The yeast cell cycle gene CDC34 encodes a ubiquitin-conjugating enzyme.

Mutants in the gene CDC34 of the yeast Saccharomyces cerevisiae are defective in the transition from G1 to the S phase of the cell cycle. This gene was cloned and shown to encode a 295-residue protein that has substantial sequence similarity to the product of the yeast RAD6 gene. The RAD6 gene is required for a variety of cellular functions including DNA repair and was recently shown to encode a ubiquitin-conjugating enzyme. When produced in Escherichia coli, the CDC34 gene product catalyzed the covalent attachment of ubiquitin to histones H2A and H2B in vitro, demonstrating that the CDC34 protein is another distinct member of the family of ubiquitin-conjugating enzymes. The cell cycle function of CDC34 is thus likely to be mediated by the ubiquitin-conjugating activity of its product.

Ras is required for a limited number of cell fates and not for general proliferation in Caenorhabditis elegans.

Experiments with mammalian tissue culture cells have implicated the small GTPase Ras in the control of cellular proliferation. Evidence is presented here that this is not the case for a living animal, the nematode Caenorhabditis elegans: proliferation late in embryogenesis and throughout the four larval stages is not noticeably affected in animals lacking Ras in various parts of their cell lineages. Instead, genetic mosaic analysis of the let-60 gene suggests that Ras is required only, at least later in development (a maternal effect cannot be excluded), for establishment of a few temporally and spatially distinct cell fates. Only one of these, the duct cell fate, appears to be essential for viability.

Structural comparison of the yeast cell division cycle gene CDC4 and a related pseudogene.

The function of the cell division cycle gene, CDC4, is required in Saccharomyces cerevisiae for progression beyond the G1 phase of the cell cycle. The wild-type gene was isolated from a plasmid library by selection for complementation of a recessive, temperature-sensitive allele. Hybridization of genomic sequences with the cloned gene revealed the presence of a duplicated sequence. Both CDC4 and the duplicated sequence were subjected to DNA sequence analysis. These analyses revealed (1) that CDC4 contains a large open reading frame encoding a protein of 779 amino acids, and (2) that the duplicated sequence bears strong homology with the carboxy-terminal segment of this open reading frame. Presence of a nonsense codon within the duplicated sequence suggested that it does not encode a functional product. Disruption of the duplicated sequence within the yeast genome provided a more critical test for function. The absence of any detectable phenotype for this disruption confirms that the sequence should be considered a pseudogene. The marker inserted to disrupt the sequence also served to map the duplication and to establish that it is not genetically linked to CDC4. The structural features determined suggest evolutionary relationships between these genes as well as between the CDC4 product and other proteins.

A new marker for mosaic analysis in Caenorhabditis elegans indicates a fusion between hyp6 and hyp7, two major components of the hypodermis.

A fusion of the sur-5 protein to the green fluorescent protein containing a nuclear localization signal is demonstrated as a marker for genetic mosaic analysis in the nematode Caenorhabditis elegans. Because of an extensive accumulation of bright fluorescence in many nuclei, normal growth plates, each containing hundreds of worms, can be rapidly screened with a dissecting microscope for rare mosaic individuals. As the marker can also be used to detect transgenic worms, the construction of strains for mosaic analyses can be minimized. In the course of examining rare mosaic animals, an unexpected pattern of fluorescence was noticed for hyp6, a syncytial component of the hypodermis, which indicated that the marker may serve as a means of assessing cellular fusions during development. Immunofluorescent staining of adherens junctions confirmed a postembryonic fusion of hyp6 with hyp7, the major syncytium of the hypodermis.

A gene for a low density lipoprotein receptor-related protein in the nematode Caenorhabditis elegans.

A >23-kb gene that encodes a large integral membrane protein with a predicted structure similar to that of the low density lipoprotein (LDL) receptor-related protein (LRP) of mammals has been isolated and sequenced from the free-living nematode Caenorhabditis elegans. The 4753-amino acid predicted C. elegans product shares a nearly identical number and arrangement of amino acid sequence motifs with human LRP, and several exons of the C. elegans LRP gene correspond to exons of related parts of the human LDL receptor gene. The existence of an apparent homolog of LRP in C. elegans offers the possibility of genetic analysis of the in vivo roles of LRP and of the relationship between protein structure and function in a simple model organism.

glp-1 and lin-12, genes implicated in distinct cell-cell interactions in C. elegans, encode similar transmembrane proteins.

