The regulatory alpha subunit of phosphorylase kinase may directly participate in the binding of glycogen phosphorylase.

The yeast two-hybrid screen has been used to identify potential regions of interaction of the largest regulatory subunit, alpha, of phosphorylase kinase (PhK) with two fragments of its protein substrate, glycogen phosphorylase b (Phb). One fragment, corresponding to residues 17-484 (PhbN'), contained the regulatory domain of the protein, but in missing the first 16 residues was devoid of the sole phosphorylation site of Phb, Ser14; the second fragment corresponded to residues 485-843 (PhbC) and contained the catalytic domain of Phb. Truncation fragments of the alpha subunit were screened for interactions against these two substrate fragments. PhbC was not found to interact with any alpha constructs; however, PhbN' interacted with a region of alpha (residues 864-1014) that is near the phosphorylatable region of that subunit. PhbN' was also screened for interactions against a variety of fragments of the catalytic gamma subunit of PhK; however, no interactions were detected, even with full-length gamma. Our results support the idea that amino acid residues proximal to the convertible serine of Phb are important for its specific interaction with the catalytic subunit of PhK, but that regions distinct from the convertible serine residue of Phb and from the catalytic domain of PhK may also be involved in the interaction of these two proteins.

Direct visualization of the calmodulin subunit of phosphorylase kinase via electron microscopy following subunit exchange.

Calmodulin is a tightly bound, intrinsic subunit (delta) of the hexadecameric phosphorylase-b kinase holoenzyme, (alphabetagammadelta)4. To introduce specifically labeled calmodulin into the phosphorylase-b kinase complex for its eventual visualization by electron microscopy, we have developed a method for rapidly exchanging exogenous calmodulin for the intrinsic delta subunit. This method exploits previous findings that low concentrations of urea in the absence of Ca(2+) ions cause the specific dissociation of only the delta subunit from the holoenzyme [Paudel, H. K., and Carlson, G. M. (1990) Biochem. J. 268, 393-399]. In the current study, phosphorylase-b kinase was incubated with excess exogenous calmodulin and a threshold concentration of urea to promote exchange of its delta subunit with the exogenous calmodulin. Size exclusion HPLC was then used to remove the excess calmodulin from the holoenzyme containing exchanged delta subunits. Using metabolically labeled [35S]calmodulin to allow quantification and optimization of exchange conditions, we achieved exchange of approximately 10% of all delta subunits within 1 h, with the exchanged holoenzyme retaining full catalytic activity. Calmodulins derivatized with Nanogold for visualization by scanning transmission electron microscopy were then exchanged for delta, which for the first time allowed localization of the delta subunit within the bridged, bilobal phosphorylase b kinase holoenzyme complex. The delta subunits were determined to be near the edge of the lobes, just distal to the interlobal bridges and proximal to a previously identified region of the enzyme's catalytic gamma subunit.

Self-association of the alpha subunit of phosphorylase kinase as determined by two-hybrid screening.

The structural organization of the (alphabetagammadelta)(4) phosphorylase kinase complex has been studied using the yeast two-hybrid screen for the purpose of elucidating regions of alpha subunit interactions. By screening a rabbit skeletal muscle cDNA library with residues 1-1059 of the alpha subunit of phosphorylase kinase, we have isolated 16 interacting, independent, yet overlapping transcripts of the alpha subunit containing its C-terminal region. Domain mapping of binary interactions between alpha constructs revealed two regions involved in the self-association of the alpha subunit: residues 833-854, a previously unrecognized leucine zipper, and an unspecified region within residues 1015-1237. The cognate binding partner for the latter domain has been inferred to lie within the stretch from residues 864-1059. Indirect evidence from the literature suggests that the interacting domains contained within the latter two, overlapping regions may be further narrowed to the stretches from 1057 to 1237 and from 864 to 971. Cross-linking of the nonactivated holoenzyme with N-(gamma-maleimidobutyroxy)sulfosuccin-imide ester produced intramolecularly cross-linked alpha-alpha dimers, consistent with portions of two alpha subunits in the holoenyzme being in sufficient proximity to associate. This is the first report to identify potential areas of contact between the alpha subunits of phosphorylase kinase. Additionally, issues regarding the general utility of two-hybrid screening as a method for studying homodimeric interactions are discussed.

