Low atmospheric CO2 concentrations dominated the recent evolutionary history of plants. However, our knowledge of plant performance in low CO2 environments is poor, and that of how low CO2 interacts with nitrogen source and availability is even poorer. Here, we investigated growth, photosynthetic traits and nitrogen isotopic signature in Elymus canadensis, grown from seed at either current CO2concentrations (400 ppm) or values representative of the last glacial maximum (180-190 ppm), in combination with either high or low nitrogen supply, with the high nitrogen treatment supplied as nitrate, ammonium, or a mix of both.
Results/Conclusions
Low CO2 reduced total biomass by almost half, except when nitrogen was limited, where growth was unaffected by CO2. Plants grown with nitrate, ammonium, or at low nitrogen up-regulated photosynthesis at low CO2, presenting higher maximum electron transport rates (Jmax), but not maximum Rubisco carboxylation rates (Vcmax), than plants grown at ambient CO2. Growth at low CO2 also increased leaf nitrogen concentrations. Compared to plants from ambient CO2, low CO2 plants were enriched in 15N (1.2‰) under nitrate fertilization, but 0.8‰ depleted under low nitrogen availability. Our work demonstrates that the effects of low CO2 on plants varies depending on nitrogen source and availability; such responses should be considered when inferring data about plant responses to past climates, especially when carbon resources were most limiting.