Metformin, but not exercise training, increases insulin responsiveness in skeletal muscle of Sprague-Dawley rats

We assessed the effects of combined metformin treatment and exercise training on body composition, on insulin concentration following glucose loading, on insulin-stimulated glucose transport in skeletal muscle, and on muscle glycogen content. Male Sprague-Dawley rats were treated for 35 days with or without metformin (320 mg/kg/day) and/or treadmill exercise training (20 min at 20 m/min, 5 days/wk). Because metformin reduces food intake, pair-fed controls were included. Metformin, training, and pair-feeding all decreased food intake, body weight, and insulin concentration following glucose loading. Metformin and training reduced intra-abdominal fat, but pair feeding did not. In isolated strips derived from soleus, epitrochlearis and extensor carpi ulnaris muscles, metformin increased insulin-stimulated transport of [3H]-2-deoxyglucose by 90%, 89% and 125%, respectively (P < 0.02) and training increased [3H]-2-deoxyglucose transport in the extensor carpi ulnaris muscle only (66%, P < 0.05). Pair-feeding did not alter [3H]-2-deoxyglucose transport. Training increased gastrocnemius muscle glycogen by 100% (P < 0.001). Metformin and pair-feeding did not alter muscle glycogen. We conclude that metformin reverses the maturation-induced impairment of insulin responsiveness in Sprague-Dawley rats by increasing insulin-stimulated glucose transport in skeletal muscle and that this effect is not secondary to reduced food intake. We also conclude that metformin and exercise training may increase insulin sensitivity by different mechanisms, with training causing increased glucose transport only in some muscles and also causing increased muscle glycogen storage.     

Metformin restores responses to insulin but not to growth hormone in Sprague-Dawley rats

Administration of growth hormone (GH) increases muscle mass in F344 x BN rats, but not in Sprague-Dawley (S-D) rats. S-D rats are insulin-resistant and insulin responsiveness is required for the anabolic actions of GH. We hypothesized that correction of insulin resistance with metformin might also restore anabolic effects of GH. Treatment with GH (0.25 or 1.0 mg/kg twice daily for 9 days) had limited anabolic effects, reducing weight gain by 14%, increasing muscle glycogen content by 40% and increasing exercise capacity by 24%, but failing to increase muscle mass or to reduce fat mass. GH also impaired insulin responsiveness and increased visceral fat TNF content of visceral fat by 77%. Metformin enhanced insulin responsiveness in skeletal muscle, but failed to enhance anabolic effects of GH. Rats aged 14 weeks were treated for 21 days with metformin (320 mg/kg/day) and for the last 9 days, with GH (0.25 mg/kg, twice daily). Metformin caused a 2.3-fold increase in insulin-stimulated muscle glucose transport and a 20% reduction in muscle fatty acid oxidation, indicating increased glucose utilization. However, metformin did not augment GH-induced weight reduction. Metformin decreased visceral fat by 22% and subcutaneous fat by 20%, but no decreases were observed in the GH/metformin group. GH increased muscle glycogen by 40%, but the effect was reversed by metformin. VO(2max) was increased 24% by GH and 17% by metformin, but was not elevated in the GH/metformin group. GH increased TNF in visceral fat and the effect was augmented by metformin (144% increase). We conclude that metformin enhances some aspects of insulin responsiveness, but does not enhance anabolic responses to GH. The latter may, in part, be explained by the failure of metformin to prevent GH-induced elevation of TNF in visceral fat.     

Chronic selective glycogen synthase kinase-3 inhibition enhances glucose disposal and muscle insulin action in prediabetic obese Zucker rats

