Kinetics of the interaction of rabbit skeletal muscle phosphorylase kinase with glycogen

The kinetics of the interaction of rabbit skeletal muscle phosphorylase kinase with glycogen was studied by the turbidimetric method at pH 6.8 and 8.2. Binding of phosphorylase kinase by glycogen occurs only in the presence of Ca2+ and Mg2+. The initial rate of complex formation is proportional to the enzyme and polysaccharide concentration; this suggests the formation of a complex with 1:1 stoichiometry in the initial step of phosphorylase kinase binding by glycogen. The kinetic data suggest that phosphorylase kinase substrate--glycogen phosphorylase b--favors the binding of phosphorylase kinase with glycogen. This conclusion is supported by direct experiments on the influence of phosphorylase b on the interaction of phosphorylase kinase with glycogen using analytical sedimentation analysis. The kinetic curves of the formation of the complex of phosphorylase kinase with glycogen obtained in the presence of ATP are characterized by a lag period. Preincubation of phosphorylase kinase with ATP in the presence of Ca2+ and Mg2+ causes the complete disappearance of the lag period. On changing the pH from 6.8 to 8.2, the rate of phosphorylase kinase binding by glycogen is appreciably increased, and complex formation becomes possible even in the absence of Mg2+. A model of phosphorylase kinase and phosphorylase b adsorption on the surface of the glycogen particle explaining the increase in the strength of phosphorylase kinase binding with glycogen in the presence of phosphorylase b is proposed.     

The role of phosphorylase kinase subunits in interaction with glycogen

The interaction of rabbit skeletal muscle phosphorylase kinase with CNBr-activated glycogen results in the formation of a covalent complex. The non-bound kinase was removed by chromatography on DEAE-cellulose and phenyl-Sepharose. The amount of the bound protein increased with an increase in the number of activated groups in the glycogen molecule; the enzyme activity was thereby decreased. The kinase covalently and non-covalently bound to glycogen exhibited a higher affinity for the protein substrate (phosphorylase b) as well as for Mg2+ and Ca2+ than did the kinase in the absence of glycogen. Electrophoresis performed under denaturating conditions showed that the gamma-subunit of phosphorylase kinase is responsible for the enzyme binding to CNBr-glycogen. The effect of cross-linking reagents (glutaric aldehyde, 1.5-difluoro-2.4-dinitrobenzene) on the binding of phosphorylase kinase subunits was studied. Glycogen afforded protection of the gamma-subunit from the cross-linking to other enzyme subunits. An analysis of the subunit composition of phosphorylase kinase covalently bound to CNBr-glycogen and of the enzyme treated with cross-linking reagents in the presence of glycogen-revealed that the gamma-subunit is involved in the specific binding of phosphorylase kinase to glycogen.     

Regulation of the activity of rabbit skeletal muscle phosphorylase kinase by glycogen

The effects of glycogen on the non-activated and activated forms of phosphorylase kinase were studied. It was found that in the presence of glycogen the activity of non-activated kinase at pH 6.8 and 8.2 and that of the activated (in the course of phosphorylation) form are enhanced. The degree of activation depends on glycogen concentration. At saturating concentrations, this enzyme activity increases 2-3-fold; the enzyme affinity for the protein substrate, phosphorylase b, also shows an increase. The polysaccharide has no effect on the activity of phosphorylase kinase stimulated by limited proteolysis. In the presence of glycogen, the rate of autocatalytic phosphorylation of the enzyme is increased. Glycogen stabilizes the enzyme activity upon dilution. The experimental results suggest that the polysaccharide directly affects the phosphorylase kinase molecule. The maximal binding was shown to occur at the enzyme/polysaccharide ratio of 1:10 (w/w) in the presence of Ca2+ and Mg2+.     

