The nitrogen (N) and phosphorus (P) stoichiometry in organisms reflects environmental resources under homeostatic constraints. However, whether and how N and P stoichiometry in plant membrane lipids responds to N deficiency remains untested. This study examined membrane lipid N and P stoichiometry in leaves and roots of Arabidopsis thaliana and its close relative, Crucihimalaya himalaica, under N deficiency. C. himalaica, native to N-poor habitats, exhibits greater N-deficiency tolerance and less membrane lipid reduction than A. thaliana. In leaves, membrane lipid N stoichiometry reflects N supply, with stronger homeostasis in C. himalaica. Lipid P stoichiometry is coupled with N in both: as N supply declines, A. thaliana’s N:P ratio shifts toward 0.61, whereas C. himalaica’s remains stably fixed at 0.61. Roots show stronger N and N:P homeostasis than leaves, with lipid N:P ratios constant at 0.75. Both organs display large negative homeostasis coefficients (H), distinct from whole-plant patterns but indicating tight N:P regulation. These results suggest that membrane lipid N:P homeostasis correlates positively with N-deficiency tolerance, and fixed N:P ratios may represent a novel adaptive strategy, providing new insights into stoichiometric mechanisms for plant survival in extreme N-limited habitats.
Wang et al. (Thu,) studied this question.
Synapse has enriched 5 closely related papers on similar clinical questions. Consider them for comparative context: