Orotic acid biosynthesis in rat liver: studies on the source of carbamoylphosphate.

Measurements of the incorporation of radiolabeled precursors into orotic acid in tissue slices and minces provided evidence of the participation of the intramitochondrial carbamoylphosphate synthetase (CPSase-I) in the de novo biosynthesis of pyrimidines in rat liver. Ammonia, the only nitrogen source utilized by CPSase-I, markedly stimulated the incorporation of NaH¹⁴CO₃ into orotic acid in liver slices, and ornithine, which enhances the intramitochondrial consumption of carbamoylphosphate (CP) in citrulline synthesis, antagonized the stimulation by ammonia. Sensitivity of the incorporation of NaH¹⁴CO₃ into orotic acid to stimulation by ammonia was found to increase with age in concert with the emergence of CPSase-I in the liver during late fetal and neonatal development. Tissues lacking in CPSase-I activity did not exhibit the responses to ammonia and ornithine observed with the adult rat liver. While the occurrence of CPSase-I in the liver contributes extensively toward the exceptionally high capacity of that tissue for the de novo biosynthesis of orotic acid, our results also indicate that the physiological rate of orotic acid biosynthesis in rat liver is approximately one-third of capacity; the incorporation of NaH¹⁴CO₃ into orotic acid averaged 488 nmol/g of tissue in 3 h in the presence of toxic levels of ammonia, but declined to 160 nmol/g of tissue in 3 h when physiological levels of both ammonia and ornithine were provided. However, the rate of orotic acid biosynthesis observed with physiological concentrations of ammonia and ornithine could be reduced further, to about one-quarter of the physiological rate, by providing additional ornithine; thus, physiological levels of ornithine do not prevent the escape of intramitochondrial CP into the cytoplasm. Finally, over 80% of the incorporation of NaH¹⁴CO₃ into orotic acid at physiological levels of ammonia and ornithine was found to be ammonia dependent, and all but a small fraction of the ammonia-dependent incorporation could be blocked by providing ornithine in amounts in excess of physiological. These results indicate that CPSase-I is the major source of CP in the biosynthesis of hepatic pyrimidines under normal (physiological) conditions as well as in ammonia toxicity.     

Biosynthesis and scavenging of pyrimidines by pathogenic mycobacteria

Mycobacterium microti incorporated a wide range of exogenously supplied pyrimidines into its nucleic acids. M. avium incorporated a relatively narrow range of pyrimidines but both M. avium and M. microti when recovered after growth in vivo incorporated a slightly wider range of pyrimidines than the same strains grown in vitro. M. microti and M. leprae could not take up uridine nucleotides directly but could utilize the pyrimidines by hydrolysing them to uridine and then taking up the uridine. Pyrimidine biosynthesis, judged by the ability to incorporate carbon from CO2 or aspartate into pyrimidines was readily detected in non-growing suspensions of M. microti and M. avium harvested from Dubos medium, which does not contain pyrimidines. The biosynthetic activity was diminished in mycobacteria grown in vivo when there is likely to be a source of pyrimidines which they might use. Relative activities for pyrimidine biosynthesis de novo in M. microti were 100 for cells isolated from Dubos medium, 6 for cells isolated from Dubos medium containing the pyrimidine cytidine and 11 from cells recovered after growth in mice. In contrast, relative activities for a scavenging reaction, uracil incorporation, were 100, 71 and 59, respectively. Three key enzymes in the pathway of pyrimidine biosynthesis de novo were detected in M. microti and M. avium. Two, dihydroorotate synthase and orotate phosphoribosyltransferase appeared to be constitutive in M. microti and M. avium. Aspartate transcarbamoylase activity was higher in these mycobacteria grown in vivo than in Dubos medium but it was repressed in M. microti or M. avium grown in Dubos medium in the presence of 50 microM-pyrimidine. Aspartate transcarbamoylase was strongly inhibited by the feedback inhibitors ATP, CTP and UTP. Enzymes for scavenging pyrimidines were detected at low specific activities in all mycobacteria studied. Activities of phosphoribosyltransferases, enzymes that convert bases directly to nucleotides, were not related to the ability of intact mycobacteria to take up pyrimidine bases while activities of pyrimidine nucleoside kinases were generally related to the ability of intact mycobacteria to take up nucleosides. Phosphoribosyltransferase activity for uracil, cytosine, orotic acid and--in organisms grown in Dubos medium with 50 microM-uridine-thymine, as well as kinases for uridine, deoxyuridine, cytidine and thymidine were detected in M. microti. However, M. avium only contained uracil and orotate phosphoribosyltransferase, uridine, cytidine and thymidine kinase, and additionally deoxyuridine kinase when grown axenically with 50 microM-uracil, reflecting its more limited abilities in pyrimidine scavenging.     

