Evidence for Positive Regulation of the Proline Utilization Pathway in Saccharomyces cerevisiae

A mutation has been identified that prevents Saccharomyces cerevisiae cells from growing on proline as the sole source of nitrogen, causes noninducible expression of the PUT1 and PUT2 genes, and is completely recessive. In the put3-75 mutant, the basal level of expression (ammonia as nitrogen source) of PUT1-lacZ and PUT2-lacZ gene fusions as measured by beta-galactosidase activity is reduced 4- and 7-fold, respectively, compared with the wild-type strain. Normal regulation is not restored when the cells are grown on arginine as the sole nitrogen source and put3-75 cells remain sensitive to the proline analog, L-azetidine-2-carboxylic acid, indicating that the block is not at the level of transport of the inducer, proline. In a cross between the put3-75 strain and the semidominant, constitutive mutation PUT3c-68, only parental ditype tetrads were found, indicating allelism of the two mutations. Further support for allelism derives from the comparison of enzyme levels in heteroallelic and heterozygous diploid strains. The constitutive allele appears to be fully dominant to the noninducible allele but only partially dominant to the wild type, suggesting an interaction between the wild-type and PUT3c-68 gene products. The PUT3 gene maps on chromosome XI, about 5.7 cM from the centromere. The phenotypes of alleles of the PUT3 gene, either recessive and noninducible (the put3-75 phenotype) or semidominant and constitutive (the PUT3c-68 phenotype), and their pleiotropy suggest that the PUT3 gene product is a positive activator of the proline utilization pathway.     

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.     

Proline utilization in Saccharomyces cerevisiae: analysis of the cloned PUT2 gene.

The PUT2 gene was isolated on a 6.5-kilobase insert of a recombinant DNA plasmid by functional complementation of a put2 (delta 1-pyrroline-5-carboxylate dehydrogenase-deficient) mutation in Saccharomyces cerevisiae. Its identity was confirmed by a gene disruption technique in which the chromosomal PUT2+ gene was replaced by plasmid DNA carrying the put2 gene into which the S. cerevisiae HIS3+ gene had been inserted. The cloned PUT2 gene was used to probe specific mRNA levels: full induction of the PUT2 gene resulted in a 15-fold increase over the uninduced level. The PUT2-specific mRNA was approximately 2 kilobases in length and was used in S1 nuclease protection experiments to locate the gene to a 3-kilobase HindIII fragment. When delta 1-pyrroline-5-carboxylate dehydrogenase activity levels were measured in strains carrying the original plasmid, as well as in subclones, similar induction ratios were found as compared with enzyme levels in haploid yeast strains. Effects due to increased copy number or position were also seen. The cloned gene on a 2 mu-containing vector was used to map the PUT2 gene to chromosome VIII.     

Improving freeze-tolerance of baker’s yeast through seamless gene deletion of <Emphasis Type="Italic">NTH1</Emphasis> and <Emphasis Type="Italic">PUT1</Emphasis>

Baker’s yeast strains with freeze-tolerance are highly desirable to maintain high leavening ability after freezing. Enhanced intracellular concentration of trehalose and proline in yeast is linked with freeze-tolerance. In this study, we constructed baker’s yeast with enhanced freeze-tolerance by simultaneous deletion of the neutral trehalase-encoded gene NTH1 and the proline oxidase-encoded gene PUT1. We first used the two-step integration-based seamless gene deletion method to separately delete NTH1 and PUT1 in haploid yeast. Subsequently, through two rounds of hybridization and sporulation-based allelic exchange and colony PCR-mediated tetrad analysis, we obtained strains with restored URA3 and deletion of NTH1 and/or PUT1. The resulting strain showed higher cell survival and dough-leavening ability after freezing compared to the wild-type strain due to enhanced accumulation of trehalose and/or proline. Moreover, mutant with simultaneous deletion of NTH1 and PUT1 exhibits the highest relative dough-leavening ability after freezing compared to mutants with single-gene deletion perhaps due to elevated levels of both trehalose and proline. These results verified that it is applicable to construct frozen dough baker’s yeast using the method proposed in this paper.     

Mutational analysis of upstream activation sequence 2 of the CYC1 gene of Saccharomyces cerevisiae: a HAP2-HAP3-responsive site.

