Glycogen phosphorylase kinase deficiency: a survey of enzymes in phosphorylase activating system

A four year-old Japanese boy with hepatomegaly and hypoglycemia has low activity of hepatic phosphorylase. A survey of enzymes involved in the phosphorylase activating system has revealed that liver phosphorylase kinase is deficient although adenosine 3′,5′-monophosphate (cyclic AMP)-dependent protein kinase and total phosphorylase measured in a mixture supplemented by rabbit muscle phosphorylase kinase show normal activities. The hormone receptor as well as adenyl cyclase system appears to be normal since cyclic AMP increases immediately after intravenous injection of glucagon. His muscle phosphorylase activating system is normal.     

A new type of glycogen storage disease caused by deficiency of cardiac phosphorylase kinase

A five-month-old Japanese boy was found to have marked glycogen accumulation only in the heart. A survey of enzymes revealed normal activities of phosphorylase, cyclic AMP-dependent protein kinase, acid maltase and amylo-1,6-glucosidase. However, the heart had capacity of activating neither rabbit muscle phosphorylase b nor endogenous phosphorylase b, which was converted to active form only when supplemented rabbit muscle phosphorylase kinase. In contrast to the heart, activities of phosphorylase kinase were found within normal levels in other organ tissues so far tested. These findings indicate that the present case of the cardiac glycogenosis is caused by deficiency of cardiac phosphorylase kinase.     

Control of platelet glycogenolysis; Activation of phosphorylase kinase by calcium.

An apparent enigma during platelet aggregation is that increased glycogenolysis occurs despite a fall in cyclic AMP levels; Activation by a classical cascade is therefore unlikely, and an alternative stimulus for phosphorylase a formation was sought. It was found that low levels of Ca-2+ markedly activate phosphorylase b kinase from human platelets, with a Ka of 0i muM Ca-2+, which is similar to that for the skeletal muscle enzyme; The kinase activity is unstable, and on enzyme ageing is a 50% loss in activity with the Ka decreasing to 0.33 muM Ca-2+. In unstilulated platelets, phosphorylase a was 13.3% of toal measured activity, and glycogen synthetase I was 32.3%. Aggregation induced by ADP did not change the percentage of I synthetase, while increasing that for phosphorylase a. Dibutyryl cyclic AMP did, as expected, increase the percentage of both phosphorylated enzymes; These findings suggest that the natural activator of platelet glycogenolysis during aggregation is Ca-2+, which directly stimulates phosphorylase b kinase without altering glycogen synthetase activity. The cyclic AMP-dependent protein kinase does not appear to be involved;     

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.     

Studies on the role of adenosine 3':5'-monophosphate in the activation of liver phosphorylase.

Crude extracts of rabbit liver, preincubated to promote the dephosphorylation of enzymes or other regulatory proteins, were used to study the role of cyclic AMP in the activation of glycogen phosphorylase. Inasmuch as endogenous liver phosphorylase was irreversibly altered by the preincubation procedure, crystalline skeletal muscle phosphorylase was used as the substrate in these studies. In the presence of magnesium ions and ATP, phosphorylase b was converted to phosphorylase a, and in an apparent biphasic process the phosphorylase a formed was subsequently converted to phosphorylase b. In the presence of adenosine 3':5'-monophosphate the rate of phosphorylase a formation and the maximal amount of phosphorylase a formed were increased. The cyclic AMP effect was enhanced by glucose-6-P and required the presence of glycogen. The catalytic subunit of cyclic AMP-dependent protein kinase could replace cyclic AMP in the stimulation of phosphorylase a formation. The effects of cyclic AMP or the catalytic subunit were shown to be due to stimulation of phosphorylase kinase rather than to inhibition of phosphorylase phosphatase. Preliminary fractionation experiments showed that it is possible to separate phosphorylase kinase catalytic activity from a factor or factors required for stimulation of its activation by the catalytic subunit.     

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.     

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.     

Liver phosphorylase b kinase. Cyclic-AMP-mediated activation and properties of the partially purified rat-liver enzyme.

