Fate of DNA encoding hygromycin resistance after meiosis in transformed strains of Gibberella fujikuroi (Fusarium moniliforme)

Stability of foreign DNA transformed into a novel host is an important parameter in decisions to permit the release of genetically engineered microorganisms into the environment. Meiotic instability of transformed DNA has been reported in fungi such as Ascobolus, Aspergillus, and Neurospora. We used strains of Gibberella fujikuroi (Fusarium moniliforme) transformed with the hygr gene from Escherichia coli to study meiotic stability of foreign DNA in this plant pathogenic fungus. Crosses with single-copy transformants segregated hygr:hygs in a 1:1 manner consistent with that expected for a Mendelian locus in a haploid organism. Multicopy transformants, however, segregated hygr:hygs in a 1:2 manner that was not consistent with Mendelian expectations for a chromosomal marker, even though two unrelated auxotrophic nuclear genes were segregating normally. Segregation ratios in crosses in which hygr was introduced via the male parent did not differ significantly from crosses in which the transformed strain served as the female parent. Some of the sensitive progeny from the crosses with the multicopy transformants carried hygr sequences. When these phenotypically sensitive progeny were crossed with a wild-type strain that carried no hygr sequences, some of the progeny were phenotypically hygr. Some progeny from some crosses were more resistant to hygromycin than were their sibs or the transformant strains that served as their parents. Transformants passaged through a maize plant only rarely segregated progeny with the high levels of resistance. The mechanism underlying these genetic instabilities is not clear but may involve unequal crossing over or methylation or both. Further work with cloned genes with homology to sequences already present in the Fusarium genome is warranted.     

Homologous recombination in plant cells after Agrobacterium-mediated transformation.

A single amino-acid change in the acetolactate synthase (ALS) protein of tobacco confers resistance to the herbicide chlorsulfuron. A deleted, nonfunctional fragment from the acetolactate synthase gene, carrying the mutant site specifying chlorsulfuron resistance plus a closely linked novel restriction site marker, was cloned into a binary vector. Tobacco protoplasts transformed with Agrobacterium tumefaciens carrying this vector yielded chlorsulfuron-resistant colonies. DNA gel blot analysis of DNA from these colonies suggested that in three transformants homologous recombination had occurred between the endogenous ALS gene and the deleted ALS gene present in the incoming T-DNA. Plants were regenerated from these chlorsulfuron-resistant colonies, and in two of the transformants, genetic analysis of their progeny showed that the novel gene segregated as a single Mendelian locus. Possible models for the generation of these recombinant plants are discussed.     

Ribosomal DNA inheritance and recombination in Neurospora crassa

Summary The genetic segregation of ribosomal DNA (rDNA) in Neurospora crassa was analyzed by exploiting restriction fragment length polymorphisms in the nontranscribed spacer (NTS) sequences of nine laboratory wild-type strains and wild-collected strains. In an analysis of random spore progeny from seven crosses, and of ordered tetrads from two of those crosses the rDNA was shown to be inherited in a simple, stable Mendelian fashion, exhibiting an approximately 1:1 ratio of the two parental rDNA types. No meiotic recombinants were detected among the progeny, indicating that non-sister-chromatid crossing over is highly suppressed in the rDNA region. The basis for this suppression of meiotic recombination is not known.     

Transformation by Complementation of an Adenine Auxotroph of the Lignin-Degrading Basidiomycete Phanerochaete chrysosporium

Swollen basidiospores of an adenine auxotroph of Phanerochaete chrysosporium were protoplasted with Novozyme 234 and transformed to prototrophy by using a plasmid containing the gene for an adenine biosynthetic enzyme from Schizophyllum commune. Transformation frequencies of 100 transformants per μg of DNA were obtained. Southern blot analysis of DNA extracted from transformants demonstrated that plasmid DNA was integrated into the chromosomal DNA in multiple tandem copies. Analysis of conidia and basidiospores from transformants demonstrated that the transforming character was mitotically and meiotically stable on both selective and nonselective media. Genetic crosses between double mutants transformed for adenine prototrophy and other auxotrophic strains yielded Ade⁻ progeny, which indicated that integration occurred at a site(s) other than the resident adenine biosynthetic gene.     

