AXY8 编码一种α-岩藻糖苷酶,突出了质外体代谢对拟南芥细胞壁多糖精细结构的重要性。
AXY8 encodes an α-fucosidase, underscoring the importance of apoplastic metabolism on the fine structure of Arabidopsis cell wall polysaccharides.
机构信息
University of California, Berkeley, California, 94720, USA.
出版信息
Plant Cell. 2011 Nov;23(11):4025-40. doi: 10.1105/tpc.111.089193. Epub 2011 Nov 11.
Abstract
An Arabidopsis thaliana mutant with an altered structure of its hemicellulose xyloglucan (XyG; axy-8) identified by a forward genetic screen facilitating oligosaccharide mass profiling was characterized. axy8 exhibits increased XyG fucosylation and the occurrence of XyG fragments not present in the wild-type plant. AXY8 was identified to encode an α-fucosidase acting on XyG that was previously designated FUC95A. Green fluorescent protein fusion localization studies and analysis of nascent XyG in microsomal preparations demonstrated that this glycosylhydrolase acts mainly on XyG in the apoplast. Detailed structural analysis of XyG in axy8 gave unique insights into the role of the fucosidase in XyG metabolism in vivo. The genetic evidence indicates that the activity of glycosylhydrolases in the apoplast plays a major role in generating the heterogeneity of XyG side chains in the wall. Furthermore, without the dominant apoplastic glycosylhydrolases, the XyG structure in the wall is mainly composed of XXXG and XXFG subunits.
摘要
通过正向遗传学筛选促进寡糖质量分析,鉴定了一个拟南芥突变体,其半纤维素木葡聚糖(XyG;axy-8)的结构发生了改变。axy8 表现出 XyG 岩藻糖基化增加,以及在野生型植物中不存在的 XyG 片段的出现。AXY8 被鉴定为编码作用于 XyG 的α-岩藻糖苷酶,该酶先前被指定为 FUC95A。绿色荧光蛋白融合定位研究和对微粒体制剂中新生 XyG 的分析表明,这种糖苷水解酶主要作用于质外体中的 XyG。对 axy8 中 XyG 的详细结构分析深入了解了该岩藻糖苷酶在体内 XyG 代谢中的作用。遗传证据表明,质外体中糖苷水解酶的活性在产生细胞壁中 XyG 侧链的异质性方面起着主要作用。此外,没有显性质外体糖苷水解酶,细胞壁中的 XyG 结构主要由 XXXG 和 XXFG 亚基组成。
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