Regulation of the carbamoylphosphate synthetase belonging to the arginine biosynthetic pathway of Saccharomyces cerevisiae

Two classes of regulatory mutations affecting the synthesis of the carbamoylphosphate synthetase belonging to the arginine biosynthetic pathway have been selected in Saccharomyces cerevisiae. Together, they delineate a negative type of control. The cpaI0 mutations, closely linked with one of the two genes coding for the enzyme and cis dominant, meet properties of operator mutations. The cpaR mutations can be interpreted as mutations impairing the formation of an active repressor of carbamoylphosphate synthetase which is distinct from the one acting on the synthesis of the other enzymes of the arginine biosynthetic pathway.     

Control of arginine utilization in Neurospora.

The response of Neurospora to changes in the availibility of exogenous arginine was investigated. Upon addition of arginine to the growth medium, catabolism is initiated within minutes. This occurs prior to expansion of the arginine pool or augmentation of catabolic enzyme levels. (Basal levels are approximately 25% of those found during growth in arginine-supplemented medium.) Catabolism of arginine is independent of protein synthesis, indicating that the catabolic enzymes are active but that arginine is not available for catabolism unless present in the medium. Upon exhaustion of the supply of exogenous arginine, catabolism ceases abruptly, despite an expanded arginine pool and induced levels of the catabolic enzymes. The arginine pool supports protein synthesis until the cells regain their normal capacity for endogenous arginine synthesis. These observations, combined with the known small level of induction of arginine catabolic enzymes, non-repressibility of most biosynthetic enzymes, and vesicular localization of the bulk of the arginine pool, suggest that compartmentation plays a significant role in controlling arginine metabolism in Neurospora.     

Regulation of enzyme synthesis in the arginine biosynthetic pathway of Pseudomonas aeruginosa.

In Pseudomonas aeruginosa the synthesis of only two out of eight arginine biosynthetic enzymes tested was regulated. Comparisons were made between the specific activities of these enzymes in bacteria grown on arginine or on its precursor, glutamate. N2-Acetylornithine 5-aminotransferase (ACOAT), an enzyme involved in both the biosynthesis and catabolism of arginine, was induced about 14-fold during growth of the organism on arginine as the only carbon and nitrogen source, and the anabolic ornithine carbamoyltransferase (aOTC), a strictly biosynthetic enzyme, was repressed 18-fold. Addition of various carbon sources to the arginine medium led to repression of ACOAT and to derepression of aOTC. Fructose, which supported only slow growth of P. aeruginosa, had a weak regulatory effect on the synthesis of the two arginine enzymes while citrate, a good carbon source for this organism, had a strong effect. The repression of ACOAT by citrate was not relieved by adding cyclic AMP to the medium. Under a variety of growth conditions leading to different enzyme activities, a linear relationship between the reciprocal of the specific activity of ACOAT and the specific activity of aOTC was observed. This inverse regulation of the formation of the two enzymes suggested that a single regulatory system governs their synthesis. Such a view was supported by the isolation of citrate-resistant regulatory mutants which constitutively formed ACOAT at the induced level and aOTC at the repressed level.     

Control of arginine metabolism in Neurospora: flux through the biosynthetic pathway.

The flux into the arginine biosynthetic pathway of Neurospora crassa was investigated using a mutant strain lacking the ornithine-degrading enzyme ornithine aminotransferase (EC 2.6.1.13). Flux was measured by the increase in the sum of the radioactivity (derived from [14C]glutamic acid) in the ornithine pool, the arginine pool, and arginine incorporated into proteins. Complete cessation of flux occurred immediately upon the addition of arginine to the growth medium. This response occurred prior to expansion of the arginine pool. After short-term exposure to arginine (80 min), flux resumed quickly upon exhaustion of arginine from the medium. This took place despite the presence of an expanded arginine pool. Initiation of flux required approximately 80 min when the mycelia were grown in arginine-supplemented medium for several generations before exhaustion of the exogenous arginine. The arginine pool of such mycelia was similar to that found in mycelia exposed to exogenous arginine for only 80 min. The results are consistent with rapid onset and release of feedback inhibiton of arginine biosynthesis in response to brief exposure to exogenous arginine. The insensitivity of flux to the size of the arginine pool is consistent with a role for compartmentation in this regulatory process. The lag in initiation of flux after long-term growth in the presence of exogenous arginine suggests the existence of an additional regulatory mechanism(s). Several possibilities are discussed.     

