Biolistic transformation of Trichoderma harzianum and Gliocladium virens using plasmid and genomic DNA

Biolistic (biological ballistic) and protoplast-mediated procedures were compared as methods for transforming strains of Gliocladium virens and Trichoderma harzianum. For biolistic transformation, conidia were bombarded using a helium-driven biolistic device to accelerate M5 tungsten particles coated with plasmid or genomic DNA. DNA from either source contained a bacterial hygromycin B resistance gene (hygB) as a dominant selectable marker. The same sources of DNA were also used to transform protoplasts using a standard polyethylene glycol-CaCl₂ protoplast fusion protocol. Hygromycin B-resistant (HygB^R) transformants were recovered from all strains, methods, and DNA sources except for genomic DNA used with the protoplast method. The biolistic procedure was technically simpler, and increased transformation frequency and genetic stability in the progeny as compared with the protoplast-mediated transformation. Southern analysis of homokaryotic HygB^R progenies showed that the transforming sequences were integrated into the genome of the recipient strains, and apparently were methylated. This is the first study presenting detailed results on biolistic transformation of a filamentous fungus.     

Transformation of the phytopathogenic fungus Septoria nodorum to hygromycin B resistance

Summary The phytopathogenic fungus Septoria nodorum has been transformed using a plasmid (pAN7-1) containing the Escherichia coli hygromycin phosphotransferase gene (hph). Large, stable hygromycin-resistant transformant colonies appeared at frequencies between 2 and 25 per g DNA when wheat-adapted and barley-adapted wild type strains were used as recipients. These transformants grew at hygromycin concentrations up to ten times that which inhibits the wild types. A second type of colony also developed on transformation plates. These appeared at higher frequencies, grew less vigorously and could not be subcultured in the presence of hygromycin. They are believed to be abortive transformants. Southern hybridization analyses indicated that transformation takes place via the integration of plasmid DNA into the fungal chromosomal DNA. Multiple integrations occur producing tandemly iterated arrays of plasmid molecules. Some transformants arose as heterokaryons. These could be resolved by propagation through a single spore and transformants purified in this way remained mitotically stable. All of 1,025 transformants tested were unchanged in pathogenicity. Reisolates from leaves retained their hygromycin-resistance, indicating that transformants remain stable during growth in plant tissue. Cotransformation of an unselected plasmid (p3SR2) carrying the Aspergillus nidulans amdS gene occurred at a high frequency.     

A transformation procedure for Botryotinia squamosa

Summary The onion leaf blight fungus, Botrytis squamosa, was transformed to hygromycin B resistance using a plasmid (pDH25) containing a bacterial gene for hygromycin phosphotransferase (hph) fused to promoter elements from Aspergillus. Southern hybridization of transformants indicated that single or multiple copies of the vector were integrated into heterologous regions of the B. squamosa genome. Free plasmid was found in undigested preparations of transformant DNA, but was not detected after 3–5 passages of selective transfer. Most transformants were mitotically stable in both selective and non-selective growth; however, both genetic rearrangements and loss of integrated DNA occurred during vegetative growth.     

Transformation of Botrytis cinerea with the hygromycin B resistance gene,hph

A transformation method has been developed for the phytopathogenic fungus Botrytis cinerea. Protoplasts were transformed with pAN7-1 plasmid carrying the Escherichia coli hygromycin phosphotransferase gene (hph), confering hygromycin B resistance, downstream from an Aspergillus nidulans promoter. Molecular analysis showed that transformation resulted in an integration of the plasmid into different regions of the B. cinerea genome and occurred through non-homologous recombination. The frequency was 2–10 transformants per g of DNA. Transformants expressed phosphotransferase activity confirming that the hph gene conferred the hygromycin-resistance phenotype. All transformants analysed so far proved to be stable after several subcultures without any selective pressure.     

