GTP cyclohydrolase I utilizes metal-free GTP as its substrate.

GTP cyclohydrolase I (GCH) is the rate-limiting enzyme for the synthesis of tetrahydrobiopterin and its activity is important in the regulation of monoamine neurotransmitters such as dopamine, norepinephrine and serotonin. We have studied the action of divalent cations on the enzyme activity of purified recombinant human GCH expressed in Escherichia coli. First, we showed that the enzyme activity is dependent on the concentration of Mg-free GTP. Inhibition of the enzyme activity by Mg2+, as well as by Mn2+, Co2+ or Zn2+, was due to the reduction of the availability of metal-free GTP substrate for the enzyme, when a divalent cation was present at a relatively high concentration with respect to GTP. We next examined the requirement of Zn2+ for enzyme activity by the use of a protein refolding assay, because the recombinant enzyme contained approximately one zinc atom per subunit of the decameric protein. Only when Zn2+ was present was the activity of the denatured enzyme effectively recovered by incubation with a chaperone protein. These are the first data demonstrating that GCH recognizes Mg-free GTP and requires Zn2+ for its catalytic activity. We suggest that the cellular concentration of divalent cations can modulate GCH activity, and thus tetrahydrobiopterin biosynthesis as well.     

IMP dehydrogenase inhibitors reduce intracellular tetrahydrobiopterin levels through reduction of intracellular GTP levels. Indications of the regulation of GTP cyclohydrolase I activity by restriction of GTP availability in the cells.

GTP cyclohydrolase I exhibits a positive homotropic cooperative binding to GTP, which raises the possibility of a role for GTP in regulating the enzyme reaction (Hatakeyama, K., Harada, T., Suzuki, S., Watanabe, Y., and Kagamiyama, H. (1989) J. Biol. Chem. 264, 21660-21664). We examined whether or not the intracellular GTP level is within the range of affecting GTP cyclohydrolase I activity, using PC-12 rat pheochromocytoma and IMR-32 human neuroblastoma cells. Since GTP cyclohydrolase I was the rate-limiting enzyme for the biosynthesis of tetrahydrobiopterin in these cell lines, the intracellular activities of this enzyme were reflected in the tetrahydrobiopterin contents. We found that the addition of guanine or guanosine increased GTP but not tetrahydrobiopterin in these cells. On the other hand, three IMP dehydrogenase inhibitors, tiazofurin, 2-amino-1,3,4-thiadiazole, and mycophenolic acid, decreased both GTP and tetrahydrobiopterin in a parallel and dose-dependent manner, and these effects were reversed by the simultaneous addition of guanine or guanosine. There was no evidence suggesting that these inhibitors inhibited other enzymes involved in the biosynthesis and regeneration of tetrahydrobiopterin. Comparing intracellular activities of GTP cyclohydrolase I in the inhibitor-treated cells with its substrate-velocity curve, we estimated that the intracellular concentration of free GTP is 150 microM at which point the activity of GTP cyclohydrolase I is elicited at its maximum velocity. Below this GTP concentration, GTP cyclohydrolase I activity is rapidly decreased. Therefore GTP can be a regulator for tetrahydrobiopterin biosynthesis.     

Purification of GTP cyclohydrolase I from human liver and production of specific monoclonal antibodies

GTP cyclohydrolase I, the first enzyme in the de novo biosynthesis of tetrahydrobiopterin, was enriched more than 13,000-fold from human liver by preparative isoelectric focusing using Sephadex G-200 SF gels. The pI of the active enzyme was determined as 5.6 by analytical isoelectric focusing in the same matrix. The native enzyme has an apparent molecular mass of 440 kDa and appears to be composed of eight 50-kDa subunits as estimated from SDS/PAGE. The enriched enzyme preparation was used to produce specific monoclonal antibodies. From 11 monoclonal antibodies obtained, one was extensively characterized for further applications. This monoclonal antibody belongs to the IgM class and shows immunoreactivity with GTP cyclohydrolase I both from man and from Escherichia coli. It is capable of highly sensitive detection of GTP cyclohydrolase I by ELISA and by Western blot analysis. The monoclonal antibody was used for the immunoenzymatic localisation of GTP cyclohydrolase I in human peripheral blood mononuclear cells. Furthermore, it was possible to demonstrate the absence of immunoreactivity in cells with GTP cyclohydrolase I deficiency. The antibody's use as a tool either for differential diagnosis of atypical phenylketonuria due to GTP cyclohydrolase I deficiency or prenatal diagnosis of this severe inherited metabolic disease is now under investigation.     