Pyrimidine biosynthetic enzymes of Salmonella typhimurium, repressed specifically by growth in the presence of cytidine.

The repressive effects of exogenous cytidine on growing cells was examined in a specially constructed strain in which the pool sizes of endogenous uridine 5'-diphosphate and uridine 5'-triphosphate cannot be varied by the addition of uracil and/or uridine to the medium. Five enzymes of the pyrimidine biosynthetic pathway and one enzyme of the arginine biosynthetic pathway were assayed from cells grown under a variety of conditions. Cytidine repressed the synthesis of dihydroorotase (encoded by pyrC), dihydroorotate dehydrogenase (encoded by pyrD), and ornithine transcarbamylase (encoded by argI). Moreover, aspartate transcarbamylase (encoded by pyrB) became further derepressed upon cytidine addition, whereas no change occurred in the levels of the last two enzymes (encoded by pyrE and pyrF) of the pyrimidine pathway. Quantitative nucleotide pool determinations have provided evidence that any individual ribo- or deoxyribonucleoside mono-, di-, or triphosphate of cytosine or uracil is not a repressing metabolite for the pyrimidine biosynthetic enzymes. Other nucleotide derivatives or ratios must be considered.     

Arginine metabolism in the deep sea tube worm Riftia pachyptila and its bacterial endosymbiont

The present study describes the distribution and properties of enzymes involved in arginine metabolism in Riftia pachyptila, a tubeworm living around deep sea hydrothermal vents and known to be engaged in a highly specific symbiotic association with a bacterium. The results obtained show that the arginine biosynthetic enzymes, carbamyl phosphate synthetase, ornithine transcarbamylase, and argininosuccinate synthetase are present in all of the tissues of the worm and in the bacteria. Thus, Riftia and its bacterial endosymbiont can assimilate nitrogen and carbon via this arginine biosynthetic pathway. The kinetic properties of ornithine transcarbamylase strongly suggest that neither Riftia nor the bacteria possess the catabolic form of this enzyme belonging to the arginine deiminase pathway, the absence of this pathway being confirmed by the lack of arginine deiminase activity. Arginine decarboxylase and ornithine decarboxylase are involved in the biosynthesis of polyamines such as putrescine and agmatine. These activities are present in the trophosome, the symbiont-harboring tissue, and are higher in the isolated bacteria than in the trophosome, indicating that these enzymes are of bacterial origin. This finding indicates that Riftia is dependent on its bacterial endosymbiont for the biosynthesis of polyamines that are important for its metabolism and physiology. These results emphasize a particular organization of the arginine metabolism and the exchanges of metabolites between the two partners of this symbiosis.     

Genetically determined differences in concentrations of isoaccepting tRNAs in Escherichia coli.

Two examples of genetically determined altered concentrations of isoaccepting tRNAs are presented. The concentrations of isoaccepting tRNAsThr are selectively changed by a mutation causing a fourfold overproduction of the cognate aminoacyl-tRNA-synthetase, the threonyl-tRNA synthetase, whereas the distribution of isoaccepting tRNAs of four control tRNA-species in these E. coli mutants was not affected by that mutation. Secondly evidence is presented for a correlation between mutations in structural genes of aminoacid biosynthetic enzymes and alterations in concentrations of cognate isoaccepting tRNAs in two different E. coli strains, auxotrophic for threonine, isoleucine/valine and leucine, and arginine respectively.     

