Wildlife conservation

Last updated
Ankeny Wildlife Refuge in Oregon. Ankeny National Wildlife Refuge.jpg
Ankeny Wildlife Refuge in Oregon.

Wildlife conservation refers to the practice of protecting wild species and their habitats in order to maintain healthy wildlife species or populations and to restore, protect or enhance natural ecosystems. Major threats to wildlife include habitat destruction, degradation, fragmentation, overexploitation, poaching, pollution, climate change, and the illegal wildlife trade. The IUCN estimates that 42,100 species of the ones assessed are at risk for extinction. [1] Expanding to all existing species, a 2019 UN report on biodiversity put this estimate even higher at a million species. It is also being acknowledged that an increasing number of ecosystems on Earth containing endangered species are disappearing. To address these issues, there have been both national and international governmental efforts to preserve Earth's wildlife. Prominent conservation agreements include the 1973 Convention on International Trade in Endangered Species of Wild Fauna and Flora (CITES) and the 1992 Convention on Biological Diversity (CBD). [2] [3] There are also numerous nongovernmental organizations (NGO's) dedicated to conservation such as the Nature Conservancy, World Wildlife Fund, and Conservation International.

Contents

Threats to wildlife

A forest burned for agriculture in southern Mexico. Lacanja burn crop.JPG
A forest burned for agriculture in southern Mexico.

Habitat destruction

Habitat destruction decreases the number of places where wildlife can live in. Habitat fragmentation breaks up a continuous tract of habitat, often dividing large wildlife populations into several smaller ones. [4] Human-caused habitat loss and fragmentation are primary drivers of species declines and extinctions. Key examples of human-induced habitat loss include deforestation, agricultural expansion, and urbanization. Habitat destruction and fragmentation can increase the vulnerability of wildlife populations by reducing the space and resources available to them and by increasing the likelihood of conflict with humans. Moreover, destruction and fragmentation create smaller habitats. Smaller habitats support smaller populations, and smaller populations are more likely to go extinct. [5] The COVID-19 pandemic has caused a significant shift in human behavior, resulting in mandatory and voluntary limitations on movement. As a result, people have started utilizing green spaces more frequently, which were previously habitats for wildlife. Unfortunately, this increased human activity has caused destruction to the natural habitat of various species. [6]

Deforestation

Deforestation is the clearing and cutting down forests on purpose. Deforestation is a cause of human-induced habitat action destruction, by cutting down habitats of different species in the process of removing trees. Deforestation is often done for several reasons, often for either agricultural purposes or for logging, which is the obtainment of timber and wood for use in construction or fuel. [7] Deforestation causes many threats to wildlife as it not only causes habitat destruction for the many animals that survive in forests, as more than 80% of the world's species live in forests but also leads to further climate change. [8] Deforestation is a main concern in the tropical forests of the world. Tropical forests, like the Amazon, are home to the most biodiversity out of any other biome, making deforestation there an even more prevalent issue, especially in populated areas, as in these areas deforestation leads to habitat destruction and the endangerment of many species in one area. [9] Some policies have been enacted to attempt to stop deforestation in different parts of the world, like the Wilderness Act of 1964 which designated specific areas wilderness to be protected. [10]

Overexploitation

Overexploitation is the harvesting of animals and plants at a rate that's faster than the species' ability to recover. While often associated with Overfishing, overexploitation can apply to many groups including mammals, birds, amphibians, reptiles, and plants. [11] The danger of overexploitation is that if too many of a species offspring are taken, then the species may not recover. [12] For example, overfishing of top marine predatory fish like tuna and salmon over the past century has led to a decline in fish sizes as well as fish numbers. [4]

Confiscated animal pelts from the illegal wildlife trade. Illegal wildlife trade confiscated skins.jpeg
Confiscated animal pelts from the illegal wildlife trade.

Poaching

Poaching for illegal wildlife trading is a major threat to certain species, particularly endangered ones whose status makes them economically valuable. [13] Such species include many large mammals like African elephants, tigers, and rhinoceros (traded for their tusks, skins, and horns respectively). [13] [14] Less well-known targets of poaching include the harvest of protected plants and animals for souvenirs, food, skins, pets, and more. [15] Poaching causes already small populations to decline even further as hunters tend to target threatened and endangered species because of their rarity and large profits. [15]

Ocean Acidification

Pterapod shell dissolved in seawater adjusted to an ocean chemistry projected for the year 2100 Pterapod shell dissolved in seawater adjusted to an ocean chemistry projected for the year 2100.jpg
Pterapod shell dissolved in seawater adjusted to an ocean chemistry projected for the year 2100

As carbon dioxide levels increase concentration in the atmosphere, they increase in the ocean as well. Typically, the ocean will absorb carbon from the atmosphere, where it can be sequestered in the deep ocean and sea floor; this is a process called the biological pump. Increased carbon dioxide emissions and increased stratification (which slows the biological pump) decrease the ocean pH, making it more acidic. Calcifying organisms such as coral are especially susceptible to decreased pH, resulting in mass bleaching events, inevitably destroying a habitat for many of coral's diverse inhabitants. Research (conducted through methods such as coral fossils and ancient ice core carbon analysis) suggests ocean acidification has occurred in the geological past (more likely at a slower pace), and correlate with past extinction events. [16]

Culling

Culling is the deliberate and selective killing of wildlife by governments for various purposes. An example of this is shark culling, in which "shark control" programs in Queensland and New South Wales (in Australia) have killed thousands of sharks, as well as turtles, dolphins, whales, and other marine life. [17] [18] [19] The Queensland "shark control" program alone has killed about 50,000 sharks — it has also killed more than 84,000 marine animals. [20] [17] There are also examples of population culling in the United States, such as bison in Montana and swans, geese, and deer in New York and other places. [21] [22]

Aerial view of the BP Deepwater Horizon oil spill in 2010. Deepwater Horizon Oil Spill - Gulf of Mexico.jpg
Aerial view of the BP Deepwater Horizon oil spill in 2010.