Effect of molecular crowding on self-association of phosphorylase kinase and its interaction with phosphorylase b and glycogen

Self-association of phosphorylase kinase (PhK) and its interaction with glycogen (M=5500 kDa) and phosphorylase b (Phb) has been studied using analytical ultracentrifugation and turbidimetry under the conditions of molecular crowding arising from the presence of high concentrations of osmolytes. In accordance with the predictions of the molecular crowding theory, trimethylamine N-oxide (TMAO) and betaine greatly favor self-association of PhK induced by Mg2+ and Ca2+ and PhK interaction with glycogen. In contrast, proline suppresses these processes, probably, due to its specific interaction with PhK. All osmolytes tested prevented the complex formation between PhK and its physiological substrate, Phb. The specific interactions of PhK and Phb with glycogen, in the living cell, presumably is a factor allowing the negative effect of crowding on the recognition of Phb by PhK to be overcome.     

Studies on interaction of phosphorylase kinase from rabbit skeletal muscle with glycogen in the presence of ATP and ADP.

The influence of ATP on complex formation of phosphorylase kinase (PhK) with glycogen in the presence of Ca(2+) and Mg(2+) has been studied. The initial rate of complex formation decreases with increasing ATP concentration, the dependence of the initial rate on the concentration of ATP having a cooperative character. Formation of the complex of PhK with glycogen in the presence of ATP occurs after a lag period, which increases with increasing ATP concentration. The dependence of the initial rate of complex formation (v) on the concentration of non-hydrolyzed ATP analogue, beta,gamma-methylene-ATP, follows the hyperbolic law. A correlation between PhK-glycogen complex formation and (32)P incorporation catalyzed by PhK itself and by the catalytic subunit of cAMP-dependent protein kinase has been shown. For ADP (the product and allosteric effector of the PhK reaction) the dependence of v on ADP concentration has a complicated form, probably due to the sequential binding of ADP at two allosteric sites on the beta subunit and the active site on the gamma subunit.     

Inhibition of rabbit muscle glycogen phosphorylase by D-gluconohydroximo-1,5-lactone-N-phenylurethane

The effect of the beta-glycosidase inhibitor D-gluconohydroximo-1,5-lactone-N-phenylurethane (PUG) on the kinetic and ultracentrifugation properties of glycogen phosphorylase has been studied. Recent crystallographic work at 2.4 A resolution [D. Barford et al. (1988) Biochemistry 27, 6733-6741] has shown that PUG binds in the catalytic site of phosphorylase b crystals with its gluconohydroximolactone moiety occupying a position similar to that observed for other glucosyl compounds and the N-phenylurethane side chain fitting into an adjacent cavity with little conformational change in the enzyme. In solution, PUG was shown to be a potent inhibitor of phosphorylase b, directly competitive with alpha-D-glucopyranose 1-phosphate (glucose-1-P) (Ki = 0.40 mM) and noncompetitive with respect to glycogen and AMP. When PUG was tested for synergistic inhibition in the presence of caffeine, the Dixon plots of reciprocal velocity versus PUG concentration at different fixed caffeine concentrations provided intersecting lines with interaction constant (alpha) values of 0.95-1.38, indicating that the binding of one inhibitor is not significantly affected by the binding of the other. For glycogen phosphorolysis, PUG was noncompetitive with respect to phosphate, suggesting that it can bind to the central enzyme-AMP-glycogen-phosphate complex. PUG was shown to inhibit phosphorylase alpha (without AMP) activity (Ki = 0.43 mM) in a manner similar to that of the b form. However, in the presence of AMP, PUG exhibited complex kinetics, acting as a noncompetitive inhibitor with respect to glucose-1-P, while a twofold decrease of PUG binding to the enzyme-AMP-glycogen complex was observed. Ultracentrifugation experiments demonstrated that PUG does not cause any significant dissociation of phosphorylase alpha tetramer. Furthermore the dimerization of phosphorylase alpha by glucose is completely prevented in the presence of PUG. These observations are consistent with PUG binding to both the R and the T conformations of phosphorylase.     

