Induction and repression of arginase and ornithine transaminase in baker's yeast

Metabolic engineering of Saccharomyces cerevisiae for production of novel cyanophycins with an extended range of constituent amino acids

Cyanophycin (multi-l-arginyl-poly-l-aspartic acid; also known as cyanophycin grana peptide [CGP]) is a putative precursor for numerous biodegradable technically used chemicals. Therefore, the biosynthesis and production of the polymer in recombinant organisms is of special interest. The synthesis of cyanophycin derivatives consisting of a wider range of constituents would broaden the applications of this polymer. We applied recombinant Saccharomyces cerevisiae strains defective in arginine metabolism and expressing the cyanophycin synthetase of Synechocystis sp. strain PCC 6308 in order to synthesize CGP with citrulline and ornithine as constituents. Strains defective in arginine degradation (Car1 and Car2) accumulated up to 4% (wt/wt) CGP, whereas strains defective in arginine synthesis (Arg1, Arg3, and Arg4) accumulated up to 15.3% (wt/wt) of CGP, which is more than twofold higher than the previously content reported in yeast and the highest content ever reported in eukaryotes. Characterization of the isolated polymers by different analytical methods indicated that CGP synthesized by strain Arg1 (with argininosuccinate synthetase deleted) consisted of up to 20 mol% of citrulline, whereas CGP from strain Arg3 (with ornithine carbamoyltransferase deleted) consisted of up to 8 mol% of ornithine, and CGP isolated from strain Arg4 (with argininosuccinate lyase deleted) consisted of up to 16 mol% lysine. Cultivation experiments indicated that the incorporation of citrulline or ornithine is enhanced by the addition of low amounts of arginine (2 mM) and also by the addition of ornithine or citrulline (10 to 40 mM), respectively, to the medium.

Synergistic operation of the CAR2 (Ornithine transaminase) promoter elements in Saccharomyces cerevisiae

Dal82p binds to the UIS(ALL) sites of allophanate-induced genes of the allantoin-degradative pathway and functions synergistically with the GATA family Gln3p and Gat1p transcriptional activators that are responsible for nitrogen catabolite repression-sensitive gene expression. CAR2, which encodes the arginine-degradative enzyme ornithine transaminase, is not nitrogen catabolite repression sensitive, but its expression can be modestly induced by the allantoin pathway inducer. The dominant activators of CAR2 transcription have been thought to be the ArgR and Mcm1 factors, which mediate arginine-dependent induction. These observations prompted us to investigate the structure of the CAR2 promoter with the objectives of determining whether other transcription factors were required for CAR2 expression and, if so, of ascertaining their relative contributions to CAR2's expression and control. We show that Rap1p binds upstream of CAR2 and plays a central role in its induced expression irrespective of whether the inducer is arginine or the allantoin pathway inducer analogue oxalurate (OXLU). Our data also explain the early report that ornithine transaminase production is induced when cells are grown with urea. OXLU induction derives from the Dal82p binding site, which is immediately downstream of the Rap1p site, and Dal82p functions synergistically with Rap1p. This synergism is unlike all other known instances of Dal82p synergism, namely, that with the GATA family transcription activators Gln3p and Gat1p, which occurs only in the presence of an inducer. The observations reported suggest that CAR2 gene expression results from strong constitutive transcriptional activation mediated by Rap1p and Dal82p being balanced by the down regulation of an equally strong transcriptional repressor, Ume6p. This balance is then tipped in the direction of expression by the presence of the inducer. The formal structure of the CAR2 promoter and its operation closely follow the model proposed for CAR1.

