Bioinformatics Center, Institute for Chemical Research, Kyoto University, Uji, Kyoto 611-0011 Japan.
Nucleic Acids Res. 2011 Jul;39(13):5526-37. doi: 10.1093/nar/gkr154. Epub 2011 Mar 29.
Ras proteins control many aspects of eukaryotic cell homeostasis by switching between active (GTP-bound) and inactive (GDP-bound) conformations, a reaction catalyzed by GTPase exchange factors (GEF) and GTPase activating proteins (GAP) regulators, respectively. Here, we show that the complexity, measured as number of genes, of the canonical Ras switch genetic system (including Ras, RasGEF, RasGAP and RapGAP families) from 24 eukaryotic organisms is correlated with their genome size and is inversely correlated to their evolutionary distances from humans. Moreover, different gene subfamilies within the Ras switch have contributed unevenly to the module's expansion and speciation processes during eukaryote evolution. The Ras system remarkably reduced its genetic expansion after the split of the Euteleostomi clade and presently looks practically crystallized in mammals. Supporting evidence points to gene duplication as the predominant mechanism generating functional diversity in the Ras system, stressing the leading role of gene duplication in the Ras family expansion. Domain fusion and alternative splicing are significant sources of functional diversity in the GAP and GEF families but their contribution is limited in the Ras family. An evolutionary model of the Ras system expansion is proposed suggesting an inherent 'decision making' topology with the GEF input signal integrated by a homologous molecular mechanism and bifurcation in GAP signaling propagation.
Ras 蛋白通过在活性(GTP 结合)和非活性(GDP 结合)构象之间转换来控制真核细胞内稳态的许多方面,该反应分别由 GTP 酶交换因子(GEF)和 GTP 酶激活蛋白(GAP)调节剂催化。在这里,我们表明,来自 24 种真核生物的经典 Ras 开关遗传系统(包括 Ras、RasGEF、RasGAP 和 RapGAP 家族)的复杂性(以基因数量衡量)与其基因组大小相关,并且与它们与人类的进化距离成反比。此外,Ras 开关内的不同基因亚家族在真核生物进化过程中对模块的扩展和物种形成过程的贡献不均等。Ras 系统在 Euteleostomi 分支分裂后显著减少了其遗传扩展,目前在哺乳动物中几乎呈现出实际的结晶状态。支持证据表明基因复制是 Ras 系统产生功能多样性的主要机制,强调了基因复制在 Ras 家族扩展中的主导作用。结构域融合和选择性剪接是 GAP 和 GEF 家族中功能多样性的重要来源,但在 Ras 家族中的贡献有限。提出了 Ras 系统扩展的进化模型,该模型提出了一种固有“决策制定”拓扑结构,其中 GEF 输入信号通过同源分子机制集成,并且 GAP 信号传递发生分支。
