Dominant Progressive Hearing Loss (DPHL) has its onset in childhood and progresses to severe to profound loss in adulthood. The cause of the hearing loss is unknown, and there is currently no treatment to stop the progression. There is general phenotypic consistency within families, but marked differences between families for such characteristics as age of onset, rate of progression, frequencies initially affected, and vestibular involvement. This variation reflects the genetic heterogeneity which has now been proven in our laboratory and in others. Genetic heterogeneity will complicate research into the causes and treatment of progressive hearing loss, since different genes can be expected to have different pathogenic mechanisms. This project will utilize a dense map of DNA microsatellite repeat polymorphisms to localize the genes for DPHL and complete audiological and vestibular evaluations will be used to characterize their phenotypes. Localization of the genes for DPHL through linkage analysis has two important effects. First, the particular gene involved in causing the hearing loss in a given family can be identified by its linkage results. From this, data from individuals with the same type of hearing loss can be grouped for further research into mechanism and treatment. Secondly, gene localization is the first step toward characterization of the gene itself. Over the longer term, the data collected as part of this project will help foster further research into therapies that may prevent the gradual deterioration of hearing.

Project Start
1997-09-01
Project End
1998-08-31
Budget Start
1996-10-01
Budget End
1997-09-30
Support Year
8
Fiscal Year
1997
Total Cost
Indirect Cost
Name
Father Flanagan's Boys' Home
Department
Type
DUNS #
City
Boys Town
State
NE
Country
United States
Zip Code
68010
Song, Lei; McGee, Joann; Walsh, Edward J (2008) The influence of thyroid hormone deficiency on the development of cochlear nonlinearities. J Assoc Res Otolaryngol 9:464-76
Song, Lei; McGee, JoAnn; Walsh, Edward J (2008) Development of cochlear amplification, frequency tuning, and two-tone suppression in the mouse. J Neurophysiol 99:344-55
Varga, R; Avenarius, M R; Kelley, P M et al. (2006) OTOF mutations revealed by genetic analysis of hearing loss families including a potential temperature sensitive auditory neuropathy allele. J Med Genet 43:576-81
Song, Lei; McGee, Jo Ann; Walsh, Edward J (2006) Consequences of combined maternal, fetal and persistent postnatal hypothyroidism on the development of auditory function in Tshrhyt mutant mice. Brain Res 1101:59-72
Song, Lei; McGee, Joann; Walsh, Edward J (2006) Frequency- and level-dependent changes in auditory brainstem responses (ABRS) in developing mice. J Acoust Soc Am 119:2242-57
Higgins, Maureen B; McCleary, Elizabeth A; Ide-Helvie, Dana L et al. (2005) Speech and voice physiology of children who are hard of hearing. Ear Hear 26:546-58
Pennings, Ronald J E; Topsakal, Vedat; Astuto, Lisa et al. (2004) Variable clinical features in patients with CDH23 mutations (USH1D-DFNB12). Otol Neurotol 25:699-706
Varga, R; Kelley, P M; Keats, B J et al. (2003) Non-syndromic recessive auditory neuropathy is the result of mutations in the otoferlin (OTOF) gene. J Med Genet 40:45-50
Higgins, Maureen B; McCleary, Elizabeth A; Carney, Arlene Earley et al. (2003) Longitudinal changes in children's speech and voice physiology after cochlear implantation. Ear Hear 24:48-70
Bhattacharya, Gautam; Miller, Caroline; Kimberling, William J et al. (2002) Localization and expression of usherin: a novel basement membrane protein defective in people with Usher's syndrome type IIa. Hear Res 163:1-11

Showing the most recent 10 out of 75 publications