To identify new molecules involved in neuromuscular signaling, we used RNAi to screen for cell adhesion molecules whose absence alters the responsiveness of Caenorhabditis elegans to the acetylcholinesterase
inhibitor aldicarb. Aldicarb treatment causes acute paralysis due to the accumulation of acetylcholine (ACh) in the synaptic cleft at the neuromuscular junction (NMJ). Gene inactivations that alter synaptic function can cause either resistance or hypersensitivity to aldicarb ( Miller et al., 1996, Sieburth et al., 2005 and Vashlishan selleck chemical et al., 2008). For this screen, we selected a collection of 216 putative cell adhesion molecules, based on the presence of protein domains found in CAMs (data not shown). A gene identified in this screen was rig-3, which encodes a GPI-anchored protein containing two Ig domains and a divergent fibronectin type III (FNIII) domain ( Figure 1A). RIG-3 has a pattern of protein domains that is similar to the Drosophila proteins Klingon and Wrapper, and to mammalian NCAMs ( Cox et al., 2004 and Yamagata check details et al., 2003). RIG-3 was previously implicated in axon guidance in C. elegans; however rig-3 single mutants do not show guidance defects ( Schwarz et al., 2009). Inactivation of rig-3 by RNAi caused significant hypersensitivity to aldicarb ( Figure 1B) and
a similar defect was Mannose-binding protein-associated serine protease observed in homozygous rig-3(ok2156) mutants ( Figure 1C). The ok2156 mutation deletes 1.5 kb of the rig-3 gene, spanning exons 2–5 (including most of the Ig domains and part of the FNIII domain); consequently, ok2156 is likely to cause a severe loss of gene function (www.wormbase.org) ( Figure 1A) ( Schwarz et al., 2009). The rig-3 aldicarb hypersensitivity defect was rescued by transgenes driving RIG-3 expression in all neurons (utilizing the snb-1 Synaptobrevin promoter, data not shown) and in cholinergic neurons (utilizing the unc-17 VAChT promoter) ( Figure 1C). By contrast, rig-3 transgenes expressed in GABA neurons, or in the intestine lacked rescuing
activity ( Figure 1C). None of these transgenes altered aldicarb responsiveness of wild-type animals (data not shown). These results suggest that RIG-3 functions in cholinergic neurons to regulate some aspect of neuromuscular function or development. Prior work showed that rig-3 is expressed in neurons and in the intestine (www.wormbase.org) ( Schwarz et al., 2009). A construct containing the full rig-3 genomic region, with mCherry inserted just after the signal sequence ( Figure 1A), was expressed in ventral cord motor neurons but not in body muscles ( Figure 2A and data not shown). To identify the rig-3 expressing motor neurons, we performed several double labeling experiments.