Identification and sequence analysis of a rap gene from the true slime mold Physarum polycephalum

A member of the ras gene superfamily, belonging to the rap family and designated Pprap1, was isolated from a cDNA library from the true slime mold Physarum polycephalum by plaque hybridization in combination with 5′-RACE. The assembled nucleotide sequence of Pprap1 (1062 bp) has an open reading frame coding for a protein of 188 amino acids of a calculated M_r of 21035. This protein exhibits: (i) a highly conserved GTP binding domain containing a putative effector domain, with the threonine-for-glutamine substitution characteristic of rap proteins, (ii) a hypervariable domain, and (iii) the CAAX motif. Analysis of the C-terminal amino acid sequence of Pprap1 shows that it presumably undergoes geranylgeranylation but is not palmitoylated; however, it contains a lysine-rich domain which might serve as the second membrane localization signal. Pprap1 exhibits significantly high amino acid homology within the GTP binding domain with its homologues: Ddrap1 from Dictyostelium discoideum (92%) and human Rap1A (83%), and relatively low homology (59%) with the Saccharomyces cerevisiae homologue, RSR1. It has also 59% and 61% homology with the P. polycephalum Ppras1 and Ppras2 proteins, respectively. This gene is the third member of the ras gene superfamily identified in P. polycephalum so far.     

Identification of the First Fungal Annexin: Analysis of Annexin Gene Duplications and Implications for Eukaryotic Evolution

Annexin homologues have been found in animals, plants, and distinct protist lineages. We report the identification of the first fungal annexin, encoded by the anx14 gene of the filamentous ascomycete Neurospora crassa. Annexins have a complex evolutionary history and exhibit a large number of gene duplications and gene losses in various taxa, including the complete loss of annexin sequences from another ascomycete, the budding yeast Saccharomyces cerevisiae. Surprisingly, the N. crassa annexin homologue is most closely related to the annexin homologue of the slime mold Dictyostelium discoideum, suggesting a phylogenetic link between cellular slime molds and true fungi. Both of these annexin homologues are closely related to the family of annexin homologues present in animals, an observation consistent with the existence of the animal–fungal clade. These data further suggest that the gene duplications that generated the family of annexin sequences present in animals, fungi, and slime molds began prior to the divergence of these taxa. Received: 10 December 1997 / Accepted: 17 April 1998     

SURVEY AND SUMMARY: exon-intron organization of genes in the slime mold Physarum polycephalum

The slime mold Physarum polycephalum is a morphologically simple organism with a large and complex genome. The exon–intron organization of its genes exhibits features typical for protists and fungi as well as those characteristic for the evolutionarily more advanced species. This indicates that both the taxonomic position as well as the size of the genome shape the exon–intron organization of an organism. The average gene has 3.7 introns which are on average 138 bp, with a rather narrow size distribution. Introns are enriched in AT base pairs by 13% relative to exons. The consensus sequences at exon–intron boundaries resemble those found for other species, with minor differences between short and long introns. A unique feature of P.polycephalum introns is the strong preference for pyrimidines in the coding strand throughout their length, without a particular enrichment at the 3′-ends.     

The drosophila ras oncogenes: Structure and nucleotide sequence

Three Drosophila genes homologous to the Ha-ras probe were isolated and mapped to positions 85D, 64B, and 62B on chromosome 3. Two of these genes (termed Dras1 and Dras2) were sequenced. In the case of Dras1, which contains multiple introns, a cDNA clone was isolated and sequenced. In the case of Dras2, the nucleotide sequence of the genomic clone was determined. Each gene codes for a protein with a predicted molecular weight of 21.6 kd. Alignment of the amino acid sequence of Dras1 with the vertebrate Ha-ras protein shows that at the amino terminus and central portion (residues 1–121 and 137–164) the two proteins are remarkably similar, and have an overall homology of 75%. The Dras2 gene lacks significant homology to the vertebrate counterpart at the extreme amino terminus and is homologous only between positions 28–120 and 139–161 (overall homology of 50%). This result suggests that the N terminus of p21 forms a distinct regulatory or functional domain. At the carboxy terminus, the major region of variability among the vertebrate ras proteins, the two Drosophila sequences also display considerable variability. However, both appear to be more similar to exon 4B of the Ki-ras gene.     

Novel chlorinated dibenzofurans isolated from the cellular slime mold,Polysphondylium filamentosum,and their biological activities

Cellular slime molds are expected to have the huge potential for producing secondary metabolites including polyketides, and we have studied the diversity of secondary metabolites of cellular slime molds for their potential utilization as new biological resources for natural product chemistry. From the methanol extract of fruiting bodies of Polysphondylium filamentosum, we obtained new chlorinated benzofurans Pf-1 (4) and Pf-2 (5) which display multiple biological activities; these include stalk cell differentiation-inducing activity in the well-studied cellular slime mold, Dictyostelium discoideum, and inhibitory activities on cell proliferation in mammalian cells and gene expression in Drosophila melanogaster.     

