An SSB encoded by and operating on linear killer plasmids from Kluyveromyces lactis.

The Kluyveromyces lactis linear plasmids k1 and k2 belong to the family of protein-primed linear DNA genomes, which includes adenoviruses. Here we identify the 18 kDa gene product of k2ORF5 as a novel putative single-stranded DNA binding protein, SSB. As judged from Western analysis using an epitope-tagged fusion protein and ssDNA-agarose affinity chromatography, the Orf5 protein preferentially binds to ssDNA in vitro. Consistently, electrophoretic mobility shift assays demonstrate that ssDNA plasmid probes from k1 and k2 are retarded by this Orf5-associated SSB activity. ORF5 gene shuffle-mediated mutagenesis in vivo results in k1/k2 plasmid instability, pointing towards a role for the Orf5 protein in plasmid replication. Consistently, the Orf5 protein protects ssDNA from exonuclease digestion and stimulates Klenow enzyme. Our findings suggest a functional role for the Orf5 protein as a putative SSB probably required during k1/k2 plasmid DNA synthesis.

Isolation and characterization of Saccharomyces cerevisiae mutants with derepressed thiamine gene expression.

Using a THI4-lacZ reporter gene, mutant strains have been isolated that display constitutive expression of thiamine genes in the presence of normally repressing levels of exogenous thiamine. In total, eight strains were isolated in which this derepressed expression on thiamine (Det(-)) phenotype was the result of single gene mutations. The Det(-) mutations of three of these strains were partially dominant in a heterozygous diploid configuration, whereas the other five were recessive. The partially dominant mutants DET1, DET12 and DET13, and the recessive mutant det2, all showed derepressed THI4-lacZ expression levels comparable to those of a fully induced normal strain. Use of other promoter-lacZ gene fusions revealed that these four mutants were pleiotropic; expression levels of all thiamine-regulated genes tested were also derepressed. Genetic analysis of the four mutants suggested that det2 and DET13 were allelic, whereas the others were at different loci; these four mutations therefore represent three different genes. None of the mutations were allelic with THI80, mutations of which have previously been shown to confer derepression on thiamine-regulated genes. Also, intracellular thiamine levels were close to normal and none of the four mutants excreted thiamine into the growth medium. All mutant strains were found to be prototrophic for thiamine and none of those tested were compromised for thiamine uptake. It is possible that some may be alleles of, or interact with, the activator gene THI3. Taken together, these results imply that DET1, det2, DET12 and DET13 represent new genes encoding negative regulators of thiamine-repressed genes.

Genetic manipulation of Kluyveromyces lactis linear DNA plasmids: gene targeting and plasmid shuffles.

Genetic manipulation of yeast linear DNA plasmids, particularly of k1 and k2 from the non-conventional dairy yeast Kluyveromyces lactis, has been advanced by the recent establishment of DNA transformation-mediated one-step gene disruption and allele replacement techniques. These methods provide the basis for a strategy for the functional analysis of plasmid genes and DNA elements. By use of double selection regimens, these single-gene procedures have been extended to effect disruption of individual genes on plasmid k2 and transplacement of a functional copy onto plasmid k1, resulting in the production of yeast strains with an altered plasmid composition. This cytoplasmic gene shuffle system facilitates the introduction of specifically modified alleles into k1 or k2 in order to study the function, expression (from UCS promoters) and regulation of cytoplasmic linear plasmid genes. Additionally, identification, characterization and localization of plasmid gene products of interest are made possible by shuffling GFP-, epitope- or affinity purification-tagged alleles between k2 and k1. The gene shuffle approach can also be used for vector development and heterologous protein expression in order to exploit the biotechnical potential of the K. lactis k1/k2 system in yeast cell factory research.

Thiamine repression and pyruvate decarboxylase autoregulation independently control the expression of the Saccharomyces cerevisiae PDC5 gene.

The Saccharomyces cerevisiae gene PDC5 encodes the minor isoform of pyruvate decarboxylase (Pdc). In this work we show that expression of PDC5 but not that of PDC1, which encodes the major isoform, is repressed by thiamine. Hence, under thiamine limitation both PDC1 and PDC5 are expressed. PDC5 also becomes strongly expressed in a pdc1delta mutant. Two-dimensional gel electrophoresis of whole protein extracts shows that thiamine limitation stimulates the production of THI gene products and of Pdc5p. Deletion of PDC1 only stimulates production of Pdc5p. We conclude that the stimulation of PDC5 expression in a pdc1delta mutant is not due to a response to thiamine limitation.