Cha4p of Saccharomyces cerevisiae activates transcription via serine/threonine response elements

The CHA1 gene of Saccharomyces cerevisiae encodes the catabolic L-serine (L-threonine) deaminase responsible for the utilization of serine/threonine as nitrogen sources. Previously, we identified two serine/threonine response elements in the CHA1 promoter, UASCHA. We report isolation of a mutation, cha4-1, that impairs serine/threonine induction of CHA1 transcription. The cha4-1 allele causes noninducibility of a CHA1 p-lacZ translational gene fusion, indicating that Cha4p exerts its action through the CHA1 promoter. Molecular and genetic mapping positioned the cha4 locus 17 cM centromere proximal to put1 on chromosome XII. The coding region of CHA4 predicts a 648-amino acid protein with a DNA-binding motif (residues 43-70) belonging to the Cys6 zinc cluster class. Gel retardation employing a recombinant peptide, Cha4p1-174, demonstrated that the peptide in vitro specifically binds UASCHA. Binding is abolished by a G-C to T-A mutation in the middle bases of the two CEZ-elements in UASCHA. The transcriptional activating ability of UASCHA derivatives in vivo correlates with their ability to bind Cha4p1-174 in vitro. We conclude that Cha4p is a positive regulator of CHA1 transcription and that Cha4p alone, or as part of a complex, is binding UASCHA.

Saccharomyces cerevisiae BUF protein binds to sequences participating in DNA replication in addition to those mediating transcriptional repression (URS1) and activation

The heteromeric BUF protein was originally shown to bind to URS1 elements which are situated upstream of many genes in Saccharomyces cerevisiae and mediate negative control of their transcription. Among the genes regulated through the URS1 site and the proteins interacting with it are those participating in carbon, nitrogen, and inositol metabolism; electron transport; meiosis; sporulation; and mating-type switching. We show here that pure BUF protein, in addition to binding to the negatively acting URS1 site, also binds to CAR1 sequences supporting transcriptional activation (upstream activation sequences). To determine the BUF protein structure, we cloned and sequenced the BUF1 and BUF2 genes and found them to be identical to the RF-A (RP-A) gene whose products participate in yeast DNA replication as single-stranded DNA binding proteins. These data argue that BUF protein-binding sites serve multiple roles in transcription and replication.

Saccharomyces cerevisiae BUF protein binds to sequences participating in DNA replication in addition to those mediating transcriptional repression (URS1) and activation

The heteromeric BUF protein was originally shown to bind to URS1 elements which are situated upstream of many genes in Saccharomyces cerevisiae and mediate negative control of their transcription. Among the genes regulated through the URS1 site and the proteins interacting with it are those participating in carbon, nitrogen, and inositol metabolism; electron transport; meiosis; sporulation; and mating-type switching. We show here that pure BUF protein, in addition to binding to the negatively acting URS1 site, also binds to CAR1 sequences supporting transcriptional activation (upstream activation sequences). To determine the BUF protein structure, we cloned and sequenced the BUF1 and BUF2 genes and found them to be identical to the RF-A (RP-A) gene whose products participate in yeast DNA replication as single-stranded DNA binding proteins. These data argue that BUF protein-binding sites serve multiple roles in transcription and replication.

Analysis of the inducer-responsive CAR1 upstream activation sequence (UASI) and the factors required for its operation

Induced production of arginase (CAR1) enzyme activity and steady-state CAR1 mRNA in Saccharomyces cerevisiae requires wild-type ARG80/ARGRI and ARG81/ARGRII gene products. We demonstrate here that these gene products, along with that of the MCM1 gene, are required for the inducer-dependent USAI-A, UASI-B and UASI-C elements to function but they are not required for operation of inducer-independent CAR1 UASC1 or UASC2. Through the use of single and multiple point mutations, the CAR1 UASI-B and UASI-C elements were demonstrated to be at least 23 bp in length. Moreover, simultaneous mutation of both ends of an elements gave stronger phenotypes than mutations at either end. The center of the element was more sensitive to mutation than were the ends.

Participation of RAP1 protein in expression of the Saccharomyces cerevisiae arginase (CAR1) gene

Regulated expression of the inducible arginase (CAR1) gene of Saccharomyces cerevisiae has been shown to require three upstream activation sequences (UASs) and an upstream repression sequence, URS1. Two of the UAS elements, UASC1 and UASC2, operate in an inducer-independent manner, while the third, UASI, is inducer dependent. UASC1 and UASC2 were previously shown to contain ABF-1 binding sites that were required for normal transcription. In this work, we demonstrate that UASC1 and UASC2 also contain two and three sites, respectively, that are able to bind RAP1 protein. RAP1 binding to these sites, however, is significantly weaker than that to sites in TEF2 and HMRE. The effects of mutating the sites individually or in combination suggest that at least three of them, two in UASC1 and one in UASC2, probably participate in CAR1 expression.

