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Conservation biology is the scientific study of the nature and status of Earth's biodiversity with the aim of protecting species, their habitats, and ecosystems from excessive rates of extinction. It is an interdisciplinary subject drawing on sciences, economics, and the practice of natural resource management. The term conservation biology was introduced as the title of a conference held at the University of Californiamarker in La Jolla, California in 1978 organized by biologists Bruce Wilcox and Michael Soulé. The meeting was prompted by the growing concern among scientists over tropical deforestation, disappearing species, eroding genetic diversity within species. The conference and proceedings that resulted sought to bridge a gap existing at the time between theory in ecology and population biology on the one hand and conservation policy and practice on the other. Conservation biology and the concept of biological diversity (biodiversity) emerged together, helping crystallize the modern era of conservation science and policy.

The rapid decline of biological systems around the world means that conservation biology is often referred to as a "Discipline with a deadline". Conservation biology is tied closely to ecology in researching the dispersal, migration, demographics, effective population size, inbreeding depression, and minimum population viability of rare or endangered species. Conservation biology is concerned with phenomena that affect the maintenance, loss, and restoration of biodiversity and the science of sustaining evolutionary processes that engender genetic, population, species, and ecosystem diversity. The concern stems from estimates suggesting that up to 50% of all species on the planet will disappear within the next 50 years, which has contributed to poverty, starvation, and will reset the course of evolution on this planet.

Conservation biologists research and educate on the trends and process of biodiversity loss, species extinctions, and the negative affect this is having on our capabilities to sustain the well-being of human society. Conservation biologists work in the field and office, in government, universities, non-profit organizations and industry. They are funded to research, monitor, and catalog every angle of the earth and its relation to society. The topics are diverse, because this is an interdisciplinary network with professional alliances in the biological as well as social sciences. Those dedicated to the cause and profession advocate for a global response to the current biodiversity crisis based on morals, ethics, and scientific reason. Organizations and citizens are responding to the biodiversity crisis through conservation action plans that direct research, monitoring, and education programs that engage concerns at local through global scales.

Context and trends

Conservation biologists study trends and process from the paleontological past to the ecological present as they gain an understanding of the context related to species extinction. It is generally accepted that there have been five major global mass extinctions that register in the planets history. These include: the Ordovician (440 mya), Devonian (370 mya), Permian–Triassic (245 mya), Triassic–Jurassic (200 mya), and Cretaceous (65 mya) extinction spasms. Within the last 10,000 years, human influence over the Earth's ecosystems has been so extensive that scientists have difficulty estimating the number of species lost; that is to say the rates of deforestation, reef destruction, wetland draining and other human acts are proceeding much faster than human assessment of species. The latest Living Planet Report by the World Wide Fund for Nature estimates that we have exceeded the bio-regenerative capacity of the planet, requiring 1.5 Earths to support the current demands placed on our natural resources.

Sixth extinction

Conservation biologists are dealing with and have published evidence from all corners of the planet indicating that humanity is living the sixth and greatest planetary extinction event of all time (see also [30957][30958]). We are living an era of unprecedented numbers of species extinctions, also known as the Holocene extinction event. The global extinction rate is approximately 100,000 times higher than the natural background extinction rate. It is estimated that two-thirds of all mammal genera and one-half of all mammal species weighing at least have gone extinct in the last 50,000 years. This sixth extinction period is unique because it is the first major extinction to be caused by another biotic agent over the course of the earth's 4 billion year history.

The Global Amphibian Assessment reports that amphibians are declining on a global scale faster than any other vertebrate group, with over 32% of all surviving species being threatened with extinction. The surviving populations are in continual decline in 43% of those that are threatened. Since the mid-1980s the actual rates of extinction have exceeded 211 times rates measured from the fossil record. However, "The current amphibian extinction rate may range from 25,039 to 45,474 times the background extinction rate for amphibians." The global extinction trend occurs in every major vertebrate group that is being monitored. For example, 23% of all mammals and 12% of all birds are Red Listed by the International Union for Conservation of Nature (IUCN), meaning they too are threatened with extinction.

Status of oceans and reefs

Global assessments of coral reefs of the world continue to report drastic and rapid rates of decline. By 2000, 27% of the world's coral reef ecosystems had effectively collapsed. The largest period of decline occurred in a dramatic "bleaching" event in 1998, where approximately 16% of all the coral reefs in the world disappeared in less than a year. Coral bleaching is caused by a mixture of environmental stresses, including increases in ocean temperatures and acidity, causing both the release of symbiotic algae and death of corals. Decline and extinction risk in coral reef biodiversity has risen dramatically in the past ten years. The loss of coral reefs, which are predicted to go extinct in the next century, will have huge economic impacts, threatens the balance of global biodiversity, and endangers food security for hundreds of millions of people. Conservation biology plays an important role in international agreements covering the world's oceans (and other issues pertaining to biodiversity, e.g. [30960]).