The RAG3 gene of Kluyveromyces lactis is involved in the transcriptional regulation of genes coding for enzymes implicated in pyruvate utilization and genes of the biosynthesis of thiamine pyrophosphate.

The RAG3 gene of Kluyveromyces lactis, a homolog of PDC2 of Saccharomyces cerevisiae, is known to be a regulator of the pyruvate decarboxylase gene KlPDC1. We have identified new target genes for Rag3p. The RAG3 gene product was found to be required for the transcription of two genes of the biosynthetic pathway of thiamine (a cofactor of pyruvate decarboxylase). Conversely, the RAG3 gene product partially repressed the expression of the pyruvate dehydrogenase gene KlPDA1. Therefore, RAG3 may act as a general regulator in the balance of the two alternative pathways of pyruvate metabolism in yeast.

Thiamin metabolism and thiamin diphosphate-dependent enzymes in the yeast Saccharomyces cerevisiae: genetic regulation.

The yeast Saccharomyces cerevisiae utilises external thiamin for the production of thiamin diphosphate (ThDP) or can synthesise the cofactor itself. Prior to uptake into the cell thiamin phosphates are first hydrolysed and thiamin is taken up as free vitamin which is then pyrophosphorylated by a pyrophosphokinase. Synthesis of ThDP starts with the production of hydroxyethylthiazole and hydroxymethylpyrimidine. Those are linked to yield thiamin phosphate which is hydrolysed to thiamin and subsequently pyrophosphorylated. The THI genes encoding the enzymes of these final steps of ThDP production and of thiamin utilisation have been identified. Their expression is controlled by the level of thiamin and a number of regulatory proteins involved in regulated expression of the THI genes are known. However, the molecular details of the regulatory circuits need to be deciphered. Since the nucleotide sequence of the entire yeast genome is known we can predict the number of ThDP-dependent enzymes in S. cerevisiae. Eleven such proteins have been found: pyruvate decarboxylase (Pdc, three isoforms), acetolactate synthase, a putative alpha-ketoisocaproate decarboxylase with a regulatory role in ThDP synthesis and two proteins of unknown function form the group of Pdc related enzymes. In addition there are two isoforms for transketolase as well as the E1 subunits of pyruvate dehydrogenase and 2-oxoglutarate dehydrogenase. Expression of most of these genes is either induced or repressed by glucose. Surprisingly, it has been found recently that expression of one of the genes for Pdc is repressed by thiamin. In addition, the regulatory protein Pdc2p was shown to be required for high level expression of both the THI and the PDC genes. Apparently, the production of ThDP and of the enzymes using this cofactor is coordinately regulated. Future research will focus on the elucidation of the molecular mechanisms of this novel type of regulation.

Dual role for the yeast THI4 gene in thiamine biosynthesis and DNA damage tolerance.

The THI4 gene of Saccharomyces cerevisiae encodes an enzyme of the thiamine biosynthetic pathway. The plant homolog thi1, from Arabidopsis thaliana, is also involved in thiamine biosynthesis; but was originally cloned due to its capacity to complement DNA repair deficient phenotypes in Escherichia coli. Here, the behavior of a thi4 disrupted strain was examined for increased sensitivity to treatment with the DNA damaging agents ultraviolet radiation (UV, 254 nm) and methyl methanesulfonate (MMS). Although the thi4 null mutant showed a similar level of survival as the wild-type strain, a higher frequency of respiratory mutants was induced by the two treatments. A similar phenotype was seen with wild-type strains expressing an antisense THI4 construct. Further analysis of respiratory mutants revealed that these were due to mutations of mitochondrial DNA (mtDNA) rather than nuclear DNA, consisting of rho-petite mutants. Moreover, the frequency of mutations was unaffected by the presence or absence of thiamine in the growth medium, and the defect leading to induction of petites in the thi4 mutant was corrected by expression of the Arabidopsis thi1 gene. Thus, Thi4 and its plant homolog appear to be dual functional proteins with roles in thiamine biosynthesis and mitochondrial DNA damage tolerance.

ORF7 of yeast plasmid pGKL2: analysis of gene expression in vivo.

ORF7 of Kluyveromyces lactis killer plasmid pGKL2 (k2) is capable of encoding a putative RNA polymerase subunit of 16 kDa. RNA analysis detected a single, plasmid-dependent ORF7 transcript of 550 nt indicating that the gene is transcribed mono-cistronically. Attempted one-step gene disruption of ORF7 resulted in chromosomal integration of the marker gene rather than the formation of stable recombinant k2ORF7(0) deletion plasmids. Thus, ORF7 appears to be a potential cis-dominant locus the integrity of which is indispensable for plasmid stability. The ORF7 gene product was over-produced as a c-myc-tagged fusion protein in Escherichia coli. Western-blot analysis of total yeast protein extracts using an antibody against this Orf7-c-myc fusion product identified a protein band with an apparent molecular weight of 17 kDa. This protein corresponds in size to the predicted product and is only detectable in plasmid-carrying killer yeasts.