Increasing evidence supports a negative role of glycogen synthase kinase-3 (GSK-3) in regulation of skeletal muscle glucose transport. We assessed the effects of chronic treatment of insulin-resistant, prediabetic obese Zucker (fa/fa) rats with a highly selective GSK-3 inhibitor (CT118637) on glucose tolerance, whole body insulin sensitivity, plasma lipids, skeletal muscle insulin signaling, and in vitro skeletal muscle glucose transport activity. Obese Zucker rats were treated with either vehicle or CT118637 (30 mg/kg body wt) twice per day for 10 days. Fasting plasma insulin and free fatty acid levels were reduced by 14 and 23% (P < 0.05), respectively, in GSK-3 inhibitor-treated animals compared with vehicle-treated controls. The glucose response during an oral glucose tolerance test was reduced by 18% (P < 0.05), and whole body insulin sensitivity was increased by 28% (P < 0.05). In vivo insulin receptor substrate-1 (IRS-1) tyrosine phosphorylation (50%) and IRS-1-associated phosphatidylinositol-3' kinase (79%) relative to fasting plasma insulin levels were significantly elevated (P < 0.05) in plantaris muscles of GSK-3 inhibitor-treated animals. Whereas basal glucose transport in isolated soleus and epitrochlearis muscles was unaffected by chronic GSK-3 treatments, insulin stimulation of glucose transport above basal was significantly enhanced (32-60%, P < 0.05). In summary, chronic treatment of insulin-resistant, prediabetic obese Zucker rats with a specific GSK-3 inhibitor enhances oral glucose tolerance and whole body insulin sensitivity and is associated with an amelioration of dyslipidemia and an improvement in IRS-1-dependent insulin signaling in skeletal muscle. These results provide further evidence that selective targeting of GSK-3 in muscle may be an effective intervention for the treatment of obesity-associated insulin resistance.     

Effect of metformin on the vascular and glucose metabolic actions of insulin in hypertensive rats

We investigated the long-term effect of metformin treatment on blood pressure, insulin sensitivity, and vascular responses to insulin in conscious spontaneously hypertensive rats (SHR). The rats were instrumented with intravascular catheters and pulsed Doppler flow probes to measure blood pressure, heart rate, and blood flow. Insulin sensitivity was assessed by the euglycemic hyperinsulinemic clamp technique. Two groups of SHR received metformin (100 or 300 mg x kg(-1) x day(-1)) for 3 wk while another group of SHR and a group of Wistar Kyoto (WKY) rats were left untreated. We found that vasodilation of skeletal muscle and renal vasculatures by insulin is impaired in SHR. Moreover, a reduced insulin sensitivity was detected in vivo and in vitro in isolated soleus and extensor digitorum longus muscles from SHR compared with WKY rats. Three weeks of treatment with metformin improves the whole-body insulin-mediated glucose disposal in SHR but has no blood pressure-lowering effect and no influence on vascular responses to insulin (4 mU x kg(-1) x min(-1)). An improvement in insulin-mediated glucose transport activity was detected in isolated muscles from metformin-treated SHR, but in the absence of insulin no changes in basal glucose transport activity were observed. It is suggested that part of the beneficial effect of metformin on insulin resistance results from a potentiation of the hormone-stimulating effect on glucose transport in peripheral tissues (mainly skeletal muscle). The results argue against a significant antihypertensive or vascular effect of metformin in SHR.     

Metformin counters the insulin-induced suppression of fatty acid oxidation and stimulation of triacylglycerol storage in rodent skeletal muscle

The present study examined the acute effects of metformin on fatty acid (FA) metabolism in oxidative soleus (SOL) and glycolytic epitrochlearis (EPT) rodent muscle. SOL and EPT were incubated for either 30 or 180 min in the absence or presence of 2 mM metformin and with or without insulin (10 mU/ml). Metformin did not alter basal FA metabolism but countered the effects of insulin on FA oxidation and incorporation into triacylglyerol (TAG). Specifically, metformin prevented the insulin-induced suppression of FA oxidation in SOL but did not alter FA incorporation into lipid pools. In contrast, in EPT metformin blunted the incorporation of FA into TAG when insulin was present but did not alter FA oxidation. In SOL, metformin resulted in a 50% increase in AMP-activated protein kinase alpha2 activity and prevented the insulin-induced increase in malonyl-CoA content. In both fiber types, basal and insulin-stimulated glucose oxidation were not significantly altered by metformin. All effects were similar regardless of whether they were measured after 30 or 180 min. Because increased muscle lipid storage and impaired FA oxidation have been associated with insulin resistance in this tissue, the ability of metformin to reverse these abnormalities in muscle FA metabolism may be a part of the mechanism by which metformin improves glucose clearance and insulin sensitivity. The present data also suggest that increased glucose clearance is not due to its enhanced subsequent oxidation. Additional studies are warranted to determine whether chronic metformin treatment has similar effects on muscle FA metabolism.     

