Department of Biochemistry and Molecular Medicine, Robert-Cedergren Centre for Bioinformatics and Genomics, Université de Montréal, Montreal, Quebec, Canada.
Department of Biochemistry and Molecular Biology, Centre for Comparative Genomics and Evolutionary Bioinformatics, Dalhousie University, Halifax, Nova Scotia, Canada.
Mol Biol Evol. 2021 Mar 9;38(3):788-804. doi: 10.1093/molbev/msaa223.
The mitoribosome, as known from studies in model organisms, deviates considerably from its ancestor, the bacterial ribosome. Deviations include substantial reduction of the mitochondrial ribosomal RNA (mt-rRNA) structure and acquisition of numerous mitochondrion-specific (M) mitoribosomal proteins (mtRPs). A broadly accepted view assumes that M-mtRPs compensate for structural destabilization of mt-rRNA resulting from its evolutionary remodeling. Since most experimental information on mitoribosome makeup comes from eukaryotes having derived mitochondrial genomes and mt-rRNAs, we tested this assumption by investigating the mitochondrial translation machinery of jakobids, a lineage of unicellular protists with the most bacteria-like mitochondrial genomes. We report here proteomics analyses of the Andalucia godoyi small mitoribosomal subunit and in silico transcriptomic and comparative genome analyses of four additional jakobids. Jakobids have mt-rRNA structures that minimally differ from their bacterial counterparts. Yet, with at least 31 small subunit and 44 large subunit mtRPs, the mitoriboproteome of Andalucia is essentially as complex as that in animals or fungi. Furthermore, the relatively high conservation of jakobid sequences has helped to clarify the identity of several mtRPs, previously considered to be lineage-specific, as divergent homologs of conserved M-mtRPs, notably mS22 and mL61. The coexistence of bacteria-like mt-rRNAs and a complex mitoriboproteome refutes the view that M-mtRPs were ancestrally recruited to stabilize deviations of mt-rRNA structural elements. We postulate instead that the numerous M-mtRPs acquired in the last eukaryotic common ancestor allowed mt-rRNAs to pursue a broad range of evolutionary trajectories across lineages: from dramatic reduction to acquisition of novel elements to structural conservatism.
线粒体核糖体,正如在模式生物研究中所发现的,与它的祖先细菌核糖体有很大的不同。这种差异包括线粒体核糖体 RNA(mt-rRNA)结构的大量减少和获得许多线粒体特异的(M)线粒体核糖体蛋白(mtRPs)。一个被广泛接受的观点是,M-mtRPs 补偿了 mt-rRNA 因进化重塑而导致的结构不稳定。由于大多数关于线粒体核糖体组成的实验信息来自于具有衍生线粒体基因组和 mt-rRNAs 的真核生物,我们通过研究单细胞原生动物 jakobids 的线粒体翻译机制来检验这个假设,jakobids 的线粒体基因组与细菌最为相似。我们在这里报告了对 Andalucia godoyi 小线粒体核糖体亚基的蛋白质组学分析,以及对另外四个 jakobids 的转录组学和比较基因组学的分析。Jakobids 的 mt-rRNA 结构与细菌的 mt-rRNA 结构最小程度上有所不同。然而,Andalucia 的小亚基和大亚基 mtRPs 至少有 31 个和 44 个,线粒体核糖体蛋白组与动物或真菌基本相同。此外,jakobid 序列的相对高度保守有助于澄清几个先前被认为是谱系特异性的 mtRPs 的身份,如保守的 M-mtRPs 的 diverged同源物,特别是 mS22 和 mL61。具有细菌样 mt-rRNA 和复杂的线粒体核糖体蛋白组的共存反驳了 M-mtRPs 是为了稳定 mt-rRNA 结构元件的偏离而从祖先招募的观点。我们假设,在最后的真核生物共同祖先中获得的大量 M-mtRPs 允许 mt-rRNAs 在谱系中追求广泛的进化轨迹:从剧烈减少到获得新的元素到结构保守性。