Identification of agthi1, whose product is involved in biosynthesis of the thiamine precursor thiazole, in actinorhizal nodules of Alnus glutinosa.

A cDNA clone, pAgthi1, encoding a homologue of yeast Thi4, which is involved in thiazole biosynthesis, was isolated from a library made from poly(A) RNA from actinorhizal nodules of Alnus glutinosa by differential screening with nodule and root cDNA, respectively. The corresponding gene, agthi1, was shown to be expressed at high levels in nodules and shoot tips of A. glutinosa, while having low expression levels in roots, flowers, and developing fruits. The function of AgThi1 was demonstrated by yeast complementation studies, in which AgThi1 was able to rescue a yeast thi4 mutant when fused to the yeast Thi4 signal peptide. In A. glutinosa nodules, high levels of agthi1 mRNA were detected in the infected cortical cells and in the pericycle of the nodule vascular system. A homologue of this cDNA, ara6/tz, was identified in Arabidopsis thaliana. ara6 maps in a region of chromosome 5 of Arabidopsis containing the tz locus which is consistent with the fact that ara6 transcription is disturbed in two tz mutant lines. ara6/tz is expressed at high levels in chloroplast-containing parenchymatic cells of leaves, inflorescence shoots and flowers of Arabidopsis, and at lower levels in the vascular system.

Thi1, a thiamine biosynthetic gene in Arabidopsis thaliana, complements bacterial defects in DNA repair.

An Arabidopsis thaliana cDNA was isolated by complementation of the Escherichia coli mutant strain BW535 (xth, nfo, nth), which is defective in DNA base excision repair pathways. This cDNA partially complements the methyl methane sulfonate (MMS) sensitive phenotype of BW535. It also partially corrects the UV-sensitive phenotype of E. coli AB1886 (uvrA) and restores its ability to reactivate UV-irradiated lambda phage. It has an insert of ca. 1.3 kb with an open reading frame of 1047 bp (predicting a protein with a molecular mass of 36 kDa). This cDNA presents a high homology to a stress related gene from two species of Fusarium (sti35) and to genes whose products participate in the thiamine biosynthesis pathway, THI4, from Saccharomyces cerevisiae and nmt2 from Schizosaccharomyces pombe. The Arabidopsis predicted polypeptide has homology to several protein motifs: amino-terminal chloroplast transit peptide, dinucleotide binding site, DNA binding and bacterial DNA polymerases. The auxotrophy for thiamine in the yeast thi4::URA3 disruption strain is complemented by the Arabidopsis gene. Thus, the cloned gene, named thi1, is likely to function in the biosynthesis of thiamine in plants. The data presented in this work indicate that thi1 may also be involved in DNA damage tolerance in plant cells.

Yeast killer plasmid pGKL2: molecular analysis of UCS5, a cytoplasmic promoter element essential for ORF5 gene function.

A k2/k1 plasmid gene shuffle system has been used to investigate linear plasmid promoter function in Kluyveromyces lactis. By transplacing various ORF5 deletion constructs from the larger plasmid k2 onto k1, and analysing trans-complementation of an ORF5(0) deletion on k2, a 40 bp k2 fragment, including the UCS motif of ORF5 (UCS5), has been identified as a cis-acting promoter element essential for ORF5 gene function. Qualitative and quantitative transcript analyses of a UCS5-ScLEU2 fusion gene using Northern blot analysis and phosphor image technology revealed a plasmid-dependent LEU2 transcript distinct in size (1.55 kb) and regulation from its nuclear counterpart (1.35 kb): cytoplasmic, UCS5-driven expression of the marker gene was non-repressible by leucine and reduced five- to eight-fold compared to fully derepressed nuclear K1LEU2 mRNA levels. Thus, the killer plasmids k2 and k1 appear to express low levels of transcript overall, when relative gene copy numbers (one for the nuclear allele versus 50-100 copies for the plasmid-borne LEU2 gene) are taken into account.

A cytoplasmic gene-shuffle system in Kluyveromyces lactis: use of epitope tagging to detect a killer plasmid-encoded gene product.

