低磷和铝毒胁迫条件下菜豆有机酸的分泌与累积

以水培方式研究了低磷、铝毒胁迫条件下,不同菜豆基因型根系有机酸的分泌及其在植穆不同部位的累积,结果表明,低磷,铝毒胁迫诱导菜豆有机酸的分泌与累积存在显著的基因差异。低磷、铝毒胁迫诱导菜豆主要分泌柠檬酸、酒石酸和乙酸,其中,50μmol/LAl^3 诱导柠檬酸分泌量最高;低磷（小于20μmol/LH2PO4^－）胁迫诱导柠榨菜酸分泌量显著高于高磷处理,但低磷处理之间差异不明显,铝毒胁迫诱导菜豆有机酸的分泌与累积显著高于低磷胁迫处理,低磷,铝毒胁迫植株不同部位有机酸的含量为叶片大小根系,低磷,铝毒胁迫时,G842菜豆型柠檬酸有机酸分泌总量显著高于273、AFR和ZPV,其干重和磷吸收明明显于大G273,AFR和ZPV,且铝吸收量小于G273,AFR和ZPV,说明,G482菜豆基因型对低磷,铝毒的适应能力强于G273,AFR和ZPV基因型,菜豆有机酸,,尤其柠檬酸的分泌是其适应低磷、铝毒胁迫的重要生理反应。     

植物耐铝的生物化学与分子机理

某些耐铝植物在铝胁迫下分泌有机酸被认为是一个重要的抗性机制.从根系分泌出来的有机酸能与根际的Al3 结合,形成无毒性的螯合物,从而减轻了铝对根系的毒害.但是,铝诱导有机酸分泌的中间环节及调节机制至今仍不清楚.一些证据表明,铝能激活根尖细胞质膜内的阴离子通道,因而可以调节有机酸的分泌.近年来,人们开始注意一些信号分子如蛋白激酶、水杨酸等介导铝诱导有机酸的分泌,已经获得一些成果.同时,铝胁迫基因的分离和鉴定也为人们从分子水平上研究和认识铝胁迫下植物的抗性机制奠定了基础.     

盐胁迫下构树幼苗各器官中K+、Ca2+、Na+和Cl-含量分布及吸收特征

将当年生构树幼苗置于含有不同浓度（04、1、2、3、4 g·kg^-1）NaCl的土壤中,研究其生物量积累、叶片细胞质膜透性和K⁺、Ca²⁺、Na⁺、Cl^-等离子的吸收、分布及运输,并观察盐害症状.结果表明：构树幼苗的叶片质膜透性随着NaCl浓度的增加和胁迫时间的延长而升高,根冠比随NaCl浓度的升高而增加,大于3 g·kg^-1的土壤盐胁迫对构树叶片的质膜透性及植株的生物量积累影响显著.构树幼苗各器官中Na⁺和Cl^-含量随土壤NaCl浓度升高而显著增加,K⁺和Ca²⁺则随之降低,叶片各离子含量均明显高于根和茎.说明盐胁迫影响根系对K⁺和Ca²⁺的吸收,并抑制了它们向地上部分的选择性运输,使叶和茎的K⁺和Ca²⁺含量下降.构树通过吸收积累Na⁺和Cl^-抵御土壤盐分带来的渗透胁迫,但过量的Na⁺和Cl^-积累会造成单盐毒害.作为抗盐性较高的非盐生植物,构树地上部分的拒盐作用不显著.     

转ZjAPX基因拟南芥对NaCl、干旱胁迫的耐性研究

旨在探讨枣树抗坏血酸过氧化物酶基因ZjAPX在植物渗透胁迫中的作用。将ZjAPX基因转入到模式植物拟南芥,以野生型(WT)、转ZjAPX拟南芥株系T2为试材,进行不同浓度NaCl胁迫和干旱胁迫。结果表明,转基因株系的种子萌发、植株生长均优于野生型株系;荧光定量PCR检测转基因拟南芥植株在干旱和盐胁迫处理10 d后目的基因ZjAPX的表达量显著高于野生拟南芥,表明ZjAPX的高表达明显提高了植株的抗旱和耐盐性。     