Tripartite structure of the Saccharomyces cerevisiae arginase (CAR1) gene inducer-responsive upstream activation sequence

Arginase (CAR1) gene expression in Saccharomyces cerevisiae is induced by arginine. The 5' regulatory region of CAR1 contains four separable regulatory elements--two inducer-independent upstream activation sequences (UASs) (UASC1 and UASC2), an inducer-dependent UAS (UASI), and an upstream repression sequence (URS1) which negatively regulates CAR1 and many other yeast genes. Here we demonstrate that three homologous DNA sequences originally reported to be present in the inducer-responsive UASI are in fact three exchangeable elements (UASI-A, UASI-B, and UASI-C). Although two of these elements, either the same or different ones, are required for transcriptional activation to occur, all three are required for maximal levels of induction. The elements operate in all orientations relative to one another and to the TATA sequence. All three UASI elements bind protein(s); protein binding does not require arginine or overproduction of any of the putative arginine pathway regulatory proteins. The UASI-protein complex was also observed even when extracts were derived from arg80/argRI or arg81/argRII deletion mutants. Similar sequences situated upstream of ARG5,6 and ARG3 and reported to negatively regulate their expression are able to functionally substitute for the CAR1 UASI elements and mediate reporter gene expression.

The yeast UME6 gene product is required for transcriptional repression mediated by the CAR1 URS1 repressor binding site

URS1 is known to be a repressor binding site in Saccharomyces cerevisiae that negatively regulates expression of many genes including CAR1 (arginase), several required for sporulation, mating type switching, inositol metabolism, and oxidative carbon metabolism. In addition to the proteins previously shown to directly bind to the URS1 site, we show here that the UME6 gene product is required for URS1 to mediate repression of gene expression in the absence of inducer. We also show that mutations in the CAR80 (CARGRI) gene are allelic to those in UME6.

Arginine catabolism in the phototrophic bacterium Rhodobacter capsulatus E1F1. Purification and properties of arginase

The phototrophic bacterium Rhodobacter capsulatus E1F1 grew with L-arginine or L-homoarginine as nitrogen source under light/anaerobiosis. However, when L-arginine was used as the only source of both carbon and nitrogen, the bacterium exhibited weak growth levels and the excess of nitrogen was excreted to the medium as ammonia. By contrast, L-ornithine was used under phototrophic conditions as either nitrogen or carbon source. Other compounds of the arginine catabolic pathways, such as putrescine or proline, also supported phototrophic growth of this bacterium. Under heterotrophic/dark conditions, R. capsulatus always showed a low growth rate with those nitrogen compounds. Cells growing on media containing L-arginine, L-homoarginine or L-ornithine induced an Mn(2+)-dependent arginase activity regardless of the presence of ammonium ions and other readily utilizable nitrogen sources. Arginase activity was strongly inhibited by Zn2+, Cu2+, borate, L-cysteine, L-ornithine and gamma-guanidinobutyrate. Mercurials also inactivated arginase, the activity being partially restored by the presence of thiols. Arginase was purified to electrophoretic homogeneity and found to consist of four identical subunits of 31 kDa. The molecular parameters and kinetic constants of arginase from R. capsulatus E1F1 resembled those previously described for the Saccharomyces cerevisiae enzyme rather than those of bacterial arginases.

Nitrogen catabolite repression of arginase (CAR1) expression in Saccharomyces cerevisiae is derived from regulated inducer exclusion

Expression of the Saccharomyces cerevisiae arginase (CAR1) gene is regulated by induction and nitrogen catabolite repression (NCR). Arginine was demonstrated to be the native inducer. CAR1 sensitivity to NCR has long been accepted to be accomplished through a negative control mechanism, and cis-acting sites for it have been hypothesized. In search of this negatively acting site, we discovered that CAR1 sensitivity to NCR derives from regulated inducer (arginine) exclusion. The route of catabolic entry of arginine into the cell, the general amino acid permease (GAP1), is sensitive to NCR. However, CAR1 expression in the presence of sufficient intracellular arginine is NCR insensitive.

