Abstract
Aims/hypothesis
Adiponectin and leptin are negatively and positively correlated with human obesity respectively, and have both been shown to regulate energy metabolism in skeletal muscle. However, little is known about their signalling and functional crosstalk. Here we investigated the effects of leptin on metabolic actions of (1) globular adiponectin (gAd) and (2) full-length adiponectin (fAd) in L6 cells.
Methods
Glucose uptake was measured upon gAd and fAd treatment after incubation with different doses (0.3, 0.6, 3, 6, 60 nmol/l) of leptin for 6, 12 and 24 h. We also measured adiponectin receptor (ADIPOR) expression and stimulation of downstream signalling by gAd and fAd using co-immunoprecipitation and western blotting following leptin pretreatment, as well as analysis of fatty acid uptake and oxidation using radiolabelled tracers.
Results
Leptin attenuated the stimulation of glucose uptake by gAd and fAd in a dose- and time-dependent manner, a finding correlated with decreased levels of ADIPOR1 and ADIPOR2. gAd and fAd increased palmitate uptake via activation of AMP protein kinase (T172), enhanced expression of the fatty acid transporter CD36, phosphorylated acetyl-CoA carboxylase (S79) and enhanced palmitate oxidation, all of which were attenuated by leptin pretreatment. Adiponectin can also enhance insulin sensitivity via direct signalling crosstalk; here we show that enhanced insulin-stimulated IRS-1 (Y612) and Akt (T308) phosphorylation in response to fAd was attenuated by leptin. APPL1 was recently identified as a critical mediator of adiponectin action in skeletal muscle. We demonstrated that leptin attenuated binding of APPL1 to LKB1, a downstream target leading to AMPK phosphorylation.
Conclusions/interpretation
The direct metabolic and insulin-sensitising effects of adiponectin were attenuated in the presence of leptin.
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Introduction
The prevalence of obesity has become a major health concern due to association with many complications such as type 2 diabetes and cardiovascular disease [1, 2]. One potential underlying mechanism is altered endocrine effects of adipose-derived hormones [3]. Due to its anti-diabetic, anti-atherogenic, anti-inflammatory and cardioprotective functions [4, 5], adiponectin has attracted great interest since being identified. The metabolic effects of adiponectin, both direct and via insulin sensitisation, have been identified in skeletal muscle and liver by several groups [6, 7]. Moreover, the synergistic effect of adiponectin and insulin on glucose uptake in L6 muscle cells was reported by our group [7]. It has also been demonstrated that adiponectin modulates carbohydrate and lipid metabolism in muscle primarily through stimulation of AMP protein kinase (AMPK) and peroxisome proliferator-activated receptor alpha [8]. More recently, Liu’s group have shown that adiponectin and insulin signalling crosstalk via a mechanism involving the LKB1/AMPK/tuberous sclerosis 1/2 pathway [9].
In circulation, adiponectin exists as multimers, namely low molecular weight trimers, middle molecular weight hexamers and high molecular weight oligomers [10]. The formation of these distinct structures is physiologically significant since oligomers have been observed to be capable of mediating distinct cellular effects [11]. Adiponectin can also be proteolytically cleaved to yield the globular C-terminal domain of adiponectin, which mediates potent metabolic effects in skeletal muscle [7, 12].
Adiponectin mediates its effects through at least two receptor isoforms, adiponectin receptor (ADIPOR)1 and ADIPOR2 [8]. Decreased levels of ADIPORs were observed in many, but not all, studies involving obese and diabetic patients as well as animal models [13, 14]; these decreases can often be corrected by exercise [15]. ADIPORs were recently shown to interact with a novel adapter protein containing a pleckstrin homology domain, phosphotyrosine binding (PTB) domain and leucine zipper motif (APPL1). This binding mediated adiponectin effects in muscle and endothelial cells, and, importantly, was identified as a major point of crosstalk with insulin signalling [16–18].
Hyperleptinaemia is a characteristic feature in human obesity. Several recent studies have alluded to the potential crosstalk between physiological actions of leptin and adiponectin [19, 20]. Leptin is known to regulate a wide range of intracellular signalling pathways [21]; however the potential crosstalk between leptin and adiponectin signalling is unclear. To date, three recent studies examining cell cycle regulation and cell proliferation have demonstrated that adiponectin and leptin can crosstalk [22–24]. The objective of this study was to characterise the effect of chronic leptin pretreatment on subsequent adiponectin signalling and consequently on metabolic function in rat skeletal muscle cells.