Characterization of the Ca2+- and Mg2+-Dependent ATPases in Electrophorus Electroplax Microsomes

Electrophorus electroplax microsomes were examined for Ca2+- and Mg2+-dependent ATPase activity. In addition to the previously reported low-affinity ATPase, a high-affinity (Ca2+,Mg2+)-ATPase was found. At low ATP and Mg2+ concentrations (200 microM or less), the high-affinity (Ca2+,Mg2+)-ATPase exhibits an activity of 18 nmol Pi mg-1 min-1 with 0.58 microM Ca2+. At higher ATP concentrations (3 mM), the low-affinity Ca2+-ATPase predominates, with an activity of 28 nmol Pi mg-1 min-1 with 1 mM Ca2+. In addition, Mg2+ can also activate the low-affinity ATPase (18 nmol Pi mg-1 min-1). The high-affinity ATPase hydrolyzes ATP at a greater rate than it does GTP, ITP, or UTP and is insensitive to ouabain, oligomycin, or dicyclohexylcarbodiimide inhibition. The high-affinity enzyme is inhibited by vanadate, trifluoperazine, and N-ethylmaleimide. Added calmodulin does not significantly stimulate enzyme activity; rinsing the microsomes with EGTA does not confer calmodulin sensitivity. Thus the high-affinity ATPase from electroplax microsomes is similar to the (Ca2+,Mg2+)-ATPase reported to be associated with Ca2+ transport, based on its affinity for calcium and its response to inhibitors. The low-affinity enzyme hydrolyzes all tested nucleoside triphosphates, as well as diphosphates, but not AMP. Vanadate and N-ethylmaleimide do not inhibit the low-affinity enzymes. The low-affinity enzyme reflects a nonspecific nucleoside triphosphatase, probably an ectoenzyme.     

Enzymic characteristics of ecto-adenosine triphosphatase in rat epididymal intact spermatozoa.

Ecto-ATPase in rat cauda-epididymal intact spermatozoa has a high degree of substrate specificity for the hydrolysis of ATP and dATP rather than of ADP, AMP, GTP, dGTP, CTP, dCTP, TTP and UTP. The enzyme is activated by bivalent metal ions in the order Mg2+ greater than Mn2+ greater than Co2+ greater than Ca2+. The apparent Km values of the enzyme for Mg2+, Mn2+, Co2+ and Ca2+ are approx. 80, 100, 100 and 150 microM respectively. Addition of Ca2+ (0.1 or 1 mM) gives no further stimulation of the Mg2+-activated ecto-ATPase activity. The apparent Km value of the enzyme for ATP is 95 microM. Pi (16 mM) inhibits the enzymic activity (by 25%), whereas Na+ (50 mM) or K+ (10 mM) alone or in combination, polyamines (spermine and spermidine; 1--12.5mM) and nucleic acids (yeast RNA and calf thymus DNA; 0.12 or 0.62 mg/ml) had no significant effect on the activity of the enzyme. Orthovanadate at a relatively low concentration (20 microM) strongly inhibits (approx. 50%) the ecto-ATPase activity. Vanadate inhibition can be reversed by noradrenaline (2.5 mM). The vanadate-sensitivity of the enzyme increases markedly during spermatozoal maturation in the epididymis. However, the activity of the spermatozoal ecto-ATPase decreases progressively during the epididymal transit of the testicular spermatozoa.     