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.

Mg2+ induces conformational changes in the catalytic subunit of phosphorylase kinase, whether by itself or as part of the holoenzyme complex.

Phosphorylase kinase (PhK) from skeletal muscle is a structurally complex, highly regulated, hexadecameric enzyme of subunit composition (alpha beta gamma delta)4. Previous studies have revealed that the activity of its catalytic gamma subunit is controlled by alterations in quaternary structure initiated at allosteric and covalent modification sites on PhK's three regulatory subunits; however, changes in the conformation of the holoenzyme initiated by the catalytic subunit have been more difficult to document. In this study a monoclonal antibody (mAb gamma79) has been generated against isolated gamma subunit and used as a conformational probe of that subunit. The epitope recognized by this antibody is within the catalytic core of the gamma subunit, between residues 100 and 240, and monovalent fragments of the antibody inhibit the catalytic activity of the holoenzyme, the gamma-calmodulin binary complex, and the free gamma subunit. Activation of PhK by a variety of mechanisms known or thought to act through its regulatory subunits (phosphorylation, ADP binding, or alkaline pH) increased the binding of the holoenzyme to immobilized mAb gamma79, indicating that activation by any of these distinct mechanisms involves repositioning of the portion of the catalytic domain of the gamma subunit containing the epitope for mAb gamma79. The activating ligand Mg2+ also stimulated the binding of the PhK holoenzyme to immobilized mAb gamma79, as well as the binding of mAb gamma79 to immobilized gamma subunit. Thus, Mg2+ increases the accessibility of the mAb gamma79 epitope in both the isolated gamma subunit and in the holoenzyme. Our results suggest that previously reported influences of Mg2+ on the quaternary structure of the PhK holoenzyme are directly mediated by the gamma subunit.

Activators of phosphorylase kinase alter the cross-linking of its catalytic subunit to the C-terminal one-sixth of its regulatory alpha subunit.

Phosphorylase kinase, a regulatory enzyme of glycogenolysis in skeletal muscle, is a hexadecameric oligomer consisting of four copies each of a catalytic subunit (gamma) and three regulatory subunits (alpha, beta, and delta, the last being endogenous calmodulin). The enzyme is activated by a variety of effectors acting through its regulatory subunits. To probe the quaternary structure of nonactivated and activated forms of the kinase, we used the heterobifunctional, photoreactive cross-linker N-5-azido-2-nitrobenzoyloxysuccinimide. Mono-derivatization of the holoenzyme with the succinimidyl group, followed by photoactivation of the covalently attached azido group, resulted in intramolecular cross-linking to form two distinct heterodimers: a major (alphagamma) and a minor (betadelta) conjugate. Formation of both conjugates was significantly altered in activated conformations of the enzyme induced by phosphorylation, alkaline pH, and several allosteric activators (ADP, exogenous calmodulin/Ca2+, and Ca2+ alone). Of these activating mechanisms, all increased formation of alphagamma, except Ca2+ alone, which inhibited its formation. When cross-linking was carried out at alkaline pH or in the presence of ADP or exogenous calmodulin/Ca2+, the cross-linked enzyme remained activated following removal of the activators; however, cross-linking in the presence of Ca2+ resulted in sustained inhibition. The results indicate that perturbations in the subunit cross-linking forming the alphagamma dimer reflect the subsequent extent of sustained activation of the holoenzyme that is measured. The region cross-linked to the catalytic gamma subunit was confined to the C-terminal 1/6th of the alpha subunit, which contains known regulatory regions. These results suggest that activators of the phosphorylase kinase holoenzyme perturb interactions between the C-terminal region of the inhibitory alpha subunit and the catalytic gamma subunit, ultimately leading to activation of the latter.

Zero-length crosslinking of the beta subunit of phosphorylase kinase to the N-terminal half of its regulatory alpha subunit.

