Photosynthetic o(2) exchange kinetics in isolated soybean cells.

Light-dependent O(2) exchange was measured in intact, isolated soybean (Glycine max. var. Williams) cells using isotopically labeled O(2) and a mass spectrometer. The dependence of O(2) exchange on O(2) and CO(2) was investigated at high light in coupled and uncoupled cells. With coupled cells at high O(2), O(2) evolution followed similar kinetics at high and low CO(2). Steady-state rates of O(2) uptake were insignificant at high CO(2), but progressively increased with decreasing CO(2). At low CO(2), steady-state rates of O(2) uptake were 50% to 70% of the maximum CO(2)-supported rates of O(2) evolution. These high rates of O(2) uptake exceeded the maximum rate of O(2) reduction determined in uncoupled cells, suggesting the occurrence of another light-induced O(2)-uptake process (i.e. photorespiration).Rates of O(2) exchange in uncoupled cells were half-saturated at 7% to 8% O(2). Initial rates (during induction) of O(2) exchange in uninhibited cells were also half-saturated at 7% to 8% O(2). In contrast, steady-state rates of O(2) evolution and O(2) uptake (at low CO(2)) were half-saturated at 18% to 20% O(2). O(2) uptake was significantly suppressed in the presence of nitrate, suggesting that nitrate and/or nitrite can compete with O(2) for photoreductant.These results suggest that two mechanisms (O(2) reduction and photorespiration) are responsible for the light-dependent O(2) uptake observed in uninhibited cells under CO(2)-limiting conditions. The relative contribution of each process to the rate of O(2) uptake appears to be dependent on the O(2) level. At high O(2) concentrations (>/=40%), photorespiration is the major O(2)-consuming process. At lower (ambient) O(2) concentrations (</=20%), O(2) reduction accounts for a significant portion of the total light-dependent O(2) uptake.