Use of a <Emphasis Type="Italic">ura5</Emphasis><Superscript>+</Superscript>–<Emphasis Type="Italic">lys7</Emphasis><Superscript>+</Superscript> cassette to construct unmarked gene knock-ins in <Emphasis Type="Italic">Schizosaccharomyces pombe</Emphasis>

While the counterselectable Schizosaccharomyces pombe ura4 ⁺ gene can be used to prepare a site in the S. pombe genome to receive an unmarked mutant allele (loss of ura4 ⁺ confers 5FOA-resistant (5FOA^R) growth), the desired unmarked knock-in strains are generally outnumbered by spontaneously arising 5FOA^R mutants. Relative to the same approach using the homologous URA3 ⁺ gene in Saccharomyces cerevisiae, knock-ins in S. pombe are harder to identify due to a lower efficiency of homologous recombination and a relatively high background of spontaneous 5FOA^R colonies. To develop an improved method for identifying cells receiving unmarked mutant alleles, we first determined that 5FOA^R strains carry mutations in either of two genes; ura4 ⁺ and ura5 ⁺. We then cloned the S. pombe ura5 ⁺ orotate phosphoribosyltransferase gene and constructed a 2.1 kb cassette containing ura5 ⁺ together with the S. pombe lys7 ⁺ gene. Using this doubly marked cassette to disrupt the sck1 ⁺ kinase gene, we can distinguish between strains created by homologous knock-in of unmarked wild-type or kinase-dead alleles and spontaneously arising ura4 ⁻ and ura5 ⁻ mutants by screening 5FOA^R colonies for the loss of the lys7 ⁺ marker. The utility of this system, especially when the phenotype for the strain carrying the knock-in allele is indistinguishable from that of the disruption strain, is borne out by the fact that ~95% of 5FOA^R colonies in our studies arose from background ura4 ⁻ and ura5 ⁻ mutations.     

Mapping of rRNA genes by integration of hybrid plasmids in Schizosaccharomyces pombe

Summary The major rRNA genes of the fission yeast Schizosaccharomyces pombe were mapped on chromosome III by plasmid integration. The integration vector YIp33 containing S. cerevisiae LEU2 gene was combined with the S. pombe rDNA. Since LEU2 complements S. pombe leu1 deficiency, it could be used as the genetic marker for integration. The 10.4 kb rDNA repeat contained ARS sequence, and therefore 2.4 kb and 0.7 kb subfragments not containing ARS were subcloned into YIp33 and transformed leu1 S. pombe cells to Leu⁺. Genetic analyses of the transformants indicated that the integrated rDNA resides in the long arm of the shortest chromosome III, tightly linked to ade5 (1.4 cM). This result is consistent with our previous finding that the DAPI-stained smallest chromosomes were associated with the nucleolus (Umesono et al. 1983).Abbreviations ARS autonomously replicating sequence - DAPI 4,6-diamidino-2-phenylindole - kb kilo base pairs - rDNA DNA segment containing ribosomal RNA genes - rRNA ribosomal RNA     

Recombinational properties of the Saccharomyces cerevisiae FLP gene expressed in Escherichia coli

Summary The FLP gene from the 2-m DNA of Saccharomyces cerevisiae is shown to be functionally expressed in Escherichia coli leading to site-specific intramolecular as well as intermolecular recombination between IR sequences. The expression was achieved under control of a low expression as well as a high expression E. coli promoter. The FLP gene was found to complement in trans a Flp^– plasmid and promote its interconversion.By the use of a low Flp expression plasmid, it could be shown that the rate of interconversion of a Flp^– plasmid by complementation in trans, was lower than that of a Flp⁺ plasmid, suggesting that in addition to the IR sequences another cis-acting function exists.Expression of the FLP gene fused to the lac promoter in an in vitro system yielded two polypeptides with apparent molecular weights of 44,000 and 37,000. The 37,000 dalton polypeptide can also be produced from Flp^– plasmids and is generated from a translation start within the FLP gene. The 44,000 dalton polypeptide is considered to represent the FLP gene product.     

pH sensitivity of Schizosaccharomyces pombe: effect on the cellular phenotype associated with lacZ gene expression

