植物支链淀粉合成的关键酶—淀粉分支酶

支链淀粉是植物淀粉的主要成分,而淀粉分酶支酶是其合成的关键酶。开展对该酶的深入研究不论是在基因理论研究领域还是在实现应用方面都具重要意义。     

水稻胚乳中淀粉合成相关酶活性的变化对支链淀粉精细结构的影响

分析了水稻（Oryza sativa L．）籽粒发育过程淀粉生物合成途径中的关键酶——ADP-葡萄糖焦磷酸化酶、可溶性淀粉合酶、淀粉分支酶以及淀粉脱支酶活性变化,同时研究了淀粉结构形成动态．与野生型晚粳9522相比,转基因晚粳9522中直链淀粉的合成被显著抑制,而总淀粉含量和籽粒终重量没有改变．淀粉生物合成途径中关键酶活性表达时间不一致,存在明显的时段特征,这与淀粉积累动态密切相关．可溶性淀粉合酶活性表达最早,其在灌浆前期驱动淀粉合成起始;而淀粉粒结合态淀粉合酶在胚乳发育的中期活性最大．两水稻实验材料间,除淀粉脱支酶活性变化有所不同外,ADP-葡萄糖焦磷酸化酶和淀粉分支酶活性的变化没有明显差异．并且,支链淀粉的分支模式在水稻籽粒发育过程中变化较大,且与品种有关．以上结果揭示,支链淀粉的合成要先于直链淀粉,并且在控制支链淀粉各分支的形成过程中有不同的酶在起特异的作用．     

植物支链淀粉合成的关键酶——淀粉分支酶

支链淀粉是植物淀粉的主要成分,而淀粉分支酶是其合成的关键酶。淀粉分支酶可分为两同形体家族,本文从酶学特性、染色体定位、基因及基因表达方面阐明了它们之间的联系和区别,并证实不同同形体在植物支链淀粉合成和结构决定上所起作用不同。开展对该酶的深入研究不论是在基础理论研究领域还是在现实应用方面都具重要意义。     

小麦籽粒淀粉分支酶遗传多样性及对支链淀粉含量的影响

采用非变性聚丙烯酰胺凝胶电泳,对90份小麦品种的淀粉分支酶同工酶(SBE)进行检测,以分析不同基因型对支链淀粉含量的遗传效应.结果表明:(1)SBEⅠ型显现出较为丰富的变异,具有A、B、Dⅰ和Dⅱ4个等位基因位点;SBEⅡ型仅具有SBEⅡa单一等位基因位点.根据SBEⅠ型4个基因位点在不同品种中的分布,可将90个品种分为7种基因型.不同基因型对支链淀粉含量的遗传效应分析表明,含有A位点的基因型(ADⅰDⅱ和ADⅰB)所对应的支链淀粉含量较高,且与由1个基因位点组成的基因型(Dⅰ)和2个基因位点组成的基因型(DⅰB和DⅰDⅱ)的支链淀粉含量差异显著.     

淀粉合酶的酶学与分子生物学研究进展

淀粉合酶作为淀粉合成的关键酶之一,一直是淀粉研究的重要内容,这些研究多集中在对其同工型的研究,淀粉合酶的两类主要同工型分别为淀粉粒结合的淀粉合酶和可溶性淀粉合酶,这两类同工型的作用极为复杂,本文介绍了淀粉合酶同工型的酶学和分子生物学近年来的研究进展,同时也讨论了这些同工型的分类,相互关系及其在淀粉合成过程中的生理功能等内容。     

淀粉合酶的酶学与分子生物学研究进展

淀粉合酶作为淀粉合成的关键酶之一,一直是淀粉研究的重要内容。这些研究多集中在对其同工型的研究,淀粉合酶的两类主要同工型分别为淀粉粒结合的淀粉合酶和可溶性淀粉合酶,这两类同工型的作用极为复杂。本文介绍了淀粉合酶同工型的酶学和分子生物学近年来的研究进展,同时也讨论了这些同工型的分类、相互关系及其在淀粉合成过程中的生理功能等内容。     

淀粉的生物合成及其关键酶

介绍了淀粉的生物合成途径及其关键酶的最新研究进展。     

萌发中食松幼苗淀粉合酶同工酶与淀粉成分的关系

利用14C－ADPG标定法测定可溶性及与淀粉粒结合的淀粉合酶活性,采用过氯酸抽提、DMSO玻璃纤维纸层析、硫酸水解法定量测定各类淀粉成分,探讨了食松（PinusedulisEngelm）幼苗生长过程中淀粉合酶与淀粉成分间的关系。结果表明,在胚根出现以后,淀粉含量迅速增加,伴随着淀粉颗粒数目和质量的增加,两类淀粉合酶活性的增加以及淀粉合酶免疫印迹图谱的变化。支链淀粉是食松淀粉的主要成分,占总淀粉的84％。可溶性淀粉合酶峰值比淀粉粒结合的淀粉合酶活性峰值高1．3倍,与支链淀粉和直链淀粉的比例相对应。结果支持食松可溶性淀粉合酶是负责支链淀粉合成的主要酶的假说,同时表明淀粉粒结合的淀粉合酶在支链淀粉的合成中也有作用。     

应用RNA干扰技术降低玉米支链淀粉含量

为了调控玉米淀粉的生物合成过程,克隆了玉米淀粉分支酶(starch branching enzymes,SBE)基因,构建高效的siRNA表达体系,通过花粉管通道法将其导入玉米自交系.PCR扩增和Southern杂交结果证明,目的基因已被整合到基因组中,且能够遗传.Northern杂交分析表明,该目的基因在转基因植株中能正常转录并导致内源SBE mRNA含量下降.对转基因植株淀粉分支酶活性和淀粉含量测定结果表明,分支酶活性明显地低于对照,相差最多的低85%;总淀粉含量与对照之间基本没有差异,但直链淀粉的含量提高了约50%.     

