Development of a homologous transformation system for Aspergillus parasiticus with the gene encoding nitrate reductase

Summary The nitrate reductase structural gene (niaD) and an niaD mutant strain were isolated from Aspergillus parasiticus and used to develop a homologous transformation system. A transformation frequency of 110 to 120 transformants per microgram linear DNA was obtained with the 10.9 kb plasmid pSL82, which contained the niaD gene of A. parasiticus. Plasmid pSL82 was also capable of complementing Aspergillus nidulans FGSC A691, a niaD mutant, though at lower frequencies. Southern hybridization analyses of A. parasiticus niaD transformants showed that the niaD gene of pSL82 had integrated into the fungal genome. In addition, vector (bacterial plasmid) sequences were also present in one of the niaD transformants.Authors with primary and equal contribution in the research project     

Transformation of a nitrate reductase deficient mutant of Penicillium chrysogenum with the corresponding Aspergillus niger and A. nidulans niaD genes

Summary A heterologous gene mediated transformation system based on niaD, the structural gene encoding nitrate reductase, has been developed for Penicillium chrysogenum. Transformation frequencies of up to 20 transformants per microgram DNA were obtained using the Aspergillus nidulans gene and 9 transformants per microgram using the A. niger gene. Vector constructs carrying the A. nidulans ans-1 sequence and the A. niger niaD gene did not show increased transformation frequencies. Southern blot hybridisation analysis demonstrated that vector sequences had integrated into the recipient genome. The control of heterologous niaD gene expression generally agreed with that found in the wild-type strain, that is, induction by nitrate and repression in the presence of ammonium.     

Methionine Requirements of Rats in Various Body Weights

A niaD gene encoding nitrate reductase was isolated from Aspergillus oryzae KBN616 and sequenced. The structural gene comprises 2973 bp and 868 amino acids, which showed a high degree of similarity to nitrate reductases from other filamentous fungi. The coding sequence is interrupted by six introns varying in size from 48 to 98 bp. The intron positions are all conserved among the niaD genes from A. oryzae, Aspergillus nidulans, and Aspergillus niger. A homologous transformation system was developed for an industrial shoyu koji mold, A. oryzae KBN616, based on the nitrate reductase (niaD) of the nitrate assimilation pathway.     

米曲霉异源蛋白表达系统研究进展及展望

米曲霉作为一种重要的工业微生物,在异源蛋白表达方面已有广泛应用,受限于被表达蛋白的修饰及分泌过程,目前实际生产使用的基因供体主要局限于其他真菌,尤其是丝状真菌。当外源基因来源于植物、昆虫和哺乳动物时,米曲霉所生产的异源蛋白产量及生物活性往往不尽如人意。本文综述了米曲霉作为宿主表达异源蛋白的研究进展,包括其现有的遗传操作手段及异源表达方面的应用及探索,重点介绍了应用过程中面临的挑战和解决策略,另外,对米曲霉表达异源蛋白的应用前景及发展方向进行了展望。     

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.     

Isolation and characterization of Nicotiana plumbaginifolia nitrate reductase-deficient mutants: genetic and biochemical analysis of the NIA complementation group

Summary Two hundred and eleven nitrate reductase-deficient mutants (NR^–) were isolated from mutagenized Nicotiana plumbaginifolia protoplast cultures by chlorate selection and regenerated into plant. More than 40% of these clones were classified as cnx and presumed to be affected in the biosynthesis of the molybdenum cofactor, the remaining clones being classified as nia mutants. A genetic analysis of the regenerated plants confirmed this proportion of nia and cnx clones. All mutants regenerated were found to carry monogenic recessive mutations that impaired growth on nitrate as sole nitrogen source. Mutants propagated by grafting on N. tabacum systematically displayed a chlorotic leaf phenotype. This chlorosis was therefore related to the NR deficiency. The observation of leaves with NR^– chlorotic sectors surrounded by NR⁺ wild-type tissues suggeests that an NR deficiency is not corrected by diffusible factors. Periclinal chimeras between wild-type tobacco and the NR^– graft were also observed. In this type of chimeric tissue chlorosis was no longer detectable when NR⁺ cells were in the secondmost (L2) layer, but was still detectable when NR^– cells were in the secondmost layer. The genetic analysis of nia mutants revealed that they belong to a single complementation group. However three nia mutants were found to complement some of the other nia mutants. The apoenzyme of nitrate reductase was immunologically detected in several nia mutants but not in other members of this complementation group. Some of the nia mutants, although they were NR^–, still displayed methylviologenitrate reductase activity at a high level. These data show that the nia complementation group corresponds to the structural gene of nitrate reductase. Some of the mutations affecting this structural gene result in the overproduction of an inactive nitrate reductase, suggesting a feedback regulation of the level of the apoenzyme in the wild type.     

