Analysis of C. elegans acetylcholine synthesis mutants reveals a temperature-sensitive requirement for cholinergic neuromuscular function

In Caenorhabditis elegans, the cha-1 gene encodes choline acetyltransferase (ChAT), the enzyme that synthesizes the neurotransmitter acetylcholine. We have analyzed a large number of cha-1 hypomorphic mutants, most of which are missense alleles. Some homozygous cha-1 mutants have approximately normal ChAT immunoreactivity; many other alleles lead to consistent reductions in synaptic immunostaining, although the residual protein appears to be stable. Regardless of protein levels, neuromuscular function of almost all mutants is temperature sensitive, i.e., neuromuscular function is worse at 25° than at 14°. We show that the temperature effects are not related to acetylcholine release, but specifically to alterations in acetylcholine synthesis. This is not a temperature-dependent developmental phenotype, because animals raised at 20° to young adulthood and then shifted for 2 hours to either 14° or 25° had swimming and pharyngeal pumping rates similar to animals grown and assayed at either 14° or 25°, respectively. We also show that the temperature-sensitive phenotypes are not limited to missense alleles; rather, they are a property of most or all severe cha-1 hypomorphs. We suggest that our data are consistent with a model of ChAT protein physically, but not covalently, associated with synaptic vesicles; and there is a temperature-dependent equilibrium between vesicle-associated and cytoplasmic (i.e., soluble) ChAT. Presumably, in severe cha-1 hypomorphs, increasing the temperature would promote dissociation of some of the mutant ChAT protein from synaptic vesicles, thus removing the site of acetylcholine synthesis (ChAT) from the site of vesicular acetylcholine transport. This, in turn, would decrease the rate and extent of vesicle-filling, thus increasing the severity of the behavioral deficits.

UNC-41/stonin functions with AP2 to recycle synaptic vesicles in Caenorhabditis elegans

The recycling of synaptic vesicles requires the recovery of vesicle proteins and membrane. Members of the stonin protein family (Drosophila Stoned B, mammalian stonin 2) have been shown to link the synaptic vesicle protein synaptotagmin to the endocytic machinery. Here we characterize the unc-41 gene, which encodes the stonin ortholog in the nematode Caenorhabditis elegans. Transgenic expression of Drosophila stonedB rescues unc-41 mutant phenotypes, demonstrating that UNC-41 is a bona fide member of the stonin family. In unc-41 mutants, synaptotagmin is present in axons, but is mislocalized and diffuse. In contrast, UNC-41 is localized normally in synaptotagmin mutants, demonstrating a unidirectional relationship for localization. The phenotype of snt-1 unc-41 double mutants is stronger than snt-1 mutants, suggesting that UNC-41 may have additional, synaptotagmin-independent functions. We also show that unc-41 mutants have defects in synaptic vesicle membrane endocytosis, including a ∼50% reduction of vesicles in both acetylcholine and GABA motor neurons. These endocytic defects are similar to those observed in apm-2 mutants, which lack the µ2 subunit of the AP2 adaptor complex. However, no further reduction in synaptic vesicles was observed in unc-41 apm-2 double mutants, suggesting that UNC-41 acts in the same endocytic pathway as µ2 adaptin.

Neuroligin-deficient mutants of C. elegans have sensory processing deficits and are hypersensitive to oxidative stress and mercury toxicity

Neuroligins are postsynaptic cell adhesion proteins that bind specifically to presynaptic membrane proteins called neurexins. Mutations in human neuroligin genes are associated with autism spectrum disorders in some families. The nematode Caenorhabditis elegans has a single neuroligin gene (nlg-1), and approximately a sixth of C. elegans neurons, including some sensory neurons, interneurons and a subset of cholinergic motor neurons, express a neuroligin transcriptional reporter. Neuroligin-deficient mutants of C. elegans are viable, and they do not appear deficient in any major motor functions. However, neuroligin mutants are defective in a subset of sensory behaviors and sensory processing, and are hypersensitive to oxidative stress and mercury compounds; the behavioral deficits are strikingly similar to traits frequently associated with autism spectrum disorders. Our results suggest a possible link between genetic defects in synapse formation or function, and sensitivity to environmental factors in the development of autism spectrum disorders.

