Department of Biology, Indiana University, Bloomington, IN 47405, USA.
Proc Natl Acad Sci U S A. 2013 Jul 23;110(30):E2821-8. doi: 10.1073/pnas.1310980110. Epub 2013 Jul 8.
One of the most striking features of proteins is their common assembly into multimeric structures, usually homomers with even numbers of subunits all derived from the same genetic locus. However, although substantial structural variation for orthologous proteins exists within and among major phylogenetic lineages, in striking contrast to patterns of gene structure and genome organization, there appears to be no correlation between the level of protein structural complexity and organismal complexity. In addition, there is no evidence that protein architectural differences are driven by lineage-specific differences in selective pressures. Here, it is suggested that variation in the multimeric states of proteins can readily arise from stochastic transitions resulting from the joint processes of mutation and random genetic drift, even in the face of constant directional selection for one particular protein architecture across all lineages. Under the proposed hypothesis, on a long evolutionary timescale, the numbers of transitions from monomers to dimers should approximate the numbers in the opposite direction and similarly for transitions between higher-order structures.
蛋白质最显著的特征之一是它们通常会组装成多聚体结构,通常是由相同遗传基因座产生的偶数个亚基组成的同聚物。然而,尽管在主要的系统发育谱系内和谱系之间同源蛋白存在大量的结构变异,但与基因结构和基因组组织的模式形成鲜明对比的是,蛋白质结构复杂性与生物体复杂性之间似乎没有相关性。此外,没有证据表明蛋白质结构差异是由谱系特异性选择压力驱动的。在这里,有人提出,即使在所有谱系中对一种特定的蛋白质结构都存在持续的定向选择,蛋白质的多聚状态的变化也可以很容易地从突变和随机遗传漂变的联合过程中产生的随机跃迁中产生。在提出的假设下,在很长的进化时间尺度上,从单体到二聚体的跃迁次数应该近似于相反方向的跃迁次数,并且对于更高阶结构之间的跃迁也是如此。