Single-Cell RNA-seq Uncovers Dynamic Processes Orchestrated by RNA-Binding Protein DDX43 in Chromatin Remodeling during Spermiogenesis

Abstract

AbstractAdvances in single-cell RNA sequencing (scRNA-seq) have allowed for elucidating biological mechanisms at cell state level. Mammalian spermatogenic process showcases dynamic switches of gene expression pattern with delicate morphological and functional alterations of germ cells, but it is unclear how such dynamics is genetically controlled. Here we demonstrate that mouse testis-enriched RNA helicase DDX43, as well as its ATP hydrolysis site, is required for spermiogenesis. Genetic mutation of Ddx43 renders spermatids heterogeneously defective in multiple steps of chromatin remodeling, resulting in incomplete substitution of transition protein by protamine and less condensed sperm nucleus. Through scRNA-seq analyses of testicular cells derived from adult wild-type and Ddx43 mutant testes in mice, we reveal that the DDX43 deficiency-elicited perturbation in the dynamic RNA regulatory processes underlies the differentiation deficiency of spermatids. Further, focused analyses on early-stage spermatids combined with enhanced CLIP sequencing (eCLIP-seq) identify Elfn2 as DDX43-targeted hub gene, whose in vivo knockdown shows similar phenotypic defects as Ddx43 mutant. Our study illustrates an essential role for DDX43 in post-meiotic chromatin remodeling and highlights the single cell-based strategy for a refined dissection of stage-specific regulation of germline differentiation.