Role of the complex upstream region of the GDH2 gene in nitrogen regulation of the NAD-linked glutamate dehydrogenase in Saccharomyces cerevisiae

We analyzed the upstream region of the GDH2 gene, which encodes the NAD-linked glutamate dehydrogenase in Saccharomyces cerevisiae, for elements important for the regulation of the gene by the nitrogen source. The levels of this enzyme are high in cells grown with glutamate as the sole source of nitrogen and low in cells grown with glutamine or ammonium. We found that this regulation occurs at the level of transcription and that a total of six sites are required to cause a CYC1-lacZ fusion to the GDH2 gene to be regulated in the same manner as the NAD-linked glutamate dehydrogenase. Two sites behaved as upstream activation sites (UASs). The remaining four sites were found to block the effects of the two UASs in such a way that the GDH2-CYC1-lacZ fusion was not expressed unless the cells containing it were grown under conditions favorable for the activity of both UASs. This complex regulatory system appears to account for the fact that GDH2 expression is exquisitely sensitive to glutamine, whereas the expression of GLN1, coding for glutamine synthetase, is not nearly as sensitive.

Role of the complex upstream region of the GDH2 gene in nitrogen regulation of the NAD-linked glutamate dehydrogenase in Saccharomyces cerevisiae

We analyzed the upstream region of the GDH2 gene, which encodes the NAD-linked glutamate dehydrogenase in Saccharomyces cerevisiae, for elements important for the regulation of the gene by the nitrogen source. The levels of this enzyme are high in cells grown with glutamate as the sole source of nitrogen and low in cells grown with glutamine or ammonium. We found that this regulation occurs at the level of transcription and that a total of six sites are required to cause a CYC1-lacZ fusion to the GDH2 gene to be regulated in the same manner as the NAD-linked glutamate dehydrogenase. Two sites behaved as upstream activation sites (UASs). The remaining four sites were found to block the effects of the two UASs in such a way that the GDH2-CYC1-lacZ fusion was not expressed unless the cells containing it were grown under conditions favorable for the activity of both UASs. This complex regulatory system appears to account for the fact that GDH2 expression is exquisitely sensitive to glutamine, whereas the expression of GLN1, coding for glutamine synthetase, is not nearly as sensitive.

Arxula adeninivorans, a yeast assimilating many nitrogenous and aromatic compounds

A detailed description of the yeast species Arxula adeninivorans (syn. Trichosporon adeninovorans) was given. The yeast assimilated all the sugars, polyalcohols and organic acids used in the conventional carbon compound assimilation test rapidly, except for L-rhamnose, inulin, lactose, lactate and methanol. As nitrogen sources served all conventionally used compounds except creatine and creatinine. Several nitrogenous compounds, e.g. amino acids, purine derivatives, served as sole source of carbon, nitrogen and energy. This was also true of many primary n-alkylamines and terminal diamines, but of nitrogen-less analogous compounds such as alcohols, dialcohols, carboxylic acids and dicarboxylic acids only intermediates of general metabolism were assimilated. For observing growth at the expense of potentially toxic compounds the slant culture method was developed. In this test lactate was readily assimilated but proved to be toxic at the same time. Several aliphatic organic acids and their esters supported growth in this test, as was the case with several benzene compounds such as hydroquinone, 3- and 4-hydroxybenzoic acid, protocatechuic, gentisic, gallic and ferulic acids, 4-hydroxyacetophenone and 1-phenyl-n-dodecane.

A cis-acting element present in multiple genes serves as a repressor protein binding site for the yeast CAR1 gene

