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反平行β-折叠二级结构中长度依赖性稳定性和链长限制

Length-dependent stability and strand length limits in antiparallel beta -sheet secondary structure.

作者信息

Stanger H E, Syud F A, Espinosa J F, Giriat I, Muir T, Gellman S H

机构信息

Department of Chemistry, University of Wisconsin, Madison, WI 53706, USA.

出版信息

Proc Natl Acad Sci U S A. 2001 Oct 9;98(21):12015-20. doi: 10.1073/pnas.211536998. Epub 2001 Oct 2.

DOI:10.1073/pnas.211536998
PMID:11593011
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC59824/
Abstract

Designed peptides that fold autonomously to specific conformations in aqueous solution are useful for elucidating protein secondary structural preferences. For example, autonomously folding model systems have been essential for establishing the relationship between alpha-helix length and alpha-helix stability, which would be impossible to probe with alpha-helices embedded in folded proteins. Here, we use designed peptides to examine the effect of strand length on antiparallel beta-sheet stability. alpha-Helices become more stable as they grow longer. Our data show that a two-stranded beta-sheet ("beta-hairpin") becomes more stable when the strands are lengthened from five to seven residues, but that further strand lengthening to nine residues does not lead to further beta-hairpin stabilization for several extension sequences examined. (In one case, all-threonine extension, there may be an additional stabilization on strand lengthening from seven to nine residues.) These results suggest that there may be an intrinsic limit to strand length for most sequences in antiparallel beta-sheet secondary structure.

摘要

设计出的能在水溶液中自主折叠成特定构象的肽,对于阐明蛋白质二级结构偏好很有用。例如,自主折叠模型系统对于建立α-螺旋长度与α-螺旋稳定性之间的关系至关重要,而对于嵌入折叠蛋白中的α-螺旋进行探测则不可能做到这一点。在此,我们使用设计肽来研究链长度对反平行β-折叠稳定性的影响。α-螺旋随着长度增加而变得更稳定。我们的数据表明,当链从五个残基延长到七个残基时,双链β-折叠(“β-发夹”)变得更稳定,但对于所研究的几个延伸序列,链进一步延长到九个残基并不会导致β-发夹进一步稳定。(在一种情况即全苏氨酸延伸中,从七个残基延长到九个残基时链上可能存在额外的稳定性。)这些结果表明,对于反平行β-折叠二级结构中的大多数序列,链长度可能存在内在限制。

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