Immunocytochemical localization of two myosins within the same muslce cells in Caenorhabditis elegans.

Nematodes synthesize two major classes of myosin heavy chains. These heavy chains associate to form only homodimeric myosin molecules, and these myosin homodimers are anti-genically different from one another (Schachat, Garcea and Epstein, 1978). The two myosins may be designated unc-54 myosin, since this species is altered in mutants of the unc-54 locus, and non-unc-54 myosin, since this class is not affected in unc-54 mutants. We present here experiments in which specific anti-myosin IgG and anti-unc-54 myosin IgG are used to locate the two myosins within the same body-wall muscle cells of Caenorhabditis elegans. These results are necessary for further evaluation of the possible functions of the two myosin homodimers in the thick filaments of these muscles.Myosin can be localized to all body-wall and pharyngeal muscle cells using anti-myosin antibody. In longitudinal sections of body-wall muscle, the staining with anti-myosin coincides with the birefringence of A bands that contain thick filaments. Anti-unc-54 myosin stains all body-wall A bands uniformly but does not react with the pharynx. This result demonstrates that unc-54 is located exclusively in body-wall muscle cells of the wild-type strain N2. Non-unc-54 myosin is localized with anti-myosin in all body-wall muscle cells of the unc-54 null mutant E190, as expected; however, unc-54 myosin could not be detected by anti-unc-54 myosin antibody in this mutant.Since we can localize unc-54 myosin and non-unc-54 myosin in all body-wall muscle cells of wild-type and E190, respectively, we conclude that the two myosins must be present in the same muscle cells. In addition, since unc-54 myosin is located in all body-wall A bands, at least some sarcomeres must contain both myosins. This conclusion is consistent with the observations of Garcea, Schachat and Epstein (1978) that wild-type and E190 synthesize similar amounts of non-unc-54 myosin. Within the limits of resolution of our methods, unc-54 myosin is distributed throughout body-wall A bands. We conclude, therefore, that the majority of thick filaments within these A bands must contain unc-54 myosin along their entire length. Possible roles for unc-54 and non-unc-54 myosins in the assembly and organization of thick filaments are discussed.     

Muscle development in Caenorhabditis elegans: Mutants exhibiting retarded sarcomere construction

We have studied the structural changes within the body-wall muscle cells of Caenorhabditis elegans during postmitotic development. In wild-type, the number of sarcomeres progressively increases, and each sarcomere appears to grow in length and depth continuously during this period. In mature wild-type cells, the anterior-most body-wall muscle cells have 6–7 sarcomeres; the rest have 9–10 sarcomeres per cell. Twelve mutants in the unc-52 II gene exhibit markedly retarded sarcomere construction and progressive paralysis. Several unc-52 mutants, such as the severely paralyzed SU200, produce only 2–3 sarcomeres per body-wall muscle cell, while the other midly paralyzed unc-52 mutants, such as SU250, build 3–4 sarcomeres per muscle cell. Other structures such as the pharynx and even the noncontractile organelles of the body-wall muscle cells do not appear to be structurally or functionally altered. The unc-52 body-wall sarcomeres become moderately disorganized as they are outstripped by cell growth; sufficient order is preserved, however, so that the majority of thick and thin filaments still interdigitate.The myosin heavy chains of SU200 body-wall muscle fail to accumulate normally, while the pharyngeal myosin heavy chains do not appear to be specifically affected. This biochemical result correlates well with the specificity of morphological changes in the mutant. A model is discussed in which the biochemical and morphological deficits are explained by a simple regulatory mechanism.     

Myosins exist as homodimers of heavy chains: demonstration with specific antibody purified by nematode mutant myosin affinity chromatography.

