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介导高尔基体堆栈内运输的两种不同SNARE复合体的逆流分布。

Countercurrent distribution of two distinct SNARE complexes mediating transport within the Golgi stack.

作者信息

Volchuk Allen, Ravazzola Mariella, Perrelet Alain, Eng William S, Di Liberto Maurizio, Varlamov Oleg, Fukasawa Masayoshi, Engel Thomas, Söllner Thomas H, Rothman James E, Orci Lelio

机构信息

Department of Morphology, University of Geneva Medical School, Geneva, Switzerland.

出版信息

Mol Biol Cell. 2004 Apr;15(4):1506-18. doi: 10.1091/mbc.e03-08-0625. Epub 2004 Jan 23.

DOI:10.1091/mbc.e03-08-0625
PMID:14742712
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC379251/
Abstract

Genetic and biochemical evidence has established that a SNARE complex consisting of syntaxin 5 (Sed5)-mYkt6 (Ykt6)-GOS28 (Gos1)-GS15 (Sft1) is required for transport of proteins across the Golgi stack in animals (yeast). We have utilized quantitative immunogold labeling to establish the cis-trans distribution of the v-SNARE GS15 and the t-SNARE subunits GOS28 and syntaxin 5. Whereas the distribution of the t-SNARE is nearly even across the Golgi stack from the cis to the trans side, the v-SNARE GS15 is present in a gradient of increasing concentration toward the trans face of the stack. This contrasts with a second distinct SNARE complex, also required for intra-Golgi transport, consisting of syntaxin 5 (Sed5)-membrin (Bos1)-ERS24 (Sec22)-rBet1 (Bet1), whose v-(rBet1) and t-SNARE subunits (membrin and ERS24), progressively decrease in concentration toward the trans face. Transport within the stack therefore appears to utilize countercurrent gradients of two Golgi SNAREpins and may involve a mechanism akin to homotypic fusion.

摘要

遗传学和生物化学证据表明,在动物(酵母)中,由Syntaxin 5(Sed5)-mYkt6(Ykt6)-GOS28(Gos1)-GS15(Sft1)组成的SNARE复合体是蛋白质跨高尔基体转运所必需的。我们利用定量免疫金标记法确定了v-SNARE GS15以及t-SNARE亚基GOS28和Syntaxin 5在顺式-反式方向上的分布。t-SNARE在从顺式面到反式面的整个高尔基体堆栈中的分布几乎是均匀的,而v-SNARE GS15则以浓度梯度的形式存在,朝着堆栈的反式面浓度逐渐增加。这与另一种不同的SNARE复合体形成对比,该复合体也是高尔基体内部运输所必需的,由Syntaxin 5(Sed5)-membrin(Bos1)-ERS24(Sec22)-rBet1(Bet1)组成,其v-SNARE亚基(rBet1)和t-SNARE亚基(membrin和ERS24)的浓度朝着反式面逐渐降低。因此,堆栈内的运输似乎利用了两种高尔基体SNAREpin的逆流梯度,并且可能涉及一种类似于同型融合的机制。

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