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Active NON-SBIR/STTR RPGS NIH (US)

Molecular mechanisms underlying morphogenesis of the tectorial membrane

$3.24M USD

Funder NATIONAL INSTITUTE ON DEAFNESS AND OTHER COMMUNICATION DISORDERS
Recipient Organization University of Utah
Country United States
Start Date Feb 09, 2021
End Date Jan 31, 2026
Duration 1,817 days
Number of Grantees 1
Roles Principal Investigator
Data Source NIH (US)
Grant ID 10766131
Grant Description

PROJECT SUMMARY/ABSTRACT The tectorial membrane (TM) is an extracellular matrix (ECM) that lies over the organ of Corti. The TM plays important roles in frequency selection, propagation, and amplification of sound waves. Malformation of the TM causes hereditary hearing deficits. Since the TM is an acellular structure, its unique properties arise from the

matrix architecture. The TM exhibits sophisticated ultrastructural features and domain-specific patterns of matrix organization. However, the mechanisms by which the specific matrix architectures are organized outside of cells are unknown. Is it determined by its molecular composition and/or mode of organization? We

observed that surface-tethering of a-tectorin/TECTA via a glycosylphosphatidylinositol (GPI)-anchor is required to prevent diffusion of secreted TM components into the luminal space of the scala media and to form the TM matrix on the apical surface of TM-producing cells. The release of TECTA plays a critical role in the growth of

the TM layers. Our in vitro assays show that TECTA is released from the producing cells by multiple mechanisms and that the different forms of TECTA released by these distinct mechanisms show unique multimerization activities. In this proposal, we will determine the molecular mechanism by which TECTA

mediates the organization of specific TM architecture. We will characterize molecular dynamics that occur during the matrix maturation. Our results will provide the first evidence of how a complex ECM structure is established and matures in the extracellular space at the molecular level. This will provide novel insights into

the process of morphogenesis as well as the mechanism of hereditary and age-related hearing deficits.

All Grantees

University of Utah

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