Interaction of muscle glycogen phosphorylase B with F-actin

The binding of rabbit muscle glycogen phosphorylase b to F-actin has been studied by sedimentation in analytical centrifuge in 10 mM Tris-acetate buffer pH 6.8 at 20 degrees C. The adsorption capacity of F-actin is equal to (7.8 +/- 0.9) X 10(-7) mole of glycogen phosphorylase b per 1 g of F-actin; the microscopic dissociation constant for the glycogen phosphorylase-F-actin complex is (5.4 +/- 0.5) X 10(-7) M. It was found that the allosteric activator, AMP, facilitates the adsorption of glycogen phosphorylase b on F-actin, whereas the substrate, Pi, and the inhibitor, ATP, cause an opposite effect.     

Structural features contributing to complex formation between glycogen phosphorylase and phosphorylase kinase.

A polyclonal antibody was generated against a peptide corresponding to a region opposite the regulatory face of glycogen phosphorylase b (P-b), providing a probe for detecting and quantifying P-b when it is bound to its activating kinase, phosphorylase kinase (PhK). Using both direct and competition enzyme-linked immunosorbent assays (ELISAs), we have measured the extent of direct binding to PhK of various forms of phosphorylase, including different conformers induced by allosteric effectors as well as forms differing at the N-terminal site phosphorylated by PhK. Strong interactions with PhK were observed for both P-b', a truncated form lacking the site for phosphorylation, and P-a, the phosphorylated form of P-b. Further, the binding of P-b, P-b', and P-a was stimulated a similar amount by Mg(2+), or by Ca(2+) (both being activators of PhK). Our results suggest that the presence and conformation of P-b's N-terminal phosphorylation site do not fully account for the protein's affinity for PhK and that regions distinct from that site may also interact with PhK. Direct ELISAs detected the binding of P-b by a truncated form of the catalytic gamma subunit of PhK, consistent with the necessary interaction of PhK's catalytic subunit with its substrate P-b. In contrast, P-b' bound very poorly to the truncated gamma subunit, suggesting that the N-terminal phosphorylatable region of P-b may be critical in directing P-b to PhK's catalytic subunit and that the binding of P-b' by the PhK holoenzyme may involve more than just its catalytic core. The sum of our results suggests that structural features outside the catalytic domain of PhK and outside the phosphorylatable region of P-b may both be necessary for the maximal interaction of these two proteins.     

Kinetics of the reaction between muscle glycogen phosphorylase B and glycogen

Kinetics of glycogen binding by glycogen phosphorylase b has been studied by stopped flow and temperature jump methods. This reaction is followed by increase in light scattering whose amplitude depends upon the enzyme binding sites concentration of glycogen particles occupied by the enzyme. It has been shown that the complex formation has the first order with respect to enzyme and glycogen concentrations. Relaxation kinetics is compatible with proposed bimolecular reaction scheme. Microscopic rate constants of the forward and reverse reactions of glycogen binding by glycogen phosphorylase b are determined in temperature range from 12,7 to 30 degrees C. The possibility of diffusional control of the binding rate is discussed.     

The interplay between covalent and non-covalent regulation of glycogen phosphorylase. The role of different effectors of phosphorylase b on the phosphorylase b to a conversion rate.

