Regulation of acid phosphatases in anAspergillus niger pacC disruption strain

AnAspergillus niger strain has been constructed in which the pH-dependent regulatory gene,pacC, was disrupted. ThepacC gene ofA. niger, like that ofA. nidulans, is involved in the regulation of acid phosphatase expression. Disruptants were identified by a reduction in acid phosphatase staining of colonies. Southern analysis demonstrated integration of the disruption plasmid at thepacC locus and Northern analysis showed that the disruption strain produced a truncatedpacC mRNA of 2.2 kb (as compared to 2.8 kb in the wild type). The strain carrying thepacC disruption was used to assign thepacC gene to linkage group IV; this was confirmed by CHEF electrophoresis and Southern analysis. This strain further allowed us to determine which extracellular enzyme and transport systems are under the control ofpacC inA. niger. Expression of theA. niger pacC wild-type gene and the truncatedpacC gene showed that, in contrast to the auto-regulated wild-type expression, which was elevated only at alkaline pH, the truncatedpacC gene was deregulated, as high-level expression occurred regardless of the pH of the culture medium. Analysis of the phosphatase spectrum by isoelectric focussing and enzyme activity staining both in the wild-type and thepacC disruptant showed that at least three acid phosphatases are regulated by thepacC. For the single alkaline phosphatase no pH regulation was observed.     

Identification, cloning and analysis of theAspergillus niger genepacC, a wide domain regulatory gene responsive to ambient pH

A wide domain regulatory gene implicated in modulating gene expression in response to ambient pH has been cloned and sequenced from the industrially useful filamentous fungusAspergillus niger. This gene,pacC, is able to restore apacC ⁺ phenotype toA. nidulans pacC ^c 11 andpacC ^c 14 mutants with respect to extent of conidiation, conidial pigment intensity and acid phosphatase regulation. ThepacC gene ofA. niger comprises three exons, encodes a three-zinc-finger protein of 677 amino acids, and shows pH-dependent regulation of expression: mRNA levels are elevated under alkaline conditions and considerably reduced under acidic conditions. The occurrence of PacC consensus binding targets within the sequences upstream ofpacC may indicate autoregulation.     

Identification,cloning and analysis of theAspergillus niger genepacC,a wide domain regulatory gene responsive to ambient pH

A wide domain regulatory gene implicated in modulating gene expression in response to ambient pH has been cloned and sequenced from the industrially useful filamentous fungusAspergillus niger. This gene,pacC, is able to restore apacC ⁺ phenotype toA. nidulans pacC ^c 11 andpacC ^c 14 mutants with respect to extent of conidiation, conidial pigment intensity and acid phosphatase regulation. ThepacC gene ofA. niger comprises three exons, encodes a three-zinc-finger protein of 677 amino acids, and shows pH-dependent regulation of expression: mRNA levels are elevated under alkaline conditions and considerably reduced under acidic conditions. The occurrence of PacC consensus binding targets within the sequences upstream ofpacC may indicate autoregulation.     

Regulation of gene expression by pH of the growth medium in Aspergillus nidulans

Summary In the fungus Aspergillus nidulans the levels of a number of enzymes whose location is at least in part extracellular (e.g. acid phosphatase, alkaline phosphatase, phosphodiesterase) and of certain permeases (e.g. that for -amino-n-butyrate) are controlled by the pH of the growth medium. For example, at acidic pH, levels of acid phosphatase are high and those of alkaline phosphatase are low whereas at alkaline pH the reverse is true. Mutations in five genes, palA, B, C, E and F, mimic the effects of growth at acid pH whereas mutations in pacC mimic the effects of growth at alkaline pH. palA, B, C, E and F mutations result in an intracellular pH (pH_in) which is more alkaline than that of the wild type whereas pacC mutations result in a pH_in more acidic than that of the wild type. This indicates that these mutations exert their primary effects on the regulation of gene expression by pH rather than on the pH homeostatic mechanism but that the expression of at least some component(s) of the pH homeostatic mechanism is subject to the pH regulatory system. It is suggested that pacC might be a wide domain regulatory gene whose product acts positively in some cases (e.g. acid phosphatase) and negatively in others (e.g. alkaline phosphatase). The products of palA, B, C, E and F are proposed to be involved in a metabolic pathway leading to synthesis of an effector molecule able to prevent the (positive and negative) action of the pacC product.These genes are, to our knowledge, the first examples of genes involved in the regulation of extracellular enzyme and permease synthesis by the pH of the growth medium to be described in any organism.     