Genomic DNA closely related in sequence to lin-12, a gene that specifies certain cell fates during C. elegans development, was isolated from a C. elegans library by low stringency hybridization. DNA sequencing of genomic and cDNA clones predicts the new sequence to encode an integral membrane protein that shares three repeated amino acid sequence motifs with the lin-12 product and the Drosophila Notch product: an epidermal growth factor-like motif, the "lin-12/Notch Repeat," and a motif present in two yeast gene products that have cell cycle dependent functions. Austin and Kimble (see accompanying paper) present evidence that this sequence corresponds to glp-1, a gene implicated in cell-cell interactions distinct from those involving lin-12. Possible implications of the predicted structure of the glp-1 product with respect to these cell-cell interactions are discussed.

The Caenorhabditis elegans lin-12 gene encodes a transmembrane protein with overall similarity to Drosophila Notch.

The lin-12 gene seems to control certain binary decisions during Caenorhabditis elegans development, from genetic and anatomical studies of lin-12 mutants that have either elevated or reduced levels of lin-12 activity. We report here the complete DNA sequence of lin-12: 13.5 kilobases (kb) derived from genomic clones and 4.5 kb from complementary DNA clones. It is of interest that the predicted product is a putative transmembrane protein, given that many of the decisions controlled by lin-12 activity require cell-cell interactions for the correct choice of cell fate. In addition, the predicted lin-12 product may be classified into several regions, based on amino acid sequence similarities to other proteins. These include extensive overall sequence similarity to the Drosophila Notch protein, which also is involved in cell-cell interactions that specify cell fate; a repeated motif found in proteins encoded by the yeast cell-cycle control genes cdc10 (Schizosaccharomyces pombe) and SWI6 (Saccharomyces cerevisiae); and a repeated motif exemplified by epidermal growth factor, found in many mammalian proteins.

A Ras-mediated signal transduction pathway is involved in the control of sex myoblast migration in Caenorhabditis elegans.

Sex myoblast migration in the Caenorhabditis elegans hermaphrodite represents a simple, genetically amenable model system for studying how cell migration is regulated during development. Two separable components of sex myoblast guidance have been described: a gonad-independent mechanism sufficient for the initial anterior migration to the mid-body region, and a gonad-dependent mechanism required for precise final positioning (J. H. Thomas, M. J. Stern and H. R. Horvitz (1990) Cell 62, 1041-1052). Here, we demonstrate a role for a Ras-mediated signal transduction pathway in controlling sex myoblast migration. Loss-of-function mutations in let-60 ras, ksr-1, lin-45 raf, let-537/mek-2 or sur-1/mpk-1 cause defects in sex myoblast final positions that resemble those seen in gonad-ablated animals, while constitutively active let-60 ras(G13E) trans-genes allow fairly precise positioning to occur in the absence of the gonad. A mosaic analysis demonstrated that let-60 ras is required within the sex myoblasts to control proper positioning. Our results suggest that gonadal signals normally stimulate let-60 ras activity in the sex myoblasts, thereby making them competent to sense or respond to positional cues that determine the precise endpoint of migration. let-60 ras may have additional roles in sex myoblast guidance as well. Finally, we have also investigated genetic interactions between let-60 ras and other genes important for sex myoblast migration, including egl-15, which encodes a fibroblast growth factor receptor tyrosine kinase (D. L. DeVore, H. R. Horvitz and M. J. Stern (1995) Cell 83, 611-623). Since mutations reducing Ras pathway activity cause a different phenotype than those reducing egl-15 activity and since constitutive Ras activity only partially suppresses the migration defects of egl-15 mutants, we argue that let-60 ras and egl-15 do not act together in a single linear pathway.

A gp330/megalin-related protein is required in the major epidermis of Caenorhabditis elegans for completion of molting.

A genetic analysis of a gp330/megalin-related protein, LRP-1, has been undertaken in Caenorhabditis elegans. Consistent with megalin's being essential for development of mice, likely null mutations reveal that this large member of the low density lipoprotein receptor family is also essential for growth and development of this nematode. The mutations confer a striking defect, an inability to shed and degrade all of the old cuticle at each of the larval molts. The mutations also cause an arrest of growth usually at the molt from the third to the fourth larval stage. Genetic mosaic analysis suggests that the lrp-1 gene functions in the major epidermal syncytium hyp7, a polarized epithelium that secretes cuticle from its apical surface. Staining of whole mounts with specific monoclonal antibodies reveals that the protein is expressed on the apical surface of hyp7. Sterol starvation can phenocopy the lrp-1 mutations, suggesting that LRP-1 is a receptor for sterols that must be endocytosed by hyp7. These observations indicate that LRP-1 is related to megalin not only structurally but also functionally.