Pollution

A wide range of pollutants negatively impact wildlife health. For some pollutants, simple exposure is enough to do damage (e.g. pesticides). For others, its through inhaling (e.g. air pollutants) or ingesting it (e.g. toxic metals). Pollutants affect different species in different ways so a pollutant that is bad for one might not affect another.

Climate change

Humans are responsible for present-day climate change currently changing Earth's environmental conditions. It is related to some of the aforementioned threats to wildlife like habitat destruction and pollution. Rising temperatures, melting ice sheets, changes in precipitation patterns, severe droughts, more frequent heat waves, storm intensification, ocean acidification, and rising sea levels are some of the effects of climate change. [26] Phenomena like droughts, wildfires, heatwaves, intense storms, ocean acidification, and rising sea levels, directly lead to habitat destruction. For example, longer dry seasons, warmer springs, and dry soil has been observed to increase the length of wildfire season in forests, shrublands and grasslands. Increased severity and longevity of wildfires can completely wipe out entire ecosystems, causing them to take decades to fully recover. Wildfires are a prime example of the direct negative effect climate change has on wildlife and ecosystems. [27] Meanwhile, a warming climate, fluctuating precipitation, and changing weather patterns will impact species ranges. Overall, the effects of climate change increase stress on ecosystems, and species unable to cope with the rapidly changing conditions will go extinct. [28] While modern climate change is caused by humans, past climate change events occurred naturally and have led to extinctions. [29]

Illegal Wildlife Trade

The illegal wildlife trade is the illegal trading of plants and wildlife. This illegal trading is worth an estimate of 7-23 billion [30] and an annual trade of around 100 million plants and animals. [31] In 2021 it was found that this trade has caused a 60% decline in species abundance, and 80% for endangered species. [31]

This trade can be devastating to both humans and animals. It has the capacity to spread zoonotic diseases to humans, as well as contribute to local extinction. The pathogens to humans may be spread through small animal vectors like ticks, or through ingestion of food and water. Extinction can be caused due to non-native species being introduced that become invasive. An example of how this may happen is through by-catch.These new species will outcompete the native species and take over, therefore causing the local or global extinction of a species. [32]

Due to the fittest animals in the species being hunted or poached, the less fit organisms will mate, causing less fitness in the generations to come. In addition to species fitness being lowered and therefore endangering species, the illegal wildlife trade has ecological costs. Sex-ratio balances may be tipped or reproduction rates are slowed, which can be detrimental to vulnerable species. The recovery of these populations may take longer due to the reproduction rates being slower. [33]

The wildlife trade also causes issues for natural resources that people use in their everyday lives. Ecotourism is how some people bring in money to their homes, and with depleting the wildlife, this may be a factor in taking away jobs. [33]

Illegal wildlife trade has also become normalized through various social media outlets. There are TikTok accounts that have gone viral for their depiction of exotic pets, such as various monkey and bird species. These accounts show a cute and fun side of owning exotic pets, therefore indirectly encouraging illegal wildlife trade. On March 30, 2021, TikTik joined the Coalition to End Wildlife Trafficking Online. They, along with other big social media companies work to protect species from illegal, harmful trade online. [34] [35] Research has shown that machine learning can filter through social media posts to identify indications of illegal wildlife trade. This filtration system is able to search for keywords, pictures, and phrases that indicate illegal wildlife trade, and report it. [36]

Species conservation

Leatherback sea turtle (Dermochelys coriacea) Leatherback Sea Turtle (17665415746).jpg
Leatherback sea turtle (Dermochelys coriacea)

It is estimated that, because of human activities, current species extinction rates are about 1000 times greater than the background extinction rate (the 'normal' extinction rate that occurs without additional influence). [37] According to the IUCN, out of all species assessed, over 42,100 are at risk of extinction and should be under conservation. [1] Of these, 25% are mammals, 14% are birds, and 40% are amphibians. [1] However, because not all species have been assessed, these numbers could be even higher. A 2019 UN report assessing global biodiversity extrapolated IUCN data to all species and estimated that 1 million species worldwide could face extinction. [38] [39] Conservation of a select species are often prioritized on several factors which include significant economic and ecological value, as well as desirability or attractiveness. [40] Yet, because resources are limited, sometimes it is not possible to give all species that need conservation due consideration.

Leatherback sea turtle

The leatherback sea turtle (Dermochelys coriacea) is the largest turtle in the world, is the only turtle without a hard shell, and is endangered. [41] It is found throughout the central Pacific and Atlantic Oceans but several of its populations are in decline across the globe (though not all). The leatherback sea turtle faces numerous threats including being caught as bycatch, harvest of its eggs, loss of nesting habitats, and marine pollution. [41] In the US where the leatherback is listed under the Endangered Species Act, measures to protect it include reducing bycatch captures through fishing gear modifications, monitoring and protecting its habitat (both nesting beaches and in the ocean), and reducing damage from marine pollution. [42] There is currently an international effort to protect the leatherback sea turtle. [43]

Habitat conservation

Red-cockaded woodpecker (Picoides borealis) Red-cockaded woodpecker feeding young (5806270700).jpg
Red-cockaded woodpecker (Picoides borealis)

Habitat conservation is the practice of protecting a habitat [44] in order to protect the species within it. [4] This is sometimes preferable to focusing on a single species especially if the species in question has very specific habitat requirements or lives in a habitat with many other endangered species. The latter is often true of species living in biodiversity hotspots, which are areas of the world with an exceptionally high concentration of endemic species (species found nowhere else in the world). [45] Many of these hotspots are in the tropics, mainly tropical forests like the Amazon. [46] Habitat conservation is usually carried out by setting aside protected areas like national parks or nature reserves. Even when an area isn't made into a park or reserve, it can still be monitored and maintained.

