Gene dosage effect of L-proline biosynthetic enzymes on L-proline accumulation and freeze tolerance in Saccharomyces cerevisiae

We have previously reported that L-proline has cryoprotective activity in Saccharomyces cerevisiae. A freeze-tolerant mutant with L-proline accumulation was recently shown to carry an allele of the PRO1 gene encoding gamma-glutamyl kinase, which resulted in a single amino acid substitution (Asp154Asn). Interestingly, this mutation enhanced the activities of gamma-glutamyl kinase and gamma-glutamyl phosphate reductase, both of which catalyze the first two steps of L-proline synthesis and which together may form a complex in vivo. Here, we found that the Asp154Asn mutant gamma-glutamyl kinase was more thermostable than the wild-type enzyme, which suggests that this mutation elevated the apparent activities of two enzymes through a stabilization of the complex. We next examined the gene dosage effect of three L-proline biosynthetic enzymes, including Delta(1)-pyrroline-5-carboxylate reductase, which converts Delta(1)-pyrroline-5-carboxylate into L-proline, on L-proline accumulation and freeze tolerance in a non-L-proline-utilizing strain. Overexpression of the wild-type enzymes has no influence on L-proline accumulation, which suggests that the complex is very unstable in nature. However, co-overexpression of the mutant gamma-glutamyl kinase and the wild-type gamma-glutamyl phosphate reductase was effective for L-proline accumulation, probably due to a stabilization of the complex. These results indicate that both enzymes, not Delta(1)-pyrroline-5-carboxylate reductase, are rate-limiting enzymes in yeast cells. A high tolerance for freezing clearly correlated with higher levels of L-proline in yeast cells. Our findings also suggest that, in addition to its cryoprotective activity, intracellular L-proline could protect yeast cells from damage by oxidative stress. The approach described here provides a valuable method for breeding novel yeast strains that are tolerant of both freezing and oxidative stresses.     

Effect of L-proline on sake brewing and ethanol stress in Saccharomyces cerevisiae

During the fermentation of sake, cells of Saccharomyces cerevisiae are exposed to high concentrations of ethanol, thereby damaging the cell membrane and functional proteins. L-proline protects yeast cells from damage caused by freezing or oxidative stress. In this study, we evaluated the role of intracellular L-proline in cells of S. cerevisiae grown under ethanol stress. An L-proline-accumulating laboratory strain carries a mutant allele of PRO1, pro1(D154N), which encodes the Asp154Asn mutant gamma-glutamyl kinase. This mutation increases the activity of gamma-glutamyl kinase and gamma-glutamyl phosphate reductase, which catalyze the first two steps of L-proline synthesis and which together may form a complex in vivo. When cultured in liquid medium in the presence of 9% and 18% ethanol under static conditions, the cell viability of the L-proline-accumulating laboratory strain is greater than the cell viability of the parent strain. This result suggests that intracellular accumulation of L-proline may confer tolerance to ethanol stress. We constructed a novel sake yeast strain by disrupting the PUT1 gene, which is required for L-proline utilization, and replacing the wild-type PRO1 allele with the pro1(D154N) allele. The resultant strain accumulated L-proline and was more tolerant to ethanol stress than was the control strain. We used the strain that could accumulate L-proline to brew sake containing five times more L-proline than what is found in sake brewed with the control strain, without affecting the fermentation profiles.     

Self-cloning baker's yeasts that accumulate proline enhance freeze tolerance in doughs

We constructed self-cloning diploid baker's yeast strains by disrupting PUT1, encoding proline oxidase, and replacing the wild-type PRO1, encoding gamma-glutamyl kinase, with a pro1(D154N) or pro1(I150T) allele. The resultant strains accumulated intracellular proline and retained higher-level fermentation abilities in the frozen doughs than the wild-type strain. These results suggest that proline-accumulating baker's yeast is suitable for frozen-dough baking.     

Gene-enzyme relationships in the proline biosynthetic pathway of Saccharomyces cerevisiae.

