All organisms are faced with environmental uncertainty. Bet-hedging theory expects unpredictable selection to result in the evolution of traits that maximize the geometric-mean fitness even though such traits appear to be detrimental over the shorter term. Despite the centrality of fitness measures to evolutionary analysis, no direct test of the geometric-mean fitness principle exists. Here, we directly distinguish between predictions of competing fitness maximization principles by testing Cohen's 1966 classic bet-hedging model using the fungus Neurospora crassa. The simple prediction is that propagule dormancy will evolve in proportion to the frequency of ‘bad’ years, whereas the prediction of the alternative arithmetic-mean principle is t...
Genotypes can persist in unpredictable environments by ‘hedging their bets’ and producing diverse ph...
In ecology, species can mitigate their extinction risks in uncertain environments by diversifying in...
In order to understand how organisms cope with ongoing changes in environmental variability, it is n...
All organisms are faced with environmental uncertainty. Bet-hedging theory expects unpredictable sel...
Genotypes that hedge their bets can be favored by selection in an unpredictably varying environment....
Proper timing of activities is one of the principal challenges faced by most organisms. Organisms ne...
Adaptive phenotypic plasticity evolves when cues reliably predict fitness consequences of life-histo...
Adaptive plasticity is expected to evolve when informative cues predict environmental variation. How...
Understanding the adaptations that allow species to live in temporally variable environments is esse...
During the growing season, some individuals in perennial plant populations may remain alive below gr...
Determining the probability of fixation of beneficial mutations is critically important for building...
Understanding how organisms adapt to environmental variation is a key challenge of biology. Central ...
Genotypes can persist in unpredictable environments by ‘hedging their bets’ and producing diverse ph...
In ecology, species can mitigate their extinction risks in uncertain environments by diversifying in...
In order to understand how organisms cope with ongoing changes in environmental variability, it is n...
All organisms are faced with environmental uncertainty. Bet-hedging theory expects unpredictable sel...
Genotypes that hedge their bets can be favored by selection in an unpredictably varying environment....
Proper timing of activities is one of the principal challenges faced by most organisms. Organisms ne...
Adaptive phenotypic plasticity evolves when cues reliably predict fitness consequences of life-histo...
Adaptive plasticity is expected to evolve when informative cues predict environmental variation. How...
Understanding the adaptations that allow species to live in temporally variable environments is esse...
During the growing season, some individuals in perennial plant populations may remain alive below gr...
Determining the probability of fixation of beneficial mutations is critically important for building...
Understanding how organisms adapt to environmental variation is a key challenge of biology. Central ...
Genotypes can persist in unpredictable environments by ‘hedging their bets’ and producing diverse ph...
In ecology, species can mitigate their extinction risks in uncertain environments by diversifying in...
In order to understand how organisms cope with ongoing changes in environmental variability, it is n...