Effects of elevated CO2 concentration and nutrition on net photosynthesis, stomatal conductance and needle respiration of field-grown Norway spruce trees

Abstract

To study the effects of elevated CO₂ on gas exchange, nonstructural carbohydrate and nutrient concentrations in current-year foliage of 30-year-old Norway spruce (Picea abies (L.) Karst.) trees, branches were enclosed in ventilated, transparent plastic bags and flushed with ambient air (mean 370 μmol CO₂ mol⁻¹; control) or ambient air + 340 μmol CO₂ mol⁻¹ (elevated CO₂) during two growing seasons. One branch bag was installed on each of 24 selected trees from control and fertilized plots. To reduce the effect of variation among trees, results from each treated branch were compared with those from a control branch on the same whorl of the same tree. Elevated CO₂ increased rates of light-saturated photosynthesis on average by 55% when measured at the treatment CO₂ concentration. The increase was larger in shoots with high needle nitrogen concentrations than in shoots with low needle nitrogen concentrations. However, shoots grown in elevated CO₂ showed a decrease in photosynthetic capacity compared with shoots grown in ambient CO₂. When measured at the internal CO₂ concentration of 200 μmol CO₂ mol⁻¹, photosynthetic rates of branches in the elevated CO₂ treatments were reduced by 8 to 32%. The elevated CO₂ treatment caused a 9 to 20% reduction in carboxylation efficiency and an 18% increase in respiration rates. In response to elevated CO₂, starch, fructose and glucose concentrations in the needles increased on average 33%, whereas concentrations of potassium, nitrogen, phosphorus, magnesium and boron decreased. Needle nitrogen concentrations explained 50–60% of the variation in photosynthesis and CO₂ acclimation was greater at low nitrogen concentrations than at high nitrogen concentrations. We conclude that the enhanced photosynthetic rates found in shoots exposed to elevated CO₂ increased carbohydrate concentrations, which may have a negative feedback on the photosynthetic apparatus and stimulate cyanide-resistant respiration. We also infer that the decrease in nutrient concentrations of needles exposed to elevated CO₂ was the result of retranslocation of nutrients to other parts of the branch or tree.