Extrachromosomal genetics of Cephalosporium acremonium

Summary In order to facilitate strain improvement by concerted breeding in the cephalosporin producing imperfect filamentous fungus Cephalo sporium acremonium, it is attempted to develop a eukaryotic vector for molecular cloning based on mitochondrial (mt) DNA.Fragments of mtDNA from C. acremonium were inserted into a yeast/bacterial hybrid plasmid (pDAM1) lacking a eukaryotic replicon. Six hybrid plasmids were obtained each containing a different mt fragment which together comprise about 60% of the total mtDNA. One of these recombinant plasmid vectors (pCP2) showed a high replication efficiency which is comparable to that of vectors containing yeast 2 m DNA. This plasmid therefore fulfills the requirements for practical application.     

Organization of the 5.8S, 16–18S,and 23–28S ribosomal RNA genes of Cephalosporium acremonium

Summary A 9.2 kb Pst1 restriction fragment, repeated tandemly head-to-tail in the genome, contains the 5.8S, 16–18S, and 23–28S ribosomal RNA (rRNA) genes of Cephalosporium acremonium, a filamentous fungus used at the industrial scale for production of cephalosporin antibiotics. These rRNA genes were located in Pst1 digests of C. acremonium genomic DNA using a hybridization probe that contained the 5.8S, 18S, and 25S rRNA genes from the yeast Saccharomyces cerevisiae. This probe was also used in screening a recombinant lambda library to identify phage carrying rRNA genes of C. acremonium. Yeast rRNA genes contained separately on individual ³²P-labeled plasmids were used to demonstrate that a cloned 7.2 kb C. acremonium sequence, represented in the repeated 9.2 kb Pst1 fragment, contained DNA from the C. acremonium 5.8S, 16–18S, and 23–28S rRNA genes. These genes were ordered with the 5.8S gene located between the 16–18S and 23–28S rRNA genes. The order of the 16–18S, 5.8S, and 23–28S rRNA genes observed in C. acremonium is the same as that observed in rRNA repeats of many other lower eucaryotes, e.g. S. cerevisiae, Aspergillus nidulans, and Neurospora crassa.     

Integrative and replicative genetic transformation of Aureobasidium pullulans

A hybrid selectable marker for transformation was constructed by placing the promoter (TEF1p) from the gene encoding the Aureobasidium pullulans translation elongation factor 1- (TEF1) adjacent to the 5 end of the Escherichia coli hygromycin B phosphotransferase gene (HPT). Plasmids containing this hybrid gene (TEF1p/HPT) transformed A. pullulans strain R106 to a hygromycin B-resistant (HmB^R) phenotype. A PCR-generated DNA fragment consisting of the TEF1p/HPT resistance marker flanked by 41 bp of homologous DNA has also been shown to transform A. pullulans to HmB^R. Linearized plasmid DNA consistently produced more transformants than circular plasmid DNA. Analyses of 23 HmB^R transformants revealed integration of the plasmid in only eight of these transformants. In two transformants, integration into the largest chromosome (VIII) resulted in an alteration of the molecular karyotype. In four other transformants, integration occurred in chromosome VI (the chromosome containing TEF1) but only one was the result of homologous recombination with the genomic copy of the TEF1 promoter. The remainder of the transformants contained replicative plasmids that could be visualized on an agarose gel by ethidium bromide staining. These plasmids were generally 7–8 kb in size. One transformant appeared to contain four plasmids ranging in size from 4 to 8 kb, suggesting rearrangement of the transforming DNA. One plasmid obtained from a HmB^R A. pullulans transformant was able to transform E. coli to ampicillin resistance. However, after recovery from E. coli, this plasmid (approximately 4 kb) was unable to transform A. pullulans to HmB^R.     