Glycogen phosphorylase b is converted to glycogen phosphorylase a, the covalently activated form of the enzyme, by phosphorylase kinase. Glc-6-P, which is an allosteric inhibitor of phosphorylase b, and glycogen, which is a substrate of this enzyme, are already known to have respectively an inhibiting and activating effect upon the rate of conversion from phosphorylase b to phosphorylase a by phosphorylase kinase. In the former case, this effect is due to the binding of glucose-6-phosphate to glycogen phosphorylase b. In order to investigate whether or not the rate of conversion of glycogen phosphorylase b to phosphorylase a depends on the conformational state of the b substrate, we have tested the action of the most specific effectors of glycogen phosphorylase b activity upon the rate of conversion from phosphorylase b to phosphorylase a at 0 degrees C and 22 degrees C : AMP and other strong activators, IMP and weak activators, Glc-6-P, glycogen. Glc-1-P and phosphate. AMP and strong activators have a very important inhibitory effect at low temperature, but not at room temperature, whereas the weak activators have always a very weak, if even existing, inhibitory effect at both temperatures. We confirmed the very strong inhibiting effect of Glc-6-P at both temperatures, and the strong activating effect of glycogen. We have shown that phosphate has a very strong inhibitory effect, whereas Glc-1-P has an activating effect only at room temperature and at non-physiological concentrations. The concomitant effects of substrates and nucleotides have also been studied. The observed effects of all these ligands may be either direct ones on phosphorylase kinase, or indirect ones, the ligand modifying the conformation of phosphorylase b and its interaction with phosphorylase kinase. Since we have no control experiments with a peptidic fragment of phosphorylase b, the interpretation of our results remains putative. However, the differential effects observed with different nucleotides are in agreement with the simple conformational scheme proposed earlier. Therefore, it is suggested that phosphorylase kinase recognizes differently the different conformations of glycogen phosphorylase b. In agreement with such an explanation, it is shown that the inhibiting effect of AMP is mediated by a slow isomerisation which has been previously ascribed to a quaternary conformational change of glycogen phosphorylase b. The results presented here (in particular, the important effect of glycogen and phosphate) are also discussed in correlation with the physiological role of the different ligands as regulatory signals in the in vivo situation where phosphorylase is inserted into the glycogen particle.     

The interaction of muscle glycogen phosphorylase b with glycogen

Interaction of muscle glycogen phosphorylase b (EC 2.4.1.1) with glycogen was studied by sedimentation, stopped-flow and temperature-jump methods. The equilibrium enzyme concentration was determined by sedimentation in an analytical ultracentrifuge equipped with absorption optics and a photoelectric scanning system. The maximum adsorption capacity of pig liver glycogen is 3.64 mumol dimeric glycogen phosphorylase b per g glycogen, which corresponds to 20 dimeric enzyme molecules per average glycogen molecule of Mr 5.5 X 10(6). Microscopic dissociation constants were determined for the enzyme-glycogen complex within the temperature range from 12.7 to 30.0 degrees C. Enzyme-glycogen complexing is accompanied by increasing light scattering and its increment depends linearly on the concentration of the binding sites on a glycogen particle that are occupied by the enzyme. Complex formation and relaxation kinetics are in accordance with the proposed bimolecular reaction scheme. The monomolecular dissociation rate constant of the complex increases as the temperature increases from 12.7 to 30.0 degrees C, whereas the bimolecular rate constant changes slightly and is about 10(8) M-1 X S-1. These data point to the possibility of diffusional control of the complex formation.     

Ca2+- and Mg2+-dependent association of phosphorylase kinase with human erythrocyte membranes

The interaction of rabbit muscle phosphorylase kinase (EC 2.7.1.38) with human erythrocyte membranes was investigated. It was found that at pH 7.0 the kinase binds to the inner face of the erythrocyte membrane (inside-out vesicles) and that this binding is Ca2+- and Mg2+-dependent. The sharpest increase in the binding reaction occurs at concentrations between 70 and 550 nM free Ca2+. Erythrocyte ghost or right-side out erythrocyte vesicles showed a significantly lower capacity to interact with phosphorylase kinase. Autophosphorylated phosphorylase kinase shows a similar Ca2+-dependent binding profile, while trypsin activation of the kinase and calmodulin decrease the original binding capacity by about 50%. Heparin (200 micrograms/ml) and high ionic strength (50 mM NaCl) almost completely blocks enzyme-membrane interaction; glycogen does not affect the interaction.     

Activation of protein kinase and glycogen phosphorylase in isolated rat liver cells by glucagon and catecholamines.