Effects of Mn2+ on the exchange reaction of phosphoenolpyruvate carboxykinase in the presence of high concentrations of Mg2+

The mitochondrial phosphoenolpyruvate carboxykinase (GTP:oxaloacetate carboxy-lyase (transphosphorylating), EC 4.1.1.32), purified from chick embryo liver, was synergistically activated by a combination of Mn2+ and Mg2+ in the oxaloacetate ---- H14CO-3 exchange reaction. Increases in the Mg2+ concentration caused decreases in the K0.5 value of Mn2+ in line with the earlier finding that the enzyme was markedly activated by low Mn2+ (microM) plus high Mg2+ (mM). In the presence of 2.5 mM Mg2+, increases in the Mn2+ level first enhanced the activity of phosphoenolpyruvate carboxykinase, and then suppressed it to the maximal velocity shown in the presence of Mn2+ alone. Kinetic studies showed that high Mn2+ inhibited the activity of Mg2+ noncompetitively, and those of GTP and oxaloacetate uncompetitively. The inhibition constant for oxaloacetate (K'i = 550 microM) was lower than that of Mg2+ (Ki = K'i = 860 microM) or GTP (K'i = 1.6 mM), and was nearly equal to the apparent half-maximal inhibition concentration of Mn2+. These results suggested that Mn2+ can play two roles, of activating and suppressing phosphoenolpyruvate carboxykinase activity in the presence of high Mg2+.     

New inhibitors of sepiapterin reductase. Lack of an effect of intracellular tetrahydrobiopterin depletion upon in vitro proliferation of two human cell lines.

N-Acetylserotonin (compound 1) and N-acetyldopamine (compound 7) inhibit bovine adrenal medullary sepiapterin reductase in a manner competitive with the pterin substrate and have Ki values of 0.12 and 0.4 microM, respectively. Molecular modeling suggests that the phenyl rings of the two compounds bind in the pyrimidine pocket of the enzyme with the 3-hydroxyl of dopamine or the 5-hydroxyl of serotonin aligned at the pyrimidine 4-position. Further, the acetyl moieties of the two inhibitors appear to mimic the substrate side chain. Consistent with this analysis, N-acetyl-m-tyramine (compound 13) is also an excellent competitive inhibitor (Ki = 0.13 microM), whereas N-acetyltryptamine (compound 2), N-acetyl-p-tyramine (compound 14) and N-acetylphenylethylamine (compound 15) all bind poorly. Interestingly, restricted-rotation analogs of N-acetyldopamine and N-acetyl-m-tyramine are noncompetitive inhibitors of the enzyme. Modification of N-acetyldopamine to N-chloroacetyldopamine (compound 10) or of N-acetylserotonin to the N-chloroacetyl (5) or N-methoxyacetyl (compound 6) analogs results in greatly increased competitive affinity, with Ki = 0.014 microM for the dopamine analog and 0.006 and 0.008 microM, respectively, for the serotonin analogs. In MOLT-4 T-cell leukemia and MCF-7 breast adenocarcinoma in culture, 0.1 mM N-methoxyacetylserotonin depleted tetrahydrobiopterin by greater than or equal to 97 and greater than 50%, respectively, with no effect upon cell growth. In both cell lines, the GTP cyclohydrolase inhibitor, 2,4-diamino-6-hydroxypyrimidine at 1-5 mM also depleted tetrahydrobiopterin greater than or equal to 97%. In this case, however, modest growth inhibition did occur. Since the growth inhibition could not be reversed upon tetrahydrobiopterin repletion, inhibition was due to other effects of the inhibitor rather than to tetrahydrobiopterin depletion. The results show that there is no effect on cell growth when at least 97% of the tetrahydrobiopterin in these cell lines is depleted. Since the sepiapterin reductase inhibitor depleted tetrahydrobiopterin with fewer nonspecific effects than the cyclohydrolase inhibitor, it will be useful for determining metabolic effects of tetrahydrobiopterin depletion.     

