Interaction between the Saccharomyces cerevisiae CDC25 gene product and mammalian ras.

In order to characterize the interaction between the Saccharomyces cerevisiae Cdc25 protein and Harvey-ras (p21H-ras), we have constructed a yeast strain disrupted at the RAS1 and RAS2 loci, expressing both p21H-ras and the catalytic domain of the bovine GTPase activating protein (GAP) and containing the cdc25-2 mutation. Such a strain exhibits a temperature-sensitive phenotype. The shift to the nonpermissive temperature is accompanied by the loss of guanyl nucleotide-dependent activity of adenylylcyclase in vitro. The temperature-sensitive phenotype can be rescued by CDC25 itself, as well as by a plasmid containing a truncated SDC25 gene. In addition, wild type CDC25 significantly improves the guanyl nucleotide response observed in the background of the cdc25ts allele at the permissive temperature in a dosage-dependent manner and restores the guanyl nucleotide response at the restrictive temperature. Both CDC25 and a truncated SDC25 also restored p21H-ras-dependent guanyl nucleotide response in a strain isogenic to the one described above but containing a disrupted CDC25 locus instead of the temperature-sensitive allele. These results suggest that the S. cerevisiae Cdc25 protein interacts with p21H-ras expressed in yeast by promoting GDP-GTP exchange. It follows that the yeast system can be used for characterizing the interaction between guanyl nucleotide exchangers of Ras proteins and mammalian p21H-ras.     

A mouse CDC25-like product enhances the formation of the active GTP complex of human ras p21 and Saccharomyces cerevisiae RAS2 proteins.

GDP-dissociation stimulators (GDSs) are the key element for the regeneration of the active state of ras proteins, but despite intensive investigations, little is so far known about their functional and structural properties, particularly in mammals. A growing number of genes from various organisms have been postulated to encode GDSs on the basis of sequence similarity with the Saccharomyces cerevisiae CDC25 gene, whose product acts as a GDS of RAS proteins. However, except for CDC25 and the related SDC25 C-domain, no biochemical evidence of ras GDS activity for these CDC25-like proteins has yet been available. We show that the product of a recently isolated mouse CDC25-like gene (CDC25Mm) can strongly enhance (more than 1000 times) the GDP release from both human c-Ha-ras p21 and yeast RAS2 in vitro. As a consequence, the CDC25Mm induces a rapid formation of the biologically active Ras.GTP complex. This GDS is much more active on the GDP than on the GTP complex and has a narrow substrate specificity, since it was found to be inactive on several ras-like proteins. The mouse GDS can efficiently substitute for yeast CDC25 in an in vitro adenylylcyclase assay on RAS2 cdc25 yeast membranes. Our results show that a cloned GDP to GTP exchange factor of mammalian ras belongs to the novel family of CDC25-like proteins.     

The GAP-related domain of the neurofibromatosis type 1 gene product interacts with ras p21

The neurofibromatosis type 1 (NF1) protein contains a region of significant sequence similarity to ras p21 GTPase-activating protein (GAP) and the yeast IRA1 gene product. A fragment of NF1 cDNA encoding the GAP-related domain (NF1 GRD) was expressed, immunoaffinity purified, and assayed for effects on N-ras p21 GTPase activity. The GTPase of wild-type ras p21 was stimulated by NF1 GRD, but oncogenic mutants of ras p21 (Asp-12 and Val-12) were unaffected, and the GTPase of an effector mutant (Ala-38) was only weakly stimulated. NF1 GRD also down-regulated RAS function in S. cerevisiae. The affinity of NF1 GRD for ras p21 was estimated to be 250 nM: this is more than 20-fold higher than the affinity of GAP for ras p21. However, its specific activity was about 30 times lower. These kinetic measurements suggest that NF1 may be a significant regulator of ras p21 activity, particularly at low ras p21 concentrations.     

On the mechanism of guanosine triphosphate hydrolysis in ras p21 proteins.

