http://orcid.org/0000-0002-1151-1370
Figures
Abstract
Aims
FFA and FFA metabolites cause insulin resistance and impair beta cell function. The goal of our research was to examine whether elevation of plasma FFA impairs mitochondrial function and alters PGC-1α promoter methylation.
Methods
In this uncontrolled, change from baseline study design, insulin sensitivity and glucose-stimulated insulin secretion were measured in 9 normal glucose tolerant subjects before and after 3 day lipid infusion to elevate plasma FFA concentration. Vastus lateralis muscle biopsies were obtained and mitochondrial function, PGC-1α expression, and PGC-1α promoter methylation were quantitated.
Results
Increased plasma FFA (440±93 μmol/Lto 997±242 μM, p<0.001) decreased insulin-stimulated total glucose disposal (TGD) by 25% (p = 0.008), impaired suppression of endogenous glucose production (p = 0.01), and reduced mitochondrial ATP synthesis with complex 1 (34%, p<0.05) and complex 2 (30%, p<0.05) substrates. Lipid infusion had no effect on muscle PGC-1α RNA expression, total methylation or non-CpG methylation, but methylation of the alternative PGC-1α promoter decreased (1.30±0.30 to 0.84±0.15% methylated residues/patient•strand, p = 0.055). Within PGC-1α promoter there was demethylation of CpT residues (0.72±0.16 vs. 0.28±0.10 methylated residues/patient•strand) (p = 0.002), which was inversely correlated with PGC-1α mRNA expression (r = -0.94, p<0.0001) and ATP synthesis with complex 1 (r = -0.80, p<0.01) and complex 2 (r = -0.69, p<0.05) substrates. Lipid infusion increased DNMT-3B (methyltransferase associated with PGC-1α promoter non-CpG methylation) mRNA expression (0.87 ± 0.09 to 1.62 ± 0.22 arbitrary units, p = 0.005), which correlated inversely with CpT demethylation (r = 0.67, p<0.05).
Citation: Eldor R, Norton L, Fourcaudot M, Galindo C, DeFronzo RA, Abdul-Ghani M (2017) Increased lipid availability for three days reduces whole body glucose uptake, impairs muscle mitochondrial function and initiates opposing effects on PGC-1α promoter methylation in healthy subjects. PLoS ONE 12(12): e0188208. https://doi.org/10.1371/journal.pone.0188208
Editor: Víctor Sánchez-Margalet, Virgen Macarena University Hospital, School of Medicine, University of Seville, SPAIN
Received: June 7, 2017; Accepted: November 2, 2017; Published: December 20, 2017
Copyright: © 2017 Eldor et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: All relevant data are within the paper and its Supporting Information files.
Funding: This study was supported by an NIH grant (R01 DK097554-01) to MAG, and (NIH-DK 24092-42) to RAD. Furthermore, RAD received research support from the following: Bristol Myers Squibb, Boehringer-Ingelheim, Takeda, and Astra Zeneca. Dr. Ralph A. DeFronzo’s salary is supported, in part, by the South Texas Veterans Health Care System. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: RAD has the following competing interests - Advisory Board: Astra Zeneca, Novo Nordisk, Janssen, Intarcia, Boehringer-Ingelheim; Research Support: Bristol Myers Squibb, Boehringer-Ingelheim, Takeda, Astra Zeneca; Speaker’s Bureau: Novo-Nordisk, Astra Zeneca. Other authors have no conflict of interest. This does not alter our adherence to PLOS ONE policies on sharing data and materials. There are no restrictions in sharing data and/or materials.
