Catalytic domains of carbamyl phosphate synthetase. Glutamine-hydrolyzing site of Escherichia coli carbamyl phosphate synthetase

We present evidence that cysteine 269 of the small subunit of Escherichia coli carbamyl phosphate synthetase is essential for the hydrolysis of glutamine. When cysteine 269 is replaced with glycine or with serine by site-directed mutagenesis of the carA gene, the resulting enzymes are unable to catalyze carbamyl phosphate synthesis with glutamine as nitrogen donor. Even though the glycine 269, and particularly the serine 269 enzyme bind significant amounts of glutamine, neither glycine 269 nor serine 269 can hydrolyze glutamine. The mutations at cysteine 269 do not affect carbamyl phosphate synthesis with NH3 as substrate. The NH3-dependent activity of the mutant enzymes was equal to that of wild-type. Measurements of Km indicate that the enzyme uses unionized NH3 rather than ammonium ion as substrate. The apparent Km for NH3 of the wild-type enzyme is calculated to be about 5 mM, independent of pH. The substitution of cysteine 269 with glycine or with serine results in a decrease of the apparent Km value for NH3 from 5 mM with the wild-type to 3.9 mM with the glycine, and 2.9 mM with the serine enzyme. Neither the glycine nor the serine mutation at position 269 affects the ability of the enzyme to catalyze ATP synthesis from ADP and carbamyl phosphate. Allosteric properties of the large subunit are also unaffected. However, substitution of cysteine 269 with glycine or with serine causes an 8- and 18-fold stimulation of HCO-3 -dependent ATPase activity, respectively. The increase in ATPase activity and the decrease in apparent Km for NH3 provide additional evidence for an interaction of the glutamine binding domain of the small subunit with one of the two known ATP sites of the large subunit.     

Mutational analysis of carbamyl phosphate synthetase. Substitution of Glu841 leads to loss of functional coupling between the two catalytic domains of the synthetase subunit.

The synthetase subunit of Escherichia coli carbamyl phosphate synthetase has two catalytic nucleotide-binding domains, one involved in the activation of HCO3- and the second in phosphorylation of carbamate. Here we show that a Glu841----Lys841 substitution in a putative ATP-binding domain located in the carboxyl half of the synthetase abolishes overall synthesis of carbamyl phosphate with either glutamine or NH3 as the nitrogen source. Measurements of partial activities indicate that while HCO3(-)-dependent ATP hydrolysis at saturating concentrations of substrate proceeds at higher than normal rates, ATP synthesis from ADP and carbamyl phosphate is nearly completely suppressed by the mutation. These results indicate Glu841 to be an essential residue for the phosphorylation of carbamate in the terminal step of the catalytic mechanism. The Lys841 substitution also affects the kinetic properties of the HCO3- activation site. Both kcat and Km for ATP increase 10-fold, while Km for HCO3- is increased 100-fold. Significantly, NH3 decreases rather than stimulates Pi release from ATP in the HCO3(-)-dependent ATPase reaction. The increase in kcat of the HCO3(-)-dependent ATPase reaction, and an impaired ability of the Lys841 enzyme to catalyze the reaction of NH3 with carboxy phosphate, strongly argues for interactions between the two catalytic ATP sites that couple the formation of enzyme-bound carbamate with its phosphorylation.     

Identification of the junction between the glutamine amidotransferase and carbamyl phosphate synthetase domains of the mammalian CAD protein

The hamster CAD gene encodes a protein that catalyzes the first three steps of pyrimidine biosynthesis. We have sequenced a portion of a CAD cDNA and determined the location of the carbamyl phosphate synthetase II coding region. Subdomains coding for the glutamine hydrolyzing and carbamyl phosphate synthesizing functions have been identified through their high degree of similarity to carbamyl phosphate synthetase genes from a variety of organisms. The proline-rich junction between the glutaminase and synthetase domains, however, does not appear to be conserved among carbamyl phosphate synthetases.     

Carbamyl phosphate synthetase II in the mucosal cells of gall bladders

A glutamine dependent carbamyl phosphate synthetase has been detected in the extra mitochondrial fraction of gall bladder mucosal cells obtained from rabbits and cattle. This enzyme is inhibited by azaserine. Thus, the enzyme appears to be carbamyl phosphate synthetase II. The activity of the preparation obtained from rabbits is four to seven times that of the bovine gall bladder.     

