山葡萄CBF基因表达载体构建及对拟南芥根生长的影响

为了研究山葡萄CBF基因调节植物对盐胁迫的应答机理,分别构建了山葡萄Va CBF1、Va CBF2和Va CBF3的植物过表达载体。经酶切及琼脂糖电泳检测证实3个基因均插入到p BASTA中,表明表达载体构建成功。然后,分别将3个植物过表达载体转入农杆菌EHA105中,并通过浸花法浸染拟南芥。利用除草剂筛选获得3个基因的拟南芥过表达株系。最后,对野生型拟南芥与转基因拟南芥进行盐胁迫处理,发现OE-CBF2转基因植株的主根伸长长度显著长于其它植株,3个转基因株系的侧根长度也明显长于野生型植株。上述结果表明山葡萄CBF基因可能在植物盐胁迫中对根部生长发育起到非常重要的调控作用。     

过量表达棉花GaSus3基因增强拟南芥的耐盐性

构建了植物过量表达载体p35S：：GaSus3,通过花序浸染法成功获得转GaSus3基因拟南芥植株。利用NaCl模拟盐胁迫处理,证实转基因拟南芥与野生型相比耐盐性明显增强。在盐胁迫下,转基因拟南芥受到的影响较小,而野生型则受盐害影响严重：转基因拟南芥具有更好的萌发率和主根长度,以保证植株正常生长;盐胁迫下转基因拟南芥能保持较多的绿色叶片,而野生型则过早黄化死亡。研究还发现,转基因拟南芥的过氧化氢酶活性在胁迫前后都高于野生型,这说明转GaSus3基因能够提高拟南芥抗氧化胁迫的能力。研究结果为进一步探讨GaSus3基因在棉花耐盐方面的功能奠定了基础。     

AtNHX5基因过量表达对拟南芥耐盐性的影响

为了研究AtNHX5基因在植物耐盐中的作用,构建了植物过量表达载体pROKⅡ-AtNHX5,并转化拟南芥。结果显示:(1)RT-PCR检测表明,转基因拟南芥中AtNHX5基因的表达大幅提高。(2)对转基因纯合株系进行耐盐性分析显示,AtNHX5过量表达提高了植株在种子萌发和苗期的耐盐性。(3)转基因植株在盐处理下的干重、鲜重以及地上部分Na+、K+含量均高于野生型对照。在200mmol/L NaCl处理下,以转基因株系a1-4为例,其地上部分单株鲜重、单株干重、K+含量分别是野生型的1.27、1.54、1.16倍,较野生型显著升高。研究表明,过量表达AtNHX5基因促进了盐胁迫下转基因植株对K+的吸收,转基因拟南芥的耐盐性明显提高。     

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。     

水稻含有B-box锌指结构域的OsBBX25蛋白参与植物对非生物胁迫的响应

锌指蛋白在调控植物生长发育和应对逆境过程中发挥着重要作用.为进一步研究锌指类蛋白参与植物非生物胁迫响应的分子机制,对水稻(Oryza sativa)中一个编码含有B-box锌指结构域蛋白的OsBBX25基因进行了功能分析.OsBBX25受盐、干旱和ABA诱导表达.异源表达OsBBX25的转基因拟南芥(Arabidopsis thaliana)与野生型相比对盐和干旱的耐受性增强,且盐胁迫条件下转基因植物中KIN1、RD29A和COR15的表达上调,干旱胁迫下KIN1、RD29A和RD22的表达上调.外源施加ABA时,转基因植物的萌发率与野生型之间没有明显差异.OsBBX25可能作为转录调控的辅助因子调节胁迫应答相关基因的表达,进而参与植物对非生物胁迫的响应.     

