Prior AICAR Stimulation Increases Insulin Sensitivity in Mouse Skeletal Muscle in an AMPK-Dependent Manner

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1 2042 Diabetes Volume 64, June 2015 Rasmus Kjøbsted, 1,2 Jonas T. Treebak, 1,2 Joachim Fentz, 1 Louise Lantier, 3,4,5 Benoit Viollet, 3,4,5 Jesper B. Birk, 1 Peter Schjerling, 6 Marie Björnholm, 7 Juleen R. Zierath, 2,7 and Jørgen F.P. Wojtaszewski 1 Prior AICAR Stimulation Increases Insulin Sensitivity in Mouse Skeletal Muscle in an AMPK-Dependent Manner Diabetes 2015;64: DOI: /db SIGNAL TRANSDUCTION An acute bout of exercise increases glucose uptake in skeletal muscle by an insulin-independent mechanism. In the period after exercise, insulin sensitivity to increased glucose uptake is enhanced. The molecular mechanisms underpinning this phenomenon are poorly understood but appear to involve an increased cell surface abundance of GLUT4. While increased proximal insulin signaling does not seem to mediate this effect, elevated phosphorylation of TBC1D4, a downstream target of both insulin (Akt) and exercise (AMPK) signaling, appears to play a role. The main purpose of this study was to determine whether AMPK activation increases skeletal muscle insulin sensitivity. We found that prior AICAR stimulation of wild-type mouse muscle increases insulin sensitivity to stimulate glucose uptake. However, this was not observed in mice with reduced or ablated AMPK activity in skeletal muscle. Furthermore, prior AICAR stimulation enhanced insulin-stimulated phosphorylation of TBC1D4 at Thr 649 and Ser 711 in wild-type muscle only. These phosphorylation events were positively correlated with glucose uptake. Our results provide evidence to support that AMPK activation is sufficient to increase skeletal muscle insulin sensitivity. Moreover, TBC1D4 phosphorylation may facilitate the effect of prior AMPK activation to enhance glucose uptake in response to insulin. The effect of insulin on skeletal muscle glucose uptake is increased in the period after a single bout of exercise. This phenomenon is observed in muscle from both humans and rodents (1 6) and may persist for up to 48 h after exercise, depending on carbohydrate availability (7 9). Improved muscle insulin sensitivity postexercise is mediated by one or several local contraction-induced mechanisms (10) involving both enhanced transport and intracellular processing of glucose. This period is characterized by increased GLUT4 protein abundance at the plasma membrane and enhanced glycogen synthase activity (11,12). These changes occur independent of global protein synthesis (13), including both total GLUT4 and glycogen synthase protein content (4,11), and are independent of changes in proximal insulin signaling, including Akt activation (3,4,13 17). AMPK is a heterotrimeric complex consisting of catalytic (a1/a2) and regulatory subunits (b1/b2 and g1/g2/g3). Of the 12 heterotrimeric combinations, only 3 and 5 combinations have been found in the skeletal muscle of human and mouse, respectively (18,19). AMPK is activated in response to various stimuli that increase cellular energy stress (e.g., metformin, hypoxia, hyperosmolarity, muscle contraction, and exercise) (20). With energy stress, intracellular concentrations of AMP and ADP accumulate. This activates AMPK allosterically and decreases the ability of upstream phosphatases to dephosphorylate Thr 172, which further increases AMPK phosphorylation and activity (21). Like exercise, AICAR increases AMPK activity in skeletal muscle (22), which partly mimics the metabolic changes observed during muscle contraction (23). TBC1D4 is involved in insulin-stimulated glucose transport in skeletal muscle (24) and is regulated via 1 Section of Molecular Physiology, August Krogh Centre, Department of Nutrition, Exercise and Sports, University of Copenhagen, Copenhagen, Denmark 2 The Novo Nordisk Foundation Center for Basic Metabolic Research, Section of Integrative Physiology, University of Copenhagen, Copenhagen, Denmark 3 INSERM, U1016, Institut Cochin, Paris, France 4 CNRS, UMR8104, Paris, France 5 Université Paris Descartes, Sorbonne Paris Cité, Paris, France 6 Institute of Sports Medicine, Department of Orthopedic Surgery, Bispebjerg Hospital and Center for Healthy Aging, Faculty of Health Sciences, University of Copenhagen, Copenhagen, Denmark 7 Integrative Physiology, Department of Molecular Medicine and Surgery, Karolinska Institutet, Stockholm, Sweden Corresponding author: Jørgen F.P. Wojtaszewski, jwojtaszewski@nexs.ku.dk. Received 11 September 2014 and accepted 20 December R.K. and J.T.T. share first authorship by the American Diabetes Association. Readers may use this article as long as the work is properly cited, the use is educational and not for profit, and the work is not altered. See accompanying article, p

2 diabetes.diabetesjournals.org Kjøbsted and Associates 2043 phosphorylation at multiple sites by Akt (25), thereby increasing translocation of GLUT4 to the plasma membrane. AMPK also targets TBC1D4; however, this does not seem to directly affect glucose uptake (26). As insulin (Akt) and exercise/aicar (AMPK) signaling pathways converge on TBC1D4, this may explain how exercise modulates insulin action to regulate glucose transport in skeletal muscle. Supporting this concept, TBC1D4 phosphorylation is elevated in skeletal muscle several hours after an acute bout of exercise in both rodents and humans, concomitant with increased insulin sensitivity to stimulate glucose uptake in the postexercise period (15,16,27 30). Prior AICAR stimulation increases skeletal muscle insulin sensitivity (13). However, because AICAR exerts multiple AMPK-independent effects (31), the direct relationship between AMPK and muscle insulin sensitivity has not been established. Thus, the primary purpose of the current study was to determine whether AMPK directly regulates skeletal muscle insulin sensitivity on glucose uptake. We established an ex vivo protocol using mouse muscle to study insulin sensitivity after prior AICAR stimulation and tested the hypothesis that AMPK is necessary for the effect of AICAR to enhance insulin sensitivity. Furthermore, we evaluated TBC1D4 phosphorylation status because this protein is a convergence point for insulin- and exercise-mediated signaling events. RESEARCH DESIGN AND METHODS Animals/Humans All experiments were approved by the Danish Animal Experimental Inspectorate and the regional animal ethics committee of Northern Stockholm and complied with the European Union Convention for the Protection of Vertebrate Animals Used for Scientific Purposes (Council of Europe 123, Strasbourg, France, 1985). Except for the wild-type (WT) mice (C57BL/6J; Taconic, Ejby, Denmark) used in Figs. 1, 3E, and 8, the animals used in this study were muscle-specific kinase-dead a 2 -AMPK (AMPK KD) (32), muscle-specific a 2 - and a 1 -AMPK double-knockout (AMPK mdko) (33), and g 3 -AMPK KO mice (34) with corresponding WT littermates used as controls. All mice in this study were female (mean weight g) and were maintained on a 12:12 light-dark cycle (6:00 A.M. to 6:00 P.M.) with unlimited access to standard rodent chow and water. Serum was obtained from healthy young men in accordance with a protocol approved by the Ethics Committee of Copenhagen (protocol #H ) and