Polarity of meiotic gene conversion is 5′ to 3′ within the niaD gene of Aspergillus nidulans

We have examined polarity of meiotic gene conversion in the niiA-niaD gene cluster of Aspergillus nidulans in two-point crosses. The type and position of the mutations represented by the niaD alleles and the correlation between the relative frequency of gene conversion and the physical position of these mutations were determined. We show that polarity of meiotic gene conversion is 5 to 3 (transcribed strand) within the niaD gene. Additional crosses involving a niiA allele and a niaD allele show little polarity of gene conversion, which suggests that the recombination events leading to restoration of the niaD gene are initiated upstream of the coding region of the niaD gene but within the niiA-niaD gene cluster, possibly within the intergenic promoter region.     

Evidence for the nitrate-dependent spatial regulation of the nitrate reductase gene in chicory roots

Young chicory plants (Cichorium intybus L. var. Witloof) show a tenfold higher nitrate reductase NR activity in roots compared to leaves. Northern analysis revealed, besides the nitrate inducibility of the nitrate reductase gene (nia), a higher level of expression in the roots. By modifying the external nitrate concentration the NR activity in the leaves remained negligible whereas a maximal activity was observed in the roots when grown in the presence of 5 mM nitrate. Surprisingly, variation of the external nitrate concentration induced changes in the spatial regulation of nia within the root. In-situ hybridization mainly localized nia mRNA in the cortical cells of roots grown at low nitrate concentrations (0.2 mM). At high nitrate concentrations (5 mM), nia mRNA was more abundant in the vascular tissues. The root apex revealed a strong signal under both conditions. The isolation and characterization of the NR structural gene from chicory is also presented. Southern blot analysis revealed the presence of a single nia gene per haploid genome of chicory.     

The PDR-type ABC transporters AtrA and AtrG are involved in azole drug resistance in Aspergillus oryzae

For strain improvement of Aspergillus oryzae, development of the transformation system is essential, wherein dominant selectable markers, including drug-resistant genes, are available. However, A. oryzae generally has a relatively high resistance to many antifungal drugs effective against yeasts and other filamentous fungi. In the course of the study, while investigating azole drug resistance in A. oryzae, we isolated a spontaneous mutant that exhibited high resistance to azole fungicides and found that pleiotropic drug resistance (PDR)-type ATP-binding cassette (ABC) transporter genes were upregulated in the mutant; their overexpression in the wild-type strain increased azole drug resistance. While deletion of the gene designated atrG resulted in increased azole susceptibility, double deletion of atrG and another gene (atrA) resulted in further azole hypersensitivity. Overall, these results indicate that the ABC transporters AtrA and AtrG are involved in azole drug resistance in A. oryzae.     

The Mechanism of Nitrate Accumulation in Pakchoi [Brassica Campestris L.ssp. Chinensis(L.)]