NUT1, a major nitrogen regulatory gene inMagnaporthe grisea, is dispensable for pathogenicity

NUT1, a gene homologous to the major nitrogen regulatory genesnit-2 ofNeurospora crassa andareA ofAspergillus nidulans, was isolated from the rice blast fungus,Magnaporthe grisea. NUT1 encodes a protein of 956 amino acid residues and, likenit-2 andareA, has a single putative zinc finger DNA-binding domain. Functional equivalence ofNUT1 toareA was demonstrated by introducing theNUT1 gene by DNA-mediated transformation into anareA loss-of-function mutant ofA. nidulans. The introducedNUT1 gene fully complemented theareA null mutation, restoring to the mutant the ability to utilize a variety of nitrogen sources. In addition, the sensitivity ofAspergillus NUT1 transformants to ammonium repression of extracellular protease activity was comparable to that of wild-typeA. nidulans. Thus,NUT1 andareA encode functionally equivalent gene products that activate expression of nitrogen-regulated genes. A one-step gene disruption strategy was used to generatenutl ^– mutants ofM. grisea by transforming a rice-infecting strain with a disruption vector in which a gene for hygromycin B phosphotransferase (Hyg) replaced the zinc-finger DNA-binding motif ofNUT1. Of 31 hygromycin B (hyg B)-resistant transformants shown by Southern hybridization to contain a disruptedNUT1 gene (nut1::Hyg), 26 resulted from single-copy replacement events at theNUT1 locus. Althoughnut1 ^– transformants ofM. grisea failed to grown on a variety of nitrogen sources, glutamate, proline and alanine could still be utilized. This contrasts withA. nidulans where disruption of the zinc-finger region ofareA prevents utilization of nitrogen sources other than ammonium and glutamine. The role ofNUT1 and regulation of nitrogen metabolism in the disease process was evaluated by pathogenicity assays. The infection efficiency ofnut1 ^– transformants on susceptible rice plants was similar to that of the parental strain, although lesions were reduced in size. These studies demonstrate that theM. grisea NUT1 gene activates expression of nitrogen-regulated genes but is dispensable for pathogenicity.     

A novel gene——samfR involved in early stage of Streptomyces ansochromogenes differentiation

A 4.6 kb DNA fragment was cloned from the DNA library ofStreptomyces ansochromogenes using a partial DNA fragment located in the downstream of promoter-P_TH4 as probe. The experiments revealed that this DNA fragment consists ofsaw D gene and a 1.4 kbPvu II fragment which can accelerate mycelium formation ofS. ansochromogenes. The nucleotide sequence of 1.4 kb DNA fragment was determined and analysed; the result indicated that the fragment contains one complete open reading frame (ORF) which encodes a protein with 213 amino acids, and this gene was designated assamfR. The deduced protein has 36% amino acid identities and 52% amino acid similarities in comparison with that encoded byhppR gene, which is involved in the regulation of catabolism for 3-(3-hydroxyphenyl) propionate (3HPP) inRhodococcus globerulus. The function ofsamfR gene was studied using strategy of gene disruption, and the resultingsamfR mutant failed to form aerial hyphae and spores, its development and differentiation stopped at the stage of substrate mycelium in contrast with wild type strain. The results showed that thesamfR gene is closely related toS. ansochromogenes differentiation. Project supported by the National Natural Science Foundation of China (Grant No. 39830010).     