The oceans are threatened by acidification due to an increase in CO2 levels. This is a most serious threat to societies relying heavily upon oceanic natural resources. A concern is that the majority of all marine species will not be able to evolve or acclimate in response to the changes in the ocean chemistry.

The prospects of averting mass extinction seems unlikely when "[...] 90% of all of the large (average approximately ≥50 kg), open ocean tuna, billfishes, and sharks in the ocean" are reportedly gone. Given the scientific review of current trends, the ocean is predicted to have few surviving multi-cellular organisms with only microbes left to dominate marine ecosystems.

Insects and other groups

There are serious concerns also being hailed from taxonomic groups that do not receive the same degree of social attention or attract funds as the vertebrates do, including fungi, lichen, plant and insect communities where the vast majority of biodiversity is represented. Insect conservation, in particular, is of pivotal importance for conservation biology. The value of insects in the biosphere is enormous because they outnumber all other living groups in measure of species richness. The greatest bulk of biomass on land is found in plants, which is sustained by insect relations. This great ecological value of insects is countered by a society that oftentimes reacts negatively toward these aesthetically 'unpleasant' creatures.

One area of concern in the insect world that has caught the public eye is the mysterious case of missing honey bees (Apis mellifera). Honey bees provide an indispensable ecological services through their acts of pollination supporting a huge variety of agriculture crops. The sudden disappearance of bees leaving empty hives or colony collapse disorder (CCD) is not uncommon. However, in a 16-month period from 2006 through 2007, 29% of 577 beekeepers across the United States reported CCD losses in up to 76% of their colonies. This sudden demographic loss in bee numbers is placing a strain on the agricultural sector. The cause behind the massive declines is puzzling scientists. Pests, pesticides, and global warming are all being considered as possible causes.

Another highlight that links conservation biology to insects, forests, and climate change is the mountain pine beetle (Dendroctonus ponderosae) epidemic of British Columbiamarker, Canada, which has infested of forested land since 1999. An action plan has been prepared by the Government of British Columbia to address this problem.

Threats to biodiversity

Many of the threats to biodiversity, including disease and climate change, are reaching inside borders of protected areas, leaving them 'not-so protected' (e.g. Yellowstone National Parkmarker). Climate change, for example, is often cited as a serious threat in this regard, because there is a feedback loop between species extinction and the release of carbon dioxide into the atmosphere. Ecosystems store and cycle large amounts of carbon to regulate global conditions. The effects of global warming adds a catastrophic threat toward a mass extinction of global biological diversity. The extinction threat is estimated to range from 15 to 37 percent of all species by 2050, or 50 percent of all species over the next 50 years.

Some of the most significant and insidious threats to biodiversity and ecosystem processes include climate change, mass agriculture, deforestation, overgrazing, slash-and-burn agriculture, urban development, wildlife trade, light pollution and pesticide use.

Habitat fragmentation poses one of the more difficult challenges, because the global network of protected areas only covers 11.5% of the Earth's surface. A significant consequence of fragmentation and lack of linked protected areas is the reduction of animal migration on a global scale. Considering that billions of tonnes of biomass are responsible for nutrient cycling across the earth, the reduction of migration is a serious matter for conservation biology.

See also,

These figures do not imply, however, that human activities must necessarily cause irreparable harm to the biosphere. With conservation management and planning for biodiversity at all levels, from genes to ecosystems, there are examples where humans mutually coexist in a sustainable way with nature. However, it may be too late for human intervention to reverse the current mass extinction.

Concepts and foundations

Measuring extinction rates

The five major extinction spasms measured by extinction levels in marine animal genera through time.
Blue graph shows apparent percentage (not absolute number) of extinctions during any given time interval.

Extinction rates are measured in a variety of ways. Conservation biologists measure and apply statistical measures of fossil records, rates of habitat loss, and a multitude of other variables such as loss of biodiversity as a function of the rate of habitat loss and site occupancy to obtain such estimates. The Theory of Island Biogeography is possibly the most significant contribution toward the scientific understanding of both the process and how to measure the rate of species extinction. The current background extinction rate is estimated to be one species every few years.

The measure of ongoing species loss is made more complex by the fact that most of the Earth's species have not been described or evaluated. Estimates vary greatly on how many species actually exist (estimated range: 3,600,000-111,700,000) to how many have received a species binomial (estimated range: 1.5-8 million). Less than 1% of all species that have been described have been studied beyond simply noting its existence. From these figures, the IUCN reports that 23% of vertebrates, 5% of invertebrates and 70% of plants that have been evaluated are designated as endangered or threatened.