Metformin activates AMP kinase through inhibition of AMP deaminase

The mechanism for how metformin activates AMPK (AMP-activated kinase) was investigated in isolated skeletal muscle L6 cells. A widely held notion is that inhibition of the mitochondrial respiratory chain is central to the mechanism. We also considered other proposals for metformin action. As metabolic pathway markers, we focused on glucose transport and fatty acid oxidation. We also confirmed metformin actions on other metabolic processes in L6 cells. Metformin stimulated both glucose transport and fatty acid oxidation. The mitochondrial Complex I inhibitor rotenone also stimulated glucose transport but it inhibited fatty acid oxidation, independently of metformin. The peroxynitrite generator 3-morpholinosydnonimine stimulated glucose transport, but inhibited fatty acid oxidation. Addition of the nitric oxide precursor arginine to cells did not affect glucose transport. These studies differentiate metformin from inhibition of mitochondrial respiration and from active nitrogen species. Knockdown of adenylate kinase also failed to affect metformin stimulation of glucose transport. Hence, any means of increase in ADP appears not to be involved in the metformin mechanism. Knockdown of LKB1, an upstream kinase and AMPK activator, did not affect metformin action. Having ruled out existing proposals, we suggest a new one: metformin might increase AMP through inhibition of AMP deaminase (AMPD). We found that metformin inhibited purified AMP deaminase activity. Furthermore, a known inhibitor of AMPD stimulated glucose uptake and fatty acid oxidation. Both metformin and the AMPD inhibitor suppressed ammonia accumulation by the cells. Knockdown of AMPD obviated metformin stimulation of glucose transport. We conclude that AMPD inhibition is the mechanism of metformin action.     

Increased glucose transporter (GLUT4) protein expression in hyperthyroidism

We have studied skeletal muscle glucose uptake by perfused hindquarter preparations from rats treated with thyroxine. Basal glucose uptake (in the absence of insulin) was approximately 2 fold higher in muscle of hyperthyroid rats compared to controls. Insulin (10(-7) M) stimulated glucose uptake 4.0 and 6.8 fold in the 10 day and 30 day controls rats, respectively. Maximal glucose uptake (10(-7) M insulin) was not different in control and hyperthyroid rats and thus insulin responsiveness in the hyperthyroid animals was reduced to 2.5 fold stimulation. The abundance of the insulin-sensitive glucose transporter protein (muscle/fat, GLUT-4), measured by Western blot analysis using polyclonal antisera, was higher in skeletal muscle from both groups of hyperthyroid rats. These studies indicate that thyroid hormones increase basal glucose uptake in skeletal muscle and this is due, at least in part, to an increment of GLUT-4 isoform. Increased expression of muscle glucose transporter proteins may be responsible for the increased peripheral glucose utilization seen in hyperthyroidism.     

beta-3 adrenergic agonist restores skeletal muscle insulin responsiveness in Sprague-Dawley rats.

Between 7 and 14 weeks of age, male Sprague-Dawley rats develop a greater than 50% loss in insulin-stimulated glucose transport in skeletal muscle. We treated rats aged 14 weeks with the beta-3 adrenergic agonist CL316,243 (1 mg/kg/day by minipump for 14 days). Treatment resulted in a 56% reduction in visceral fat (P < 0.05). Muscle mass and body weight were unchanged. In strips of soleus muscle isolated from rats treated with CL316,243, basal transport of [(3)H]-2-deoxyglucose (2-DOG) was unchanged (105.8 +/- 7.5 nmol/g/min for vehicle vs 122.0 +/- 8.7 for CL316,243). However, in rats treated with CL316,243, the increase in 2-DOG transport in response to a maximal concentration of insulin was substantially increased (55.5 +/- 13.1 nmol/g/min for vehicle vs 102.4 +/- 13.5 for CL316,243, P < 0.03). CL 316,243 caused no significant changes in fasting glucose, insulin, or free fatty acids. Treatment of soleus muscle strips in vitro with CL316,243 (either 0.1 nM or 1.0 nM for 120 min at 37 degrees C) had no effect either on basal 2-DOG transport or on insulin-stimulated transport. We conclude that the CL316,243 causes a reduction in visceral fat and a reversal of muscle insulin resistance. The effect CL 316,243 on muscle insulin responses appears to be indirect, as it did not occur in vitro.     