The PRO1, PRO2, and PRO3 genes were isolated by functional complementation of pro1, pro2, and pro3 (proline-requiring) strains of Saccharomyces cerevisiae. Independent clones with overlapping inserts were isolated from S. cerevisiae genomic libraries in YEp24 (2 microns) and YCp50 (CEN) plasmids. The identity of each gene was determined by gene disruption, and Southern hybridization and genetic analyses confirmed that the bona fide genes had been cloned. Plasmids containing each gene were introduced into known bacterial proline auxotrophs, and the ability to restore proline prototrophy was assessed. Interspecies complementation demonstrated that the S. cerevisiae PRO1 gene encoded gamma-glutamyl kinase, PRO2 encoded gamma-glutamyl phosphate reductase, and PRO3 encoded delta 1-pyrroline-5-carboxylate reductase. The presence of the PRO3 gene on a high-copy-number plasmid in S. cerevisiae caused a 20-fold overproduction of delta 1-pyrroline-5-carboxylate reductase. The PRO2 gene mapped on chromosome XV tightly linked to cdc66, and the PRO3 gene was located on the right arm of chromosome V between HIS1 and the centromere.     

Desensitization of feedback inhibition of the Saccharomyces cerevisiae gamma-glutamyl kinase enhances proline accumulation and freezing tolerance

In response to osmotic stress, proline is accumulated in many bacterial and plant cells as an osmoprotectant. The yeast Saccharomyces cerevisiae induces trehalose or glycerol synthesis but does not increase intracellular proline levels during various stresses. Using a proline-accumulating mutant, we previously found that proline protects yeast cells from damage by freezing, oxidative, or ethanol stress. This mutant was recently shown to carry an allele of PRO1 which encodes the Asp154Asn mutant gamma-glutamyl kinase (GK), the first enzyme of the proline biosynthetic pathway. Here, enzymatic analysis of recombinant proteins revealed that the GK activity of S. cerevisiae is subject to feedback inhibition by proline. The Asp154Asn mutant was less sensitive to feedback inhibition than wild-type GK, leading to proline accumulation. To improve the enzymatic properties of GK, PCR random mutagenesis in PRO1 was employed. The mutagenized plasmid library was introduced into an S. cerevisiae non-proline-utilizing strain, and proline-overproducing mutants were selected on minimal medium containing the toxic proline analogue azetidine-2-carboxylic acid. We successfully isolated several mutant GKs that, due to extreme desensitization to inhibition, enhanced the ability to synthesize proline better than the Asp154Asn mutant. The amino acid changes were localized at the region between positions 142 and 154, probably on the molecular surface, suggesting that this region is involved in allosteric regulation. Furthermore, we found that yeast cells expressing Ile150Thr and Asn142Asp/Ile166Val mutant GKs were more tolerant to freezing stress than cells expressing the Asp154Asn mutant.     

Desensitization of Feedback Inhibition of the Saccharomyces cerevisiae γ-Glutamyl Kinase Enhances Proline Accumulation and Freezing Tolerance

In response to osmotic stress, proline is accumulated in many bacterial and plant cells as an osmoprotectant. The yeast Saccharomyces cerevisiae induces trehalose or glycerol synthesis but does not increase intracellular proline levels during various stresses. Using a proline-accumulating mutant, we previously found that proline protects yeast cells from damage by freezing, oxidative, or ethanol stress. This mutant was recently shown to carry an allele of PRO1 which encodes the Asp154Asn mutant γ-glutamyl kinase (GK), the first enzyme of the proline biosynthetic pathway. Here, enzymatic analysis of recombinant proteins revealed that the GK activity of S. cerevisiae is subject to feedback inhibition by proline. The Asp154Asn mutant was less sensitive to feedback inhibition than wild-type GK, leading to proline accumulation. To improve the enzymatic properties of GK, PCR random mutagenesis in PRO1 was employed. The mutagenized plasmid library was introduced into an S. cerevisiae non-proline-utilizing strain, and proline-overproducing mutants were selected on minimal medium containing the toxic proline analogue azetidine-2-carboxylic acid. We successfully isolated several mutant GKs that, due to extreme desensitization to inhibition, enhanced the ability to synthesize proline better than the Asp154Asn mutant. The amino acid changes were localized at the region between positions 142 and 154, probably on the molecular surface, suggesting that this region is involved in allosteric regulation. Furthermore, we found that yeast cells expressing Ile150Thr and Asn142Asp/Ile166Val mutant GKs were more tolerant to freezing stress than cells expressing the Asp154Asn mutant.     

