Scarcity of ars sequences isolated in a morphogenesis mutant of the yeast Yarrowia lipolytica

Previous attempts is isolate autonomously replicating sequences (ars) from the dimorphic yeast Yarrowia lipolytica have been unsuccessful. We isolated a Fil- mutant unable to produce hyphae and growing only in a yeast form to facilitate ars isolation. This mutant was transformed with a Y. lipolytica DNA bank and several unstable clones were obtained. Extrachromosomal plasmids were evidenced in yeast, recovered in Escherichia coli and characterized by restriction mapping. They were able to retransform Fil- and Fil+ yeast strains at high frequency and transformants displayed a slightly unstable phenotype. The detailed analysis of the plasmids showed that only two different ars sequences had been isolated, each of them corresponding to a unique sequence in the Y. lipolytica genome. We concluded that functional ars sequences that can be cloned on plasmids are rare in this yeast.     

A set of plasmids carrying antibiotic resistance markers and Cre recombinase for genetic engineering of nonconventional yeast Zygosaccharomyces rouxii

The so-called nonconventional yeasts are becoming increasingly attractive in food and industrial biotechnology. Among them, Zygosaccharomyces rouxii is known to be halotolerant, osmotolerant, petite negative, and poorly Crabtree positive. These traits and the high fermentative vigour make this species very appealing for industrial and food applications. Nevertheless, the biotechnological exploitation of Z. rouxii has been biased by the low availability of genetic engineering tools and the recalcitrance of this yeast towards the most conventional transformation procedures. Centromeric and episomal Z. rouxii plasmids have been successfully constructed with prototrophic markers, which limited their usage to auxotrophic strains, mainly derived from the Z. rouxii haploid type strain Centraalbureau voor Schimmelcultures (CBS) 732^T. By contrast, the majority of industrially promising Z. rouxii yeasts are prototrophic and allodiploid/aneuploid strains. In order to expand the genetic tools for manipulating these strains, we developed two centromeric and two episomal vectors harbouring KanMX^R and ClonNAT^R as dominant drug resistance markers, respectively. We also constructed the plasmid pGRCRE that allows the Cre recombinase-mediated marker recycling during multiple gene deletions. As proof of concept, pGRCRE was successfully used to rescue the kanMX–loxP module in Z. rouxii ATCC 42981 G418-resistant mutants previously constructed by replacing the MATα^P expression locus with the loxP–kanMX–loxP cassette.     

Sequence of the yeast protein expression plasmid pEG(KT)

The plasmid pEG(KT) is a widely used plasmid for expressing high levels of GST fusion proteins in the yeast Saccharomyces cerevisiae. Unfortunately, a complete sequence file has been lacking, thus complicating efforts to design cloning projects or to modify the plasmid for other uses (e.g. exchanging selection markers, epitope tags or protease cleavage sites to remove the epitope tag). Here, the complete sequence of the pEG(KT) plasmid is reported, thus facilitating its use. Additionally, its use as a vector backbone for high‐level expression of a TAP‐tagged protein is shown. Copyright © 2009 John Wiley & Sons, Ltd.     

Characterization of Na+/H+-antiporter gene closely related to the salt-tolerance of yeast Zygosaccharomyces rouxii

In order to clarify the relationship between salt-tolerance of Zygosaccharomyces rouxii and the function of Na⁺/H⁺-antiporter, a gene was isolated from Z. rouxii which exhibited homology to the Na⁺/H⁺-antiporter gene (sod2) from Schizosaccharomyces pombe. This newly isolated gene (Z-SOD2) encoded a product of 791 amino acids, which was larger than the product encoded by its Sz. pombe homologue. The predicted amino-acid sequence of Z-Sod2p was highly homologous to that of the Sz. pombe protein, but included an extra-hydrophilic stretch in the C-terminal region. The expression of Z-SOD2 was constitutive and independent of NaCl-shock. Z-SOD2-disruptants of Z. rouxii did not grow in media supplemented with 3 M -NaCl, but grew well in the presence of 50% sorbitol, indicating that the function of Z-SOD2 was closely related to the salt-tolerance of Z. rouxii. Several genes are also compared and discussed in relation to the salt-tolerance of Z. rouxii. The nucleotide sequence data reported in this paper will appear in the GSDB, DDBJ, EMBL and NCBI nucleotide sequence databases with the following accession number: D43629.     

