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Query: UMLS:C0011053 (
deafness
)
10,271
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
We performed linkage analysis in a Belgian family with autosomal dominant midfrequency hearing loss, which has a prelingual onset and a nonprogressive course in most patients. We found LOD scores >6 with markers on chromosome 11q. Analysis of key recombinants maps this
deafness
gene (
DFNA12
) to a 36-cM interval on chromosome 11q22-24, between markers D11S4120 and D11S912. The critical regions for the recessive
deafness
locus DFNB2 and the dominant locus DFNA11, which were previously localized to the long arm of chromosome 11, do not overlap with the candidate interval of
DFNA12
.
...
PMID:A gene for autosomal dominant nonsyndromic hearing loss (DFNA12) maps to chromosome 11q22-24. 915 Jan 64
alpha-Tectorin is one of the major noncollagenous components of the mammalian tectorial membrane in the inner ear. We have mapped the gene encoding
alpha-tectorin
to mouse chromosome 9 and human chromosome 11 in a known region of conserved synteny. Human YAC clones containing
alpha-tectorin
have been identified, demonstrating physical linkage to the anonymous marker D11S925. This places
alpha-tectorin
within the genetic interval that contains both the human nonsyndromic autosomal dominant
deafness
DFNA12
and the proximal limit of a subset of deletions within Jacobsen syndrome. Thus both
DFNA12
and the hearing loss in some cases of Jacobsen syndrome may be due to haploinsufficiency for
TECTA
.
...
PMID:Mapping of the alpha-tectorin gene (TECTA) to mouse chromosome 9 and human chromosome 11: a candidate for human autosomal dominant nonsyndromic deafness. 950 15
In our efforts to identify new loci responsible for non-syndromic autosomal recessive forms of
deafness
, DFNB loci, we have pursued the analysis of large consanguineous affected families living in geographically isolated areas. Here, we report on the study of a Lebanese family comprising nine members presenting with a pre-lingual severe to profound sensorineural isolated form of
deafness
. Linkage analysis led to the characterization of a new locus,
DFNB21
, which was assigned to chromosome 11q23-25. Already mapped to this chromosomal region was
TECTA
. This gene encodes
alpha-tectorin
, a 2155 amino acid protein which is a component of the tectorial membrane. This gene recently has been shown to be responsible for a dominant form of
deafness
,
DFNA8
/12. Sequence analysis of the
TECTA
gene in the
DFNB21
-affected family revealed a G to A transition in the donor splice site (GT) of intron 9, predicted to lead to a truncated protein of 971 amino acids. This establishes that
alpha-tectorin
mutations can be responsible for both dominant and recessive forms of
deafness
. Comparison of the phenotype of the
DFNB21
heterozygous carriers with that of
DFNA8
/12-affected individuals supports the hypothesis that the
TECTA
mutations which cause the dominant form of
deafness
have a dominant-negative effect. The present results provide genetic evidence for
alpha-tectorin
forming homo- or heteromeric structures.
...
PMID:An alpha-tectorin gene defect causes a newly identified autosomal recessive form of sensorineural pre-lingual non-syndromic deafness, DFNB21. 994
More than 50% of severe childhood
deafness
is genetically determined, approximately 70% of which occurs without other abnormalities and is thus termed nonsyndromic. So far, 30 nonsyndromic recessive
deafness
loci have been mapped and the defective genes at 6 loci, DFNB1, DFNB2, DFNB3, DFNB4, DFNB9 and DNFB21, have been identified, encoding connexin-26 (ref. 3), myosin VIIA (ref. 4), myosin XV (ref. 5), pendrin, otoferlin and
alpha-tectorin
, respectively. Here we map a new recessive nonsyndromic
deafness
locus, DFNB26, to a 1.5-cM interval of chromosome 4q31 in a consanguineous Pakistani family. A maximum lod score of 8.10 at theta=0 was obtained with D4S1610 when only the 8 affected individuals in this family were included in the calculation. There are seven unaffected family members who are also homozygous for the DFNB26-linked haplotype and thus are non-penetrant. A dominant modifier, DFNM1, that suppresses
deafness
in the 7 nonpenetrant individuals was mapped to a 5.6-cM region on chromosome 1q24 with a lod score of 4.31 at theta=0 for D1S2815.
