Anti-Cdc25 antibodies inhibit guanyl nucleotide-dependent adenylyl cyclase of Saccharomyces cerevisiae and cross-react with a 150-kilodalton mammalian protein.

The CDC25 gene product of the yeast Saccharomyces cerevisiae has been shown to be a positive regulator of the Ras protein. The high degree of homology between yeast RAS and the mammalian proto-oncogene ras suggests a possible resemblance between the mammalian regulator of Ras and the regulator of the yeast Ras (Cdc25). On the basis of this assumption, we have raised antibodies against the conserved C-terminal domain of the Cdc25 protein in order to identify its mammalian homologs. Anti-Cdc25 antibodies raised against a beta-galactosidase-Cdc25 fusion protein were purified by immunoaffinity chromatography and were shown by immunoblotting to specifically recognize the Cdc25 portion of the antigen and a truncated Cdc25 protein, also expressed in bacteria. These antibodies were shown both by immunoblotting and by immunoprecipitation to recognize the CDC25 gene product in wild-type strains and in strains overexpressing Cdc25. The anti-Cdc25 antibodies potently inhibited the guanyl nucleotide-dependent and, approximately 3-fold less potently, the Mn(2+)-dependent adenylyl cyclase activity in S. cerevisiae. The anti-Cdc25 antibodies do not inhibit cyclase activity in a strain harboring RAS2Val-19 and lacking the CDC25 gene product. These results support the view that Cdc25, Ras2, and Cdc35/Cyr1 proteins are associated in a complex. Using these antibodies, we were able to define the conditions to completely solubilize the Cdc25 protein. The results suggest that the Cdc25 protein is tightly associated with the membrane but is not an intrinsic membrane protein, since only EDTA at pH 12 can solubilize the protein. The anti-Cdc25 antibodies strongly cross-reacted with the C-terminal domain of the Cdc25 yeast homolog, Sdc25. Most interestingly, these antibodies also cross-reacted with mammalian proteins of approximately 150 kDa from various tissues of several species of animals. These interactions were specifically blocked by the beta-galactosidase-Cdc25 fusion protein.     

The activation of adenylate cyclase by guanyl nucleotides in Saccharomyces cerevisiae is controlled by the CDC25 start gene product.

In the thermosensitive cdc25 start mutant of Saccharomyces cerevisiae, the regulation of adenylate cyclase by guanyl nucleotides was rapidly nullified when the enzyme was prepared from nonsynchronized cells shifted to the restrictive temperature. In agreement with previous in vivo complementation studies, this biochemical defect was fully suppressed by the expression of either the whole cloned CDC25 gene or its C-terminal portion. Moreover, membranes prepared from cdc25(Ts) cells grown at the permissive temperature evinced an altered regulation of adenylate cyclase by guanyl nucleotides. These results indicate that the CDC25 protein, together with RAS, is involved in the regulation of adenylate cyclase by guanyl nucleotides and raise the possibility that adenylate cyclase might form a ternary complex with RAS and CDC25.     

SDC25, a CDC25-like gene which contains a RAS-activating domain and is a dispensable gene of Saccharomyces cerevisiae.

In the yeast Saccharomyces cerevisiae, the CDC25 gene product activates adenylate cyclase through RAS1 and RAS2 gene products. We have recently described the cloning of a DNA fragment which suppresses the cdc25 mutation but not ras1, ras2, or cdc35 mutations. This fragment contains a 5'-truncated open reading frame which shares 47% identity with the C-terminal part of the CDC25 gene. We named the entire gene SDC25. In this paper, we report the cloning, sequencing, and characterization of the complete SDC25 gene. The SDC25 gene is located on the chromosome XII close to the centromere. It is transcribed into a 4-kb-long mRNA that contains an open reading frame of 1,251 codons. Homology with the CDC25 gene extends in the N-terminal part, although the degree of similarity is lower than in the C-terminal part. In contrast with the C-terminal part, the complete SDC25 gene was found not to suppress the CDC25 gene defect. A deletion in the N-terminal part restored the suppressing activity, a result which suggests the existence of a regulatory domain. The SDC25 gene was found to be dispensable for cell growth under usual conditions. No noticeable phenotype was found in the deleted strain.     