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     

Behaviour of recombinant plasmids in Aspergillus nidulans: structure and stability

Summary A pyrG ^– Aspergillus strain was transformed with plasmid pDJB-1, derived from pBR325 by insertion of the Neurospora crassa pyr4 gene (orotidine 5-phosphate carboxylase), giving mitotically unstable transformants. Aspergillus DNA which acted as an autonomously replicating sequence (ARS) in yeast was inserted into pDJB-1 and the resulting construct, pDJB12.1, gave mitotically stable transformants when introduced into Aspergillus. Transformants obtained with pDJB-1 and pDJB12.1 gave few pyr ^– progeny in crosses to a pyrG ⁺ strain. Southern hybridisation analysis of pyr ⁺ transformants obtained with pDJB-1 revealed restriction fragments expected for integrated plasmid but transformants obtained with pDJB12-1 showed only bands derived from free plasmid. pDJB-1 and derivatives of pDJB12.1 could be recovered from transformants. These derivatives could not be explained by straightforward excision of integrated pDJB12.1 sequences but could result from recombination between plasmid molecules. Hybridisation of undigested transformant DNAs showed that the transforming DNA was present in a high molecular weight form. These results suggest: (1) pDJB12.1 derivatives and possibly pDJB-1 can replicate autonomously in Aspergillus; (2) A. nidulans DNA acting as an ARS in yeast enhances replication and/or segregation of transforming plasmids in Aspergillus; and (3) recombinant plasmids may undergo rearrangements when introduced into Aspergillus.Abbreviations PABA para-amino benzoic acid - EDTA disodium salt of ethylene diamine tetra-acetic acid - SDS sodium dodecyl sulphate - DTT dithiothreitol - UV ultra violet - SSC standard saline citrate; 0.15 M sodium chloride, 0.015 M trisodium citrate pH 7. - ARS('s) autonomously replicating sequence(s) - kb kilobase pairs     

Heterologous gene expression of the glyphosate resistance marker and its application in yeast transformation

Summary The E. coli aroA gene was inserted between yeast promoter and terminator sequences in different shuttle expression plasmids and found to confer enhanced EPSP synthase activity as well as resistance to glyphosate toxicity. Subsequently, a transformation system using these newly constructed vectors in yeast was characterized. The efficiency of the glyphosate resistance marker for transformation and selection with plasmid pHR6/20-1 in S. cerevisiae laboratory strain SHY2 was found to be relatively high when compared with selection for LEU2 prototrophy. The fate of the recombinant plasmid pHR6/20-1 in the transformants, the preservation of the aroA E. coli DNA fragment in yeast, mitotic stability, EPSP synthase activity, and growth on glyphosate-containing medium have been investigated. As this plasmid also allows direct selection for glyphosate resistant transformants on rich media, the glyphosate resistance marker was used for transforming both S. cerevisiae laboratory strain SHY2 and brewer's yeast strains S. cerevisiae var. uvarum BHS5 and BHS2. In all cases, the vector pHR6/20-1 was maintained as an autonomously replicating plasmid. The resistance marker is, therefore, suitable for transforming genetically unlabeled S. cerevisiae laboratory, wild, and industrial yeast strains.Abbreviations EPSP 5-enolpyruvylshikimate 3-phosphate     

The CDC8 gene product is required for transformation with episomal and integrative plasmids in Saccharomyces cerevisiae

Summary The product of the yeast CDC8 gene (thymidylate kinase), which is required for chromosomal, mitochondrial and 2 plasmid replication, also participates in plasmid transformation processes in S. cerevisiae. The thermosensitive cdc8-1 mutant strain was transformed with episomal pDQ9 and integrative pDQ9-1 plasmids both of which carry the CDC8 gene. The results suggest that thymidylate kinase is essential for the expression of genes carried on transforming episomal plasmid DNA (probably through its replication) and is also essential for homologous recombination between chromosomal and linearized integrative plasmid DNA.     

