Inhibition of tryptophanyl-tRNA synthetase by modifying ATP analogs

The interaction between tryptophanyl-tRNA synthetase (EC 6.1.1.2) from beef pancreas and the ATP analogs containing alkylating or phosphorylating groups in the polyphosphate moiety of ATP was studied as an approach to investigate the structure of the enzyme active center. Some of the compounds under study were shown to irreversibly inhibit the enzyme activity; the presence of ATP in the most cases protects the enzyme against inactivation. The kinetic constants Ki and k2 of interaction of the irreversible inhibitors with the enzyme were determined. It was found that the Ki values for a number of irreversible competitive inhibitors are by 1-2 orders of magnitude less than the Km value for ATP; the k2 values were found equal to 0.02-0.04 min-1. this suggests that the compounds may be used as affinity reagents, the most efficient ones being adenosine 5'-(beta-chloroethyl phosphate) and mixed AMP-mesithylene carbonic acid anhydride. The absence of a protective effect of ATP in the case of adenosine 5'-(beta-bromoethane phosphonate) and non-competitive type of reversible inhibition inhibition of the enzyme by adenosine 5'-chloromethane phosphonate indicate that the molecule of tryptophanyl-tRNA synthetase contains sites interacting with adenine nucleotides, other than the ATP binding sites of the active center.     

Interaction of Na,K-ATPase with modifying ATP analogs and chloromethylphosphonic acid

The interaction of synthetic ATP analogs, containing active groups in the triphosphate moiety and in the 8-position of the nucleotide molecule, with highly purified Na, K-ATPase from the medullar layer of porcine kidney was studied. It was found that 11 out of 17 ATP analogs studied irreversibly inhibit the ATPase activity of the enzyme. The pH optimum of the enzyme inactivation by adenosine-5'-(beta-chloroethylphosphate) and adenosine-5'-(p-fluorosulfonylphenylphosphate) beside the pronounced protective effect of ATP suggests possible covalent blocking of histidine and dicarboxylic amino acid residues in the enzyme active center. The irreversible inhibition of the enzyme by "oxo-ATP" containing aldehyde groups in the modified ribose residue in the presence of sodium borohydride suggests a possible presence of the lysine residue epsilon-amino group in the ATP binding site of the enzyme. Na, K-ATPase was found to possess an inorganic phosphate binding site, which is specifically blocked by chloromethylphosphonic acid. the accessibility of this site for modification depends on ATP, NA+ and K+.     

Interaction of N1-, N6- and C8-substituted derivatives of adenosine-5'-triphosphate with the catalytic subunit of cAMP-dependent protein kinase from rabbit skeletal muscles

In order to investigate the structure of the active site of the cAMP-dependent protein kinase catalytic subunit a synthesis of several previously unknown adenosine-5'-triphosphate (ATP) derivatives containing substituents of various nature at N(1), N(C6) and C(8) positions of the purine base was carried out. The interaction of these derivatives with a homogeneous preparation of the catalytic subunit of rabbit skeletal muscle cAMP-dependent protein kinase was investigated. All the nucleotide analogs were found to inhibit the enzyme activity; the inhibition was competitive with respect to ATP. It was assumed that the adenine moiety of the ATP molecule is bound to the active site of protein kinase by the hydrophobic interaction with the aromatic amino acid residues and by formation of the hydrogen bond between the exo-NH2-group of the substrate and a corresponding group of the enzyme. The "correct" binding of ATP to the enzyme active center is defined by the anti-conformation of the nucleotide.     

Substrate specificity of T4 RNA-ligase. The role of phosphate nucleotide residues in the formation of a covalent AMP-RNA-ligase complex]

The inhibiting effect of adenosine, AMP, ADP, ATP, gamma-thio ATP (I), beta,gamma-imine ATP (II), beta,gamma-methylene ATP (III), P1,P3-di(adenosine-5') triphosphate (IV), P1,P4-di(adenosine-5') tetraphosphate (V) and adenosine 5'-tetraphosphate (VI) on the first step of the T4 RNA ligase reaction was studied. All the compounds tested, with the exception of adenosine, appeared to be competitive inhibitors of the first step of the enzymatic reaction. The inhibition constants (Ki) for the ATP analogs were determined. The data obtained suggest that the efficiency of inhibition depends on the number of phosphate groups and on the structure of ATP analogs. All the compounds under study (I-VI), except for AMP and ADP, form covalent AMP-RNA ligase complexes.     