Differential expression and function of synaptotagmin 1 isoforms in Caenorhabditis elegans

Synaptotagmin 1, encoded by the snt-1 gene in Caenorhabditis elegans, is a major synaptic vesicle protein containing two Ca(2+)-binding (C2) domains. Alternative splicing gives rise to two synaptotagmin 1 isoforms, designated SNT-1A and SNT-1B, which differ in amino acid sequence in the third, fourth, and fifth beta-strands of the second C2 domain (C2B). We report here that expression of either SNT-1 isoform under control of a strong pan-neural promoter fully rescues the snt-1 null phenotype. Furthermore, C-terminal fusions of either isoform with GFP are trafficked properly to synapses and are fully functional, unlike synaptotagmin 1Colon, two colonsGFP fusions in mice. Analysis of isoform expression with genomic GFP reporter constructs revealed that the SNT-1A and-1B isoforms are differentially expressed and localized in the C. elegans nervous system. We also report molecular, behavioral, and immunocytochemical analyses of twenty snt-1 mutations. One of these mutations, md259, specifically disrupts expression of the SNT-1A isoform and has defects in a subset of synaptotagmin 1-mediated behaviors. A second mutation, md220, is an in-frame 9-bp deletion that removes a conserved tri-peptide sequence (VIL) in the second beta-strand of the C2B domain and disrupts the proper intracellular trafficking of synaptotagmin. Site-directed mutagenesis of a functional SNT-1Colon, two colonsGFP fusion protein was used to examine the potential role of the VIL sequence in synaptotagmin trafficking. Although our results suggest the VIL sequence is most likely not a specific targeting motif, the use of SNT-1Colon, two colonsGFP fusions has great potential for investigating synaptotagmin trafficking and localization.

The Caenorhabditis elegans snf-11 gene encodes a sodium-dependent GABA transporter required for clearance of synaptic GABA

Sodium-dependent neurotransmitter transporters participate in the clearance and/or recycling of neurotransmitters from synaptic clefts. The snf-11 gene in Caenorhabditis elegans encodes a protein of high similarity to mammalian GABA transporters (GATs). We show here that snf-11 encodes a functional GABA transporter; SNF-11-mediated GABA transport is Na+ and Cl- dependent, has an EC50 value of 168 microM, and is blocked by the GAT1 inhibitor SKF89976A. The SNF-11 protein is expressed in seven GABAergic neurons, several additional neurons in the head and retrovesicular ganglion, and three groups of muscle cells. Therefore, all GABAergic synapses are associated with either presynaptic or postsynaptic (or both) expression of SNF-11. Although a snf-11 null mutation has no obvious effects on GABAergic behaviors, it leads to resistance to inhibitors of acetylcholinesterase. In vivo, a snf-11 null mutation blocks GABA uptake in at least a subset of GABAergic cells; in a cell culture system, all GABA uptake is abolished by the snf-11 mutation. We conclude that GABA transport activity is not essential for normal GABAergic function in C. elegans and that the localization of SNF-11 is consistent with a GABA clearance function rather than recycling.

Analysis of point mutants in the Caenorhabditis elegans vesicular acetylcholine transporter reveals domains involved in substrate translocation

Cholinergic neurotransmission depends upon the regulated release of acetylcholine. This requires the loading of acetylcholine into synaptic vesicles by the vesicular acetylcholine transporter (VAChT). Here, we identify point mutants in Caenorhabditis elegans that map to highly conserved regions of the VAChT gene of Caenorhabditis elegans (CeVAChT) (unc-17) and exhibit behavioral phenotypes consistent with a reduction in vesicular transport activity and neurosecretion. Several of these mutants express normal amounts of VAChT protein and exhibit appropriate targeting of VAChT to synaptic vesicles. By site-directed mutagenesis, we have replaced the conserved amino acid residues found in human VAChT with the mutated residue in CeVAChT and stably expressed these cDNAs in PC-12 cells. These mutants display selective defects in initial acetylcholine transport velocity (K(m)), with values ranging from 2- to 8-fold lower than that of the wild-type. One of these mutants has lost its specific interaction with vesamicol, a selective inhibitor of VAChT, and displays vesamicol-insensitive uptake of acetylcholine. The relative order of behavioral severity of the CeVAChT point mutants is identical to the order of reduced affinity of VAChT for acetylcholine in vitro. This indicates that specific structural changes in VAChT translate into specific alterations in the intrinsic parameters of transport and in the storage and synaptic release of acetylcholine in vivo.