Phosphorylase b kinase was extensively purified from rat liver. It was located in a form which could be activated 20--30-fold by a preincubation with adenosine 3':5'-monophosphate (cyclic AMP) and ATP-Mg. This activation was time-dependent, and was paralleled by a simultaneous incorporation of 32P from [gamma-32P]ATP into two polypeptides which comigrated in sodium dodecyl sulfate gel electrophoresis with the alpha and beta subunits of rabbit skeletal muscle phosphorylase b kinase. The liver enzyme was eluted from Sepharose 4B and Bio-Gel A-50m columns at the same place as muscle phosphorylase b kinase, which is indicative of a molecular weight of 1.3 x 10(6). After activation, the most purified liver preparation had a specific activity about 10-fold less than the homogeneous muscle enzyme at pH 8.2. The inactive enzyme form had a pronounced pH optimum around pH 6.0, whereas the activated form was mostly active above neutral pH. The activation of the enzyme reduced the Km for its substrate phosphorylase b severalfold. Liver phosphorylase b kinase was shown to be partially dependent on Ca2+ ions for its activity: addition of 0.5 mM [ethylenebis-(oxoethylenenitrilo)]tetraacetic acid (EGTA) to the phosphorylase b kinase assay increased the Km for phosphorylase b about twofold for both the inactive and the activated form of liver phosphorylase b kinase, but affected the V of the inactive species only.     

Skeletal muscle glycogen content, structure, and metabolism are normal in rats with hepatic glycogen phosphorylase kinase deficiency

Skeletal muscle glycogen content and structure, and the activities of several enzymes of glycogen metabolism are reported for the hepatic glycogen phosphorylase b kinase deficient (gsd/gsd) rat. The skeletal muscle glycogen content of the fed gsd/gsd rat is 0.50 +/- 0.11% tissue wet weight, and after 40 hours of starvation this value is lowered 40% to 0.30 +/- 0.05% tissue wet weight. In contrast the gsd/gsd rat liver has an elevated glycogen content which remains high after starvation. The skeletal muscle phosphorylase b kinase, glycogen phosphorylase, glycogen synthase and acid alpha-glucosidase activities are 17.2 +/- 2.9 units/g tissue, 119.9 +/- 6.4 units/g tissue, 12.2 +/- 0.4 units/g tissue and 1.4 +/- 0.4 milliunits/g tissue, respectively, with approx. 20% of phosphorylase and approx. 24% of synthase in the active form (at rest). These enzyme activities resemble those of Wistar skeletal muscle, and again this contrasts with the situation in the liver where there are marked differences between the Wistar and the gsd/gsd rat. Fine structural analysis of the purified glycogen showed resemblance to other glycogens in branching pattern. Analysis of the molecular weight distribution of the purified glycogen indicated polydispersity with approx. 66% of the glycogen having a molecular weight of less than 250 X 10(6) daltons and approx. 25% greater than 500 X 10(6) daltons. This molecular weight distribution resembles those of purified Wistar liver and skeletal muscle glycogens and differs from that of the gsd/gsd liver glycogen which has an increased proportion of the low molecular weight material.(ABSTRACT TRUNCATED AT 250 WORDS)     

The rate of calcium uptake into sarcoplasmic reticulum of cardiac muscle and skeletal muscle. Effects of cyclic AMP-dependent protein kinase and phosphorylase b kinase.

Calcium transport into sarcoplasmic reticulum fragments isolated from dog cardiac and mixed skeletal muscle (quadriceps) and from mixed fast (tibialis), pure fast (caudofemoralis) and pure slow (soleus) skeletal muscles from the cat was studied. Cyclic AMP-dependent protein kinase and phosphorylase b kinase stimulated the rate of calcium transport although some variability was observed. A specific protein kinase inhibitor prevented the effect of protein kinase but not of phosphorylase b kinase. The addition of cyclic AMP to the sarcoplasmic reticulum preparations in the absence of protein kinase had only a slight stimulatory effect despite the presence of endogenous protein kinase. Cyclic AMP-dependent protein kinase catalyzed the phosphorylation of several components present in the sarcoplasmic reticulum fragments; a 19000 to 21 000 dalton peak was phosphorylated with high specific activity in sarcoplasmic reticulum preparations isolated from heart and from slow skeletal muscle, but not from fast skeletal muscle. Phosphorylase b kinase phosphorylated a peak of molecular weight 95000 in all of the preparations. Cyclic AMP-dependent protein kinase-stimulated phosphorylation was optimum at pH 6.8; phosphorylase b kinase phosphorylation had a biphasic curve in cardiac and slow skeletal muscle with optima at pH 6.8 and 8.0. The addition of exogenous phosphorylase b kinase or protein kinase increased the endogenous level of phosphorylation 25-100%. All sarcoplasmic reticulum preparations contained varying amounts of adenylate cyclase, phosphorylase b and a (b:a = 30.1), "debrancher" enzyme and glycogen (0.3 mg/mg protein), as well as varying amounts of protein kinase and phosphorylase b kinase which were responsible for a significant endogenous phosphorylation. Thus, the two phosphorylating enzymes stimulated calcium uptake in the sarcoplasmic reticulum of a variety of muscles possessing different physiologic characteristics and different responses to drugs. In addition, the phosphorylation catalyzed by these enzymes occurred at two different protein moieties which make physiologic interpretation of the role of phosphorylation difficult. While the role phosphorylation in these mechanisms is complex, the presence of a glycogenolytic enzyme system may be an important link in this phenomenon. The sarcoplasmic reticulum represents a new substrate for phosphorylase b kinase.     

