Introgression, also known as introgressive hybridization, in genetics (particularly plant genetics) is the movement of a gene (gene flow) from one species into the gene pool of another by the repeated backcrossing of an interspecific hybrid with one of its parent species. Purposeful introgression is a long-term process; it may take many hybrid generations before the backcrossing occurs.

Introgression is an important source of genetic variation in natural populations and may contribute to adaptation and even adaptive radiation.^[1] It can occur across hybrid zones due to chance, selection or hybrid zone movement.^[2] There is evidence that introgression is a ubiquitous phenomenon in plants, animals,^[3][4] and even humans,^[5] in which it may have introduced the microcephalin D allele.^[6]

Introgression differs from simple hybridization. Introgression results in a complex mixture of parental genes, while simple hybridization results in a more uniform mixture, which in the first generation will be an even mix of two parental species. Natural introgression does not have human direct interference while the exotic introgression is induced intentionally (as for instance genetically modified organisms^{[clarification needed]}) or not (human activities affecting local races of crops or human disturbances such as by introducing weeds).^{[citation needed]}

Examples

One important example of introgression has been observed in butterfly mimicry. Genus Heliconius has been studied. This genus comprehends 43 species and many races with different color patterns. Congeners exhibiting overlapping distributions show similar color patterns. The distribution of the subspecies H. melpomene amaryllis and H. melpomene timareta ssp. nov. overlap. Using the ABBA/BABA test, some researchers have observed that there is ≈2-5% introgression between the pair of subspecies. It is important to know that this is not random introgression. They saw important introgression in chromosomes 15 and 18, where important mimicry loci are located (loci B/D and N/Yb). They compared both subspecies with H.melpomene agalope, which is a subspecies near H.melpomene amaryllis in entire genome trees. The result of this experiment was that there is no relation between those two species and H.melpomene agalope in the loci B/D and N/Yb. Moreover, they performed the same experiment with two other species with overlapping distributions, H.timareta florencia and H.melpomene agalope. They demonstrated introgression between the two taxa, especially in the loci B/D and N/Yb. Finally, they concluded their experiments with sliding-window phylogenetic analyses, estimating different phylogenetic trees depending on the different regions of the loci. When a locus is important in the color pattern expression, there is a close phylogenetic relationship between the species. When the locus is not important in the color pattern expression, the two species are phylogenetically distant because there is no introgression at such loci.

Introgression could be an important conservation problem for wild species through hybridisation, for instance, between wild and domestic cats ^[7] or among wild canids and domestic dogs.^[8]Another important example has been studied by Arnold & Bennett 1993: iris species from southern Louisiana.^[9]

Introgression line

An introgression line (abbreviation: IL) in plant molecular biology is a line of a crop species that contains genetic material derived from a similar species, for example a "wild" relative. An example of a collection of ILs (called IL-Library) is the use of chromosome fragments from Solanum pennellii (a wild variety of tomato) introgressed in Solanum lycopersicum (the cultivated tomato). The lines of an IL-library usually cover the complete genome of the donor. Introgression lines allow the study of quantitative trait loci, but also the creation of new varieties by introducing exotic traits.

See also

• Gene flow
• Transgene
• Hybridization
• Genetic engineering
• Genetically modified organism
• Transgenic plant
• Chimera (genetics)
• Gene pool
• Genetic pollution
• Genetic erosion

References

Further reading

• Arnold, M. L. (2007). Evolution through Genetic Exchange. New York: Oxford University Press. ISBN 0-19-922903-1. 
• Anderson, E. 1949. Introgressive Hybridization. Wiley, New York.
• Eyal Friedman et al., "Zooming In on a Quantitative Trait for Tomato Yield Using Interspecific Introgressions", Science vol.305 pag.1786-1798 (2004)

• Rieseberg, L. H. & Wendel, J. F. (1993). "Introgression and its consequences in plants". In: Harrison, R. G. (ed.) Hybrid Zones and Evolutionary Process, pp. 70–109. Oxford University Press, New York. ISBN 978-0-19-506917-4

• Martinsen G. D., Whitham R. J. Turek, Keim P. (2001). "Hybrid populations selectively filter gene introgression between species". Evolution 55 (7): 1325–1335. doi:10.1554/0014-3820(2001)055[1325:hpsfgi]2.0.co;2. PMID 11525457. 

• Whitney, K.D., Ahern J.R.,Campbell L.G, Albert L.P., King M.S. (2010). "Patterns of hybridization in plants" (PDF). Evolution and Sytematics 12: 175–182. doi:10.1016/j.ppees.2010.02.002.  ("Forbidden" - No Access 2015-04-06) Alternate Link: Patterns of Hybridization in Plants

• The Heliconius genome Consortium. Butterfly genome reveals promiscuous exchange of mimicry adaptations among species. Nature 487,94-98 (2012).