盐胁迫对4树种叶片中K^＋和Na^＋的影响及其耐盐能力的评价

通过盆栽试验,对我国南方银杏（Ginkgo biloba L.)、侧柏[Patycladus orentalis(L.)Franco]、火炬松（Pinus taeda L.)和剌槐(Robinia Pseudoacacia L.)4造林树种苗木叶片中K^ 、N^ 浓度浓度和N^ ／K^ 比进行测定,盐处理水平为0.0％（CK）、0.1%、0.3%和0.5％。随着盐浓度的提高,各树种叶片中Na^ 浓度和N^ ／K^ 有逐渐升高的趋势,但K^ 浓度变化较小;随着盐胁迫时间的推移,各树种叶片中Na^ 、K^ 浓度和Na^ /K^ 比都没有明显的变化规律。方差分析和多层比较表明,侧柏、火炬松和剌槐叶片中Na^ 、K^ 浓度和N^ ／K^ 比在4组处理间的差异均达显著或极显著水平。4树种中剌槐和侧柏的耐盐能力最强,银杏次之,火炬松最弱。     

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。     

拟南芥液泡膜Na+/H+逆向转运蛋白研究进展

盐分是植物生长发育的主要限制因素之一,而离子在胞内区室之间的选择性运动对提高植物耐盐性是至关重要的。来自于拟南芥(Arabidopsis thaliana)的AtNHX1基因可编码Na /H 逆向转运蛋白,而Na /H 逆向转运蛋白AtNHX1可将细胞质中多余的Na 排进液泡来消除Na 的毒害,维持细胞的渗透平衡,提高植物的耐盐性。简要综述了AtNHX1基因及Na /H 逆向转运蛋白AtNHX1的特征,AtNHX1的耐盐机制以及植物耐盐基因工程改良等方面的研究进展。     

The microfilament cytoskeleton plays a vital role in salt and osmotic stress tolerance in Arabidopsis

Although recent studies have suggested that the microfilament (MF) cytoskeleton of plant cells participates in the response to salt stress, it remains unclear as to whether the MF cytoskeleton actually plays an active role in a plant's ability to withstand salt stress. In the present study, we report for the first time the role of MFs in salt tolerance of Arabidopsis thaliana . Our experiments revealed that Arabidopsis seedlings treated with 150 m m NaCl maintained MF assembly and bundle formation, whereas treatment with 250 m m NaCl initially induced MF assembly but subsequently caused MF disassembly. A corresponding change in the fluorescence intensity of MFs was also observed; that is, a sustained rise in fluorescence intensity in seedlings exposed to 150 m m NaCl and an initial rise and subsequent fall in seedlings exposed to 250 m m NaCl. These results suggest that MF assembly and bundles are induced early after salt stress treatment, while MF polymerization disappears after high salt stress. Facilitation of MF assembly with phalloidin rescued wild-type seedlings from death, whereas blocking MFs assembly with latrunculin A and cytochalasin D resulted in few survivors under salt stress. Pre-treatment of seedlings with phalloidin also clearly increased plant ability to withstand salt stress. MF assembly increased survival of Arabidopsis salt-sensitive sos2 mutants under salt stress and rescued defective sos2 mutants. Polymerization of MFs and its role in promoting survival was also found in plants exposed to osmotic stress. These findings suggest that the MF cytoskeleton participates and plays a vital role in responses to salt and osmotic stress in Arabidopsis .     

质膜Na^＋／H^＋逆向转运蛋白与植物耐盐性

土壤盐碱化是造成农作物减产的主要原因之一。质膜Na^＋／H^＋逆向转运蛋白能够介导植物根部Na^＋的外排和体内Na^＋的长距离运输, 并能够调控细胞K＋的稳态平衡及细胞内pH值和Ca^2＋的转运, 因此其在植物耐盐性方面具有重要作用。该文概述了植物质膜Na^＋／H^＋逆向转运蛋白的分子结构、功能、表达调控及其与植物耐盐性关系等方面的研究进展, 并对今后有关该蛋白的主要研究方向作了分析和展望。     

新疆盐生植物耐盐基因NHX转化甘蓝型油菜及其耐盐性的初步研究

以甘蓝型油菜带柄子叶为转化受体,通过根癌农杆菌EHA105(Agrobacterium tumefaciens)介导将盐角草(Salicornia)的Na /H 反向运输体基因NHX导入新疆主栽油菜1khp11品系,获得了抗卡那霉素的再生植株,并对影响遗传转化的一些关键因素进行了研究。实验结果表明:带柄子叶在含有2,4-D的培养基上经过2d短时间的预培养后在菌液浓度OD600为0.3时在28℃摇床浸染15min时卡那抗性绿苗率可达10%￣12%;经过抗性植株的PCR及RT-PCR检测证明外源基因已整合到油菜基因组中,并通过表型实验证实由于外源基因的导入提高了植株的耐盐能力。     

A novel calmodulin-binding protein functions as a negative regulator of osmotic stress tolerance in Arabidopsis thaliana seedlings