Introduction
Insulin resistance is a key pathophysiologic derangement in type 2 diabetes mellitus (T2DM) and is strongly associated with obesity [1]. Lipotoxicity plays a pivotal role in development of insulin resistance [2–4]. Studies from our laboratory and others have shown that acute exposure (2–6 hour) to supraphysiological plasma free fatty acid (FFA) levels (increased to 5–10 fold above fasting levels) reduced insulin sensitivity in healthy individuals and in individuals with T2DM [5–9]. However, the clinical relevance of these experiments was limited since FFA levels in healthy individual under normal living conditions rarely rise to such high levels. A more clinically relevant approach is to increase the plasma FFA level to the high physiologic range as seen in T2DM and obese individuals [9]) for longer a period of time (2–4 days). We have shown that this results in both an increase in insulin resistance in healthy individuals [10] and impaired insulin secretion in genetically predisposed, normal-glucose-tolerant (NGT) individuals[11]. Conversely, sustained plasma FFA reduction with acipimox in NGT subjects with strong family history of T2DM and in obese NGT and T2DM subjects enhances insulin-mediated muscle glucose disposal and suppression of hepatic glucose production [12, 13].
In vivo and ex vivo studies [14–16] have demonstrated impaired mitochondrial function in skeletal muscle of insulin resistant individuals. We have shown that reduction in plasma FFA with acipimox improves mitochondrial ATP synthesis rate by >50% (7). The increase in ATP synthesis rate correlated closely with the decrease in plasma FFA and increase in insulin-mediated glucose disposal.
A potential link between lipotoxicity and mitochondrial dysfunction may be peroxisome proliferator-activated receptor γ co-activator 1α (PGC-1α) which plays a central role in regulating skeletal muscle mitochondrial function and biogenesis in response to changes in plasma and intracellular lipid levels [17, 18]. We previously have shown that lipid infusion for 48- hours resulted in a decrease in PGC-1α mRNA expression [19]. Hypermethylation of the PGC-1α promoter was identified in a genome-wide analysis screening for differential promoter DNA methylation in T2DM [20]. PGC-1α promoter methylation has been implicated in development of mitochondrial dysfunction following an increase in plasma/intracellular lipid levels. In low birth weight subjects, high-fat overfeeding caused peripheral insulin resistance, reduced PGC-1α gene expression, and increased PGC-1α promoter methylation at sequence CpG sites. However, PGC-1α promoter methylation did not correlate with PGC-1α mRNA expression [21]. In skeletal muscle of T2DM individuals increased methylation of non-CpG nucleotides of PCG-1α promoter was negatively correlated with PGC-1α mRNA expression and responsive to acute ex vivo FFA exposure, but not to insulin [20].
We hypothesized that mitochondrial dysfunction could be induced in healthy NGT individuals by short-term increased lipid availability and that PGC-1α promoter methylation played a pivotal role in mediating this negative interaction. The aim of our research was to examine whether elevation of plasma FFA impairs mitochondrial function and alters PGC-1α promoter methylation.
Methods
Subjects
Eleven subjects were recruited between July 2007 and February 2009. Two subjects withdrew consent during the study and nine healthy normal glucose tolerant (NGT) subjects [4 females/5 males; age = 37.2±3.2 years (range 22–40 years); BMI = 23.6 ± 1.2 kg/m2; FPG = 99±3 mg/dl] completed the study. All subjects had a normal 2-hour OGTT. Body weight was stable (±2 lbs) over 3 months prior to study and no subject participated in an excessively heavy exercise program. Routine screening blood tests, urinalysis, thyroid function, and EKG were normal. Protocol was approved by Institutional Review Board of University of Texas Health Science Center at San Antonio and informed written consent was obtained before participation.
Study design
After screening, eligible subjects received: (i) 4-hour euglycemic insulin clamp (80 mU/m2min) with vastus lateralis muscle biopsies before the start of insulin clamp, (ii) 2-step hyperglycemic clamp (+100 and +300 mg/dl), (iii) DEXA scan. After completing baseline studies, subjects were admitted to the CRC and received intravenous 20% neutral triglyceride solution (Liposyn III; Hospira Inc., Lake Forest, IL) containing 54.5% linoleic, 22.4% oleic, 10.5% palmitic, 4.2% stearic, and 8.3% linolenic acid (1 ml/minute) for 4 days and heparin (0.2 units per kilogram per min) on days 1 and 2 [22]. On days 3 and 4, euglycemic insulin and hyperglycemic clamp studies [23] were repeated.
