植物Na+/H+逆向转运蛋白研究进展

盐胁迫主要由Na 引起,过高的Na 浓度引起的离子毒害,渗透胁迫和K ／Na 比率的不平衡使植物新陈代谢异常,这是对大多数器官造成伤害的原因。植物抵御盐胁迫的主要方式是将细胞内过多的Na 从质膜向细胞外排放和将Na 在液泡中区隔化,这一过程是由Na ／H 逆向转运蛋白完成的。本文概述了植物中Na ／H 逆向转运蛋白的发现、特征、分子生物学方面的研究,以及Na ／H 逆向转运蛋白在植物耐盐性中的重要作用。     

植物Na+/H+反向转运蛋白的研究进展

盐胁迫是限制植物生长发育的主要因素之一,植物Na+/H+反向转运蛋白可通过将Na+逆向转运出细胞外或将Na+区隔化于液泡中来抵制环境中过高的Na+浓度.植物中Na+/H+反向转运蛋白存在于细胞质膜和液泡膜上,现在已得到多种编码这些Na+/H+反向转运蛋白的基因,对其结构功能特性进行了大量研究,并发现将这些基因转入非抗盐植物中过量表达可提高转基因植物的抗盐性.概述了Na+/H+反向转运蛋白及其编码基因的最新研究进展.     

Na+/H+ 逆向转运蛋白与植物耐盐性关系

Na+/H+ 逆向转运蛋白与植物的耐盐性有密切的关系。在高等植物体内,主要存在两种Na+/H+ 逆向转运蛋白,分别为位于细胞质膜上的逆向转运蛋白SOS1,以及存在于液泡膜上的AtNHX1。质膜Na+/H+ 逆向转运蛋白主要负责Na+ 的外排,液泡膜Na+/H+ 逆向转运蛋白主要负责把Na+ 区隔化入液泡。过量表达质膜Na+/H+ 逆向转运蛋白SOS1或液泡膜Na+/H+ 逆向转运蛋白AtNHX1能够明显提高植物的耐盐性。本文对植物中Na+/H+ 逆向转运蛋白及其与植物耐盐性之间的关系研究最新进展作一概述。     

北美海蓬子SbNHX1基因耐盐性及功能结构域分析

对从北美海蓬子中分离的Na+/H+逆向转运蛋白基因SbNHX1进行了耐盐性及功能结构域分析.利用套叠PCR技术去除SbNHX1基因C末端162个核苷酸,得到SbNHX1-C基因,然后将SbNHX1、SbNHX1-C和拟南芥Na+/H+ 逆向转运蛋白基因AtNHX1分别插入pET22b(+)表达载体,转化大肠杆菌B菌株,进行各种金属盐离子胁迫分析.结果表明,北美海蓬子Na+/H+ 逆向转运蛋白基因SbNHX1只对Na+ 、K+离子有抗性,且耐盐性强于拟南芥Na+/H+ 逆向转运蛋白基因AtNHX1.缺失C末端的SbNHX1-C基因对Na+、K+离子胁迫无抗性,说明北美海蓬子Na+/H+ 逆向转运蛋白基因SbNHX1的耐盐作用与该基因C末端1 353 bp至1 514 bp的序列密切相关.     

植物Na~+/H~+逆向转运蛋白功能及调控的研究进展

Na+/H+逆向转运蛋白是一种调控Na+、H+跨膜转运的膜蛋白,对细胞内Na+的平衡和pH值的调控等活动具有重要作用。该文主要对近年来Na+/H+逆向转运蛋白功能及其调控的研究进展进行概述,着重讨论其在调控离子稳态平衡,液泡pH值大小与花色显现,以及在影响细胞,器官(叶片)发育,盐胁迫信号转导等方面的可能作用。     

