The type I membrane protein EFF-1 is essential for developmental cell fusion.

Multinucleate cells are widespread in nature, yet the mechanism by which cells fuse their plasma membranes is poorly understood. To identify animal fusogens, we performed new screens for mutations that abolish cell fusion within tissues of C. elegans throughout development. We identified the gene eff-1, which is expressed as cells acquire fusion competence and encodes a novel integral membrane protein. EFF-1 sequence motifs suggest physicochemical actions that could cause adjacent bilayers to fuse. Mutations in the extracellular domain of EFF-1 completely block epithelial cell membrane fusion without affecting other perfusion events such as cell generation, patterning, differentiation, and adhesion. Thus, EFF-1 is a key component in the mechanism of cell fusion, a process essential to normal animal development.

Fusogenic activity of EFF-1 is regulated via dynamic localization in fusing somatic cells of C. elegans.

BACKGROUND: Many animal tissues form via fusion of cells. Yet in all instances of developmental cell fusion, the mechanism underlying fusion of plasma membranes remains poorly understood. EFF-1 is required for most somatic cell fusions in C. elegans, and misexpressed EFF-1 alters the normal pattern of fusing hypodermal cells. However, the autonomous activity of EFF-1, the rules governing its specificity, and the mechanism of its action have not been examined. RESULTS: We show that EFF-1 acts as a cellular fusogen, capable of inducing fusion of virtually any somatic cells in C. elegans, yet targeted precisely to fusion-fated contacts during normal development. Misexpression of EFF-1 in early embryos causes fusion among groups of cells composed entirely of nonfusion-fated members. Measurements of cytoplasm diffusion in induced fusion events show that ectopic EFF-1 expression produces fusion pores similar to those in normal fusion events. GFP-labeled EFF-1 is specifically targeted to fusion-competent cell contacts via reciprocal localization to the touching membranes of EFF-1-expressing cells. EFF-1 function is also governed by intercellular barriers that prohibit cell fusion between distinct tissues. Analysis of mutant versions of EFF-1 indicates a novel mode of fusogenicity, employing neither a phospholipase active site nor hydrophobic fusion-peptide acting solely in pore formation. CONCLUSIONS: EFF-1 can confer potent fusogenic activity to nonfusing cell types. However, it is normally targeted only to fusion-fated cell borders via mutual interaction between EFF-1-expressing cells and relocalization to the plasma membrane. Because EFF-1 appears evolutionarily unique to nematodes, multiple mechanisms may have evolved for controlled plasma-membrane fusion in development.