In vivo synthesis of carbamyl phosphate from NH3 by the large subunit of Escherichia coli carbamyl phosphate synthetase

The cloned carAB operon of Escherichia coli coding for the small and large subunits of carbamyl phosphate synthetase has been used to construct a recombinant plasmid with a 4.16 kilobase ClaI fragment of the car operon that lacks the major promoters, P1 and P2. The plasmid, pHN12, carries a functional carB gene. A mutant E. coli strain lacking both subunits of carbamyl phosphate synthetase when transformed with pHN12 overproduces the large subunit by 200-fold (8-10% of the cellular protein). The elevated levels of the large subunit enable the transformed cells to utilize NH3 but not glutamine as nitrogen donor for carbamyl phosphate synthesis. The large subunit has been purified from the overexpressing strain. The purified native large subunit is capable of synthesizing carbamyl phosphate from ammonia, HCO-3, and ATP. The kinetic properties of the large subunit compared with the holoenzyme indicate that the Michaelis constants of the large subunit for HCO-3 and ATP are modulated by its association with the small glutamine binding subunit.     

ATP regeneration using immobilized carbamyl phosphokinase

A simple and efficient system for continuous ATP regeneration is described. The procedure is based on the enzyme-catalyzed reaction between carbamyl phosphate and ADP. The carbamyl phosphate was generated in situ by reaction between potassium cyanate and potassium phosphate. The enzyme, carbamyl phosphokinase, was isolated from extracts of Streptococcus faccalis and partially purified. Immobilization of the enzyme was achieved using glutaraldehyde-treated alkylamine glass giving 200–250 units of activity per gram of glass. A column of carbamyl phosphokinase on glass was used to form ATP continuously from ADP, phosphate, and cyanate and lost approximately 16% of the initial activity after 14 days operation at room temperature.     

Biochemical and genetic characterization of a carbamyl phosphate synthetase mutant of Escherichia coli K12.

An unusual Escherichia coli K12 mutant for carbamyl phosphate synthetase is described. The mutation was generated by bacteriophage MUI insertion and left a 5% residual activity of the enzyme using either ammonia or glutamine as donors. The mutation is recessive to the wild-type allele and maps at or near the pyrA gene, but the mutant requires only arginine and not uracil for growth. By a second block in the pyrB gene it was possible to shift the accumulated carbamyl phosphate to arginine biosynthesis. The Km values and the levels of ornithine activation and inhibition by UMP were normal in the mutant enzyme.     

Modes of modifier action in E. coli aspartate transcarbamylase

The observed patterns for inhibition by CTP and succinate of equilibrium exchange kinetics with native aspartate transcarbamylase (E. coli) are consistent with an ordered substrate-binding system in which aspartate binds after carbamyl phosphate, and phosphate is released after carbamyl aspartate. ATP selectively stimulates Asp carbamyl-Asp exchange, but not carbamyl phosphate P_i. Initial velocity studies at 5 °, 15 °, and 35 °C were carried out, using modifiers as perturbants of the system. Modifiers alter the Hill n and S_0.5 for aspartate, most markedly at 15 °C but less so at the other temperatures. ATP does increase V under saturating substrate conditions, and substrate inhibition is observed for aspartate. ATP does not make the Hill n = 1 at any temperature. It is proposed that CTP and ATP act by separate mechanisms, not by simply perturbing in opposite directions the equilibrium for aspartate binding. ATP appears to act to increase the rate of aspartate association and dissociation, whereas CTP induces an intramolecular competitive effect in the protein.     

Biochemical Studies on Amphibian Metamorphosis : I. The effect of thyroxine on protein synthesis in the tadpole

Thyroxine has been shown to accelerate the synthesis of carbamyl phosphate synthetase in the liver of Rana catesbeiana. Stimulation of carbamyl phosphate synthetase synthesis by thyroxine appears to be relatively specific because of the following observations: (1) succinoxidase activity decreased during the time that carbamyl phosphate synthetase increased; (2) liver catalase responded more slowly than carbamyl phosphate synthetase to thyroxine; (3) the ratio of biochemical changes/morphological changes was greatly altered during thyroxine-induced metamorphosis. The relationships between the concentration of thyroxine and (1) temperature; (2) duration of exposure of the tadpole to thyroxine; and (3) the activity of carbamyl phosphate synthetase during the induced synthesis of carbamyl phosphate synthetase by thyroxine are discussed. Chloramphenicol and thiouracil partly counteracted the effect of thyroxine on the synthesis of carbamyl phosphate synthetase.     