Purification and characterization of a smooth muscle myosin phosphatase from turkey gizzards

A phosphoprotein phosphatase that dephosphorylates smooth muscle myosin has been purified to apparent homogeneity from turkey gizzards. Smooth muscle phosphatase (SMP) IV has a molecular weight of 150,000 as determined by gel filtration on a Sephadex G-200 column and is composed of two subunits (Mr = 58,000 and 40,000). Although it is active toward a number of proteins, its activities toward the contractile proteins, intact myosin, heavy meromyosin, and isolated myosin light chains are higher than its activities toward phosphorylase alpha, histone IIA, and phosphorylase kinase. SMP-IV preferentially dephosphorylates the beta-subunit of phosphorylase kinase. The properties of the enzyme have been studied using heavy meromyosin, a soluble chymotryptic fragment of myosin, and isolated myosin light chains as substrates. SMP-IV has high affinity for both substrates and is optimally active at neutral pH. Divalent cations, Ca2+ and Mg2+, activate the dephosphorylation of heavy meromyosin but inhibit the activity toward myosin light chains. Low concentrations of ATP (1-5 mM) activate SMP-IV but concentrations higher than 5 mM are inhibitory. Inhibition of 50% of the activity of the enzyme by NaF and PPi requires concentrations higher than 10 mM. Rabbit skeletal muscle heat stable inhibitor-2 has no effect on the activity of SMP-IV toward heavy meromyosin, myosin light chains, and phosphorylase alpha.     

An affinity label for the regulatory dithiol of ribulose-5-phosphate kinase from maize (Zea mays).

Ribulose-5-phosphate kinase from maize (Zea mays) can exist in either a reduced, active form or an oxidized, inactive form. Reduced ribulose-5-phosphate kinase is rapidly and irreversibly inactivated by the dichlorotriazine dye Reactive Red 1 (Procion Red MX-2B), but the irreversible inactivation of the oxidized form of ribulose-5-phosphate kinase occurs at only 0.05% of this rate. The rate of inactivation of the reduced enzyme by Reactive Red 1 (apparent bimolecular rate constant 10(4)M-1 X s-1 at pH 7.4 and 25 degrees C) is several orders of magnitude greater than previous estimates of the rates of dye-mediated inactivation of other enzymes. The dye-dependent inactivation of the reduced enzyme is inhibited by Hg2+ or p-mercuribenzoate (thiol reagents that reversibly inhibit ribulose-5-phosphate kinase activity), or by ATP and ADP, the nucleotide substrates of the enzyme. Hydrolysed Reactive Red 1, which does not inactivate the enzyme, is a reversible inhibitor of ribulose-5-phosphate kinase. This inhibition is competitive with respect to ATP (Ki approximately 0.5 mM). The dye appears to act as an affinity label for the ATP/ADP-binding site by preferentially arylating a thiol residue generated during the reductive activation of the enzyme that is achieved by dithiothreitol or thioredoxin in vitro or during illumination of leaves.     

The MgATP-dependent protein phosphatase and protein phosphatase 1 have identical substrate specificities

The MgATP-dependent phosphorylase phosphatase was found to have a broad substrate specificity. Its activity against all phosphoproteins tested was dependent upon preincubation with the activating factor FA and MgATP. The enzyme dephosphorylated and inactivated phosphorylase kinase and inhibitor 1, and dephosphorylated and activated glycogen synthase and acetyl-CoA carboxylase. Glycogen synthase was dephosphorylated at similar rates whether it had been phosphorylated by cyclic-AMP-dependent protein kinase, phosphorylase kinase or glycogen synthase kinase 3. The enzyme also catalysed the dephosphorylation of ATP citrate lyase, initiation factor eIF-2, and troponin I. The properties of the MgATP-dependent protein phosphatase from either dog liver or rabbit skeletal muscle showed a remarkable similarity to highly purified preparations of protein phosphatase 1 from rabbit skeletal muscle. The relative activities of the two enzymes against all phosphoproteins tested was very similar. Both enzymes dephosphorylated the beta-subunit of phosphorylase kinase 40-fold faster than the alpha-subunit, and both enzymes were inhibited by identical concentrations of the two proteins termed inhibitor 1 and inhibitor 2, which inhibit protein phosphatase 1 specifically. These results demonstrate that the MgATP-dependent protein phosphatase is a type-1 protein phosphatase, and is distinct from type-2 protein phosphatases which dephosphorylate the alpha-subunit of phosphorylase kinase and are unaffected by inhibitor 1 and inhibitor 2. The possibility that the MgATP-dependent protein phosphatase is an inactive form of protein phosphatase 1 and that both proteins share the same catalytic subunit is discussed.     