Methods
Materials
[9,10-3H]Palmitic acid and 2-deoxy-d-[3H]glucose were purchased from Amersham (Baie d'Urfé, QC, Canada). Recombinant murine leptin and compound C were purchased from Calbiochem (San Diego, CA, USA). Insulin (Humulin) was obtained from Eli Lilly (Toronto, ON, Canada). TRIzol reagent and Platinum SYBR Green qPCR SuperMix UDG Kit were obtained from Invitrogen Life Technologies (Burlington, ON, Canada). Anti-APPL1 antibody was produced in-house by immunisation of rabbits as previously described [16]. Horseradish peroxidase-linked anti-rabbit antibody, phospho-specific antibodies for rabbit AMPK (Thr 172), ACC (Ser 79), Akt (Thr 308), Akt and β-actin were purchased from Cell Signaling (Beverly, MA, USA). Fatty acid transport protein (FATP)1, FATP4, AMPKα1, AMPKα2, CD36, IRS-1 and LKB1 antibodies were obtained from Santa Cruz Biotechnology (Santa Cruz, CA, USA). Phospho-specific antibody for IRS-1(Tyr612) was obtained from BioSource (Camarillo, CA, USA). ADIPOR1 and ADIPOR2 antibodies were obtained from IBL (Takasaki, Japan). All other chemicals were purchased from Sigma-Aldrich Canada (Oakville, ON, Canada). All cell culture components were purchased from Wisent (St-Bruno, QC, Canada).
Production of recombinant gAd and fAd
Recombinant globular adiponectin (gAd) was produced by subcloning murine gAd cDNA (a kind gift from P. Scherer, Department of Cell Biology, Bronx, Albert Einstein College of Medicine, Bronx, NY, USA) into the pTrisEx expression vector (Novagen, Gibbstown, NJ, USA) as described previously [25]. A human embryonic kidney (HEK) cell line stably expressing recombinant full-length multimers of adiponectin (fAd) was generated as previously described [26]. HEK cells were cultured in DMEM containing 10% (vol./vol.) FBS and allowed to secrete adiponectin into serum-free alpha modification Eagle’s medium (AMEM) for 24 h. The conditioned medium was concentrated using stirred ultrafiltration cell system (Millipore, Billerica, MA, USA) with ultrafiltration membrane (NMWL 30 kDa; Millipore). Conditioned medium containing adiponectin was then diluted to 100 mg/l in serum-free AMEM and stored at −80°C. Control conditioned medium was made using HEK cell line transfected with vector without adiponectin sequence. Glucose uptake was performed to test biological activity of fAd and gAd. The concentrations and treatment time of fAd and gAd used in this study were based on preliminary studies and various publications by ourselves and others [7, 25].
Cell culture
Rat L6 skeletal muscle cells were grown in AMEM containing 10% (vol./vol.) FBS under 5% CO2 at 37°C. For experimental procedures, myoblasts were cultured in 2% FBS AMEM for 5 to 7 days for differentiation of myotubes.
Analysis of Adipor1 and -2 expression
L6 myotubes were incubated with leptin (60 nmol/l) for 24 h, then RNA was isolated. Adipor1, Adipor2 and β-actin expression levels were measured using platinum SYBR Green qPCR SuperMix UDG Kit. Primer sequences for the genes were: Adipor1: forward 5′-GCTGGCCTTTATGCTGCTCG-3′, reverse 5′-TCTAGGCCGTAACGGAATTC-3′; Adipor2: forward 5′-CCCTCTGCAAGAGAAAGTGG-3′, reverse 5′-TAGCCAGCCTATCTGCCCTA-3′; β-actin: forward 5′-CTGTGCCCATCTATGAGGGT-3′, reverse 5′-CTCTCAGCTTGGTGGTGAA-3′. The annealing temperature for Adipor1 and Adipor2 was 60°C, that for β-actin was 65°C; 40 cycles were performed.