Systematic conservation planning

Systematic conservation planning is an effective way to seek and identify efficient and effective types of reserve design to capture or sustain the highest priority biodiversity values and to work with communities in support of local ecosystems. Margules and Pressey identify six interlinked stages in the systematic planning approach:

  1. Compile data on the biodiversity of the planning region
  2. Identify conservation goals for the planning region
  3. Review existing conservation areas
  4. Select additional conservation areas
  5. Implement conservation actions
  6. Maintain the required values of conservation areas

Conservation biologists regularly prepare detailed conservation plans for grant proposals or to effectively coordinate their plan of action and to identify best management practices (e.g.

). Systematic strategies generally employ the services of Geographic Information Systems to assist in the decision making process.

Conservation biology as a profession

The Society for Conservation Biology is a global community of conservation professionals dedicated to advancing the science and practice of conserving biodiversity. Conservation biology as a discipline reaches beyond biology, into subjects such as philosophy, law, economics, humanities, arts, anthropology, and education. Within biology, conservation genetics and evolution are immense fields unto themselves, but these disciplines are of prime importance to the practice and profession of conservation biology.

Is conservation biology an objective science when biologists advocate for an inherent value in nature? Do conservationists introduce bias when they support policies using qualitative description, such as habitat degradation, or healthy ecosystems? As all scientists hold values, so do conservation biologists. Conservation biologists advocate for reasoned and sensible management of natural resources and do so with a disclosed combination of science, reason, logic, and values in their conservation management plans. This sort of advocacy is similar to the medical profession advocating for healthy lifestyle options, both are beneficial to human well-being yet remain scientific in their approach. Many conservation biologists, in addition to having a Bachelors of Science (or extensive natural experience) often receive professional accreditation during their career (e.g. [30962]).

There is a movement in conservation biology suggesting a new form of leadership is needed to mobilize conservation biology into a more effective discipline that is able to communicate the full scope of the problem to society at large. The movement proposes an adaptive leadership approach that parallels an adaptive management approach. The concept is based on a new philosophy or leadership theory steering away from historical notions of power, authority, and dominance. Adaptive conservation leadership is reflective and more equitable as it applies to any member of society who can mobilize others toward meaningful change using communication techniques that are inspiring, purposeful, and collegial. Adaptive conservation leadership and mentoring programs are being implemented by conservation biologists through organizations such as the Aldo Leopold Leadership Program


A preservationist differs from a conservation biologist through the principal of non-interference. Preservationists advocate for giving areas of nature and species a protected existence that halts interference from the humans. In this regard, conservationists differ from preservationists in the social dimension, as conservation biology engages society and seeks equitable solutions for both society and ecosystems.

Ethics and values

Conservation biologists are interdisciplinary researchers that practice ethics in the biological and social sciences. Chan states that conservationists must advocate for biodiversity and can do so in a scientifically ethical manner by not promoting simultaneous advocacy against other competing values. A conservationist researches biodiversity and reasons through a Resource Conservation Ethic[30963], which identify what measures will deliver "the greatest good for the greatest number of people for the longest time."

Some conservation biologists argue that nature has an intrinsic value that is independent of anthropocentric usefulness or utilitarianism. Intrinsic value advocates that a gene, or species, be valued because they have a utility for the ecosystems they sustain. Aldo Leopold was a classical thinker and writer on such conservation ethics whose philosophy, ethics and writings are still valued and revisited by modern conservation biologists. His writing is oftentimes required reading for those in the profession.

Conservation priorities

While most in the community of conservation science "stress the importance" of sustaining biodiversity, there is debate on how to prioritize genes, species, or ecosystems, which are all components of biodiversity (e.g. Bowen, 1999). While the predominant approach to date has been to focus efforts on endangered species by conserving biodiversity hotspots, some scientists (e.g. ) and conservation organizations, such as the Nature Conservancy, argue that it is more cost effective, logical, and socially relevant to invest in biodiversity coldspots. The costs of discovering, naming, and mapping out the distribution every species, they argue, is an ill advised conservation venture. They reason it is better to understand the significance of the ecological roles of species.

Biodiversity hotspots and coldspots are a way of recognizing that the spatial concentration of genes, species, and ecosystems is not uniformly distributed on the Earth's surface. For example, "[...] 44% of all species of vascular plants and 35% of all species in four vertebrate groups are confined to 25 hotspots comprising only 1.4% of the land surface of the Earth."