OGTT
A catheter was placed into an antecubital vein and blood samples were collected at –30, –15, 0, 30, 60, 90 and 120 min for measurement of plasma glucose, insulin, C-peptide and FFA.
Dual X-ray absorptiometry
Dual X-ray absorptiometry (Hologic Inc., Waltham, MA) was performed to measure fat and fat-free mass (FFM).
Euglycemic insulin clamp [23]
Following 10-hour overnight fast, a catheter was placed into antecubital vein for infusion of all test substances. A second catheter was inserted retrogradely into vein on dorsum of hand which was placed into a thermoregulated box heated to 70°C. At 0800 hours, participants received prime (40 μCi × fasting plasma glucose/90)–continuous (0.40 μCi/min) infusion of [3-3H] glucose (DuPont NEN Life Science, Boston, MA). After 2-hour basal tracer equilibration period, participants received prime–continuous insulin infusion at 240 pmol•min−1•m−2 (80 mU•min−1•m−2) for 240 min. During last 30 min of basal equilibration period, plasma samples were taken at 5–10 min intervals for determination of plasma glucose and insulin concentrations and [3H] glucose radioactivity. During insulin infusion, plasma glucose was measured every 5 minutes, and variable infusion of 20% glucose was adjusted to maintain plasma glucose at each participant’s fasting level with coefficient of variation <5%. Plasma samples were collected every 5–15 min for determination of plasma glucose and insulin concentrations and [3H] glucose radioactivity.
Muscle biopsies
Sixty minutes before insulin clamp, percutaneous vastus lateralis muscle biopsy (∼300 mg) was obtained [24]. Muscle biopsy was placed in buffer on ice for mitochondrial isolation and measurement of mitochondrial ATP synthesis and ROS production rate.
Hyperglycemic clamp [23]
Following 10-hour overnight fast, a catheter was placed into antecubital vein for infusion of all test substances. A second catheter was inserted retrogradely into vein on dorsum of hand, and hand was placed into thermoregulated box heated to 70°C. After obtaining three baseline samples, plasma glucose was rapidly raised and maintained by +100 mg/dL above fasting for 120 minutes and then by +300 mg/dL for an additional 90 minutes with variable infusion of 20% glucose. At 210 minutes, a 5 gram bolus of arginine was infused over 1 minute while maintaining plasma glucose constant for another 30 minutes. Blood samples were collected at -30,−20, −10, 0, 2, 4, 6, 8, 10, 12, 15, 30, 45, 60, 75, 90, 100,110, 120, 122, 124, 126, 128, 130, 135, 150, 165, 180, 190, 200, 210, 212, 214, 216, 218, 220, 225, 230 and 240 minutes for measurement of plasma insulin and C-peptide concentrations.
Analytical techniques
Plasma glucose was measured by glucose oxidase reaction (Glucose Oxidase Analyzer; Beckman, Fullerton, CA). Plasma insulin was measured by radioimmunoassay (Coat A Count; Diagnostic Products, Los Angeles, CA). Tritiated glucose-specific activity was determined on deproteinized barium/zinc plasma samples. Plasma FFA was measured by enzymatic colorimetric method (Wako Chemicals, Neuss, Germany).
Mitochondrial purification
Mitochondria were purified from muscle tissue as previously described [25]. Mitochondrial integrity was assessed by respiratory control ratio (>6 with pyruvate) at end of each experiment. All procedures were performed on ice and entire isolation procedure lasted ~ 60 min. Final mitochondrial solution was kept on ice and used immediately following isolation.
Mitochondrial ATP production
Mitochondrial ATP synthesis rate was measured ex vivo with chemiluminescence technique as previously described [13]. Briefly, mitochondria were isolated from fresh muscle tissue by differential centrifugation. 4 μg of mitochondrial protein was aliquoted to each reaction well. Substrates were added as follows: 2.5 mM pyruvate, 2.5 mM glutamate, 5 mM succinate plus 0.001 mM rotenone, 0.5 mM palmitoyl-L-carnitine. 2.5 mM malate was added to complex I substrates. Luciferine/luciferase was added to monitor ATP production. After 5 minute incubation at 37°C, substrates were added and reaction was started by addition of adenosine diphosphate (ADP) [25].
