TITLE: Maintenance and Disassembly of Olfactory Cilia The long-term goal of this project is to determine the role of cilia in the regulation and maintenance of olfactory function and their alterations in cilia-related disorders. Olfactory dysfunction is common, affecting at least 16 million people in the U.S. alone. Our lab and others have found olfactory dysfunction to be a clinical manifestation of a class of human genetic disorders termed ciliopathies. Bardet-Biedl syndrome (BBS) is one such disorder, in which the altered cilia morphology of olfactory sensory neurons (OSNs) renders the cells unresponsive to odors. Despite the identification of numerous genes underlying ciliopathies, curative therapies (including for olfactory dysfunctions) are not yet available to patients. We reported that gene replacement to restore cilia and hence sensory input in a limited number of differentiated OSNs was sufficient to rescue peripheral odor responses in mouse models of a subset of ciliopathies. However, to better understand cilia biology in the olfactory system and advance potential therapies, we must define the cellular mechanisms underlying olfactory penetrance of ciliopathies. We must also determine whether these mechanisms are conserved across different ciliopathies and might thus be amenable to the same therapeutic strategies. OSN cilia compartmentalize all of necessary signaling machinery for odor detection and even though OSN cilia can be lost in both physiological and pathological conditions, the cellular mechanisms that maintain the integrity of this essential OSN cell compartment remain poorly understood. Cilia in other cells and organisms contain a multiprotein complex at its base, termed the transition zone (TZ), that functions as a regulatory gate to control the unique protein and lipid composition of cilia. Surprisingly little is known about the TZ in OSNs. This grant application will elucidate the composition and subcellular organization of the OSN cilia TZ and how aberrant protein and lipid translocation into cilia contributes to the disassembly of cilia. Our preliminary data suggest that alterations in intracellular Ca2+ contribute to cilia disassembly by disrupting TZ components. We hypothesize that sustained elevations of intracellular Ca2+ result in TZ remodeling of OSN cilia that is permissive for changes in cilia membrane lipid distribution and actin infiltration, both of which are necessary for cilia disassembly in ciliopathies. Therefore, we propose the following Specific Aims: (1) Determine the composition and organization of the OSN cilia TZ and alterations accompanying disassembly in ciliopathies; (2) Determine the effects of elevated intracellular Ca2+ on OSN cilia disassembly; (3) Determine the role of membrane PIP2 redistribution and F-actin infiltration in cellular mechanisms of OSN cilia disassembly. Successful completion of this work will provide critical new insights into the pathogenesis of human sensory perception diseases and is a necessary step for the development of treatments for congenital anosmia and related olfactory dysfunctions that result from ciliopathy.
LAYMAN?S STATEMENT/ NARRATIVE One known cause of smell impairment is a disruption of cilia, hair-like projections that extend from neurons in the nose into the nasal cavity. Olfactory cilia are essential for detecting odors, and genetic diseases that disrupt the cilia ? called ciliopathies ? have been tied to the loss of smell. The goal for this proposal is to better understand the function of olfactory cilia, how disruption to these cilia causes smell impairment, and how gene therapy approaches could be used to restore smell function in people with these disorders.
