Protective manifestation of bacoside A and bromelain in terms of cholinesterases, gamma-amino butyric acid, serotonin level and stress proteins in the brain of dichlorvos-intoxicated mice.

The objective of the study was to evaluate the neuroprotective effects of bacoside A and bromelain against dichlorvos-incited toxicity. Healthy 6-8-week old, male Swiss mice were administered subacute doses of dichlorvos (40 mg/kg bw), bacoside A (5 mg/kg bw) and bromelain (70 mg/kg bw). AChE, BChE, GABA, serotonin and total protein content and their expressions were used for determination of toxic action of dichlorvos. Protective effects of bacoside A and bromelain were evaluated on the same parameters. Exposure to dichlorvos leads to significant decline in activities of AChE (p < 0.01, p < 0.001), BChE (p < 0.05) and GABA (p < 0.01) and total protein levels (p < 0.01). Antioxidant treatment significantly increased the activities of AChE (p < 0.01, p < 0.001), BChE (p < 0.05), GABA (p < 0.01) and total protein level (p < 0.05) compared to those in dichlorvos-treated mice. Overexpression of Hsp 70 protein and underexpression of phosphorylase a and b, catalase SOD and GPx were observed after dichlorvos exposure which suggests the oxidative stress. The results indicate that dichlorvos-induced neuronal damage which results in the generation of molecular expression of proteins is in agreement with the biochemical data ameliorated by bacoside A and bromelain.

Sensitive assay of glycogen phosphorylase activity by analysing the chain-lengthening action on a Fluorogenic [corrected] maltooligosaccharide derivative.

The action of glycogen phosphorylase (GP) is essentially reversible, although GP is generally classified as a glycogen-degrading enzyme. In this study, we developed a highly sensitive and convenient assay for GP activity by analysing its chain-lengthening action on a fluorogenic maltooligosaccharide derivative in a glucose-1-phosphate-rich medium. Characterization of the substrate specificity of GP using pyridylaminated (PA-) maltooligosaccharides of various sizes revealed that a maltotetraosyl (Glc(4)) residue comprising the non-reducing-end of a PA-maltooligosaccharide is indispensable for the chain-lengthening action of GP, and PA-maltohexaose is the most suitable substrate for the purpose of this study. By using a high-performance liquid chromatograph equipped with a fluorescence spectrophotometer, PA-maltoheptaose produced by the chain elongation of PA-maltohexaose could be isolated and quantified at 10 fmol. This method was used to measure the GP activities of crude and purified GP preparations, and was demonstrated to have about 1,000 times greater sensitivity than the spectrophotometric orthophosphate assay.

Insulin sensitivity in Belgian horses with polysaccharide storage myopathy.

OBJECTIVE: To determine insulin sensitivity, proportions of muscle fiber types, and activities of glycogenolytic and glycolytic enzymes in Belgians with and without polysaccharide storage myopathy (PSSM). ANIMALS: 10 Quarter Horses (QHs) and 103 Belgians in which PSSM status had been determined. PROCEDURES: To determine insulin sensitivity, a hyperinsulinemic euglycemic clamp (HEC) technique was used in 5 Belgians with PSSM and 5 Belgians without PSSM. Insulin was infused i.v. at 3 mU/min/kg for 3 hours, and concentrations of blood glucose and plasma insulin were determined throughout. An i.v. infusion of glucose was administered to maintain blood glucose concentration at 100 mg/dL. Activities of glycogenolytic and glycolytic enzymes were assessed in snap-frozen biopsy specimens of gluteus medius muscle obtained from 4 Belgians with PSSM and 5 Belgians without PSSM. Percentages of type 1, 2a, and 2b muscle fibers were determined via evaluation of >or= 250 muscle fibers in biopsy specimens obtained from each Belgian used in the aforementioned studies and from 10 QHs (5 with PSSM and 5 without PSSM). RESULTS: Belgians with and without PSSM were not significantly different with respect to whole-body insulin sensitivity, muscle activities of glycogenolytic and glycolytic enzymes, or proportions of muscle fiber types. However, Belgians had an increased proportion of type 2a and decreased proportion of type 2b muscle fibers, compared with proportions in QHs, regardless of PSSM status. CONCLUSIONS AND CLINICAL RELEVANCE: PSSM in Belgians may be attributable to excessive glycogen synthesis rather than decreased glycogen utilization or enhanced glucose uptake into muscle cells.

