Primate-specific adaptation of Ku protects transcriptomic integrity by suppressing Alu-mediated alternative splicing.
Tianji Yu, Jimin Yoon, Yimeng Zhu, Angelina Li, Brian J Lee, Daniel F Moakley, Jing Duan, Qiannian Deng, Fanjia Hou, Mengfang Yan, Vincenzo A Gennarino, Ke Zhang, Li Chen, Shan Zha, Chaolin Zhang
Abstract
Open AccessAccurate pre-mRNA splicing is essential for the transfer of genetic information but faces unique challenge in higher primates due to the massive expansion of intronic Alu elements 1-3 . While studying Ku, the Ku70/Ku80 heterodimer best known for initiating non-homologous end-joining (NHEJ) by encircling DNA ends 4 , we discovered that Ku expression increased markedly during primate evolution in parallel with Alu expansion 5 . Ku binds double-stranded RNA (dsRNA) stem-loops, including those at the antisense Alu (asAlu) elements within introns 5 . Here, we show that Ku-depletion in human cells has a broad impact on splicing largely independent of cell-cycle states, NHEJ, or innate immune signaling, significantly affecting ~8-10% of quantifiable alternative splicing events. Mechanistically, Ku directly binds exonic asAlu to prevent their aberrant inclusion and binds asAlu within inverted-repeat Alu (irAlu) pairs flanking canonical exons to prevent exon skipping 6 . Among human tissues, Ku expression in the brain is consistently ~50% lower, correlating with more permissive expression of Alu-derived splice variants, particularly those encoding mitochondrial proteins and RNA-binding factors. Correspondingly, heterozygous Ku loss in patient causes developmental delay, neurological dysfunction, and acidosis. Together our findings identified Ku as a critical suppressor of Alu-associated alternative splicing co-opted during evolution with implications for primate brain function and human disease.