Calcium-dependent regulation of glycogen synthase activity in a muscle glycogen particle

The calcium-dependent inactivation of glycogen synthase in an isolated glycogen-protein complex (glycogen pellet) from rabbit skeletal muscle has been investigated. Addition of 1 mm Ca²⁺, 10 mm Mg²⁺, and 1 mm ATP-γ-S to a concentrated suspension of glycogen pellet resulted in a rapid activation of glycogen phosphorylase concomitant with an inactivation of glycogen synthase. These conversion reactions were blocked by ethylene glycol bis(β-aminoethyl ether) N, N′-tetraacetic acid or by pretreatment of the complex with an antiserum to purified phosphorylase kinase. These data suggest that in the glycogen-protein complex, which may be a functional unit of glycogen metabolism in vivo, phosphorylase kinase can catalyze a Ca²⁺-dependent activation of glycogen phosphorylase synchronized with an inactivation of glycogen synthase. If under similar conditions phosphoprotein phosphatase activity was assayed using exogenous [³²P]phosphorylase, there was an apparent inactivation of the phosphatase. Evidence is presented that this apparent inactivation of phosphatase was due to an accumulation of endogenous phosphorylase a which acted as an inhibitor to the exogenous [³²P]-phosphorylase.     

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.     

Rabbit brain purine nucleoside phosphorylase. Physical and chemical properties. Inhibition studies with aminopterin, folic acid and structurally related compounds.

Rabbit brain purine nucleoside phosphorylase used in this study was purified 6000-fold to apparent homogeneity and a specific activity or 50 μmol min^?1 mg ^?1 protein. A molecular weight of 70.000 daltons was determined for the native enzyme by gel filtration on Sephadex. Electrophoresis on polyacrylamide gel, in presence of sodium dodecyl sulfate, gave a subunit molecular weight of 34,500 daltons, suggesting that the enzyme is dimeric with, probably, identical subunits. The relationship of the structure of certain biologically active substances to their inhibitory action on the enzyme was examined. Folic acid and the compound d,l-6-methyl 5,6,7,8-tetrahydropterine, with similar substituents on their primary ring structure, were competitive inhibitors of the enzyme. The inhibition constants calculated were 3.37 × 10^?5M for folic acid and 3.80 × 10^?5m for d,l-6-methyl 5,6,7,8-tetrahydropterine. Aminopterin and the purine analog 8-aza-2,6-diaminopurine, with similar substituents on their primary ring structure, were noncompetitive inhibitors of the enzyme. Their respective inhibition constants were 1.50 × 10^?4 and 1.95 × 10^?4m. Erythro-9-(2-hydroxy-3-nonyl) adenine, an adenosine deaminase inhibitor, was also examined for inhibitory potency with mammalian purine nucleoside phosphorylase, and was observed to be a competitive inhibitor of this enzyme, with an inhibition constant of 1.90 × 10^?4m. The Michaelis constant for the substrate guanosine was near 6.0 × 10^?5m. Physical probe of the nature of the functional groups which participate in enzymic catalysis implicated both histidine and cysteine as the essential catalytic species. Photooxidation studies suggested a pH-dependent sensitivity of an essential catalytic group, and its probable location at the active site.     

Inactivation of E. coli RNA polymerase by pyridoxal 5'-phosphate: identificationof a low pKa lysine as the modified residue.

The inactivation of E. coli RNA polymerase (3.3 × 10^?7M) by pyridoxal 5′-phosphate (1 × 10^?4M to 5 × 10^?4M) is a first order process with respect to the remaining active enzyme. Studies of the variation of the first order rate constant with the concentration of pyridoxal 5′-phosphate show that the inactivation reaction follows saturation kinetics. The formation of a reversible enzyme-inhibitor intermediate is postulated. Kinetic studies at different pH values indicate that the inactivation rate constant depends on the mole fraction of one conjugate base with pK_a 7.9. The apparent equilibrium constant (association) for the inactivation reaction is independent of the pH and is 1.8 × 10⁴ M^?1. By electrophoretic and chromatographic analysis of enzyme hydrolyzates after pyridoxal 5′-phosphate and NaBH₄ treatment only N-ε-pyridoxyllysine was found. It is postulated that a lysine ε-amino group with a low pK_a is critical for the activity of the enzyme.     