Mode of Action of the Toxin from Pseudomonas phaseolicola: I. Toxin Specificity, Chlorosis, and Ornithine Accumulation

The specificity of the Pseudomonas phaseolicola toxin for enzyme inhibition and its relationship to toxin-induced chlorosis in bean leaves (Phaseolus vulgaris L.) was examined. The toxin showed no significant inhibitory activity against glutamine synthetase, glutamine transferase, carbamyl phosphate synthetase, aspartate carbamoyltransferase, or arginase at concentrations 100-fold higher than that needed to inhibit ornithine carbamoyltransferase by 50%.     

Effects of bicarbonate on fluid and electrolyte transport by guinea pig and rabbit gallbladder: Stimulation of absorption

Summary The effect of bicarbonate (HCO₃) on fluid absorption by guinea pig gallbladder was investigatedin vitro. Stimulation of fluid absorption was concentration dependent resulting in a fourfold increase in transport over the range 1 to 50mm. Phosphate, Tris, glycodiazine and glutamine buffers failed to substitutte for HCO₃ in stimulating absorption. Unidirectional²²Na fluxes were measured across short-circuited sheets of guinea pig and rabbit gallbladders mounted in Ussing-type chambers. In both species the net Na flux was unaffected by serosal HCO₃ alone but was stimulated by addition of HCO₃ to the mucosal bathing solution. Transepithelial electrical potential difference in rabbit gallbladder was about 1.4 mV (lumen positive) when HCO₃ was present in the mucosal or in both compartments. This fell to 0.2 mV under HCO₃-free conditions or when HCO₃ was present only in the serosal solution. The respective values for guinea pig gallbladder were –1.6 and –0.6 mV (lumen negative). HCO₃ stimulation of Na absorption by guinea pig gallbladder was abolished by increasing the bathing pH from 7.4 to 7.8, an effect resulting mainly from a reduction inJ _mis ^Na . Tris buffer (25mm) inhibited HCO₃-dependent fluid absorption in this species completely at pH 8.5 and partially at 7.5. These results indicate that HCO₃ stimulates gallbladder transport in both species by an action from the mucosal side. This effect cannot be attributed to simple buffering of H⁺ but may be explained by the participation of HCO₃ in the maintenance of intracellular H⁺ for a Na/H-exchange.     

Pyrimidine synthesis in tissue culture

Abstract— Myelinated cerebellar tissue culture (organ culture) was used to assess the salvage and de novo pathways of pyrimidine synthesis in mammalian brain. Radioactive orotic acid and carbamyl aspartic acid were readily incorporated into UMP and into perchloric acid-insoluble RNA. The incorporation was effectively blocked by azauridine. Neither radioactive sodium bicarbonate or citrulline was incorporated into UMP or blocked by azauridine. [³H]Uridine, on the other hand, rapidly entered the cultures, was incorporated into UMP and perchloric acid-insoluble material, and was partially inhibited by azauridine. The failure to demonstrate activity of carbamyl phosphate synthetase suggests the potential importance of the salvage pathway and the likely dependence of the brain upon exogenous and endogenous pyrimidine precursors.     

Effect of nitrogenous compounds on nitrogenase gene expression in anaerobic cultures of Anabaena variabilis.

The effects of several organic and inorganic nitrogen compounds on nitrogenase mRNA and enzyme activity levels were examined in anaerobic cultures of Anabaena variabilis 29413. Even low concentrations of exogenous ammonia (20 microM) prevented nitrogenase gene expression. Nitrate, in contrast, had little effect, even at very high concentrations. Neither compound had a significant direct effect on existing enzyme activity. The amino acids glutamine and glutamate did not repress nif gene expression. Methionine sulfoximine, but not 7-azatryptophan, was shown to eliminate the repressive effect of ammonia, and this action occurred at the mRNA level. Low concentrations of carbamyl phosphate caused a rapid decrease in nitrogenase mRNA levels. These results are consistent with the ideas that nif gene regulation in Anabaena spp. occurs primarily at the mRNA level and that ammonia, and possibly also glutamine and glutamate, is not the immediate effector of regulation.     

