Polyamines and regulation of ornithine biosynthesis in Escherichia coli.

The growth rate of several polyamine-deficient mutants of Escherichia coli was very low in minimal medium and increased markedly upon the addition of putrescine, spermidine, arginine, citrulline, or argininosuccinic acid. The endogenous content of polyamines was not significantly altered by the supplementation of polyamine-starved cultures with arginine or its precursors. In contrast, these compounds as well as putrescine or spermidine caused a 40-fold reduction in intracellular ornithine levels when added to polyamine-depleted bacteria. In vivo experiments with radioactive glutamic acid as a precursor and in vitro assays of the related enzymes showed that the decrease in ornithine levels was due to the inhibition of its biosynthesis rather than to an increase in its conversion to citrulline or delta 1-pyrroline-5-carboxylic acid and proline. High endogenous concentrations of ornithine were toxic for the E. coli strains tested. The described results indicate that the stimulatory effect of putrescine and spermidine on the growth of certain polyamine-starved bacteria may be partially due to the control of ornithine biosynthesis by polyamines.     

Analysis of ven3 and ven6 reticulate mutants reveals the importance of arginine biosynthesis in Arabidopsis leaf development

Arabidopsis thaliana reticulate mutants exhibit differential pigmentation of the veinal and interveinal leaf regions, a visible phenotype that often indicates impaired mesophyll development. We performed a metabolomic analysis of one ven6 (venosa6) and three ven3 reticulate mutants that revealed altered levels of arginine precursors, namely increased ornithine and reduced citrulline levels. In addition, the mutants were more sensitive than the wild-type to exogenous ornithine, and leaf reticulation and mesophyll defects of these mutants were completely rescued by exogenous citrulline. Taken together, these results indicate that ven3 and ven6 mutants experience a blockage of the conversion of ornithine into citrulline in the arginine pathway. Consistent with the participation of VEN3 and VEN6 in the same pathway, the morphological phenotype of ven3 ven6 double mutants was synergistic. Map-based cloning showed that the VEN3 and VEN6 genes encode subunits of Arabidopsis carbamoyl phosphate synthetase (CPS), which is assumed to be required for the conversion of ornithine into citrulline in arginine biosynthesis. Heterologous expression of the Arabidopsis VEN3 and VEN6 genes in a CPS-deficient Escherichia coli strain fully restored bacterial growth in minimal medium, demonstrating the enzymatic activity of the VEN3 and VEN6 proteins, and indicating a conserved role for CPS in these distinct and distant species. Detailed study of the reticulate leaf phenotype in the ven3 and ven6 mutants revealed that mesophyll development is highly sensitive to impaired arginine biosynthesis.     

Arginine-specific carbamoyl phosphate metabolism in mitochondria of Neurospora crassa. Channeling and control by arginine

Citrulline is synthesized in mitochondria of Neurospora crassa from ornithine and carbamoyl phosphate. In mycelia grown in minimal medium, carbamoyl phosphate limits citrulline (and arginine) synthesis. Addition of arginine to such cultures reduces the availability of intramitochondrial ornithine, and ornithine then limits citrulline synthesis. We have found that for some time after addition of excess arginine, carbamoyl phosphate synthesis continued. Very little of this carbamoyl phosphate escaped the mitochondrion to be used in the pyrimidine pathway in the nucleus. Instead, mitochondrial carbamoyl phosphate accumulated over 40-fold and turned over rapidly. This was true in ornithine- or ornithine carbamoyltransferase-deficient mutants and in normal mycelia during feedback inhibition of ornithine synthesis. The data suggest that the rate of carbamoyl phosphate synthesis is dependent to a large extent upon the specific activity of the slowly and incompletely repressible synthetic enzyme, carbamoyl-phosphate synthetase A. In keeping with this conclusion, we found that when carbamoyl-phosphate synthetase A was repressed 2-10-fold by growth of mycelia in arginine, carbamoyl phosphate was still synthesized in excess of that used for residual citrulline synthesis. Again, only a small fraction of the excess carbamoyl phosphate could be accounted for by diversion to the pyrimidine pathway. The continued synthesis and turnover of carbamoyl phosphate in mitochondria of arginine-grown cells may allow rapid resumption of citrulline formation after external arginine disappears and no longer exerts negative control on ornithine biosynthesis.     

