Gcn2 mediates Gcn4 activation in response to glucose stimulation or UV radiation not via GCN4 translation.

In mammalian cells transcription factors of the AP-1 family are activated by either stress signals such as UV radiation, or mitogenic signals such as growth factors. Here we show that a similar situation exists in the yeast Saccharomyces cerevisiae. The AP-1 transcriptional activator Gcn4, known to be activated by stress signals such as UV radiation and amino acids starvation, is also induced by growth stimulation such as glucose. We show that glucose-dependent Gcn4 activation is mediated through the Ras/cAMP pathway. This pathway is also responsible for UV-dependent Gcn4 activation but is not involved in Gcn4 activation by amino acid starvation. Thus, the unusual phenomenon of activation of mitogenic pathways and AP-1 factors by contradictory stimuli through Ras is conserved from yeast to mammals. We also show that activation of Gcn4 by glucose and UV requires Gcn2 activity. However, in contrast to its role in amino acid starvation, Gcn2 does not increase eIF2alpha phosphorylation or translation of GCN4 mRNA in response to glucose or UV. These findings suggest a novel mechanism of action for Gcn2. The finding that Gcn4 is activated in response to glucose via the Ras/cAMP pathway suggests that this cascade coordinates glucose metabolism with amino acids and purine biosynthesis and thereby ensures availability of both energy and essential building blocks for continuation of the cell cycle.

GCN4-based expression system (pGES): translationally regulated yeast expression vectors.

The expression of foreign proteins in Saccharomyces cerevisiae is a powerful tool for basic research and the biotechnological industry. In spite of the potential of S. cerevisiae, only a few useful expression vectors have been developed for this yeast. These vectors are based on an increasing transcription rate in combination with an increase in gene dosage. Most vectors are maintained as plasmids, which forces growth of cultures on poor selective media. Expression of the yeast Gcn4 protein is regulated at the translational level and increases strongly under amino acid starvation. Because under these conditions protein synthesis in general ceases, it is conceivable that regulatory elements that control Gcn4 expression could support selective expression of foreign genes. We cloned DNA fragments residing upstream from the GCN4 coding sequence (including the 5' UTR) and ligated them to a cDNA that encodes the human serum albumin (HSA) gene. These GCN4 regulatory elements induced efficient HSA expression at the translational level under amino acid starvation. The GCN4/HSA cassette promoted efficient, inducible expression on either a multicopy or integrative plasmid. The integrated cassette induced a high level of HSA in dense cultures grown on rich media. Thus, the GCN4-based expression system (pGES) provides high protein quantities. pGES is the first expression vector to be induced at the translational level.

The N-terminal half of Cdc25 is essential for processing glucose signaling in Saccharomyces cerevisiae.

Saccharomyces cerevisiae Cdc25 is the prototype Ras GDP/GTP exchange protein. Its C-terminal catalytic domain was found to be highly conserved in the homologues p140(ras-GRF) and Sos. The regulatory domains in each Ras exchanger mediate the signals arriving from upstream elements such as tyrosine kinases for Sos, or Ca2+ and G proteins for p140.(Ras-GRF) In this study, we show that the N-terminal half (NTH) of S. cerevisiae Cdc25, as well as the C-terminal 37 amino acids, is essential for processing the elevation of cAMP in response to glucose. The mammalian p140(ras-GRF) catalytic domain (CGRF) restores glucose signaling in S. cerevisiae only if tethered between the N-terminal half (NTH) of S. cerevisiae Cdc25 and the C-terminal 37 amino acids. The glucose-induced transient elevation in cAMP is nullified or severely hampered by the deletion of domains within the NTH of Cdc25. These deletions, however, do not modify the intrinsic GDP/GTP exchange activity of mutant proteins as compared to native Cdc25. We also show that 7 Ser to Ala mutations at the cAMP-dependent protein kinase putative phosphorylation sites within the NTH of Cdc25 eliminate the descending portion of the glucose response curve, responsible for signal termination. These findings support a dual role of the NTH of Cdc25 in both enabling the glucose signal and being responsible for its attenuation.

UV-responsive genes of arabidopsis revealed by similarity to the Gcn4-mediated UV response in yeast.