The body-walls of Caenorhabditis elegans contain two different myosin heavy chains (Epstein, Waterston and Brenner, 1974) that associate to form at least two species of myosin (Schachat, Harris and Epstein, 1977a). To better define the distribution of these heavy chains in myosin molecules, we have characterized the myosin of C. elegans by immunochemical methods. Specific, precipitating anti-myosin antibody has been prepared in rabbits using highly purified nematode myosin as the immunogen. The difference in reactivity of the anti-myosin antibody with wild-type myosin containing both kinds of heavy chains (designated unc-54 and non-unc-54 heavy chains on the basis of genetic specification) and myosin from the mutant E190 that lacks unc-54 heavy chains Indicates that there are antigenic differences between myosin molecules containing unc-54 heavy chains and myosin molecules containing only non-unc-54 heavy chains. Antibody specific for the unc-54 myosin determinants has been prepared by the immunoadsorption of anti-myosin antibody with E190 myosin. This specific anti-unc-54 myosin antibody precipitates myosin that contains only unc-54 heavy chains. At the limits of resolution of our immunoprecipitation techniques, we could detect no heterodimeric myosin molecules containing both unc-54 and non-unc-54 heavy chains. The body-wall myosins of C. elegans therefore exist only as homodimers of either class of heavy chain.This specific anti-unc-54 myosin antibody promises to be a valuable tool in elucidating the role of two myosins in body-wall muscle and in molecular characterizations of mutant myosins in C. elegans. We report here the use of this antibody to detect antigenic differences between unc-54 myosin from the wild-type and the muscle mutant E675. In conjunction with the original anti-myosin antibody, other studies show that both unc-54 and non-unc-54 myosins exist within the same body-wall muscle cells (Mackenzie, Schachat and Epstein, 1978) and that both myosins are coordinately synthesized during muscle development in C. elegans (Garcea, Schachat and Epstein, 1978). We discuss the implications of the self-association of unc-54 and non-unc-54 myosin heavy chains into homodimeric myosins within the same body-wall muscles with respect to the assembly of thick filaments and their organization into a regular lattice.     

Coordinate synthesis of two myosins in wild-type and mutant nematode muscle during larval development

In this paper we examine the role of two myosins in body-wall muscle cells of the nematode Caenorhabditis elegans. Large populations of nematodes are synchronized, and the synthesis and accumulation of myosin heavy chains and total protein are followed through postmitotic larval development. Growth is exponential with time for both the wild-type N2 and the body-wall muscledefective mutant E675, with a longer doubling time for the mutant. Utilizing the electrophoretic polymorphism of the E675 myosin heavy chains, we show that distinguishable classes of heavy chains accumulate differentially throughout development. Immunochemical measurements confirm a similar result in N2. Total myosin heavy chain accumulation is also quantitatively similar for the two strains. Myosin heavy chain relative synthetic rates as determined by pulse-labeling are constant throughout development and are equivalent for the two strains. The final fraction of accumulated unc-54 to total heavy chains of approximately 0.63 equals the constant synthetic fraction of approximately 0.62.Since myosin heavy chain accumulation and relative synthesis are equivalent, we conclude that the turnover of heavy chains is also similar in N2 and E675 despite the extensive structural and functional disruption within body-wall muscle cells of the latter strain. Since the accumulated fraction of unc-54 myosin heavy chains reaches a plateau at the constant synthetic fraction, myosin accumulation In the body-wall muscle cells may be attributed to a constant ratio of synthetic rates of the two body-wall myosin species. The coordinate synthesis of two myosins in the same body-wall muscle cells is discussed.     

Paramyosin of Caenorhabditis elegans

Paramyosin has been isolated from the nematode, Caenorhabditis elegans. Its identity has been established by a variety of criteria, including purification, molecular weight, immunological cross reactivity with known paramyosin and formation of characteristic paracrystals. The presence of paramyosin in both pharyngeal and body-wall musculature was shown by a technique that allows analysis by sodium dodecyl sulphate gels of the protein in a single worm. The possibility of defining the role of paramyosin in the structure and function of the invertebrate muscle through the isolation of mutants in this protein is discussed.     