Biosynthesis and metabolism of pterins in peripheral blood mononuclear cells and leukemia lines of man and mouse

The cellular origin and the control of neopterin release associated with immune stimulation was studied in cell cultures. Using purified human mononuclear cells, the intracellular change in concentrations of GTP and pterins was measured under various kinds of stimulation. Three enzymes involved in tetrahydrobiopterin biosynthesis, i.e. GTP cyclohydrolase I, 6-pyruvoyl tetrahydropterin synthase and sepiapterin reductase, were also determined. Human macrophages stimulated with culture supernatant from activated T-lymphocytes were the main producers of neopterin. In these cells, GTP cyclohydrolase I activity was elevated due to high GTP levels and therefore neopterin accumulated. Human macrophages lack 6-pyruvoyl tetrahydropterin synthase activity. Exogenous tetrahydrobiopterin added to the culture medium of stimulated T cells and macrophages suppressed the elevation of GTP cyclohydrolase I activity and neopterin concentration, but not the elevation of intracellular GTP. Stimulation of macrophages with recombinant human interferon-gamma and neutralization of the effect of T cell supernatants by addition of a monoclonal antibody specific for human interferon-gamma showed that immune interferon induced the alterations in GTP cyclohydrolase I activity and neopterin concentration. In the human macrophage line U-937 and in the leukemia line HL-60, no GTP cyclohydrolase I activity or intracellular pterins were detected, but high levels of GTP. In mouse mononuclear cells, no neopterin was detected, but biopterin and pterin. After stimulation, biopterin was elevated in the same way as neopterin in human mononuclear cells. This is explained by the different regulation of the rate-limiting steps of tetrahydrobiopterin biosynthesis in man and in mouse. These results suggest that neopterin is an unspecific marker for the activation of the cellular immune system.     

Effects of sepiapterin and 6-acetyldihydrohomopterin on the guanosine triphosphate cyclohydrolase I of mouse, rat and the fruit-fly Drosophila.

The regulation of GTP cyclohydrolase I would lead to the regulation of tetrahydrobiopterin, an important cofactor for synthesis of neurotransmitters. In an attempt to extend a previous finding [Bellahsene, Dhondt, & Farriaux (1984) Biochem. J. 217, 59-65] that GTP cyclohydrolase I of rat liver is inhibited by subnanomolar concentrations of reduced biopterin and sepiapterin, we found that this could not be verified with the enzyme from mouse liver, fruit-fly (Drosophila) heads or, indeed, from rat liver. It was shown, however, that 12 microM-sepiapterin inhibited mouse liver GTP cyclohydrolase I. Another compound, namely 6-acetyldihydrohomopterin, was also employed in the present study to explore its effect on enzymes that lead to its synthesis in Drosophila and for effects on mammalian systems; at 2-5 microM this compound was shown to stimulate one form of mouse liver GTP cyclohydrolase I and then to inhibit at higher concentrations (40 microM). Neither sepiapterin nor 6-acetyldihydrohomopterin caused any effect on the Drosophila head enzyme. On the other hand, the sigmoid GTP concentration curve for the Drosophila enzyme may indicate a regulatory characteristic of this enzyme. Another report, on the lower level of GTP cyclohydrolase I in mutant mouse liver [McDonald, Cotton, Jennings, Ledley, Woo & Bode (1988) J. Neurochem. 50, 655-657], was confirmed and extended. Instead of having 10% activity, we find that the hph-1 mouse mutant has less than 2% activity in the liver. These studies demonstrate that micromolar levels of reduced pterins may have regulatory effects on GTP cyclohydrolase I and that a mouse mutant is available that has low enough activity to be considered as a model for human atypical phenylketonuria.     

Some properties of the H-ATPase activity present in root plasmalemma of Avena sativa L. Two different enzymes or one enzyme with two ATP sites?