We analyzed upstream activation sequence 2 (UAS2), one of two independent UAS elements in the CYC1 gene of Saccharomyces cerevisiae. Deletions and linker scanning mutations across the 87 base pairs previously defined as UAS2 showed two separate functional elements required for full activity. Region 1, from -230 to -200, contains the principal activation site and responds to the trans-acting regulatory loci HAP2 and HAP3. A portion of region 1 is homologous to two other HAP2-HAP3-responsive UASs and includes the G----A transition mutation UP1, which increases UAS2 activity. This consensus sequence TNATTGGT bears striking similarity to several CAAT box sequences of higher cells. Region 2, from -192 to -178, substantially enhances the activity of region 1, yet has little activity by itself. These regions bind distinct proteins found in crudely fractionated yeast extracts.     

Activation of the Klebsiella pneumoniae nifU promoter: identification of multiple and overlapping upstream NifA binding sites.

The Klebsiella pneumoniae nifU promoter is positively controlled by the NifA protein and requires a form of RNA polymerase holoenzyme containing the rpoN encoded sigma factor, sigma 54. Occupancy of the K. pneumoniae nifU promoter by NifA was examined using in vivo dimethyl sulphate footprinting. Three binding sites for NifA (Upstream Activator Sequences, UASs 1, 2 and 3) located at -125, -116 and -72 were identified which conform to the UAS consensus sequence TGT-N10-ACA. An additional NifA binding site was identified at position -90. The UASs located at -125 (UAS1) and -116 (UAS2) overlap and do not appear to bind NifA as independent sites. They may represent a NifA binding site interacting with two NifA dimers. UAS3 is located at -72, and abuts a binding site for integration host factor (IHF) and is not normally highly occupied by NifA. In the absence of IHF UAS3 showed increased occupancy by NifA. Mutational and footprinting analysis of the three UASs indicates (1) IHF and NifA can compete for binding and that this competition influences the level of expression from the nifU promoter (2) that UAS2 is a principle sequence of the UAS 1,2 region required for activation and (3) that none of the NifA binding sites interacts with NifA independently. In vivo KMnO4 footprinting demonstrated that NifA catalyses open complex formation at the nifU promoter. IHF was required for maximal expression from the nifU and nifH promoters in Escherichia coli, and for the establishment of a Nif+ phenotype in E. coli from the nif plasmid pRD1.     

Amino-terminal fragments of delta 1-pyrroline-5-carboxylate dehydrogenase direct beta-galactosidase to the mitochondrial matrix in Saccharomyces cerevisiae.

delta 1-Pyrroline-5-carboxylate (P5C) dehydrogenase, the second enzyme in the proline utilization (Put) pathway of Saccharomyces cerevisiae and the product of the PUT2 gene, was localized to the matrix compartment by a mitochondrial fractionation procedure. This result was confirmed by demonstrating that the enzyme had limited activity toward an externally added substrate that could not penetrate the inner mitochondrial membrane (latency). To learn more about the nature of the import of this enzyme, three gene fusions were constructed that carried 5'-regulatory sequences through codons 14, 124, or 366 of the PUT2 gene ligated to the lacZ gene of Escherichia coli. When these fusions were introduced into S. cerevisiae either on multicopy plasmids or stably integrated into the genome, proline-inducible beta-galactosidase was made. The shortest gene fusion, PUT2-lacZ14, caused the production of a high level of beta-galactosidase that was found exclusively in the cytoplasm. The PUT2-lacZ124 and PUT2-lacZ366 fusions made lower levels of beta-galactosidases that were mitochondrially localized. Mitochondrial fractionation and protease-protection experiments showed that the PUT2-lacZ124 hybrid protein was located exclusively in the matrix, while the PUT2-lacZ366 hybrid was found in the matrix as well as the inner membrane. Thus, the amino-terminal 124 amino acids of P5C dehydrogenase carries sufficient information to target and deliver beta-galactosidase to the matrix compartment. The expression of the longer hybrids had deleterious effects on cell growth; PUT2-lacZ366-containing strains failed to grow on proline as the sole source of nitrogen. In the presence of the longest hybrid beta-galactosidase, the wild-type P5C dehydrogenase was still properly localized in the matrix compartment, but its activity was reduced. The nature of the effects of these hybrid proteins on cell growth is discussed.