Red-cockaded woodpecker

Red-cockaded Woodpecker (picoides borealis) Picoides borealis USMC2005729133853B.jpg
Red-cockaded Woodpecker (picoides borealis)

The red-cockaded woodpecker (Picoides borealis) is an endangered bird in the southeastern US. [47] It only lives in longleaf pine savannas which are maintained by wildfires in mature pine forests. Today, it is a rare habitat (as fires have become rare and many pine forests have been cut down for agriculture) and is commonly found on land occupied by US military bases, where pine forests are kept for military training purposes and occasional bombings (also for training) set fires that maintain pine savannas. [4] Woodpeckers live in tree cavities they excavate in the trunk. In an effort to increase woodpecker numbers, artificial cavities (essentially birdhouses planted within tree trunks) were installed to give woodpeckers a place to live. An active effort is made by the US military and workers to maintain this rare habitat used by red-cockaded woodpeckers.

Conservation genetics

Florida panther (Puma concolor coryi) Florida panther(2) (5164633462).jpg
Florida panther (Puma concolor coryi)

Conservation genetics studies genetic phenomena that impact the conservation of a species. Most conservation efforts focus on managing population size, but conserving genetic diversity is typically a high priority as well. High genetic diversity increases survival because it means greater capacity to adapt to future environmental changes. [5] Meanwhile, effects associated with low genetic diversity, such as inbreeding depression and loss of diversity from genetic drift, often decrease species survival by reducing the species' capacity to adapt or by increasing the frequency of genetic problems. Though not always the case, certain species are under threat because they have very low genetic diversity. As such, the best conservation action would be to restore their genetic diversity.

Florida panther

The Florida panther is a subspecies of cougar (specifically Puma concolor coryi) that resides in the state of Florida and is currently endangered. [48] Historically, the Florida panther's range covered the entire southeastern US. In the early 1990s, only a single population with 20-25 individuals were left. The population had very low genetic diversity, was highly inbred, and suffered from several genetic issues including kinked tails, cardiac defects, and low fertility. [5] In 1995, eight female Texas cougars were introduced to the Florida population. The goal was to increase genetic diversity by introducing genes from a different, unrelated puma population. By 2007, the Florida panther population had tripled and offspring between Florida and Texas individuals had higher fertility and less genetic problems. In 2015, the US Fish and Wildlife Service estimated there were 230 adult Florida panthers and in 2017, there were signs that the population's range was expanding within Florida. [48]

Conservation methods

Wildlife Monitoring

Non-invasive monitoring of the dhole is crucial for knowledge about its conservation status. Asiatic Wild Dogs (44187676292).jpg
Non-invasive monitoring of the dhole is crucial for knowledge about its conservation status.

Monitoring of wildlife populations is an important part of conservation because it allows managers to gather information about the status of threatened species and to measure the effectiveness of management strategies. Monitoring can be local, regional, or range-wide, and can include one or many distinct populations. Metrics commonly gathered during monitoring include population numbers, geographic distribution, and genetic diversity, although many other metrics may be used.

Monitoring methods can be categorized as either "direct" or "indirect". Direct methods rely on directly seeing or hearing the animals, whereas indirect methods rely on "signs" that indicate the animals are present. For terrestrial vertebrates, common direct monitoring methods include direct observation, mark-recapture, transects, and variable plot surveys. Indirect methods include track stations, fecal counts, food removal, open or closed burrow-opening counts, burrow counts, runaway counts, knockdown cards, snow tracks, or responses to audio calls. [49]

For large, terrestrial vertebrates, a popular method is to use camera traps for population estimation along with mark-recapture techniques. This method has been used successfully with tigers, black bears and numerous other species. [50] [51] Trail cameras can be triggered remotely and automatically via sound, infrared sensors, etc. Computer vision-based animal individual re-identification methods have been developed to automate such sight-resight calculations. [52] [53] Mark-recapture methods are also used with genetic data from non-invasive hair or fecal samples. [54] Such information can be analyzed independently or in conjunction with photographic methods to get a more complete picture of population viability.

When designing a wildlife monitoring strategy, it is important to minimize harm to the animal and implement the 3Rs principles (Replacement, Reduction, Refinement). [55] In wildlife research, this can be done through the use of non-invasive methods, sharing samples and data with other research groups, or optimizing traps to prevent injuries. [56] [57]

Vaccine administration

Distributing vaccinations to wildlife who are particularly vulnerable is useful in conservation to prevent or decelerate extreme population declination in a species from disease and also decrease the risk of a zoonotic spillover to humans. A pathogen that has never once been exposed to a specific species' evolutionary pathway can have detrimental impacts on the population. In most cases, these risks escalate in conjunction to other anthropogenic stressors, such as climate change or habitat loss, that ultimately lead a population to extinction without human intervention. [58] Methods of vaccination varies depending on both the extent and efficiency of limiting the transmission of disease, and can be applied orally, topically, intranasally (IN), or injected either subcutaneously (SC) or intramuscularly (IM). [59] [60] Conservation efforts regarding vaccinations often only serve the purpose of preventing disease related extinction. Rather than completely cleansing the population of the pathogen, infection rates are limited to a smaller percentage of the population. [61]

Case study: Ethiopian Wolf

Ethiopian wolf (Canis simensis citernii) Ethiopian wolf (Canis simensis citernii) 2.jpg
Ethiopian wolf (Canis simensis citernii)

The Ethiopian Wolf (Canissimensis), a canid native to Ethiopia, is an endangered species with less than 440 wolves remaining in the wild. [62] These wolves are primarily exposed to the rabies virus by domestic dogs and are facing extreme population declines, especially in the southern Ethiopia region of the Bale Mountains. [62] [63] To counter this, oral vaccinations are administered to these wolves within favorable bait that is widely distributed around their territories. The wolves consume the bait and with it ingest the vaccine, developing an immunity to rabies as antibodies are produced at significant levels. [63] Wolves within these packs who did not ingest the vaccine will be protected by herd immunity as fewer wolves are exposed to the virus. With continued periodic vaccinations, conservationists will be able to spend more resources on further proactive efforts to help prevent their extinction. [63]