The gene-enzyme relationships of proline biosynthesis in Escherichia coli

A simple chromatographic procedure has been devised to separate gamma-glutamyl phosphate reductase and 1-pyrroline-5-carboxylate reductase, allowing the measurement of the former in crude Escherichia coli extracts. Analysis of a number of strains of E. coli has demonstrated that gene proA codes for gamma-glutamyl phosphate reductase and proB for gamma-glutamyl kinase. Introduction of a ColE1 hybrid plasmid containing the proA,B region into a strain with a chromosomal deletion of proA,B led to 3- and 17-fold increases in the specific activities of gamma-glutamyl kinase and gamma-glutamyl phosphate reductase, respectively.     

Proline biosynthesis in Saccharomyces cerevisiae: molecular analysis of the PRO1 gene, which encodes gamma-glutamyl kinase.

The PRO1 gene of Saccharomyces cerevisiae encodes the 428-amino-acid protein gamma-glutamyl kinase (ATP:L-glutamate 5-phosphotransferase, EC 2.7.2.11), which catalyzes the first step in proline biosynthesis. Amino acid sequence comparison revealed significant homology between the yeast and Escherichia coli gamma-glutamyl kinases throughout their lengths. Four close matches to the consensus sequence for GCN4 protein binding and one close match to the RAP1 protein-binding site were found in the PRO1 upstream region. The response of the PRO1 gene to changes in the growth medium was analyzed by measurement of steady-state mRNA levels and of beta-galactosidase activity encoded by a PRO1-lacZ gene fusion. PRO1 expression was not repressed by exogenous proline and was not induced by the presence of glutamate in the growth medium. Although expression of the PRO1 gene did not change in response to histidine starvation, both steady-state PRO1 mRNA levels and beta-galactosidase activities were elevated in a gcd1 strain and reduced in a gcn4 strain. In addition, a pro1 bradytrophic strain became completely auxotrophic for proline in a gcn4 strain background. These results indicate that PRO1 is regulated by the general amino acid control system.     

Biosynthesis of proline in Pseudomonas aeruginosa. Partial purification and characterization of gamma-glutamyl kinase.

A gamma-glutamyl kinase (ATP-L-glutamate 5-phosphotransferase) was purified about 85-fold from crude extracts of Pseudomonas aeruginosa strain PAO 1 by (NH4)2SO4 precipitation, molecular-sieving by Sephadex G-150 and DEAE-cellulose chromatography. The molecular weight of this enzyme was 84,000. The preparation catalysed formation of gamma-glutamyl hydroxamate from L-glutamate, ATP and Mg2+ or Mn2+ with concomitant hydrolysis of ATP to ADP + Pi. L-Proline inhibited the gamma-glutamyl kinase activity by 50% at 5 mM and almost completely at 30 mM. The inhibition of L-proline was non-competitive, wherease L-methionine-DL-sulphoximine inhibited the enzyme competitively. Proline was found to inhibit the gamma-glutamyl kinase activity of the wild-type strain and of representatives of two of the three transductional classes of proline-auxotrophic mutants. Strain PAO 879, a mutant representing the third transductional class of proline auxotrophs, lacked proline-inhibitible gamma-glutamyl kinase. Thiol-blocking reagents inhibited the gamma-glutamyl kinase and this effect was prevented by dithiothreitol.     

Activation of glutamate by gamma-glutamate kinase: formation of gamma-cis-cycloglutamyl phosphate, an analog of gamma-glutamyl phosphate