Genetic analysis of myosin assembly inCaenorhabditis elegans

The established observations and unresolved questions in the assembly of myosin are outlined in this article. Much of the background information has been obtained in classical experiments using the myosin and thick filaments from vertebrate skeletal muscle. Current research is concerned with problems of myosin assembly and structure in smooth muscle, a broad spectrum of invertebrate muscles, and eukaryotic cells in general. Many of the general questions concerning myosin assembly have been addressed by a combination of genetic, molecular, and structural approaches in the nematode Caenorhabditis elegans. Detailed analysis of multiple myosin isoforms has been a prominent aspect of the nematode work. The molecular cloning and determination of the complete sequences of the genes encoding the four isoforms of myosin heavy chain and of the myosin-associated protein paramyosin have been a major landmark. The sequences have permitted a theoretical analysis of myosin rod structure and the interactions of myosin in thick filaments. The development of specific monoclonal antibodies to the individual myosins has led to the delineation of the different locations of the myosins and to their special roles in thick filament structure and assembly. In nematode body-wall muscles, two isoforms, myosins A and B, are located in different regions of each thick filament. Myosin A is located in the central biopolar zones, whereas myosin B is restricted to the flanking polar regions. This specific localization directly implies differential behavior of the two myosins during assembly. Genetic and structural experiments demonstrate that paramyosin and the levels of expression of the two forms are required for the differential assembly. Additional genetic experiments indicate that several other gene products are involved in the assembly of myosin. Structural studies of mutants have uncovered two new structures. A core structure separate from myosin and paramyosin appears to be an integral part of thick filaments. Multifilament assemblages exhibit multiple nascent thick filament-like structures extending from central paramyosin regions. Dominant mutants of myosin that disrupt thick filament assembly are located in the ATP and actin binding sites of the heavy chain. A model for a cycle of reactions in the assembly of myosin into thick filaments is presented. Specific reactions of the two myosin isoforms, paramyosin, and core proteins with multifilament assemblages as possible intermediates in assembly are proposed.     

Mutants with altered muscle structure in Caenorhabditis elegans

In the small nematode, Caenorhabditis elegans, mutants with a disorganized myofilament lattice structure have been identified by polarized light and electron microscopy. Genetic analysis places the mutations in 12 complementation groups which are distributed over the six linkage groups of C. elegans. The phenotypes are described for the mutants from the 9 complementation groups not previously reported on in detail. Most are paralyzed, but some exhibit essentially normal movement; mutants of two loci show changes only in later larval stages and adulthood. Morphological studies show that, in general, all the members of a complementation group show similar changes in muscle structure and that these changes are distinctive for that group. In mutants of several genes, disorganization of the myofilament lattice is general with no one component of the lattice more obviously altered than others. In mutants of other genes specific structures are prominently altered. In one of the instances where thick filaments appear to be abnormal, double mutants combining mutations in this gene (unc-82 IV) with mutations in the gene for a myosin heavy chain (MacLeod et al., 1977a,b) or paramyosin (Waterston et al., 1977) were used to show that the unc-82 gene product probably affects thick filament assembly through its actions on paramyosin. Some possible implications of the morphological features of the mutants as well as the conclusions derived from the genetic studies are discussed.     

UNC-98 and UNC-96 interact with paramyosin to promote its incorporation into thick filaments of Caenorhabditis elegans

Mutations in unc-96 or -98 cause reduced motility and a characteristic defect in muscle structure: by polarized light microscopy birefringent needles are found at the ends of muscle cells. Anti-paramyosin stains the needles in unc-96 and -98 mutant muscle. However there is no difference in the overall level of paramyosin in wild-type, unc-96, and -98 animals. Anti-UNC-98 and anti-paramyosin colocalize in the paramyosin accumulations of missense alleles of unc-15 (encodes paramyosin). Anti-UNC-96 and anti-UNC-98 have diffuse localization within muscles of unc-15 null mutants. By immunoblot, in the absence of paramyosin, UNC-98 is diminished, whereas in paramyosin missense mutants, UNC-98 is increased. unc-98 and -15 or unc-96 and -15 interact genetically either as double heterozygotes or as double homozygotes. By yeast two-hybrid assay and ELISAs using purified proteins, UNC-98 interacts with paramyosin residues 31-693, whereas UNC-96 interacts with a separate region of paramyosin, residues 699-798. The importance of surface charge of this 99 residue region for UNC-96 binding was shown. Paramyosin lacking the C-terminal UNC-96 binding region fails to localize throughout A-bands. We propose a model in which UNC-98 and -96 may act as chaperones to promote the incorporation of paramyosin into thick filaments.     

β-Filagenin, a Newly Identified Protein Coassembling with Myosin and Paramyosin in Caenorhabditis elegans

Muscle thick filaments are stable assemblies of myosin and associated proteins whose dimensions are precisely regulated. The mechanisms underlying the stability and regulation of the assembly are not understood. As an approach to these problems, we have studied the core proteins that, together with paramyosin, form the core structure of the thick filament backbone in the nematode Caenorhabditis elegans. We obtained partial peptide sequences from one of the core proteins, β-filagenin, and then identified a gene that encodes a novel protein of 201–amino acid residues from databases using these sequences. β-Filagenin has a calculated isoelectric point at 10.61 and a high percentage of aromatic amino acids. Secondary structure algorithms predict that it consists of four β-strands but no α-helices. Western blotting using an affinity-purified antibody showed that β-filagenin was associated with the cores. β-Filagenin was localized by immunofluorescence microscopy to the A bands of body–wall muscles, but not the pharynx. β-filagenin assembled with the myosin homologue paramyosin into the tubular cores of wild-type nematodes at a periodicity matching the 72-nm repeats of paramyosin, as revealed by immunoelectron microscopy. In CB1214 mutants where paramyosin is absent, β-filagenin assembled with myosin to form abnormal tubular filaments with a periodicity identical to wild type. These results verify that β-filagenin is a core protein that coassembles with either myosin or paramyosin in C. elegans to form tubular filaments.     