The effects of Mg2+, K+ and ATP on a H-ATPase activity from a native plasmalemma fraction of oat roots were explored at 20 degrees C and pH 6.5. In the presence of 3 mM ATP and no K+, H-ATPase activity vs. [Mg2+] approached a monotonic activation but it became biphasic, with a decline above 3 mM Mg2+, in the presence of 20 mM K+. Mg2+ inhibition occurred also in K-free solutions when [ATP] was lowered to 0.05 mM. Also, an apparent monotonic H-ATPase activation by [K+] at 3.0 mM ATP was transformed in biphasic (inhibition by high [K+]) when [ATP] was reduced to 0.05 mM. The best fits of the ATP stimulation curves of hydrolysis satisfied the sum of two Michaelian functions where that with higher affinity had lower Vmx. Taking into consideration all conditions of activity assay, the high-affinity component (1) had a Km about 11-16 microM and a Vmx around 0.14-0.28 mumol Pi/mg per min whereas that with lower affinity (2) had a Km of 220-540 microM and a Vmx of 0.5-1.0 mumol Pi/mg per min. Km2 was markedly affected by the [K+] and [Mg2+]; at optimal concentrations of these cations (1 mM Mg2+ and 10 mM K+) it had a value of 235 +/- 24 microM which was increased to 540 +/- 35 microM at 20 mM [Mg2+] and 60 mM [K+]. In addition, Vmx1 was reduced to about a half when the concentrations of Mg2+ and K+ were increased to inhibitory levels. These results could be explained by the existence of two different enzymes or one enzyme with two ATP sites. In the second case, we could not tell at this stage if both are catalytic or one is regulatory.     

Role of Mg2+ in activation of NADPH oxidase of human neutrophils: evidence that Mg2+ acts through G-protein.

The membrane fraction and three cytosolic proteins of neutrophils, p47-phox, p67-phox and a G-protein, are involved in the cell-free activation of the O2(-)-generating NADPH oxidase in the presence of SDS, though it has been controversial whether the G-protein is required or just enhancing the activity. We have used the three cytosolic factors, the solubilized membrane fraction, GTP gamma S and SDS, and found that both G-protein and GTP gamma S are essential for the activation of the NADPH oxidase. The effect of GTP gamma S is modified by Mg2+: the cations enhance the O2- generation at low concentrations of GTP gamma S, whereas they attenuate the activity at higher concentrations of GTP gamma S. In presence of 10 microM GTP gamma S, the maximal activity is observed at 0.1 microM Mg2+, which is several-fold higher than that at 1 mM Mg2+. The omission of Mg2+ followed by the chelation with EDTA results in loss of the activation, which is completely restored by the addition of Mg2+. Thus, Mg2+ seems to modulate the activation of the NADPH oxidase at the level of the G-protein.     

Effect of divalent cations on the inhibition of alkylsulfatase induction and the generation of ATP in Pseudomonas aeruginosa after exposure to exogenous uridine 5'-triphosphate.

In the absence of added Mg2+, alkylsulfatase induction in resting cells of Pseudomonas aeruginosa was inhibited 17% by exogenous 0.05 mM UTP. Under these conditions, the cells converted UTP to ATP and rapid degradation of these nucleotides did not occur. In the presence of 0.73 mM Mg2+, 0.05 mM UTP repressed the synthesis of the enzyme by 71%. Under these conditions, the cells rapidly degraded both ATP derived from UTP as well as residual UTP. In the presence of Mg2+ and 0.1 mM UTP, full repression of alkylsulfatase formation occurred whereas Mg2+-depleted cell suspensions were still capable of synthesizing 47% of the enzyme under these conditions compared with control levels. The inhibition of alkylsulfatase induction was highly specific for UTP. Some inhibition was observed with exogenous uracil, uridine, and pyrophosophate but only at concentrations greater than 1.0 mM. Exogenous UMP and UDP (2mM) had no effect.     

