5-Aminoimidazole-4-carboxamide 1-beta -D-ribofuranoside (AICAR) stimulates myocardial glycogenolysis by allosteric mechanisms

doi:10.1152/ajpregu.00319.2002

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5-Aminoimidazole-4-carboxamide 1- $beta$ -D-ribofuranoside (AICAR) stimulates myocardial glycogenolysis by allosteric mechanisms

Sarah L. Longnus¹, Richard B. Wambolt¹, Hannah L. Parsons¹, Roger W. Brownsey², and Michael F. Allard¹

¹ McDonald Research Laboratories/The iCAPTUR⁴E Centre, Department of Pathology and Laboratory Medicine, University of British Columbia-St.Paul's Hospital, Vancouver, British Columbia V6Z 1Y6; and ² Department of Biochemistry and Molecular Biology, University of British Columbia, Vancouver, British Columbia, Canada V6T 1Z3

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

We tested the hypothesis that activation of AMP-activated protein kinase (AMPK) promotes myocardial glycogenolysis by decreasingglycogen synthase (GS) and/or increasing glycogen phosphorylase(GP) activities. Isolated working hearts from halothane-anesthetizedmale Sprague-Dawley rats perfused in the absence or presence of0.8 or 1.2 mM 5-aminoimidazole-4-carboxamide 1- $beta$ -D-ribofuranoside(AICAR), an adenosine analog and cell-permeable activator of AMPK,were studied. Glycogen degradation was increased by AICAR, whileglycogen synthesis was not affected. AICAR increased myocardial5-aminoimidazole-4-carboxamide 1- $beta$ -D-ribofuranotide (ZMP), theactive intracellular form of AICAR, but did not alter the activityof GS and GP measured in tissue homogenates or the content ofglucose-6-phosphate and adenine nucleotides in freeze-clampedtissue. Importantly, the calculated intracellular concentrationof ZMP achieved in this study was similar to the K_m value of ZMPfor GP determined in homogenates of myocardial tissue. We concludethat the data are consistent with allosteric activation of GPby ZMP being responsible for the glycogenolysis caused by AICARin the intact ratheart.

myocardium; glycogen metabolism; adenosine 5'-monophosphate-activated protein kinase

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

THE AMP-ACTIVATED PROTEIN kinase (AMPK) system has been described as a protective system for individual cells during metabolicstress by acting as a "fuel gauge," being activated by depletionof ATP and the resultant increase in the AMP:ATP ratio (17).Once activated, AMPK initiates energy-saving and energy-generatingsystems. In this regard, AMPK has been shown to phosphorylateand inhibit 3-hydroxy-3-methylglutaryl (HMG)-CoA reductase (12,43) and acetyl-CoA carboxylase (ACC) in isolated hepatocytes(43) and in intact rat liver (12). By inhibiting HMG-CoA reductaseand ACC, activated AMPK promotes energy saving in these tissuesby reducing sterol and fatty acid synthesis,respectively.

Interestingly, AMPK mRNA expression is substantial in cardiac (47) and skeletal (14) muscle, even though neither cardiacnor skeletal muscle possesses the biosynthetic capabilities offat and liver. In these tissues, activation of AMPK has been shownto be associated with increased energy production. For example,studies of skeletal muscle in vivo (49) and in vitro (23)show that AMPK is activated and fatty acid oxidation elevatedduring prolonged exercise or increased electrical stimulation.In isolated hearts exposed to global ischemia, activation of AMPKis accompanied by phosphorylation and inhibition of ACC as wellas a reduction in its end product, malonyl-CoA (26, 27, 30).During subsequent reperfusion of the hearts, AMPK activity remainshigh, and the accompanying reduction in malonyl-CoA levels, whichrelieves the inhibition of carnitine palmitoyltransferase-1 andstimulates transport of long-chain fatty acids into the mitochondria(26, 27, 30), leads to accelerated rates of fatty acid oxidation(26, 27). Glucose uptake in skeletal muscle (7, 18, 34,50) and in cardiac muscle (41) has also been shown to be increasedon activation of AMPK by increases in workload or by exposureto 5-aminoimidazole-4-carboxamide 1- $beta$ -D-ribofuranoside (AICAR),an adenosine analog and cell-permeable activator of AMPK (11).In addition, AMPK has recently been shown to phosphorylate andactivate 6-phosphofructo-2-kinase (PFK-2) in vitro and in isolatedcells (33), suggesting that AMPK-induced activation of PFK-2is involved in the stimulation of glycolysis during times of metabolicstress. Taken together, the results of these studies support theconcept that activation of AMPK increases myocardial energy productionby stimulating both fatty acid oxidation and glucoseutilization.