Phosphorylase kinase, a regulatory enzyme of glycogenolysis in skeletal muscle, is a hexadecameric oligomer containing four copies each of four distinct subunits: alpha, beta, gamma, and delta. By intramolecular zero-length crosslinking with transglutaminase, we have previously demonstrated that the regulatory alpha and beta subunits abut one another in the holoenzyme [Nadeau, O. W., and Carlson, G. M. (1994) J. Biol. Chem. 269, 29670-29676]. Selective partial proteolysis of the 138 kDa alpha subunit in holoenzyme that had been crosslinked by transglutaminase has revealed a high molecular weight conjugate corresponding to full-length beta subunit crosslinked to a 60 kDa N-terminal fragment of alpha (determined by SDS-PAGE, Western blotting and N-terminal sequencing). This conjugate was also observed when the enzyme was first activated by partial proteolysis of alpha and then crosslinked by transglutaminase. Both forms of the kinase, generated by either sequential crosslinking and proteolysis or the reverse, coeluted with non-crosslinked hexadecameric control enzyme in size exclusion chromatography, indicating that the crosslinking was intramolecular, i.e., within hexadecamers. This is the first demonstration of any intersubunit interaction involving the N-terminal domain of the alpha subunit and the first region of any subunit shown to interact with the beta subunit. The results are consistent with the predicted path of the polypeptide backbone of the alpha subunits within the holoenzyme and with the proposed location of the beta subunits.

Evaluation of phosphoenolpyruvate as a phosphoryl group donor for phosphoproteins in skeletal muscle.

The possible existence of a phosphoenolpyruvate-dependent protein kinase activity in muscle first reported by Khandelwal et al. (FEBS Lett. 162, 127-132, 1983) was further examined in this study. [32P]Phosphoenolpyruvate was used to assay rabbit muscle extract that was first dialyzed and then passed over a gel filtration column. Fractions from the column were assayed for activity (as shown by counts incorporated into an acid-precipitable product), which was observed only when two distinct and resolved fractions were combined. The approximate masses of these two components, as estimated by nondenaturing gel filtration chromatography, were 30 and 160 kDa. The activity showed time and concentration dependence and was inactivated by heat and proteolysis. [gamma-32P]ATP could not substitute for [32P]phosphoenolpyruvate in the activity assays, nor was there evidence for the formation of ATP during the assays. Elution of the reaction mixture from a sizing column revealed several radioactive peaks. Other tissues (heart, kidney, liver, lung, spleen, and back skeletal muscle) from rabbit and rat were screened; the total activity was detected in all tissues examined, but was highest in the skeletal muscle of both species, with that from rabbit being twice that from rat.

Effector-sensitive cross-linking of phosphorylase b kinase by the novel cross-linker 4-phenyl-1,2,4-triazoline-3,5-dione.

The dienophile 4-phenyl-1,2,4-triazoline-3,5-dione (PTD) was identified as a novel protein cross-linker, and utilized as a conformational probe of phosphorylase b kinase (PhK), a hexadecameric enzyme with the subunit composition (alphabetagammadelta)4. In its reaction with this enzyme, PTD produced five major cross-linked conjugates as resolved by denaturing gel electrophoresis: alphabeta, betagammagamma, alphagamma and a doublet of differently migrating homodimers, betabeta1 and betabeta2. Cross-linking in the presence of six different activators of the kinase targeted to its various subunits caused substantial changes in the amounts of three of the conjugates. The formation of alphagamma was increased by all of the activators but the largest enhancement was caused by exogenous Ca2+/calmodulin. All except one of the activators decreased the amount of betagammagamma formed, with Mg2+ having the greatest effect, and all except two increased the amount of betabeta1, with Mg2+ again having the largest influence. From the overall similarity of the changes in cross-linking by PTD induced by the various activators, we conclude that, even though they are targeted to different sites and subunits, they induce activated conformations of PhK that have certain structural features in common. Regarding the mechanism of cross-linking by PTD, its reaction with a model nucleophile suggests that its initial reaction with a side chain nucleophile of PhK involves a 1,4-conjugate addition to form a urazole adduct, with the secondary cross-linking reaction occurring through an as yet unknown pathway.