We report on a series of experiments inSchizosaccharomyces pombe to detect the blue-colour colony phenotype associated with expression of theEscherichia coli lacZ gene. Increasing the pH in solid minimal medium to optimize blue colony colour revealed a pH-sensitive phenotype in auxotrophic strains requiring uracil and leucine as external supplements. This phenotype was observed among commonS. pombe stock strains, 5-fluoroorotic acid (5-FOA)-selected strains, and random genetic segregants. Growth of prototrophicS. pombe strains 972 and 975 or the adenine auxotrophic strain NCYC 1860 were unaffected by an increase in external pH. Analysis of genetic segregants from three independent crosses indicated that a single auxotrophic marker (ura4 ^- orleu1-32) was sufficient for yeast cell-growth inhibition when the medium pH was increased above 6.6. In contrast, growth of aSaccharomyces cerevisiae strain isogenic to AH22, requiring uracil, leucine and histidine, was unaffected by changes in the pH of the medium. These observations suggest that uptake of uracil and leucine intoS. pombe cells is compromised by alterations in external pH. Our results have implications for detection of thelacZ gene-encoded bluecolour colony phenotype inS. pombe, which is optimized by growth in the presence of 5-bromo-4-chloro-3-indolyl--D-galactoside (Xgal) at pH 7.0. We discuss the conditions under which this blue-colour phenotype can be routinely observed inS. pombe.     

Diploid yeast cells yield homozygous spontaneous mutations

A leucine-requiring hybrid of Saccharomyces cerevisiae, homoallelic at the LEU1 locus (leu1–12/leu1–12) and heterozygous for three chromosome-VII genetic markers distal to the LEU1 locus, was employed to inquire: (1) whether spontaneous gene mutation and mitotic segregation of heterozygous markers occur in positive nonrandom association and (2) whether homozygous LEU1/LEU1 mutant diploids are generated. The results demonstrate that gene mutation of leu1–12 to LEU1 and mitotic segregation of heterozygous chromosome-VII markers occur in strong positive nonrandom association, suggesting that the stimulatory DNA lesion is both mutagenic and recombinogenic. In addition, genetic analysis of diploid Leu⁺ revertants revealed that approximately 3% of mutations of leu1–12 to LEU1 result in LEU1/LEU1 homozygotes. Red-white sectored Leu⁺ colonies exhibit genotypes that implicate postreplicational chromatid breakage and exchange near the site of leu1–12 reversion, chromosome loss, and subsequent restitution of diploidy, in the sequence of events leading to mutational homozygosis. By analogy, diploid cell populations can yield variants homozygous for novel recessive gene mutations at biologically significant rates. Mutational homozygosis may be relevant to both carcinogenesis and the evolution of asexual diploid organisms.This work was supported by the Director, Office of Energy Research, Office of Health Effects Research, Biological Research Division, of the U.S. Department of Energy under Contract No. DE-AC03-76SF00098 and grants from the Public Health Service and National Aeronautics and Space Administration     

Cloning of a Candida utilis gene which complements leu2 mutation in Saccharomyces cerevisiae

Summary DNA fragments containing the LEU2 gene of Candida utilis have been isolated, utilizing the genome library (constructed in YRp12) of this organism. Two recombinant plasmids pZR84 and pZR32, containing the cloned LEU2 gene, were 4.24 kb and 10.4 kb, respectively, and were shown to complement leu2 mutation in Saccharomyces cerevisiae and leuB mutation in Escherichia coli. The cloned fragment in pZR84 contained one restriction site each for EcoRI and PvuII, and two for HindIII, but none for SalI, BamHI or Pstl. This cloned fragment hybridized with the total DNA from C. utilis and from Leu⁺ transformants of S. cerevisiae, but not with that from untransformed S. cerevisiae. Subcloning analyses showed that a 2.34 kb BamHI HindIII fragment of the cloned C. utilis sequence contains the region essential for the expression of the LEU2 gene.Journal Article No. 11669 from the Michigan Agricultural Experiment Station     

Kluyveromyces lactis killer system: ORF1 of pGKL2 has no function in immunity expression and is dispensable for killer plasmid replication and maintenance

Summary To functionally characterize the genes encoded by the larger killer plasmid pGKL2 from Kluyveromyces lactis a previously developed in-vivo recombination system was exploited. An in-vitro modified version of the cytoplasmically expressible LEU2 gene cartridge (LEU2 ^*) flanked by appropriate pGKL2 segments was used to replace the central part of the ORF1 region of pGKL2. Transformation of a Leu^- killer strain resulted in the expected disruption of ORF1 in the resident pGKL2. The Leu⁺ transformants obtained can be assigned to three classes. Class I carries both killer plasmids, pGKL1/2, and the recombinant pGKL2 derivative termed pRKL2. Class II and III additionally harbor palindrome and hairpin-like plasmids, respectively. Upon subculturing of class I transformants under selective pressure, segregation of the native pGKL2 and the recombinant pRKL2 eventually occurs resulting in total loss of pGKL2. No differences concerning killer and immunity phenotype between a pRKL2-harboring strain and the native pGKL2-carrying recipient could be detected. Thus pGKL2 ORF1 is dispensable for both expression of killer/immunity phenotypes and for the replication and maintenance of the K. lactis killer plasmids.     

