Gross M
Oxford Centre for Molecular Sciences, University of Oxford, New Chemistry Laboratory, Oxford, OX1 3QT, UK.
Curr Protein Pept Sci. 2000 Dec;1(4):339-47. doi: 10.2174/1389203003381289.
The sequence of a protein normally determines which amino acid residues will form alpha helices, and which one beta sheets, to an extent that allows secondary structure prediction to be made with a reasonable reliability. Nevertheless, non-native helical structures are observed during in vitro folding of several model proteins and may even occur during protein biosynthesis within the ribosomal exit tunnel. Moreover, non-native beta sheet structures are common in amyloid fibrils formed by a variety of pathogenic and even non-pathogenic proteins and peptides. In all of these cases, the formation of alpha helix precedes the appearance of beta sheet, which suggests that conversion from the simpler, more local helix structure to the often more convoluted sheet architecture during folding and pathogenic misfolding processes could be a unifying principle of general importance. A better understanding of this switching process, and the ability to design molecular systems which can be induced to switch between these conformations will have a significant impact on fields ranging from fundamental biochemistry through to applied technology and medicine.
蛋白质的序列通常在一定程度上决定哪些氨基酸残基会形成α螺旋,哪些会形成β折叠,从而使二级结构预测具有合理的可靠性。然而,在几种模型蛋白的体外折叠过程中会观察到非天然螺旋结构,甚至在核糖体出口通道内的蛋白质生物合成过程中也可能出现。此外,非天然β折叠结构在由多种致病甚至非致病蛋白质和肽形成的淀粉样纤维中很常见。在所有这些情况下,α螺旋的形成先于β折叠的出现,这表明在折叠和致病性错误折叠过程中,从更简单、更局部的螺旋结构转变为通常更复杂的折叠结构可能是一个具有普遍重要性的统一原则。更好地理解这种转换过程,以及设计能够被诱导在这些构象之间转换的分子系统的能力,将对从基础生物化学到应用技术和医学等领域产生重大影响。