mab-20 encodes Semaphorin-2a and is required to prevent ectopic cell contacts during epidermal morphogenesis in Caenorhabditis elegans

The Semaphorins are a family of secreted and transmembrane proteins known to elicit growth cone repulsion and collapse. We made and characterized a putative null mutant of the C. elegans gene semaphorin-2a (Ce-sema-2a). This mutant failed to complement mutants of mab-20 (Baird, S. E., Fitch, D. H., Kassem, I. A. A. and Emmons, S. W. (1991) Development 113, 515–526). In addition to low-frequency axon guidance errors, mab-20 mutants have unexpected defects in epidermal morphogenesis. Errant epidermal cell migrations affect epidermal enclosure of the embryo, body shape and sensory rays of the male tail. These phenotypic traits are explained by the formation of inappropriate contacts between cells of similar type and suggest that Ce-Sema-2a may normally prevent formation or stabilization of ectopic adhesive contacts between these cells.

Properties of a class of genes required for ray morphogenesis in Caenorhabditis elegans.

We have identified eight mutations that define at least five terminal differentiation genes (ram genes) whose products are required during the extension of the male-specific ray sensilla in Caenorhabditis elegans. ram gene mutations result in morphological abnormalities in the sensory rays but do not appear to interfere with ray functions. A similar ray morphology phenotype was observed in males harboring mutations in three previously defined genes, dpy-11, dpy-18 and sqt-1, that also affect body shape. One of these genes, sqt-1, is known to encode a collagen. Mutations in different ram genes failed to complement, from which we infer that their gene products functionally interact. For one ram gene, failure to complement was shown to result from haploinsufficiency. Intergenic noncomplementation did not extend to the body morphology genes. The temperature-sensitive periods of both ram and body morphology mutations corresponded to the period of development in which ray extension occurs. We propose that ram gene products act together in a critical interaction between the rays and the cuticle required for wild-type ray morphology.