complied with the ethical guidelines of the Declaration of Helsinki II. Informed consent was obtained from all participating subjects before they entered the study. Muscle Incubations Fed animals were anesthetized by intraperitoneal injection of pentobarbital (10 mg/100 g body wt) before soleus and extensor digitorum longus (EDL) muscles were dissected and suspended in incubation chambers (Multi Wire Myograph System; DMT, Aarhus, Denmark) containing Krebs-Ringer buffer (KRB) (117 mmol/l NaCl, 4.7 mmol/l KCl, 2.5 mmol/l CaCl 2, 1.2 mmol/l KH 2 PO 4, 1.2 mmol/l MgSO 4, 0.5 mmol/l NaHCO 3, ph 7.4) supplemented with 0.1% BSA, 8 mmol/l mannitol, and 2 mmol/l pyruvate. During the entire incubation period, the buffer was oxygenated with 95% O 2 and 5% CO 2, and maintained at 30 C. After 10 min of preincubation, muscles were incubated for 50 min in the absence or presence of 1 mmol/l AICAR (Toronto Research Chemicals, Toronto, Ontario, Canada) in 100% human serum from healthy overnight-fasted men. The use of serum is necessary to elicit an effect of AICAR on muscle insulin sensitivity (13). Soleus and EDL muscles were allowed to recover in the absence of AICAR in modified KRB supplemented with 5 mmol/l glucose, 5 mmol/l mannitol, and 0.1% BSA for 4 h (soleus muscle) or 6 h (EDL muscle). During recovery, the medium was replaced once every hour to maintain an adequate glucose concentration. Subsequently, paired muscles from each animal were incubated for 30 min in KRB in the absence or presence of a submaximal concentration (100 mu/ml) of insulin (Actrapid; Novo Nordisk, Bagsvaerd, Denmark). The uptake of 2-deoxyglucose was measured during the last 10 min of the 30-min period by adding 1 mmol/l [ 3 H]2-deoxyglucose (0.056 MBq/mL) and 7 mmol/l [ 14 C]mannitol ( MBq/mL) to the incubation medium. After incubation, muscles were harvested, washed in ice-cold KRB, quickly dried on filter paper, and frozen in liquid nitrogen. Muscle Processing Muscles were homogenized in 400 ml of ice-cold buffer (10% glycerol, 20 mmol/l sodium pyrophosphate, 1% NP-40, 2 mmol/l phenylmethylsulfonyl fluoride [PMSF], 150 mmol/l sodium chloride, 50 mmol/l HEPES, 20 mmol/l b-glycerophosphate, 10 mmol/l sodium fluoride, 1 mmol/l EDTA, 1 mmol/l EGTA, 10 mg/ml aprotinin, 3 mmol/l benzamidine, 10 mg/ml leupeptin, and 2 mmol/l sodium orthovanadate, ph 7.5) for s at 30 Hz using steel beads and a TissueLyzer II (QIAGEN, Hilden, Germany). Homogenates were rotated end over end for 1 h before centrifugation at 16,000g for 20 min. The supernatant (lysate) was collected, frozen in liquid nitrogen, and stored at 280 C for later analyses. Glucose Uptake Measurements Glucose uptake was assessed by the accumulation of [ 3 H] 2-deoxyglucose in muscle with the use of [ 14 C]mannitol (PerkinElmer, Waltham, MA) as an extracellular marker. Radioactivity was measured in 250 ml of lysate by liquid scintillation counting (Ultima Gold and Tri-Carb 2910 TR; PerkinElmer) and was related to the specific activity of the incubation buffer.

3 2044 AMPK and Insulin Sensitivity in Skeletal Muscle Diabetes Volume 64, June 2015 Figure 1 Glucose uptake (A) and phospho-ampk (pampk) Thr 172 (B) in soleus and EDL muscles in response to acute AICAR stimulation (50 min, mmol/l) (n =7 8). P < 0.05 vs. control (0 mmol/l) within muscle type. C: Glucose uptake in soleus and EDL muscles after 4 and 6 h of recovery from prior AICAR treatment (50 min, 1 mmol/l), respectively (n = 8). D: Glucose uptake in EDL muscle incubated with or without insulin (100 mu/ml) 6 h after prior AICAR treatment (50 min, 1 mmol/l) (n = 24). P < 0.05 vs. basal control; *P < 0.05 vs. basal value within group; #P < 0.05 vs. response to insulin in control (interaction: insulin 3 AICAR). E: Glucose uptake in soleus muscle incubated with or without insulin (100 mu/ml) 4 h after prior AICAR stimulation (50 min, 1 mmol/l) (n = 8). *P < 0.001, main effect of insulin. Data were analyzed by one-way ANOVA (A and B), paired t test (C), or two-way repeated-measures ANOVA (D and E). Data are expressed as the means 6 SEM. F: Representative Western blot image. AU, arbitrary units; hr, hour; SOL, soleus. SDS-PAGE and Western Blot Analyses Total protein abundance in muscle lysates was determined by the bicinchoninic acid method (ThermoFisher Scientific, Waltham, MA). Muscle lysates were prepared in Laemmli buffer and heated for 10 min at 96 C. Equal amounts of protein were separated by SDS-PAGE on 5% or 7% self-cast gels and transferred to polyvinylidene fluoride membranes using semidry blotting. Membranes were blocked for 5 10 min in 2% skim milk or 3% BSA and probed with primary and secondary antibodies. Proteins with bound antibody were visualized with chemiluminescence (Millipore) using a digital imaging system (ChemiDoc MP System; Bio-Rad). All membranes were stripped with buffer (100 mmol/l 2-mecaptoethanol, 2% SDS, 62.5 mmol/l Tris-HCl, ph 6.7) and reprobed with new primary antibodies for the detection of other phosphorylation sites on identical proteins or the corresponding total proteins. The stripping procedure was verified by reincubating membranes with secondary antibodies for the detection of primary antibodies that were possibly still bound. Antibodies The following antibodies were from Cell Signaling Technology (Danvers, MA): anti phospho-ampk-thr 172 (catalog

4 diabetes.diabetesjournals.org Kjøbsted and Associates 2045 #2531), anti phospho-acetyl-coa carboxylase (ACC) Ser 79 (catalog #3661), anti-akt2 (D6G4) (catalog #3063), anti phospho-akt-thr 308 (catalog #9275), anti phospho- Akt-Ser 473 (catalog #9271), anti phospho-tbc1d1-thr 590 (catalog #6927), anti phospho-tbc1d4-ser 318 (catalog #8619), anti phospho-tbc1d4-ser 588 (#8730), and anti phospho- TBC1D4-Thr 642 (catalog #8881). Anti DYKDDDDK-Tag (FLAG-Tag) (catalog #F1804; Sigma-Aldrich), anti phospho- TBC1D1-Ser 237 (catalog # ; Millipore), anti-tbc1d1 as previously described (35), anti-as160 (TBC1D4) (catalog #07 741; Millipore), anti phospho-tbc1d4-ser 711 as previously described (26), and anti AMPK-a2 (catalog #SC-19131; Santa Cruz Biotechnology). The antibodies used for AMPK activity measurements were anti AMPKg3, anti AMPK-a1, and anti AMPK-a2, all of which were provided by Professor D.G. Hardie (University of Dundee, Dundee, Scotland, U.K.). AMPK Activity Assay Five different AMPK trimer complexes have been detected in mouse skeletal muscle: a2b2g3, a2b1g1, a2b2g1, a1b1g1, and a1b2g1 (19). a2b2g3-ampk activity was measured on g3-ampk immunoprecipitates (IPs) from 300 mg of muscle lysate using AMPK-g3 antibody, G-protein coupled agarose beads (Millipore) and IP buffer (50 mmol/l NaCl, 1% Triton X-100, 50 mmol/l sodium fluoride, 5 mmol/l sodium-pyrophosphate, 20 mmol/l Trisbase, ph 7.5, 500 mmol/l PMSF, 2 mmol/l dithiothreitol, 4 mg/ml leupeptin, 50 mg/ml soybean trypsin inhibitor, 6 mmol/l benzamidine, and 250 mmol/l sucrose). Samples were treated as previously described (19,36). In short, after overnight end-over-end rotation at 4 C, IPs were centrifuged for 1 min at 2,000g and washed once in IP buffer, once in 63 assay buffer (240 mmol/l HEPES, 480 mmol/l NaCl, ph 7.0), and twice in 33 assay buffer (1:1). The activity assay was performed for 30 min at 30 C in a total volume of 30 ml of kinase mix (40 mmol/l HEPES, 80 mmol/l NaCl, 833 mmol/l