Fumonisin production by field strains of Fusarium nygamai (Gibberella nygamai) and ascospore progeny of laboratory crosses

Field strains of Fusarium nygamai (Gibberella nygamai) are important producers of the fumonisin mycotoxins. Such strains were mated on carrot agar to obtain ascospore progeny. Field strains and ascospore progeny of F. nygamai produced differential levels of fumonisin B1 (FB1) and B2 (FB2) suitable for genetic analyses. Most of the strains produced higher levels of FB1 than FB2. Ascospore progeny from crosses segregated in 1:1 ratios for loci controlling FB1 production and mating type. These findings can be used as the basis to elucidate the genetics of fumonisin production by F. nygamai.     

Segregation of secondary metabolite biosynthesis in hybrids of Fusarium fujikuroi and Fusarium proliferatum

Fusarium fujikuroi and Fusarium proliferatum are two phylogenetically closely related species of the Gibberella fujikuroi species complex (GFC). In some cases, strains of these species can cross and produce a few ascospores. In this study, we analyzed 26 single ascospore isolates of an interspecific cross between F. fujikuroi C1995 and F. proliferatum D4854 for their ability to produce four secondary metabolites: gibberellins (GAs), the mycotoxins fusarin C and fumonisin B(1), and a family of red polyketides, the fusarubins. Both parental strains contain the biosynthetic genes for all four metabolites, but differ in their ability to produce these metabolites under certain conditions. F. fujikuroi C1995 produces GAs and fusarins, while F. proliferatum D4854 produces fumonisins and fusarubins. The segregation amongst the progeny of these traits is not the expected 1:1 Mendelian ratio. Only eight, six, three and three progeny, respectively, produce GAs, fusarins, fumonisin B(1) and fusarubins in amounts similar to those synthesized by the producing parental strain. Beside the eight highly GA(3)-producing progeny, some of the progeny produce small amounts of GAs, predominantly GA(1), although these strains contain the GA gene cluster of the non-GA-producing F. proliferatum parental strain. Some progeny had recombinant secondary metabolite profiles under the conditions examined indicating that interspecific crosses can yield secondary metabolite production profiles that are atypical of the parent species.     

Heritability of fumonisin B1 production in Gibberella fujikuroi mating population A.

Fumonisins are mycotoxins produced by strains belonging to several different mating populations of Gibberella fujikuroi (anamorphs, Fusarium section Liseola), a major pathogen of maize and sorghum worldwide. We studied the heritability of fumonisin production in mating population A by crossing fumonisin-producing strains collected from maize and sorghum in the United States with fumonisin-nonproducing strains collected from maize in Nepal. Random ascospore and tetrad progeny from three of these crosses were analyzed by gas chromatography-mass spectrometry and high-performance liquid chromatography for their ability to produce fumonisins on autoclaved cracked maize. In all three crosses, the ability to produce fumonisins, predominately fumonisin B1, segregated as a single gene or group of closely linked genes. Intercrosses between appropriate progeny and parents were poorly fertile, so we could not determine if the apparent single genes that were segregating in each of these crosses were allelic with one another. Mating type and spore-killer traits were scored in some crosses, and each segregated, as expected, as a single gene that was unlinked to the ability to produce fumonisins. We conclude that G. fujikuroi mating population A provides a powerful genetic system for the study of this important fungal toxin.     

Heritability of fumonisin B1 production in Gibberella fujikuroi mating population A.

