Overexpression of the ThTPS gene enhanced salt and osmotic stress tolerance in Tamarix hispida

Trehalose is a non-reducing disaccharide with high stability and strong water absorption properties that can improve the resistance of organisms to various abi-otic stresses.Trehalose-6-phosphate synthase (TPS) plays important roles in trehalose metabolism and signaling.In this study,the full-length cDNA of ThTPS was cloned from Tamarix hispida Willd.A phylogenetic tree includ-ing ThTPS and 11 AtTPS genes from Arabidopsis indicated that the ThTPS protein had a close evolutionary relationship with AtTPS7.However,the function of AtTPS7 has not been determined.To analyze the abiotic stress tolerance function of ThTPS,the expression of ThTPS in T.hispida under salt and drought stress and JA,ABA and GA3 hormone stimu-lation was monitored by qRT-PCR.The results show that ThTPS expression was clearly induced by all five of these treatments at one or more times,and salt stress caused par-ticularly strong induction of ThTPS in the roots of T.hispida.The ThTPS gene was transiently overexpressed in T.his-pida.Both physiological indexes and staining results showed that ThTPS gene overexpression increased salt and osmotic stress tolerance in T.hispida.Overall,the ThTPS gene can respond to abiotic stresses such as salt and drought,and its overexpression can significantly improve salt and osmotic tolerance.These findings establish a foundation to better understand the responses of TPS genes to abiotic stress in plants.     

刚毛柽柳NAC24基因的表达及抗逆功能分析

【目的】NAC类转录因子是植物特有的最大的转录因子家族之一,广泛参与植物的生长发育过程,并在植物响应盐、干旱等多种非生物胁迫的过程中发挥至关重要的调控作用。本研究拟从盐生木本植物刚毛柽柳中克隆获得一个NAC转录因子基因,研究该基因的耐盐、抗旱功能,以期为研究木本植物NAC转录因子的抗逆分子机制奠定理论基础。【方法】在刚毛柽柳NaHCO_3胁迫转录组数据库中筛选获得一个NAC转录因子基因,将其命名为ThNAC24(GenBank登陆号:KF031949)。利用生物信息学工具将其与其他9个物种的NAC蛋白进行多序列比对,与拟南芥105个NAC蛋白进行进化树分析。分别用300 mmol·L^-1 NaCl和400 mmol·L^-1甘露醇对刚毛柽柳进行胁迫,在胁迫6、12、24和48 h后分别取刚毛柽柳根及叶组织。通过实时荧光定量RT-PCR(qRT-PCR)技术分析盐、干旱胁迫下ThNAC24基因在不同胁迫时间点及不同组织的表达情况,初步鉴定其是否响应盐、干旱胁迫。为进一步研究ThNAC24基因的抗逆功能,分别构建植物过表达(pROKⅡ-ThNAC24)及抑制表达(pFGC5941-ThNAC24)载体。利用农杆菌介导的高效瞬时遗传转化体系获得ThNAC24基因瞬时过表达(OE)、抑制表达(IE)及对照(Control)刚毛柽柳植株。在盐、干旱胁迫下分析比较了ThNAC24基因瞬时过表达、抑制表达及对照刚毛柽柳植株的二氨基联苯胺(DAB)和氯化硝基四氮唑蓝(NBT)染色情况,过氧化物酶(POD)和超氧化物歧化酶(SOD)活性,及电解质渗透率、失水率及丙二醛(MDA)含量,鉴定ThNAC24基因的耐盐、抗旱功能。【结果】ThNAC24基因的开放阅读框为1 023 bp,编码340个氨基酸。多序列比对结果显示ThNAC24在N端的氨基酸序列相似度比较高,具有NAC家族的序列特征;系统进化树分析结果显示ThNAC24与ANAC103和ANAC082的亲缘关系较近。qRT-PCR结果显示:盐胁迫下,ThNAC24基因上调表达,在根组织中胁迫12 h表达量最高,而叶组织中胁迫24 h的表达量最高;干旱胁迫下,ThNAC24基因上调表达,在根组织中胁迫6 h表达量最高,在叶组织中胁迫12 h的表达量最高。ThNAC24基因在刚毛柽柳根和叶组织中均有表达且响应盐和干旱胁迫。过表达ThNAC24基因显著降低了刚毛柽柳H_2O_2和超氧阴离子含量,增强了POD和SOD酶的活性,从而减少活性氧(ROS)的积累。过表达ThNAC24基因能够降低刚毛柽柳在逆境胁迫下的电解质渗透率、失水率及MDA的积累,从而保护细胞膜结构的完整性。【结论】刚毛柽柳ThNAC24基因能够响应盐、干旱胁迫,过表达ThNAC24基因植株通过增强POD和SOD活性,进而提高ROS清除能力,减少细胞受损或死亡,从而提高刚毛柽柳的耐盐及抗旱能力。     