A UV response that involves the Ras proteins and AP-1 transcription factors has recently been described in mammals and yeast. To test whether an equivalent response exists in plants, we monitored the expression of Arabidopsis histidinol dehydrogenase gene (HDH), a homologue of the yeast HIS4 gene, which is strongly induced by UV light and is a target of the transcriptional activator Gcn4. We show that HDH mRNA levels increase specifically in response to UV-B light. Only small increases were detected upon exposure to other wavelengths. To isolate plant genes involved in this UV response, a gcn4 mutant was transfected with an Arabidopsis thaliana cDNA library. A new type of nucleotide diphosphate kinase (NDPK Ia) with a significant homology to the human tumor suppressor protein Nm23 rescued the gcn4 phenotype. NDPK Ia specifically binds to the HIS4 promoter in vitro and induces HIS4 transcription in yeast. In Arabidopsis, the NDPK Ia protein is located in the nucleus and cytosol. Expression studies in seedlings revealed that the level of NDPK Ia mRNA, like that of HDH, increases in response to UV-B light. It appears that NDPK Ia and HDH are components of a novel UV-responsive pathway in A. thaliana.

Dimerization of Ste5, a mitogen-activated protein kinase cascade scaffold protein, is required for signal transduction.

The mitogen-activated protein kinase cascade of the Saccharomyces cerevisiae pheromone response pathway is organized on the Ste5 protein, which binds each of the kinases of the cascade prior to signaling. In this study, a structure-function analysis of Ste5 deletion mutants uncovered new functional domains of the Ste5 protein and revealed that Ste5 dimerizes during the course of normal signal transduction. Dimerization, mediated by two regions in the N-terminal half of Ste5, was first suggested by intragenic complementation between pairs of nonfunctional Ste5 mutants and was confirmed by using the two-hybrid system. Coimmunoprecipitation of differently tagged forms of Ste5 from cells in which the pathway has been activated by Ste5 overexpression further confirmed dimerization. A precise correlation between the biological activity of various Ste5 fragments and dimerization suggests that dimerization is essential for Ste5 function.

Differential activation of yeast adenylyl cyclase by Ras1 and Ras2 depends on the conserved N terminus.

Although both Ras1 and Ras2 activate adenylyl cyclase in yeast, a number of differences can be observed regarding their function in the cAMP pathway. To explore the relative contribution of conserved and variable domains in determining these differences, chimeric RAS1-RAS2 or RAS2-RAS1 genes were constructed by swapping the sequences encoding the variable C-terminal domains. These constructs were expressed in a cdc25ts ras1 ras2 strain. Biochemical data show that the difference in efficacy of adenylyl cyclase activation between the two Ras proteins resides in the highly conserved N-terminal domain. This finding is supported by the observation that Ras2 delta, in which the C-terminal domain of Ras2 has been deleted, is a more potent activator of the yeast adenylyl cyclase than Ras1 delta, in which the C-terminal domain of Ras1 has been deleted. These observations suggest that amino acid residues other than the highly conserved residues of the effector domain within the N terminus may determine the efficiency of functional interaction with adenylyl cyclase. Similar levels of intracellular cAMP were found in Ras1, Ras1-Ras2, Ras1 delta, Ras2, and Ras2-Ras1 strains throughout the growth curve. This was found to result from the higher expression of Ras1 and Ras1-Ras2, which compensate for their lower efficacy in activating adenylyl cyclase. These results suggest that the difference between the Ras1 and the Ras2 phenotype is not due to their different efficacy in activating the cAMP pathway and that the divergent C-terminal domains are responsible for these differences, through interaction with other regulatory elements.

Two distinct regions of Ras participate in functional interaction with GDP-GTP exchangers.

We have previously implemented a combined genetic/biochemical approach, for analysis of insertion-deletion mutants, to identify sites of Harvey-Ras participating in the interaction with guanine nucleotide exchangers, using the yeast Cdc25 as a model exchanger. We showed that positions 101-106 may be required for catalyzed exchange. We here present a further improved strategy to define more precisely the residues on Ras participating in this interaction. Non-conservative replacements at positions 103 or 105 abolished response to Cdc25 while substitutions at positions 102 or 104 were partially affected. The same substitutions had no effect on coupling to adenylyl cyclase. Since the strategy enables us to assess Ras functional interaction with both the exchanger and effector simultaneously, we have also examined the effect of substitutions in the distal part of the switch II region (amino acids 69-78). In contrast to other reports, substitutions at positions 69 or 73 prevented Cdc25 response while mutations at position 74 did not prevent this interaction. However, all these substitutions partly affected cyclase activation. These findings establish the crucial role of the 102-105 region in the catalyzed exchange reaction and suggest that the 69-74 area would be required for the functional interaction with both exchangers and effector molecules.

A Candida albicans homolog of CDC25 is functional in Saccharomyces cerevisiae.

