等长张力下蛋白质的解折叠——整合素能产生何种力,它能使III型纤连蛋白结构域解折叠吗?
Protein unfolding under isometric tension-what force can integrins generate, and can it unfold FNIII domains?
作者信息
Erickson Harold P
机构信息
Department of Cell Biology, Duke University Medical Center, Durham, NC 27710, USA.
出版信息
Curr Opin Struct Biol. 2017 Feb;42:98-105. doi: 10.1016/j.sbi.2016.12.002. Epub 2016 Dec 27.
Abstract
Extracellular matrix fibrils of fibronectin (FN) are highly elastic, and are typically stretched three to four times their relaxed length. The mechanism of stretching has been controversial, in particular whether it involves tension-induced unfolding of FNIII domains. Recent studies have found that ∼5pN is the threshold isometric force for unfolding various protein domains. FNIII domains should therefore not be unfolded until the tension approaches 5pN. Integrins have been reported to generate forces ranging from 1 to >50pN, but I argue that studies reporting 1-2pN are the most convincing. This is not enough to unfold FNIII domains. Even if domains were unfolded, 2pN would only extend the worm-like-chain to about twice the length of the folded domain. Overall I conclude that stretching FN matrix fibrils involves primarily the compact to extended conformational change of FN dimers, with minimal contribution from unfolding FNIII domains.
摘要
纤连蛋白(FN)的细胞外基质纤维具有高度弹性,通常会被拉伸至其松弛长度的三到四倍。拉伸机制一直存在争议,特别是其是否涉及张力诱导的FNIII结构域展开。最近的研究发现,约5皮牛是展开各种蛋白质结构域的等长力阈值。因此,在张力接近5皮牛之前,FNIII结构域不应展开。据报道,整合素产生的力范围为1至>50皮牛,但我认为报告1-2皮牛的研究最具说服力。这不足以展开FNIII结构域。即使结构域展开,2皮牛也只会将类蠕虫链延伸至折叠结构域长度的约两倍。总体而言,我得出结论,拉伸FN基质纤维主要涉及FN二聚体从紧密构象到伸展构象的变化,FNIII结构域展开的贡献最小。
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