The residue Gln61 is assumed to play a major role in the mechanism of ras p21, and mutations of this residue are often found in human tumors. Such mutations lead to a major reduction in the rate of GTP hydrolysis by the complex of ras p21 and the GTPase activating protein (GAP) and lock the protein in a growth-promoting state. This work examines the role of Gln61 in ras p21 by using computer simulation approaches to correlate the structure and energetics of this system. Free energy perturbation calculations and simpler electrostatic considerations demonstrate that Gln61 is unlikely to serve as the general base in the intrinsic GAP-independent reaction of p21. Glutamine is already a very weak base in water, and surprisingly the GlnH+ OH-reaction intermediate is even less stable in the protein active site than in the corresponding reaction in water. The electrostatic field of Glu63, which could in principle stabilize the protonated Gln61, is found to be largely shielded by the surrounding solvent. However, it is still possible that Gln61 is a general base in the GAP/ras p21 complex since this system could enhance the electrostatic effect of Glu63. It is also possible that the gamma-phosphate acts as general base and that Gln61 accelerates the reaction by stabilizing the OH- nucleophile. If such a mechanism is operative, then GAP may enhance the effect of Gln61 by preorienting its hydrogen bonds in the transition-state configuration.     

Regulation of nuclear genes encoding mitochondrial proteins in Saccharomyces cerevisiae.

Selection for mutants which release glucose repression of the CYB2 gene was used to identify genes which regulate repression of mitochondrial biogenesis. We have identified two of these as the previously described GRR1/CAT80 and ROX3 genes. Mutations in these genes not only release glucose repression of CYB2 but also generally release respiration of the mutants from glucose repression. In addition, both mutants are partially defective in CYB2 expression when grown on nonfermentable carbon sources, indicating a positive regulatory role as well. ROX3 was cloned by complementation of a glucose-inducible flocculating phenotype of an amber mutant and has been mapped as a new leftmost marker on chromosome 2. The ROX3 mutant has only a modest defect in glucose repression of GAL1 but is substantially compromised in galactose induction of GAL1 expression. This mutant also has increased SUC2 expression on nonrepressing carbon sources. We have also characterized the regulation of CYB2 in strains carrying null mutation in two other glucose repression genes, HXK2 and SSN6, and show that HXK2 is a negative regulator of CYB2, whereas SSN6 appears to be a positive effector of CYB2 expression.     

Interaction of ras oncogene product p21 with guanine nucleotides

The nucleotide exchange reaction was observed with purified ras oncogene product p21 overproduced in Escherichia coli (Hattori, S. et al. (1985) Mol. Cell Biol. 5, 1449-1455) under various conditions. (NH4)2SO4 increased the rate of dissociation of bound GDP from c-rasH and v-rasH p21. The dissociation kinetics were those of a first order reaction, and there was a linear relationship between the rate constant and the (NH4)2SO4 concentration. At any concentration of (NH4)2SO4, the exchange rate was faster with v-rasH p21 than that with c-rasH p21. EDTA and (NH4)2SO4 synergetically stimulated the dissociation reaction. Nucleotide-free p21 was prepared by gel filtration on Sephadex G-25 in the presence of 5 mM EDTA and 200 mM (NH4)2SO4 at room temperature. The free p21 was quite thermolabile, but the addition of GDP or GTP completely protected p21 from thermal inactivation. The dissociation constants for GDP and GTP were determined with free p21 to be 8.9 and 8.2 nM, respectively, for v-rasH p21, and 1.0 and 2.6 nM for c-rasH p21. In the presence of 200 mM (NH4)2SO4, these dissociation constants increased 3- to 12-fold.     

DNA binding properties of the Saccharomyces cerevisiae DAT1 gene product.