Induction of the arginase (CAR1) gene expression in Saccharomyces cerevisiae has previously been shown to require participation of a cis-dominantly regulated upstream repression sequence (URS). Deletion of this element results in high-level expression of the CAR1 gene without inducer. To determine the structure of the CAR1 URS element, we performed a saturation mutagenesis. Results of the mutagenic analysis indicated that the CAR1 URS was a 9-base-pair palindromic sequence, 5'-AGCCGCCGA-3'. A DNA fragment containing this sequence was shown to bind one or more proteins by a gel shift assay. DNA fragments containing point mutations that completely eliminated URS function were not effective competitors in this assay, whereas those which supported URS function were effective competitors. Sequences in the 5'-flanking regions of 14 other genes were found to be homologous to the CAR1 URS. These sequences were shown to support varying degrees of URS function in the expression vector assay, to bind protein as demonstrated by the gel shift assay, and to compete with a DNA fragment containing the CAR1 URS for protein binding. These results indicate that the CAR1 URS element possesses the characteristics of a repressor binding site. Further, they are consistent with the suggestion that sites homologous to the CAR1 URS may be situated in the 5'-flanking regions of multiple unrelated yeast genes. The widespread occurrence of this element raises the possibility that it is the target site for one or more negatively acting general transcription factors.

A cis-acting element present in multiple genes serves as a repressor protein binding site for the yeast CAR1 gene

Induction of the arginase (CAR1) gene expression in Saccharomyces cerevisiae has previously been shown to require participation of a cis-dominantly regulated upstream repression sequence (URS). Deletion of this element results in high-level expression of the CAR1 gene without inducer. To determine the structure of the CAR1 URS element, we performed a saturation mutagenesis. Results of the mutagenic analysis indicated that the CAR1 URS was a 9-base-pair palindromic sequence, 5'-AGCCGCCGA-3'. A DNA fragment containing this sequence was shown to bind one or more proteins by a gel shift assay. DNA fragments containing point mutations that completely eliminated URS function were not effective competitors in this assay, whereas those which supported URS function were effective competitors. Sequences in the 5'-flanking regions of 14 other genes were found to be homologous to the CAR1 URS. These sequences were shown to support varying degrees of URS function in the expression vector assay, to bind protein as demonstrated by the gel shift assay, and to compete with a DNA fragment containing the CAR1 URS for protein binding. These results indicate that the CAR1 URS element possesses the characteristics of a repressor binding site. Further, they are consistent with the suggestion that sites homologous to the CAR1 URS may be situated in the 5'-flanking regions of multiple unrelated yeast genes. The widespread occurrence of this element raises the possibility that it is the target site for one or more negatively acting general transcription factors.

Carbon assimilation and extracellular antigens of some yeast-like fungi

Many yeast-like fungi assimilated n-hexadecane, butylamine and putrescine as sole carbon sources. Methanol was not assimilated. This points to a physiological similarity to endomycetous, hydrocarbon-utilizing yeasts. Stephanoascus ciferrii assimilated uric acid, adenine and allantoin as sole source of carbon and nitrogen. All strains of Geotrichum candidum and many other yeast-like fungi assimilated acetoin and butan-2,3-diol. Assimilation tests for adenine, uric acid, allantoin, acetoin and butan-2,3-diol were found to be suitable for taxonomic purposes. Extracellular antigens immunologically related to those produced by Geotrichum candidum were detected in the cell-free culture liquids of several yeast-like fungi. The extracellular antigen excreted by Stephanoascus ciferrii was species-specific.

The effect of growth conditions on production and excretion of extracellular antigens by three ascomycetous yeasts

Ascomycetous yeasts produce extracellular antigens that are almost specific for the species. The antigen production by Hansenula wickerhamii and Stephanoascus ciferrii was independent of the carbon source and was proportional to the final cell density of the cultures. The same was true of chemostat cultures of Stephanoascus ciferrii, irrespective of the dilution rate and whether glucose or ammonia was the limiting nutrient. In cultures of Saccharomyces cerevisiae, however, antigen excretion mainly took place in the late exponential growth phase. Large amounts of antigen were extracted from the cell wall of Saccharomyces cerevisiae. A small amount was detected in the cytoplasm.