DL-7-azatryptophan and citrulline metabolism in the cyanobacterium Anabaena sp. strain 1F.

An alternative route for the primary assimilation of ammonia proceeds via glutamine synthetase-carbamyl phosphate synthetase and its inherent glutaminase activity in Anabaena sp. strain 1F, a marine filamentous, heterocystous cyanobacterium. Evidence for the presence of this possible alternative route to glutamate was provided by the use of amino acid analogs as specific enzyme inhibitors, enzymological studies, and radioistopic labeling experiments. The amino acid pool patterns of continuous cultures of Anabaena sp. strain 1F were markedly influenced by the nitrogen source. A relatively high concentration of glutamate was maintained in the amino acid pools of all cultures irrespective of the nitrogen source, reflecting the central role of glutamate in nitrogen metabolism. The addition of 1.0 microM azaserine increased the intracellular pools of glutamate and glutamine. All attempts to detect any enzymatic activity for glutamate synthase by measuring the formation of L-[14C]glutamate from 2-keto-[1-14C]glutarate and glutamine failed. The addition of 10 microM DL-7-azatryptophan caused a transient accumulation of intracellular citrulline and alanine which was not affected by the presence of chloramphenicol. The in vitro activity of carbamyl phosphate synthetase and glutaminase increased severalfold in the presence of azatryptophan. Results from radioisotopic labeling experiments with [14C]bicarbonate and L-[1-14C]ornithine also indicated that citrulline was formed via carbamyl phosphate synthetase and ornithine transcarbamylase. In addition to its effects on nitrogen metabolism, azatryptophan also affected carbon metabolism by inhibiting photosynthetic carbon assimilation and photosynthetic oxygen evolution.     

15N isotope effects in glutamine hydrolysis catalyzed by carbamyl phosphate synthetase: evidence for a tetrahedral intermediate in the mechanism

15N isotope effects have been measured on the hydrolysis of glutamine catalyzed by carbamyl phosphate synthetase of Escherichia coli. The isotope effect in the amide nitrogen of glutamine is 1. 0217 at 37 degrees C with the wild-type enzyme in the presence of MgATP and HCO(3)(-) (overall reaction taking place). This V/K isotope effect indicates that breakdown of the tetrahedral intermediate formed with Cys 269 to release ammonia is the rate-limiting step in the hydrolysis. A full isotope effect of 1. 0215 is also seen in the partial reaction catalyzed by an E841K mutant enzyme, whose rate of glutamine hydrolysis is not affected by MgATP and HCO(3)(-). With wild-type enzyme in the absence of MgATP and HCO(3)(-), however, the (15)N isotope effect is reduced to 1. 0157. These isotope effects are interpreted in terms of partitioning of the tetrahedral intermediate whose rate of formation is dependent upon a conformation change which closes the active site after glutamine binding and prepares the enzyme for catalysis. An Ordered Uni Bi mechanism for glutamine hydrolysis that is consistent with the isotope effects and with the catalytic properties of the enzyme is proposed.     

关键基因的修饰对枯草芽孢杆菌尿苷合成的影响

【目的】探究磷酸核糖焦磷酸(PRPP)合成酶(prs)和氨甲酰磷酸合成酶(pyr AA/pyr AB)的点突变,以及异源5′-核苷酸酶(sdt1)的过表达,对枯草芽孢杆菌尿苷生物合成的影响。【方法】依据推断的变构位点,分别在prs基因和pyr AB基因编码序列中引入点突变;将点突变的prs基因在染色体xyl R位点整合表达,pyr AB基因则在染色体原位被修饰;sdt1基因在染色体sac B位点整合过表达。通过对重组菌摇瓶发酵液中尿苷、胞苷和尿嘧啶的分析,表征相关基因修饰对尿苷合成的影响。【结果】在PRPP合成酶中引入Asn120Ser、Leu135Ile和Glu52Gly或Val312Ala点突变,分别导致尿苷积累量提高67%和96%。进一步在氨甲酰磷酸合成酶中引入Ser948Phe、Thr977Ala和Lys993Ile点突变,导致尿苷积累量又增加了182%,达到6.97 g/L。在此基础上,过表达异源5′-核苷酸酶,导致尿苷产量增加17%,达到8.16 g/L。【结论】PRPP合成酶和氨甲酰磷酸合成酶的酶活或反馈抑制调节机制,是限制尿苷过量合成的重要因素。PRPP合成酶的Asn120Ser和Leu135Ile点突变,以及氨甲酰磷酸合成酶的Ser948Phe、Thr977Ala和Lys993Ile点突变,能够显著促进尿苷合成。PRPP合成酶附加的Glu52Gly或Val312Ala点突变,有利于尿苷合成。异源的嘧啶专一性5′-核苷酸酶的引入,也对尿苷的合成有明显的促进作用。     

