Chase H Smith, Raquel Mejia-Trujillo, Justin C Havird
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引用次数: 0
Abstract
Mitonuclear coevolution is common in eukaryotes, but bivalve lineages that have doubly uniparental inheritance (DUI) of mitochondria may be an interesting example. In this system, females transmit mtDNA (F mtDNA) to all offspring, while males transmit a different mtDNA (M mtDNA) solely to their sons. Molecular evolution and functional data suggest oxidative phosphorylation (OXPHOS) genes encoded in M mtDNA evolve under relaxed selection due to their function being limited to sperm only (vs. all other tissues for F mtDNA). This has led to the hypothesis that mitonuclear coevolution is less important for M mtDNA. Here, we use comparative phylogenetics, transcriptomics, and proteomics to understand mitonuclear interactions in DUI bivalves. We found nuclear OXPHOS proteins coevolve and maintain compatibility similarly with both F and M mtDNA OXPHOS proteins. Mitochondrial recombination did not influence mitonuclear compatibility and nuclear-encoded OXPHOS genes were not upregulated in tissues with M mtDNA to offset dysfunction. Our results support that selection maintains mitonuclear compatibility with F and M mtDNA despite relaxed selection on M mtDNA. Strict sperm transmission, lower effective population size, and higher mutation rates may explain the evolution of M mtDNA. Our study highlights that mitonuclear coevolution and compatibility may be broad features of eukaryotes.
在双亲单性遗传的双壳类动物中,尽管对雄性线粒体 DNA 的选择较为宽松,但线粒体核兼容性仍得以保持。
线粒体核共同进化在真核生物中很常见,但线粒体双单亲遗传(DUI)的双壳类群可能是一个有趣的例子。在这一系统中,雌性将线粒体DNA(F mtDNA)遗传给所有后代,而雄性则只将不同的线粒体DNA(M mtDNA)遗传给儿子。分子进化和功能数据表明,M mtDNA编码的氧化磷酸化(OXPHOS)基因由于其功能仅限于精子(相对于F mtDNA的所有其他组织)而在宽松选择下进化。这导致一种假设,即有丝分裂核共同进化对 M mtDNA 的重要性较低。在这里,我们利用比较系统发生学、转录组学和蛋白质组学来了解 DUI 双壳类的有丝分裂核相互作用。我们发现核 OXPHOS 蛋白与 F 和 M mtDNA OXPHOS 蛋白共同进化并保持相似的兼容性。线粒体重组并不影响有丝分裂核的兼容性,而且在具有 MtDNA 的组织中,核编码的 OXPHOS 基因并没有上调以抵消功能障碍。我们的研究结果表明,尽管对 M mtDNA 的选择较为宽松,但选择仍能维持有丝核与 F 和 M mtDNA 的兼容性。严格的精子传播、较低的有效种群规模和较高的突变率可能解释了M mtDNA的进化。我们的研究强调了有丝分裂核共同进化和兼容性可能是真核生物的广泛特征。
期刊介绍:
Evolution, published for the Society for the Study of Evolution, is the premier publication devoted to the study of organic evolution and the integration of the various fields of science concerned with evolution. The journal presents significant and original results that extend our understanding of evolutionary phenomena and processes.