Government involvement

In the US, the Endangered Species Act of 1973 was passed to protect US species deemed in danger of extinction. [64] The concern at the time was that the country was losing species that were scientifically, culturally, and educationally important. In the same year, the Convention on International Trade in Endangered Species of Fauna and Flora (CITES) was passed as part of an international agreement to prevent the global trade of endangered wildlife. [2] In 1980, the World Conservation Strategy was developed by the IUCN with help from the UN Environmental Programme, World Wildlife Fund, UN Food and Agricultural Organization, and UNESCO. [65] Its purpose was to promote the conservation of living resources important to humans. In 1992, the Convention on Biological Diversity (CBD) was agreed on at the UN Conference on Environment and Development (often called the Rio Earth Summit) as an international accord to protect the Earth's biological resources and diversity. [3]

According to the National Wildlife Federation, wildlife conservation in the US gets a majority of its funding through appropriations from the federal budget, annual federal and state grants, and financial efforts from programs such as the Conservation Reserve Program, Wetlands Reserve Program and Wildlife Habitat Incentives Program. [66] [67] A substantial amount of funding comes from the sale of hunting/fishing licenses, game tags, stamps, and excise taxes from the purchase of hunting equipment and ammunition. [68]

The Endangered Species Act is a continuously updated list that remains up-to-date on species that are endangered or threatened. Along with the update of the list, the Endangered Species Act also seeks to implement actions to protect the species within its list. [69] Furthermore, the Endangered Species Act also lists the species that the act has recovered. It is estimated that the act has prevented the extinction of about 291 species, like bald eagles and humpback whales, since its implementation through its different recovery plans and the protection that it provides for these threatened species. [70]

Non-government involvement

In the late 1980s, as the public became dissatisfied with government environmental conservation efforts, people began supporting private sector conservation efforts which included several non-governmental organizations (NGOs) . [71] Seeing this rise in support for NGOs, the U.S. Congress made amendments to the Foreign Assistance Act in 1979 and 1986 “earmarking U.S. Agency for International Development (USAID) funds for [biodiversity]”. [71] From 1990 till now, environmental conservation NGOs have become increasingly more focused on the political and economic impact of USAID funds dispersed for preserving the environment and its natural resources. [72] After the terrorist attacks on 9/11 and the start of former President Bush's War on Terror, maintaining and improving the quality of the environment and its natural resources became a “priority” to “prevent international tensions” according to the Legislation on Foreign Relations Through 2002 [72] and section 117 of the 1961 Foreign Assistance Act. [72]

Non-governmental organizations

Many NGOs exist to actively promote, or be involved with, wildlife conservation:

See also

Related Research Articles

<span class="mw-page-title-main">Holocene extinction</span> Ongoing extinction event caused by human activity

The Holocene extinction, or Anthropocene extinction, is the ongoing extinction event caused by humans during the Holocene epoch. These extinctions span numerous families of plants and animals, including mammals, birds, reptiles, amphibians, fish, and invertebrates, and affecting not just terrestrial species but also large sectors of marine life. With widespread degradation of biodiversity hotspots, such as coral reefs and rainforests, as well as other areas, the vast majority of these extinctions are thought to be undocumented, as the species are undiscovered at the time of their extinction, which goes unrecorded. The current rate of extinction of species is estimated at 100 to 1,000 times higher than natural background extinction rates and is increasing. During the past 100–200 years, biodiversity loss and species extinction have accelerated, to the point that most conservation biologists now believe that human activity has either produced a period of mass extinction, or is on the cusp of doing so. As such, after the "Big Five" mass extinctions, the Holocene extinction event has also been referred to as the sixth mass extinction or sixth extinction; given the recent recognition of the Capitanian mass extinction, the term seventh mass extinction has also been proposed for the Holocene extinction event.

This is an index of conservation topics. It is an alphabetical index of articles relating to conservation biology and conservation of the natural environment.

<span class="mw-page-title-main">Conservation biology</span> Study of threats to biological diversity

Conservation biology is the study of the conservation of nature and of Earth's biodiversity with the aim of protecting species, their habitats, and ecosystems from excessive rates of extinction and the erosion of biotic interactions. It is an interdisciplinary subject drawing on natural and social sciences, and the practice of natural resource management.

<span class="mw-page-title-main">Habitat conservation</span> Management practice for protecting types of environments

Habitat conservation is a management practice that seeks to conserve, protect and restore habitats and prevent species extinction, fragmentation or reduction in range. It is a priority of many groups that cannot be easily characterized in terms of any one ideology.

<span class="mw-page-title-main">Habitat destruction</span> Process by which a natural habitat becomes incapable of supporting its native species

Habitat destruction occurs when a natural habitat is no longer able to support its native species. The organisms once living there have either moved to elsewhere or are dead, leading to a decrease in biodiversity and species numbers. Habitat destruction is in fact the leading cause of biodiversity loss and species extinction worldwide.

<span class="mw-page-title-main">Conservation in New Zealand</span>

Conservation in New Zealand has a history associated with both Māori and Europeans. Both groups of people caused a loss of species and both altered their behaviour to a degree after realising their effect on indigenous flora and fauna.

<span class="mw-page-title-main">Wildlife of Costa Rica</span>

The wildlife of Costa Rica comprises all naturally occurring animals, fungi and plants that reside in this Central American country. Costa Rica supports an enormous variety of wildlife, due in large part to its geographic position between North and South America, its neotropical climate, and its wide variety of habitats. Costa Rica is home to more than 500,000 species, which represent nearly 5% of the species estimated worldwide, making Costa Rica one of the 20 countries with the highest biodiversity in the world. Of these 500,000 species, a little more than 300,000 are insects.

