Novel aspects of skeletal muscle protein kinase and protein phosphatase regulation by Ca2+

Preparation and functional characterization of a catalytically active fragment of phosphorylase kinase

Limited proteolysis of rabbit muscle phosphorylase kinase catalyzed by chymotrypsin generates a 33 kD product whose kinase activity is independent of both calcium and pH over the range of 6.8 to 8.3 (Malencik, D.A. & Fischer, E.H. Calcium and Cell Function III: 161-188, 1982). This active preparation consists of three related species containing residues 1-290, 1-296, and 1-298 of the 44.7 kD gamma-subunit of phosphorylase kinase (Harris, W.R., Malencik, D.A., Johnson, C.M., Carr, S.A., Roberts, G.D., Byles, C.E., Anderson, S.R., Heilmeyer, L.M.G., Fischer, E.H. & Crabb, J.W.J. Biol. Chem. 265:11740-11745, 1991). Good recoveries of catalytic activity--with varying degrees of calcium dependence--result upon the digestion of phosphorylase kinase with assorted proteases. However, especially high yields of the chymotryptic fragment are obtainable, with purification on an Ultrogel-34 column and a DEAE Sepharose CL-6B column giving 23% of the maximum possible protein. Physical characterization shows that the 33 kD chymotryptic fragment is globular, with S20,w = 2.9S, and that it has an isoelectric point of 5.3. Our continuous catalytic assay, based on differences in the binding of the fluorescent dye 1-anilinonaphthalene-8-sulfonate by phosphorylase a and b, shows that, on a molar basis, the activity of the fragment is 2.8 fold greater than that of phosphorylase kinase (Malencik, D.A., Zhao, Z. and Anderson, S.R. Biochem. Biophys. Res. Comm. 174: 344-350, 1991). The active fragment also undergoes autophosphorylation. Incubation with Mg[gamma-P32] ATP results in the reaction of 0.7 mol 32P/mol fragment. When the catalytic subunit of the cAMP-dependent protein kinase is also present, the amount of 32P incorporated increases to 1.1 mol/mol. In the former case, phosphorylation occurs primarily at Ser30 while in the latter an additional reaction takes place at Ser81. The phosphopeptides correspond to sequences occurring in the gamma-subunit of phosphorylase kinase.

Interaction sites on phosphorylase kinase for calmodulin

Holophosphorylase kinase was digested with Glu-C specific protease; from the peptide mixture calmodulin binding peptides were isolated by affinity chromatography and identified by N-terminal sequence analysis. Two peptides originating from the alpha subunit, having a high tendency to form a positively charged amphiphilic helix and containing tryptophane, were synthesized. Additionally, a homologous region of the beta subunit and a peptide from the alpha subunit present in a region deleted in the alpha' isoform were also selected for synthesis. Binding stoichiometry and affinity were determined by following the enhancement in tryptophane fluorescence occurring upon 1:1 complex formation between these peptides and calmodulin. Finally, Ca2+ binding to calmodulin in presence of peptides was measured. By this way, the peptides alpha 542-566, alpha 547-571, alpha 660-677 and beta 597-614 have been found to bind specifically to calmodulin. Together with previously predicted and synthesized calmodulin binding peptides four calmodulin binding regions have been characterized on each the alpha and beta subunits. It can be concluded that endogenous calmodulin can bind to two calmodulin binding regions in gamma as well as to two regions in alpha and beta. Exogenous calmodulin can bind to two regions in alpha and in beta. A binding stoichiometry of 0.8 mol of calmodulin/alpha beta gamma delta promoter of phosphorylase kinase has been determined by inhibiting the ubiquitination of calmodulin with phosphorylase kinase. Phosphorylase kinase is half maximally activated by 23 nM calmodulin which is in the affinity range of calmodulin binding peptides from beta to calmodulin. Therefore, binding of exogenous calmodulin to beta activates the enzyme. A model for switching endogenous calmodulin between alpha, beta and gamma and modulation of ATP binding to alpha as well as Mg2+/ADP binding to beta by calmodulin is presented.