Acetylornithine transcarbamylase: a novel enzyme in arginine biosynthesis

Ornithine transcarbamylase is a highly conserved enzyme in arginine biosynthesis and the urea cycle. In Xanthomonas campestris, the protein annotated as ornithine transcarbamylase, and encoded by the argF gene, is unable to synthesize citrulline directly from ornithine. We cloned and overexpressed this X. campestris gene in Escherichia coli and show that it catalyzes the formation of N-acetyl-L-citrulline from N-acetyl-L-ornithine and carbamyl phosphate. We now designate this enzyme as an acetylornithine transcarbamylase. The K(m) values for N-acetylornithine and carbamyl phosphate were 1.05 mM and 0.01 mM, respectively. Additional putative transcarbamylases that might also be misannotated were found in the genomes of members of other xanthomonads, Cytophaga, and Bacteroidetes as well as in DNA sequences of bacteria from environmental isolates. It appears that these different paths for arginine biosynthesis arose very early in evolution and that the canonical ornithine transcarbamylase-dependent pathway became the prevalent form. A potent inhibitor, N(alpha)-acetyl-N(delta)-phosphonoacetyl-L-ornithine, was synthesized and showed a midpoint of inhibition at approximately 22 nM; this compound may prove to be a useful starting point for designing inhibitors specific to this novel family of transcarbamylases.     

Ornithine transcarbamylase from Neurospora crassa: purification and properties

Ornithine transcarbamylase catalyzes the synthesis of citrulline from carbamyl phosphate and ornithine. This enzyme is involved in the biosynthesis of arginine in many organisms and participates in the urea cycle of mammals. The biosynthetic ornithine transcarbamylase has been purified from the filamentous fungus, Neurospora crassa. It was found to be a homotrimer with an apparent subunit molecular weight of 37,000 and a native molecular weight of about 110,000. Its catalytic activity has a pH optimum of 9.5 and Km's of about 5 and 2.5 mM for the substrates, ornithine and carbamyl phosphate, respectively, at pH 9.5. The Km's and pH optimum are much higher than those of previously characterized enzymes from bacteria, other fungi, and mammals. These unusual kinetic properties may be of significance with regard to the regulation of ornithine transcarbamylase in this organism, especially in the avoidance of a futile ornithine cycle. Polyclonal antibodies were raised against the purified enzyme. These antibodies and antibody raised against purified rat liver ornithine transcarbamylase were used to examine the structural similarities of the enzyme from a number of organisms. Cross-reactivity was observed only for mitochondrial ornithine transcarbamylases of related organisms.     

Arginine catabolism in wine lactic acid bacteria: is it via the arginine deiminase pathway or the arginase-urease pathway?

The wine lactic acid bacteria Leuconostoc oenos OENO and Lactobacillus buchneri CUC-3 catabolize L-arginine to ornithine and ammonia as major end-products, with 1 mole of arginine converted into 2 moles of ammonia and 1 mole of ornithine. Some citrulline was also excreted into the medium. The excreted citrulline was reassimilated and catabolized by the lactobacillus strain, though not by the leuconostoc. Urea was not detected during arginine degradation. The activities of all three enzymes of the arginine deiminase pathway (arginine deiminase, ornithine transcarbamylase and carbamate kinase) increased significantly over time in the presence of arginine. On the other hand, arginase and urease activities were undetectable in cell extracts of cultures grown in the presence of arginine. The results show that the arginine deiminase pathway, and not the arginase-urease pathway, is the route for arginine degradation in wine lactic acid bacteria.     