A clone for a novel Arabidopsisthaliana calmodulin (CaM)-binding protein of 25 kDa (AtCaMBP25) has been isolated by using a radiolabelled CaM probe to screen a cDNA expression library derived from A. thaliana cell suspension cultures challenged with osmotic stress. The deduced amino acid sequence of AtCaMBP25 contains putative nuclear localization sequences and shares significant degree of similarity with hypothetical plant proteins only. Fusion of the AtCaMBP25 coding sequence to reporter genes targets the hybrid protein to the nucleus. Bacterially expressed AtCaMBP25 binds, in a calcium-dependent manner, to a canonical CaM but not to a less conserved isoform of the calcium sensor. AtCaMBP25 is encoded by a single-copy gene, whose expression is induced in Arabidopsis seedlings exposed to dehydration, low temperature or high salinity. Transgenic plants overexpressing AtCaMBP25 exhibits an increased sensitivity to both ionic (NaCl) and non-ionic (mannitol) osmotic stress during seed germination and seedling growth. By contrast, transgenic lines expressing antisense AtCaMBP25 are significantly more tolerant to mannitol and NaCl stresses than the wild type. Thus, the AtCaMBP25 gene functions as a negative effector of osmotic stress tolerance and likely participates in stress signal transduction pathways.     

Separate signal pathways regulate the expression of a low-temperature-induced gene in Arabidopsis thaliana (L.) Heynh.

A cDNA clone corresponding to a novel low-temperature-induced Arabidopsis thaliana gene, named lti140, was employed for studies of the environmental signals and the signal pathways involved in cold-induced gene expression. The single-copy lti140 gene encodes a 140 kDa cold acclimation-related polypeptide. The lti140 mRNA accumulates rapidly in both leaves and roots when plants are subject to low temperature or water stress or are treated with the plant hormone abscisic acid (ABA), but not by heat-shock treatment. The low-temperature induction of lti140 is not mediated by ABA, as shown by normal induction of the lti140 mRNA in both ABA-deficient and ABA-insensitive mutants and after treatment with the ABA biosynthesis inhibitor fluridone. The effects of low temperature and exogenously added ABA are not cumulative suggesting that these two pathways converge. The induction by ABA is abolished in the ABA-insensitive mutant abi-1 indicating that the abi-1 mutation defines a component in the ABA response pathway. Accumulation of the lti140 mRNA in plants exposed to water stress was somewhat reduced by treatment with fluridone and in the ABA-insensitive mutant abi-1 suggesting that the water stress induction of lti140 could be partly mediated by ABA. It is concluded that three separate but converging signal pathways regulate the expression of the lti140 gene.     

A tomato cDNA inducible by salt stress and abscisic acid: nucleotide sequence and expression pattern

We have characterized a new tomato cDNA, TAS14, inducible by salt stress and abscisic acid (ABA). Its nucleotide sequence predicts an open reading frame coding for a highly hydrophilic and glycine-rich (23.8%) protein of 130 amino acids. Southern blot analysis of tomato DNA suggests that there is one TAS14 structural gene per haploid genome. TAS14 mRNA accumulates in tomato seedlings upon treatment with NaCl, ABA or mannitol. It is also induced in roots, stems and leaves of hydroponically grown tomato plants treated with NaCl or ABA. TAS14 mRNA is not induced by other stress conditions such as cold and wounding. The sequence of the predicted TAS14 protein shows four structural domains similar to the rice RAB21, cotton LEA D11 and barley and maize dehydrin genes.     

The structure of the Arabidopsis thaliana SOS3: molecular mechanism of sensing calcium for salt stress response

The Arabidopsis thaliana SOS3 gene encodes a calcium sensor that is required for plant salt tolerance. The SOS3 protein binds to and activates the self-inhibited SOS2 protein kinase, which mediates the expression and activities of various transporters important for ion homeostasis under salt stress. SOS3 belongs to a unique family of calcium-binding proteins that contain two pairs of EF hand motifs with four putative metal-binding sites. We report the crystal structure of a dimeric SOS3 protein in complex with calcium, and with calcium and manganese. Analytical ultracentrifugation experiments and circular dichroism measurements show that calcium binding is responsible for the dimerization of SOS3. This leads to a change in the global shape and surface properties of the protein that may be sufficient to transmit the Ca(2+) signal elicited during salt stress.     

Na+/H+ antiporters,molecular devices that couple the Na+ and H+ circulation in cells

Na⁺/H⁺ antiporters are universal devices involved in the Na⁺ and H⁺ circulation of both eukaroyotes and prokaryotes, thus playing an essential role in the pH and Na⁺ homeostasis of cells. This review focuses on the major impact of the application of molecular biology tools in the study of the antiporters. These tools permit the verification of the role of the antiporters and provide insights into their unique biology. A novel signal transduction to Na⁺ involvingnhaR, a positive regulator, controls the expression ofnhaA inE. coli. A pH sensor regulates the activity of Na⁺/H⁺ antiporters, both in eukaryotes and prokaryotes. A most intricate signal transduction to pH involving phosphorylation steps controls the activity ofnhel in higher mammals. The identification of Histidine 226 in the pH sensor of NhaA is a step forward towards the understanding of the pH regulation of these proteins.