Gibberella pulicaris transformants: state of transforming DNA during asexual and sexual growth

A genetically fertile, trichothecene-producing plant pathogen, Gibberella pulicaris (Fusarium sambucinum), was transformed with three different vectors: cosHyg1, pUCH1, and pDH25. All three vectors carry hph (encoding hygromycin B phosphotransferase) as the selectable marker. Transformation frequency was 0.03 transformants per mg of DNA for pDH25 and 0.5 for pUCH1 or cosHyg1. The vector DNA sequences integrated at different sites into the fungal genome. Transformants were classified into three types based upon distinctive integration patterns: type A contained a single, intact copy of the vector at one site per genome; type B contained multiple tandem copies or a combination of single and multiple tandem copies at one or more sites per genome; type C contained a partial vector copy at one site per genome. While the transformants with cosHyg1 and pUCH1 were type A or B, type C was unique to pDH25 transformants. Type A and C transformants were both meiotically and mitotically stable. However, type B multiple inserts were unstable in mitosis and meiosis since: (1) multiple tandem copies were deleted: (2) rearrangements occurred during premeiosis; and (3) inserts in one of the type B transformants became methylated during premeiosis. Differential expression of transforming sequences between spore germination and mycelial growth was also observed among type B transformants. The ability to transform G. pulicaris with the resulting varied features of integration patterns and the behavior of transforming DNA during mitosis and meiosis provides a means to isolate, manipulate, and study cloned genes in this mycotoxin-producing plant pathogen.Mention of companies or products by name does not imply the endorsement by the U.S. Department of Agriculture over others not cited     

Genetic transformation of the symbiotic basidiomycete fungus Hebeloma cylindrosporum

Summary The pAN7.1 plasmid containing the E. coli hygromycin B phosphotransferase gene was used to transform protoplasts of the ectomycorrhizal fungus Hebeloma cylindrosporum. Hygromycin-resistant transformants were selected at a frequency of one to five per g of transforming DNA. Southern blot analyses revealed multiple copy integration of the transforming plasmid into the genome. The selection system was used to introduce other genes of interest by co-transformation. Two plasmids, one containing tryptophan biosynthesis genes and the other the NADP-glutamate dehydrogenase gene from the saprophytic basidiomycete Coprinus cinereus, were successfully introduced into the H. cylindrosporum genome with up to 70% efficiency of co-transformation. The hygromycin resistance phenotype was stably maintained during growth of transformants on hygromycinfree medium. All tranformants retained their ability to form mycorrhizae with the habitual host plant Pinus pinaster, making them suitable for future physiological studies.     

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.     

Transformation of Sordaria macrospora to hygromycin B resistance: characterization of transformants by electrophoretic karyotyping and tetrad analysis

The ascomycete Sordaria macrospora was transformed using different plasmid molecules containing the bacterial hygromycin B resistance gene (hph) under the control of different expression signals. The highest transformation frequency was obtained with vector pMW1. On this plasmid molecule, expression of the hph gene is directed by the upstream region of the isopenicillin N synthetase gene (pcbC) from the deuteromycete Acremonium chrysogenum. Southern analysis suggests that the vector copies are integrated as tandem repeats into the S. macrospora chromosomes and that duplicated sequences are most probably not inactivated by methylation during meiosis. Furthermore, the hygromycin B resistance (hygR) is not correlated with the number of integrated vector molecules. Electrophoretic karyotyping was used to further characterize S. marcospora transformants. Five chromosomal bands were separated by pulsed-field gel electrophoresis (PFGE) representing seven chromosomes with a total genome size of 39.5 Mb. Hybridization analysis revealed ectopic integration of vector DNA into different chromosomes. In a few transformants, major rearrangements were detected. Transformants were sexually propagated to analyze the fate of the heterologous vector DNA. Although the hygR phenotype is stably maintained during mitosis, about a third of all lines tested showed loss of the resistance marker gene after meiosis. However, as was concluded from electrophoretic karyotyping, the resistant spores showed a Mendelian segregation of the integrated vector molecules in at least three consecutive generations. Our data indicate that heterologous marker genes can be used for transformation tagging, or the molecular mapping of chromosomal loci in S. macrospora     

