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8 - Allostatic Load and Life Cycles: Implications for Neuroendocrine Control Mechanisms
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- By John C. Wingfield, University of Washington
- Edited by Jay Schulkin, Georgetown University, Washington DC
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- Book:
- Allostasis, Homeostasis, and the Costs of Physiological Adaptation
- Published online:
- 05 February 2015
- Print publication:
- 25 October 2004, pp 302-342
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- Chapter
- Export citation
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Summary
INTRODUCTION
Animals live in environments that change predictably over time, and individuals adjust their life cycles in anticipation of those changes. Habitat variation is most predictable at middle and high latitudes where short days of autumn and winter are accompanied by low primary productivity (plant growth) resulting in decreasing food resources for most animals. Lengthening days of spring and early summer bring a resurgence of growth and increasing food abundance. It is not surprising then that many vertebrates breed in spring when resources are increasing. This maximizes the chances for reproductive success. Even those animals that mate or give birth in autumn and winter time the period of maximum food requirements for feeding young with spring and summer (Lack, 1968; Bronson, 1989). In tropical regions, resources for breeding also fluctuate but often on a more variable time scale. The most well-known seasonal change in the tropics is rainfall, but the onset of the rainy season can vary in timing and amount from year to year. Thus, animals time breeding to coincide with maximum plant growth and subsequent fruit and insect production – or with the end of the rainy season when densities of young animals are great, in the case of many predators and vultures (Brown and Britton, 1980). Virtually all of these vertebrate organisms must initiate gonadal development, and many migrate to favorable breeding areas in anticipation of the onset of environmental conditions that are conducive to breeding. Equally important is termination of the reproductive period and gonadal regression as, or before, resources for breeding decline. Many species then undergo a molt, and migratory populations move back to wintering areas. These major changes in life history stages (LHSs; Jacobs and Wingfield, 2000) require profound adjustments of physiology, morphology, and behavior.
Although predictable cycles of morphology, physiology, and behavior are easily studied at the population level (e.g., daily, seasonal, tidal rhythms), individuals must also regulate their life cycles differently according to social status, body condition, parasite load, and so on. For example, resources for breeding are rarely distributed uniformly through the environment.