Genomic organization, expression, and analysis of the troponin C gene pat-10 of Caenorhabditis elegans.

We have cloned and characterized the troponin C gene, pat-10 of the nematode Caenorhabditis elegans. At the amino acid level nematode troponin C is most similar to troponin C of Drosophila (45% identity) and cardiac troponin C of vertebrates. Expression studies demonstrate that this troponin is expressed in body wall muscle throughout the life of the animal. Later, vulval muscles and anal muscles also express this troponin C isoform. The structural gene for this troponin is pat-10 and mutations in this gene lead to animals that arrest as twofold paralyzed embryos late in development. We have sequenced two of the mutations in pat-10 and both had identical two mutations in the gene; one changes D64 to N and the other changes W153 to a termination site. The missense alteration affects a calcium-binding site and eliminates calcium binding, whereas the second mutation eliminates binding to troponin I. These combined biochemical and in vivo studies of mutant animals demonstrate that this troponin is essential for proper muscle function during development.

An abnormal ketamine response in mutants defective in the ryanodine receptor gene ryr-1 (unc-68) of Caenorhabditis elegans.

To characterize excitation-contraction coupling in Caenorhabditis elegans, we applied two approaches. First, we isolated a mutant having abnormal responses to ketamine, an anesthetic in vertebrates. The novel mutation unc-68(kh30) (isolated as kra-1(kh30)), exhibited strict ketamine-dependent convulsions followed by paralysis. Second, we cloned the C. elegans ryanodine receptor gene ryr-1 that is located near the center of chromosome V. ryr-1 consists of 46 exons, which encode a predicted protein of 5071 amino acid residues that is homologous to Drosophila and vertebrate ryanodine receptors. ryr-1 promoter/lacZ plasmids were expressed in body-wall and pharyngeal muscles. Non-muscle cell expression may be seen with a truncated promoter. In addition, we show that the unc-68/kra-1(kh30) mutation is a Ser1444 Asn substitution at a putative protein kinase C phosphorylation site in ryr-1, and that unc-68(e540) contains a splice acceptor mutation that creates a premature stop codon in the ryr-1 gene. We confirmed that unc-68(e540) is a mutation in ryr-1 by injecting the complete ryr-1 gene into unc-68(e540) animals and recovering wild-type progeny. Results presented here will be useful in studying the structure and function of ryanodine receptors in excitation-contraction coupling and in understanding the evolution of ryanodine receptor tissue specificity.

The third and fourth tropomyosin isoforms of Caenorhabditis elegans are expressed in the pharynx and intestines and are essential for development and morphology.

The tropomyosin gene tmy-1/lev-11 of Caenorhabditis elegans spans 14.5 kb and encodes three isoforms by alternative splicing. To identify, characterize and compare the genome and tissue expression of a fourth isoform, the technique of rapid amplification of cDNA ends and microinjection with lacZ and gfp fusion plasmids were employed. We elucidated CeTMIV, a fourth isoform of tmy-1, which encoded a 256 residue polypeptide. CeTMIV isoform had a similar promoter region to CeTMIII isoform, but was alternatively spliced to generate a cDNA that differed in two exons. The tmy-1::lacZ and tmy-1::gfp fusion genes, with 3.2 kb promoter sequence and 1.1 kb of CeTMIV isoform specific exons, were expressed in the pharyngeal and intestinal cells. Further unidirectional deletion of the sequence located the primary promoter region 853 bp upstream from the initial codon. We show within the upstream region, the presence of B and C subelement-like sequences of myo-2, which may be used to stimulate pharyngeal expression. Despite the presence of a ges-1 like sequence, we were unable to locate the two GATA sites required for intestinal expression. Reassessing tissue expression for CeTMIII isoform with newly constructed fusion plasmids, we showed further expression in germ-line tissue and intestinal cells in addition to pharyngeal expression. Finally, to demonstrate that tropomyosin is essential for development, we inactivated the body wall and pharynx-specific isoforms by RNA-mediated interference. In addition to 50-75 % embryonic lethality in both cases, the worms that survived body wall interference had abnormal body morphology and uncoordinated movements, and those that survived pharynx interference had deformed pharynges and gut regions. These results show the function of tropomyosin in normal muscle filament assembly and embryonic development, and illustrate the different expression patterns characteristic of tropomyosin isoforms in C. elegans.

Genome structure, mapping and expression of the tropomyosin gene tmy-1 of Caenorhabditis elegans.

The complete tropomyosin gene, designated tmy-1, of Caenorhabditis elegans was recovered by genome walking from a fragment that was obtained by exon-expression cloning using specific cloning using specific anti-tropomyosin antiserum as a probe. The genome structure of the tmy-1 gene has been determined by combining the DNA sequences of cDNA clones with those of the genomic fragments. The single-copy gene spans approximately 13 kb and include 14 exons. Comparison of cDNA and genomic sequences demonstrates that three isoforms are encoded by the gene tmy-1. Homology of the 27 C-terminal amino acid residues to those of Drosophila and vertebrates suggest that these may be the body wall, pharyngeal and non-muscle types. Tissue-specific expression of the tmy-1 gene was determined by microinjection of a promoter/lacZ fusion gene and with immunohistochemistry by using affinity-purified tissue-specific anti-tropomyosins. The 5' end promoter common to CeTMI and CeTMII is expressed in the body wall muscles, vulva, anus muscles and male tail muscles. Control sequences of the 5' end promoter are located 660 to 800 bp upstream of the initial methionine codon. The third isoform, CeTMIII, encoding 256 amino acids residues was expressed in the pharyngeal muscles by the promoter in the third intron. The mRNA of CeTMIII was trans-spliced with SL1 and SL2. These results allow is to solve the question of what is common from this worm to vertebrates, and also what are the cross-species complexities and the tissue-specific differences of tropomyosins. The tmy-1 gene is located on the C. elegans genomic YAC grid near the right end of chromosome I, in the region on the lev-11 gene.

Mutations and expressions of the tropomyosin gene and the troponin C gene of Caenorhabditis elegans.

How does muscle gene mutation affect the muscle structure and function of an animal? Mutant animals of the tropomyosin and troponin C genes of Caenorhabditis elegans show Pat (paralyzed, arrested elongation at twofold) phenotypes together with abnormal muscle filament assembly. We present evidence that the mutation sites of lev-11 gene was in the tropomyosin gene, tmy-1 and that of pat-10 was in the troponin C gene, tnc-1, of the worm, respectively. The lev-11 (st557) mutation occurred at the splice donor site of exon 1 and results in translation termination. Although the gene product from heterozygous (+/st557) animal was not detected, our result could be the reason for the Pat phenotype of this mutation. The lev-11(x12) mutation, isolated as an allele of levamisole resistance, occurred in exon 7 and results in amino acid substitution at 234 from Glu to Lys. This substitution give a charge change from - to + at this point which is common in three isoforms. There may be functional importance of this region for molecular interaction of the tropomyosin. Mutation site of pat-10(st575) was Asp64 to Asn and Trp153 to termination in the troponin C. The first mutation site was in the second calcium binding site and the second mutation raised the deletion of H helix in the troponin C. Both might affect the calcium binding or the retaining of the conformation for its function. Results presented here will be useful to understand the interaction site between the tropomyosin and troponin complex.