Your search keyword '"Hildebrand, MS"' showing total 16 results

1. Utilizing ethnic-specific differences in minor allele frequency to recategorize reported pathogenic deafness variants.

Author

Shearer AE, Eppsteiner RW, Booth KT, Ephraim SS, Gurrola J 2nd, Simpson A, Black-Ziegelbein EA, Joshi S, Ravi H, Giuffre AC, Happe S, Hildebrand MS, Azaiez H, Bayazit YA, Erdal ME, Lopez-Escamez JA, Gazquez I, Tamayo ML, Gelvez NY, Leal GL, Jalas C, Ekstein J, Yang T, Usami S, Kahrizi K, Bazazzadegan N, Najmabadi H, Scheetz TE, Braun TA, Casavant TL, LeProust EM, and Smith RJ

Subjects

Case-Control Studies, Connexin 26, Connexins, Gene Frequency, Genome, Human genetics, Genome-Wide Association Study, Humans, Phylogeny, Ethnicity genetics, Evolution, Molecular, Exome genetics, Genetic Variation genetics, Hearing Loss genetics, Hearing Loss pathology

Abstract

Ethnic-specific differences in minor allele frequency impact variant categorization for genetic screening of nonsyndromic hearing loss (NSHL) and other genetic disorders. We sought to evaluate all previously reported pathogenic NSHL variants in the context of a large number of controls from ethnically distinct populations sequenced with orthogonal massively parallel sequencing methods. We used HGMD, ClinVar, and dbSNP to generate a comprehensive list of reported pathogenic NSHL variants and re-evaluated these variants in the context of 8,595 individuals from 12 populations and 6 ethnically distinct major human evolutionary phylogenetic groups from three sources (Exome Variant Server, 1000 Genomes project, and a control set of individuals created for this study, the OtoDB). Of the 2,197 reported pathogenic deafness variants, 325 (14.8%) were present in at least one of the 8,595 controls, indicating a minor allele frequency (MAF) > 0.00006. MAFs ranged as high as 0.72, a level incompatible with pathogenicity for a fully penetrant disease like NSHL. Based on these data, we established MAF thresholds of 0.005 for autosomal-recessive variants (excluding specific variants in GJB2) and 0.0005 for autosomal-dominant variants. Using these thresholds, we recategorized 93 (4.2%) of reported pathogenic variants as benign. Our data show that evaluation of reported pathogenic deafness variants using variant MAFs from multiple distinct ethnicities and sequenced by orthogonal methods provides a powerful filter for determining pathogenicity. The proposed MAF thresholds will facilitate clinical interpretation of variants identified in genetic testing for NSHL. All data are publicly available to facilitate interpretation of genetic variants causing deafness., (Copyright © 2014 The American Society of Human Genetics. Published by Elsevier Inc. All rights reserved.)

Published

2014

2. AudioGene: predicting hearing loss genotypes from phenotypes to guide genetic screening.

Author

Taylor KR, Deluca AP, Shearer AE, Hildebrand MS, Black-Ziegelbein EA, Anand VN, Sloan CM, Eppsteiner RW, Scheetz TE, Huygen PL, Smith RJ, Braun TA, and Casavant TL

Subjects

Algorithms, Audiometry, Genetic Testing, Genotype, Humans, Internet, Phenotype, Reproducibility of Results, Hearing Loss diagnosis, Hearing Loss genetics, Software

Abstract

Autosomal dominant nonsyndromic hearing loss (ADNSHL) is a common and often progressive sensory deficit. ADNSHL displays a high degree of genetic heterogeneity and varying rates of progression. Accurate, comprehensive, and cost-effective genetic testing facilitates genetic counseling and provides valuable prognostic information to affected individuals. In this article, we describe the algorithm underlying AudioGene, a software system employing machine-learning techniques that utilizes phenotypic information derived from audiograms to predict the genetic cause of hearing loss in persons segregating ADNSHL. Our data show that AudioGene has an accuracy of 68% in predicting the causative gene within its top three predictions, as compared with 44% for a majority classifier. We also show that AudioGene remains effective for audiograms with high levels of clinical measurement noise. We identify audiometric outliers for each genetic locus and hypothesize that outliers may reflect modifying genetic effects. As personalized genomic medicine becomes more common, AudioGene will be increasingly useful as a phenotypic filter to assess pathogenicity of variants identified by massively parallel sequencing., (© 2012 Wiley Periodicals, Inc.)