The low-molecular-weight acid phosphatase from bovine liver: Isolation,amino acid composition,and chemical modification studies

The smallest of the three molecular weight forms of acid phosphatase from bovine liver was purified to a specific activity of 100 μmol min^?1 mg^?1 (measured at pH 5.5 and 37 °C with p-nitrophenyl phosphate). Using several chromatographie and electrophoretic methods, no evidence of heterogeneity was detected. The enzyme was characterized with respect to its stability as a function of pH, molecular weight, amino acid composition, steady-state kinetic parameters in the pH range 4–7 and inhibition by common acid phosphatase inhibitors at pH 5.5. The amino acid composition differed somewhat from a previous literature report. The enzyme was stoichiometrically inactivated upon incubation with Hg²⁺, Ag⁺, and iodoacetate. Inactivation also occurred upon photoinactivation in the presence of Rose Bengal but no inactivation occurred with diethyl pyrocarbonate. The alkylation of one of five cysteine residues by iodoacetate was shown to cause complete inactivation of the enzyme. This alkylation was prevented by the presence of phosphate ion. A tryptic dipeptide containing this essential cysteine was isolated following inactivation with iodo[2-¹⁴C]acetate.     

Modification of human prostatic acid phosphatase by potassium ferrate

Prostatic acid phosphatase (orthophosphoric-monoester phosphohydrolase, acid optimum, EC 3.1.3.2) reacts with potassium ferrate, K₂FeO₄ a potent oxidizing agent and an analogue of orthophosphate. Treatment of the enzyme with 10^?6m ferrate at pH 7.5 0 C leads to the immediate loss of 95% of the activity. Molybdate, the competitive inhibitor of prostatic phosphatase, partially protects the enzyme from inactivation. Ferrate inactivation at pH 7.5 is accompanied by the modification of 2 histidine, 4 lysine and 4 methionine residues. Histidine is protected by molybdate, whereas methionine is not and lysine is partly protected. Partial inactivation with ferrate leads to the retardation of the modified enzyme on Sephadex G-200 column, which is eluted in the position of the active monomeric unit.     

Kinetics of Denaturation of Rabbit Skeletal Muscle Glycogen Phosphorylase b by Guanidine Hydrochloride

The kinetics of denaturation and aggregation of rabbit muscle glycogen phosphorylase b in the presence of guanidine hydrochloride (GuHCl) have been studied. The curve of inactivation of phosphorylase b in time includes a region of the fast decline in the enzymatic activity,an intermediate plateau,and a part with subsequent decrease in the enzymatic activity. The fact that the shape of the inactivation curves is dependent on the enzyme concentration testifies to the dissociative mechanism of inactivation. The dissociation of phosphorylase b dimers into monomers in the presence of GuHCl is supported by sedimentation data. The rate of phosphorylase b aggregation in the presence of GuHCl rises as the denaturant concentration increases to 1.12 M; at higher concentration of GuHCl, suppression of aggregation occurs. At rather low concentration of the protein (0.25 mg/ml), the terminal phase of aggregation follows the kinetics of a monomolecular reaction (the reaction rate constant is equal to 0.082 min^–1;1 M GuHCl, 25°C). At higher concentration of phosphorylase b (0.75 mg/ml), aggregation proceeds as a trimolecular reaction.     

Inactivation and reactivation of phosphoprotein phosphatase

Summary The catalytic subunit of phosphoprotein phosphatase (Mr = 35 000) is inactivated by phosphate compounds such as trimetaphosphate, PPi, and ATP. The inactivation of phosphoprotein phosphatase by these phosphate compounds is time- and concentration-dependent, is not reversed by dilution or gel filtration and is protected by Pi. A dissociation constant for the enzyme-trimetaphosphate complex and a rate constant for the reaction were calculated to be 4.6 × 10^–4 M and 0.29 min ¹, respectively. The inactivation of phosphatase by PPi and ATP shows more complex kinetics than that by trimetaphosphate. The addition of EDTA to PPi and ATP exhibits more potent inactivation, even though EDTA alone does not inactivate phosphatase. This phosphoprotein phosphatase is not labeled by [-³²P]ATP. The inactivation of phosphatase by PPi or ATP can only be reversed by Mn²⁺ or Co²⁺, among all other metals or cationic compounds tried. The reactivation also requires sulfhydryl compounds. The effectiveness of sulfhydryl compounds follows the order: dithioerythritol > mercaptoethanol > cysteine. Glutathione was without effect. Metal analysis of the catalytic subunit did not reveal any significant amounts of Ca, Cd, Co, Cu, Fe, Mg, Mn, Ni, Sn, or Zn. Phosphoprotein phosphatase activity from zinc-deficient rat livers also eliminated the possibility of this phosphatase being a zinc metalloenzyme. Inactivation does not seem to be due to a loss of a critical metal ion. Other mechanisms for inactivation are presented.Abbreviations used EDTA Ethylenediamine tetraacetic acid - PPi Inorganic pyrophosphate - DTE Dithioerythritol. To whom requests for reprints should be addressed.     