...
PMID:Dominant modifier DFNM1 suppresses recessive deafness DFNB26. 1110 39
TECTA
and DFNA5 are the mouse orthologues of the human
deafness
-associated genes
TECTA
and DFNA5. To determine how expression of these genes is regulated during development, relative mRNA abundance was examined in mice by non-radioactive RT-PCR.
TECTA
mRNA was detected on embryonic day 15 (E15), increased to its highest level on postnatal day 3 (P3) and then dramatically decreased by P15. Low levels persisted (adulthood, P45 to 67) with mean mRNA abundance after P15 less than 25% of P3 levels. DFNA5 mRNA expression was constant throughout these time points. These results imply that
TECTA
is transcribed at a particularly high level during tectorial membrane morphogenesis. In contrast, DFNA5 is present in both the developing and mature cochlea.
...
PMID:Quantification of TECTA and DFNA5 expression in the developing mouse cochlea. 1171 60
Hereditary deafness has proved to be extremely heterogeneous genetically with more than 40 genes mapped or cloned for non-syndromic dominant
deafness
and 30 for autosomal recessive non-syndromic
deafness
. In spite of significant advances in the understanding of the molecular basis of hearing loss, identifying the precise genetic cause in an individual remains difficult. Consequently, it is important to exclude syndromic causes of
deafness
by clinical and special investigation and to use all available phenotypic clues for diagnosis. A clinical approach to the aetiological investigation of individuals with hearing loss is suggested, which includes ophthalmology review, renal ultrasound scan and neuro-imaging of petrous temporal bone. Molecular screening of the GJB2 (Connexin 26) gene should be undertaken in all cases of non-syndromic
deafness
where the cause cannot be identified, since it is a common cause of recessive hearing impairment, the screening is straightforward, and the phenotype unremarkable. By the same token, mitochondrial inheritance of hearing loss should be considered in all multigeneration families, particularly if there is a history of exposure to aminoglycoside antibiotics, since genetic testing of specific mitochondrial genes is technically feasible. Most forms of non-syndromic autosomal recessive hearing impairment cause a prelingual hearing loss, which is generally severe to profound and not associated with abnormal radiology. Exceptions to this include DFNB2 (MYO7A), DFNB8/10 (TMPRSS3) and DFNB16 (STRC) where age of onset may sometimes be later on in childhood, DFNB4 (SLC26A4) where there may be dilated vestibular aqueducts and endolymphatic sacs, and DFNB9 (OTOF) where there may also be an associated auditory neuropathy. Unusual phenotypes in autosomal dominant forms of
deafness
, include low frequency hearing loss in DFNA1 (HDIA1) and DFNA6/14/38 (WFS1), mid-frequency hearing loss in
DFNA8
/12 (
TECTA
), DFNA13 (COL11A2) and vestibular symptoms and signs in DFNA9 (COCH) and sometimes in DFNA11 (MYO7A). Continued clinical evaluation of types and course of hearing loss and correlation with genotype is important for the intelligent application of molecular testing in the next few years.
...
PMID:Hereditary deafness and phenotyping in humans. 1232 85
Forty-five consanguineous Iranian families segregating autosomal recessive nonsyndromic hearing loss (ARNSHL) and negative for mutations at the DFNB1 locus were screened for allele segregation consistent with homozygosity by descent (HBD) at the
DFNB21
locus. In three families demonstrating HBD at this locus, mutation screening of
TECTA
led to the identification of three novel homozygous mutations: one frameshift mutation (266delT), a transversion of a cytosine to an adenine (5,211C > A) leading to a stop codon, and a 9.6 kb deletion removing exon 10. In total, six mutations in
TECTA
have now been described in families segregating ARNSHL. All of these mutations are inactivating and produce a similar phenotype that is characterized by moderate-to-severe hearing loss across frequencies with a mid frequency dip. The truncating nature of these mutations is consistent with loss-of-function, and therefore the existing
TECTA
knockout mouse mutant represents a good model in which to study
DFNB21
-related
deafness
.