In liver cells isolated from fed female rats, glucagon (290nM) increased adenosine 3':5'-monophosphate (cyclic AMP) content and decreased cyclic AMP binding 30 s after addition of hormones. Both returned to control values after 10 min. Glucagon also stimulated cyclic AMP-independent protein kinase activity at 30 s and decreased protein kinase activity assayed in the presence of 2 muM cyclic AMP at 1 min. Glucagon increased the levels of glycogen phosphorylase a, but there was no change in total glycogen phosphorylase activity. Glucagon increased glycogen phosphorylase a at concentrations considerably less than those required to affect cyclic AMP and protein kinase. The phosphodiesterase inhibitor, 1-methyl-3-isobutyl xanthine, potentiated the action of glucagon on all variables, but did not increase the maximuM activation of glycogen phosphorylase. Epinephrine (1muM) decreased cyclic AMP binding and increased glycogen phosphorylase a after a 1-min incubation with cells. Although 0.1 muM epinephrine stimulated phosphorylase a, a concentration of 10 muM was required to increase protein kinase activity. 1-Methyl-3-isobutyl xanthine (0.1 mM) potentiated the action of epinephrine on cyclic AMP and protein kinase. (-)-Propranolol (10muM) completely abolished the changes in cyclic AMP binding and protein kinase due to epinephrine (1muM) in the presence of 0.1mM 1-methyl-3-isobutyl xanthine, yet inhibited the increase in phosphorylase a by only 14 per cent. Phenylephrine (0.1muM) increased glycogen phosphorylase a, although concentrations as great as 10 muM failed to affect cyclic AMP binding or protein kinase in the absence of phosphodiesterase inhibitor. Isoproterenol (0.1muM) stimulated phosphorylase and decreased cyclic AMP binding, but only a concentration of 10muM increased protein kinase. 1-Methyl-3-isobutyl xanthine potentiated the action of isoproterenol on cyclic AMP binding and protein kinase, and propranolol reduced the augmentation of glucose release and glycogen phosphorylase activity due to isoproterenol. These data indicate that both alpha- and beta-adrenergic agents are capable of stimulating glycogenolysis and glycogen phosphorylase a in isolated rat liver cells. Low concentrations of glucagon and beta-adrenergic agonists stimulate glycogen phosphorylase without any detectable increase in cyclic AMP or protein kinase activity. The effects of alpha-adrenergic agents appear to be completely independent of changes in cyclic AMP protein kinase activity.     

Activation of endogenous phosphorylase kinase in liver glycogen pellet by cAMP-dependent protein kinase

Liver glycogen phosphorylase associated with the glycogen pellet was activated by a MgATP-dependent process. This activation was reduced by 90% by ethylene glycol bis(beta-aminoethyl ether)N,N,N',N'-tetraacetic acid, not affected by the inhibitor of the cAMP-dependent protein kinase, and increased 2.5-fold by the catalytic subunit of cAMP-dependent protein kinase. Low levels of free Ca2+ (8 x 10(-8) M) completely prevented the effects of the chelator. The activation of phosphorylase by MgATP was shown not to be due to formation of AMP. DEAE-cellulose chromatography of the glycogen pellet separated phosphorylase from phosphorylase kinase. The isolated phosphorylase was no longer activated by MgATP in the presence or absence of the catalytic subunit of cAMP-dependent protein kinase. The isolated phosphorylase kinase phosphorylated and activated skeletal muscle phosphorylase b and the activation was increased 2- to 3-fold by the catalytic subunit of cAMP-dependent protein kinase. Mixing the isolated phosphorylase and phosphorylase kinase together restored the effects of MgATP and the catalytic subunit of cAMP-dependent protein kinase on phosphorylase activity. These findings demonstrate that the phosphorylase kinase associated with liver glycogen has regulatory features similar to those of muscle phosphorylase kinase.     