Inhibition of muscle phosphorylase a by natural components of the sarcoplasm

Using a reconstituted glycolytic enzyme system from muscle tissue, it was shown that phosphorylase activity was regulated by some process to provide only the required amount of glucose 1-phosphate, regardless of the percentage of phosphorylase in the a form. By carrying out phosphorylase a assays at high enzyme concentration (2 mg ml^?1), the same concentration as in the reconstituted system and comparable with in vivo, it was shown that (a) the K_m for phosphate was higher and V lower than at low enzyme concentration (2 μg ml^?1), (b) the presence of other glycolytic enzymes at 40 mg ml^?1 suppressed the activity a further threefold, and (c) phosphocreatine inhibited the enzyme. Taken together, these three effects were sufficient to explain the relative lack of activity of phosphorylase a in the reconstituted system. The inhibition by phosphocreatine is seen as a mode of feedback control on phosphorylase activity in vivo.     

Adenosine 5'-O(3-thiotriphosphate) in the control of phosphorylase activity

Rabbit muscle phosphorylase b (EC 2.4.1.1) is converted to a thio-analog of phosphorylase a by phosphorylase kinase, Mg²⁺ and adenosine 5′-O(3-thiotriphosphate)(ATPγS). Conversion proceeds at one-fifth the rate obtained with ATP though the extent of reaction and final level of activation of the enzyme are the same. However, the thiophosphorylase a produced is resistant to phosphorylase phosphatase and, therefore, behaves as a competitive inhibitor with a K_I of 3 μM, similar to the K_M obtained with normal phosphorylase a. ATPγS can also be utilized by protein kinase in the activation of phosphorylase kinase at a rate similar to that obtained with ATP. It is hydrolyzed at 5 to 10 times the normal rate by the sarcoplasmic reticulum ATPase. When added to a muscle glycogen-particulate complex in the presence of Ca²⁺ and Mg²⁺, ATPγS triggers an activation of phosphorylase with simultaneous inhibition of phosphorylase phosphatase as previously observed with ATP.     

The ATPMg-dependent phosphatase is present in mammalian vascular smooth muscle

An ATPMg-dependent phosphorylase phosphatase was identified in vascular smooth muscle from bovine aorta. The smooth muscle enzyme, like the corresponding enzyme from striated muscle, exists as an inactive phosphatase (F_C-enzyme) which can be activated by a protein, F_A, in the presence of ATP and Mg²⁺. Moreover, smooth muscle F_C is activatable by skeletal muscle F_A and skeletal muscle F_C can be activated by smooth muscle F_A. The mode of activation of aortic F_C by aortic F_A is similar to that reported for the skeletal muscle proteins. In accord with earlier findings obtained with the skeletal muscle system, the activity of the aortic phosphatase is inhibited by a specific heat-stable modulator protein (previously called phosphatase inhibitor-2). Thus, the fundamental properties of arterial ATPMg-dependent phosphatase appear to be identical to those of its skeletal muscle counterpart which purportedly represents the major phosphorylase phosphatase in that tissue. Since glycogen phosphorylase is activated when vascular smooth muscle contracts, ATPMg-dependent protein phosphatase may participate in coordinating arterial metabolism and contractility.     