AtsHsp17.6-CⅠ和AtsHsp17.6-CⅡ基因对非生物胁迫的应答研究

小分子热激蛋白是植物受到热胁迫后的主要表达产物之一,与植物细胞耐热有密切关系。该研究发现,拟南芥小分子热激蛋白基因AtsHsp17.6-CⅠ和AtsHsp17.6-CⅡ 除热激之外,重金属离子Ni⁺、Pb²⁺、Cu²⁺、Zn²⁺和Al³⁺均能诱导这2个热激蛋白基因的表达;氧化胁迫和渗透胁迫同样也能诱导它们表达。该研究将由CaMV35S启动子驱动的这2个小分子热激蛋白基因导入拟南芥,RT-PCR分析表明,2个小分子热激蛋白基因在转基因植物中呈现组成型表达。实验结果表明,组成型表达小分子热激蛋白基因AtsHsp17.6-CⅠ的转基因植物表现出对6 μmol·L^-1 Cd²⁺胁迫、0.4% NaCl胁迫的耐受性。研究表明,这2个小分子热激蛋白基因可能参与着多种抗逆途径,推测其能够减轻或抵抗逆境胁迫引起的伤害并对其进行修复。     

铝胁迫下植物根系的有机酸分泌及其解毒机理

酸性土壤中的铝毒害问题,已成为限制植物生长发育的主要因素之一.耐铝植物通过根系分泌有机酸来解除或减轻铝的毒害是外部解铝毒的重要机制.文章对铝胁迫下植物根系分泌有机酸的种类,有机酸解铝毒机理、解铝毒能力,有机酸分泌方式及调控其分泌的主要因素等相关研究进行综述.     

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.     

植物适应酸铝胁迫机理的研究进展

酸铝胁迫是限制植物正常生长发育的重要非生物胁迫因子,严重制约了我国酸性土壤地区的农业生产水平。植物抵御酸铝胁迫的形式复杂多样,如分泌有机酸、提高根际pH、分泌黏液、细胞壁对Al³⁺的固定、有机酸对细胞溶质中Al³⁺的螯合与液泡区隔化等。现有研究多集中于常规生理特征分析,缺乏深入的分子生物学解析。基于此,本文对国内外植物适应酸铝胁迫机理的相关研究进行了归纳和总结,从酸铝胁迫对植物生长与生理代谢的影响、植物适应酸铝胁迫最主要的两种生理机制(Al排除机制、Al耐受机制)以及分子水平上调控相关耐铝基因进行了综述。最后针对现有研究的不足提出了展望,以期为深入揭示植物适应酸铝胁迫的机理以及挖掘适于酸土生长的优质作物资源提供理论依据。     

过量表达星星草PtSOS_1提高拟南芥的耐盐性

将星星草中分离的质膜型Na+/H+逆向转运蛋白基因PtSOS1(GenBank登录号EF440291)构建到pGWB2植物表达载体上,转化拟南芥,获得抗卡那霉素的抗性植株.PCR和Northern检测表明,PtSOS1已整合到拟南芥基因组中并过量表达.耐盐性实验表明,PtSOS1过量表达提高了拟南芥植株的耐盐性.盐分测定表明,盐胁迫下PtSOS1转基因植株中Na+积累低于野生型的,K+含量则高于野生型的,转基因植株中K+/Na+比值高于野生型.     

盐胁迫条件下提高内源乙烯对拟南芥幼苗生长和根尖活性氧水平的影响

以模式植物拟南芥（Arabidopsis thaliana）为材料,研究了内源乙烯对幼苗耐盐性的影响。研究结果表明,在施加了浓度为100 mmol·L^-1的NaCl胁迫的基质环境中,野生型拟南芥幼苗的根长和根重都显著减小。在施加外源乙烯利后不仅能够缓解盐胁迫对幼苗根伸长生长的抑制作用,而且能够缓解盐胁迫对幼苗根增重生长的抑制作用。施加外源ACC则只能缓解盐胁迫对幼苗根增重生长的抑制作用,而不能缓解盐胁迫对根的伸长生长的抑制。此外,100 mmol·L^-1 NaCl的胁迫条件下,拟南芥幼苗根尖中ROS水平明显升高,而施加了乙烯利和ACC处理下,幼苗根尖ROS的水平在NaCl胁迫下并没有明显的升高,说明内源乙烯可以调控植物体内的ROS维持在正常的水平,使植物体免受氧化损伤,从而提高了幼苗耐盐性。     