Those arguing in favor of setting priorities for coldspots point out that there are other measures to consider beyond biodiversity. They point out that emphasizing hotspots downplays the importance of the social and ecological connections to vast areas of the Earth's ecosystems where biomass, not biodiversity, reigns supreme. It is estimated that 36% of the Earth's surface, encompassing 38.9% of the worlds vertebrates, lacks the endemic species to qualify as biodiversity hotspot. Moreover, measures show that maximizing protections for biodiversity does not capture ecosystem services any better than targeting randomly chosen regions. Population level biodiversity (i.e. coldspots) are disappearing at a rate that is ten times that at the species level. The level of importance in addressing biomass versus endemism as a concern for conservation biology is highlighted in literature measuring the level of threat to global ecosystem carbon stocks that do not necessarily reside in areas of endemism. A hotspot priority approach would not invest so heavily in places such as steppes, the Serengetimarker, the Arctic, or taiga. These areas contribute a great abundance of population (not species) level biodiversity and ecosystem services, including cultural value and planetary nutrient cycling.

Summary of 2006 IUCN Red List categories.
Those in favor of the hotspot approach point out that species are irreplaceable components of the global ecosystem, they are concentrated in places that are most threatened, and should therefore receive maximal strategic protections. The IUCN Red List categories, which appear on Wikipedia species articles, is an example of the hotspot conservation approach in action; species that are not rare or endemic are listed the least concern and their wikipedia articles tend to be ranked low on the importance scale. This is a hotspot approach because the priority is set to target species level concerns over population level or biomass. Species richness and genetic biodiversity contributes to and engenders ecosystem stability, ecosystem processes, evolutionary adaptability, and biomass.The following papers are examples of research showing the relationship between biodiversity, biomass, and ecosystem stability:[30964]

Both sides agree, however, that conserving biodiversity is necessary to reduce the extinction rate and identify an inherent value in nature; the debate hinges on how to prioritize limited conservation resources in the most cost effective way.

Economic values and natural capital

Conservation biologists have started to collaborate with leading global economists to determine how to measure the wealth and services of nature and to make these values apparent in global market transactions. This system of accounting is called natural capital and would, for example, register the value of an ecosystem before it is cleared to make way for development. The WWF publishes its Living Planet Report and provides a global index of biodiversity by monitoring approximately 5,000 populations in 1,686 species of vertebrate (mammals, birds, fish, reptiles, and amphibians) and report on the trends in much the same way that the stock market is tracked.

This method of measuring the global economic benefit of nature has been endorsed by the G8+5 leaders and the European Commissionmarker. Nature sustains many ecosystem services that benefit humanity. Many of the earths ecosystem services are public goods without a market and therefore no price or value. When the stock market registers a financial crisis, traders on Wall Streetmarker are not in the business of trading stocks for much of the planet's living natural capital stored in ecosystems. There is no natural stock market with investment portfolios into sea horses, amphibians, insects, and other creatures that provide a sustainable supply of ecosystem services that are valuable to society. The ecological footprint of society has exceeded the bio-regenerative capacity limits of the planet's ecosystems by about 30 percent, which is the same percentage of vertebrate populations that have registered decline from 1970 through 2005.

The inherent natural economy plays an essential role in sustaining humanity, including the regulation of global atmospheric chemistry, pollinating crops, pest control, cycling soil nutrients, purifying our water supply, supplying medicines and health benefits, and unquantifiable quality of life improvements. There is a relationship, a correlation, between markets and natural capital, and social income inequity and biodiversity loss. This means that there are greater rates of biodiversity loss in places where the inequity of wealth is greatest

Although a direct market comparison of natural capital is likely insufficient in terms of human value, one measure of ecosystem services suggests the contribution amounts to trillions of dollars yearly. For example, one segment of North American forests has been assigned an annual value of 250 billion dollars; as another example, honey-bee pollination is estimated to provide between 10 and 18 billion dollars of value yearly. The value of ecosystem services on one New Zealandmarker island has been imputed to be as great as the GDP of that region. This planetary wealth is being lost at an incredible rate as the demands of human society is exceeding the bio-regenerative capacity of the Earth. While biodiversity and ecosystems are resilient, the danger of losing them is that humans cannot recreate many ecosystem functions through technological innovation.

Strategic species concepts

Keystone species

Some species, called a keystone species, form a central supporting hub in the ecosystem. The loss of such a species results in a collapse in ecosystem function, as well as the loss of coexisting species. The importance of a keystone species was shown by the extinction of the Steller's Sea Cow (Hydrodamalis gigas) through its interaction with sea otters, sea urchins, and kelp. Kelp beds grow and form nurseries in shallow waters to shelter creatures that support the food chain. Sea urchins feed on kelp, while sea otters feed on sea urchins. With the rapid decline of sea otters due to overhunting, sea urchin populations grazed unrestricted on the kelp beds and the ecosystem collapsed. Left unchecked, the urchins destroyed the shallow water kelp communities that supported the Steller's Sea Cow's diet and hastened their demise. The sea otter is a keystone species because the coexistence of many ecological associates in the kelp beds relied upon otters for their survival.

