Characterization of functional domains of p21 ras by use of chimeric genes

Dominant effects of the bcr-abl oncogene on Drosophila morphogenesis

We targeted expression of human/fly chimeric Bcr-Abl proteins to the developing central nervous system (CNS) and eye imaginal disc of Drosophila melanogaster. Neural expression of human/fly chimeric P210 Bcr-Abl or P185 Bcr-Abl rescued abl mutant flies from pupal lethality, indicating that P210 and P185 Bcr-Abl can substitute functionally for Drosophila Abl during axonogenesis. However, increased levels of neurally expressed P210 or P185 Bcr-Abl but not Drosophila Abl produced CNS defects and lethality. Expression of P210 or P185 in the eye imaginal disc produced a dominant rough eye phenotype that was dependent on dosage of the transgene. Drosophila Enabled, previously identified as a suppressor of the abl mutant phenotype and substrate for Drosophila Abl kinase, had markedly increased phosphotyrosine levels in Bcr-Abl expressing Drosophila, indicating that it is a substrate for Bcr-Abl as well. Drosophila, therefore, is a suitable model system to identify Bcr-Abl interactions important for signal transduction and oncogenesis.

Mutational analysis of the role of Rap1 in regulating cytoskeletal function in Dictyostelium

It was shown previously that increased expression of the ras-related rap1 gene in Dictyostelium discoideum altered cell morphology (Rebstein et al., Dev. Genet., 1993, 14, 347-355). Vegetative Rap1 transformants were more flattened and spread than parental Ax2 cells and had increased F-actin near the cell periphery. In addition, Rap1 cells were inhibited in the rapid cell contraction that occurs upon refeeding with nutrient media. In this communication, we show that expression of Rap also markedly reduces the contraction response that occurs upon addition of azide to vegetative cells. The changes in cell morphology, the refeeding contraction response, and the azide contraction response have been used to analyze mutants of Rap1 generated by site-directed mutagenesis. The substitution G12V, predicted to increase the proportion of protein binding GTP, did not alter the effect of Rap on cell morphology or on its ability to inhibit the contraction response to azide, but modestly enhanced the ability of Rap1 to inhibit cell rounding in response to nutrient media. The substitution S17N, predicted to restrict the protein to the GDP-bound state, did not produce the flattened cell morphology and abolished the inhibitory effects of Rap in the two cell contraction assays. These results are consistent with a requirement of GTP binding for the Rap-induced effects. Transformants carrying the Rap-S17N protein had a more polar morphology than the parental Ax2 cells, suggesting the possibility that Rap-S17N interferes with the ability of endogenous Rap to regulate the cytoskeleton. Substitutions at amino acid 38, within the presumptive effector domain, reduced but did not abolish the effects of Rap1 on cell contraction, while the substitution T61Q had no effect on Rap1 activity. Taken together, the results suggest that Rap may have multiple regulatory effects on cytoskeletal function.

Biological activity of a K-ras mutant that contains the 12R/59T/116Y mutations

The 12R/59T/116Y mutations have been shown to confer a dominant negative activity on H-ras oncogene (H-ras 116Y). To determine whether this event is unique for H-ras, we introduced the same mutations into K-ras oncogene. This mutant, K-ras 116Y, suppressed transformed phenotypes induced by overexpression of H-ras proto-oncogene. NIH3T3 cells expressing K-ras 116Y were resistant to transformation by v-fes oncogene. Analysis of chimaeras between H- and K-ras 116Y showed that the C-terminal variable region determines the level of suppressor activity. These results suggest that these mutations are applicable to other GDP/GTP binding proteins.