Published

2013

3. Pre-capture multiplexing improves efficiency and cost-effectiveness of targeted genomic enrichment.

Author

Shearer AE, Hildebrand MS, Ravi H, Joshi S, Guiffre AC, Novak B, Happe S, LeProust EM, and Smith RJ

Subjects

Case-Control Studies, Cost-Benefit Analysis, DNA Barcoding, Taxonomic, High-Throughput Nucleotide Sequencing economics, Humans, Mutation, Oligonucleotide Array Sequence Analysis, Oligonucleotides genetics, Sequence Analysis, DNA economics, Genome, Human, Genomics, Hearing Loss genetics, High-Throughput Nucleotide Sequencing methods, Sequence Analysis, DNA methods

Abstract

Background: Targeted genomic enrichment (TGE) is a widely used method for isolating and enriching specific genomic regions prior to massively parallel sequencing. To make effective use of sequencer output, barcoding and sample pooling (multiplexing) after TGE and prior to sequencing (post-capture multiplexing) has become routine. While previous reports have indicated that multiplexing prior to capture (pre-capture multiplexing) is feasible, no thorough examination of the effect of this method has been completed on a large number of samples. Here we compare standard post-capture TGE to two levels of pre-capture multiplexing: 12 or 16 samples per pool. We evaluated these methods using standard TGE metrics and determined the ability to identify several classes of genetic mutations in three sets of 96 samples, including 48 controls. Our overall goal was to maximize cost reduction and minimize experimental time while maintaining a high percentage of reads on target and a high depth of coverage at thresholds required for variant detection., Results: We adapted the standard post-capture TGE method for pre-capture TGE with several protocol modifications, including redesign of blocking oligonucleotides and optimization of enzymatic and amplification steps. Pre-capture multiplexing reduced costs for TGE by at least 38% and significantly reduced hands-on time during the TGE protocol. We found that pre-capture multiplexing reduced capture efficiency by 23 or 31% for pre-capture pools of 12 and 16, respectively. However efficiency losses at this step can be compensated by reducing the number of simultaneously sequenced samples. Pre-capture multiplexing and post-capture TGE performed similarly with respect to variant detection of positive control mutations. In addition, we detected no instances of sample switching due to aberrant barcode identification., Conclusions: Pre-capture multiplexing improves efficiency of TGE experiments with respect to hands-on time and reagent use compared to standard post-capture TGE. A decrease in capture efficiency is observed when using pre-capture multiplexing; however, it does not negatively impact variant detection and can be accommodated by the experimental design.

Published

2012

4. Prediction of cochlear implant performance by genetic mutation: the spiral ganglion hypothesis.

Author

Eppsteiner RW, Shearer AE, Hildebrand MS, Deluca AP, Ji H, Dunn CC, Black-Ziegelbein EA, Casavant TL, Braun TA, Scheetz TE, Scherer SE, Hansen MR, Gantz BJ, and Smith RJ

Subjects

Acoustic Stimulation, Adult, Aged, Analysis of Variance, Audiometry, Pure-Tone, Auditory Threshold, Carrier Proteins genetics, Chi-Square Distribution, Female, Gene Expression Regulation, Genetic Predisposition to Disease, Hearing Loss diagnosis, Hearing Loss pathology, Hearing Loss physiopathology, Humans, Male, Membrane Proteins genetics, Middle Aged, Neoplasm Proteins genetics, Patient Selection, Phenotype, Serine Endopeptidases genetics, Severity of Illness Index, Spiral Ganglion pathology, Cochlear Implantation instrumentation, Cochlear Implants, Correction of Hearing Impairment, DNA Mutational Analysis, Hearing Loss genetics, Hearing Loss rehabilitation, Mutation, Persons With Hearing Impairments rehabilitation, Spiral Ganglion physiopathology