...
PMID:Identification of three novel TECTA mutations in Iranian families with autosomal recessive nonsyndromic hearing impairment at the DFNB21 locus. 1743 2
An audioprofile displays phenotypic data from several audiograms on a single graph that share a common genotype. In this report, we describe the application of audioprofiling to a large family in which a genome-wide screen failed to identify a
deafness
locus. Analysis of audiograms by audioprofiling suggested that two persons with hearing impairment had a different
deafness
genotype. On this basis, we reassigned affectation status and identified a p.Cys1837Arg autosomal dominant mutation in
alpha-tectorin
segregating in all family members except two persons, who segregated autosomal recessive
deafness
caused by p.Val37Ile and p.Leu90Pro mutations in Connexin 26. One nuclear family in the extended pedigree segregates both dominant and recessive non-syndromic hearing loss.
...
PMID:Audioprofiling identifies TECTA and GJB2-related deafness segregating in a single extended pedigree. 1766 17
Mutations in the
TECTA
gene result in sensorineural non-syndromic hearing impairment.
TECTA
-related
deafness
can be inherited autosomal dominantly (designated as
DFNA8
/12) or autosomal recessively (as
DFNB21
). The
alpha-tectorin
protein, which is encoded by the
TECTA
gene, is one of the major components of the tectorial membrane in the inner ear. Six mutations in the
TECTA
gene have already been reported in families segregating autosomal recessive non-syndromic hearing impairment. In this study, seventy-five Iranian families segregating autosomal recessive non-syndromic hearing impairment were analyzed for homozygosity at the
DFNB21
locus by genotyping two short tandem repeat markers closely linked to the
TECTA
gene. Allelic segregation consistent with possible linkage to the
DFNB21
locus was found in 1/75 families studied. By sequencing all 23 coding exons of
TECTA
, a 16bp deletion (c.6203-6218del16) in exon 21, leading to a frameshift, segregating with the hearing loss was found. All 3 affected individuals of this family have moderate-to-severe hearing loss across all frequencies, which is more pronounced in the mid frequencies. This new mutation, as well as the six previously reported mutations in the
TECTA
gene, is inactivating. All of these mutations lead to an easily recognized audiometric profile of moderate to severe hearing impairment as presented by the family in this study too. The
TECTA
autosomal recessive non-syndromic
deafness
phenotype differs from the typical profound
deafness
phenotype that is seen in most families segregating autosomal recessive non-syndromic
deafness
. On the basis of the recognizable phenotype, we recommend mutation screening of
TECTA
in families with this hearing phenotype.
...
PMID:A novel TECTA mutation confirms the recognizable phenotype among autosomal recessive hearing impairment families. 1802 53
Discovery of
deafness
genes has progressed but clinical application lags because of the genetic heterogeneity. To establish clinical application strategy, we reviewed the frequency and spectrum of mutations found in Japanese hearing loss patients and compared them to those in populations of European ancestry. Screening revealed that in Japanese, mutations in GJB2, SLC26A4, and CDH23, and the mitochondrial 12S rRNA are the major causes of hearing loss. Also, mutations in KCNQ4,
TECTA
, COCH, WFS1, CRYM, COL9A3, and KIAA1199 were found in independent autosomal dominant families. Interestingly, spectrums of GJB2, SLC26A4, and CDH23 mutations in Japanese were quite different from those in Europeans. Simultaneous screening of multiple
deafness
mutations based on the mutation spectrum of a corresponding population using an Invader panel revealed that approximately 30% of subjects could be diagnosed. This assay will enable us to detect
deafness
mutations in an efficient and practical manner in the clinical platform. We conclude that specific racial populations may have unique
deafness
gene epidemiologies; therefore, ethnic background should be considered when genetic testing is performed. Simultaneous examination of multiple mutations based on a population's spectrum may be appropriate and effective for detecting
deafness
genes, facilitating precise clinical diagnosis, appropriate counseling, and proper management.
...
PMID:The responsible genes in Japanese deafness patients and clinical application using Invader assay. 1836 81
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