Biology:Population bottleneck

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Short description: Effects of a sharp reduction in numbers on the diversity and robustness of a population
Population bottleneck followed by recovery or extinction

A population bottleneck or genetic bottleneck is a sharp reduction in the size of a population due to environmental events such as famines, earthquakes, floods, fires, disease, and droughts; or human activities such as genocide, specicide, widespread violence or intentional culling. Such events can reduce the variation in the gene pool of a population; thereafter, a smaller population, with a smaller genetic diversity, remains to pass on genes to future generations of offspring. Genetic diversity remains lower, increasing only when gene flow from another population occurs or very slowly increasing with time as random mutations occur.[1][self-published source] This results in a reduction in the robustness of the population and in its ability to adapt to and survive selecting environmental changes, such as climate change or a shift in available resources.[2] Alternatively, if survivors of the bottleneck are the individuals with the greatest genetic fitness, the frequency of the fitter genes within the gene pool is increased, while the pool itself is reduced.

The genetic drift caused by a population bottleneck can change the proportional random distribution of alleles and even lead to loss of alleles. The chances of inbreeding and genetic homogeneity can increase, possibly leading to inbreeding depression. Smaller population size can also cause deleterious mutations to accumulate.[3]

Population bottlenecks play an important role in conservation biology (see minimum viable population size) and in the context of agriculture (biological and pest control).[4]

Minimum viable population size

Main page: Earth:Minimum viable population

In conservation biology, minimum viable population (MVP) size helps to determine the effective population size when a population is at risk for extinction.[5][6] The effects of a population bottleneck often depend on the number of individuals remaining after the bottleneck and how that compares to the minimum viable population size.

Founder effects

Main page: Biology:Founder effect

A slightly different form of bottleneck can occur if a small group becomes reproductively (e.g., geographically) separated from the main population, such as through a founder event, e.g., if a few members of a species successfully colonize a new isolated island, or from small captive breeding programs such as animals at a zoo. Alternatively, invasive species can undergo population bottlenecks through founder events when introduced into their invaded range.[7]

Examples

Humans

According to a 1999 model, a severe population bottleneck, or more specifically a full-fledged speciation, occurred among a group of Australopithecina as they transitioned into the species known as Homo erectus two million years ago. It is believed that additional bottlenecks must have occurred since Homo erectus started walking the Earth, but current archaeological, paleontological, and genetic data are inadequate to give much reliable information about such conjectured bottlenecks.[8] Nonetheless, a 2023 genetic analysis discerned such a human ancestor population bottleneck of a possible 100,000 to 1000 individuals "around 930,000 and 813,000 years ago [which] lasted for about 117,000 years and brought human ancestors close to extinction."[9][10]

A 2005 study from Rutgers University theorized that the pre-1492 native populations of the Americas are the descendants of only 70 individuals who crossed the land bridge between Asia and North America.[11]

The Neolithic Y-chromosome bottleneck refers to a period around 5000 BC where the diversity in the male y-chromosome dropped precipitously, to a level equivalent to reproduction occurring with a ratio between men and women of 1:17.[12] Discovered in 2015[13] the research suggests that the reason for the bottleneck was not a reduction in the number of males, but a drastic decrease in the percentage of males with reproductive success.

Toba catastrophe theory

Main page: Earth:Toba catastrophe theory

The controversial Toba catastrophe theory, presented in the late 1990s to early 2000s, suggested that a bottleneck of the human population occurred approximately 75,000 years ago, proposing that the human population was reduced to perhaps 10,000–30,000 individualsCite error: Closing </ref> missing for <ref> tag

In 2000, a Molecular Biology and Evolution paper suggested a transplanting model or a 'long bottleneck' to account for the limited genetic variation, rather than a catastrophic environmental change.[8] This would be consistent with suggestions that in sub-Saharan Africa numbers could have dropped at times as low as 2,000, for perhaps as long as 100,000 years, before numbers began to expand again in the Late Stone Age.[14]

Other animals

Year American
bison (est)
Before 1492 60,000,000
1890 750
2000 360,000

European bison, also called wisent (Bison bonasus), faced extinction in the early 20th century. The animals living today are all descended from 12 individuals and they have extremely low genetic variation, which may be beginning to affect the reproductive ability of bulls.[15]

The population of American bison (Bison bison) fell due to overhunting, nearly leading to extinction around the year 1890, though it has since begun to recover (see table).

Overhunting pushed the northern elephant seal to the brink of extinction by the late 19th century. Although they have made a comeback, the genetic variation within the population remains very low.