Activation of imidazoline I-2B receptor by metformin to increase glucose uptake in skeletal muscle

Metformin (dimethylbiguanide) belongs to guanidinium-derivative and is widely used for treatment of diabetic disorders in clinic. Metformin lowers blood glucose in diabetic animals through increase of glucose uptake into skeletal muscle. Recent evidence indicates that activation of imidazoline I2B receptor (I2BR) by guanidinium-derivatives also increased glucose uptake; however, the effect of metformin on I2BR is still unknown. The blood glucose levels were determined by a glucose kit. The ability of glucose uptake into isolated skeletal muscle or cultured C2C12 cells was determined using 2-[14C]-deoxyglucose as tracer. The expressions of 5' AMP-activated protein kinase (AMPK) and glucose transporter 4 (GLUT-4) were identified by Western blotting analysis. The metformin-induced blood glucose-lowering action was dose-dependently blocked by BU224, a specific I2R antagonist, in Wistar rats. Also, similar reversion by BU224 was observed in isolated skeletal muscle regarding the metformin-induced glucose uptake. Moreover, AMPK phosphorylation by metformin was concentration-dependently reduced by BU224 in isolated skeletal muscle. In addition, signals for metformin increased glucose uptake were identified via I2R/PI3K/PKC/AMPK dependent pathway in C2C12 cells. Thus, we suggest that metformin can activate I2BR to increase glucose uptake and I2BR will be a new target for diabetic therapy.     

Essential role of p38 MAPK for activation of skeletal muscle glucose transport by lithium

Lithium increases glucose transport and glycogen synthesis in insulin-sensitive cell lines and rat skeletal muscle, and has been used as a non-selective inhibitor of glycogen synthase kinase-3 (GSK-3). However, the molecular mechanisms underlying lithium action on glucose transport in mammalian skeletal muscle are unknown. Therefore, we examined the effects of lithium on glucose transport activity, glycogen synthesis, insulin signaling elements (insulin receptor (IR), Akt, and GSK-3beta), and the stress-activated p38 mitogen-activated protein kinase (p38 MAPK) in the absence or presence of insulin in isolated soleus muscle from lean Zucker rats. Lithium (10 mM LiCl) enhanced basal glucose transport by 62% (p < 0.05) and augmented net glycogen synthesis by 112% (p < 0.05). Whereas lithium did not affect basal IR tyrosine phosphorylation or Akt ser(473) phosphorylation, it did enhance (41%, p < 0.05) basal GSK-3beta ser(9) phosphorylation. Lithium further enhanced (p < 0.05) the stimulatory effects of insulin on glucose transport (43%), glycogen synthesis (44%), and GSK-3beta ser(9) phosphorylation (13%). Lithium increased (p < 0.05) p38 MAPK phosphorylation both in the absence (37%) and presence (41%) of insulin. Importantly, selective inhibition of p38 MAPK (using 10 microM A304000) completely prevented the basal activation of glucose transport by lithium, and also significantly reduced (52%, p < 0.05) the lithium-induced enhancement of insulin-stimulated glucose transport. Theses results demonstrate that lithium enhances basal and insulin-stimulated glucose transport activity and glycogen synthesis in insulin-sensitive rat skeletal muscle, and that these effects are associated with a significant enhancement of GSK-3beta phosphorylation. Importantly, we have documented an essential role of p38 MAPK phosphorylation in the action lithium on the glucose transport system in isolated mammalian skeletal muscle.     

Insulin action in skeletal muscle from patients with NIDDM

Insulin resistance in peripheral tissues is a common feature of non insulin-dependent diabetes mellitus (NIDDM). The decrease in insulin-mediated peripheral glucose uptake in NIDDM patients can be localized to defects in insulin action on glucose transport in skeletal muscle. Following short term in vitro exposure to both submaximal and maximal concentrations of insulin, 3-O-methylglucose transport rates are 40-50% lower in isolated skeletal muscle strips from NIDDM patients when compared to muscle strips from nondiabetic subjects. In addition, we have shown that physiological levels of insulin induce a 1.6-2.0 fold increase in GLUT4 content in skeletal muscle plasma membranes from control subjects, whereas no significant increase was noted in NIDDM skeletal muscle. Impaired insulin-stimulated GLUT4 translocation and glucose transport in NIDDM skeletal muscle is associated with reduced insulin-stimulated IRS-1 tyrosine phosphorylation and PI3-kinase activity. The reduced IRS-1 phosphorylation cannot be attributed to decreased protein expression, since the IRS-1 protein content is similar between NIDDM subjects and controls. Altered glycemia may contribute to decreased insulin-mediated glucose transport in skeletal muscle from NIDDM patients. We have shown that insulin-stimulated glucose transport is normalized in vitro in the presence of euglycemia, but not in the presence of hyperglycemia. Thus, the circulating level of glucose may independently regulate insulin stimulated glucose transport in skeletal muscle from NIDDM patients via a down regulation of the insulin signaling cascade.     

