Versatile use of Schizosaccharomyces pombe plasmids in Saccharomyces cerevisiae

The two model yeasts Saccharomyces cerevisiae and Schizosaccharomyces pombe appear to have diverged 1000 million years ago. Here, we describe that S.?pombe vectors can be propagated efficiently in S.?cerevisiae as pUR19 derivatives, and the pREP and pJR vector series carrying the S.?cerevisiae LEU2 or the S.?pombe ura4(+) selection marker are maintained in S.?cerevisiae cells. In addition, genes transcribed from the S.?pombe nmt1(+) promoter and derivatives are expressed in budding yeast. Thus, S.?pombe vectors can be used as shuttle vectors in S.?cerevisiae and S.?pombe. Our finding greatly facilitates the testing for functional orthologs of protein families and simplifies the cloning of new S.?pombe plasmids by using the highly efficient in vivo homologous recombination activity of S.?cerevisiae.     

A set of loxP marker cassettes for Cre-mediated multiple gene disruption in Schizosaccharomyces pombe

For functional analysis, the presence of gene families and isoenzymes often makes it necessary to delete more than one gene, while the number of marker genes is limited in Schizosaccharomyces pombe. Here we describe a loxP-flanked ura4(+) cassette and Cre recombinase vector for a Cre-loxP-mediated marker removal procedure in S. pombe. This loxP-ura4-loxP cassette can be used for disruption of hmt1(+) as a model target gene. We have constructed two vectors which express Cre recombinase under the control of the nmt1 or nmt41 promoter. Excisive recombination at loxP sites in the chromosome was promoted efficiently and accurately when the Cre recombinase was expressed under the control of the nmt41 promoter. In addition, ura4(+) could be excised from the genome by Cre recombinase, when a single loxP site was adjacent to ura4. The use of the Cre-loxP system proved to be a practical strategy to excise a marker gene for repeated use in S. pombe.     

Efficient Targeted Integration at Leu1-32 and Ura4-294 in Schizosaccharomyces Pombe

Homologous integration into the fission yeast Schizosaccharomyces pombe has not been well characterized. In this study, we have examined integration of plasmids carrying the leu1(+) and ura4(+) genes into their chromosomal loci. Genomic DNA blot analysis demonstrated that the majority of transformants have one or more copies of the plasmid vector integrated via homologous recombination with a much smaller fraction of gene conversion to leu1(+) or ura4(+). Non-homologous recombination events were not observed for either gene. We describe the construction of generally useful leu1(+) and ura4(+) plasmids for targeted integration at the leu1-32 and ura4-294 loci of S. pombe.     

High-frequency cotransformation by copolymerization of plasmids in the fission yeast Schizosaccharomyces pombe.

We have developed a high-frequency cotransformation system which is useful in introducing nonreplicating circular DNA plasmids into the fission yeast Schizosaccharomyces pombe. This system depends on two factors: the ability of the ural-complementing helper plasmids pFYM2 and pFYM225 to propagate autonomously in S. pombe, and the intensive recombination activity intrinsic to this yeast. If cotransformed with a helper plasmid, plasmids such as YIp5 or YIp32, Escherichia coli-Saccharomyces cerevisiae shuttle vectors incapable of replication in S. pombe, can enter S. pombe and express the gene carried on them at a frequency comparable to that of autonomously replicating plasmids (10(3) to 10(4) transformants per microgram of DNA). Even if characters of the nonreplicating DNA are not selected directly, 50 to 70% of Ura+ cells transformed with the helper have also incorporated the nonreplicating plasmid. It is shown that these two plasmids have physically recombined at a site of common DNA sequence to form a heteropolymer in the fission yeast. Since any foreign DNA cloned in pBR322 or ColE1 derivatives can be incorporated into S. pombe by using pFYM2 or pFYM225 as a helper, this cotransformation system will serve as a convenient method to examine functional expression of such cloned DNA in S. pombe. This work also demonstrates that the kanamycin resistance gene carried by the bacterial transposon Tn903 can be expressed in S. pombe, as shown by its ability to inactivate the antibiotic G418.     

Telomere-associated chromosome breakage in fission yeast results in variegated expression of adjacent genes.

The sequence requirements for in vivo telomere function in the fission yeast, Schizosaccharomyces pombe, have been investigated. A 258 bp tract of previously characterized cloned fission yeast terminal repeats adjacent to 800 bp of telomere-associated sequences is sufficient to seed new telomeres onto linearized ars-containing plasmids when introduced into cells. The resulting transformants contain unrearranged, acentric, linear episomes. Cloned telomeres, with and without telomere-associated sequences adjacent to the 258 bp terminal repeats, were utilized to introduce chromosome breaks at specific sites in a non-essential minichromosome. Truncated minichromosome derivatives were recovered containing the ura4 or ade6 gene adjacent to a newly formed telomere. These telomeres exert reversible position effects on the expression of the adjacent ura4 or ade6 genes.     