Regulation of GTP cyclohydrolase I and dihydropteridine reductase in rat pheochromocytoma PC 12 cells

The addition of 8-bromo cyclic AMP, forskolin, theophylline, and 3-isobutyl-1-methylxanthine to the medium of PC 12 cells resulted in an increase in GTP cyclohydrolase I activity, but had no effect on dihydropteridine reductase activity, except theophylline which caused a decrease in dihydropteridine reductase activity at 96 h. GTP cyclohydrolase I activity peaked at 24 h and returned to normal 96 h after drug treatment. Cycloheximide decreased GTP cyclohydrolase I activity at 48 and 96 h, but had little effect on dihydropteridine reductase activity. The addition of reserpine selectively increased only GTP cyclohydrolase I activity. The addition of tetrahydrobiopterin and sepiapterin, however, coordinately inhibited both GTP cyclohydrolase I and dihydropteridine reductase activities. It appears that GTP cyclohydrolase I activity in PC 12 cells is regulated by cyclic AMP stimulation and by end-product inhibition, whereas dihydropteridine reductase activity is only subject to pterin inhibition.     

Interaction of sodium and potassium ions with Na+,K+-ATPase. II. General properties of ouabain-sensitive K+ binding

General properties of ouabain-sensitive K+ binding to purified Na+,K+-ATPase [EC 3.6.1.3] were studied by a centrifugation method with 42K+. 1) The affinity for K+ was constant at pH values higher than 6.4, and decreased at pH values lower than 6.4. 2) Mg2+ competitively inhibited the K+ binding. The dissociation constant (Kd) for Mg2+ of the enzyme was estimated to be about 1 mM, and the ratio of Kd for Mg2+ to Kd for K+ was 120 : 1. The order of inhibitory efficiency of divalent cations toward the K+ binding was Ba2+ congruent to Ca2+ greater than Zn2+ congruent to Mn2+ greater than Sr2+ greater than Co2+ greater than Ni2+ greater than Mg2+. 3) The order of displacement efficiency of monovalent cations toward the K+ binding in the presence or absence of Mg2+ was Tl+ greater than Rb+ greater than or equal to (K+) greater than NH4+ greater than or equal to Cs+ greater than Na+ greater than Li+. The inhibition patterns of Na+ and Li+ were different from those of other monovalent cations, which competitively inhibited the K+ binding. 4) The K+ binding was not influenced by different anions, such as Cl-, SO4(2-), NO3-, acetate, and glycylglycine, which were used for preparing imidazole buffers. 5) Gramicidin D and valinomycin did not affect the K+ binding, though the former (10 micrograms/ml) inhibited the Na+,K+-ATPase activity by about half. Among various inhibitors of the ATPase, 0.1 mM p-chloromercuribenzoate and 0.1 mM tri-n-butyltin chloride completely inhibited the K+ binding. Oligomycin (10 micrograms/ml) and 10 mM N-ethylmaleimide had no effect on the K+ binding. In the presence of Na+, however, oligomycin decreased the K+ binding by increasing the inhibitory effect of Na+, whether Mg2+ was present or not. 6) ATP, adenylylimido diphosphate and ADP each at 0.2 mM decreased the K+ binding to about one-fourth of the original level at 10 microM K+ without MgCl2 and at 60 microM K+ with 5 mM MgCl2. On the other hand, AMP, Pi, and p-nitrophenylphosphate each at 0.2 mM had little effect on the K+ binding.     

Characterization of a High-Affinity Mg2+-Independent Ca2+-ATPase from Rat Brain Synaptosomal Membranes