A new host gene (groPC) necessary for lambda DNA replication.

The isolation of a bacterial mutation in a gene, designated groPC, which affects the growth of phages lambda and P2 is described. Lambda replication is severely limited in the strain, and some lambda pi mutations, which map in (or near) the P gene, allow growth. The gro mutation, groPC259, is recessive to wild type and maps between threonine (thr) and diaminopimelate (dapB) on the E. coli chromosome. The possibility that the groPC gene is concerned with host DNA replication is discussed.

Identification of the E. coli dnaJ gene product.

We have previously shown that a mutation (groPC259) in the E. coli dnaJ gene renders the cell inviable at high temperatures and arrests bacteriophage lambda DNA replication at all temperatures (Sunshine et al., 1977). We have isolated lambda dnaJ+ transducing phages both by in vitro cloning and by abnormal excision of a lambda dnaK transducing phage integrated near the dnaJ locus. The dnaJ gene product has been identified on SDS polyacrylamide gels after infection of UV-irradiated E. coli cells by lambda dnaJ+ derivative phages. It is a polypeptide chain with an apparent molecular weight of 37,000-daltons. This has been verified by the fact that a transducing phage carrying an amber mutation in the dnaJ gene fails to induce the synthesis of the 37,000-dalton polypeptide chain upon infection of sup+ bacteria, but does so upon infection of supF or supD bacteria.

Genetic analysis of two genes, dnaJ and dnaK, necessary for Escherichia coli and bacteriophage lambda DNA replication.

We show that a collection of 93 E. coli mutations which map between thr and leu and which block phage lambda DNA replication define two closely linked cistrons. Work published in the accompanying paper shows that these mutations also affect host DNA replication, so we designate them dnaJ and dnaK; the gene order is thr--dnaK--dnaJ--leu. Demonstration of two cistrons was possible with the isolation of lambda transducing phages carrying one or the other or both of the dna genes. These phages were employed in phage vs bacterial complementation studies which unambiguously show that dnaK and dnaJ are different cistrons.

Identification of the C. coli dnaK (groPC756) gene product.

The E. coli dnaK (groPC756) gene product is essential for bacteriophage lambda DNA replication. Bacterial DNA segments carrying this gene have been cloned onto a bacteriophage lambda vector. The product of the dnaK gene has been identified on SDS polyacrylamide gels after infection of UV-irradiated E. coli cells. The dnaK gene codes for a polypeptide with an apparent molecular weight of 93,000-Mr. Transducing phages carrying amber mutations in the dnaK gene fail to induce the synthesis of the 93,000-Mr polypeptide chain upon infection of sup+ bacteria, but do so upon infection of supF bacteria. E coli carrying the dnaK756 mutation are, in addition, temperature sensitive for growth at 43 degrees C. It is shown that the dnaK756 mutation results in an overproduction of the dnaK gene product at that temperature.

A relationship between the yeast cell cycle genes CDC4 and CDC36 and the ets sequence of oncogenic virus E26.

We report here significant primary sequence homology among the predicted translational products of three genes: CDC4 , CDC36 and ets. CDC4 and CDC36 are Saccharomyces cerevisiae cell division cycle genes, while ets is a transformation-specific sequence of avian erythroblastosis virus E26. The deduced primary structures of the three gene products were compared by computer to a large data base of known and predicted protein sequences. The search revealed 22.0-25.5% identity over regions of 140-206 codons, respectively between the different pairwise combinations. For these particular sequences, these identity scores fall 3.4-4.0 standard deviations above the empirically-determined mean values of fortuitous similarity. S. cerevisiae calls require CDC36 and CDC4 in order to complete two early events in the cell cycle: execution of start ( CDC36 ) and spindle pole body separation ( CDC4 ). In virus E26, the ets sequence is linked in frame with delta gag and mybE in the tripartite structure 5'-delta gag- mybE -ets-3', comprising the E26 transforming oncogene. The homologies described here suggest that the biochemical functions or regulation of the CDC4 , CDC36 and ets products may be related.