小麦HMW谷蛋白亚基基因克隆研究进展

高分子量麦谷蛋白亚基 (HMW GS)作为小麦胚乳中的重要贮藏蛋白 ,其组成及含量对小麦面粉的烘烤品质具有重要的决定作用。因此 ,改变小麦中HMW 谷蛋白的组成及含量是小麦品质改良的主要内容。而定向克隆小麦HMW GS基因则为利用基因工程方法改良小麦品质提供新的基因资源 ,从而为优质小麦的发展起到积极的推动作用。综述了近 2 0年来国内外小麦HMW GS基因克隆的研究进展 ,并讨论了近年来发展起来的一些新的基因克隆方法及其在小麦HMW GS基因克隆上的应用前景。     

不同品质类型小麦谷蛋白聚合体含量及亚基组成的初步研究

以6个不同品质类型小麦品种为试验材料,对其面粉总蛋白含量(FP％)、谷蛋白总聚合体含量(TGP％)、大聚合体含量(GMP％)进行了测定和比较,并利用多层浓缩胶SDS—PAGE对不同品种小麦面粉大聚合体亚基组成进行了初步分析。结果表明：(1)面包和面条型小麦面粉谷蛋白总聚体含量明显高于饼干型小麦;(2)分子量约为32—43kD和14kD的亚基主要是组成麦谷蛋白大聚合体。     

小麦HMW-GS基因及其AS-PCR分子标记研究进展

小麦高分子量谷蛋白亚基(HMW-GS)与小麦品质性状,尤其是沉降值性状显著相关。利用其做分子标记选育聚合优质亚基的品种,具有快速、简单、实用、有效的特点。目前,普通小麦基因组中已有15个已命名Glu-1基因被克隆和测序,这使设计引物序列、进行等位基因的特异性扩增成为可能。对普通小麦高分子量谷蛋白亚基基因组成特点及分子标记现状进行了分析,并针对国内利用高分子量谷蛋白亚基进行分子标记辅助育种做了展望。     

小麦HMW-GS 12基因克隆及植物表达载体构建

目的:为了利用基因遗传转化改良小麦品质,采用聚合酶链式反应(PCR)技术。方法:从小麦品种东农7742基因组DNA中扩增并克隆了小麦高分子量谷蛋白12亚基基因(HMW-GS 12)。结果:序列分析结果表明,该基因全长1 980bp,其核苷酸顺序和推导的氨基酸顺序与已发表的序列相比,同源性分别为99.5%和99.7%。经过基因拼接,分别构建了胚乳特异性表达和组成型表达的高分子量谷蛋白12亚基基因的两个植物表达载体pDNPPBIHG和pUbPBIHG。     

应用SDS-PAGE分析和PCR鉴定长发带芒草的高分子量谷蛋白亚基

利用SDS-PAGE分析、PCR扩增和序列测定与分析研究了长发带芒草(Taeniatherumcrinitum)的高分子量谷蛋白亚基及其基因。结果显示,长发带芒草中发现的高分子量谷蛋白亚基与普通小麦中的类似,但迁移率存在较大差异。其中,x型亚基均比Dx2亚基迁移率小或接近,y型亚基均比Dx12亚基迁移率更快。本研究结果揭示了带芒草属具有与普通小麦类似的高分子量谷蛋白亚基,这些亚基在小麦品质遗传改良中具有潜在的利用价值。     

小麦高分子量麦谷蛋白亚基鉴定及其品质效应研究进展

高分子量谷蛋白亚基(HMW-GS,high molecular weight glutenin subunits)是小麦子粒贮藏蛋白的重要组成成分,其组成、搭配、表达水平及含量决定面团弹性和面包加工品质。本文主要介绍了小麦HMW-GS编码基因的克隆、分子特征、分子标记开发及其在小麦育种中的应用,并综述了不同HMW-GS与面粉加工品质之间的关系,以及HMW-GS基因遗传转化、微量配粉和突变体培育等方面的研究进展,分析了目前研究中存在的主要问题,认为通过分子标记辅助选择和转基因技术聚合优质亚基,培育优质面包小麦品种和明确各个HMW-GS基因的品质效应是今后的研究重点。     