A high-affinity Mg2+-independent Ca2+-ATPase (Ca2+-ATPase) has been differentiated from the Mg2+-dependent, Ca2+-stimulated ATPase (Ca2+,Mg2+-ATPase) in rat brain synaptosomal membranes. Using ATP as a substrate, the K0.5 of Ca2+ for Ca2+-ATPase was found to be 1.33 microM with a Km for ATP of 19 microM and a Vmax of 33 nmol/mg/min. Using Ca-ATP as a substrate, the Km for Ca-ATP was found to be 0.22 microM. Unlike Ca2+,Mg2+-ATPase, Ca2+-ATPase was not inhibited by N-ethylmaleimide, trifluoperazine, lanthanum, zinc, or vanadate. La3+ and Zn2+, in contrast, stimulated the enzyme activity. Unlike Ca2+, Mg2+-ATPase activity, ATP-dependent Ca2+ uptake was negligible in the absence of added Mg2+, indicating that the Ca2+ transport into synaptosomal endoplasmic reticulum may not be a function of the Ca2+-ATPase described. Ca2+-ATPase activity was not stimulated by the monovalent cations Na+ or K+. Ca2+, Mg2+-ATPase demonstrated a substrate preference for ATP and ADP, but not GTP, whereas Ca2+-ATPase hydrolyzed ATP and GTP, and to a lesser extent ADP. The results presented here suggest the high-affinity Mg2+-independent Ca2+-ATPase may be a separate form from Ca2+,Mg2+-ATPase. The capacity of Mg2+-independent Ca2+-ATPase to hydrolyze GTP suggests this protein may be involved in GTP-dependent activities within the cell.     

Deoxythymidine kinase induced in the HELA TK- cells by herpes simplex virus type I and type II. Substrate specificity and kinetic behavior.

Deoxythymidine kinases (EC 2.7.1.--) induced in HeLa TK- cells by Herpes simplex Type I and Type II viruses both had a requirement for divalent cations. The enzymes had the highest activities in the presence of Mg2+, followed by Mn2+, Ca2+, Fe2+, and in that order, whereas they were inactive in the presence of Zn2+ and Cu2+. The amount of Mg2+ required for optimal activity was dependent on the amount of ATP present, so that optimal activities were found when the concentration of Mg2+ was equal to that of ATP; an excess of Mg2+ inhibited the reaction. The activities of various nucleoside triphosphates as phosphate donors for Herpes simplex virus Type I deoxythymidine kinase were in the order: ATP = dATP = ara ATP greater than CTP greater than dCTP greater than UTP greater than dUTP greater than GTP greater than dGTP. Those for Herpes simplex virus Type II deoxythymidine kinase were in the order: CTP greater than dCTP = ara CTP greater than dATP greater than ATP greater than UTP greater than GTP greater than dUTP = dGTP. For both deoxythymidine kinases induced by Herpes simplex virus, the nucleoside triphosphates tested exerted cooperative effects. The Km values of ATP and CTP for the Herpes simplex virus Type I enzyme were 30 and 70 muM respectively; whereas those for the Herpes simplex virus Typr II enzyme were 140 and 450 muM. Studies on binding of various thymidine analogs with free 5'-OH to these deoxythymidine kinases indicated that 5-substituted ethyl-, vinyl-, allyl-, propyl-, iodo- and bromo-dUrd as well as iodo5 dCyd and bromo5 dCyd had good affinity to both enzymes. In contrast, vinyl5 Urd, iodo5 Urd and arabinosylthymidine had good affinity only to the Herpes simplex virus Type I enzyme but not to the Herpes simplex virus Type II deoxythymidine kinase. All of these thymidine analogs were competitive inhibitors, with KI values in the range of 0.25 to 1.5 muM. Herpes simplex virus Type I deoxythymidine kinase was less sensitive to either dTTP or iodo dUTP inhibition than Herpes simplex virus Type II. Both dThd and dCyd could serve as substrates and competed with each other for Herpes simplex viruses Type I and Type II induced kinases, but they differed in their Km values for these enzymes. The Km values of dThd and dCyd were 0.59 muM and 25 muM for Herpes simplex virus Type I deoxythymidine kinase; while they were 0.36 muM and 88 muM respectively for the Herpes simplex virus Type II enzyme.     