Fumonisins are mycotoxins produced by strains belonging to several different mating populations of Gibberella fujikuroi (anamorphs, Fusarium section Liseola), a major pathogen of maize and sorghum worldwide. We studied the heritability of fumonisin production in mating population A by crossing fumonisin-producing strains collected from maize and sorghum in the United States with fumonisin-nonproducing strains collected from maize in Nepal. Random ascospore and tetrad progeny from three of these crosses were analyzed by gas chromatography-mass spectrometry and high-performance liquid chromatography for their ability to produce fumonisins on autoclaved cracked maize. In all three crosses, the ability to produce fumonisins, predominately fumonisin B1, segregated as a single gene or group of closely linked genes. Intercrosses between appropriate progeny and parents were poorly fertile, so we could not determine if the apparent single genes that were segregating in each of these crosses were allelic with one another. Mating type and spore-killer traits were scored in some crosses, and each segregated, as expected, as a single gene that was unlinked to the ability to produce fumonisins. We conclude that G. fujikuroi mating population A provides a powerful genetic system for the study of this important fungal toxin.     

Expression and inheritance pattern of two foreign genes in petunia

Transgenic petunia (Petunia hybrida Vilm.) plants were obtained from Agrobacterium-mediated shoot apex transformation. Studies at the phenotypic as well as molecular level established both the presence of the NPT II (neomycin phosphotransferase II) and GUS (-glucuronidase) genes and their level of activity. Twenty-nine primary transformed plants showed varying patterns of phenotype expression of both genes. NPT II and GUS expression in 7 primary plants over a 4-month interval showed varying levels of gene expression within and among individual plants. All primary transgenic plants were self-pollinated and backcrossed to establish the inheritance patterns of both genes. Mendelian and non-Mendelian inheritance patterns for both genes were observed. Analysis of the progeny showed poor transmission of the foreign genes through the pollen especially when two or more bands were present in the Southern hybridization. Most plants whose progeny segregated in Mendelian ratios for either the NPT II or GUS gene had just one copy of the gene. In this study where both foreign genes were examined in both self and test crosses, no transgenic plant showed Mendelian patterns of inheritance for both foreign traits.Department of Plant Pathology and Microbiology     

Physical methods for the transformation of plant cells

Transfer and expression of foreign genes in adult plants and their progeny has been achieved by acceleration of DNA-coated particles or microinjection techniques. Cultured cells or embryoids served as targets for the introduction of marker genes that were stably expressed in the nucleus or the chloroplast. Cloned genes from the maize anthocyanin pathway were regulated in a tissue-specific manner when transferred into maize by particle acceleration. In spite of these successes, stable transformation efficiency was low due to uneven particle distribution and cell death after bombardment. Transferred genes did not always segregate in a Mendelian fashion in the succeeding generation, and additional efforts of embryo rescue or shoot grafts were needed to obtain viable progeny from original transformants. New technical advances such as the helium-driven particle gun may improve transformation rates in the future, but some problems of cell manipulation remain.     

Magnaporthe Grisea Genes for Pathogenicity and Virulence Identified through a Series of Backcrosses