Decreased nitrate in vegetables can improve crop nitrogen utilization efficiency and lessen the human health risk caused by the reduction of nitrate to nitrite in vegetables. This paper studied the mechanisms of differences in nitrate accumulation and distribution within organs of two cultivars of pakchoi (Brassica campestris L.ssp. Chinensis (L.) previously screened in hydroponic experiments from 12 cultivars popularly grown in China at present. The two typical cultivars used in this experiment were Shanghaiqing with low nitrate accumulation and Liangbaiye 1 with high nitrate accumulation. There was no significant difference of total nitrate uptake but a significant difference in nitrate content existed between the two cultivars. Compared with Liangbaiye 1, Shanghaiqing showed a significantly higher photosynthetic rate and nitrate reductase activity. Determination of nitrate concentration (activity) in vacuoles with double-barrelled nitrate-selective microelectrodes showed that Shanghaiqing had lower vacuolar nitrate activity than Liangbaiye 1. Two putative nitrate reductase genes, nia1 and nia2, were amplified from the leaf blades of these two cultivars. Nia1 mRNA fragments (887 bp, accession numbers DQ082868 and DQ082869) were amplified using degenerate primer and nia2 mRNA fragment was amplified using one pair of generate primers designed according to DQ001901. Sequence analysis of DQ082868 and DQ082869 both showed 97% and 87% similarity with two nitrate reductase mRNA sequences of Brassica napus, accession numbers D38219 and D38220, respectively. The results of real time PCR to compare the relative expression of the putative nitrate reductase genes (nia1 and nia2) showed that Shanghaiqing had significantly higher expression level than Liangbaiye 1 and nia2 was significantly higher than nia1 in leaf blade and petiole. Both the nitrate reductase activity and the relative expression level of nia1 were in the order of leaf blade > root > petiole, while that of nia2 was leaf blade > petiole > root. There was no statistically significant difference of nitrate activity stored in vacuoles between the different organs of the two cultivars. It can be concluded that Shanghaiqing took up slightly less nitrate, but had significantly higher nitrate reductase activity in cytosol and had a higher relative expression of the putative nitrate reductase genes than Liangbaiye 1; this leads to the fact that Shanghaiqing has a lower nitrate content than Liangbaiye 1.     

GENETIC STUDIES OF NITRATE ASSIMILATION IN ASPERGILLUS NIDULANS

(1) In Aspergillus nidulans, at least 16 genes can mutate to affect the reduction of nitrate to ammonium, a process requiring two enzymes, nitrate reductase and nitrite reductase. (2) niaD is the only gene whose effects on enzyme structure are confined to nitrate reductase alone. It specifies a core polypeptide, one or more of which form the basic subunit of nitrate reductase, molecular weight 50000. (3) At least five cnx genes together specify a molybdenum co-factor, necessary for the activity of nitrate reductase, and of xanthine dehydrogenases I and II. The cnxH gene specifies a polypeptide component of this co-factor, and the cnxE and F gene products are involved in co-factor elaboration, The role of the remaining cnx genes is at present unknown. (4) Functional nitrate reductase has a molecular weight of 200000 and is likely to consist of four subunits, together with one or more molecules of the cnx-specified co-factor. (5) The co-factor plays a catalytic role in the aggregation of nitrate-reductase subunits. (6) The niiA gene is the structural gene for nitrite reductase. (7) Other genes affecting nitrate assimilation are either regulatory or bring about their effects indirectly. (8) Of the genes affecting nitrate assimilation, close linkage is found only between the niiA and niaD genes. (9) Nitrate and nitrite reductases are subject to control by nitrate induction and ammonium repression. (10) Nitrate induction is mediated by the nirA gene whose product must be active for the niiA and niaD genes to be expressed. Since most niaD mutants produce nitrite reductase constitutively, it is likely that the nirA gene product is normally inactivated by nitrate reductase, but only when the latter is not complexed with nitrate, (11) Ammonium repression is mediated by the areA gene, whose product must be active for the expression of the niiA and niaD genes, and which is inactive in the presence of ammonium. (12) The tamA gene may function similarly to the areA gene, both gene products being necessary for the expression of the niiA and niaD genes. (13) Although the niiA and niiD genes are probably contiguous, they are not likely to be organized into a structure equivalent to a bacterial operon. (14) Whereas the areA and nirA genes regulate the synthesis of nitrate and nitrite reductases, it is probable that at least nitrate reductase is also subject to post-translational control, the presence of active enzyme being correlated with high levels of NADPH. (15) The regulation of the pentose-phosphate pathway, of mannitol-I-phosphate dehydrogenase and of certain activities required for the catabolism of some nitrogen-containing compounds appears to be connected with that of nitrate assimilation. In all cases, it is probable that the nirA gene and nitrate reductase itself are involved.     