A new RAS mutation that suppresses the CDC25 gene requirement for growth of Saccharomyces cerevisiae.

In the yeast Saccharomyces cerevisiae, the activation of adenylate cyclase requires the products of the RAS genes and of CDC25. We isolated several dominant extragenic suppressors of the yeast cdc25 mutation. They did not suppress a thermosensitive allele of the adenylate cyclase gene (CDC35). One of these suppressors was a mutated RAS2 gene in which the transition C/G----T/A at position 455 resulted in replacement of threonine 152 by isoleucine in the protein. The same mutation in a v-Ha-ras gene reduces the affinity of p21 for guanine nucleotides (L.A. Feig, B. Pan, T.M. Roberts, and G.M. Cooper, Proc. Natl. Acad. Sci. USA 83:4607-4611, 1986). These results support a model in which the CDC25 gene product is the GDP-GTP exchange factor regulating the activity of the RAS gene product.     

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.     

Protein recruitment systems for the analysis of protein +/- protein interactions

The yeast Saccharomyces cerevisiae serves as an excellent genetic tool for the analysis of protein +/- protein interactions. The most common system, used to date, is the two-hybrid system. Although proven very powerful, the two-hybrid system exhibits several inherent problems and limitations. Recently, two alternative systems have been described that take advantage of the fact that localization of signal transduction effectors to the inner leaflet of the plasma membrane is absolutely necessary for yeast viability. These effectors can either be the Ras guanyl nucleotide exchange factor or Ras itself. The yeast strain used in both systems is a temperature-sensitive mutant in the yeast Ras guanyl nucleotide exchange factor, CDC25. Membrane localization of these effectors is achieved via protein +/- protein interaction. Each system can be used to test interaction between known protein pairs, as well as for isolation of novel protein interactions. Described here are the scientific and technical steps to be considered for both protein recruitment systems.     

In vitro reconstitution of cdc25 regulated S. cerevisiae adenylyl cyclase and its kinetic properties.

The attenuated GTP regulation adenylyl cyclase (CDC35) lysates or membranes prepared from cells of a cdc25ts strain is enhanced 2.5- to 6-fold by mixing these lysates or membranes with lysates or membranes from a cdc35ts strain harboring wild-type CDC25. The kinetics of activation of the Saccharomyces cerevisiae adenylyl cyclase in vitro is first order, as is the activation of mammalian adenylyl cyclase. The rate of enzyme activation in the presence of non-hydrolysable analogs of GTP increases with the number of CDC25 gene copies present in the cell. When GppNHp was used the rate of activation of the cyclase in a strain harboring a multicopy plasmid of CDC25 was 7.0-fold higher than the rate in an isogenic strain with the cdc25-2 mutation. The rate of adenylyl cyclase activation from a strain with a disrupted CDC25 gene is 14.7-fold lower than the rate in an isogenic strain containing the CDC25 gene on a multicopy plasmid. The reconstitution experiments described provide direct biochemical evidence for the role of the CDC25 protein in regulating the RAS dependent adenylyl cyclase in S.cerevisiae. The reconstitution experiments and the kinetic experiments may also provide a biochemical assay for the CDC25 protein and can form the basis for its characterization. In this study we also show that adenylyl cyclase activity in ras1ras2byc1 cells is found in the soluble fraction, whereas in wild-type strain it is found in the membrane fraction. Overexpression of the gene CDC25 in the ras1ras2bcy1 strain relocalizes adenylyl cyclase activity to the membrane fraction. This finding suggests a biochemical link between CDC25 and CDC35 in the absence of RAS, in addition to its role in regulating RAS dependent adenylyl cyclase.     

Cdc42p GTPase is involved in controlling polarized cell growth in Schizosaccharomyces pombe.