L-ornithine transaminase synthesis in Saccharomyces cerevisiae: Regulation by inducer exclusion

Summary The ornithine transaminase (EC.2.6.1.13) of Saccharomyces cerevisiae is induced by arginine, ornithine, and their analogs. Genetic regulatory elements which are involved in this induction process have been defined due to the isolation of specific mutants. Two classes of OTAse operator mutants have previously been described; three unlinked genes are presumed to code for a specific repressor, CARGR of both of the arginine catabolic enzymes, arginase, and ornithine transaminase. The level of transaminase of cells grown on ammonia plus arginine is much lower than it is when arginine is the sole nitrogen source. Ammonia thus seems to limit the amount of enzyme synthesized when arginine is present in the growth medium. Nevertheless, all attempts to disclose a nitrogen catabolite repression process in OTAse synthesis have failed; neither the action of mutations that release this regulation on arginase and other catabolic enzymes, nor the use of derepressing growth conditions, affect OTAse synthesis. A decrease of the cells' arginine pool when amonia or aminoacids (serine, glutamate) are added to arginine as a nitrogen nutrient results in a progressive reduction of transaminase synthesis. This suggests that arginine is the only physiological effector in those conditions: ammonia or some aminoacids would reduce the enzyme synthesis because of an inducer exclusion. The first stage of OTAse induction would then be operated by the CARGR repressor, and an additional regulatory element might take part in the full scale process. Preliminary data favoring the involvment of such an element are presented.     

Arginine hydroxamate-resistant mutants of Bacillus subtilis with altered control of arginine metabolism.

Arginine hydroxamate inhibits the growth of Bacillus subtilis. From a large number of mutants isolated as resistant to this arginine analogue, 29 were chosen for further investigation. Most of these shared diminished ability to utilize arginine, citrulline and/or ornithine as sole nitrogen source. All 29 had reduced levels of the catabolic enzymes arginase and ornithine aminotransferase under various conditions in which these enzymes are induced in the parent. In some circumstances, five of the mutants also showed elevated levels of the biosynthetic enzyme ornithine carbamoyltransferase. On the basis of these data, the 29 mutants were divided into six phenotypic classes; in four of these, control of ornithine carbamoyltransferase was the same as in the wild type, while in the other two it was altered. It is suggested that the isolates carry regulatory mutations, and that certain of these may affect simultaneously the formation of arginine catabolic and biosynthetic enzymes. The implication of the latter is that in B. subtilis, as in yeast, controls of the catabolic and biosynthetic pathways are connected. Single representatives of five of the phenotypic classes carry mutations conferring arginine hydroxamate resistance linked to cysA by transduction with phage PBSI; this did not appear to be true for a representative of the sixth class.     

Cloning and characterization of argR, a gene that participates in regulation of arginine biosynthesis and catabolism in Pseudomonas aeruginosa PAO1.

Gel retardation experiments indicated the presence in Pseudomonas aeruginosa cell extracts of an arginine-inducible DNA-binding protein that interacts with the control regions for the car and argF operons, encoding carbamoylphosphate synthetase and anabolic ornithine carbamoyltransferase, respectively. Both enzymes are required for arginine biosynthesis. The use of a combination of transposon mutagenesis and arginine hydroxamate selection led to the isolation of a regulatory mutant that was impaired in the formation of the DNA-binding protein and in which the expression of an argF::lacZ fusion was not controlled by arginine. Experiments with various subclones led to the conclusion that the insertion affected the expression of an arginine regulatory gene, argR, that encodes a polypeptide with significant homology to the AraC/XylS family of regulatory proteins. Determination of the nucleotide sequence of the flanking regions showed that argR is the sixth and terminal gene of an operon for transport of arginine. The argR gene was inactivated by gene replacement, using a gentamicin cassette. Inactivation of argR abolished arginine control of the biosynthetic enzymes encoded by the car and argF operons. Furthermore, argR inactivation abolished the induction of several enzymes of the arginine succinyltransferase pathway, which is considered the major route for arginine catabolism under aerobic conditions. Consistent with this finding and unlike the parent strain, the argR::Gm derivative was unable to utilize arginine or ornithine as the sole carbon source. The combined data indicate a major role for ArgR in the control of arginine biosynthesis and aerobic catabolism.     