水稻受盐抑制基因OsZFP1的转基因分析

OsZFP1(水稻锌指蛋白1)基因编码的蛋白含有3个推测的Cys2/Cys2-型锌指结构域,它的表达受盐胁迫负调控。构建了以35S为启动子的OsZFP1基因的植物表达载体,并将其转入拟南芥(ArabidopsisthalianaL.)植物和水稻(OryzasativaL.)愈伤组织中以过量表达OsZFP1基因。转基因的拟南芥植株和水稻愈伤组织对盐处理的敏感性都比野生型要高。这一结果表明OsZFP1基因可能编码一种负调控蛋白,它可能抑制某些盐诱导基因的表达。在ABA处理下,转基因拟南芥植株比野生型植株抽苔晚,说明OsZFP1基因的作用可能受ABA调节。     

水稻受盐抑制基因OsZFP1的转基因分析

OsZFP1(水稻锌指蛋白1)基因编码的蛋白含有3个推测的Cys2/Cys2-型锌指结构域,它的表达受盐胁迫负调控.构建了以35S为启动子的OsZFP1基因的植物表达载体,并将其转入拟南芥(Arabidopsis thaliana L.)植物和水稻(Oryza sativa L.)愈伤组织中以过量表达OsZFP1基因.转基因的拟南芥植株和水稻愈伤组织对盐处理的敏感性都比野生型要高.这一结果表明OsZFP1基因可能编码一种负调控蛋白,它可能抑制某些盐诱导基因的表达.在ABA处理下,转基因拟南芥植株比野生型植株抽苔晚,说明OsZFP1基因的作用可能受ABA调节.     

过量表达NtRopl基因增加了植物对盐胁迫的敏感和过氧化氢的含量

Rop／Rbo类的小G蛋白是一类重要的信号分子,它在植物的生长发育过程中起着重要的调控作用．根据已知的序列信息,我们从烟草中克隆得到了编码NtRopl基因的基因组序列,并研究了该基因在不同胁迫处理下的表达情况及转基因植物在盐胁迫下的反应,该基因的基因组中含有7个外显子和6个内含子,半定量RT-PCR表明,该基因的表达受到NaCl,甲基紫精（MV）和1．氨基环丙烷－1－羧酸（ACC）的诱导,而脱落酸（ABA）抑制该基因的表达,与野生型拟南芥相比,转基因拟南芥增加了对盐胁迫的敏感性,具体表现为,在盐胁迫下,转基因植株根的长度明显比对照短,并且相对电导率也明显比对照高,通过对过氧化氢含量的测定发现,转基因拟南芥的过氧化氢的含量比对照高,这表明NtRopl基因可能是通过增加植物体内过氧化氢含量从而导致植物对盐胁迫的敏感性。     

过量表达星星革PtSOS1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PtSOSJ（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Northem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。     

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.     

过量表达水稻细胞质型OsAPXs基因提高转基因烟草的耐盐性

为了验证水稻(Oryza sativa L.)细胞质型APXs与细胞耐盐性的关系,实验分别将OsAPXa和OsAPXb（基因登录号：D45423、AB053297）转化到烟草(Nictiana tabacum,N.plum)植株中。Southern结果表明,二基因分别整合到烟草的基因组;Northern分析表明,外源基因在转基因烟草中得到高效表达;在碳酸盐逆境下,T2代转基因植株与野生型对照相比,其APX活性呈现显著的提高,T₂代品系的H₂O₂含量和叶片受害程度显著低于野生型;T₂代品系分别在含有10 mmol·L^-1 NaHCO₃、5 mmol·L^-1 Na₂CO₃的MS培养基上生长,根的生长受到抑制,叶片产生黄化;野生型烟草则难以存活。水稻细胞质型OsAPXs基因的过量表达提高了转基因烟草的耐盐性,揭示出OsAPXa和OsAPXb在碳酸盐逆境应答过程中发挥着重要的作用。     