The DAT1 gene of Saccharomyces cerevisiae encodes a DNA binding protein (Dat1p) that specifically recognizes the minor groove of non-alternating oligo(A).oligo(T) tracts. Sequence-specific recognition requires arginine residues found within three perfectly repeated pentads (G-R-K-P-G) of the Dat1p DNA binding domain [Reardon, B. J., Winters, R. S., Gordon, D., and Winter, E. (1993) Proc. Natl. Acad. Sci. USA 90, 11327-1131]. This report describes a rapid and simple method for purifying the Dat1p DNA binding domain and the biochemical characterization of its interaction with oligo(A).oligo(T) tracts. Oligonucleotide binding experiments and the characterization of yeast genomic Dat1p binding sites show that Dat1p specifically binds to any 11 base sequence in which 10 bases conform to an oligo(A).oligo(T) tract. Binding studies of different sized Dat1p derivatives show that the Dat1p DNA binding domain can function as a monomer. Competition DNA binding assays using poly(I).poly(C), demonstrate that the minor groove oligo(A).oligo(T) constituents are not sufficient for high specificity DNA binding. These data constrain the possible models for Dat1p/oligo(A).oligo(T) complexes, suggest that the DNA binding domain is in an extended structure when complexed to its cognate DNA, and show that Dat1p binding sites are more prevalent than previously thought.     

Detection of the intracellular ras p21 oncogene product by flow cytometry

Rapid identification of the expression of oncogene products in specific cell types could potentially be useful in the diagnosis and treatment of human malignancy. We have now observed that through the use of lysolecithin permeabilization and fluorescence-activated flow cytometry, cells expressing high levels of the v-Ha-ras oncogene product, p21, can readily be distinguished from the nontransformed parent cells in a rapid and quantitative manner.     

Disruption of single-copy genes encoding acidic ribosomal proteins in Saccharomyces cerevisiae.

Using the cloned genes coding for the ribosomal acidic proteins L44 and L45, constructions were made which deleted part of the coding sequence and inserted a DNA fragment at that site carrying either the URA3 or HIS3 gene. By gene disruption techniques with linearized DNA from these constructions, strains of Saccharomyces cerevisiae were obtained which lacked a functional gene for either protein L44 or protein L45. The disrupted genes in the transformants were characterized by Southern blots. The absence of the proteins was verified by electrofocusing and immunological techniques, but a compensating increase of the other acidic ribosomal proteins was not detected. The mutant lacking L44 grew at a rate identical to the parental strain in complex as well as in minimal medium. The L45-disrupted strain also grew well in both media but at a slower rate than the parental culture. A diploid strain was obtained by crossing both transformants, and by tetrad analysis it was shown that the double transformant lacking both genes is not viable. These results indicated that proteins L44 and L45 are independently dispensable for cell growth and that the ribosome is functional in the absence of either of them.     

Cloning of genes related to exo-beta-glucanase production in Saccharomyces cerevisiae: characterization of an exo-beta-glucanase structural gene

The EXG1 gene of Saccharomyces cerevisiae was cloned and identified by complementation of a mutant strain (exg1-2) with highly reduced extracellular exo-beta-1,3-glucanase (EXG) activity. Two recombinant plasmids containing an overlapping region of 5.2 kb were isolated from a genomic DNA library and characterized by restriction mapping. The coding region was located by subcloning the original DNA inserts in a 2.7-kb HindIII-XhoI fragment. Exg+ strains and Exg- mutants transformed with yeast multicopy plasmids containing this DNA fragment showed an EXG activity 5- to 20-fold higher than for the untransformed Exg+ wild-type (wt) strains. The overproduced EXG had the same enzymic activity on different substrates, and showed the same electrophoretic behaviour on polyacrylamide gels and identical properties upon filtration through Sephacryl S-200 as those of the main EXG from Exg+ wt strains. The EXG1 gene transformed Schizosaccharomyces pombe, yielding extracellular EXG activity which showed cross-reactivity with anti-S. cervisiae EXG antibodies. A fragment including only a part of the EXG1 region was subcloned into the integrating vector YIp5, and the resulting plasmid was used to transform an Exg+ strain. Genetic and Southern analysis of several stable Exg- transformants showed that the fragment integrated by homology with the EXG1 locus. The chromosomal DNA fragment into which the plasmid integrated has a restriction pattern identical to that of the fragment on which we had previously identified the putative EXG1 gene. Only one copy of the EXG1 gene per genome was found in several strains tested by Southern analysis. Furthermore, two additional recombinant plasmids sharing a yeast DNA fragment of about 4.1 kb, which partially complements the exg1-2 mutation but which shows no homology with the 2.7-kb fragment containing the EXG1 gene, were also identified in this study. This 4.1-kb DNA fragment does not appear to contain an extragenic suppressor and could be related in some way to EXG production in S. cerevisiae.     