Inactivation and reactivation of liver phosphorylase b kinase.

When crude rat liver preparations were incubated at 30degrees C, a gradual loss of phosphorylase kinase (ATP:phosphorylase b phosphotransferase, EC 2.7.1.38) activity was observed. This inactivation was Mg2+ dependent and was partially inhibited by sodium fluoride. Addition of Mg2+ ATP to the liver preparations, at any time throughout the incubation, caused a reactivation of the phosphorylase kinase and this was accelerated by micromolar concentrations of cyclic AMP. The reactivation process could be completely abolished by the addition of a heat stable protein kinase inhibitor, implicating cyclic AMP dependent protein kinase in the activation reaction. Both the low and the high activity forms of the enzyme required micromolar quantities of Ca2+ for full activity (KA = 0.6 micronM). The two forms exhibit quite different pH dependencies and at the physiological pH of liver (pH 7.4) their activities differed by a factor of 5-10. Conversion of the lower activity form into the higher seems to affect only the V - Km for muscle phosphorylase b (EC 2.4.1.1) was about 1 mg/ml for both enzyme forms.     

Rat liver 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase. Identification of essential sulfhydryl residues in the primary sequence of the enzyme

The kinase and sugar phosphate exchange reactions of rat liver 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase were inactivated by treatment with 5'-p-fluorosulfonylbenzoyladenosine or 8-azido-ATP, but activity could be restored by the addition of dithiothreitol. This inactivation was accompanied by incorporation of 5'-p-sulfonylbenzoyl[8-14C]adenosine into the enzyme that was not released by the addition of dithiothreitol. The lack of effect of ATP analogs on the ATP/ADP exchange or on bisphosphatase activity and reversal of their effects on the kinase and sugar phosphate reactions by dithiothreitol suggest that 1) they reacted with sulfhydryl groups important for sugar phosphate binding in the kinase reaction, and 2) the inactivation of the kinase by these analogs involves a specific reaction that is not related to their general mechanism of attacking nucleotide-binding sites. In addition, alkylation of the enzymes' sulfhydryls with iodoacetamide prevented inactivation by 5'-p-fluorosulfonylbenzoyladenosine, suggesting that the same thiols were involved. o-Iodosobenzoate inactivated the kinase and sugar phosphate exchange; the inactivation was reversed by dithiothreitol; but there was no effect on the bisphosphatase or nucleotide exchange, indicating that oxidation occurred at the same sulfhydryl that are associated with sugar phosphate binding. ATP or ADP, but not fructose 6-phosphate, protected these groups from modification by 5'-p-fluorosulfonylbenzoyladenosine, 8-azido-ATP, and o-iodosobenzoate. ATP also induced dramatic changes in the circular dichroism spectrum of the enzyme, suggesting that adenine nucleotide protection of thiol groups resulted from changes in enzyme secondary structure. Analysis of cyanogen bromide fragments of 14C-carboxamidomethylated enzyme showed that all radioactivity was associated with cysteinyl residues in a single cyanogen bromide fragment. Three of these cysteinyl residues are clustered in a 38-residue region, which probably plays a role in maintaining the conformation of the kinase sugar phosphate-binding site.     

