Localization of the bronx waltzer (bv) deafness gene to mouse Chromosome 5

The bronx waltzer (bv) mutation is an autosomal recessive mutation that is manifested as head tossing and circling in the mouse. The mutation affects the inner hair cells (IHCs) and pillar cells in the organ of Corti of the cochlea and the maculae and cristae of the vestibular part of the inner ear. IHCs begin to degenerate by a controlled mechanism of cell death as early as gestational day 17 (G17) in the basal coil of the cochlea, and few surviving IHCs are seen in the adult. As a first step towards the identification of bv, we analyzed a total of 20 loci in 118 mice from an intraspecific backcross giving the gene order: centromere–D5Mit1–D5Mit73–D5Mit55–[D5Mit12, Nds4 (Afp)]–D5Mit87–[D5Mit205, 20, 88, 208, 93–D5Mit338]–D5Mit25–D5Mit209–bv–D5Mit188–D5Mit367–D5Mit95–D5Mit43–D5Mit102. A total of 701 mice were then analyzed for the markers D5Mit93 and D5Mit95, defining a region of 12.08 cM flanking bv. Mice that were recombinant between D5Mit93 and D5Mit95 were analyzed for D5Mit338, D5Mit25, D5Mit209, bv, D5Mit188, and D5Mit367. bv maps 0.14 cM distal of the marker D5Mit209 and 1.14 cM proximal of the marker D5Mit188 in 701 backcross progeny. Received: 3 March 1997 / Accepted: 30 May 1997     

Cytoskeletal integration in a highly ordered sensory epithelium in the organ of Corti: reponse to loss of cell partners in the Bronx waltzer mouse

This report is concerned with control of cell shaping, positioning, and cytoskeletal integration in a highly ordered cochlear neuroepithelium. It is largely based on investigations of events that occur during abnormal morphogenesis of the organ of Corti in the Bronx waltzer (bv/bv) mutant mouse. The organ's sensory hair cells and adjacent supporting cells ordinarily construct a spatially elaborate and supracellularly integrated cytoskeletal framework. Large microtubule bundles are connected to cytoskeletal components in neighbouring cells by actin-containing meshworks that link them to substantial arrays of adherens junctions. In bv/bv mice, degeneration and loss of most inner hair cells and outer pillar cells occurs during organ development. These cells flank each side of a row of inner pillar cells that respond by upregulating assembly of their actin-containing meshworks. This only occurs in surface regions where they no longer contact cell types involved in construction of the cytoskeletal framework. The meshworks are larger and exhibit a more extensive sub-surface deployment than is normally the case. Hence, assembly of intercellular cytoskeletal connecting components can proceed without contact with appropriate cell neighbours but termination of assembly is apparently subject to a negative feedback control triggered by successful completion of intercellular connection with the correct cell neighbours. In addition, inner pillar cells compensate for loss of cell neighbours by interdigitating and overlapping each other more extensively than is usually the case to increase opportunities for generating adherens junctions. Certain adherens junctions in the organs of +/+ and bv/bv mice exhibit features that distinguish them from all previously described cell junctions. The dense plaques on their cytoplasmic faces are composed of aligned ridges. We suggest that they are called ribbed adherens junctions. Perturbations of cell shaping and positioning indicate that loss of inner hair cells is the primary consequence of the bv mutation. Most of the other abnormalities can be understood in terms of a secondary sequence of morphogenetic aberrations (precipitated by loss of inner hair cells). These aberrations provide new information about the ways in which supporting cells help to control hair cell positioning.     

Deafness genes: expressions of surprise.

Recent rapid progress in identifying genes involved in deafness has suggested that a wide range of different types of gene products can result in hearing impairment, which, given the complexity of the auditory system, is not surprising. However, what has given some surprises are the unexpected expression patterns within the ear of some of these genes, which suggests that cochlear physiologists need to look again at some of the cell types involved.