Specific induction of catabolism and its relation to repression of biosynthesis in arginine metabolism of Saccharomyces cerevisiae.

Experimental results are presented in support of the model previously proposed for specific induction of the synthesis of enzymes for arginine catabolism in Saccharomyces cerevisiae (Wiame, 1971a,b), and its connection with end-product repression of arginine biosynthetic enzymes. The data support the occurrence of negative regulation of metabolism in a eukaryote.Operator regions, one for arginase and another for ornithine transaminase, are identified. The operator mutations are fully constitutive. A mutation compatible with the occurrence of a catabolic represser, CARGR, leads to partial pleiotropic constitutivity.The connection between the induction process and the repression of biosynthetic enzymes is due to a common receptor of metabolic signals, an ambivalent repressor ARGR endowed with the property of a usual repressor for anabolic enzymes and playing the role of inducer at the level of CARGR; this cascade process simulates a positive control. argR^? mutations, by producing defective ARGR, “turn on” anabolic enzyme synthesis and “turn off” the synthesis of catabolic enzymes (Fig. 2). The dual role of ARGR is confirmed by the isolation of a mutation argRII^d which, in contrast to the defective properties caused by usual argR^? mutations, causes a dominant hyperactivity toward induction of a catabolic enzyme, but retains recessive hypoactivity toward repression of an anabolic enzyme. Such an ambivalent repressor is a function necessary for mutual, balanced exclusion between opposite metabolisms.Many operator constitutive mutations for arginase, cargA⁺O^?, change the level of enzyme to a similar value, thus defining a genetic function. One of these mutations, cargA⁺O^h, in addition to having unusual genetic behaviour, leads to production of twice as much arginase as cargA⁺O^?. This suggests the existence of another genetic region near the structural gene for this enzyme and an additional regulatory function to be analyzed in a separate paper (Dubois &; Wiame, 1978).     

Xylanase production in Aspergillus nidulans: induction and carbon catabolite repression

Abstract The induction of the synthesis of extracellular xylanases was investigated in the fungus Aspergillus nidulans using a number of compounds, including xylans of different origin, monosaccharides, xylooligosaccharides and xylose derivatives. Certain xylans (wheat arabinoxylan, oat spelt xylan, birchwood xylan and 4-O-methyl-D-glucurono-D-xylan) were found to be the most powerful inducers. Also, xylooligosaccharides such as xylobiose, xylotriose and xylotetraose served as inducers, their efficiency being directly related to their chain length. Xylose, on the contrary, was not a true inducer. Of the three endo-β-(1,4)-xylanases secreted by A. nidulans , that of 24 kDa was not under carbon catabolite repression, whereas the other two, of 22 and 34 kDa, were under glucose repression mediated by the creA gene product.     

Effect of the areA gene on regulation of arginine catabolism in Aspergillus nidulans.

The areA gene which is known to be involved in ammonium repression in Aspergillus nidulans was found to participate in regulation of arginine catabolism. Mutations in this gene are hypostatic to mutations in arcA, suDpro and suEpro genes which are responsible for regulation of synthesis of arginine catabolic enzymes.     

Ammonium and glucose repression of the arginine catabolic enzymes in Aspergillus nidulans

Summary The synthesis of two enzymes of the arginine catabolic pathway, arginase and ornithine -transaminase (OTAse), in Aspergillus nidulans was found to be sensitive to both glucose and ammonium repression. The glucose and nitrogen starvation result in the identical derepression of OTAse synthesis and have no effects on arginase synthesis. Glucose and ammonium affect the kinetics of induction of both enzymes, however, the effect of ammonium is much stronger. Evidence was obtained for the direct involvement of ammonium in the repression phenomenon. The relations between glucose and ammonium repression are discussed.     

Cloning of the regulatory gene areA mediating nitrogen metabolite repression in Aspergillus nidulans.

The areA gene, which mediates nitrogen metabolite repression in the fungus Aspergillus nidulans, lies sufficiently close to a telomere that no indispensable gene can be distal to it. We were able therefore to exploit the existence of a near terminal pericentric inversion to devise a method for cloning areA plus the region beyond it towards the telomere. In crosses heterozygous for this inversion a class of duplication-deficient progeny lacking areA and the region centromere-distal to it is obtained. We, therefore, sought clones from an A. nidulans gene library in lambda Charon 4 able to hybridize to total genomic DNA from a wild-type strain but not to that from a duplication-deficiency strain. A clone, containing an 11.6-kb insert, which hybridised weakly to duplication-deficiency DNA, overlapped chromosome breakpoints of three different aberration-associated areA alleles and was able to transform an areA mutant to areA+. Southern blotting and genetic analysis established that the transforming sequence had integrated in the region centromere distal to areA. The cloning method yielded other clones from the region centromere-distal to areA which were used to show that the translocation associated with a mutant areA allele is reciprocal rather than non-reciprocal, a fact which could not be established by classical genetics. Finally, analysis of the cloned portion of the dispensable region centromere-distal to areA indicates that this region contains at least 0.5% of the A. nidulans genome.     

