主要作物蜡质基因型起源与发展的分子研究

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Vikram S Gaur, Salej Sood, Carlos Guzmán, Kenneth M Olsen
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引用次数: 0

摘要

淀粉是种子胚乳的重要成分,在食品和工业上具有重要的商业意义。具有糯(蜡)粒特征的作物品种,即具有高支链淀粉和低直链淀粉的淀粉,在世界一些地区具有长期的文化重要性,并具有工业生产的独特特性。许多作物的蜡质性状是由一个被称为GBSSI(或蜡质)的基因调控的,该基因编码的颗粒结合淀粉合成酶1活性为零或降低。蜡质基因的几个等位变异导致不同水平的直链淀粉含量已在不同的作物植物中报道。对主要谷物以及最近对小米和伪谷物进行测序的蛋白质序列和编码GBSSI的基因组DNA的系统发育分析表明,GBSSI同源物形成不同的簇,每个簇代表一个单独的作物谱系。随着食品和非食品领域对蜡质淀粉需求的迅速增加,传统的作物育种技术和基因沉默、基因组编辑等现代作物改良技术已被用于开发新的蜡质作物品种。不同作物间蜡质等位基因的研究进展揭示了改变直链淀粉和支链淀粉合成的新可能性,从而有可能在未来创造定制作物。本文介绍了各种作物中蜡质基因出现的分子谱证据,包括蜡质基因的发生进化、分子结构、比较分析和育种创新。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Molecular insights on the origin and development of waxy genotypes in major crop plants.

Starch is a significant ingredient of the seed endosperm with commercial importance in food and industry. Crop varieties with glutinous (waxy) grain characteristics, i.e. starch with high amylopectin and low amylose, hold longstanding cultural importance in some world regions and unique properties for industrial manufacture. The waxy character in many crop species is regulated by a single gene known as GBSSI (or waxy), which encodes the enzyme Granule Bound Starch Synthase1 with null or reduced activity. Several allelic variants of the waxy gene that contribute to varying levels of amylose content have been reported in different crop plants. Phylogenetic analysis of protein sequences and the genomic DNA encoding GBSSI of major cereals and recently sequenced millets and pseudo-cereals have shown that GBSSI orthologs form distinct clusters, each representing a separate crop lineage. With the rapidly increasing demand for waxy starch in food and non-food applications, conventional crop breeding techniques and modern crop improvement technologies such as gene silencing and genome editing have been deployed to develop new waxy crop cultivars. The advances in research on waxy alleles across different crops have unveiled new possibilities for modifying the synthesis of amylose and amylopectin starch, leading to the potential creation of customized crops in the future. This article presents molecular lines of evidence on the emergence of waxy genes in various crops, including their genesis and evolution, molecular structure, comparative analysis and breeding innovations.

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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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