α-螺旋中 n→π* 相互作用的特征。
Signature of n→π* interactions in α-helices.
机构信息
Graduate Program in Biophysics, University of Wisconsin-Madison, Madison, Wisconsin 53706, USA.
出版信息
Protein Sci. 2011 Jun;20(6):1077-81. doi: 10.1002/pro.627. Epub 2011 Apr 26.
Abstract
The oxygen of a peptide bond has two lone pairs of electrons. One of these lone pairs is poised to interact with the electron-deficient carbon of the subsequent peptide bond in the chain. Any partial covalency that results from this n→π* interaction should induce pyramidalization of the carbon (C'(i)) toward the oxygen (O(i-1)). We searched for such pyramidalization in 14 peptides that contain both α- and β-amino acid residues and that assume a helical structure. We found that the α-amino acid residues, which adopt the main chain dihedral angles of an α-helix, display dramatic pyramidalization but the β-amino acid residues do not. Thus, we conclude that O(i-1) and C'(i) are linked by a partial covalent bond in α-helices. This finding has important ramifications for the folding and conformational stability of α-helices in isolation and in proteins.
摘要
肽键中的氧具有两对孤对电子。其中一对孤对电子准备与链中后续肽键的缺电子碳原子相互作用。这种 n→π*相互作用所产生的任何部分共价键合都应该诱导碳原子(C'(i))朝向氧(O(i-1))的金字塔化。我们在包含α-和β-氨基酸残基并采用螺旋结构的 14 个肽中寻找这种金字塔化。我们发现,采用α-螺旋主链二面角的α-氨基酸残基显示出明显的金字塔化,但β-氨基酸残基则没有。因此,我们得出结论,O(i-1)和 C'(i)在α-螺旋中通过部分共价键连接。这一发现对孤立和蛋白质中α-螺旋的折叠和构象稳定性具有重要意义。
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