Improved phosphorus acquisition by tobacco through transgenic expression of mitochondrial malate dehydrogenase from Penicillium oxalicum

Phosphorus (P) is an essential nutrient for plant growth and development, but is generally unavailable and inaccessible in soil, since applied P is mostly fixed to aluminium (Al) and ferrum (Fe) in acidic soils and to calcium (Ca) in alkaline soils. Increased organic acid excretion is thought to be one mechanism by which plants use to enhance P uptake. In this study, we overexpressed a mitochondrial malate dehydrogenase (MDH) gene from the mycorrhizal fungi Penicillium oxalicum in tobacco. The MDH activity of transgenic lines was significantly increased compared to that of wild type. Malate content in root exudation of transgenic lines induced in response to P deficiency was 1.3- to 2.9-fold greater than that of wild type under the same condition. Among the transgenic lines that were selected for analysis, one line (M1) showed the highest level of MDH activity and malate exudate. M1 showed a significant increase in growth over wild type, with 149.0, 128.5, and 127.9% increases in biomass, when grown in Al-phosphate, Fe-phosphate, and Ca-phosphate media, respectively. M1 also had better P uptake compared to wild type, with total P content increased by 287.3, 243.5, and 223.4% when grown in Al-phosphate, Fe-phosphate, and Ca-phosphate media, respectively. To our knowledge, this is the first study on improving the ability of a plant to utilize P from Al-phosphate, Fe-phosphate, and Ca-phosphate by manipulating the organic acid metabolism of the plant through genetic engineering.     

高粱ATP合成酶E亚基基因(SbATPase-E)的克隆及其抗逆功能研究

高粱是一种抗旱性较强的禾谷类作物。本研究在高粱中克隆到一个全长为693 bp的编码ATP合成酶E亚基的基因(SbATPase-E)。在高粱幼苗期,SbATPase-E基因受Na Cl和脱落酸(ABA)处理诱导上调表达。该基因在拟南芥中过量表达可提高转基因植株的耐旱性和耐盐性,在逆境胁迫条件下转基因拟南芥植株较野生型植株根系发达,可能是转基因植株耐旱性和耐盐性提高的主要原因。在干旱胁迫条件下,转基因植株中DREB2A、P5CS1、RD29A、RAB18和ABI1基因的表达量相对于野生型植株中的表达量提高更为显著;在高盐处理条件下,转基因植株中SOS1和SOS2基因的表达量也较野生型植株中的表达量明显提高。这些抗逆相关基因的上调表达可能是转基因植株抗逆性提高的主要分子机制。     

转拟南芥P5CS1基因增强羽衣甘蓝的耐旱性

为提高羽衣甘蓝的耐旱性,本文将拟南芥Δ1-吡咯啉-5-羧酸合成酶（P5CS1）基因经农杆菌介导转入羽衣甘蓝植株中,检测转基因株系与野生型植株在干旱胁迫下P5CS1 mRNA表达量、幼苗脯氨酸含量、株系根系性状、整株干重、鲜重和整株存活率。结果表明,在15%PEG6000渗透胁迫下,转基因植株的P5CS1基因mRNA表达量明显增加,转基因植株脯氨酸含量是野生型的2.4倍;主根长、最长侧根长、侧根数目、整株干重和鲜重均高于野生型,干重/鲜重则低于野生型,转基因植株的平均存活率为78%,极显著高于野生型。数据显示,AtP5CS1基因在羽衣甘蓝中的表达明显改善了转基因植株的耐旱性。     

Overexpression of MsALMT1, from the Aluminum-Sensitive Medicago sativa, Enhances Malate Exudation and Aluminum Resistance in Tobacco

Aluminum (Al) toxicity is a major limiting factor for plant growth and crop production in acidic soils. Al-induced organic acid (OA) exudation plays an important role in plant Al resistance. The exudation of OAs is mediated by membrane-localized OA transporters. In our previous study, a gene encoding the Al-induced malate transporter (MsALMT1) was identified in the roots of the Al-sensitive plant Medicago sativa L. cv. Yumu no. 1 (YM1). To further validate the function of MsALMT1, transgenic plants that overexpressed MsALMT1 under the control of the CaMV 35S (35S) promoter were generated. This transgenic tobacco showed an enhanced capacity for malate efflux and better Al resistance than wild type (WT) plants after exposure to 30 μM Al for 24 h. The Al content in the transgenic plant roots decreased to 40–52 % of that in WT plant roots. These results demonstrate that MsALMT1 is an Al-resistant gene in YM1 and encodes a malate transporter, the overexpression of which effectively enhances the Al resistance of transgenic tobacco plants.     