Measurement of glucose uptake
L6 myotubes were incubated for 24 h with different concentrations of leptin (0.3, 0.6, 3, 6, 60 nmol/l). For time-course experiments, cells were incubated with 6 nmol/l leptin for 6, 12 and 24 h. Cells were then treated for 2 h with 5 mg/l fAd or gAd in the presence of leptin. After treatment, uptake of 2-deoxy-d-[3H]glucose was determined as described previously [7]. Briefly, cells were incubated for 5 min at room temperature in transport solution. Cells were then lysed and transferred to scintillation vials for 3H radioactivity counting. Values were expressed in pmol min−1 (mg protein)−1 (see results section) and expressed in graphs as fold of basal pmol min−1 (mg protein)−1.
Measurement of fatty acid uptake
Cells were grown in 24-well plates. Leptin was added to appropriate wells to a final concentration of 60 nmol/l and wells were incubated for 24 h. Cells were serum-starved for 4 h and then treated with fAd (5 μg/ml) or gAd (5 μg/ml) in the presence or absence of AMPK inhibitor compound C (20 μmol/l). [9,10-3H]Palmitic acid was measured as previously described [7, 27]. Briefly, cells were washed and treated for 1 min with transport solution (140 mmol/l NaCl, 20 mmol/l HEPES-Na, 2.5 mmol/l MgSO4, 1 mmol/l CaCl2, 5 mmol/l KCl, 20 µmol/l sodium palmitate, 18.5 MBq/l [9,10-3H]palmitic acid, pH 7.4). Cells were lysed with 1 mol/l KOH. Lysates were transferred to vials containing scintillation fluid for radioactive counting and used for protein determination. Values were expressed in pmol min−1 (mg protein)−1 and shown in graphs as fold of basal pmol min−1 (mg protein)−1.
Measurement of fatty acid oxidation
Myotubes were cultivated in 12-well plates and incubated in the presence of leptin (60 nmol/l) for 24 h. fAd and gAd (5 μg/ml each) were added to cells under normal and leptin pretreatment conditions. 5-Amino-4-imidazole carboxamide riboside (AICAR) was added to a final concentration of 2 mmol/l as positive control. After 6 h incubation in AMEM containing 0.1 mmol/l palmitate (9,10-[3H]palmitate, 37 MBq/l) and 2% (wt/wt) BSA, palmitate oxidation was assessed by measuring 3H2O produced in the incubation medium as described previously [28]. Medium was collected into Eppendorf tubes. Then 10% (vol./vol.) trichloroacetic acid was added to each tube and tubes were centrifuged for 10 min at 14,999 g at 4°C. The supernatant fraction was collected into capless Eppendorf tubes. These tubes were placed in vials containing equal volumes of distilled water and incubated overnight in a 50°C water bath. After incubation, 5 ml of scintillation liquid was added to each vial for radioactive counting; 1 mol/l KOH was added to prepare lysates and determine protein concentration. As previously published using this method, values are expressed in cpm/mg protein [28].
Small interfering RNA to knockdown expression of AMPKα
L6 cells were cultured in 24-well tissue culture plates and transfected for 24 h with 50 nmol/l AMPKα1 (also known as PRKAA1) and 50 nmol/l AMPKα2 (also known as PRKAA2), or with scrambled small interfering RNA (siRNA) (Silencer Negative Control 1 siRNA; Ambion, Austin, TX, USA) as previously described [29]. siRNA sequences for AMPKα1 and AMPKα2 were: AMPKα1 GCAUAUGCUGCAGGUAGAU; AMPKα2, CGUCAUUGAUGAUGAGGCU (Ambion).
Western blot analysis
L6 myotubes were cultured in six-well plates and incubated with leptin (60 nmol/l) for 24 h. Cells were serum-starved for 4 h before stimulation with gAd (5 µg/ml) or fAd (5 µg/ml). Cell lysates were resolved by SDS-PAGE and transferred to a nitrocellulose membrane.
Co-immunoprecipitation
Cells were incubated with leptin (60 nmol/l) for 24 h and treated with gAd (5 µg/ml) or fAd (5 µg/ml). After treatment, cells were lysed with RIPA buffer (1% (vol./vol.) NP40, 0.5% (wt/wt) SDC, 0.1% (wt/wt) SDS in PBS buffer, pH 7.4) complemented with protease inhibitor mixture on ice. Non-soluble material was discarded after centrifugation (16,249 g for 5 min at 4°C) and the supernatant fraction was incubated overnight with 1 µg of mouse monoclonal LKB1 antibody. Then protein A sepharose beads (GE Healthcare Bio-Sciences, Baie d'Urfé, QC, Canada) were added and incubated for 3 h. After incubation, the beads were pelleted and washed. Beads were resuspended in SDS sample buffer, supplemented with 10% (vol./vol.) β-mercaptoethanol, then boiled for 5 min and subjected to western blot analysis using polyclonal antibody against APPL1.