gamma-Glutamate kinase, the enzyme that catalyzes the first step in the pathway from glutamate to proline, has been postulated to convert glutamate to a gamma-activated form (possibly gamma-glutamyl phosphate), which is reduced by a NADPH-linked reductase to yield glutamate gamma-semialdehyde (in equilibrium with delta 1-pyrroline-5-carboxylate). In the present work we found that the kinase, in the absence or presence of the reductase (and in the absence of NADPH), catalyzes stoichiometric formation of 5-oxo-L-proline and Pi from L-glutamate and ATP, but catalyzes hydroxamate formation at only about 10% of the rate of ATP-cleavage. A new substrate of the kinase was found; thus, cis-cycloglutamate (cis-1-amino-1,3-dicarboxycyclohexane), a glutamate analog which cannot cyclize to form an analog of 5-oxoproline, interacts effectively with the kinase. The trans form of cycloglutamate does not interact with the kinase; only the cis form can assume a diequatorial conformation equivalent to the extended conformation of glutamate. cis-Cycloglutamyl phosphate formation was shown and evidence was obtained for formation of an enzyme-ADP-cycloglutamyl phosphate complex. Although cis-cycloglutamyl phosphate is not a reducible substrate of the NADPH-dependent reductase, the findings indicate that it interacts with the reductase. These studies, which elucidate several aspects of the mechanism of the utilization of glutamate for formation of delta 1-pyrroline-5-carboxylate, support the hypothesis that the kinase and reductase function as an enzyme complex. A model is suggested in which gamma-glutamyl phosphate formed on the kinase interacts with the reductase to form a gamma-glutamyl-reductase complex, which is reduced by NADPH to yield glutamate gamma-semialdehyde.     

Proline accumulation by mutation or disruption of the proline oxidase gene improves resistance to freezing and desiccation stresses in Saccharomyces cerevisiae

We examined the role of intracellular proline under freezing and desiccation stress conditions in Saccharomyces cerevisiae. When cultured in liquid minimal medium, the proline-nonutilizing mutant containing the put1 mutation (proline oxidase-deficient) produced more intracellular proline, and increased the cell survival rate as compared to the wild-type strain after freezing and desiccation. We also constructed two PUT1 gene disruptants. PUT1-disrupted mutants in minimal medium supplemented with external proline at 0.1% accumulated higher proline levels than those of the control strains (17-22-fold). These disruptants also had a 2-5-fold increase in cell viability compared to the control strains after freezing and desiccation stresses. These results indicate that proline has a stress-protective function in yeast.     

Self-Cloning Baker's Yeasts That Accumulate Proline Enhance Freeze Tolerance in Doughs

We constructed self-cloning diploid baker's yeast strains by disrupting PUT1, encoding proline oxidase, and replacing the wild-type PRO1, encoding γ-glutamyl kinase, with a pro1(D154N) or pro1(I150T) allele. The resultant strains accumulated intracellular proline and retained higher-level fermentation abilities in the frozen doughs than the wild-type strain. These results suggest that proline-accumulating baker's yeast is suitable for frozen-dough baking.     

Characterization of cyclic AMP-requiring yeast mutants altered in the catalytic subunit of protein kinase

The cyr2 mutant of yeast, Saccharomyces cerevisiae, required cAMP for growth at 35 degrees C. The cyr2 mutation was suppressed by the bcy1 mutation which resulted in deficiency of the regulatory subunit of cAMP-dependent protein kinase. The DEAE-Sephacel elution profile of cyr2 cAMP-dependent protein kinase was markedly different from that observed for the wild-type enzyme. With histone as substrate, the cAMP-dependent protein kinase activity of cyr2 cells showed 100-fold greater Ka value for activation by cAMP at 35 degrees C than that of the wild-type cells, while the Kd value for cAMP of the mutant enzyme was not altered. The electrophoretic character, molecular weight, and pI value of the regulatory subunit of the mutant enzyme were the same as those of the wild-type enzyme. When histone, trehalase, and glutamate dehydrogenase were used as substrate, the free catalytic subunit of the mutant enzyme showed a markedly decreased affinity for ATP and was more thermolabile compared to that of the wild-type enzyme. The results indicated that the cyr2 phenotype was produced by a structural mutation in the cyr2 gene coding for the catalytic subunit of cAMP-dependent protein kinase in yeast.     

