Identification and functional study of a new missense mutation in the motor head domain of myosin VIIA in a family with autosomal dominant hearing impairment (DFNA11).

The MYO7A encodes a protein classified as an unconventional myosin. Here, we present a family with non-syndromic autosomal dominant hearing impairment that clinically resembles other previously published DFNA11 families. Affected members of the family present with an ascending audiogram affecting low and middle frequencies at young ages and then affecting all frequencies with increasing age. Genome-wide linkage analysis using Illumina Cyto-12 Chip mapped the disease locus to the DFNA11 interval in the family. A c.2003G→A (p.R668H) mutation of the MYO7A, is heterozygous in all affected family members and absent in 100 healthy individuals. Arg668His is located in a region of the myosin VIIA motor domain that is highly conserved among different species. Molecular modeling predicts that the conserved R668 residue plays important structural role in linking different lobes of motor domain together. In the actin-activated ATPase activity assay, the rate of NADH oxidation was higher in the wild-type myosin VIIA, indicating that the ATPase activity in the p.R668H mutant myosin VIIA was significantly destroyed.

A novel mutation in the MITF may be digenic with GJB2 mutations in a large Chinese family of Waardenburg syndrome type II.

Waardenburg syndrome type II (WS2) is associated with syndromic deafness. A subset of WS2, WS2A, accounting for approximately 15% of patients, is attributed to mutations in the microphthalmia-associated transcription factor (MITF) gene. We examined the genetic basis of WS2 in a large Chinese family. All 9 exons of the MITF gene, the single coding exon (exon 2) of the most common hereditary deafness gene GJB2 and the mitochondrial DNA (mtDNA) 12S rRNA were sequenced. A novel heterozygous mutation c.[742_743delAAinsT;746_747delCA] in exon 8 of the MITF gene co-segregates with WS2 in the family. The MITF mutation results in a premature termination codon and a truncated MITF protein with only 247 of the 419 wild type amino acids. The deaf proband had this MITF gene heterozygous mutation as well as a c.[109G>A]+[235delC] compound heterozygous pathogenic mutation in the GJB2 gene. No pathogenic mutation was found in mtDNA 12S rRNA in this family. Thus, a novel compound heterozygous mutation, c.[742_743delAAinsT;746_747delCA] in MITF exon 8 was the key genetic reason for WS2 in this family, and a digenic effect of MITF and GJB2 genes may contribute to deafness of the proband.

Maternally transmitted late-onset non-syndromic deafness is associated with the novel heteroplasmic T12201C mutation in the mitochondrial tRNAHis gene.

The authors report here the clinical, genetic, molecular and biochemical characterisation of a large five-generation Han Chinese pedigree with maternally transmitted non-syndromic hearing loss. 17 of 35 matrilineal relatives exhibited variable severity and age at onset of sensorineural hearing loss. The average age at onset of hearing loss in matrilineal relatives of this family is 29 years, while matrilineal relatives among families carrying other mitochondrial DNA mutations developed hearing loss with congenital conditions or early age at onset. Molecular analysis of their mitochondrial genome identified the novel heteroplasmic T12201C mutation in the transfer RNA (tRNA)(His) gene. The levels of T12201C mutation in matrilineal relatives of this family correlated with the severity and age at onset of non-syndromic hearing loss. By contrast, other heteroplasmic mitochondrial DNA mutations often cause syndromic hearing loss. The T12201C mutation destabilises a highly conservative base-pairing (5A-68U) on the acceptor stem of tRNA(His). tRNA northern analysis revealed that the T12201C mutation caused an ∼75% reduction in the steady-state level of tRNA(His). An in vivo protein labeling analysis showed an ∼47% reduction in the rate of mitochondrial translation in cells carrying the T12201C mutation. Impaired mitochondrial translation is apparently a primary contributor to the marked reduction in the rate of overall respiratory capacity, malate/glutamate-promoted respiration, succinate/glycerol-3-phosphate-promoted respiration or N,N,N,N-tetramethyl-p-phenylenediamine/ascorbate-promoted respiration. These data provide the first direct evidence that mitochondrial dysfunctions caused by the heteroplasmic tRNA(His) mutation lead to late-onset non-syndromic deafness. Thus, the authors' findings provide new insights into the understanding of pathophysiology and valuable information on the management and treatment of maternally inherited hearing loss.