小麦谷蛋白亚基基因的PCR鉴定及其在品质改良中的应用

小麦谷蛋白是胚乳中的主要贮藏蛋白,对面包品质具有重要作用。因此,改变品种的谷蛋白等位基因组成是品质改良的主要内容,而谷蛋白亚基基因的选择手段是决定品质育种成效的关键。本文介绍了近年来发展起来的小麦谷蛋白亚基基因PCR分子鉴定技术,通过与传统SDSPAGE方法的比较,总结了PCR技术应用于谷蛋白基因鉴定和品质改良计划的优越性及其研究进展,并讨论了分子标记技术在小麦品质改良计划中的应用前景及今后的研究方向。     

小麦谷蛋白亚基基因的PCR鉴定及其在品质改良中的应用

小麦谷蛋白是胚乳中的主要贮藏蛋白,对面包品质具有重要作用。因此,改变品种的谷蛋白等位基因组成是品质改良的主要内容,而谷蛋白亚基基因的选择手段是决定品质育种成效的关键。本文介绍了近年来发展起来的小麦谷蛋白亚基基因PCR分子鉴定技术,通过与传统SDS－PAGE方法的比较,总结了PCR技术应用于谷蛋白基因鉴定和品质改良计划的优越性及其研究进展,并讨论了分子标记技术在小麦品质改良计划中的应用前景及今后的研究方向。     

类大麦材料y型高分子量谷蛋白基因不表达的鉴定

利用SDS-PAGE检测了2份类大麦属植物的高分子量谷蛋白亚基组成,在小麦的高分子量区域仅检测到1条蛋白带,因此怀疑其y型亚基没有表达.根据其它高分子量谷蛋白提取方法的结果以及基因编码区部分序列测定,确认其y型高分子量谷蛋白基因是沉默的.     

小麦高分子量麦谷蛋白亚基的遗传变异与小麦加工品质改良

高分子量麦谷蛋白亚基（HMW-GS）是小麦胚乳中一种具有多态性的蛋白质组分,在面团中它们可以通过相互之间或与低分子量麦谷蛋白亚基（LMw-Gs）之间形成二硫键来组成麦谷蛋白多聚体。由于其在小麦面粉加工所需的粘性和弹力方面具有极其重要的作用,过去几十年间在小麦加工品质相关蛋白研究方面的工作大多数集中在高分子量麦谷蛋白亚基上。近几年在高分子量麦谷蛋白亚基及其编码基因的鉴定、基因的遗传变异以及不同变异在小麦加工品质中的作用方面进行了大量研究。本文对近几年在HMW-GS领域的研究进展进行综述并且重点讨论HMW-GS的变异及其对小麦品质育种的重要意义。     

小麦高分子量谷蛋白亚基及其基因的研究进展

主要介绍了小麦高分子量谷蛋白亚基（HMW－GS）及其基因的研究进展情况,目前,转基因小麦的技术已经逐渐成熟,由于分子生物学领域分子标记技术的迅速发展,尤其是PCR技术的广泛应用,为实现外源优良储藏蛋白基因导入改良品种提供了可能,利用已知小麦品种的基因序列设计引物,从众多的未知小麦品种中扩增出新基因加以研究并做外源优质HMW－GS基因的转入已成为一种趋势。     

基因枪法获得无选择标记的1Dx5基因表达的转基因小麦

利用基因枪将无选择标记的优质高分子量麦谷蛋白亚基基因1Dx5导入新疆耐盐小麦品种新冬26,为利用优质基因进行小麦品质改良奠定基础。构建无选择标记的线性1Dx5表达框。利用基因枪将其转入不含该亚基的小麦品种新冬26幼胚盾片中,经PCR二分法筛选,从转化的1 000块幼胚盾片中共获得3株转基因阳性植株,转化效率0.3%。利用SDS-PAGE分析目的基因在转基因后代籽粒中的表达。转基因植株后代种子分析表明,1Dx5在转基因后代部分种子中表达。本研究成功地将无选择标记的线性1Dx5片段导入普通小麦新冬26中,并在后代部分种子中得到了表达。为利用优质亚基基因改良小麦加工品质奠定基础。     

