. To achieve the goals of biodiversity conservation, effective management, and sustainable practices are required.

Ans: Some of the popular biodiversity hotspots in India are the Himalayas, Indo-Burma, Western Ghats & Sundaland.

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Shiva Tyagi

With an experience of over a year, I've developed a passion for writing blogs on wide range of topics. I am mostly inspired from topics related to social and environmental fields, where you come up with a positive outcome.

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Climate change and its impact on biodiversity and human welfare

K. r. shivanna.

Ashoka Trust for Research in Ecology and the Environment, Srirampura, Jakkur Post, Bengaluru, 560064 India

Climate change refers to the long-term changes in temperature and weather due to human activities. Increase in average global temperature and extreme and unpredictable weather are the most common manifestations of climate change. In recent years, it has acquired the importance of global emergency and affecting not only the wellbeing of humans but also the sustainability of other lifeforms. Enormous increase in the emission of greenhouse gases (CO 2 , methane and nitrous oxide) in recent decades largely due to burning of coal and fossil fuels, and deforestation are the main drivers of climate change. Marked increase in the frequency and intensity of natural disasters, rise in sea level, decrease in crop productivity and loss of biodiversity are the main consequences of climate change. Obvious mitigation measures include significant reduction in the emission of greenhouse gases and increase in the forest cover of the landmass. Conference of Parties (COP 21), held in Paris in 2015 adapted, as a legally binding treaty, to limit global warming to well below 2 °C, preferably to 1.5 °C by 2100, compared to pre-industrial levels. However, under the present emission scenario, the world is heading for a 3–4 °C warming by the end of the century. This was discussed further in COP 26 held in Glasgow in November 2021; many countries pledged to reach net zero carbon emission by 2050 and to end deforestation, essential requirements to keep 1.5 °C target. However, even with implementation of these pledges, the rise is expected to be around 2.4 °C. Additional measures are urgently needed to realize the goal of limiting temperature rise to 1.5 °C and to sustain biodiversity and human welfare.

Introduction

Climate change refers to long-term changes in local, global or regional temperature and weather due to human activities. For 1000s of years, the relationship between lifeforms and the weather have been in a delicate balance conducive for the existence of all lifeforms on this Planet. After the industrial revolution (1850) this balance is gradually changing and the change has become apparent from the middle of the twentieth century. Now it has become a major threat to the wellbeing of humans and the sustainability of biodiversity. An increase in average global temperature, and extreme and unpredictable weather are the most common manifestations of climate change. It has now acquired the importance of global emergency. According to the report of the latest Intergovernmental Panel for Climate Change (AR6 Climate Change 2021 ), human-induced climate change as is prevalent now is unprecedented at least in the last 2000 years and is intensifying in every region across the globe. In this review the drivers of climate change, its impact on human wellbeing and biodiversity, and mitigation measures being taken at global level are briefly discussed.

Drivers of climate change

Emission of green-house gases.

Steady increase in the emission of greenhouse gases (GHGs) due to human activities has been the primary driver for climate change. The principal greenhouse gases are carbon dioxide (76%), methane (16%), and to a limited extent nitrous oxide (2%). Until recent decades, the temperature of the atmosphere was maintained within a reasonable range as some of the sunlight that hits the earth was reflected back into the space while the rest becomes heat that keeps the earth and the atmosphere warm enough for the sustenance of life forms. Accumulation of greenhouse gases combine with water vapour to form a transparent layer in the atmosphere that traps infrared radiation (net heat energy) emitted from the Earth’s surface and reradiates it back to Earth’s surface, thus contributing to the increasing temperature (greenhouse effect). Methane is 25 times and nitrous oxide 300 times more potent than CO 2 in trapping heat. Until 2019, the US, UK, European Union, Canada, Australia, Japan and Russia were the major CO 2 producers and were responsible for 61% of world’s emissions. Now, China produces the maximum amount of CO 2 (27%) followed by USA (11%) and India (6.6%); on per capita basis, however, India stands ninth.

The emission of GHGs is largely due to the burning of fossil fuels (coal, oil and natural gas) for automobiles and industries which result in carbon emissions during their extraction as well as consumption. The amount of CO 2 in the atmosphere before the industrial revolution used to be around 280 ppm and now it has increased to 412 ppm (as of 2019). Increase in the atmospheric temperature also leads to an increase in the temperature of the ocean. The oceans play an important role in the global carbon cycle and remove about 25% of the carbon dioxide emitted by human activities. Further, some CO 2 dissolves in the ocean water releasing carbonic acid which increases the acidity of the sea water. Rising ocean temperatures and acidification not only reduce their capacity to act as carbon sinks but also affect ocean ecosystems and the populations that relay on them.

Increasing demand for meat and milk has led to a significant increase in the population of livestock and conversion of enormous amount of the land to pasture and farm land to raise livestock. Ruminant animals (largely cows, buffaloes and sheep) produce large amounts of methane when they digest food (through enteric fermentation by microbes), adding to the greenhouse gases in the atmosphere (Sejiyan et al. 2016 ). To produce 1 kg of meat it requires 7 kg of grain and between 5000 and 20,000 L of water whereas to produce 1 kg of wheat it requires between 500 and 4000 L of water (Pimentel and Pimentel 2003 ). Anaerobic fermentation of livestock manure also produces methane. According to Patrick Brown, our animal farming industry needs to be changed; using readily available plant ingredients, the nutritional value of any type of meat can be matched with about one twentieth of the cost (See Leeming 2021 ).

The main natural source of nitrous oxide released to the atmosphere (60%) comes from the activity of microbes on nitrogen-based organic material from uncultivated soil and waste water. The remaining nitrous oxide comes from human activities, particularly agriculture. Application of nitrogenous fertilizers to crop plants is a routine practice to increase the yield; many of the farmers tend to apply more than the required amount. However, it results in nitrous oxide emissions from the soil through nitrification and denitrification processes by microbes. Both synthetic and organic fertilizers increase the amount of nitrogen available in the soil to microbial action leading to the release of nitrous oxide. Organic fertilizers, however, release nitrogen more slowly than synthetic ones so that most of it gets absorbed by the plants as they become available. Synthetic fertilizers release nitrogen rapidly which cannot be used by plants right away, thus making the excess nitrogen available to microbes to convert to nitrous oxide. Presently CO 2 concentration in the atmosphere is higher than at any time in at least 2 million years, and methane and nitrous oxide are higher than at any time in the last 800,000 years (AR6 Climate Change 2021 ).

