Connexin26 deafness in several interconnected families.

Mutations in the connexin26 gene are the basis of much autosomal recessive sensorineural deafness. There is a high frequency of mutant alleles, largely accounted for by one common mutation, 35delG. We have studied a group of families, who had been brought together through marriages between Deaf persons, in which there are more than 30 Deaf people in four generations. We show that many of the several cases of deafness are the result of 35delG homozygosity or 35delG/Q57X compound heterozygosity at the connexin26 locus. A considerable range of audiographic phenotypes was observed. The combined effects of a high population frequency of mutant alleles, and of positive assortative marriage among the Deaf, led to an infrequently observed recessive pedigree pattern.

Mitochondrial A7445G mutation in two pedigrees with palmoplantar keratoderma and deafness.

A New Zealand and a Scottish pedigree with maternally inherited sensorineural deafness were both previously shown to carry a heteroplasmic A7445G mutation in the mitochondrial genome. More detailed clinical examination of the New Zealand family showed that the hearing loss was progressive, with the severity of the overall loss and the frequencies most affected differing markedly between individuals of similar age, and showed that many relatives also had palmoplantar keratoderma. Review of the literature demonstrated three other large families with presumed autosomal dominant inheritance of palmoplantar keratoderma and hearing loss. In a United Kingdom pedigree the syndrome was transmitted by female and male parents, an inheritance pattern which made mitochondrial inheritance unlikely; however, in a Turkish and a Japanese pedigree the affected individuals were all maternally related. Subsequent analysis of the Japanese pedigree documented the same A7445G mitochondrial mutation as was previously found in the New Zealand and Scottish pedigrees. Other mitochondrial sequence variants previously reported in the New Zealand or Scottish pedigrees were absent from the Japanese pedigree which suggests that the A7445G mutation arose independently in all three pedigrees. To our knowledge palmoplantar keratoderma has not previously been associated with mitochondrial defects; however, the current findings suggest that the A7445G mutation is associated not only with progressive hearing loss but also with palmoplantar keratoderma. The penetrance and expressivity of both symptoms varied considerably between individuals in the Scottish and New Zealand Studies which suggests that additional environmental and/or genetic factors are involved.

Prelingual deafness: high prevalence of a 30delG mutation in the connexin 26 gene.

Prelingual non-syndromic (isolated) deafness is the most frequent hereditary sensory defect. In >80% of the cases, the mode of transmission is autosomal recessive. To date, 14 loci have been identified for the recessive forms (DFNB loci). For two of them, DFNB1 and DFNB2, the genes responsible have been characterized; they encode connexin 26 and myosin VIIA, respectively. In order to evaluate the extent to which the connexin 26 gene (Cx26) contributes to prelingual deafness, we searched for mutations in this gene in 65 affected Caucasian families originating from various countries, mainly tunisia, France, New Zealand and the UK. Six of these families are consanguineous, and deafness was shown to be linked to the DFNB1 locus, 10 are small non consanguineous families in which the segregation of the trait has been found to be compatible with the involvement of DFNB1, and in the remaining 49 families no linkage analysis has been performed. A total of 62 mutant alleles in 39 families were identified. Therefore, mutations in Cx26 represent a major cause of recessively inherited prelingual deafness since according to the present results they would underlie approximately half of the cases. In addition, one specific mutation, 30delG, accounts for the majority (approximately 70%) of the Cx26 mutant alleles. It is therefore one of the most frequent disease mutations so far identified. Several lines of evidence indicate that the high prevalence of the 30delG mutation arises from a mutation hot spot rather than from a founder effect. Genetic counseling for prelingual deafness has been so far considerably impaired by the difficulty in distinguishing genetic and non genetic deafness in families presenting with a single deaf child. Based on the results presented here, the development of a simple molecular test could be designed which should be of considerable help.

The contribution of the DFNB1 locus to neurosensory deafness in a Caucasian population.

Classical studies have demonstrated genetic heterogeneity for nonsyndromic autosomal recessive congenital neurosensory deafness, with at least six loci postulated. Linkage analysis in two consanguineous Tunisian kindreds has demonstrated that one such deafness locus, DFNB1, maps near chromosome 13 markers D13S175, D13S143, and D13S115. We tested these markers for cosegregation with deafness in 18 New Zealand and 1 Australian nonconsanguineous kindreds, each of which included at least two siblings with nonsyndromic presumed congenital sensorineural deafness and that had a pedigree structure consistent with autosomal recessive inheritance. When all families were combined, a peak two-point lod score of 2.547 (theta = .1) was obtained for D13S175, 0.780 (theta = .2) for D13S143, and 0.664 (theta = .3) for D13S115. While there was no statistically significant evidence for heterogeneity at any of the three loci tested, nine families showed cosegregation of marker haplotypes with deafness. These observations suggest that the DFNB1 locus may make an important contribution to autosomal recessive neurosensory deafness in a Caucasian population. In the nine cosegregating families, phenotypic variation was observed both within sibships (in four families), which indicates that variable expressivity characterizes some genotypes at the DFNB1 locus, and between generations (in two families), which suggests allelic heterogeneity.