Transformation of Aspergillus giganteus to hygromycin B resistance

Summary A wild strain of A. giganteus was transformed to hygromycin B resistance using a bacterial resistance gene under the control of A. nidulans sequences. Stable transformants arose by heterogenous integration, mainly of tandem repeats of vector DNA at various sites in the host genome. Between 6 and 30 resistant colonies were obtained per g DNA per 3×10³ viable protoplasts. Vector DNA could be recovered by transformation of Escherichia coli with undigested genomic DNA from Aspergillus giganteus transformants.     

Biolistic transformation of conidia of Botryotinia fuckeliana

Botryotinia fuckeliana, the causal agent of grey mould, was biolistically transformed to hygromycin B resistance using a plasmid (pOHT) containing a bacterial hygromycin phosphotransferase gene fused to regulatory sequences from Aspergillus nidulans. Multiple copies of the plasmid, precipitated onto tungsten particles, were delivered into the conidia by a helium-driven gene gun. Southern analysis showed that the plasmid was integrated into the fungal genome at one single locus. After five subsequent transfers on selective medium, all transformants were mitotically stable. When propagated on non-selective medium, four out of eight transformants retained their resistance to hygromycin B. Southern analysis of the fifth generation of transformants showed that no genetic rearrangements occurred during vegetative growth of stable transformants.     

Transformations of Penicillium islandicum and Penicillium frequentans that produce anthraquinone-related compounds

Wild-type strains of Penicillium islandicum and Penicillium frequentans, which produce anthraquinone and related compounds, were transformed to benomyl and hygromycin B resistance. Plasmids pSV50 and pBT6, with benomyl-resistant -tublin genes, and plasmids pAN7-1 and pDH25, with a bacterial hygromycin phosphotransferase gene under the control of Aspergillus nidulans sequences, were used respectively. Transformation frequencies with these plasmids were 10–20 transformants per g of DNA per 4-8×10⁷ viable protoplasts. Intergration of plasmid DNAs into chromosomal DNAs was confirmed by Southern-blot analysis. Copy numbers and sites of integration varied among transformants. The integrated plasmid DNAs conferring a drug-resistant phenotype were mitotically stable with or without selection. The demonstration of such transformation systems is the essential first step in the application of recombinant DNA technology to study the biosynthetic genes of anthraquinone and related compounds in P. islandicum and P. frequentans.     

Transformation of the oomycete pathogen Phytophthora megasperma f. sp. glycinea occurs by DNA integration into single or multiple chromosomes

A procedure for stable transformation was developed for Phytophthora megasperma f. sp. glycinea, an oomycete pathogen of soybean. Transformants were obtained using a bacterial hygromycin resistance gene fused to a promoter and terminator from the ham34 gene of another oomycete, Bremia lactucae. Vector DNA, alone or complexed to cationic liposomes, was introduced into protoplasts using polyethylene glycol and CaCl₂. DNA and RNA hybridization, and phosphotransferase assays, confirmed the presence and expression of vector DNA in the transformants. Hybridization to electrophoretically separated chromosomes of P. m. glycinea showed that vector DNA had integrated into only one chromosome in four transformants, and into multiple chromosomes in one transformant.     

Development of a transformation system for the filamentous,ML-236B (compactin) — producing fungus Penicillium citrinum

Summary We present here the first report of a transformation system developed for the filamentous, ML-236B (compactin)-producing fungus Penicillium citrinum. Hygromycin B-resistant colonies were obtained after treatment of protoplasts with a vector containing an Escherichia coli hygromycin B phosphotransferase gene fused to a 3-phosphoglycerate kinase promoter from Aspergillus nidulans. The transformation rate was 194 transformants per g circular DNA per 4x10⁵ viable protoplasts under optimized transformation conditions. Transformation took place via the integration of plasmid DNA into the fungal chromosomal DNA. Most of the integration events appeared to produce tandemly iterated arrays of plasmid molecules at different sites in the chromosome. The transformed, drug-resistant, phenotype and the integrated plasmids were mitotically stable with or without selection in a majority of cases. The demonstration of such a transformation system is an essential first step in the application of recombinant DNA technology to strain improvement and for the production of novel ML-236B derivatives.     