Selection and characterisation of mutants lacking arginase in Neurospora crassa

Summary A Neurospora mutant (aga) lacking arginase was selected by virtue of its inability to utilize arginine as a source of ornithine, using a strain in which ornithine was needed to satisfy a proline requirement. It mapped in linkage group VII (right arm), close to wc. The most important characteristic of the mutant was its extreme sensitivity to arginine. Inclusion of 1 mM arginine in the medium lead to a 40-fold increase in the arginine pool and a 90% inhibition of growth. This inhibition was relieved by the addition of ornithine or proline. The high arginine pool was associated with only a slight repression of two biosynthetic enzymes examined and with a five-fold induction of ornthine transaminase, the second enzyme of arginine catabolism. It is expected that the aga mutant will be of value in further work on the regulation of arginine biosynthesis in Neurospora.     

Control of Arginine Biosynthesis in Escherichia coli: Role of Arginyl-Transfer Ribonucleic Acid Synthetase in Repression

The physiological role of arginyl-transfer ribonucleic acid (Arg-tRNA) synthetase (E.C. 6.1.1.13, arginine: RNA ligase adenosine monophosphate) in repression of arginine biosynthetic enzymes was examined. Mutants with nonrepressible synthesis of arginine biosynthetic enzymes were isolated from various strains of Escherichia coli by resistance to growth inhibition by canavanine, an arginine analogue. These mutants possessed reduced Arg-tRNA synthetase activities which were qualitatively different from the synthetase activity of the wild type. The mutant enzymes exhibited turnover in vivo and were less stable in vitro than the wild type at both 4 C and 40 C; they possessed different affinities for both arginine and canavanine as measured by the three common assay systems for aminoacyl-tRNA synthetases. Furthermore, in one case it was shown that (i) the mutant possesed unaltered uptake of arginine, and (ii) that the mutant possessed diminished ability to incorporate canavanine into proteins and to attach canavanine to tRNA. These observations suggested that the mutation to canavanine resistance involved a structural change in Arg-tRNA synthetase. Likewise, the results of genetic experiments suggested that the mutants differed from the wild-type strain at only one locus, and that this lies in the region of the chromosomes that includes a structural gene for Arg-tRNA synthetase. It appears that Arg-tRNA synthetase may be involved in some way in repression by arginine of its own biosynthetic enzymes.     

Simultaneous purification of three mitochondrial enzymes. Acetylglutamate kinase, acetylglutamyl-phosphate reductase and carbamoyl-phosphate synthetase from Neurospora crassa

The early enzymes of arginine biosynthesis in Neurospora crassa are localized in the mitochondrion and catalyze the conversion of glutamate to citrulline. The final conversion of citrulline to arginine occurs via two enzymatic steps in the cytoplasm. We have devised a method for the isolation and purification of three of the mitochondrial arginine biosynthetic enzymes from a single extract. Acetylglutamate kinase and acetylglutamyl-phosphate reductase (both products of the complex arg-6 locus) were purified to homogeneity and near homogeneity, respectively. The large catalytic subunit of carbamoyl-phosphate synthetase was also purified to homogeneity. The three enzymes were resolved into separate fractions by chromatography on three dye-ligand affinity resins, which are specific for nucleotide binding enzymes and have a high protein binding capacity. High performance liquid chromatography was employed in the final stages of purification and was extremely effective in fractionating both acetylglutamate kinase and acetylglutamyl-phosphate reductase from proteins with very similar properties, which were not removed by other techniques. The purified proteins were used to raise specific antisera against these proteins. Acetylglutamate kinase and acetylglutamyl-phosphate reductase were shown to be immunologically unrelated. This finding suggests that the arg-6 locus encompasses two nonoverlapping cistrons. The antisera raised against carbamoyl-phosphate synthetase has been shown to cross-react with related enzymes in Saccharomyces cerevisiae, Escherichia coli, and rat liver (Ness, S. A., and Weiss, R. L. (1985) J. Biol. Chem. 260, 14355-14362). Acetylglutamate kinase is a regulatory enzyme and has been shown to be feedback-inhibited by arginine. We have determined the submitochondrial localization of acetylglutamate kinase and the second arg-6 product, acetylglutamyl-phosphate reductase. Both enzymes were shown to be soluble matrix enzymes. We discuss the relevance of this finding with respect to possible mechanisms for end product inhibition of a mitochondrial enzyme by a cytoplasmic effector.     

