In situ regulation of mammalian CTP synthetase by allosteric inhibition

The regulatory role of the allosteric site of CTP synthetase on flux through the enzyme in situ and on pyrimidine nucleotide triphosphate (NTP) pool balance was investigated using a mutant mouse T lymphoblast (S49) cell line which contains a CTP synthetase refractory to complete inhibition by CTP. Measurements of [3H]uridine incorporation into cellular pyrimidine NTP pools as a function of time indicated that CTP synthesis in intact wild type cells was markedly inhibited in a cooperative fashion by small increases in CTP pools, whereas flux across the enzyme in mutant cells was much less affected by changes in CTP levels. The cooperativity of the allosteric inhibition of the enzyme was greater in situ than in vitro. Exogenous manipulation of levels of GTP, an activator of the enzyme, indicated that GTP had a moderate effect on enzyme activity in situ, and changes in pools of ATP, a substrate of the enzyme, had small effects on CTP synthetase activity. The consequences of incubation with actinomycin D, cycloheximide, dibutyryl cyclic AMP, and 6-azauridine on the flux across CTP synthetase and on NTP pools differed considerably between wild type and mutant cells. Under conditions of growth arrest, an intact binding site for CTP on CTP synthetase was required to maintain a balance between the CTP and UTP pools in wild type cells. Moreover, wild type cells failed to incorporate H14CO3- into pyrimidine pools following growth arrest. In contrast, mutant cells incorporated the radiolabel at a high rate indicating loss of a regulatory function. These results indicated that uridine nucleotides are important regulators of pyrimidine nucleotide synthesis in mouse S49 cells, and CTP regulates the balance between UTP and CTP pools.     

Cooperative effects of CTP on calf liver CTP synthetase.

In all previous kinetics studies of calf liver CTP synthetase, simple Michaelis-Menten hyperbolic plots were obtained. In this study it was shown that calf liver CTP synthetase could generate sigmoidal kinetic plots as a function of the substrate UTP when in the presence of the product of the reaction, CTP. The Hill number was estimated to be 2.8. The enzyme did not generate sigmoidal plots as a function of the other substrates (L-glutamine and ATP) either in the presence or absence of CTP. Thus, CTP apparently induced changes in the liver enzyme which altered the binding of UTP to the enzyme by acting at a site distinct from the UTP binding site (allosteric site). This concept was further strengthened by the fact that 3-deazaUTP, a known competitive inhibitor of the liver enzyme, did not induce sigmoidal kinetic plots. It was also shown that CTP had no effect upon the dimerization of the enzyme, thus ruling out monomer to dimer transitions as a potential mechanism for the observed sigmoidal kinetics.     

Synthesis and biological evaluation of some new N4-substituted isatin-3-thiosemicarbazones

A new series of 12 N⁴-substituted isatin-3-thiosemicarbazones 2a-l has been synthesized, characterized and screened for in vitro cytotoxic, phytotoxic and urease inhibitory effects. All the compounds proved to be active in the brine shrimp bioassay; 2a, 2b, 2d, 2f and 2h-l exhibited a high degree of cytotoxic activity (LD₅₀ = 1.10 × 10^{? 5} M–3.10 × 10^{? 5} M). In urease-inhibition assay, compounds 2a, 2b, 2e, 2f, 2h-j and 2l proved to be potent inhibitors displaying relatively much greater inhibition of the enzyme with IC₅₀ values ranging from 20.6 μM to 50.6 μM. Amongst these, 2a and 2f were found to be the most potent ones exhibiting pronounced inhibition with IC₅₀ value 20.6 μM. All the synthetic compounds showed weak to moderate (10–40%) phytotoxicity at the highest tested concentration (500 μg/mL) indicating their usefulness as inhibitors of soil ureases.     

Inactivation and covalent modification of CTP synthetase by thiourea dioxide.

