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)     

Targeted disruption of the NIT8 gene in Chlamydomonas reinhardtii.

We have used homologous recombination to disrupt the nuclear gene NIT8 in Chlamydomonas reinhardtii. This is the first report of targeted gene disruption of an endogenous locus in C. reinhardtii and only the second for a photosynthetic eukaryote. NIT8 encodes a protein necessary for nitrate and nitrite assimilation by C. reinhardtii. A disruption vector was constructed by placing the CRY1-1 selectable marker gene, which confers emetine resistance, within the NIT8 coding region. nit8 mutants are unable to grow on nitrate as their sole nitrogen source (Nit-) and are resistant to killing by chlorate. One of 2,000 transformants obtained after selection on emetine-chlorate medium contained a homologous insertion of five copies of the disruption plasmid into the NIT8 gene, producing an emetine-resistant, chlorate-resistant Nit- phenotype. The mutant phenotype was rescued by the wild-type NIT8 gene upon transformation. Seven other mutations at the nit8 locus, presumably resulting from homologous recombination with the disruption plasmid, were identified but were shown to be accompanied by deletions of the surrounding genomic region.     

Ornithine decarboxylase of Stagonospora (Septoria) nodorum is required for virulence toward wheat

A knockout strain of Stagonospora (Septoria) nodorum lacking the single ornithine decarboxylase (ODC) allele has been created by targeted gene replacement. A central region of the S. nodorum ODC gene was isolated by polymerase chain reaction using degenerate oligonucleotides and used to probe a lambda genomic library. The gene was sequenced and the encoded ODC protein sequence was shown to be similar to those from other fungi. The functionality of the S. nodorum ODC was confirmed by complementation of an Aspergillus nidulans mutant (puA) strain devoid of ODC activity, restoring growth in the absence of exogenous polyamines. Sporulation of the transformants was reduced suggesting abberant regulation of the S. nodorum gene in A. nidulans. Transformation-mediated gene replacement was used to create strains which were auxotrophic for putrescine and lack ODC coding sequences. Pathogenicity studies on these mutants showed that they are greatly reduced in virulence compared with non-disrupted transformants. This confirms that the strains carrying an ODC disruption cannot obtain sufficient polyamines from the host plant for normal growth and, thus, that fungal ODC may be a suitable target for chemical intervention.     

Molecular cloning, characterization, and nucleotide sequence of nit-6, the structural gene for nitrite reductase in Neurospora crassa.

The Neurospora crassa assimilatory nitrite reductase structural gene, nit-6, has been isolated. A cDNA library was constructed from poly(A)+ RNA isolated from Neurospora mycelia in which nitrate assimilation had been induced. This cDNA was ligated into lambda ZAP II (Stratagene) and amplified. This library was then screened with a polyclonal antibody specific for nitrite reductase. A total of six positive clones were identified. Three of the six clones were found to be identical via restriction digests, restriction fragment length polymorphism mapping, Southern hybridization, and some preliminary sequencing. One of these cDNA clones (pNiR-3) was used as a probe in Northern assays and was found to hybridize to a 3.5-kb poly(A)+ RNA whose expression is nitrate inducible and glutamine repressible in wild-type mycelia. pNiR-3 was used to probe an N. crassa genomic DNA library in phage lambda J1, and many positive clones were isolated. When five of these clones were tested for their ability to transform nit-6 mutants, one clone consistently generated many wild-type transformants. The nit-6 gene has been subcloned to generate pnit-6. The nit-6 gene has been sequenced and mapped; its deduced amino acid sequence exhibits considerable levels of homology to the sequences of Aspergillus sp. and Escherichia coli nitrite reductases. Several pnit-6 transformants have been propagated as homokaryons. These strains have been assayed for the presence of multiple copies of the nit-6 gene, as well as nitrite reductase activity.     

尖孢镰孢一新硝酸盐营养突变类型与营养体亲和性

从73个尖孢镰孢(Fusarium oxysporum)不同专化型菌株上获得684个硝酸盐营养突变株(nit mutant)。作相关氮源利用试验及亚硝酸反应后,鉴定出一新硝酸盐营养突变类型:亚硝酸盐还原酶结构基因类型,命名为nit8,占总突变株的6.7%。同时被鉴别的还有nit1、nit3和Nit M三种突变类型,它们分别占突变株总数的81.0%,3.8%和8.5%。此外,首次引入一种亚硝酸反应在这类研究中的应用,还提出了互补指数概念与公式来表示nit突变株营养体之间亲和的能力。     

