The pathogenesis of common Gjb2 mutation associated with human hereditary deafness in mice

Mutations in GJB2 (Gap junction protein beta 2) are the most common genetic cause of non-syndromic hereditary deafness in humans, especially the 35delG and 235delC mutations. Owing to the homozygous-lethal of Gjb2 mutation in mice, there are currently no perfect mouse models carrying Gjb2 mutation to mimic human hereditary deafness and unveil the pathogenesis. Here, we first constructed heterozygous mutant mice, Gjb2+/35delG and Gjb2+/235delC, through androgenic haploid embryonic stem cells (AG-haESCs) mediated semi-cloning technology, which showed normal hearing function at P28. Furthermore, a homozygous mutant mouse model, Gjb235delG/35delG, was generated via enhanced tetraploid embryo complementation, which exhibited profound hearing loss like human patients at P14. Mechanism analysis showed that Gjb2 35delG disrupts the formation of intercellular gap junction channel and tunnel of Corti, and hair cell mechanotransduction, rather than the development of hair cells. Collectively, our study provides ideal mouse models for understanding the pathogenic mechanism and opens up a new avenue for investigating the treatment for DFNB1A-related hereditary deafness. The cochleae of wild-type and Gjb2 35delG/35delG mice were carefully collected and surgically divided into three equal sections, including the apical, middle, and basal turns.