Abstract

Background: Up to 7% of patients with severe-to-profound deafness do not benefit from cochlear implantation. Given the high surgical implantation and clinical management cost of cochlear implantation (>$1 million lifetime cost), prospective identification of the worst performers would reduce unnecessary procedures and healthcare costs. Because cochlear implants bypass the membranous labyrinth but rely on the spiral ganglion for functionality, we hypothesize that cochlear implant (CI) performance is dictated in part by the anatomic location of the cochlear pathology that underlies the hearing loss. As a corollary, we hypothesize that because genetic testing can identify sites of cochlear pathology, it may be useful in predicting CI performance., Methods: 29 adult CI recipients with idiopathic adult-onset severe-to-profound hearing loss were studied. DNA samples were subjected to solution-based sequence capture and massively parallel sequencing using the OtoSCOPE(®) platform. The cohort was divided into three CI performance groups (good, intermediate, poor) and genetic causes of deafness were correlated with audiometric data to determine whether there was a gene-specific impact on CI performance., Results: The genetic cause of deafness was determined in 3/29 (10%) individuals. The two poor performers segregated mutations in TMPRSS3, a gene expressed in the spiral ganglion, while the good performer segregated mutations in LOXHD1, a gene expressed in the membranous labyrinth. Comprehensive literature review identified other good performers with mutations in membranous labyrinth-expressed genes; poor performance was associated with spiral ganglion-expressed genes., Conclusions: Our data support the underlying hypothesis that mutations in genes preferentially expressed in the spiral ganglion portend poor CI performance while mutations in genes expressed in the membranous labyrinth portend good CI performance. Although the low mutation rate in known deafness genes in this cohort likely relates to the ascertainment characteristics (postlingual hearing loss in adult CI recipients), these data suggest that genetic testing should be implemented as part of the CI evaluation to test this association prospectively., (Copyright © 2012 Elsevier B.V. All rights reserved.)

Published

2012

5. Carcinoembryonic antigen-related cell adhesion molecule 16 interacts with alpha-tectorin and is mutated in autosomal dominant hearing loss (DFNA4).

Author

Zheng J, Miller KK, Yang T, Hildebrand MS, Shearer AE, DeLuca AP, Scheetz TE, Drummond J, Scherer SE, Legan PK, Goodyear RJ, Richardson GP, Cheatham MA, Smith RJ, and Dallos P

Subjects

Amino Acid Sequence, Animals, Blotting, Western, Cell Adhesion Molecules chemistry, Cell Adhesion Molecules genetics, GPI-Linked Proteins metabolism, Hearing Loss genetics, Humans, In Situ Hybridization, Mice, Molecular Sequence Data, RNA, Messenger genetics, Cell Adhesion Molecules metabolism, Extracellular Matrix Proteins metabolism, Genes, Dominant, Hearing Loss metabolism, Mutation, Myosin Heavy Chains genetics, Myosin Type II genetics

Abstract

We report on a secreted protein found in mammalian cochlear outer hair cells (OHC) that is a member of the carcinoembryonic antigen-related cell adhesion molecule (CEACAM) family of adhesion proteins. Ceacam16 mRNA is expressed in OHC, and its protein product localizes to the tips of the tallest stereocilia and the tectorial membrane (TM). This specific localization suggests a role in maintaining the integrity of the TM as well as in the connection between the OHC stereocilia and TM, a linkage essential for mechanical amplification. In agreement with this role, CEACAM16 colocalizes and coimmunoprecipitates with the TM protein α-tectorin. In addition, we show that mutation of CEACAM16 leads to autosomal dominant nonsyndromic deafness (ADNSHL) at the autosomal dominant hearing loss (DFNA4) locus. In aggregate, these data identify CEACAM16 as an α-tectorin-interacting protein that concentrates at the point of attachment of the TM to the stereocilia and, when mutated, results in ADNSHL at the DFNA4 locus.