Development of a system for integrative and stable transformation of the zygomycete<Emphasis Type="Italic"> Rhizopus oryzae</Emphasis> by<Emphasis Type="Italic"> Agrobacterium</Emphasis>-mediated DNA transfer

Two transformation systems, based on the use of CaCl₂/PEG and Agrobacterium tumefaciens, respectively, were developed for the zygomycete Rhizopus oryzae. Irrespective of the selection marker used, a pyr4 marker derived from R. niveus or a dominant amdS⁺ marker from Aspergillus nidulans, and irrespective of the configuration of the transforming DNA (linear or circular), the transformants obtained with the CaCl₂/PEG transformation method were found to carry multiple copies of tandemly linked vector molecules, which failed to integrate into the genomic DNA. Furthermore, these transformants displayed low mitotic stability. In contrast, transformants obtained by Agrobacterium-mediated transformation were mitotically stable, even under non-selective conditions. Detailed analysis of these transformants revealed that the transforming DNA had integrated into the genome of R. oryzae at a single locus in independently obtained transformants. In addition, truncation of the transforming DNA was observed, resulting in the integration of the R. niveus pyr4 marker gene, but not the second gene located on the transferred DNA. Modification of the transforming DNA, resulting in partial resistance to restriction enzyme digestion, was observed in transformants obtained with the CaCl₂/PEG transformation method, suggesting that a specific genome defence mechanism may exist in R. oryzae. It is likely that the unique mechanism used by A. tumefaciens to deliver its transferred DNA to its hosts facilitates bypass of the host defence mechanisms, thus allowing the DNA to integrate into the chromosomal genome.An erratum to this article can be found at Communicated by C. P. Hollenberg     

Formation of NADPH-nitrate reductase activity in vitro from Aspergillus nidulans niaD and cnx mutants

Summary Mutants of A. nidulans at several loci lack detectable NADPH-nitrate reductase activity. These loci include niaD, the structural gene for the nitrate reductase polypeptide, and five other loci termed cnxABC, E, F, G and H which are presumed to be involved in the formation of a molybdenum-containing component (MCC) necessary for nitrate reductase activity. When frozen mycelia from A. nidulans deletion mutant niaD26 were homogenized in a Ten Broeck homogenizer together with frozen mycelia from either enzA6, cnxE29, cnxF12, enxG4 or cnxH3 strains grown on urea+nitrate as the nitrogen source, nitrate reductase activity was detectable in the extract. Similar results were obtained by co-homogenizing niaD mycelia with Neurospora crassa nit-1 mycelia induced on nitrate. Thus, all A. nidulans cnx mutants are similar to the N. crassa nit-1 strain in their capacity to yield NADPH-nitrate reductase in the presence of the presumed MCC. As judged by the amounts of nitrate reductase formed, niaD26 mycelia grown on urea±nitrate contained much more available MCC than ammonium-grown mycelia. No NADPH-nitrate reductase activity was found in extracts prepared by co-homogenizing mycelia from all five A. nidulans cnx strains. Wild-type A. nidulans NADPH-nitrate reductase acid dissociated by adjustment to pH 2.0–2.5 and re-adjusted to pH 7 could itself re-assemble to form active nitrate reductase and thus was not a sueful source of MCC for these experiments. These results are consistent with the conclusion that the active nitrate reductase complex is composed of polypeptide components which are the niaD gene product, plus the MCC which is formed through the combined action of the cnx gene products. Further, the production of MCC may be regulated in response to the nitrogen nutrition available to the organism.     

DNA mediated transformation of Aspergillus ficuum

Summary Two DNA-mediated transformation systems were successfully adapted to Aspergillus ficuum. Both the Escherichia coli hygromycin B resistance gene and the A. nidulans amdS gene transformation systems produced stable A. ficuum NRRL 3135 transformants. Cotransformation with the E. coli lacZ gene was also achieved with the hygromycin B system. In cotransformation a second unselected gene, in this case the lacZ gene which codes for -galactosidase, was also integrated and expressed in hygromycin B transformants. Since both of these transformation systems utilized dominant selection markers, they are potentially useful in other genetically uncharacterized filamentous fungi.     

Transformation System for Aspergillus oryzae with Double Auxotrophic Mutations,niaD and sC

We developed a transformation system for Aspergillus oryzae using the Aspergillus nidulans sC gene encoding ATP sulfurylase as a selectable marker. The sC^? mutants can be readily isolated by positive selection for selenate resistance, thereby the niaD^? mutant strain of A. oryzae was bestowed with the sC^? mutation. Transformation of the A. oryzae host (niaD^?,sC^?) with the plasmid carrying A. nidulans sC gave random and multi-copy integrants, while that with the A. oryzae niaD-carrying plasmid occurred mainly by single-copy and homologous integration events (more than 50% frequency), indicating that with this transformation system, the transformation marker could be selected according to the integration pattern one desires.     