根癌农杆菌介导的乙肝表面抗原基因对烟草的转化

构建了植物表达载体pBRSAg,该载体具有完整的植物表达元件,CaMV35S启动子、农杆菌T-DNA左右边界、植物报告基因gus和植物选择标记基因hpt,适用于农杆菌的转化;通过冻融法将重组质粒pBRSAg转入根癌农杆菌LBA4404中,利用农杆菌介导法转化烟草叶盘,经筛选培养获得烟草植株。抗性植株经GUS染色和PCR检测为阳性,初步表明乙肝表面抗原基因在烟草中得到表达。     

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。     

An Isopentyl Transferase Gene Driven by the Stress-Inducible rd29A Promoter Improves Salinity Stress Tolerance in Transgenic Tobacco

Soil salinity is a serious worldwide problem. To improve the salt tolerance of plants, an increasing number of genes related to abiotic stress have been recently expressed by genetic engineers. In the present study, the successful introduction into tobacco of isopentenyl transferase (IPT) from Agrobacterium tumefaciens via Agrobacterium-mediated transformation is reported. A stress-inducible genetic construct was cloned using IPT under the control of the stress-inducible promoter rd29A from Arabidopsis thaliana. A total of 40 putative transgenic plant lines were obtained from independent Kan-resistant shoots. IPT integration into the tobacco genome was confirmed by polymerase chain reaction (PCR) and Southern blot analyses. Four positive transgenic lines each with a single T-DNA insertion were obtained. Real-time PCR confirmed a marked increase in IPT expression in young tobacco plants harboring rd29A-IPT after short-term exposure to salt. Ectopic IPT overexpression IPT under the control of the stress-inducible rd29A promoter resulted in significantly enhanced tolerance to salt stress. No obvious adverse effect on growth and development was observed in transgenic plants. Two IPT transgenic lines, T10 and T25, were chosen for further physiological analyses. The leaves of transgenic tobacco plants showed significantly prolonged chlorophyll retention times under a 2-week salt-stress treatment (150?mmol?L^?1). In contrast, the leaves of the non-transformed plants (wild type) gradually senesced under the same condition. After re-watering for 2?weeks, chlorophyll in transgenic plants increased to a level comparable with that in the unstressed plants. On the other hand, the level in the non-transgenic control still remained low. Malondialdehyde (MDA) levels increased in both transgenic plants and the control after salt stress. However, the MDA levels only mildly increased in transgenic plants, and dramatically increased in the control. After re-watering for 7?days, MDA in transgenic plants returned to normal, whereas the level in the control remained high. Superoxide dismutase activity also similarly increased in transgenic plants during salt stress, and returned to normal after re-watering. These results indicate that enhanced reactive oxygen species scavenging capability may play a significant role in acquiring tolerance to abiotic stress.     

Overexpression of a wheat Na+/H+ antiporter gene (TaNHX2) enhances tolerance to salt stress in transgenic tomato plants (Solanum lycopersicum L.)

Soil salinity is a major environmental stress limiting plant productivity. Vacuole Na⁺/H⁺ antiporters play important roles for the survival of plants under salt stress conditions. We have developed salt stress tolerant transgenic tomato plants (Solanum lycopersicum cv. PED) by overexpression of the wheat Na⁺/H⁺ antiporter gene TaNHX2 using Agrobacterium tumefaciens strain LBA4404 harbouring a binary vector pBin438 that contains the TaNHX2 gene under the control of double CaMV 35S promoter and npt II as a selectable marker. PCR and Southern blot analysis confirmed that TaNHX2 gene has been integrated and expressed in the T₁ generation transgenic tomato plants. When TaNHX2 expressing plants were exposed to 100 or 150 mM NaCl, they were found to be more tolerant to salt stress compared to wild type plants. Biochemical analyses also showed that transgenic plants have substantial amount of relative water content and chlorophyll content under salt stress conditions compared to wild type plants. The relative water content in transgenic and wild type plants ranged from 68 to 75 % and 46–73 % and chlorophyll content fall in between 1.8 to 2.4 mg/g fw and 1.0 to 2.4 mg/g fw, respectively, in all stress conditions. In the present study, we observed a better germination rate of T₁ transgenic seeds under salt stress conditions compared with wild type plants. Our results indicated that TaNHX2-transgenic tomato plants coped better with salt stress than wild type plants.     