Published

2011

6. Loss-of-function mutations of ILDR1 cause autosomal-recessive hearing impairment DFNB42.

Author

Borck G, Ur Rehman A, Lee K, Pogoda HM, Kakar N, von Ameln S, Grillet N, Hildebrand MS, Ahmed ZM, Nürnberg G, Ansar M, Basit S, Javed Q, Morell RJ, Nasreen N, Shearer AE, Ahmad A, Kahrizi K, Shaikh RS, Ali RA, Khan SN, Goebel I, Meyer NC, Kimberling WJ, Webster JA, Stephan DA, Schiller MR, Bahlo M, Najmabadi H, Gillespie PG, Nürnberg P, Wollnik B, Riazuddin S, Smith RJ, Ahmad W, Müller U, Hammerschmidt M, Friedman TB, Riazuddin S, Leal SM, Ahmad J, and Kubisch C

Subjects

Animals, Chromosome Mapping, Chromosomes, Human, Pair 3 genetics, Consanguinity, Ear, Inner, Female, Genetic Linkage, Genotype, Humans, In Situ Hybridization, Lod Score, Male, Mice, Pedigree, Zebrafish, Codon, Nonsense genetics, Genes, Recessive genetics, Genetic Predisposition to Disease, Hearing Loss genetics, Receptors, Cell Surface genetics

Abstract

By using homozygosity mapping in a consanguineous Pakistani family, we detected linkage of nonsyndromic hearing loss to a 7.6 Mb region on chromosome 3q13.31-q21.1 within the previously reported DFNB42 locus. Subsequent candidate gene sequencing identified a homozygous nonsense mutation (c.1135G>T [p.Glu379X]) in ILDR1 as the cause of hearing impairment. By analyzing additional consanguineous families with homozygosity at this locus, we detected ILDR1 mutations in the affected individuals of 10 more families from Pakistan and Iran. The identified ILDR1 variants include missense, nonsense, frameshift, and splice-site mutations as well as a start codon mutation in the family that originally defined the DFNB42 locus. ILDR1 encodes the evolutionarily conserved immunoglobulin-like domain containing receptor 1, a putative transmembrane receptor of unknown function. In situ hybridization detected expression of Ildr1, the murine ortholog, early in development in the vestibule and in hair cells and supporting cells of the cochlea. Expression in hair cell- and supporting cell-containing neurosensory organs is conserved in the zebrafish, in which the ildr1 ortholog is prominently expressed in the developing ear and neuromasts of the lateral line. These data identify loss-of-function mutations of ILDR1, a gene with a conserved expression pattern pointing to a conserved function in hearing in vertebrates, as underlying nonsyndromic prelingual sensorineural hearing impairment., (Copyright © 2011 The American Society of Human Genetics. Published by Elsevier Inc. All rights reserved.)

Published

2011

7. Comprehensive genetic testing for hereditary hearing loss using massively parallel sequencing.

Author

Shearer AE, DeLuca AP, Hildebrand MS, Taylor KR, Gurrola J 2nd, Scherer S, Scheetz TE, and Smith RJ

Subjects

DNA Mutational Analysis, Genotype, Humans, Polymorphism, Single Nucleotide, Software, Genetic Testing methods, Hearing Loss genetics, Sequence Analysis, DNA methods

Abstract

The extreme genetic heterogeneity of nonsyndromic hearing loss (NSHL) makes genetic diagnosis expensive and time consuming using available methods. To assess the feasibility of target-enrichment and massively parallel sequencing technologies to interrogate all exons of all genes implicated in NSHL, we tested nine patients diagnosed with hearing loss. Solid-phase (NimbleGen) or solution-based (SureSelect) sequence capture, followed by 454 or Illumina sequencing, respectively, were compared. Sequencing reads were mapped using GSMAPPER, BFAST, and BOWTIE, and pathogenic variants were identified using a custom-variant calling and annotation pipeline (ASAP) that incorporates publicly available in silico pathogenicity prediction tools (SIFT, BLOSUM, Polyphen2, and Align-GVGD). Samples included one negative control, three positive controls (one biological replicate), and six unknowns (10 samples total), in which we genotyped 605 single nucleotide polymorphisms (SNPs) by Sanger sequencing to measure sensitivity and specificity for SureSelect-Illumina and NimbleGen-454 methods at saturating sequence coverage. Causative mutations were identified in the positive controls but not in the negative control. In five of six idiopathic hearing loss patients we identified the pathogenic mutation. Massively parallel sequencing technologies provide sensitivity, specificity, and reproducibility at levels sufficient to perform genetic diagnosis of hearing loss.