dithiothreitol, 200 mmol/l AMP, 100 mmol/l AMARA peptide, 5 mmol/l MgCl 2, 200 mmol/l ATP, and 2 mci of [g-33p]-atp; PerkinElmer). The reaction was terminated by adding 10 ml of1%phosphoric acid. Twenty microliters of the reaction mix were spotted on P81 filter paper. Filter papers were subsequently washed min in 1% phosphoric acid. 33P radioactivity was analyzed on dried filter paper using a Storm 850 PhosphorImager (Molecular Dynamics). The combined activity of a2b1g1 and a2b2g1 was measured on supernatants from the g3-ampk IPs using the AMPK-a2 antibody for a second IP, and the combined activity of a1b1g1 and a1b2g1 was measured on supernatants from the a2-ampk IPs using a1-ampk antibody for a third IP. In Vivo Gene Electrotransfer TBC1D4 WT and TBC1D4 T649A and S711A DNA mutant constructs, containing T-to-A and S-to-A point mutations, respectively, were commercially and individually synthesized from the gene encoding mouse TBC1D4 (GeneArt; Life Technologies, Darmstadt, Germany). All three constructs were subsequently subcloned into a p3xflag-cmv-9 10 vector using NotI and KpnI cloning sites before amplification in Escherichia coli TOP10 cells (Invitrogen). Plasmid DNA was extracted using an endotoxin-free Plasmid Mega Kit (QIAGEN) and was diluted in isotonic saline solution to a final concentration of 2 mg/ml. DNA (50 mg) was injected into the tibialis anterior muscle 2 h after treatment with hyaluronidase (Sigma-Aldrich) (one injection of 30 units/muscle, 1 unit/ml), and gene electrotransfer was performed as previously described (24). Seven days after gene electrotransfer, phosphorylation of TBC1D4 Thr 649 and Ser 711 was assessed in the tibialis anterior muscle of anesthetized (8 mg pentobarbital/100 g body wt) animals in response to retro-orbital injection of either saline solution or insulin (10 units/kg). Ten minutes after injection, the tibialis anterior muscle was removed, quickly frozen in liquid nitrogen, and stored at 280 C for subsequent analysis. Statistics Statistical analyses were performed using SigmaPlot version 11.0 (SYSTAT, Erkrath, Germany) and SPSS version 20 (IBM) software. SPSS version 20 was used for three-way ANOVA with repeated measures, while all other analyses were performed using SigmaPlot version Data are presented as the mean 6 SEM. One-, two-, or three-way ANOVAs with or without repeated measures was used to assess statistical differences, where appropriate. When a three-way interaction occurred (P, 0.05; genotype 3 AICAR 3 insulin), a two-way ANOVA with repeated measures was used on each genotype (WT and KD or WT and mdko) in order to determine the site of interaction between AICAR and insulin (P, 0.05; AICAR 3 insulin). Any main effects of genotype are included in the figure legends. For post hoc testing, a Student-Newman-Keuls test was used. Correlation analyses were performed by determination of Pearson product moment correlation coefficient. Differences were considered statistically significant at P, RESULTS Prior AICAR Stimulation Increases Insulin Sensitivity in EDL Muscle but Not in Soleus Muscle Acute AICAR stimulation increased glucose uptake and AMPK phosphorylation in both soleus and EDL muscles (Fig. 1A, B, andf). We then determined the time point at which glucose uptake had reversed to basal levels in order to evaluate the effect of AICAR on insulin sensitivity. In WT soleus and EDL muscle, glucose uptake reversed to basal levels after 4 and 6 h of recovery from AICAR stimulation, respectively (Fig. 1C). Prior AICAR treatment increased the effect of a submaximal insulin concentration (100 mu/ml) to stimulate glucose uptake in the EDL muscle, but not in the soleus muscle of WT mice (Fig. 1D and E). Based on these results, we chose to use only EDL muscle for subsequent experiments.

5 2046 AMPK and Insulin Sensitivity in Skeletal Muscle Diabetes Volume 64, June 2015 Prior AICAR Stimulation Increases Muscle Insulin Sensitivity in an AMPK-Dependent Manner In order to clarify whether the effect of AICAR on insulin sensitivity is dependent on AMPK, we took advantage of the AMPK KD and AMPK mdko mouse models in which AMPK activity is decreased or ablated in skeletal muscle. Prior AICAR stimulation increased insulin sensitivity in isolated EDL muscle from WT littermates but failed to increase insulin sensitivity in both transgenic models (Fig. 2A and B). The incremental increase in insulin-stimulated glucose uptake (glucose uptake with insulin minus basal glucose uptake) was significantly higher after prior AICAR stimulation in WT littermates only (Fig. 2C and D). AMPK Activity and Signaling As AICAR acutely increases phosphorylation of AMPK and the downstream target ACC, we investigated whether this effect was maintained into recovery. Phosphorylation of AMPK and ACC was increased in EDL muscle previously stimulated with AICAR independent of genotype (Fig. 3A D, H, andi). We assume that the observed increase in ACC phosphorylation in muscle from both transgenic mouse models after prior AICAR treatment corresponds to AMPK-independent effects of AICAR on ACC phosphorylation or AMPK activation in nonmuscle cells. However, prior AICAR treatment increased ACC phosphorylation to a greater extent in muscle from WT littermates than in muscle from both transgenic models (although the increase was significant only in WT mice from the mdko model), indicating a maintained effect of prior AICAR stimulation on AMPK in muscle cells. Therefore, we measured AMPK activity in WT EDL muscle that had been previously stimulated with AICAR. The combined activity of a1b1g1 and a1b2g1 was;1.4-fold higher compared with unstimulated control muscle (P = 0.037), while a2b2g3 activity was ;2.3-fold higher (P, 0.001) (Fig. 3E). In contrast, the combined activity of AMPK trimer complexes a2b2g1 and a2b1g1 was unchanged by prior AICAR treatment. This indicates a persistent effect of prior AICAR stimulation on specific AMPK trimer activity in particular a2b2g3 activity. Prior AICAR Stimulation Increases Muscle Insulin Sensitivity in an AMPK-g3 Dependent Manner A persistent increase in AMPK a2b2g3 activity after AICAR stimulation prompted us to test the hypothesis that the effect of AICAR to enhance muscle insulin sensitivity is mediated through the AMPK a2b2g3 trimer complex. Indeed, prior AICAR stimulation failed to increase muscle insulin sensitivity in whole-body g 3 -AMPK KO mice (Fig. 3F and G). For unknown reasons, prior AICAR Figure 2 Glucoseuptake(A and B) ord glucose uptake (insulin minus basal) (C and D) in EDL muscle from either AMPK KD mice (A and C)orAMPKmdKOmice(B and D) and corresponding WT littermates incubated with or without insulin (100 mu/ml) 6 h after prior AICAR treatment (50 min, 1 mmol/l) (KD n =9 10, mdko n = 12). Data are expressed as the means 6 SEM. A: AICAR3 insulin 3 genotype interaction (P < 0.001). *P < 0.05 vs. basal value within genotype; #P < vs. response to insulin in WT control mice (interaction AICAR 3 insulin). B: AICAR3 insulin 3 genotype interaction (P < 0.05). *P < vs. basal value within genotype; #P < vs. response to insulin in WT control (interaction AICAR 3 Insulin). C: Data are extracted from the raw data given in A. P < vs. control within genotype. D: Data are extracted from the raw data given in B. P < 0.05 vs. control within genotype. hr, hour.