Development of genetically modified wheat to assess its dough functional properties

End-use functionality of bread wheat depends mainly on the protein content, the presence of particular subunits of high and low molecular weight glutenin, the ratio of high molecular weight to low molecular weight glutenin subunits, and the ratio of glutenin to gliadin. The exact contribution of each of these factors to end-use functionality is still largely unknown. Transgenic plants can allow these factors to be studied within a particular background thus contributing to our understanding of end-use functionality. Two Canadian wheat lines, one of them containing high molecular weight glutenin subunits (HMW-GS) coded by all three Glu-1 loci and one line null at all three loci were assessed for dough rheological properties and bread and tortilla-making properties. Protein composition of the flours were characterized by sodium dodecyl sulfate polyacrylamide gel electrophoresis, size exclusion high performance liquid chromatography, and sedimentation test. Proteins in the samples were fractionated and the proportions of monomeric proteins, soluble glutenin, and insoluble glutenin were quantified. Functionality of the flours were characterized by small-scale methods such as the 2 g mixograph, 10 g farinograph, and micro-extension testing. End-use quality was evaluated by small-scale bread and tortilla production. Mixograph development time and mixograph peak height were much higher for the lines containing HMW-GS. The lines null for HMW-GS showed no resistance to extension. Lines null for HMW-GS produced 'brick'-like bread. Tortilla prepared from the null lines had poor rollability and lower puncture force. The results showed very strong dependencies of quality on the presence of HMW-GS.     

Production and characterization of a transgenic bread wheat line over-expressing a low-molecular-weight glutenin subunit gene

The end-use properties, and thus the value, of wheat flours are determined to a large extent by the proteins that make up the polymeric network called gluten. Low molecular weight glutenin subunits (LMW-GS) are important components of gluten structure. Their relative amounts and/or the presence of specific components can influence dough visco-elasticity, a property that is correlated with the end-use properties of wheat flour. For these reasons, manipulation of gluten dough strength and elasticity is important. We are pursuing this goal by transforming the bread wheat cultivar Bobwhite with a LMW-GS gene driven by its own promoter. Particle bombardment of immature embryos produced several transgenic lines, one of which over-expressed the LMW-GS transgene. Southern blots confirmed that the transgene was integrated into the wheat genome, although segregation analyses showed that its expression was sometimes poorly transmitted to progeny. We have determined that the transgene-encoded LMW-GS accumulates to very high levels in seeds of this line, and that it is incorporated into the glutenin polymer, nearly doubling its overall amount. However, SDS sedimentation test values were lower from the transgenic material compared to a non transgenic flour. These results suggest that the widely accepted correlation between the amount of the glutenin polymers and flour technological properties might not be valid, depending on the components of the polymer.     

Role of the amino- and carboxy-terminal regions in the folding and oligomerization of wheat high molecular weight glutenin subunits

The high molecular weight glutenin subunits are considered one of the most important components of wheat (Triticum aestivum) gluten, but their structure and interactions with other gluten proteins are still unknown. Understanding the role of these proteins in gluten formation may be aided by analyses of the conformation and interactions of individual wild-type and modified subunits expressed in heterologous systems. In the present report, the bacterium Escherichia coli was used to synthesize four naturally occurring X- and Y-type wheat high molecular weight glutenin subunits of the Glu-1D locus, as well as four bipartite chimeras of these proteins. Naturally occurring subunits synthesized in the bacteria exhibited sodium dodecyl sulfate-polyacrylamide gel electrophoresis migration properties identical to those of high molecular weight glutenin subunits extracted from wheat grains. Wild-type and chimeric subunits migrated in sodium dodecyl sulfate gels differently than expected based on their molecular weights due to conformational properties of their N- and C-terminal regions. Results from cycles of reductive cleavage and oxidative reformation were consistent with the formation of both inter- and intramolecular disulfide bonds in patterns and proportions that differed among specific high molecular weight glutenin species. Comparison of the chimeric and wild-type proteins indicated that the two C-terminal cysteines of the Y-type subunits are linked by intramolecular disulfide bonds, suggesting that the role of these cysteines in glutenin polymerization may be limited.     