Effects of metal ions on sphingomyelinase activity of Bacillus cereus

Some divalent metal ions were examined for their effects on sphingomyelinase activity of Bacillus cereus. The enzyme activity toward mixed micelles of sphingomyelin and Triton X-100 proved to be stimulated by Co2+ and Mn2+, as well as by Mg2+. Km's for Co2+ and Mn2+ were 7.4 and 1.7 microM, respectively, being smaller than the Km for Mg2+ (38 microM). Sr2+ proved to be a competitive inhibitor against Mg2+, with a Ki value of 1 mM. Zn2+ completely abolished the enzyme activity at concentrations above 0.5 mM. The concentration of Zn2+ causing 50% inhibition of the enzyme activity was 2.5 microM. Inhibition by Zn2+ was not restored by increasing concentrations of Mg2+ when the concentration of Zn2+ was above 10 microM. Ba2+ was without effect. When sphingomyelinase was incubated with unsealed ghosts of bovine erythrocytes at 37 degrees C, the enzyme was significantly adsorbed onto the membrane in the presence of Mn2+, Co2+, Sr2+ or Ba2+. Incubation with intact or Pronase-treated erythrocytes caused enzyme adsorption only in the presence of Mn2+. In the course of incubation, the enzyme was first adsorbed on the membranes of intact bovine erythrocytes in the presence of Mn2+; then sphingomyelin breakdown proceeded with ensuing desorption of adsorbed enzyme. Hot-cold hemolysis occurred in parallel with sphingomyelin breakdown. In this case, the hydrolysis of membranous sphingomyelin as well as the initial enzyme adsorption took place in the following order: unsealed ghosts greater than Pronase-treated erythrocytes greater than intact erythrocytes.     

Energy interconversion in sarcoplasmic reticulum vesicles in the presence of Ca2+ and Sr2+ gradients

Sarcoplasmic reticulum vesicles of rabbit skeletal muscle are able to accumulate Ca2+ or Sr2+ at the expense of ATP hydrolysis. Depending on the conditions used, vesicles loaded with Ca2+ can catalyze either an ATP in equilibrium Pi exchange or the synthesis of ATP from ADP and Pi. Both reactions are impaired in vesicles loaded with Sr2+. The Sr2+ concentration required for half-maximal ATPase activity increases from 2 microM to 60-70 microM when the Mg2+ concentration is raised from 0.5 to 50 mM. The enzyme is phosphorylated by ATP in the presence of Sr2+. The steady state level of phosphoenzyme varies depending on both the Sr2+ and Mg2+ concentrations in the medium. Phosphorylation of the enzyme by Pi is inhibited by both Ca2+ and Sr2+. In the presence of 2 and 20 mM Mg2+, half-maximal inhibition is attained in the presence of 4 and 8 microM Ca2+ or in the presence of 0.24 mM and more than 2 mM Sr2+, respectively. After the addition of Sr2+, the phosphoenzyme is cleaved with two different rate constants, 0.5-1.5 s-1 and 10-18 s-1. The fraction of phosphoenzyme cleaved at a slow rate is smaller the higher the Sr2+ concentration in the medium. Ca2+ inhibition of enzyme phosphorylation by Pi is overcome by the addition of ITP. This is not observed when Ca2+ is replaced by Sr2+.     

Purification and characterization of rat liver GTP cyclohydrolase I. Cooperative binding of GTP to the enzyme

GTP cyclohydrolase I, an enzyme that catalyzes the first step in the biosynthetic pathway of tetrahydrobiopterin, has been purified about 38,000-fold to apparent homogeneity from rat liver extract with a yield of 5%. The molecular weight of the enzyme was estimated to be 300,000 by gel filtration on Ultrogel AcA 34. The purified enzyme gave a single band on sodium dodecyl sulfate-polyacrylamide gel electrophoresis at a position corresponding to a molecular weight of 30,000. N-terminal amino acid sequence analysis gave a single amino acid at every step of the Edman degradation up to residue 10. These results suggest that the enzyme is probably a homopolymer. The enzyme showed positive cooperativity with a Hill coefficient of 2.4 at a substrate (GTP) concentration of 10-50 microM. The Vmax value of the enzyme was 45 nmol/min.mg protein. The GTP concentration producing half-maximal velocity was 30 microM at a KCl concentration of 0.1 M. This value increased as the KCl concentration rose, without any change in Vmax or Hill number. Biosynthesis of tetrahydrobiopterin may be controlled by the intracellular level of GTP.