Point mutation generates constitutive expression of an inducible eukaryotic gene

We describe the analysis of two cis-dominant mutations that result in constitutive expression of the inducible CAR1 gene from yeast. One mutation results from insertion of a Ty element just upstream from the point where CAR1-specific transcription begins. The other mutation is a C-to-G transversion at position -153. Isolation of this point mutation, outside of the transcribed region of CAR1, suggests that expression of this gene is regulated at transcription. It also demonstrates the feasibility and usefulness of analyzing the regulatory sequences of eukaryotic genes on a nucleotide-by-nucleotide basis.

induction and derepression of arginase and ornithine transaminase in different strains of Saccharomyces cerevisiae

The syntheses of arginase and ornithine transaminase were studied in two strains of Saccharomyces cerevisiae, viz. strain B and strain alpha-sigma 1278b. Derepression of both enzymes during nitrogen starvation was shown only by strain B, non-specific induction of arginase only by strain alpha-sigma 1278b. This different response of both strains studied reveals substantial differences in the regulation of enzyme synthesis among yeast strains of one and the same species. The specific enzyme activities observed in chemostat cultures with arginine as the nitrogen source and different sugars, at variable carbon to nitrogen ratios, did not indicate the involvement of carbon catabolite repression in the regulation of arginase and ornithine transaminase syntheses. Specific arginase activities observed in the continuous cultures varied widely and did not show a correlation with the intracellular arginine concentration. Extracellular steady-state arginine concentrations higher than about 1.0 mM, in addition to abundant energy supply, were found to be required for high production of arginase. It is suggested that, besides intracellular arginine, extracellular arginine may provide an induction signal necessary for full-scale induction of arginase synthesis. A possible intermediary role of arginine permeases or of other membrane proteins is discussed.

Detection, with the dye phloxine B, of yeast mutants unable to utilize nitrogenous substances as the sole nitrogen source

Yeast mutants unable to degrade certain nitrogen compounds produce characteristic small red colonies on an agar medium containing the red dye phloxine B, galactose, the test nitrogen compound, and a small amount of ammonium chloride.

The substrate constant for the ammonium ion of growing Saccharomyces cerevisiae

The relation between ammonium concentration and growth rate was studied in steady state continuous cultures of Saccharomyces cerevisiae in nitrogen-limited glucose ammonium medium. This relation could be described by the Monod equation. A maximum specific growth rate of 0.41 h-1 and a substrate constant for ammonium of 5-11 muM were calculated. Ammonium was determined by a modification of the phenol hypochlorite method. A discussion of the results in view of literature data on the substrate constants for other nutrients is given.

Nitrogen repression of the allantoin degradative enzymes in Saccharomyces cerevisiae

Saccharomyces cerevisiae can utilize allantoin as a sole nitrogen source by degrading it to ammonia, "CO(2)," and glyoxylate. We have previously shown that synthesis of the allantoin degradative enzymes is contingent upon the presence of allophanate, the last intermediate in the pathway. The reported repression of arginase by ammonia prompted us to ascertain whether or not the allantoin degradative system would respond in a similar manner. We observed that the differential rates of allantoinase and allophanate hydrolase synthesis were not decreased appreciably when comparing cultures grown on urea to those grown on urea plus ammonia. These experiments were also performed using the strain and conditions previously reported by Dubois, Grenson, and Wiame. We found allophanate hydrolase production to be twofold repressed by ammonia when that strain was grown on glucose-urea plus ammonia medium. If, however, serine or a number of other readily metabolized amino acids were provided in place of ammonia, production of the allantoin degradative enzymes was quickly (within 20 min) and severely repressed in both strains. We conclude that repression previously attributed to ammonia may result from its metabolism to amino acids and other metabolites.

Regulation of the nicotinamide adenine dinucleotide- and nicotinamide adenine dinucleotide phosphate-dependent glutamate dehydrogenases of Saccharomyces cerevisiae

Saccharomyces cerevisiae contains two distinct l-glutamate dehydrogenases. These enzymes are affected in a reciprocal fashion by growth on ammonia or dicarboxylic amino acids as the nitrogen source. The specific activity of the nicotinamide adenine dinucleotide phosphate (NADP) (anabolic) enzyme is highest in ammonia-grown cells and is reduced in cells grown on glutamate or aspartate. Conversely, the specific activity of the nicotinamide adenine dinucleotide (NAD) (catabolic) glutamate dehydrogenase is highest in cells grown on glutamate or aspartate and is much lower in cells grown on ammonia. The specific activity of both enzymes is very low in nitrogen-starved yeast. Addition of the ammonia analogue methylamine to the growth medium reduces the specific activity of the NAD-dependent enzyme and increases the specific activity of the NADP-dependent enzyme.