SummaryCold-blooded animals, which cannot directly control their body temperatures, have adapted to function within specific temperature ranges that vary between species. However, little is known about what sets the limits of the viable temperature range. Here we show that the speed of the first cell division in C. elegans N2 varies with temperature according to the Arrhenius equation. However, it does so only within certain limits. Outside these limits we observe alterations in the cell cycle. Interestingly, these temperature limits also correspond to the animal’s fertile range. In C. briggsae AF16, isolated from a warmer climatic region, both the fertile range and the temperature range over which the speed of cell division follows the Arr...
Understanding how species’ thermal limits have evolved across the tree of life is central to predict...
Understanding how species’ thermal limits have evolved across the tree of life is central to predict...
Understanding how species’ thermal limits have evolved across the tree of life is central to predict...
Cold-blooded animals, which cannot directly control their body temperatures, have adapted to functio...
Cold-blooded animals, which cannot directly control their body temperatures, have adapted to functio...
Cold-blooded animals, which cannot directly control their body temperatures, have adapted to functio...
SummaryCold-blooded animals, which cannot directly control their body temperatures, have adapted to ...
Cold-blooded animals, which cannot directly control their body temperatures, have adapted to functio...
Cold-blooded animals, which cannot directly control their body temperatures, have adapted to functio...
Biologists have long been interested in the dynamic relationship between organism development and en...
Most ectotherms follow the temperature‐size rule (TSR): in cold environments individuals grow slowly...
Keywords: Thermal reaction norm, phenotypic plasticity, enzyme kinetics, temperature, development ra...
Keywords: Thermal reaction norm, phenotypic plasticity, enzyme kinetics, temperature, development ra...
1. Terrestrial ectotherms are likely to face increased periods of heat stress as mean temperatures a...
All organisms live within a given thermal range, but little is known about the mechanisms setting th...
Understanding how species’ thermal limits have evolved across the tree of life is central to predict...
Understanding how species’ thermal limits have evolved across the tree of life is central to predict...
Understanding how species’ thermal limits have evolved across the tree of life is central to predict...
Cold-blooded animals, which cannot directly control their body temperatures, have adapted to functio...
Cold-blooded animals, which cannot directly control their body temperatures, have adapted to functio...
Cold-blooded animals, which cannot directly control their body temperatures, have adapted to functio...
SummaryCold-blooded animals, which cannot directly control their body temperatures, have adapted to ...
Cold-blooded animals, which cannot directly control their body temperatures, have adapted to functio...
Cold-blooded animals, which cannot directly control their body temperatures, have adapted to functio...
Biologists have long been interested in the dynamic relationship between organism development and en...
Most ectotherms follow the temperature‐size rule (TSR): in cold environments individuals grow slowly...
Keywords: Thermal reaction norm, phenotypic plasticity, enzyme kinetics, temperature, development ra...
Keywords: Thermal reaction norm, phenotypic plasticity, enzyme kinetics, temperature, development ra...
1. Terrestrial ectotherms are likely to face increased periods of heat stress as mean temperatures a...
All organisms live within a given thermal range, but little is known about the mechanisms setting th...
Understanding how species’ thermal limits have evolved across the tree of life is central to predict...
Understanding how species’ thermal limits have evolved across the tree of life is central to predict...
Understanding how species’ thermal limits have evolved across the tree of life is central to predict...