Nucleotide binding to human UMP-CMP kinase using fluorescent derivatives -- a screening based on affinity for the UMP-CMP binding site

Methylanthraniloyl derivatives of ATP and CDP were used in vitro as fluorescent probes for the donor-binding and acceptor-binding sites of human UMP-CMP kinase, a nucleoside salvage pathway kinase. Like all NMP kinases, UMP-CMP kinase binds the phosphodonor, usually ATP, and the NMP at different binding sites. The reaction results from an in-line phosphotransfer from the donor to the acceptor. The probe for the donor site was displaced by the bisubstrate analogs of the Ap5X series (where X = U, dT, A, G), indicating the broad specificity of the acceptor site. Both CMP and dCMP were competitors for the acceptor site probe. To find antimetabolites for antivirus and anticancer therapies, we have developed a method of screening acyclic phosphonate analogs that is based on the affinity of the acceptor-binding site of the human UMP-CMP kinase. Several uracil vinylphosphonate derivatives had affinities for human UMP-CMP kinase similar to those of dUMP and dCMP and better than that of cidofovir, an acyclic nucleoside phosphonate with a broad spectrum of antiviral activities. The uracil derivatives were inhibitors rather than substrates of human UMP-CMP kinase. Also, the 5-halogen-substituted analogs inhibited the human TMP kinase less efficiently. The broad specificity of the enzyme acceptor-binding site is in agreement with a large substrate-binding pocket, as shown by the 2.1 A crystal structure.     

Purification and characterization of a phosphoprotein phosphatase from bovine adrenal cortex.

A phosphoprotein phosphatase which is active against chemically phosphorylated protamine has been purified about 500-fold from bovine adrenal cortex. The enzyme has a pH optimum between 7.5 and 8.0, and has an apparent Km for phosphoprotamine of about 50 muM. The hydrolysis of phosphoprotamine is stimulated by salt, and by Mn2+. Hydrolysis of phosphoprotamine is inhibited by ATP, ADP, AMP, and Pi, but is not affected by AMP or cyclic GMP. The purified phosphoprotein phosphatase preparation also dephosphorylates p-nitrophenyl phosphate and phosphohistone, and catalyzes the inactivation of liver phosphorylase, the inactivation of muscle phosphorylase a (and its conversion to phosphorylase b), and the inactivation of muscle phosphorylase b kinase. Phosphatase activities against phosphoprotamine and muscle phosphorylase a copurify over the last three stages of purification. Phosphoprotamine inhibits phosphorylase phosphatase activity, and muscle phosphorylase a inhibits the dephosphorylation of phosphoprotamine. These results suggest that one enzyme possesses both phosphoprotamine phosphatase and phosphorylase phosphatase activities. The stimulation of phosphorylase phosphatase activity, but not of phosphoprotamine phosphatase activity, by caffeine and by glucose, suggests that the different activities of this phosphoprotein phosphatase may be regulated separately.     

Regulation of glycogen metabolism in liver by the autonomic nervous system. VI. Possible mechanism of phosphorylase activation by the splanchnic nerve.

The effects of autonomic-nerve stimulation on the activities of phosphorylase (EC 2.4.1.1), dephospho-phosphorylase kinase (EC 2.7.1.38) and phosphorylase phosphatase (EC 3.1.3.17), and on the concentration of adenosine 3', 5'-monophosphate in rabbit liver were investiaged. Results were compared with the effects of epinephrine and glucagon on these enzymes. 1. The acitivity of liver phosphorylase increased rapidly and markedly on electrical stimulation of the splanchnic nerve, or after intraportal administration of epinephrine or glucagon. The activity was not affected by vagal stimulation. 2. The activity of dephospho-phosphorylase kinase increased about 2--3-fold 1 min after injections of epinephrine and glucagon, glucagon causing more activation than epinephrine. The enzyme activity was not altered by splanchnic-nerve, or vagal stimulation. 3. Injections of epinephrine and glucagon caused marked elevation of liver adenosine 3', 5'-monophosphate within a few minutes. With epinephrine, the nucleotide concentration rose to a maximum after 1 min and amounted to about 3-fold increase, while with glucagon the maximum increase of approximately 8-fold increase was observed after 2 min. Stimulation of the splanchnic nerve for 10 min did not affect the adenosine 3', 5'-monophosphate level in the liver. Vagal stimulation also had no effect on the level. 4. The activity of phosphorylase phosphatase decreased promptly (within 30 s) and markedly on splanchnic-nerve stimulation, but did not change significantly on administration of epinephrine of glucagon. A small but insignificant increase in phosphatase activity wasobserved upon vagal stimulation. 5. The effect of Ca-2+ on purified dephospho-phosphorylase kinase was studied. The activity was found to depend partially on free Ca-2+ at low Ca-2+ concentrations (1-10-minus 7--1-10-minus 5 M). 6. These results suggest that the rise in hepatic phosphorylase content upon splanchnic-nerve stimulation, unlike that induced by epinephrine and glucagon, is not mediated by adenosine 3', 5'-monophosphate and subsequent activation of dephospho-phosphorylase kinase, but rather by inactivation of phosphorylase phosphatase. The possible existence of a new factor in this mechanism is discussed.     

