Abstract
Changes in RNA splicing over the course of evolution have profoundly diversified the functional landscape of the human genome. Emerging evidence suggests that inverted pairs of intronic Alu elements can promote exon skipping by forming RNA stem-loop structures. However, their prevalence and influence throughout evolution remain unknown. Here, we present a systematic analysis of inverted Alu pairs across the human genome to assess their impact on exon skipping and their relevance to hominoid evolution. We found that inverted Alu pairs are enriched in the flanking regions of skippable exons genome-wide and are predicted to form stable stem-loop structures. Exons defined by weak 3' acceptor splice sites appear especially prone to this skipping mechanism. Through comparative genome analysis across nine primate species, we identified 67 126 hominoid-specific Alu insertions, primarily from AluY and AluS subfamilies, which form inverted pairs enriched across skippable exons in genes of ubiquitination-related pathways. Experimental validation among several hominoid-specific inverted Alu pairs further reinforced their potential evolutionary significance. This work extends our current knowledge of the roles of RNA secondary structure formed by inverted Alu pairs and details a newly emerging mechanism through which transposable elements have contributed to genomic innovation across hominoid evolution.