On the relevance of using laboratory selection to study the adaptive value of circadian clocks

The reproductive fitness of cyanobacteria is altered by variation of temperature conditions and differential mutation of Kai genes that contribute to circadian rhythms. The degree and significance of these effects were tested in three distinct strains of Synechococcus elongatus cyanobacteria: a wild-type strain (AMC149) and two mutated strains with either an optimized or a disrupted circadian rhythm. These strains were allowed to compete in mixed cultures to determine the adaptive value of circadian clocks in relation to the reproductive fitness of cyanobacteria. Pure cultures served as controls, ensuring that growth rates were the same. Results illustrate that under constant light conditions at high temperatures, the strains with mutant circadian rhythms were both more reproductively fit than the wild-type strain. In conclusion, we found that circadian clocks do not confer a reproductive advantage for cyanobacteria when the cycle of the circadian clock does not match the light/dark cycle of the environment.

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Laboratory selection for the comparative physiologist

Journal of Experimental Biology ◽

10.1242/jeb.202.20.2709 ◽

1999 ◽

Vol 202 (20) ◽

pp. 2709-2718 ◽

Cited By ~ 4

Author(s):

A.G. Gibbs

Keyword(s):

Experimental Approach ◽

Comparative Physiology ◽

Behavioral Differences ◽

Physiological Mechanisms ◽

Success Stories ◽

Laboratory Selection ◽

Adaptive Value ◽

Selection Experiments ◽

Experimental Approaches ◽

Selection For

An increasingly popular experimental approach in comparative physiology is to study the evolution of physiological traits in the laboratory, using microbial, invertebrate and vertebrate models. Because selective conditions are well-defined, selected populations can be replicated and unselected control populations are available for direct comparison, strong conclusions regarding the adaptive value of an evolved response can be drawn. These studies have shown that physiological systems evolve rapidly in the laboratory, but not always as one would expect from comparative studies of different species. Laboratory environments are often not as simple as one thinks, so that the evolution of behavioral differences or selection acting on different life stages can lead to unanticipated results. In some cases, unexpected responses to laboratory selection may suggest new insights into physiological mechanisms, which might not be available using other experimental approaches. I outline here recent results (including success stories and caveats for the unwary investigator) and potential directions for selection experiments in comparative physiology.

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