(-)-Adrenaline elicits positive inotropic, lusitropic, and biochemical effects through beta2 -adrenoceptors in human atrial myocardium from nonfailing and failing hearts, consistent with Gs coupling but not with Gi coupling.

Activation of either coexisting beta1- or beta2 -adrenoceptors with noradrenaline or adrenaline, respectively, causes maximum increases of contractility of human atrial myocardium. Previous biochemical work with the beta2 -selective agonist zinterol is consistent with activation of the cascade beta2 -adrenoceptors-->Gsalpha-protein-->adenylyl cyclase-->cAMP-->protein kinase (PKA)-->phosphorylation of phospholamban, troponin I, and C-protein-->hastened relaxation of human atria from nonfailing hearts. However, in feline and rodent myocardium, catecholamines and zinterol usually do not hasten relaxation through activation of beta2 -adrenoceptors, presumably because of coupling of the receptors to Gi protein. It is unknown whether the endogenously occurring beta2 -adrenoceptor agonist adrenaline acts through the above cascade in human atrium and whether its mode of action could be changed in heart failure. We assessed the effects of (-)-adrenaline, mediated through beta2 -adrenoceptors (in the presence of CGP 20712A 300 nM to block beta1 -adrenoceptors), on contractility and relaxation of right atrial trabecula obtained from nonfailing and failing human hearts. Cyclic AMP levels were measured as well as phosphorylation of phospholamban, troponin I, and protein C with Western blots and the back-phosphorylation procedure. For comparison, beta1 -adrenoceptor-mediated effects of (-)-noradrenaline were investigated in the presence of ICI 118,551 (50 nM to block beta2 -adrenoceptors). The positive inotropic effects of both (-)-noradrenaline and (-)-adrenaline were accompanied by reductions in time to peak force and time to reach 50% relaxation. (-)-Adrenaline caused similar positive inotropic and lusitropic effects in atrial trabeculae from failing hearts. However, the inotropic potency, but not the lusitropic potency, of (-)-noradrenaline was reduced fourfold in atrial trabeculae from heart failure patients. Both (-)-adrenaline and (-)-noradrenaline enhanced cyclic AMP levels and produced phosphorylation of phospholamban, troponin I, and C-protein to a similar extent in atrial trabeculae from nonfailing hearts. The hastening of relaxation caused by (-)-adrenaline together with the PKA-catalyzed phosphorylation of the three proteins involved in relaxation, indicate coupling of beta2 -adrenoceptors to Gs protein. The phosphorylation of phospholamban at serine16 and threonine17 evoked by (-)-adrenaline through beta2 -adrenoceptors and by (-)-noradrenaline through beta1 -adrenoceptors was not different in atria from nonfailing and failing hearts. Activation of beta2 -adrenoceptors caused an increase in phosphorylase a activity in atrium from failing hearts further emphasizing the presence of the beta2 -adrenoceptor-Gsalpha-protein pathway in human heart. The positive inotropic and lusitropic potencies of (-)-adrenaline were conserved across Arg16Gly- and Gln27Glu-beta2 -adrenoceptor polymorphisms in the right atrium from patients undergoing coronary artery bypass surgery, chronically treated with beta1 -selective blockers. The persistent relaxant and biochemical effects of (-)-adrenaline through beta2 -adrenoceptors and of (-)-noradrenaline through beta1 -adrenoceptors in heart failure are inconsistent with an important role of coupling of beta2 -adrenoceptors with Gialpha-protein in human atrial myocardium.

Nuclear targeting of protein phosphatase-1 by HIV-1 Tat protein.

Transcription of human immunodeficiency virus (HIV)-1 genes is activated by HIV-1 Tat protein, which induces phosphorylation of the C-terminal domain of RNA polymerase-II by CDK9/cyclin T1. We previously showed that Tat-induced HIV-1 transcription is regulated by protein phosphatase-1 (PP1). In the present study we demonstrate that Tat interacts with PP1 and that disruption of this interaction prevents induction of HIV-1 transcription. We show that PP1 interacts with Tat in part through the binding of Val36 and Phe38 of Tat to PP1 and that Tat is involved in the nuclear and subnuclear targeting of PP1. The PP1 binding mutant Tat-V36A/F38A displayed a decreased affinity for PP1 and was a poor activator of HIV-1 transcription. Surprisingly, Tat-Q35R mutant that had a higher affinity for PP1 was also a poor activator of HIV-1 transcription, because strong PP1 binding competed out binding of Tat to CDK9/cyclin T1. Our results suggest that Tat might function as a nuclear regulator of PP1 and that interaction of Tat with PP1 is critical for activation of HIV-1 transcription by Tat.