Expression of multiple UNC-13 proteins in the Caenorhabditis elegans nervous system

The Caenorhabditis elegans UNC-13 protein and its mammalian homologues are important for normal neurotransmitter release. We have identified a set of transcripts from the unc-13 locus in C. elegans resulting from alternative splicing and apparent alternative promoters. These transcripts encode proteins that are identical in their C-terminal regions but that vary in their N-terminal regions. The most abundant protein form is localized to most or all synapses. We have analyzed the sequence alterations, immunostaining patterns, and behavioral phenotypes of 31 independent unc-13 alleles. Many of these mutations are transcript-specific; their phenotypes suggest that the different UNC-13 forms have different cellular functions. We have also isolated a deletion allele that is predicted to disrupt all UNC-13 protein products; animals homozygous for this null allele are able to complete embryogenesis and hatch, but they die as paralyzed first-stage larvae. Transgenic expression of the entire gene rescues the behavior of mutants fully; transgenic overexpression of one of the transcripts can partially compensate for the genetic loss of another. This finding suggests some degree of functional overlap of the different protein products.

RIC-8 (Synembryn): a novel conserved protein that is required for G(q)alpha signaling in the C. elegans nervous system

Recent studies describe a network of signaling proteins centered around G(o)alpha and G(q)alpha that regulates neurotransmitter secretion in C. elegans by controlling the production and consumption of diacylglycerol (DAG). We sought other components of the Goalpha-G(q)alpha signaling network by screening for aldicarb-resistant mutants with phenotypes similar to egl-30 (G(q)alpha) mutants. In so doing, we identified ric-8, which encodes a novel protein named RIC-8 (synembryn). Through cDNA analysis, we show that RIC-8 is conserved in vertebrates. Through immunostaining, we show that RIC-8 is concentrated in the cytoplasm of neurons. Exogenous application of phorbol esters or loss of DGK-1 (diacylglycerol kinase) rescues ric-8 mutant phenotypes. A genetic analysis suggests that RIC-8 functions upstream of, or in conjunction with, EGL-30 (G(q)alpha).

Alternative splicing leads to two cholinergic proteins in Caenorhabditis elegans

The cha-1 gene of Caenorhabditis elegans encodes choline acetyl-transferase (the acetylcholine synthetic enzyme). The C. elegans unc-17 gene encodes a synaptic vesicle-associated acetylcholine transporter. The two genes thus define sequential biochemical steps in the metabolism of the neurotransmitter acetylcholine. Cloning, sequencing, and molecular analysis of the unc-17 region indicate that cha-1 and unc-17 transcripts share a 5' untranslated exon, and the rest of the unc-17 transcript is nested within the long first intron of cha-1. Thus, two proteins with related functions but with no sequences in common are produced as a result of alternative splicing of a common mRNA precursor. The structure of this transcription unit suggests a novel type of coordinate gene expression, and a temporal processing model is proposed for the regulation of cha-1 and unc-17 expression.

Cloning and characterization of the choline acetyltransferase structural gene (cha-1) from C. elegans

We have cloned the cha-1 gene from Caenorhabditis elegans using the method of transposon tagging, cha-1 is the structural gene for ChAT, the enzyme that synthesizes ACh. Sequence analysis of cDNAs predicts a protein of 71.5 kDa; comparison of the deduced amino acid sequence with ChAT sequences from other species confirms that cha-1 encodes ChAT. Comparison of cDNA and genomic sequences reveals that transcription is from right to left on the genetic map, and that some of the transcripts may result from trans-splicing of the 22-base spliced leader SL 1. The cha-1 gene is organized into 11 exons. The first exon contains only untranslated sequences, and is followed by an extremely long intron. The coding sequence of the cha-1 transcript is disrupted by mutations in the cha-1 gene. We have determined the sites of four transposon insertions and the end-points of two deletions that lead to the cha-1 mutant phenotype; one of the deletions appears to eliminate gene function completely. Comparison of the Drosophila, rat, and C. elegans genes reveals conserved motifs and conserved intron sites.