Compartmentalized protein phosphorylation/dephosphorylation in glycogen particles from rabbit skeletal muscle

Activation of phosphorylase in intact glycogen particles from skeletal muscle by Ca2+ and MgATP is known as flash activation. By using [gamma-32P]ATP to monitor protein phosphorylation, we have demonstrated that there is, coincident with phosphorylase activation and inactivation, coordinated phosphorylation/dephosphorylation of phosphorylase, glycogen synthase, the beta-subunit of phosphorylase kinase and proteins of Mr = 43,000 and 32,000. Our results show that within the glycogen particle phosphorylase kinase and type-1 protein phosphatase are organized to allow access to a set of protein components. This arrangement may contribute to the reciprocal regulation of their activities.     

Rabbit muscle glycogen-bound phosphoprotein phosphatases: substrate specificities and effects of inhibitor-1

A phosphoprotein phosphatase which has an apparent molecular weight of 240,000 was partially purified (500-fold) from the glycogen-protein complex of rabbit skeletal muscle. The enzyme exhibited broad substrate specificity as it dephosphorylated phosphorylase, phosphohistones, glycogen synthase, phosphorylase kinase, regulatory subunit of cAMP-dependent protein kinase, and phosphatase inhibitor 1. The phosphatase showed high specificity towards dephosphorylation of the beta-subunit of phosphorylase kinase and site 2 of glycogen synthase. With the latter substrate, the presence of phosphate in sites 1a and 1b decreased the apparent Vmax, perhaps by inhibiting the dephosphorylation of site 2. The phosphorylated form of inhibitor 1 did not significantly inhibit this high-molecular-weight phosphatase. However, an inhibitor 1-sensitive phosphatase activity could be derived from this preparation by limited trypsinization. Furthermore, greater than 70% of the phosphatase activity in skeletal muscle extracts and in the glycogen-protein complex was insensitive to inhibitor 1. Limited trypsinization of each fraction obtained from the phosphatase purification increased the total activity (1.5- to 2-fold) and converted the enzyme into a form which was inhibited by inhibitor 1. The results suggest that inhibitor 1-sensitive phosphatase may be a proteolyzed enzyme.     

Inactivation and reactivation of phosphoprotein phosphatase of rabbit skeletal muscle. Role of ATP and divalent metal ions.

The regulatory mechanism of a phosphoprotein phosphatase (EC 3.1.3.16), which is considered to catalyze the dephosphorylation reaction of several phosphoproteins (glycogen synthetase-D (EC 2.4.1.11), phospho-form of phosphorylase b kinase (EC 2.7.1.38), phosphohistone and phosphorylase a (EC 2.4.1.1)), was studied with partially purified preparations from rabbit skeletal muscle. Time- and temperature-dependent inactivation and reactivation of phosphohistone phosphatase, as well as phosphorylase phosphatase (EC 3.1.3.17), were observed on pre0incubation of the enzyme(s) with ATP, and subsequent incubation with divalent metal ions (Mg2+, Mn2+, or Co2+) without any change of molecular size. Manganese, however, instantly restored the activity of the ATP-inactivated enzyme, and increased the maximal velocity of the enzyme while decreasing its affinity to phosphorylase a. However, the metal ion inhibited the reactivated enzyme competively with respect to phosphorylase a. It is suggested that phosphoprotein phosphatase(s) is a metalloenzyme, and that ATP results in a conformational change of the enzyme protein in such a way that a metal ion can be easily released due to the chelating effect of ATP, or incorporated (in the presence of excess metal ions) into the enzyme protein.     