Arthrogryposis multiplex with deafness, inguinal hernias, and early death: a family report of a probably autosomal recessive trait.

We report on three male newborn infants of a highly inbred Lebanese family presenting with a characteristic phenotype: arthrogryposis multiplex, deafness, large inguinal hernia, hiccup-like diaphragmatic contractions, and inability to suck, requiring nasogastric gavage feeding. All three boys died from respiratory failure during the first 3 months of life. Intra vitam or post mortem examinations revealed myopathic changes and elevated glycogen content of muscle tissue. This new syndrome is probably transmitted in an autosomal recessive mode, although X-linked inheritance cannot be excluded.

Increased potency and efficacy of combined phosphorylase inactivation and glucokinase activation in control of hepatocyte glycogen metabolism.

Glucokinase and phosphorylase both have a high control strength over hepatocyte glycogen metabolism and are potential therapeutic targets for type 2 diabetes. We tested whether combined phosphorylase inactivation and glucokinase activation is a more effective strategy for controlling hepatic glycogen metabolism than single-site targeting. Activation of glucokinase by enzyme overexpression combined with selective dephosphorylation of phosphorylase-a by an indole carboxamide that favors the T conformation of phosphorylase caused a greater stimulation of glycogen synthesis than the sum of either treatment alone. This result is explained by the complementary roles of elevated glucose-6-phosphate (G6P; a positive modulator) and depleted phosphorylase-a (a negative modulator) in activating glycogen synthase and also by synergistic inactivation of phosphorylase-a by glucokinase activation and the indole carboxamide. Inactivation of phosphorylase-a by the indole carboxamide was counteracted by 5-aminoimidazole-4-carboxamide 1-beta-D-ribofuranoside, which is metabolized to an AMP analog; this effect was reversed by G6P. Our findings provide further evidence for the inverse roles of G6P and AMP in regulating the activation state of hepatic phosphorylase. It is proposed that dual targeting of glucokinase and phosphorylase-a enables improved potency and efficacy in controlling hepatic glucose metabolism.

Endogenous effectors of human liver glycogen phosphorylase modulate effects of indole-site inhibitors.

Phosphorylase is regulated by a number of small-molecular-weight effectors that bind to three sites on the enzyme. Recently, a fourth site referred to as the indole-inhibitor site has been identified. Synthetic compounds bind to the site and inhibit activity. However, the effects of these compounds in the presence of other endogenous effectors are unknown. We have determined the effects of four indole derivative glycogen phosphorylase inhibitors (GPI) on recombinant human liver glycogen phosphorylase a activity. The GPIs tested were all potent inhibitors. However, the endogenous inhibitors (glucose, ADP, ATP, fructose 1-phosphate, glucose 6-phosphate, UDP-glucose) and the activator (AMP) markedly reduced the inhibitory effect of GPIs. Consistent with these in vitro findings, the IC50 for the inhibition of glycogenolysis in cells and the liver drug concentration associated with glucose-lowering activity in diabetic ob/ob mice in vivo were also significantly higher than those determined in in vitro enzyme assays. The inhibitory effect of indole-site effectors is modulated by endogenous small-molecular-weight effectors of phosphorylase a activity. However, at higher concentrations (10-30 microM), the GPI effect was dominant and resulted in inhibition of phosphorylase a activity irrespective of the presence or absence of the other modulators of the enzyme.

Contraction-mediated glycogenolysis in mouse skeletal muscle lacking creatine kinase: the role of phosphorylase b activation.

