Plant response to nitrate starvation is determined by N storage capacity matched by nitrate uptake capacity in two Arabidopsis genotypes

In a low-input agricultural context, plants facing temporalnutrient deficiencies need to be efficient. By comparing theeffects of NO-starvation in two lines of Arabidopsis thaliana (RIL282 and 432 from the Bay-0xShahdarapopulation), this study aimed to screen the physiological mechanismsallowing one genotype to withstand NO-deprivation better than another and to rate the relative importance of processessuch as nitrate uptake, storage, and recycling. These two lines,chosen because of their contrasted shoot N contents for identicalshoot biomass under N-replete conditions, underwent a 10 d nitratestarvation after 28 d of culture at 5 mM NO. It was demonstrated that line 432 coped betterwith NO-starvation, producing higher shoot and root biomass and sustaining maximal growthfor a longer time. However, both lines exhibited similar featuresunder NO-starvation conditions. In particular, the nitrate pool underwent the same drastic andearly depletion, whereas the protein pool was increased to asimilar extent. Nitrate remobilization rate was identical too.It was proportional to nitrate content in both shoots and roots,but it was higher in roots. One difference emerged: line 432had a higher nitrate content at the beginning of the starvationphase. This suggests that to overcome NO-starvation, line 432 did not directly rely on theN pool composition, nor on nitrate remobilization efficiency,but on higher nitrate storage capacities prior to NO-starvation. Moreover, the higher resistanceof 432 corresponded to a higher nitrate uptake capacity anda 2–9-fold higher expression of AtNRT1.1, AtNRT2.1, andAtNRT2.4 genes, suggesting that the corresponding nitrate transportersmay be preferentially involved under fluctuating N supply conditions. Key words: Arabidopsis thaliana, genetic variability, N partitioning, N recycling, N use efficiency, nitrate deficiency, nitrate remobilization rate, nitrate transporter gene expression, nitrogen reserves, plant development Received 12 July 2007; Revised 21 November 2007 Accepted 17 December 2007