Altered morphology of vegetative amoebae induced by increased expression of the Dictyostelium discoideum ras-related gene rap1

The rap1 gene of Dictyostelium discoideum is a member of the ras-gene superfamily of low molecular weight GTPase proteins. The rap1 gene is expressed both during growth and development in D. discoideum. To examine the action of the Rap1 protein in D. discoideum, the rap1 cDNA was expressed under the control of the inducible discoidin promoter. Treatment with conditioned media, which induces the discoidin promoter, increased Rap1 protein levels in vegetative cells approximately six fold. Overexpression of the Rap1 protein correlated with the appearance of morphologically aberrant vegetative amoebae: cells were extensively spread and flattened. The distribution of F-actin was altered in these cells, with an increase in actin staining around the cell periphery. Induction of the discoidin promoter by starvation in the rap1 transformants also resulted in spread flat cells. When starved D. discoideum amoebae are refed with HL5 media, the cells rapidly respond by rounding up. By contrast, the rap1 transformant cells showed a pronounced delay in rounding up. Rapid tyrosine phosphorylation of a p45 protein occurred in both control cells and the rap1 transformant upon refeeding, implying that the signal transduction pathway leading to tyrosine phosphorylation remained functional in the rap1 transformant. We propose that the Rap1 protein functions in the regulation of cell morphology in D. discoideum.

Expression of c-Ki-ras in developing rat liver

1. Two major c-Ki-ras transcripts are present in rat liver throughout development. 2. Both transcripts are functional, i.e. translatable into ras protein. 3. They exhibit low levels in early foetuses and increase gradually towards term. 4. Peak levels of transcripts are detected on the fourth day of postnatal life. 5. Results from nuclear run-off assays demonstrate that the rise in level of transcripts is a result of increase in rate of transcription with the highest rate detected on the fourth day of postnatal life. 6. Western blot analysis reveals that the accumulation of c-Ki-ras protein clearly follows the pattern of changes in transcription of c-Ki-ras gene.

The Drosophila roughened mutation: activation of a rap homolog disrupts eye development and interferes with cell determination

Roughened is a dominant mutation of D. melanogaster that disrupts eye development. The majority of the ommatidia in the adult eye lack a single photoreceptor cell, which is most commonly the R7 cell. The Roughened mutation disrupts the early stages of photoreceptor cell determination. Roughened is a dominant gain-of-function mutation that results from a single amino acid change (Phe157 to Leu) in the Drosophila Rap1 protein. Loss of function Rap1 mutations are lethal. Drosophila Rap1 protein is 88% identical to human rap1A/K-rev1 protein, a putative antagonist of ras action.

Relationship among methylation, isoprenylation, and GTP binding in 21- to 23-kDa proteins of neuroblastoma

1. Dimethylsulfoxide-induced differentiated neuroblastoma express high levels of membrane 21 to 23-kDa carboxyl methylated proteins. Relationships among methylation, isoprenylation, and GTP binding in these proteins were investigated. Protein carboxyl methylation, protein isoprenylation, and [alpha-32P]GTP binding were determined in the electrophoretically separated proteins of cells labeled with the methylation precursor [methyl-3H]methionine or with an isoprenoid precursor [3H]mevalonate. 2. A broad band of GTP-binding proteins, which overlaps with the methylated 21 to 23-kDa proteins, was detected in [alpha-32P]GTP blot overlay assays. This band of proteins was separated in two-dimensional gels into nine methylated proteins, of which four bound GTP. 3. The carboxyl-methylated 21 to 23-kDa proteins incorporated [3H]mevalonate metabolites with characteristics of protein isoprenylation. The label was not removed by organic solvents or destroyed by hydroxylamine. Incorporation of radioactivity from [3H]mevalonate was enhanced when endogenous levels of mevalonate were reduced by lovastatin, an inhibitor of mevalonate synthesis. Lovastatin blocked methylation of the 21 to 23-kDa proteins as well (greater than 70%). 4. Methylthioadenosine, a methylation inhibitor, inhibited methylation of these proteins (greater than 80%) but did not affect their labeling by [3H]mevalonate. The results suggest that methylation of the 21 to 23-kDa proteins depends on, and is subsequent to, isoprenylation. The sequence of events may be similar to that known in ras proteins, i.e., carboxyl methylation of a C-terminal cysteine that is isoprenylated. 5. Lovastatin reduced the level of small GTP-binding proteins in the membranes and increased GTP binding in the cytosol. Methylthioadensoine blocked methylation without affecting GTP binding. 6. Thus, isoprenylation appears to precede methylation and to be important for membrane association, while methylation is not required for GTP binding or membrane association. The role of methylation remains to be determined but might be related to specific interactions of the small GTP-binding proteins with other proteins.

