Phosphorus deprivation effects on water relations of Nicotiana tabacum plant via reducing plasma membrane permeability

Plants grown in phosphorus-deprived solutions often exhibit disruption of water transport due to reduction in root hydraulic conductivity (Lp_r). To uncover the relationship between root Lp_r and water permeability coefficient (P_f) of plasma membrane and the role of aquaporins, we evaluated P_f of plasma membrane and also PIP-type aquaporin gene expression in tobacco (Nicotiana tabacum L.) plant roots after seven days P-deprivation. The results showed significant reduction in sap flow rate (J_v) and osmotic root hydraulic conductivity (L_pr-o) in P-deprived roots. These effects were reversed 24 h after P-resupplying. Interestingly, the P_f of root protoplasts was 57% lower in P-deprived plants compared with P-sufficient ones. The expression of NtPIP1;1 and NtPIP2;1 aquaporins did not change significantly in P-deprived plants compared with P-sufficient ones, but the copy number of NtAQP1 increased significantly in P-deprived plants. P-deprivation did not change Lpr-o significantly in antisense NtAQP1 plants. Taken together, these findings suggest that P-deprivation may play an important role in modulation of root hydraulic conductivity by affecting P_f in transcellular pathway of water flow across roots and aquaporins. Finally, we concluded that dominant water transport pathway under P-deprivation was transcellular one.