Thiourea dioxide was used in chemical modification studies to identify functionally important amino acids in Escherichia coli CTP synthetase. Incubation at pH 8.0 in the absence of substrates led to rapid, time dependent, and irreversible inactivation of the enzyme. The second-order rate constant for inactivation was 0.18 M-1 s-1. Inactivation also occurred in the absence of oxygen and in the presence of catalase, thereby ruling out mixed-function oxidation/reduction as the mode of amino acid modification. Saturating concentrations of the substrates ATP and UTP, and the allosteric activator GTP prevented inactivation by thiourea dioxide, whereas saturating concentrations of glutamine (a substrate) did not. The concentration dependence of nucleotide protection revealed cooperative behavior with respect to individual nucleotides and with respect to various combinations of nucleotides. Mixtures of nucleotides afforded greater protection against inactivation than single nucleotides alone, and a combination of the substrates ATP and UTP provided the most protection. The Hill coefficient for nucleotide protection was approximately 2 for ATP, UTP, and GTP. In the presence of 1:1 ratios of ATP:UTP, ATP:GTP, and UTP:GTP, the Hill coefficient was approximately 4 in each case. Fluorescence and circular dichroism measurements indicated that modification by thiourea dioxide causes detectable changes in the structure of the protein. Modification with [14C]thiourea dioxide demonstrated that complete inactivation correlates with incorporation of 3 mol of [14C]thiourea dioxide per mole of CTP synthetase monomer. The specificity of thiourea dioxide for lysine residues indicates that one or more lysines are most likely involved in CTP synthetase activity. The data further indicate that nucleotide binding prevents access to these functionally important residues.     

Substrate specificity of CTP synthetase from Escherichia coli

The stoichiometry of the enzymatic reaction catalyzed by CTP synthetase from Escherichia coli was analyzed by high-performance liquid chromatography. The results revealed that for every mole of UTP transformed to CTP, one mole of ATP was converted to ADP. The substrate specificity of CTP synthetase from E. coli was investigated by means of UTP analogs. Chemical modification of UTP involved either the uracil, ribose or 5'-triphosphate part. None of the UTP analogs studied proved to be a substrate. The capacity of the UTP analogs to inhibit CTP synthetase was investigated. From the UTP derivatives employed only 2-thiouridine 5'-triphosphate was found to inhibit the enzyme competitively with reasonable affinity: Ki/Km(UTP) = 1. This study indicated that the three main structural elements of the UTP molecule: uracil, ribose and 5'-triphosphate moiety, contribute to substrate specificity. The behaviour of a limited number of CTP analogs as product-like inhibitors supported this view.     

Synthesis and biological evaluation of some new N(4)-substituted isatin-3-thiosemicarbazones

A new series of 12 N(4)-substituted isatin-3-thiosemicarbazones 2a-l has been synthesized, characterized and screened for in vitro cytotoxic, phytotoxic and urease inhibitory effects. All the compounds proved to be active in the brine shrimp bioassay; 2a, 2b, 2d, 2f and 2h-l exhibited a high degree of cytotoxic activity (LD(50) = 1.10 x 10(- 5) M-3.10 x 10(- 5) M). In urease-inhibition assay, compounds 2a, 2b, 2e, 2f, 2h-j and 2l proved to be potent inhibitors displaying relatively much greater inhibition of the enzyme with IC(50) values ranging from 20.6 microM to 50.6 microM. Amongst these, 2a and 2f were found to be the most potent ones exhibiting pronounced inhibition with IC(50) value 20.6 microM. All the synthetic compounds showed weak to moderate (10-40%) phytotoxicity at the highest tested concentration (500 microg/mL) indicating their usefulness as inhibitors of soil ureases.     