Genes in S. cerevisiae encoding proteins with domains homologous to the mammalian ras proteins

The ras genes, which were first identified by their presence in RNA tumor viruses and which belong to a highly conserved gene family in vertebrates, have two close homologs in yeast, detectable by Southern blotting. We have cloned both genes (RAS1 and RAS2) from plasmid libraries and determined the complete nucleotide sequence of their coding regions. They encode proteins with nearly 90% homology to the first 80 positions of the mammalian ras proteins, and nearly 50% homology to the next 80 amino acids. Yeast RAS1 and RAS2 proteins are more homologous to each other, with about 90% homology for the first 180 positions. After this, at nearly the same position that the mammalian ras proteins begin to diverge from each other, the two yeast ras proteins diverge radically. The yeast ras proteins, like the proteins encoded by the mammalian genes, terminate with the sequence cysAAX, where A is an aliphatic amino acid. Thus the yeast ras proteins have the same overall structure and interrelationship as the family of mammalian ras proteins. The domains of divergence may correspond to functional domains of the ras proteins. Monoclonal antibody directed against mammalian ras proteins immunoprecipitates protein in yeast cells containing high copy numbers of the yeast RAS2 gene.     

Ras p21 oncoprotein is autoregulated and acts as a potential mediator of insulin action or the H-ras1 promoter

Rat fibroblast cells carrying an exogenous normal or mutant T24 human H-ras1 gene were transfected with plasmids carrying the normal or mutant T24 H-ras1 gene promoter linked to the reporter chloramphenicol acetyl transferase (CAT) gene and the cells were treated with insulin. We found that the H-ras1 gene was positively autoregulated and that insulin potentiated the response of the T24 ras p21 to the H-ras1 gene promoter. We have also examined the effect of insulin directly on the H-ras1 promoter by treating stable transfectants obtained after transfection of rat fibroblasts with plasmids carrying the normal or mutant T24 H-ras1 gene promoter linked to the reporter CAT gene and the selectable marker aminoglycoside phosphotransferase (aph) gene. We found that insulin appeared to have no direct effect on the H-ras1 promoter in this case, suggesting that the effect is mediated through the ras p21 oncogene product. We suggest that the mutant T24 H-ras p21 protein mediates the action of insulin.     

The analysis of genomic structures in the L1 family of cell adhesion molecules provides no evidence for exon shuffling events after the separation of arthropod and chordate lineages

Members of the L1 family of neural cell adhesion molecules consist of multiple extracellular immunoglobulin and fibronectin type III domains that mediate the adhesive properties of this group of transmembrane proteins. In vertebrate genomes, these protein domains are separated by introns, and it has been suggested that L1-type genes might have been subject to exon-shuffling events during evolution. However, comparison of the human L1-CAM and the chicken neurofascin gene with the genomic structure of their Drosophila homologue, neuroglian, indicates that no major rearrangement of protein domains has taken place subsequent to the split of the arthropod and chordate phyla. The Drosophila neuroglian gene appears to have lost most of the introns that have been conserved in the human L1-CAM and the chicken neurofascin gene. Nevertheless, exon shuffling or the generation of new exons by mutational changes might have been responsible for the generation of additional, alternatively spliced exons in L1-type genes.     

Involvement of ras in sexual differentiation but not in growth control in fission yeast

The function of the ras⁺ gene of Schizosaccharomyces pombe has been studied by constructing null and activated alleles of this gene. An activated allele (^rasVal ₁₂) inhibits conjugation but has no effect on cell growth, entry into stationary phase or sporulation. The phenotype of ^rasVal ₁₂ is distinct from that caused by elevating the intracellular level of cAMP. This supports the hypothesis that ras of fission yeast does not modulate adenylate cyclase in a manner analogous to S. cerevisiae RAS. Introduction of a human ras sequence into fission yeast cells containing a non-functional null allele of ras restored the sexual differentiation process thus indicating that the human sequence can complement S. pombe ras. Our data suggest that although ras genes are highly conserved across a considerable evolutionary divide, the cellular function of the ras gene product varies in different organisms.     

Caenorhabditis elegans SUR-5, a Novel but Conserved Protein, Negatively Regulates LET-60 Ras Activity during Vulval Induction

The let-60 ras gene acts in a signal transduction pathway to control vulval differentiation in Caenorhabditis elegans. By screening suppressors of a dominant negative let-60 ras allele, we isolated three loss-of-function mutations in the sur-5 gene which appear to act as negative regulators of let-60 ras during vulval induction. sur-5 mutations do not cause an obvious mutant phenotype of their own, and they appear to specifically suppress only one of the two groups of let-60 ras dominant negative mutations, suggesting that the gene may be involved in a specific aspect of Ras activation. Consistent with its negative function, overexpressing sur-5 from an extragenic array partially suppresses the Multivulva phenotype of an activated let-60 ras mutation and causes synergistic phenotypes with a lin-45 raf mutation. We have cloned sur-5 and shown that it encodes a novel protein. We have also identified a potential mammalian SUR-5 homolog that is about 35% identical to the worm protein. SUR-5 also has some sequence similarity to acetyl coenzyme A synthetases and is predicted to contain ATP/GTP and AMP binding sites. Our results suggest that sur-5 gene function may be conserved through evolution.     