The stimulation of glutamine hydrolysis in isolated rat liver mitochondria by Mg2+ depletion and hypo-osmotic incubation conditions.

1. In respiring rat liver mitochondria EDTA stimulates glutaminase activity measured in the presence of phosphate and HCO3- ions. The stimulation can be reversed by the addition of low concentrations of MgCl2. EGTA does not stimulate glutamine hydrolysis. 2. Glutaminase activity assayed in disrupted mitochondria is not significantly affected by EDTA or MgCl2. 3. The addition of EDTA results in a decrease in the concentration of phosphate required for half-maximal glutaminase activity. 4. Depletion of mitochondrial Mg2+ by the addition of the ionophore A23187 also stimulates glutamine hydrolysis in both the presence and the absence of EDTA. The effect of the ionophore can be abolished by the addition of MgCl2. 5. Hypo-osmotic incubation conditions increase the rate of mitochondrial glutamine hydrolysis. The effect of hypo-osmoticity on glutaminase is much less when EDTA is present. 6. It is suggested that glutaminase is partially and indirectly inhibited by endogenous mitochondrial Mg2+ and that the inner membrane may play a role in the regulation of glutaminase activity.     

Inhibition of carbamyl phosphate synthetase by P1, P5-di(adenosine 5')-pentaphosphate: evidence for two ATP binding sites.

Studies on the effect of a series of alpha, omega-diadenosine 5'-polyphosphate (ApnA; n = 2 to 6) on carbamyl phosphate synthetase showed that only Ap5A is an effective inhibitor. Ap5A also inhibits two partial reactions catalyzed by the enzyme: bicarbonate-dependent ATPase and ATP synthesis from carbamyl phosphate and ADP. The data indicate that Ap5A binds to the enzyme sites that interact with ATP. Of a variety of ATP-utilizing enzymes (kinases, hydrolases, synthetases), only adenylate kinase (Leinhard, G. E., and Secemski, I. I. (1973) J. Biol. Chem. 248, 1121--1123) and carbamyl phosphate synthetase are inhibited by Ap5A. The present findings provide strong evidence that carbamyl phosphate synthetase has two separate binding sites for ATP in which the gamma-phosphate moeities of ATP are bound in close proximity to the bicarbonate binding site of the enzyme.     

Purification and regulation of aspartate transcarbamylase from germinated mung bean (Vigna radiata) seedlings

Aspartate transcarbamylase (EC 2.1.3.2) was purified to homogeniety from germinated mung bean seedlings by treatment with carbamyl phosphate. The purified enzyme was a hexamer with a subunit molecular weight of 20,600. The enzyme exhibited multiple activity bands on Polyacrylamide gel electrophoresis, which could be altered by treatment with carbamyl phosphate or UMP indicating that the enzyme was probably undergoing reversible association or dissociation in the presence of these effectors. The carbamyl phosphate stabilized enzyme did not exhibit positive homotropic interactions with carbamyl phosphate and hysteresis. The enzyme which had not been exposed to carbamyl phosphate showed a decrease in specific activity with a change in the concentration of both carbamyl phosphate and protein. The carbamyl phosphate saturation and UMP inhibition patterns were complex with a maximum and a plateau region. The partially purified enzyme also exhibited hysteresis and the hysteretic response, a function of protein concentration, was abolished by preincubation with carbamyl phosphate and enhanced by preincubation with UMP. All these observations are compatible with a postulation that the enzyme activity may be regulated by slow reversible association-dissociation dependent on the interaction with allosteric ligands