Modulation of muscle insulin resistance by selective inhibition of GSK-3 in Zucker diabetic fatty rats

A role for elevated glycogen synthase kinase-3 (GSK-3) activity in the multifactorial etiology of insulin resistance is now emerging. However, the utility of specific GSK-3 inhibition in modulating insulin resistance of skeletal muscle glucose transport is not yet fully understood. Therefore, we assessed the effects of novel, selective organic inhibitors of GSK-3 (CT-98014 and CT-98023) on glucose transport in insulin-resistant muscles of Zucker diabetic fatty (ZDF) rats. Incubation of type IIb epitrochlearis and type I soleus muscles from ZDF rats with CT-98014 increased glycogen synthase activity (49 and 50%, respectively, P < 0.05) but did not alter basal glucose transport (2-deoxyglucose uptake). In contrast, CT-98014 significantly increased the stimulatory effects of both submaximal and maximal insulin concentrations in epitrochlearis (37 and 24%) and soleus (43 and 26%), and these effects were associated with increased cell-surface GLUT4 protein. Lithium enhanced glycogen synthase activity and both basal and insulin-stimulated glucose transport in muscles from ZDF rats. Acute oral administration (2 x 30 mg/kg) of CT-98023 to ZDF rats caused elevations in GSK-3 inhibitor concentrations in plasma and muscle. The glucose and insulin responses during a subsequent oral glucose tolerance test were reduced by 26 and 34%, respectively, in the GSK-3 inhibitor-treated animals. Thirty minutes after the final GSK-3 inhibitor treatment, insulin-stimulated glucose transport was significantly enhanced in epitrochlearis (57%) and soleus (43%). Two hours after the final treatment, insulin-mediated glucose transport was still significantly elevated (26%) only in the soleus. These results indicate that specific inhibition of GSK-3 enhances insulin action on glucose transport in skeletal muscle of the insulin-resistant ZDF rat. This unique approach may hold promise as a pharmacological treatment against insulin resistance of skeletal muscle glucose disposal.     

Modulation of insulin resistance and hypertension by voluntary exercise training in the TG(mREN2)27 rat.

Hypertension is often accompanied by insulin resistance of skeletal muscle glucose transport. The male heterozygous TG(mREN2)27 rat, which harbors a mouse transgene for renin, displays local elevations in the renin-angiotensin system and exhibits markedly elevated systolic blood pressure (SBP). The present study was undertaken to characterize insulin-stimulated skeletal muscle glucose transport in male heterozygous TG(mREN2)27 rats and to evaluate the effect of voluntary exercise training on SBP and skeletal muscle glucose transport. Compared with normotensive Sprague-Dawley rats, TG(mREN2)27 rats displayed a 53% elevation (P < 0.05) in SBP, a twofold increase in plasma free fatty acid levels, and an exaggerated insulin response during an oral glucose tolerance test. Moreover, insulin-mediated glucose transport (2-deoxyglucose uptake) in isolated epitrochlearis and soleus muscles of TG(mREN2)27 animals was 33 and 43% less, respectively, than in Sprague-Dawley controls. TG(mREN2)27 rats ran voluntarily for 6 wk and achieved daily running distances of 6-7 km over the final 3 wk. Training caused a 36% increase in peak aerobic capacity and a 16% reduction in resting SBP. Fasting plasma insulin (21%) and free fatty acid (34%) levels were reduced in the trained TG(mREN2)27 rats. Whole body glucose tolerance was improved in the trained TG(mREN2)27 rats and was associated with increases of 39 and 50% in insulin-mediated glucose transport in epitrochlearis and soleus muscles, respectively. Whole muscle GLUT-4 protein was increased in the soleus (23%), but not in the epitrochlearis, of trained TG(mREN2)27 rats. These data indicate that the male heterozygous TG(mREN2)27 rat is a model of both hypertension and insulin resistance. Importantly, both of these defects can be beneficially modified by voluntary exercise training.     