Statistical analysis
Data are expressed as mean values ± SEM with number of repeats (n) stated in each case. Statistical analysis was undertaken using two-way ANOVA or the paired Student's t test where appropriate. Differences between groups were considered statistically significant at p < 0.05.
Results
Prevention of fAd- and gAd-stimulated glucose uptake by leptin in a time- and dose-dependent manner
We evaluated the effect of varying leptin concentrations (0.3, 0.6, 3, 6, 60 nmol/l) and pretreatment times (6, 12, 24 h) on the ability of fAd or gAd to stimulate 2-deoxy-d-[3H]glucose uptake. The concentrations of leptin were chosen, on the basis of published literature by our own and other groups, as those used to elicit physiological effects in cultured cells [30, 31]. Basal glucose uptake levels remained unchanged by all leptin concentrations (Fig. 1a, b). Both fAd (5 μg/ml, 2 h) and gAd (5 μg/ml, 2 h) elicited a statistically significant increase in glucose uptake under normal, 0.3 and 0.6 nmol/l leptin treatment conditions (Fig. 1a, b). Our data revealed that pretreatment of cells with leptin for 24 h inhibited fAd- or gAd-stimulated 2-deoxy-d-[3H]glucose uptake in a dose-dependent manner (Fig. 1a, b). A significant inhibitory effect was observed at 3, 6 and 60 nmol/l for fAd and gAd. When cells were incubated in 6 nmol/l leptin for 12 and 24 h, the stimulation of glucose uptake by fAd and gAd was prevented, whereas 6 h pretreatment with the same dose of leptin had no inhibitory effect (Fig. 1c, d).
Changes of AdipoR1 and AdipoR2 expression in response to leptin
We performed real-time quantitative PCR and western blotting to determine whether leptin (60 nmol/l, 24 h) regulated mRNA and protein levels of the ADIPOR isoforms. It was observed that leptin treatment reduced both mRNA expression and protein levels of ADIPOR1 and ADIPOR2 compared with normal growth conditions (Fig. 1e–h). Adipor1 mRNA expression (Fig. 1e) decreased by ~45%, whereas an approximate 50% reduction was observed for Adipor2 mRNA expression (Fig. 1g). Protein levels of each isoform decreased by about 60% (Fig. 1f, h).
Effect of fAd and gAd on fatty acid uptake and regulation by leptin
To examine long-chain fatty acid uptake in L6 cells, we measured [9,10-3H]palmitate uptake. This study demonstrated that both fAd and gAd (5 μg/ml, 6 h) significantly increased palmitate uptake (Fig. 2a, b). Pretreatment of cells with leptin (60 nmol/l, 24 h) did not alter basal fatty acid uptake levels, but did prevent the increase in palmitate uptake stimulated by fAd or gAd (Fig. 2a, b). Levels of several fatty acid transporters, including FATP1, FATP4 and CD36, were examined in response to fAd or gAd (5 μg/ml, 6 h). CD36 levels significantly increased after fAd or gAd treatment under normal, but not under leptin treatment conditions (Fig. 2c, d). No change of FATP1 and FATP4 levels was found in response to fAd and gAd (data not shown).
Regulation of AMPK by fAd and gAd and role in stimulation of fatty acid uptake
To clarify the regulation of AMPK by fAd and gAd, as well as the subsequent role of AMPK in mediating the increased fatty acid uptake, we introduced siRNA to reduce AMPKα expression and used compound C, a pharmacological inhibitor, to block AMPK activity. As shown in Fig. 3a, b, compound C clearly abrogated the ability of fAd and gAd (5 μg/ml, 6 h) to stimulate palmitate uptake. Use of siRNA lowered AMPKα1 and -2 expression by 70% (Fig. 3c) compared with cells transfected with a scrambled siRNA sequence; under these conditions stimulation of fatty acid uptake by fAd was attenuated (Fig. 3d). Indeed, fAd and gAd (5 μg/ml, 5 min and 15 min) were found to increase phosphorylation of AMPK under normal conditions but not after leptin treatment (60 nmol/l, 24 h) (Fig. 3e, f). AICAR has been showed to increase phosphorylation of AMPK through mimicking effects of AMP by its derivative 5-aminoimidazole-4-carboxamide-ribotide (AICAribotide; ZMP) [32, 33]. The phosphorylation of AMPK stimulated by AICAR was not affected by leptin treatment (Fig. 3g). We did not detect any significant effect of leptin (60 nmol/l, 24 h) on total levels of AMPKα1 and AMPKα2. Phosphorylation of AMPK was not significantly altered by leptin treatment under these conditions (data not shown).