Mitochondrial ROS production
The rate of mitochondrial ROS production was measured by quantitation of the release of mitochondrial H2O2 with the fluorescent dye Amplex Red (Molecular Probes, Eugene, OR) as previously described [14]. ROS production rate was performed in mitochondria under state II (with substrate and without the addition of ADP) conditions. The substrate concentrations were the same as with the measurement of ATP synthesis. Fluorescence was observed at 530 nm excitation and 590 nm emission for 5 min. The slope in fluorescence was converted to the H2O2 production rate using a standard curve [15].
Bisulfite sequencing
Bisulfite treatment was performed using EpiTect Bisulfite Kit (QIAGEN) according to manufacturer’s protocol. DNA was extracted from a fragment of the vastus lateralis muscle obtained by biopsy. For amplification of region from 337 to 37 of PGC-1α promoter, the following primers were used: sense 50 TAT AGT TAT TTT GTT ATG AAA TAG GGA GTT TT G 30; antisense 50 CCA ATC ACA TAA CAA AAC TAT TAA AAA ATA A 30. For amplification of the region from 243 to 47 of the alternative PGC-1α promoter, the following primers were used: sense 50 ATA GGG TTG TTG GAA AGT ATA TGA TAT T 30; antisense 50 AAA AAA CAC TCA CAA CAA AAA CTT C 30. The obtained PCR fragments were purified from agarose gel using MinElute Gel Extraction Kit (QIAGEN) and cloned using pGEM®-T Easy vector system (Promega), according to manufacturer’s protocol. Individual clones were grown and plasmids purified using QIAprep Spin Miniprep Kit (QIAGEN) and EcoR1 Fast Digest restriction enzyme (Thermo Fisher Scientific, Rockford, IL). For each condition, 10–15 clones were sequenced using T7 promoter primer on ABI 3730xl DNA Analyzer platform (Cogenics, Hope End, UK).
Quantitative PCR
Total RNA was isolated using TRIZOL reagent (Sigma-Aldrich, St Louis, MO). One-step RT-PCR was performed on ABI-Prism-7900HT System (Applied Biosystems, Foster City, CA). mRNA levels were normalized to HMBS. Primers were designed using Primer Express computer software (Applied Biosystems).
Statistical analysis and calculations
Following an overnight fast, steady-state conditions prevail and endogenous glucose production (EGP) was calculated as [3H] glucose infusion rate (dpm/min) divided by steady state plasma [3H] glucose specific activity (dpm/mmol). During insulin clamp, non-steady-state conditions for [3H] glucose specific activity prevail, and rate of glucose appearance (Ra) was calculated with Steele’s equation [26]. Rate of residual EGP during insulin clamp was calculated by subtracting exogenous glucose infusion rate from tracer-derived Ra. Insulin-stimulated total glucose disposal (TGD) rate was calculated by adding rate of residual EGP to exogenous glucose infusion rate.
ATP synthesis rate was measured as slope of chemi-luminescence over time. Slope of the blank well (mitochondria without substrate) was subtracted from slope obtained with any given substrate, and normalized per mg mitochondrial protein per min. Rate of H2O2 production was measured as slope of fluorescence over time. Slope of blank well was subtracted from slope obtained with any given substrate and normalized per mg mitochondrial protein per min. Methylation was calculated as mean of percent methylated cytosine residues from total and specific combinations of residues per patient.
Values are presented as mean ± standard error. For comparison of values obtained during insulin clamp performed with and without Liposyn infusion, ANOVA was used. Simple Pearson correlation was used to assess correlation between variables. Statistical analyses were performed with SPSS (version 14) (SPSS, Chicago, IL). Statistical significance was considered at p<0.05. Statistical significant differences were confirmed by Bonferroni test.
