Transformation of the filamentous fungus Gibberella fujikuroi using the Aspergillus niger niaD gene encoding nitrate reductase

Recent advances in metabolic regulation and bioengineering of gibberellic acid biosynthesis in Fusarium fujikuroi

The plant growth hormone gibberellic acid (GA₃), as one of the representative secondary metabolites, is widely used in agriculture, horticulture and brewing industry. GA₃ is detected in both plants and several fungi with the ability to stimulate plant growth. Currently, the main mode of industrial production of GA₃ is depended on the microbial fermentation via long-period submerged fermentation using Fusarium fujikuroi as the only producing strain, qualified for its natural productivity. However, the demand of large-sale industrialization of GA₃ was still restricted by the low productivity. The biosynthetic route of GA₃ in F. fujikuroi is now well-defined. Furthermore, the multi-level regulation mechanisms involved in the whole network of GA₃ production have also been gradually unveiled by the past two decades based on the identification and characterization of several global regulators and their mutual functions. Combined with the quick development of genetic manipulation techniques, the rational modification of producing strain F. fujikuroi development become practical for higher productivity achievement. Herein, we review the latest advances in the molecular regulation of GA₃ biosynthesis in F. fujikuroi and conclude a comprehensive network involving nitrogen depression, global regulator, histone modification and G protein signaling pathway. Correspondingly, the bioengineering strategies covering conventional random mutation, genetic manipulating platform development, metabolic edition and fermentation optimization were also systematically proposed.

The Gibberellin Producer Fusarium fujikuroi: Methods and Technologies in the Current Toolkit

In recent years, there has been a noticeable increase in research interests on the Fusarium species, which includes prevalent plant pathogens and human pathogens, common microbial food contaminants and industrial microbes. Taken the advantage of gibberellin synthesis, Fusarium fujikuroi succeed in being a prevalent plant pathogen. At the meanwhile, F. fujikuroi was utilized for industrial production of gibberellins, a group of extensively applied phytohormone. F. fujikuroi has been known for its outstanding performance in gibberellin production for almost 100 years. Research activities relate to this species has lasted for a very long period. The slow development in biological investigation of F. fujikuroi is largely due to the lack of efficient research technologies and molecular tools. During the past decade, technologies to analyze the molecular basis of host-pathogen interactions and metabolic regulations have been developed rapidly, especially on the aspects of genetic manipulation. At the meanwhile, the industrial fermentation technologies kept sustained development. In this article, we reviewed the currently available research tools/methods for F. fujikuroi research, focusing on the topics about genetic engineering and gibberellin production.

Characterization, regulation, and phylogenetic analyses of thePenicillium griseoroseumnitrate reductase gene and its use as selection marker for homologous transformation

Penicillium griseoroseum has been studied because of its efficient pectinases production. In this work, the Penicillium griseoroseum nitrate reductase gene was characterized, transcriptionaly analyzed in different nitrogen sources, and used to create a phylogenetic tree and to develop a homologous transformation system. The regulatory region contained consensus signals involved in nitrogen metabolism and the structural region was possibly interrupted by 6 introns coding for a deduced protein with 864 amino acids. RT–PCR analysis revealed high amounts of niaD transcript in the presence of nitrate. Transcription was repressed by ammonium, urea, and glutamine showing an efficient turnover of the niaD mRNA. Phylogenetics analysis showed distinct groups clearly separated in accordance with the classical taxonomy. A mutant with a 122-bp deletion was used in homologous transformation experiments and showed a transformation frequency of 14 transformants/µg DNA. All analyzed transformants showed that both single- and double-crossover recombination occurred at the niaD locus. The establishment of this homologous transformation system is an essential step for the improvement of pectinase production in Penicillium griseoroseum.Key words: nitrate reductase, nitrogen metabolism, Penicillium griseoroseum, phylogenetic analysis, homologous transformation.