High-fat diet feeding impairs both the expression and activity of AMPKa in rats' skeletal muscle

OBJECTIVE: To investigate the effects of high-fat feeding on the expression and activity of AMPK in rats' skeletal muscle. METHODS: Total 40 male Wistar rats were randomly divided into three groups and received either a rat maintenance diet (Control group) or an isocaloric rich-fat diet (HF group and MET group) for five months. Metformin was administered orally with the daily dose of 300mg in MET group during the last month of high-fat feeding. Hyperinsulinemic-euglycemic clamp study was performed to estimate whole-body insulin sensitivity. The ability of insulin-stimulated glucose uptake in isolated skeletal muscle was detected just before execution. mRNA levels of AMPKa1, AMPKa2, and Glut4 of rats' skeletal muscle were determined using real-time PCR. Protein contents of AMPKa, P-AMPKa, P-ACC, and Glut4 in rats' skeletal muscle were measured using Western blot. RESULTS: (1) Hyperinsulinemic-euglycemic clamp study revealed a significantly impaired insulin action at the whole-body level after high-fat feeding (p<0.01). Also, both basal and insulin-stimulated glucose uptake in isolated skeletal muscle decreased after high-fat feeding (p<0.05), indicating onset of high-fat induced insulin resistance. (2) Five months of high-fat treatment induced a significant decrease of AMPKa protein contents and AMPKa2 mRNA levels in rats' skeletal muscles (p<0.05), while it did not alter AMPKa1 mRNA levels. Protein levels of P-AMPKa also decreased after high-fat feeding (p<0.01). These data suggest that high-fat exposure might impair AMPKa expression and activities. (3) P-ACC protein contents, mRNA and protein levels of Glut4 in rats' skeletal muscles also decreased after high-fat treatment (p<0.05). (4) Compared with HF group, although no significant alternations of AMPKa expression in rats' skeletal muscles were detected, P-AMPKa levels revealed a 162% increase after metformin treatment (p<0.05), demonstrating the AMPK-activating effect of metformin. Accompanied with activation of AMPKa, rats in MET group exhibited significantly elevated P-ACC contents, Glut4 mRNA and protein levels, and an obviously enhanced insulin sensitivity at both whole-body and skeletal muscle levels (p<0.05). CONCLUSIONS: High-fat feeding impaired both the expression and activities of AMPKa, while activating AMPKa by metformin obviously ameliorated high-fat induced insulin resistance, thus indicating a possible role of AMPKa in lipotoxicity.     

Improvement of metabolic parameters and vascular function by metformin in obese non-diabetic rats

AimsMetformin is an insulin sensitizing agent with beneficial effects in diabetic patients on glycemic levels and in the cardiovascular system. We examined whether the metabolic changes and the vascular dysfunction in monosodium glutamate-induced obese non-diabetic (MSG) rats might be improved by metformin.Main methods16 week-old MSG rats were treated with metformin for 15 days and compared with age-matched untreated MSG and non-obese non-diabetic rats (control). Blood pressure, insulin sensitivity, vascular reactivity and prostanoid release in the perfused mesenteric arteriolar bed as well as nitric oxide production and reactive oxygen species generation in isolated mesenteric arteries were analyzed.Key findings18-week-old MSG rats displayed higher Lee index, fat accumulation, dyslipidemia, insulin resistance and hyperinsulinemia. Metformin treatment improved these alterations. The norepinephrine-induced response, increased in the mesenteric arteriolar bed from MSG rats, was corrected by metformin. Indomethacin corrected the enhanced contractile response in MSG rats but did not affect metformin effects. The sensitivity to acetylcholine, reduced in MSG rats, was also corrected by metformin. Indomethacin corrected the reduced sensitivity to acetylcholine in MSG rats but did not affect metformin effects. The sensitivity to sodium nitroprusside was increased in preparations from metformin-treated rats. Metformin treatment restored both the reduced PGI2/TXA2 ratio and the increased reactive oxygen species generation in preparations from MSG rats.SignificanceMetformin improved the vascular function in MSG rats through reduction in reactive oxygen species generation, modulation of membrane hyperpolarization, correction of the unbalanced prostanoids release and increase in the sensitivity of the smooth muscle to nitric oxide.     

