Evolutionary physiology is the study of the biological
evolution of
physiological structures and processes; that is, the manner in which the functional characteristics of individuals in a population of
organisms have responded to
natural selection across multiple
generations during the history of the population.[1] It is a
sub-discipline of both
physiology and
evolutionary biology. Practitioners in the field come from a variety of backgrounds, including physiology, evolutionary biology,
ecology, and
genetics.
As the name implies, evolutionary physiology is the product of what were at one time two distinct scientific disciplines. According to Garland and Carter,[1] evolutionary physiology arose in the late 1970s, following debates concerning the metabolic and thermoregulatory status of
dinosaurs (see
physiology of dinosaurs) and
mammal-like reptiles.
Shortly thereafter, selection experiments and
experimental evolution became increasingly common in evolutionary physiology. Macrophysiology has emerged as a sub-discipline, in which practitioners attempt to identify large-scale patterns in physiological traits (e.g. patterns of co-variation with
latitude) and their ecological implications.[7][8][9]
More recently, the importance of a merger of evolutionary biology and physiology has been argued from the perspective of functional analyses,
epigenetics, and an
extended evolutionary synthesis.[10] The growth of evolutionary physiology is also reflected in the emergence of sub-disciplines, such as evolutionary
endocrinology,[11][12] which addresses such hybrid questions as "What are the most common endocrine mechanisms that respond to selection on behavior or life-history traits?"[13]
Emergent properties
As a hybrid scientific discipline, evolutionary physiology provides some unique perspectives. For example, an understanding of physiological mechanisms can help in determining whether a particular pattern of phenotypic variation or co-variation (such as an
allometric relationship) represents what could possibly exist or just what selection has allowed.[1] Similarly, a thorough knowledge of physiological mechanisms can greatly enhance understanding of possible reasons for evolutionary correlations and constraints than is possible for many of the traits typically studied by evolutionary biologists (such as
morphology).
In the United States, research in evolutionary physiology is funded mainly by the
National Science Foundation. A number of scientific societies feature sections that encompass evolutionary physiology, including:
^Lovegrove, B. G. (2006). "The power of fitness in mammals: perceptions from the African slipstream". Physiological and Biochemical Zoology. 79 (2): 224–236.
doi:
10.1086/499994.
PMID16555182.
S2CID24536395.
^Feder, M. E.; A. F. Bennett; W. W. Burggren; R. B. Huey, eds. (1987). New directions in ecological physiology. New York: Cambridge Univ. Press.
ISBN978-0-521-34938-3.
^Kingsolver, J. G (1988). "Evolutionary physiology: Where's the ecology? A review of New Directions in Ecological physiology, Feder et al. 1987". Ecology. 69 (5): 1645–1646.
doi:
10.2307/1941674.
JSTOR1941674.
^Gaston, K. J.; Chown, S. L.; Calosi, P.; Bernardo, J.; Bilton, D. T.; Clarke, A.; Clusella-Trullas, S.; Ghalambor, C. K.; Konarzewski, M.; Peck, L. S.; Porter, W. P.; Pörtner, H. O.; Rezende, E. L.; Schulte, P. M.; Spicer, J. I.; Stillman, J. H.; Terblanche, J. S.; van Kleunen, M. (2009).
"Macrophysiology: a conceptual reunification"(PDF). The American Naturalist. 174 (5): 595–612.
doi:
10.1086/605982.
hdl:10019.1/119921.
PMID19788354.
S2CID6239591.