Evolutionary grouping of the RAS-protein family

Over 50 proteins related to the mammalian H-, K-, and N-RAS GTP binding and hydrolyzing proteins are known. These relatively low molecular weight proteins are usually grouped into four subfamilies, termed true RAS, RAS-like, RHO, and RAB/YPT, based on the presence of shared amino acid sequence motifs in addition to those involved in guanine nucleotide binding. Here, we apply parsimony analysis to the overall amino acid sequences of these proteins to infer possible phylogenetic relationships among them.

The GTPase superfamily: conserved structure and molecular mechanism

GTPases are conserved molecular switches, built according to a common structural design. Rapidly accruing knowledge of individual GTPases--crystal structures, biochemical properties, or results of molecular genetic experiments--support and generate hypotheses relating structure to function in other members of the diverse family of GTPases.

Regulation of Ki-ras expression in Reuber H35 cells

Glucagon at a low concentration has a stimulatory effect on Ki-ras expression, whereas, at high concentrations the hormone suppresses the level of the Ki-ras transcripts. Incubation of the hepatoma cells with 10 microM dibutyryl cyclic AMP results in suppression of Ki-ras expression but the phorbol ester, 21-O-tetradecanoylphorbol 13-acetate (TPA) causes an increase. Down regulation of protein kinase C by prolonged exposure of hepatoma cells to TPA causes a dramatic decrease in the glucagon-stimulated effect on Ki-ras expression. The presence of diacylglycerol for 2 h in the culture medium results in a significant increase in Ki-ras expression, while treatment of the cells with 1-(5-isoquinolinylsulphonyl)-2-methylpiperazine, a potent inhibitor of protein kinase C, leads to a dramatic reduction. The calcium ionophore, A23187 is able to stimulate Ki-ras expression, whereas, addition of verapamil or EGTA results in its suppression. The present findings suggest that the inductive effect of glucagon on Ki-ras expression at low concentrations is via the activation of protein kinase C which causes phosphorylation of some regulatory proteins that may eventually affect the level of Ki-ras mRNA. The suppressive effect of glucagon at higher concentrations is via an increase in cAMP through activation of adenylate cyclase.

Neurospora crassa cDNA clones coding for a new member of the ras protein family

A new member of the ras gene family was characterized from Neurospora crassa cDNA libraries. The clone designated NC-ras codes for a polypeptide containing 213 amino acids (Mr 24,000). This polypeptide is 84% homologous to the H-ras-1 domain comprising the first 80 amino acids and 60% homologous to the next 84 residues. The NC-ras polypeptide contains all the well-known sequences involved in the interaction with GTP/GDP, the recognition of the Y13-259 neutralizing antibody, the 'effector site' for interaction with GAP proteins, and the CAAX acylation motif in the COOH-terminal.

A domain responsible for the transformation suppressor activity in Krev-1 protein

Krev-1 cDNA encodes a ras-related protein and exhibits an activity of inducing flat revertants at certain frequencies (2-5% of total transfectants) when introduced into a v-K-ras-transformed mouse NIH3T3 cell line, DT. To explore the functional organization of Krev-1 protein, we constructed a series of chimeric genes consisting of fragments of H-ras and Krev-1 cDNAs, and tested their biological activities in DT cells. The results indicated that the determinant for the transformation suppressor activity resides in the N-terminal one-third of the Krev-1 encoded polypeptide within which a highly conserved, putative effector-binding domain is present.

The ras-related mouse ypt1 protein can functionally replace the YPT1 gene product in yeast

The protein-coding region of the essential Saccharomyces cerevisiae YPT1 gene coding for a ras-related, guanine-nucleotide-binding protein was exchanged in chromosome VI by the protein-coding segment of either the mouse ypt1 gene or the v-Ki-ras gene, and different chimeric YPT1-v-Ki-ras genes. The mouse ypt1 protein with 71% of identical residues compared with the yeast Ypt1 protein could functionally fully replace its yeast homologue as long as the mouse gene was overexpressed under transcriptional control of the inducible GAL10 promoter. In contrast, neither the viral Ki-ras nor the hybrid proteins were able to substitute for the loss of YPT1 gene function. This study suggests that different parts of the yeast Ypt1 protein are required for the interaction with cellular targets and that these essential parts are conserved in the mammalian ypt1 protein.

