Book contents
- Frontmatter
- Contents
- List of contributors
- Preface
- Adaptation of biological membranes to temperature: biophysical perspectives and molecular mechanisms
- Temperature adaptation: molecular aspects
- Stenotherms and eurytherms: mechanisms establishing thermal optima and tolerance ranges
- Ecological and evolutionary physiology of stress proteins and the stress response: the Drosophila melanogaster model
- Temperature adaptation and genetic polymorphism in aquatic animals
- Phenotypic plasticity and evolutionary adaptations of mitochondria to temperature
- Temperature and ontogeny in ectotherms: muscle phenotype in fish
- Ectotherm life-history responses to developmental temperature
- Testing evolutionary hypotheses of acclimation
- Experimental investigations of evolutionary adaptation to temperature
- Thermal evolution of ectotherm body size: why get big in the cold?
- Physiological correlates of daily torpor in hummingbirds
- Development of thermoregulation in birds: physiology, interspecific variation and adaptation to climate
- Evolution of endothermy in mammals, birds and their ancestors
- The influence of climate change on the distribution and evolution of organisms
- Index
The influence of climate change on the distribution and evolution of organisms
Published online by Cambridge University Press: 04 May 2010
- Frontmatter
- Contents
- List of contributors
- Preface
- Adaptation of biological membranes to temperature: biophysical perspectives and molecular mechanisms
- Temperature adaptation: molecular aspects
- Stenotherms and eurytherms: mechanisms establishing thermal optima and tolerance ranges
- Ecological and evolutionary physiology of stress proteins and the stress response: the Drosophila melanogaster model
- Temperature adaptation and genetic polymorphism in aquatic animals
- Phenotypic plasticity and evolutionary adaptations of mitochondria to temperature
- Temperature and ontogeny in ectotherms: muscle phenotype in fish
- Ectotherm life-history responses to developmental temperature
- Testing evolutionary hypotheses of acclimation
- Experimental investigations of evolutionary adaptation to temperature
- Thermal evolution of ectotherm body size: why get big in the cold?
- Physiological correlates of daily torpor in hummingbirds
- Development of thermoregulation in birds: physiology, interspecific variation and adaptation to climate
- Evolution of endothermy in mammals, birds and their ancestors
- The influence of climate change on the distribution and evolution of organisms
- Index
Summary
Introduction
The study of how organisms adapt to temperature has a long and distinguished history. During the past few decades much attention has been directed at understanding the mechanisms by which such adaptation is achieved. At the same time palaeobiologists have been attempting to unravel the influence of climate on the evolution and extinction of the Earth's biota, a concern heightened by the recent realisation that mankind's own activities may already have initiated a significant experiment in the impact of climate change.
In this chapter I discuss the impact of past climate change on organisms, using results from palaeobiology, environmental physiology and comparative ecology. A comprehensive review of these fields would require a whole book and so for this chapter I have necessarily been selective, concentrating on those areas that might help generate a coherent picture of how organisms respond to climate change. I have attempted to emphasise both areas of agreement and what appear, with current knowledge, to be significant mismatches between different fields of enquiry. In doing so I have tried to balance citation between key historical literature, comprehensive reviews and important recent work. Space constraints mean that usually only a single illustrative example can be used and I have quite deliberately chosen some of these from the older literature; it is not always the most recent work that is either the best or the most relevant.
- Type
- Chapter
- Information
- Animals and TemperaturePhenotypic and Evolutionary Adaptation, pp. 377 - 408Publisher: Cambridge University PressPrint publication year: 1996
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