Cdc42p is a highly conserved low-molecular-weight GTPase that is involved in controlling cellular morphogenesis. We have isolated the Cdc42p homolog from the fission yeast Schizosaccharomyces pombe by its ability to complement the Saccharomyces cerevisiae cdc42-1ts mutation. S. pombe Cdc42p is 85% identical in predicted amino acid sequence to S. cerevisiae Cdc42p and 83% identical to the human Cdc42p homolog. The Cdc42p protein fractionates to both soluble and particulate fractions, suggesting that it exists in two cellular pools. We have disrupted the cdc42+ gene and shown that it is essential for growth. The cdc42 null phenotype is an arrest as small, round, dense cells. In addition, we have generated three site-specific mutations, G12V, Q61L, and D118A, in the Cdc42p GTP-binding domains that correspond to dominant-lethal mutations in S. cerevisiae CDC42. In contrast to the S. cerevisiae cdc42 mutations, the S. pombe cdc42 mutant alleles were not lethal when overexpressed. However, the cdc42 mutants did exhibit an abnormal morphological phenotype of large, misshapen cells, suggesting that S. pombe Cdc42p is involved in controlling polarized cell growth.     

Identification and analysis of a DNA fragment from Saccharomyces kluyveri that can complement the loss of CDC25 function in Saccharomyces cerevisiae.

In the budding yeast, Saccharomyces cerevisiae, the function of wild-type Ras proteins is dependent on the CDC25 protein, which promotes the exchange of guanine nucleotides bound to Ras. To facilitate the identification of proteins which similarly regulate Ras function in higher eukaryotes, we have identified the CDC25 gene from another budding yeast, Saccharomyces kluyveri, by low-stringency hybridization to an S. cerevisiae CDC25 restriction fragment. This protein, SKCDC25, shares significant amino acid homology with CDC25, SCD25, and Ste6 of Schizosaccharomyces pombe in the C-terminal portion of the protein. The expression of SKCDC25 in a temperature-sensitive cdc25 strain of S. cerevisiae complements the loss of endogenous CDC25 activity. The identification of the highly conserved C-terminal sequences, which direct bona fide CDC25 activity within these proteins, will aid in the isolation of CDC25 genes from higher eukaryotes.     

Cdc50p,a conserved endosomal membrane protein,controls polarized growth in Saccharomyces cerevisiae

During the cell cycle of the yeast Saccharomyces cerevisiae, the actin cytoskeleton and the growth of cell surface are polarized, mediating bud emergence, bud growth, and cytokinesis. We identified CDC50 as a multicopy suppressor of the myo3 myo5-360 temperature-sensitive mutant, which is defective in organization of cortical actin patches. The cdc50 null mutant showed cold-sensitive cell cycle arrest with a small bud as reported previously. Cortical actin patches and Myo5p, which are normally localized to polarization sites, were depolarized in the cdc50 mutant. Furthermore, actin cables disappeared, and Bni1p and Gic1p, effectors of the Cdc42p small GTPase, were mislocalized in the cdc50 mutant. As predicted by its amino acid sequence, Cdc50p appears to be a transmembrane protein because it was solubilized from the membranes by detergent treatment. Cdc50p colocalized with Vps21p in endosomal compartments and was also localized to the class E compartment in the vps27 mutant. The cdc50 mutant showed defects in a late stage of endocytosis but not in the internalization step. It showed, however, only modest defects in vacuolar protein sorting. Our results indicate that Cdc50p is a novel endosomal protein that regulates polarized cell growth.     

The S. cerevisiae CDC25 gene product regulates the RAS/adenylate cyclase pathway

The gene corresponding to the S. cerevisiae cell division cycle mutant cdc25 has been cloned and sequenced, revealing an open reading frame encoding a protein of 1589 amino acids that contains no significant homologies with other known proteins. Cells lacking CDC25 have low levels of cyclic AMP and decreased levels of Mg2+-dependent adenylate cyclase activity. The lethality resulting from disruption of the CDC25 gene can be suppressed by the presence of the activated RAS2val19 gene, but not by high copy plasmids expressing a normal RAS2 or RAS1 gene. These results suggest that normal RAS is dependent on CDC25 function. Furthermore, mutationally activated alleles of CDC25 are capable of inducing a set of phenotypes similar to those observed in strains containing a genetically activated RAS/adenylate cyclase pathway, suggesting that CDC25 encodes a regulatory protein. We propose that CDC25 regulates adenylate cyclase by regulating the guanine nucleotide bound to RAS proteins.     