Activation of mammalian folylpolyglutamate synthetase by sodium bicarbonate

NaHCO3 activated the folylpolyglutamate synthetase (FPGS) from rat liver and the human leukemia cell lines K562 and CCRF-CEM by 1.7- to 2.0-fold. Optimal activation was achieved by 10 mM NaHCO3 in all cases; NaCl, sodium formate, sodium acetate, NaN3, and Na2SO3 at 10 mM did not cause activation. Activation could be masked if assay solutions which had extensively absorbed atmospheric CO2 were used. Activation of the human CCRF-CEM FPGS was examined in detail. Km and Vmax values for pteroyl substrates (aminopterin or methotrexate) and L-glutamate increased proportionally in the presence of NaHCO3; there was thus no apparent change in the catalytic efficiency (Vmax/Km) of the FPGS reaction with these substrates. However, NaHCO3 increased the efficiency of the reaction with respect to ATP by decreasing its apparent Km while increasing the Vmax of the reaction. NaHCO3 also activated FPGS activity when folic acid, dihydrofolic acid and tetrahydrofolic acid were substrates. The relative distribution of products synthesized from methotrexate or tetrahydrofolate by FPGS was not altered by addition of NaHCO3. The potency of 5,8-dideazapteroylornithine, an FPGS-specific inhibitor, was not changed by the presence of NaHCO3 (IC50 = 0.4 microM). These results suggest that FPGS activity with folates and classical antifolates may be activated at physiological concentrations of NaHCO3. In addition, inadvertent contamination of assay solutions with bicarbonate from atmospheric CO2 may cause artifacts in the determination of activity levels and kinetic constants of FPGS.     

Nucleotide sequence of Escherichia coli pyrG encoding CTP synthetase

The amino acid sequence of Escherichia coli CTP synthetase was derived from the nucleotide sequence of pyrG. The derived amino acid sequence, confirmed at the N terminus by protein sequencing, predicts a subunit of 544 amino acids having a calculated Mr of 60,300 after removal of the initiator methionine. A glutamine amide transfer domain was identified which extends from approximately amino acid residue 300 to the C terminus of the molecule. The CTP synthetase glutamine amide transfer domain contains three conserved regions similar to those in GMP synthetase, anthranilate synthase, p-aminobenzoate synthase, and carbamoyl-P synthetase. The CTP synthetase structure supports a model for gene fusion of a trpG-related glutamine amide transfer domain to a primitive NH3-dependent CTP synthetase. The major 5' end of pyrG mRNA was localized to a position approximately 48 base pairs upstream of the translation initiation codon. Translation of the gene eno, encoding enolase, is initiated 89 base pairs downstream of pyrG. The pyrG-eno junction is characterized by multiple mRNA species which are ascribed to monocistronic pyrG and/or eno mRNAs and a pyrG eno polycistronic mRNA.     

Synthesis and evaluation of N1/C4-substituted beta-lactams as PPE and HLE inhibitors

4-(Alkylamino)carbonyl-1-(alkoxy)carbonyl-2-azetidinones (9-11) have been prepared in five steps from 4-(benzyloxy)carbonyl-1-(t-butyldimethyl)silyl-2-azetidinone (1). The beta-lactam reactivity of 9 has been established by 1H NMR experiment. Compound 11 was a good reversible inhibitor of PPE and HLE. Based on theoretical design, series of 2-azetidinones (12-17) and 4-(alkoxy)carbonyl-2-azetidinones (18-21) bearing various carbonyl (ester, thiolester, amide) and thiocarbonyl (thioamide) functionalities at position N1 were similarly prepared. In the absence of C4-substituent, the compounds were inactive against elastases. On the other hand, 4-(benzyloxy)carbonyl-1-(ethylthioxy)carbonyl-2-azetidinone (19) and 4-(benzyloxy)carbonyl-1-(benzylamino)thiocarbonyl-2-azetidinone (21) were both good reversible inhibitors, but acting most probably via different mechanisms (enzymic processing of the exocyclic ester function or beta-lactam ring opening).     