A novel gene shuffle approach has been developed for investigating the functions of genes on the cytoplasmic linear DNA killer plasmids of Kluyveromyces lactis. By transplacing k2ORF5 from larger plasmid pGKL2(k2) onto pGKL1(k1) we have shown this gene to be essential and functionally interchangeable between plasmids. Once transferred onto k1, k2ORF5 is fully able to complement a k2ORF5(0) deletion on k2 in trans, giving rise to yeast strains containing only the two recombinant plasmid forms. Additionally, the in vivo product of k2ORF5 has been identified as a 19.5 kDa protein by transplacing an epitope-tagged k2ORF5 allele from k2 to k1. The ease of detection of the tagged ORF5 product in comparison to TRF1, the gene product of k2ORF10, indicates that Orf5p is one of the most abundant k2 products, implying structural rather than regulatory function.

The Saccharomyces cerevisiae HSP12 gene is activated by the high-osmolarity glycerol pathway and negatively regulated by protein kinase A.

The HSP12 gene encodes one of the two major small heat shock proteins of Saccharomyces cerevisiae. Hsp12 accumulates massively in yeast cells exposed to heat shock, osmostress, oxidative stress, and high concentrations of alcohol as well as in early-stationary-phase cells. We have cloned an extended 5'-flanking region of the HSP12 gene in order to identify cis-acting elements involved in regulation of this highly expressed stress gene. A detailed analysis of the HSP12 promoter region revealed that five repeats of the stress-responsive CCCCT motif (stress-responsive element [STRE]) are essential to confer wild-type induced levels on a reporter gene upon osmostress, heat shock, and entry into stationary phase. Disruption of the HOG1 and PBS2 genes leads to a dramatic decrease of the HSP12 inducibility in osmostressed cells, whereas overproduction of Hog1 produces a fivefold increase in wild-type induced levels upon a shift to a high salt concentration. On the other hand, mutations resulting in high protein kinase A (PKA) activity reduce or abolish the accumulation of the HSP12 mRNA in stressed cells. Conversely, mutants containing defective PKA catalytic subunits exhibit high basal levels of HSP12 mRNA. Taken together, these results suggest that HSP12 is a target of the high-osmolarity glycerol (HOG) response pathway under negative control of the Ras-PKA pathway. Furthermore, they confirm earlier observations that STRE-like sequences are responsive to a broad range of stresses and that the HOG and Ras-PKA pathways have antagonistic effects upon CCCCT-driven transcription.

The DNA and RNA polymerase genes of yeast plasmid pGKL2 are essential loci for plasmid integrity and maintenance.

Novel recombinant plasmids derived from the Kluyveromyces lactis killer plasmid k2 have been constructed to study plasmid biology and gene function. In vivo recombination between native resident k2 and suitable disruption vectors, employing the KITRP1 gene fused to a plasmid promoter as selection marker, yielded ORF2 and ORF6 deletion plasmids at high frequencies. As judged from Southern hybridization and plasmid restriction mapping analyses, these novel hybrids, termed rk2/2 and rk2/6, respectively, carry deletions in their putative DNA (ORF2) and RNA (ORF6) polymerase structural genes with central regions replaced by the input marker DNA. Long-term selection for TRP1 over 350 generations of growth did not favour maintenance of hybrids over wild-type k2. Thus, neither rk2/2 nor rk2/6 was fully functional and able to displace parental k2, indicating that both target genes are essential for plasmid integrity or maintenance. Recombinant plasmids were reduced in copy number relative to k2 with rk2/2 more drastically affected than rk2/6 implying a direct involvement of the ORF2 product in plasmid replication and an indirect maintenance function for the ORF6 gene product.

Kluyveromyces lactis killer plasmid pGKL2: molecular analysis of an essential gene, ORF5.

The ORF5 of Kluyveromyces lactis killer plasmid pGKL2 (k2) is capable of encoding a small neutral protein of 18 kDa of as yet unassigned function. Although this ORF is located between two larger ORFs, 4 and 6, which it overlaps, RNA analysis showed that it is transcribed monocistronically. One-step gene disruption of ORF5, via in vivo homologous recombination between native plasmid k2 and a transfer vector employing the Saccharomyces cerevisiae LEU2 gene fused to the k2 UCS5 element, yielded Leu+ transformants at high frequencies. The transformants were found to carry a new recombinant form of k2 with ORF5 replaced by the LEU2 marker, termed rk2, in addition to the wild-type plasmids k1 and k2. Northern analysis detected a plasmid-dependent LEU2 transcript distinct in size and regulation from its nuclear counterpart. Recombinant plasmid, rk2, was unable to displace native k2 during Leu+ selective growth; however rk2 was displaced by k2 during non-selective growth. Thus, ORF5 appears to be an essential gene for plasmid integrity and/or maintenance. The ORF5 product was detected by over-expression of an epitope-tagged allele in the baculovirus system. Western analysis using a monoclonal antibody specific for the epitope tag identified a protein band with apparent molecular weight of 20 kDa, corresponding in size to the predicted product.