Comparison of Al-induced gene expression in sensitive and tolerant soybean cultivars

In order to identify genes involved in soybean resistance to aluminium (Al) stress differential gene expression patterns of Al-stressed and non-stressed tolerant and sensitive soybean cultivars were compared. Out of eight described genes, potentially related to mechanisms of aluminium stress, only phosphoenolpyruvate carboxylase (PEPC) revealed enhanced expression in roots of tolerant as compared to sensitive soybean cultivars under stress conditions. Additionally, two novel full-length cDNA sequences, homologous to translationally controlled tumour proteins (TCTP, clone 58, GenBank accession number AF421558) and inosine-5'-monophosphate dehydrogenases (IMPDH, clone 633, GenBank accession number AF421559) with enhanced expression of the corresponding genes only in roots of Al-tolerant soybean cultivar under stress conditions were isolated and characterized. For functional analysis full-length cDNA 633 was transferred in Arabidopsis thaliana. Only 6% of the seedlings from the wild type survived Al stress, whereas 86% of transgenics were vital demonstrating superiority in stress protection. Compared with the wild type, transgenic plants showed diminished Al penetration into the roots after the stress treatment especially in the division and elongation zones of the roots. Formation of numerous lateral roots in transgenic plants with low elicited callose accumulation under stress conditions indicated ability of the IMPDH homologue to mediate aluminium tolerance in transgenic plants. Possible functional activities of Al up-regulated genes in resistance mechanisms are discussed.     

香蕉MaASR1基因的抗干旱作用

ASR(ABA, stress, ripening induced protein)是一类响应植物干旱胁迫的关键转录因子, 在许多植物中已有报道, 然而尚未见香蕉(Musa acuminata)中ASR与抗旱作用的相关研究。该实验从香蕉果实cDNA文库中筛选出1个ASR基因, 即MaASR1(登录号为AY628102)。干旱胁迫下, 该基因在叶片中的表达量高于根部。将MaASR1转入拟南芥(Arabidopsis thaliana), Southern检测确定了两株独立表达的转基因株系(命名为L14和L38)。表型观察发现, 此两转基因株系的叶片变小且变厚; Northern和Western检测结果表明, MaASR1在L14和L38中表达。控水处理后, L14和L38的存活率及脯氨酸含量均高于野生型。经干旱胁迫和外源ABA处理后, 对MaASR1转基因株系中ABA/胁迫响应基因的表达分析, 发现MaASR1可增强转基因株系对ABA信号的敏感度, 但不能增强植株依赖于ABA途径的抗旱性。     

Interactions between hydrogen sulphide and nitric oxide regulate two soybean citrate transporters during the alleviation of aluminium toxicity

Hydrogen sulphide (H₂S) is emerging as an important signalling molecule involved in plant resistance to various stresses. However, the underlying mechanism of H₂S in aluminium (Al) resistance and the crosstalk between H₂S and nitric oxide (NO) in Al stress signalling remain elusive. Citrate secretion is a wide‐spread strategy for plants against Al toxicity. Here, two citrate transporter genes, GmMATE13 and GmMATE47, were identified and characterized in soybean. Functional analysis in Xenopus oocytes and transgenic Arabidopsis showed that GmMATE13 and GmMATE47 mediated citrate exudation and enhanced Al resistance. Al treatment triggered H₂S generation and citrate exudation in soybean roots. Pretreatment with an H₂S donor significantly elevated Al‐induced citrate exudation, reduced Al accumulation in root tips, and alleviated Al‐induced inhibition of root elongation, whereas application of an H₂S scavenger elicited the opposite effect. Furthermore, H₂S and NO mediated Al‐induced GmMATE expression and plasma membrane (PM) H⁺‐ATPase activity and expression. Further investigation showed that NO induced H₂S production by regulating the key enzymes involved in biosynthesis and degradation of H₂S. These findings indicate that H₂S acts downstream of NO in mediating Al‐induced citrate secretion through the upregulation of PM H⁺‐ATPase‐coupled citrate transporter cotransport systems, thereby conferring plant resistance to Al toxicity.     

