Parhad Swapnil S, Tu Shikui, Weng Zhiping, Theurkauf William E
Program in Molecular Medicine, University of Massachusetts Medical School, 373 Plantation Street, Worcester, MA 01605, USA.
Program in Bioinformatics and Integrative Biology, University of Massachusetts Medical School, 368 Plantation Street, Worcester, MA 01605, USA.
Dev Cell. 2017 Oct 9;43(1):60-70.e5. doi: 10.1016/j.devcel.2017.08.012. Epub 2017 Sep 14.
Reproductive isolation defines species divergence and is linked to adaptive evolution of hybrid incompatibility genes. Hybrids between Drosophila melanogaster and Drosophila simulans are sterile, and phenocopy mutations in the PIWI interacting RNA (piRNA) pathway, which silences transposons and shows pervasive adaptive evolution, and Drosophila rhino and deadlock encode rapidly evolving components of a complex that binds to piRNA clusters. We show that Rhino and Deadlock interact and co-localize in simulans and melanogaster, but simulans Rhino does not bind melanogaster Deadlock, due to substitutions in the rapidly evolving Shadow domain. Significantly, a chimera expressing the simulans Shadow domain in a melanogaster Rhino backbone fails to support piRNA production, disrupts binding to piRNA clusters, and leads to ectopic localization to bulk heterochromatin. Fusing melanogaster Deadlock to simulans Rhino, by contrast, restores localization to clusters. Deadlock binding thus directs Rhino to piRNA clusters, and Rhino-Deadlock co-evolution has produced cross-species incompatibilities, which may contribute to reproductive isolation.
生殖隔离定义了物种分化,并与杂种不相容基因的适应性进化相关。黑腹果蝇和拟暗果蝇之间的杂种是不育的,并且在PIWI相互作用RNA(piRNA)途径中表现出表型模拟突变,该途径可使转座子沉默并显示出广泛的适应性进化,而果蝇的Rhino和Deadlock基因编码与piRNA簇结合的复合物中快速进化的成分。我们发现,Rhino和Deadlock在拟暗果蝇和黑腹果蝇中相互作用并共定位,但由于快速进化的Shadow结构域中的替代,拟暗果蝇的Rhino不能与黑腹果蝇的Deadlock结合。重要的是,在黑腹果蝇Rhino主干中表达拟暗果蝇Shadow结构域的嵌合体无法支持piRNA的产生,破坏了与piRNA簇的结合,并导致异位定位于大量异染色质。相比之下,将黑腹果蝇的Deadlock与拟暗果蝇的Rhino融合可恢复其对簇的定位。因此,Deadlock的结合将Rhino引导至piRNA簇,并且Rhino-Deadlock的共同进化产生了跨物种的不相容性,这可能有助于生殖隔离。