Overexpression ofENA1 from yeast increases salt tolerance inArabidopsis

In yeast, the plasma membrane Na⁺/H⁺ antiporter and Na⁺-ATPase are key enzymes for salt tolerance.Saccharomyces cerevisiae Na⁺-ATPase (Enalp ATPase) is encoded by theENA1/PMR2A gene; expression ofENA1 is tightly regulated by Na⁺ and depends on ambient pH. Although Enalp is active mainly at alkaline pH values inS. cerevisiae, no Na⁺-ATPase has been found in flowering plants. To test whether this yeast enzyme would improve salt tolerance in plants, we introducedENA1 intoArabidopsis (cv. Columbia) under the control of the cauliflower mosaic virus 35S promoter. Transformants were selected for their ability to grow on a medium containing kanamyin. Southern blot analyses confirmed thatENA1 was transferred into theArabidopsis genome and northern blot analyses showed thatENA1 was expressed in the transformants. Several transgenic homozygous lines and wild-type (WT) plants were evaluated for salt tolerance. No obvious morphological or developmental differences existed between the transgenic and WT plants in the absence of stress. However, overexpression ofENA1 inArabidopsis improved seed germination rates and salt tolerance in seedlings. Under saline conditions, transgenic plants accumulated a lower amount of Na⁺ than did the wild type, and fresh and dry weights of the former were higher. Other experiments revealed that expression ofENA1 promoted salt tolerance in transgenicArabidopsis under both acidic and alkaline conditions. These authors contributed equally to this article.     

NUT1, a major nitrogen regulatory gene inMagnaporthe grisea,is dispensable for pathogenicity

NUT1, a gene homologous to the major nitrogen regulatory genesnit-2 ofNeurospora crassa andareA ofAspergillus nidulans, was isolated from the rice blast fungus,Magnaporthe grisea. NUT1 encodes a protein of 956 amino acid residues and, likenit-2 andareA, has a single putative zinc finger DNA-binding domain. Functional equivalence ofNUT1 toareA was demonstrated by introducing theNUT1 gene by DNA-mediated transformation into anareA loss-of-function mutant ofA. nidulans. The introducedNUT1 gene fully complemented theareA null mutation, restoring to the mutant the ability to utilize a variety of nitrogen sources. In addition, the sensitivity ofAspergillus NUT1 transformants to ammonium repression of extracellular protease activity was comparable to that of wild-typeA. nidulans. Thus,NUT1 andareA encode functionally equivalent gene products that activate expression of nitrogen-regulated genes. A one-step gene disruption strategy was used to generatenutl ^? mutants ofM. grisea by transforming a rice-infecting strain with a disruption vector in which a gene for hygromycin B phosphotransferase (Hyg) replaced the zinc-finger DNA-binding motif ofNUT1. Of 31 hygromycin B (hyg B)-resistant transformants shown by Southern hybridization to contain a disruptedNUT1 gene (nut1::Hyg), 26 resulted from single-copy replacement events at theNUT1 locus. Althoughnut1 ^? transformants ofM. grisea failed to grown on a variety of nitrogen sources, glutamate, proline and alanine could still be utilized. This contrasts withA. nidulans where disruption of the zinc-finger region ofareA prevents utilization of nitrogen sources other than ammonium and glutamine. The role ofNUT1 and regulation of nitrogen metabolism in the disease process was evaluated by pathogenicity assays. The infection efficiency ofnut1 ^? transformants on susceptible rice plants was similar to that of the parental strain, although lesions were reduced in size. These studies demonstrate that theM. grisea NUT1 gene activates expression of nitrogen-regulated genes but is dispensable for pathogenicity.     

