Studies on phosphorylase isozymes in lower vertebrates. Purification and properties of lamprey phosphorylase.

Skeletal muscle phosphorylase b has been purified from lamprey, Entosphenus japonicus, to a state of homogeneity as judged by the criterion of sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis. The enzyme was completely dependent on AMP for activity and converted into the a form by rabbit muscle phosphorylase kinase in the presence of ATP and Mg²⁺. The subunit molecular weight determined by SDS-gel electrophoresis was 94,000 ± 1,600 (SE). The enzyme activity was stimulated by Na₂SO₄, but was not affected by mercaptoethanol. The K_m values of the a form for glucose 1-phosphate and glycogen were 3.5 mm and 0.13%, respectively, and those of the b form for glucose 1-phosphate, glycogen, and AMP were 15 mm, 0.4%, and 0.1 mm, respectively. These values were smaller than those reported with lobster phosphorylase and greater than those reported with mammalian skeletal muscle phosphorylases. Electrophoretic and immunological studies have indicated that lamprey phosphorylase b exists as a single molecular form in skeletal muscle, heart, brain, and kidney. Rabbit antibody against lamprey phosphorylase cross-reacted with phosphorylases from skate and shark livers more intensely than with those from skeletal muscles.     

The cardiac sarcoplasmic reticulum-glycogenolytic complex A possible effector site for cyclic

Cardiac sarcoplasmic reticulum-glycogenolytic complex, isolated as a single peak on sucrose density gradient, may function as a “compartmented” effector site for cyclic AMP resulting in modulation of both glycogenolysis and calcium transport. The conversion of phosphorylase b to a is stimulated by ATP and inhibited by protein kinase inhibitor. Cyclic AMP alone stimulated neither phosphorylase b to a conversion nor calcium uptake. An inhibitor of adenylate cyclase depressed both calcium uptake and phosphorylase activation and both functions were subsequently stimulated by micromolar concentrations of cyclic AMP. Endogenous phosphorylation of sarcoplasmic reticulum was also inhibited by adenylate cyclase inhibitor and the inhibition was reversed by cyclic AMP. These results suggest that the sarcoplasmic reticulum of cardiac muscle is an internal effector site for cyclic AMP which may regulate both calcium and metabolism. It appears that cyclic AMP formation in vitro is not the rate-controlling step in the activation sequence.     

The role of phosphorylase in the inhibitory effect of EDTA and ATP on liver glycogen synthase phosphatase.

The work of Gilboe and Nuttall on the inhibition of liver synthase phosphatase activity by EDTA (J. Biol. Chem., 253, 4078–4081, 1978) and by ATP (Biochim. Biophys. Acta, 338, 57–67, 1974) has been confirmed and extended. It appears that these inhibitory effects are not specific since they can be elicited by other polyvalent anions and that they are transient since they last only as long as phosphorylase a is present. The duration of these inhibitory effects can be shortened by the addition of glucose or caffeine which stimulate phosphorylase phosphatase activity. It is concluded that the inhibitory effects of EDTA and ATP are mediated by phosphorylase a.     

Control of platelet glycogenolysis activation of phosporylase 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 Ca²⁺ markedly activate phosphorylase b kinase from human platelets, with a K_a of 0.89 μM Ca²⁺, which is similar to that for the skeletal muscle enzyme. The kinase activity is unstable, and on enzyme ageing there is a 50% loss in activity with the K_a decreasing to 0.33 μM Ca²⁺.In unstimulated platelets, phosphorylase a was 13.3% of total 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 Ca²⁺, which directly stimulates phosphorylase b kinase without altering glycogen synthetase activity. The cyclic AMP-dependent protein kinase does not appear to be involved.     

The susceptibility of muscle phosphorylases a and b to digestion by a neutral proteinase from rat intestinal muscle. Comparison with the effects produced by pancreatic trypsin and chymotrypsin