Catabolism of arginine, citrulline and ornithine by Pseudomonas and related bacteria

The distribution of the arginine succinyltransferase pathway was examined in representative strains of Pseudomonas and related bacteria able to use arginine as the sole carbon and nitrogen source for growth. The arginine succinyltransferase pathway was induced in arginine-grown cells. The accumulation of succinylornithine following in vivo inhibition of succinylornithine transaminase activity by aminooxyacetic acid showed that this pathway is responsible for the dissimilation of the carbon skeleton of arginine. Catabolism of citrulline as a carbon source was restricted to relatively few of the organisms tested. In P. putida, P. cepacia and P. indigofera, ornithine was the main product of citrulline degradation. In most strains which possessed the arginine succinyltransferase pathway, the first step of ornithine utilization as a carbon source was the conversion of ornithine into succinylornithine through an ornithine succinyltransferase. However P. cepacia and P. putida used ornithine by a pathway which proceeded via proline as an intermediate and involved an ornithine cyclase activity.     

Biochemical and genetic studies with arginine and proline auxotrophs of Neisseria gonorrhoeae

The prevalence of specific arginine biosynthesis gene defects was studied for 319 arginine-requiring clinical isolates of Neisseria gonorrhoeae by using the ability of the strains to utilize intermediates of arginine biosynthesis. Only 11% of the uracil-requiring strains defective in the carbamylation of ornithine to yield citrulline had a defective carbamoylphosphate synthetase gene (carAB). Strains defective in carAB were of auxotype CUH. The other strains (89%) having a dual requirement for citrulline and uracil, which were mostly of auxotype PCU, were defective in the ornithine transcarbamoylase gene (argF). Over 90% of the strains were defective either in argJ (174 strains) or in argF (126 strains). Three argininosuccinate-requiring strains (i.e., defective in argG) of auxotype PAU were identified. Some of the arginine auxotrophs of N. gonorrhoeae defective in carAB, argJ, argF, or argG were complemented by genetic transformation with DNA from recombinant bacteriophages carrying characterized gonococcal arginine biosynthesis genes. Gene defects in proA (five strains) and in proB (six strains) were identified by gonococcal transformation assays with recombinant bacteriophages or plasmids carrying proline biosynthesis genes from N. gonorrhoeae. None of the 11 proline-requiring strains tested was defective in proC.     

Control of the ornithine cycle in Neurospora crassa by the mitochondrial membrane.

In Neurospora crassa, the mitochondrial membrane separates ornithine used in arginine biosynthesis from ornithine used in the arginine degradative pathway in the cytosol. Ornithine easily exchanges across the mitochondrial membrane under conditions appropriate for synthesis of the immediate biosynthetic product, citrulline. Neither of the two mitochondrial enzymes required for the ornithine-to-citrulline conversion is feedback inhibitable in vitro. Nevertheless, when arginine is added to cells and cytosolic ornithine increases as arginine degradation begins, the rate of citrulline synthesis drops immediately to about 20% of normal (B. J. Bowman and R. H. Davis, Bacteriol. 130:285-291, 1977). We have studied this phenomenon in citrulline-accumulating strains carrying the arg-1 mutation. Citrulline accumulation is blocked when arginine is added to an arg-1 strain but not to an arg-1 strain carrying a mutation conferring insensitivity of intramitochondrial ornithine synthesis to arginine. Thus, ornithine is evidently unable to enter mitochondria in normal (feedback-sensitive) cells. Other experiments show that cytosolic ornithine enters mitochondria readily except when arginine or other basic amino acids are present at high levels in the cells. We conclude that in N. crassa, the mitochondrial membrane has evolved as a secondary site of feedback inhibition in arginine synthesis and that this prevents a wasteful cycling of catabolic ornithine back through the anabolic pathway. This is compared to the quite different mechanism by which the yeast Saccharomyces cerevisiae prevents a futile ornithine cycle.     