There is evidence to suggest that AMPK may participate in the control of glycogen metabolism. AMPK has been shown to phosphorylateglycogen synthase purified from rabbit skeletal muscle at Ser7 (10), a site known to be phosphorylated in vivo (37, 52).This phosphorylation promotes subsequent phosphorylation at Ser10 by casein kinase-1, which ultimately causes inactivation ofglycogen synthase (37, 44, 52). More recently, activationof AMPK by AICAR was shown to lead to the phosphorylation andinactivation of glycogen synthase in rat skeletal muscle (50).AMPK has also been shown to phosphorylate purified rabbit skeletalmuscle phosphorylase kinase, the kinase responsible for phosphorylatingand activating glycogen phosphorylase (10), although anotherreport suggests that this may not be the case (9). If suchAMPK-dependent phosphorylations occur in the heart and are physiologicallyrelevant, they should lead to inactivation of glycogen synthaseand/or activation of glycogen phosphorylase and, thereby, promotethe breakdown of glycogen in the intact heart to increase energyproduction from endogenous glucose stores. This scenario makesgreat intuitive sense when the importance of glycogen as a fuel,especially during times of metabolic stress, is considered (1).Importantly, the effects of AMPK-induced changes in phosphorylationon enzyme activity and on glycogen metabolism in the intact heartare not yet fullyknown.

In the present study, we tested the hypothesis that increased AMPK activity promotes glycogenolysis in the intact heart byincreasing glycogen phosphorylase activity and decreasing glycogensynthase activity. The effects of AMPK activation on myocardialglycogen metabolism were determined in isolated working rat heartsexposed to the cell-permeable AMPK activator AICAR. We specificallychose to perform this investigation in vitro, where conditionscould be accurately controlled, to avoid confounding effects ofchanges induced by AICAR administration invivo.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Animals

Male Sprague-Dawley rats weighing 250-350 g were housed in a temperature-controlled (22 ± 1°C) and light-controlled (12:12-hlight-dark cycle) room. Rats had free, unlimited access to feed(Rodent Diet 5001, PMI Nutrition, Brentwood, MO) and water. Careof the animals was performed in accordance with guidelines setout by the Canadian Council on Animal Care and with the AmericanPhysiological Society's "Guiding Principles for Research InvolvingAnimals and HumanBeings."

Isolated Heart Preparation and Perfusion Protocol

As previously described (20), hearts from halothane (3-4%)-anesthetized rats were isolated and perfused as working preparationswith modified Krebs-Henseleit (KH) solution at a preload of 11mmHg and an afterload of 80 mmHg. The KH solution contained 5.5mM [5-³H]glucose, 0.5 mM lactate, and 2.5 mM Ca²⁺ and either 1.2 mM palmitate or 2.4 mM octanoate as the sourceof fatty acid. Octanoate, a medium-chain-length fatty acid, wasused as an alternative fatty acid source because AICAR-inducedactivation of AMPK does not significantly increase its oxidation(29). In this way, confounding effects of enhanced fatty acidoxidation on glycogen metabolism were minimized and could be accountedfor by comparison with palmitate-perfused hearts. Hearts werepaced (250 beats/min) if the intrinsic heart rate fell below 230beats/min; AICAR was found to have slight negative chronotropiceffects in preliminaryexperiments.