A classic example of a population bottleneck is that of the northern elephant seal, whose population fell to about 30 in the 1890s. Although it now numbers in the hundreds of thousands, the potential for bottlenecks within colonies remains. Dominant bulls are able to mate with the largest number of females—sometimes as many as 100. With so much of a colony's offspring descended from just one dominant male, genetic diversity is limited, making the species more vulnerable to diseases and genetic mutations.

The golden hamster is a similarly bottlenecked species, with the vast majority of domesticated hamsters descended from a single litter found in the Syrian desert around 1930, and very few wild golden hamsters remaining.

An extreme example of a population bottleneck is the New Zealand black robin, of which every specimen today is a descendant of a single female, called Old Blue. The Black Robin population is still recovering from its low point of only five individuals in 1980.

The genome of the giant panda shows evidence of a severe bottleneck about 43,000 years ago.[16] There is also evidence of at least one primate species, the golden snub-nosed monkey, that also suffered from a bottleneck around this time. An unknown environmental event is suspected to have caused the bottlenecks observed in both of these species. The bottlenecks likely caused the low genetic diversity observed in both species.

Other facts can sometimes be inferred from an observed population bottleneck. Among the Galápagos Islands giant tortoises—themselves a prime example of a bottleneck—the comparatively large population on the slopes of the Alcedo volcano is significantly less diverse than four other tortoise populations on the same island. DNA analyses date the bottleneck to around 88,000 years before present (YBP).[17] About 100,000 YBP the volcano erupted violently, deeply burying much of the tortoise habitat in pumice and ash.

Another example can be seen in the greater prairie chickens, which were prevalent in North America until the 20th century. In Illinois alone, the number of greater prairie chickens plummeted from over 100 million in 1900 to about 46 in 1998.[18] These declines in population were the result of hunting and habitat destruction, but the random consequences have also caused a great loss in species diversity. DNA analysis comparing the birds from 1990 and mid-century shows a steep genetic decline in recent decades. Management of the greater prairie chickens now includes genetic rescue efforts including the translocation prairie chickens between leks to increase each populations genetic diversity.[18]

Population bottlenecking poses a major threat to the stability of species populations as well. Papilio homerus is the largest butterfly in the Americas and is endangered according to the IUCN. The disappearance of a central population poses a major threat of population bottleneck. The remaining two populations are now geographically isolated and the populations face an unstable future with limited remaining opportunity for gene flow.[19]

Genetic bottlenecks exist in cheetahs.[20][21]

Selective breeding

Bottlenecks also exist among pure-bred animals (e.g., dogs and cats: pugs, Persian) because breeders limit their gene pools by a few (show-winning) individuals for their looks and behaviors. The extensive use of desirable individual animals at the exclusion of others can result in a popular sire effect.

Selective breeding for dog breeds caused constricting breed-specific bottlenecks.[22] These bottlenecks have led to dogs having an average of 2–3% more genetic loading than gray wolves.[23] The strict breeding programs and population bottlenecks have led to the prevalence of diseases such as heart disease, blindness, cancers, hip dysplasia, and cataracts.[22]

Selective breeding to produce high-yielding crops has caused genetic bottlenecks in these crops and has led to genetic homogeneity.[24] This reduced genetic diversity in many crops could lead to broader susceptibility to new diseases or pests, which threatens global food security.[25]

Plants

Research showed that there is incredibly low, nearly undetectable amounts of genetic diversity in the genome of the Wollemi pine (Wollemia nobilis).[26] The IUCN found a population count of 80 mature individuals and about 300 seedlings and juveniles in 2011, and previously, the Wollemi pine had fewer than 50 individuals in the wild.[27] The low population size and low genetic diversity indicates that the Wollemi pine went through a severe population bottleneck.

A population bottleneck was created in the 1970s through the conservation efforts of the endangered Mauna Kea silversword (Argyroxiphium sandwicense ssp. sandwicense).[28] The small natural population of silversword was augmented through the 1970s with outplanted individuals. All of the outplanted silversword plants were found to be first or subsequent generation offspring of just two maternal founders. The low amount of polymorphic loci in the outplanted individuals led to the population bottleneck, causing the loss of the marker allele at eight of the loci.