1. Phosphorylase b was inactivated three times more rapidly than phosphorylase a by a neutral, trypsin-like proteinase from rat intestinal muscle. Digestion of phosphorylase a produced a modified form which was deactivated by AMP. Removal of the pyridoxal phosphate cofactor increased the rate of inactivation of the b form by about 3-fold but the subceptibility of apophosphorylase a was no different from the holo form. 2. The extent of proteolysis of both holoenzyme forms, as guaged by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis, was limited and similar digestion patterns were obtained in both cases. 3. With ³²P-labelled phosphorylase a as substrate, the initial event in the inactivation was the release of a trichloroacetic acid-soluble peptide from the N-terminus of the enzyme, leaving the original 100000 subunit form essentially unchanged. Subsequent proteolysis was restricted, producing derivatives of mol.wt. 85000, 70000 and 65000, none of which contained any radioactive label. 4. By treatment of inactivated phosphorylase b with carboxypeptidase B, it was shown that the intestinal muscle proteinase had cleaved approximately 3 -Lys-X and 3 -Arg-X bonds in the polypeptide. 5. The protective effects of various allosteric modulators of phosphorylase on the inactivation of the a and b forms were generally in agreement with the known roles of the modifiers. Glucose increased the susceptibility of phosphorylase a. 6. Inactivation of phosphorylase b by trypsin and chymotrypsin also resulted in limited proteolysis but, in both cases, the digestion patterns obtained on sodium dodecyl sulphate/polyacrylamide gels were different from each other and from the pattern obtained with the intestinal muscle proteinase. 7. Inactivation of phosphorylase b by the muscle proteinase is about 100 times more rapid than the effects produced by trypsin or chymotrypsin when the activities are compared on an equimolar basis. 8. Consideration is given to regulation of the rate of enzyme degradation intracellularly by modulation of the conformation and susceptibility of the enzyme via factors such as covalent modification, allosteric ligands and state of aggregation.     

Effect of adrenalectomy on cellular calcium metabolism and on the response to adrenergic stimulation of hepatocytes isolated from male and female rats

The effects of adrenalectomy on cell calcium metabolism and on the effects of epinephrine on cAMP, phosphorylase a activity, and calcium efflux were studied in hepatocytes isolated from adult male and female rats. Adrenalectomy increased the total calcium of hepatocytes, all exchangeable calcium pools, and all calcium fluxes between the cellular pools in both sexes. After adrenalectomy, basal cAMP was elevated, phosphorylase a + b was decreased, but basal phosphorylase a activity was not changed. In adrenalectomized males and at all concentrations of epinephrine studied (1·10^?8?1·10^?5M) stimulation of calcium efflux was decreased and cAMP accumulation was enhanced, while the resulting phosphorylase a activation was depressed. In hepatocytes from adrenalectomized females there was a similar increase in cAMP accumulation induced by epinephrine, and a decrease in the stimulation of calcium efflux; however, the depression in phosphorylase a activation was much less and was significant only at 1·10^?8 and 1·10^?5M epinephrine. In the male, while activation of phosphorylase a shifted from a pure α-adrenergic response mediated by calcium to one also involving a cAMP-mediated β-adrenergic response, the contribution of the attenuated calcium signal was still significant. Hepatocytes from female rats did not show a comparable α- to β-shift, since the relative contribution of calcium and cAMP to phosphorylase activation was similar in sham-operated and adrenalectomized animals.     

Purification and characterization of the Novikoff hepatoma glycogen phosphorylase and its relations to a fetal form

The Novikoff hepatoma glycogen phosphorylase b has been purified over 300-fold, free of glycogen synthetase, some of its properties have been studied, and its relationship to fetal forms of rat muscle and liver phosphorylase has been established immunochemically. Its molecular weight is approximately 200,000, and, like the liver but unlike the muscle isozyme, it does not dimerize on conversion to the a form. However, it differs from the liver isozyme in being activated by AMP (K_a = 0.2 mM) and in not being activated by sulfate ion. Antibody to the adult rat muscle phosphorylase did not inhibit the activity of the tumor or liver isozyme. Although antibody to liver or hepatoma phosphorylase had no effect on adult muscle phosphorylase, each of these antibodies partially inhibited the other enzyme. These findings indicate the presence of some liver isozyme in the tumor, and this was confirmed by isoelectric focusing. Rat liver and muscle phosphorylase (and synthetase) were low during embryonal development but rose rapidly at or shortly after birth. Immunochemical studies revealed that both fetal liver and fetal muscle phosphorylases are immunologically identifiable with the tumor enzyme; and the fetal form is also present as a major form in rat kidney and brain.     

Effect of limited proteolysis of potato phosphorylase on activity and structure.

The course of the proteolysis of potato α-gluean phosphorylase (EC 2.4.1.D has been followed hy means of sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and by determination of residual activity. Trypsinolysis results in rapid hydrolysis in the middle part of the polypeptide chain (site a) without loss of enzyme activity, followed by much slower cleavage near the terminus (site b) which accompanies a significant decrease in activity. Substrate causes suppression of the inactivation and of the hydrolysis at site b, but not of the one at site a. The results of a kinetic study indicate that the site of substrate binding interacts directly with site b. Preferential hydrolysis in the middle part of the chain has been observed also in the case of chymotrypsinolysis. The results are discussed in connection with the structure of potato phosphorylase.     

