拟南芥PIP1;1水通道蛋白在低硝酸盐可利用性条件下抑制侧根发育和硝酸盐吸收。

The Arabidopsis PIP1;1 Aquaporin Represses Lateral Root Development and Nitrate Uptake Under Low Nitrate Availability.

作者信息

Schley Thayssa Rabelo, Zhu Ting, Geist Birgit, Crabos Amandine, Dietrich Daniela, Alandes Regina A, Bennett Malcolm, Nacry Philippe, Schäffner Anton R

机构信息

Department of Environmental Sciences, Institute of Biochemical Plant Pathology, Helmholtz Zentrum München, Neuherberg, Germany.

IPSiM, CNRS, INRAE, Institut Agro, University of Montpellier, Montpellier, France.

出版信息

Plant Cell Environ. 2025 Feb;48(2):1500-1513. doi: 10.1111/pce.15222. Epub 2024 Oct 27.

DOI:10.1111/pce.15222

PMID:39462913

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11695785/

Abstract

Nitrate (NO ) deficiency decreases root water uptake and root hydraulic conductance. This adaptive response is correlated with reduced abundance and activity of plasma membrane intrinsic protein (PIP) aquaporins. We therefore screened changes in the root architecture of a complete set of Arabidopsis pip loss-of-function mutants grown under NO deficiency to systematically approach the impact of PIPs under these conditions. NO deprivation led to attenuated responses of specific pip single mutants compared to the strongly altered LR parameters of wild-type plants. In particular, pip1;1 exhibited a lower relative reduction in LR length and LR density, revealing that PIP1;1 represses LR development when NO is scarce. Indeed, PIP1;1 compromises root and shoot NO accumulation during early developmental stages. A fluorescent VENUS-PIP1;1 fusion revealed that PIP1;1 is specifically repressed in the pericycle, endodermis and at the flanks of emerging LRs upon NO deficiency. Thus, LR plasticity and NO uptake are affected by an interactive mechanism involving aquaporins (PIP1;1) and nitrate accumulation during seedling development under NO -deficient conditions.

摘要

硝酸盐（NO₃⁻）缺乏会降低根系对水分的吸收以及根的水力导度。这种适应性反应与质膜内在蛋白（PIP）水通道蛋白丰度和活性的降低相关。因此，我们筛选了在硝酸盐缺乏条件下生长的一整套拟南芥pip功能缺失突变体根系结构的变化，以便系统地研究这些条件下PIP的影响。与野生型植物侧根参数的显著改变相比，硝酸盐剥夺导致特定pip单突变体的反应减弱。特别是，pip1;1在侧根长度和侧根密度上的相对降低幅度较小，这表明在硝酸盐缺乏时，PIP1;1抑制侧根发育。事实上，PIP1;1在早期发育阶段会影响根和地上部硝酸盐的积累。一种荧光VENUS - PIP1;1融合蛋白显示，在硝酸盐缺乏时，PIP1;1在中柱鞘、内皮层以及新出现侧根的侧面被特异性抑制。因此，在硝酸盐缺乏条件下的幼苗发育过程中，侧根可塑性和硝酸盐吸收受到一种涉及水通道蛋白（PIP1;1）和硝酸盐积累的相互作用机制的影响。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/b009/11695785/75f90e51df0e/PCE-48-1500-g002.jpg

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拟南芥PIP1;1水通道蛋白在低硝酸盐可利用性条件下抑制侧根发育和硝酸盐吸收。

The Arabidopsis PIP1;1 Aquaporin Represses Lateral Root Development and Nitrate Uptake Under Low Nitrate Availability.

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