Hearts were perfused in the absence or presence of AICAR (0.8 or 1.2 mM, as indicated) for 15 min. Concentrations of AICARin the range chosen have been shown to activate AMPK in skeletalmuscle (7) and heart (32, 41). Additionally, we have previouslyshown that lower concentrations of AICAR stimulate long-chainfatty acid oxidation in isolated working rat hearts perfused undersimilar conditions (29). Higher concentrations of AICAR werenot used because they adversely affected heart function in preliminaryexperiments. AICAR is the riboside derivative of the Z-base compound5-amino-4-imidazole carboxamide (42). After entry into the cell,AICAR is monophosphorylated by adenosine kinase to form 5-aminoimidazole-4-carboxamide1- $beta$ -D-ribofuranotide (ZMP), which is a normal constituent of thede novo purine synthesis pathway (42). As a consequence, AICARhas been used experimentally to restore purine nucleotide poolsin postischemic myocardium (45) and in cerebral tissue of patientswith Lesch-Nyan Syndrome (31). ZMP mimics the multiple effectsof AMP on AMPK, causing allosteric activation and also promotingphosphorylation and activation by the upstream kinase, AMPK kinase(AMPKK) (17, 19). The time course for these experiments waschosen because 15 min is sufficient for AICAR-induced activationof AMPK in skeletal muscle (34) and because it minimizes thedecrease in glycogen content observed in hearts perfused withoctanoate for longer time periods (2). Selected octanoate-perfusedhearts were exposed to either isoproterenol (100 nM) or insulin(100 mU/l). These latter experiments were used to validate themethods to measure glycogen synthesis and degradation under conditionsin which glycogen is known to decrease (isoproterenol) or increase(insulin).

During the perfusion period, heart rate and peak systolic pressure were recorded at 5-min intervals with a DIREC physiologicalrecording system (Fine Science Tools) using a pressure transducer(Viggo-Spectramed) in the aortic afterload line. The rate-pressureproduct (heart rate multiplied by peak systolic pressure) wascalculated to determine the work performed by the heart (3).At the end of the 15-min perfusion period, hearts were quicklyfrozen using aluminum tongs cooled to the temperature of liquidnitrogen. Frozen heart tissue was powdered using a mortar andpestle and then stored in cryovials at $-$ 70°C untiluse.

Analytical Procedures

Myocardial glycogen. Myocardial glycogen content was determined after extraction of frozen ventricular tissue with 30% KOH, ethanol precipitation,and acid hydrolysis of glycogen (20). As described, a portionof the glycogen extract was used to determine net incorporationof radiolabeled glucose to measure net glycogen synthesis (4,20). The extent of glycogen degradation was calculated as thedifference between myocardial glycogen content at the start ofthe perfusion and the amount of unlabeled glycogen in the myocardiumat the end of the perfusion (4). The former value was obtainedfrom hearts frozen at the end of the Langendorff perfusion (114.9± 4.3 µmol/g dry wt, n = 8), while the latter value representsthe difference between total glycogen content and net glycogensynthesis in myocardium at the end of theperfusion.

Activity of glycogen synthase, glycogen phosphorylase, and AMPK. Glycogen synthase, calculated from the ratio of activities determined with low or high glucose-6-phosphate and expressed asa percentage of total activity (%a), was determined, essentiallyas previously described (46). This method is based on the measurementof the incorporation of radioactivity into glycogen from UDP-[U-¹⁴C]glucose. To approximate in vivo conditions, synthase activitywas measured in the presence of glucose-6-phosphate at a concentrationof either 0.25 mM (a form) or 15 mM (total activity) (16).

Glycogen phosphorylase activity, based on the measurement of ¹⁴C incorporation into glycogen from labeled glucose-1-phosphateand expressed as a percentage of total activity (%a), was determinedusing a previously described method (40). Phosphorylase activitywas generally measured in the presence of 0.5 mM caffeine to eliminateallosteric effects of AMP or ZMP during the reaction (22). Inseparate experiments to examine the effects of adding ZMP andAMP to myocardial homogenates, caffeine was omitted from the glycogenphosphorylaseassays.

AMPK activity was assayed by following the incorporation of ³²P into the synthetic SAMS peptide (26, 29). The SAMS peptide(HMRSAMSGLHLVKRR) was synthesized at the Nucleic Acid and ProteinService Laboratory at the University of British Columbia, Canada.Protein concentration was measured using the bicinchoninic acidmethod (Sigma Chemical, procedure TPRO-562).

In separate experiments, the dose-response relationship between ZMP concentration and activity of glycogen phosphorylase,glycogen synthase, or AMPK in myocardial homogenates was determined.The concentrations of ZMP giving half-maximal activation (K_m)of glycogen phosphorylase were determined using zero correcteddata with a nonlinear curve fit using a Michaelis-Menten hyperbolafunction (Origin, Microcal Software, Northampton,MA).