超表达AVP1基因提高甜菜的耐低磷和耐盐抗旱性

为探讨H⁺-焦磷酸酶编码基因对甜菜磷吸收和抗性的影响,实现优良基因在甜菜基因工程中的利用,研究在甜菜中超表达拟南芥液泡膜H⁺-焦磷酸酶编码基因AVP1,对转基因甜菜分析其耐低磷、耐盐性和抗旱性。结果显示,AVP1基因在甜菜植株的叶片和块根中表达,且在逆境胁迫下增强表达量响应胁迫;低磷处理条件下,转基因甜菜与野生型甜菜相比具有更高的含磷量,可提高甜菜对磷的吸收利用效率;干旱、盐胁迫处理条件下,AVP1基因在转基因甜菜中显著上升,在盐胁迫或干旱处理条件下,转基因植株的生长受抑程度相对较轻。随着盐和干旱胁迫的加剧,转基因植株体内MDA含量与野生型植株相比较低而脯氨酸含量显著增加,AVP1基因可通过减轻逆境对甜菜细胞膜的损伤及提高甜菜细胞的渗透调节能力,进而增强甜菜对高盐和干旱胁迫的抗性。     

Secretion of malate and citrate from roots is related to high Al-resistance in Lespedeza bicolor

Lespedeza bicolor (Lespedeza bicolor Turcz. cv. Jiangxi) is a leguminous shrub that is well adapted to acid infertile soils. However, the mechanisms of aluminum resistance in this species have not been established. This study aimed to assess the possible resistance mechanisms of this plant to Al. An Al-sensitive species of Lespedeza, sericea lespedeza [Lespedeza cuneata (Dum.-Cours.) G. Don cv. Zhejiang], was used as a reference. The roots of L. bicolor secreted both malate and citrate after exposure to Al, but roots of L. cuneata did not. The secretion of organic acids from L. bicolor was specific to Al; neither 15-day P starvation nor 50 μM lanthanum induced the secretion of these organic acid anions. Secretion of organic acid anions in L. bicolor was detected after 3–6 h exposure to Al, and the amount increased significantly after 6 h exposure, suggesting that this plant shows a pattern II-type organic acid secretion. This is supported by the finding that the secretion was significantly inhibited by a protein-synthesis inhibitor, cycloheximide. Two kinds of anion-channel inhibitors had different effects on Al-induced secretion of organic acids: 9-anthracene carboxylic acid completely inhibited secretion, phenylglyoxal had no effect. Root elongation in L. bicolor was more severely inhibited by Al in the presence of 9-anthracene carboxylic acid. All these results indicated that the secretion of malate and citrate is a specialized response to Al stress in L. bicolor roots, which might be one of the Al-resistance mechanisms in this species.     

谷胱甘肽转移酶基因过量表达能加速盐胁迫下转基因拟南芥的生长

盐地碱蓬谷胱甘肽转移酶基因(glutathione s-transferase gene,GST)克隆到植物表达载体pROKⅡ35s启动子的下游,通过农杆菌介导,利用花絮浸泡法转化拟南芥.转化子在含有卡那霉素的培养基上经过筛选以后,将初步验证为阳性的转基因植株通过PCR-Southem进一步证实.经过选育,筛选并分离到卡那霉素的抗性并且遗传稳定的T3代纯合子转基因拟南芥品系.通过Northern杂交证实外源基因在转基因拟南芥中表达.在盐胁迫条件下,通过测量转基因植株(GT)和野生型植株(wY)的生物量和谷胱甘肽(氧化型:GSSG;还原型:GsH)发现:转基因植株的生物量较野生型有一定程度的提高;GssG含量在转基因品系中比野生型的含量明显高.因此,过量表达GsT能够提高转基因植株在盐胁迫条件下的生长,而且这很可能是由于还原型谷胱甘肽被氧化的结果.