NaCl胁迫对盐芥质膜和液泡膜ATPase活性的影响

以盐生植物盐芥和中生植物拟南芥幼苗为材料,研究了盐胁迫对它们叶片和根质膜、液泡膜H+-ATPase、Ca2+-ATPases和K+-ATPase活性以及H+-ATPase、Na+/H+ 逆向转运蛋白表达的影响.结果显示:在NaCl胁迫下,盐芥叶片和根质膜的H+-ATPase活性分别比对照显著升高41%～212%和35%～53%,液泡膜的H+-ATPase分别显著升高281%～373%和4%～38%,而拟南芥却比相应对照都显著降低;相同盐浓度胁迫下,盐芥叶片的H+-ATPase活性比根部高4～8倍,盐芥根也远高于拟南芥.在NaCl胁迫下,盐芥叶片和根的液泡膜H+-ATPase蛋白质β亚基含量变化与其酶活性变化趋势一致,质膜Na+/H+ 逆向转运蛋白的表达量与Na+含量变化趋势一致.盐胁迫下盐芥根中Ca2+-ATPases和K+-ATPase活性的增加与根中Ca2+和K+含量呈显著正相关.研究发现,在盐胁迫条件下,盐芥能有效增强H+-ATPase蛋白和Na+/H+逆向转运蛋白表达,显著提高其根系与叶片质膜和液泡膜的H+-ATPase、Ca2+-ATPase和K+-ATPase活性,维持细胞质中较高的Ca2+和K+水平,从而缓解盐胁迫的伤害,增强耐盐性.     

新疆盐生植物车前PmNHX1基因的克隆及生物信息学分析

盐分对植物的伤害主要是Na+引起的,而Na+/H+逆向运输蛋白催化Na+/H+逆向跨膜运输,从而使质膜上Na+运出细胞和液泡膜中的Na+区隔化。这是植物尤其是盐生植物抵御盐胁迫的主要方式之一。根据不同植物编码液泡膜逆向运输蛋白基因的保守序列,设计简并引物,采用RT-PCR和RACE技术,首次从新疆盐生植物车前（Plantago maritima）中克隆到Na+/H+逆向运输蛋白基因的cDNA全长2464 bp,命名为PmNHX1(GenBank登录号：EU233808),该基因编码区长为1 662bp,编码553个氨基酸,理论分子量为61.16kDa,等电点为7.22。数据分析结果显示,该蛋白质主要定位于液泡膜上,由12个序列保守的跨膜结构域组成,其中TM3跨膜结构域上存在“LFFIYLLPPI”-氨氯吡嗪咪结合域,并且该位点与Na+有竞争作用。PmNHX1逆向运输蛋白与其他植物逆向运输蛋白的氨基酸同源性为64％~80％。通过生物信息学方法对其理化性质和功能分析进行预测,这为进一步研究转耐盐基因PmNHX1及其功能鉴定奠定了基础。     

高等植物Na+ 吸收、转运及细胞内Na+ 稳态平衡研究进展

盐胁迫是影响农业生产的重要环境因素之一。本文对植物Na+吸收的机制和途径、Na+在植物体内的长距离转运以及细胞内Na+稳态平衡的研究进展进行了概述。参与植物Na+吸收与转运的蛋白和通道可能包括HKT、LCT1、AKT和NSCC等。其中, HKT是植物体内普遍存在的一类转运蛋白, 能够介导Na+的吸收, 其结构中的带电氨基酸残基对于其离子选择性有着非常明显的影响。LCT1是从小麦中发现的一类能够介导低亲和性阳离子吸收的蛋白, 然而在典型的土壤Ca2+浓度下LCT1并不能发挥吸收Na+的功能。AKT家族的成员在高盐环境下可能也参与了Na+的吸收。目前虽然还没有克隆到编码NSCC蛋白的基因, 但是NSCC作为植物吸收Na+的主要途径的观点已被广泛接受。SOS1和HKT参与了Na+在根部与植株地上部的长距离转运过程, 它们在木质部和韧皮部的Na+装载和卸载中发挥重要作用, 从而影响植物的抗盐性。另外, 由质膜Na+/H+逆向转运蛋白SOS1、蛋白激酶SOS2以及Ca2+结合蛋白SOS3组成的SOS复合体对细胞的Na+稳态具有重要的调节作用, 单子叶和双子叶植物之间的这种调节机制在结构和功能上具有保守性。SOS复合体与其它位于质膜或液泡膜上的Na+/H+逆向转运蛋白以及H+泵一起调节着细胞的Na+稳态。     