Indicator species

An indicator species has a narrow set of ecological requirements, therefore they become useful targets for observing the health of an ecosystem. Some animals, such as amphibians with their semi-permeable skin and linkages to wetlands, have an acute sensitivity to environmental harm and thus may serve as a miner's canary. Indicator species are monitored in an effort to capture environmental degradation through pollution or some other link to proximate human activities. Monitoring an indicator species is a measure to determine if there is a significant environmental impact that can serve to advise or modify practice, such as through different forestsilviculture treatments and management scenarios, or to measure the degree of harm that a pesticide may impart on the health of an ecosystem.

Government regulators, consultants, or NGOs regularly regularly monitor indicator species, however, there are limitations coupled with many practical considerations that must be followed for the approach to be effective. It is generally recommended that multiple indicators (genes, populations, species, communities, and landscape) be monitored for effective conservation measurement that prevents harm to the complex, and oftentimes unpredictable, response from ecosystem dynamics (Noss, 1997 ).

Umbrella and flagship species

An example of an umbrella species is the Monarch butterfly, because of its lengthy migrations and aesthetic value. The Monarch migrates across North America, covering multiple ecosystems and so requires a large area to exist. Any protections afforded to the Monarch butterfly will at the same time umbrella many other species and habitats. An umbrella species is often used as flagship species, which are species, such as the Giant Panda, Blue Whale, tigers, and the Monarch butterfly, that capture the public's attention and attract support for conservation measures.


Natural resource conservation

Efforts to conserve and protect global biodiversity are a recent phenomenon. Prior to the global conservation era, there was the coming of the age of conservation. Some historians have linked this with the 1916 National Parks Act, which included the 'use without impairment' clause, sought by John Muir. This eventually resulted in the removal of a proposal to build a dam in Dinosaur National Monument in 1959.

Natural resource conservation, however, has a history that extends prior to the age of conservation. Resource ethics grew out of necessity through direct relations with nature. Regulation or communal restraint became necessary to prevent selfish motives from taking more than could be locally sustained, therefore compromising the long-term supply for the rest of the community. This social dilemma with respect to natural resource management is often called the "Tragedy of the Commons."Also considered to be a consequence of evolution, where individual selection is favored over group selection. For recent discussions, see:

and From this principal, conservation biologists can trace communal resource based ethics throughout cultures as a solution to communal resource conflict. For example, the Alaskan Tlingit peoples and the Haida of the Pacific Northwest had resource boundaries, rules, and restrictions among clans with respect to the fishing of Sockeye Salmon. These rules were guided by clan elders who knew life-long details of each river and stream they managed. There are numerous examples in history where cultures have followed rules, rituals, and organized practice with respect to communal natural resource management.

Conservation ethics are also found in early religious and philosophical writings. There are examples in the Tao, Shinto, Hindu, Islamic and Buddhist traditions. In Greek philosophy, Plato lamented about pasture land degradation: "What is left now is, so to say, the skeleton of a body wasted by disease; the rich, soft soil has been carried off and only the bare framework of the district left." In the bible, through Moses, God commanded to let the land rest from cultivation every seventh year. Before the 18th century, however, much of European culture considered it a pagan view to admire nature. Wilderness was denigrated while agricultural development was praised. Even in 18th century America, However, as early as AD 680 a wildlife sanctuary was founded on the Farne Islandsmarker by St Cuthbert in response to his religious beliefs.

Early naturalists

Natural history was a major preoccupation in the 18th century, with grand expeditions and the opening of popular public displays in Europe and North America. By 1900 there were 150 natural history museums in Germanymarker, 250 in Great Britainmarker, 250 in the United Statesmarker, and 300 in Francemarker. Preservationist or conservationist sentiments are a development in the late 18th to early 20th century. The 19th century fascination with natural history engendered a fervor to be the first to collect rare specimens with the goal of doing so before they became extinct by other such collectors. Although his artistic works and romantic depiction of avian life inspired many bird enthusiasts and conservation organizations, the writings of John James Audubon, by modern standards, show insensitivity toward bird conservation as he shot and collected hundreds of specimens. Inspired by him, however, the first chapter of the Audubon Societymarker started in 1905[30965] for the purpose of protecting birds.

Coming of the Age of Conservation

The modern concept of ecosystem services can be found in the late 19th century. "The utility of Natural History or its applicability to promote the material wealth of the State cannot be doubted. It was a great mistake to suppose that the subjects of Zoology, Botany, and Geology did not involve much that affects our comfort, convenience, health and wealth." However, the article continues and discusses the dread of agricultural pests and the utility of understanding their natural history for the purpose of facilitating their destruction.