Differential affinity cross-linking of phosphorylase kinase conformers by the geometric isomers of phenylenedimaleimide.

Phosphorylase b kinase (PbK) from skeletal muscle is a highly regulated oligomer consisting of four copies of four distinct subunits (alphabetagamma)delta4. The gamma subunit is catalytic, and the remaining subunits are regulatory. To characterize effector-induced changes in the quaternary structure of the enzyme, we utilized the ortho-, meta, and para-isomers of phenylenedimaleimide (PDM), which in addition to having different geometries, also vary 2.5-fold in their cross-linking spans. Even at concentrations equivalent to the alphabetagammadelta protomers of PbK, all three isomers caused specific, rapid, and extensive cross-linking of the holoenzyme to form primarily alphabeta dimers, plus smaller amounts of betagammagamma and alphagammagamma trimers. The formation of these three conjugates was nearly totally inhibited by a 10-fold molar excess over PDM of N-(o- and p-tolyl)succinimide, which are chemically inert structural analogs of PDM. This inhibition suggests that PbK has binding sites for PDM and that PDM acts as an affinity cross-linker in binding to these sites prior to forming cross-linked conjugates. The largest effect on cross-linking in progressing from o- to p-PDM was on the alphagammagamma trimer, which is preferentially formed by the p-isomer. Activation of the enzyme by either phosphorylation or the allosteric activators ADP and GDP resulted in large increases in the amount of alphagammagamma formed, small increases in betagammagamma, and little change in alphabeta. When cross-linked in the presence of the reversibly activating nucleoside diphosphates, PbK remained activated after their removal, indicating that cross-linking had locked it in the active conformation. Our results provide direct evidence for perturbations in the interactions of the catalytic gamma subunit with the regulatory alpha and beta subunits upon activation of PbK.

The structural effects of endogenous and exogenous Ca2+/calmodulin on phosphorylase kinase.

The activity of phosphorylase b kinase (PbK) is stimulated by Ca2+ ions, which act through its endogenous calmodulin subunit (delta), and further stimulated by the Ca2+-dependent binding of exogenous calmodulin (delta'). In contrast to their highly characterized effects on activity, little is known regarding the structural effects on the (alphabetagammadelta)4 PbK holoenzyme induced by Ca2+ and delta'/Ca2+. We have used mono- and bifunctional chemical modifiers as conformational probes to compare how the two effectors influence the structure of the catalytic gamma subunit and the interactions among all of the subunits. As determined by reductive methylation and carboxymethylation, Ca2+ increased the accessibility of the gamma subunit; it also increased the formation by phenylenedimaleimide of an alphagammagamma conjugate that is characteristic of activated conformations of PbK (Nadeau, O. W., Sacks, D. M., and Carlson, G. M. (1997) J. Biol. Chem. 272, 26196-26201); however, Ca2+ also had structural effects that were clearly distinct from other activators. Moreover, similar structural effects of Ca2+ were observed with PbK that had been activated by phosphorylation, consistent with the fact that such activation does not eliminate the catalytic dependence of the enzyme on Ca2+. Our results suggest tiers of conformational transitions in the activation of PbK, with the most fundamental being induced by Ca2+. Analysis of the various cross-linked conjugates formed in the presence of Ca2+ by o-phenylenedimaleimide or m-maleimidobenzoyl-N-hydroxysuccinimide ester showed that the binding of Ca2+ to the delta subunit triggers changes in the interactions among all subunits, including between protomers, indicating an extensive communication network throughout the PbK complex. Most of the structural effects of delta'/Ca2+ were qualitatively similar to, but quantitatively greater than, the effects of Ca2+ alone; but delta'/Ca2+ also had distinct effects, especially involving cross-linking of the delta subunit.

Proximal regions of the catalytic gamma and regulatory beta subunits on the interior lobe face of phosphorylase kinase are structurally coupled to each other and with enzyme activation.

