New insights into galactose metabolism by Schizosaccharomyces pombe: isolation and characterization of a galactose-assimilating mutant

The fission yeast Schizosaccharomyces pombe cannot use galactose as a carbon or energy source, and little is known about galactose metabolism in this species. Here we report isolation of a galactose-assimilating mutant that grows on a medium containing galactose as a sole carbon source through use of a proofreading-deficient DNA polymerase δ variant encoded by cdc6-1. Based on comparative analysis of gene expression profiles in the wild-type and the mutant (FG2-8), we found that SPBPB2B2.10c (gal7+), SPBPB2B2.12c (gal10+) and SPBPB2B2.13 (gal1+), homologous to Saccharomyces cerevisiae GAL7, GAL10 and GAL1, respectively, and SPBPB2B2.08, SPBPB2B2.09c, and SPBPB2B2.11 that localize close to the gal genes, were highly expressed and dramatically induced by addition of galactose. The gal7Δ strain, carrying an integrated ura4+ marker at the gal7+ locus, grew on 5-fluoroorotic acid (5-FOA)-containing medium. In contrast, the FG2-8 gal7Δ strain could not grow on 5-FOA medium. In addition, expression of gal7+, SPBPB2B2.13, gal10+ and gal1+ genes increased in the wild-type strain when carried on a vector, and these transformants grew on galactose medium. We suggest that gal7+, gal10+, and gal1+ are localized close to a chromosomal terminal repressed by gene silencing in S. pombe. In contrast, gene silencing was defective in the FG2-8 strain making galactose assimilation possible.     

Effect of ethanol on the production of carboxypeptidase Y using the GAL10 promoter in a Saccharomyces cerevisiae gal80 mutant

In the course of studying carboxypeptidase Y (CPY) production, we found that the expression level of the gene, which is under the control of the GAL10 promoter, increased in a Saccharomyces cerevisiae gal80 mutant grown in a medium containing ethanol as the sole carbon source. In the cultivation of the gal80 mutant KS58-2D/pCY303 carrying a multicopy plasmid, which contains the PRC1 gene fused to the GAL10 promoter, CPY production continued after the consumption of galactose. In this phase, the cells utilized ethanol as the carbon source. To increase the CPY production level, we examined the effect of carbon source feeding in a fed-batch culture. The production level in the fed-batch culture using ethanol was 1.3-fold higher than that in a batch culture and 1.6-fold higher than that in a fed-batch culture using galactose. By 5'-deletion analysis of the GAL10 promoter, the region between -256 and -232 was found to be important for the promoter activity in the gal80 mutant growing in the presence of ethanol.     

Construction of recombinant sake yeast containing a dominant FAS2 mutation without extraneous sequences by a two-step gene replacement protocol

A novel two-step gene replacement protocol was developed to construct a recombinant industrial yeast free of bacterial and drug-resistant marker sequences. A yeast strain exhibiting cerulenin resistance conferred by a dominant mutation of FAS2 was previously shown to produce high levels of a flavor component of Japanese sake. A N- and C-terminally truncated portion of the mutant FAS2 gene was subcloned to an integrating plasmid containing an aureobasidin A-resistant transformation marker and a galactose-inducible growth inhibitory sequence (GAL10p::GIN11). The plasmid was targeted into the chromosomal FAS2 locus of sake yeast Kyokai no. 7, resulting in a tandem repeat of inactive FAS2 sequences surrounding the integrated plasmid sequences. Cells containing the integrated plasmid were unable to grow on galactose medium due to the inhibitory effect of GAL10p::GIN11. This growth inhibition allowed efficient counter-selection for cells that had undergone homologous recombination between the FAS2 repeats by their growth on galactose medium. This recombination event resulted in loss of the integrated plasmid sequences and the resulting strains should contain a single copy of either wild-type or cerulenin-resistant FAS2. The selected cerulenin-resistant strains produced approximately 3.7-fold more ethyl caproate, a flavor component, than the Kyokai no. 7 strain. Southern blot and sequence analyses confirmed the presence of the FAS2 mutation and the absence of integrated plasmid sequences in the genome of the selected strain. This gene replacement method provides a straightforward approach for the construction of recombinant industrial yeasts free of undesirable DNA sequences.     