Universal intracellular transducer ras and its role in the development of drosophila

Ras genes were first identified in the 1960s as transforming oncogenes that caused tumors in rats infected with Harvey and Kirsten sarcoma viruses (Ha-ras and Ki-ras oncogenes, accordingly). Subsequently, transforming ras genes were found in human cancer cells. Further investigations of neuroblastoma cells resulted in the finding of the third ras gene in the human, which was called N-ras. Ras gene products play an important role in the processes of cellular proliferation and differentiation and are controlled by receptor tyrosine kinases. Using drosophila as a model object allowed us to perform a successful genetic analysis while studying the functions of ras genes. Three polytene chromosome bands were detected in D. melanogaster with the help of the v-Ha ras sampling. According to Bridges’ map, all three bands (Dras1, Dras2, Dras3) were mapped to regions 85D, 64B, and 62B of chromosome 3. Among them, only Dras1 has a common origin with ras genes of mammals. Although there are numerous investigations of the role played by ras genes in the development of insects, this problem is still not fully understood. The importance of ras gene variations in the course of the evolutionary process has been insufficiently studied as well. Currently, Ras target proteins are actively identified, their signal pathways, as well as effects of influencing these pathways in the drosophila tissues, are studied in the cells of yeast and mammals. The main functions of Ras protein is in the signaling pathways controlling mutations during drosophila’s morphogenesis and the connections of ras gene with phenotypic symptoms of tumors.     

Genomic structure and domain organisation of the human Bak gene

The Bcl-2 homologue, Bak, is a potent inducer of apoptosis. FISH data presented here located the gene to 6p21.3. Mapping was consistent with its location centromeric of the HSET locus and approximately 400 kb from the MHC. The construction of a contig of genomic clones across the locus facilitated the sequencing of a PAC containing the gene. Comparison of the gene structure to functional and physical domains revealed a good agreement between the physical structure and the intron–exon organisation. The position of a single intron was conserved in comparison to other members of the Bcl-2 family, namely Bax, CED-9, Bcl-X and Bcl-2, but all other introns were displaced, consistent with a divergent phylogeny.     

An intron-containing,heat-inducible stress-70 gene in the millipede Tachypodoiulus niger (Julidae,Diplopoda)

The highly conserved part of the nucleotide-binding domain of the hsp70 gene family was amplified from the soil diplopod Tachypodoiulus niger (Julidae, Diplopoda). Genomic DNA yielded 701, 549 and 540 bp sequences, whereas cDNA from heat shocked animals produced only one distinct fragment of 543 bp. The sequences could be classified as a 70 kDa heat shock protein (hsp70), the corresponding 70 kDa heat shock cognate (hsc70) and a glucose-related hsp70 homologue (grp78). Comparisons of genomic and cDNA sequences of hsc70 identified two introns within the consensus sequence. Generally, stress-70 expression levels were low, which hampered successful RT-PCR and subsequent subcloning. Following experimental heat shock, however, the spliced hsc70 was amplified predominantly, instead of its inducible homologue hsp70. This finding suggests that microevolution in this soil-dwelling arthropod is directed towards low constitutive stress-70 levels and that the capacity for stress-70 induction presumably is limited. hsc70, albeit having introns, apparently is inducible and contributes to the stress-70 response.     

CHARACTERIZATION AND MOLECULAR PHYLOGENYOF A PROTEIN KINASE cDNA FROM THE DINOFLAGELLATE GONYAULAX (DINOPHYCEAE)1

Degenerate primers corresponding to conserved protein kinase motifs were used to amplify potential kinase DNA fragments from a Gonyaulax polyedra Stein cDNA library using PCR. One PCR fragment, potentially encoding a CAMP-dependent protein kinase, was used as a probe to isolate a near full-length cDNA from the library. The nucleic acid sequence of the entire cDNA clone had a high homology to the catalytic subunit of cAMP-dependent protein kinase (cAPK subfamily and affiliated members. Northern blot analysis showed that the corresponding mRNA had a size (about 1.4 kb) and a relative high abundance consistent with a cAPK homologue. Southern blot analysis showed that while there are roughly 30 copies of the kinase gene per genome, the pattern of restriction fragments is inconsistent with the hypothesis of a large gene family. Phylogenetic analyses comparing the deduced amino acid sequence from the Gonyaulax cDNA with other cAPK sequences place Gonyaulax close to the slime mold Dictyostelium discoideum. This is the first phylogenetic analysis of dinoflagellates based on protein sequence, and the results are in agreement with similar analyses based on rRNA sequences.