Utilization of ornithine and arginine as specific precursors of clavulanic acid

Ornithine and arginine (5 to 20 mM), but not glutamic acid or proline, exerted a concentration-dependent stimulatory effect on the biosynthesis of clavulanic acid in both resting-cell cultures and long-term fermentations of Streptomyces clavuligerus. Ornithine strongly inhibited cephamycin biosynthesis in the same strain. [1-14C]-, [5-14C]-, or [U-14 C] ornithine was efficiently incorporated into clavulanic acid, whereas the incorporation of uniformly labeled glutamic acid was very poor. [U-14C] citrulline were not incorporated at all. Mutant nca-1, a strain that is blocked in clavulanic acid biosynthesis, did not incorporate arginine into clavulanic acid. S. clavuligerus showed arginase activity, converting arginine into ornithine, but not amidinotransferase activity. Both arginase activity and clavulanic acid formation were enhanced simultaneously by supplementing the production medium with 10 mM arginine.     

Arginine metabolism in Halobacterium salinarium, an obligately halophilic bacterium

Dundas, Ian E. D. (University of Illinois, Urbana), and H. Orin Halvorson. Arginine metabolism in Halobacterium salinarium, an obligately halophilic bacterium. J. Bacteriol. 91:113-119. 1966.-Arginine was shown to be essential for growth of Halobacterium salinarium strain 1 in a chemically defined medium. Citrulline was the only compound which could substitute for arginine without affecting growth. Resting cells of H. salinarium converted arginine to citrulline and citrulline to ornithine. Cells grown in an arginine-free medium with C(14)-ureido-labeled citrulline incorporated the isotope mainly into the arginine of their proteins. The enzymes arginine desimidase and ornithine transcarbamylase were found and studied in cell-free extracts of H. salinarium. Experiments indicated that arginine was degraded in H. salinarium by arginine desimidase to citrulline, and that citrulline was further degraded by ornithine transcarbamylase to carbamyl phosphate and ornithine. Synthesis of arginine from citrulline seems to occur via the formation of argininosuccinic acid.     

Utilization of ornithine and arginine as specific precursors of clavulanic acid.

Ornithine and arginine (5 to 20 mM), but not glutamic acid or proline, exerted a concentration-dependent stimulatory effect on the biosynthesis of clavulanic acid in both resting-cell cultures and long-term fermentations of Streptomyces clavuligerus. Ornithine strongly inhibited cephamycin biosynthesis in the same strain. [1-14C]-, [5-14C]-, or [U-14 C] ornithine was efficiently incorporated into clavulanic acid, whereas the incorporation of uniformly labeled glutamic acid was very poor. [U-14C] citrulline were not incorporated at all. Mutant nca-1, a strain that is blocked in clavulanic acid biosynthesis, did not incorporate arginine into clavulanic acid. S. clavuligerus showed arginase activity, converting arginine into ornithine, but not amidinotransferase activity. Both arginase activity and clavulanic acid formation were enhanced simultaneously by supplementing the production medium with 10 mM arginine.     

Isolation and characterization of Pseudomonas putida mutants affected in arginine, ornithine and citrulline catabolism: function of the arginine oxidase and arginine succinyltransferase pathways.

Pseudomonas putida mutants impaired in the utilization of arginine are affected in either the arginine succinyltransferase pathway, the arginine oxidase route, or both. However, mutants affected in one of the pathways still grow on arginine as sole carbon source. Analysis of the products excreted by both wild-type and mutant strains suggests that arginine is mainly channelled by the oxidase route. Proline non-utilizing mutants are also affected in ornithine utilization, confirming the role of proline as an intermediate in ornithine catabolism. Mutants affected in ornithine cyclodeaminase activity still grow on proline and become unable to use ornithine. Both proline non-utilizing mutants and ornithine-cyclodeaminase-minus mutants are unable to use citrulline. These results, together with induction of ornithine cyclodeaminase when wild-type P. putida is grown on citrulline, indicate that utilization of citrulline as a carbon source proceeds via proline with ornithine as an intermediate. Thus in P. putida, the aerobic catabolism of arginine on the one hand and citrulline and ornithine on the other proceed by quite different metabolic segments.     