The ras superfamily proteins

Several recent discoveries indicate that the ras genes, frequently activated to a transforming potential in some human tumours, belong to a large family that can be divided into three main branches: the first branch represented by the ras, ral and rap genes; the second branch, by the rho genes; and the third branch, by the rab genes. The C-terminal end of the encoded proteins always includes a cystein, which may become fatty-acylated, suggesting a sub-membrane localization. The ras superfamily proteins share four regions of high homology corresponding to the GTP binding site; however, even in these regions, significant differences are found, suggesting that the various proteins may possess slightly different biochemical properties. Recent reports show that some of these proteins play an essential role in the control of physical processes such as cell motility, membrane ruffling, endocytosis and exocytosis. Nevertheless, the characterization of the proteins directly interacting with the ras or ras-related gene-products will be required to precisely understand their function.

Posttranslational modification of ras proteins: detection of a modification prior to fatty acid acylation and cloning of a gene responsible for the modification

Products of ras genes are synthesized as precursors in the cytosol and transported to the plasma membrane by a process which involves posttraslational modification by fatty acid. In this paper, we present evidence for the occurrence in the cytosol of an intermediate modification of ras proteins prior to the fatty acid acylation. The modification is detected by a slight shift in the mobility of the protein on SDS polyacrylamide gel. The fatty acid acylation does not contribute to this mobility shift. This modification is affected by the dprl mutation which has recently been shown to affect the processing of yeast RAS proteins. To further characterize the nature of the modification event, we have cloned DPR1 gene from the DNA of Saccharomyces cerevisiae. The gene is actively transcribed in yeast cells producing mRNA of approximately 1.6 kb. Genes related to the DRP1 appear to be present in a distantly related yeast, Schizosaccharomyces pombe as well as in guinea pig and human cells.

The Drosophila Abelson proto-oncogene homolog: identification of mutant alleles that have pleiotropic effects late in development

The Abelson gene in Drosophila (abl) consists of ten exons extending over 26 kb of genomic DNA. The DNA sequence encodes a protein of 1520 amino acids with sequence homology to the human c-abl proto-oncogene product, beginning at the amino terminus and extending 656 amino acids through the region essential for tyrosine kinase activity. Mutant lesions in the abl gene were identified first by their failure to complement chromosomal deletions that overlap the abl DNA sequence and then by rescue of the mutant phenotypes with an abl minigene in transgenic flies. Elimination of abl zygotic function by mutations produces some recessive lethality at the pharate adult pupal stage, and mutant adults with reduced longevity, reduced fecundity, and an irregular pattern of retinal cells.

Structure of the human and murine R-ras genes, novel genes closely related to ras proto-oncogenes

The human R-ras gene was isolated by low-stringency hybridization with a v-H-ras probe. The predicted 218 amino acid R-ras protein has an amino-terminal extension of 26 residues compared with H-ras p21, and shows 55% amino acid identity; conserved domains include the p21 GTP-binding site and the carboxy-terminal membrane localization sequence. R-ras has at least six exons, with the position of the first intron conserved relative to the Drosophila ras64B and Dictyostelium ras genes; there is no similarity in the exon-intron structure of the R-ras gene and of the mammalian H-, K-, and N-ras proto-oncogenes. Cloned mouse R-ras cDNAs exhibit 88% nucleotide and 94.5% predicted amino acid identity to human R-ras. Human R-ras was localized to chromosome 19, a site different from ras p21 genes. Mouse R-ras is syntenic with c-H-ras on chromosome 7.

Sequence and genomic structure of ras homologues Dmras85D and Dmras64B of Drosophila melanogaster

The ras homologues of Drosophila melanogaster located at 85D and 64B on the polytene chromosome map were cloned using the Ha-ras gene of Harvey murine sarcoma virus as a probe. The genomic sequences of Dmras85D and Dmras64B were determined and shown to differ from previously published sequences. Dmras85D is much more similar to the Ha-ras, Ki-ras, and N-ras genes than it is to either the Dmras64B gene or to the ras genes of Saccharomyces cerevisiae. Comparison of the Dmras85D genomic sequences with the previously published nucleotide sequence (Neuman-Silberberg et al., Cell 37 (1984) 1027-1033) shows that the positions of the two introns are not conserved relative to the positions of the introns in Dmras64B or in vertebrate ras genes. The Dmras64B and Dmras85D transcripts were analyzed by blot hybridization and shown to be dissimilar. The data suggest that the divergence of the Dmras genes was ancient, and that Dmras85D and Dmras64B have different functions.