Repression of enzymes of nitrogen catabolism by methylammonium and caesium chloride in strains of Aspergillus nidulans insensitive to ammonium repression

Summary Growth of Aspergillus nidulans in the presence of methylammonium leads to lowered levels of the enzymes, acetamidase, formamidase, benzamidase, histidase, nitrate reductase and urate oxidase. This phenomenon is not altered in strains that are insensitive to ammonium repression due to a lesion in the gdhA gene. Similarly repression of acetamidase, formamidase and histidase by high concentrations of caesium ion is not affected in these strains. The results indicate that caesium ion and methylammonium may not act as direct analogues of ammonium in repression of enzyme synthesis.     

Studies on the role of the areA gene in the regulation of nitrogen catabolism in Aspergillus nidulans.

Mutants of Apergillus nidulans with lesions in a gene, areA (formerly called amdT), have been isolated by a variety of different selection methods. The areA mutants show a range of pleiotropic growth responses to a number of compounds as sole nitrogen sources, but are normal in utilization of carbon sources. The levels of two amidase enzymes as well as urease have been investigated in the mutants and have been shown to be affected by this gene. Most of the areA mutants have much lower amidase-specific activities when grown in ammonium-containing medium, compared with mycelium incubated in medium lacking a nitrogen source. Some of the areA mutants do not show derepression of urease upon relief of ammonium repression. The dominance relationships of areA alleles have been investigated in heterozygous diploids, and these studies lend support to the proposal that areA codes for a positively acting regulatory product. One of the new areA alleles is partially dominant to areA+ and areA102. This may be a result of negative complementation or indicate that areA has an additional negative regulatory function. Investigation of various amdR; areA double mutants has led to the conclusion that amdR and areA participate in independent regulatory circuits in the control of acetamide utilization. Studies on an amdRc; areA double mutant indicate that areA is involved in derepression of acetamidase upon relief of ammonium repression.     

Analysis of the creA gene, a regulator of carbon catabolite repression in Aspergillus nidulans.

The complete nucleotide sequence derived from a genomic clone and two cDNA clones of the creA gene of Aspergillus nidulans is presented. The gene contains no introns. The derived polypeptide of 415 amino acids contains two zinc fingers of the C2H2 class, frequent S(T)PXX motifs, and an alanine-rich region indicative of a DNA-binding repressor protein. The amino acid sequence of the zinc finger region has 84% similarity to the zinc finger region of Mig1, a protein involved in carbon catabolite repression in yeast cells, and it is related both to the mammalian Egr1 and Egr2 proteins and to the Wilms' tumor protein. A deletion removing the creA gene was obtained, by using in vitro techniques, in both a heterokaryon and a diploid strain but was unobtainable in a pure haploid condition. Evidence is presented suggesting that the phenotype of such a deletion, when not complemented by another creA allele, is leaky lethality allowing limited germination of the spore but not colony formation. This phenotype is far more extreme than that of any of the in vivo-generated mutations, and thus either the gene product may have an activator activity as well as a repressor function or some residual repressor function may be required for full viability.     

Carbon and nitrogen repression of arginine catabolic enzymes in Bacillus subtilis.

Specific activities of arginase and ornithine aminotransferase, inducible enzymes of arginine catabolism in Bacillus subtilis 168, were examined in cells grown with various carbon and nitrogen sources. Levels of these enzymes were similar in arginine-induced cultures whether glucose or citrate was the carbon source (in contrast to histidase), suggesting that carbon source catabolite repression has only limited effect. In media with combinations of nitrogen sources, glutamine strongly repressed induction of these enzymes by proline or arginine. Ammonium, however, only repressed induction by proline and had no effect on induction by arginine. These effects correlate with generation times in media containing these substances as sole nitrogen sources: growth rates decreased in the order glutamine-arginine-ammonium-proline. Similar phenomena were observed when glutamine or ammonium were added to arginine- or proline-grown cultures, or when arginine or proline were added to glutamine- or ammonium-grown cultures. In the latter cases, an additional feature was apparent, namely a surprisingly long transition between steady-state enzyme levels. The results are compared with those for other bacteria and for eucaryotic microorganisms.     

Mutations simultaneously affecting ammonium and glucose repression of the arginine catabolic enzymes in Aspergillus nidulans

Summary Two kinds of mutants of Aspergillus nidulans with altered response of arginine catabolic enzymes to glucose and ammonium repression were obtained. Mutations in the suF locus result in the insensitivity of these enzymes to glucose and to one type of ammonium repression. Mutations in the AniA locus result in hypersensitivity to both types of repression. The enzymes studied can be induced by arginine in AniA mutants only when glucose or the nitrogen source is removed from the medium. The suF mutations are recessive while AniA are dominant. Double suF AniA mutants retain only the suF properties. The functions of both genes and their interrelations are discussed.     