Permafrost (permanently frozen soil), widespread in Arctic regions of Siberia, Canada, Greenland, Alaska, and Tibetan plateau contains large quantities of organic carbon in the top soil leftover from dead plants that could not be decomposed or rot away due to the cold. Global warming-induced thawing of permafrost facilitates decomposition of this material by microbes thus releasing additional amount of carbon dioxide and methane to the atmosphere.

Deforestation

Limited deforestation in early part of human civilization was the result of subsistence farming; farmers used to cut down trees to grow crops for consumption of their families and local population. In preindustrial period also, there was a balance between the amount of CO 2 emitted through various processes and the amount absorbed by the plants. Forests are the main sinks of atmospheric CO 2 . After the industrial revolution, the trend began to change; increasing proportion of deforestation is being driven by the demands of urbanization, industrial activities and large-scale agriculture. A new satellite map has indicated that field crops have been extended to one million additional km 2 of land over the last two decades and about half of this newly extended land has replaced forests and other ecosystems (Potapov et al. 2021 ).

In recent decades the demands on forest to grow plantation crops such as oil palm, coffee, tea and rubber, and for cattle ranching and mining have increased enormously thus reducing the forest cover. According to the World Wildlife Fund (WWF), over 43 million hectares of forest was lost between 2004 and 2017 out of 377 million hectares monitored around the world (Pacheco et al. 2021 ). Amazon Rain Forest is the largest tropical rain forest of the world and covers over 5 million km 2 . It is undergoing extensive degradation and has reached its highest point in recent years. According to National Geographic, about 17% of Amazon rain forest has been destroyed over the past 50 years and is increasing in recent years; during the last 1 year it has lost over 10,000 km 2 . In most of the countries the forest cover is less than 33%, considered necessary. For example, India’s forest and tree cover is only about 24.56% of the geographical area (Indian State Forest Report 2019 ).

Impacts of climate change

Increase in atmospheric temperature has serious consequences on biodiversity and ecosystems, and human wellbeing. The most important evidences of climate change is the long term data available on the CO 2 levels, global temperature and weather patterns. The impacts of climate change in the coming decades are based on published models on the basis of the analysis of the available data. Comparison of the performance of climate models published between 1970 and 2007 in projecting global mean surface temperature and associated changes with actual observations have shown that the models were consistent in predicting global warming in the years after publication (Hausfather et al. 2019 ). This correlation between predicted models and actual data indicates that the models are indeed reliable in accurately predicting the global warming and its impacts on weather pattern in the coming decades and their consequences on biodiversity and human welfare.

Weather pattern and natural disasters

One of the obvious changes observed in recent years is the extreme and unpredictable weather, and an increase in the frequency and intensity of natural disasters. Brazil’s south central region saw one of the worst droughts in 2021with the result many major reservoirs reached < 20% capacity, seriously affecting farming and energy generation (Getirana et al. 2021 ). In earlier decades, it was possible to predict with reasonable certainty annual weather pattern including the beginning and ending of monsoon rains; farmers could plan sowing periods of their crops in synchrony with the prevailing weather. Now the weather pattern is changing almost every year and the farmers are suffering huge losses. Similarly the extent of annual rainfall and the locations associated with heavy and scanty rainfall are no more predictable with certainty. Many areas which were associated with scanty rainfall have started getting much heavier rains and the extent of rainfall is getting reduced in areas traditionally associated with heavy rainfall. Similarly the period and the extent of snowfall in temperate regions have also become highly variable.

Increase in the frequency and intensity of natural disasters such as floods and droughts, cyclones, hurricanes and typhoons, and wildfires have become very obvious. Top five countries affected by climate change in 2021 include Japan, Philippines, Germany, Madagascar and India. Apart from causing death of a large number of humans and other animals, economic losses suffered by both urban and rural populations have been enormous. Deadly floods and landslides during 2020 forced about 12 million people leave their homes in India, Nepal and Bangladesh. According to World Meteorological Organization’s comprehensive report published in August 2021 (WMO-No.1267), climate change related disasters have increased by a factor of five over the last 50 years; however, the number of deaths and economic losses were reduced to 2 million and US$ 3.64 trillion respectively, due to improved warning and disaster management. More than 91% of these deaths happened in developing countries. Largest human losses were brought about by droughts, storms, floods and extreme temperatures. The report highlights that the number of weather, climate and water-extremes will become more frequent and severe as a result of climate change.

Global warming enhances the drying of organic matter in forests, thus increasing the risks of wildfires. Wildfires have become very common in recent years, particularly is some countries such as Western United States, Southern Europe and Australia, and are becoming more frequent and widespread. They have become frequent in India also and a large number of them have been recorded in several states. According to European Space Agency, fire affected an estimated four million km 2 of Earth’s land each year. Wildfires also release large amounts of carbon dioxide, carbon monoxide, and fine particulate matter into the atmosphere causing air pollution and consequent health problems. In 2021, wildfires around the world, emitted 1.76 billion tonnes of carbon (European Union’s Copernicus Atmospheric Monitoring Service). In Australia, more than a billion native animals reported to have been killed during 2020 fires, and some species and ecosystems may never recover (OXFAM International 2021 ).

Sea level rise

Global warming is causing mean sea level to rise in two ways. On one hand, the melting of the glaciers, the polar ice cap and the Atlantic ice shelf are adding water to the ocean and on the other hand the volume of the ocean is expanding as the water warms. Incomplete combustion of fossil fuels, biofuels and biomass releases tiny particles of carbon (< 2.5 µm), referred to as black carbon. While suspended in the air (before they settle down on earth’s surface) black carbon particles absorb sun’s heat 1000s of times more effectively than CO 2 thus contributing to global warming. When black particles get deposited over snow, glaciers or ice caps, they enhance their melting further adding to the rise in sea level. Global mean sea level has risen faster since 1900 than over any preceding century in at least the last 3000 years. Between 2006 and 2016, the rate of sea-level rise was 2.5 times faster than it was for almost the whole of the twentieth century (OXFAM International 2021 ). Precise data gathered from satellite radar measurements reveal an accelerating rise of 7.5 cm from 1993 to 2017, an average of 31 mm per decade (WCRP Global Sea Level Budget Group 2018 ).