The binding of phosphorylase kinase to immobilized calmodulin

The binding of phosphorylase kinase to calmodulin-Sepharose 4B was studied by column and batch methods. It was found that the Ca2+ dependence of the interaction strongly depended on the degree of substitution of agarose with calmodulin. Equilibrium adsorption isotherms (i.e., bulk ligand binding functions and lattice site binding functions) of phosphorylase kinase were measured on calmodulin-Sepharose. Sigmoidal bulk ligand binding functions (bulk adsorption coefficients: 1.5-5.8) were found which indicate intermolecular attraction during binding. Hyperbolic lattice site binding functions (lattice adsorption coefficients: 1.0) were obtained thus excluding the existence of a critical surface concentration of immobilized calmodulin and indicating single independent binding sites on the gel surface and on phosphorylase kinase. These findings were combined to optimize the adsorption of phosphorylase kinase on calmodulin-Sepharose, for purification procedures at low Ca2+ concentrations (5-10 microM) minimizing proteolysis by calpains. With this novel method phosphorylase kinase from rabbit and frog skeletal muscle could be purified ca 100- and 200-fold, respectively, in two steps.

Sites phosphorylated in bovine cardiac troponin T and I. Characterization by 31P-NMR spectroscopy and phosphorylation by protein kinases

Bovine cardiac troponin isolated in a highly phosphorylated form shows four 31P-NMR signals [Beier, N., Jaquet, K., Schnackerz, K. & Heilmeyer, L.M.G. Jr (1988) Eur. J. Biochem. 176, 327-334]. Troponin I, which contains phosphate covalently linked to serine-23 and/or -24 [Swiderek, K., Jaquet, K., Meyer, H. E. & Heilmeyer, L. M. G. Jr (1988) Eur. J. Biochem. 176, 335-342], shows three resonances. Mg2(+)-saturation of holotroponin shifts these troponin I resonances to higher fields. Direct binding of Mg2+ to the phosphate groups can be excluded. Both these serine residues of troponin I, 23 and 24, are substrates for cAMP- and cGMP-dependent protein kinases as well as for protein kinase C. Isolated bovine cardiac troponin T contains 1.5 mol phosphoserine/mol protein, indicating that minimally two serine residues are phosphorylated. One phosphoserine residue is located at the N-terminus. An additional phosphoserine is located in the C-terminal cyanogen bromide fragment, CN4, which contains covalently bound phosphate. Protein kinase C phosphorylates serine-194, thus demonstrating exposure of this residue on the surface of holotoponin.

Evidence that phosphorylase kinase exhibits phosphatidylinositol kinase activity

Phosphorylase kinase phosphorylates the pure phospholipid phosphatidylinositol. Furthermore, it catalyzed phosphatidylinositol 4-phosphate formation using as substrate phosphatidylinositol that is associated with an isolated trypsin-treated Ca2+-transport adenosinetriphosphatase (ATPase) preparation from skeletal muscle sarcoplasmic reticulum. On this basis a fast and easy assay was developed that allows one to follow the phosphatidylinositol kinase activity during a standard phosphorylase kinase preparation. Both activities are enriched in parallel approximately to the same degree. Neither chromatography on DEAE-cellulose nor that on hydroxyapatite in the presence of 1 M KCl separates phosphatidylinositol kinase from phosphorylase kinase. The presence of a lipid kinase, phosphatidylinositol kinase, in phosphorylase kinase is not a general phenomenon; diacylglycerol kinase can be easily separated from phosphorylase kinase. Polyclonal anti-phosphorylase kinase antibodies as well as a monoclonal antibody directed specifically against the alpha subunit of phosphorylase kinase immunoprecipitate both phosphorylase kinase and phosphatidylinositol kinase.

Two-dimensional electron microscopic analysis of the chalice form of phosphorylase kinase

Phosphorylase kinase (Mr 1.3 X 10(6], a Ca2+-calmodulin-dependent protein kinase, plays a key role in the initiation of glycogenolysis. After purification on hydroxylapatite, the negatively stained enzyme was used for electron microscopy. In electron micrographs, phosphorylase kinase shows two major molecular forms: a butterfly form (approx. 60%) and a chalice form (approx. 40%). Images of the chalice form of the enzyme were computer-averaged by the method of single particle averaging. The following apparent molecular dimensions were obtained from the averages: total height, 20 nm; maximal width, 18 nm. The chalice form of phosphorylase kinase consists of a major structure termed the cup (11 nm X 18 nm), containing a large accessible cleft, and a minor structure termed the stem (8 nm X 9 nm). A closer examination of the images by averaging of molecular parts revealed two subpopulations of the cup part: a flexed (closed) type and an extended (open) type. The orifice, which can be closed partly by two protrusions (I, I'), is about 6 nm wide when the protrusions are flexed and 9 nm wide when they are extended. It is suggested that the substrates, e.g. phosphorylase b, may be accommodated in the large cleft of the enzyme. While the orientation of the protrusions (I, I') is the most obvious difference between the two types, more structural differences can be detected, suggesting a concerted movement of the protein domains against each other.

Dual function of calmodulin (delta) in phosphorylase kinase

The Ca2+-independent activity of fast skeletal muscle phosphorylase kinase, A0, can be reversibly stimulated by heparin more than 20-fold; concomitantly the Ca2+-dependent A2 activity is abolished completely. Heparin also drastically changes the aggregation state of the enzyme; aggregated species contain significantly less delta and show an about fivefold higher A0 activity than the tetrameric form containing delta stoichiometrically. We interpret this to mean that delta has two functions in the phosphorylase kinase: an inhibitory one with respect to A0 and an activating one with respect to A2. The inhibition of A0 by Ca2+-free delta is released, i.e. A0 increases when this subunit dissociates from the holoenzyme. The maximally heparin-stimulated A0 activity, A0,hep, is enriched from a crude extract to the same degree and approximately with the same yield as the major activity, A2. The phosphorylase kinase is not eluted from DEAE-cellulose as a symmetrical bell-shaped protein peak. The peak fraction contains the activities A2 and A0,hep superimposed and yields a nearly homogeneous sedimentation boundary with an S20,w value of 25.5 S. The A0 yields a much broader eluation profile showing a distinct maximum from the A2 activity which contains slower sedimenting species of 12.1 S, some tetrameric enzyme of 22.7 S and higher aggregated material. Over the whole profile the activity ratio A2/A0 decreases about sevenfold whereas the ratio A2/A0,hep is constant on average. This shows that A0 is an intrinsic activity of phosphorylase kinase. The heparin-activated A0 activity or A0 itself in the presence of the phosphorylase phosphatase inhibitor, fluoride, can trigger a Ca2+-independent flash activation of phosphorylase in a protein-glycogen complex. Thus, A0 could be responsible for the conversion of phosphorylase b to a at 20 nM free Ca2+ in resting, hormone-stimulated, muscle.

The association of phosphorylase kinase with rabbit muscle T-tubules

Evidence is presented for the association of a phosphorylase kinase activity with transverse tubules as well as terminal cisternae in triads isolated from rabbit skeletal muscle. This activity remained associated with T-tubules throughout the purification of triad junctions by one cycle of dissociation and reassociation. The possibility that the presence of phosphorylase kinase in these highly purified membrane vesicle preparations was due to its association with glycogen was eliminated by digestion of the latter with alpha-amylase. The phosphorylase kinase activity associated with the T-tubule membranes was similar to that reported for other membrane-bound phosphorylase kinases. The enzyme had a high pH 6.8/pH 8.2 activity ratio (0.4-0.7) and a high level of Ca2+ independent activity (EGTA/Ca2+ = 0.3-0.5). The kinase activated and phosphorylated exogenous phosphorylase b with identical time courses. When mechanically disrupted triads were centrifuged on continuous sucrose gradients, the distribution of phosphorylase kinase activity was correlated with the distribution of a Mr 128,000 polypeptide in the gradients. This polypeptide and a Mr 143,000 polypeptide were labeled with 32P by endogenous and exogenous protein kinases. These findings suggest that the membrane-associated phosphorylase kinase may be similar to the cytosolic enzyme. Markers employed for the isolated organelles included a Mr 102,000 membrane polypeptide which followed the distribution of Ca2+-stimulated 3-O-methylfluorescein phosphatase activity, which is specific for the sarcoplasmic reticulum. A Mr 72,000 polypeptide was confirmed to be a T-tubule-specific protein. Several proteins of the triad component organelle were phosphorylated by the endogenous kinase in a Ca2+/calmodulin-stimulated manner, including a Mr ca. 72,000 polypeptide found only in the transverse tubule.

Nonactivated phosphorylase kinase is a phosphoprotein: differentiation of two classes of endogenous phosphoserine residues by phosphorus-31 nuclear magnetic resonance spectroscopy and phosphatase sensitivity