Skeletal muscle that is deficient in creatine kinase (CK-/-) exhibits accelerated glycogenolysis during contraction. Understanding this phenomenon could provide insight into the control of glycogenolysis during contraction. Therefore, glycogen breakdown was investigated in isolated extensor digitorum longus CK-/- muscle. Muscles were stimulated to produce repeated tetani for 20 s in the presence of sodium cyanide to block mitochondrial respiration. Accumulation of lactate after stimulation was similar in wild-type (WT) and CK-/- muscles, whereas accumulation of glucose-6-phosphate was twofold higher in CK-/- muscles, indicating greater glycogenolysis in CK-/- muscles. Total phosphorylase activity was decreased by almost 30 % in CK-/- muscle (P < 0.001). Phosphorylase fractional activity (-/+ 3.3 mM AMP) was similar in both groups in the basal state (about 10 %), but increased to a smaller extent in CK-/- muscles after stimulation (39 +/- 4 % vs. 52 +/- 4 % in WT, P < 0.05). Inorganic phosphate, the substrate for phosphorylase, increased marginally in CK-/- muscles after stimulation (basal = 25.3 +/- 2.2 micromol (g dry muscle)-1; stimulated = 33.9 +/- 2.3 micromol (g dry muscle)-1), but substantially in WT muscles (basal = 11.4 +/- 0.7 micromol (g dry muscle)-1; stimulated = 54.2 +/- 4.5 micromol (g dry muscle)-1). Kinetic studies of phosphorylase b (dephosphorylated enzyme) from muscle extracts in vitro demonstrated higher relative activities in CK-/- muscles (60-135 %) in response to low AMP concentrations (up to 50 microM) in both the basal state and after stimulation (P < 0.05), whereas no differences in activity between CK-/- and WT muscles were observed at high AMP concentrations (> 100 microM). These data indicate that allosteric activation of phosphorylase b accounts for the accelerated glycogenolysis in CK-/- muscle during contraction.

Parallel purification of three catalytic subunits of the protein serine/threonine phosphatase 2A family (PP2A(C), PP4(C), and PP6(C)) and analysis of the interaction of PP2A(C) with alpha4 protein.

The protein serine/threonine phosphatase (PP) type 2A family consists of three members: PP2A, PP4, and PP6. Specific rabbit and sheep antibodies corresponding to each catalytic subunit, as well as a rabbit antibody recognizing all three subunits, were utilized to examine the expression of these enzymes in select rat tissue extracts. PP2A, PP4, and PP6 catalytic subunits (PP2A(C), PP4(C), and PP6(C), respectively) were detected in all rat tissue extracts examined and exhibited some differences in their levels of expression. The expression of alpha4, an interacting protein for PP2A family members that may function downstream of the target of rapamycin (Tor), was also examined using specific alpha4 sheep antibodies. Like the phosphatase catalytic subunits, alpha4 was ubiquitously expressed with particularly high levels in the brain and thymus. All three PP2A family members, but not alpha4, bound to the phosphatase affinity resin microcystin-Sepharose. The phosphatase catalytic subunits were purified to apparent homogeneity (PP2A(C) and PP4(C)) or near homogeneity (PP6(C)) from bovine testes soluble extracts following ethanol precipitation and protein extraction. In contrast to PP2A(C), PP4(C) and PP6(C) exhibited relatively low phosphatase activity towards several substrates. Purified PP2A(C) and native PP2A in cellular extracts bound to GST-alpha4, and co-immunoprecipitated with endogenous alpha4 and ectopically expressed myc-tagged alpha4. The interaction of PP2A(C) with alpha4 was unaffected by rapamycin treatment of mammalian cells; however, protein serine/threonine phosphatase inhibitors such as okadaic acid and microcystin-LR disrupted the alpha4/PP2A complex. Together, these findings increase our understanding of the biochemistry of alpha4/phosphatase complexes and suggest that the alpha4 binding site within PP2A may include the phosphatase catalytic domain.

The 35 kDa acid metallophosphatase of the frog Rana esculenta liver: studies on its cellular localization and protein phosphatase activity.