Regulation of fatty acid oxidation by fAd and gAd in the absence or presence of leptin
Fatty acid oxidation was also examined in the absence or presence of leptin (60 nmol/l, 24 h). Under normal conditions, fAd and gAd (5 μg/ml, 6 h) stimulated palmitate oxidation, with AICAR (2 mmol/l, 6 h) used as a positive control in this assay (Fig. 4a, b). The ability of fAd and gAd to enhance palmitate oxidation was abolished by pretreatment of cells with leptin (Fig. 4a, b). Of note, leptin alone (60 nmol/l, 24 h) induced a slight decrease in levels of palmitate oxidation in L6 cells. Phosphorylation of ACC was also measured under similar conditions and an increased phosphorylation of ACC (Ser79), which correlates with decreased activity of this enzyme, was observed in response to fAd and gAd (5 μg/ml, 5 min and 15 min) (Fig. 4c, d). However, no significant difference was detected when cells were treated with leptin (Fig. 4c, d). Total ACC levels were unaltered by leptin (data not shown).
Effect of leptin on insulin-sensitising effects of fAd and crosstalk between adiponectin and insulin signalling
L6 myotubes were pretreated with fAd (5 μg/ml, 15 min) then treated with insulin (10 nmol/l, 5 min). As expected, insulin stimulated phosphorylation of IRS-1 (Tyr612) and Akt (Thr308), while no stimulation was observed in response to fAd alone (Fig. 5a). Importantly, the insulin-stimulated phosphorylation of IRS-1 and Akt was markedly enhanced in L6 cells pretreated with fAd (Fig. 5a). The adiponectin-enhanced insulin signalling was blunted by leptin treatment (60 nmol/l, 24 h) with the levels of IRS-1 and Akt phosphorylation returning to those induced in the presence of insulin alone (Fig. 5a). Using immunoprecipitation of LKB1 and western blotting for APPL1, we also found that fAd (5 μg/ml, 5 min and 10 min) stimulated the interaction of LKB1 with APPL1 (Fig. 5b) and that this interaction was abolished by leptin pretreatment (60 nmol/l, 24 h). LKB1 expression was not altered by leptin (±adiponectin) under the conditions used in these experiments (data not shown).
Discussion
Leptin and adiponectin are both important for the maintenance of appropriate insulin sensitivity and overall energy balance [3, 4, 34]. Changes in skeletal muscle insulin action play a central role in the development of metabolic changes in the metabolic syndrome, while, of particular relevance to this study, both leptin and adiponectin have been extensively documented to regulate basal and insulin-stimulated carbohydrate and fatty acid metabolism in skeletal muscle [35]. However, very little is known about their potential interaction in regulating metabolism in this tissue. In this study, we investigated whether high leptin levels, a condition commonly seen in human obesity, affected the ability of adiponectin to exert its metabolic effects in skeletal muscle cells.
We have revealed that high leptin concentrations exert a direct negative effect on insulin-stimulated glucose uptake in cultured L6 skeletal muscle cells [36, 37], suggesting that hyperleptinaemia could contribute to the development of insulin resistance. However, previous work demonstrated that leptin exposure did not alter insulin-stimulated glucose uptake in isolated rodent skeletal muscle, while enhanced insulin-stimulated glucose uptake was observed in high-fat fed rats with long term leptin administration [38–41]. A difference in leptin concentration and time of exposure to leptin could account for these observations. Here, we examined the effect of chronic leptin treatment on adiponectin-stimulated glucose uptake. Consistent with previous results from ourselves and others [7, 12, 25], we found that gAd and fAd increased glucose uptake in L6 skeletal muscle cells after 2 h treatment. Importantly, we demonstrate for the first time that this response was attenuated in the presence of leptin in a dose- and time-dependent manner. A statistically significant inhibitory effect was found at 3 nmol/l leptin and above. Although absolute leptin levels vary among normal and obese individuals, 3 nmol/l plasma leptin is in keeping with levels observed in obese individuals [42, 43]. The time-course experiment revealed that a prolonged pretreatment time (longer than 12 h) is necessary for leptin to exert an inhibitory effect.