Substrate specificity of phosphorylase kinase: effects of heparin and calcium

Phosphorylase b and two peptides with sequences homologous to phosphorylation site 2 (syntide 2) and site 3 (syntide 3) of glycogen synthase were compared as substrates for purified muscle phosphorylase kinase. The substrate specificity of phosphorylase kinase varied according to whether heparin (at pH 6.5) or Ca2+ (at pH 8.2) was used as a stimulator of its activity. Phosphorylase b was preferentially phosphorylated in the presence of Ca2+; the rate of syntide 2 phosphorylation was the same for both stimulators; and the phosphorylation of syntide 3 was completely dependent on the presence of heparin. A kinetic analysis confirmed this stimulator-dependent substrate specificity since both the Vmax and Km for these substrates were affected diversely by heparin and Ca2+. Heparin stimulated phosphorylase kinase maximally at pH 6.5, whereas the effect of Ca2+ was optimal at a pH above 8. However, the stimulator-related substrate specificity could not be explained by the different pH values at which the effects of the stimulators were assessed. Nor did substrate-directed effects by heparin or Ca2+ apparently play a role. No indications were found for a stimulator-dependent specificity in the phosphorylation of sites in protein substrates of phosphorylase kinase (phosphorylase b, the alpha- and beta-subunits of phosphorylase kinase, or glycogen synthase). The diverse substrate specificity of the calcium- and heparin-dependent activities of phosphorylase kinase could be explained in two ways: either by the existence of separate calcium- and heparin-stimulated catalytic sites, or by just one catalytic site with two active conformations. The second possibility is favored by the observation that both calcium and heparin stimulated the isolated gamma-subunit (gamma X calmodulin complex) of phosphorylase kinase.     

Interaction of muscle glycogen phosphorylase B with methotrexate, folic and folinic acids

The interaction of rabbit skeletal muscle glycogen phosphorylase b with methotrexate, folic and folinic acids has been studied. Microscopic dissociation constant for the glycogen phosphorylase b--methotrexate complex determined by analytical ultracentrifugation is 0.43 mM. A subunit of glycogen phosphorylase b is shown to have two sites for methotrexate binding. AMP and FMN diminish the affinity of glycogen phosphorylase b to methotrexate, whereas glycogen does not influence the methotrexate binding to the enzyme. Methotrexate, folic and folinic acids are found to be inhibitors of the muscle glycogen phosphorylase b. The inhibition is reversible and characterized by positive kinetic cooperativity (the Hill coefficient exceeds one unity). The value of the pterin concentration causing two-fold diminishing of the enzymatic reaction rate increased in the order: folic acid (0.65 mM), methotrexate (1.01 mM), folinic acid (3.7 mM). The antagonism between methotrexate, folic and folinic acids, on the one hand, and AMP and FMN, on the other, is revealed for their combined action.     

Flexibility in the phosphorylase catalytic reaction. Glucosyltransfer from pyridoxal (5')-triphospho(1)-alpha-D-glucose to glycogen catalyzed by phosphorylase

When rabbit muscle phosphorylase reconstituted with pyridoxal (5')-diphospho(1)-alpha-D-glucose is incubated with glycogen, its glucosyl moiety is transferred to the nonreducing end of glycogen with the formation of a new alpha-1,4-glucosidic linkage. This finding provided the first evidence for the direct phosphate-phosphate interaction between the coenzyme pyridoxal 5'-phosphate and the substrate alpha-D-glucose 1-phosphate in the phosphorylase catalytic reaction (Takagi, M., Fukui, T., and Shimomura, S. (1982) Proc. Natl. Acad. Sci. U. S. A. 79, 3716-3719). We have examined whether pyridoxal(5')triphospho(1)-alpha-D-glucose can act in a similar manner to the diphospho compound or not. In the absence of glucan the enzyme-bound triphospho compound was stable for 1 day at pH 6-9. In the presence of glucan, however, its glucosidic linkage was cleaved, and the glucosyl moiety liberated was transferred to glycogen with the formation of a new alpha-1,4-glucosidic linkage. Allosteric activator AMP accelerated the reaction and allosteric inhibitor glucose 6-phosphate showed the reverse effect. The pH optimum of the reaction was pH 8.1-8.4. Mg2+ slightly but significantly accelerated the reaction, whereas Mn2+ and Ca2+ inhibited the reaction. These results indicate that the glucosyltransfer from the triphospho compound occurs in an identical manner to that from the diphospho compound. Based on the present and previous data, we discuss the catalytic mechanism of phosphorylase, especially in comparison with that of phosphoryltransferases.     

