When wild populations reach extremely low levels and are in imminent danger of extinction, the only way to save them is to bring them into captivity, build up their numbers, and try to re-establish the wild population.  This is being tried with many endangered species, but it involves many challenges, both biological and political. 

GENETIC PROBLEMS WITH SMALL POPULATIONS

Several problems arise when a species reaches a very small population size:

Loss of Genetic Variability.  When a population gets below about 500 breeding individuals, the amount of genetic variation is reduced, and this can eventually diminish the species' capacity to adapt to environmental changes. An example is the cheetah, a member of the cat family. There are 37 species in the cat family, and all except the domestic cat are considered threatened or endangered.

Cheetahs are genetically extremely uniform. This has been shown in two ways: first, protein patterns as seen by gel electrophoresis (slide). None of 52 genes tested showed variation in the cheetah whereas between 8% and 31% of the same group of genes showed variation in other mammals including other cats. Second, skin grafts between cheetahs are not rejected, indicating that they are genetically identical as far as histocompatibility genes are concerned; these are the most variable genes in other mammals. Cat House

Inbreeding.  Populations that fall below about 50 breeding individuals are forced to breed with close relatives - a pattern of breeding called inbreeding which can lead to depression of fitness called inbreeding depression - this includes problems such as decreased fertility, high juvenile mortality and birth defects, already well known from human populations. Captive populations of endangered species such as the California condor, which was down to less than 30 individuals, have to be managed very carefully in order to minimize inbreeding effects. The chart shows how, with most species, the offspring of related parents ("inbred") show higher juvenile mortality than offspring of unrelated parents ("noninbred").

In the cheetah, there is high juvenile mortality in both sets of offspring; this is presumably because even unrelated parents are genetically very similar, just like related parents. Cheetahs show other reproductive problems including very low sperm counts and high incidence of abnormal sperm; these are also thought to be due to genetic uniformity.

The number of cheetahs in the wild is not known precisely; it is estimated at between 1,500 and 25,000. This is not a small enough population in itself to show loss of variability and inbreeding effects. Rather, it is thought that the cheetah population went through a very small bottleneck in the recent past, leaving the present population exceptionally uniform.

Inbreeding also leads to the expression of specific genetic defects, that are masked by dominant normal alleles in outbred populations. For example, inbreeding has apparently caused a high incidence of a genetic defect of the diaphragm in the endangered Golden lion tamarin, and kinky tail in the Florida panther.

Inbreeding was probably one of the factors responsible for the extinction of the heath hen. This bird was once widespread in the eastern United States, but it was reduced by overhunting, disease, and bad weather to a population of less than 100 birds on Martha's Vineyard. By 1920, the population had become so small that genetic deterioration resulting from inbreeding caused the population to die out in 1932.

There are some examples of populations that have been reduced to very low levels and appear to have recovered quite well. The Northern elephant seal was reduced to a population of less than 100 but is now thriving with over 30,000 individuals. 

 All of the pet golden hamstersin the world are descended from one female caught in Syria in the 1930s, and the species has not been found in the wild since. It is not known why some species are more sensitive to inbreeding than others.

Hybridization seems to occur more often when species are reduced to very small numbers. This can be a significant problem because species hybrids cannot be protected under the Endangered Species Act. For example, a large fraction of both red wolves and gray wolves have turned out to be wolf/coyote hybrids.

The 50 or so Florida panthers include some that are the products of hybridization with a South American subspecies (because some hybrid panthers were released into the Everglades between 1957 and 1967). This may be beneficial to the Florida panther, which shows significant reproductive problems, probably due to inbreeding. But the current status of the Florida panther as endangered could be revoked under a strict interpretation of the Endangered Species Act.  What You Can Do to Save the Florida Panther.

The present-day population of Przewalski's horse occasionally produces an individual with an unusual coat color, probably because the species has hybridized with the domestic horse at least once in its history.

Hybridization between subspecies has led to a major problem in buffalo conservation in Canada. Most of the wood buffalo in Wood Buffalo National Park in Alberta are hybrids resulting from interbreeding with plains buffalo (a different subspecies) that were removed from cattle country in southern Alberta. But there is still a small herd of pure wood buffalo. The biologists are considering killing or at least removing all the hybrids and allowing the park to be taken over by the pure wood buffalo.

The "hybrid policy" of the Endangered Species Act has often been questioned. It has been argued that hybrids between species should not be given protection because this destroys the integrity of the species, but that hybridization between subspecies is a natural process that helps prevent loss of genetic diversity and inbreeding depression. Therefore, hybrids between subspecies should be given protection under the Act.

Selective breeding.  With long periods in captivity there is a danger that unintentional selective breeding will result in the establishment of traits that are desirable in captivity but not in the wild. There is a danger that animals may gradually become domesticated because of their dependence on human caretakers. A possible example is the golden lion tamarin, where the first animals released in Brazil failed to respond to danger or a predator.  More releases are being tried.