细菌Na+/H+逆向转运蛋白的研究进展

Na+/H+逆向转运蛋白在维持细胞内pH稳态、Na+离子动态平衡和调控细胞体积方面发挥着重要作用。目前,细菌中许多参与高盐或高碱性环境压力应答的Na+/H+逆向转运蛋白得到了鉴定和功能阐释。继续挖掘高效的Na+/H+逆向转运蛋白,深入探究Na+/H+逆向转运蛋白的分子机理,将为工业菌株或农作物的改良提供新的研究思路。本文以4种模式菌株为例,简要概述细菌Na+/H+逆向转运蛋白的种类和特征,同时对其结构和功能等方面也进行探讨。     

花烟草NaNHX1基因的克隆及其在非生物胁迫下的表达模式

植物NHX家族基因,在植物的生长发育以及生物与非生物胁迫的应答反应中发挥着十分重要的作用。为了探究花烟草Na+/H+逆向转运蛋白的生理功能,为花烟草耐盐分子机制的研究提供参考。采用同源克隆的方法进行基因克隆,对花烟草进行非生物胁迫,并运用qPCR的方法进行基因表达模式分析。结果表明,从花烟草(Nicotiana alata)中克隆了一个属于Na+/H+逆向转运蛋白家族的基因NaNHX1。该基因的开放阅读框全长为1 599 bp,编码了532个氨基酸残基。生物信息学分析结果表明,该基因编码的蛋白分子量为58.4 kD,等电点为5.66;具有Na+/H+逆向转运蛋白家族典型的保守结构域NhaP2;该蛋白属于疏水性蛋白,包含10个跨膜区。NaNHX1基因主要定位于细胞质膜,并含有多个磷酸化位点。同源性分析的结果显示,NaNHX1基因与美花烟草(Nicotiana sylvestris)、茸毛烟草(Nicotiana tomentosiformis)以及番茄(Solanum lycoperisicum)NHX基因的亲缘关系最近,而与拟南芥的NHX基因同源性最低。NaNHX1基因的表达具有组织表达特异性,花中表达量最高,茎中次之,根和叶中表达量较低。在高盐、干旱、低温、ABA、低钾及H2O2等非生物胁迫下,NaNHX1的表达呈现3种不同的表达模式。其中,对高盐及低钾胁迫的响应强烈。本研究的结果表明,NaNHX1基因属于Na+/H+逆向转运蛋白家族,可能参与了花烟草高盐和低钾胁迫,以及其它非生物胁迫响应在内的众多生理过程。     

Properties of two different Na+/H+ antiport systems in alkaliphilic Bacillus sp. strain C-125.

Na+/H+ antiport was studied in alkaliphilic Bacillus sp. strain C-125, its alkali-sensitive mutant 38154, and a transformant (pALK2) with recovered alkaliphily. The transformed was able to maintain an intracellular pH (pHin) that was lower than that of external milieu and contained an electrogenic Na+/H+ antiporter driven only by delta psi (membrane potential, interior negative). The activity of this delta psi-dependent Na+/H+ antiporter was highly dependent on pHin, increasing with increasing pHin, and was found only in cells grown at alkaline pH. On the other hand, the alkali-sensitive mutant, which had lost the ability to grow above pH 9.5, lacked the delta psi-dependent Na+/H+ antiporter and showed defective regulation of pHin at the alkaline pH range. However, this mutant, like the parent strain, still required sodium ions for growth and for an amino acid transport system. Moreover, another Na+/H+ antiporter, driven by the imposed delta pH (pHin > extracellular pHout), was active in this mutant strain, showing that the previously reported delta pH-dependent antiport activity is probably separate from delta psi-dependent antiporter activity. The delta pH-dependent Na+/H+ antiporter was found in cells grown at either pH 7 or pH 9. This latter antiporter was reconstituted into liposomes by using a dilution method. When a transmembrane pH gradient was applied, downhill sodium efflux was accelerated, showing that the antiporter can be reconstituted into liposomes and still retain its activity.     