Ssa1p chaperone interacts with the guanine nucleotide exchange factor of ras Cdc25p and controls the cAMP pathway in Saccharomyces cerevisiae

We have found that the guanine nucleotide exchange factor for ras, Cdc25p, interacts with Ssa1p in Saccharomyces cerevisiae. This interaction was observed with GST-fused Cdc25p polypeptides and confirmed by coimmunoprecipitation with the endogenous Cdc25p. Hsp82 appeared also to be co-immunoprecipitated with Cdc25p, albeit to a lower level than Hsp70. In a strain deleted for SSA1 and SSA2, we observed a reduced cellular content of Cdc25p. Consistent with a reduced activity of the cAMP-dependent PKA pathway, the rate of accumulation of both trehalose and glycogen was stimulated in the ssa-deleted strain. Expression of SSA1 reversed these effects, whereas co-expression of SSA1 and PDE2 restored high accumulation. The expression of genes repressed by cAMP, GAC1 and TPS1, fused to beta-galactosidase, was also stimulated by deletion of SSA genes. The effect of ssa deletion on glycogen accumulation was lost in a strain deleted for CDC25 rescued by the RAS2ile152 allele. Altogether, these results lead to the conclusion that Ssa1p positively controls the cAMP pathway through Cdc25p. We propose that this connection plays a critical role in the adaptation of cells to stress conditions.     

Dominant yeast and mammalian RAS mutants that interfere with the CDC25-dependent activation of wild-type RAS in Saccharomyces cerevisiae.

Two mutant alleles of RAS2 were discovered that dominantly interfere with wild-type RAS function in the yeast Saccharomyces cerevisiae. An amino acid substitution which caused the dominant interference was an alanine for glycine at position 22 or a proline for alanine at position 25. Analogous mutations in human H-ras also dominantly inhibited RAS function when expressed in yeast cells. The inhibitory effects of the mutant RAS2 or H-ras genes could be overcome by overexpression of CDC25, but only in the presence of wild-type RAS. These results suggest that these mutant RAS genes interfere with the normal interaction of RAS and CDC25 proteins and suggest that this interaction is direct and has evolutionarily conserved features.     

<Emphasis Type="Italic">STM1</Emphasis>, a gene which encodes a guanine quadruplex binding protein,interacts with<Emphasis Type="Italic"> CDC13</Emphasis> in<Emphasis Type="Italic"> Saccharomyces cerevisiae</Emphasis>

The CDC13 gene encodes a protein that binds to the G-rich single-strand at yeast telomeres, and serves as a regulator of telomere replication. Cdc13 interacts with Est1 and DNA polymerase alpha, and cells carrying the temperature-sensitive allele cdc13-1 cannot complete telomere replication at the restrictive temperature and possess long telomeres. We attempted to isolate and characterize genes that interact with CDC13, in order to clarify the molecular mechanisms of telomere replication. A STM1 cDNA was isolated in a two-hybrid screen using CDC13 as a bait. The temperature-sensitive growth phenotype and the alteration in telomere size in cdc13-1 cells were corrected by introduction of the STM1 gene on a multicopy vector, but the extended G-rich single-strand overhangs which are also characteristic in the cdc13-1 mutant were not affected. Furthermore, we found that multiple copies of SGS1, a gene encoding a helicase that can unwind guanine quadruplexes, inhibited suppression of the cdc13-1 phenotype by STM1. We also demonstrate that a fusion protein consisting of the N-terminal region of Cdc13 and the C-terminal region of Stm1 (which shows similarity to the beta-subunit of the telomere binding complex in Oxytricha) could complement a cdc13 disruptant. Although STM1 itself is not essential for telomere replication, our findings suggest that STM1 genetically interacts with CDC13 to maintain telomere structure.     

The Saccharomyces cerevisiae CKS1 gene, a homolog of the Schizosaccharomyces pombe suc1+ gene, encodes a subunit of the Cdc28 protein kinase complex.

The Saccharomyces cerevisiae gene CDC28 encodes a protein kinase required for cell cycle initiation. In an attempt to identify genes encoding proteins that interact with the Cdc28 protein kinase, high-copy plasmid suppressors of a temperature-sensitive cdc28 mutation were isolated. One such suppressor, CKS1, was found to encode an 18-kilodalton protein that shared a high degree of homology with the suc1+ protein (p13) of Schizosaccharomyces pombe (67% amino acid sequence identity). Disruption of the chromosomal CKS1 gene conferred a G1 arrest phenotype similar to that of cdc28 mutants. The presence of the 18-kilodalton Cks1 protein in yeast lysates was demonstrated by using Cks-1 specific antiserum. Furthermore, the Cks1 protein was shown to be physically associated with active forms of the Cdc28 protein kinase. These data suggest that Cks1 is an essential component of the Cdc28 protein kinase complex.     