CAPTIVE BREEDING

The maintenance of species in captivity in zoos, aquaria, and botanic gardens is sometimes called ex situ conservation. It is the only hope for the survival of some species where the threat to their existence in the wild is now extreme. This conservation method, however, serves many other purposes such as allowing more control over breeding in order to avoid inbreeding, increased reproductive rate, providing educational and public awareness programs and providing materials for basic and applied research.

Zoos

The technology for management of captive populations of endangered species in zoos is primitive but rapidly improving. There are roughly 500,000 mammals, birds, reptiles and amphibians in captivity in zoos throughout the world. 500,000 is equal to about 1% of the number of cats in American households. 

Not all attempts at captive propagation have been successful. Only 26 of 274 species of rare mammals in captivity are self-sustaining. Giant pandas, cheetahs, elephants, penguins, humming birds, killer whales, and vicunas have been very difficult to breed. Only one species of bats (gray headed flying fox) has ever been bred in captivity. Only about 10% of reptile species in zoos have reproduced.

Improved management of the genetics of small captive populations is beginning to make propagation more successful by eliminating some of the problems associated with inbreeding. The International Species Inventory System now keeps genealogical information on individual animals of 2,500 species of mammals and birds kept in 326 zoos in Europe and North America. This makes it possible to arrange matings by computer in order to minimize problems caused by inbreeding.

Molecular methods are also being used to obtain more definitive information on the relationships between endangered species and their close relatives. Lack of this type of information has already caused problems in endangered species conservation. For example, in the early 1980's the five remaining male individuals of the dusky seaside sparrow were crossed with what was thought to be their closest relative, the subspecies Scott's seaside sparrow, to produce hybrids that, theoretically, could be interbred to give back a strain that was close to 100% dusky. But subsequent mitochondrial DNA analysis show that Scott's seaside sparrow was actually a distant relative while there were four other subspecies that were much closer to the dusky. Thus DNA analysis can be a useful source of information in desperate situations such as this.

The potential role of zoos for species conservation is limited by space and expense. In the U.S., zoos contain self-sustaining populations of a total of only 96 species. The cost of maintaining a herd of about 100 herbivores is up to $250,000 a year, much more than the cost of maintaining the same number in the wild.

It is estimated that if existing zoos were used exclusively for captive propagation of threatened species, a maximum of about 900 species of vertebrates could be kept alive in captivity. But at least 2000 mammals, reptiles and birds would have to be bred in captivity in the near future in order to escape extinction. Of course, the ultimate hope is that zoos will serve as facilities for the temporary recovery of species prior to their return to the wild within a few generations.

Most captive propagation programs in zoos focus on large birds and mammals, partly because they face greater extinction threats than do most small animals, but also because these are more successful in attracting customers. This has also led to some problems. The World Wildlife Fund recently sued the Fish and Wildlife Service for providing the Toledo Zoo with a permit to import two Giant pandas, a species close to extinction (fewer than 1000 animals) in the wild in China. Pandas are listed as endangered under the U.S. Endangered Species Act and are on CITES Appendix I. The zoo was planning to set up a special exhibit of the pandas, charge a special fee, make about $3 million for a three-month exhibit, and pay about $300,000 to China for the loan. The WWF argued that the exhibit was primarily for commercial gain and that issuing the permit would therefore violate the ESA and CITES, both of which prohibit commercial trafficking in endangered species. This case was especially troublesome because the two animals were of breeding age and were taken from a captive breeding facility in China, in violation of China's policy to loan only non-breeding animals. Thirty other zoos were negotiating with the Chinese to borrow pandas when this case went to court.

Because of concerns about short-term exhibition loans and how the demand for such loans might impact pandas in the wild, the U.S. Fish and Wildlife Service imposed a moratorium on live panda import permit applications from 1993 to 1998. In 1998 they announced a new policy under which the service has to make the following determinations before it can issue a permit:

the import cannot be for primarily commercial purposes;

the purpose for the import must not be detrimental to the survival of the species in the wild;

the importer must have facilities and the expertise to care for the panda;

the import must enhance the survival or propagation of the species as outlined under the ESA, meaning that scientific research or the propagation of the species must benefit wild pandas; and

the import must not jeopardize the continued existence of giant panda populations in the wild.

Aquaria

Aquaria have been much less successful than zoos in propagating threatened species, in spite of the fact that there are threats to large numbers of freshwater species and that many of these fish take up very little space. The captive breeding specialist group of IUCN is mounting a major effort to develop captive breeding programs for endangered fish species, such as the cichlids of Lake Victoria, the desert fishes of North America and Appalachian stream fishes. Some of these will need to be propagated in aquaria for many generations in view of the difficulty in solving the exotic predators and/or acid rain problems.

Marine Mammal Parks

River dolphin. The Dallas World Aquarium has filed for a permit with National Marine Fisheries Service (NMFS) to capture and import four Amazon River dolphins from South America to Dallas. These animals do not do well in captivity, the Aquarium has no plans to breed or reintroduce them, and the species in the wild is likely to be listed as endangered in the near future.

Butterfly Houses

At present, zoos are not able to deal with the hundreds of thousands of insects and other invertebrates threatened with extinction by habitat loss. However, some zoos and independent operations are developing the technology for captive propagation of these other kinds of organisms. For example, there are now 47 butterfly houses in England, three in the U.S., and two in Australia. These operations could attempt captive propagation of endangered species of insects (but they have not done so yet).