Phosphorylation of AMPK and ACC. Phosphorylation of AMPK was determined to complement AMPK activity measurements in myocardial tissue extracts. The extentof phosphorylation of ACC, an important downstream target of AMPK,was also quantified as a means to assess AMPK activity in theintact heart (48). Phosphorylation of ACC has been shown tobe a useful reporter of AMPK activity in skeletal muscle stimulatedat low frequencies where AMPK activity is not measurably altered(36). The extent of phosphorylation of AMPK and ACC proteinsin myocardium was determined by Western analysis by a previouslydescribed method (4). Briefly, samples of frozen ventriculartissue homogenate (containing 20 µg total protein) were solubilizedby boiling in reducing sample buffer, separated by electrophoresison 10% SDS-polyacrylamide gels, and transferred by electroblottingto a nitrocellulose membrane. After nonspecific blocking, theblots were probed overnight with primary rabbit antibodies againstrat phospho-AMPK (1:1,000 dilution, Cell Signaling Technology,Mississauga, Ontario, Canada) or phospho-ACC (1:100 dilution,Upstate Biochemicals, Lake Placid, NY). After incubation withgoat anti-rabbit secondary antibody, the signal was detected byan ECL-based detection system. Bands were quantified by densitometry.Equivalence of protein loading was confirmed by detection of totalAMPK andACC.

Other procedures. Adenine nucleotides as well as glucose-6-phosphate were determined in perchloric acid extracts of frozen ventricular tissue.Adenine nucleotides were measured in the tissue extracts by high-performanceliquid chromatography according to a previously described method(5). Glucose-6-phosphate was measured by a standard spectrophotometrictechnique (8).

Data Analysis

Data are expressed as means ± SE. Individual group means were compared using t-tests. The Bonferroni procedure was appliedto all tests to correct for multiple tests and comparisons. Acorrected value of P < 0.05 was consideredsignificant.

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Heart Function

Heart function was stable over the 15-min perfusion in all groups (Fig. 1). AICAR (0.8 or 1.2 mM) had no significant effecton mechanical function in either octanoate- or palmitate-perfusedhearts (Table 1).

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Fig. 1. Mechanical function of isolated working hearts perfused with octanoate (open symbols) or palmitate (filled symbols) for 15 min. Circles, no 5-aminoimidazole-4-carboxamide 1- $beta$ -D-ribofuranoside (AICAR); squares, 0.8 mM AICAR; triangles, 1.2 mM AICAR. bpm, Beats/min.

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Table 1. Mechanical function of isolated working hearts perfused with octanoate or palmitate

Glycogen Content

Myocardial glycogen, including glycogen degradation, glycogen synthesis, and total content in hearts perfused with octanoateor palmitate, is summarized in Fig. 2. Octanoate-perfused heartsshowed a dose-dependent increase in the extent of glycogen degradationwith increasing AICAR concentration (Fig. 2A). Significantly moreglycogen was degraded at both 0.8 and 1.2 mM AICAR compared withoctanoate-perfused hearts without AICAR. Among palmitate-perfusedhearts, glycogen degradation also increased in the presence ofAICAR compared with palmitate-perfused hearts without AICAR (Fig.2A). Furthermore, octanoate-perfused hearts degraded significantlymore glycogen than palmitate-perfused hearts in the presence of1.2 mM AICAR (P < 0.05).

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Fig. 2. Glycogen degraded (A), newly synthesized glycogen (B), and total glycogen content (C) in octanoate-perfused (open bars) and palmitate-perfused (filled bars) hearts. Values are means ± SE. The amount of glycogen degraded was calculated as the difference between glycogen at the outset of the perfusion (114.9 ± 4.3 µmol/g dry wt) and the amount of unlabeled glycogen at the end of the perfusion. The latter represents the difference between total glycogen content and net glycogen synthesized at the end of perfusion. * Significantly different from control value, P < 0.05; $dagger$ significantly different from octanoate-perfused value, P < 0.05; n = 3-5/group.