Studies on phosphorylase b kinase from neutral tissues

Abstract— Phosphorylase b kinase (ATP: phosphorylase phosphotransferase; EC 2.7.1.38), the enzyme which converts phosphorylase b to phosphorylase a (α-1,4-glucan: orthophosphate glucosyltransferase; EC2.4.1.1) was examined in nerve tissue. Both phosphorylase and phosphorylase kinase were present in all nerve tissues tested, with central tissues about ten times as active as peripheral nerve. Exceptions were the superior cervical and stellate ganglia, tissues rich in synapses, which displayed activity similar to brain. Phosphorylase kinase in brain had properties similar to those of the enzyme in skeletal and cardiac muscle; it was activated in vitro by ATP and adenosine 3′,5′-monophosphate (cyclic AMP) and by Ca²⁺. Subconvulsive doses of insulin or of amphetamine administered to mice produced some activation of the enzyme. It is concluded that the mechanism for activation of phosphorylase in nerve tissue is similar to that in muscle.     

Comparison of glycogen phosphorylase kinases of various rat tissues

Glycogen phosphorylase kinases in soluble fractions of various rat tissues were examined for the pH 6.8/8.5 activity ratio, Ca2+-dependency, activation by cyclic AMP-dependent protein kinase (protein kinase A), and reactivity with anti-skeletal muscle phosphorylase kinase serum. The enzymes could be divided into at least two major groups; muscle and liver types. The muscle type, that has a low value of pH 6.8/8.5 activity ratio, is highly dependent on Ca2+, markedly activated by protein kinase A, and strongly inhibited by the antiserum. Inversely, the liver type, that has a high value of pH 6.8/8.5 activity ratio, is poorly dependent on Ca2+, not activated by protein kinase A, and weakly inhibited by the antiserum. The enzymes from heart and skeletal muscle were similar and belonged to the former entity. Whereas, the enzymes from liver, kidney, spleen, lung, and testis appeared to belong to the latter entity. The enzyme from brain apparently differs from these entities, and seems to be an intermediate type or a hybrid of the two.     

Thiophosphate-activated phosphorylase kinase as a probe in the regulation of phosphorylase phosphatase.

Rabbit muscle nonactivated phosphorylase kinase (EC 2.7.1.38) is converted to thiophosphate-activated phosphorylase kinase by cyclic AMP dependent protein kinase, Mg2+ and ATP-gamma-S/adenosine-5'-O-(s-thiotriphosphate)/. The formation of thiophosphate-activated phosphorylase kinase wal also observed in the protein-glycogen complex from skeletal muscle. This new form of kinase is resistant to the action of phosphatase and behaves as a competitive inhibitor in the dephosphorylation of phosphorylase alpha by phosphorylase phosphatase (Ki = 0.04 mg per ml). The fact that the inhibitory effect of thiophosphate-activated phosphorylase kinase is 3 times higher than in the case of nonactivated kinase, may explain the transient inhibition of phosphorylase phosphatase in the protein-glycogen complex. The use of activated (phosphorylated) phosphorylase kinase supports this assumption since it causes a delay in the dephosphorylation of phosphorylase alpha, i.e. the conversion of phosphorylase alpha into beta could start only after the dephosphorylation of activated phosphorylase kinase.     