Cyclopentenylcytosine triphosphate. Formation and inhibition of CTP synthetase

Cyclopentenylcytosine (CPEC) is phosphorylated in L1210 cells with CPEC triphosphate as the major metabolite. Partially purified uridine-cytidine kinase catalyzes the initial phosphorylation of cyclopentenylcytosine with an apparent Km of 196 +/- 9 microM, and cyclopentenylcytosine is a competitive inhibitor of cytidine phosphorylation by this enzyme with a Ki value of 144 +/- 14 microM. Examination of the CTP synthetase activity in extracts of L1210 cells revealed a dose-dependent decrease on exposure of cells to CPEC. Synthesis of CPEC triphosphate by an enzymatic method permitted direct examination of the inhibition of partially purified CTP synthetase. CPEC triphosphate inhibited bovine CTP synthetase with a median inhibitory concentration of 6 microM, whereas CPEC mono- and diphosphates were ineffective. CTP synthetase showed a classical Michaelis-Menten hyperbolic plot of velocity and UTP concentration in the presence of saturating concentrations of ATP and glutamine, but CPEC triphosphate induced sigmoidal kinetic plots. The Hill coefficient was calculated to be 3.2.     

Rapid in vivo inactivation by acivicin of CTP synthetase,carbamoyl-phosphate synthetase II,and amidophosphoribosyltransferase in hepatoma

A single injection of the anti-glutamine drug, acivicin (NSC 163501), in tumor-bearing rats in 30 min decreased the activities of amidophosphoribosyltransferase, carbamoyl-phosphate synthetase II and CTP synthetase to 56, 50 and 7% of those of the controls. By 1 hr the activities were down to 32, 13 and 3% and they remained low for 12 hr, after which they slowly returned towards normal range in 72 hr. The decline of the activity of CTP synthetase (a loss of 80% in 10 min) was the most rapid, and the activity only returned to 60% of the controls by 3 days after the acivicin injection. In the hepatoma the concentrations of ATP and UTP changed little, but those of GTP and CTP rapidly decreased, reaching at the lowest point 32 and 2%, respectively, of control values 2 hr after acivicin; concentrations started to rise at 12 hr, reaching normal levels by 48 hr. The drop in enzyme activities preceded the decline in the pools of GTP and CTP. The behavior of enzyme activities and nucleotide concentrations in the host liver had a pattern similar to that in the hepatoma; however, the changes were less extensive than those in the tumor. The differential response between tumor and liver is attributed, in part at least, to the tissue L-glutamine concentration which in the hepatoma (0.5 mM) was 9 times lower than in the liver (4.5 mM). The selectivity of acivicin action in inhibiting glutamine-utilizing enzymes is also demonstrated by the lack of effect on aspartate carbamoyltransferase, a an enzymic activity which resides in the same complex as that of carbamoyl-phosphate synthetase II. The rapid decline in the activities of glutamine-utilizing enzymes is attributed to an in-activation of the enzymes by acivicin which functions as an active site-directed affinity analog of L-glutamine. The rapid modulation of the enzymic phenotype and ribonucleotide concentrations by acivicin provides a useful tool for elucidating the role of enzymic and nucleotide imbalance in the commitment of cancer cells to replication and in the targeting of anticancer chemotherapy.     

Synthesis of tetraphenylsubstituted porphyrins by interaction of 5-aryldipyrromethanes with 4-substituted benzaldehydes

Synthesis of tetraphenyl substituted porphyrins with tert-butyl and methoxycarbonyl groups in meso-aryl radicals is described. It is shown that, during the condensation of dipyrromethanes with substituted benzaldehydes, a rearrangement occurs with the formation of a mixture of isomeric porphyrins. The character of these rearrangements depends on the position of substituents in the starting compounds.     

Reversible inhibition of mammalian glutamine synthetase by tyrosine nitration

The effect of tyrosine nitration on mammalian GS activity and stability was studied in vitro. Peroxynitrite at a concentration of 5 micro mol/l produced tyrosine nitration and inactivation of GS, whereas 50 micro mol/l peroxynitrite additionally increased S-nitrosylation and carbonylation and degradation of GS by the 20S proteasome. (-)Epicatechin completely prevented both, tyrosine nitration and inactivation of GS by peroxynitrite (5 micro mol/l). Further, a putative "denitrase" activity restored the activity of peroxynitrite (5 micro mol/l)-treated GS. The data point to a potential regulation of GS activity by a reversible tyrosine nitration. High levels of oxidative stress may irreversibly damage and predispose the enzyme to proteasomal degradation.     

Regulation of mammalian asparagine synthetase by adenine nucleotides.