Evidence for autonomous replication and stabilization of recombinant plasmids in the transformants of yeast Hansenula polymorpha

Summary For the transformation of the yeast Hansenula polymorpha we have constructed a set of hybrid plasmids carrying the LEU2 gene of Saccharomyces cerevisiae as a selective marker and fragments of mitochondrial DNA of Candida utilis and H. polymorpha or chromosomal DNA fragments of H. polymorpha as replicator sequences. The replication properties of chimeric plasmids in the yeast H. polymorpha were investigated. We showed that for plasmids propagated autonomously in this yeast the plasmid monomers could be detected in the transformants only during the immediate time after the transformation event. Further growth under selective conditions led to the selection of polymeric forms of plasmid DNA as it was clearly shown for transformants carrying cosmid pL2 with mtDNA fragment of C. utilis. Such transformants carrying polymerized plasmids showed a remarkably increased stability of the transformed phenotype. Cosmid pL2 was able to shuttle between Escherichia coli, S. cerevisiae and H. polymorpha, whereas plasmids with DNA fragments from H. polymorpha did not transform S. cerevisiae effectively.     

Trehalose and maltose metabolism in yeast transformed by a MAL4 regulatory gene cloned from a constitutive donor strain

Summary A 6.8 kb fragment of DNA containing the regulatory sequence MAL4p has been cloned from a genomic library prepared from Saccharomyces cerevisiae strain 1403-7A which ferments maltose constitutively. The library was prepared by ligation of 5–20 kb Sau3AI restriction fragments of total yeast DNA into the BamH1 restriction site of shuttle vector YEp13. A restriction map of the cloned fragment indicates that it encompasses a 2.6 kb segment which closely resembles the regulatory MAL6 gene previously identified (Needleman et al. 1984). The hybrid plasmid, p(MAL4p)4, could transform maltose-nonfermenting strains which contain cryptic -glucosidase and maltose permease genes (malp MALg), but could not transform strains containing a functional regulatory sequence and a defective maltase-permease region (MAlp malg). A correlated absence of maltase and permease DNA from the cloned fragment was indicated by the restriction map. Although the cloned DNA fragment was derived from a constitutive strain, maltose fermentation and -glucosidase formation by yeast transformed with p(MAL4p)4 was largely inducible by maltose and sensitive to catabolite repression. Moreover, the active trehalose accumulation pattern (TAC(+) phenotype) linked to the complete MAL4 locus in strain 1403-7A and other constitutive MAL strains (Oliveira et al. 1981b) was not found in p(MAL4p)4 transformants. It may be concluded that constitutivity of maltose fermentation and the associated active trehalose accumulation are not merely consequences of a cis-dominant mutation causing constitutive formation of the MALp regulatory product. Moreover, constitutivity may not be caused solely by a mutation within the structural region of the MALp gene.     

Integrative transformation of the yeast Yarrowia lipolytica

Summary An EcoR1 shotgun of Yarrowia lipolytica DNA was inserted into the plasmid YIp333 which carries the LYS2 gene of S. cerevisiae. The resulting plasmid pool was transformed in both S. cerevisiae and Y. lipolytica. Whereas numerous replicating plasmids could be isolated from the S. cerevisiae Lys⁺ transformants, all transformants of Y. lipolytica so far analyzed were found to result from integrative transformation. This occurred at a frequency of 1 to 10 transformants per g of input DNA. Co-transformation occurred at high frequency and resulted in tandem integration of 2 to 10 copies of the incoming DNA. Structural and segregational stability of the transforming DNA were both high.     

Transformation ofGaeumannomyces graminis to benomyl resistance

Summary Gaeumannomyces graminis var.graminis andtritici were transformed to benomyl resistance using pBT3, a plasmid encoding fungicide-resistant -tubulin. Either circular or linear plasmid DNA producedG. graminis var.graminis transformants in which plasmid DNA was integrated into the fungal genome. There was no evidence for autonomous plasmid replication in any of the transformants examined. 4/11 linear DNA transformants had a single plasmid copy, whereas 8/9 circular DNA transformants had multiple copies of the plasmid. Integration of transforming DNA occurred by nonhomologous recombination in all (20/20) of these transformants.     