Modification of the Low Molecular Weight (LMW) Glutenin Composition of Transgenic Durum Wheat: Effects on Glutenin Polymer Size and Gluten Functionality

The low-molecular weight (LMW) glutenin subunits are major determinants of the viscoelasticity of durum wheat gluten, and therefore of its technological quality, with both quantitative effects and qualitative effects. We have modified the LMW glutenin subunit composition of the durum wheat cultivar Ofanto by expression of a transgene encoding a B-type LMW glutenin subunit and have carried out detailed analyses of two independent transformed lines in order to assess the effect of the transgene on the size distribution of the glutenin polymers and on their functional properties. In one line the expression of the transgene led to an increase in the amount of large glutenin polymers resulting in stronger and more stable dough. In the second line, however, the expression of the transgenic subunit was accompanied by decreased expression of endogenous LMW subunits with consequent detrimental effects on glutenin polymers and dough viscoelasticity. These results demonstrate that the LMW glutenin subunits contribute to the functional properties of wheat by influencing the amount and the distribution of glutenin polymers and indicate that either plant breeding or GM technology can be used to 'fine tune' the properties of durum wheat for different end uses by manipulating the amount and structures of individual LMW subunit proteins.     

小麦高分子量麦谷蛋白亚基序列及其结构与加工品质的关系

高分子量麦谷蛋白亚基（high molecular weight glutenin subunit,HMW-GS）是小麦种子贮藏蛋白的主要成分,其组成、含量和结构直接影响小麦面粉面筋的弹展性,决定着小麦的加工品质。本文主要对小麦HMW-GS的序列、结构和亚基之间组合形式做了详细的综述,并较系统地讨论了HMW-GS的结构和组成、特点等与面粉的加工品质之间的关系以及如何从定性和定量两方面来影响面粉的加工品质。     

水稻谷蛋白GluA-2基因在小麦胚乳中的表达(英文)

水稻(Oryza sativa L.)谷蛋白(Glutelin)约占水稻储藏蛋白总量的80％,谷蛋白赖氨酸含量较高并易于被人体消化吸收。为了提高小麦(Triticum aestivum L. )的营养品质,将水稻谷蛋白GluA-2基因的cDNA序列导入小麦栽培品种Bobwhite(T. aestivum cv. Bobwhite)。共轰击了600个小麦幼胚,经PCR和Southern杂交鉴定,共获得4棵转GluA-2基因小麦;SDS-PAGE分析表明,GluA-2基因在3棵转基因植株及其后代中表达,在1棵转基因植株中未表达,但其内源的高分子量麦谷蛋白亚基Bx7和By9含量显著降低,并且可遗传至T_代。     

A cysteine in the repetitive domain of a high-molecular-weight glutenin subunit interferes with the mixing properties of wheat dough

The quality of wheat (Triticum aestivum L.) for making bread is largely due to the strength and extensibility of wheat dough, which in turn is due to the properties of polymeric glutenin. Polymeric glutenin consists of high- and low-molecular-weight glutenin protein subunits linked by disulphide bonds between cysteine residues. Glutenin subunits differ in their effects on dough mixing properties. The research presented here investigated the effect of a specific, recently discovered, glutenin subunit on dough mixing properties. This subunit, Bx7.1, is unusual in that it has a cysteine in its repetitive domain. With site-directed mutagenesis of the gene encoding Bx7.1, a guanine in the repetitive domain was replaced by an adenine, to provide a mutant gene encoding a subunit (MutBx7.1) in which the repetitive-domain cysteine was replaced by a tyrosine residue. Bx7.1, MutBx7.1 and other Bx-type glutenin subunits were heterologously expressed in Escherichia coli and purified. This made it possible to incorporate each individual subunit into wheat flour and evaluate the effect of the cysteine residue on dough properties. The Bx7.1 subunit affected dough mixing properties differently from the other subunits. These differences are due to the extra cysteine residue, which may interfere with glutenin polymerisation through cross-linkage within the Bx7.1 subunit, causing this subunit to act as a chain terminator.