Growth rate is increasingly recognized as a key life-history trait that may affect fitness directly rather than evolve as a by-product of selection on size or age. An ongoing challenge is to explain the abundant levels of phenotypic and genetic variation in growth rates often seen in natural populations, despite what is expected to be consistently strong selection on this trait. Such a paradox suggests limits to how contemporary growth rates evolve. We explored limits arising from variation in selection, based on selection differentials for age-specific growth rates expressed under different ecological conditions. We present results from a field experiment that measured growth rates and reproductive output in wild individuals of a colonial ...
Environmental conditions experienced during early growth and development markedly shape phenotypic t...
Many life-history traits are important determinants of the generation time. For instance, semelparou...
Phenotypic plasticity is predicted to evolve in more variable environments, conferring an advantage ...
Growth rate is increasingly recognised as a key life-history trait that may affect fitness directly,...
Growth rates are highly variable, both within and among genotypes and populations. The resolution of...
Explaining the strong variation in lifespan among organisms remains a major challenge in evolutionar...
Explaining the strong variation in lifespan among organisms remains a major challenge in evolutionar...
Understanding the factors that shape the timing of life-history switch points (SPs; e.g. hatching, m...
How do environmental fluctuations affect the evolution of life history traits? Advocates of r- and K...
Classic methods of population genetics can be applied for traits not affecting generation length. Ho...
According to a classic result in evolutionary biodemography, selection on age-specific survival inva...
Organisms must cope with both short- and long-term environmental changes to persist. In this study w...
In life histories with generation overlap, selection that acts differently on different life-stages ...
Understanding the consequences of environmental change on ecological and evolutionary dynamics is in...
Offspring size is one of the most important life-history traits with consequences for both the ecolo...
Environmental conditions experienced during early growth and development markedly shape phenotypic t...
Many life-history traits are important determinants of the generation time. For instance, semelparou...
Phenotypic plasticity is predicted to evolve in more variable environments, conferring an advantage ...
Growth rate is increasingly recognised as a key life-history trait that may affect fitness directly,...
Growth rates are highly variable, both within and among genotypes and populations. The resolution of...
Explaining the strong variation in lifespan among organisms remains a major challenge in evolutionar...
Explaining the strong variation in lifespan among organisms remains a major challenge in evolutionar...
Understanding the factors that shape the timing of life-history switch points (SPs; e.g. hatching, m...
How do environmental fluctuations affect the evolution of life history traits? Advocates of r- and K...
Classic methods of population genetics can be applied for traits not affecting generation length. Ho...
According to a classic result in evolutionary biodemography, selection on age-specific survival inva...
Organisms must cope with both short- and long-term environmental changes to persist. In this study w...
In life histories with generation overlap, selection that acts differently on different life-stages ...
Understanding the consequences of environmental change on ecological and evolutionary dynamics is in...
Offspring size is one of the most important life-history traits with consequences for both the ecolo...
Environmental conditions experienced during early growth and development markedly shape phenotypic t...
Many life-history traits are important determinants of the generation time. For instance, semelparou...
Phenotypic plasticity is predicted to evolve in more variable environments, conferring an advantage ...