Insulin regulation of RNA synthesis

During periods of nitrogen exportation from the cell, mitochondrial carbamoyl phosphate is synthesized, thus initiating the urea cycle. During times of nitrogen conservation by the liver cell, carbamoyl phosphate is synthesized in the cytosol of the cell, whereupon the de novo pyrimidine synthesis pathway is initiated. The de novo pathway provides pyrimidines for increased ribonucleic acid synthesis. Formerly, it was believed that these two pathways functioned irrespective of one another. However, recent experimental evidence indicates that, when excess ammonia is present, mitochondrial carbamoyl phosphate passes from the mitochondria into the cell cytosol, where it is metabolized by the de novo pyrimidine synthesis pathway. When ornithine and excess ammonia are both present, mitochondrial carbamoyl phosphate no longer passes from the mitochondria into the cytosol to be metabolized by the de nova pathway. Thus the metabolic fate of mitochondrial carbamoyl phosphate, and that of excess nitrogen, is determined by the presence or absence of ornithine. In turn, this key molecule is the substrate for the cytoplasmic enzyme ornithine decarboxylase. When ornithine decarboxylase is stimulated by insulin, ornithine is metabolized to putrescine. The activated ornithine decarboxylase combines with ribonucleic acid polymerase, activating the later enzyme. When ornithine is acted upon by ornithine decarboxylase, it is no longer available for the perpetuation of the urea cycle and mitochondrial carbamoyl phosphate levels rise until the carbamoyl phosphate passes into the cytosol to be metabolized by the de novo pathway. Increased amounts of pyrimidines are available for the activated ribonucleic acid polymerase. Therefore insulin, through its stimulation of ornithine decarboxylase, achieves cellular nitrogen retention by regulating nitrogen incorporation into newly synthesized ribonucleic acid.     

Pyrimidine Biosynthesis Is Not an Essential Function for Trypanosoma brucei Bloodstream Forms

Background

African trypanosomes are capable of both pyrimidine biosynthesis and salvage of preformed pyrimidines from the host, but it is unknown whether either process is essential to the parasite.

Methodology/Principal Findings

Pyrimidine requirements for growth were investigated using strictly pyrimidine-free media, with or without single added pyrimidine sources. Growth rates of wild-type bloodstream form Trypanosoma brucei brucei were unchanged in pyrimidine-free medium. The essentiality of the de novo pyrimidine biosynthesis pathway was studied by knocking out the PYR6-5 locus that produces a fusion product of orotate phosphoribosyltransferase (OPRT) and Orotidine Monophosphate Decarboxylase (OMPDCase). The pyrimidine auxotroph was dependent on a suitable extracellular pyrimidine source. Pyrimidine starvation was rapidly lethal and non-reversible, causing incomplete DNA content in new cells. The phenotype could be rescued by addition of uracil; supplementation with uridine, 2′deoxyuridine, and cytidine allowed a diminished growth rate and density. PYR6-5⁻/⁻ trypanosomes were more sensitive to pyrimidine antimetabolites and displayed increased uracil transport rates and uridine phosphorylase activity. Pyrimidine auxotrophs were able to infect mice although the infection developed much more slowly than infection with the parental, prototrophic trypanosome line.