Incorporation of radiolabeled glucose, which is a measure of net glycogen synthesis during the perfusion period (4, 20),was not significantly altered by the presence of AICAR in eitheroctanoate- or palmitate-perfused hearts (Fig. 2B). Total myocardialglycogen content tended to decrease in a stepwise manner withincreasing AICAR concentration in both octanoate- and palmitate-perfusedhearts (Fig. 2C). However, compared with corresponding heartswithout AICAR, total glycogen content was reduced significantlyonly in octanoate-perfused hearts exposed to 1.2 mMAICAR.

As anticipated, insulin increased net glycogen synthesis (6.7 ± 0.3 vs. 3.1 ± 0.9 µmol/g dry wt, P < 0.05) and isoproterenolincreased glycogen degradation (77.4 ± 6.7 vs. 3.6 ± 2.8 µmol/gdry wt, P < 0.05) compared with values in hearts perfused in theirabsence. Correspondingly, isoproterenol decreased (45.3 ± 4.4µmol/g dry wt, n = 4, P < 0.05) and insulin increased (132 ± 6µmol/g dry wt, n = 3, P < 0.05) total myocardial glycogen contentcompared with hearts perfused in the absence of either agent (114.0± 3.7 µmol/g drywt).

Activities of AMPK, Glycogen Synthase, and Glycogen Phosphorylase

Activities of AMPK, glycogen synthase, and glycogen phosphorylase in hearts perfused in the presence and absence of AICARare summarized in Table 2. AMPK activity measured in myocardialextracts was not significantly altered by AICAR in either groupof hearts perfused. This contrasts dramatically with the three-to fourfold elevation in AMPK activity observed in rat heartsexposed to no-flow global ischemia (1,722 ± 647 pmol · min¹ · mg protein¹, n = 4). Activities of glycogen synthase and glycogen phosphorylasemeasured in heart homogenates were also not significantly alteredafter perfusion with AICAR in the presence of octanoate or palmitate.

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Table 2. Biochemical parameters in hearts perfused with octanoate or palmitate

Significant concentration-dependent effects of ZMP on glycogen phosphorylase activity in myocardial homogenates were observed(Fig. 3A), yielding a K_m of glycogen phosphorylase for ZMP of708 ± 37 µM. As shown previously by Corton et al. (11), AMPKis dose dependently activated by relevant concentrations of ZMP(Fig. 3B). We also found that ZMP inhibits glycogen synthase butdoes so only at concentrations >5 mM (Fig. 3C). This latter findingis in keeping with that of other investigators who showed no alterationin glycogen synthase by 3 mM ZMP (50).

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Fig. 3. Representative plots of the concentration-dependent effects of 5-aminoimidazole-4-carboxamide 1- $beta$ -D-ribofuranotide (ZMP) on glycogen phosphorylase (A), AMP-activated protein kinase (AMPK; B), and glycogen synthase (C) activity in homogenates of rat myocardium. U, µmol/min; prt, Protein.

Phosphorylation of AMPK and ACC

The extent of phosphorylation of AMPK and ACC in hearts perfused with and without AICAR is summarized in Fig. 4. Exposureof hearts to 1.2 mM AICAR caused no significant increase in phosphorylationof AMPK, a finding consistent with a failure to detect changesin measurable AMPK activity in response to AICAR. In contrast,phosphorylation of ACC was increased in hearts exposed to AICAR,indicating that AMPK was activated in the myocardium during theheart perfusion.

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Fig. 4. Representative immunoblots of the phosphorylated forms of AMPK (phosphoAMPK; A, top) and acetyl-CoA carboxylase (phosphoACC; B, top) as well as total AMPK (AMPK 1/2; A, bottom) and ACC (B, bottom) in isolated working rat hearts perfused in the absence (Control) or presence of AICAR. Homogenate from hearts exposed to 30 min no-flow ischemia (Ischemia) serves as a control for changes in phosphorylation of AMPK and ACC. Protein (20 µg) from the myocardial homogenate was loaded on each lane. Each lane represents a single heart.

Myocardial Metabolites

Myocardial ZMP content increased in a stepwise manner with increasing AICAR concentrations (Table 2). ZMP content was ~4times higher in hearts exposed to 1.2 mM AICAR than in heartsperfused in the absence of AICAR. Significant differences in contentof ATP or in other adenine nucleotides were not observed in responseto AICAR (Table 2). Similarly, content of glucose-6-phosphatewas not significantly affected by AICAR (Table 2).