Thus, to investigate potential underlying mechanisms, we first examined changes in levels of ADIPORs, of which two isoforms, ADIPOR1 and ADIPOR2, exist in skeletal muscle. ADIPOR1 and ADIPOR2 differ with respect to tissue distribution and affinity for adiponectin forms, with ADIPOR1 exhibiting a higher binding affinity for gAd and ADIPOR2 for fAd [8]. We have also previously documented that L6 cells express ADIPOR1 in a 6:1 ratio compared with ADIPOR2 [25]. We found that mRNA and protein levels of ADIPOR1 and ADIPOR2 were decreased after exposure of cells to leptin. The most simple interpretation of this observation is that there would be a corresponding reduction in the availability of these receptors to bind adiponectin and a subsequent decline in gAd-and fAd-stimulated effects. Many, but not all, studies in animal models [44] and humans [13, 14] have also suggested an important role for alterations in ADIPORs in the pathogenesis of insulin resistance and diabetes. Of particular interest, Adipor1 −/− mice showed increased adiposity associated with decreased glucose tolerance and energy expenditure, whereas Adipor2 −/− mice were lean and resistant to high-fat diet-induced obesity [44]. In human studies, Steinberg’s group has shown that skeletal muscle from obese or obese type 2 diabetic patients showed decreased sensitivity to gAd, yet ADIPOR1 levels were higher, suggesting that aspects downstream of the receptor may inhibit adiponectin action [13]. In contrast to our current study, others also found that leptin (2.5 μg/ml, 6 h) stimulated ADIPOR1 expression in myotubes derived from lean healthy individuals, but not in those derived from obese or obese diabetic patients [45]. Finally, exercise is a well-known effective therapeutic approach for treatment of diabetes, with current literature suggesting that although exercise does not tend to alter circulating adiponectin levels, there may be a correlation with increased skeletal muscle ADIPOR in exercised animals or humans [15]. Leptin, therefore, clearly has a capacity to regulate ADIPOR expression and under certain circumstances this may be of physiological importance.
A number of studies have indicated diminished fatty acid oxidation in skeletal muscle of obese and type 2 diabetic patients [46, 47]. The impaired capability of skeletal muscle to appropriately oxidise fatty acids may be associated with development of insulin resistance. Leptin has been shown to acutely stimulate fatty acid oxidation in C2C12 cells and primary human skeletal muscle cells [48, 49]. Here, we found that chronic leptin treatment had no effect on the basal fatty acid oxidation rate, which is consistent with a previous publication demonstrating no change of fatty acid oxidation in resting soleus muscle in response to chronic leptin administration [41]. Adiponectin has also been shown to mediate insulin-sensitising effects and one potential mechanism is the enhancement of skeletal muscle fatty acid uptake and oxidation, thus avoiding deleterious lipotoxicity [50]. We have previously shown that adiponectin stimulated fatty acid uptake in skeletal muscle cells [25]. Here, we provide evidence that the mechanism of increased fatty acid uptake after 6 h fAd or gAd treatment may involve increased expression of CD36. Furthermore, and as expected, we show that fAd and gAd phosphorylate AMPK at 5 and 15 min. For the first time, we also show that fAd- and gAd-stimulated fatty acid uptake is mediated via AMPK. Similar observations on the important role of AMPK in fatty acid transporter expression have been reported in cardiac myocytes and mouse skeletal muscle [51, 52]. Importantly, all of the above were attenuated when cells were pretreated with leptin. Although transient activation of AMPK was induced by leptin in skeletal muscle in vitro, there was no significant change in phosphorylation or total levels of AMPK after cells were treated with leptin for 24 h, indicating that lack of adiponectin action under these conditions was not simply due to an already elevated level of AMPK phosphorylation. Furthermore, AICAR-stimulated phosphorylation of AMPK was not affected by leptin at concentrations and times that inhibit adiponectin action, indicating the inhibitory effect of leptin on adiponectin is not non-specific and occurs upstream of AMPK. Our results also indicate that gAd and fAd stimulated ACC phosphorylation, causing inhibition of this enzyme and subsequent increases in palmitate oxidation, all of which were attenuated by leptin. Thus, it is clear from our in vitro studies that the normally beneficial effects of adiponectin leading to enhanced fatty acid uptake and oxidation are lost in the presence of high leptin levels and that this is conceivably of great pathophysiological significance in the development of insulin resistance in individuals with hyperleptinaemia and normal skeletal muscle leptin sensitivity.