Hexose Metabolism in Pancreatic Islets: Glycogen Synthase and Glycogen Phosphorylase Activities

The activity of glycogen synthase and glycogen phosphorylase was measured in rat pancreatic islet homogenates. For this purpose, the sensitivity of current radioisotopic procedures for the assay of these enzymes in liver extracts was increased by about two orders of magnitude. Even so, the measurement of glycogen synthase and phosphorylase in islet homogenates was hampered by a potent amylase-like activity, resulting in the hydrolysis of preformed or newly formed ¹⁴C-labeled glycogen. Acarbose suppressed the latter phenomenon which was found attributable to both minute contamination of isolated islets by acinar cells and genuine α-amylase activity in purified islet β-cells. As measured by the more sensitive method in the presence of acarbose, the a/(a + b) ratio for glycogen synthase activity in islet homogenates was increased in islets preincubated in the presence as distinct from absence of D-glucose and decreased after preincubation with forskolin. These changes represented a mirror image of those evoked by D-glucose and forskolin in the a/(a + b) ratio for glycogen phosphorylase activity. It is concluded that glycogen synthesis and breakdown are regulated in the endocrine pancreas in a manner qualitatively comparable to that prevailing in hepatocytes, the possible participation of an amylase-like activity to glycogen metabolism in intact islet β-cells requiring further investigation.     

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.     

Evidence for the non-identity of proteins having synthase phosphatase,phosphorylase phosphatase and histone phosphatase activity in rat liver

Synthase phosphatase, phosphorylase phosphatase and histone phosphatase in rat liver were measured using as substrate purified liver synthase D, phosphorylase a and ³²P-labelled phosphorylated f1 histone, respectively. The three phosphatase enzymes had different sedimentation characteristics. Both synthase phosphatase and phosphorylase phosphatase were found to sediment with the microsomal fraction under our experimental conditions. Only 10% of histone phosphatase was in this fraction; the majority was in the cytosol. No change in histone phosphatase was observed in the adrenalectomized fasted rat whereas synthase phosphatase and phosphorylase phosphatase activities were decreased 5–10-fold. Fractionation of liver extract with ethanol produced a dissociation of the three phosphatase activities. When a partially purified fraction was put on a DEAE-cellulose column, synthase phosphatase and phosphorylase phosphatase both exhibited broad elution profiles but their activity peaks did not coincide. Histone phosphatase eluted as a single discrete peak. When the supernatant of CaCl₂-treated microsomal fraction was put on a Sepharose 4B column, the majority of synthase phosphatase was found to elute with the larger molecular weight proteins whereas the majority of phosphorylase phosphatase eluted with the smaller species. Histone phosphatase migrated as a single peak and was of intermediate size. Synthase phosphatase was inhibited by phosphorylase a (K_i < 1 unit/ml) and phosphorylase phosphatase by synthase D (K₁ ≈ units/ml). The inhibition of synthase phosphatase by phosphorylase a was kinetically non-competitive with substrate. Histone phosphatase activity was not inhibited by synthase D or by phosphorylase a. The above results suggest that different proteins are involved in the dephosphorylation of synthase D, phosphorylase a and histone in the cell.     

Lack of Types 1 and 2A Protein Serine(P)/Threonine(P) Phosphatase Activities in Chloroplasts

Protein phosphatase activity in crude leaf extracts and in purified intact chloroplasts of wheat (Triticum aestivum) and pea (Pisum sativum) was analyzed using exogenously supplied phosphoproteins or endogenous thylakoid proteins. Leaf extracts contain readily detectable amounts of protein phosphatase activity measured with either phosphohistone or phosphorylase a, substrates of mammalian protein phosphatases. No significant chloroplast protein phosphatase activity was detected using these exogenous phosphoproteins. The dephosphorylation of endogenous thylakoid light-harvesting chlorophyll a/b binding proteins in situ was inhibited by fluoride, but not by microcystin-LR or okadaic acid, diagnostic inhibitors of mammalian types 1 and 2A protein phosphatases. Additionally, no evidence for a pea chloroplast alkaline phosphatase activity was found using β-glycerolphosphate or 4-methylum-belliferyl phosphate as substrates. From these results, we conclude that phosphohistone and phosphorylase a are not useful substrates for chloroplast thylakoid protein phosphatase activity and that the chloroplast enzymes may not fit into one of the canonical classifications currently used for protein phosphatases.     

Studies on phosphorylase isozymes in lower vertebrates: evidence for the presence of two isozymes in elasmobranchs.