Formation of multiple forms of acid and alkaline phosphatases in relation to the culture age of Aspergillus niger

Acid phosphatase (EC 3.1.3.2 [EC] ) was extracted from mycelia ofAspergillus niger, then separated and purified into four fractions.These acid phosphatases, designated IA, IB, II and III, hadpH optima at 5.0, 4.5–5.0, 4.5 and 2.5, respectively.None required the presence of divalent cations, and all werestrongly inhibited by NaF. They were non-specific acid phosphatasesbut varied in their activities with various substrates. Thealkaline phosphatase (EG 3.1.3.1 [EC] ) of A. niger was also separatedinto two fractions, alkaline phosphatases I and II. Changes in the activity ratios of these acid and alkaline phosphataseswere studied during culture in a peptone medium. The activityof acid phosphatase II was higher than the others when the culturewas young. The activity of acid phosphatase III increased toa maximum in the actively growing phase, then decreased. Thatof acid phosphatase I became highest in the mature culture.In contrast, the activity of alkaline phosphatase I was higherthan the others in young cultures, while alkaline phosphataseII became dominant in the mature culture. Activities of the various acid and alkaline phosphatases indifferent regions of the growing colonies were also studied.The changing patterns of these enzymes in both liquid and surfacecultures were compared. When A. niger was cultured in a medium containing a low concentrationof phosphate, acid phosphatase activity greatly increased afterthe consumption of phosphate, but alkaline phosphatase activitydid not. ¹ The present experiments were carried out, for the most partat the Institute of Applied Microbiology of the University ofTokyo. (Received February 10, 1975; )     

Molecular cloning of alpha-amylase genes fromDrosophila melanogaster. III. An inversion at theAmy locus in an amylase-null strain

Overlapping clones of the structural gene region for alpha-amylase,Amy, were isolated from a lambda EMBL4 library containing genomic DNA fragments from an amylase-null strain ofDrosophila melanogaster. Southern blot analysis and restriction endonuclease mapping of the cloned region indicate that it contains anAmy gene duplication within an inverted repeat sequence as is characteristic of the genomic arrangement for this species. Spacing between the cloned gene copies is similar to that commonly found in other strains. Evidence is presented for the presence of an inversion 4 to 9 kb in length within the clonedAmy region of the null strain. We postulate a causal relationship between the presence of the inversion and the failure of individuals from the null strain to express amylase. A model is proposed that suggests the inversion may have arisen through intramolecular (or sister-strand) recombination mediated by homologous pairing of the inverted repeat sequences at theAmy locus.This research was supported by NIH Grant GM25255.     

Effect of aPMR1 disruption on the processing of heterologous glycoproteins secreted in the yeastSaccharomyces cerevisiae

TheSaccharomyces cerevisiae PMR1 gene encodes a Ca²⁺-ATPase localized in the Golgi. We have investigated the effects ofPMR1 disruption inS. cerevisiae on the glycosylation and secretion of three heterologous glycoproteins, human α₁-antitrypsin (α₁-AT), human antithrombin III (ATHIII), andAspergillus niger glucose oxidase (GOD). Thepmr1 null mutant strain secreted larger amounts of ATHIII and GOD proteins per a unit cell mass than the wild type strain. Despite a lower growth rate of thepmr1 mutant, two-fold higher level of human ATHIII was detected in the culture supernatant from thepmr1 mutant compared to that of the wild-type strain. Thepmr1 mutant strain secreted α₁-AT and the GOD proteins mostly as core-glycosylated forms, in contrast to the hyperglycosylated proteins secreted in the wild-type strain. Furthermore, the core-glycosylated forms secreted in thepmr1 mutant migrated slightly faster on SDS-PAGE than those secreted in themnn9 deletion mutant and the wild type strains. Analysis of the recombinant GOD with anti-α1,3-mannose antibody revealed that GOD secreted in thepmr1 mutant did not have terminal α1,3-linked mannoses unlike those secreted in themnn9 mutant and the wild type strains. The present results indicate that thepmr1 mutant, with the super-secretion phenotype, is useful as a host system to produce recombinant glycoproteins lacking high-mannose outer chains.     