Isolation of uridine auxotrophs from Trichoderma reesei and efficient transformation with the cloned ura3 and ura5 genes

Summary Uridine auxotrophs of the filamentous fungus Trichoderma reesei have been selected using a positive screening procedure with 5-fluoro orotate. Mutants deficient for the orotidine-5-phosphate decarboxylase gene (ura3 mutants) and for the orotate phosphoribosyl transferase gene (ura5 mutants) have been characterized. The homologous ura3 and ura5 genes have been isolated and used to transform the auxotrophic mutants. Transformation efficiency with these homologous systems is very high (>10⁴ transformants per g DNA). Transformation occurred by integration of vector DNA at homologous and ectopic loci. Mitotic instability was observed among some of the transformants. Sequence analysis at the protein level, of the T. reesei ura3 and ura5 genes showed extensive blocks of homology, with the corresponding genes from other organisms. The ura3 gene from T. reesei contains an insertion of 103 aa. A similar sequence is also found inserted in OMPdecase from the pyrenomycetes Neurospora crassa and Cephalosporium acremonium.     

Cloning the Schizosaccharomyces pombe lys2 + gene and construction of new molecular genetic tools

Molecular genetic analyses in Schizosaccharomyces pombe rely on selectable markers that are used in cloning vectors or to mark targeted gene deletions and other integrated constructs. In this study, we used genetic mapping data and genomic sequence information to predict the identity of the S. pombe lys2 ⁺ gene, which is homologous to Saccharomyces cerevisiae LYS4 ⁺. We confirmed this prediction, showing that the cloned SPAC343.16 gene can complement a lys2-97 mutant allele, and constructed the lys2 ⁺-based cloning vector pRH3. In addition, we deleted the S. pombe his7 ⁺ gene with a lys2 ⁺-marked polymerase chain reaction (PCR) product and the S. pombe lys2 ⁺ gene with a his7 ⁺-marked PCR product. Strains carrying these deletions of lys2 ⁺ or his7 ⁺ serve as relatively efficient hosts for the deletion of the ade6 ⁺ gene by lys2 ⁺- or his7 ⁺-marked PCR products when compared with hosts carrying lys2 or his7 point mutations. Therefore, these studies provide plasmids and strains allowing the use of lys2 ⁺ as a selectable marker, along with improved strains for the use of his7 ⁺ to mark gene deletions.     

Mapping of four ras superfamily genes by physical and genetic means in Schizosaccharomyces pombe

Summary Four ras superfamily genes, namely ypt1, ypt2, ypt3 and ryh1, have been located on the S. pombe linkage map. This was achieved by constructing strains carrying a new NotI cutting site and the S. cerevisiae LEU2 gene integrated next to the respective gene. The physical location of these genes of the chromosomes was then determined by NotI restriction analysis of the DNA prepared from each strain. Fine genetic mapping was carried out by conventional tetrad analysis using the integrated LEU2 gene as a marker. The results indicated that ypt1 is tightly linked to top1 on the right arm of chromosome II; that ypt2 is 2.5 cM apart from ura2 on the right arm of chromosome I; that ypt3 is tightly linked to arg3 on the left arm of chromosome I; and that rhy1 is located approximately 20 cM from ade3 on the left arm of chromosome I.     

Meiosis-dependent mRNA splicing of the fission yeast Schizosaccharomyces pombe mes1 + gene

The mes1 ⁺ gene of the fission yeast Schizosaccharomyces pombe is essential for the second meiotic division. We have cloned a 1.1-kb HindIII fragment containing mes1 ⁺ by complementation from an S. pombe genomic library. Sequencing of the genomic and cDNA fragments indicates the existence of one small intron of 75 nucleotides, although both the 5 (G/GTTAGT) and 3 (CAG/T) intron-exon junctions deviate from the consensus sequences proposed for S. pombe. The putative translation product of the mature mes1 ⁺ mRNA is a 11-kDa protein of 101 amino acids which has no significant homology to any previously-reported proteins. Disruption of mes1 has no effect on cell growth but causes an arrest of meiosis before the second meiotic division. Northern-blot analysis revealed that mes1 ⁺ was preferentially transcribed under conditions of nitrogen starvation. When a h ⁹⁰ homothallic strain was shifted to a nitrogen-deficient medium, a pre-mRNA accumulated and then was gradually processed to generate a mature mRNA. This splicing did not occur in either a heterothallic haploid strain or in a homothallic mei2 mutant strain which was defective in the initiation of meiosis. Expression of the first exon alone was not able to suppress the mes1 null allele. These results indicate that mes1 ⁺ is required for the completion of meiosis, that splicing is required for the function of the mes1 ⁺ gene, and that this splicing requires the function of the mei2 ⁺ product.     