Conclusions/Significance

Pyrimidine salvage was not an essential function for bloodstream T. b. brucei. However, trypanosomes lacking de novo pyrimidine biosynthesis are completely dependent on an extracellular pyrimidine source, strongly preferring uracil, and display reduced infectivity. As T. brucei are able to salvage sufficient pyrimidines from the host environment, the pyrimidine biosynthesis pathway is not a viable drug target, although any interruption of pyrimidine supply was lethal.     

Pyrimidine synthesis in Burkholderia cepacia ATCC 25416

K. LI AND T.P. WEST. 1995. Pyrimidine synthesis in the food spoilage agent Burkholderia cepacia ATCC 25416 was investigated. The five de novo pathway enzymes of pyrimidine biosynthesis were found to be active in B. cepacia ATCC 25416 and growth of this strain on uracil had an effect on the de novo enzyme activities. The in vitro regulation of aspartate transcarbamoylase activity in B. cepacia ATCC 25416 was studied and its activity was inhibited by PP_i, ATP, GTP, CTP and UTP. The enzymes cytidine deaminase, uridine phosphorylase and cytosine deaminase were found to be active in the salvage of pyrimidines in ATCC 25416. Overall, de novo pyrimidine synthesis in B. cepacia ATCC 25416 was regulated at the level of enzyme activity and its pyrimidine salvage enzymes differed from those found in B. cepacia ATCC 17759.     

Pyrimidine biosynthetic pathway of Pseudomonas fluorescens

Pyrimidine biosynthesis in Pseudomonas fluorescens strain A126 was investigated. In this study, de novo pyrimidine biosynthetic pathway mutant strains were isolated using both conventional mutagenesis and transposon mutagenesis. The resulting mutant strains were deficient for either aspartate transcarbamoylase, dihydroorotase or orotate phosphoribosyltransferase activity. Uracil, uridine or cytosine could support the growth of every mutant strain selected. In addition, the aspartate transcarbamoylase mutant strains could utilize orotic acid to sustain their growth while the orotidine-5'-monophosphate decarboxylase mutant strains grew slowly upon uridine 5'-monophosphate. The wild-type strain and the mutant strains were used to study possible regulation of de novo pyrimidine biosynthesis in P. fluorescens. Dihydroorotase specific activity more than doubled after the wild-type cells were grown in orotic acid relative to unsupplemented minimal-medium-grown cells. Starving the mutant strains of pyrimidines also influenced the levels of several de novo pyrimidine biosynthetic pathway enzyme activities.     

Aspartate Carbamyltransferase : Site of End-Product Inhibition of the Orotate Pathway in Intact Cells of Cucurbita pepo

Lovatt et al. (1979 Plant Physiol 64: 562-569) have previously demonstrated that end-product inhibition functions as a mechanism regulating the activity of the orotic acid pathway in intact cells of roots excised from 2-day-old squash plants (Cucurbita pepo L. cv Early Prolific Straightneck). Uridine (0.5 millimolar final concentration) or one of its metabolites inhibited the incorporation of NaH¹⁴CO₃, but not [¹⁴C]carbamylaspartate or [¹⁴C]orotic acid, into uridine nucleotides (ΣUMP). Thus, regulation of de novo pyrimidine biosynthesis was demonstrated to occur at one or both of the first two reactions of the orotic acid pathway, those catalyzed by carbamylphosphate synthetase (CPSase) and aspartate carbamyltransferase (ACTase). The results of the present study provide evidence that ACTase alone is the site of feedback control by added uridine or one of its metabolites. Evidence demonstrating regulation of the orotic acid pathway by end-product inhibition at ACTase, but not at CPSase, includes the following observations: (a) addition of uridine (0.5 millimolar final concentration) inhibited the incorporation of NaH¹⁴CO₃ into ΣUMP by 80% but did not inhibit the incorporation of NaH¹⁴CO₃ into arginine; (b) inhibition of the orotate pathway by added uridine was not reversed by supplying exogenous ornithine (5 millimolar final concentration), while the incorporation of NaH¹⁴CO₃ into arginine was stimulated more than 15-fold when both uridine and ornithine were added; (c) incorporation of NaH¹⁴CO₃ into arginine increased, with or without added ornithine when the de novo pyrimidine pathway was inhibited by added uridine; and (d) in assays employing cell-free extracts prepared from 2-day-old squash roots, the activity of ACTase, but not CPSase, was inhibited by added pyrimidine nucleotides.     