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Myocardial glycogen content reflects the balance between the flux through glycogen synthase and glycogen phosphorylase, bothenzymes being controlled in a complex manner via phosphorylationand key allosteric mediators that include AMP, ATP, inorganicphosphate, and glucose-6-phosphate (35, 38). In the presentexperiments, measurable changes in glycogen phosphorylase or glycogensynthase activity were not observed in tissue extracts preparedfrom hearts after perfusion in the presence of AICAR (Table 2),even though glycogen degradation was stimulated (Fig. 2). Thisfinding indicates that changes in phosphorylation of these keyregulatory enzymes did not occur under the conditions of studyand cannot explain the stimulation of glycogen degradation observedin response to AICAR. Other investigators have observed that AICARactivates glycogen phosphorylase and stimulates glycogenolysis,assessed indirectly as lactate production, in isolated skeletalmuscle (51), presumably through phosphorylation and activationof phosphorylase kinase. The discrepant findings between cardiacand skeletal muscle may be a reflection of differing sensitivitiesof adult rat heart and skeletal muscle to the effects of AICAR.Alternatively, they may result from inherent differences in therelative importance of phosphorylation as opposed to allostericcontrol of glycogen metabolism between cardiac and skeletal muscle.The constant work load and dynamics of the heart might demanda greater reliance on the rapid control features afforded by allostericmechanisms.

Changes in the cellular concentrations of key allosteric mediators, including glucose-6-phosphate and adenine nucleotides,were not observed in the presence of AICAR, indicating that thesefactors are not responsible for the stimulation of glycogen degradationobserved. In concordance with our results, others have found thatAICAR does not alter adenine nucleotide levels in well-perfusedhearts (42). Inorganic phosphate was not measured in the currentexperiments. However, given the absence of changes in adeninenucleotides, it is unlikely that inorganic phosphate increasedin the present experiments and, thereby, was presumably not acontributing factor to the changes in glycogen observed. We did,however, detect a substantial increase in ZMP in the presenceof AICAR (Table 2). Importantly, ZMP was found to mimic the effectsof AMP on glycogen phosphorylase in extracts of myocardium (Fig.3). These effects on glycogen phosphorylase activity were observedat concentrations of ZMP in the range of those detected in thehearts in our study. On the basis of the ZMP content in heartsexposed to 1.2 mM AICAR, and assuming an intracellular water contentof 2 ml/g dry wt (25), we calculate that the intracellular concentrationof ZMP was ~600 µM in these hearts. This concentration of ZMPis very similar to the K_m value of ZMP for glycogen phosphorylasedetermined in myocardial extracts. Others have observed similarconcentration-dependent effects of ZMP on glycogen phosphorylaseactivity in skeletal muscle extracts (51). We also found thatglycogen synthase activity in myocardial extracts is unaffectedby concentrations of ZMP achieved in these experiments (Fig. 3).Thus we speculate that, in the absence of changes in the phosphorylationstate of regulatory enzymes or in content of key allosteric mediators,the AICAR-induced elevation of ZMP is responsible for the increasedglycogen degradation observed in the present experiments by wayof allosteric activation of glycogen phosphorylase. This viewpointis entirely consistent with the well-recognized importance ofallosteric modifiers in the control of glycogen metabolism inmuscle (21, 39).

Our finding that AICAR stimulates glycogen degradation stands in contrast to those of other investigators. The majority havefound that AICAR does not significantly alter total glycogen contentin skeletal muscle (7, 28, 50) or heart muscle (41).However, Aschenbach et al. (6) recently found that total glycogencontent of skeletal muscle was increased by AICAR administrationin vivo. This discrepancy with respect to the effects of AICARon muscle glycogen may be related to the different methods and/orpreparations used to assess the effect of AICAR on glycogen metabolism.Determination of total glycogen content alone does not providean accurate assessment of glycogen metabolism because it failsto account for simultaneous synthesis and degradation of glycogen(i.e., glycogen turnover), a process that actively occurs in rathearts perfused under similar conditions (15, 20). By accountingfor newly synthesized glycogen as well as the amount of glycogenat the outset of the perfusion (4), a more accurate determinationof the extent of glycogen degradation was obtained in this studythan could be obtained by measuring changes in total glycogencontent alone. Failure to account for newly synthesized glycogenmay thus explain why AICAR-induced changes in the extent of glycogendegradation were not observed in previous studies. The effectof AICAR on glycogen metabolism in vivo is complicated by accompanyingeffects on the concentration of relevant substrates in the circulation(6), which are likely a contributing factor to the increasedskeletal muscle glycogen content observed. Of relevance, the authorsof this investigation concluded that AICAR did not promote glycogensynthesis by changing glycogen synthase or phosphorylase activity.Rather, the increased synthesis of glycogen was attributed toalterations in intracellular concentrations of key allostericmodulators, specifically glucose-6-phosphate.