Phosphorylase kinase from skeletal muscle is a hexadecameric enzyme with the subunit composition (alphabeta gammadelta)4 and a mass of 1.3 x 10(6) Da. The catalytic gamma subunit and the remaining regulatory subunits are packed as a tetrahedral structure composed of two elongated, opposing (alphabeta gammadelta)2 octameric lobes. We show by immunoelectron microscopy with subunit-specific monoclonal antibodies that a portion of the beta subunit occurs on the interior face of the lobes at a region of inter-lobal interactions, and that at a proximal position slightly more central and distal on the interior lobe face lies the base (residues 277 to 290) of the helical domain of the catalytic core of the gamma subunit. Activation of the kinase by a variety of means caused similar increases in the binding to the holoenzyme of the monoclonal antibodies against these two regions of the beta and gamma subunits. Moreover, monovalent fragments of the antibodies against both regions stimulated the activity of the non-activated holoenzyme. Thus, the epitopes of the beta and gamma subunits recognized by the monoclonal antibodies are structurally coupled to each other and with the activation of phosphorylase kinase. Activation of the holoenzyme apparently involves the repositioning of the base of the catalytic domain of the gamma subunit and a proximal region of the beta subunit within the identified area on the interior face of the lobes of the tetrahedral phosphorylase kinase molecule.

Divalent cations but not other activators enhance phosphorylase kinase's affinity for glycogen phosphorylase.

To better understand the physical interaction between glycogen phosphorylase-b (P-b) and its only known kinase, phosphorylase kinase (PbK) and the relationship of this interaction to the activation of PbK, direct binding studies are necessary. By utilizing an enzyme-linked immunosorbent assay, a method was developed for measuring the binding of PbK to immobilized P-b under a variety of experimental conditions. A monoclonal antibody specific for the alpha subunit of PbK that had no effect on the phosphorylation of P-b by PbK or on the interaction of PbK with known effectors was used to detect PbK bound to plated P-b. Hyperbolic binding curves were obtained regardless of whether the concentration of Pbk or P-b was varied, and the assay detected changes in relative affinity caused by certain effectors of the kinase. The allosteric effector ADP, alkaline pH, and phosphorylation by cAMP-dependent protein kinase, all activators of PbK, did not cause significant changes in its relative affinity for P-b; however, Ca2+ and Mg2+ ions, which also stimulate PbK, increased its affinity for P-b, with Mg2+ being more effective. Mn2+, which inhibits the P-b conversion activity of PbK, was found to be the most potent enhancer of its affinity for P-b, although divalent cations may enhance binding. Inclusion of ATP analogs in the binding assay with Ca2+ and Mg2+ to stimulate catalytic assay conditions did not further affect the apparent affinity for P-b, which is consistent with the previously reported rapid equilibrium random bi-bi kinetic mechanism for P-b conversion.

Zero length conformation-dependent cross-linking of phosphorylase kinase subunits by transglutaminase.

Transglutaminase, a zero length cross-linker that catalyzes the formation of isopeptide bonds between proximal Gln and Lys side chains, was used as a structural and conformational probe of the hexadecameric phosphorylase kinase molecule (alpha beta gamma delta)4. Brief cross-linking of nonactivated kinase caused formation of alpha-beta dimers, with no cross-linking involving the gamma- and delta-subunits. When the kinase was first activated by autophosphorylation, significant amounts of alpha-alpha dimers were also observed in addition to the alpha-beta, demonstrating the occurrence of a conformational change in the alpha-subunits concomitant with activation. Both dimers resulted from intramolecular cross-linking. Because the COOH-terminal regions of the alpha-subunits are at the lobe tips of this bilobal kinase (Wilkinson D. A. Marion, T. N., Tillman, D. M., Norcum, M. T., Hainfeld, J. F., Seyer, J. M., and Carlson, G. M. (1994) J. Mol. Biol. 235, 974-982), the formation of zero length cross-linked alpha-alpha dimers indicates that the polypeptide backbones of these subunits must stretch from the lobe tips to a more central location where they abut each other. Excess putrescine, as the amine substrate in place of endogenous Lys, was incorporated by transglutaminase predominately into the alpha-subunits of the kinase, with only slight modification of the beta- and gamma-subunits. Exogenous calmodulin (delta'), an activator of the kinase with a binding site on the alpha-subunits (James, P., Cohen, P., and Carafoli, E. (1991) J. Biol. Chem. 266, 7087-7091), was a potent inhibitor of cross-linking. It also inhibited incorporation of putrescine into the alpha-subunits but stimulated incorporation into the beta- and gamma-subunits. Heparin, another activator of the kinase, had the same effects as exogenous calmodulin on cross-linking and putrescine incorporation, suggesting a commonality in the mechanism through which these two effectors activate the holoenzyme, including promoting a conformational change that increases the surface accessibility of target Gln residues on the catalytic gamma-subunit.