Regulation of p21ras by GTPase activating proteins and guanine nucleotide exchange proteins.

Ras proteins play a critical role in controlling normal cellular growth and, when activated by mutation, in causing malignant transformation. Regulation of p21ras is achieved by GTPase activating proteins, which control the rate of hydrolysis of GTP to GDP, and also by GDP dissociation stimulators, which catalyze the exchange of guanine nucleotides. Several such proteins have now been identified and their control mechanisms characterized.     

Comparative biochemical properties of p21 ras molecules coded for by viral and cellular ras genes.

In earlier studies, we molecularly cloned a normal cellular gene, c-rasH-1, homologous to the v-ras oncogene of Harvey murine sarcoma virus (v-rasH). By ligating a type c retroviral promotor to c-rasH-1, we could transform NIH 3T3 cells with the c-rasH-1 gene. The transformed cells contained high levels of a p21 protein coded for by the c-rasH-1 gene. In the current studies, we have purified extensively both v-rasH p21 and c-rasH p21 and compared the in vivo and in vitro biochemical properties of both these p21 molecules. The p21 proteins coded for by v-rasH and c-rasH-1 shared certain properties: each protein was synthesized as a precursor protein which subsequently became bound to the inner surface of the plasma membrane; each protein was associated with guanine nucleotide-binding activity, a property which copurified with p21 molecules on a high-pressure liquid chromatography molecular sizing column. In some other properties, the v-rasH and c-rasH p21 proteins differed. In vivo, approximately 20 to 30% of v-rasH p21 molecules were in the form of phosphothreonine-containing pp21 molecules, whereas in vivo only a minute fraction of c-rasH-1 p21 contained phosphate, and this phosphate was found on a serine residue. v-rasH pp21 molecules with an authentic phosphothreonine peptide could be synthesized in vitro in an autophosphorylation reaction in which the gamma phosphate of GTP was transferred to v-rasH p21. No autophosphorylating activity was associated with purified c-rasH-1 p21 in vitro. The results indicate a major qualitative difference between the p21 proteins coded for by v-rasH and c-rasH-1. The p21 coded for by a mouse-derived oncogenic virus, BALB murine sarcoma virus, resembled the p21 coded for by c-rasH-1 in that it bound guanine nucleotides but did not label appreciably with 32Pi. The forms of p21 coded for by other members of the ras gene family were compared, and the results indicate that the guanine nucleotide-binding activity is common to p21 molecules coded for by all known members of the ras gene family.     

Interaction of the human insulin receptor with the ras oncogene product p21

Autophosphorylation of the purified human insulin receptor tyrosyl kinase was found to be inhibited by the ras oncogene product p21 in a concentration- and GDP-dependent manner. GDP-β-S but not Gpp(NH)p could substitute for GDP in eliciting the ras-dependent inhibition. The inhibition was seen with both normal or mutant (Lys-61) p21^N-ras and normal or mutant (Val-12) p21^Ha-ras. Inhibition occurred at 23°C but not 4°C and was unaffected by the presence or absence of insulin although insulin stimulated the autophosphorylation rate of the receptor β-subunit some 2-fold. The insulin receptor did not phosphorylate native p21^Ha-ras in the presence or absence of added guanine nucleotide. After denaturation of p21^Ha-ras with urea it became a substrate, but then failed to inhibit receptor autophosphorylation even in the presence of added GDP.     

Regulation of p21ras activity.

The ras genes encode GTP/GDP-binding proteins that participate in mediating mitogenic signals from membrane tyrosine kinases to downstream targets. The activity of p21ras is determined by the concentration of GTP-p21ras, which is tightly regulated by a complex array of positive and negative control mechanisms. GAP and NF1 can negatively regulate p21ras activity by stimulating hydrolysis of GTP bound to p21ras. Other cellular factors can positively regulate p21ras by stimulating GDP/GTP exchange.