In vitro interaction between Saccharomyces cerevisiae CDC25 and RAS2 proteins.

In Saccharomyces cerevisiae the CDC25 protein is a positive regulator of RAS/cAMP pathway [1-4], enhancing the GDP-releasing rate of RAS2 protein [5]. In this work we have tried to detect a direct interaction between CDC25 and RAS2 gene products. The results indicate that both the whole RAS2 protein and a truncated version that lacks approximately 25 C-terminal residues interact specifically with the CDC25 protein. On the contrary, a derivative of RAS2 that lacks the 112 C-terminal residues as well as the p21TI-ras is not able to bind the CDC25 protein in our assay conditions. The 310 C-terminal aminoacids of CDC25 bind RAS2 while a C-terminus deletion within this aminoacid stretch abolishes the binding. The possible physiological significance of these findings is discussed.     

A role for the noncatalytic N terminus in the function of Cdc25, a Saccharomyces cerevisiae Ras-guanine nucleotide exchange factor

The Saccharomyces cerevisiae CDC25 gene encodes a guanine nucleotide exchange factor (GEF) for Ras proteins. Its catalytic domain is highly homologous to Ras-GEFs from all eukaryotes. Even though Cdc25 is the first Ras-GEF identified in any organism, we still know very little about how its function is regulated in yeast. In this work we provide evidence for the involvement of the N terminus of Cdc25 in the regulation of its activity. A truncated CDC25 lacking the noncatalytic C-terminal coding sequence was identified in a screen of high-copy suppressors of the heat-shock-sensitive phenotype of strains in which the Ras pathway is hyper-activated. The truncated gene acts as a dominant-negative mutant because it only suppresses the heat-shock sensitivity of strains that require the function of CDC25. Our two-hybrid assays and immunoprecipitation analyses show interactions between the N terminus of Cdc25 and itself, the C terminus, and the full-length protein. These results suggest that the dominant-negative effect may be a result of oligomerization with endogenous Cdc25. Further evidence of the role of the N terminus of Cdc25 in the regulation of its activity is provided by the mapping of the activating mutation of CDC25HS20 to the serine residue at position 365 in the noncatalytic N-terminal domain. This mutation induces a phenotype similar to activating mutants of other genes in the Ras pathway in yeast. Hence, the N terminus may exert a negative control on the catalytic activity of the protein. Taken together these results suggest that the N terminus plays a crucial role in regulating Cdc25 and consequently Ras activity, which in S. cerevisiae is essential for cell cycle progression.     

Phosphatase 2A negatively regulates mitotic exit in Saccharomyces cerevisiae

In budding yeast Saccharomyces cerevisiae, Cdc5 kinase is a component of mitotic exit network (MEN), which inactivates cyclin-dependent kinase (CDK) after chromosome segregation. cdc5-1 mutants arrest at telophase at the nonpermissive temperature due to the failure of CDK inactivation. To identify more negative regulators of MEN, we carried out a genetic screen for genes that are toxic to cdc5-1 mutants when overexpressed. Genes that encode the B-regulatory subunit (Cdc55) and the three catalytic subunits (Pph21, Pph22, and Pph3) of phosphatase 2A (PP2A) were isolated. In addition to cdc5-1, overexpression of CDC55, PPH21, or PPH22 is also toxic to other temperature-sensitive mutants that display defects in mitotic exit. Consistently, deletion of CDC55 partially suppresses the temperature sensitivity of these mutants. Moreover, in the presence of spindle damage, PP2A mutants display nuclear localized Cdc14, the key player in MEN pathway, indicative of MEN activation. All the evidence suggests the negative role of PP2A in mitotic exit. Finally, our genetic and biochemical data suggest that PP2A regulates the phosphorylation of Tem1, which acts at the very top of MEN pathway.