Characteristics of stria vascularis melanocytes of viable dominant spotting (Wv/Wv) mouse mutants.

The Wv mutation lies in the kinase domain of the proto-oncogene c-kit which is expressed in a variety of cells including neural crest derived melanoblasts. The mutation results in the abnormal migration, proliferation, survival and/or differentiation of melanoblasts. Viable Dominant Spotting (Wv/Wv) mouse mutants have a white coat due to the absence of melanocytes. The majority of these animals have no melanocytes within the stria vascularis and no endocochlear potential (EP). A proportion of homozygous mutants partially escape the effects of the mutation: 47.2% of pinnae and 21% of vestibular regions were pigmented and 10.8% of ears had an EP. All ears with an EP that were available for histology had some pigmentation of the stria. There was no obvious correlation between external and internal spotting in Wv/Wv mice, and asymmetrical pigmentation of the ears was common. Both light and dark intermediate cells (which are derived from melanocytes) were present in the middle and/or basal turns of these cochlear ducts and they appeared to function normally in enabling the stria to produce an EP (although the EP was usually lower than normal). This suggests that the c-kit gene product is needed only during development of the stria, and not for mature melanocyte function because the melanocytes present in the mutant strias were carrying the mutant version of the c-kit gene. Melanocytes were similar in appearance in controls and mutants, except that fewer melanin granules were observed in the strias of Wv/Wv mice. The observations that strial melanocytes with very few melanin granules in Wv/Wv mutants are able to support EP production, together with previous observations that albino animals with strial melanocytes but no melanin have a normal EP, suggest that melanocytes but not melanin are essential for normal strial function.

A histologic study of nonmorphogenetic forms of hereditary hearing impairment.

It appears that many forms of syndromic and nonsyndromic hereditary hearing impairment are secondary to either neuroepithelial or cochleosaccular dysfunction. Making this distinction can be difficult in human temporal bone specimens; however, this added knowledge may ultimately provide prognostic and therapeutic information in hearing habilitation. Fundamental studies using animal models of different types of hereditary deafness may also prove useful in this respect.

Another role for melanocytes: their importance for normal stria vascularis development in the mammalian inner ear.

The stria vascularis of the mammalian cochlea is composed primarily of three types of cells. Marginal cells line the lumen of the cochlear duct and are of epithelial origin. Basal cells also form a continuous layer and they may be mesodermal or derived from the neural crest. Intermediate cells are melanocyte-like cells, presumably derived from the neural crest, and are scattered between the marginal and basal cell layers. The marginal cells form extensive interdigitations with the basal and intermediate cells in the normal adult stria. The stria also contains a rich supply of blood vessels. We investigated the role of melanocytes in the stria vascularis by studying its development in a mouse mutant, viable dominant spotting, which is known to have a primary neural crest defect leading to an absence of recognisable melanocytes in the skin. Melanocytes were not found in the stria of most of the mutants examined, and from about 6 days of age onwards a reduced amount of interdigitation amongst the cells of the stria was observed. These ultrastructural anomalies were associated with strial dysfunction. In the normal adult mammal, the stria produces an endocochlear potential (EP), a resting dc potential in the endolymph in the cochlear duct, which in mice is normally about +100 mV. In our control mice, EP rose to adult levels between 6 and 16 days after birth. In most of the mutants we studied, EP was close to zero at all ages from 6 to 20 days. Melanocyte-like cells appear to be vital for normal stria vascularis development and function. They may be necessary to facilitate the normal process of interdigitation between marginal and basal cell processes at a particular stage during development, and the lack of adequate interdigitation in the mutants may be the cause of their strial dysfunction. Alternatively, melanocytes may have some direct, essential role in the production of an EP by the stria. Melanocytes may be important both for normal strial development and for the production of the EP. We believe this is the clearest demonstration yet of a role for migratory melanocytes other than their role in pigmentation.

Strial dysfunction in mice with cochleo-saccular abnormalities.

Most viable dominant spotting (Wv/Wv) mutant mice, which show cochleo-saccular degeneration, were found to have an endocochlear potential (EP) around zero together with a structurally abnormal stria vascularis. Inner hair cells were well preserved, but outer hair cells in the basal half of the cochlea were degenerating, possibly as a result of primary strial dysfunction. Thresholds for the detection of a compound action potential were raised to around 100 dB SPL in the mutants with no EP, and there was little if any cochlear microphonic at the round window. Of the 20 Wv/Wv mice studied, five partially escaped the effects of the mutation and had measurable positive potentials (15-86 mV) in scala media in the basal turn; responses in these animals were intermediate between control responses and those of mutants with no EP. These findings confirm that the pathological processes in this mutant, with cochleo-saccular abnormalities, are fundamentally different from the pathological processes in animals with neuroepithelial abnormalities reported previously [see Steel and Bock (1983) Arch. Otolaryngol. 109, 22-29, for references].

Central auditory function in a hearing-impaired white mouse.

The dysfunction of the stria vascularis in the viable dominant spotting mutant mouse results in the reduction or the absence of the endocochlear potential. However, these mutants respond to an intense acoustic stimulus with a Preyer reflex (pinna twitch). This study used 14C autoradiography and electromyography to investigate central auditory responses in this mutant. There were three main findings: autoradiography demonstrated an increase in the metabolic rate within each of the central auditory nuclei during noise exposure compared with silence; electromyographic recordings indicated that there was no tensor tympani muscle reflex; the mutants were found to be susceptible to audiogenic seizures. It was concluded that the central auditory pathway of the viable dominant spotting mutant could be activated despite the abnormal strial function. Absence of the tensor tympani muscle reflex, together with auditory deprivation, might contribute to the susceptibility to audiogenic seizures.

Lysosomal enzyme content of Kupffer and endothelial liver cells isolated from germfree and clean conventional rats.

Rats kept under germfree conditions showed lower specific lysosomal enzyme activities in liver endothelial cells, but not in Kupffer cells.