Kinetics of photosynthetic membrane protein assembly in Rhodopseudomonas spheroides

Glycogen phosphorylase in cell-free extracts of Neurospora crassa is activated 10- to 15-fold by incubation with MgATP^2?. When the MgATP^2? is removed, the active form (a form) reverts to the inactive form (b form). The inactivation requires Mg²⁺ and is inhibited by NaF. The results confirm that Neurospora crassa glycogen phosphorylase exists in two interconvertible forms and strongly suggests that the interconversion is catalyzed by a kinase and phosphatase. The a form was partially purified. The enzyme has a molecular weight of 320,000. Uridine diphosphate glucose is a linear competitive inhibitor with respect to glucose-1-phosphate and a linear non-competitive inhibitor with respect to glycogen. Glucose-6-phosphate is a hyperbolic (partial) noncompetitive inhibitor with respect to all substrates in both directions. The b form of the enzyme in crude cell-free extracts is stimulated 2- to 3-fold by 5′-AMP. As the b form is purified, the 5′-AMP activation is diminished. The molecular weight of the partially purified “b” form was also 320,000.     

A new enzymatic method for the determination of inorganic phosphate and its application to the nucleoside diphosphatase assay

A new enzymatic method has been developed for the determination of inorganic phosphate, in which purine nucleoside phosphorylase and xanthine oxidase are used as indicator enzymes. This method has been applied to the assay of nucleoside diphosphatase. Incidental to this work, the apparent Michaelis constant of phosphate for calf spleen purine nucleoside phosphorylase was determined to be 0.25 mm, and the extinction coefficient of uric acid at 293 nm and pH 7.4 was found to be 13.0 × 10³m^?1 cm^?1.     

Evidence of essential arginyl residues in rabbit muscle pyruvate kinase.

Rabbit muscle pyruvate kinase is inactivated by 2,3-butanedione in borate buffer. The inactivation follows pseudo-first-order kinetics with a calculated second-order rate constant of 4.6 m^?1 min^?1. The modification can be reversed with almost total recovery of activity by elimination of the butanedione and borate buffer, suggesting that only arginyl groups are modified; this result agrees with the loss of arginine detected by amino acid analysis of the modified enzyme. Using the kinetic data, it was estimated that the reaction of a single butanedione molecule per subunit of the enzyme is enough to completely inactivate the protein. The inactivation is partially prevented by phosphoenolpyruvate in the presence of K⁺ and Mg²⁺, but not by the competitive inhibitors lactate and bicarbonate. These findings point to an essential arginyl residue being located near the phosphate binding site of phosphoenolpyruvate.     

Dephosphorylation and activation of acetyl-CoA carboxylase by phosphorylase phosphatase

Acetyl-CoA carboxylase from rat epididymal fat tissue is activated by phosphorylase phosphatase, a reaction which is inhibited by phosphatase inhibitor-1. This activation is accompanied by a corresponding loss of ³²P from the labelled enzyme. These results establish that dephosphorylation of the enzyme causes its activation.     

The separation and properties of two phosphoprotein phosphatases from the dimorphic fungus Mucor rouxii

Soluble preparations from mycelium of the dimorphic fungus Mucor rouxii contained detectable amounts of phosphoprotein phosphatase activity. This cytosolic phosphatase activity exhibited a molecular weight below 80,000 and could be resolved into two different forms (enzymes I and II) by chromatography on DEAE-cellulose followed by gel filtration on Sephacryl S-300. Enzyme I (M_r 64,000) was mainly a histone phosphatase activity, absolutely dependent on divalent cations, with a K_0.5 for MnCl₂ of 2 mm. Enzyme II (M_r 40,000) was active with histone and phosphorylase. Its activity was independent or slightly inhibited by Mn²⁺. This enzyme was strongly inhibited by 50 mm NaF or 1 mm ATP. When partially purified enzymes I and II were separately treated with ethanol, the catalytic properties of enzyme II were apparently not affected while those of enzyme I were drastically changed. The activity with histone, which was originally dependent on Mn²⁺, became independent or slightly inhibited by the cation. The treatment was accompanied by a notable increase in phosphorylase phosphatase activity which was strongly inhibited by Mn²⁺. Treated enzyme I eluted from DEAE-cellulose and Sephacryl S-300 columns at a position similar to that of enzyme II.     