Purified thick filaments from the nematode Caenorhabditis elegans: evidence for multiple proteins associated with core structures

The thick filaments of the nematode, Caenorhabditis elegans, arising predominantly from the body-wall muscles, contain two myosin isoforms and paramyosin as their major proteins. The two myosins are located in distinct regions of the surfaces, while paramyosin is located within the backbones of the filaments. Tubular structures constitute the cores of the polar regions, and electron-dense material is present in the cores of the central regions (Epstein, H.F., D.M. Miller, I. Ortiz, and G.C. Berliner. 1985. J. Cell Biol. 100:904-915). Biochemical, genetic, and immunological experiments indicate that the two myosins and paramyosin are not necessary core components (Epstein, H.F., I. Ortiz, and L.A. Traeger Mackinnon. 1986. J. Cell Biol. 103:985-993). The existence of the core structures suggests, therefore, that additional proteins may be associated with thick filaments in C. elegans. To biochemically detect minor associated proteins, a new procedure for the isolation of thick filaments of high purity and structural preservation has been developed. The final step, glycerol gradient centrifugation, yielded fractions that are contaminated by, at most, 1-2% with actin, tropomyosin, or ribosome-associated proteins on the basis of Coomassie Blue staining and electron microscopy. Silver staining and radioautography of gel electrophoretograms of unlabeled and 35S-labeled proteins, respectively, revealed at least 10 additional bands that cosedimented with thick filaments in glycerol gradients. Core structures prepared from wild-type thick filaments contained at least six of these thick filament-associated protein bands. The six proteins also cosedimented with thick filaments purified by gradient centrifugation from CB190 mutants lacking myosin heavy chain B and from CB1214 mutants lacking paramyosin. For these reasons, we propose that the six associated proteins are potential candidates for putative components of core structures in the thick filaments of body-wall muscles of C. elegans.     

CSN-5, a Component of the COP9 Signalosome Complex,Regulates the Levels of UNC-96 and UNC-98, Two Components of M-lines in Caenorhabditis elegans Muscle

In Caenorhabditis elegans two M-line proteins, UNC-98 and UNC-96, are involved in myofibril assembly and/or maintenance, especially myosin thick filaments. We found that CSN-5, a component of the COP9 signalosome complex, binds to UNC-98 and -96 using the yeast two-hybrid method. These interactions were confirmed by biochemical methods. The CSN-5 protein contains a Mov34 domain. Although one other COP9 signalosome component, CSN-6, also has a Mov34 domain, CSN-6 did not interact with UNC-98 or -96. Anti-CSN-5 antibody colocalized with paramyosin at A-bands in wild type and colocalized with abnormal accumulations of paramyosin found in unc-98, -96, and -15 (encodes paramyosin) mutants. Double knockdown of csn-5 and -6 could slightly suppress the unc-96 mutant phenotype. In the double knockdown of csn-5 and -6, the levels of UNC-98 protein were increased and the levels of UNC-96 protein levels were slightly reduced, suggesting that CSN-5 promotes the degradation of UNC-98 and that CSN-5 stabilizes UNC-96. In unc-15 and unc-96 mutants, CSN-5 protein was reduced, implying the existence of feed back regulation from myofibril proteins to CSN-5 protein levels. Taken together, we found that CSN-5 functions in muscle cells to regulate UNC-98 and -96, two M-line proteins.     

