Genotypic variation in physiological and growth responses of Populus tremuloides to elevated atmospheric CO2 concentration

Physiological and biomass responses of six genotypes of Populus tremuloides Michx., grown in ambient t (357 micromol mol(-1)) or twice ambient (707 micromol mol(-1)) CO2 concentration (CO2]) and in low-N or high-N soils, were studied in 1995 and 1996 in northern Lower Michigan, USA. There was a significant CO2 x genotype interaction in photosynthetic responses. Net CO2 assimilation (A) was significantly enhanced by elevated CO2] for five genotypes in high-N soil and for four genotypes in low-N soil. Enhancement of A by elevated CO2] ranged from 14 to 68%. Genotypes also differed in their biomass responses to elevated CO2], but biomass responses were poorly correlated with A responses. There was a correlation between magnitude of A enhancement by elevated CO2] and stomatal sensitivity to CO2. Genotypes with low stomatal sensitivity to CO2 had a significantly higher A at elevated CO2] than at ambient CO2], but elevated CO2] did not affect the ratio of intercellular CO2] to leaf surface CO2]. Stomatal conductance and A of different genotypes responded differentially to recovery from drought stress. Photosynthetic quantum yield and light compensation point were unaffected by elevated CO2]. We conclude that P. tremuloides genotypes will respond differentially to rising atmospheric CO2], with the degree of response dependent on other abiotic factors, such as soil N and water availability. The observed genotypic variation in growth could result in altered genotypic representation within natural populations and could affect the composition and structure of plant communities in a higher CO2] environment in the future.