Effects of promoters on the enhancement of pectin methyl esterase expression inAspergillus niger

Summary A pectin methylesterase-encoding gene (pmeA)_has been cloned and transformed intoA. niger wild-type NRRL3. Transformants produced 20-fold more PME than the host strain. For studying the effects of different promoters on thepmeA expression two novel plasmids were constructed, in which thepmeA promoter was replaced by efficient promoters such as theA. nidulans glyceraldehyde-3-phosphate dehydrogenase (pK45) or theA. oryzae -amylase (pK61) promoter. The highest level of PME expression was achieved with theA. oryzae -amylase promoter, reaching a 200-fold increase compared to the production by the host strain.     

Induced expression of the Aspergillus nidulans QUTE gene introduced by transformation into Neurospora crassa

Summary Theqa-2 gene ofNeurospora crassa encodes catabolic dehydroquinase which catabolizes dehydroquinic acid to dehydroshikimic acid. TheQUTE gene ofAspergillus nidulans corresponds to theqa-2 gene ofN. crassa. The plasmid pEH1 containing theQUTE gene fromA. nidulans was used to transform aqa-2 ^– strain ofN. crassa. In Southern blot analyses, DNAs isolated from these transformants hybridized specifically to theQUTE gene probe. Northern blot analyses indicated thatQUTE mRNA was produced in the transformants. The functional integrity of theQUTE gene inN. crassa was indicated by transformants which had regained the ability to grow on quinic acid as sole carbon source. Enzyme assays indicated that the specific activities of catabolic dehydroquinase induced by quinic acid in the transformants ranged from 4% to 32% of that induced in wild-typeN. crassa. The evidence that theQUTE structural gene ofA. nidulans is inducible when introduced into theN. crassa genome implies that theN. crassa qa activator protein can recognize, at least to a limited extent, DNA binding sequences 5 to theQUTE gene.     

Cloning,sequence and expression of the gene coding for rhamnogalacturonase ofAspergillus aculeatus; a novel pectinolytic enzyme

Rhamnogalacturonase was purified from culture filtrate ofAspergillus aculeatus after growth in medium with sugar-beet pulp as carbon source. Purified protein was used to raise antibodies in mice and with the antiserum obtained a gene coding for rhamnogalacturonase (rhgA) was isolated from a λ cDNA expression library. The clonedrhgA gene has an open-reading frame of 1320 base pairs encoding a protein of 440 amino acids with a predicted molecular mass of 45 962 Da. The protein contains a potential signal peptidase cleavage site behind Gly-18 and three potential sites forN-glycosylation. Limited homology withA. niger polygalacturonase amino acid sequences is found. A genomic clone ofrhgA was isolated from a recombinant phage λ genomic library. Comparison of the genomic and cDNA sequences revealed that the coding region of the gene is interrupted by three introns. Furthermore, amino acid sequences of four different peptides, derived from purifiedA. aculeatus rhamnogalacturonase, were also found in the deduced amino acid sequence ofrhgA.A. aculeatus strains overexpressing rhamnogalacturonase were obtained by cotransformation using either theA. niger pyrA gene or theA. aculeatus pyr A gene as selection marker. For expression of rhamnogalacturonase inA. awamori theA. awamori pyrA gene was used as selection marker. Degradation patterns of modified hairy regions, determined by HPLC, show the recombinant rhamnogalacturonase to be active, and the enzyme was found to have a positive effect in the apple hot-mash liquefaction process.     

The role of acid phosphatase activity during enzymic dephosphorylation of phytates byAspergillus niger phytase

Acid phosphatase present in preparations ofAspergillus niger phytase accelerated dephosphorylation of sodium phytate. Its influence on the reaction rate and distribution ofmyo-inositol phosphates was most apparent at low pH value (2.5) and when acid-hydrolysed substrate was de-esterified enzymatically. With partly purified phytase, the predominant inositol form was tetraphosphate but a preparation having acid phosphatase activity caused an even distribution of lower inositol phosphates after a few hours.