Atmospheric carbon dioxide concentration, nitrogen availability, temperature and the photosynthetic capacity of current-year
Norway spruce shoots
Peter Roberntz (1)
1. Department for Production Ecology, Swedish University of Agricultural Sciences, P.O. Box 7042, SE-750 07 Uppsala, Sweden () / Received August 18, 2000
Summary
Branches of field-grown Norway spruce (Picea abies (L.) Karst.) trees were exposed to either long-term ambient or to elevated CO2 concentrations ([CO2]) using the branch bag technique. The light-saturated photosynthetic rates (Amax) of current-year shoots differing in nitrogen (N) status were measured at various temperatures and at either ambient (360
μmol mol–1, AMB) or elevated (ambient + 350 μmol mol–1, EL) [CO2]. The value of Amax was determined at various intercellular [CO2]s (A/Ci curves) and used to normalize photosynthetic rates to the mean treatment Ci values, which were 200 μmol mol–1 (AMB) and 450 μmol mol–1 (EL), respectively. Needle N status and temperature strongly affected Amax. The response to N increased with temperature, and the photosynthetic temperature optimum increased with N status. This was
assumed to be a result of reduced mesophyll CO2 conductance. The relative increase of Amax in the EL treatment compared to the AMB treatment varied from 15 to 90%, and increased with temperature, but decreased with
N status. Nevertheless, the absolute photosynthetic response to EL increased with shoot N status. The relative increase in
the instantaneous response of Amax to elevated [CO2] was about 20% higher than the long-term response, i.e., there was downward acclimation in Amax in response to elevated [CO2]. The photosynthetic temperature optimum increased 4 °C with either a short- or a long-term increase in [CO2]. The bag treatment itself increased Amax by approximately 16% and the temperature optimum of Amax by approximately 3 °C.
Keywords:
Amax, climate change, Picea abies, temperature optimum.