The cellular localization of the 35 kDa, low molecular mass acid metallophosphatase (LMW AcPase) from the frog (Rana esculenta) liver and its activity towards P-Ser and P-Tyr phosphorylated peptides were studied. This enzyme was localized to the cytoplasm of hepatocytes but did not appear in other cells of liver tissue (endothelium, macrophages, blood cells). This LMW AcPase does not display activity towards (32)P-phosphorylase a under conditions standard for the enzymes of PPP family. Proteins containing P-Ser: rabbit (32)P-phosphorylasea and phosvitin are hydrolysed only at acidic pH and are poor substrates for this enzyme. The frog AcPase is not inhibited by okadaic acid and F(-) ions, the Ser/Thr protein phosphatase inhibitors. Moreover, the frog enzyme does not cross-react with specific antisera directed against N-terminal fragment of human PP2A and C-terminal conserved fragment of the eukaryotic PP2A catalytic subunits. These results exclude LMW AcPase from belonging to Ser/Thr protein phosphatases: PP1c or PP2Ac. In addition to P-Tyr, this enzyme hydrolyses efficiently at acidic pH P-Tyr phosphorylated peptides (hirudin and gastrin fragments). K(m) value for the hirudin fragment (7.55 +/- 1.59 x 10(-6) M) is 2-3 orders of magnitude lower in comparison with other substrates tested. The enzyme is inhibited competitively by typical inhibitors of protein tyrosine phosphatases (PTPases): sodium orthovanadate, molybdate and tungstate. These results may suggest that the LMW AcPase of frog liver can act as PTPase in vivo. A different cellular localization and different response to inhibition by tetrahedral oxyanions (molybdate, vanadate and tungstate) provide further evidence that LMW AcPase of frog liver is distinct from the mammalian tartrate-resistant acid phosphatases.

Inactivation of phosphorylase is a major component of the mechanism by which insulin stimulates hepatic glycogen synthesis.

Multiple signalling pathways are involved in the mechanism by which insulin stimulates hepatic glycogen synthesis. In this study we used selective inhibitors of glycogen synthase kinase-3 (GSK-3) and an allosteric inhibitor of phosphorylase (CP-91149) that causes dephosphorylation of phosphorylase a, to determine the relative contributions of inactivation of GSK-3 and dephosphorylation of phosphorylase a as alternative pathways in the stimulation of glycogen synthesis by insulin in hepatocytes. GSK-3 inhibitors (SB-216763 and Li+) caused a greater activation of glycogen synthase than insulin (90% vs. 40%) but a smaller stimulation of glycogen synthesis (30% vs. 150%). The contribution of GSK-3 inactivation to insulin stimulation of glycogen synthesis was estimated to be less than 20%. Dephosphorylation of phosphorylase a with CP-91149 caused activation of glycogen synthase and translocation of the protein from a soluble to a particulate fraction and mimicked the stimulation of glycogen synthesis by insulin. The stimulation of glycogen synthesis by phosphorylase inactivation cannot be explained by either inhibition of glycogen degradation or activation of glycogen synthase alone and suggests an additional role for translocation of synthase. Titrations with the phosphorylase inactivator showed that stimulation of glycogen synthesis by insulin can be largely accounted for by inactivation of phosphorylase over a wide range of activities of phosphorylase a. We conclude that a signalling pathway involving dephosphorylation of phosphorylase a leading to both activation and translocation of glycogen synthase is a critical component of the mechanism by which insulin stimulates hepatic glycogen synthesis. Selective inactivation of phosphorylase can mimic insulin stimulation of hepatic glycogen synthesis.

Effects of chronic ethanol treatment on the angiotensin II-mediated p42/p44 mitogen-activated protein kinase and phosphorylase a activation in rat hepatocytes.

We have demonstrated previously that 24 h of ethanol treatment potentiates angiotensin II (ANG II)-stimulated p42/p44 mitogen-activated protein kinase (MAPK) activity in hepatocytes. This potentiation of p42/p44 MAPK by ethanol exhibited agonist selectivity. To compare the effects of acute (24 h) versus chronic (6 weeks) ethanol treatment, ANG II-induced intracellular signaling was examined in (1) rat hepatocytes treated with ethanol for 24 h and (2) hepatocytes obtained from rats fed ethanol for 6 weeks. In hepatocytes obtained from rats fed ethanol for 6 weeks, ANG II-stimulated phosphorylase a was reduced, and this activity was calcium dependent and p42/p44 MAPK independent. Surprisingly, ANG II-stimulated p42/p44 MAPK activation was not affected in hepatocytes obtained from rats fed ethanol chronically (6 weeks). However, chronic (6 weeks) ethanol treatment decreased ethanol potentiation of p42/p44 MAPK by about 56.3% +/- 3.6% for p42 MAPK and 61.3% +/- 11.7% for p44 MAPK. Furthermore, ethanol had no effect on the expression of angiotensinogen and c-myc mRNA in hepatocytes. A decrease in ANG II-activated phosphorylase a, but not in p42/p44 MAPK activation, after chronic (6 weeks) ethanol treatment leads to the conclusion that they may not be dependent on each other.