Protein kinase Cdelta mediates insulin-induced glucose transport in primary cultures of rat skeletal muscle

Insulin activates certain protein kinase C (PKC) isoforms that are involved in insulin-induced glucose transport. In this study, we investigated the possibility that activation of PKCdelta by insulin participates in the mediation of insulin effects on glucose transport in skeletal muscle. Studies were performed on primary cultures of rat skeletal myotubes. The role of PKCdelta in insulin-induced glucose uptake was evaluated both by selective pharmacological blockade and by over-expression of wild-type and point-mutated inactive PKCdelta isoforms in skeletal myotubes. We found that insulin induces tyrosine phosphorylation and translocation of PKCdelta to the plasma membrane and increases the activity of this isoform. Insulin-induced effects on translocation and phosphorylation of PKCdelta were blocked by a low concentration of rottlerin, whereas the effects of insulin on other PKC isoforms were not. This selective blockade of PKCdelta by rottlerin also inhibited insulin-induced translocation of glucose transporter 4 (GLUT4), but not glucose transporter 3 (GLUT3), and significantly reduced the stimulation of glucose uptake by insulin. When overexpressed in skeletal muscle, PKCdelta and PKCdelta were both active. Overexpression of PKCdelta induced the translocation of GLUT4 to the plasma membrane and increased basal glucose uptake to levels attained by insulin. Moreover, insulin did not increase glucose uptake further in cells overexpressing PKCdelta. Overexpression of PKCdelta did not affect basal glucose uptake or GLUT4 location. Stimulation of glucose uptake by insulin in cells overexpressing PKCdelta was similar to that in untransfected cells. Transfection of skeletal myotubes with dominant negative mutant PKCdelta did not alter basal glucose uptake but blocked insulin-induced GLUT4 translocation and glucose transport. These results demonstrate that insulin activates PKCdelta and that activated PKCdelta is a major signaling molecule in insulin-induced glucose transport.     

Subchronic treatment with metformin produces anorectic effect and reduces hyperinsulinemia in genetically obese Zucker rats.

The effect of subchronic metformin treatment on food intake, weight gain and plasma and tissue hormone levels was investigated in genetically obese male Zucker rats and in their lean controls. Metformin hydrochloride (320 mg/kg/day for 14 days in the drinking water) significantly reduced 24 hour food intake both after one and two weeks treatment in obese rats. In contrast, metformin had only a transient effect on food intake in lean animals. The reduced food intake was associated with body weight decrease, particularly in obese rats. Metformin markedly reduced also the hyperinsulinemia of the obese animals without altering their plasma glucose or pancreatic insulin content which may reflect an improved insulin sensitivity after metformin treatment. Metformin did not change plasma corticosterone levels or insulin and somatostatin concentrations in the pancreas. Metformin reduced pyloric region somatostatin content in lean rats. It is concluded that metformin has an anorectic effect and reduces body weight and hyperinsulinemia in genetically obese Zucker rat.     

Glucose metabolism in perfused skeletal muscle. Demonstration of insulin resistance in the obese Zucker rat.

1. The effect of insulin (0.5, 10 and 50 munits/ml of perfusate) on glucose uptake and disposal in skeletal muscle was studied in the isolated perfused hindquarter of obese (fa/fa) and lean (Fa/Fa) Zucker rats and Osborne-Mendel rats. 2. A concentration of 0.5 munit of insulin/ml induced a significant increase in glucose uptake (approx. 2.5 mumol/min per 30 g of muscle) in lean Zucker rats and in Osborne-Mendel rats, and 10 munits of insulin/ml caused a further increase to approx. 6 mumol/min per 30 g of muscle; but 50 munits of insulin/ml had no additional stimulatory effect. In contrast, in obese Zucker rats only 10 and 50 munits of insulin/ml had a stimulatory effect on glucose uptake, the magnitude of which was decreased by 50-70% when compared with either lean control group. Since under no experimental condition tested was an accumulation of free glucose in muscle-cell water observed, the data suggest an impairment of insulin-stimulated glucose transport across the muscle-cell membrane in obese Zucker rats. 3. The intracellular disposal of glucose in skeletal muscle of obese Zucker rats was also insulin-insensitive: even at insulin concentrations that clearly stimulated glucose uptake, no effect of insulin on lactate oxidation (nor an inhibitory effect on alanine release) was observed; [14C]glucose incorporation into skeletal-muscle lipids was stimulated by 50 munits of insulin/ml, but the rate was still only 10% of that observed in lean Zucker rats. 4. The data indicate that the skeletal muscle of obese Zucker rats is insulin-resistant with respect to both glucose-transport mechanisms and intracellular pathways of glucose metabolism, such as lactate oxidation. The excessive degree of insulin-insensitivity in skeletal muscle of obese Zucker rats may represent a causal factor in the development of the glucose intolerance in this species.     