Over-expression of Candida albicans mitochondrial ribosomal protein S9 (MrpS9p) disturbs mitochondrial function in Saccharomyces cerevisiae

A Candida albicans mitochondrial ribosomal protein S9 (MRPS9) cDNA was identified in a screen for sequences whose expression induce galactose lethality in Saccharomyces cerevisiae. MRPS9 appears to encode a protein of 346 amino acids with an N-terminal mitochondrial targeting sequence and an internal S9 signature that is conserved amongst eukaryotic mitochondrial and prokaryotic ribosomal protein S9 sequences. Expression of a GAL1-CaMRPS9 fusion in S. cerevisiae caused the slow development of a galactose-negative phenotype upon repeated subculturing, and this correlated with an increased frequency of petite mutant formation. Therefore, over-expression of CaMRPS9 interferes with S. cerevisiae mitochondrial function, which accounts for the inhibition of growth on galactose.     

A positive selection for plasmid loss in Saccharomyces cerevisiae using galactose-inducible growth inhibitory sequences

Counter-selections for the loss of introduced plasmid sequences are useful for gene manipulations in yeast. We have used GAL10 promoter-mediated overexpression of GIN sequences, which inhibit the growth of cells, to develop a novel counter-selection system. Yeast cells carrying a GIN sequence grow normally on glucose medium but are unable to grow on galactose medium, whereas derivatives that have lost the GIN sequence are able to grow in the presence of galactose. We constructed autonomously replicating, integrating, and disruption plasmids carrying GIN sequences and tested their use to select for loss of the plasmid. The results showed that the GIN sequences provide a selection for efficient loss of plasmids or integrated constructs from yeast during growth on galactose medium, indicating that this system can be used for plasmid shuffling, gene replacements and marker gene recycling. This counter-selection system has wide application, because any Gal+ strain and a wide variety of marker genes can be used. In addition, counter-selection systems using growth-inhibitory sequences should be applicable to other yeasts and possibly to other organisms.     

A two-step cloning-free PCR-based method for the deletion of genes in the opportunistic pathogenic yeast Candida lusitaniae

We describe a new cloning-free strategy to delete genes in the opportunistic pathogenic yeast Candida lusitaniae. We first constructed two ura3 Δ strains in C. lusitaniae for their use in transformation experiments. One was deleted for the entire URA3 coding sequence; the other possessed a partial deletion within the coding region, which was used to determine the minimum amount of homology required for efficient homologous recombination by double crossing-over of a linear DNA fragment restoring URA3 expression. This amount was estimated to 200 bp on each side of the DNA fragment. These data constituted the basis of the development of a strategy to construct DNA cassettes for gene deletion by a cloning-free overlapping PCR method. Two cassettes were necessary in two successive transformation steps for the complete removal of a gene of interest. As an example, we report here the deletion of the LEU2 gene. The first cassette was constituted by the URA3 gene flanked by two large fragments (500 bp) homologous to the 5' and 3' non-coding regions of LEU2. After transformation of an ura3 Δ recipient strain and integration of the cassette at the LEU2 locus, the URA3 gene was removed by a second transformation round with a DNA cassette made by the fusion between the 5' and 3' non-coding regions of the LEU2 gene. The overall procedure takes less than 2 weeks and allows the creation of a clean null mutant that retains no foreign DNA sequence integrated in its genome.     

Sets of integrating plasmids and gene disruption cassettes containing improved counter-selection markers designed for repeated use in budding yeast

Counter-selection is a useful gene manipulation technique for repeated gene disruptions, gene shufflings and gene replacements in yeasts. We developed a novel counter-selection system using a galactose-inducible growth inhibitory sequence (Kawahata et al.1999. Yeast 15: 1-10). This counter-selection marker, named GAL10p-GIN11, has several advantages over previous counter-selection markers, i.e. use of an inexpensive galactose medium for counter-selection, combined use with any transformation markers for gene introduction, and no requirement of specific mutations in the host strains. The GIN11 sequence, which is a part of an X-element of the subtelomeric regions, contained a conserved autonomously replicating sequence, causing the possibility of inefficient chromosomal integration. We isolated GIN11 mutants that lost the replication activity but retained the growth-inhibitory effect when overexpressed. A mutant GIN11M86 sequence was selected and fused to the CUP1 promoter for the counter-selection on a copper-containing medium. The GALp-GIN11M86 and the CUPp-GIN11M86 were used for constructing sets of integrating plasmids containing auxotrophic markers involving HIS3, TRP1, LEU2, URA3 or ADE2, or a drug-resistant marker PGKp-YAP1. In addition, a set of gene disruption cassettes that contained each of the auxotrophic markers and the GALp-GIN11M86, which were flanked by direct repeats of a hisG sequence, were constructed. The counter-selectable integrating plasmids and the gene disruption cassettes can allow the markers to be used repeatedly for yeast gene manipulations.     