By the early 1800s biogeography was ignited through efforts of Von Humboldt, DeCandolle, Lyell and Darwin; their efforts, while important in relating species to their environments, were part of the naturalist tradition and fell short of conservation biology proper. Darwin, for example, hunted and shot birds and kept natural history cabinets in line with Victorian tradition.

Modern roots of conservation biology can be found in the late 19th century Enlightenment period particularly in Englandmarker and Scotlandmarker. A number of thinkers, among them notably Lord Monboddo, described the importance of "preserving nature"; much of this early emphasis had its origins in Christian theology.

20th century conservation

In the 20th century, actions in the United Kingdommarker, United Statesmarker, and Canadamarker emphasized the protection of habitat areas pursuant to visions of such people as John Muir, Theodore Roosevelt, and Aldo Leopold. While the Canadian nor the United Kingdom governments did not pioneer the creation of National Parks as the United States did in the late 19th century, there were many far-sighted civil servants who were dedicated to wildlife conservation and of notable mention. Some of these historical figures include Charles Gordon Hewitt [30966] and James Harkin.

The term conservation came into use in the late 19th century and referred to the management, mainly for economic reasons, of such natural resources as timber, fish, game, topsoil, pastureland, and minerals. In addition it referred to the preservation of forests (forestry), wildlife (wildlife refuge), parkland, wilderness, and watersheds. Western Europe was the source of much 19th century progress for conservation biology, particularly the British Empire with the Sea Birds Preservation Act 1869. However, the United States made contributions to this field starting with thinking of Thoreau and taking form with the Forest Act of 1891, John Muir's founding of the Sierra Club in 1892, the founding of the New York Zoological Society in 1895 and establishment of a series of national forests and preserves by Theodore Roosevelt from 1901 to 1909.

Not until the mid 20th century did efforts arise to target individual species for conservation, notably efforts in big cat conservation in South America led by the New York Zoological Society. In the early 20th century the New York Zoological Society was instrumental in developing concepts of establishing preserves for particular species and conducting the necessary conservation studies to determine the suitability of locations that are most appropriate as conservation priorities; the work of Henry Fairfield Osborn Jr., Archie Carr and Archie Carr III is notable in this era.

By the 1970s, led primarily by work in the United States under the Endangered Species Act along with the Species at Risk Act (SARA) of Canada, Biodiversity Action Plans developed in Australia, Swedenmarker, the United Kingdommarker, hundreds of species specific protection plans ensued. Notably the United Nations acted to conserve sites of outstanding cultural or natural importance to the common heritage of mankind. The programme was adopted by the General Conference of UNESCOmarker in 1972. As of 2006, a total of 830 sites are listed: 644 cultural, 162 natural. The first country to pursue aggressive biological conservation through national legislation was the United States, which passed back to back legislation in the Endangered Species Act (1966) and National Environmental Policy Act (1970), which together injected major funding and protection measures to large scale habitat protection and threatened species research. Other conservation developments, however, have taken hold throughout the world. India, for example, passed the Wildlife Protection Act of 1972 [30967].

In 1980 a significant development was the emergence of the urban conservation movement. A local organization was established in Birminghammarker, UKmarker, a development followed in rapid succession in cities across the UK, then overseas. Although perceived as a grassroots movement, its early development was driven by academic research into urban wildlife. Initially perceived as radical, the movement's view of conservation being inextricably linked with other human activity has now become mainstream in conservation thought. Considerable research effort is now directed at urban conservation biology. The Society for Conservation Biology originated in 1985.

By 1992 most of the countries of the world had become committed to the principles of conservation of biological diversity with the Convention on Biological Diversity; subsequently many countries began programmes of Biodiversity Action Plans to identify and conserve threatened species within their borders, as well as protect associated habitats. The late 1990s saw increasing professionalism in the sector, with the maturing of organisations such as the Institute of Ecology and Environmental Management and the Society for the Environment.

Since 2000 the concept of landscape scale conservation has risen to prominence, with less emphasis being given to single-species or even single-habitat focused actions. Instead an ecosystem approach is advocated by most mainstream conservationist, although concerns have been expressed by those working to protect some high-profile species.

Ecology has clarified the workings of the biosphere; i.e., the complex interrelationships among humans, other species, and the physical environment. The burgeoning human population and associated agriculture, industry, and the ensuing pollution, have demonstrated how easily ecological relationships can be disrupted.