Structure of phosphorylase kinase. A three-dimensional model derived from stained and unstained electron micrographs.

Phosphorylase kinase, the first protein kinase discovered, is a key regulatory enzyme in glycogen metabolism. Although its biochemical properties are well characterized, details of its three-dimensional structure and subunit topology are yet to be elucidated. This study describes four characteristic views of the hexadecameric holoenzyme (alpha 4 beta 4 gamma 4 delta 4) as observed in both negatively stained and unstained electron micrographs. The predominant views are the widely reported "butterfly" with two wing-like lobes connected by thin bridges, and the previously described "chalice", composed of "cup" and "stem" segments. Two additional views, a "cube", similar to the previously reported "tetrad", and a "cross" or "X" are less common, but illustrate the overall geometry of the particle. Based on these images, the first three-dimensional model of the enzyme has been constructed. It is composed of four identical protomers that associate with D2 symmetry to form the two major structural elements (the two lobes). Two protomers in a head to head arrangement make up each symmetrical lobe; to complete the holoenzyme, one lobe is inverted and placed perpendicular to the other. Thus, the overall structure has three 2-fold axes of symmetry, and the arrangement of the four protomers approximates a tetrahedron. Each lobe of the model corresponds to a wing of the butterfly projection. Two projections form the chalice: in the intra-lobe orientation, one lobe forms the cup and the other forms the stem, and in the inter-lobe view, one-half of each lobe contributes to each segment of the image. The cube and cross projections result from 90 degrees rotations from the butterfly orientation. In the cube, the distal portions of each lobe are projected separately. In the cross, one lobe is crossed over and is above the other. This model both accounts for and predicts all of the observed microscopic images.

Calmodulin-dependent enzymes undergo a protein-induced conformational change that is associated with their interactions with calmodulin.

The anionic hydrophobic (amphipathic) fluorescent probe 2-(p-toluidinyl)-naphthalene-6-sulfonate was used to investigate the surface hydrophobic properties of calmodulin (CaM)-dependent enzymes as follows: calcineurin, myosin light chain kinase, cyclic nucleotide phosphodiesterase, CaM-dependent protein kinase II, and the gamma-subunit of phosphorylase kinase. We found that certain domains of these enzymes that interacted with 2-(p-toluidinyl)-naphthalene-6-sulfonate were exposed by a transient proton (H+) increase within the neutral pH range. This H(+)-induced exposure, which could be caused either by direct addition of H+ or by the release of H+ from metal chelators upon their binding of Ca2+, seemed to be more closely linked with a change in pH value (i.e. transient H+ increase) than with the actual equilibrium pH value of the system. Unlike the case with CaM-dependent enzymes, the H(+)-induced conformational change was uncommon in CaM-independent enzymes. When CaM-binding domains were removed from calcineurin and smooth muscle myosin light chain kinase, the resultant enzymes no longer exposed new domains in response to H+ increase. Using dansylated CaM to monitor the formation of CaM-enzyme complexes, we found that complex formation occurred with an uptake of H+ from solution. When CaM-dependent enzymes were evaluated at suboptimal concentrations of Ca2+, addition of H+ enhanced both the formation of CaM-enzyme complexes and the CaM-dependent catalytic activities, but this synergistic H+ effect occurred within only a narrow range of Ca2+ concentrations. These findings suggest that the H(+)-exposed domains in CaM-dependent enzymes are involved in the binding of CaM and that both conformational changes in CaM and its enzyme targets are necessary for complex formation. Further, the findings are consistent with the notion that CaM-binding domains are masked in the nonactivated (uncomplexed) conformations of CaM-dependent enzymes. The interplay between H+ and Ca2+ is discussed in relation to other systems that display interdependent effects of these two ions.