刚毛柽柳 TheIF1A 基因的互作蛋白及其表达模式分析

翻译起始因子是一类翻译起始所必需的特异蛋白因子,前期研究表明柽柳翻译起始因子 (TheIF1A) 基因能对外界盐和干旱等非生物胁迫做出响应,且过表达 TheIF1A基因能提高酵母和烟草的抗旱耐盐能力。为进一步研究TheIF1A基因的抗逆机制,本研究通过酵母双杂交对柽柳翻译起始因子(TheIF1A) 基因的互作蛋白进行了筛选,共获得5个互作蛋白,分别为RNA聚合酶β II亚基 (RNA polymerase beta II subunit)、ATP合成酶CF1α亚基蛋白 (ATP synthase CF1 alpha subunit protein)、细胞色素b6/f 复合物亚基IV(cytochrome b6/f complex subunit IV)、核酮糖1,5-二磷酸羧化酶/加氧酶小亚基蛋白(ribulose 1,5-bisphosphate carboxylase/oxygenase small subunit)和组蛋白乙酰转移酶(histone acetyltransferase)。利用实时荧光定量PCR对这5个蛋白基因及 TheIF1A 基因在盐和干旱胁迫处理下的表达模式进行分析,结果表明:这些蛋白基因在盐和干旱胁迫下的表达模式与 TheIF1A基因基本一致,表明TheIF1A可能通过与这些蛋白相互作用来参与逆境胁迫应答。为进一步研究TheIF1A 基因的抗逆机理奠定了基础,有利于完善林木抗逆机制的研究,并为通过基因工程手段提高林木抗逆性提供了候选基因。     

Verification of the resistance of a LEA gene from Tamarix expression in Saccharomyces cerevisiae to abiotic stresses

The role of late embryogenesis abundant （LEA） proteins in stress tolerance was examined by using a yeast expression system. LEA protein tolerance to the abotic stresses in plants involved in salt, drought and freezing stresses and additional tolerance to heat, NaHCO3 （salt-alkali） and ultraviolet radiation was also investigated. The transgenic yeast harboring the Tamarix LEA gene （DQ663481） was generated under the control of inducible GAL promoter （pYES2 vector）, yeast cells transformed with pYES2 empty vector were also generated as a control. Stress tolerance tests showed that LEA yeast transformants exhibited a higher survival rates than the control transformants under high temperature, NaHCO3, ultraviolet radiation, salt （NaCl）, drought and freezing, indicating that the LEA gene is tolerant to these abiotic stresses. These results suggest that the LEA gene is resistant to a wider repertoire of stresses and may play a common role in plant acclimation to the examined stress conditions.     

Improvement of paper mulberry tolerance to abiotic stresses by ectopic expression of tall fescue FaDREB1

Dehydration-responsive element binding/C-repeat-binding factors (DREB/CBF) control the activity of multiple stress response genes and therefore represent attractive targets for genetic improvement of abiotic stress tolerance. Paper mulberry (Broussonetia papyrifera L. Vent) is well known for its bark fibers and high levels of chalcone and flavonoid derivatives. Transgenic paper mulberry plants expressing a tall fescue (Festuca arundinacea Schreb.) FaDREB1 gene under the control of CaMV 35S were produced to examine the potential utility of FaDREB1 to increase the tolerance of paper mulberry plants to abiotic stress. The overexpressing FaDREB1 plants showed higher salt and drought tolerance than the wild-type plants (WT). After 13 days of withholding water, or 15 days in the presence of 250 mM NaCl, all the WT plants died, while the over-expressing FaDREB1 plants survived. The FaDREB1 plants had higher leaf water and leaf chlorophyll contents, accumulated more proline and soluble sugars, and had less ion leakage (which reflects membrane damage) than the WT plants had under high salt- and water-deficient conditions. The 35S promoter-driven expression of FaDREB1 did not cause growth retardation under normal growth conditions. Therefore, improved tolerance to multiple environmental stresses in paper mulberry might be achieved via genetic engineering through the ectopic expression of an FaDREB1 gene.     