Two Weeks of Metformin Treatment Enhances Mitochondrial Respiration in Skeletal Muscle of AMPK Kinase Dead but Not Wild Type Mice

Metformin is used as an anti-diabetic drug. Metformin ameliorates insulin resistance by improving insulin sensitivity in liver and skeletal muscle. Reduced mitochondrial content has been reported in type 2 diabetic muscles and it may contribute to decreased insulin sensitivity characteristic for diabetic muscles. The molecular mechanism behind the effect of metformin is not fully clarified but inhibition of complex I in the mitochondria and also activation of the 5′AMP activated protein kinase (AMPK) has been reported in muscle. Furthermore, both AMPK activation and metformin treatment have been associated with stimulation of mitochondrial function and biogenesis. However, a causal relationship in skeletal muscle has not been investigated. We hypothesized that potential effects of in vivo metformin treatment on mitochondrial function and protein expressions in skeletal muscle are dependent upon AMPK signaling. We investigated this by two weeks of oral metformin treatment of muscle specific kinase dead α₂ (KD) AMPK mice and wild type (WT) littermates. We measured mitochondrial respiration and protein activity and expressions of key enzymes involved in mitochondrial carbohydrate and fat metabolism and oxidative phosphorylation. Mitochondrial respiration, HAD and CS activity, PDH and complex I-V and cytochrome c protein expression were all reduced in AMPK KD compared to WT tibialis anterior muscles. Surprisingly, metformin treatment only enhanced respiration in AMPK KD mice and thereby rescued the respiration defect compared to the WT mice. Metformin did not influence protein activities or expressions in either WT or AMPK KD mice.We conclude that two weeks of in vivo metformin treatment enhances mitochondrial respiration in the mitochondrial deficient AMPK KD but not WT mice. The improvement seems to be unrelated to AMPK, and does not involve changes in key mitochondrial proteins.     

Oxidative stress--mediated alterations in glucose dynamics in a genetic animal model of type II diabetes

Insulin resistance, characterized by an inexorable decline in skeletal muscle glucose utilization and/or an excessive hepatic glucose production, constitutes a major pathogenic importance in a cluster of clinical disorders including diabetes mellitus, hypertension, dyslipidemia, central obesity and coronary artery disease. A novel concept suggests that heightened state of oxidative stress during diabetes contributes, at least in part, to the development of insulin resistance. Several key predictions of this premise were subjected to experimental testing using Goto-Kakizaki (GK) rats as a genetic animal model for non-obese type II diabetes. Euglycemic-hyperinsulinemic clamp studies with an insulin infusion index of 5 mU/kg bw/min were used to measure endogenous glucose production (EGP), glucose infusion rate (GIR), glucose disposal rate (GDR) and skeletal muscle glucose utilization index (GUI). Moreover, the status of oxidative stress as reflected by the urinary levels of isoprostane and protein carbonyl formation were also assessed as a function of diabetes. Post-absorptive basal EGP and circulating levels of insulin, glucose and free fatty acid (FFA) were elevated in GK rats, compared to their corresponding control values. In contrast, steady state GIR and GDR of the hyperglycemic/hyperinsulinemic animals were reduced, concomitantly with impaired insulin's ability to suppress EGP. Insulin stimulated [3H]-2-deoxyglucose (2-DG) uptake (a measure of glucose transport activity) by various types of skeletal muscle fibers both in vivo and in vitro (isolated muscle, cultured myoblasts) was diminished in diabetic GK rats. This diabetes-related suppression of skeletal muscle glucose utilization was associated with a decrease in insulin's ability to promote the phosphorylation of tyrosine residues of insulin receptor substrate-1 (IRS-1). Similarly, the translocation of GLUT-4 from intracellular compartment to plasma membrane in response to insulin was also reduced in these animals. Oxidative stress-based markers (e.g. urinary isoprostane, carbonyl-bound proteins) were elevated as a function of diabetes. Nullification of the heightened state of oxidative stress in the GK rats with alpha-lipoic acid resulted in a partial amelioration of the diabetes-related impairment of the in vivo and in vitro insulin actions. Collectively, the above data suggest that 1) insulin resistance in GK rats occurs at the hepatic and skeletal muscle levels, 2) muscle cell glucose transport exhibited a blunted response to insulin and it is associated with a major defect in key molecules of both GLUT-4 trafficking and insulin signaling pathways, 3) skeletal muscle insulin resistance in GK rats appears to be of genetic origin and not merely related to a paracrine or autocrine effect, since this phenomenon is also observed in cultured myoblasts over several passages and finally heightened state of oxidative stress may mediate the development of insulin resistance during diabetes.