Initial velocity kinetic data indicate that ADP and AMP are inhibitors of mammalian liver asparagine synthetase. The non-product nucleotide ADP is a much more potent inhibitor than AMP, although both apparently compete for the same site. This modifier site, however, does not overlap spatially with the substrate site for ATP. Both ADP and AMP are V_max inhibitors, but ADP also raises the K_m for ATP. Adenylate energy charge, calculated at various levels of ATP and ADP show typical correlations with activity, but with AMP these correlations are weak and atypical.     

Expression of Human CTP synthetase in Saccharomyces cerevisiae reveals phosphorylation by protein kinase A

CTP synthetase (EC 6.3.4.2, UTP:ammonia ligase (ADP-forming)) is an essential enzyme in all organisms; it generates the CTP required for the synthesis of nucleic acids and membrane phospholipids. In this work we showed that the human CTP synthetase genes, CTPS1 and CTPS2, were functional in Saccharomyces cerevisiae and complemented the lethal phenotype of the ura7Delta ura8Delta mutant lacking CTP synthetase activity. The expression of the CTPS1- and CTPS2-encoded human CTP synthetase enzymes in the ura7Delta ura8Delta mutant was shown by immunoblot analysis of CTP synthetase proteins, the measurement of CTP synthetase activity, and the synthesis of CTP in vivo. Phosphoamino acid and phosphopeptide mapping analyses of human CTP synthetase 1 isolated from (32)P(i)-labeled cells revealed that the enzyme was phosphorylated on multiple serine residues in vivo. Activation of protein kinase A activity in yeast resulted in transient increases (2-fold) in the phosphorylation of human CTP synthetase 1 and the cellular level of CTP. Human CTP synthetase 1 was also phosphorylated by mammalian protein kinase A in vitro. Using human CTP synthetase 1 purified from Escherichia coli as a substrate, protein kinase A activity was dose- and time-dependent, and dependent on the concentrations of CTP synthetase 1 and ATP. These studies showed that S. cerevisiae was useful for the analysis of human CTP synthetase phosphorylation.     

Identification of a cDNA encoding an isoform of human CTP synthetase

A full-length cDNA clone encoding an isoform of human CTP synthetase (type II) was isolated. A 1761-nucleotide open reading frame which corresponds to a protein of 586 amino acids with a predicted molecular mass of 65678 Da was identified. The predicted protein sequence showed 74% identity with the translation product of a previously identified human CTP synthetase cDNA clone (type I). The function of the human cDNA encoding type II CTP synthetase was verified by successful complementation of the cytidine-requiring CTP synthetase deficient mutant JF618 of Escherichia coli. The gene encoding type II CTP synthetase has been localized on chromosome Xp22.     

New N4-substituted piperazine naphthamide derivatives as BACE-1 inhibitors

Synthesis and enzymatic evaluation of new series of N₄-substituted piperazine naphthamide derivatives as BACE-1 inhibitors for the treatment of Alzheimer's disease are reported.     

Synthesis of quinolinate from D-aspartate in the mammalian liver-Escherichia coli quinolinate synthetase system.

Two proteins (A and B) from $\text{Escherichia coli}$ are required for the synthesis of the NAD precursor quinolinate from aspartate and dihydroxyacetone phosphate. Mammalian liver contains a FAD linked protein which replaces $\text{E. coli}$ B protein for quinolinate synthesis. D-aspartic acid but not L-aspartic acid is a substrate for quinolinic acid synthesis in a system composed of the B protein replacing activity of mammalian liver and $\text{E. coli}$ A protein. In contrast the $\text{E. coli}$ B protein-$\text{E. coli}$ A protein quinolinate synthetase system requires L-aspartic acid as substrate. The previous report that L-aspartate was a substrate in the liver-$\text{E. coli}$ system was due to contamination of commercially available [¹⁴C]L-aspartate with [¹⁴C]D-aspartate. These and other observations suggest that liver B protein is D-aspartate oxidase and $\text{E. coli}$ B protein is L-aspartate oxidase.