Snow accounts for almost all current precipitation in the Arctic region. However, it continues to warm four times faster than the rest of the world as the melting ice uncovers darker land or ocean beneath, which absorbs more sunlight causing more heating. The latest projections indicate more rapid warming and sea ice loss in the Arctic region by the end of the century than predicted in previous projections (McCrystall et al. 2021 ). It also indicates that the transition from snow to rain-dominated Arctic in the summer and autumn is likely to occur decades earlier than estimated. In fact this transition has already begun; rain fell at Greenland’s highest summit (3216 m) on 14 August 2021 for several hours for the first time on record and air temperature remained above freezing for about 9 h (National Snow and Ice Sheet Centre Today, August 18, 2021).

In the annual meeting of the American Geophysical Union (13 December 2021) researchers warned that rapid melting and deterioration of one of western Antarctica’s biggest glaciers, roughly the size of Florida, Thwaites (often called as Doomsday Glacier), could lead to ice shelf’s complete collapse in just a few years. It holds enough water to raise sea level over 65 cm. Thwaites glacier is holding the entire West Antarctic ice sheet and is being undermined from underneath by warm water linked to the climate change. Melting of Thwaites could eventually lead to the loss of the entire West Antarctic Ice Sheet, which locks up 3.3 m of global sea level rise. Such doomsday may be coming sooner than expected (see Voosen 2021 ). If this happens, its consequences on human tragedy and biodiversity loss are beyond imagination.

The Himalayan mountain range is considered to hold the world’s third largest amount of glacier ice after Arctic and Antarctic regions. It is considered as Asian water tower (Immerzeel et al. 2020 ); the meltwater from the Himalayan glaciers provide the source of fresh water to nearly 2 billion people living along the mountain valleys and lowlands around the Himalayas. These glaciers are melting at unprecedented rates. Recently King et al. ( 2021 ) studied 79 glaciers close to Mt. Everest by analysing mass-change measurements from satellite archives and reported that the rate of ice loss from glaciers consistently increased since the early 1960s. This loss is likely to increase in the coming years due to further warming. In another study, a tenfold acceleration in ice loss was observed across the Himalayas than the average rate in recent decades over the past centuries (Lee et al. 2021 ). Melting of glaciers also results in drying up of perennial rivers in summer leading to the water scarcity for billions of humans and animals, and food and energy production downstream. See level rise and melting of glaciers feeding the rivers could lead to migration of huge population, creating additional problems. Even when the increase in global temperature rise is limited to 1.5 °C (discussed later), it generates a global sea-level rise between 1.7 and 3.2 feet by 2100. If it increases to 2 °C, the result could be more catastrophic leading to the submergence of a large number of islands, and flooding and submergence of vast coastal areas, saltwater intrusion into surface waters and groundwater, and increased soil erosion. A number of islands of Maldives for example, would get submerged as 80% of its land area is located less than one meter above the sea level. The biodiversity in such islands and coastal areas becomes extinct. China, Vietnam, Fiji, Japan, Indonesia, India and Bangladesh are considered to be the most at risk. Sundarbans National Park (UNESCO world heritage Site), the world’s largest Mangrove Forest spread over 140,000 hectares across India and Bangladesh, is the habitat for Royal Bengal Tiger and several other animal species. The area has already lost 12% of its shoreline in the last four decades by rising see level; it is likely to be completely submerged. Jakarta in Indonesia is the fastest sinking city in the world; the city has already sunk 2.5 m in the last 10 years and by 2050, most of it would be submerged. In Europe also, about three quarters of all cities will be affected by rising sea levels, especially in the Netherlands, Spain, Belgium, Greece and Italy. The entire city of Venice may get submerged (Anonymous 2018 ). In USA, New York City and Miami would be particularly vulnerable.

Crop productivity and human health

Many studies have indicated that climate change is driving increasing losses in crop productivity (Zhu et al. 2021 ). The models on global yield loss for wheat, maize and rice indicate an increase in yield losses by 10 to 25% per degree Celsius warming (Deutsch et al. 2018 ). Bras et al. ( 2021 ) reported that heatwave and drought roughly tripled crop losses over the last 50 years, from − 2.2% (1964–1990) to − 7.3% (1991–2015). Overall, the loss in crop production from climate-driven abiotic stresses may exceed US$ 170 billion year –1  and represents a major threat to global food security (Razaaq et al. 2021 ). Analysis of annual field trials of common wheat in California from 1985 to 2019 (35 years), during which the global atmospheric CO 2  concentration increased by 19%, revealed that the yield declined by 13% (Bloom and Plant 2021 ). Apart from crop yield, climate change is reported to result in the decline of nutritional value of food grains (Jagermeyr et al. 2021 ). For example, rising atmospheric CO 2 concentration reduces the amounts of proteins, minerals and vitamins in rice (Zhu et al. 2018 ). This may be true in other cereal crops also. As rice supplies 25% of all global calories, this would greatly affect the food and nutritional security of predominantly rice growing countries. Climate change would also increase the prevalence of insect pests adding to the yield loss of crops. The prevailing floods and droughts also affect food production significantly. Global warming also affects crop productivity through its impact on pollinators. Insect pollinators contribute to crop production in 75% of the leading food crops (Rader et al. 2013 ). Climate change contributes significantly to the decline in density and diversity of pollinators (Shivanna 2020 ; Shivanna et al. 2020 ). Under high as well as low temperatures, bees spend less time in foraging (Heinrich 1979 ) adding additional constraints to pollination efficiency of crop species.

The IPCC Third Assessment Report (Climate change 2001: The scientific basis – IPCC) concluded that the poorest countries would be hardest hit with reductions in crop yields in most tropical and sub-tropical regions due to increased temperature, decreased water availability and new or changed insect pest incidence. Rising ocean temperatures and ocean acidification affect marine ecosystems. Loss of fish habitats is modifying the distribution and productivity of both marine and freshwater species thus affecting the sustainability of fisheries and populations dependent on them (Salvatteci 2022 ).

Air pollution is considered as the major environmental risk of climate change due to its impact on public health causing increasing morbidity and mortality (Manisalidis 2020 ). Particulate matter, carbon monoxide, nitrogen oxide, and sulphur dioxide are the major air pollutants. They cause respiratory problems such as asthma and bronchiolitis and lung cancer. Recent studies have indicated that exposure to air pollution is linked to methylation of immunoregulatory genes, altered immune cell profiles and increased blood pressure in children (Prunicki et al. 2021 ). In another study wildfire smoke has been reported to be more harmful to humans than automobiles emissions (Aquilera et al. 2021 ). Stubble burning (intentional incineration of stubbles by farmers after crop harvest) has been a common practice in some parts of South Asia particularly in India; it releases large amount of toxic gases such as carbon monoxide and methane and causes serious damage to the environment and health (Abdurrahman et al. 2020 ). It also affects soil fertility by destroying the nutrients and microbes of the soil. Attempts are being made to use alternative methods to prevent this practice.