Linear DNA plasmid pPK2 of Pichia kluyveri: distinction between cytoplasmic and mitochondrial linear plasmids in yeasts

The linear plasmids frequently found in plants and filamentous fungi are associated with mitochondria or chloroplasts. In contrast, all the linear plasmids known in yeasts are cytoplasmic elements. From a strain of the yeast Pichia kluyveri, we have isolated a new linear plasmid, pPK2, which was found to be associated with mitochondria. This 7·1 kilobase pairs‐long DNA contained only two genes, which code for DNA and RNA polymerases, as judged from their nucleotide sequences translated by a mitochondrial genetic code. When we examined several recently isolated yeast plasmids for their subcellular localization, we found that two linear plasmids, pPH1 from Pichia heedii, as well as pPK1 from another strain of P. kluyveri, were also localized in mitochondria. These plasmids are the first examples of mitochondria‐associated linear plasmids in yeast. All other linear plasmids we examined were of cytoplasmic origin. Whilst the cytoplasmic type linear plasmids were efficiently eliminated by ultraviolet irradiation of host cells, the mitochondria‐associated plasmids were highly resistant. The mitochondrial pPK2 plasmid was rapidly lost by treatment of the host cells with ethidum bromide. Copyright © 1999 John Wiley & Sons, Ltd.     

Isolation and sequence analysis of the gene encoding triose phosphate isomerase from Zygosaccharomyces bailii.

The ZbTPI1 gene encoding triose phosphate isomerase (TIM) was cloned from a Zygosaccharomyces bailii genomic library by complementation of the Saccharomyces cerevisiae tpi1 mutant strain. The nucleotide sequence of a 1.5 kb fragment showed an open reading frame (ORF) of 746 bp, encoding a protein of 248 amino acid residues. The deduced amino acid sequence shares a high degree of homology with TIMs from other yeast species, including some highly conserved regions. The analysis of the promoter sequence of the ZbTPI1 revealed the presence of putative motifs known to have regulatory functions in S. cerevisiae. The GenBank Accession No. of ZbTPI1 is AF325852.     

Effects of phosphoglycerate kinase overproduction in Saccharomyces cerevisiae on the physiology and plasmid stability.

In this report the effects of phosphoglycerate kinase (PGK) overproduction on the physiology and plasmid stability in baker's yeast Saccharomyces cerevisiae containing the PGK1 gene on an episomal plasmid are described. This examination reveals that there is a preferred intracellular level for this enzyme, amounting to 10-15% of the total soluble protein. Strains containing the plasmid and the host strain were grown in non-selective batch cultures and continuous culture, under different growth conditions. Plasmid-containing yeast strains stabilize the copy number of the episomal plasmid at a level at which the PGK concentration is about 12%. This stabilization is due to an equilibrium between normal plasmid loss and selective pressure because of advantages resulting from the increased amount of PGK under glucose-limited conditions. During respiro-fermentative growth, PGK-overproducing cells showed an increased respiration rate and decreased fermentative activity, compared to the host strain. The PGK1 gene can be applied as a direct positive selection marker to obtain a high episomal plasmid stability during growth on glucose. The results are consistent with previously reported data on the physiology and gene stability of PGK-overproducing yeast cells that contain multiple copies of the PGK1 gene integrated into the genome.     

Novel episomal vectors and a highly efficient transformation procedure for the fission yeast Schizosaccharomyces japonicus

Schizosaccharomyces japonicus is a fission yeast for which new genetic tools have recently been developed. Here, we report novel plasmid vectors with high transformation efficiency and an electroporation method for Sz. japonicus. We isolated 44 replicating segments from 12 166 transformants of Sz. japonicus genomic fragments and found a chromosomal fragment, RS1, as a new replicating sequence that conferred high transformation activity to Sz. japonicus cells. This sequence was cloned into a pUC19 vector with ura4⁺ of Sz. pombe (pSJU11) or the kan gene on the kanMX6 module (pSJK11) as selection markers. These plasmids transformed Sz. japonicus cells in the early‐log phase by electroporation at a frequency of 123 cfu/µg for pSJK11 and 301 cfu/µg for pSJU11, which were higher than previously reported autonomously replicating sequences. Although a portion of plasmids remained in host cells by integration into the chromosome via RS1 segment, the plasmids could be recovered from transformants. The plasmid copy number was estimated to be 1.88 copies per cell by Southern blot analysis using a Sz. pombe ura4⁺ probe. The plasmid containing ade6⁺ suppressed the auxotrophic growth of the ade6‐domE mutant, indicating that the plasmid would be useful for suppressor screening and complementation assays in Sz. japonicus. Furthermore, pSJU11 transformed Sz. pombe cells with the same frequency as the pREP2 plasmid. This study is a report to demonstrate practical use of episomal plasmid vectors for genetic research in Sz. japonicus. RS1 has been submitted to the DDBJ/EMBL/GenBank database (Accession No. AB547343). Copyright © 2010 John Wiley & Sons, Ltd.     

The ade6 gene of the fission yeast Schizosaccharomyces pombe has the same chromatin structure in the chromosome and in plasmids.