Menacing mold: the molecular biology of Aspergillus fumigatus

Infections with mold pathogens have emerged as an increasing risk faced by patients under sustained immunosuppression. Species of the Aspergillus family account for most of these infections, and in particular Aspergillus fumigatus may be regarded as the most important airborne pathogenic fungus. The improvement in transplant medicine and the therapy of hematological malignancies is often complicated by the threat of invasive aspergillosis. Specific diagnostic methods are still limited as are the possibilities of therapeutic intervention, leading to the disappointing fact that invasive aspergillosis is still associated with a high mortality rate that ranges from 30% to 90%. In recent years considerable progress has been made in understanding the genetics of A. fumigatus, and molecular techniques for the manipulation of the fungus have been developed. Molecular genetics offers not only approaches for the detailed characterization of gene products that appear to be key components of the infection process but also selection strategies that combine classical genetics and molecular biology to identify virulence determinants of A. fumigatus. Moreover, these methods have a major impact on the development of novel strategies leading to the identification of antimycotic drugs. This review summarizes the current knowledge on the biology, molecular genetics, and genomics of A. fumigatus.

Transformation of Penicillium griseoroseum nitrate reductase mutant with the nia gene from Fusarium oxysporum

A heterologous transformation system for Penicillium griseoroseum has been developed. This system is based on nia, the structural gene from Fusarium oxysporum encoding nitrate reductase. Penicillium griseoroseum niaD mutants have been selected from chlorate-resistant colonies. Among 24 chlorate-resistant colonies analyzed, 2 were confirmed to be niaD mutants. Transformation frequencies of 8 transformants/microgram of DNA were obtained. DNA hybridization analyses of five transformants showed distinct integration patterns of the plasmid and in all of them the integration occurred at tandem arrays. The transformation system established in this work will be useful for genetic studies of the pectinolytic complex genes from P. griseoroseum.

The Gibberella fujikuroi niaD gene encoding nitrate reductase: isolation, sequence, homologous transformation and electrophoretic karyotype location

The Gibberella fujikuroi niaD gene, encoding nitrate reductase, has been isolated and used to develop an efficient homologous transformation system. A cosmid vector designated pGFniaD was generated based on niaD selection and shown to give comparable transformation efficiencies. Using pGFniaD, a genomic library was prepared and used for genetic transformations, giving frequencies of up to 200 transformants per microgram DNA. Of 15 transformants analysed by Southern blots, six showed homologous integration whilst the remaining nine integrated at heterologous sites, indicating that the vector may be used reliably for both types of integration. The system therefore may be used both for self-cloning of gibberellin biosynthetic genes on the basis of complementation of defective mutants, and also for gene disruption experiments. Electrophoretic karyotype determination suggested at least 11 chromosomes ranging from 2 to 6 Mb, the total genome size being at least 37 Mb. The niaD gene was assigned to chromosome V by Southern blot analysis. The niaD gene is interrupted by one intron, and remarkably the promoter sequence, but not the 3' untranslated sequence, is highly homologous to that of the corresponding Fusarium oxysporum gene. This situation appears to be unique with respect to the promoter regions of corresponding genes in related species of filamentous fungi.

A homologous and self-replicating system for efficient transformation of Fusarium oxysporum

A highly efficient transformation system has been developed for Fusarium oxysporum f. sp. lycopersici based on the complementation of a nitrate-reductase mutant with the homologous nit1 gene and on the presence of ARS and telomeric sequences in the vector. Preliminary transformation experiments with the niaD gene from Aspergillus 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 the F. oxysporum nit1 gene, resulting in plasmid pFNit-Lam. This allowed the isolation of a new linear plasmid within self-replicative F. oxysporum transformants (pFNit-Lam-TLam, linear). The circular form of this vector yielded 5600 fungal transformants per microgram 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 from F. oxysporum responsible for autonomous replication, and maintenance as linear plasmid molecules, has been determined. Comparison analysis with the ARS from different organisms has shown that this fragment contained the commonly identified ARS consensus sequence, 5'A/TTTTATA/GTTTA/T3' and, in addition to this core, ten copies of the ARS-box, 5'TNTA/GAA3'. Adjacent to this presumed ARS, the telomeric hexanucleotide sequence (TTAGGG)n was present in six tandem copies followed by 18 copies of its complementary sequence.

Secondary metabolite production in filamentous fungi displayed

We report the potential of differential display technology for the isolation of genes of biotechnological interest. We have assessed the usefulness of the technique for the cloning of genes involved in the production of secondary metabolites, many of which are of industrial use or interest. We have used the complex pathway for the biosynthesis of gibberellins, as well as bikaverin and carotenoids, present in the filamentous fungus Gibberella fujikuroi as a test system. From a total display of approximately 16000 PCR products for each RNA sample, 100 were derived from the derepressed but not the repressed condition. These products were analysed by Northern blotting and a subset of 16 such PCR products showed differential expression at the transcript level. A number of different mRNA species were observed on this basis which varied in their size. Hence, this approach appears suitable for the isolation of genes involved in the complex pathways often required for the synthesis of secondary metabolites in organisms which are genetically intractable. Moreover, the method has the advantage that it is quick, differential displays being obtained after 2 days and DNA clones in 6 days.

Nitrate reductase of the ascomycetous fungus, Leptosphaeria maculans: gene sequence and chromosomal location

The nitrate reductase (niaD) gene was isolated from the phytopathogenic loculoascomycete Leptosphaeria maculans by screening a genomic DNA library with the Aspergillus nidulans niaD gene. The L. maculans niaD gene is the first protein-encoding gene characterised from this fungus. It encodes a predicted protein of 893 amino acids and contains four putative introns at positions in the gene equivalent to those of four of the six introns in the A. nidulans niaD gene. Mutants defective in niaD and molybdenum cofactor gene(s) of L. maculans have been isolated. Transformation of a L. maculans niaD mutant with a 3.8 kb SacII fragment containing the L. maculans niaD gene restored wild-type growth on nitrate as a sole nitrogen source. The niaD gene is present as a single copy on a chromosome which ranges in size from 2.6 to 2.8 Mb between the different L. maculans isolates examined.

Genetics and gibberellin production in Gibberella fujikuroi

Gibberella fujikuroi (Fusarium moniliforme) is a complex group of plant pathogens. Some strains produce gibberellic acid and other gibberellins that promote growth and regulate various stages in plant development. The paper describes the research effort directed to development of genetic tools for this species. Furthermore the main features of the gibberellin biosynthetic pathway as established in Gibberella are described.

The genetics of chemical diversity

The plethora of natural organic chemicals contrasts with the relative scarcity of genes and the apparent difficulty to evolve new ones. The genetical analysis of metabolism may be reviewed with this paradox in mind. The terpenoids constitute a particularly varied group of natural compounds; many of them are dispensable to the cell and their biosynthesis is amenable to mutational analysis and other genetical and chemical methods. The production of carotene and gibberellins by the fungi Phycomyces blakesleeanus and Gibberella fujikuroi, respectively, seems to require an unexpectedly small number of genes. A number of gene-saving devices are detected that may have general validity for other cases of secondary metabolism. The most important one is versatile genes whose products are specific for a chemical reaction but not for the substrate. This versatility allows a combinatorial use that increases chemical and behavioral diversity. Physical separation of cellular functions in compartments or enzyme aggregates not only makes processes more efficient but helps avoid some deleterious consequences of enzyme versatility.

The regulatory gene nit-2 of Neurospora crassa complements a nnu mutant of Gibberella zeae (Fusarium graminearum)

The nnu mutant of Gibberella zeae (=Fusarium graminearum) is unable to catabolize many of the nitrogen sources utilized by its wild-type parent, and may have suffered a mutation in the major nitrogen regulatory locus. Transformation of this mutant with the major nitrogen regulatory gene from Neurospora crassa, nit-2, restored the wild-type phenotype, thus confirming that the nnu mutation is in the major nitrogen regulatory locus of G. zeae. Our results are consistent with the premise of conservation of the structure of regulatory factors and suggest the possibility that functional DNA homologues of this regulatory element occur across a broad range of ascomycetous fungi.

Transformation of Gibberella fujikuroi: effect of the Aspergillus nidulans AMA1 sequence on frequency and integration

A stable and reproducible transformation selection system for Gibberella fujikuroi protoplasts based on the Aspergillus nidulans arg B gene, encoding ornithine transcarbamylase, has been developed. Inclusion into the vector of the A. nidulans DNA fragment (AMA1), which permits plasmid autonomous replication in A. nidulans, A. niger and A. oryzae, appeared to permit autonomous replication of G. fujikuroi although the transformation frequency was increased by only two-fold. Transformation was also achieved using the bacterial hygromycin B resistance gene under the control of G. pulicaris and A. nidulans promoters.

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.