See also


  1. Coral reefs to be destroyed in 20-40 years
  2. J. Douglas. 1978. Biologists urge US endowment for conservation. Nature Vol. 275, 14 September, 1978. J. Douglas. 1978. Natural Sciences. Science News. September 30, 1978.
  3. Organization of the meeting itself also entailed bridging a gap between genetics and ecology. Soulé, was an evolutionary geneticist working with wheat geneticist Sir Otto Frankel to advance conservation genetics as a new field at the time. Jared Diamond, who originally suggested the idea for a conference to Wilcox was concerned with the application of community ecology and island biogeography theory to conservation. Wilcox and Thomas Lovejoy, who together initiated planning for the conference in June 1977 when Lovejoy secured a commitment of seed funding at World Wildlife Fund, felt both genetics and ecology should be represented. Wilcox suggested use of a new term conservation biology to encompass the application of biological sciences in general to conservation. Subsequently, Soulé and Wilcox wrote in the program for the meeting they jointly convened on September 6-9, 1978, titled First International Conference on Resesarch in Conservation Biology, "The purpose of this conference is to accelerate and facilitate the development of a rigorous new discipline called conservation biology -- a multidisciplinary field drawing its insights and methodology mostly from population ecology, community ecology, sociobiology, population genetics, and reproductive biology." This inclusion of topics at the meeting related to animal breeding reflected participation and support of the zoo and captive breeding communities.
  4. Millennium Ecosystem Assessment (2005). Ecosystems and Human Well-being: Biodiversity Synthesis. World Resources Institute, Washington, DC.[1]
  5. [2]
  6. Although controversial, small bands of hunters with primitive hunting technologies had the capability of driving Quaternary megafaunal extinctions: Turvey and Risley (2006) Modeling the extinction of Steller’s sea cow. Biol. Lett. 2, 94–97. [3]
  7. [4]
  8. M. L. McCallum. (2007). Amphibian Decline or Extinction? Current Declines Dwarf Background Extinction Rate. Journal of Herpetology, 41(3): 483–491.
  9. The Royal Society. 2005. Ocean acidification due to increasing atmospheric carbon dioxide. Policy document 12/05. ISBN 0 85403 617 2 Download
  10. Edward O. Wilson. 1987. The Little Things That Run the World (The Importance and Conservation of Invertebrates). Conservation Biology, 1(4):pp. 344-346 [5]
  11. M. J. Samways. (1993). Insects in biodiversity conservation: some perspectives and directives. Biodiversity and Conservation, 2:258-282
  12. [6]
  13. By 2050 Warming to Doom Million Species, Study Says
  14. T. Longcore and C. Rich. (2004). Ecological light pollution. Front Ecol Environ 2004; 2(4): 191–198.[7]
  15. Delaney, Gumal, Bennett: Asia’s biodiversity vanishing into the marketplace. Bio-Medicine, 2004 [8]
  16. Sautner, Bennett: Greatest threat to Asia’s wildlife is hunting, scientists say. Bio-Medicine, 2002 [9]
  17. Hance, J: Wildlife trade creating “empty forest syndrome” across the globe., January 19, 2009[10]
  18. G. Schmidt. 2005. Ecology & Anthropology: A Field Without Future? Ecological and Environmental Anthropology. 1(1): 13-15. [11] [12]
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  20. D. I. MacKenzie, J. D. Nichols, J. E. Hines, M. G. Knutson, and A. B. Franklin. (2003) Estimating site occupancy, colonization, and local extinction when a species is detected imperfectly. Ecology, 84(8): 2200–2207[14]
  21. [15]
  22. Edward O. Wilson. 2000. On the Future of Conservation Biology. Conservation Biology, 14(1): 1-3
  23. IUCN Red-list statistics (2006)
  24. The IUCN does not disaggregate endangered from critically endangered or threatened for the purpose of these statistics.
  26. Committee on Recently Extinct Organisms. " Why Care About Species That Have Gone Extinct?". URL accessed July 30 2006.
  27. G. W. Luck, G. C. Daily and P. R. Ehrlich. (2003). Population diversity and ecosystem services. 18, (7): 331-336[16]
  28. In the paper referenced herein, the authors map biodiversity hotspots against ecosystem service values and show that published maps on biodiversity priority have a disproportionate share of ecosystem service value. W. R. Turner, K. Brandon, T. M. Brooks, R. Costanza, G. A. B. Da Fonseca, and R. Portela. 2007. Global Conservation of Biodiversity and Ecosystem Services. BioScience, 57(10): 868-873. [17]
  29. The Global Conservation Fund is an example of funding organization that excludes biodiversity coldspots in its strategic campaign. [18]
  30. [19]
  31. R. Costanza, R. d’Arge, R. de Groot, S. Farberk, M. Grasso, B. Hannon, K. Limburg, S. Naeem, R. V. O’Neill, J. Paruelo, R. G. Raskin, P. Suttonkk and M. van den Belt. The value of the world’s ecosystem services and natural capital. Nature, 387: 253-260[20]
  32. [21]
  33. Millennium Ecosystem Assessment. (2005). Ecosystems and Human Well-being: Biodiversity Synthesis. World Resources Institute, Washington, DC. [22]
  34. [23]
  35. [24]
  36. Staff of World Resources Program. (1998). Valuing Ecosystem Services. World Resources 1998-99. [25]
  37. Valuation of Ecosystem services : A Backgrounder
  38. Ecosystem Services: Estimated value in trillions
  39. Canadian Forest Congress: Carbon capture, water filtration, other boreal forest ecoservices worth estimated $250 billion/year
  40. APIS, Volume 10, Number 11, November 1992, M.T. Sanford: Estimated value of honey bee pollination
  41. Regional council, Waikato: The hidden economy
  42. P. K. Anderson. (1996). Competition, predation, and the evolution and extinction of Steller’s Sea Cow, Hydrodamalis gigas. Marine Mammal Science, 11(3):391-394
  43. Mason, Rachel and Judith Ramos. (2004). Traditional Ecological Knowledge of Tlingit People concerning the Sockeye Salmon Fishery of the Dry Bay Area, A Cooperative Agreement Between Department of the Interior National Park Service and the Yakutat Tlingit Tribe, Final Report (FIS) Project 01-091, Yakutat, Alaska.[26]
  44. Hamilton, E., and H. Cairns (eds). 1961. Plato: the collected dialogues. Princeton University Press, Princeton, NJ
  45. The Bible, Leviticus, 25:4-5
  46. Page 91, in C. D. Wilber. (1861). Transactions of the Illinois Natural History Society. Illinois Natural History Society. [27]
  47. Short history of biogeography and conservation biology
  48. For an review and introduction to the history of wildlife conservation and preservation in Canada, see
  49. [28] Environmental timeline 1890-1920
  50. A.R. Rabinowitz, Jaguar: One Man's Battle to Establish the World's First Jaguar Preserve, Arbor House, New York, N.Y. (1986)
  51. Henry Fairfield Osborn Jr. Biographical summary
  52. U.S. Endangered Species Act (7 U.S.C. § 136, 16 U.S.C. § 1531 et seq.) of 1973, Washington DC, U.S. Government Printing Office
  53. U.S. Endangered Species Act of 1966 with subsequent amendments
  54. 42 USC 4321 National Environmental Policy Act (2000): full text of the law
  55. [29]
  56. Convention on Biological Diversity Official Page