Results
Plasma FFA concentration
Baseline fasting plasma FFA concentration was 440±93 μmol/L. 72-hours of Liposyn infusion increased plasma FFA ~2-fold (997±242 μM, p<0.001).
Insulin sensitivity in muscle and liver
3-day physiologic increase in plasma FFA increased basal fasting (pre-clamp) insulin levels from 3.6± 0.7 to 7.0 ± 0.9 mIU/ml (S1a Fig, p<0.001), reduced insulin-stimulated TGD from 12.1±1.0 to 9.2±1.2 mg/kg•min (p = 0.01) (Fig 1a), while insulin-induced suppression of endogenous glucose production was impaired (0.10±0.10 vs. 0.63±0.21 mg /kg•min p = 0.008) (Fig 1b and S1 Fig).
a: insulin-stimulated total body glucose disposal (TGD) and b: suppression of endogenous glucose production (EGP) during the euglycemic insulin clamp. n = 9, *p<0.05. c: Plasma insulin concentration following an overnight fast and during the two-step hyperglycemic clamp (+125 and +300 mg/dL) with arginine. n = 9, *p<0.05.
Glucose-stimulated insulin secretion
The fasting plasma insulin concentration, as well as the plasma insulin response during all hyperglycemic clamp steps (+125mg/dL, +300 mg/dL and arginine), were higher after Liposyn infusion (but did not reach statistical significance during the +300 mg/dL step): fasting (2.3±0.7 vs. 4.0±0.7 μIU/ml, p = 0.03); +125mg/dL (time 90-120min: 37±5 vs. 51±7 μIU/ml; p = 0.01); +300mg/dL (time 90-120min: 154±21 vs. 180±26 p = 0.10); and after arginine (428±35 vs. 476±29 uU/ml; p = 0.01) (Fig 1c and S2 Fig), indicating the normal physiologic response to the insulin resistance associated with Liposyn infusion. The lack of statistical significance in insulin secretion in the 2nd hyperglycemic clamp step may be due to the relatively small number of subjects in this study or perhaps to a specific mechanism by which extreme hyperglycemia may overcome the Liposyn mediated increase in glucose stimulated insulin secretion. We previously have shown in a similar study that prolonged Liposyn infusion to produce a physiologic increase in the plasma FFA concentration results in a significant increase in insulin secretion during the 2nd phase of the hyperglycemic clamp in NGT individuals [11].
Mitochondrial ATP synthesis
Due to technical problems, mitochondrial ATP synthesis was not tested in 1 of the 9 subjects and ATP synthesis data are presented on 8 subjects. FFA-induced insulin resistance was accompanied by reduced mitochondrial ATP synthesis with complex 1 (by ~ 34±9%, p<0.05) and complex 2 (by 30±5%, p<0.05) substrates (Fig 2a). When results obtained from men and women were analyzed separately the trend towards reduced mitochondrial function did not change. Mitochondrial ROS generation was significantly lower with pyruvate and glutamate, but not with palmitoyl-L-carnitine or succinate (Fig 2b).
a: Rate of mitochondrial ATP production with complex I substrates 2.5 mM pyruvate (Pyr), 2.5 mM glutamate (Glu), 0.5 mM palmitoyl-L-carnitine (PC) and the complex II substrate 5 mM succinate plus 0.001 mM rotenone (Suc) (*p = 0.002, **p = 0.004, ***p = 0.001, †p = 0.005 paired student’s t-test). b: Rate of mitochondrial hydrogen peroxide production with complex I substrates 2.5 mM pyruvate (Pyr), 2.5 mM glutamate (Glu), 0.5 mM palmitoyl-L-carnitine (PC) and the complex II substrate 5 mM succinate plus 0.001 mM rotenone (Suc) (*p = 0.02, **p = 0.03, paired student’s t-test). c: Correlation between change in individual subject mitochondrial complex I function (ΔATP synthesis with pyruvate) and change in individual subject PGC-1α mRNA expression (Δ PGC-1α mRNA expression) following lipid infusion. Results are from 8 subjects with available data. PGC-1α mRNA expression was assessed by real time rtPCR. PGC-1α levels were corrected for HMBS gene expression. Complex I function was measured by ATP synthesis with pyruvate. p = 0.03 one-tailed Pearsons correlation.