A number of diseases such as zika fever, dengue and chikungunya are transmitted by Aedes mosquitoes and are now largely restricted to the monsoon season. Global warming facilitates their spread in time and space thus exposing new populations and regions for extended period to these diseases. Lyme disease caused by a bacterium is transmitted through the bite of the infected blacklegged ticks. It is one of the most common disease in the US. The cases of Lyme disease have tripled in the past two decades. Recent studies have suggested that variable winter conditions due to climate change could increase tick’s activity thus increasing the infections (see Pennisi 2022 ).

Biodiversity

Biodiversity and associated ecoservices are the basic requirements for human livelihood and for maintenance of ecological balance in Nature. Documentation of biodiversity, and its accelerating loss and urgent need for its conservation have become the main concern for humanity since several decades (Wilson and Peter 1988 ; Wilson 2016 ; Heywood 2017 ; IPBES 2019 ; Genes and Dirzo 2021 ; Shivanna and Sanjappa 2021 ). It is difficult to analyse the loss of biodiversity exclusively due to climate change as other human-induced environmental changes such as habitat loss and degradation, overexploitation of bioresources and introduction of alien species also interact with climate change and affect biodiversity and ecosystems. In recent decades there has been a massive loss of biodiversity leading to initiation of the sixth mass extinction crisis due to human-induced environmental changes. These details are not discussed here; they are dealt in detail in many other reviews (Leech and Crick 2007 ; Sodhi and Ehrlich 2010 ; Lenzen et al. 2012 ; Dirzo and Raven 2003 ; Raven 2020 ; Ceballos et al. 2015 ; Beckman et al. 2020 ; Shivanna 2020 ; Negrutiu et al. 2020 ; Soroye et al. 2020 ; Wagner 2020 ,  2021 ; Anonymous 2021 ; Zattara and Aizen 2021 ).

Terrestrial species

There are several effects on biodiversity caused largely by climate change. Maxwell et al. ( 2019 ) reviewed 519 studies on ecological responses to extreme climate events (cyclones, droughts, floods, cold waves and heat waves) between 1941 and 2015 covering amphibians, birds, fish, invertebrates, mammals, reptiles and plants. Negative ecological responses have been reported for 57% of all documented groups including 31 cases of local extirpations and 25% of population decline.

Increase in temperature impacts two aspects of growth and development in plants and animals. One of them is a shift in distributional range of species and the other is the shift in phenological events. Plant and animal species have adapted to their native habitat over 1000s of years. As the temperature gets warmer in their native habitat, species tend to move to higher altitudes and towards the poles in search of suitable temperature and other environmental conditions. There are a number of reports on climate change-induced shifts in the distributional range of both plant and animal species (Grabherr et al. 1994 ; Cleland et al. 2007 ; Parmesan and Yohe 2003 ; Beckage et al. 2008 ; Pimm 2009 ; Miller-Rushing et al. 2010 ; Lovejoy and Hannah 2005 ; Lobell et al. 2011 ). Many species may not be able to keep pace with the changing weather conditions and thus lag behind leading to their eventual extinction. Long-term observations extending for over 100 years have shown that many species of bumblebees in North-America and Europe are not keeping up with the changing climate and are disappearing from the southern portions of their range (Kerr et al. 2015 ). Most of the flowering plants depend on animals for seed dispersal (Beckman et al. 2020 ). Defaunation induced by climate change and other environmental disturbances has reduced long-distance seed dispersal. Prediction of dispersal function for fleshly-fruited species has already reduced the capacity of plants to track climate change by 60%, thus severely affecting their range shifts (Fricke et al. 2022 ).

Climate change induced shifts in species would threaten their sustenance even in protected areas as they hold a large number of species with small distributional range (Velasquez-Tibata et al. 2013 ). Pautasso ( 2012 ) has highlighted the sensitivity of European birds to the impacts of climate change in their phenology (breeding time), migration patterns, species distribution and abundance. Metasequoia glyptostroboides is one of the critically endangered species with extremely small populations distributed in South-Central China. Zhao et al. ( 2020 ) analysed detailed meteorological and phenological data from 1960 to 2016 and confirmed that climate warming has altered the phenology and compressed the climatically suitable habitat of this species. Their studies revealed that the temperature during the last 57 years has increased significantly with the expansion of the length of growing season of this species. Climatically suitable area of the species has contracted at the rate of 370.8 km 2 per decade and the lower and upper elevation limits shrunk by 27 m over the last 57 years.

The other impact of climate change on plant and animal species has been in their phenological shift. Phenology is the timing of recurring seasonal events; it is a sort of Nature’s calendar for plants and animals. In flowering plants, various reproductive events such as the timing of flowering, fruiting, their intensity, and longevity are important phenological events, and in animals some of the phenological events include building of nests in birds, migration of animal species, timing of egg laying and development of the larva, pupa and adult in insects. Phenological events of both plants and animals are generally fixed in specific time of the year as they are based on environmental cues such as temperature, light, precipitation and snow melt. Phenological timings of species are the results of adaptations over 100 s of years to the prevailing environment. Wherever there is a mutualism between plants and animals, there is a synchrony between the two partners. For example in flowering plants, flowering is associated with the availability of pollinators and fruiting is associated with the availability of seed dispersers and optimal conditions for seed germination and seedling establishment. In animals also, phenological events are adapted to suit normal growth and reproduction. In temperate regions, melting of ice initiates leafing in plants; this is followed by the flowering in the spring. Similarly, warming of the climate before the spring induces hatching of the hibernating insects which feed on newly developed foliage. Insects emerge and ready to pollinate the flowers by the time the plants bloom.

The dates of celebration of the cherry blossom festival, an important cultural event in Japan that coincides with the peak of flowering period of this species and for which > 1000 years of historical records are available, has shown advances in the dates of the festival in recent decades (Primack et al. 2009 ). The records between 1971 and 2000 showed that the trees flowered an average of 7 days earlier than all the earlier years (Allen et al. 2013 ). These advances were correlated with increasing temperature over the years. Spring temperatures in the Red River valley, North Dakota, USA have extended the period of the growing season of plants significantly over the years. Flowering times, for which data are available from1910 to1961, have been shown to be sensitive to at least one variable related to temperature or precipitation for 75% of the 178 species investigated (Dunnell and Traverse 2011 ). The first flowering time has been significantly shifted earlier or later over the last 4 years of their study in 5–15% of the observed species relative to the previous century. Rhododendron arboretum , one of the central Himalayan tree species, flowers from early February to mid-March. Generalized additive model using real-time field observations (2009–2011) and herbarium records (1893–2003) indicated 88–97 days of early flowering in this species over the last 100 years (Gaira et al. 2014 ). This early flowering was correlated with an increase in the temperature.