Characterization of different promoters for designing a new expression vector in Saccharomyces cerevisiae

The widely used pESC vector series (Stratagene, La Jolla, CA, USA) with the bidirectional GAL1/GAL10 promoter provides the possibility of simultaneously expressing two different genes from a single vector in Saccharomyces cerevisiae. This system can be induced by galactose and is repressed by glucose. Since S. cerevisiae prefers glucose as a carbon source, and since its growth rate is higher in glucose than in galactose‐containing media, we compared and evaluated seven different promoters expressed during growth on glucose (pTEF1, pADH1, pTPI1, pHXT7, pTDH3, pPGK1 and pPYK1) with two strong galactose‐induced promoters (pGAL1 and pGAL10), using lacZ as a reporter gene and measuring LacZ activity in batch and continuous cultivation. TEF1 and PGK1 promoters showed the most constant activity pattern at different glucose concentrations. Based on these results, we designed and constructed two new expression vectors which contain the two constitutive promoters, TEF1 and PGK1, in opposite orientation to each other. These new vectors retain all the features from the pESC–URA plasmid except that gene expression is mediated by constitutive promoters. Copyright © 2010 John Wiley & Sons, Ltd.     

栽培大豆Rubisco小亚基基因（rbcS）全长cDNA的克隆及原核表达

根据NCBI中发表的大豆Rubisco小亚基基因（rbcS）序列（AF303939-1）设计特异引物,以吉农13大豆为实验材料,采用Trizol法提取叶片总RNA,通过RT-PCR克隆大豆rbcS的cDNA。将该基因与原核表达载体pET-30a（＋）连接,转化大肠杆菌E.coli BL21感受态细胞,双酶切鉴定后筛选阳性克隆,测序结果显示：rbcS全长696bp,其中开放阅读框为537bp,编码178个氨基酸;选择含大豆rbcS cDNA阳性克隆菌液IPTG诱导,经SDSPAGE分析,诱导表达出分子量为29.1kDa的融合蛋白,表达产物大小与预计理论值相符。诱导7h蛋白表达量最高,为64.15%。     

Galactose-inducible Expression Systems in Candida maltosa using Promoters of Newly-isolated GAL1 and GAL10 Genes

The GAL1 and GAL10 gene cluster encoding the enzymes of galactose utilization was isolated from an asporogenic yeast, Candida maltosa. The structure of the gene cluster in which both genes were divergently transcribed from the central promoter region resembled those of some other yeasts. The expression of both genes was strongly induced by galactose and repressed by glucose in the medium. Galactose-inducible expression vectors in C. maltosa were constructed on low- and high-copy number plasmids using the promoter regions of both genes. With these vectors and the β-galactosidase gene from Kluyveromyces lactis as a reporter, galactose-inducible expression was confirmed. Homologous overexpression of members of the cytochrome P-450 gene family in C. maltosa was also successful by using a high-copy-number vector under the control of these promoters. © 1997 by John Wiley & Sons, Ltd.     

Improvement of galactose induction system in Saccharomyces cerevisiae

Here we report a significant enhancement of galactose response without altering the characteristics of glucose repression. To improve the galactose response, we fabricated transgenic yeasts harboring HIS3pro-GAL1, HIS3pro-GAL2 and GAL10pro-GAL4, and evaluated the synergistic effects of these three genes by immunoblot and flow cytometry analyses.     

Cassettes for the PCR-mediated construction of regulatable alleles in Candida albicans

The recent availability of genome sequence information for the opportunistic pathogen Candida albicans has greatly facilitated the ability to perform genetic manipulations in this organism. Two important molecular tools for studying gene function are regulatable promoters for generating conditional mutants and fluorescent proteins for determining the subcellular localization of fusion gene products. We describe a set of plasmids containing promoter-GFP cassettes (P(MET3)-GFP, P(GAL1)-GFP, and P(PCK1)-GFP), linked to a selectable nutritional marker gene (URA3). PCR-mediated gene modification generates gene-specific promoter, or gene-specific promoter-GFP, fusions at the 5'-end of the gene of interest. One set of primers can be used to generate three strains expressing a native protein of interest, or an amino-terminal GFP-tagged version, from three different regulatable promoters. Thus, these promoter cassette plasmids facilitate construction of conditional mutant strains, overexpression alleles and/or inducible amino-terminal GFP fusion proteins.