Published

2010

8. Mutations in TMC1 are a common cause of DFNB7/11 hearing loss in the Iranian population.

Author

Hildebrand MS, Kahrizi K, Bromhead CJ, Shearer AE, Webster JA, Khodaei H, Abtahi R, Bazazzadegan N, Babanejad M, Nikzat N, Kimberling WJ, Stephan D, Huygen PL, Bahlo M, Smith RJ, and Najmabadi H

Subjects

Chromosome Mapping, Computers, Handheld, Consanguinity, Deafness congenital, Deafness genetics, Genome-Wide Association Study, Genotype, Hearing Loss congenital, Humans, Iran, Microsatellite Repeats, Pedigree, Polymorphism, Single Nucleotide, RNA Splice Sites genetics, Sequence Analysis, DNA, Sequence Deletion, Hearing Loss genetics, Membrane Proteins genetics, Mutation

Abstract

Objectives: We investigated the cause of autosomal recessive nonsyndromic hearing loss (ARNSHL) that segregated in 2 consanguineous Iranian families., Methods: Otologic and audiometric examinations were performed on affected members of each family. Genome-wide parametric multipoint linkage mapping using a recessive model was performed with Affymetrix 50K GeneChips or short tandem repeat polymorphisms. Direct sequencing was used to confirm the causative mutation in each family., Results: In 2 Iranian families, L-1651 and L-8600606, with ARNSHL that mapped to the DFNB7/11 locus, homozygosity for a reported splice site mutation (c.776+1G>A), and a novel deletion (c.1589_1590delCT; p.S530*) were identified in the TMC1 gene, respectively., Conclusions: Consistent with the previously reported phenotype in DFNB7/11 families, the 2 Iranian families had segregated congenital, profound hearing impairment. However, in family L-1651, one affected family member (IV:3) has milder hearing impairment than expected, suggesting a potential genetic modifier effect. These results indicate that DFNB7/11 is a common form of genetic hearing loss in Iran, because this population is the source of 6 of the 29 TMC1 mutations reported worldwide.

Published

2010

9. Variable hearing impairment in a DFNB2 family with a novel MYO7A missense mutation.

Author

Hildebrand MS, Thorne NP, Bromhead CJ, Kahrizi K, Webster JA, Fattahi Z, Bataejad M, Kimberling WJ, Stephan D, Najmabadi H, Bahlo M, and Smith RJ

Subjects

Adult, Amino Acid Sequence, Base Sequence, Chromosome Mapping, Consanguinity, Family, Female, Hearing Loss, Sensorineural genetics, Humans, Male, Middle Aged, Molecular Sequence Data, Myosin VIIa, Hearing Loss genetics, Mutation, Missense, Myosins genetics

Abstract

Myosin VIIA mutations have been associated with non-syndromic hearing loss (DFNB2; DFNA11) and Usher syndrome type 1B (USH1B). We report clinical and genetic analyses of a consanguineous Iranian family segregating autosomal recessive non-syndromic hearing loss (ARNSHL). The hearing impairment was mapped to the DFNB2 locus using Affymetrix 50K GeneChips; direct sequencing of the MYO7A gene was completed. The Iranian family (L-1419) was shown to segregate a novel homozygous missense mutation (c.1184G>A) that results in a p.R395H amino acid substitution in the motor domain of the myosin VIIA protein. As one affected family member had significantly less severe hearing loss, we used a candidate approach to search for a genetic modifier. This novel MYO7A mutation is the first reported to cause DFNB2 in the Iranian population and this DFNB2 family is the first to be associated with a potential modifier. The absence of vestibular and retinal defects, and less severe low frequency hearing loss, is consistent with the phenotype of a recently reported Pakistani DFNB2 family. Thus, we conclude this family has non-syndromic hearing loss (DFNB2) rather than USH1B, providing further evidence that these two diseases represent discrete disorders.

Published

2010

10. A contemporary review of AudioGene audioprofiling: a machine-based candidate gene prediction tool for autosomal dominant nonsyndromic hearing loss.

