Mutations in the sup-38 gene of Caenorhabditis elegans suppress muscle-attachment defects in unc-52 mutants.

Mutations in the unc-52 locus of Caenorhabditis elegans have been classified into three different groups based on their complex pattern of complementation. These mutations result in progressive paralysis (class 1 mutations) or in lethality (class 2 and 3 mutations). The paralysis exhibited by animals carrying class 1 mutations is caused by disruption of the myofilaments at their points of attachment to the cell membrane in the body wall muscle cells. We have determined that mutations of this class also have an effect on the somatic gonad, and this may be due to a similar disruption in the myoepithelial sheath cells of the uterus, or in the uterine muscle cells. Mutations that suppress the body wall muscle defects of the class 1 unc-52 mutations have been isolated, and they define a new locus, sup-38. Only the muscle disorganization of the Unc-52 mutants is suppressed; the gonad abnormalities are not, and the suppressors do not rescue the lethal phenotype of the class 2 and class 3 mutations. The suppressor mutations on their own exhibit a variable degree of gonad and muscle disorganization. Putative null sup-38 mutations cause maternal-effect lethality which is rescued by a wild-type copy of the locus in the zygote. These loss-of-function mutations have no effect on the body wall muscle structure.

Mutations in the unc-52 gene responsible for body wall muscle defects in adult Caenorhabditis elegans are located in alternatively spliced exons.

The unc-52 gene in Caenorhabditis elegans produces several large proteins that function in the basement membrane underlying muscle cells. Mutations in this gene result in defects in myofilament assembly and in the attachment of the myofilament lattice to the muscle cell membrane. The st549 and ut111 alleles of unc-52 produce a lethal (Pat) terminal phenotype whereas the e444, e669, e998, e1012 and e1421 mutations result in viable, paralyzed animals. We have identified the sequence alterations responsible for these mutant phenotypes. The st549 allele has a premature stop codon in exon 7 that should result in the complete elimination of unc-52 gene function, and the ut111 allele has a Tc1 transposon inserted into the second exon of the gene. The five remaining mutations are clustered in a small interval containing three adjacent, alternatively spliced exons (16, 17 and 18). These mutations affect some, but not all of the unc-52-encoded proteins. Thirteen intragenic revertants of the e669, e998, e1012 and e1421 alleles have also been sequenced. The majority of these carry the original mutation plus a G to A transition in the conserved splice acceptor site of the affected exon. This result suggests that reversion of the mutant phenotype in these strains may be the result of exon-skipping.

UNC-52/perlecan isoform diversity and function in Caenorhabditis elegans.

The unc-52 gene encodes the nematode homologue of mammalian perlecan, the major heparan sulphate proteoglycan of the extracellular matrix. This is a large complex protein with regions similar to low-density lipoprotein receptors, laminin and neural cell-adhesion molecules. Three major classes of UNC-52/perlecan isoforms are produced through alternative splicing, and these distinct proteins exhibit complex spatial and temporal expression patterns throughout development. The unc-52 gene plays an essential role in myofilament assembly in body-wall muscle during embryonic development.

Molecular cloning and characterization of the dpy-20 gene of Caenorhabditis elegans.

We describe the molecular analysis of the dpy-20 gene in Caenorhabditis elegans. Isolation of genomic sequences was facilitated by the availability of a mutation that resulted from insertion of a Tc1 transposable element into the dpy-20 gene. The Tc1 insertion site in the m474::Tc1 allele was identified and was found to lie within the coding region of dpy-20. Three revertants (two wild-type and one partial revertant) resulted from the excision of this Tc1 element. Genomic dpy-20 clones' were isolated from a library of wild-type DNA and were found to lie just to the left of the unc-22 locus on the physical map, compatible with the position of dpy-20 on the genetic map. Cosmid DNA containing the dpy-20 gene was successfully used to rescue the mutant phenotype of animals homozygous for another dpy-20 allele, e1282ts. Sequence analysis of the putative dpy-20 homologue in Caenorhabditis briggsae was performed to confirm identification of the coding regions of the C. elegans gene and to identify conserved regulatory regions. Sequence analysis of dpy-20 revealed that it was not similar to other genes encoding known cuticle components such as collagen or cuticulin. The dpy-20 gene product, therefore, identifies a previously unknown type of protein that may be directly or indirectly involved in cuticle function. Northern blot analysis showed that dpy-20 is expressed predominantly in the second larval stage and that the mRNA is not at all abundant. Data from temperature shift studies using the temperature-sensitive allele e1282ts showed that the sensitive period also occurs at approximately the second larval stage. Therefore, expression of dpy-20 mRNA and function of the DPY-20 protein are closely linked temporally.

Lethal mutations defining 112 complementation groups in a 4.5 Mb sequenced region of Caenorhabditis elegans chromosome III.

The central gene cluster of chromosome III was one of the first regions to be sequenced by the Caenorhabditis elegans genome project. We have performed an essential gene analysis on the left part of this cluster, in the region around dpy-17III balanced by the duplication sDp3. We isolated 151 essential gene mutations and characterized them with regard to their arrest stages. To facilitate positioning of these mutations, we generated six new deficiencies that, together with preexisting chromosomal rearrangements, subdivide the region into 14 zones. The 151 mutations were mapped into these zones. They define 112 genes, of which 110 were previously unidentified. Thirteen of the zones have been anchored to the physical sequence by polymerase chain reaction deficiency mapping. Of the 112 essential genes mapped, 105 are within these 13 zones. They span 4.2 Mb of nucleotide sequence. From the nucleotide sequence data, 920 genes are predicted. From a Poisson distribution of our mutations, we predict that 234 of the genes will be essential genes. Thus, the 105 genes constitute 45% of the estimated number of essential genes in the physically defined zones and between 2 and 5% of all essential genes in C. elegans.