Two distinct phosphorylase isozymes, skeletal muscle phosphorylase b and liver phosphorylase b, have been purified from skate (Raja pulchra) in a homogeneous form as judged by electrophoretic and immunological criteria. Both isozymes were dependent on AMP for activity and converted to a forms by rabbit muscle phosphorylase kinase. Their subunit molecular weight determined by sodium dodecyl sulfate-gel electrophoresis was 94,000. These isozymes were distinctly different in affinities for glycogen and AMP, while they were very similar in sensitivities to SO₄^2?. Rabbit antibodies against each of the muscle and liver isozymes inhibited completely the respective specific antigens. No cross-reaction was observed in double diffusion tests, but some immunological relatedness of these isozymes was demonstrated by inhibition tests with antibodies. Their similarity was also shown by amino acid analyses. No evidence has been obtained that the skate possesses such an isozyme as mammalian phosphorylase L, the b form of which is inactive even in the presence of AMP. Electrophoretic studies on phosphorylases of crucian carp, toad, and snake revealed that these animals possess three isozymes which strikingly resemble mammalian isozymes in the organ-specific distribution and electrophoretic behavior.     

Regulation of muscle phosphorylase activity by carnosine and anserine

Carnosine (β-alanyl-L-histidine) activates rabbit muscle phosphorylase $\text{a}$ in the presence and absence of AMP and phosphorylase $\text{b}$ in the presence of AMP in a biphasic manner with a maximal activation at about 50mM carnosine and with phosphorylase $\text{b}$ showing a greater degree of activation than phosphorylase $\text{a}$. Anserine (β-alanyl-L-N^π-methyl-histidine) activates phosphorylase $\text{a}$ to a lesser extent than carnosine up to a concentration of 90mM, whereas with phosphorylase $\text{b}$ a weak activation below 30mM and a concentration-dependent inhibition above this concentration occurs. These effects are specific for the dipeptides and are not shown by their constituent amino acids. Carnosine and anserine activate phosphorylase $\text{a}$ in the presence of the allosteric inhibitors ATP, D-glucose and caffeine, and the inhibition of phosphorylase $\text{b}$ by anserine is also observed in the presence of these inhibitors.     

The phosphorylation of troponin B by phosphorylase b kinase in skeletal muscle of mice carrying the phosphorylase b kinase deficiency gene

In skeletal muscle of animals with the phosphorylase $\text{b}$ kinase deficiency gene there is < 1% of the normal activity to convert phosphorylase $\text{b}$ to $\text{a}$ in the presence of Ca⁺⁺, Mg⁺⁺, and ATP (1). Correspondingly, there is < 1% of the normal activity to phosphorylate phosphorylase $\text{b}$. Nevertheless, under the same conditions, these extracts catalyze the phosphorylation of troponin at a rate 57% of normal. Phosphorylase $\text{b}$ converting activity can be sedimented from skeletal muscle of control mice by centrifugation. This fraction isolated from I strain skeletal muscle extracts phosphorylates troponin at a rate 29–39% of the control. EGTA¹ (15 mM) inhibits troponin phosphorylation by 50–60% in this fraction from both strains. The EGTA inhibition is reversed by 15 mM Ca⁺⁺. Thus the phosphorylase $\text{b}$ kinase in skeletal muscle of animals with the phosphorylase $\text{b}$ kinase deficiency gene can phosphorylate troponin B, although it shows little or no activity with phosphorylase as a substrate. This observation is consistent with the normal muscle contractility of I strain animals.     

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.     

Purification and properties of glycogen phosphorylase a from the muscle of the blue crab, Callinectes danae

Blue crab muscle (Callinectes danae) glycogen phosphorylase a was purified by adsorption of a crude extract on a starch column, elution with a dilute glycogen solution, selective precipitation with ammonium sulfate, dialysis against a solution containing ammonium sulfate and ethylenediaminetetraacetate, followed by centrifugation and chromatography on Sephadex G-25 (sp act 64.5 IU, recovery of 53.8%, and a purification factor of 189). The lyophilized preparation is stable for several months. Disc electrophoresis of the purified phosphorylase yields two protein bands, both with enzymatic activity of the a form. One of the protein bands represents about 10% of the total amount of protein present in the two bands. The molecular weight of the enzyme is 176,000 as determined by ultracentrifugation in a sucrose density gradient and 180,000 as determined by discontinuous polyacrylamide gel electrophoresis. The molecular weight found by disc electrophoresis corresponds to the main protein band. Crab muscle phosphorylase a is not associated under electrophoretic conditions in which rabbit muscle phosphorylase a shows association behavior. Subunit studies by continuous SDS-gel electrophoresis suggest that crab muscle phosphorylase a possesses only one subunit. Pyridoxal-5′-phosphate is a cofactor of the enzyme.     