Clinical and biochemical features of 10 adult patients with muscle phosphorylase kinase deficiency.

Ten adult patients complained of exercise intolerance; five of them had cramps and three had recurrent myoglobinuria. Resting serum CK was increased in five. Muscle biopsies showed phosphorylase b kinase (PbK) deficiency, whereas the activities of other enzymes of carbohydrate metabolism were normal. None of the patients exhibited symptoms indicative of liver PbK deficiency. Thus, these patients are new additions to a class of PbK glycogen storage disease characterized by enzyme deficiency in muscle but not liver. Family histories were consistent with autosomal recessive transmission. Monoclonal antibodies specific for the beta and gamma subunits of PbK cross-reacted differentially with muscle biopsies from three of these patients, suggesting that this phenotype of PbK deficiency is biochemically heterogeneous.

An epitope proximal to the carboxyl terminus of the alpha-subunit is located near the lobe tips of the phosphorylase kinase hexadecamer.

An epitope of the alpha-subunit of phosphorylase kinase from fast-twitch skeletal muscle was localized to the tips of the bilobal kinase molecule by two types of immunoelectron microscopy. This is the first direct evidence identifying the location of any of the enzyme's 16 subunits within the phosphorylase kinase molecule. Negatively stained complexes of phosphorylase kinase with an immunoglobulin G monoclonal antibody specific for the alpha-subunit (mAb 157) were observed by conventional transmission electron microscopy, and complexes of the unstained enzyme with undecagold-labeled Fab' fragments derived from mAb 157 were visualized by scanning transmission electron microscopy. Images from both techniques indicate a symmetrical arrangement of the epitope, consistent with a "head-to-head" packing arrangement of the four alpha-subunits. In Western blots, mAb 157 crossreacted with comigrating fragments obtained by digesting non-denatured phosphorylase kinase with a variety of proteases, suggesting that the epitope for the anti-alpha mAb is contained within a protease-resistant domain. Partial sequencing of a 24.1 kDa immunoreactive chymotryptic fragment narrowed the epitope to somewhere within the carboxyl-terminal one-sixth of the alpha-subunit. Studies of the crossreactivity of mAb 157 with the holoenzyme in the presence of calmodulin, after phosphorylation or with different isoforms (all with known alpha-subunit sequence targets or differences), suggest that the epitope is even more proximal to the carboxyl terminus. This epitope was not implicated in any known function or activity of the enzyme, suggesting that the region proximal to the carboxyl terminus of the alpha-subunit, and thus to the lobe tips of the hexadecamer, may have a role other than catalytic or regulatory.

The model calmodulin-binding peptide melittin inhibits phosphorylase kinase by interacting with its catalytic center.

The inhibition by melittin, a model calmodulin-binding peptide, of phosphorylase kinase, which contains an intrinsic calmodulin subunit, has been characterized in detail. The inhibition was competitive with respect to phosphorylase b for both the phosphorylase kinase holoenzyme and its isolated catalytic gamma-subunit (minus calmodulin), and the ratios of the Km for phosphorylase to the Ki for melittin were similar for both forms of the kinase. These findings indicate that inhibition of the phosphorylase kinase holoenzyme by melittin is caused predominantly by its interaction with the catalytic subunit of the enzyme, and not with the endogenous calmodulin subunit. Further proof that melittin interacts directly with the catalytic site was obtained when it was observed that melittin was also a substrate for phosphorylase kinase, with a Km that was less than that for phosphorylase b, although the kcat/Km specificity constant was only 1/200th of that for phosphorylase. The apparent tight binding of melittin to the kinase active site could not be readily rationalized by conventional comparison of sequence similarity between melittin and phosphorylase; however, considerable sequence similarity, centered around the convertible seryl residue of phosphorylase, was observed when the sequences were aligned in reversed polarity. The possible regulatory significance of the direct interaction of the catalytic site of this Ca(2+)-dependent kinase with a calmodulin-binding peptide is discussed.