A homologous and self-replicating system for efficient transformation ofFusarium oxysporum

A highly efficient transformation system has been developed forFusarium oxysporum f. sp.lycopersici based on the complementation of a nitrate-reductase mutant with the homologousnitI gene and on the presence ofARS and telomeric sequences in the vector. Preliminary transformation experiments with theniaD gene fromAspergillus niger generated self-replicating plasmids within the transformed entity that contained extra-fungal DNA. A fragment of the extra DNA was inserted into pUC19 together with theF. oxysporum nitl gene, resulting in plasmid pFNit-Lam. This allowed the isolation of a new linear plasmid within self-replicativeF. oxysporum transformants (pFNit-Lam-TLam, linear). The circular form of this vector yielded 5600 fungal transformants per g of DNA. All of the transformants contained autonomous linear plasmids harboring direct repeats of fungal DNA at both ends. The sequence of the 1.2-kb fragment fromF. oxysporum responsible for autonomous replication, and maintenance as linear plasmid molecules, has been determined. Comparison analysis with theARS from different organisms has shown that this fragment contained the commonly identifiedARS consensus sequence, 5A/TTTTATA/GTTTA/T3 and, in addition to this core, ten copies of theARS-box, TNTA/GAA3. Adjacent to this presumedARS, the telomeric hexanucleotide sequence (TTAGGG)_n was present in six tandem copies followed by 18 copies of its complementary sequence.     

Cloning of the Trichoderma reesei pyrG gene and its use as a homologous marker for a high-frequency transformation system

Summary The Trichoderma reesei orotidine-5-phosphate decarboxylase gene was isolated by heterologous hybridization with the corresponding Neurospora gene as a probe. A 2.7 kb SalI fragment, which exclusively hybridized to the Neurospora gene, was subcloned in pGEM-5Zf(+). This subclone was termed pFG1 and was used to transform a Trichoderma reesei pyrG^- negative mutant to PYR⁺. The transformation frequency in this homologous system was up to 12000 transformants per g DNA. About one-fifth of the transformants tested were abortive. Perfect mitotic stability was found in half of the non-abortive transformants, correlating with vector integration at homologous and ectopic loci. In the unstable transformants the transforming DNA appears to be present in the form of extrachromosomal elements.     

Homologous transformation of the lignin-degrading basidiomycete Phanerochaete chrysosporium

Summary A clone containing the Phanerochaete chrysosporium ade1 gene was isolated from a EMBL3 genomic library using the ade5 gene encoding aminoimidazole ribonucleotide synthetase, from Schizophyllum commune, as a probe. A 6.0 kb fragment incorporating the ade1 gene was subcloned into pUC18 (pADE1) and used to transform the P. chrysosporium ade1 auxotrophic strain. Transformation frequencies were similar to those obtained previously with the S. commune ade5 gene; however, homologous transformants arose earlier than heterologous transformants. The transformants were mitotically and meiotically stable and Southern blot analysis indicated that the plasmid, pADE1, integrated ectopically in single or multiple copies. The pADE1 insert was mapped for restriction sites and the approximate location of the ade1 gene within the insert was determined.     

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     

Highly-efficient electrotransformation of the yeast Hansenula polymorpha

A highly-efficient method for transformation of the methylotrophic yeast Hansenula polymorpha has been developed. Routinely, transformation frequencies of up to 1.7×10⁶/g plasmid DNA were obtained by applying an electric pulse of the exponential decay type of 7.5 kV/cm to a highly-concentrated cell mixture during 5 ms. Efficient transformation was dependent on: (1) pretreatment of the cells with the reducing agent dithiotreitol, (2) the use of sucrose as an osmotic stabilizer in an ionic electroporation buffer, and (3) the use of cells grown to the mid-logarithmic phase. Important parameters for optimizing the transformation frequencies were field strength, pulse duration, and cell concentration during the electric pulse. In contrast to electrotransformation protocols described for Saccharomyces cerevisiae and Candida maltosa, transformation frequencies (transformants per g DNA) for H. polymorpha remained high when large amounts (up to 10g) of plasmid DNA were added. This feature renders this procedure pre-eminently advantageous for gene cloning experiments when high numbers of transformants are needed.     