Regulation of urocaninase activity in the liver: role of 3',5'-AMP]

A dependence of rat liver urocaninase activity on the agents affecting the adenylate cyclase system was studied in vitro and in vivo. Urocaninase is considerably activated after the injection of glucagone, NaF, theophylline and 3',5'-AMP. Under conditions optimal for the protein kinase activity of phosphorylase the urocaninase of liver extracts was activated 7-fold on the average. The nezyme retains its activity after gel-filtration through Sephadex G-25 and is capable of inactivation in the presence of Mg2+ and of reactivation after addition of ATP and 3',5'-AMP. These data suggest a possibility of regulation of mammalian liver urocaninase activity by 3',5'-AMP-dependent phosphorylation of the enzyme. Derivatives of hypoxanthine (theophylline and caffeine) in concentration 10(-4) M activate urocaninase in liver extracts 2--3 and 1.5-fold respectively. The activation is probably not due to the 3',5'-AMP phosphodiesterase inhibition, since another phosphodiesterase inhibitor--papaverine--has no activating effect on urocaninase.     

Comparison of the substrate specificities of protein phosphatases involved in the regulation of glycogen metabolism in rabbit skeletal muscle.

Muscle extracts were subjected to fractionation with ethanol, chromatography on DEAE-cellulose, precipitation with (NH4)2SO4 and gel filtration on Sephadex G-200. These fractions were assayed for protein phosphatase activities by using the following seven phosphoprotein substrates: phosphorylase a, glycogen synthase b1, glycogen synthase b2, phosphorylase kinase (phosphorylated in either the alpha-subunit or the beta-subunit), histone H1 and histone H2B. Three protein phosphatases with distinctive specificities were resolved by the final gel-filtration step and were termed I, II and III. Protein phosphatase-I, apparent mol.wt. 300000, was an active histone phosphatase, but it accounted for only 10-15% of the glycogen synthase phosphatase-1 and glycogen synthase phosphatase-2 activities and 2-3% of the phosphorylase kinase phosphatase and phosphorylase phosphatase activity recovered from the Sephadex G-200 column. Protein phosphatase-II, apparent mol.wt. 170000, possessed histone phosphatase activity similar to that of protein phosphatase-I. It possessed more than 95% of the activity towards the alpha-subunit of phosphorylase kinase that was recovered from Sephadex G-200. It accounted for 10-15% of the glycogen synthase phosphatase-1 and glycogen synthase phosphatase-2 activity, but less than 5% of the activity against the beta-subunit of phosphorylase kinase and 1-2% of the phosphorylase phosphatase activity recovered from Sephadex G-200. Protein phosphatase-III was the most active histone phosphatase. It possessed 95% of the phosphorylase phosphatase and beta-phosphorylase kinase phosphatase activities, and 75% of the glycogen synthase phosphatase-1 and glycogen synthase phosphatase-2 activities recovered from Sephadex G-200. It accounted for less than 5% of the alpha-phosphorylase kinase phosphatase activity. Protein phosphatase-III was sometimes eluted from Sephadex-G-200 as a species of apparent mol.wt. 75000(termed IIIA), sometimes as a species of mol.wt. 46000(termed IIIB) and sometimes as a mixture of both components. The substrate specificities of protein phosphatases-IIA and -IIB were identical. These findings, taken with the observation that phosphorylase phosphatase, beta-phosphorylase kinase phosphatase, glycogen synthase phosphatase-1 and glycogen synthase phosphatase-2 activities co-purified up to the Sephadex G-200 step, suggest that a single protein phosphatase (protein phosphatase-III) catalyses each of the dephosphorylation reactions that inhibit glycogenolysis or stimulate glycogen synthesis. This contention is further supported by results presented in the following paper [Cohen, P., Nimmo, G.A. & Antoniw, J.F. (1977) Biochem. J. 1628 435-444] which describes a heat-stable protein that is a specific inhibitor of protein phosphatase-III.     