Genetic control of the arginine pathways in Aspergillus nidulans. Common regulation of anabolism and catabolism

Summary Two regulatory mutants for arginine catabolism isolated as proline suppressors were tested for the synthesis of ornithine transcarbamylase (OTC), the arginine anabolic enzyme. Mutations at one locus, suD, result in the insensitivity of OTC synthesis to effectors responsible for the enzyme level in the wild strain. The common genetic regulation of both catabolic and anabolic pathways of arginine is postulated.     

Role of glutamine synthetase in nitrogen metabolite repression in Aspergillus nidulans

Glutamine synthetase (GS), EC 6.3.1.2, is a central enzyme in the assimilation of nitrogen and the biosynthesis of glutamine. We have isolated the Aspergillus nidulans glnA gene encoding GS and have shown that glnA encodes a highly expressed but not highly regulated mRNA. Inactivation of glnA results in an absolute glutamine requirement, indicating that GS is responsible for the synthesis of this essential amino acid. Even when supplemented with high levels of glutamine, strains lacking a functional glnA gene have an inhibited morphology, and a wide range of compounds have been shown to interfere with repair of the glutamine auxotrophy. Heterologous expression of the prokaryotic Anabaena glnA gene from the A. nidulans alcA promoter allowed full complementation of the A. nidulans glnADelta mutation. However, the A. nidulans fluG gene, which encodes a protein with similarity to prokaryotic GS, did not replace A. nidulans glnA function when similarly expressed. Our studies with the glnADelta mutant confirm that glutamine, and not GS, is the key effector of nitrogen metabolite repression. Additionally, ammonium and its immediate product glutamate may also act directly to signal nitrogen sufficiency.     

Metabolic control analysis of xylose catabolism in Aspergillus

A kinetic model for xylose catabolism in Aspergillus is proposed. From a thermodynamic analysis it was found that the intermediate xylitol will accumulate during xylose catabolism. Use of the kinetic model allowed metabolic control analysis (MCA) of the xylose catabolic pathway to be carried out, and flux control was shown to be dependent on the metabolite levels. Due to thermodynamic constraints, flux control may reside at the first step in the pathway, i.e., at the xylose reductase, even when the intracellular xylitol concentration is high. On the basis of the kinetic analysis, the general dogma specifying that flux control often resides at the step following an intermediate present at high concentrations was, therefore, shown not to hold. The intracellular xylitol concentration was measured in batch cultivations of two different strains of Aspergillus niger and two different strains of Aspergillus nidulans grown on media containing xylose, and a concentration up to 30 mM was found. Applying MCA showed that the first polyol dehydrogenase (XDH) in the catabolic pathway of xylose exerted the main flux control in the two strains of A. nidulans and A. niger NW324, but the flux control was exerted mainly at the first enzyme of the pathway (XR) of A. niger NW 296.     

Carbon catabolite repression of the Aspergillus nidulans xlnA gene

Expression of the Aspergillus nidulans 22 kDa endoxylanase gene, xlnA , is controlled by at least three mechanisms: specific induction by xylan or xylose; carbon catabolite repression (CCR); and regulation by ambient pH. Deletion analysis of xlnA upstream sequences has identified two positively acting regions: one that mediates specific induction by xylose; and another that mediates the influence of ambient pH and contains two PacC consensus binding sites. The extreme derepressed mutation creA^d 30 results in considerable, although not total, loss of xlnA glucose repressibility, indicating a major role for CreA in its CCR. Three consensus CreA binding sites are present upstream of the structural gene. Point mutational analysis using reporter constructs has identified a single site, xlnA .C1, that is responsible for direct CreA repression in vivo . Using the creA^d 30 derepressed mutant background, our results indicate the existence of indirect repression by CreA.     

Induction and repression of a Streptomyces lividans chitinase gene promoter in response to various carbon sources

Induction and repression of a gene for chitinase (chiA) in Streptomyces lividans was investigated using a catechol 2,3-dioxygenase gene (xylE) as the reporter gene. Of various substrates examined, expression of the promoter (PchiA) was observed after a delay when colloidal chitin or small chitin-oligosaccharides were added to the medium. N-acetylglucosamine completely repressed the chiA promoter. The duration of the delay in expression of PchiA differed with the inducer used, with chitobiose inducing the activity most rapidly. The minimum concentration of chitobiose needed for induction was 1 microM. It appears, therefore, that an efficient inducer of the gene for chitinase in S. lividans is chitobiose.