Induction of major heat-shock proteins of Saccharomyces cerevisiae, including plasma membrane Hsp30, by ethanol levels above a critical threshold.

Many of the changes induced in yeast by sublethal yet stressful amounts of ethanol are the same as those resulting from sublethal heat stress. They include an inhibition of fermentation, increased induction of petites and stimulation of plasma membrane ATPase activity. Ethanol, at concentrations (4-10%, v/v) that affect growth and fermentation rates, is also a potent inducer of heat-shock proteins including those members of the Hsp70 protein family induced by heat shock. This induction occurs above a threshold level of about 4% ethanol, although different heat-shock proteins and heat-shock gene promoters are optimally induced at different higher ethanol levels. In addition ethanol (6-8%) causes the same two major changes to integral plasma-membrane protein composition that result from a sublethal heat stress, reduction in levels of the plasma membrane ATPase protein and acquisition of the plasma membrane heat-shock protein Hsp30.

Regulation of THI4 (MOL1), a thiamine-biosynthetic gene of Saccharomyces cerevisiae.

THI4, a Saccharomyces cerevisiae gene originally identified as a result of transient expression in molasses medium and named MOL1 is regulated by thiamine. Using a THI4 promoter-lacZ fusion on a centromeric yeast vector, we have shown that the THI4 is completely repressed throughout batch culture by thiamine at a concentration around 1 microM, but shows high level constitutive expression in thiamine-free medium. The transient expression pattern observed in molasses medium can be mimicked by the addition of 0.15 microM-thiamine to defined minimal medium. Cells grown in thiamine-free medium have an intracellular thiamine concentration of around 9 pmol/10(7) cells. A low level (1 microM) of exogenous thiamine is completely sequestered from the medium within 30 min; intracellular thiamine concentrations rise rapidly, followed by a gradual decrease as a result of dilution during growth. A saturating extracellular level of thiamine leads to a maximal intracellular concentration of around 1600 pmol/10(7) cells, at which point the transport system is shut down. After transfer from repressing to non-repressing medium, THI4 becomes induced when the intracellular concentration of thiamine falls to 20 pmol/10(7) cells. A thi4::URA3 disruption strain is auxotrophic for thiamine, but can grow in the presence of hydroxyethyl thiazole, indicating that the gene product is involved in the biosynthetic pathway leading to the formation of the thiazole precursor of thiamine.

MOL1, a Saccharomyces cerevisiae gene that is highly expressed in early stationary phase during growth on molasses.

We have isolated a new Saccharomyces cerevisiae gene, MOL1, that is transiently expressed at high levels in the early stationary phase of batch cultures growing on industrial molasses medium. The DNA sequence of the MOL1 gene (for MOLasses-inducible) with its flanking regions was determined (EMBL accession number X61669). It encodes a polypeptide of M(r) 35 kDa that is closely related to stress-inducible proteins of similar size from two Fusarium species. Unlike ST135 of Fusarium, MOL1 is not induced by ethanol or heat shock. MOL1 expression is absent in rich (YP) medium, and only very low levels of expression are detectable in minimal (YNB) medium. The gene is not essential, and a MOL1 disruption strain showed no apparent phenotype under a variety of growth conditions. The 5' region of MOL1 contains the complete sequence previously determined for the SUF4 locus, encoding a tRNA-gly (UCC) gene, which has been mapped to chromosome VII.

HSP12, a new small heat shock gene of Saccharomyces cerevisiae: analysis of structure, regulation and function.

We have isolated a new small heat shock gene, HSP12, from Saccharomyces cerevisiae. It encodes a polypeptide of predicted Mr 12 kDa, with structural similarity to other small heat shock proteins. HSP12 gene expression is induced several hundred-fold by heat shock and on entry into stationary phase. HSP12 mRNA is undetectable during exponential growth in rich medium, but low levels are present when cells are grown in minimal medium. Analysis of HSP12 expression in mutants affected in cAMP-dependent protein phosphorylation suggests that the gene is regulated by cAMP as well as heat shock. A disruption of the HSP12 coding region results in the loss of an abundant 14.4 kDa protein present in heat shocked and stationary phase cells. It also leads to the induction of the heat shock response under conditions normally associated with low-level HSP12 expression. The HSP12 disruption has no observable effect on growth at various temperatures, nor on the ability to acquire thermotolerance.