• climate gradients;
  • leaf nitrogen;
  • leaf lifespan;
  • photosynthesis;
  • plant metabolism;
  • specific leaf area


  • • 
    Leaf dark respiration (R) is one of the most fundamental physiological processes in plants and is a major component of terrestrial CO2 input to the atmosphere. Still, it is unclear how predictably species vary in R along broad climate gradients.
  • • 
    Data for R and other key leaf traits were compiled for 208 woody species from 20 sites around the world. We quantified relationships between R and site climate, and climate-related variation in relationships between R and other leaf traits.
  • • 
    Species at higher-irradiance sites had higher mean R at a given leaf N concentration, specific leaf area (SLA), photosynthetic capacity (Amass) or leaf lifespan than species at lower-irradiance sites. Species at lower-rainfall sites had higher mean R at a given SLA or Amass than species at higher-rainfall sites. On average, estimated field rates of R were higher at warmer sites, while no trend with site temperature was seen when R was adjusted to a standard measurement temperature.
  • • 
    Our findings should prove useful for modelling plant nutrient and carbon budgets, and for modelling vegetation shifts with climate change.