Stimulation of phosphorylase kinase autophosphorylation by peptide analogs of phosphorylase.
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Autoactivation of phosphorylase kinase in the presence of substrates has been studied to determine the cause of the hysteresis, or lag, in the phosphorylase kinase reaction. Peptide analogs corresponding to the convertible serine region of phosphorylase have been used as low molecular weight alternative substrates. Autophosphorylation of the kinase molecule was measured under conditions that favored autoactivation. Phosphorylase b and a tetradecapeptide, which was found to be a good model of phosphorylase, stimulated autoactivation by 86- and 37-fold, respectively. The tetradecapeptide also stimulated autophosphorylation of subunits A and B of the kinase molecule. This increased autophosphorylation coincided with an increased ability to convert phosphorylase. This finding supports the hypothesis that autophosphorylation is responsible for the lag in the phosphorylase kinase reaction. No evidence was obtained to suggest that the lag could be due to dissociation of the kinase. The stoichiometry of phosphate incorporation into phosphorylase kinase subunits by autophosphorylation was much greater than that reported to occur by protein kinase phosphorylation. Multiple phosphorylation sites in subunit A accounted for most of the phosphate incorporation during autophosphorylation. Saturating levels of hexa- and octapeptide analogs also caused stimulation of autophosphorylation. Possible mechanisms and experimental implications of substrate-stimulated autophosphorylation are discussed. Consideration also is given to the possible role of effectors in autophosphorylation in vivo. (+info)
A tentative mechanism of the ternary complex formation between phosphorylase kinase, glycogen phosphorylase b and glycogen.
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The kinetics of rabbit skeletal muscle phosphorylase kinase interaction with glycogen has been studied. At pH 6.8 the binding of phosphorylase kinase to glycogen proceeds only in the presence of Mg2+, whereas at pH 8.2 formation of the complex occurs even in the absence of Mg2+. On the other hand, the interaction of phosphorylase kinase with glycogen requires Ca2+ at both pH values. The initial rate of the complex formation is proportional to the enzyme and glycogen concentrations, suggesting the formation of the complex with stoichiometry 1:1 at the initial step of phosphorylase kinase binding by glycogen. According to the kinetic and sedimentation data, the substrate of the phosphorylase kinase reaction, glycogen phosphorylase b, favors the binding of phosphorylase kinase with glycogen. We suggest a model for the ordered binding of phosphorylase b and phosphorylase kinase to the glycogen particle that explains the increase in the tightness of phosphorylase kinase binding with glycogen in the presence of phosphorylase b. (+info)
Kinetics of the interaction of rabbit skeletal muscle phosphorylase kinase with glycogen.
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The kinetics of the interaction of rabbit skeletal muscle phosphorylase kinase with glycogen was studied by the turbidimetric method at pH 6.8 and 8.2. Binding of phosphorylase kinase by glycogen occurs only in the presence of Ca2+ and Mg2+. The initial rate of complex formation is proportional to the enzyme and polysaccharide concentration; this suggests the formation of a complex with 1:1 stoichiometry in the initial step of phosphorylase kinase binding by glycogen. The kinetic data suggest that phosphorylase kinase substrate--glycogen phosphorylase b--favors the binding of phosphorylase kinase with glycogen. This conclusion is supported by direct experiments on the influence of phosphorylase b on the interaction of phosphorylase kinase with glycogen using analytical sedimentation analysis. The kinetic curves of the formation of the complex of phosphorylase kinase with glycogen obtained in the presence of ATP are characterized by a lag period. Preincubation of phosphorylase kinase with ATP in the presence of Ca2+ and Mg2+ causes the complete disappearance of the lag period. On changing the pH from 6.8 to 8.2, the rate of phosphorylase kinase binding by glycogen is appreciably increased, and complex formation becomes possible even in the absence of Mg2+. A model of phosphorylase kinase and phosphorylase b adsorption on the surface of the glycogen particle explaining the increase in the strength of phosphorylase kinase binding with glycogen in the presence of phosphorylase b is proposed. (+info)
beta2-adrenergic cAMP signaling is uncoupled from phosphorylation of cytoplasmic proteins in canine heart.
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BACKGROUND: Recent studies of beta-adrenergic receptor (beta-AR) subtype signaling in in vitro preparations have raised doubts as to whether the cAMP/protein kinase A (PKA) signaling is activated in the same manner in response to beta2-AR versus beta1-AR stimulation. METHODS AND RESULTS: The present study compared, in the intact dog, the magnitude and characteristics of chronotropic, inotropic, and lusitropic effects of cAMP accumulation, PKA activation, and PKA-dependent phosphorylation of key effector proteins in response to beta-AR subtype stimulation. In addition, many of these parameters and L-type Ca2+ current (ICa) were also measured in single canine ventricular myocytes. The results indicate that although the cAMP/PKA-dependent phosphorylation cascade activated by beta1-AR stimulation could explain the resultant modulation of cardiac function, substantial beta2-AR-mediated chronotropic, inotropic, and lusitropic responses occurred in the absence of PKA activation and phosphorylation of nonsarcolemmal proteins, including phospholamban, troponin I, C protein, and glycogen phosphorylase kinase. However, in single canine myocytes, we found that beta2-AR-stimulated increases in both ICa and contraction were abolished by PKA inhibition. Thus, the beta2-AR-directed cAMP/PKA signaling modulates sarcolemmal L-type Ca2+ channels but does not regulate PKA-dependent phosphorylation of cytoplasmic proteins. CONCLUSIONS: These results indicate that the dissociation of beta2-AR signaling from cAMP regulatory systems is only apparent and that beta2-AR-stimulated cAMP/PKA signaling is uncoupled from phosphorylation of nonsarcolemmal regulatory proteins involved in excitation-contraction coupling. (+info)
Complete genomic structure and mutational spectrum of PHKA2 in patients with x-linked liver glycogenosis type I and II.