We have identified genes for pathogenicity toward rice (Oryza sativa) and genes for virulence toward specific rice cultivars in the plant pathogenic fungus Magnaporthe grisea. A genetic cross was conducted between the weeping lovegrass (Eragrostis curvula) pathogen 4091-5-8, a highly fertile, hermaphroditic laboratory strain, and the rice pathogen O-135, a poorly fertile, female-sterile field isolate that infects weeping lovegrass as well as rice. A six-generation backcrossing scheme was then undertaken with the rice pathogen as the recurrent parent. One goal of these crosses was to generate rice pathogenic progeny with the high fertility characteristic of strain 4091-5-8, which would permit rigorous genetic analysis of rice pathogens. Therefore, progeny strains to be used as parents for backcross generations were chosen only on the basis of fertility. The ratios of pathogenic to nonpathogenic (and virulent to avirulent) progeny through the backcross generations suggested that the starting parent strains differ in two types of genes that control the ability to infect rice. First, they differ by polygenic factors that determine the extent of lesion development achieved by those progeny that infect rice. These genes do not appear to play a role in infection of weeping lovegrass because both parents and all progeny infect weeping lovegrass. Second, the parents differ by simple Mendelian determinants, ``avirulence genes,' that govern virulence toward specific rice cultivars in all-or-none fashion. Several crosses confirm the segregation of three unlinked avirulence genes, Avr1-CO39, Avr1-M201 and Avr1-YAMO, alleles of which determine avirulence on rice cultivars CO39, M201, and Yashiro-mochi, respectively. Interestingly, avirulence alleles of Avr1-CO39, Avr1-M201 and Avr1-YAMO were inherited from the parent strain 4091-5-8, which is a nonpathogen of rice. Middle repetitive DNA sequences (``MGR sequences'), present in approximately 40-50 copies in the genome of the rice pathogen parent, and in very low copy number in the genome of the nonpathogen of rice, were used as physical markers to monitor restoration of the rice pathogen genetic background during introgression of fertility. The introgression of highest levels of fertility into the most successful rice pathogen progeny was incomplete by the sixth generation, perhaps a consequence of genetic linkage between genes for fertility and genes for rice pathogenicity. One chromosomal DNA segment with MGR sequence homology appeared to be linked to the gene Avr1-CO39. Finally, many of the crosses described in this paper exhibited a characteristic common to many crosses involving M. grisea rice pathogen field isolates. That is, pigment-defective mutants frequently appeared among the progeny.     

Transduction of Myxococcus virescens by coliphage P1CM: generation of plasmids containing both phage and Myxococcus genes.

Chloramphenicol-resistant Myxococcus virescens were obtained by infecting myxococci with Escherichia coli specialized transducing phage P1CM. The drug-resistant myxococci were phenotypically unstable. They contained more than one type of plasmid; these plasmids were not found in the parent strain. Chloramphenicol-resistant E. coli were obtained by transformation with either a fraction of myxococcal DNA containing the plasmids or with P1CM prophage DNA. These transformants contained plasmids. Escherichia coli transformed by DNA from the myxococci contained both P1CM and myxococcal genes. Individual transformant clones differed in the genetic make-up of their plasmids. Among the myxococcal genes expressed in these plasmid-harbouring E. coli strains were a capacity for self-transmissibility and a pattern of phage sensitivity characteristic of R factor incompatibility group W. Escherichia coli transformed with P1CM prophage contained incomplete P1CM genomes; none of the chloramphenicol-resistant transformants produced P1CM phage particles. The significance of these findings for an understanding of mechanisms for the generation of R factors is discussed.     

Simultaneous amplification of multiple DNA fragments by polymerase chain reaction in the analysis of transgenic plants and their progeny

We describe the simultaneous amplification of different segments of foreign DNA in transgenic plants using the polymerase chain reaction (PCR). We used PCR to simultaneously amplify different regions of transformed T-DNA in order to assay the integrity of transformed constructions in primary tomato transformants. We also used simultaneous PCR amplification to examine the segregation of transformed sequences in progeny of primary transformants. A tomato transformant containing the maize transposable elementAc was crossed to transformants containing the non-autonomousDs1 element flanked by maizeAdh1 sequences. We then ran PCR reactions on DNA from F1 progeny using two sets of primers, one set homologous toAc and one set homologous toAdh1 sequences on either side ofDs1. Because theAc andAdh1 primers resulted in amplification of fragments of different sizes, it was possible to monitor the inheritance ofAc and theDs1 containingAdh1 genein a single reaction. Additionally, it was possible to identify F1 plants in whichDs1 had excised by the amplification of a fragment the size predicted for an empty donor site. In order to run these reactions, we have constructed a simple and inexpensive thermal cycler which, when used in conjunction with the rapid miniscreen plant DNA isolation procedure described, allows the processing of a large number of samples in a single day. Therefore, we have shown that PCR can be a useful tool to monitor the integrity of foreign genes in transgenic plants, to follow the segregation of foreign DNA in progeny, and to assay for the excision of transposable elements.     