PGC-1α expression
Mean skeletal muscle PGC-1α mRNA expression of the complete cohort did not change significantly following Liposyn infusion (0.83±0.08 vs. 0.73±0.10) (n = 9). However, the change in PGC-1α mRNA expression levels in individual subjects correlated positively (r = 0.69, p = 0.03, one-tailed Pearsons correlation) with the change in pyruvate-induced mitochondrial ATP synthesis following lipid infusion (Fig 2c). Higher levels of PGC-1α mRNA expression were associated with a smaller reduction in ATP synthesis in response to increased lipid availability. These observations align with previous publications suggesting a decline in mitochondrial ATP synthesis in response to lipid exposure [25]) and an association between PGC-1α expression and mitochondrial ATP synthesis [27–29].
PGC-1α promoter methylation
Lipid infusion had no effect on total PGC-1α promoter methylation or on non CpG methylation, while there was a non-statistically significant trend towards reduced methylation of the alternative PGC-1α promoter (0.84±0.15% vs. 1.29±0.29% methylated residues/patient•strand, p = 0.055) (Fig 3a and 3b). When the following specific cytosine residue combinations (CpG, CpC, CpT, CpA) in PGC-1α promoter were examined, a significant decrease in CpT methylation was demonstrated (0.28±0.09% vs. 0.72±0.16% methylated residues/subject, p = 0.002) (Fig 3c and S3 Fig)] with no change in CpT methylation in Alt- PGC-1α promoter (Fig 3d). The decrease in CpT methylation was observed both in men and women when each group was analyzed separately. Reduction in CpT methylation was inversely correlated with the individual change in PGC-1α mRNA expression (r = -0.94, p<0.0001) (Fig 4a), suggesting an inhibitory effect of CpT methylation on PGC-1α mRNA expression. A similar trend with high r values was obtained when samples from men and women were analyzed separately (r = 0.946 men and r = 0.939 in women). Similarly, change in CpT methylation correlated negatively with lipid-associated reduction in ATP synthesis by mitochondrial complex 1 activity (ATP synthesis with pyruvate; r = -0.80, p<0.01) (Fig 4b) and complex 2 activity (ATP synthesis with succinate plus rotenone; r = -0.69; p = 0.03) (Fig 4c). Thus, CpT de-methylation during prolonged FFA exposure was associated with preservation of mitochondrial ATP synthesis. It is notable that the two subjects with minimal or no change in CpT methylation are the subjects with the greatest change in PGC-1α mRNA expression and the greatest decline in mitochondrial complex 1 activity. While these individuals may be considered outliers, their response during the insulin clamp studies, their plasma FFA levels, and other physiologic parameters did not differ from the rest of the cohort. Because of the consistent response with respect to methylation, gene expression and mitochondrial function assays, we believe that the results in these 2 subjects represent a physiologic response to lipid exposure. Correlation beteween CpT methylation and mitochondrial H2O2 production was less consistent; while a significant negative correlation was noted with the complex 1 substrates glutamate (r = -0.66, p = 0.038) and palmitoyl-L-carnitine (r = -0.865, p = 0.003), no correlation was observed with pyruvate and the complex 2 substrate succinate (S4 Fig).
a: Change in % methylation/strand of all cytosine residues in PGC-1α (left) and b: alternative PGC-1α (right) promoters (n = 9). Alternative PGC-1α p = 0.055 vs baseline study without Liposyn infusion. c,d: Change in % methylation of each cytosine residue combination in the PGC-1α promoter before and after lipid infusion. c: % methylation of specific cytosine-residue combinations relative to total cytosine residues in the amplified strand (CG-4; CA-21; CT-29; CC-9) (n = 9). *p = 0.002 for CT methylation. d: % methylation of specific cytosine-residue combination relative to total cytosine residue combinations in the amplified strand (n = 9).
