Hearing loss is the most prevalent sensory deficit in humans and causes a significant toll on the quality of life of those afflicted. The mammalian cochlea initiates the perception of sound by converting sound waves into electrical signals with exquisite sensitivity, speed and precision. Mechanotransduction in sensory hair cells leads to electrochemical signalsthat induce neurotransmitter release from specialized ribbon synapses, initiating the neural signal for auditory processing. The molecular composition of the auditory processing machinery in hair cells is not well understood, and the nature of how specific molecular interactions lead to physiological events for the processing of sound is unclear. Over 100 nonsyndromic forms of genetic hearing loss have been described but many of the genes linked with these mutations are unknown or not well characterized. Mutations in Catechol-O- methyltransferase 2 (COMT2) cause nonsyndromic recessive deafness (DFNB63) in humans. Our lab generated by ENU-mutagenesis a mouse mutant (termed `Add') in which a point mutation in Comt2, the mouse homolog of the human gene, leads to profound deafness. Comt2 mRNA is expressed by hair cells in the inner ear but the manner in which COMT2 contributes to auditory processing in mice and humans is completely unknown. The objective of this proposal is to investigate the role of COMT2 in the peripheral auditory system and the contribution of COMT2 to auditory processing. The hypothesis is that COMT2 contributes to hair cell function and auditory processing by regulating synapse function in the cochlea.
Aim 1 will utilize in situ hybridization, immunohistochemistry and immunogold electron microscopy to precisely characterize the cell-specific and temporal expression patterns of Comt2 mRNA in the mouse inner ear and auditory brainstem and the subcellular localization of COMT2 protein in sensory hair cells.
Aim 2 will use CRISPR/Cas9 technologies to generate and validate constitutive Comt2 null mice and floxed Comt2 mice to facilitate studies that will examine loss of Comt2 function on peripheral auditory function and auditory processing.
Aim 3 will analyze Comt2 mutants to determine the mechanism by which Comt2 contributes to auditory processing in sensory hair cells. By interrogating Comt2 expression patterns and functions within the auditory system, this work will contribute to a better understanding of mechanisms of auditory processing, physiological roles of COMT2, and etiologies of DFNB63 in humans.
Genetic studies of deafness-related genes in mice provide significant opportunities to gain insights into mechanisms of auditory processing and etiologies of disease in humans. Mutations in Catechol-O- methyltransferase 2 (COMT2) cause nonsyndromic recessive deafness DFNB63 in humans, and deafness in mice by mechanisms that are not understood. This project will seek to characterize COMT2 expression and function in mice, providing important insights into auditory processing and peripheral auditory function, and the etiology of COMT2-linked deafness.
Cunningham, Christopher L; Wu, Zizhen; Jafari, Aria et al. (2017) The murine catecholamine methyltransferase mTOMT is essential for mechanotransduction by cochlear hair cells. Elife 6: |