Site-directed mutants of glycogen phosphorylase are altered in their interaction with phosphorylase kinase

Glycogen phosphorylase is found in resting muscle as phosphorylase b, which is inactive without AMP. Phosphorylation by phosphorylase kinase (PhK) produces phosphorylase a, which is active in the absence of AMP. PhK is the only kinase that can phosphorylate phosphorylase b, which in turn is the only physiological substrate for PhK. We have explored the reasons for this specificity and how these two enzymes recognize each other by studying site-directed mutants of glycogen phosphorylase. All mutants were assayed for changes in their interaction with a truncated form of the catalytic subunit of phosphorylase kinase, gamma(1-300). Five mutations (R69K, R69E, R43E, R43E/R69E, and E501A), made at sites that interact with the amino terminus in either phosphorylase b or a, showed little difference in phosphorylation by gamma(1-300) compared to wild-type phosphorylase b. Five mutations, made at three sites in the amino-terminal tail of phosphorylase (K11A, K11E, I13G, R16A, and R16E), however, produced decreases in catalytic efficiency for gamma(1-300), compared to that for phosphorylase b. R16E was the poorest substrate for gamma(1-300), giving a 47-fold decrease in catalytic efficiency. The amino terminus, and especially Arg 16, are very important factors for recognition of phosphorylase by gamma(1-300). A specific interaction between Lys 11 of phosphorylase and Glu 110 of gamma(1-300) was also confirmed. In addition, I13G and R16A were able to be phosphorylated by protein kinase A, which does not recognize native phosphorylase.     

Interaction of phosphorylase kinase from rabbit skeletal muscle with flavin adenine dinucleotide

The interaction of flavin adenine dinucleotide (FAD) with rabbit skeletal muscle phosphorylase kinase has been studied. Direct evidence of binding of phosphorylase kinase with FAD has been obtained using analytical ultracentrifugation. It has been shown that FAD prevents the formation of the enzyme-glycogen complex, but exerts practically no effect on the phosphorylase kinase activity. The dependence of the relative rate of phosphorylase kinase-glycogen complex formation on the concentration of FAD has cooperative character (the Hill coefficient is 1.3). Under crowding conditions in the presence of 1 M trimethylamine-N-oxide (TMAO), FAD has an inhibitory effect on self-association of phosphorylase kinase. The data suggest that the complex of glycogen metabolism enzymes in protein-glycogen particles may function as a flavin depot in skeletal muscle. Published in Russian in Biokhimiya, 2006, Vol. 71, No. 6, pp. 808–814.     

Regulatory properties of phosphorylase from chicken skeletal muscle

The main kinetic parameters for purified phosphorylase kinase from chicken skeletal muscle were determined at pH 8.2: Vm = 18 micromol/min/mg; apparent Km values for ATP and phosphorylase b from rabbit muscle were 0.20 and 0.02 mM, respectively. The activity ratio at pH 6.8/8.2 was 0.1-0.4 for different preparations of phosphorylase kinase. Similar to the rabbit enzyme, chicken phosphorylase kinase had an absolute requirement for Ca2+ as demonstrated by complete inhibition in the presence of EGTA. Half-maximal activation occurred at [Ca2+] = 0.4 microM at pH 7.0. In the presence of Ca2+, the chicken enzyme from white and red muscles was activated 2-4-fold by saturating concentrations of calmodulin and troponin C. The C0.5 value for calmodulin and troponin C at pH 6.8 was 2 and 100 nM, respectively. Similar to rabbit phosphorylase kinase, the chicken enzyme was stimulated about 3-6-fold by glycogen at pH 6.8 and 8.2 with half-maximal stimulation occurring at about 0.15% glycogen. Protamine caused 60% inhibition of chicken phosphorylase kinase at 0.8 mg/ml. ADP (3 mM) at 0.05 mM ATP caused 85% inhibition with Ki = 0.2 mM. Unlike rabbit phosphorylase kinase, no phosphorylation of the chicken enzyme occurred in the presence of the catalytic subunit of cAMP-dependent protein kinase. Incubation with trypsin caused 2-fold activation of the chicken enzyme.