Effects of thioredoxin reductase-1 deletion on embryogenesis and transcriptome

Thioredoxin reductases (Txnrd) maintain intracellular redox homeostasis in most organisms. Metazoan Txnrds also participate in signal transduction. Mouse embryos homozygous for a targeted null mutation of the txnrd1 gene, encoding the cytosolic thioredoxin reductase, were viable at embryonic day 8.5 (E8.5) but not at E9.5. Histology revealed that txnrd1-/- cells were capable of proliferation and differentiation; however, mutant embryos were smaller than wild-type littermates and failed to gastrulate. In situ marker gene analyses indicated that primitive streak mesoderm did not form. Microarray analyses on E7.5 txnrd-/- and txnrd+/+ littermates showed similar mRNA levels for peroxiredoxins, glutathione reductases, mitochondrial Txnrd2, and most markers of cell proliferation. Conversely, mRNAs encoding sulfiredoxin, IGF-binding protein 1, carbonyl reductase 3, glutamate cysteine ligase, glutathione S-transferases, and metallothioneins were more abundant in mutants. Many gene expression responses mirrored those in thioredoxin reductase 1-null yeast; however, mice exhibited a novel response within the peroxiredoxin catalytic cycle. Thus, whereas yeast induce peroxiredoxin mRNAs in response to thioredoxin reductase disruption, mice induced sulfiredoxin mRNA. In summary, Txnrd1 was required for correct patterning of the early embryo and progression to later development. Conserved responses to Txnrd1 disruption likely allowed proliferation and limited differentiation of the mutant embryo cells.     

Amino acid substitution of the largest subunit of yeast RNA polymerase II: effect of a temperature-sensitive mutation related to G1 cell cycle arrest

A mammalian temperature-sensitive mutant tsAF8 shows cell cycle arrest at nonpermissive temperatures in mid-G1 phase. DNA sequence comparison of the largest subunit of RNA polymerase II (Rpb1) from the wild-type and the mutant shows that the mutant phenotype results from a (hemizygous) C-to-A variation at nucleotide 944 in one rpb1 allele, giving rise to an Ala-to-Asp substitution at residue 315 in the protein. This amino acid substitution was introduced into the Schizosaccharomyces pombe rpb1 gene. Whereas tsAF8 cells showed growth defects and altered Rpb1 distribution at nonpermissive temperatures, yeast cells harboring this amino acid substitution did not show apparent temperature sensitivity. The effect of another temperature-sensitive Rpb1 mutation was also small. These results suggest that mutation of the rpb1 gene, which is critical in mammalian cells, may not be deleterious in yeast cells.     

Suppression of defective RAS1 and RAS2 functions in yeast by an adenylate cyclase activated by a single amino acid change.

We have constructed the yeast strain TS1, with the RAS2 gene replaced by mutant allele encoding a partially defective gene product, and with an inactive RAS1 gene. TS1 cells accumulate as unbudded cells upon temperature shift from 30 to 37 degrees C, thus showing that the RAS1 and RAS2 gene functions are important for progression through the G1 phase of the cell cycle. After the isolation of revertants able to grow at the nonpermissive temperature, we have found that a chromosomal point mutation can bypass the G1 arrest of TS1 and cdc25 cells, and the lethality of ras1 ras2 mutants. The mutation predicts the replacement of threonine by isoleucine at position 1651 of yeast adenylate cyclase. The RAS-independent, as well as the RAS-dependent adenylate cyclase activity, is increased by the mutation. Like the wild-type enzyme, the RAS-dependent activity of the mutant adenylate cyclase is turned on by the GTP-bound form of the RAS2 protein. The amino acid sequence surrounding the threonine 1651 shows similarity with protein kinase substrates. Possible implications for the function of adenylate cyclase are discussed.     

Yeast flavohemoglobin protects against nitrosative stress and controls ferric reductase activity

The role of Saccharomyces cerevisiae flavohemoglobin (Yhb1) is controversial and far from understood. This study compares the effects of nitrosative and oxidative challenge on the yeast mutant lacking the YHB1 gene. Growth of the mutant was impaired by nitrosoglutathione and peroxynitrite, whereas increased sensitivity to reactive oxygen species was not observed. Increased levels of intracellular NO(*) after incubation with NO(*) donors were found in the mutants cells as compared to the wild-type cells. Deletion of the YHB1 gene was found to augment the reduction of Fe(3+) by yeast cells which suggests that flavohemoglobin participates in regulation of the activity of plasma membrane ferric reductase(s).