Further reading

Scientific literature
  • B. W. Bowen, (1999). Preserving genes, species, or ecosystems? Healing the fractured foundations of conservation policy. Molecular Ecology, 8:S5-S10.[30968]
  • T. M. Brooks, R. A. Mittermeier, G. A. B. da Fonseca, J. Gerlach, M. Hoffmann, J. F. Lamoreux, C. G. Mittermeier, J. D. Pilgrim, and A. S. L. Rodrigues. (2006). Global Biodiversity Conservation Priorities. Science 313 (5783), 58.
  • P. Kareiva, M. Marvier. (2003) Conserving Biodiversity Coldspots. American Scientist 91(4):344-351.[30969]
  • M. L. McCallum. (2008) Amphibian Decline or Extinction? Current Declines Dwarf Background Extinction Rate. Journal of Herpetology, 41(3): 483–491. [30970]
  • N. Myers, R. A. Mittermeier, C. G. Mittermeier, G. A. B. da Fonseca and J. Kent. (2000). Biodiversity hotspots for conservation priorities. Nature 403, 853-858. B. W. Bowen, (1999). Preserving genes, species, or ecosystems? Healing the fractured foundations of conservation policy. Molecular Ecology, 8:S5-S10.[
  • T. M. Brooks, R. A. Mittermeier, G. A. B. da Fonseca, J. Gerlach, M. Hoffmann, J. F. Lamoreux, C. G. Mittermeier, J. D. Pilgrim, and A. S. L. Rodrigues. (2006). Global Biodiversity Conservation Priorities. Science 313 (5783), 58.
  • P. Kareiva, M. Marvier. (2003) Conserving Biodiversity Coldspots. American Scientist 91(4):344-351.[30971]
  • M. L. McCallum. (2008) Amphibian Decline or Extinction? Current Declines Dwarf Background Extinction Rate. Journal of Herpetology, 41(3): 483–491. [30972]
  • N. Myers, R. A. Mittermeier, C. G. Mittermeier, G. A. B. da Fonseca and J. Kent. (2000). Biodiversity hotspots for conservation priorities. Nature 403, 853-858.[30973]
  • D. B. Wake and V. T. Vredenburg. (2008). Are we in the midst of the sixth mass extinction? A view from the world of amphibians. PNAS, 105(1): 11466-11473. [30974]



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