The Caenorhabditis elegans vitellogenin gene family includes a gene encoding a distantly related protein.

While the nematode Caenorhabditis elegans is more primitive than most egg-laying organisms, it's vitellogenins, or yolk protein precursors, appear to be more complex. C. elegans oocytes accumulate two major classes of yolk proteins. The first consists of two polypeptides with an Mr of about 170,000 (yp170A and yp170B) encoded by a family of five closely related genes called vit-1 through vit-5. The second class consists of two smaller proteins with Mr values of 115,000 (yp115) and 88,000 (yp88) which are cut from a single precursor. Here we report the cloning and analysis of a single-copy gene (vit-6) that encodes this precursor. The lengths of the gene and its mRNA are about 5 X 10(3) base pairs. Like vit-1 through vit-5, vit-6 is expressed exclusively in adult hermaphrodites. Comparison of portions of the coding sequence indicates that vit-6 is distantly related to the vit-1 through vit-5 gene family. Thus, even though the two classes of yolk proteins are antigenically and physically distinct, they are encoded by a single highly diverged gene family.     

Identification of a large multigene family encoding the major sperm protein of Caenorhabditis elegans

DNA fragments corresponding to genes encoding the MSP of Caenorhabditis elegans sperm have been isolated by recombinant DNA techniques. Analyses of individual genomic clones suggest that there are multiple MSP genes that are dispersed in the genome. From restriction enzyme digests of genomic DNA fractionated and hybridized with an MSP complementary DNA probe, there appear to be more than 30 MSP genes in the genome. Despite the occurrence of this large dispersed multigene family, the MSP messenger RNA from both males and hermaphrodites is homogene in size. There are at least three different proteins of identical molecular weight but different isoelectric point that cross-react with anti-MSP antisera. Each protein is a primary translation product with no detectable post-translational modifications, suggesting that at least three of the MSP genes are expressed.     

Characterization of Ce-atl-1, an ATM-like gene from Caenorhabditis elegans

An ATM-like gene was identified in the genome of Caenorhabditis elegans. The putative product of the gene, termed Ce-atl-1 (C. elegans ATM-like 1) consists of 2514 amino acid residues. The C-terminal sequence, which contains a PI-3 kinase-like domain, showed good homology with the products of the gene MEC1/ESR1 from budding yeast, the rad3+ gene of fission yeast and mammalian ATM (ataxia-telangiectasia and rad3+ related) genes. The results of RNA-mediated interference indicated that the major phenotype associated with repression of Ce-atl-1 was lethality (approximately 50-80%) during early embryogenesis. Among the surviving progeny, males (XO animals) arose at a high frequency (2-30%). In addition, 5% of oocyte chromosomes demonstrated aneuploidy due to a defect in pre-meiotic chromosomal segregation. Gene expression analyses indicated that Ce-atl-1 mRNA was expressed in all larval stages and that its level increased about fivefold in the adult stage. The adult expression level was decreased in the glp-4 mutant, which is defective in germ line proliferation. Ce-atl-1 was strongly expressed in both the mitotic and meiotic cells of adult gonads. In summary, Ce-atl-1 appears to be important for early embryogenesis, and loss of its function results in a defect in chromosome segregation, similar to what has been observed for AT-related proteins.     

Identification of an essential Caulobacter crescentus gene encoding a member of the Obg family of GTP-binding proteins.

We have identified an essential Caulobacter crescentus gene (cgtA) that encodes a member of a recently identified subfamily of GTPases (the Obg family) conserved from Bacteria to Archaea to humans. This evolutionary conservation between distantly related species suggests that this family of GTP-binding proteins possesses a fundamental, yet unknown, cellular role. In this report, we describe the isolation and sequence of the cgtA gene. The predicted CgtA protein displays striking similarity to the Obg family of small, monomeric GTP-binding proteins, both in the conserved guanine nucleotide-binding domains and throughout the N-terminal glycine-rich domain that is found in many members of the Obg family. Disruption of the cgtA gene was lethal, demonstrating that this gene is essential for cell growth. Immunoblot analysis revealed that CgtA protein levels remained constant throughout the C. crescentus cell cycle.     