Glycogen phosphorylase from flight muscle of the hawk moth,Manduca sexta: purification and properties of three interconvertible forms and the effect of flight on their interconversion

Glycogen phosphorylase (EC 2.4.1.1) of Manduca sexta flight muscle was separated into three distinct peaks of activity on diethylaminoethyl-Sephacel. The three fractions of phosphorylase activity were further purified by affinity chromatography on AMP-Sepharose and shown to have the same relative molecular mass (=178000) on polyacrylamide gradient gel electrophoresis under non-denaturating conditions and to produce subunits of molecular mass =92000 on SDS gelelectrophoresis. On the basis of their kinetic properties with respect to the activator AMP and the inhibitor caffeine, the three fractions of phosphorylase activity were assigned as follows: peak 1=phosphorylase b (unphosphorylated form), peak 3=phosphorylase a (phosphorylated form); peak 2 represented a phospho-dephospho hybrid in which only one subunit of the dimeric enzyme was phosphorylated. This hypothesis was corroborated as the various forms could be interconverted in vitro by either dephosphorylation by an endogenous protein phosphatase producing the b form, or by phosphorylation catalyzed by purified phosphorylase kinase from rabbit muscle producing phosphorylase ab and a. From muscle of resting moths more phosphorylase was isolated in the b form (41%) than in the forms ab (28%) and a (31%), respectively. This proportion was changed in favour of the fully phosphorylated a form after a brief interval of flight when 68% of the phosphorylase activity was represented by the a form and only 13% by the b form. Unlike the phosphorylated forms a and ab of phosphorylase, the b form had low affinities for the substrates and for the activator AMP, and was virtually inactive if near-physiological concentrations of substrates and effectors were employed in the assays. The results demonstrate that in Manduca flight muscle three forms of phosphorylase coexist and that their interconversion is a mechanism for regulating phosphorylase activity in vivo.Abbreviations DEAE diethylaminoethyl - EDTA ethylenediamine tetraacetate - EGTA ethyleneglycol-bis(-aminoethylether)N,N-tetra-acetic acid - M _r relative molecular mass - NMR nuclear magnetic resonance - PAGGE polyacrylamide gradient gel electrophoresis - P_i morganic phosphate - SDS sodium dodecylsulphate - TRIS tris(hydroxymethyl)-aminomethane - V _max maximum activity     

Ca2+-dependent activation of phosphorylase by phosphorylase kinase in adipose tissue

Phosphorylase kinase (EC 2.7.1.38) activity in crude cytosol preparations of chicken adipose tissue was assayed using as substrate either the endogenous phosphorylase b in the preparation or added purified rabbit skeletal muscle phosphorylase b. The results obtained with the two substrates were similar. The phosphorylase kinase reaction was markedly inhibited by ethyleneglycol-bis-(β-aminoethylether)-N,N′,-tetraacetic acid (EGTA), maximum inhibition (about 90%) occurring at approx. 0.2 mM. This inhibition was readily reversed by addition of Ca²⁺. Full reversal was achieved with 0.3 mM Ca²⁺ in the presence of 0.5 mM EGTA; the estimated free Ca²⁺ concentration required was 4 μM. The activation of phosphorylase b was blocked immediately and completely by EGTA added during the course of the assay; reversal was achieved without a time lag by the addition of Ca²⁺. The Ca²⁺ requirement was also demonstrated directly by preparing an enzyme fraction from which Ca²⁺ had been removed and by using Ca²⁺-free reagents. Under these conditions the Ca²⁺ concentration needed for half maximum activation was 10 μM and maximum activation was obtained at about 100 μM. The possibility that the effects of EGTA and Ca²⁺ might be related to changes in phosphorylase phosphatase activity rather than phosphorylase kinase was considered unlikely since the phosphorylase phosphatase activity was inhibited during the phosphorylase kinase assay step by the inclusion of fluoride and β-glycerophosphate. Phosphorylase kinase activity in rat adipocytes, using endogenous phosphorylase as substrate, was also inhibited EGTA but, whereas the activity in chicken adipose tissue was inhibited by 90%, the activity in rat adipose tissue was inhibited only 60%. These data indicate that adipose tissue phosphorylase kinase has a Ca²⁺ requirement for optimal activity and is thus qualitatively similar to the enzyme in contractile tissues.