LEU2 directed expression of β-galactosidase activity and phleomycin resistance in Yarrowia lipolytica

Summary The nucleotide sequence of a 968 by DNA fragment spanning the promoter and the 5 upstream sequence of the LEU2 coding sequence of the yeast Yarrowia lipolytica has been determined. A LEU2:lacZ gene fusion has been constructed and expressed in transformed yeast cells, showing that as few as 232 by of the LEU2 promotor were sufficient to direct gene expression. In order to develop new markers for transformation of this yeast, the LEU2 initiation codon was destroyed by in vitro mutagenesis and replaced by a cloning site. A gene confering phleomycin resistance in E. coli was attached to the LEU2 promoter and shown to be efficiently expressed in yeast: direct selection of phleomycin resistant transformants was possible.     

‘Phase variation’-type regulation of gene expression and gene replacement mediated by FLP recombinase in the yeast Saccharomyces cerevisiae

Expression of a neomycin phosphotransferase II (NPTII) gene has been designed to be regulated by an FLP-mediated switching of the orientation of the NPTII coding region located on the invertible DNA segment in episomal yeast plasmids. Inversion of the segment from inverted to direct orientation with respect to the promoter resulted in a dramatic increase in G418 resistance. FLP also promoted a double reciprocal exchange between the transforming and the resident 2-m plasmid, leading to insertion of the FLP and REP2 genes into the transforming plasmid. The results demonstrate a possible use of FLP recombinase for phase variation-type regulation of gene expression and gene replacement in eukaryotic cells.     

A mutated swi4 gene causes duplications in the mating-type region of Schizosaccharomyces pombe

Summary Efficient mating-type (MT) switching in homothallic strains of Schizosaccharomyces pombe is significantly reduced if they have a mutation in any of the eleven known swi genes. The swi4 mutation causes heterothallic as well as homothallic segregants, both of which have duplications in the MT region. In contrast to homothallic strains, h ⁺ swi4 strains yield only a few duplications. The duplications originate in the process of MT switching, presumably by mistakes in the resolution of DNA intermediates. They always consist of one cassette and one of the intervening sequences, L and K respectively. Strains with up to seven cassettes in the MT region were found. The possible modes of their origins are discussed.     

FLP recombinase induction of the breakage-fusion-bridge cycle and gene conversion in Saccharomyces cerevisiae

Summary A YEp chimaeric plasmid containing URA3 and SMR1 [sulfometuron methyl resistant (SM^R) allele of ILV2] as selectable markers, and the 2 m site-specific recombination FLP recognition target (FRT), was integrated at the ilv2-1 site in chromosome XIII in a cir°] haploid. Southern analysis defined two integrant structures. Structure I had URA3 distal and SMR1 proximal to FRT whereas in structure II both markers were distal to FRT. Selectable markers were stably inherited in [cir°] haploids and [cir°] diploids heterozygous for the integrant and ILV2. Approximately 14% of heterozygous [cir ⁺] diploid cells exhibited homozygotization for the distal (500 kb) ade4 marker in trans. In [cir ⁺] diploids FLP-FRT recombination resulted in the simultaneous loss of both structure II markers, whereas the structure I distal URA3 marker loss always preceded the variable loss of the proximal SMR1 marker. URA^– cells continued to segregate for loss of SMR1 until stable URA^– SM^R or URA^–SM^S cells were produced. Gene conversion was identified in stable URA^–SM^R cells that were homozygous SMR1/SMR1 but contained wild type ILV2 restriction endonuclease sites. These observations support a model based on concerted FLP-FRT action resulting from the secondary integration of native 2 m DNA followed by unequal sister chromatid exchange (USCE) within inverted FRTs. The resultant chromatid bridge resulted in a double-stand break. Fusion of the broken ends of sister chromatids generated a breakage-fusion-bridge cycle (BFBC). Repeated rounds of the BFBC resulted in proximal marker loss and the generation of additional double-strand breaks. Recombinogenic properties of the double-strand break initiated events leading to homozygotization and gene conversion.     