6 diabetes.diabetesjournals.org Kjøbsted and Associates 2047 Figure 3 Phospho-AMPK (pampk) Thr 172 (A and C) and phospho-acc (pacc) Ser 212 (B and D) in EDL muscle from either AMPK KD mice (A and B) or AMPK mdko mice (C and D) and corresponding WT littermates incubated with or without insulin (100 mu/ml) 6 h after prior AICAR treatment (50 min, 1 mmol/l) (KD n =9 10, mdko n = 12). AMPK trimer specific activity in EDL muscle from C57BL/6J mice incubated with or without insulin (100 mu/ml) 6 h after prior AICAR treatment (50 min, 1 mmol/l) (N =4 6) (E). Glucose uptake (F) ord insulin-stimulated glucose uptake (insulin minus basal) (G) in EDL muscle from g 3 -AMPK KO mice and corresponding WT littermates incubated with or without insulin (100 mu/ml) 6 h after prior AICAR treatment (50 min, 1 mmol/l) (n =6 8). Data are expressed as the means 6 SEM. A: Main effect of AICAR (P < 0.05). Main effect of genotype (P < 0.001). B: Main effect of AICAR (P < 0.01). Main effect of genotype (P < 0.001). C: AICAR 3 insulin 3 genotype interaction (P < 0.001). P < vs. control within genotype; #P < vs. response to AICAR in WT basal (interaction AICAR 3 insulin). D: P < 0.01 vs. control value within genotype; P < vs. response in

7 2048 AMPK and Insulin Sensitivity in Skeletal Muscle Diabetes Volume 64, June 2015 treatment still affected basal glucose uptake in WT littermates in this particular experiment, suggesting that the acute effect of AICAR on glucose uptake was not fully reversed. Akt Signaling Prior AICAR stimulation potentially enhances muscle insulin sensitivity to stimulate glucose uptake by regulating proximal insulin-signaling proteins. To investigate this, we measured the phosphorylation of Akt Thr 308 and Ser 473. Insulin did not further increase the phosphorylation of Thr 308 and Ser 473 in muscle previously stimulated with AICAR compared with control muscle (Fig. 4A F). TBC1D1 Signaling TBC1D1 is a closely related paralog of TBC1D4 that is regulated by both AMPK and Akt, and regulates glucose transport (37 40). As AMPK increases the phosphorylation of TBC1D1 Ser 231 in response to contraction and AICAR, and as Akt increases the phosphorylation of Thr 590 in response to insulin, we investigated whether changes in TBC1D1 phosphorylation occurred in parallel with the increase in muscle insulin sensitivity after prior AICAR stimulation. Phosphorylation of TBC1D1 Ser 231 was markedly increased in WT muscle previously stimulated with AICAR. Prior AICAR stimulation also modestly increased the phosphorylation of TBC1D1 Ser 231 in muscle from AMPK KD and mdko mice (Fig. 5A, B, E, and F). Furthermore, insulin increased the phosphorylation of TBC1D1 Thr 590 in both mouse models independent of genotype (Fig. 5C F). However, in AMPK mdko mice and WT littermates, insulin-stimulated phosphorylation of TBC1D1 Thr 590 in prior AICAR-stimulated muscle was decreased compared with control muscle (Fig. 5D). TBC1D4 Signaling TBC1D4 (like TBC1D1) has been identified as a substrate of both AMPK and Akt in skeletal muscle (25,26), and the phosphorylation of TBC1D4 is critical for insulinstimulated glucose uptake (24,41). In addition, TBC1D4 is phosphorylated at multiple sites in the postexercise period in parallel with enhanced muscle insulin sensitivity (15,16,27 30). This indicates that the regulation of muscle insulin sensitivity is linked to TBC1D4 phosphorylation. We found an increased effect of insulin on TBC1D4 Thr 649 and Ser 711 phosphorylation in muscle previously stimulated with AICAR compared with control muscle (Fig. 6A D, I, and J). Furthermore, this effect was dependent on AMPK, because no difference in insulin-mediated phosphorylation was observed between control and prior AICAR-stimulated muscle from either of the two AMPK transgenic models. Importantly, the effect of prior AICAR treatment was site specific, as insulin-stimulated phosphorylation of TBC1D4 Ser 324 and Ser 595 was unaffected (Fig. 6E J) Glucose Uptake Correlates With TBC1D4 Site-Specific Phosphorylation Levels To investigate whether AICAR/AMPK increases muscle insulin sensitivity through TBC1D4, we performed a correlation analysis between D values (insulin minus basal) on muscle glucose uptake and TBC1D4 phosphorylation. We found that glucose uptake and phosphorylation of TBC1D4 Ser 711 was positively correlated in WT littermates from both AMPK mouse models (P, and P, 0.01; Fig. 7A and B, respectively). Correlating data for glucose uptake and phosphorylation of TBC1D4 Thr 649 revealed a more scattered pattern that was positively correlated in WT littermates from the AMPK KD strain (P, 0.01; Fig. 7C), but was not correlated in WT littermates from the AMPK mdko strain (P = 0.18; Fig. 7D). In addition, the phosphorylation levels of TBC1D4 Thr 649 and Ser 711 were positively and strongly correlated in WT littermates from both AMPK mouse models (P, 0.001; Fig. 7E and F). Phosphorylation Levels of TBC1D4 Thr 649 and Ser 711 May Be Causally Linked AMPK has been shown to regulate the phosphorylation of TBC1D4 Ser 711, and in muscle overexpressing a 4P mutant of TBC1D4 (in which Ser 711 is not mutated) the phosphorylation of Ser 711 is severely blunted (26). In order to investigate whether changes in phosphorylation level of TBC1D4 Ser 711 affect TBC1D4 Thr 649 phosphorylation and vice versa, TBC1D4-WT, TBC1D4-S711A, and TBC1D4-T649A constructs were expressed in mouse tibialis anterior muscle by gene electrotransfer. Insulin increased the phosphorylation of TBC1D4 Thr 649 in muscle expressing TBC1D4-WT or TBC1D4-S711A, but Thr 649 phosphorylation levels were significantly blunted in the latter (Fig. 8A and C). Insulin increased the phosphorylation of TBC1D4 Ser 711 in muscle expressing TBC1D4-WT, and this response was completely ablated in muscle expressing TBC1D4-T649A (Fig. 8B and C). Our results suggest that the phosphorylation levels of TBC1D4 Thr 649 and Ser 711 are mutually dependent on each other. DISCUSSION Several lines of evidence imply that AMPK activation regulates skeletal muscle insulin sensitivity. In C 2 C 12 myotubes, AICAR stimulation or hyperosmotic stress increases insulin sensitivity, which is inhibited by the WT (interaction genotype 3 AICAR). E: Effect of AICAR within group (P < 0.001). F: AICAR 3 insulin 3 genotype interaction (P < 0.05). *P < vs. basal values within genotype; #P < 0.05 vs. response to insulin in WT control (interaction AICAR 3 insulin); P < control vs. AICAR. G: Data are extracted from the raw data given in F. P < vs. control within genotype. H and I: Representative Western blot images from AMPK KD and mdko studies, respectively. AU, arbitrary units; hr, hour; IB, immunoblotting.