Evidence for the location of foreign genes in three different chromosomes in a plant obtained from direct DNA transfer

Tobacco mesophyll protoplasts were treated with plasmids, pCT2 (17.1 kbp) or pCT2T3 (18.3 kbp), which contained a chimeric aminoglycoside phosphotransferase II (APH(3′)II) gene and an intact nopaline synthase gene. Expression of two marker enzymes, APH(3′)II and nopaline synthase, were analyzed in transformed plants. Four out of 16 transformants obtained by pCT2T3 possessed both enzymes. Upon self-pollination, the progeny of one of transformants (T2) segregated to 153∶4 in terms of resistant and susceptible character to kanamycin, suggesting insertion of foreign genes into three independent chromosomes. The kanamycin resistant character in the rest of transformants showed 3∶1 segregation. DNA blot analysis of the T2 transformant and progenies indicated the presence of two marker genes.     

A comparison of the phenotypic and genetic stability of recombinant Trichoderma spp. generated by protoplast- and Agrobacterium-mediated transformation

Four different Trichoderma strains, T. harzianum CECT 2413, T. asperellum T53, T. atroviride T11 and T. longibrachiatum T52, which represent three of the four sections contained in this genus, were transformed by two different techniques: a protocol based on the isolation of protoplasts and a protocol based on Agrobacterium-mediated transformation. Both methods were set up using hygromycin B or phleomycin resistance as the selection markers. Using these techniques, we obtained phenotypically stable transformants of these four different strains. The highest transformation efficiencies were obtained with the T. longibrachiatum T52 strain: 65-70 transformants/microg DNA when transformed with the plasmid pAN7-1 (hygromycin B resistance) and 280 transformants/107 spores when the Agrobacterium-mediated transformation was performed with the plasmid pUR5750 (hygromycin B resistance). Overall, the genetic analysis of the transformants showed that some of the strains integrated and maintained the transforming DNA in their genome throughout the entire transformation and selection process. In other cases, the integrated DNA was lost.     

The Mu Transposable Elements of Maize: Evidence for Transposition and Copy Number Regulation during Development

The Mu transposon of maize exists in a highly mutagenic strain called Robertson's Mutator. Plants of this strain contain 10-50 copies of the Mu element, whereas most maize strains and other plants have none. When Mutator plants are crossed to plants of the inbred line 1S2P, which does not have copies of Mu, the progeny plants have approximately the same number of Mu sequences as did their Mutator parent. Approximately one-half of these copies have segregated from their parent and one-half have arisen by transposition and are integrated into new positions in the genome. This maintenance of copy number can be accounted for by an extremely high rate of transposition of the Mu elements (10-15 transpositions per gamete per generation). When Mutator plants are self-pollinated, the progeny double their Mu copy number in the first generation, but maintain a constant number of Mu sequences with subsequent self-pollinations. Transposition of Mu and the events that lead to copy number maintenance occur very late in the development of the germ cells but before fertilization. A larger version of the Mu element transposes but is not necessary for transposition of the Mu sequences. The progeny of crosses with a Mutator plant occasionally lack Mutator activity; these strains retain copies of the Mu element, but these elements no longer transpose.     

In planta transformation of Arabidopsis thaliana

Transformants of Arabidopsis thaliana can be generated without using tissue culture techniques by cutting primary and secondary inflorescence shoots at their bases and inoculating the wound sites with Agrobacterium tumefaciens suspensions. After three successive inoculations, treated plants are grown to maturity, harvested and the progeny screened for transformants on a selective medium. We have investigated the reproducibility and the overall efficiency of this simple in planta transformation procedure. In addition, we determined the T-DNA copy number and inheritance in the transformants and examined whether transformed progeny recovered from the same Agrobacterium-treated plant represent one or several independent transformation events. Our results indicate that in planta transformation is very reproducible and yields stably transformed seeds in 7–8 weeks. Since it does not employ tissue culture, the in planta procedure may be particularly valuable for transformation of A. thaliana ecotypes and mutants recalcitrant to in vitro regeneration. The transformation frequency was variable and was not affected by lower growth temperature, shorter photoperiod or transformation vector. The majority of treated plants gave rise to only one transformant, but up to nine siblings were obtained from a single parental plant. Molecular analysis suggested that some of the siblings originated from a single transformed cell, while others were descended from multiple, independently transformed germ-line cells. More than 90% of the transformed progeny exhibited Mendelian segregation patterns of NPTII and GUS reporter genes. Of those, 60% contained one functional insert, 16% had two T-DNA inserts and 15% segregated for T-DNA inserts at more than two unlinked loci. The remaining transformants displayed non-Mendelian segregation ratios with a very high proportion of sensitive plants among the progeny. The small numbers of transformants recovered from individual T₁ plants and the fact that none of the T₂ progeny were homozygous for a specific T-DNA insert suggest that transformation occurs late in floral development.     