<span class="mw-page-title-main">Captive breeding</span> Of wild organisms, by humans

Captive breeding, also known as captive propagation, is the process of keeping plants or animals in controlled environments, such as wildlife reserves, zoos, botanic gardens, and other conservation facilities. It is sometimes employed to help species that are being threatened by the effects of human activities such as climate change, habitat loss, fragmentation, overhunting or fishing, pollution, predation, disease, and parasitism.

The Lower Guinean forests also known as the Lower Guinean-Congolian forests, are a region of coastal tropical moist broadleaf forest in West Africa, extending along the eastern coast of the Gulf of Guinea from eastern Benin through Nigeria and Cameroon.

<span class="mw-page-title-main">Western barred bandicoot</span> Species of marsupial

The Western barred bandicoot, also known as the Shark Bay bandicoot or the Marl, is a small species of bandicoot; now extinct across most of its former range, the western barred bandicoot only survives on offshore islands and in fenced sanctuaries on the mainland.

<span class="mw-page-title-main">Black-shanked douc</span> Species of Old World monkey

The black-shanked douc is an endangered species of douc found mostly in the forests of Eastern Cambodia, with some smaller populations in Southern Vietnam. The region they are mostly found in is called the Annamite Range, a mountainous area that passes through Cambodia and Vietnam. Its habitat is mostly characterized by evergreen forest in the mountains, in the middle to upper canopy. They move around quadrupedally and by brachiation up in the trees. This species is unique with its coloration among the doucs as it has a bluish face with yellow rings around its eyes a blue scrotum and a pink penis. Like other doucs, this species has a tail as long as its body and head length. Black-shanked douc have been observed in groups ranging from 3 to 30 individuals, depending on their habitat. Group tend to have a fission-fusion dynamic that changes with food availability. Their diet varies from dry to wet season. Regardless of the season, their diet consists mostly of leaves, but they have also been found to consume considerable amounts of fruits and flowers during wet season. The species changed conservation status in 2015 from endangered to critically endangered in the IUCN Red List of Endangered Species. This reassessment is due to an increase of the rate of population decline. No global population estimate exists. The majority of the population can be found in Cambodia, with smaller populations in Vietnam. In fact, the Wildlife Conservation Society reports almost 25,000 individuals in Cambodia's Keo Seima Wildlife Sanctuary, a population that has remained stable over the last decade. The largest populations estimated to be in Vietnam is around 500-600 individuals. The biggest challenges that the black-shanked douc faces in terms of conservation are habitat loss and illegal poaching. Conservation efforts are being made to control illegal poaching and trade in Vietnam by putting laws against hunting and trading threatened species.

<span class="mw-page-title-main">Wildlife trade</span> Worldwide industry dealing in the acquisition and sale of wildlife

Wildlife trade refers to the products that are derived from non-domesticated animals or plants usually extracted from their natural environment or raised under controlled conditions. It can involve the trade of living or dead individuals, tissues such as skins, bones or meat, or other products. Legal wildlife trade is regulated by the United Nations' Convention on International Trade in Endangered Species of Wild Fauna and Flora (CITES), which currently has 184 member countries called Parties. Illegal wildlife trade is widespread and constitutes one of the major illegal economic activities, comparable to the traffic of drugs and weapons.

<span class="mw-page-title-main">Wildlife of Cambodia</span>

The wildlife of Cambodia is very diverse with at least 162 mammal species, 600 bird species, 176 reptile species, 900 freshwater fish species, 670 invertebrate species, and more than 3000 plant species. A single protected area, Keo Seima Wildlife Sanctuary, is known to support more than 950 total species, including 75 species that are listed as globally threatened on the IUCN Red List. An unknown amount of species remains to be described by science, especially the insect group of butterflies and moths, collectively known as lepidopterans.

Genetic erosion is a process where the limited gene pool of an endangered species diminishes even more when reproductive individuals die off before reproducing with others in their endangered low population. The term is sometimes used in a narrow sense, such as when describing the loss of particular alleles or genes, as well as being used more broadly, as when referring to the loss of a phenotype or whole species.

<span class="mw-page-title-main">Earthwatch Institute</span> Scientific field research institute

Earthwatch Institute is an international environmental charity. It was founded in 1971 as Educational Expeditions International by Bob Citron and Clarence Truesdale. Earthwatch Institute supports Ph.D. researchers internationally and conducts over 100,000 hours of research annually using the Citizen Science methodology. Earthwatch's mission statement states that the organization "connects people with scientists worldwide to conduct environmental research and empowers them with the knowledge they need to conserve the planet." As such, it is one of the global underwriters of scientific field research in climate change, archaeology, paleontology, marine life, biodiversity, ecosystems and wildlife. For over fifty years, Earthwatch has raised funds to recruit individuals, students, teachers, and corporate fellows to participate in field research to understand nature's response to accelerating global change.

<span class="mw-page-title-main">Endangered species</span> Species of organisms facing a very high risk of extinction

An endangered species is a species that is very likely to become extinct in the near future, either worldwide or in a particular political jurisdiction. Endangered species may be at risk due to factors such as habitat loss, poaching, invasive species, and climate change. The International Union for Conservation of Nature (IUCN) Red List lists the global conservation status of many species, and various other agencies assess the status of species within particular areas. Many nations have laws that protect conservation-reliant species which, for example, forbid hunting, restrict land development, or create protected areas. Some endangered species are the target of extensive conservation efforts such as captive breeding and habitat restoration.

<span class="mw-page-title-main">Defaunation</span> Loss or extinctions of animals in the forests

Defaunation is the global, local, or functional extinction of animal populations or species from ecological communities. The growth of the human population, combined with advances in harvesting technologies, has led to more intense and efficient exploitation of the environment. This has resulted in the depletion of large vertebrates from ecological communities, creating what has been termed "empty forest". Defaunation differs from extinction; it includes both the disappearance of species and declines in abundance. Defaunation effects were first implied at the Symposium of Plant-Animal Interactions at the University of Campinas, Brazil in 1988 in the context of Neotropical forests. Since then, the term has gained broader usage in conservation biology as a global phenomenon.

