Ecological genetics is the study of genetics in natural populations. Traits in a population can be observed and quantified to represent a species adapting to a changing environment.

This contrasts with classical genetics, which works mostly on crosses between laboratory strains, and DNA sequence analysis, which studies genes at the molecular level.

Research in this field is on traits of ecological significance—that is, traits related to fitness, which affect an organism's survival and reproduction. Examples might be: flowering time, drought tolerance, polymorphism, mimicry, and avoidance of attacks by predators.

Ecological genetics is an especially useful tool when studying endangered species.[1] Meta-barcoding and eDNA are used to examine the biodiversity of species in an ecosystem.[2]

Research usually involves a mixture of field and laboratory studies.[3] Samples of natural populations may be taken back to the laboratory for their genetic variation to be analyzed. Changes in the populations at different times and places will be noted, and the pattern of mortality in these populations will be studied. Research is often done on insects and other organisms such as microbial communities, that have short generation times.[4]

History

Although work on natural populations had been done previously, it is acknowledged that the field was founded by the English biologist E.B. Ford (1901–1988) in the early 20th century. Ford was taught genetics at Oxford University by Julian Huxley, and started research on the genetics of natural populations in 1924. Ford also had a long working relationship with R.A. Fisher. By the time Ford had developed his formal definition of genetic polymorphism,[5][6] Fisher had got accustomed to high natural selection values in nature. This was one of the main outcomes of research on natural populations. Ford's magnum opus was Ecological genetics, which ran to four editions and was widely influential.[7]

Other notable ecological geneticists would include Theodosius Dobzhansky who worked on chromosome polymorphism in fruit flies. As a young researcher in Russia, Dobzhansky had been influenced by Sergei Chetverikov, who also deserves to be remembered as a founder of genetics in the field, though his significance was not appreciated until much later. Dobzhansky and colleagues carried out studies on natural populations of Drosophila species in western USA and Mexico over many years.[8][9][10]

Philip Sheppard, Cyril Clarke, Bernard Kettlewell and A.J. Cain were all strongly influenced by Ford; their careers date from the post World War II era. Collectively, their work on lepidoptera, and on human blood groups, established the field, and threw light on selection in natural populations where its role had been once doubted.

Work of this kind needs long-term funding, as well as grounding in both ecology and genetics. These are both difficult requirements. Research projects can last longer than a researcher's career; for instance, research into mimicry started 150 years ago, and is still going strongly.[11][12] Funding of this type of research is still rather erratic, but at least the value of working with natural populations in the field cannot now be doubted.

See also

References

  1. Vaishnav, V; Mahesh, S; Kumar, P (2019). "ASSESSMENT OF GENETIC STRUCTURE OF THE ENDANGERED FOREST SPECIES BOSWELLIA SERRATA POPULATION IN CENTRAL INDIA". Journal of Tropical Forest Science. 31 (2): 200–210. doi:10.26525/jtfs2019.31.2.200210. ISSN 0128-1283. JSTOR 26626991. S2CID 196656543.
  2. Bista, Iliana; Carvalho, Gary R.; Walsh, Kerry; Seymour, Mathew; Hajibabaei, Mehrdad; Lallias, Delphine; Christmas, Martin; Creer, Simon (2017-01-18). "Annual time-series analysis of aqueous eDNA reveals ecologically relevant dynamics of lake ecosystem biodiversity". Nature Communications. 8 (1): 14087. doi:10.1038/ncomms14087. ISSN 2041-1723. PMC 5253663. PMID 28098255.
  3. Ford E.B. 1981. Taking genetics into the countryside. Weidenfeld & Nicolson, London.
  4. Kassen, Rees; Rainey, Paul B. (October 2004). "The Ecology and Genetics of Microbial Diversity". Annual Review of Microbiology. 58 (1): 207–231. doi:10.1146/annurev.micro.58.030603.123654. ISSN 0066-4227. PMID 15487936.
  5. Ford E.B. 1940. Polymorphism and taxonomy. In Huxley J. The new systematics. Oxford University Press.
  6. Ford E.B. 1965. Genetic polymorphism. All Souls Studies, Faber & Faber, London.
  7. Ford E.B. 1975. Ecological genetics, 4th ed. Chapman and Hall, London.
  8. Dobzhansky, Theodosius. Genetics and the origin of species. Columbia, N.Y. 1st ed 1937; second ed 1941; 3rd ed 1951.
  9. Dobzhansky, Theodosius 1970. Genetics of the evolutionary process. Columbia, New York.
  10. Dobzhansky, Theodosius 1981. Dobzhansky's genetics of natural populations I-XLIII. R.C. Lewontin, J.A. Moore, W.B. Provine & B. Wallace, eds. Columbia University Press, New York 1981. (reprints the 43 papers in this series, all but two of which were authored or co-authored by Dobzhansky)
  11. Mallet J. and Joron M. 1999. Evolution in diversity in warning color and mimicry: polymorphisms, shifting balance and speciation. Annual Review of Ecological Systematics 1999. 30 201–233
  12. Ruxton G.D. Sherratt T.N. and Speed M.P. 2004. Avoiding attack: the evolutionary ecology of crypsis, warning signals & mimicry. Oxford University Press.

Further reading

  • Cain A.J. and W.B. Provine 1992. Genes and ecology in history. In: R.J. Berry, T.J. Crawford and G.M. Hewitt (eds). Genes in ecology. Blackwell Scientific: Oxford. Provides a good historical background.
  • Conner J.K. and Hartl D.L. 2004. A primer of ecological genetics. Sinauer Associates, Sunderland, Mass. Provides basic and intermediate level processes and methods.
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