a: Correlation between the change in CpT methylation in the PGC-1α promoter and PGC-1α mRNA expression following prolonged (3 day) lipid infusion (n = 9) (r = -0.94, p<0.0001). b: Correlation between the change in CpT methylation in the PGC-1α promoter and change in mitochondrial Complex I function following prolonged lipid infusion (n = 8). Complex I function was measured by ATP synthesis with pyruvate (r = -0.80, p<0.01). c: Correlation between the change in CpT methylation in the PGC-1α promoter and change in mitochondrial Complex II function following prolonged lipid infusion (n = 8). Complex II function was measured by ATP synthesis with succinate + the complex I inhibitor rotenone (r = -0.69, p = 0.03). d, e: Real-time PCR analysis of DNMT-3B and DNMT-1 change in expression after lipid infusion. RNA was extracted from vastus lateralis muscle biopsies obtained at baseline and after lipid infusion for 72 hours. Results are shown as fold induction normalized to HMBS values. *p = 0.005 for change in DNMT-3B expression level between baseline and Liposyn exposure. p = 0.27 for change in DNMT-1 expression level between baseline and Liposyn exposure. n = 9. f: Correlation between the change in CpT methylation in the PGC-1α promoter and DNMT-3B mRNA expression following prolonged lipid infusion amongst a subset of “responders” (7 of 9 subjects excluding two subjects who had minimal or no CpT demethylation), (n = 7). DNMT-3B mRNA expression was assessed by real time rtPCR and corrected for HMBS gene expression (r = 0.67, p<0.05).
In mammals, three DNA methyltransferases have been identified: DNMT-1 is considered to be a maintenance DNA methyltransferase, while DNMT-3A and DNMT-3B contribute to de novo DNA methylation [30]. In skeletal muscle from NGT and T2DM subjects, quantitative analysis of DNMT isoforms using RT-PCR revealed an increase in mRNA expression of DNMT3B in T2DM versus NGT subjects while DNMT1 and DNMT3A did not change. Consistent with this, we measured DNMT-3A in 5 subjects (corrected for 18S) and failed to observe any change from baseline (0.83 ± 0.43, p = 0.19 arbitrary PCR units). Liposyn infusion resulted in significant increase in DNMT-3B expression (1.61 ± 0.22 to 0.87 ± 0.09 arbitrary PCR units relative to HMBS expression, p = 0.005) without change in DNMT-1 expression (1.09 ± 0.19 vs. 0.96 ± 0.15 arbitrary PCR units relative to HMBS expression, p = NS) (Fig 4d and 4e). In an ex vivo human skeletal muscle model, DNMT-3B silencing with siRNA prevented palmitate-induced down regulation of PGC-1α mRNA expression [20]. Amongst a subset of “responders” (7 of 9 subjects, excluding the two subjects mentioned above who had minimal or no change in CpT methylation), a greater increase in individual DNMT-3B expression correlated with less Liposyn-induced CpG demethylation (i.e. demethylation of the PGC-1α promoter was lower in subjects in whom DNMT3B mRNA expression was higher) (Fig 4f) (p = 0.04, r = 0.67). A non-statistically significant inverse trend was noted between DNMT-3B expression and change in individual PGC-1α expression level (p = 0.07, r = 0.60).
Lastly, we combined all values obtained at baseline and during Liposyn treatment, looking for correlation between absolute levels of methylation, PGC-1α and DNMT-3B mRNA expression levels and mitochondrial ATP production with complex 1 and complex 2 substrates. %CT methylation/site strand was significantly and negatively correlated with DNMT-3B mRNA expression (S4e Fig r = -0.48, p = 0.02) and ATP production with complex 1 substrates was correlated with ATP production with complex 2 substrates (r = 0.902, p<0.001)
Discussion
The lipotoxic effect of elevated plasma FFA and intracellular lipid metabolites (FACoAs, diacylglycerol, ceramides) on insulin sensitivity in muscle/liver and beta cell function is well established (2–4). We previously demonstrated that increased lipid availability impairs insulin signaling and decreases insulin-mediated glucose disposal in lean NGT individuals [22]. Conversely, reduced lipid availability improves insulin-mediated glucose disposal in NGT obese and T2DM individuals [12, 13, 31, 32]. The present results confirm these observations by demonstrating reduced peripheral and hepatic insulin sensitivity (Fig 1a and 1b) in response to chronic (3 day) lipid infusion and extends these results by demonstrating that a physiologic increase in plasma FFA reduces skeletal muscle mitochondrial ATP synthesis.