Enzymes of Pyrimidine Metabolism in Mycoplasma mycoides subsp. mycoides

The major pathways of ribonucleotide biosynthesis in Mycoplasma mycoides subsp. mycoides have been proposed from studies on its use of radioactive purines and pyrimidines. To interpret more fully the observed pattern of pyrimidine usage, cell extracts of this organism have been assayed for several enzymes associated with the salvage synthesis of pyrimidine nucleotides. M. mycoides possessed uracil phosphoribosyltransferase, uridine phosphorylase, uridine (cytidine) kinase, uridine 5'-monophosphate kinase, and cytidine 5'-triphosphate synthetase. No activity for phosphorolysis of cytidine was detected, and no in vitro conditions were found to give measurable deamination of cytidine. Of the two potential pathways for incorporation of uridine, our data suggest that this precursor would largely undergo initial phosphorolysis to uracil and ribose-1-phosphate. Conversely, cytidine is phosphorylated directly to cytidine 5'-monophosphate in its major utilization, although conversion of cytidine to uracil, uridine, and uridine nucleotide has been observed in vivo, at least when uracil is provided in the growth medium. Measurements of intracellular nucleotide contents and their changes on additions of pyrimidine precursors have allowed suggestions as to the operation of regulatory mechanisms on pyrimidine nucleotide biosynthesis in M. mycoides in vivo. With uracil alone or uracil plus uridine as precursors of pyrimidine ribonucleotides, the regulation of uracil phosphoribosyltransferase and cytidine 5'-triphosphate synthetase is probably most important in determining the rate of pyrimidine nucleotide synthesis. When cytidine supplements uracil in the growth medium, control of cytidine kinase activity would also be important in this regard.     

Pyrimidine biosynthesis and its regulation in the estrogen-stimulated chick oviduct.

Studies on the incorporation of radio-labeled precursors into orotic acid and the pyrimidine nucleotides of RNA have established the occurrence of the orotate pathway for the de novo biosynthesis of pyrimidines in the chick oviduct. Measurements of the rate of incorporation of precursors into orotic acid in minces of oviduct revealed the activity of the orotate pathway to be accelerated in response to estrogen-stimulated nucleic acid synthesis and tissue growth. These data indicate that extrahepatic tissues of avian species meet their requirements for pyrimidine nucleotides through de novo synthesis rather than depend upon the liver or other exogenous sources for a supply of preformed pyrimidines. An examination of the influence of pyrimidine and purine nucleosides on the incorporation of radio-labeled precursors into orotic acid yielded evidence that pyrimidine biosynthesis in the chick is quite sensitive to inhibition by both purines and pyrimidines; the data indicate the reaction catalyzed by carbamoylphosphate synthetase to be the site of inhibition in both cases.     

Orotate (orotic acid): An essential and versatile molecule

ABSTRACT

Orotate (OA) is well-known as a precursor in biosynthesis of pyrimidines; in mammals it is released from the mitochondrial dihydroorotate dehydrogenase (DHODH) for conversion to UMP by the cytoplasmic UMP synthase enzyme. OA is also a normal part of the diet, being found in milk and dairy products, and it is converted to uridine for use in the pyrimidine salvage pathway predominantly in liver, kidney and erythrocytes. Early research into nutrition identified orotate as “vitamin B13,” and its use as a complex with organic cations or metal ions was promulgated in body-building, and in assisting therapies of metabolic syndromes. It has recently been established that the amelioration of gout by dairy products arises from the competition of orotate and urate at the hURAT1 transporter. The orotic aciduria that arises in children with defective UMP synthase can be rescued by oral uridine therapy, since UMP is the end-product and also a feedback inhibitor of the de novo pathway. In contrast, Miller (dysmorphology) syndrome is connected with defects in DHODH, and hence in the supply of OA, and cannot be helped by uridine. Other models of dysmorphisms are connected with enzymes early in the pyrimidine de novo pathway. We conclude that the OA molecule is itself required for the regulation of genes that are important in the development of cells, tissues and organisms.     