Cloning of the C-URA3 gene and construction of a triple auxotroph (his5, ade1, ura3) as a useful host for the genetic engineering of Candida maltosa

The C-URA3 gene of the n-alkane assimilating-yeast Candida maltosa was cloned by complementation of the ura3 mutation of Saccharomyces cerevisiae. The nucleotide sequence of C-URA3 and its deduced amino-acid sequence showed significant homology to those of the orotidine 5-phosphate decarboxylases of other fungal species. To construct a useful host for genetic engineering of C. maltosa using C-URA3 as a marker, one allele of C-URA3 in a double auxotroph (his5, ade1) was disrupted by C-ADE1, and subsequently two kinds of ura3 mutants were isolated by selecting for spontaneous 5-fluoro-orotic acid (5FOA) resistance. One of the mutants was homozygous for the disruption (ura3::C-ADE1/ura3::C-ADE1); the other was heterozygous (ura3::C-ADE1/ura3). The ura3::C-ADE1 allele in the latter strain was re-substituted by C-URA3 to rescue the adenine auxotroph (his5, ade1, C-URA3/ura3). Finally, by selecting a 5FOA-resistant mutant, a triple auxotroph (his5, ade1, ura3/ura3) was isolated.     

The primary structure of the leul + gene of Schizosaccharomyces pombe

Summary A DNA fragment which carries the leul gene encoding beta-isopropylmalate dehydrogenase in Schizosaccharomyces pombe has been isolated by complementation of an E. coli leuB mutation. This 1.5 kb DNA fragment complements not only the S. pombe leul mutation, but also the S. cerevisiae leu2 mutation. The nucleotide sequence of the essential part of the leul gene and its flanking regions was determined. This sequence contains an open reading frame of 371 codons, from which a protein having a Mr = 39,732 can be predicted. The deduced amino acid sequence and its codon usage were compared with those of the S. cerevisiae LEU2 protein. The cloned DNA will be a useful marker when transforming S pombe.     

Molecular properties of the lys1 + gene and the regulation of α-aminoadipate reductase in Schizosaccharomyces pombe

The -aminoadipate pathway for the biosynthesis of lysine is unique to fungi. Molecular properties of the cloned lys1 ⁺ gene and the regulation of the encoded -aminoadipate reductase (AAR) were investigated in the fission yeast Schizosaccharomyces pombe. A 5.2-kb HindIII-EcoRI fragment of S. pombe DNA, containing a functional lys1 ⁺ gene and a promoter, was subcloned to make the 10.7-kb plasmid pLYS1H. A nested 1.778-kb HindIII-EcoRI DNA fragment that complemented the lys1-131 mutant phenotype was sequenced from the plasmid pLYS1D, and shown to contain an open reading frame (ORF) of 470 amino acids, preceded by putative POLII promoter elements (TATA and CCAAT box elements, and two potential yeast GCN4-binding motifs) within 368 bp upstream of the start codon. This ORF shared with the corresponding region of the isofunctional AAR of Saccharomyces cerevisiae 49% amino-acid identity (62% similarity) overall, within which were smaller regions of marked sequence conservation. One such region coincided (95% identity) with a putative AMP-binding domain motif identified in the AAR of S. cerevisiae. In wild-type S. pombe, AAR activity from cells grown in lysine-supplemented minimal or YEPD media was less than the activity of cells grown in minimal mediu. The AAR of S. pombe was more sensitive to feedback inhibition by lysine in vitro than the AAR of S. cerevisiae. These results show the effects of extensive evolutionary divergence on the structure and expression of a pivotal enzyme in the -aminoadipate pathway. Presumably, delineated regions of strong sequence conservation correspond to discrete domains essential to AAR function.     

Six new amino acid-auxotrophic markers for targeted gene integration and disruption in fission yeast

Fission yeast Schizosaccharomyces pombe is amenable to genetics and is an excellent model system for studying eukaryotic cell biology. However, auxotrophic markers that can be used for both targeted gene integration and disruption are very limited. Here we performed a forward genetic screen in an effort to develop a new set of selectable markers for use in this yeast. Mutants that were auxotrophic for arginine, asparagine, cysteine, lysine, methionine and phenylalanine were isolated. Six genes were analyzed in detail and the mutations in the genes were identified. Among these six are three new genes: asn1 ⁺, cys2 ⁺ and pha2 ⁺ were required for biosynthesis of asparagine, cysteine and phenylalanine, respectively. New alleles of arg1 ⁺, lys3 ⁺ and met6 ⁺ were also identified. All of these genes proved to be suitable as selectable markers for targeted gene integration and disruption. We also showed that in Schizosaccharomyces pombe there are two apparent homologues of Saccharomyces cerevisiae MET2: the previously known met6 ⁺, and SPBC106.17c (named cys2 ⁺). The cys2 mutation required cysteine rather than methionine. These new tools, specifically, new selectable markers, will be useful in further genetic and biological studies in fission yeast.