The tail tip of C. elegans males is a simple and powerful model for elucidating the mechanism of postembryonic morphogenesis and its regulation in space and time. In males during L4, the four tail tip cells hyp(8–11) fuse, change shape, and migrate anteriorly, forming the rounded ("peloderan") shape of the adult tail. When tail tip morphogenesis fails or is delayed, as in heterochronically retarded
lin-41(gf) mutants, adults retain the pointed ("leptoderan", Lep) shape of the larval tail tip. In precocious
lin-41(lf) mutants, tail tip retraction occurs in the L3 stage, continues throughout L4, and results in over-retracted (Ore) tail tips (Del Rio Albrechtsen et al. 2006). To identify as completely as possible all the components involved in tail tip morphogenesis and its regulation, we performed an RNAi screen by feeding clones from the Ahringer library to L1 larvae and scoring the tails of adult males at 400 for Lep and Ore phenotypes. The screen identified 202 candidate genes, most of which produced Lep phenotypes when knocked down, but some of which produced Ore phenotypes. We made GFP fusion constructs to characterize the spatial and temporal patterns of expression of some of the genes identified by RNAi. These GFP constructs were also used in expression-epistasis experiments. Several regulatory modules were identified, including Hox and other transcription factors, the TGFβ and other signaling pathways, and the heterochronic pathway. It seems likely that regulation is integrated at
dmd-3, a proposed "master regulator" which is necessary and sufficient for tail tip morphogenesis (Mason et al. 2008). There are also crucial roles for cell-biological modules such as those involved in vesicular trafficking or endocytosis, cellular polarity, cytoskeleton organization, and intercellular transport. Furthermore, the online database NBrowse (Kao & Gunsalus 2008) predicted additional components that bridge some of the candidate genes and modules identified in our RNAi screen. A few of these were tested by RNAi and expression analysis, confirming their role in tail tip morphogenesis as well. Future work will test further interactions, determine the nature of these interactions, and characterize the dynamics of gene regulation. These studies also provide a foundation for exploring the evolution of tail tip morphogenesis in rhabditid nematodes.