Effects of the activities of key enzymes involved in starch biosynthesis on the fine structure of amylopectin in developing rice (Oryza sativa L.) endosperms

The dynamic changes of the activities of enzymes involving in starch biosynthesis, including ADP-glucose pyrophosphorylase (AGPase), soluble starch synthases (SSS), starch branching enzyme (SBE) and starch debranching enzymes (DBE) were studied, and changes of fine structure of amy- lopectin were characterized by isoamylase treatment during rice grain development, using trans anti-waxy gene rice plants. The relationships between the activities of those key enzymes were also analyzed. The amylose synthesis was significantly inhibited in transgenic Wanjing 9522, but the total starch content and final grain weight were less affected as compared with those of non-transgenic Wanjing 9522 rice cultivar. Analyses on the changes of activities of enzymes involving in starch bio- synthesis showed that different enzyme activities were expressed differently during rice endosperm development. Soluble starch synthase is relatively highly expressed in earlier stage of endosperm de- velopment, whilst maximal expression of granule-bound starch synthase (GBSS) occurred in mid-stage of endosperm development. No obvious differences in changes of the activities of AGPase and SBE between two rice cultivars investigated, except the DBEs. Distribution patterns of branches of amy- lopectin changed continually during the development of rice grains and varied between two rice culti- vars. It was suggested that amylopectin synthesis be prior to the synthesis of amylose and different enzymes have different roles in controlling syntheses of branches of amylopectin.     

禾谷类作物胚乳的淀粉合成

禾谷类作物胚乳拥有独特的淀粉合成途径,需要多种特异性同工酶的参与,这些酶在禾谷类其他组织或非禾谷类作物中是不存在的。近来明确了单个淀粉同工酶的功能,这有助于我们更深入地了解禾谷类淀粉直链、支链的合成与分布。在对禾谷类淀粉合成进行遗传分析的基础上,提出了脱分支酶作用模型。以水稻全基因组序列草图为背景,本文首次全面分析了禾谷类作物的淀粉合成。     

Progress in understanding the biosynthesis of amylose

The storage of glucose in insoluble granules is a distinctive feature of plant cells. Biosynthesis of amylose, the minor low molecular mass fraction of starch occurs from ADP-glucose. This takes place within the polysaccharide matrix through the action of granule-bound starch synthase, the major protein associated with the granule. Recently, amylose has been successfully synthesized in vitro from purified granules. Two models have been proposed to explain the mechanism of amylose synthesis in plants. The first calls for priming of synthesis through small-size malto-oligosaccharides. The second suggests that glucans are extended by granule-bound starch synthase from a high molecular mass primer present within the granule. This extension is terminated through cleavage to produce amylose. This process is subsequently repeated to give several rounds of amylose synthesis.     

The structure of starch can be manipulated by changing the expression levels of starch branching enzyme IIb in rice endosperm

When the starch branching enzyme IIb (BEIIb) gene was introduced into a BEIIb-defective mutant, the resulting transgenic rice plants showed a wide range of BEIIb activity and the fine structure of their amylopectins showed considerable variation despite having the two other BE isoforms, BEI and BEIIa, in their endosperm at the same levels as in the wild-type. The properties of the starch granules, such as their gelatinization behaviour, morphology and X-ray diffraction pattern, also changed dramatically depending on the level of BEIIb activity, even when this was either slightly lower or higher than that of the wild-type. The over-expression of BEIIb resulted in the accumulation of excessive branched, water-soluble polysaccharides instead of amylopectin. These results imply that the manipulation of BEIIb activity is an effective strategy for the generation of novel starches for use in foodstuffs and industrial applications.     

水稻sbe1启动子驱动的反义sbe-GUS融合基因在转基因水稻中的表达

为研究水稻基因启动子对外源基因在转基因水稻中表达的影响,构建了由sbe1启动子引导的反义sbe-GUS融合基因。经农杆菌介导,将不同的融合基因导入水稻中,定量测定转基因水稻植株不同组织中的GUS酶活力。结果表明,sbe1启动子可驱动反义sbe-GUS融合基因在转基因水稻植株的胚乳中高效表达,而在颖壳、胚和茎叶等组织中的表达活性较弱。证实sbe1启动子在驱动外源基因的表达上表现有明显的组织特异性。     

Creation of a potato mutant lacking the starch branching enzyme gene StSBE3 that was generated by genome editing using the CRISPR/dMac3-Cas9 system

The potato tuber starch trait is changed depending on the composition of amylose and amylopectin. The amount of amylopectin is determined by the activity of the starch branching enzymes SBE1, SBE2, and SBE3 in potato. SBE3, a homolog of rice BEI, is a major gene that is abundant in tubers. In this study, we created mutants of the potato SBE3 gene using CRISPR/Cas9 attached to the translation enhancer dMac3. Potato has a tetraploid genome, and a four-allele mutant of the SBE3 gene is desired. Mutations in the SBE3 gene were found in 89 of 126 transformants of potato plants. Among these mutants, 10 lines contained four mutant SBE3 genes, indicating that 8% efficiency of target mutagenesis was achieved. These mutants grew normally, similar to the wild-type plant, and yielded sufficient amounts of tubers. The potato starch in these tubers was similar to that of the rice BEI mutant. Western blot analysis revealed the defective production of SBE3 in the mutant tubers, suggesting that these transformants were loss-of-function mutants of SBE3.