8 diabetes.diabetesjournals.org Kjøbsted and Associates 2049 Figure 4 Phospho-Akt (pakt) Thr 308 /Akt2 protein (A and B) and pakt Ser 473 /Akt2 protein (C and D) in EDL muscle from either AMPK KD mice (A and C) or AMPK mdko mice (B and D) and corresponding WT littermates incubated with or without insulin (100 mu/ml) 6 h after prior AICAR treatment (50 min, 1 mmol/l) (KD n =9 10, mdko n = 12). Data are expressed as the means 6 SEM. A: *Effect of insulin (P < 0.001). B: *Effect of insulin (P < 0.001). Main effect of AICAR (P = 0.048). Main effect of genotype (P < 0.001). C: *P < vs. basal; #P < 0.05 vs. response to insulin in control (interaction insulin 3 AICAR). Main effect of genotype (P =0.033).D: *Effect of insulin (P < 0.001); P < vs. response to insulin in WT (interaction insulin 3 genotype); genotype 3 AICAR interaction (P =0.034).E and F: Representative Western blot images from AMPK KD and mdko mouse studies, respectively. AU, arbitrary units; IB, immunoblotting. unspecific AMPK inhibitor compound C (42). Similarly, insulin sensitivity is increased in myotubes transfected with a constitutive active form of AMPKa, which is also suppressed by compound C (43). Furthermore, AICAR fails to increase insulin action in cells transfected with a dominant-negative form of AMPKa (43). Collectively, our data and those obtained in cell culture systems (42,43) suggest that AMPK plays an important role in mediating AICAR-induced increases in skeletal muscle insulin sensitivity to stimulate glucose transport. AICARistakenupbythecell,whereitactsasanAMP mimetic, thus potentially affecting multiple proteins regulated by AMP. Within recent years, an increased number of AMPK-independent effects of AICAR have been described together with reports identifying AICAR as a modulator of enzymes such as glycogen phosphorylase, glucokinase, and phosphofructokinase (31). However, because AICAR did not increase insulin sensitivity in muscle from AMPK KD or mdko mice, any possible AMPK-independent effect of AICAR does not seem to account for changes in glucose uptake in response to insulin. The improved insulin-stimulated glucose uptake in muscle previously stimulated with AICAR occurred independently of changes in proximal insulin signaling (Akt phosphorylation). This is consistent with earlier findings showing that prior AICAR treatment does not increase either Akt phosphorylation or phosphoinositide-3 kinase activity in rat skeletal muscle (13). Similar observations have been made in both human and rodent skeletal muscle

9 2050 AMPK and Insulin Sensitivity in Skeletal Muscle Diabetes Volume 64, June 2015 Figure 5 Phospho-TBC1D1 (ptbc1d1) Ser 231 /TBC1D1 protein (A and B) and ptbc1d1 Thr 590 /TBC1D1 protein (C and D) in EDL muscle from either AMPK KD mice (A and C) or AMPK mdko mice (B and D) and corresponding WT littermates incubated with or without insulin (100 mu/ml) 6 h after prior AICAR treatment (50 min, 1 mmol/l) (KD n =9 10, mdko n = 12). Data are expressed as the means 6 SEM. A: P < vs. control value within genotype; genotype 3 AICAR interaction (P < 0.01). B: P < vs. control value within genotype; genotype 3 AICAR interaction (P = 0.001); #insulin 3 AICAR interaction (P =0.041).C: *Effect of insulin (P < 0.001). Main effect of genotype (P < 0.001). D: *P < vs. basal; #P < vs. response to insulin in control (interaction insulin 3 AICAR). E and F: Representative Western blot images from AMPK KD and mdko studies, respectively. AU, arbitrary units; IB, immunoblotting. after an acute bout of exercise (3,4,13,16,17). Based on this, the mechanism responsible for the AMPK-dependent increase in muscle insulin sensitivity likely involves signal transduction downstream of Akt, implicating a role for TBC1D1 or TBC1D4. We evaluated the phosphorylation status of key sites on TBC1D1 previously shown to increase in response to AICAR, muscle contraction, exercise, or insulin (16,37,44,45). Phosphorylation of TBC1D1 Ser 231 was markedly increased in muscle from WT mice, and only modestly increased in muscle from AMPK KD and mdko mice 6 h after AICAR treatment. Conversely, phosphorylation of TBC1D1 Thr 590 was increased in response to insulin independent of genotype. Given that prior AICAR stimulation increased the phosphorylation of TBC1D1 Ser 231 in both basal and insulin-stimulated muscle, and insulin increased the phosphorylation of TBC1D1 Thr 590 in all groups, our results suggest that the phosphorylation of TBC1D1 Ser 231 and Thr 590 is not sufficient for regulating muscle insulin sensitivity in response to prior AICAR treatment. This is supported by findings of identical TBC1D1 Ser 231 phosphorylation, and similar increases in insulin-stimulated PAS-TBC1D1 and Ser 590 phosphorylation in previously rested or exercised muscle from humans and rats (15,16,29). In addition to TBC1D1, we also analyzed the phosphorylation status of TBC1D4 at multiple sites because it has been suggested to play a prominent role in regulating

10 diabetes.diabetesjournals.org Kjøbsted and Associates 2051 Figure 6 Phospho-TBC1D4 (ptbc1d4) Thr 649 /TBC1D4 protein (A and B), ptbc1d4 Ser 711 /TBC1D4 protein (C and D), ptbc1d4 Ser 324 / TBC1D4 protein (E and F), and ptbc1d4 Ser 595 /TBC1D4 protein (G and H) in EDL muscle from either AMPK KD mice (A, C, E, and G) or AMPK mdko mice (B, D, F, and H) and corresponding WT littermates incubated with or without insulin (100 mu/ml) 6 h after prior AICAR treatment (50 min, 1 mmol/l) (KD n =8 10, mdko n = 12). Data are expressed as the mean 6 SEM. A: AICAR 3 insulin 3 genotype interaction (P < 0.05). *P < 0.05 vs. basal value within genotype; #P < 0.05 vs. response to insulin in WT control (interaction AICAR 3 insulin). B: AICAR 3 insulin 3 genotype interaction (P < 0.001). *P < 0.05 vs. basal value within genotype; #P < vs. response to insulin in WT control (interaction AICAR 3 insulin); effect of AICAR within basal (P < 0.001). C: AICAR 3 insulin 3 genotype interaction (P < 0.01). *P < vs. basal value within genotype; #P < vs. response to insulin in WT control (interaction AICAR 3 insulin); effect of AICAR within basal (P < 0.05). D: AICAR 3 insulin 3 genotype interaction (P < 0.05). *P < 0.05 vs. basal value within genotype; #P < vs. response to insulin in WT control (interaction AICAR 3 insulin); borderline effect of AICAR within basal (P = 0.05). E: *Effect of insulin (P < 0.001). Main effect of genotype (P < 0.01). F and G: *Effect of insulin (P < 0.001). H: *Effect of insulin (P < 0.001); P < 0.05 vs. response to insulin in WT (interaction insulin 3 genotype). I and J: Representative Western blot images from AMPK KD and mdko studies, respectively. AU, arbitrary units; IB, immunoblotting.