The Na+:H+ antiport in cancer

Several carriers mediate ionic fluxes across the plasma membrane in a variety of mammalian cell types. Intracellular proton concentration is regulated by virtue of the operation of at least two distinct systems: a stilbene-sensitive, Na+- dependent HCO3-/Cl- exchange system, and an amiloride-sensitive Na+/H+ antiporter. The contribution of these two transporters to the modulation of intracellular pH in response to either extracellular pH variations or cell stimulation by growth factors and tumor promoters has been studied in several cell lines, including fibroblast mutants lacking Na+/H+ antiport activity. The attainment of a permissive intracellular pH value is critical to the development of the mitogenic response elicited by growth factors. Kinetic studies have revealed particular features of the Na+/H+ antiporter that explain its function in the early sequence of biochemical events leading to DNA replication. The detailed investigation of the mechanisms by which protons and other ions might regulate cell proliferation has important implications for the understanding of the role of pH microenvironment in carcinogenesis, tumor development and chemotherapy.     

Characterization of a multigene-encoded sodium/hydrogen antiporter (sha) from Pseudomonas aeruginosa: its involvement in pathogenesis

Sha (also known as Mrp/Mnh/Pha) is a Na+/H+ antiporter encoded by a cluster of six or seven genes that probably form a multisubunit transport complex. The Sha system is important for the homeostasis of H+, Na+, and other monovalent cations and plays a critical role in various functions, including alkaliphily, sporulation, and symbiosis. Here, we characterized the sha homologue genes from the opportunistic pathogen Pseudomonas aeruginosa, which exist as a cluster of six genes (PA1054 to PA1059). The gene cluster PA1054 to PA1059, but not the cluster with a deletion of PA1054, complemented a growth defect in the presence of 0.2 M NaCl and a defect in Na+/H+ antiport activity of the Escherichia coli TO114 mutant lacking the three major Na+/H+ antiporters, indicating that genes PA1054 to PA1059 are responsible for Na+/H+ antiport activity. We disrupted PA1054 (a shaA homologue gene) and determined its effect on Na+ tolerance during growth, Na+ efflux, and pathogenicity in mice. Disruption of PA1054 resulted in severe Na+ sensitivity during growth and decreased Na+ efflux activity. In mice, the deletion mutant of PA1054 also exhibited an attenuated virulence in systemic, pulmonary, and urinary tract infections and also a decrease in colonization of the infected organs. From these results, we conclude that the genes PA1054 to PA1059 encode a Na+/H+ antiporter that is largely responsible for Na+ extrusion in P. aeruginosa and has a role in the infection of the pathogen. We propose to designate PA1054 to PA1059 as the sha (sodium hydrogen antiporter) genes, shaABCDEFG.     

Deletion of ant in Escherichia coli reveals its function in adaptation to high salinity and an alternative Na+/H+ antiporter system(s)

We have deleted the chromosomal ant gene from Escherichia coli by substitution with the kan gene, which encodes kanamycin resistance. The delta ant strains obtained cannot adapt to high sodium concentrations (700 mM, pH 6.8), which do not affect the wild type. The Na+ sensitivity of delta ant is pH dependent, increasing at alkaline pH. Thus at pH 8.5, 100 mM NaCl retard growth of delta ant with no effect on the wild type. The delta ant strains also cannot challenge the toxic effects of Li+ ions, a substrate of the Na+/H+ antiporter system. However, growth of these strains is normal on carbon sources which require Na+ ions for transport and growth. Moreover, antiporter activity, as measured in everted membrane vesicles, is not significantly impaired. A detailed analysis of the remaining antiporter activity in a delta ant strain reveals kinetic properties which differ from those displayed by the ant protein: (a) Km for transport of Li+ ions is about 15 times higher and (b) the activity is practically independent of intracellular pH. Our results demonstrate the presence of an alternative Na+/H+ antiporter(s) in E. coli, additional to ant system.     