One of the consequences of a shift in the distributional range of species and phenological timings is the possible uncoupling of synchronization between the time of flowering of plant species and availability of its pollinators (see Gerard et al. 2020 ). When a plant species migrates, its pollinator may not be able to migrate; similarly when a pollinator migrates, the plant species on which it depends for sustenance may not migrate. Memmott et al. ( 2007 ) explored potential disruption of pollination services due to climate change using a network of 1420 pollinators and 429 plant species by simulating consequences of phenological shifts that can be expected with doubling of atmospheric CO 2 . They reported phenological shifts which reduced available floral resources to 17–50% of all pollinator species. A long-term study since the mid-1970s in the Mediterranean Basin has indicated that unlike the synchrony present in the earlier decades between the flowering of plant species and their pollinators, insect phenoevents during the last decade showed a steeper advance than those of plants (Gordo and Sanz 2005 ). Similar asynchrony has been reported between the flowering of Lathyrus and one of its pollinators, Hoplitis fulgida (Forrest and Thomson 2011 ). Asynchrony between flowering and appearance of pollinator has also been reported in a few other cases (Kudo and Ida 2013 ; Kudo 2014 ). Such asynchrony could affect the sustenance of plant and/or pollinator species in the new environment.

Marine species

Amongst the marine species, corals are the most affected groups due to the rise in temperature and acidity of oceans. Corals live in a symbiotic relationship with algae which provide colour and photosynthates to the corals. Corals are extremely sensitive to heat and acidity; even an increase of 2–3°F of ocean water above normal results in expulsion of the symbiotic algae from their tissues leading to their bleaching (Hoegh-Guldberg et al. 2017 ). When this bleached condition continues for several weeks, corals die. Nearly one-third of the Great Barrier Reef, the world’s largest coral reef system that sustains huge Australian tourism industry, has died as a result of global warming (Hughes et al. 2018 ). According to the experts the reef will be unrecognizable in another 50 years if greenhouse gas emissions continue at the current rate.

According to UNESCO, coral reefs in all 29 reef-containing World Heritage sites would cease to exist as functioning ecosystems by the end of this century if greenhouse gas emissions continue to be emitted at the present rate (Elena et al. 2020 ). Recent assessment of the risk of ecosystem collapse to coral reefs of the Western Indian Ocean, covering about 5% of the global total, range from critically endangered to vulnerable (Obura et al. 2021 ). Coral reefs provide suitable habitat for thousands of other species, including sharks, turtles and whales. If corals die, the whole ecosystem will get disrupted.

Melting of ice in Arctic region due to global warming is threatening the survival of native animals such as polar bear, Arctic fox and Arctic wolf. Rising of sea level also leads to the extinction of a large number of endangered and endemic plant and animal species in submerged coastal areas and islands. Over 180,000 islands around the globe contain 20% of the world’s biodiversity. Bellard et al. ( 2013 ) assessed consequences of sea level rise of 1–6 m for 10 insular biodiversity hotspots and their endemic species at the risk of potential extinction. Their study revealed that 6 to19% of the 4447 islands would be entirely submerged depending on the rise of sea level; three of them, the Caribbean islands, the Philippines and Sundaland, displayed the most significant hotspots representing a potential threat for 300 endemic species. According to the Centre for Biological Diversity ( 2013 ) 233 federally protected threatened and endangered species in 23 coastal states are threatened if rising sea is unchecked. Recently more than 100 Aquatic Science Societies representing over 80,000 scientists from seven continents sounded climate alarm (Bonar 2021 ). They have highlighted the effects of climate change on marine and aquatic ecosystems and have called on the world leaders and public to undertake mitigation measures to protect and sustain aquatic systems and theirs services.

Mitigation measures

The principal mitigation measures against climate change are obvious; they include significant reduction in greenhouse gas emission, prevention of deforestation and increase in the forest cover. To reduce greenhouse gas emission, use of coal and fossil fuels needs to be reduced markedly. As climate change is a global challenge, local solutions confined to one or a few countries do not work; we need global efforts. Many attempts are being made to achieve these objectives at the global level since many decades. Mitigation measures are largely at the level of diplomatic negotiations involving states and international organizations, Governments and some nongovernmental organizations. The Intergovernmental Panel on Climate Change (IPCC) was established by the United Nations Environment Programme (UNEP) and the World Meteorological Organization (WMO) in 1988. Its mandate was to provide political leaders with periodic scientific assessments concerning climate change, its implications and risks, and also to put forward adaptation and mitigation strategies. In 1992 more than 1700 World scientists, including the majority of living Nobel laureates gave the first Warning to Humanity about climate change and associated problems. They expressed concern about potential damage to the Planet Earth by human-induced environmental changes such as climate change, continued human population growth, forest loss, biodiversity loss and ozone depletion. Conference of Parties (COP) of the UN Convention on Climate Change was established in 1992 under the United Nations Framework Convention on Climate Change (UNFCCC) to discuss global response to climate change. Its first meeting (COP 1) was held in Berlin in March 1995 and is being held every year since then. The Fifth Assessment Report of the IPCC, released in November 2014, projected an increase in the mean global temperature of 3.7 to 4.8 °C by 2100, relative to preindustrial levels (1850), in the absence of new policies to mitigate climate change; it highlighted that such an increase would have serious consequences. This prediction compelled the participating countries at the COP 21 held in Paris in December 2015 to negotiate effective ways and means of reducing carbon emissions. In this meeting the goal to limit global warming to well below 2 °C, preferably to 1.5 °C, compared to preindustrial levels was adapted by 196 participating countries as a legally binding treaty on climate change. It also mandated review of progress every 5 years and the development of a fund containing $100 billion by 2020, which would be replenished annually, to help developing countries to adopt non-greenhouse-gas-producing technologies.

