Deafness in Claudin 11-null mice reveals the critical contribution of basal cell tight junctions to stria vascularis function

A Gow, C Davies, CM Southwood… - Journal of …, 2004 - Soc Neuroscience
A Gow, C Davies, CM Southwood, G Frolenkov, M Chrustowski, L Ng, D Yamauchi…
Journal of Neuroscience, 2004Soc Neuroscience
Generation of a strong electrical potential in the cochlea is uniquely mammalian and may
reflect recent evolutionary advances in cellular voltage-dependent amplifiers. This
endocochlear potential is hypothesized to dramatically improve hearing sensitivity, a
concept that is difficult to explore experimentally, because manipulating cochlear function
frequently causes rapid degenerative changes early in development. Here, we examine the
deafness phenotype in adult Claudin 11-null mice, which lack the basal cell tight junctions …
Generation of a strong electrical potential in the cochlea is uniquely mammalian and may reflect recent evolutionary advances in cellular voltage-dependent amplifiers. This endocochlear potential is hypothesized to dramatically improve hearing sensitivity, a concept that is difficult to explore experimentally, because manipulating cochlear function frequently causes rapid degenerative changes early in development. Here, we examine the deafness phenotype in adult Claudin 11-null mice, which lack the basal cell tight junctions that give rise to the intrastrial compartment and find little evidence of cochlear pathology. Potassium ion recycling is normal in these mutants, but endocochlear potentials were below 30 mV and hearing thresholds were elevated 50 dB sound pressure level across the frequency spectrum. Together, these data demonstrate the central importance of basal cell tight junctions in the stria vascularis and directly verify the two-cell hypothesis for generation of endocochlear potential. Furthermore, these data indicate that endocochlear potential is an essential component of the power source for the mammalian cochlear amplifier.
Soc Neuroscience