Regulation of the dephosphorylation of phosphorylase A by glucose, AMP and polyamines

1. The effect of glucose, caffeine, AMP and polyamines was investigated on the dephosphorylation of phosphorylase a by the catalytic subunits of protein phosphatase-1 and -2A. 2. Caffeine at 1-20 microM inhibited the dephosphorylation of the dimeric phosphorylase a at 37 degrees C using skeletal muscle enzymes; 0.1-10 mM of caffeine enhanced the rate of dephosphorylation greatly at 13 degrees C and slightly at 37 degrees C. 3. alpha-D-Glucose was more effective in accelerating both the dephosphorylation and the tryptic digestion of phosphorylase a than the beta-anomer. 4. Polyamines were found to moderate the inhibitory effect of AMP at concentrations which may occur in the tissues. In the presence of 5 mM glucose polyamines could cancel the AMP inhibition of the dephosphorylation of liver phosphorylase a by hepatic protein phosphatase-1 and -2A.     

Effects of decapitation, ether and pentobarbital on guanosine 3′,5′-phosphate and adenosine 3′,5′-phosphate levels in rat tissues

Cyclic GMP and cyclic AMP levels in eight different rat tissues were examined after animlas were immersed in liquid nitrogen. In order of decreasing concentration, cerebellu, kidney, lung and cerebral cortex contained the greatest quantities fo cyclic GMP. These tissues also contained relatively high concentrations of cyclic AMP. Compared to values in animals which were sacrificed in liquid nitrogen, levels of both nucleotides in many of the tissues examined were altered by decapitation or anesthesia with ether and pentobarbital. Decapitation increased the levels of both cyclic GMP and cyclic AMP in cerebellum, lung, heart, liver and skeletabl muscle. However, decapitation increased only cyclic AMP in cerebral cortex and kidney. Our previously reported high level of cyclic GMP in lung was attributed to ether anesthesia and surgical removal which increased the cyclic GMP content in lung, heart, testis and skeletal muscle. The effect of ether on cyclic GMP levels in lung and heart was blocked by pretreatment of animals with atropine which indicated that cholinergic agents increase cyclic GMP content in these tissues. Acetylcholine and carbachol in the presence of theophylline increased the accumulation of cyclic GMP in incubations of rat lung minces. Increases in cyclic GMP and cyclic AMP levels in cerebellum with ether anesthesia were prevented if rats were immersed in liquid nitrogen after anesthesis with ether. Anesthesia with pentobarbital decreased the levels of cyclic GMP in cerebellum and kidney and increased the nucleotide in heart, liver, testis and skeletal muscle compared to levels in tissues from animals immersed in liquid nitrogen. However, pentobarbital increased cyclic AMP levels in cerebellum and cerebral cortex and decreased the nucleotide in liver, kidney, testis and skeletal muscle. These studies provide a possible explanation for the variability in in vivo levels of cyclic GMP and cyclic AMP which have been previously reported. In addition, these studies support the hypothesis that the synthesis and degradation of cyclic AMP and cyclic GMP are regulated independently and not necessarily in a parallel or reciprocal manner. These studies also suggest that the increase accumulation of one cyclic nucleotide has no major effect on the synthesis and/or metabolism of the other; however, such interactions cannot be entirely excluded from the results of this study.     

The effect of adenylate cyclase inhibitor (ACI) on guanylate cyclase, phosphodiesterase and other enzymes in heart.

The effect of an inhibitor of adenylate cyclase (ACI) was measured on some enzymes associated with cyclic nucleotide-regulated metabolism. Soluble guanylate cyclase was inhibited; both soluble and particulate cyclic GMP-phosphodiesterases were stimulated. Cyclic AMP phosphodiesterases were unaffected. In contrast, the activities of Na, K-ATPase, protein kinase, phosphorylase kinase, glycogen synthetase and a number of glycosidases were not altered by equipotent amounts of the inhibitor. It is concluded that this substance acts as a modulator of both cyclic AMP and cyclic GMP metabolism in heart and other tissues.     

Metabolic control of phosphorylase conversion in muscle. Effect of fasting and refeeding on the response of rat diaphragm glycogen phosphorylase, cyclic AMP Dependent protein kinase, and phosphorylase b kinase to adrenergic stimulation.