Dominant mutations affecting muscle structure in Caenorhabditis elegans that map near the actin gene cluster

By examining F1 progeny of mutagenized Caenorhabditis elegans larvae, we recovered several dominant mutations which affect muscle structure. Five of these new mutations resulted in phenotypes unlike the previously recognized unc-54 and unc-15 dominant alleles. Mapping studies placed all five mutations in the same small region of linkage group V. Polarized light, fluorescence and electron microscopic studies showed that a prominent feature of the disorganized myofilament lattice is the abnormal placement of thin filaments within the body wall muscle cells. Pharyngeal musculature is also affected by three of the mutations when homozygous. Of the five mutations only three are homozygous viable. All three of these have unusually high intragenic reversion rates either spontaneously (~10^?6) or after ethyl methanesulfonate mutagenesis (2 × 10^?5), suggesting that reversion occurs through loss of function mutations. No unlinked suppressor mutations were found. The dominance of the mutations, the effect on thin filaments and the reversion properties suggested that these new dominant mutations lie in a gene or genes specifying a structural component of the thin filament. The positioning of a set of three actin sequences in the same region (Files et al., 1983) led us to speculate that these mutations lie in actin genes.     

The Regulation of Catch in Molluscan Muscle

Molluscan catch muscles are smooth muscles. As with mammalian smooth muscles, there is no transverse ordering of filaments or dense bodies. In contrast to mammalian smooth muscles, two size ranges of filaments are present. The thick filaments are long as well as large in diameter and contain paramyosin. The thin filaments contain actin and appear to run into and join the dense bodies. Vesicles are present which may be part of a sarcoplasmic reticulum. Neural activation of contraction in Mytilus muscle is similar to that observed in mammalian smooth muscles, and in some respects to frog striated muscle. The relaxing nerves, which reduce catch, are unique to catch muscles. 5-Hydroxytryptamine, which appears to mediate relaxation, specifically blocks catch tension but increases the ability of the muscle to fire spikes. It is speculated that Mytilus muscle actomyosin is activated by a Ca⁺⁺-releasing mechanism, and that 5-hydroxytryptamine may reduce catch and increase excitability by influencing the rate of removal of intracellular free Ca⁺⁺.     

Drosophila paramyosin is important for myoblast fusion and essential for myofibril formation

Paramyosin is a major structural protein of thick filaments in invertebrate muscles. Coiled-coil dimers of paramyosin form a paracrystalline core of these filaments, and the motor protein myosin is arranged on the core surface. To investigate the function of paramyosin in myofibril assembly and muscle contraction, we functionally disrupted the Drosophila melanogaster paramyosin gene by mobilizing a P element located in its promoter region. Homozygous paramyosin mutants die at the late embryo stage. Mutants display defects in both myoblast fusion and in myofibril assembly in embryonic body wall muscles. Mutant embryos have an abnormal body wall muscle fiber pattern arising from defects in myoblast fusion. In addition, sarcomeric units do not assemble properly and muscle contractility is impaired. We confirmed that these defects are paramyosin-specific by rescuing the homozygous paramyosin mutant to adulthood with a paramyosin transgene. Antibody analysis of normal embryos demonstrated that paramyosin accumulates as a cytoplasmic protein in early embryo development before assembling into thick filaments. We conclude that paramyosin plays an unexpected role in myoblast fusion and is important for myofibril assembly and muscle contraction.     

An X-Ray Diffraction Study of Contracting Molluscan Smooth Muscle

The living anterior byssus retractor muscle of Mytilus (ABRM), a smooth, “catch” muscle, has been studied by X-ray diffraction while relaxed and while tonically contracted. X-ray reflections were observed from the actin and paramyosin filaments and from the α-helical substructure of the paramyosin filaments. No differences in spacings or relative intensities were observed when the relaxed and contracting muscle patterns were compared. This result is consistent with a sliding filament mechanism involving an interaction between actin and paramyosin filaments.     

The alteration of myosin isoform compartmentation in specific mutants of Caenorhabditis elegans

Myosin isoforms A and B are located at the surface of the central and polar regions, respectively, of thick filaments in body muscle cells of Caenorhabditis elegans, whereas paramyosin and a distinct core structure comprise the backbones of these filaments. Thick filaments and related structures were isolated from nematode mutants that have altered thick filament protein compositions. These mutant filaments and their complexes with specific antibodies were studied by electron microscopy to determine the distribution of the two myosins. The compartmentation of the two myosin isoforms in body wall muscle thick filaments depends not only upon the intrinsic properties of the myosins but their interactions with other components such as paramyosin and their relative quantities determined by synthesis.     