Modification of human erythrocyte pyruvate kinase by an active site-directed reagent: bromopyruvate

Human erythrocyte pyruvate kinase was modified with bromopyruvate and the kinetic behavior of the modified enzyme was investigated. When the enzyme was modified with bromopyruvate in the absence of adenosine-5'-diphosphate, phosphoenolpyruvate or fructose-1,6-diphosphate the inactivation followed a pseudo first-order kinetics. The inactivation rate constant, ks, was 1.84 +/- 0.15 min(-1). Kd of the bromopyruvate-enzyme complex was 0.14 +/- 0.03 mM. The presence of adenosine-5'-diphosphate, phosphoenolpyruvate or fructose-1,6-diphosphate in the modification medium or the presence of fructose-1,6-diphosphate in the assay medium resulted in deviation of the inactivation kinetics from pseudo first-order. Phosphoenolpyruvate was better than adenosine-5'-diphosphate for protection against bromopyruvate modification whereas fructose-1,6-diphosphate was ineffective. The modified enzyme showed negative cooperativity in the presence of fructose-1,6-diphosphate whereas in the absence of it no activity was detected.     

Histochemical studies on phosphorylase activity in the tissues of the albino rat under normal and experimental conditions

Summary Various substrate mixtures have been tested for the histochemical demonstration of phosphorylase in tissue blocks. These studies indicate that phosphorylase activity, cytological detail and localization of the reaction product are optimally demonstrated when tissue blocks are incubated for one hour or longer in a medium containing high concentrations of G-1-P, ATP and PVP.Abbreviations AMP adenosine-5-monophosphate - ATP adenosine-5-triphosphate - EDTA ethylenediamine-tetraacetic acid - G-1-P glucose-1-phosphate - PPa active phosphorylase - PPb inactive phosphorylase - PVP polyvinyl pyrrolidone     

Purification of thymidine phosphorylase from Escherichia coli and its photoinactivation in the presence of thymine, thymidine, and some halogenated analogs.

Isoelectric focusing was used as the final step in the isolation of thymidine phosphorylase which was found to have an isoelectric point of 4.1. Analytical acrylamide gel electrophoresis showed the purified enzyme preparation contained one major protein band which stained for thymidine phosphorylase activity and usually a minor, faster migrating band devoid of activity. Inactivation of thymidine phosphorylase alone or in the presence of sensitizers by ultraviolet light, primarily at 253.7 nm, followed first order inactivation kinetics. The rate of inactivation of the enzyme was the same at pH 5 and 7.4 and the addition of various pyrimidine bases and nucleosides enhanced the inactivation rate at both pH values, but to a greater extent at pH 5. Linear plots of inactivation rates versus concentrations of thymidine or thymine were the same. At 7.8 mM thymidine or thymine, 11- and 4.4-fold increases in photoinactivation of thymidine phosphorylase were observed at pH 5 AND 7.4 RESPECTIVELY. Parabolic curves were obtained with increasing concentrations of either 5-iodo-2'-deoxyuridine or 5-iodouracil. 5-Iodouracil at 5.2 mM caused 212- (pH 5) and 100- (pH 7.4) FOLD INCREASES IN THE RATES OF PHOTOINACTIVATION OF THYMIDINE PHOSPHORYLASE. However, 5-iodo-2'-deoxyuridine at 5.0mM only enhanced the photoinactivation of enzyme by factors of 83 (pH 5) and 21 (pH 7.4). Neither 5-bromo-2'-deoxyuridine or 5-bromo-uracil was as potent in sensitizing the enzyme as the iodo analogs. Combinations of 5-iodouracil or 5-iodo-2'-deoxyuridine with thymine resulted in higher inactivation rates than the additive inactivation rates of individual compounds, whereas combinations of either iodo analog with thymidine resulted in lower inactivation rates. Increasing concentrations of phosphate or NaCl lessened the photoinactivation rate of thymidine phosphorylase alone and protected the enzyme from the sensitization caused by the different bases and nucleosides. No quantitative changes in the number of primary amino groups in thymidine phosphorylase was evident as a result of irradiation in the presence or absence of 5-iodouracil or 5-iodo-2'-deoxyuridine. Examination of the irradiated enzyme on Sephadex G-150 indicated that a larger protein species is formed and that 5-iodouracil promotes this process.