Department of General Chemistry, Belarussian State Medical University, Dzerzinskogo, 83, Minsk, Belarus.
Biochimie. 2013 Sep;95(9):1745-54. doi: 10.1016/j.biochi.2013.05.014. Epub 2013 Jun 10.
In this study we classified regions of random coil into four types: coil between alpha helix and beta strand, coil between beta strand and alpha helix, coil between two alpha helices and coil between two beta strands. This classification may be considered as natural. We used 610 3D structures of proteins collected from the Protein Data Bank from bacteria with low, average and high genomic GC-content. Relatively short regions of coil are not random: certain amino acid residues are more or less frequent in each of the types of coil. Namely, hydrophobic amino acids with branched side chains (Ile, Val and Leu) are rare in coil between two beta strands, unlike some acrophilic amino acids (Asp, Asn and Gly). In contrast, coil between two alpha helices is enriched by Leu. Regions of coil between alpha helix and beta strand are enriched by positively charged amino acids (Arg and Lys), while the usage of residues with side chains possessing hydroxyl group (Ser and Thr) is low in them, in contrast to the regions of coil between beta strand and alpha helix. Regions of coil between beta strand and alpha helix are significantly enriched by Cys residues. The response to the symmetric mutational pressure (AT-pressure or GC-pressure) is also quite different for four types of coil. The most conserved regions of coil are "connecting bridges" between beta strand and alpha helix, since their amino acid content shows less strong dependence on GC-content of genes than amino acid contents of other three types of coil. Possible causes and consequences of the described differences in amino acid content distribution between different types of random coil have been discussed.
在这项研究中,我们将无规卷曲区域分为四种类型:α 螺旋和β 折叠之间的无规卷曲、β 折叠和α 螺旋之间的无规卷曲、两个α 螺旋之间的无规卷曲和两个β 折叠之间的无规卷曲。这种分类可以被认为是自然的。我们使用了来自低、中、高基因组 GC 含量细菌的蛋白质数据库中收集的 610 个 3D 结构。相对较短的无规卷曲区域并不是随机的:在每种无规卷曲类型中,某些氨基酸残基或多或少地频繁出现。即,具有支链侧链的疏水性氨基酸(Ile、Val 和 Leu)在两个β 折叠之间的无规卷曲中很少见,而一些亲水性氨基酸(Asp、Asn 和 Gly)则不然。相比之下,两个α 螺旋之间的无规卷曲富含 Leu。α 螺旋和β 折叠之间的无规卷曲区域富含带正电荷的氨基酸(Arg 和 Lys),而侧链带有羟基的残基(Ser 和 Thr)的使用频率较低,与β 折叠和α 螺旋之间的无规卷曲区域形成对比。β 折叠和α 螺旋之间的无规卷曲区域富含 Cys 残基。四种无规卷曲类型对对称突变压力(AT 压力或 GC 压力)的响应也有很大的不同。无规卷曲最保守的区域是β 折叠和α 螺旋之间的“连接桥”,因为它们的氨基酸含量对基因 GC 含量的依赖性比其他三种无规卷曲类型的氨基酸含量弱。讨论了描述的不同类型无规卷曲之间氨基酸含量分布差异的可能原因和后果。