11 2052 AMPK and Insulin Sensitivity in Skeletal Muscle Diabetes Volume 64, June 2015 Figure 7 A and B: Pearson correlations between the D insulin value (insulin minus basal) on glucose uptake and phospho-tbc1d4 (ptbc1d4) Ser 711 in WT littermates from KD and mdko mice, respectively. C and D: Pearson correlations between D insulin value (insulin minus basal) on glucose uptake and ptbc1d4 Thr 649 in WT littermates from KD and mdko mice, respectively. E and F: Pearson correlations between D insulin value (insulin minus basal) on ptbc1d4 Thr 649 and Ser 711 in WT littermates from KD and mdko mice, respectively. Sample size is n = R 2 and significance level are indicated in the respective panel. To visualize any bias due to grouping effect (control and prior AICAR treatment), we also provide Pearson correlations (dashed lines) based on data from the individual groups. Control, open symbols; prior AICAR treatment, closed symbols. AU, arbitrary units; hr, hour. both insulin-stimulated glucose uptake and insulin action in skeletal muscle after exercise (24,27 29). Recent studies (26,44), using site-specific antibodies, suggest that only the phosphorylation of TBC1D4 Ser 711 is increased in mouse skeletal muscle in response to exercise, AICAR, or ex vivo muscle contraction. Because AICAR-mediated phosphorylation of TBC1D4 Ser 711 is dependent on AMPK (26), the AMPK-dependent increase in insulin sensitivity after AICAR treatment may be mediated through changes in TBC1D4 Ser 711 phosphorylation during acute AICAR stimulation. Our data showing increased insulin action on Ser 711 phosphorylation in WT mouse muscle but not in AMPK KD or mdko mouse muscle previously stimulated with AICAR are consistent with this notion. In contrast with TBC1D4 Ser 711, the phosphorylation of Thr 649 seems to be important for insulin-stimulated glucose uptake in mouse EDL muscle (26,41). However, this site is not regulated by acute AICAR treatment (26,46). Thus, the potentiated effect of insulin on TBC1D4 Ser 711 phosphorylation by prior AICAR treatment appears to mediate an enhanced AMPK-dependent phosphorylation of Thr 649, which may facilitate the

12 diabetes.diabetesjournals.org Kjøbsted and Associates 2053 Figure 8 Phosphorylation level of TBC1D4 Thr 649 (A) and Ser 711 (B) in the tibialis anterior muscle in response to retro-orbital injection of saline solution or insulin (10 units/kg, 10 min) 7 days after muscle gene electrotransfer of TBC1D4-WT, TBC1D4-T649A, and TBC1D4-S711A. The top bands in the phospho-tbc1d4 (ptbc1d4) Ser 711 blot are unspecific and do not represent actual TBC1D4 protein. Total flag-tagged TBC1D4 protein indicates the expression level of the three constructs (n = 4 6). Data are expressed as the mean 6 SEM. A and B: *Effect of insulin within group (P < 0.05); #P < 0.05 vs. WT. C: Representative Western blot image. AU, arbitrary units; N.D, not detected. increased effect of insulin on glucose uptake. Such a relationship is supported by the correlative relationship between TBC1D4 Thr 649 and Ser 711 phosphorylation, and in particular by the strong relationship between Ser 711 phosphorylation and muscle glucose uptake. In addition, the expression of the S711A TBC1D4 mutant decreased the total phosphorylation of TBC1D4 Thr 649, whereas the T649A mutant severely decreased the phosphorylation of Ser 711 both in the presence or absence of insulin. This clearly indicates interdependence between the two sites and supports a possible mechanism by which AMPK, through TBC1D4 Ser 711, regulates insulin action to stimulate glucose uptake. Previously, it has been shown (47) that discrepancies between Akt and TBC1D4 phosphorylation exist, indicating that only a small fraction of the insulin signal is necessary for mediating full glucose uptake in response to insulin. This is also observed in the current study where phosphorylation of Akt Ser 308 and Thr 473 does not match either phosphorylation of TBC1D4 Thr 649 and Ser 711 or glucose uptake in prior AICAR-stimulated WT muscle. However, in cases of normal (and perhaps increased) insulin sensitivity there seems to be a good correlation between plasma membrane GLUT4 and TBC1D4 phosphorylation (47). This indicates that glucose uptake and phosphorylation of TBC1D4 are associated, as also indicated by the correlations in the current study. Besides a change in TBC1D4 phosphorylation, it has been demonstrated that AICAR enhances insulin action in muscle cells by decreasing membrane cholesterol levels in an AMPK-dependent manner (48). This seems plausible since AMPK has been shown to decrease the activity of 3-hydroxy-3-methylglutaryl CoA reductase, the rate-limiting enzyme in cholesterol synthesis (49). We did not measure membrane cholesterol levels, and therefore we cannot rule out that muscle insulin sensitivity after prior AICAR stimulation was affected by a change in membrane cholesterol content. The enhanced insulin-stimulated glucose uptake after AICAR treatment seems to be dependent on a persistent increase in muscle g 3 -AMPK activity, as evidenced by AMPK activity measurements and insulin-stimulated glucose uptake in g 3 -AMPK KO mice. Furthermore, prior AICAR stimulation failed to increase insulin sensitivity in mouse soleus muscle in which the a2b2g3 complex represents,2% of all AMPK trimer complexes (19). In both human vastus lateralis muscle (18) and mouse EDL muscle (19), the AMPK a2b2g3 trimer complex accounts for one-fifth of all AMPK complexes (36). Of interest, AMPK-g3 protein level is markedly decreased in skeletal muscle from trained humans (50), although insulin sensitivity in general is increased. Conversely, enhanced muscle insulin sensitivity after an acute bout of exercise seems to be lost in the trained state (51). Collectively, these results suggest that prior AICAR stimulation mimics the effect of exercise to enhance skeletal muscle insulin sensitivity, possibly through an AMPK-g3 dependent mechanism. In conclusion, prior AICAR stimulation is sufficient to enhance muscle insulin sensitivity. We provide evidence that this effect is likely mediated through AMPK signaling, as AICAR failed to increase insulin sensitivity in skeletal muscle in which AMPK activity was blunted. Although we observed no change in proximal insulin-signaling events, the enhanced insulin-stimulated glucose uptake observed after prior AICAR stimulation was associated and positively correlated with increased TBC1D4 Thr 649 and Ser 711 phosphorylation. This supports the idea that