Recent evidence has also indicated that adiponectin can improve insulin sensitivity via acute effects involving intracellular signalling pathway crosstalk. Initial studies identified APPL1 as a novel binding partner of AdipoRs in response to adiponectin stimulation and established a role for this protein in mediating nitric oxide production in endothelial cells [16] or in crosstalk with insulin signalling in C2C12 muscle cells [17]. Subsequent work demonstrated that the APPL1/LKB1/AMPK axis plays a vital role in mediating the insulin-sensitising effects of adiponectin [9], and most recently it was shown that APPL1 can release Akt trapped in a cytosolic localisation by its inhibitor TRB3, thereby promoting Akt activation by insulin [18]. Here, we demonstrate a significant synergistic effect on stimulation of IRS-1 (Y612) and Akt (T308) when cells were pretreated with fAd for 15 min followed by 5 min insulin treatment. Interestingly, pretreatment of cells with high leptin levels attenuated the insulin-sensitising function of fAd. Since we have shown that leptin attenuated adiponectin-stimulated AMPK phosphorylation and it has been shown that adiponectin sensitises insulin signalling via an LKB1/AMPK-dependent mechanism [9], we propose that blunting of adiponectin-stimulated AMPK phosphoryation by leptin and the synergistic effects of adiponectin on insulin signalling occur through inhibition of LKB1/AMPK activation. Therefore, we employed a co-immunoprecipitation approach to study the interaction of LKB1 with several signalling molecules potentially involved in adiponectin–insulin crosstalk. We saw that under normal conditions fAd increased binding of LKB1 to the upstream regulator APPL1 and that this interaction was blunted by the presence of leptin. Our data suggest that leptin inhibits AMPK stimulation by adiponectin probably via inhibited interaction between LKB1 and APPL1.
In summary, although it is well established that circulating adiponectin levels, particularly high molecular weight adiponectin, decrease in obesity, there is currently an increasing awareness of the potential development of adiponectin resistance in individuals exhibiting features of the metabolic syndrome [53]. Taken together, our data demonstrate that prolonged treatment of skeletal muscle cells with elevated leptin concentrations reduced adiponectin signalling and metabolic effects in skeletal muscle cells. Hence, our study indicates crosstalk between leptin and adiponectin signalling and action, and suggests that hyperleptinaemia may be an important contributory factor leading to adiponectin resistance in skeletal muscle, thus exacerbating the disturbed metabolic milieu.
Abbreviations
- ACC:
-
Acetyl-CoA carboxylase
- ADIPOR:
-
Adiponectin receptor
- AICAR:
-
5-Amino-4-imidazole carboxamide riboside
- AMEM:
-
Alpha modification Eagle’s medium
- AMPK:
-
AMP protein kinase
- APPL1:
-
Adapter protein containing a pleckstrin homology domain, phosphotyrosine binding (PTB) domain and leucine zipper motif
- fAd:
-
Full-length adiponectin
- FATP:
-
Fatty acid transport protein
- gAd:
-
Globular adiponectin
- HEK:
-
Human embryonic kidney
- LKB1:
-
Protein serine/threonine kinase
- siRNA:
-
Small interfering RNA
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Acknowledgements
Funding for this work was provided by The Canadian Institutes of Health Research (CIHR) via an operating grant and a New Investigator award to G. Sweeney. X. Fang acknowledges Doctoral Studentship support from The Heart and Stroke Foundation of Canada and The Canadian Diabetes Association.
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The authors declare that there is no duality of interest associated with this manuscript.
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Fang, X., Fetros, J., Dadson, K.E. et al. Leptin prevents the metabolic effects of adiponectin in L6 myotubes. Diabetologia 52, 2190–2200 (2009). https://doi.org/10.1007/s00125-009-1462-0
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DOI: https://doi.org/10.1007/s00125-009-1462-0