RAM, a gene of yeast required for a functional modification of RAS proteins and for production of mating pheromone a-factor

We have identified a gene (SUPH) of S. cerevisiae that is required for both RAS function and mating by cells of a mating type. supH is allelic to ste16, a gene required for the production of the mating pheromone a-factor. Both RAS and a-factor coding sequences terminate with the potential acyltransferase recognition sequence Cys-A-A-X, where A is an aliphatic amino acid. Mutations in SUPH-STE16 prevent the membrane localization and maturation of RAS protein, as well as the fatty acid acylation of it and other membrane proteins. We propose the designation RAM (RAS protein and a-factor maturation function) for SUPH and STE16. RAM may encode an enzyme responsible for the modification and membrane localization of proteins with this C-terminal sequence.

Molecular cloning of the temperature-sensitive 371 Kirsten murine sarcoma virus and expression in Escherichia coli of the mutant and wild-type viral Kirsten ras p21 proteins

Rodent fibroblasts infected with the ts371 Kirsten murine sarcoma virus (KiMuSV) are temperature sensitive for the maintenance of transformation because of the production of an abnormal p21 protein. We cloned the ts371 KiMuSV provirus from the genome of a conditionally transformed nonproducer cell line, ts371 KiMuSV NRK clone 5 (T. Y. Shih, M. O. Weeks, H. A. Young, and E. M. Scolnick, J. Virol. 31:546-556, 1979). The molecularly cloned virus had 1,000-fold lower transformed focus-forming activity at 39 degrees C than at 34 degrees C. The ts371-v-Ki-ras gene differed from the wild type (wt) by a single point mutation, resulting in the substitution of arginine for glutamine at amino acid residue 43 of the encoded p21. A second difference from the published sequence for wt v-Ki-ras (N. Tsuchida, T. Ryder, and E. Ohtsubo, Science 217:937-939, 1982) at amino acid residue 37 was found. However, on sequencing the wt v-Ki-ras in this region, we found that it also contained a glutamate at residue 37. Preliminary characterization of bacterially expressed wt and ts371-v-Ki-ras p21 proteins is discussed.

A new cell division operon in Escherichia coli

At 76 min on the E. coli genetic map there is a cluster of genes affecting essential cellular functions, including the heat shock response and cell division. A combination of in-vivo and in-vitro genetic analysis of cell division mutants suggests that the cell division gene fts E is the second gene in a 3 gene operon. A cold-sensitive mutant, defective in the third gene, is also unable to divide at the restrictive temperature, and we designate this new cell division gene fts X. Another cell division gene, fts S, is very close to, but distinct from, the 3 genes of the operon. The fts E product is a 24.5 Kd polypeptide which shows strong homology with a small group of proteins involved in transport. Both the fts E product and the protein coded by the first gene (fts Y) in the operon have a sequence motif found in a wide range of heterogeneous proteins, including the Ras proteins of yeast. This common domain is indicative of a nucleotide-binding site.

The Drosophila EGF receptor gene homolog: conservation of both hormone binding and kinase domains

Chicken v-erB probe was used to isolate a unique clone of Drosophila melanogaster DNA. It maps by in situ hybridization to position 57F on chromosome 2. A complete nucleotide sequence of the coding region has been obtained. The putative Drosophila EGF receptor protein is similar in overall organization to the human homolog. It shows three distinct domains: an extracellular putative EGF binding domain, a hydrophobic transmembrane region, and a cytoplasmic kinase domain. The overall amino acid homology is 41% in the extracellular domain and 55% in the kinase domain. Two cysteine-rich regions, a hallmark of the human ligand-binding domain, have also been conserved. Fusion of the coding sequences of the kinase and extracellular domains generating the receptor gene must have occurred over 800 million years ago.