The primary structure of a minor isoform (H1.2) of histone H1 from the nematode Caenorhabditis elegans.

The complete amino acid sequence of a minor isoform (H1.2) of histone H1 from the nematode Caenorhabditis elegans was determined. The amino acid chain consists of 190 residues and has a blocked N-terminus. Histone subtype H1.2 is 17 residues shorter than the major isoform H1.1, mainly as the result of deletions of short peptide fragments. Considerable divergence from isoform H1.1 has occurred in the N-terminal domain and the very C-terminus of the molecule, but the central globular domain and most of the C-terminal domain, including two potential phosphorylation sites, have been well conserved. Secondary-structure predictions for both H1 isoforms reveal a high potential for helix formation in the N-terminal region 1-33 of isoform H1.1 whereas the corresponding region in isoform H1.2 has low probability of being found in alpha-helix. No major differences in secondary structure are predicted for other parts of both H1 subtypes. The aberrant conformation of isoform H1.2 may be indicative of a significantly different function.     

The Caenorhabditis elegans K10C2.4 gene encodes a member of the fumarylacetoacetate hydrolase family: a Caenorhabditis elegans model of type I tyrosinemia

In eukaryotes and many bacteria, tyrosine is degraded to produce energy via a five-step tyrosine degradation pathway. Mutations affecting the tyrosine degradation pathway are also of medical importance as mutations affecting enzymes in the pathway are responsible for type I, type II, and type III tyrosinemia. The most severe of these is type I tyrosinemia, which is caused by mutations affecting the last enzyme in the pathway, fumarylacetoacetate hydrolase (FAH). So far, tyrosine degradation in the nematode Caenorhabditis elegans has not been studied; however, genes predicted to encode enzymes in this pathway have been identified in several microarray, proteomic, and RNA interference (RNAi) screens as perhaps being involved in aging and the control of protein folding. We sought to identify and characterize the genes in the worm tyrosine degradation pathway as an initial step in understanding these findings. Here we describe the characterization of the K10C2.4, which encodes a homolog of FAH. RNAi directed against K10C2.4 produces a lethal phenotype consisting of death in young adulthood, extensive damage to the intestine, impaired fertility, and activation of oxidative stress and endoplasmic stress response pathways. This phenotype is due to alterations in tyrosine metabolism as increases in dietary tyrosine enhance it, and inhibition of upstream enzymes in tyrosine degradation with RNAi or genetic mutations reduces the phenotype. We also use our model to identify genes that suppress the damage produced by K10C2.4 RNAi in a pilot genetic screen. Our results establish worms as a model for the study of type I tyrosinemia.     

Characterization of a Caenorhabditis elegans recA-like gene Ce-rdh-1 involved in meiotic recombination.

A recA-like gene was identified in the Caenorhabditis elegans genome project database. The putative product of the gene, termed Ce-rdh-1 (C. elegans RAD51 and DMC1/LIM15 homolog 1), consists of 357 amino acid residues. The predicted amino acid sequence of Ce-rdh-1 showed 46-60% identity to both RAD51 type and DMC1/LIM15 type genes in several eukaryote species. The results of RNAi (RNA-mediated interference) indicated that repression of Ce-rdh-1 blocked chromosome condensation of six bivalents and dissociation of chiasmata in oocytes of F1 progeny. Oogenesis did not proceed to the diakinesis stage. Accordingly, all the eggs produced (F2) died in early stages. These results suggest that Ce-rdh-1 participates in meiotic recombination.     

The tra-3 sex determination gene of Caenorhabditis elegans encodes a member of the calpain regulatory protease family.