We have cloned, by functional complementation of the cdc25-2 mutation of Saccharomyces cerevisiae, a homolog of CDC25 from the pathogenic yeast Candida albicans. The new gene, named CSC25 codes for a 1333-amino-acid protein. The full length gene, as well as a truncated form coding for 795 amino acids, suppresses the thermosensitive phenotype of cdc25ts mutants. Biochemical analysis has shown that Csc25 activates the Ras/adenylyl cyclase pathway in S. cerevisiae at a rate two to three times faster than Cdc25, under the same conditions. The C-terminal domain of Csc25 is highly similar to the C-terminal domain of Cdc25, to almost the same extent as the C-terminus of the endogenous Cdc25 homolog Sdc25. We show that polyclonal anti-Cdc25 antibodies interact with Csc25 expressed in S. cerevisiae. In addition to the full length protein (approximately 150 kDa), we have found a approximately 50-kDa polypeptide which seems to include the C-terminus of the CSC25 gene product.

The signal transduction between beta-receptors and adenylyl cyclase.

The beta-adrenergic receptor-dependent adenylyl cyclase system is the most extensively studied G-protein-coupled system. Studies of the coupling between the receptor and effector can provide an insight into the nature of all these systems in general. In the activation of adenylyl cyclase by the receptor, the binding of an agonist to the stimulatory receptor (Rs) and the binding of GTP to the G-protein (Gs) are both required to activate the catalytic moiety (C). The active state decays as GTP is hydrolysed to GDP and inorganic phosphate (Pi), but reactivation occurs as GTP is replenished. The receptor acts as a catalyst, i.e. one agonist-bound receptor can activate numerous adenylyl cyclase molecules. Kinetic studies led to the formulation of the 'collision coupling' model of receptor activation and show that Gs protein does not shuttle between the receptor and cyclase. The Gs protein appears to undergo conformational changes between an 'open' state in which it can bind with GTP, and a 'closed' state unable to achieve this binding. This mechanism of activation does not involve the dissociation of Gs or of Gi. A model which fits the experimental data suggests that Gi*GTP affects cyclase only in its Gs-activated state via the G alpha 1 subunit, but that the oligomeric state of Gi is required for inhibition. The site on C which interacts with Gi is formed only when C is activated by Gs.

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.

The GppNHp-activated adenylyl cyclase complex from turkey erythrocyte membranes can be isolated with its beta gamma subunits.

The adenylyl cyclase complex, derived from turkey erythrocyte membranes, was activated using guanosine 5'-[beta, gamma-imido]triphosphate (Gpp[NH]p) and separated under low-detergent and low-salt conditions using conventional molecular-sieve chromatography followed by high-pressure ion-exchange and molecular-sieve chromatography. Although the complex remains activated with Gpp[NH]p throughout the isolation, the beta gamma subunits copurify with the cyclase. The stoichiometry of the cyclase to the alpha subunit of the stimulatory guanosine-nucleotide-binding regulatory protein (alpha s) to the beta subunit is close to unity, demonstrating that the beta gamma subunits do not dissociate from the Gs.cyclase complex (Gs, guanosine-nucleotide-binding regulatory protein) upon activation of the enzyme. If the final purification step was performed at high-salt concentrations, the beta gamma subunits could be separated from the alpha s.cyclase complex. Previously reported results on bovine brain cyclase also showed that the Gs.cyclase complex remains intact subsequent to activation by hormone and Gpp[NH]p [Marbach, I., Bar-Sinai, A., Minich, M. and Levitzki, A. (1990) J. Biol. Chem. 265, 9999-10,004]. These results, using adenylyl cyclase from two different sources, support our previous kinetic experiments which first suggested that beta gamma subunits are not released from Gs upon cyclase activation. We, therefore, argue that the mode of adenylyl cyclase inhibition by the inhibitory guanosine-nucleotide-binding regulatory protein cannot be via shifting the alpha s to beta gamma equilibrium as is commonly believed, and an alternate hypothesis is proposed.

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.

Beta subunit copurifies with GppNHp-activated adenylyl cyclase.