刚毛柽柳 FeSOD 基因的克隆及耐盐应答分析磁

植物响应盐胁迫逆境,涉及一系列的保护酶类基因的表达和调控, SOD酶是其中重要的一类。本研究通过对盐胁迫后7个柽柳转录组分析和进一步测序验证,获得了2个柽柳FeSOD基因全长cDNA序列,它们编码蛋白的氨基酸残基数分别为256、308,分子量为63.8、75.4 kDa,理论等电点为5.0和5.1。实时荧光定量PCR结果显示这2个FeSOD基因在盐胁迫后柽柳根和叶中呈现不同的表达模式。在根中,第9天时, ThFeSOD1和ThFeSOD2基因的表达均明显上调。在叶中, ThFeSOD1和ThFeSOD2在胁迫3天受明显的诱导,而5天表达受明显的抑制。     

Cloning of four DREB genes from Tibetan Sophora moorcroftiana and analysis of their expression during abiotic stress

Sophora moorcroftiana is an endemic, droughtresistant shrub that grows in Tibet and has some degree of resistance to salt, cold, heat, and drought. In the present study, four dehydration responsive element-binding(DREB) genes(Sm DREB1, Sm DREB2, Sm DREB and Sm DREB1) were isolated from S. moorcroftiana for the first time and their expression and proline content under abiotic stress were analyzed. Proline accumulated in seedlings under drought, salt, cold, and heat stress treatments. The four genes were variously expressed in response to the four abiotic stresses. Sm DREB1 was induced by drought, cold, and heat stresses; Sm DREB2 and Sm DREB4 were both induced by salt, cold, and heat stresses, whereas Sm DREB3 was induced by drought and heat stresses. Thus, these four genes may participate in conferring tolerance to these four abiotic stresses and are candidate genes for genetic engineering in the future.     

逆境胁迫下柽柳脂质转运蛋白基因 (ThLTP)的克隆与功能初步分析

从以刚毛柽柳为材料构建的NaCl胁迫的根cDNA文库中测序得到1条LTP基因序列,其全长为635 bp、编码116个氨基酸,命名为ThLTP基因。采用实时荧光定量RT-PCR的方法,分别对0.2 mol.L-1NaCl、150μmol.L-1CdCl2、20%(W/V)PEG6000、100μmol.L-1ABA及4℃下ThLTP基因在柽柳中的表达模式进行了分析,结果表明:ThLTP基因除了在4℃条件下根组织中为下调表达外,在其它处理中均表现为上调表达。将ThLTP基因克隆到大肠杆菌(Escherichia coli)的原核表达载体pET32a中,对重组菌Escherichia coli BL21(pET32a-LTP)的抗旱耐盐性进行分析。结果表明:在0.8%(W/V)NaCl和20%(W/V)PEG6000条件下,对照菌E.coli BL21(pET32a)无对数生长期,而重组菌E.colii BL21(pET32a-LTP)经过3 h的延迟生长后,进入到对数增长期,表明ThLTP可受盐、碱、低温诱导并能提高重组菌的抗旱耐盐能力。     

一个新的柽柳类萌芽素基因ThGLP的结构及其表达分析

萌芽素和类萌芽素蛋白在不同植物的各个生长阶段和胁迫相关过程中起到不同的作用。本研究首次从刚毛柽柳cDNA文库中获得类萌芽素蛋白全长基因ThGLP,该基因编码225个氨基酸,含有植物萌芽素和类萌芽素蛋白的功能序列。通过进化树分析发现该基因屑于真正萌芽素亚家族。利用实时定量PCR方法研究了该基因在PEG、NaCl、低温、CdCl2和ABA胁迫下不同时间的表达模式。结果显示PEG、NaCl、低温、CdCl2和ABA处理均能诱导ThGLP基因在柽柳的根和叶中的表达。结果表明ThGLP在柽柳根和叶中表达,参与非生物胁迫应答并由ABA依赖的信号传导途径调控。     

Tree chitinases – stress‐ and developmental‐driven gene regulation

In recent years, a considerable number of studies have harnessed the power of genomics to decipher the role of pathogenesis‐related (PR) proteins in plant defence against various biotic and abiotic stresses. Chitinases are PR antifungal proteins expressed constitutively at low levels in plants and induced during biotic pressures and are demonstrated to be involved in the plant defence responses. Remarkable induction of chitinase enzymes by various abiotic agents (salicylic acid, jasmonic acid, ethylene and ozone) and biotic components (pathogens, insect pest, fungal cell wall components and oligosaccharides) is well demonstrated in plants. Several reviews on plant chitinase expression during host–pathogen interaction are available for annual species, whilst reports of their expression in tree species are limited to a few woody perennials: Populus, Pinus, Picea, Eucalyptus, Castanea and Pseudotsuga. The aim of this paper is to review the induction of chitinase during various stresses and developmental processes in forest tree species.     