Choosing and using Schizosaccharomyces pombe plasmids

A wide range of plasmids has been developed for molecular studies in the fission yeast Schizosaccharomyces pombe. This includes general purpose episomes, expression vectors, epitope tagging plasmids, and integration vectors. This review describes the typical features of S. pombe vectors, including replication origins, positive and negative selection markers, and constitutive and inducible promoter systems. We will also discuss vectors with epitope tags and how these can be used to modify episomal or endogenous gene sequences. Considerations for choosing and using a plasmid are presented and specialized methods are described.     

Genetic system for reversible integration of DNA constructs and lacZ gene fusions into the Escherichia coli chromosome

A plasmid system for site-specific integration into and excision and recovery of gene constructs and lacZ gene fusions from the Escherichia coli chromosome was developed. Plasmid suicide vectors utilizing the origin of replication of R6K plasmids and containing the attP sequence of bacteriophage lambda, multiple cloning site, and antibiotic resistance markers facilitate reversible integration into the E. coli chromosome by site-specific recombination. Additional vectors permit construction of lacZ gene fusions in three possible reading frames for recombination with the bacterial chromosome. These suicide vectors can be propagated in newly constructed E. coli strains that harbor different pir alleles. Two helper plasmids that encode the necessary gene products for integration (Int) and excision (Int and Xis) were also constructed. This plasmid system was shown to be a reliable and efficient means to integrate and subsequently recover plasmids from the E. coli attB site.     

Gene insertion and replacement in Schizosaccharomyces pombe mediated by the Streptomyces bacteriophage phiC31 site-specific recombination system

The site-specific recombination system used by the Streptomyces bacteriophage phiC31 was tested in the fission yeast Schizosaccharomyces pombe. A target strain with the phage attachment site attP inserted at the leu1 locus was co-transformed with one plasmid containing the bacterial attachment site attB linked to a ura4+ marker, and a second plasmid expressing the phiC31 integrase gene. High-efficiency transformation to the Ura+ phenotype occurred when the integrase gene was expressed. Southern analysis revealed that the attB-ura4+ plasmid integrated into the chromosomal attP site. Sequence analysis showed that the attBxattP recombination was precise. In another approach, DNA with a ura4+ marker flanked by two attB sites in direct orientation was used to transform S. pombe cells bearing an attP duplication. The phiC31 integrase catalyzed two reciprocal cross-overs, resulting in a precise gene replacement. The site-specific insertions are stable, as no excision (the reverse reaction) was observed on maintenance of the integrase gene in the integrant lines. The irreversibility of the phiC31 site-specific recombination system sets it apart from other systems currently used in eukaryotic cells, which reverse readily. Deployment of the phiC31 recombination provides new opportunities for directing transgene and chromosome rearrangements in eukaryotic systems.     

The Ade6-M26 Mutation of Schizosaccharomyces Pombe Increases the Frequency of Crossing over

The ade6-M26 mutation of Schizosaccharomyces pombe increases conversion frequency in comparison with the nearby mutation ade6-M375. In order to investigate the effect of ade6-M26 on crossover frequency, heteroallelic ade6 duplications were constructed by integration of plasmids carrying the marker gene ura4. One ade6 gene carries either of the mutations M26 or M375 while the other ade6 copy carries the L469 mutation in both duplications. The duplication with ade6-M26 yields Ade(+) recombinants at significantly higher frequencies in meiosis, but not in mitosis. Tetrad analysis and physical characterization of spore clones from recombination tetrads demonstrate that conversions, unequal crossovers and intrachromatid exchanges occur at higher frequencies but with unaltered proportions among them. The conversion events show a pronounced bias when M26 is involved: they take place preferentially at the M26 allele. Thus the ade6-M26 mutation not only enhances conversion frequency as demonstrated before, but also crossover frequency. It displays the properties expected for a preferred site of initiation of general meiotic recombination. The duplications also yielded new information on ectopic recombination in S. pombe: ectopic crossovers occur in the duplications at much higher frequency than among naturally dispersed homologous sequences.     

System of centromeric, episomal, and integrative vectors based on drug resistance markers for Saccharomyces cerevisiae

Integrative, centromeric, and episomal plasmids are essential for easy, fast, and reliable genetic manipulation of yeast. We constructed a system of shuttle vectors based on the widely used plasmids of the pRS series. We used genes conferring resistance to Geneticin (kanMX4), nourseothricin (natNT2), and hygromycin B (hphNT1) as markers. The centromeric and episomal plasmids that we constructed can be used the same way as the traditional auxotrophic marker-based shuttle vectors (pRS41x and pRS42x series). Additionally, we created a set of nine yeast integrative vectors with the three dominant markers. These plasmids allow for direct integration in the LEU2, URA3, and HIS3 locus of any yeast strain and the concomitant partial deletion of the gene. This prevents multiple integrations and allows for the rapid identification of correct integrants. The set of new vectors considerably enhances the flexibility of genetic manipulations and gene expression in yeast. Most notably, the new vectors allow one to work with natural yeast isolates, which do not contain auxotrophic markers.     

pEMBL: a new family of single stranded plasmids.