Channeling of extramitochondrial ornithine to matrix ornithine transcarbamylase

In the presence of citrulline synthesis, we made the following observations. External ornithine is channeled between its transporter and ornithine transcarbamylase; mitochondria preloaded with cold ornithine, then incubated with [3H]ornithine, produced citrulline of the same specific radioactivity as that of external ornithine, while matrix ornithine remained essentially unlabeled. The channeling of ornithine suggests that some soluble enzymes are organized within the mitochondrial matrix. The rate of ornithine transport can be greater than 80 nmol/min/mg. At rates of carbamyl phosphate synthesis of 10-50 nmol/min/mg, the rate of citrulline synthesis is controlled by external ornithine in the range 0.03-0.2 mM; at greater than or equal to 0.2 mM ornithine, transport is not limiting for citrulline synthesis. At external ornithine concentrations less than or equal to 1 mM, i.e. within the physiological range, this amino acid is undetectable in the matrix. Given the rates of citrulline and urea synthesis which occur in vivo and the concentrations of ornithine present in the liver, our findings indicate that ornithine may contribute to the physiological regulation of urea synthesis. Preliminary reports of parts of this work have been published (Raijman, L., Cheung, C-W., and Cohen, N. S. (1984) Fed. Proc. 43, 1831; Cohen, N. S., Cheung, C-W., and Raijman, L. (1986) Fed. Proc. 45, 2677).     

Kinetic mechanism of antiports catalyzed by reconstituted ornithine/citrulline carrier from rat liver mitochondria

The transport mechanism of the reconstituted ornithine/citrulline carrier purified from rat liver mitochondria was investigated kinetically. A complete set of half-saturation constants (K(m)) was established for ornithine, citrulline and H(+) on both the external and internal side of the liposomal membrane. The internal affinity for ornithine was much lower than that determined on the external surface. The exclusive presence of a single transport affinity for ornithine on each side of the membrane indicated a unidirectional insertion of the ornithine/citrulline carrier into liposomes, probably right-side-out with respect to mitochondria. Two-reactant initial velocity studies of the homologous (ornithine/ornithine) and heterologous (ornithine/citrulline) exchange reactions resulted in a kinetic pattern which is characteristic of a simultaneous antiport mechanism. This type of mechanism implies that the carrier forms a ternary complex with the substrates before the transport reaction occurs. A quantitative analysis of substrate interaction revealed that rapid-equilibrium random conditions were fulfilled, characterized by a fast and independent binding of internal and external substrates.     

Effect of ornithine concentration on citrulline synthesis in mouse liver mitochondria

The rate of citrulline synthesis in mitochondria from OTC-deficient spf-ash mice (15% of the normal activity) was found to be the same as that in mitochondria from control mice. The amount of NAG in their mitochondria varied markedly according to whether they had received a high- or low-protein diet, and the rate of citrulline synthesis was found to be affected by the level of NAG. These results indicate that the CPS stage, not the OTC stage, is rate-limiting in the citrulline synthesis process. Kinetic studies on the effect of ornithine concentration on citrulline synthesis in mitochondria showed that the Km for ornithine was very low in the mitochondria from the mice given a low-protein diet. Kinetic studies on the effect of ornithine concentration on mouse OTC at various concentrations of carbamylphosphate showed that OTC has a ping-pong mechanism, i.e., that the Km for ornithine and Vmax decrease with the reduction in carbamylphosphate concentration. This may explain the low Km value observed in citrulline synthesis in the mitochondria. We conclude that in mitochondrial citrulline synthesis the rate of carbamylphosphate synthesis by CPS in the presence of NAG plays a key role in determining the rate of citrulline synthesis and ornithine dependency.     

A possible rate limiting factor in urea synthesis by isolated hepatocytes: the transport of ornithine into hepatocytes and mitochondria

The uptake of ornithine by isolated hepatocytes and by the particulate fraction of these cells was measured under various conditions of urea synthesis. Under conditions of maximum urea synthesis, i.e. in the presence of glucose, ornithine, ammonium chloride and oleate, the cytosolic concentration and the mitochondrial concentration of ornithine was extremely low, while citrulline accumulated in the cytosol. The data indicate that the rate of citrulline synthesis is limited by the availability of mitochondrial ornithine.     