The AMPK activities observed in this study correspond well with previously reported values measured in isolated, perfusedrat hearts (13, 27). Activity of AMPK measured in myocardialextracts in the absence of AMP, which is a reflection of the phosphorylationstate of the kinase (34), was not altered after perfusion ofhearts in the presence of AICAR in the current study (Table 2).This finding is supported by the observation that phosphorylationof AMPK, assessed by immunoblot analysis with anti-phospho-AMPKantibodies, was not altered by AICAR (Fig. 4). This failure todetect measurable changes in AMPK activity in myocardial extractsoccurred even though the concentrations of AICAR used were comparableto or higher than those previously shown to activate AMPK in rathearts in vivo (41) and in isolated hearts from newborn rabbits(32). One potential factor that may account for the differencebetween the present and previous studies is the duration of exposureof the heart to AICAR, even though studies in skeletal musclehave shown it to be sufficient (34). In the current study, AMPKwas not measurably activated by exposure to AICAR for 15 min,a shorter duration of exposure than in investigations in whichmeasurable AMPK activity was significantly elevated in the heart(32, 41).

It is important to recognize that absence of measurable changes in AMPK activity in tissue extracts does not exclude activationof AMPK allosterically, the effects of which are not readily detectableby in vitro assay. In fact, finding that phosphorylation of ACC,which serves as a reporter of AMPK activity in the intact organor tissue (48), is increased in hearts exposed to AICAR (Fig.4) indicates that AMPK is activated by AICAR in the intact heartindependent of changes in phosphorylation, presumably by allostericmechanisms. Support for this viewpoint comes from considerationof the concentration of ZMP achieved in these experiments, whichis sufficient to increase AMPK activity (Ref. 11 and Fig. 3).Further support for this viewpoint comes from the finding thatpalmitate oxidation, an important AMPK-sensitive metabolic pathwayin the heart, is stimulated by lower concentrations of AICAR inrat hearts perfused under similar conditions (29). Moreover,fatty acid oxidation is stimulated by AICAR in skeletal musclein the absence of measurable changes in AMPK activity (24).An important corollary of this observation is that it suggeststhat AMPK is more sensitive to the allosteric effects of ZMP thanits upstream kinase,AMPKK.

The likelihood of allosteric activation of AMPK (by AICAR) notwithstanding, our data do not unequivocally rule out the possibilitythat AMPK plays a role in the control of myocardial glycogen metabolism.In fact, recent data from skeletal muscle, where AMPK activitywas increased by AICAR, suggest that AMPK phosphorylates and inactivatesglycogen synthase (50), in keeping with phosphorylation of isolatedglycogen synthase protein (10). Coupled with the fact that activationof AMPK is reported to increase intracellular glucose-6-phosphateconcentration (7, 18, 34, 50), an important allostericmodulator, our data and that of others indicate that glycogenmetabolism may be influenced by AMPK activation and changes inZMP (or AMP) in several ways (Fig. 5). Further studies, includingthose in which AMPK is substantially and measurably activated,will be required to clarify this issue in the heart.

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Fig. 5. Diagram illustrating the potential control of myocardial glycogen metabolism by ZMP and AMPK. After its formation inside the cardiac myocyte, ZMP allosterically activates glycogen phosphorylase (GP), leading to enhanced degradation of glycogen. ZMP also causes activation of AMPK, which may inhibit glycogen synthase (GS). At the same time, ZMP-induced activation of AMPK results in increased uptake of glucose and glucose-6-phosphate (G-6-P) formation and activation of GS. In the current experiments, allosteric activation of GP by ZMP was presumably the predominant effect, accounting for the acceleration of glycogenolysis observed.