Escherichia coli phosphoenolpyruvate carboxylase: kinetics and mechanism of inactivation

In dilute solution phosphoenolpyruvate carboxylase of Escherichia coli undergoes a spontaneous inactivation that can be described mathematically by a two-component declining exponential equation. The rate constant for the decay of the first component is 3.05 ± 0.52 × 10^?2 min^?, whereas that for the second component is variable, smaller in magnitude, and dependent upon the dilution conditions. Analysis of the coefficients for the exponential equation suggests that the decline of enzymatic activity with time is a function of the initial concentrations of catalytically active dimer and tetramer. From the concentrations of these two species, as determined from their initial activities, an equilibrium constant of 3 × 10^?7m for the tetramer-dimer dissociation was determined.The diluted enzyme exhibits properties similar to those ascribed to hysteretic enzymes. The appearance of hysteresis is a function of the time after dilution and the presence of modifiers of catalytic activity, i.e., it is not present immediately after dilution and can be prevented from occurring if aspartate is present in the dilution buffer. The data are consistent with a scheme in which dimeric and tetrameric forms of the enzyme undergo inactivation by dissociation to monomers. The tetramer can dissociate directly to monomers and become inactivated or it can dissociate first to dimers than to monomers before undergoing inactivation. Monomer-to-dimer reassociation occurs to form a catalytically active species, but monomer-to-tetramer reassociation to an active species is not apparent. Hysteresis is presumed to result from reversible isomerization of the monomeric species to a form that can also result in an irreversibly inactivated enzyme.     

An active site-directed, irreversible inactivation of yeast hexokinase by (R,S)2,3-epoxypropyl beta-D-glucopyranoside

(1) Only (R,S)2′,3′-epoxypropyl β-d-glucopyranoside of the complete series of mono (R,S)2′.3′-epoxypropyl ethers and glycosides of d-glucopyranose significantly inactivated yeast hexokinase.(2) (R,S)2′,3′-Epoxypropyl β-d-glucopyranoside inactivates yeast hexokinase in the absence of MgATP^2?, The rate of inactivation is unaffected by MgATP^2?.(3) The rate of inactivation of hexokinase with (R,S)2′,3′-epoxypropyl β-d-ilucopyranoside was much greater when hexokinase was present in a monomeric form than when it was present in a dimeric form.(4) (R,S)2′,3′-Epoxypropyl β-d-glucopyranoside has a high K_t (0.38 M) and at a saturating concentrarion, the first order rate constant for the inactivation of monomeric hexokinase is 8.3 · 10^?4 sec.(5) d-Glucose protects against this inactivation and this was used to derive a dissocistion constant of 0.21 mM for d-glucose in the absence of MgATP^2?.(6) The alkylation of yeast hexokinase by (R,S)2′,3′-epoxypropyl β-d-gluco-pyranoside was not specific to the active site. When the concentration of (R,S)2′,3′-epoxypropyl β-d-glucopyranoside was 50 mM two thiol groups outside the active site were also alkylated.(7) The reaction between 5,5′-dithiobis-(2-nitrobenzoic acid) (DTNB) and yeast hexokinase was examined in detail. Two thiol groups per monomer (mol. wt. 50000) reacted with a second order rate constant of 27 1 mole^?1 sec^?1. A third thiol group reacted more slowly with a second-order rate constant of 1.6 1 mole^?1 sec^?1 and a fourth thiol group reacted very slowly with inactivation of the enzyme. Tue second-order rate constant in this case was 0.1 1 mole^?1 sec^?1.     

Irreversible inactivation of urocanase by 4-bromocrotonate.

Urocanase from Pseudomonas putida is irreversibly inactivated by 4-bromocrotonate. At pH 6.7 and 25°, the rate of inactivation is first-order in remaining active enzyme and follows saturation kinetics with a K₁ of 180 mM and a maximum inactivation rate of 0.889 min^?1. The rate constant of inactivation decreases with pH in the pH range 5.8 to 8.5. 4-Bromocrotonate methyl ester inactivates urocanase at only 3% the rate observed with bromocrotonate while other alkylating reagents are ineffective in promoting a time-dependent loss of activity. Dihydrourocanate protects competitively against bromocrotonate inactivation; an average value of 3.3 mM at pH 6.7 is obtained for the enzyme-dihydrourocanate dissociation constant. Protection against inactivation is also offered by fumarate and crotonate, but not by maleate. The results are consistent with bromocrotonate reacting within the active site region of the enzyme.