新牧一号杂花苜蓿MvNHX1基因的表达分析和提高烟草耐盐性的研究

提取新牧一号杂花苜蓿的总RNA,用特异引物RT-PCR扩增后的cDNA片段连接入pMD19-T载体,转化大肠杆菌DH5α,对阳性克隆进行序列分析,新牧一号苜蓿NHX1（MvNHX1）全长1 626 bp,Genbank登录号为：EU375310。半定量RT-PCR和实时荧光定量PCR分析表明,在盐胁迫下MvNHX1基因的表达均上调。构建重组植物表达载体pBI121-MvNHX1后,通过农杆菌介导的叶盘法转化烟草,转基因烟草在盐胁迫下发芽率和生物量均高于非转基因烟草,表明MvNHX1能够提高转基因烟草的耐盐性。     

A salt-inducible chloroplastic monodehydroascorbate reductase from halophyte Avicennia marina confers salt stress tolerance on transgenic plants

Plant growth and productivity are adversely affected by various abiotic stress factors. In our previous study, we used Avicennia marina, a halophytic mangrove, as a model plant system for isolating genes functioning in salt stress tolerance. A large scale random EST sequencing from a salt stressed leaf tissue cDNA library of one month old A. marina plants resulted in identification of a clone showing maximum homology to Monodehydroascorbate reductase (Am-MDAR). MDAR plays a key role in regeneration of ascorbate from monodehydroascorbate for ROS scavenging. In this paper, we report the cellular localization and the ability to confer salt stress tolerance in transgenic tobacco of this salt inducible Am-MDAR. A transit peptide at the N-terminal region of Am-MDAR suggested that it encodes a chloroplastic isoform. The chloroplastic localization was confirmed by stable transformation and expression of the Am-MDAR-GFP fusion protein in tobacco. Transgenic tobacco plants overexpressing Am-MDAR survived better under conditions of salt stress compared to untransformed control plants. Assays of enzymes involved in ascorbate–glutathione cycle revealed an enhanced activity of MDAR and ascorbate peroxidase whereas the activity of dehyroascorbate reductase was reduced under salt stressed and unstressed conditions in Am-MDAR transgenic lines. The transgenic lines showed an enhanced redox state of ascorbate and reduced levels of malondialdehyde indicating its enhanced tolerance to oxidative stress. The results of our studies could be used as a starting point for genetic engineering of economically important plants tolerant to salt stress.     

Ectopic over-expression of peroxisomal ascorbate peroxidase (SbpAPX) gene confers salt stress tolerance in transgenic peanut (Arachis hypogaea)

Peroxisomal ascorbate peroxidase gene (SbpAPX) of an extreme halophyte Salicornia brachiata imparts abiotic stress endurance and plays a key role in the protection against oxidative stress. The cloned SbpAPX gene was transformed to local variety of peanut and about 100 transgenic plants were developed using optimized in vitro regeneration and Agrobacterium mediated genetic transformation method. The T₀ transgenic plants were confirmed for the gene integration; grown under controlled condition in containment green house facility; seeds were harvested and T₁ plants were raised. Transgenic plants (T₁) were further confirmed by PCR using gene specific primers and histochemical GUS assay. About 40 transgenic plants (T₁) were selected randomly and subjected for salt stress tolerance study. Transgenic plants remained green however non-transgenic plants showed bleaching and yellowish leaves under salt stress conditions. Under stress condition, transgenic plants continued normal growth and completed their life cycle. Transgenic peanut plants exhibited adequate tolerance under salt stress condition and thus could be explored for the cultivation in salt affected areas for the sustainable agriculture.