The Caenorhabditis elegans sex determination gene tra-3 is required for the correct sexual development of the soma and germ line in hermaphrodites, while being fully dispensable in males. Genetic analysis of tra-3 has suggested that its product may act as a potentiator of another sex determination gene, tra-2. Molecular analysis reported here reveals that the predicted tra-3 gene product is a member of the calpain family of calcium-regulated cytosolic proteases, though it lacks the calcium binding regulatory domain. Calpains are regulatory processing proteases, exhibiting marked substrate specificity, and mutations in the p94 isoform underlie the human hereditary condition limb-girdle muscular dystrophy type 2A. The molecular identity of TRA-3 is consistent with previous genetic analysis which suggested that tra-3 plays a very selective modulatory role and is required in very small amounts. Based on these observations and new genetic data, we suggest a refinement of the position of tra-3 within the sex determination cascade and discuss possible mechanisms of action for the TRA-3 protein.     

Identification of a novel gene family involved in osmotic stress response in Caenorhabditis elegans

Organisms exposed to the damaging effects of high osmolarity accumulate solutes to increase cytoplasmic osmolarity. Yeast accumulates glycerol in response to osmotic stress, activated primarily by MAP kinase Hog1 signaling. A pathway regulated by protein kinase C (PKC1) also responds to changes in osmolarity and cell wall integrity. C. elegans accumulates glycerol when exposed to high osmolarity, but the molecular pathways responsible for this are not well understood. We report the identification of two genes, osm-7 and osm-11, which are related members of a novel gene family. Mutations in either gene lead to high internal levels of glycerol and cause an osmotic resistance phenotype (Osr). These mutants also have an altered defecation rhythm (Dec). Mutations in cuticle collagen genes dpy-2, dpy-7, and dpy-10 cause a similar Osr Dec phenotype. osm-7 is expressed in the hypodermis and may be secreted. We hypothesize that osm-7 and osm-11 interact with the cuticle, and disruption of the cuticle causes activation of signaling pathways that increase glycerol production. The phenotypes of osm-7 are not suppressed by mutations in MAP kinase or PKC pathways, suggesting that C. elegans uses signaling pathways different from yeast to mount a response to osmotic stress.     

The primary structure of the major isoform (H1.1) of histone H1 from the nematode Caenorhabditis elegans.

The complete primary structure of the major isoform (H1.1) of histone H1 from the nematode Caenorhabditis elegans was determined. The amino acid chain consists of 207 amino acids and has a blocked N-terminus. The nematode histone shows rather little sequence identity when compared with proteins of the H1 family derived from other organisms. However, the main characteristic features of H1 molecules have been well conserved: a tripartite domain structure consisting of a central hydrophobic core of about 80 residues, flanked by an N-terminal domain which is somewhat acidic at the very N-terminus, but very basic further on, and a long C-terminal domain very rich in lysine, alanine and proline. Several repeat structures, including a twice (with modification)-repeated and well-conserved phosphorylation site, can be recognized in this region. The presence of O-phosphoserine at these sites could not be demonstrated, however.     

Cloning of a yolk protein gene family from Caenorhabditis elegans

A novel family of large, imperfectly repeated DNA sequences has been found in Escherichia coli. Two members of this family, rhsA and rhsB, occur as direct repeats, flanking the pit glyS xyl segment of the chromosome. Unequal sister-chromatid crossing over between rhsA and rhsB accounts for the frequent tandem duplication of the glyS locus that has been observed by various workers. This unequal recombination is recA-dependent. The rhsA locus is operationally defined as the segment between xyl and mtl that is repeated at other chromosomal locations. Using this definition, rhsA extends minimally 5500 base-pairs; 3800 base-pairs of rhsA are sufficiently homologous to rhsB to form an S1 nuclease-resistant heteroduplex with it. The rhsA sequence also exhibits internal repetition. At least one additional rhs sequence occurs in the E. coli chromosome unlinked to either rhsA or rhsB. Southern analysis of restriction digests of genomic DNA from E. coli strains C and B/5 showed that both of these strains have rhs hybridizable patterns similar to strain K-12, but the rhs sequence is absent in Salmonella typhimurium. The function of the rhs sequences has not been discovered. In the course of this work we developed a technique, termed "transductional walking", by which chromosomal DNA adjacent to a previously cloned DNA segment can be cloned through genetic procedures.