13 2054 AMPK and Insulin Sensitivity in Skeletal Muscle Diabetes Volume 64, June 2015 prior activation of AMPK primes a pool of TBC1D4 to potentiate a subsequent effect of insulin to increase GLUT4 translocation to the cell surface and enhance glucose uptake. At present, we have not succeeded in establishing a mouse model for studying insulin sensitivity after prior muscle contraction. Therefore, future studies have to determine whether AMPK is also important for the enhanced insulin action after this intervention. Because TBC1D4 signaling by insulin is potentiated after exercise in both human and rat skeletal muscle (15,16,29,30,52), our hypothesis is that the exerciseinduced increase in insulin sensitivity is also regulated via an AMPK-TBC1D4 signaling axis. Acknowledgments. The authors thank Ann-Marie Petterson, Integrative Physiology Group, Department of Molecular Medicine and Surgery, Karolinska Institutet, Stockholm, Sweden, for her assistance. The authors also thank D.G. Hardie (Division of Molecular Physiology, College of Life Sciences, University of Dundee, Scotland, U.K.) and L.J. Goodyear (Joslin Diabetes Center and Harvard Medical School, Boston, MA) for the donation of antibodies. Funding. This work was carried out as a part of the research programs Physical Activity and Nutrition for Improvement of Health funded by the University of Copenhagen Excellence Program for Interdisciplinary Research and the UNIK project Food, Fitness & Pharma for Health and Disease (see which was supported by the Danish Ministry of Science, Technology and Innovation, and by the Novo Nordisk Foundation Center for Basic Metabolic Research. The Novo Nordisk Foundation Center for Basic Metabolic Research is an independent Research Center at the University of Copenhagen that is partially funded by an unrestricted donation from the Novo Nordisk Foundation ( This study was also funded by the Danish Council for Independent Research Medical Sciences, the Novo Nordisk Foundation, and the Lundbeck Foundation. J.T.T. was supported by a postdoctoral fellowship from the Danish Agency for Science, Technology and Innovation. Duality of Interest. No potential conflicts of interest relevant to this article were reported. Author Contributions. R.K. helped to conceive of and design the research, perform the experiments and analysis, and draft the manuscript. J.T.T. and J.F.P.W. helped to conceive of and design the research and draft the manuscript. J.F. helped to perform the experiments. L.L., B.V., J.B.B., P.S., and M.B. helped to perform the analysis. All authors interpreted the results, edited and revised the manuscript, and read and approved the final version of the manuscript. J.F.P.W. is the guarantor of this work and, as such, had full access to all the data in the study and takes responsibility for the integrity of the data and the accuracy of the data analysis. References 1. Richter EA, Garetto LP, Goodman MN, Ruderman NB. Muscle glucose metabolism following exercise in the rat: increased sensitivity to insulin. J Clin Invest 1982;69: Richter EA, Mikines KJ, Galbo H, Kiens B. Effect of exercise on insulin action in human skeletal muscle. J Appl Physiol (1985) 1989;66: Wojtaszewski JF, Hansen BF, Kiens B, Richter EA. Insulin signaling in human skeletal muscle: time course and effect of exercise. Diabetes 1997;46: Wojtaszewski JF, Hansen BF, Gade, et al. Insulin signaling and insulin sensitivity after exercise in human skeletal muscle. Diabetes 2000;49: Cartee GD, Holloszy JO. Exercise increases susceptibility of muscle glucose transport to activation by various stimuli. Am J Physiol 1990;258:E390 E Frøsig C, Rose AJ, Treebak JT, Kiens B, Richter EA, Wojtaszewski JFP. Effects of endurance exercise training on insulin signaling in human skeletal muscle: interactions at the level of phosphatidylinositol 3-kinase, Akt, and AS160. Diabetes 2007;56: Cartee GD, Young DA, Sleeper MD, Zierath J, Wallberg-Henriksson H, Holloszy JO. Prolonged increase in insulin-stimulated glucose transport in muscle after exercise. Am J Physiol 1989;256:E494 E Mikines KJ, Sonne B, Farrell PA, Tronier B, Galbo H. Effect of physical exercise on sensitivity and responsiveness to insulin in humans. Am J Physiol 1988;254:E248 E Gulve EA, Cartee GD, Zierath JR, Corpus VM, Holloszy JO. Reversal of enhanced muscle glucose transport after exercise: roles of insulin and glucose. Am J Physiol 1990;259:E685 E Richter EA, Garetto LP, Goodman MN, Ruderman NB. Enhanced muscle glucose metabolism after exercise: modulation by local factors. Am J Physiol 1984;246:E476 E Hansen PA, Nolte LA, Chen MM, Holloszy JO. Increased GLUT-4 translocation mediates enhanced insulin sensitivity of muscle glucose transport after exercise. J Appl Physiol (1985) 1998;85: Bogardus C, Thuillez P, Ravussin E, Vasquez B, Narimiga M, Azhar S. Effect of muscle glycogen depletion on in vivo insulin action in man. J Clin Invest 1983; 72: Fisher JS, Gao J, Han DH, Holloszy JO, Nolte LA. Activation of AMP kinase enhances sensitivity of muscle glucose transport to insulin. Am J Physiol Endocrinol Metab 2002;282:E18 E Bonen A, Tan MH, Watson-Wright WM. Effects of exercise on insulin binding and glucose metabolism in muscle. Can J Physiol Pharmacol 1984;62: Funai K, Schweitzer GG, Sharma N, Kanzaki M, Cartee GD. Increased AS160 phosphorylation, but not TBC1D1 phosphorylation, with increased postexercise insulin sensitivity in rat skeletal muscle. Am J Physiol Endocrinol Metab 2009; 297:E242 E Funai K, Schweitzer GG, Castorena CM, Kanzaki M, Cartee GD. In vivo exercise followed by in vitro contraction additively elevates subsequent insulinstimulated glucose transport by rat skeletal muscle. Am J Physiol Endocrinol Metab 2010;298:E999 E Hamada T, Arias EB, Cartee GD. Increased submaximal insulin-stimulated glucose uptake in mouse skeletal muscle after treadmill exercise. J Appl Physiol (1985) 2006;101: Wojtaszewski JF, Birk JB, Frøsig C, Holten M, Pilegaard H, Dela F. 5 AMP activated protein kinase expression in human skeletal muscle: effects of strength