<span class="mw-page-title-main">Biodiversity loss</span> Extinction of species or loss of species in a given habitat

Biodiversity loss happens when plant or animal species disappear completely from Earth (extinction) or when there is a decrease or disappearance of species in a specific area. Biodiversity loss means that there is a reduction in biological diversity in a given area. The decrease can be temporary or permanent. It is temporary if the damage that led to the loss is reversible in time, for example through ecological restoration. If this is not possible, then the decrease is permanent. The cause of most of the biodiversity loss is, generally speaking, human activities that push the planetary boundaries too far. These activities include habitat destruction and land use intensification. Further problem areas are air and water pollution, over-exploitation, invasive species and climate change.

<span class="mw-page-title-main">Endangerment of orangutans</span>

There are three species of orangutan. The Bornean orangutan, the most common, can be found in Kalimantan, Indonesia and Sarawak and Sabah in Malaysia. The Sumatran orangutan and the Tapanuli orangutan are both only found in Sumatra, Indonesia. The conservation status of all three of these species is critically endangered, according to the International Union for Conservation of Nature (IUCN) Red List. 

References

  1. 1 2 3 "The IUCN Red List of Threatened Species". IUCN Red List of Threatened Species. Retrieved 2019-04-15.
  2. 1 2 "What is CITES?". CITES: Convention on International Trade in Endangered Species of Wild Fauna dn Flora. Retrieved 2019-05-13.
  3. 1 2 "History of the Convention". Convention on Biological Diversity. Retrieved 2019-05-13.
  4. 1 2 3 4 Cain, Michael L.; Bowman, William D.; Hacker, Sally D. (2013). Ecology (3rd ed.). Sunderland, Massachusetts, U.S.A.: Sinauer Associates. ISBN   9780878939084. OCLC   868150915.
  5. 1 2 3 Frankham, Richard; Ballou, Jonathan D.; Ralls, Katherine; Eldridge, Mark D. B.; Dudash, Michele R.; Fenstar, Charles B.; Lacy, Robert C.; Sunnucks, Paul (2017). Genetic Management of Fragmented Animal and Plant Populations. New York, NY: Oxford University Press. ISBN   9780198783398.
  6. Coman, Ioana A.; Cooper-Norris, Caitlyn E.; Longing, Scott; Perry, Gad (2022-07-04). "It Is a Wild World in the City: Urban Wildlife Conservation and Communication in the Age of COVID-19". Diversity. 14 (7): 539. doi: 10.3390/d14070539 . ISSN   1424-2818.
  7. "Deforestation | National Geographic Society". education.nationalgeographic.org.
  8. Martin. "Forests, desertification and biodiversity". United Nations Sustainable Development. Retrieved 2022-05-29.
  9. "Deforestation and Forest Degradation | Threats | WWF". World Wildlife Fund. Retrieved 2022-05-29.
  10. "The Wilderness Act | The Wilderness Society". www.wilderness.org. Retrieved 2022-05-29.
  11. "Overexploitation". National Wildlife Federation. Retrieved 2019-05-12.
  12. "Overexploitation". The Environmental Literacy Council. Archived from the original on 2021-04-29. Retrieved 2019-05-12.
  13. 1 2 "Illegal Wildlife Trade". U.S. Fish and Wildlife Service. Retrieved 2019-04-14.
  14. "Illegal Wildlife Trade- Overview". World Wildlife Fund. Retrieved 2019-04-14.
  15. 1 2 "What is Poaching? The Illegal Wildlife Trade Explained". World Wildlife Fund. Retrieved 2023-04-12.
  16. Scott., Mills, L. Conservation of Wildlife Populations : Demography, Genetics, and Management. ISBN   978-1-118-40669-4. OCLC   1347768873.{{cite book}}: CS1 maint: multiple names: authors list (link)
  17. 1 2 Mitchell, Thom (2015-11-20). "Queensland's Shark Control Program Has Snagged 84,000 Animals". Action for Dolphins. Retrieved 2019-01-04.
  18. "Shark culling · Save our Sharks · Australian Marine Conservation Society". 2018-10-02. Archived from the original on 2018-10-02. Retrieved 2023-09-27.
  19. Morris, Jessica (2016-12-08). "Shark nets – death traps for marine animals". Humane Society International (HSI). Retrieved 2023-09-27.
  20. "Aussie shark population in staggering decline". Sydney Today. 14 December 2018.
  21. James, Will (2014-03-06). "Killing Wildlife: The Pros and Cons of Culling Animals". National Geographic. Archived from the original on March 9, 2014. Retrieved 7 March 2019.
  22. Hadidian, John (Dec 5, 2015). "Wildlife in U.S. Cities: Managing Unwanted Animals". Animals. 5 (4): 1092–1113. doi: 10.3390/ani5040401 . PMC   4693205 . PMID   26569317.
  23. "Sulfur Dioxide Basics". US EPA. 2016-06-02. Retrieved 2019-05-12.
  24. Tchounwou, Paul B.; Yedjou, Clement G.; Patlolla, Anita K.; Sutton, Dwayne J. (2012), Luch, Andreas (ed.), "Heavy Metal Toxicity and the Environment", Molecular, Clinical and Environmental Toxicology, Experientia Supplementum, vol. 101, Springer Basel, pp. 133–164, doi:10.1007/978-3-7643-8340-4_6, ISBN   9783764383398, PMC   4144270 , PMID   22945569
  25. "Persistent organic pollutants (POPs)". World Health Organization. Retrieved 2019-05-12.
  26. "The Effects of Climate Change". NASA Climate Change: Vital Signs of the Planet. Retrieved 2019-05-13.
  27. Environmental Protection Agency (July 21, 2023). "Climate Change Indicators: Wildfires". United States Environmental Protection Agency. Retrieved October 15, 2023.
  28. Dawson, T. P.; Jackson, S. T.; House, J. I.; Prentice, I. C.; Mace, G. M. (2011-04-01). "Beyond Predictions: Biodiversity Conservation in a Changing Climate". Science. 332 (6025): 53–58. Bibcode:2011Sci...332...53D. doi:10.1126/science.1200303. ISSN   0036-8075. PMID   21454781. S2CID   40618973.
  29. "Climate Change Evidence: How Do We Know?". Climate Change: Vital Signs of the Planet. Retrieved 2023-04-12.
  30. "Share the Facts About Wildlife Trafficking". www.conservation.org. Retrieved 2023-04-13.
  31. 1 2 "Wildlife trade drives declines of over 60% in species abundance, according to new research". www.sheffield.ac.uk. 2021-02-15. Retrieved 2023-04-13.
  32. Bezerra-Santos, Marcos A.; Mendoza-Roldan, Jairo A.; Thompson, R. C. Andrew; Dantas-Torres, Filipe; Otranto, Domenico (2021-03-01). "Illegal Wildlife Trade: A Gateway to Zoonotic Infectious Diseases". Trends in Parasitology. 37 (3): 181–184. doi:10.1016/j.pt.2020.12.005. ISSN   1471-4922. PMID   33454218. S2CID   231635434.
  33. 1 2 KKIENERM. "Wildlife, Forest & Fisheries Crime Module 1 Key Issues: Implications of Wildlife Trafficking". www.unodc.org. Retrieved 2023-04-13.
  34. Hernandez, Daniela. "Is TikTok promoting the exotic pet trade?". www.hybridmag.co.uk. Retrieved 2023-10-15.
  35. Wild, Asia (2023-04-04). "Asian Animal Welfare in 2023: Preventing Poaching, Abuse and Illegal Wildlife Trade". Asia Wild. Retrieved 2023-10-07.
  36. Di Minin, Enrico; Fink, Christoph; Hiippala, Tuomo; Tenkanen, Henrikki (February 2019). "A framework for investigating illegal wildlife trade on social media with machine learning". Conservation Biology. 33 (1): 210–213. Bibcode:2019ConBi..33..210D. doi:10.1111/cobi.13104. ISSN   0888-8892. PMC   7379580 . PMID   29528136.
  37. Pimm, S. L.; Jenkins, C. N.; Abell, R.; Brooks, T. M.; Gittleman, J. L.; Joppa, L. N.; Raven, P. H.; Roberts, C. M.; Sexton, J. O. (2014-05-30). "The biodiversity of species and their rates of extinction, distribution, and protection". Science. 344 (6187): 1246752. doi:10.1126/science.1246752. ISSN   0036-8075. PMID   24876501. S2CID   206552746.
  38. "UN Report: Nature's Dangerous Decline 'Unprecedented'; Species Extinction Rates 'Accelerating'". United Nations Sustainable Development. 2019-05-06. Retrieved 2019-05-22.
  39. Diaz, Sandra; Settele, Josef; Brondizio, Eduardo (2019-05-06). "Summary for policymakers of the global assessment report on biodiversity and ecosystem services of the Intergovernmental Science-Policy Platform on Biodiversity and Ecosystem Services" (PDF). ipbes. Retrieved 2019-05-22.
  40. Fischer, Anke; Bednar-Friedl, Birgit; Langers, Fransje; Dobrovodská, Marta; Geamana, Nicoleta; Skogen, Ketil; Dumortier, Myriam (2011-03-01). "Universal criteria for species conservation priorities? Findings from a survey of public views across Europe". Biological Conservation. The New Conservation Debate: Beyond Parks vs. People. 144 (3): 998–1007. Bibcode:2011BCons.144..998F. doi:10.1016/j.biocon.2010.12.004. ISSN   0006-3207.
  41. 1 2 "Leatherback Turtle". NOAA Fisheries. Retrieved 2019-06-06.
  42. Bernton, Hal; Bush, Evan. "Pacific sea turtles likely to go extinct under Trump administration policy, lawsuit argues". The Sacramento Bee. ISSN   0890-5738 . Retrieved 2019-06-12.
  43. "What is CITES?". CITES: Convention on International Trade in Endangered Species of Wild Fauna dn Flora. Retrieved 2019-05-13.
  44. "Wild Life | The Samajh". www.thesamajh.in. Archived from the original on 2022-01-29. Retrieved 2021-10-04.
  45. Kent, Jennifer; Gustavo A. B. da Fonseca; Mittermeier, Cristina G.; Mittermeier, Russell A.; Myers, Norman (2000). "Biodiversity hotspots for conservation priorities". Nature. 403 (6772): 853–858. Bibcode:2000Natur.403..853M. doi:10.1038/35002501. ISSN   1476-4687. PMID   10706275. S2CID   4414279.
  46. Stafleu, F. A. (1970). [Review of Speciation in Tropical Environments, by R. H. Lowe-McConnell]. Taxon, 19(2), 273–275. https://doi.org/10.2307/1217968
  47. "Red-Cockaded Woodpecker". U.S. Fish and Wildlife Service. 2016-12-19. Retrieved 2019-06-06.
  48. 1 2 "Florida Panther". www.fws.gov. 2018-01-11. Retrieved 2019-05-28.
  49. Witmer, Gary (2005). "Wildlife population monitoring: some practical considerations". Wildlife Research. 32 (3): 259–263. doi:10.1071/WR04003. Archived from the original on 2020-02-13. Retrieved 2019-11-18.
  50. Karanth, K. Ullas; Nichols, James D., eds. (2017). Methods For Monitoring Tiger And Prey Populations | SpringerLink (PDF). doi:10.1007/978-981-10-5436-5. ISBN   978-981-10-5435-8. S2CID   33402538.
  51. Molina, Santiago; Fuller, Angela K.; Morin, Dana J.; Royle, J. Andrew (May 2017). "Use of spatial capture–recapture to estimate density of Andean bears in northern Ecuador". Ursus. 28 (1): 117–126. doi:10.2192/URSU-D-16-00030.1. ISSN   1537-6176. S2CID   89925949.
  52. Schneider, Stefan; Taylor, Graham W.; Kremer, Stefan C. (2020). "Similarity Learning Networks for Animal Individual Re-Identification - Beyond the Capabilities of a Human Observer". 2020 IEEE Winter Applications of Computer Vision Workshops (WACVW). IEEE. pp. 44–52. arXiv: 1902.09324 . doi:10.1109/wacvw50321.2020.9096925. ISBN   978-1-7281-7162-3.
  53. Wang, Le; Ding, Rizhi; Zhai, Yuanhao; Zhang, Qilin; Tang, Wei; Zheng, Nanning; Hua, Gang (2021). "Giant Panda Identification" (PDF). IEEE Transactions on Image Processing. 30. Institute of Electrical and Electronics Engineers (IEEE): 2837–2849. Bibcode:2021ITIP...30.2837W. doi:10.1109/tip.2021.3055627. ISSN   1057-7149. PMID   33539294. S2CID   231818504.
  54. Robinson, Stacie; Waits, Lisette; Martin, Ian (2009-06-03). "Estimating abundance of American black bears using DNA-based capture–mark–recapture models". Ursus. 20: 1–11. doi:10.2192/08GR022R.1. S2CID   84690450.
  55. Russell, W. M. S.; Burch, R. L. (1959). The Principles of Humane Experimental Technique. London, UK: Methuen.
  56. Zemanova, Miriam A. (2020-03-17). "Towards more compassionate wildlife research through the 3Rs principles: moving from invasive to non-invasive methods". Wildlife Biology. 2020 (1). doi: 10.2981/wlb.00607 . hdl: 10453/143370 . ISSN   0909-6396. S2CID   216291100.
  57. Zemanova, Miriam A. (2023-11-30). "The 3Rs Principles in Wildlife Research".
  58. Russell, Robin E.; DiRenzo, Graziella V.; Szymanski, Jennifer A.; Alger, Katrina E.; Grant, Evan H. C. (2020). "Principles and Mechanisms of Wildlife Population Persistence in the Face of Disease". Frontiers in Ecology and Evolution. 8. doi: 10.3389/fevo.2020.569016 . ISSN   2296-701X.
  59. jlp342 (2020-02-17). "Wildlife Vaccination - Growing in Feasibility?". cwhl.vet.cornell.edu. Retrieved 2023-04-12.{{cite web}}: CS1 maint: numeric names: authors list (link)
  60. Tizard, Ian R. (2021-01-01), Tizard, Ian R. (ed.), "Chapter 8 - The administration of vaccines", Vaccines for Veterinarians, Elsevier, pp. 87–104.e1, ISBN   978-0-323-68299-2 , retrieved 2023-04-12
  61. Barnett, K. M.; Civitello, David J. (2020-12-01). "Ecological and Evolutionary Challenges for Wildlife Vaccination". Trends in Parasitology. 36 (12): 970–978. doi:10.1016/j.pt.2020.08.006. ISSN   1471-4922. PMC   7498468 . PMID   32952060.
  62. 1 2 "Ethiopian Wolf". African Wildlife Foundation. Retrieved 2023-04-12.
  63. 1 2 3 Sillero-Zubiri, Claudio; Marino, Jorgelina; Gordon, Christopher H.; Bedin, Eric; Hussein, Alo; Regassa, Fekede; Banyard, Ashley; Fooks, Anthony R. (2016-09-14). "Feasibility and efficacy of oral rabies vaccine SAG2 in endangered Ethiopian wolves". Vaccine. 34 (40): 4792–4798. doi:10.1016/j.vaccine.2016.08.021. ISSN   0264-410X. PMID   27543453.
  64. "Endangered Species Act | Overview". U.S. Fish & Wildlife Service. 2018-12-11. Retrieved 2019-06-06.
  65. "World Conservation Strategy" (PDF). Retrieved 2011-05-01.
  66. "Securing Funds for Conservation". National Wildlife Federation. www.nwf.org. Retrieved 2018-12-25.
  67. "Farm Bill". National Wildlife Federation. www.nwf.org. Retrieved 2018-12-25.
  68. Service, U.S. Fish and Wildlife. "Fish and Wildlife Service". www.fws.gov. Retrieved 2016-01-21.
  69. "Endangered Species Act | U.S. Fish & Wildlife Service". FWS.gov. 28 December 1973. Retrieved 2022-05-29.
  70. Greenwald, Noah; Suckling, Kieran F.; Hartl, Brett; A. Mehrhoff, Loyal (2019-04-22). "Extinction and the U.S. Endangered Species Act". PeerJ. 7: e6803. doi: 10.7717/peerj.6803 . ISSN   2167-8359. PMC   6482936 . PMID   31065461.
  71. 1 2 Meyer, Carrie A. (1993). "Environmental NGOs in Ecuador: An Economic Analysis of Institutional Change". The Journal of Developing Areas. 27 (2): 191–210. JSTOR   4192201. PMID   12286336.
  72. 1 2 3 "The Foreign Assistance Act of 1961, as amended" (PDF). Archived from the original (PDF) on 2012-04-16. Retrieved 2011-05-01.
  73. "About Us – Learn More About The Nature Conservancy". Nature.org. 2011-02-23. Retrieved 2011-05-01.
  74. "WWF in Brief". World Wildlife Fund. Retrieved 2011-05-01.
  75. "ZSL | A science-driven conservation charity". www.zsl.org.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.