In 2017, after 25 years after the first warning, 15,354 world scientists from 184 countries gave ‘second warning to humanity’ (Ripple et al. 2017 ). They emphasized that with the exception of stabilizing the stratospheric ozone layer, humanity has failed to make sufficient progress in solving these environmental challenges, and alarmingly, most of them are getting far worse. Analysis of Warren et al. ( 2018 ) on a global scale on the effects of climate change on the distribution of insects, vertebrates and plants indicated that even with 2 °C temperature increase, approximately 18% of insects, 16% of plants and 8% of vertebrates species are projected to loose > 50% geographic range; this falls to 6% for insects, 8% for plants and 4% for vertebrates when temperature increase is reduced to 1.5 °C.

UN Report on climate change (prepared by > 90 authors from 40 countries after examining 6000 scientific publications) released in October 2018 in South Korea also gave serious warning to the world. Some of the salient features of this report were:

• Overshooting 1.5 °C will be disastrous. It will have devastating effects on ecosystems, communities and economies. By 2040 there could be global food shortages, the inundation of coastal cities and a refugee crisis unlike the world has ever seen.
• Even 1.5 °C warming would rise sea levels by 26–77 cm by 2100; 2 °C would add another 10 cm which would affect another 10 million people living in coastal regions.
• Coral reefs are projected to decline 70–90% even at 1.5 °C. At 2 °C, 99% of the reefs would be ravaged.
• Storms, floods, droughts and forest fires would increase in intensity and frequency.
• The world has already warmed by about 1 °C since preindustrial times. We are currently heading for about 3–4 °C of warming by 2100.
• Unless rapid and deep reductions in CO 2 and other greenhouse gas emissions occur in the coming decades, achieving the goals of the 2015 Paris Agreement will be beyond reach.
• To keep 1.5 °C target, coal’s share of global electricity generation must be cut from the present 37% to no more than 2% by 2050. Renewable power must be greatly expanded. Net CO 2  emissions must come down by 45% (from 2010 levels) by 2030 and reach net zero (emissions of greenhouse gases no more than the amount removed from the atmosphere) around 2050.

This report awakened the world Governments about the seriousness of the climate change. The COP 26 meeting which was to be held in 2020 had to be postponed due to Covid-19 pandemic. The first part of the sixth report of IPCC was released in August 2021 (AR6 Climate Change 2021 ), just before the postponed COP 26 meeting was to be held; it highlighted that the threshold warming of 1.5 °C (the target of keeping the warming by the end of the century) would reach in the next 20 years itself and if the present trends continue, it would reach 2.7 °C by the end of the century.

Under this predicted climate emergency (see Ripple et al. 2020 ), COP 26 meeting was held in Glasgow, Scotland between October 31 and November 12, 2021. Nearly 200 countries participated in this meeting. The main aim of the COP 26 was finalization of the rules and procedures for implementation of the Paris agreement to keep the temperature increase to 1.5 °C. A number of countries including USA and European Union pledged to reach net zero carbon emission by 2050. China pledged to reach net zero emissions by 2060 and India by 2070. India also committed to reduce the use of fossil fuels by 40% by 2030. More than 100 countries committed to reduce worldwide methane emissions by 30% (of 2020 levels) by 2030 and to end deforestation by 2030. The average atmospheric concentration of methane reached a record 1900 ppb in September 2021; it was 1638 ppb in 1983 (US National Oceanic and Atmospheric Administration), highlighting the importance of acting on pledges made at the COP 26.

One of the limitations of COP meetings has been nonadherence of the commitment made by developed countries at Paris meeting to transfer US $100 billion annually to developing and poor countries to support climate mitigation and loss of damage, through 2025; only Germany, Norway and Sweden are paying their share. Several experts feel that the adoption of the Glasgow Climate Pact was weaker than expected. According to the assessment of Climate Action Tracker, a non-profit independent global analysis platform, emission reduction commitments by countries still lead to 2.4 °C warming by 2100. However, a positive outcome of the meeting was that it has kept alive the hopes of achieving the 1.5 °C goal by opening the options for further discussion in the coming COP meetings. Apart from implementation of mitigation pledges made by countries, it is also important to pay attention to climate adaptation since the negative effects of climate change will continue for decades or longer (AR6 Climate Change 2021 ). Investment in early warning is an important means of climate adaptation, which is lacking in many parts of Africa and Latin America.

Conclusions

Climate change has now become the fastest growing global threat to human welfare. The world has realized the responsibility of the present generation as it is considered to be the last generation capable of taking effective measures to reverse its impact. If it fails, human civilization is likely to be doomed beyond recovery. As emphasized by many organizations, the climate crisis is inherently unfair; poorer countries will suffer its consequences more than others. India is one amongst the nine countries identified to be seriously affected by climate change. According to a WHO analysis ( 2016 ) India could face more than 25% of all global climate-related deaths by 2050 due to decreasing food availability. China is expected to face the highest number of per capita food insecurity deaths. Bhutan, a small Himalayan kingdom with 60% forest cover, is the most net negative carbon emission country; its GHG emission is less than the amount removed from the atmosphere. Other countries should aim to emulate Bhutan as early as possible.

A number of other options have been suggested to trap atmospheric carbon dioxide (Climate change mitigation—Wikipedia). Carbon storage through sequestration of organic carbon by deep-rooted grasses has been one such approach (Fisher et al. 1994 ). Several studies from Africa have indicated that introduction of Brachiaria grasses in semi-arid tropics can help to increase not only carbon stock in the soil but also yield greater economic returns (Gichangi et al. 2017 ). Recently a new seed bank, ‘Future Seeds’ was dedicated at Palmira, Columbia to store world’s largest collection of beans, cassava, and tropical forage grasses for the use of breeders to create better performing and climate-resistant crops (Stokstad 2022 ). Brachiaria humidicola is one of the tropical forage grass stored in this seed bank for its potential benefit in carbon sequestration. Lavania and Lavania ( 2009 ) have suggested vetiver ( Vetiveria zizanioides ), a C 4 perennial grass, with massive fibrous root system that can grow up to 3 m into the soil in 1 year, as a potential species for this purpose. Vetiver is estimated to produce 20–30 tonnes of root dry matter per hectare annually and holds the potential of adding 1 kg atmospheric CO 2 annually to the soil carbon pool per m 2 surface area. Carbon dioxide capture and storage is another such potential approach. At present it is too expensive and this approach may have to wait until improvement of the technology, reduction in the cost and feasibility of transfer of the technology to developing countries (IPCC Special Report on carbon dioxide capture and storage 2005 ).