See also

  • Baby boom
  • Population boom

References

  1. William R. Catton, Jr. "Bottleneck: Humanity's Impending Impasse" Xlibris Corporation, 2009. 290 pp. ISBN:978-1-4415-2241-2[page needed][self-published source]
  2. Lande, R. (1988). "Genetics and demography in biological conservation". Science 241 (4872): 1455–1460. doi:10.1126/science.3420403. PMID 3420403. Bibcode1988Sci...241.1455L. 
  3. Lynch, M.; Conery, J.; Burger, R. (1995). "Mutation accumulation and the extinction of small populations". The American Naturalist 146 (4): 489–518. doi:10.1086/285812. 
  4. "The population genetics of a biological control introduction: mitochondrial DNA and microsatellie variation in native and introduced populations of Aphidus ervi, a parasitoid wasp". Molecular Ecology 13 (2): 337–48. February 2004. doi:10.1046/j.1365-294X.2003.02084.x. PMID 14717891. 
  5. Gilpin, M.E.; Soulé, M.E. (1986). "Minimum viable populations: The processes of species extinctions". in Soulé, Michael E.. Conservation biology: The science of scarcity and diversity. Sunderland Mass: Sinauer Associates. pp. 13–34. ISBN 978-0-87893-794-3. 
  6. Soulé, Michael E., ed (1987). Viable populations for conservation. Cambridge: Cambridge Univ. Press. ISBN 978-0-521-33657-4. https://archive.org/details/isbn_9780521336574. [page needed]
  7. Lee, C. E. (2002). Evolutionary genetics of invasive species. Trends in ecology & evolution, 17(8), 386-391.
  8. 8.0 8.1 "Population bottlenecks and Pleistocene human evolution". Molecular Biology and Evolution 17 (1): 2–22. January 2000. doi:10.1093/oxfordjournals.molbev.a026233. PMID 10666702. 
  9. Zimmer, Carl (31 August 2023). "Humanity's Ancestors Nearly Died Out, Genetic Study Suggests - The population crashed following climate change about 930,000 years ago, scientists concluded. Other experts aren't convinced by the analysis.". The New York Times. Archived from the original on 31 August 2023. https://archive.today/20230831182259/https://www.nytimes.com/2023/08/31/science/human-survival-bottleneck.html. Retrieved 2 September 2023. 
  10. Hu, Wangjie (31 August 2023). "Genomic inference of a severe human bottleneck during the Early to Middle Pleistocene transition". Science 381 (6661): 979–984. doi:10.1126/science.abq7487. Archived from the original on 1 September 2023. https://archive.today/20230901024052/https://www.science.org/doi/10.1126/science.abq7487. Retrieved 2 September 2023. 
  11. "North America Settled by Just 70 People, Study Concludes". LiveScience. 2005-05-25. http://www.livescience.com/history/050525_america_settlers.html. 
  12. Starr, Michelle (31 May 2018). "Something Weird Happened to Men 7,000 Years Ago, And We Finally Know Why". sciencealert.com. https://www.sciencealert.com/neolithic-y-chromosome-bottleneck-warring-patrilineal-clans. 
  13. Karmin (2015). "A recent bottleneck of Y chromosome diversity coincides with a global change in culture". Genome Research 25 (4): 459–466. doi:10.1101/gr.186684.114. 
  14. "The dawn of human matrilineal diversity". American Journal of Human Genetics 82 (5): 1130–40. May 2008. doi:10.1016/j.ajhg.2008.04.002. PMID 18439549. 
  15. Luenser, K.; Fickel, J.; Lehnen, A.; Speck, S.; Ludwig, A. (2005). "Low level of genetic variability in European bisons (Bison bonasus) from the Bialowieza National Park in Poland". European Journal of Wildlife Research 51 (2): 84–7. doi:10.1007/s10344-005-0081-4. 
  16. Zhang, Ya-Ping; Wang, Xiao-xia; Ryder, Oliver A.; Li, Hai-Peng; Zhang, He-Ming; Yong, Yange; Wang, Peng-yan (2002). "Genetic diversity and conservation of endangered animal species". Pure and Applied Chemistry 74 (4): 575–84. doi:10.1351/pac200274040575. http://www.degruyter.com/downloadpdf/j/pac.2002.74.issue-4/pac200274040575/pac200274040575.xml. 
  17. "Genes record a prehistoric volcano eruption in the Galápagos". Science 302 (5642): 75. October 2003. doi:10.1126/science.1087486. PMID 14526072. 