The influence of fasting and refeeding on the response to adrenergic stimulation of several enzymes involved in glycogen metabolism has been investigated in the isolated, intact rat diaphragm. The in vitro response of the phosphorylase system to terbutaline was found to decrease markedly following fasting. A pronounced increase in this response was seen upon refeeding. This increased responsiveness was normalized by incubation of isolated tissues with palmitate (1.5 mM). Plasma free fatty acid concentration was increased in fasted rats compared to the value found in refed animals. The effect of terbutaline on cyclic AMP concentration and protein kinase activity was not significantly influenced by fasting and refeeding while fasting decreased the effect of terbutaline upon phosphorylase b kinase. Diaphragm glycogen levels were reduced by more than 50% in rats fasted for 24 hours and were significantly increased upon refeeding compared to fed rats. The results indicate that the nutritional state can modulate the sensitivity of the interconverting system for phosphorylase. It is suggested that this modulation might depend upon fatty acid metabolism.     

Effect of andrenalectomy on cyclic 3',5'-guanosine monophosphate metabolism of rat liver and other tissues

Adrenalectomy increased guanyl cyclase and cyclic GMP phosphodiesterase activities in liver and other rat tissues. Liver guanyl cyclase activities from adrenalectomized rats were increased above those of normal controls according to kinetic analysis, gel filtration, ion-exchange chromatography, discontinuous sucrose gradient fractionation, sulfhydryl inhibition, and secretin activation. The effects of adrenal insufficiency on hepatic guanyl cyclase and cyclic GMP phosphodiesterase were prevented by cortisone acetate administration. Immunoassay of liver and skeletal muscle cyclic GMP after adrenalectomy showed markedly decreased levels in liver, but increased levels in skeletal muscle. In liver and other tissues, basal adenyl cyclase and cyclic AMP phosphodiesterase activities were unaffected by adrenalectomy. Hepatic levels of cyclic AMP were also unchanged by adrenalectomy. Hypophysectomy raised guanyl cyclase activity in liver but had no effect on liver cyclic GMP phosphodiesterase activity. These alterations are discussed in relation to possible glucocorticoid regulation of cyclic GMP metabolism.     

Skeletal muscle phosphorylase kinase catalytic subunit mRNAs are expressed in heart tissue but not in liver

A cDNA encoding the skeletal muscle phosphorylase kinase catalytic subunit gamma has been isolated and sequenced. It contains 57 nucleotides of 5' nontranslated sequence, the entire coding sequence, and 1004 nucleotides of 3' nontranslated sequence. Probes derived from this gamma-cDNA were used to investigate the expression of gamma-messages in liver, heart, and skeletal muscle tissues. The results demonstrate that the gamma-mRNAs expressed in heart tissue are homologous to the skeletal muscle gamma-mRNAs. However, in liver tissue, no homologous gamma-mRNAs were detected. The implications of these results for understanding gamma-isoform expression and the possibility of a liver-specific gamma-gene are discussed.     

Regulation of muscle phosphorylase b kinase activity by inorganic phosphate and calcium ions

The regulation of the activity of blowfly flight-muscle phosphorylase b kinase by P(i) and Ca(2+) was studied, and the actions of these effectors on the kinases from insect flight and rabbit leg muscles were compared. Preincubation of blowfly kinase with P(i) increased activity severalfold. The effect was concentration-dependent, with an apparent K(m) of about 20mm, and time-dependent, requiring at least 10min for maximal activation. Neither ATP nor cyclic AMP was needed, suggesting that a protein kinase may not be involved. Maximal activation of the insect kinase required Mg(2+) in addition to P(i). The apparent K(m) for Mg(2+) was 3mm. Rabbit leg-muscle phosphorylase b kinase was slightly inhibited, rather than stimulated, by P(i), and was strongly inhibited by K(+), Na(+) and Li(+). At physiological concentrations, Ca(2+) activated the phosphorylase b kinases from both blowfly flight and rabbit leg muscles. However, the responses to Ca(2+) of the enzymes from the two tissues were different. The mammalian kinase had virtually no activity in the absence of Ca(2+), and showed a large increase in activity over a narrow range of Ca(2+) concentrations. Flight-muscle kinase had appreciable activity in the absence of Ca(2+), and had a smaller increase over a wide range of Ca(2+) concentration. The concentrations of Ca(2+) required for half-activation were 0.1 and 1mum for the blowfly and rabbit enzymes respectively. The pH-activity profiles of the non-activated, phosphate- and Ca(2+)-activated kinase revealed considerable enhancement of activity with little, if any, increase in the ratio of activities at pH6.8 to those at 8.2. These results are discussed in relation to the mechanism coupling contraction to glycogenolysis and to the biochemical distinction between asynchronous and synchronous types of muscle.