There has been some discussion on the role of climate change on speciation (Levin 2019 ; Gao et al. 2020 ). Some evolutionary biologists have observed that the rate of speciation has accelerated in the recent past due to climate change and would continue to increase in the coming decades (Thomas 2015 ; Levin 2019 ; Gao et al. 2020 ). They propose that auto- and allo-polyploidy are going to be the primary modes of speciation in the next 500 years (Levin 2019 , see also Gao 2019 , Villa et al. 2022 ). However, extinction of species imposed by climate change may excel positive impact on plant speciation via polyploidy (Gao et al. 2020 ). The question is will climate change induce higher level of polyploidy and other genetic changes in crop species also that would promote evolution of new genotypes to sustain productivity and quality of food grains? If so, it would ameliorate, to some extent, food and nutritional insecurity of humans especially in the developing world.

Effective implementation of the pledges made by different countries in COP 26 and actions to be taken in the coming COP meetings are going to be crucial and determine humanity’s success or failure in tackling climate change emergency. COP 26 climate pact to cut greenhouse gas emissions, end of deforestation and shift to sustainable transport is certainly more ambitious then earlier COPs. There are also many other positive signals for reducing fossil fuels. Scientists have started using more precise monitoring equipment to collect more reliable environmental data, and more options are being developed by researchers on renewable and alternate energy sources, and to capture carbon from industries or from the air (Chandler D, MIT News 24 Oct 2019, Swain F, BBC Future Planet, 12 March 2021). Scotland has become coal-free and Costa Rica has achieved 99% renewable energy. India has reduced the use of fossil fuel by 40% of it installed capacity, 8 years ahead of its commitment at the COP 26.

Further, people are becoming more conscious to reduce carbon emission by following climate-friendly technologies. Human sufferings associated with an increase in natural disasters throughout the world have focussed public attention on climate change as never before. They also realise the benefits of improved air quality by reducing consumption of coal and fossil fuels on health and ecosystems. The demand for electric vehicles is steadily growing. Reforestation is being carried out in a large scale in many countries. Recent studies across a range of tree plantations and native forests in 53 countries have revealed that carbon storage, soil erosion control, water conservation and biodiversity benefits are delivered better from native forests compared to monoculture tree plantations, although the latter yielded more wood (Hua et al. 2022 ). This has to be kept in mind in reforestation programmes. Hopefully the world will be able to realize the goal of limiting the temperature rise to 1.5 °C by the end of the century and humanity would learn to live in harmony with Nature.

Declarations

The author declares no conflict of interest.

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Should We Change Species to Save Them?

When traditional conservation fails, science is using “assisted evolution” to give vulnerable wildlife a chance.

Credit... Photo illustration by Lauren Peters-Collaer

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By Emily Anthes

Photographs by Chang W. Lee

This story is part of a series on wildlife conservation in Australia, which Emily Anthes reported from New York and Australia, with Chang W. Lee.

• Published April 14, 2024 Updated April 16, 2024

For tens of millions of years, Australia has been a playground for evolution, and the land Down Under lays claim to some of the most remarkable creatures on Earth.

It is the birthplace of songbirds, the land of egg-laying mammals and the world capital of pouch-bearing marsupials, a group that encompasses far more than just koalas and kangaroos. (Behold the bilby and the bettong!) Nearly half of the continent’s birds and roughly 90 percent of its mammals, reptiles and frogs are found nowhere else on the planet.

Australia has also become a case study in what happens when people push biodiversity to the brink. Habitat degradation, invasive species, infectious diseases and climate change have put many native animals in jeopardy and given Australia one of the worst rates of species loss in the world.

In some cases, scientists say, the threats are so intractable that the only way to protect Australia’s unique animals is to change them. Using a variety of techniques, including crossbreeding and gene editing, scientists are altering the genomes of vulnerable animals, hoping to arm them with the traits they need to survive.

“We’re looking at how we can assist evolution,” said Anthony Waddle, a conservation biologist at Macquarie University in Sydney.

It is an audacious concept, one that challenges a fundamental conservation impulse to preserve wild creatures as they are. But in this human-dominated age — in which Australia is simply at the leading edge of a global biodiversity crisis — the traditional conservation playbook may no longer be enough, some scientists said.

“We’re searching for solutions in an altered world,” said Dan Harley, a senior ecologist at Zoos Victoria. “We need to take risks. We need to be bolder.”

The extinction vortex

The helmeted honeyeater is a bird that demands to be noticed, with a patch of electric-yellow feathers on its forehead and a habit of squawking loudly as it zips through the dense swamp forests of the state of Victoria. But over the last few centuries, humans and wildfires damaged or destroyed these forests, and by 1989, just 50 helmeted honeyeaters remained, clinging to a tiny sliver of swamp at the Yellingbo Nature Conservation Reserve.

Intensive local conservation efforts, including a captive breeding program at Healesville Sanctuary, a Zoos Victoria park, helped the birds hang on. But there was very little genetic diversity among the remaining birds — a problem common in endangered animal populations — and breeding inevitably meant inbreeding. “They have very few options for making good mating decisions,” said Paul Sunnucks, a wildlife geneticist at Monash University in Melbourne.

In any small, closed breeding pool, harmful genetic mutations can build up over time, damaging animals’ health and reproductive success, and inbreeding exacerbates the problem. The helmeted honeyeater was an especially extreme case. The most inbred birds left one-tenth as many offspring as the least inbred ones, and the females had life spans that were half as long, Dr. Sunnucks and his colleagues found.

Without some kind of intervention, the helmeted honeyeater could be pulled into an “extinction vortex,” said Alexandra Pavlova, an evolutionary ecologist at Monash. “It became clear that something new needs to be done.”

A decade ago, Dr. Pavlova, Dr. Sunnucks and several other experts suggested an intervention known as genetic rescue , proposing to add some Gippsland yellow-tufted honeyeaters and their fresh DNA to the breeding pool.

The helmeted and Gippsland honeyeaters are members of the same species, but they are genetically distinct subspecies that have been evolving away from each other for roughly the last 56,000 years. The Gippsland birds live in drier, more open forests and are missing the pronounced feather crown that gives helmeted honeyeaters their name.

Genetic rescue was not a novel idea. In one widely cited success, scientists revived the tiny, inbred panther population of Florida by importing wild panthers from a separate population from Texas.

But the approach violates the traditional conservation tenet that unique biological populations are sacrosanct, to be kept separate and genetically pure. “It really is a paradigm shift,” said Sarah Fitzpatrick, an evolutionary ecologist at Michigan State University who found that genetic rescue is underused in the United States.