Vacuolar cation/H+ exchange, ion homeostasis, and leaf development are altered in a T-DNA insertional mutant of AtNHX1, the Arabidopsis vacuolar Na+/H+ antiporter

The function of vacuolar Na+/H+ antiporter(s) in plants has been studied primarily in the context of salinity tolerance. By facilitating the accumulation of Na+ away from the cytosol, plant cells can avert ion toxicity and also utilize vacuolar Na+ as osmoticum to maintain turgor. As many genes encoding these antiporters have been cloned from salt-sensitive plants, it is likely that they function in some capacity other than salinity tolerance. The wide expression pattern of Arabidopsis thaliana sodium proton exchanger 1 (AtNHX1) in this study supports this hypothesis. Here, we report the isolation of a T-DNA insertional mutant of AtNHX1, a vacuolar Na+/H+ antiporter in Arabidopsis. Vacuoles isolated from leaves of the nhx1 plants had a much lower Na+/H+ and K+/H+ exchange activity. nhx1 plants also showed an altered leaf development, with reduction in the frequency of large epidermal cells and a reduction in overall leaf area compared to wild-type plants. The overexpression of AtNHX1 in the nhx1 background complemented these phenotypes. In the presence of NaCl, nhx1 seedling establishment was impaired. These results place AtNHX1 as the dominant K+ and Na+/H+ antiporter in leaf vacuoles in Arabidopsis and also suggest that its contribution to ion homeostasis is important for not only salinity tolerance but development as well.     

Production of<Emphasis Type="Italic">Yarrowia lipolytica</Emphasis> Nha2 Na<Superscript>+</Superscript>/H<Superscript>+</Superscript> antiporter improves the salt tolerance of<Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

Yarrowia lipolytica plasma-membrane Na+/H+ antiporter, encoded by the YlNHA2 gene, is a very efficient exporter of surplus sodium from the cytosol. Its heterologous expression in Saccharomyces cerevisiae wild-type laboratory strains increased their sodium tolerance more efficiently than the expression of ZrSod2-22 antiporter from the osmotolerant yeast Zygosaccharomvces rouxii.     

An Na+/H+ antiporter gene from wheat plays an important role in stress tolerance

A vacuole Na+/H+ antiporter gene TaNHX2 was obtained by screening the wheat cDNA library and by the 5'-RACE method. The expression of TaNHX2 was induced in roots and leaves by treatment with NaCl, polyethylene glycol (PEG), cold and abscisic acid (ABA). When expressed in a yeast mutant (deltanhx1), TaNHX2 suppressed the salt sensitivity of the mutant,which was deficient in vacuolar Na+/H+ antiporter, and caused partial recovery of growth of delta nhx1 in NaCl and LiCl media. The survival rate of yeast cells was improved by overexpressing the TaNHX2 gene under NaCl, KCl, sorbitol and freezing stresses when compared with the control. The results imply that TaNHX2 might play an important role in salt and osmotic stress tolerance in plant cells.     

Na+/H+逆向转运蛋白和植物耐盐性

Na^ /H^ 逆向转运蛋白对植物耐盐起着重要作用,它利用质膜H^ -ATPase或液泡膜H^ -ATPase及PPiase泵H^ 产生的驱动力把Na^ 排出细胞或在液泡中区隔化以消除Na^ 的毒害。主要讨论植物中Na^ /H^ 逆向转运蛋白研究在分子水平的最新进展。