  18. 18.0 18.1 Mussmann, S. M.; Douglas, M. R.; Anthonysamy, W. J. B.; Davis, M. A.; Simpson, S. A.; Louis, W.; Douglas, M. E. (February 2017). "Genetic rescue, the greater prairie chicken and the problem of conservation reliance in the Anthropocene" (in en). Royal Society Open Science 4 (2): 160736. doi:10.1098/rsos.160736. ISSN 2054-5703. PMID 28386428. PMC 5367285. https://royalsocietypublishing.org/doi/10.1098/rsos.160736. 
  19. Lehnert, Matthew S.; Kramer, Valerie R.; Rawlins, John E.; Verdecia, Vanessa; Daniels, Jaret C. (2017-07-10). "Jamaica's Critically Endangered Butterfly: A Review of the Biology and Conservation Status of the Homerus Swallowtail (Papilio (Pterourus) homerus Fabricius)" (in en). Insects 8 (3): 68. doi:10.3390/insects8030068. PMID 28698508. 
  20. Menotti-Raymond, M.; O'Brien, S. J. (Apr 1993). "Dating the genetic bottleneck of the African cheetah.". Proc Natl Acad Sci U S A 90 (8): 3172–6. doi:10.1073/pnas.90.8.3172. PMID 8475057. Bibcode1993PNAS...90.3172M. 
  21. O'Brien, S.; Roelke, M.; Marker, L; Newman, A; Winkler, C.; Meltzer, D; Colly, L; Evermann, J. et al. (March 22, 1985). "Genetic basis for species vulnerability in the cheetah". Science 227 (4693): 1428–1434. doi:10.1126/science.2983425. PMID 2983425. Bibcode1985Sci...227.1428O. http://bio150.chass.utoronto.ca/labs/cool-links/lab5/OBrien_et_al_1985_lab_5.pdf. 
  22. 22.0 22.1 Lindblad-Toh, K.; Wade, C. M.; Mikkelsen, T. S.; Karlsson, E. K. (2005). "Genome sequence, comparative analysis and haplotype structure of the domestic dog". Nature 438 (7069): 803–819. doi:10.1038/nature04338. PMID 16341006. Bibcode2005Natur.438..803L. 
  23. Marsden, C. D.; Ortega-Del Vecchyo, D.; O'Brien, D. P. et al. (2016). "Bottlenecks and selective sweeps during domestication have increased deleterious genetic variation in dogs". Proceedings of the National Academy of Sciences 113 (1): 152–157. doi:10.1073/pnas.1512501113. PMID 26699508. Bibcode2016PNAS..113..152M. 
  24. National Research Council. (1972). Genetic vulnerability of major crops. National Academies.
  25. Hyten, D. L.; Song, Q.; Zhu, Y. et al. (2006). "Impacts of genetic bottlenecks on soybean genome diversity". Proceedings of the National Academy of Sciences 103 (45): 16666–16671. doi:10.1073/pnas.0604379103. PMID 17068128. Bibcode2006PNAS..10316666H. 
  26. Peakall, R.; Ebert, D.; Scott, L. J.; Meagher, P. F.; Offord, C. A. (2003). "Comparative genetic study confirms exceptionally low genetic variation in the ancient and endangered relictual conifer, Wollemia nobilis (Araucariaceae)". Molecular Ecology 12 (9): 2331–2343. doi:10.1046/j.1365-294X.2003.01926.x. PMID 12919472. 
  27. Thomas, P. (2011). "Wollemia nobilis". The IUCN Red List of Threatened Species. doi:10.2305/IUCN.UK.2011-2.RLTS.T34926A9898196.en. 
  28. Robichaux, R. H.; Friar, E. A.; Mount, D. W. (1997). "Molecular Genetic Consequences of a Population Bottleneck Associated with Reintroduction of the Mauna Kea Silversword (Argyroxiphium sandwicense ssp. sandwicense [Asteraceae])". Conservation Biology 11 (5): 1140–1146. doi:10.1046/j.1523-1739.1997.96314.x. 

External links

  • "Population bottlenecks and Pleistocene human evolution". Molecular Biology and Evolution 17 (1): 2–22. January 2000. doi:10.1093/oxfordjournals.molbev.a026233. PMID 10666702. 
    • "New study suggests big bang theory of human evolution". University of Michigan, Department of Anthropology (Press release). January 10, 2000. Archived from the original on February 5, 2014. Retrieved March 4, 2014.
  • Northern Elephant Seal History
  • Nei M (May 2005). "Bottlenecks, genetic polymorphism and speciation". Genetics 170 (1): 1–4. doi:10.1093/genetics/170.1.1. PMID 15914771. PMC 1449701. http://www.genetics.org/cgi/pmidlookup?view=long&pmid=15914771. 



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