A set of Hansenula polymorpha integrative vectors to construct lacZ fusions

A set of YEp Saccharomyces cerevisiae-based, integrative Hansenula polymorpha plasmids was constructed to express lacZ gene under yeast gene promoters. The HpLEU2 and HpURA3 genes were used both as markers and to target the integration of plasmids into the corresponding H. polymorpha genome locus. The frequency of transformation reached with these plasmids linearised either in HpLEU2 or HpURA3 was around 100 transformants per microgram of plasmid DNA; in all transformants checked by Southern blotting the plasmid was integrated into the genome locus corresponding to the gene plasmid marker. PCR showed that about 50% of the transformants contained more than one plasmid copy per genome. Experiments carried out using the developed plasmids to determine the strength of the gene promoters involved in nitrate assimilation in H. polymorpha revealed that, in the presence of nitrate, the nitrate reductase gene promoter (YNR1) was the strongest, followed by nitrite reductase (YNI1) and nitrate transporter (YNT1). Received: 5 February 1999 / Received revision: 31 May 1999 / Accepted: 4 June 1999     

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.     

Identification of the Arabidopsis CHL3 gene as the nitrate reductase structural gene NIA2.

Chlorate, the chlorine analog of nitrate, is a herbicide that has been used to select mutants impaired in the process of nitrate assimilation. In Arabidopsis thaliana, mutations at any one of eight distinct loci confer resistance to chlorate. The molecular identities of the genes at these loci are not known; however, one of these loci--chl3--maps very near the nitrate reductase structural gene NIA2. Through the isolation, characterization, and genetic analysis of new chlorate-resistant mutants generated by gamma irradiation, we have been able to demonstrate that the CHL3 gene and the NIA2 gene are identical. Three new chlorate-resistant mutants were identified that had deletions of the entire NIA2 gene. These nia2 null mutants were viable and still retained 10% of wild-type nitrate reductase activity in the leaves of the plants. All three deletion mutations were found to be new alleles of chl3. Introduction of the NIA2 gene back into these chl3 mutants by Agrobacterium-mediated transformation partially complemented their mutant phenotype. From these data, we conclude that Arabidopsis has at least two functional nitrate reductase genes and that the NIA2 gene product accounts for the majority of the leaf nitrate reductase activity and chlorate sensitivity of Arabidopsis plants.     

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.     

Evidence for multiple nitrate uptake systems in the yeast Hansenula polymorpha

Hansenula polymorpha mutants disrupted in the high-affinity nitrate transporter gene (YNT1) are still able to grow in nitrate. To detect the nitrate transporter(s) responsible for this growth a strain containing disruption of the nitrate assimilation gene cluster and expressing nitrate reductase gene (YNR1) under the control of H. polymorpha MOX1 (methanol oxidase) promoter was used (FM31 strain). In this strain nitrate taken up is transformed into nitrite by nitrate reductase and excreted to the medium where it is easily detected. Nitrate uptake which is neither induced by nitrate nor repressed by reduced nitrogen sources was detected in the FM31 strain. Likewise, nitrate uptake detected in the strain FM31 is independent of both Ynt1p and Yna1p and is not affected by ammonium, glutamine or chlorate. The inhibition of nitrite extrusion by extracellular nitrite suggests that the nitrate uptake system shown in the FM31 strain could also be involved in nitrite uptake.     

Transformation of the entomopathogenic fungus, Metarhizium flavoviride strain CG423 to benomyl resistance

Metarhizium flavoviride strain CG423 is being developed as a mycoinsecticide against grasshoppers. This strain has been transformed to resistance to the fungicide benomyl by a polyethylene glycol (PEG)-mediated procedure using a mutant tubulin gene from Neurospora crassa . Transformation frequencies of up to 84 transformants per microgram of transforming DNA were achieved. Benomyl-resistant transformants were obtained that could tolerate greater than 30 μg ml⁻¹ benomyl. Southern blot analysis of genomic DNA reveals that the mechanism of genetic transformation of all transformants was by homologous gene replacement of the β-tubulin allele.     

Mutants of Azotobacter vinelandii altered in the regulation of nitrate assimilation

The two enzymes involved in the assimilatory pathway of nitrate in Azotobacter vinelandii are corregulated. Nitrate reductase and nitrite reductase are inducible by nitrate and nitrite. Ammonium represses induction by nitrate of both reductases. Repression by ammonium is higher in media containing 2-oxo-glutarate as carbon source than in media containing sucrose. Mutants in the gene ntrC lost nitrate and nitrite reductase simultaneously. Ten chlorate-resistant mutants with a new phenotype were isolated. In media without ammonium they had a normal phenotype, being sensitive to the toxic effect of chlorate. In media containing low ammonium concentrations they were resistant to chlorate. These mutants seem to be affected in the repression of nitrate and nitrite reductases by ammonium.     