A standard preparation of phosphorylase kinase from rabbit skeletal muscle contains 2 mol of phosphoserine/mol of alpha beta gamma delta. This basal stoichiometry is not influenced by application of propranolol and insulin in vivo; these serine phosphates could not be hydrolyzed by phosphatases of the muscle extract or by alkaline phosphatases. When the enzyme is purified in the presence of the protein phosphatase inhibitor sodium fluoride, it contains either 1 or 3 additional mol of phosphoserine/mol of alpha beta gamma delta, termed phosphatase-sensitive phosphates. Both classes of phosphates yield in formic acid one single 31P NMR signal of a narrow line width (approximately 3 Hz) very similar in chemical shift to free phosphoserine. Phosphoserine is also identified by its chemical shift when dissolved in 8 M guanidinium chloride and by its electrophoretic mobility after acid hydrolysis. By self-phosphorylation of phosphorylase kinase, 14 additional mol of phosphate/mol of alpha beta gamma delta was incorporated, and all were identified as phosphoserine by 31P NMR spectroscopy. In native phosphorylase kinase, the 31P NMR signals of both the basal and the phosphatase-sensitive phosphates are substantially broadened and reduced in intensity, indicating strong interactions of the phosphate groups with the protein. The basal and phosphatase-sensitive phosphates give in 8 M guanidinium chloride a homogeneous NMR signal above pH 6; it splits into a doublet below pH 6 and into a triplet below pH 5.(ABSTRACT TRUNCATED AT 250 WORDS)

The effects of Mg2+ on the Ca2+-binding properties and Ca2+-induced tyrosine-fluorescence changes of calmodulin isolated from rabbit skeletal muscle

Calmodulin from phosphorylase kinase (the delta subunit) was obtained as a homogeneous protein in a spectroscopically pure form, and its interaction with Ca2+ and Mg2+ was studied. 1. Determination of the binding of Ca2+ to calmodulin in a buffer of low ionic strength (0.001 M) show that it contained six binding sites for this divalent cation. 2. Employment of a buffer of high ionic strength (0.18 M) allowed two Ca2+/Mg2+-binding sites (KdCa2+ = 4.0 microM), which showed Ca2+ - Mg2+ competition (KdMg2+ = 0.75 mM), to be distinguished from two Ca2+-specific binding sites (KdCa2+ = 40 microM). The remaining two Ca2+-binding sites are not observed under these conditions and are probably Mg2+-specific binding sites. Thus, the binding sites on calmodulin are remarkably similar to those of the homologous Ca2+-binding protein, troponin C [Potter and Gergely (1975) J. Biol. Chem. 250, 4628, 4633]. 3. The conformational states of calmodulin are defined by Ca2+, Mg2+ and salt concentrations, which can be differentiated by their Ca2+ affinity and their relative tyrosine fluorescence intensity. In a buffer of high ionic strength, Mg2+ induces a conformation which enhances the apparent affinity for Ca2+. Addition of Ca2+ leads to an enhancement of the tyrosine fluorescence intensity, which remains enhanced even upon removal of Ca2+ by chelation with EGTA. Only additional chelation of Mg2+ with EDTA reduces the tyrosine fluorescence intensity. 4. Comparison of the Ca2+-binding parameters of phosphorylase kinase, which were previously determined under identical experimental conditions [Kilimann and Heilmeyer (1977) Eur. J. Biochem. 73, 191-197], with those reported here on calmodulin isolated from this enzyme, allows the conclusion that Ca2+ binding to the holoenzyme occurs by binding to the delta subunit exclusively. 5. Ca2+ binding and Ca2+ activation of phosphorylase kinase are compared and discussed in relation to the Ca2+ and Mg2+-induced conformation changes of calmodulin.

Comparison of the Mg2+ and Ca2+ binding properties of troponin complexes P1-TI2C and TI2C

The phosphoserine present in troponin T of freshly isolated skeletal muscle troponin P1-TI2C was dephosphorylated by alkaline phosphatase and the resulting troponin TI2C characterized by phosphorous content and gel electrophoresis in presence of sodium dodecylsulfate. Both complexes bind Ca2+ in an identical manner with a K0.5 of 5.3 X 10(-9) M for the Ca2+/Mg2+ binding sites and of 1.1 X 10(-6) M for the Ca2+-specific sites. 3.5 mM Mg2+ lowers the K0.5 value at the Ca2+/Mg2+ binding sites of 1.3 X 10(-7) M in the phospho-troponin P1-TI2C and leaves nearly unchanged the value of the dephosphorylated troponin TI2C at 1.2 X 10(-8) M. At 10 mM Mg2+ only one dissociation constant of about 1.0 X 10(-6) M is determined with both complexes. In analogy dephosphorylation of troponin P1-TI2C reduces the affinity for Mg2+ at the Ca2+/Mg2+ binding sites from 6.7 X 10(-5) M to 2.0 X 10(-3) M. Again the Mg2+-specific sites are uninfluenced. The possibility is discussed that removal of the phosphate group from troponin T allows the interaction of the N-terminal domain of troponin T with other amino acid side chains of troponin.