Elevated [CO2] and growth temperature have a small positive effect on photosynthetic thermotolerance of Pinus taeda seedlings

Key message

Growth temperature had little effect on the response of net photosynthesis to high temperatures (up to 47 °C). On the other hand, elevated [CO ₂ ] increased net photosynthesis at high temperatures.

Abstract

We investigated whether Pinus taeda seedlings grown under elevated CO₂-concentration ([CO₂]) and temperature would be able to maintain positive net photosynthesis (A _net) longer than seedlings grown under ambient conditions when exposed to temperatures up to 47 °C. Additionally, we investigated whether a locally applied temperature increase would yield the same short-term gas exchange response to temperatures up to 47 °C as a naturally occurring latitudinal temperature increase of equal magnitude. Growth conditions were applied for 7 months (February to August) in treatment chambers constructed at two sites in the native range of P. taeda in the southern US. The sites were located 300 km apart along a north–south axis with a natural temperature difference of 2.1 °C. Seedlings were grown under ambient temperature and [CO₂] conditions at both sites. At the northern site, we also applied a temperature increase of 2 °C (T _E), ensuring that this treatment equalled the mean temperature at the southern site. Additionally, at the northern site, we applied a treatment of elevated [CO₂] (C _E). Gas exchange was measured on all plants in walk-in environmentally controlled chambers. Under C _E, there was no difference in A _net of seedlings grown in ambient or ambient +2 °C temperatures at any measurement temperature, while differences were present under ambient [CO₂]. Furthermore, A _net was higher under C _E than under ambient [CO₂]. At 47 °C, A _net was negative in all seedlings except those in the C _E and ambient temperature treatment combination. Seedlings at the northern site in the T _E treatment showed no significant differences in A _net compared with seedlings grown at ambient temperature at the southern site, indicating that the plants responded equally to a manipulated temperature increase and a latitudinal increase in temperature. Our results suggest that elevated [CO₂] increases photosynthetic thermotolerance at high temperature (>41 °C), but this effect diminishes as temperature increases further. Temperature manipulations could provide accurate information on the effect of latitudinal differences in temperature on leaf gas exchange of P. taeda.