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构象缺陷减缓高尔基体输出、阻碍寡聚化并降低小窝蛋白-1突变蛋白的脂筏亲和力。

Conformational defects slow Golgi exit, block oligomerization, and reduce raft affinity of caveolin-1 mutant proteins.

作者信息

Ren Xiaoyan, Ostermeyer Anne G, Ramcharan Lynne T, Zeng Youchun, Lublin Douglas M, Brown Deborah A

机构信息

Department of Biochemistry and Cell Biology, State University of New York at Stony Brook, Stony Brook, NY 11794-5215, USA.

出版信息

Mol Biol Cell. 2004 Oct;15(10):4556-67. doi: 10.1091/mbc.e04-06-0480. Epub 2004 Aug 10.

DOI:10.1091/mbc.e04-06-0480
PMID:15304521
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC519149/
Abstract

Caveolin-1, a structural protein of caveolae, is cleared unusually slowly from the Golgi apparatus during biosynthetic transport. Furthermore, several caveolin-1 mutant proteins accumulate in the Golgi apparatus. We examined this behavior further in this mutant study. Golgi accumulation probably resulted from loss of Golgi exit information, not exposure of cryptic retention signals, because several deletion mutants accumulated in the Golgi apparatus. Alterations throughout the protein caused Golgi accumulation. Thus, most probably acted indirectly, by affecting overall conformation, rather than by disrupting specific Golgi exit motifs. Consistent with this idea, almost all the Golgi-localized mutant proteins failed to oligomerize normally (even with an intact oligomerization domain), and they showed reduced raft affinity in an in vitro detergent-insolubility assay. A few mutant proteins formed unstable oligomers that migrated unusually slowly on blue native gels. Only one mutant protein, which lacked the first half of the N-terminal hydrophilic domain, accumulated in the Golgi apparatus despite normal oligomerization and raft association. These results suggested that transport of caveolin-1 through the Golgi apparatus is unusually difficult. The conformation of caveolin-1 may be optimized to overcome this difficulty, but remain very sensitive to mutation. Disrupting conformation can coordinately affect oligomerization, raft affinity, and Golgi exit of caveolin-1.

摘要

小窝蛋白-1是一种小窝的结构蛋白,在生物合成运输过程中从高尔基体清除的速度异常缓慢。此外,几种小窝蛋白-1突变蛋白在高尔基体中积累。我们在这项突变研究中进一步研究了这种行为。高尔基体积累可能是由于高尔基体输出信息的丧失,而不是隐匿性保留信号的暴露,因为几种缺失突变体在高尔基体中积累。蛋白质整体的改变导致了高尔基体积累。因此,最有可能是通过影响整体构象间接起作用,而不是通过破坏特定的高尔基体输出基序。与此观点一致的是,几乎所有定位于高尔基体的突变蛋白都不能正常寡聚(即使具有完整的寡聚结构域),并且在体外去污剂不溶性测定中它们显示出降低的脂筏亲和力。一些突变蛋白形成不稳定的寡聚体,在蓝色非变性凝胶上迁移异常缓慢。只有一种突变蛋白,它缺少N端亲水区的前半部分,尽管寡聚正常且与脂筏相关,但仍在高尔基体中积累。这些结果表明小窝蛋白-1通过高尔基体的运输异常困难。小窝蛋白-1的构象可能经过优化以克服这一困难,但对突变仍非常敏感。破坏构象可协同影响小窝蛋白-1的寡聚、脂筏亲和力和高尔基体输出。

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