Impact of elevated atmospheric CO2 on nitrate reductase transcription and activity in leaves and roots of Plantago major

Abstract

Vegetative plants of an inbred line, A4, of Plantago major ssp. pleiosperma (L.) Pilger were grown at 350 μl I−1 or at elevated (700 μl I−1) CO2 in non‐limiting nutrient solution with nitrate. Both the relative growth rate (RGR) and the root to total plant weight ratio (RWR) were increased by elevated CO2. However, the stimulation of both RGR and RWR was transient and did not last longer than 8 days. To investigate the physiological mechanisms involved in this stimulation, related changes in C/N metabolism were examined. In the roots soluble sugar concentration increased during the transient period of RGR stimulation (up to 23%), as did the root respiration rate. Changes in nitrogen metabolism were also restricted to this period and consisted of an increase in (1) in vivo and in vitro root nitrate reductase (EC 1.6.6.1) activity. (2) in vitro leaf nitrate reductase activity, (3) leaf and root nitrate reductase mRNA and (4) reduced nitrogen concentration in the roots. The elevated CO2‐related signal for the increase in nitrate reductase transcript levels in the roots is discussed in terms of the increased availability of soluble sugars. The results suggest that the short‐term enhancement of root carbon and nitrogen metabolism may be responsible for the transient effect of elevated CO2 on whole plant RGR.