High efficiency transformation of Fusarium solani f. sp. cucurbitae race 2 (mating population V)

Summary A cosmid vector, suitable for library construction and DNA transformation in filamentous fungi, has been constructed and a reliable and highly efficient PEG-mediated DNA transformation system for F. solani f. sp. cucurbitae, based on resistance to hygromycin B, has been developed for use with this vector. This transformation system yielded 10⁴ transformants per g of DNA when using 10⁷ protoplasts. Factors important in achieving high efficiency included: the maintenance of an osmoticum in all transformation steps, PEG 4000 concentration, and the ratio of transforming vector DNA to protoplasts. Approximately 60% of transformants stably integrated vector DNA. Molecular analysis revealed multiple copies of the plasmid integrated into the genome at one or more sites. The frequency of transformation achieved will facilitate the isolation of genes from this fungus by complementation.     

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.     

Transformation of Trichoderma harzianum by high-voltage electric pulse

Summary We have developed conditions for an efficient method of genetic transformation in Trichoderma harzianum, using high-voltage electroporation. Transformation was obtained with a plasmid carrying the Escherichia coli, hygromycin B phosphotransferase gene as a dominant selectable marker, and the gpd promoter and trpC terminator from Aspergillus nidulans. The transformation frequency is up to 400 transformants per g of plasmid DNA. The transformants were phenotypically 100% stable; they were also mitotically stable. Hybridization experiments suggest that the transforming DNA might be integrated at the same position in the T. harzianum genome. This report opens possibilities for improving transformation systems that have already been described for fungi, or else for transforming filamentous fungi where the use of polyethylene glycol is not efficient.     

The transformation of protoplasts of Leptosphaeria maculans to hygromycin B resistance

Summary Conditions are described for the efficient isolation and regeneration of protoplasts of a fungal pathogen of brassicas, Leptosphaeria maculans. Treatment of the protoplasts with DNA of the plasmid pAN7-1 (containing an E. coli hygromycin phosphotransferase gene with Aspergillus nidulans expression signals) and plating under selective conditions resulted in the formation of hygromycin 13-resistant colonies. Southern blot analysis of resistant colonies indicated that single copies of the plasmid had integrated into different sites in the genome. In twelve of the transformants analysed so far, the integration is stable through mitosis. The demonstration of efficient transformation is an essential first step in the molecular analysis of pathogenicity of this commercially important pathogen.     

Shuttle vectors for <Emphasis Type="Italic">Candida albicans</Emphasis>: control of plasmid copy number and elevated expression of cloned genes

Plasmids containing the inosine monophosphate dehydrogenase gene CaIMH3 from Candida albicans strain ATCC 32354 transform their host to resistance against mycophenolic acid (MPA). The transformants maintain the plasmids at a high copy number (20–40 per cell) and express the CaIMH3 gene at very high levels relative to untransformed controls. The plasmid copy number can be controlled by the concentration of MPA in the media. The transformation procedure is reproducible and the efficiency of transformation is high, up to 15,000 per microgram. Unrearranged plasmids are readily recovered by transforming total DNA from transformants back into Escherichia coli. C. albicans genes cloned into the plasmid are expressed at elevated levels relative to untransformed controls. A derivative vector containing the CaMAL2 promoter and termination sequences expresses the CaERG11 ORF at high levels and confers moderate resistance to fluconazole. These shuttle vectors should facilitate global genomics approaches in C. albicans that have been hampered by its diploid genome.