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X-linked liver glycogenosis (XLG) is probably the most frequent glycogen-storage disease. XLG can be divided into two subtypes: XLG I, with a deficiency in phosphorylase kinase (PHK) activity in peripheral blood cells and liver; and XLG II, with normal in vitro PHK activity in peripheral blood cells and with variable activity in liver. Both types of XLG are caused by mutations in the same gene, PHKA2, that encodes the regulatory alpha subunit of PHK. To facilitate mutation analysis in PHKA2, we determined its genomic structure. The gene consists of 33 exons, spanning >/=65 kb. By SSCP analysis of the different PHKA2 exons, we identified five new XLG I mutations, one new XLG II mutation, and one mutation present in both a patient with XLG I and a patient with XLG II, bringing the total to 19 XLG I and 12 XLG II mutations. Most XLG I mutations probably lead to truncation or disruption of the PHKA2 protein. In contrast, all XLG II mutations are missense mutations or small in-frame deletions and insertions. These results suggest that the biochemical differences between XLG I and XLG II might be due to the different nature of the disease-causing mutations in PHKA2. XLG I mutations may lead to absence of the alpha subunit, which causes an unstable PHK holoenzyme and deficient enzyme activity, whereas XLG II mutations may lead to in vivo deregulation of PHK, which might be difficult to demonstrate in vitro. (+info)
Regulation of glycogen utilization in ischemic hearts after 24 hours of fasting.
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INTRODUCTION: Fasting protects the ischemic heart from injury and infarction. Previous studies have shown that hearts from fasted animals have greater glycogen utilization and a lower cytosolic redox state (NADH/NAD+) during global ischemia. While the mechanisms of increased glycogen utilization in fasted animals have not been elucidated, animals that hibernate or are tolerant of anoxia are known to increase the tissue content of the active form of glycogen phosphorylase, phosphorylase a. Therefore, this study was designed to (a) determine whether hearts from fasted animals have increased activity of glycogen phosphorylase during ischemia and (b) define those mechanisms responsible for this increase. METHODS: Hearts isolated from either fed or fasted (24 h) rats were perfused and freeze-clamped at baseline, and after 1 and 10 min of ischemia, for measurement of phosphorylase activity, phosphorylase kinase activity, and glucose-6-phosphate concentrations. RESULTS: Fasting increased the phosphorylase a/b ratio under both baseline and ischemic conditions. This increase was not accompanied by an increase in the activity of phosphorylase kinase, either with maximal [Ca2+] or under physiologic [Ca2+]. Glucose 6-phosphate concentrations were lower in hearts from fasted animals under baseline, but not ischemic, conditions. CONCLUSIONS: Fasting enhances glycogen utilization during ischemia by increasing the active form of glycogen phosphorylase. This increase is not due to a change in phosphorylation by phosphorylase kinase nor end-product inhibition by G-6P. While the precise mechanism of increased glycogen phosphorylase activity in fasted animals is not clear, one likely explanation may be the lower cytosolic redox state demonstrated in the myocardium of fasted animals. (+info)
Self-association of the alpha subunit of phosphorylase kinase as determined by two-hybrid screening.
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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. (+info)
In vitro inhibition of the activity of phosphorylase kinase, protein kinase C and protein kinase A by caffeic acid and a procyanidin-rich pine bark (Pinus marittima) extract.
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Caffeic acid (CA) is a common constituent of human diet while pine bark extract (PBE) is utilized either as nutritional supplement or as phytochemical remedy for different diseases. CA and PBE, are reported as efficient antioxidants and more recently have been described to modulate cellular response to oxidative challenge and to possess many other biological activities, i.e. anti-inflammatory, antimutagenic, antitumoral effects. In order to investigate in depth the mechanism of action of these polyphenols, the effects of CA and PBE on the activity of some protein kinases involved in the regulation of fundamental cellular processes were studied in vitro: phosphorylase kinase (PhK), protein kinase A (PKA), protein kinase C (PKC). PBE at the concentration of 20 microg/ml (corresponding to 69 microM catechin equivalents) inhibited PKA, PhK and PKC by about 90, 59, 57%, respectively, while 100 microM CA inhibited by 37, 52 and 54%, respectively. Considerable inhibitions have been still observed at even lower concentrations of CA and PBE. For PhK and PKA, the inhibition follows a non-competitive mechanism. CA also inhibits PKC activity in a partially purified cellular extract. The results suggest a possible involvement of CA and PBE in modulation of cellular functions. (+info)