Author

Hildebrand MS, DeLuca AP, Taylor KR, Hoskinson DP, Hur IA, Tack D, McMordie SJ, Huygen PL, Casavant TL, and Smith RJ

Subjects

Humans, Genetic Testing methods, Hearing Loss genetics, Mutation, Software

Published

2009

11. Mutations in LOXHD1, an evolutionarily conserved stereociliary protein, disrupt hair cell function in mice and cause progressive hearing loss in humans.

Author

Grillet N, Schwander M, Hildebrand MS, Sczaniecka A, Kolatkar A, Velasco J, Webster JA, Kahrizi K, Najmabadi H, Kimberling WJ, Stephan D, Bahlo M, Wiltshire T, Tarantino LM, Kuhn P, Smith RJ, and Müller U

Subjects

Amino Acid Sequence, Animals, Base Sequence, Carrier Proteins chemistry, Cilia pathology, Cilia ultrastructure, Codon, Terminator genetics, DNA Mutational Analysis, Genes, Recessive, Hair Cells, Auditory, Outer ultrastructure, Hearing Loss pathology, Heterogeneous-Nuclear Ribonucleoproteins genetics, Humans, In Situ Hybridization, Mice, Molecular Sequence Data, Mutation, Missense genetics, Nerve Degeneration genetics, Nerve Degeneration pathology, Protein Structure, Secondary, Spiral Ganglion pathology, Spiral Ganglion ultrastructure, Carrier Proteins genetics, Conserved Sequence, Evolution, Molecular, Hair Cells, Auditory, Outer pathology, Hearing Loss genetics, Mutation genetics

Abstract

Hearing loss is the most common form of sensory impairment in humans and is frequently progressive in nature. Here we link a previously uncharacterized gene to hearing impairment in mice and humans. We show that hearing loss in the ethylnitrosourea (ENU)-induced samba mouse line is caused by a mutation in Loxhd1. LOXHD1 consists entirely of PLAT (polycystin/lipoxygenase/alpha-toxin) domains and is expressed along the membrane of mature hair cell stereocilia. Stereociliary development is unaffected in samba mice, but hair cell function is perturbed and hair cells eventually degenerate. Based on the studies in mice, we screened DNA from human families segregating deafness and identified a mutation in LOXHD1, which causes DFNB77, a progressive form of autosomal-recessive nonsyndromic hearing loss (ARNSHL). LOXHD1, MYO3a, and PJVK are the only human genes to date linked to progressive ARNSHL. These three genes are required for hair cell function, suggesting that age-dependent hair cell failure is a common mechanism for progressive ARNSHL.

Published

2009

12. A novel splice site mutation in the RDX gene causes DFNB24 hearing loss in an Iranian family.

Author

Shearer AE, Hildebrand MS, Bromhead CJ, Kahrizi K, Webster JA, Azadeh B, Kimberling WJ, Anousheh A, Nazeri A, Stephan D, Najmabadi H, Smith RJ, and Bahlo M

Subjects

Case-Control Studies, Chromosomes, Human, Pair 11, Cytoskeletal Proteins chemistry, DNA genetics, DNA isolation & purification, Female, Genetic Linkage, Genetic Markers, Heterozygote, Homozygote, Humans, Introns, Iran, Lod Score, Male, Membrane Proteins chemistry, Oligonucleotide Array Sequence Analysis, Pedigree, Physical Chromosome Mapping, Polymorphism, Single Nucleotide, Protein Structure, Tertiary, Recombination, Genetic, Cytoskeletal Proteins genetics, Family, Hearing Loss genetics, Membrane Proteins genetics, Mutation, RNA Splice Sites genetics

Published

2009

13. Mutation in the COCH gene is associated with superior semicircular canal dehiscence.

Author

Hildebrand MS, Tack D, Deluca A, Hur IA, Van Rybroek JM, McMordie SJ, Muilenburg A, Hoskinson DP, Van Camp G, Pensak ML, Storper IS, Huygen PL, Casavant TL, and Smith RJ

Subjects

Age of Onset, Audiometry, DNA Mutational Analysis, Extracellular Matrix Proteins, Family Health, Hearing Loss epidemiology, Humans, Pedigree, Hearing Loss genetics, Mutation, Proteins genetics, Semicircular Canals pathology

Published

2009

14. Advances in molecular and cellular therapies for hearing loss.

Author

Hildebrand MS, Newton SS, Gubbels SP, Sheffield AM, Kochhar A, de Silva MG, Dahl HH, Rose SD, Behlke MA, and Smith RJ