植物DNA甲基化研究进展

植物经常暴露在各种生物和非生物的胁迫之下,这些胁迫会影响植物的生长发育和繁殖并最终导致植物死亡。为了抵御不利的环境条件,植物已经进化出复杂而精细的网络来感知胁迫并激活防御系统。为此,植物激活许多信号转导通路,这些信号转导通路可以改变一些胁迫响应基因的表达,从而引起植物形态、生理和生化的改变以适应逆境。DNA胞嘧啶甲基化是高等真核生物的主要表观遗传机制之一,在维持基因组稳定性和调节基因表达方面起着关键作用。表观遗传变异比遗传变异更为灵活。一旦环境条件发生变化,为了适应新的环境植物都会发生表观遗传的改变。许多研究表明DNA甲基化参与植物的发育和应激反应。基于相关研究对DNA甲基化进行了综述,对植物逆境胁迫有重要意义。     

Two novel eukaryotic translation initiation factor 5A genes from Populus simonii × P. nigra confer tolerance to abiotic stresses in Saccharomyces cerevisiae

The role of plant e IF5 A proteins in multiple biological processes, such as protein synthesis regulation,translation elongation, m RNA turnover, programmed cell death and stress tolerance is well known. Toward using these powerful proteins to increase stress tolerance in agricultural plants, in the present study, we cloned and characterized Psne IF5A2 and Psne IF5A4 from young poplar(P. simonii 9 P. nigra) leaves. The deduced amino acid sequences of Psne IF5A2 and Psne IF5A4 were 98 %similar to each other, and they are orthologs of e IF5A1 in Arabidopsis. In a subcellular localization analysis,Psne IF5A2 and Psne IF5A4 proteins were localized in the nucleus and cytoplasm. q RT-PCR analysis showed that Psne IF5A2 and Psne IF5A4 were transcribed in poplar flowers, stem, leaves, and roots. In addition, they were also induced by abiotic stresses. Transgenic yeast expressing Psne IF5A2 and Psne IF5A4 had increased salt, heavy metal, osmotic, oxidative tolerance. Our results suggest that Psne IF5A2 and Psne IF5A4 are excellent candidates for genetic engineering to improve salt and heavy metal tolerance in agricultural plants.     

平榛ChWRKY28基因克隆及表达模式分析

[目的]研究平榛ChWRKY28基因序列特征及其在不同非生物胁迫下的表达规律.[方法]以平榛为试材,采用RACE-PCR方法进行基因克隆;利用实时荧光定量PCR方法检测基因在不同组织及不同非生物胁迫下的表达模式.[结果]表明:克隆得到的WRKY基因,全长1 342 bp,基因内部包含1个长963 bp的完整开放阅读框,编码320个氨基酸残基,命名为ChWRKY28.构建的系统发育树表明:该序列与拟南芥AtWRKY28及杨树PtrWRKY93的关系最近,相似性分别为49%和60%.基因表达分析表明:ChWRKY28在雄花序、雌花芽及茎中均有表达,但在茎部(皮)中的表达量高于雄花序和雌花芽中的表达量,具有组织表达特异性;低温、干旱及盐胁迫均能诱导ChWRKY28基因的表达,但受诱导程度存在差异.亚细胞定位分析结果表明:ChWRKY28蛋白分布在细胞核内,是一个核蛋白.[结论]推测ChWRKY28基因可能参与植物响应非生物胁迫的信号转导过程.     

Overexpression of AtNHX5 improves tolerance to both salt and drought stress in Broussonetia papyrifera (L.) Vent

Paper mulberry (Broussonetia papyrifera L. Vent) is well known for its bark fibers, which are used for making paper, cloth, rope, etc. It was found that, in addition to its well-documented role in the enhancement of plant salt tolerance, overexpression of the Na+/H+ antiporter (AtNHX5) gene in paper mulberry plants showed high drought tolerance. After exposure to water deficiency and salt stress, the wild-type (WT) plants all died, while the AtNHX5-overexpressing plants remained alive under high salt stress, and had a higher survival rate (>66%) under drought stress. Measurements of ion levels indicated that Na+ and K+ contents were all higher in AtNHX5-overexpressing leaves than in WT leaves in high saline conditions. The AtNHX5 plants had higher leaf water content and leaf chlorophyll contents, accumulated more proline and soluble sugars, and had less membrane damage than the WT plants under water deficiency and high saline conditions. Taken together, the results indicate that the AtNHX5 gene could enhance the tolerance of paper mulberry plants to multiple environmental stresses by promoting the accumulation of more effective osmolytes (ions, soluble sugars, proline) to counter the osmotic stress caused by abiotic factors.