The results of these experiments have important ramifications with respect to the interpretation of experiments using AICARand to the assessment of myocardial glycogen metabolism. First,it cannot be assumed that effects observed in response to AICARare necessarily attributable to persistent activation of AMPKby phosphorylation, at least in the isolated working adult ratheart. Second, assessment of downstream targets, such as phosphorylationof relevant protein(s) or fatty acid oxidation rates, is requiredto account for the fact that AMPK can be activated (by AICAR)independent of changes in phosphorylation and in a manner notdetectable in tissue extracts. Third, measurement of glycogencontent alone fails to provide an accurate assessment of glycogenmetabolism, primarily because it does not account for simultaneoussynthesis and degradation of glycogen. Conclusions based on glycogencontent alone should, therefore, be made withcaution.

	ACKNOWLEDGEMENTS

We gratefully acknowledge K. Strynadka at the Univ. of Alberta for assistance with determination of adeninenucleotides.

	FOOTNOTES

This research was supported by grants from the Canadian Institutes for Health Research and the Heart and Stroke Foundationof British Columbia andYukon.

S. L. Longnus is a Research Trainee of the Heart and Stroke Foundation of Canada. M. F. Allard is a Career Investigator ofthe Heart and Stroke Foundation of British Columbia andYukon.

Address for reprint requests and other correspondence: M. F. Allard, McDonald Research Laboratories/iCAPTUR⁴E Centre, Rm 292, St. Paul's Hospital, 1081 Burrard St., Vancouver,BC, Canada V6Z 1Y6 (E-mail: mallard{at}mrl.ubc.ca).

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.Section 1734 solely to indicate thisfact.

10.1152/ajpregu.00319.2002

Received 3 June 2002; accepted in final form 16 December 2002.

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				Y. Zang, L.-F. Yu, T. Pang, L.-P. Fang, X. Feng, T.-Q. Wen, F.-J. Nan, L.-Y. Feng, and J. Li AICAR Induces Astroglial Differentiation of Neural Stem Cells via Activating the JAK/STAT3 Pathway Independently of AMP-activated Protein Kinase J. Biol. Chem., March 7, 2008; 283(10): 6201 - 6208. [Abstract] [Full Text] [PDF]

				C. Rantzau, M. Christopher, and F. P. Alford Contrasting effects of exercise, AICAR, and increased fatty acid supply on in vivo and skeletal muscle glucose metabolism J Appl Physiol, February 1, 2008; 104(2): 363 - 370. [Abstract] [Full Text] [PDF]

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				V. W. Dolinsky and J. R. B. Dyck Role of AMP-activated protein kinase in healthy and diseased hearts Am J Physiol Heart Circ Physiol, December 1, 2006; 291(6): H2557 - H2569. [Abstract] [Full Text] [PDF]

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				R. R. Pencek, J. Shearer, R. C. Camacho, F. D. James, D. B. Lacy, P. T. Fueger, E. P. Donahue, W. Snead, and D. H. Wasserman 5-Aminoimidazole-4-Carboxamide-1-{beta}-D-Ribofuranoside Causes Acute Hepatic Insulin Resistance In Vivo Diabetes, February 1, 2005; 54(2): 355 - 360. [Abstract] [Full Text] [PDF]

5-Aminoimidazole-4-carboxamide 1--D-ribofuranoside (AICAR) stimulates myocardial glycogenolysis by allosteric mechanisms

5-Aminoimidazole-4-carboxamide 1- $beta$ -D-ribofuranoside (AICAR) stimulates myocardial glycogenolysis by allosteric mechanisms

				J. Shearer, P. T. Fueger, J. N. Rottman, D. P. Bracy, P. H. Martin, and D. H. Wasserman AMPK stimulation increases LCFA but not glucose clearance in cardiac muscle in vivo Am J Physiol Endocrinol Metab, November 1, 2004; 287(5): E871 - E877. [Abstract] [Full Text] [PDF]

				A. A. Gonzalez, R. Kumar, J. D. Mulligan, A. J. Davis, and K. W. Saupe Effects of aging on cardiac and skeletal muscle AMPK activity: basal activity, allosteric activation, and response to in vivo hypoxemia in mice Am J Physiol Regulatory Integrative Comp Physiol, November 1, 2004; 287(5): R1270 - R1275. [Abstract] [Full Text] [PDF]