Directed mutagenesis in an asporogenous methylotrophic yeast: cloning, sequencing, and one-step gene disruption of the 3-isopropylmalate dehydrogenase gene (LEU2) of Candida boidinii to derive doubly auxotrophic marker strains.

A model system for one-step gene disruption for an asporogenous methylotrophic yeast, Candida boidinii, is described. In this system, the 3-isopropylmalate dehydrogenase gene (C. boidinii LEU2) was selected as the target gene for disruption to derive new host strains for transformation. First, the C. boidinii LEU2 gene was cloned, and its complete nucleotide sequence was determined. Next, the LEU2 disruption vectors, which had the C. boidinii URA3 gene as the selectable marker, were constructed. Of the Ura+ transformants obtained with these plasmids, more than half showed a Leu- phenotype. Finally, the double-marker strains of C. boidinii were derived. When vectors with repeated flanking sequences of the C. boidinii URA3 gene were used for gene disruption, Leu- Ura+ transformants changed spontaneously to a Leu- Ura- phenotype ca. 100 times more frequently than they did when plasmids without the repeated sequences were used. Southern analysis showed that these events included a one-step gene disruption and a subsequent popping out of the C. boidinii URA3 sequence from the transformant chromosome.     

The nitrite reductase gene of Pseudomonas aeruginosa: Effect of growth conditions on the expression and construction of a mutant by gene disruption

Abstract The expression of nitrite reductase has been tested in a wild-type strain of Pseudomonas aeruginosa (Pao1) as a function of nitrate concentration under anaerobic and aerobic conditions. Very low levels of basal expression are shown under non-denitrifying conditions (i.e. absence of nitrate, in both aerobic and anaerobic conditions); anaerobiosis is not required for high levels of enzyme production in the presence of nitrate. A Pseudomonas aeruginosa strain, mutated in the nitrite reductase gene, has been obtained by gene replacement. This mutant, the first of this species described up to now, is unable to grow under anaerobic conditions in the presence of nitrate. The anaerobic growth can be restored by complementation with the wild-type gene.     

The Nir1 locus in barley is tightly linked to the nitrite reductase apoprotein gene Nii

pBNiR1, a cDNA clone encoding part of the barley nitrite reductase apoprotein, was isolated from a barley (cv. Maris Mink) leaf cDNA library using the 1.85 kb insert of the maize nitrite reductase cDNA clone pCIB808 as a heterologous probe. The cDNA insert of pBNiR1 is 503 by in length. The nucleotide coding sequence could be aligned with the 3′ end of other higher plant nitrite reductase apoprotein cDNA sequences but diverges in the 3′ untranslated region. The whole-plant barley mutant STA3999, previously isolated from the cultivar Tweed, accumulates nitrite after nitrate treatment in the light, has very much lowered levels of nitrite reductase activity and lacks detectable nitrite reductase cross-reacting material due to a recessive mutation in a single nuclear gene which we have designated Nir1. STA3999 has the characteristics expected of a nitrite reductase apoprotein gene mutant. Here we have used pB-NiR1 in RFLP analysis to determine whether the mutation carried by STA3999 is linked to the nitrite reductase apoprotein gene locus Nii. An RFLP was identified between the wild-type barley cultivars Tweed (major hybridising band of 11.5 kb) and Golden Promise (major hybridising band of 7.5 kb) when DraI-digested DNA was probed with the insert from the partial barley nitrite reductase cDNA clone, pBNiR1. DraI-digested DNA from the mutant STA3999 also exhibited a major hybridising band of 11.5 kb after hybridisation with the insert from pBNiR1. F₁ progeny derived from the cross between the cultivar Golden Promise and the homozygous nir1 mutant STA3999 were heterozygous for these bands as anticipated. Co-segregation of the Tweed RFLP band of 11.5 kb and the mutant phenotype (leaf nitrite accumulation after nitrate treatment/loss of detectable nitrite reductase cross-reacting material at M_r 63000) was scored in an F₂ population of 312 plants derived from the cross between the cultivar Golden Promise and the homozygous mutant STA3999. The Tweed RFLP band of 11.5 kb and the mutant phenotype showed strict co-segregation (in approximately one quarter (84) of the 312 F₂ plants examined). Only those F₂ individuals heterozygous for the RFLP pattern gave rise to F₃ progeny which segregated for the mutant phenotype. We conclude that the nir1locus and the nitrite reductase apoprotein gene Nii are very tightly linked.