LEAF CO2 EXCHANGE RATES IN WINTER RYE GROWN AT COLD-HARDENING AND NONHARDENING TEMPERATURES

Abstract

CO₂ gas exchange measurements were performed on cold-hardened and unhardened Puma rye (Secale cereale L.) leaves at 10 and 20 °C in the presence of 2 and 21% O₂ and as a function of irradiance and CO₂ concentration. A decrease in O₂ concentration from 21 to 2% appeared to result in a differential stimulation of photosynthetic rates in cold-hardened and unhardened rye leaves. Under light saturating conditions the former exhibited photosynthetic rates that tended to be 1.4- to 1.5-fold higher in the presence of 2% O₂ than 21% O₂ when measured at either 10 or 20 °C. In contrast, unhardened rye leaves exhibited photosynthetic rates that tended to be about 1.3-fold higher in the presence of 2% O₂ than 21% O₂ when measured at 10 °C but about 1.8-fold higher when measured at 20 °C. Similarly, at high CO₂ concentrations, leaves of unhardened plants exhibited a greater temperature-dependent stimulation of photosynthetic rates by low O₂ than leaves of hardened plants. An increased capacity for CO₂ utilization in cold-hardened rye could be observed when photosynthetic rates were monitored at 2% O₂. Differences in transpiration rates were insufficient to account for these results. The increased capacity for CO₂ utilization observed in vivo is discussed with respect to a recent report which described an increased capacity for photosynthetic electron transport in vitro in cold-hardened rye thylakoid membranes. However, photosynthetic acclimation to the contrasting growth temperatures could only be observed when CO₂ exchange was measured at 2% O₂. We conclude that photosynthetic acclimation in vivo may be severely limited due to the restrictions imposed by photorespiration.Key words: Cold-hardening, winter rye, CO₂ exchange, photosynthesis