Phenotypic plasticity

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Norms of reaction for two genotypes. Genotype B shows a strongly bimodal distribution indicating differentiation into distinct phenotypes. Each phenotype is buffered against environmental variation - it is canalised.

The ability of an organism with a given genotype to change its phenotype in response to changes in the environment is called phenotypic plasticity.^[1] Such plasticity in some cases expresses as several highly morphologically distinct results; in other cases, a continuous norm of reaction describes the functional interrelationship of a range of environments to a range of phenotypes. The term was originally conceived in the context of development, but is now more broadly applied to include changes that occur during the adult life of an organism, such as behaviour.

Organisms of fixed genotype may differ in the amount of phenotypic plasticity they display when exposed to the same environmental change. Hence phenotypic plasticity can evolve and be adaptive if fitness is increased by changing phenotype.^[2] Immobile organisms such as plants have well developed phenotypic plasticity, giving a clue to the adaptive significance of plasticity.^[3]

A highly illustrative example of phenotypic plasticity is found in the social insects, colonies of which depend on the division of their members into distinct castes, such as workers and guards.^[4] These two castes differ dramatically in appearance and behaviour. However, while these differences are genetic in basis, they are not inherited; they arise during development and depend on the manner of treatment of the eggs by the queen and the workers, who manipulate such factors as embryonic diet and incubation temperature. The genome of each individual contains all the instructions needed to develop into any one of several 'morphs', but only the genes that form part of one developmental program are activated.^[5]

In epidemiology, a theory is that rising incidences of coronary heart disease and Type II diabetes in human populations undergoing industrialization is due to a mismatch between a metabolic phenotype determined in development and the nutritional environment an individual is subsequently exposed to. This is known as the 'Thrifty phenotype' hypothesis (see Evolutionary psychology).

1 See also
2 References
3 External links
4 Further reading

[edit] See also

[edit] References

^ Price TD, Qvarnström A, Irwin DE (July 2003). "The role of phenotypic plasticity in driving genetic evolution". Proc. Biol. Sci. 270 (1523): 1433–40. doi:10.1098/rspb.2003.2372. PMID 12965006.
^ de Jong G (April 2005). "Evolution of phenotypic plasticity: patterns of plasticity and the emergence of ecotypes". New Phytol. 166 (1): 101–17. doi:10.1111/j.1469-8137.2005.01322.x. PMID 15760355.
^ Sultan SE (December 2000). "Phenotypic plasticity for plant development, function and life history". Trends Plant Sci. 5 (12): 537–42. PMID 11120476.
^ Emlen DJ, Nijhout HF (2000). "The development and evolution of exaggerated morphologies in insects". Annu. Rev. Entomol. 45: 661–708. doi:10.1146/annurev.ento.45.1.661. PMID 10761593.
^ Miura T (2005). "Developmental regulation of caste-specific characters in social-insect polyphenism". Evol. Dev. 7 (2): 122–9. doi:10.1111/j.1525-142X.2005.05014.x. PMID 15733310.

[edit] External links

Special issue of the Journal of Experimental Biology concerning phenotypic plasticity
Massimo Pigliucci’s Evolutionary Ecology Lab web page
Developmental Plasticity and Evolution - review of the book from American Scientist

[edit] Further reading

Mary Jane West-Eberhard (2003). Developmental Plasticity and Evolution. Oxford University Press.

v • d • e The development of phenotype

Key concepts	Genotype-phenotype distinction · Norms of reaction · Gene-environment interaction · Heritability · Quantitative genetics

Genetic architecture	Dominance relationship · Epistasis · Polygenic inheritance · Pleiotropy · Plasticity · Canalisation · Fitness landscape

Non-genetic influences	Epigenetics · Maternal effect · Dual inheritance theory

Developmental architecture	Segmentation · Modularity

Evolution of genetic systems	Evolvability · Mutational robustness · Evolution of sex

Influential figures	C. H. Waddington · Richard Lewontin

Debates	Nature versus nurture

List of evolutionary biology topics

v • d • e Basic topics in evolutionary biology

Evidence of common descent

Processes of evolution	Adaptation · Macroevolution · Microevolution · Speciation

Population genetic mechanisms	Natural selection · Genetic drift · Gene flow · Mutation

Evolutionary developmental biology (Evo-devo) concepts	Phenotypic plasticity · Canalisation · Modularity

The evolution of...	DNA · Sex · Aging · Intelligence · The Ear · The Eye · Flight · Plants · Fungi · Life · Humans · Dolphins and whales

Modes of speciation	Anagenesis · Catagenesis · Cladogenesis

History	History of evolutionary thought · Charles Darwin · On the Origin of Species · Modern evolutionary synthesis · Gene-centered view of evolution · Life (classification trees)

Other subfields	Ecological genetics · Molecular evolution · Phylogenetics · Systematics

List of evolutionary biology topics · Timeline of evolution