Development of a homologous transformation system for Aspergillus niger based on the pyrG gene

Summary The development of a homologous transformation system for Aspergillus niger is described. The system is based on the use of an orotidine-5-phosphate decarboxylase deficient mutant (pyrG) and a vector, pAB4-1, which contains the functional A. niger pyrG gene as a selection marker. Transformation of the A. niger pyrG mutant with pAB4-1 resulted in the appearance of stable Pyr⁺ transformants at a frequency of 40 transformants per g of DNA. In 90% of these transformants integration had occurred at the resident pyrG locus, resulting either in replacement of the mutant allele by the wild-type allele (60%) or in insertion of one or two copies of the vector (40%). The A. niger pyrG mutant could also be transformed with the vector pDJB2 containing the pyr4 gene of Neurospora crassa, at a frequency of 2 transformants per g of DNA. Integration at the resident pyrG locus was not found with this vector. The vector pAB4-1 is also capable of transforming an Aspergillus nidulans pyrG mutant to Pyr⁺. The pyrG transformation system was used for the introduction of a non-selectable gene into A. niger.     

Mannose selection system used for cucumber transformation

The selectable marker system, which utilizes the pmi gene encoding for phosphomannose-isomerase that converts mannose-6-phosphate to fructose-6-phosphate, was adapted for Agrobacterium-mediated transformation of cucumber (Cucumis sativus L.). Only transformed cells were capable of utilizing mannose as a carbon source. The highest transformation frequency of 23% was obtained with 10 g/l mannose and 10 g/l sucrose in the medium. Molecular, genetic analysis, and PMI activity assay showed that the regenerated shoots contained the pmi gene and the gene was transmitted to the progeny in a Mendelian fashion. The results indicated that the mannose selection system, which is devoid of the disadvantages of antibiotic or herbicide selection, could be used for cucumber Agrobacterium-mediated transformation.     

Autophagy delivers misfolded secretory proteins accumulated in endoplasmic reticulum to vacuoles in the filamentous fungus Aspergillus oryzae

Autophagy is a conserved intracellular degradation process of eukaryotic cells. In filamentous fungi, although autophagy has been reported to have multiple physiological roles, it is not clear whether autophagy is involved in the degradation of misfolded proteins. Here, we investigated the role of autophagy in the degradation of misfolded secretory proteins accumulated in endoplasmic reticulum (ER) in the filamentous fungus Aspergillus oryzae. In late-phase cultures, a disulfide bond-deleted mutant of the secretory protein α-amylase AmyB fused with mDsRed that had accumulated in the ER was subsequently delivered to vacuoles, whereas wild-type AmyB-mDsRed was predominantly located at cell walls and septa. To examine the involvement of autophagy in the delivery of mutant AmyB to vacuoles, mutant AmyB-EGFP was expressed in an A. oryzae autophagy-deficient strain (ΔAoatg8). Microscopic examination revealed that the protein delivery to vacuoles did not occur in the absence of autophagic activity, with mutant AmyB-mDsRed forming large spherical structures surrounded by ER membrane. Hence, we conclude that autophagy is responsible for the delivery of misfolded secretory proteins accumulated in the ER to vacuoles for degradation during late-growth phase in A. oryzae. This is the first study to provide evidence that autophagy plays a role in the degradation of misfolded secretory proteins in filamentous fungi.     

The ternary transformation system: constitutive virG on a compatible plasmid dramatically increases Agrobacterium-mediated plant transformation

This paper describes a so-called ternary transformation system for plant cells. We demonstrate that Agrobacterium tumefaciens strain LBA4404 supplemented with a constitutive virG mutant gene (virGN54D) on a compatible plasmid is capable of very efficient T-DNA transfer to a diverse range of plant species. For the plant species Catharanthus roseus it is shown that increased T-DNA transfer results in increased stable transformation frequencies. Analysis of stably transformed C. roseus cell lines showed that, although the T-DNA transfer frequency is greatly enhanced by addition of virGN54D, only one or a few T-DNA copies are stably integrated into the plant genome. Thus, high transformation frequencies of different plant species can be achieved by introduction of a ternary plasmid carrying a constitutive virG mutant into existing A. tumefaciens strains in combination with standard binary vectors.