植物NIP水通道蛋白的结构、功能和调控研究进展  

作　　者：陈瑶 尤垂淮[3] 陈燕玲 孙婷婷[1] 赵振南 黄廷辰 阙友雄[1] 苏亚春[1,2] Yao Chen;Chuihuai You;Yanling Chen;Tingting Sun;Zhennan Zhao;Tingchen Huang;Youxiong Que;Yachun Su(Key Laboratory of Sugarcane Biology and Genetic Breeding,Ministry of Agriculture and Rural Affairs,Fujian Agriculture and Forestry University,Fuzhou 350002,China;Key Laboratory of Ministry of Education for Genetics,Breeding and Multiple Utilization of Crops,Fujian Agriculture and Forestry University,Fuzhou 350002,China;College of Life Sciences,Fujian Agriculture and Forestry University,Fuzhou 350002,China)

机构地区：[1]福建农林大学农业农村部福建甘蔗生物学与遗传育种重点实验室,福州350002 [2]福建农林大学教育部作物遗传育种与综合利用重点实验室,福州350002 [3]福建农林大学生命科学学院,福州350002

出　　处：《科学通报》2023年第14期1799-1813,共15页Chinese Science Bulletin

基　　金：中央引导地方科技发展专项(2022L3086);福建省自然科学基金(2020J01591);国家农业产业技术体系项目(CARS-17)资助。

摘　　要：类NOD26膜内在蛋白(nodulin 26-like intrinsic proteins,NIPs)又名根瘤素26-like内在蛋白、类根瘤菌26膜内在蛋白、类Nodulin26内在蛋白,是水通道蛋白(aquaporin protein,AQP)家族的亚家族之一.NIP由AqpN基因进化而来,广泛存在于植物体中,其对底物选择具有特异性,根据选择性过滤器(aromatic/arginine,ar/R区)的不同分为3个亚族.NIPs参与水分、尿素、甘油、硼、砷、硅等物质的吸收和转运,在维持植物生长过程中的水分平衡和渗透压及抵御逆境胁迫等方面发挥重要作用.近年来,有关NIPs对植物生长发育和逆境调控功能的研究越来越多.本文系统阐述了植物NIP家族的起源与进化、结构与分类、生物学功能及调控机制,并对目前NIP研究中存在的问题和未来的研究方向进行了讨论,为深入探究NIP家族在不同植物中的作用模式和遗传改良应用提供参考资料.Aquaporin protein(AQP)family,as a“carrier”of water,micronutrients,and solute macromolecules in plants,plays an important role in material transport.Unlike other members of the AQP family,nodulin 26-like intrinsic proteins(NIPs)mainly penetrate small molecules,such as water,glycerin,silicic acid,boric acid,and urea.In addition,it is involved in plant cell osmoregulation,seed germination,lateral root production,leaf and flower growth and development,and response to biotic and abiotic(drought,chilling,salinity,metalloid toxicity,hypoxia,etc.)stresses.So far,structures of the NIP family have been partially reported.The NIPs can be divided into three classes based on the pore size of the ar/R selective filter,which determines the absorption and transportation of different substrates.Moreover,the NIPs contain two NPA motifs,which are located in loop B and loop E and have a typical ring-like hourglass structure.Therefore,different structures of the NIP subfamily play different roles in plant membrane solute transport and water balance.The NIP gene family has been identified in Arabidopsis thaliana,Oryza sativa,and other plants,whose function needs to be achieved through a variety of signaling pathways and the synergistic effect of physiological processes.In recent years,more and more reports have shown how the NIP gene participates in regulating gene expression levels under various stress conditions and interacts with a variety of stress proteins to jointly regulate the water and osmotic balance of plants and improve plant resistance and adaptability.The co-expression of NIPs with AtBOR1,AtNodGS,and AtACR3 genes can enhance the transport of solute and aquaporin.Besides,the interaction between NIP and 14-3-3f proteins can stabilize cell structure and substance synthesis in vivo,thus enhancing plant cold resistance.Interestingly,NIP is regulated by WRKY transcription factors and plays an active role in the regulation and distribution of metalloid elements in plants.In addition,the NIP genes are involved in the respons

关 键 词：NIP水通道蛋白 结构 生物学功能 逆境胁迫 调控机制 

分 类 号：Q946.1[生物学—植物学]