Abstract

Chloroplast small (low-molecular-weight) heat-shock proteins (csHsps) can protect photosynthetic electron transport (P_et), and quantitative variation in csHsps is correlated with thermotolerance of net photosynthesis and Photosystem II. However, the functional (i.e. protective) consequence of natural variation in csHsps is unknown. To investigate this, we used an in vitro assay to determine the contribution of csHsps to the tolerance of P_et to high temperatures in five ecotypes of Chenopodium album collected from habitats ranging from cool to warm, and we partitioned total P_et thermotolerance into basal and induced P_et components (without and with a pre-heat treatment, respectively, to induce csHsps). The ecotypes varied in total P_et thermotolerance and this was correlated with habitat temperature. Variation in total P_et thermotolerance was associated primarily with variation in induced P_et thermotolerance, and not with basal P_et thermotolerance. Variation in induced P_et was highly correlated with csHsp protection of P_et. Variation in csHsp function was associated with variation in csHsp content among ecotypes. These results are the first to demonstrate the direct functional consequences for natural variation in Hsps in plants, and show that functional variation is associated with evolutionary adaptation to specific habitats among ecotypes.