Agrobacterium-mediated transformation of large-flowered purslane (Portulaca grandiflora H.).

Transformation of Portulaca grandiflora has been developed with Agrobacterium tumefaciens strains A281 and T1272. Transformation was assessed by the following criteria: selection of hormone independent callus, antibiotic-resistant callus, and transgenic antibiotic-resistant plants. In addition, DNA hybridization analysis demonstrated that the DNA from tumor lines contained sequences homologous to binary vector T-DNA of strain A281. Following transformation with strain T1272, segregation analysis of the progeny of transgenic plants showed that the transgene was inherited in a Mendelian manner. The kanamycin-resistant progeny tested contained the T-DNA sequence of the strain T1272.     

Genetic Analyses of Interspecific Hybrids between Phytophthora infestans and Phytophthora mirabilis

Goodwin, S. B., and Fry, W. E. 1994. Genetic analyses of interspecific hybrids between Phytophthora infestans and Phytophthora mirabilis. Experimental Mycology 18, 20-32. Four crosses were made between isolates of two host-specific Phytophthora species. Phytophthora infestans and Phytophthora mirabilis. In the two most successful crosses involving a common P. infestans A2 parent, allozyme analysis confirmed that 79 of 86 progeny were interspecific hybrids, 3 were presumed selfs, and 4 were either selfs or nonrecombinant parental types. Mating type, alleles at the allozyme locus glucose-6-phosphate isomerase, and the + alleles at a number of DNA fingerprinting loci segregated independently according to Mendelian expectation. Three DNA fingerprinting loci were tightly linked in P. mirabilis, but no other linkages were detected among these markers. Mitochondrial DNA was uniparentally inherited, mostly from the P. infestans parent. Growth rate segregated as a quantitative character. None of the 68 progeny tested infected Mirabilis jalapa (the host of P. mirabilis), 3 infected potato, and 4 were weakly pathogenic to tomato. Because most of the F₁ hybrids could not infect any of the hosts infected by the parents, host specialization could provide a postzygotic as well as a prezygotic reproductive isolating mechanism for P. infestans and P. mirabilis in central Mexico. These results indicate that P. mirabilis probably is capable of a regular outcrossing mating system.     

Genetics of metalaxyl resistance in Phytophthora infestans.

Several sexual crosses involving isolates of Phytophthora infestans of diverse sensitivities to metalaxyl were studied. Metalaxyl sensitivity was determined by comparing the growth of an isolate on metalaxyl-amended agar medium (5 microg/ml) with growth on medium containing no metalaxyl. When both parents had the same phenotype for metalaxyl sensitivity (both resistant or both sensitive), all F1 progeny had the parental phenotype. In two crosses (75 and 76) each involving one sensitive and one resistant parent, however, the progeny segregated 1:1, suggesting that the common resistant parent (Bg8) was heterozygous for metalaxyl sensitivity. When an F2 progeny was constructed from resistant F1 isolates in cross 76, the progeny segregated 1:3 (sensitive:resistant), indicating that metalaxyl resistance in Bg8 is conferred by a single dominant gene. Variation in the progeny sensitivity appears to involve minor genes. A correlation study between metalaxyl resistance and fitness components did not reveal any association.