The mechanisms controlling the formation and maintenance of neuronal trees are poorly understood. We examined the dynamic development of two arborized mechanoreceptor neurons (PVDs) required for reception of strong mechanical stimuli in Caenorhabditis elegans. The PVDs elaborated dendritic trees comprising structural units we call "menorahs." We studied how the number, structure, and function of menorahs were maintained. EFF-1, an essential protein mediating cell fusion, acted autonomously in the PVDs to trim developing menorahs. eff-1 mutants displayed hyperbranched, disorganized menorahs. Overexpression of EFF-1 in the PVD reduced branching. Neuronal pruning appeared to involve EFF-1-dependent branch retraction and neurite-neurite autofusion. Thus, EFF-1 activities may act as a quality control mechanism during the sculpting of dendritic trees.Morphologies of dendritic trees vary from one neuronal type to another, and the pattern of these arbors determines the manner in which a neuron processes its synaptic or sensory input. However, little is known regarding the mechanisms controlling the outgrowth and maintenance of dendritic trees (1-4). Two mechano-receptors in Caenorhabditis elegans (PVDR and PVDL; right and left, respectively) are responsible for an avoidance response triggered by strong mechanical stimuli to the body (5). The complete neural system of C. elegans has been considered to comprise only simple-patterned neurons (6). However, recent studies show that the PVDs have a more complex morphology (7,8).Here, we established a genetic system to dissect the mechanisms of branch generation and plasticity of arborized neurons in C. elegans. To determine branching patterns, we imaged † To whom correspondence should be addressed. podbilew@tx.technion.ac.il (B.P.), ishemer@email.unc.edu (G.S.). * Present address: Department of Biology, University of North Carolina at Chapel Hill, Chapel Hill, NC 27599, USA.
Note added in proof:After we submitted this report, showed that axotomized PLM sensory neurons fail to reconnect in eff-1 mutants. (table S1). The PVDs contained repetitive structural units reminiscent of multibranched candelabras or menorahs (Fig. 1A). Although the number of menorah branches varied, the menorahs appeared to develop in a stepwise manner from the L2 larva to the adult ( fig. S1). The stereotypical menorah structure is likely to form a functional unit necessary for the PVDs mechanosensory activities.Mutations in the cell fusion gene eff-1 (9,10) affected the pattern of PVDs arborization, resulting in disorganized and hyperbranched phenotypes (Fig. 1B). Moreover, eff-1(ok1021) mutant animals showed reduced sensitivity to strong mechanical stimuli (53%, n = 106) (11). To characterize menorah disorganization in eff-1 mutants, we quantified the number of processes at different degrees of the branching order (primary to senary branches; Fig. 1C and fig. S2). The frequency of secondary and tertiary branching was doubled in the eff-1(hy21) mutant compared with wild type. The eff-1(hy21)...