Regulation of pyrimidine biosynthesis by purine and pyrimidine nucleosides in slices of rat tissue

Evidence of the primary sites for the regulation of de novo pyrimidine biosynthesis by purine and pyrimidine nucleosides has been obtained in tissue slices through measurements of the incorporation of radiolabeled precursors into an intermediate and end product of the pathway. Both purine and pyrimidine nucleosides inhibited the incorporation of [¹⁴C]-NaHCO₃ into orotic acid and uridine nucleotides, and the inhibition was found to be reversible upon transferring the tissue slices to a medium lacking nucleoside. The ammonia-stimulated incorporation of [¹⁴C]NaHCO₃ into orotic acid, which is unique to liver slices, was sensitive to inhibition by pyrimidine nucleosides at physiological levels of ammonia, but this regulatory mechanism was lost at toxic levels of ammonia. Adenosine, but not uridine, was found to have the additional effects of inhibiting the conversion of [¹⁴C]orotic acid to UMP and depleting the tissue slices of PRPP. Since PRPP is required as an activator of the first enzyme of the de novo pathway, CPSase II, and a substrate of the fifth enzyme, OPRTase, these results indicate that adenosine inhibits the incorporation of [¹⁴C]NaHCO₃ into orotic acid and the incorporation of [¹⁴C]orotic acid into UMP by depriving CPSase II and OPRTase, respectively, of PRPP. Uridine or its metabolites, on the other hand, appear to control the de novo biosynthesis of pyrimidines through end product inhibition of an early enzyme, most likely CPSase II. We found no evidence of end product inhibition of the conversion of orotic acid to UMP in tissue slices.     

Pyrimidine biosynthesis in Pseudomonas oleovorans

AIMS: To investigate the regulation of de novo pyrimidine biosynthesis in the polyhydroxyalkanoate-producing bacterium Pseudomonas oleovorans at the level of enzyme synthesis and at the level of aspartate transcarbamoylase activity. METHODS AND RESULTS: The effect of pyrimidine supplementation on the pyrimidine biosynthetic pathway enzyme activities was analysed relative to carbon source. Two uracil auxotrophs of P. oleovorans were isolated that were deficient for aspartate transcarbamoylase or dihydroorotase activity. Pyrimidine limitation of these auxotrophs increased the de novo pathway activities to varying degrees depending on the pathway mutation and the carbon source utilized. At the level of aspartate transcarbamoylase activity, pyrophosphate and uridine ribonucleotides were found to be strongly inhibitory of the Ps. oleovorans enzyme. CONCLUSIONS: Pyrimidine biosynthesis is regulated in Ps. oleovorans. Taxonomically, the regulation of the pyrimidine biosynthetic pathway appeared dissimilar from previously studied Pseudomonas species. SIGNIFICANCE AND IMPACT OF THE STUDY: New insights regarding the regulation of nucleic acid metabolism are provided that could prove significant during the genetic manipulation of Ps. oleovorans to increase the synthesis of polyhydroxyalkanoates.     