Glucose 6-phosphate regulates hepatic glycogenolysis through inactivation of phosphorylase.

High glucose concentration suppresses hepatic glycogenolysis by allosteric inhibition and dephosphorylation (inactivation) of phosphorylase-a. The latter effect is attributed to a direct effect of glucose on the conformation of phosphorylase-a. Although glucose-6-phosphate (G6P), like glucose, stimulates dephosphorylation of phosphorylase-a by phosphorylase phosphatase, its physiological role in regulating glycogenolysis in intact hepatocytes has not been tested. We show in this study that metabolic conditions associated with an increase in G6P, including glucokinase overexpression and incubation with octanoate or dihydroxyacetone, cause inactivation of phosphorylase. The latter conditions also inhibit glycogenolysis. The activity of phosphorylase-a correlated inversely with the G6P concentration within the physiological range. The inhibition of glycogenolysis and inactivation of phosphorylase-a caused by 10 mmol/l glucose can be at least in part counteracted by inhibition of glucokinase with 5-thioglucose, which lowers G6P. In conclusion, metabolic conditions that alter the hepatic G6P content affect glycogen metabolism not only through regulation of glycogen synthase but also through regulation of the activation state of phosphorylase. Dysregulation of G6P in diabetes by changes in activity of glucokinase or glucose 6-phosphatase may be a contributing factor to impaired suppression of glycogenolysis by hyperglycemia.

New insights into beta2-adrenoceptor signaling in the adult rat heart.

OBJECTIVE: The role of cAMP in beta(2)-adrenoceptor signaling and its functional relevance in adult rat heart has been the subject of considerable controversy. Therefore, we investigated the beta(2)-adrenoceptor pathways in both adult cardiomyocytes and in the intact hearts of Wistar rats with respect to protein kinase A (at Ser16)-, the key event in shortening of relaxation time, and CaM kinase II (at Thr17)-dependent phospholamban phosphorylation. METHODS: Contractile and cellular beta(1)/beta(2)-adrenergic responses were studied in parallel on the same perfused rat heart. (-)Isoproterenol and the beta(2)-adrenergic agonists zinterol and procaterol were used to discriminate the beta-adrenoceptor subtype-related actions. RESULTS: Beta(2)-adrenoceptor stimulation induces protein kinase A-dependent phospholamban phosphorylation in both adult cardiomyocytes and in adult hearts of rats. The beta(2)-adrenoceptor-mediated shortening of relaxation time in the heart correlates with Ser16 phosphorylation. Adenosine elicited antiadrenergic action on both beta(1)- and beta(2)-adrenergic signaling cascades by reducing the phosphorylation status of phospholamban. Only beta(1)-adrenoceptor stimulation produced significant CaM kinase II-related Thr17 phosphorylation, troponin I phosphorylation and activation of phosphorylase a. CONCLUSIONS: Our findings clearly show that beta(2)-adrenoceptor signaling is coupled to phospholamban phosphorylation and shortening of relaxation time in the adult rat heart.

Mutants of phosphorylase a altered in recognition by protein phosphatase-1.

To develop our knowledge of specificity determinants for protein phosphatase-1, mutants of phosphorylase b have been converted to phosphorylase a and examined for their efficacy as substrates for protein phosphatase-1. Mutants focused on the N-terminal primary sequence surrounding the phosphoserine (R16A, R16E, and I13G) and at a site that interacts with the phosphoserine in phosphorylase a, (R69K and R69E). The success achieved studying protein kinase substrate specificity with peptide substrates has not extended to protein phosphatases. Protein phosphatases are believed to recognize higher order structure in substrates in addition to the primary sequence surrounding the phosphoserine or threonine. Peptide studies with protein phosphatase-1 have revealed a preference for basic residues N-terminal to the phosphoserine. Arginine 16 in phosphorylase a may be a positive determinant. In this work, protein phosphatase-1 preferred the positive charge on arginine 16. R16A exhibited a similar K(m) but reduced V(max), and R16E had an increased K(m) and a decreased V(max) when compared to phosphorylase. I13G had a similar K(m) but an increased V(max). The R69 mutants were also dephosphorylated preferentially over phosphorylase a. The K(m) for R69K was unchanged but had a higher V(max). R69E exhibited the most changes, with a 4-fold increase in K(m) and a 10-fold increase in V(max). These results suggest that proper presentation of the phosphoserine can greatly affect the rate of dephosphorylation.

