Phenotypic and expression analysis of a novel spontaneous myosin VI null mutant mouse.

In humans, hearing is a major factor in quality of life. Mouse models are important tools for the discovery of genes responsible for genetic hearing loss, often enabling analysis of the processes that regulate the onset of deafness in humans. Thus far, at least 400 deafness mutants have been discovered in laboratory mouse populations and used in the study of deafness. Here we report the discovery of a new spontaneous recessive Rinshoken shaker/waltzer (rsv) mutant derived from our in-house C57BL/6J stock, which exhibits circling and/or head-tossing behaviour and complete lack of auditory brain response to any sound pressure. The hearing and balance phenotypes are associated with structural defects, in particular, disorganisation and fusion of stereocilia in the inner ear hair cells. Two sets of intersubspecific N(2) mice were generated for the positional cloning of the rsv mutation. The mutant locus was mapped to a 4.8-Mb region of chromosome 9, which contains myosin VI (Myo6), a gene responsible for deafness in humans and Snell's waltzer mutation in mice. The rsv mutant showed reduced expressions of Myo6 mRNA and MYO6 protein in the inner ear. Moreover, no immunoreactivity was observed in the cochlear and vestibular hair cells in the rsv mutant mice. We sequenced the genomic region (30,154 bp) of Myo6, including all coding exons, a non-coding exon, UTRs and the Myo6 promoter; however, no mutation was discovered in these regions. We therefore speculate that loss of MYO6 expression might cause shaker/waltzer behaviour and deafness in the rsv mutant; also, loss of MYO6 expression might be the result of mutations in an unidentified regulatory region(s) of the gene.

Protein 4.1 expression in the developing hair cells of the mouse inner ear.

Protein 4.1 (band 4.1 or 4.1R) was originally identified as an abundant protein of the human erythrocyte, in which it stabilizes the spectrin/actin cytoskeleton. Subsequently, several new family members, 4.1N, 4.1G and 4.1B, have been identified, which are expressed in many cell types, in particular at cell-cell junctions. We previously reported that 4.1R and 4.1N are expressed in the inner ear hair cells with specific localization patterns, and that 4.1R forms a complex with the membrane-associated guanylate kinase (MAGUK) protein p55 and two deafness gene products, myosin XV and whirlin. To determine the functions of the other family members, 4.1G and 4.1B, we observed their expression patterns in developing stereocilia in mice inner ear hair cells. 4.1G is expressed in the basal tapers of the stereocilia bundle in early postnatal stages. 4.1B was specifically and constantly expressed in the stereocilia tips during postnatal development. Additionally, we found that 4.1B is ablated in the hair cells of both myosin XV and whirlin mutant mice at all stages in hair cell development. These results suggest that 4.1 family members play important roles in the development and maintenance of the inner ear hair cells, and that 4.1B may be a member of the myosin XV-whirlin complex that is important for stereocilia maturation.