Pyrimidine nucleotide synthesis in Pseudomonas citronellolis

Pyrimidine biosynthesis was active in Pseudomonas citronellolis ATCC 13674 and appeared to be regulated by pyrimidines. When wild-type cells were grown on succinate in the presence of uracil, the de novo enzyme activities were depressed while only four enzyme activities were depressed in the glucose-grown cells. On either carbon source, orotic acid-grown cells had diminished aspartate transcarbamoylase, dihydroorotase or OMP decarboxylase activity. Pyrimidine limitation of glucose-grown pyrimidine auxotrophic cells resulted in de novo enzyme activities, except for transcarbamoyolase activity, that were elevated by more than 5-fold compared to their activities in uracil-grown cells. Since pyrimidine limitation of succinate-grown mutant cells produced less enzyme derepression, catabolite repression appeared to be a factor. At the level of enzyme activity, aspartate transcarbamoylase activity in P. citronellolis was strongly inhibited by all effectors tested. Compared to the regulation of pyrimidine biosynthesis in taxonomically-related species, pyrimidine biosynthesis in P. citronellolis appeared more highly regulated.     

Analysis of Pyrimidine Synthesis De Novo Intermediates in Urine During Crisis of a Patient with Ornithine Transcarbamylase Deficiency

Analysis of pyrimidine synthesis de novo intermediates and pyrimidine degradation products in urine samples from a decompensated patient with an ornithine transcarbamylase deficiency showed a strikingly aberrant metabolic profile. Strongly elevated levels of N-carbamyl-aspartate, orotate and uracil were present whereas the concentration of uridine was only marginally increased. The level of pyrimidine excretion appeared to be independent of the ammonia levels in blood, which were only mildly increased.     

Analysis of pyrimidine synthesis de novo intermediates in urine during crisis of a patient with ornithine transcarbamylase deficiency

Analysis of pyrimidine synthesis de novo intermediates and pyrimidine degradation products in urine samples from a decompensated patient with an ornithine transcarbamylase deficiency showed a strikingly aberrant metabolic profile. Strongly elevated levels of N-carbamyl-aspartate, orotate and uracil were present whereas the concentration of uridine was only marginally increased. The level of pyrimidine excretion appeared to be independent of the ammonia levels in blood, which were only mildly increased.     

Purine and Pyrimidine Synthesis by the Avian Malaria Parasite,Plasmodium lophurae*

SYNOPSIS. Purine and pyrimidine biosynthesis in the avian malaria parasite Plasmodium lophurae and its host cell, the duck erythrocyte, were investigated in vitro. Pyrimidine synthesis, as measured by the incorporation of C¹⁴-NaHCO₃ into cytosine, uracil and thymine was slight in uninfected duck erythrocytes, whereas infected erythrocytes and erythrocyte-free parasites had high rates of incorporation of NaHCO₃ into these bases. In addition, orotidine-5′-monophosphate pyrophosphorylase and thymidylate synthetase, 2 enzymes of the pyrimidine biosynthetic pathway, were found in cell-free extracts of the plasmodia. Purine synthesis was measured by determining the extent of incorporation of C¹⁴-Na-formate into adenine and guanine. Uninfected and infected erythrocytes had similar rates of Na-formate incroporation into adenine. whereas free parasites incorporated little of this compound into adenine, or guanine. On the other hand, the incorporation of Na-formate into guanine was 54% higher in infected erythrocytes than in uninfected erythrocytes. It is suggested that P. lophurae synthesizes purines to a limited extent, and derives most of its purines from the host erythrocyte. The greater incorporation of Na-formate into guanine by infected cells, and its low incorporation into free parasites may be accounted for by parasite conversion of host cell adenine (in the form of ATP) into guanine. Pyrimidine biosynthesis in infected cells can be accounted for by de novo synthesis by the parasite itself.     

Pyrimidine metabolism by intracellular Chlamydia psittaci.