Botanic Gardens

It is much easier and cheaper to maintain captive populations of plants than of animals. Hundreds of species of plants can be kept in a small botanic garden. They require less care, they do not require cages, mating can be arranged more easily, they can be vegetatively propagated and they can easily be stored during their dormant seed stage. The world's roughly 1500 botanic gardens together contain at least 35,000 plant species or more than 15% of the world's flora. Seeds of many plant species, especially those with dry, small seeds, can be stored at low temperatures for long periods with little loss of viability. They are usually maintained at 5% humidity and -20oC. A small seed storage facility can easily store thousands of species. Unfortunately, there are some plant species that do not survive well in storage, and there are some plants that can only be propagated vegetatively (not via seeds). The role of botanic gardens in conservation is growing very rapidly with research into storage techniques, better data collection and better coordination.

The UCI Arboretum, directed by Dr. Peter Bowler, has a collection of 4,000 species, mostly from Africa, of which more than 200 are endangered and 76 are grown nowhere else.

EMBRYO STORAGE AND TRANSFER TECHNOLOGY

Techniques for embryo transfer and artificial insemination, which have been developed for laboratory animals and farm animals, are potentially very useful for improving the reproductive potential of captive populations of endangered species.  These kinds of techniques have been worked out mainly for mammals.

Embryo Transfer

In this technique, fertilized eggs or early embryos (usually about the 8- cell stage) are removed from the reproductive tract of a donor female and transferred into the tract of a surrogate mother, who carries the embryos to term and produces live young. This can all be done non-surgically, at least with cattle. What makes it useful is that the donor and recipient can be of two different species (although they must be of the same genus); successful transfers have been carried out from guar (endangered species) into domestic cow, Grant's zebra into horse, Przewalski's horse into domestic horse, macaque into rhesus monkey, and several others.

One technique for enhancing reproduction is superovulation; treatment of the donor with fertility hormones such as follicle-stimulating hormone causes the release of large numbers of eggs (up to 31 in eland), all of which can potentially be fertilized, transferred and carried to term in surrogate mothers. This method works well in cattle (and humans!), but not so well in other mammals so far. Another method of increasing the reproductive rate is embryo bisection to give identical twins or triplets; this has so far been demonstrated only with laboratory and domestic animals (slide: sheep twins).

Embryo transfer is useful in several ways, not all obvious: 

It increases the number of progeny per female (potentially increases the yield per ovulation and increases the number of ovulations that are productive).

It prevents disease transmission between populations (embryos are almost always free of disease agents that may have been present in the donor).

The offspring acquire passive immunity from the surrogate mother via placental blood supply or milk, and this makes them as resistant to local diseases as the surrogate mother. This method therefore potentially gives better survival than transporting the animals themselves to a new location.

Animals can be transferred from one place to another as embryos in test tubes, implanted into foster mothers and then, when they have grown, they can be used in breeding programs. This is much cheaper and safer than transferring full-grown animals. This technique is being considered for the tiger, which lives on 18 tiger reserves in India with no wildlife corridors connecting them. Moving embryos from one site to another will allow the transfer of genes that is important for maintaining fitness and adaptability of populations.

The embryos can be frozen before transfer into the recipient female. Embryos of the eland have been frozen for 1.5 years then successfully transferred and carried to term. Thousands of mouse embryos are kept frozen as a method of preserving genetic stocks. For mice, rabbits and cows, 80-90% of the embryos develop after freezing and thawing. This raises the possibility of long-term cryopreservation of embryos of many different species in a "frozen zoo", and of large numbers from individual species so that genetic variability can be maintained at fairly low cost. Cryopreservation may also be important when insufficient surrogate mothers are available or are not yet synchronized.

Artificial insemination is another technology that may be useful.  Sperm can be frozen and used later, or transferred to another breeding facility to increase genetic diversity.  Sometimes, the sperm can be added to the eggs in a dish and fertilization will occur.  In other cases (for example, horses) the sperm has to be injected into the egg.  A few years ago, the black-footed ferret was down to six individuals, but artificial insemination has now been used to produce 16 kittens.  Elephants and cheetahs have conceived, and a live cheetah cub has been born following artificial insemination.  Elephants have not bred naturally in captivity, so this method may be useful simply to make captive breeding possible.

Somatic Cell Cloning holds some promise for propagating from one or a few survivors of an almost-extinct species.  This was first done with domestic sheep at the Roslin Institute in Edinburgh (see panel, from University of Virginia) but has since been done with other mammals.  It has already been used to rescue a rare breed of cattle that had been reduced to a single old female ("Lady") and some frozen sperm.  Granulosa cells (somatic cells in the ovary) from Lady were fused with enucleated eggs (lacking DNA) from a different breed, and the resulting eggs were implanted into an Angus cow (a common breed).  The first calf born from these cells ("Elsie", =LC, =Lady's Clone) is genetically identical to Lady, as expected, although her markings are slightly different.