Crossing the two types of honeyeaters risked muddying what made each subspecies unique and creating hybrids that were not well suited for either niche. Moving animals between populations can also spread disease, create new invasive populations or destabilize ecosystems in unpredictable ways.

Genetic rescue is also a form of active human meddling that violates what some scholars refer to as conservation’s “ ethos of restraint ” and has sometimes been critiqued as a form of playing God.

“There was a lot of angst among government agencies around doing it,” said Andrew Weeks, an ecological geneticist at the University of Melbourne who began a genetic rescue of the endangered mountain pygmy possum in 2010. “It was only really the idea that the population was about to go extinct that I guess gave government agencies the nudge.”

Dr. Sunnucks and his colleagues made the same calculation, arguing that the risks associated with genetic rescue were small — before the birds’ habitats were carved up and degraded, the two subspecies did occasionally interbreed in the wild — and paled in comparison with the risks of doing nothing.

And so, since 2017, Gippsland birds have been part of the helmeted honeyeater breeding program at Healesville Sanctuary. In captivity there have been real benefits, with many mixed pairs producing more independent chicks per nest than pairs composed of two helmeted honeyeaters. Dozens of hybrid honeyeaters have now been released into the wild. They seem to be faring well, but it is too soon to say whether they have a fitness advantage.

Monash and Zoos Victoria experts are also working on the genetic rescue of other species, including the critically endangered Leadbeater’s possum, a tiny, tree-dwelling marsupial known as the forest fairy. The lowland population of the possum shares the Yellingbo swamps with the helmeted honeyeater; in 2023, just 34 lowland possums remained . The first genetic rescue joey was born at Healesville Sanctuary last month.

The scientists hope that boosting genetic diversity will make these populations more resilient in the face of whatever unknown dangers might arise, increasing the odds that some individuals possess the traits needed to survive. “Genetic diversity is your blueprint for how you contend with the future,” Dr. Harley of Zoos Victoria said.

Targeting threats

For the northern quoll, a small marsupial predator, the existential threat arrived nearly a century ago, when the invasive, poisonous cane toad landed in eastern Australia. Since then, the toxic toads have marched steadily westward — and wiped out entire populations of quolls, which eat the alien amphibians.

But some of the surviving quoll populations in eastern Australia seem to have evolved a distaste for toads . When scientists crossed toad-averse quolls with toad-naive quolls, the hybrid offspring also turned up their tiny pink noses at the toxic amphibians.

What if scientists moved some toad-avoidant quolls to the west, allowing them to spread their discriminating genes before the cane toads arrived? “You’re essentially using natural selection and evolution to achieve your goals, which means that the problem gets solved quite thoroughly and permanently,” said Ben Phillips, a population biologist at Curtin University in Perth who led the research.

A field test, however, demonstrated how unpredictable nature can be. In 2017, Dr. Phillips and his colleagues released a mixed population of northern quolls on a tiny, toad-infested island. Some quolls did interbreed , and there was preliminary evidence of natural selection for “toad-smart” genes.

But the population was not yet fully adapted to toads, and some quolls ate the amphibians and died, Dr. Phillips said. A large wildfire also broke out on the island. Then, a cyclone hit. “ All of these things conspired to send our experimental population extinct,” Dr. Phillips said. The scientists did not have enough funding to try again, but “all the science lined up,” he added.

Advancing science could make future efforts even more targeted. In 2015, for instance, scientists created more heat-resistant coral by crossbreeding colonies from different latitudes . In a proof-of-concept study from 2020, researchers used the gene-editing tool known as CRISPR to directly alter a gene involved in heat tolerance.

CRISPR will not be a practical, real-world solution anytime soon, said Line Bay, a biologist at the Australian Institute of Marine Science who was an author of both studies. “Understanding the benefits and risks is really complex,” she said. “And this idea of meddling with nature is quite confronting to people.”

But there is growing interest in the biotechnological approach. Dr. Waddle hopes to use the tools of synthetic biology, including CRISPR, to engineer frogs that are resistant to the chytrid fungus, which causes a fatal disease that has already contributed to the extinction of at least 90 amphibian species.

The fungus is so difficult to eradicate that some vulnerable species can no longer live in the wild. “So either they live in glass boxes forever,” Dr. Waddle said, “or we come up with solutions where we can get them back in nature and thriving.”

Unintended consequences

Still, no matter how sophisticated the technology becomes, organisms and ecosystems will remain complex. Genetic interventions are “likely to have some unintended impacts,” said Tiffany Kosch, a conservation geneticist at the University of Melbourne who is also hoping to create chytrid-resistant frogs . A genetic variant that helps frogs survive chytrid might make them more susceptible to another health problem , she said.

There are plenty of cautionary tales, efforts to re-engineer nature that have backfired spectacularly. The toxic cane toads, in fact, were set loose in Australia deliberately, in what would turn out to be a deeply misguided attempt to control pest beetles.

But some environmental groups and experts are uneasy about genetic approaches for other reasons, too. “Focusing on intensive intervention in specific species can be a distraction,” said Cam Walker, a spokesman for Friends of the Earth Australia. Staving off the extinction crisis will require broader, landscape-level solutions such as halting habitat loss, he said.

Moreover, animals are autonomous beings, and any intervention into their lives or genomes must have “a very strong ethical and moral justification” — a bar that even many traditional conservation projects do not clear, said Adam Cardilini, an environmental scientist at Deakin University in Victoria.

Chris Lean, a philosopher of biology at Macquarie University, said he believed in the fundamental conservation goal of “preserving the world as it is for its heritage value, for its ability to tell the story of life on Earth.” Still, he said he supported the cautious, limited use of new genomic tools, which may require us to reconsider some longstanding environmental values.

In some ways, assisted evolution is an argument — or, perhaps, an acknowledgment — that there is no stepping back, no future in which humans do not profoundly shape the lives and fates of wild creatures.

To Dr. Harley, it has become clear that preventing more extinctions will require human intervention, innovation and effort. “Let’s lean into that, not be daunted by it,” he said. “My view is that 50 years from now, biologists and wildlife managers will look back at us and say, ‘Why didn’t they take the steps and the opportunities when they had the chance?’”

Emily Anthes is a science reporter, writing primarily about animal health and science. She also covered the coronavirus pandemic. More about Emily Anthes

Chang W. Lee has been a photographer for The Times for 30 years, covering events throughout the world. He is currently based in Seoul. Follow him on Instagram @nytchangster . More about Chang W. Lee

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