Induction of astrocyte argininosuccinate synthetase and argininosuccinate lyase by dibutyryl cyclic AMP and dexamethasone

Arginine is an intermediate in the elimination of excess nitrogen and is the substrate for nitric oxide synthesis. Arginine synthesis has been reported in brain tissue. We have studied the activity of the arginine biosynthetic enzymes argininosuccinate synthetase and argininosuccinate lyase in dexamethasone and/or dibutyryl cyclic AMP treated rat astrocyte cultures. Argininosuccinate lyase activity was stimulated by treatment with either effector and an additive effect was obtained when both agents were added simultaneously. Argininosuccinate synthetase was also increased in dexamethasone treated astrocytes. The effect of dibutyryl cyclic AMP on argininosuccinate synthetase was variable, suggesting a role for additional factors in its regulation as compared to argininosuccinate lyase. Regulation of arginine synthesis in astrocytes may be important to insure that arginine is not limiting for nitric oxide synthesis in neural tissue.     

Acetylglutamate kinase. A mitochondrial feedback-sensitive enzyme of arginine biosynthesis in Neurospora crassa

The radioisotopic method used to assay acetylglutamate kinase (EC 2.7.2.8) of Neurospora crassa has been shown to detect two distinct enzymatically catalyzed reactions. The enzymes were separated by differential centrifugation into a cytosolic activity and an organellar activity. Both activities required ATP and were thermal-labile. The cytosolic activity was insensitive to inhibition by arginine and formed a stable reaction product in the absence of hydroxylamine. The organellar activity had an absolute requirement for hydroxylamine in order to form a stable reaction product. The product of the cytosolic activity was separated from acetylglutamate hydroxamate (the product of the organellar activity) and was identified as the cyclic amide pyroglutamate by cation exchange chromatography. The organellar activity has been implicated in arginine biosynthesis by the following criteria: it was completely and specifically inhibited by arginine concentrations as low as 200 microM; its level was elevated 2-fold in a mutant strain with derepressed levels of arginine biosynthetic enzymes; and it was absent in an arginine auxotrophic strain (the cytosolic activity was present). The organellar activity co-sedimented with mitochondria during isopycnic gradient centrifugation. The metabolic problems posed by a mitochondrial location of a feedback-sensitive enzyme and the cytosolic location of its effector are discussed.     

Cross-Pathway Regulation: Tryptophan-Mediated Control of Histidine and Arginine Biosynthetic Enzymes in Neurospora crassa

In Neurospora crassa, the starvation of tryptophan mutants for tryptophan resulted in the derepression of tryptophan, histidine, and arginine biosynthetic enzymes. This tryptophan-mediated derepression of histidine and arginine biosynthetic enzymes occurred despite the fact that the tryptophan-starved cells had a higher intracellular concentration of histidine and arginine than did nonstarved cells.     

Inhibition of aminoacyl-transfer ribonucleic acid synthetases and the regulation of amino acid biosynthetic enzymes in Neurospora crassa.

Growth conditions that result in the accumulation of the tryptophan intermediate indoleglycerol phosphate or of the histidine intermediate imidazoleglycerol phosphate cause mycelia of Neurospora crassa to exhibit an immediate and sustained increase in the differential rate at which the biosynthetic enzymes of the tryptophan, histidine, and arginine pathways are synthesized. These accumulated intermediates are shown to be inhibitors of the activity of aminoacyltransfer ribonucleic acid (tRNA) synthetases, as judged by an in vitro esterification assay. The tryptophan intermediate is shown to inhibit the charging of tryptophan, and the histidine intermediate is shown to inhibit charging of histidine. The inhibitions noted are consistent with the finding that the level of charged tRNATrp is decreased significantly in cells that have accumulated indoleglycerol phosphate and that of tRNAHis is decreased significantly in cells that have accumulated imidazoleglycerol phosphate. These results are interpreted as support for the involvement of aminoacyl-tRNA species in mediating cross-pathway regulation of the tryptophan, histidine, and arginine biosynthetic pathways as proposed in Lester's polyrepressor hypothesis (G. Lester, 1971). the correlations noted lead to the conclusion that Neurospora utilizes regulatory mechanisms that have the ability to react to changes in the level of charging of tRNA species.