training and type 2 diabetes. J Physiol 2005;564: Treebak JT, Birk JB, Hansen BF, Olsen GS, Wojtaszewski JFP. A activates AMPK beta1-containing complexes but induces glucose uptake through a PI3-kinase-dependent pathway in mouse skeletal muscle. Am J Physiol Cell Physiol 2009;297:C1041 C Kahn BB, Alquier T, Carling D, Hardie DG. AMP-activated protein kinase: ancient energy gauge provides clues to modern understanding of metabolism. Cell Metab 2005;1: Hardie DG, Ashford MLJ. AMPK: regulating energy balance at the cellular and whole body levels. Physiology (Bethesda) 2014;29: Merrill GF, Kurth EJ, Hardie DG, Winder WW. AICA riboside increases AMPactivated protein kinase, fatty acid oxidation, and glucose uptake in rat muscle. Am J Physiol 1997;273:E1107 E Miyamoto L, Egawa T, Oshima R, et al. AICAR stimulation metabolome widely mimics electrical contraction in isolated rat epitrochlearis muscle. Am J Physiol Cell Physiol 2013;305:C1214 C Kramer HF, Witczak CA, Taylor EB, Fujii N, Hirshman MF, Goodyear LJ. AS160 regulates insulin- and contraction-stimulated glucose uptake in mouse skeletal muscle. J Biol Chem 2006;281: Kramer HF, Witczak CA, Fujii N, et al. Distinct signals regulate AS160 phosphorylation in response to insulin, AICAR, and contraction in mouse skeletal muscle. Diabetes 2006;55:

14 diabetes.diabetesjournals.org Kjøbsted and Associates Treebak JT, Taylor EB, Witczak CA, et al. Identification of a novel phosphorylation site on TBC1D4 regulated by AMP-activated protein kinase in skeletal muscle. Am J Physiol Cell Physiol 2010;298:C377 C Arias EB, Kim J, Funai K, Cartee GD. Prior exercise increases phosphorylation of Akt substrate of 160 kda (AS160) in rat skeletal muscle. Am J Physiol Endocrinol Metab 2007;292:E1191 E Treebak JT, Frøsig C, Pehmøller C, et al. Potential role of TBC1D4 in enhanced post-exercise insulin action in human skeletal muscle. Diabetologia 2009;52: Pehmøller C, Brandt N, Birk JB, et al. Exercise alleviates lipid-induced insulin resistance in human skeletal muscle-signaling interaction at the level of TBC1 domain family member 4. Diabetes 2012;61: Schweitzer GG, Arias EB, Cartee GD. Sustained postexercise increases in AS160 Thr642 and Ser588 phosphorylation in skeletal muscle without sustained increases in kinase phosphorylation. J Appl Physiol (1985) 2012;113: Daignan-Fornier B, Pinson B. 5-Aminoimidazole-4-carboxamide-1-beta-Dribofuranosyl 59-monophosphate (AICAR), a highly conserved purine intermediate with multiple effects. Metabolites 2012;2: Mu J, Brozinick JT Jr, Valladares O, Bucan M, Birnbaum MJ. A role for AMPactivated protein kinase in contraction- and hypoxia-regulated glucose transport in skeletal muscle. Mol Cell 2001;7: Lantier L, Fentz J, Mounier R, et al. AMPK controls exercise endurance, mitochondrial oxidative capacity, and skeletal muscle integrity. FASEB J 2014;28: Barnes BR, Marklund S, Steiler TL, et al. The 59-AMP-activated protein kinase gamma3 isoform has a key role in carbohydrate and lipid metabolism in glycolytic skeletal muscle. J Biol Chem 2004;279: Chen S, Murphy J, Toth R, Campbell DG, Morrice NA, Mackintosh C. Complementary regulation of TBC1D1 and AS160 by growth factors, insulin and AMPK activators. Biochem J 2008;409: Birk JB, Wojtaszewski JFP. Predominant alpha2/beta2/gamma3 AMPK activation during exercise in human skeletal muscle. J Physiol 2006;577: Pehmøller C, Treebak JT, Birk JB, et al. Genetic disruption of AMPK signaling abolishes both contraction- and insulin-stimulated TBC1D1 phosphorylation and binding in mouse skeletal muscle. Am J Physiol Endocrinol Metab 2009;297:E665 E Vichaiwong K, Purohit S, An D, et al. Contraction regulates site-specific phosphorylation of TBC1D1 in skeletal muscle. Biochem J 2010;431: Frøsig C, Jensen TE, Jeppesen J, et al. AMPK and insulin action responses to ageing and high fat diet. PLoS One 2013;8:e An D, Toyoda T, Taylor EB, et al. TBC1D1 regulates insulin- and contractioninduced glucose transport in mouse skeletal muscle. Diabetes 2010;59: Chen S, Wasserman DH, MacKintosh C, Sakamoto K. Mice with AS160/ TBC1D4-Thr649Ala knockin mutation are glucose intolerant with reduced insulin sensitivity and altered GLUT4 trafficking. Cell Metab 2011;13: Smith JL, Patil PB, Fisher JS. AICAR and hyperosmotic stress increase insulin-stimulated glucose transport. J Appl Physiol (1985) 2005;99: Ju J-S, Gitcho MA, Casmaer CA, et al. Potentiation of insulin-stimulated glucose transport by the AMP-activated protein kinase. Am J Physiol Cell Physiol 2007;292:C564 C Treebak JT, Pehmøller C, Kristensen JM, et al. Acute exercise and physiological insulin induce distinct phosphorylation signatures on TBC1D1 and TBC1D4 proteins in human skeletal muscle. J Physiol 2014;592: Taylor EB, An D, Kramer HF, et al. Discovery of TBC1D1 as an insulin-, AICAR-, and contraction-stimulated signaling nexus in mouse skeletal muscle. J Biol Chem 2008;283: Ducommun S, Wang HY, Sakamoto K, MacKintosh C, Chen S. Thr649Ala- AS160 knock-in mutation does not impair contraction/aicar-induced glucose transport in mouse muscle. Am J Physiol Endocrinol Metab 2012;302:E1036 E Hoehn KL, Hohnen-Behrens C, Cederberg A, et al. IRS1-independent defects define major nodes of insulin resistance. Cell Metab 2008;7: Habegger KM, Hoffman NJ, Ridenour CM, Brozinick JT, Elmendorf JS. AMPK enhances insulin-stimulated GLUT4 regulation via lowering membrane cholesterol. Endocrinology 2012;153: Carling D, Clarke PR, Zammit VA, Hardie DG. Purification and characterization of the AMP-activated protein kinase. Copurification of acetyl-coa carboxylase kinase and 3-hydroxy-3-methylglutaryl-CoA reductase kinase activities. Eur J Biochem 1989;186: Frøsig C, Jørgensen SB, Hardie DG, Richter EA, Wojtaszewski JFP. 59-AMPactivated protein kinase activity and protein expression are regulated by endurance training in human skeletal muscle. Am J Physiol Endocrinol Metab 2004; 286:E411 E Mikines KJ, Sonne B, Tronier B, Galbo H. Effects of acute exercise and detraining on insulin action in trained men. J Appl Physiol (1985) 1989;66: Castorena CM, Arias EB, Sharma N, Cartee GD. Postexercise improvement in insulin-stimulated glucose uptake occurs concomitant with greater AS160 phosphorylation in muscle from normal and insulin-resistant rats. Diabetes 2014; 63: