Cloning of the nitrate-nitrite reductase gene cluster of Penicillium chrysogenum and use of the niaD gene as a homologous selection marker.

A new homologous transformation system for the filamentous fungus Penicillium chrysogenum is described. The system is based on complementation of niaD mutants using the nitrate reductase structural gene (niaD) of P. chrysogenum. Spontaneous niaD mutants were identified after selection for chlorate resistance, in growth tests and subsequent complementation with the niaD gene of Aspergillus oryzae. The P. chrysogenum niaD gene was isolated from a genomic library using the Aspergillus nidulans niaD gene as a probe. After subcloning of the hybridizing fragment, the vector obtained, pPC1-1, was capable of transforming a P. chrysogenum niaD mutant at an average of 40 transformants per micrograms of circular DNA. Southern analysis of genomic DNA from a number of transformants showed that pPC1-1 DNA was integrated predominantly at sites other than the niaD locus. Using hybridization analysis it was shown that the niaD gene of P. chrysogenum is clustered with the nitrite reductase gene (niiA). From analysis of the nucleotide sequences of parts of the niaD and niiA genes of P. chrysogenum and comparison of these sequences with nucleotide sequences of the corresponding A. nidulans genes it was deduced that the P. chrysogenum genes are divergently transcribed.     

Transformation of Aspergillus alliaceus using the Aspergillus niger niaD gene encoding nitrate reductase

Abstract A heterologous transformation system for Aspergillus alliaceus based on the Aspergillus niger nitrate reductase structural gene ( niaD ) has been developed. Two mutants of A. alliaceus (M3 and M17), each carrying an niaD mutation were isolated by screening UV-irradiated cells for the inability to grow on nitrate as sole nitrogen source. Using plasmid pSTA 10, transformation frequencies of 4 and 200 per μg DNA respectively were obtained for these two strains. All the niaD ⁺ transformants tested were mitotically stable. Southern hybridisation analyses showed that the vector DNA sequences were present.     

niaD基因与uidA基因共转化糖化酶高产菌株Aspergillus niger T21

从AspergillusnigerT21分离到自发性的氯酸盐抗性株,再经氮源生长试验获得硝酸盐还原酶缺陷的niaD突变体N44。用含有niaD的质粒pSTA10转化N44,转化频率为5个／μg（转化子／DNA）。转化子的Southern印迹分析表明niaD基因同源整合到N44的染色体DNA中。pSTA10与含葡糖苷酸酶基因（uidA）的质粒pNOM102共转化N44,共转化频率为40％。共转化子的GUS（葡糖苷酸酶）活力测定结果表明uidA基因已在N44中表达。由此可知,以niaD为选择标记,uidA为报告基因,以N44为受体的转化系统可用于丝状真菌启动子功能检测和已知调控序列的功能分析。     

Recombinational inactivation of the gene encoding nitrate reductase in Aspergillus parasiticus.

Functional disruption of the gene encoding nitrate reductase (niaD) in Aspergillus parasiticus was conducted by two strategies, one-step gene replacement and the integrative disruption. Plasmid pPN-1, in which an internal DNA fragment of the niaD gene was replaced by a functional gene encoding orotidine monophosphate decarboxylase (pyrG), was constructed. Plasmid pPN-1 was introduced in linear form into A. parasiticus CS10 (ver-1 wh-1 pyrG) by transformation. Approximately 25% of the uridine prototrophic transformants (pyrG+) were chlorate resistant (Chlr), demonstrating their inability to utilize nitrate as a sole nitrogen source. The genetic block in nitrate utilization was confirmed to occur in the niaD gene by the absence of growth of the A. parasiticus CS10 transformants on medium containing nitrate as the sole nitrogen source and the ability to grow on several alternative nitrogen sources. Southern hybridization analysis of Chlr transformants demonstrated that the resident niaD locus was replaced by the nonfunctional allele in pPN-1. To generate an integrative disruption vector (pSKPYRG), an internal fragment of the niaD gene was subcloned into a plasmid containing the pyrG gene as a selectable marker. Circular pSKPYRG was transformed into A. parasiticus CS10. Chlr pyrG+ transformants were screened for nitrate utilization and by Southern hybridization analysis. Integrative disruption of the genomic niaD gene occurred in less than 2% of the transformants. Three gene replacement disruption transformants and two integrative disruption transformants were tested for mitotic stability after growth under nonselective conditions. All five transformants were found to stably retain the Chlr phenotype after growth on nonselective medium.(ABSTRACT TRUNCATED AT 250 WORDS)     

Chromosomal location plays a role in regulation of aflatoxin gene expression in Aspergillus parasiticus.

The nor-1 gene in the filamentous fungus Aspergillus parasiticus encodes a ketoreductase involved in aflatoxin biosynthesis. To study environmental influences on nor-1 expression, we generated plasmid pAPGUSNNB containing a nor-1 promoter-beta-glucuronidase (GUS) (encoded by uidA) reporter fusion with niaD (encodes nitrate reductase) as a selectable marker. niaD transformants of A. parasiticus strain NR-1 (niaD) carried pAPGUSNNB integrated predominantly at the nor-1 or niaD locus. Expression of the native nor-1 and nor-1::GUS reporter was compared in transformants grown under aflatoxin-inducing conditions by Northern and Western analyses and by qualitative and quantitative GUS activity assays. The timing and level of nor-1 promoter function with pAPGUSNNB integrated at nor-1 was similar to that observed for the native nor-1 gene. In contrast, nor-1 promoter activity in pAPGUSNNB and a second nor-1::GUS reporter construct, pBNG3.0, was not detectable when integration occurred at niaD. Because niaD-dependent regulation could account for the absence of expression at niaD, a third chromosomal location was analyzed using pAPGUSNP, which contained nor-1::GUS plus pyrG (encodes OMP decarboxylase) as a selectable marker. GUS expression was detectable only when pAPGUSNP integrated at nor-1 and was not detectable at pyrG, even under growth conditions that required pyrG expression. nor-1::GUS is regulated similarly to the native nor-1 gene when it is integrated at its homologous site within the aflatoxin gene cluster but is not expressed at native nor-1 levels at two locations outside of the aflatoxin gene cluster. We conclude that the GUS reporter system can be used effectively to measure nor-1 promoter activity and that nor-1 is subject to position-dependent regulation in the A. parasiticus chromosome.     

Transformation of Aspergillus niger with the homologous nitrate reductase gene

A homologous transformation for Aspergillus niger was developed based on the nitrate reductase structural gene niaD. This system offered certain advantages over existing A. niger systems, such as the ease of recipient mutant isolation, absence of abortive transformants, convenient enzyme assay, ease of transformant stability testing, and complete absence of background growth. Transformation frequencies of up to 100 transformants per microgram DNA were obtained with the vector pSTA10 which carries the niaD gene of A. niger. Southern blotting analysis indicated that vector DNA had integrated into the genome of A. niger. Mitotic stability studies demonstrated that while some transformants were as stable as the wild-type (wt), others were markedly less so. No correlation was seen between plasmid integration, mitotic stability and nitrate reductase activity, which was markedly different from wt in only three of the transformants examined.     

Nitrate reactive structural gene mutants of Aspergillus nidulans

Two strains characterized as niaD structural gene mutants in Aspergillus nidulans produce a nitrate reductase which retains the ability to react with nitrate while lacking the ability to oxidize its naturally occurring substrate NADPH. Fifteen such nitrate reactive niaD strains exhibited strong interallelic complementation when tested against strains bearing point mutations in eleven other loci essential to induction and synthesis of nitrate reductase in Aspergillus. Fourteen representatives of this phenotype formed enzyme with a molecular weight equivalent to that of the wild type (200 kD) and also remained inducible by nitrate and repressible by ammonium. The mutation appears to alter the NADPH binding domain of the nitrate reductase since the affinity for the dinucleotide fold in Affigel blue and the dissociation constant (Ks) for enzyme isolated from the mutants on the basis of reduced methyl viologen-nitrate reductase activity is significantly less than that observed for the native enzyme from the wild type.     

Improvement of Aspergillus oryzae for hyperproduction of endoglucanase: expression cloning of cmc-1 gene of Aspergillus aculeatus

FI-Carboxymethylcellulase (cmc1; family 12) is one of the endoglucanases of Aspergillus aculeatus and consists of single polypeptide chain of 221 amino acids. The cmc1 gene was expressed in Aspergillus oryzae niaD300 (niaD⁻) under promoter 8142. The plasmid pCMG14 carrying the cmc1 gene at PstI site was used as a source of the gene (920 bp) and Aspergillus oryzae was successfully transformed by the plasmid pNAN-cmc1 (harboring cmc1 gene). The plasmid was integrated in Aspergillus oryzae niaD300 genome at niaD locus and the transformed fungus constitutively produced very high amounts of endoglucanases when grown on glucose, maltose, soluble starch and wheat bran.     

Cloning of the nitrate reductase gene (niaD) of Aspergillus nidulans and its use for transformation of Fusarium oxysporum

An heterologous transformation system for the phytopathogenic fungus Fusarium oxysporum has been developed based on the use of the Aspergillus nidulans nitrate reductase gene (niaD). F. oxysporum nia- mutants were easily selected by chlorate resistance. The A. nidulans niaD gene was isolated from a gene library by complementation of an A. nidulans niaD mutant. The cloned gene is capable of transforming F. oxysporum nia- mutants at a frequency of up to ten transformants per microgram of DNA. Southern analysis of the DNA of the F. oxysporum transformants showed that transformation resulted in integration of one or more copies of the vector DNA into the genome.     

Transposition of the autonomous Fot1 element in the filamentous fungus Fusarium oxysporum

Autonomous mobility of different copies of the Fot1 element was determined for several strains of the fungal plant pathogen Fusarium oxysporum to develop a transposon tagging system. Two Fot1 copies inserted into the third intron of the nitrate reductase structural gene (niaD) were separately introduced into two genetic backgrounds devoid of endogenous Fot1 elements. Mobility of these copies was observed through a phenotypic assay for excision based on the restoration of nitrate reductase activity. Inactivation of the Fot1 transposase open reading frame (frameshift, deletion, or disruption) prevented excision in strains free of Fot1 elements. Molecular analysis of the Nia+ revertant strains showed that the Fot1 element reintegrated frequently into new genomic sites after excision and that it can transpose from the introduced niaD gene into a different chromosome. Sequence analysis of several Fot1 excision sites revealed the so-called footprint left by this transposable element. Three reinserted Fot1 elements were cloned and the DNA sequences flanking the transposon were determined using inverse polymerase chain reaction. In all cases, the transposon was inserted into a TA dinucleotide and created the characteristic TA target site duplication. The availability of autonomous Fot1 copies will now permit the development of an efficient two-component transposon tagging system comprising a trans-activator element supplying transposase and a cis-responsive marked element.     

Transformation system of Beauveria bassiana and Metarhizium anisopliae using nitrate reductase gene of Aspergillus nidulans

An heterologous transformation system for entomopathogenic fungi B. bassiana and M. anisopliae was developed based on the use of A. nidulans nitrate reductase gene (niaD). B. bassiana and M. anisopliae niaD stable mutants were selected by treatment of protoplast with ethane methane sulphonate (EMS) and regenerated on chlorate medium. The cloned gene was capable of transforming B. bassiana and M. anisopliae at a frequency of 5.8 to 20 transformants per microg of DNA. Most of them were mitotically stable.     

Easy detection of green fluorescent protein multicopy transformants in Penicillium griseoroseum

Penicillium griseoroseum, a deuteromycete fungus producer of pectinolytic enzymes, was transformed with a gene encoding for green fluorescent protein (GFP). The selection of transformants was based on the homologous nitrate reductase gene (niaD). Protoplasts of a P. griseoroseum Nia mutant (PG63) were co-transformed with the plasmids pNPG1 and pAN52-1-GFP. The plasmid pNPG-1 carries the homologous niaD gene and pAN52-1-GFP carries the SGFP-TYG version of GFP. The highest transformation efficiency (102 transformants/mug of pNPG1) resulted from the utilization of equimolar amounts of transforming and co-transforming vectors. Analysis of pAN52-1-GFP insertions into the genomic DNA of the transformants revealed single and multiple copy integrations. The transformants possessing a single copy of the gfp gene showed a low level of fluorescence, whereas multicopy transformants displayed strong fluorescence under visualization with fluorescent light. The transformants showing high expression of the gfp gene had the normal mycelia pigmentation altered, displaying a bright green-yellowish color, visible with the naked eye on the plates, without the aid of any kind of fluorescent light or special filter set.     

A reporter gene analysis of penicillin biosynthesis gene expression in Penicillium chrysogenum and its regulation by nitrogen and glucose catabolite repression.

Vectors which possess a truncated niaD gene encoding nitrate reductase were developed to allow targeted gene integration during transformation of an niaD mutant Penicillium chrysogenum host. The Penicillium genes pcbC and penAB are immediately adjacent to each other and are divergently transcribed, with an intergenic control region serving as their promoters. Gene fusions were constructed with a reporter gene, uidA, which encodes beta-glucuronidase. The pcbC-penAB intergenic region was fused to the uidA gene in both orientations so that regulated expression of each structural gene could be investigated. These fusion genes were targeted to the chromosomal site of the niaD locus of P. chrysogenum, and their expression was examined under different growth conditions. The expression of each of these penicillin biosynthesis genes was found to be regulated by nitrogen repression, glucose repression, and growth stage control.     

Visualization of nuclei in Aspergillus oryzae with EGFP and analysis of the number of nuclei in each conidium by FACS

Aspergillus oryzae has been reported to form conidia with multinuclei. In order to analyze nuclei in living cells, we developed an expression system of the A. nidutans histone H2B protein tagged by EGFP (H2B::EGFP). In both A. oryzae niaD300 and A. nidulans FGSC89 transformants expressing H2B::EGFP, fluorescence was detected in nuclear regions of hyphae and conidia. While a conidium contained only one fluorescent spot in the A. nidulans transformant, approximately 66% of conidia had two, 24% had one, and 10% had three or more in the A. oryzae transformant. The conidia expressing H2B::EGFP were put through FACS (fluorescence-activated cell sorting) analysis and two sharp peaks, corresponding to one and two nuclei in each conidium, were noted in the A. oryzae transformant. In addition, the A. oryzae uninucleate conidia that were successfully isolated by FACS reproduced conidia with almost the same number distribution of nuclei as that of the original. Conidia of five A. oryzae strains used in sake brewing were scored for the number of nuclei, showing that a varied number of nuclei existed in each conidium and some strains had a small number of uninucleate conidia.     

The GUS gene fusion system (Escherichia coli beta-D-glucuronidase gene), a useful tool in studies of root colonization by Fusarium oxysporum.

The plant-pathogenic fungus Fusarium oxysporum was successfully transformed with the beta-D-glucuronidase gene from Escherichia coli (gusA) (GUS system) in combination with the gene for nitrate reductase (niaD) as the selectable marker. The frequency of cotransformation, as determined by GUS expression on plates containing medium supplemented with 5-bromo-4-chloro-3-indolyl glucuronide (GUS+), was very high (up to 75%). Southern hybridization analyses of GUS+ transformants revealed that single or multiple copies of the gusA gene were integrated into the genomes. High levels of GUS activity are expressed in some transformants, but activity in F. oxysporum does not appear to be correlated with the copy number of the gusA gene. Since the highest activity was found in a transformant with a single copy, it can be assumed that sequence elements of F. oxysporum integrated upstream of the gene can act as a promoter or enhancer. Expression of the gusA gene was also detected during growth of the fungus in plants, indicating that the GUS system can be used as a sensitive and easy reporter gene assay in F. oxysporum.