Pyrimidine metabolism was studied in the obligate intracellular bacterium Chlamydia psittaci AA Mp in the wild type and a variety of mutant host cell lines with well-defined mutations affecting pyrimidine metabolism. C. psittaci AA Mp cannot synthesize pyrimidines de novo, as assessed by its inability to incorporate aspartic acid into nucleic acid pyrimidines. In addition, the parasite cannot take UTP, CTP, or dCTP from the host cell, nor can it salvage exogenously supplied uridine, cytidine, or deoxycytidine. The primary source of pyrimidine nucleotides is via the salvage of uracil by a uracil phosphoribosyltransferase. Uracil phosphoribosyltransferase activity was detected in crude extracts prepared from highly purified C. psittaci AA Mp reticulate bodies. The presence of CTP synthetase and ribonucleotide reductase is implicated from the incorporation of uracil into nucleic acid cytosine and deoxycytidine. Deoxyuridine was used by the parasite only after cleavage to uracil. C. psittaci AA Mp grew poorly in mutant host cell lines auxotrophic for thymidine. Furthermore, the parasite could not synthesize thymidine nucleotides de novo. C. psittaci AA Mp could take TTP directly from the host cell. In addition, the parasite could incorporate exogenous thymidine and thymine into DNA. Thymidine kinase activity and thymidine-cleaving activity were detected in C. psittaci AA Mp reticulate body extract. Thus, thymidine salvage was totally independent of other pyrimidine salvage.     

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.     

Pyrimidine biosynthesis in Pseudomonas veronii and its regulation by pyrimidines

Pyrimidine biosynthesis in the nutritionally versatile bacterium Pseudomonas veronii ATCC 700474 appeared to be controlled by pyrimidines. When wild type cells were grown on glucose in the presence of uracil, four enzyme activities were depressed while all five enzyme activities increased in succinate-grown cells supplemented with uracil. Independent of carbon source, orotic acid-grown cells elevated aspartate transcarbamoylase, dihydroorotase, orotate phosphoribosyltransferase or OMP decarboxylase activity. Pyrimidine limitation of glucose-grown pyrimidine auxotrophic cells lacking OMP decarboxylase activity resulted in at least a doubling of the enzyme activities relative to their activities in uracil-grown cells. Less derepression of the enzyme activities was observed after pyrimidine limitation of succinate-grown mutant cells possibly due to catabolite repression. Aspartate transcarbamoylase activity in Ps. veronii was regulated at the level of enzyme activity since the enzyme was strongly inhibited by pyrophosphate, UDP, UTP, ADP, ATP and GTP. Overall, the regulation of pyrimidine biosynthesis in Ps. veronii could be used to differentiate it from other taxonomically related species of Pseudomonas.     

The influence of ammonia on purine and pyrimidine nucleotide biosynthesis in rat liver and brain in vitro

1. The effect of ammonia on purine and pyrimidine nucleotide biosynthesis was studied in rat liver and brain in vitro. The incorporation of NaH¹⁴CO₃ into acid-soluble uridine nucleotide (UMP) in liver homogenates and minces was increased 2.5–4-fold on incubation with 10mm-NH₄Cl plus N-acetyl-l-glutamate, but not with either compound alone. 2. The incorporation of NaH¹⁴CO₃ into orotic acid was increased 3–4-fold in liver homogenate with NH₄Cl plus acetylglutamate. 3. The 5-phosphoribosyl 1-pyrophosphate content of liver homogenate was decreased by 50% after incubation for 10min with 10mm-NH₄Cl plus acetylglutamate. 4. Concomitant with this decrease in free phosphoribosyl pyrophosphate was a 40–50% decrease in the rates of purine nucleotide synthesis, both de novo and from the preformed base. 5. Subcellular fractionation of liver indicated that the effects of NH₄Cl plus acetylglutamate on pyrimidine and purine biosynthesis required a mitochondrial fraction. This effect of NH₄Cl plus acetylglutamate could be duplicated in a mitochondria-free liver fraction with carbamoyl phosphate. 6. A similar series of experiments carried out with rat brain demonstrated a significant, though considerably smaller, effect on UMP synthesis de novo and purine base reutilization. 7. These data indicate that excessive amounts of ammonia may interfere with purine nucleotide biosynthesis by stimulating production of carbamoyl phosphate through the mitochondrial synthetase, with the excess carbamoyl phosphate in turn increasing pyrimidine nucleotide synthesis de novo and diminishing the phosphoribosyl pyrophosphate available for purine biosynthesis.