Previous kinetic studies (Tolkovsky, A.M., Braun, S., and Levitzki, A. (1982) Proc. Natl. Acad. Sci. U. S.A. 79, 213-222) and biochemical studies (Arad, H., Rosenbusch, J., and Levitzki, A. (1984) Proc. Natl. Acad. Sci. U.S.A. 81, 6579-6583) from our laboratory suggest that Gs or alpha s remain associated with the catalytic subunit of adenylyl cyclase (C) throughout the activation cycle of adenylyl cyclase by hormone receptors. In this study we have purified GppNHp-activated bovine brain adenylyl cyclase over 3000-fold under mild solution conditions. We demonstrate that although the enzyme is permanently activated it retains the beta subunit when bound to a forskolin-agarose affinity column as long as it is not exposed to high salt concentrations. The stoichiometry of alpha s to beta to C is close to unity, suggesting that beta gamma subunits do not dissociate from Gs upon its activation. The complex gamma beta alpha s (GppNHp). C dissociates partially when migrating on a Superose 12 fast protein liquid chromatography molecular-seiving column. This partial dissociation probably results from the relatively diluted state of the enzyme at a high degree of purity. Prolonged ultracentrifugation of the complex also causes partial dissociation of the beta gamma subunits from alpha s (GppNHp). C. The apparent contradiction between the results reported here and the observation that beta gamma subunits inhibit cyclase activity when added to platelet membranes (Katada, T., Bokoch, G. M., Northrup, J. K., Ui, M., and Gilman, A. G. (1984a) J. Biol. Chem. 259, 3568-3577) is discussed. We suggest an alternative model to account for this inhibitory effect of added beta gamma subunits.

Use of electrofocusing for the analysis and purification of turkey erythrocytes beta 1-adrenoceptors.

We show that following one cycle of alprenolol affinity chromatography of turkey erythrocyte beta 1-adrenoceptors, electrofocusing on polyacrylamide gels in digitonin, followed by electroelution, results in complete receptor purification. The overall yield from the electrofocusing-electroelution step of turkey erythrocyte beta-adrenoceptor is 75 +/- 3%. In addition, we are able to demonstrate that receptor-binding assays can be performed directly on the polyacrylamide gel, using 125I-cyanopindolol. This method can be employed for minute quantities of receptor which is an advantage when one wishes to characterize rapidly the beta-adrenoceptor in its native state from tissues that may be available only in limited amounts. We also report, for comparison, on the behavior of the turkey erythrocyte beta 1-adrenoceptor on immobiline polyacrylamide gels and the ability to purify only partially the receptor on these gels.

Gi affects the agonist-binding properties of beta-adrenoceptors in the presence of Gs.

Pertussis-toxin-catalyzed ADP-ribosylation of Gi in S49 membranes, but not in S49AC- membranes, which lack Gs, induces a threefold reduction of isoproterenol affinity to the beta-adrenoceptors. A similar treatment of turkey erythrocyte membranes, which are devoid of functional Gi, has no effect on beta-agonist affinity to their beta-adrenoceptors. Non-hydrolyzable analogs such as GTP[S] induce a larger decrease in beta-adrenoceptor affinity in S49 cells towards the agonist isoproterenol as compared to pertussis-toxin-catalyzed ADP-ribosylation of Gi. These results suggest that Gi affects beta-adrenoceptor affinity to its agonist and that this interaction requires the presence of Gs. It seems, therefore, that Gi physically interacts with Gs to exert its effects on the receptor and probably on adenylate cyclase as well. Our ability to detect (a) the effect of pertussis-toxin-catalyzed ADP-ribosylation in S49 cells on beta-agonist affinity and (b) the quantitative difference between the effect of pertussis toxin (approx. threefold) and GTP[S] (fivefold to sevenfold) depends on the use of a simple but rigorous method to study in detail the affinity of beta-agonists to their receptors. This method seems to be superior to the analysis of displacement curves as a means to examine receptor-ligand interactions.

Changes in Catechol Oxidase and Permeability to Water in Seed Coats of Pisum elatius during Seed Development and Maturation.

In the developing seed coat of Pisum elatius, o-dihydroxyphenols are present in appreciable amounts at all stages of development. However, catechol oxidase activity rises sharply during the later stages of development, shows a further abrupt rise during dehydration of the seed coat, and then decreases. It is suggested that a tanning reaction is induced by the contact of enzyme with its substrate while cell membranes are ruptured, and that this reaction renders the seed coats impermeable. The entire chain of events does not occur in Pisum sativum which has permeable seed coats.

Permeability of seed coats to water as related to drying conditions and metabolism of phenolics.

The seed coat of Pisum elatius is normally impermeable to water. When seeds are dried in the absence of oxygen their coats are totally permeable to water. Structural differences are observed between permeable and impermeable seed coats. In the genus Pisum, species with normally impermeable seed coats have a high content of phenolics and of catechol oxidase, while seed coats of P. sativum contain very little catechol oxidase and have a very low content of phenolics. Such differences are not noted in the cotyledons. We hypothesized that during dehydration of seeds, oxidation of phenolic compounds in seed coats through catalysis of catechol oxidase in presence of O(2) might render the seed coats impermeable to water.