We have analysed the chromatin structure of the ade6 gene of Schizosaccharomyces pombe and its flanking regions both in the chromosome and in plasmids. The chromatin structure is independent of the chromosomal or extrachromosomal location. The ade6 gene contains eight precisely positioned nucleosomes on the 5' half, 'not positioned' nucleosomes around the 3' end and a nuclease-sensitive promoter region. Precisely positioned nucleosomes, but no nuclease-sensitive region were also detected on the ura4 gene in the chromosome and on a plasmid. The results show that S. pombe chromosomal and extrachromosomal genes have chromatin structures similar to those of S. cerevisiae and higher eukaryotes.     

Genetic control of chromosome stability in the yeast Saccharomyces cerevisiae

We have identified four new genetic loci: CHL2 (on chromosome XII), CHL3 (on chromosome XII); CHL4 (on chromosome IV), and CHL5 (on chromosome IX), controlling mitotic transmission of yeast chromosomes. The frequency of loss of chromosomes is 10-100-fold higher in chl5, chl2, chl3 and chl4 mutants than observed in wild-type strains. The mutants also show unstable maintenance of artificial circular minichromosomes with various chromosomal replicators (ARS) and one of the centromeric loci (CEN3, CEN4, CEN5 or CEN6). The instability of minichromosomes in the chl5, chl2, and chl4 mutants is due to the loss of minichromosomes in mitosis (1:0 segregation). In the chl3 mutant the instability of artificial minichromosomes is due to nondisjunction (2:0 segregation). The CHL3 gene therefore appears to affect the segregation of chromosomes during cell division.     

The 2μm plasmid of laboratory yeast strains is a type-1/type-2 hybrid

Industrial yeast strains carry one of two homeologous 2μm plasmids designated as type-1 or type-2. The 2μm plasmid, Scp1, found in common laboratory strains of Saccharomyces cerevisiae is considered a type-2 plasmid, since the ori, STB, RAF and REP1 loci and intergenic sequences of the right-unique region of Scp1 are homologous to the corresponding loci in industrial strain type-2 plasmids. However, within both its 599 bp inverted repeats Scp1 has 142-bp sequences homologous to the bakers' yeast type-1 plasmid. DNA sequence analyses and oligonucleotide hybridizations indicate that the 142-bp insertion in Scp1 was probably due to homeologous recombination between type-1 and type-2 plasmids. These results suggest that some of the plasmid and chromosomal sequence polymorphisms seen in laboratory yeast strains result from homeologous recombination in their ancestral breeding stock.     

Effects of weak acids and external pH on the intracellular pH of Zygosaccharomyces bailii,and its implications in weak-acid resistance

Weak acids and hydrogen ions in different concentration combinations affect the intracellular pH value (pH_i) of Zygosaccharomyces bailii. The lowest pH_i value measured was not at the most extreme, but at intermediate conditions of inhibition. Proton and organic-acid ejection, on a cell volume basis, is greater in cells grown under inhibitory conditions and is stimulated by weak acids, whilst in cells not grown under inhibitory conditions acid efflux is lower and is depressed by weak acids; this may be important in the maintenance of tolerable pH_i values in the presence of weak acids. The concentration of benzoic acid measured internally is identical to the value expected from its pK, external pH and pH_i. Addition of fructose to starved cells causes both a decreased pH_i and a concomitant efflux of previously loaded benzoic acid, quantitatively in accord with the shift in equilibrium of the freely permeable undissociated acid. There is no evidence that weak acids are actively extruded. Protoplast volume also varies with hydrogen-ion and weak-acid concentration and this too may play a role in intracellular pH maintenace.     

Recombination in yeast based on six base pairs of homologous sequences: Structural instability in two sets of isomeric model expression plasmids

Multicopy episomal yeast (Saccharomyces cerevisiae) plasmids are frequently employed in research and industrial production despite their known limited structural and segregational stability. Employing a set of six yEGFP3 model expression plasmids (identical in size but differing in the arrangement of their functional sequences, joined via six base pair SacI sequences), we used back transformation of total DNA extracted from yeast transformants into Escherichia coli to detect potential plasmid rearrangements. This approach revealed deletions, translocations, duplications, and flippings of functional sequences in our plasmids based on homologous recombination between the SacI sequences. To extend our findings, we assembled and analysed in the same way a corresponding plasmid set of six isoforms expressing the antibacterial insect peptide defensin A. In 833 individual amp^R clones (both sets combined), we traced 28 cases (3.4%) with precise structural changes. However, the frequency in one isoform in the pIFC4.13X series, pIFC4.131, was particularly high with 18.5% (15 out of 81 clones), indicating that the architecture of this plasmid is unfavourable to the host. With an increased sensitivity, a Polymerase Chain Reaction (PCR) approach revealed further structural changes in at least half of the isoforms of each set. The changes are considered the consequence of homologous recombination events involving the SacI sequences in a random fashion. The frequency of plasmid alterations is the product of selection and counterselection seemingly favouring or disfavouring certain structures. Although no sole architectural arrangement stuck out as being particularly stable, we were able to determine with our approach unfavourable sequence associations that should be avoided.