Education: PhD, University of Wisconsin–Madison Regulation of Neuronal Polarity and Acquisition of Neuronal Fate in C. Elegans The work that goes on in my laboratory attempts to elucidate the mechanism(s) involved in (1) sorting and trafficking of neuronal specific proteins (cell biology) and (2) specification of neuronal identity (developmental biology). Our approach has been to isolate and characterize mutations that disrupt these processes with the goal of understanding the role of the wild type products in the process. Specifically we use the soil nematode Caenorhabditis elegans (C. elegans) as a model system to analyze (1) the role of the clathrin adaptor protein UNC-11 (C elegans AP180) in the trafficking of the synaptic vesicle (SV) protein synaptobrevin (SNB) and (2) the role of basic helix loop helix proteins such as HLH-3 in the differentiation and function of neurons.
Our analysis of unc-11 mutants has revealed that the UNC-11/AP180 protein is necessary to regulate the assembly of clathrin coats and is involved in the trafficking/sorting of the integral SV protein SNB (Nonet et al., 1999). Synaptobrevin is essential for generating fusion-competent SVs; it is one of the three components in the complex that mediates SV fusion. In C. elegans unc-11 encodes a family of protein isoforms; we have invested a significant amount of effort in the analysis of their structure and function to determine how these clathrin assembly proteins promote the trafficking/sorting of this essential SV protein. Since all cells have proteins homologous to UNC-11 [AP180 is in the nervous system and CALM is in the trans-Golgi network (TGN) and at the plasma membrane of all cells (Tebar et al., 1999)], and SV formation and SV recycling are specialized types of membrane recycling, then, our studies should also shed light into the mechanisms of the fundamental process of membrane trafficking and protein sorting by this family of monomeric assembly proteins in cells in general.
Our analysis of hlh-3 mutants has revealed that the HLH-3 protein (a transcription factor) has a role in the differentiation of sex specific neurons in both hermaphrodites and males. In hermaphrodites HLH-3 is necessary for the differentiation of the egg-laying motor neurons (HSNs) and in the absence of hlh-3 function mutant hermaphrodites are egg-laying defective (Egl) (Doonan et al., 2008). Mutant males are defective in specific mating steps and it appears some of the male-specific neurons mediating these behaviors are also affected in the differentiation (unpublished). Our emphasis is on characterizing how hlh-3 is regulated and identifying its downstream targets.
Representative Publications (Complete list of publications on Google Scholar)
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