Identification of the structural gene for a myosin heavy-chain in Caenorhabditis elegans

Mutants in the unc-54 gene of Caenorhabditis elegans have been characterized by cyanylation and sodium dodecyl sulphate/polyacrylamide gel electrophoresis of the total myosin present in each mutant. In the recessive mutants lacking a major fraction of the total myosin, the high molecular weight doublet of 15 × 10⁴ and 14 × 10⁴ which dominates the cyanylation pattern of the total wild-type myosin is absent. In the mutant E675, which possesses a novel heavy-chain with a molecular weight of 2 × 10⁵, each component of the cyanylation doublet is reduced by 10⁴ daltons, indicating that the doublet is derived from partial cleavage of a single polypeptide chain. This suggests that unc-54 is the structural gene for a myosin heavy-chain present in a major fraction of the total nematode myosin.     

Muscle differentiation in normal and cleavage-arrested mutant embryos of Caenorhabditis elegans

The differentiation of body-wall muscle cells was studied in the nematode Caenorhabditis elegans. Specific antibodies to myosin and paramyosin, major protein constituents of differentiated muscle, react with mesodermal cells in wild-type embryos towards the end of the first half of embryogenesis. Immunoreactive cells (2–16) first appear in embryos with 400–450 of the 550 cells present at hatching. Such embryos have developed at 25.5°C for $\text{3–4}\text{1}\text{2}$ hr beyond the two-cell stage. As development proceeds, a maximum of 81 immunoreactive cells forms four columns running anterior-posterior. Each column is composed of two lines of tightly opposed round cells, which then elongate into spindle-shaped cells. Mutant embryos in which cleavage arrests prematurely also generate cells that produce myosin and paramyosin. The initiation of muscle differentiation appears to be independent of the number of cell or nuclear divisions within a lineage or of the proliferation of other cells. These results suggest that the biosynthesis of muscle-specific proteins by nematode embryonic muscle cells is regulated by mechanisms intrinsic to these cells.     

Unc45b is essential for early myofibrillogenesis and costamere formation in zebrafish

Despite the prevalence of developmental myopathies resulting from muscle fiber defects, the earliest stages of myogenesis remain poorly understood. Unc45b is a molecular chaperone that mediates the folding of thick-filament myosin during sarcomere formation; however, Unc45b may also mediate specific functions of non-muscle myosins (NMMs). unc45b Mutants have specific defects in striated muscle development, which include myocyte detachment indicative of dysfunctional adhesion complex formation. Given the necessity for non-muscle myosin function in the formation of adhesion complexes and premyofibril templates, we tested the hypothesis that the unc45b mutant phenotype is not mediated solely by interaction with muscle myosin heavy chain (mMHC). We used the advantages of a transparent zebrafish embryo to determine the temporal and spatial patterns of expression for unc45b, non-muscle myosins and mMHC in developing somites. We also examined the formation of myocyte attachment complexes (costameres) in wild-type and unc45b mutant embryos. Our results demonstrate co-expression and co-regulation of Unc45b and NMM in myogenic tissue several hours before any muscle myosin heavy chain is expressed. We also note deficiencies in the localization of costamere components and NMM in unc45b mutants that is consistent with an NMM-mediated role for Unc45b during early myogenesis. This represents a novel role for Unc45b in the earliest stages of muscle development that is independent of muscle mMHC folding.     

Six Innexins Contribute to Electrical Coupling of C. elegans Body-Wall Muscle

C. elegans body-wall muscle cells are electrically coupled through gap junctions. Previous studies suggest that UNC-9 is an important, but not the only, innexin mediating the electrical coupling. Here we analyzed junctional current (I _j) for mutants of additional innexins to identify the remaining innexin(s) important to the coupling. The results suggest that a total of six innexins contribute to the coupling, including UNC-9, INX-1, INX-10, INX-11, INX-16, and INX-18. The I _j deficiency in each mutant was rescued completely by expressing the corresponding wild-type innexin specifically in muscle, suggesting that the innexins function cell-autonomously. Comparisons of I _j between various single, double, and triple mutants suggest that the six innexins probably form two distinct populations of gap junctions with one population consisting of UNC-9 and INX-18 and the other consisting of the remaining four innexins. Consistent with their roles in muscle electrical coupling, five of the six innexins showed punctate localization at muscle intercellular junctions when expressed as GFP- or epitope-tagged proteins, and muscle expression was detected for four of them when assessed by expressing GFP under the control of innexin promoters. The results may serve as a solid foundation for further explorations of structural and functional properties of gap junctions in C. elegans body-wall muscle.