Gap junction assembly: PTX-sensitive G proteins regulate the distribution of connexin43 within cells.

Cells expressing connexin43 are able to upregulate gap junction (GJ) communication by enhancing the assembly of new GJs, apparently through increased connexin trafficking. Because G proteins are known to regulate different aspects of protein trafficking, we examined the effects of pertussis toxin (PTX; a specific inhibitor of certain G proteins) on GJ assembly. Dissociated Novikoff hepatoma cells were reaggregated for 60 min to form nascent junctions. PTX inhibited GJ assembly, as indicated by a reduction in dye transfer. Electron microscopy also revealed a 60% decrease in the number of GJ channels per cell interface. Importantly, PTX blocked the twofold enhancement in GJ assembly found in the presence of low-density lipoprotein. Two G(i alpha) proteins (G(i alpha 2) and G(i alpha 3)), which have been implicated in the control of membrane trafficking, reacted with PTX in ADP-ribosylation studies. PTX and/or the trafficking inhibitors, brefeldin A and monensin, inhibited GJ assembly to comparable degrees. In addition, assays for GJ hemichannels demonstrated reduced plasma membrane levels of connexin43 following PTX treatment. These results suggest that PTX-sensitive G proteins regulate connexin43 trafficking, and, as a result of inhibition with PTX, the number of plasma membrane hemichannels available for GJ assembly is reduced.

Innexins get into the gap.

Connexins were first identified in the 1970s as the molecular components of vertebrate gap junctions. Since then a large literature has accumulated on the cell and molecular biology of this multi-gene family culminating recently in the findings that connexin mutations are implicated in a variety of human diseases. Over two decades, the terms "connexin" and "gap junction" had become almost synonymous. In the last few years a second family of gap-junction genes, the innexins, has emerged. These have been shown to form intercellular channels in genetically tractable invertebrate organisms such as Drosophila melanogaster and Caenorhabditis elegans. The completed genomic sequences for the fly and worm allow identification of the full complement of innexin genes in these two organisms and provide valuable resources for genetic analyses of gap junction function.

Innexin-3 forms connexin-like intercellular channels.

Innexins comprise a large family of genes that are believed to encode invertebrate gap junction channel-forming proteins. However, only two Drosophila innexins have been directly tested for the ability to form intercellular channels and only one of those was active. Here we tested the ability of Caenorhabditis elegans family members INX-3 and EAT-5 to form intercellular channels between paired Xenopus oocytes. We show that expression of INX-3 but not EAT-5, induces electrical coupling between the oocyte pairs. In addition, analysis of INX-3 voltage and pH gating reveals a striking degree of conservation in the functional properties of connexin and innnexin channels. These data strongly support the idea that innexin genes encode intercellular channels.

eat-5 and unc-7 represent a multigene family in Caenorhabditis elegans involved in cell-cell coupling.

The Drosophila melanogaster genes Passover and l(1)ogre and the Caenorhabditis elegans gene unc-7 define a gene family whose function is not known. We have isolated and characterized the C. elegans gene eat-5, which is required for synchronized pharyngeal muscle contractions, and find that it is a new member of this family. Simultaneous electrical and video recordings reveal that in eat-5 mutants, action potentials of muscles in the anterior and posterior pharynx are unsynchronized. Injection of carboxyfluorescein into muscles of the posterior pharynx demonstrates that all pharyngeal muscles are dye-coupled in wild-type animals; in eat-5 mutants, however, muscles of the anterior pharynx are no longer dye-coupled to posterior pharyngeal muscles. We show that a gene fusion of eat-5 to the green fluorescent protein is expressed in pharyngeal muscles. unc-7 and eat-5 are two of at least sixteen members of this family in C. elegans as determined by database searches and PCR-based screens. The amino acid sequences of five of these members in C. elegans have been deduced from cDNA sequences. Polypeptides of the family are predicted to have four transmembrane domains with cytoplasmic amino and carboxyl termini. We have constructed fusions of one of these polypeptides with beta-galactosidase and with green fluorescent protein. The fusion proteins appear to be localized in a punctate pattern at or near plasma membranes. We speculate that this gene family is required for the formation of gap junctions.

Mutations affecting the chemosensory neurons of Caenorhabditis elegans.

We have identified and characterized 95 mutations that reduce or abolish dye filling of amphid and phasmid neurons and that have little effect on viability, fertility or movement. Twenty-seven mutations occurred spontaneously in strains with a high frequency of transposon insertion. Sixty-eight were isolated after treatment with EMS. All of the mutations result in defects in one or more chemosensory responses, such as chemotaxis to ammonium chloride or formation of dauer larvae under conditions of starvation and overcrowding. Seventy-five of the mutations are alleles of 12 previously defined genes, mutations which were previously shown to lead to defects in amphid ultrastructure. We have assigned 20 mutations to 13 new genes, called dyf-1 through dyf-13. We expect that the genes represented by dye-filing defective mutants are important for the differentiation of amphid and phasmid chemosensilla.

Molecular and genetic analysis of unc-7, a Caenorhabditis elegans gene required for coordinated locomotion.

Mutations in the Caenorhabditis elegans gene unc-7 confer an uncoordinated phenotype. Wild-type animals trace smooth, sinuous waves as they move; unc-7 mutants make irregular bends or kinks along their bodies, particularly when they move forward. The unc-7 locus has also been implicated in the nematode's response to volatile anesthetics. We have cloned unc-7 by transposon tagging: an unc-7 mutation was correlated with the insertion of the transposon Tc1, and reversion of the mutant phenotype was correlated with loss of the Tc1 element. We have physically mapped the region flanking the sites of Tc1 insertion and identified DNA rearrangements corresponding to eight additional unc-7 alleles. Northern analysis indicates that a 2.7-kb unc-7 message is present in all developmental stages but is most abundant in L1-L3 larvae. The 5' end of the message contains a trans-spliced leader SL1. An 18-kb intron is located upstream of the predicted translational start site of the gene, and DNA breakpoints of four gamma-ray-induced alleles were located within this intron. We determined the sequence of a cDNA corresponding to the unc-7 message. The message may encode a 60-kd protein whose amino acid sequence is unrelated to any other available protein sequence; a transmembrane location for the unc-7 protein is predicted. We predict from our analysis of unc-7 genetic mosaics that the unc-7 gene product is not required in muscle cells for wild-type coordination but is probably required in motor neurons (although a hypodermal role has not been excluded). We speculate that unc-7 may be involved in the function of neuronal ion channels.