Long-term oral nicotine administration reduces insulin resistance in obese rats.

This study aimed to investigate the effect of long-term oral nicotine administration on insulin resistance in an animal model of obesity. Eight-week-old male Zucker fatty rats (ZFRs) were administered nicotine tartrate dihydrate (4.6 mg/kg/day) in the drinking water. The control group was pair-fed. The body weights and food intake over 8 weeks were similar in both groups. Plasma glucose levels at 3, 6, 9, 12, and 15 min after insulin administration (0.5 U/kg) in the nicotine group were significantly lower than those in the control group. The calculated K(ITT) value for the nicotine group was significantly higher than that for the control group. Wet weight of the liver in the nicotine group was significantly lower than that in the control group. Transaminases and histological examination of the liver revealed no alteration by nicotine administration. Glycogen, glycogen synthetase activity and gluconeogenesis in the liver in the nicotine group were significantly lower than those in the control group. Phosphorylase-a activity of the liver in the nicotine group was significantly higher than that in the control group. Glycogen, glycogen synthetase, and phosphorylase-a activity of skeletal muscle were similar in both groups. These results suggest that long-term oral nicotine administration may reduce insulin resistance in obese diabetic rats through a reduced hepatic glucose release and, in part, contribute to lowering blood glucose levels.

Epinephrine control of glycogen metabolism in glycogen-associated protein phosphatase PP1G/R(GL) knockout mice.

The glycogen-associated protein phosphatase (PP1G/ R(GL))may play a central role in the hormonal control of glycogen metabolism in the skeletal muscle. Here, we investigated the in vivo epinephrine effect of glycogen metabolism in the skeletal muscle of the wild-type and R(GL) knockout mice. The administration of epinephrine increased blood glucose levels from 200 +/- +/- 20 to 325 +/- 20 mg/dl in both wild-type and knockout mice. Epinephrine decreased the glycogen synthase -/+ G6P ratio from 0.24 +/- 0.04 to 0.10 +/- 0.02 in the wild-type, and from 0.17 +/- 0.02 to 0.06 +/- 0.01 in the knockout mice. Conversely, the glycogen phosphorylase activity ratio increased from 0.21 +/- 0.04 to 0.65 +/- 0.07 and from 0.30 +/- 0.04 to 0.81 +/- 0.06 in the epinephrine treated wild-type and knockout mice respectively. The glycogen content of the knockout mice was substantially lower (27 percent) than that of both wild-type mice; and epinephrine decreased glycogen content in the wild-type and knockout mice. Also, in Western blot analysis there was no compensation of the other glycogen targeting components PTG/R5 and R6 in the knockout mice compared with the wild-type. Therefore, R(GL) is not required for the epinephrine stimulation of glycogen metabolism, and rather another phosphatase and/or regulatory subunit appears to be involved.

Diverse effects of two allosteric inhibitors on the phosphorylation state of glycogen phosphorylase in hepatocytes.

Two distinct allosteric inhibitors of glycogen phosphorylase, 1,4-dideoxy-1,4-imino-D-arabinitol (DAB) and CP-91149 (an indole-2-carboxamide), were investigated for their effects on the phosphorylation state of the enzyme in hepatocytes in vitro. CP-91149 induced inactivation (dephosphorylation) of phosphorylase in the absence of hormones and partially counteracted the phosphorylation caused by glucagon. Inhibition of glycogenolysis by CP-91149 can be explained by dephosphorylation of phosphorylase a. This was associated with activation of glycogen synthase and stimulation of glycogen synthesis. DAB, in contrast, induced a small degree of phosphorylation of phosphorylase. This was associated with inactivation of glycogen synthase and inhibition of glycogen synthesis. Despite causing phosphorylation (activation) of phosphorylase, DAB is a very potent inhibitor of glycogenolysis in both the absence and presence of glucagon. This is explained by allosteric inhibition of phosphorylase a, which overrides the increase in activation state. In conclusion, two potent phosphorylase inhibitors exert different effects on glycogen metabolism in intact hepatocytes as a result of opposite effects on the phosphorylation state of both phosphorylase and glycogen synthase.