Subjects

Animals, Genetic Therapy methods, Hearing Loss genetics, Hearing Loss pathology, Humans, Models, Theoretical, RNA Interference, Stem Cell Transplantation methods, Disease Models, Animal, Hearing Loss therapy

Abstract

Development of effective therapeutics for hearing loss has proven to be a slow and difficult process, evidenced by the lack of restorative medicines and technologies currently available to the otolaryngologist. In large part this is attributable to the limited regenerative potential in cochlear cells and the secondary degeneration of the cochlear architecture that commonly follows sensorineural hearing impairment. Therapeutic advances have been made using animal models, particularly in regeneration and remodeling of spiral ganglion neurons, which retract and die following hair cell loss. Natural regeneration in avian and reptilian systems provides hope that replacement of hair cells is achievable in humans. The most exciting recent advancements in this field have been made in the relatively new areas of cellular replacement and gene therapy. In this review we discuss recent developments in gene- and cell-based therapy for hearing loss, including detailed analysis of therapeutic mechanisms such as RNA interference and stem cell transplantation, as well as in utero delivery to the mammalian inner ear. We explore the advantages and limitations associated with the use of these strategies for inner ear restoration.

Published

2008

15. A novel splice site mutation in EYA4 causes DFNA10 hearing loss.

Author

Hildebrand MS, Coman D, Yang T, Gardner RJ, Rose E, Smith RJ, Bahlo M, and Dahl HH

Subjects

Audiometry, Base Sequence, Chromosome Mapping, Chromosomes, Human, Pair 6 genetics, DNA Mutational Analysis, Family Health, Female, Genotype, Hearing Loss physiopathology, Humans, Lod Score, Male, Pedigree, Polymorphism, Single Nucleotide, Alternative Splicing genetics, Hearing Loss genetics, Mutation, Trans-Activators genetics

Abstract

Nonsyndromic autosomal dominant sensorineural hearing loss (SNHL) at the DFNA10 locus was described in two families in 2001. Causative mutations that affect the EyaHR domain of the 'Eyes absent 4' (EYA4) protein were identified. We report on the clinical and genetic analyses of an Australian family with nonsyndromic SNHL. Screening of the EYA4 gene showed the novel polypyrimidine tract variation ca. 1,282-12T > A that introduces a new 3' splice acceptor site. This is the first report of a point mutation in EYA4 that is hypothesized to lead to aberrant pre-mRNA splicing and human disease. The DFNA10 family described is only the fourth to be identified. One individual presented with apparently the same phenotype as other affected members of the family. However, genotyping illustrated that he did not share the DFNA10 disease haplotype. Detailed clinical investigation showed differences in the onset and severity of his hearing loss and thus he is presumed to represent a phenocopy, perhaps resulting from long-term exposure to loud noise., ((c) 2007 Wiley-Liss, Inc)

Published

2007

16. Clinical aspects of hereditary hearing loss.

Author

Kochhar A, Hildebrand MS, and Smith RJ

Subjects

Cochlea, Gene Expression Regulation, Humans, Patient Education as Topic, Prostheses and Implants, Terminology as Topic, Genetic Diseases, Inborn diagnosis, Genetic Diseases, Inborn epidemiology, Genetic Diseases, Inborn genetics, Genetic Diseases, Inborn therapy, Hearing Loss diagnosis, Hearing Loss epidemiology, Hearing Loss genetics, Hearing Loss therapy, Language Development

Abstract

Hearing loss is an etiologically diverse condition with many disease-related complications and major clinical, social, and quality of life implications. As the rate of acquired hearing loss secondary to environmental causes decreases and improvements in the diagnosis of abnormalities occur, the significance of genetic factors that lead to deafness increases. Advancements in molecular biology have led to improved detection and earlier intervention in patients with hearing loss. Subsequently, earlier implementation of educational services and cochlear implant technology in patients with profound hearing loss now results in superior communication skills and enhanced language development. The aim of this review is to provide a comprehensive framework underlying the causes of hearing impairment and to detail the clinical management for patients with hereditary hearing loss.

Published

2007