Sequence of the cloned pyr4 gene of Trichoderma reesei and its use as a homologous selectable marker for transformation

Summary We have cloned and sequenced the Trichoderma reesei pyr4 gene encoding orotidine-5-monophosphate decarboxylase. Comparison of this sequence with that of the equivalent gene from other filamentous fungi suggests that T. reesei is closely related to Cephalosporium acremonium and Neurospora crassa. The cloned pyr4 gene has been used as a homologous selectable marker for transformation of T. reesei. The majority of transformants obtained with circular plasmid were mitotically unstable and contained non-integrated plasmid molecules, sometimes in addition to plasmid integrated in the genome, Linearization of plasmid prior to transformation decreased the transformation frequency but increased the proportion of stable transformation obtained.     

Cloning and biochemical characterization of LYS5 gene of Saccharomyces cerevisiae

Summary In Saccharomyces cerevisiae, the functions of two unlinked genes (LYS2 and LYS5) are required for the synthesis of the lysine biosynthetic enzyme, -aminoadipate reductase. The LYS5 gene of S. cerevisiae was cloned by functional complementation of a lys5 mutant, X4004-3A, using a YEp24 plasmid library. The cloned LYS5 gene was contained within a 7.5 kb DNA insert of the recombinant plasmid pSC5. Cloning of LYS5 gene was confirmed by second cycle transformation of a lys5 mutant with the pSC5 plasmid, growth response studies, and plasmid loss experiments with Lys5 ⁺ transformants. Analysis of restriction digests of the pSC5 plasmid revealed 3 EcoRI, 5 PvuII, 1 PstI, 1 BglII and 2 HpaI sites in the 7.5 kb insert. A 3.9 kb internal pSC5 fragment hybridized only to the plasmid pSC5, but no homology was observed with LYS2 DNA or the YEp24 vector. The pSC5 transformed Lys5 ⁺ cells and the wild-type strain exhibited same level of -aminoadipate reductase activity, whereas lys5 mutant and plasmid-cured transformed strain exhibited none. Lys2 ⁺ transformants consistently had five times greater -aminoadipate reductase activity when compared with the wildtype and the Lys5 ⁺ transformant. The -aminoadipate reductase activity was repressed in lysine-grown wildtype and Lys5 ⁺ transformed cells but not in Lys2 ⁺ transformed cells. A Lys2 ⁺ and Lys5 ⁺ double transformant exhibited higher a-aminoadipate reductase activity than lys2 ⁺ or lys5 ⁺ transformant.     

Cloning and identification of a DNA fragment coding for the sup1 gene of Saccharomyces cerevisiae

Summary A plasmid, pYsup1-1, containing a DNA fragment able to suppress the recessive mutant phenotype of the suppressor locus sup1 (allele sup1-ts36) of Saccharomyces cerevisiae was isolated from a bank of yeast chromosomal DNA cloned in cosmid p3030. The complementing gene was localized on a 2.6 kb DNA fragment by further subcloning. Evidence is presented that the cloned DNA segment codes for the sup1 structural gene (chromosome IIR).     

Restriction fragment length polymorphisms in Septoria tritici occur at a high frequency

Summary A set of probes that detect restriction fragment length polymorphisms (RFLPs) in nuclear DNA has been developed for genetic studies of the phytopathogenic fungus Septoria tritici. Two plasmid libraries containing 0.5–1.3 or 1.3–2.4 kb fragments of S. tritici nuclear DNA were constructed. Seventeen random clones from each library were used as probes to screen for RFLP variation among a geographically-diverse group of six S. tritici isolates. Among the 196 probe-enzyme combinations tested, 145 detected RFLPs among the six isolates. The restriction enzymes EcoRV and PstI detected RFLPs most efficiently. Three probes detected deletions. A ribosomal DNA probe from yeast did not detect a significant amount of variation. These probes will be useful for studying genetic variation, population genetics, and genome organization of S. tritici.