Polyamine Metabolism in Acanthamoeba: Polyamine Content and Synthesis of Ornithine,Putrescine, and Diaminopropane1

Five polyamines which could be separated by high performance liquid chromatography were found in Acanthamoeba castellanii (strain Neff). These included in order of decreasing abundance: 1,3-diaminopropane, spermidine, spermine, norspermidine, and putrescine. Only diaminopropane and norspermidine had been found previously. Spermine was present in cultures grown in broth, but not in defined medium. Radioactive substrates were used to establish that putrescine was synthesized by decarboxylation of ornithine, ornithine was synthesized from arginine or citrulline, and diaminopropane was synthesized from spermidine. The presence of ornithine decarboxylase (EC 4.1.1.17), arginase (EC 3.5.3.1), and urease (EC 3.5.1.5) and the absence of arginine decarboxylase (EC 4.1.1.19) were established. A scheme for polyamine biosynthesis in A. castellanii is proposed.     

Anabolic ornithine carbamoyltransferase of Escherichia coli and catabolic ornithine carbamoyltransferase of Pseudomonas putida. Steady-state kinetic analysis.

The anabolic and catabolic ornithine carbamoyltransferases of Pseudomonas putida display an undirectional catalytic specialization: in citrulline synthesis for the anabolic enzyme, in citrulline phosphorolysis for the catabolic one. The irreversibility of the anabolic enzyme in vitro has been previously explained by its kinetic properties, whereas the irreversibility of the catabolic transferase in vivo was shown to be due to its allosteric behaviour. In this work a steady-state kinetic analysis has been carried out on the catabolic ornithine carbamoyltransferase at pH 6.8 in the presence of the allosteric activator, phosphate. The kinetic mechanism of Escherichia coli ornithine carbamoyltransferase serving as a reference was also determined. For the E. coli enzyme in the reverse direction, the initial velocity patterns converging on the abscissa were obtained with either citrulline or arsenate as variable substrate. The inhibition by the product ornithine was linear competitive with respect to citrulline and linear non-competitive with respect to arsenate. In the forward direction phosphate and its analogs induce an inhibition by ornithine which is partial and competitive with respect to carbamoylphosphate. Together with the results of thermo-inactivation studies in the presence of each reactant, this observation suggests a random kinetic mechanism, but with most of the reaction flux following the path where carbamoylphosphate adds before ornithine, when substrates are present at Km levels. The allosteric catabolic ornithine carbamoyltransferase of Pseudomonas displays qualitatively the same pattern as the E. coli enzyme.     

Chemical modification of the mitochondrial ornithine/citrulline carrier by SH reagents: effects on the transport activity and transition from carrier to pore-like function

The transport activity of the purified and reconstituted ornithine/citrulline carrier from rat liver mitochondria was correlated to modification of its sulfhydryl groups by various reagents. Both the ornithine/ornithine (antiport) and the ornithine/H(+) (unidirectional) transport modes catalysed by the ornithine/citrulline carrier were inhibited by methanethiosulfonates, mercurial reagents, N-ethylmaleimide (NEM) and 5,5'-dithiobis(2-nitrobenzoate) (DTNB). The treatment of the ornithine/citrulline carrier with mercurial reagents, at concentrations above 5 microM, caused the induction of an additional (pore-like) transport mode, characterized by loss of substrate specificity and a transport activity higher than that of the unmodified carrier. The S-S forming reagent Cu(2+)-phenanthroline inhibited the transport catalysed by the carrier, indicating the presence of close sulfhydryl groups. The effect of consecutive addition of the various reagents revealed a peculiar aspect of the ornithine/citrulline carrier, i.e. the presence of three distinct populations of sulfhydryl groups. The first was responsible for the inhibition of the physiological transport modes by methanethiosulfonates, NEM and DTNB and low concentrations (<5 microM) of mercurials; the second population was responsible for the transition to the pore-like activity induced by higher concentrations (>5 microM) of mercurials; the third population was involved in S-S bridge formation.