We have constructed a series of plasmids, the pEMBL family, characterized by the presence of 1) the bla gene as selectable marker, 2) a short segment coding for the alpha-peptide of beta-galactosidase and containing a multiple cloning sites polylinker, 3) the intragenic region of phage F1. pEMBL plasmids have the property of being encapsidated as single stranded DNA, upon superinfection with phage F1. These vectors have been used successfully for DNA sequencing with the dideoxy-method, and can be used for any other purpose for which M13 derivatives are used. However, the pEMBL plasmids have the advantage of being smaller than M13 vectors, and the purification of the DNA is simpler. In addition, and most importantly, long inserts have a higher stability in pEMBL plasmids than M13 vectors.     

Vectors for the construction of gene banks and the integration of cloned genes in Schizosaccharomyces pombe and Saccharomyces cerevisiae

We have constructed a variety of vectors for use in both budding yeast (Saccharomyces cerevisiae) and fission yeast (Schizosaccharomyces pombe). Four of these, pDB262, pWH4, pWH5, and pMAK262, have positive selection for the insertion of cloned DNA, making them convenient for the construction of gene banks. pDB262, pWH4 and pWH5 contain the 2 mu ARS and the LEU2 gene from S. cerevisiae and can be used for gene isolation. They can also be converted into integration vectors for use in the genetic mapping of cloned sequences. pMAK262 contains only the LEU2 gene from budding yeast and can be used to screen for ARS elements or for gene integration. We also describe two other integration vectors, pDAM3 and pDAM6, which have a variety of restriction sites suitable for subcloning.     

Detection of CaMV gene I and gene VI protein products in vivo using antisera raised to COOH-terminal β-galactosidase fusion proteins

Specific antisera were prepared to the inclusion body protein (gene VI product) and the gene I product of cauliflower mosaic virus (CaMV). Translational fusions between the lacZ gene and gene VI or gene I were constructed by cloning the relevant DNA fragments into the expression vectors pUR290, pUR291 or pUR292. Large amounts of fusion protein were synthesized when the inserted DNA fragment was in frame with the lacZ gene of the expression vector. These fusion proteins were used to raise specific antisera to gene VI and gene I proteins of CaMV. Antiserum to the gene VI product detected a range of proteins in crude extracts and in a subcellular fraction enriched for virus inclusion bodies. This range of proteins was further shown to be related to gene VI by Staphylococcus aureus V8 partial proteolysis. Antiserum to the gene I product detected viral specific proteins of 46, 42 and 38 K in preparations of CaMV replication complexes from infected plants but not in any other subcellular fraction.     

New shuttle-type vectors for cloning in Escherichia coli and Agrobacterium tumefaciens

The vectors capable of replication in Escherichia coli and Agrobacterium tumefaciens have been constructed on the basis of the plasmid pUB5502. The constructed vectors pVA12, pVA12-2, pVA12-4 contain the mini-replicon and trimethoprim resistance gene (Tp) of a broad host-range plasmid R388 (IncW). The pVA12 vector (8.8 kb) has been constructed by insertion of a kanamycin resistance gene (Km) from the plasmid pUC-4K into a Psti site. It possesses 7 unique restriction sites for XhoI, SmaI, PvuI, PvuII, HindIII, EcoRI, BamHI and the markers for kanamycin and trimethoprim resistance (Km and Tp). The pVA12-2 and pVA12-4 vectors were obtained as a result of changing of the PvuII-EcoI fragment of pVA12 carrying the Tp gene for the PvuII-EcoRI fragment of pBR322 carrying the Tc gene. These plasmids have the same size of 9.7 kb and 8 unique sites for restriction endonucleases XhoI, SmaI, PvuI, PvuII, EcoRI, EcoRV, SalI, BalI and Km and Tc genes. No difference has been registered between the two plasmids by restriction analysis, but pVA12-4 has the dramatically increased copy number in Escherichia coli cells. All three vectors are transferable to Agrobacterium tumefaciens with the same frequencies by transformation or conjugation and do not affect the oncogenicity of pTi.     

乙肝病毒核心抗原基因在大肠杆菌中的表达

根据乙型肝炎病毒(HBV)DNA全基因组克隆pHBV-NC的酶切图谱,分别用限制性内切酶HincⅡ-AvaⅠ和BgLⅡ剪切pHBV—NC_1-DNA,获得了两种不同长度HBV核心抗原基因片段:HBcAgⅠ片段和HBcAgⅡ片段。用带有P_R启动子的质粒pCQV2和带有Lac启动子的质粒pUR222与HBcAgⅠ段和HBcAgⅡ片段连接,分别转化到大肠杆菌中,获得了三种不同的表达菌株,命名为pHBcAgⅠ、pHBcAgⅡ和pLcAgⅡ,并对其核心抗原的表达量做了比较。