PGC-1α plays a central role in muscle mitochondrial biogenesis and function in response to external stimuli [18]. A possible mechanism via which PGC-1α mediates this interaction is through regulation of PGC-1α expression via modification of PGC-1α promoter methylation. In healthy subjects, acute exercise causes demethylaton of PGC-1α promoter in skeletal muscle, resulting in dose-dependent increase in PGC-1α mRNA expression [33]. Conversely, increased PGC-1α promoter methylation was observed in skeletal muscle of diabetic subjects and in myotubes exposed to palmitate ex vivo. Of note, the increase in methylation occurred primarily in non-CpG residues and was associated with an increase in DNMT-3B expression [20].
Therefore, we examined the in vivo effect of a chronic (72-hour) physiologic increase in lipid availability on PGC-1α promoter methylation in NGT subjects. Despite lack of effect on total PGC-1α methylation or CpG residue methylation, we observed a significant reduction in CpT residue methylation, which correlated with both PGC-1α mRNA expression levels (Fig 4a) and parameters of mitochondrial oxidative function (Fig 4b and 4c). DNMT-3B levels increased after lipid infusion and were correlated with preserved methylation of CpT residues. Thus, subjects with greater CpT demethylation in response to lipid infusion had greater expression of PGC-1α mRNA and relatively preserved mitochondrial function. In contrast, subjects with a greater increase in DNMT-3B levels following lipid infusion manifested reduced CpT demethylation (Fig 4f). A similar and negative correlation between absolute values of %CT methylation/site strand and DNMT-3B mRNA expression levels was observed (this analysis was conducted on absolute, combined baseline and Liposyn values).
The alternative PGC-1α promoter recently has been identified approximately 13.7kb upstream of originally identified PGC-1α promoter and yields alternative transcripts which are present at much lower levels [34]. Interestingly, methylation of the alternative PGC-1α promoter was similar between healthy individuals and individuals with T2DM and expression of it’s specific isoform, despite rapidly increasing after exercise was not associated with changes in DNA methylation in a mouse skeletal muscle [20, 35, 36]. In our study, a non-statistically significant trend towards reduced methylation was noted in the alternative PGC-1α promoter and no change in individual residue methylation levels was observed.
These results suggest two opposing responses to increased lipid availability in healthy NGT subjects:
- a previously undescribed ‘protective’ mechanism via which elevated plasma FFA/intramyocellular lipids cause PGC-1α promoter CpT demethylation, preserved PGC-1α mRNA expression and preserved mitochondrial function. The enzymatic process leading to demethylation is poorly defined but may involve Tet catalyzed oxidation followed by decarboxylation of methylcytosine [37] or activation of cytidine deaminase or apolipoprotein B mRNA editing enzyme 1 [38].
- The above sequence is opposed by an increase in DNMT-3B expression, which preserves (increases) CpT methylation and decreases PGC-1α mRNA expression. This is supported by the observation that absolute levels of DNMT-3B were higher when absolute %methylation levels of the PGC-1α promoter were lower. The strong correlative relationships between these opposing processes support this hypothesis. We hypothesize that the insulin resistant, obese diabetic phenotype emerges when the DNMT-3B-mediated increase in PGC-1α promoter methylation and subsequent mitochondrial dysfunction outweighs the beneficial effect of PGC-1α promoter demethylation and preservation of mitochondrial function.
Environmental-induced changes in non-CpG methylation in mammals have been described in human and murine mitochondrial DNA control regions (D-loop) [39] and in adult murine brains in regions with low CpG density [40]. The later is similar to the area we examined in the PGC-1α promoter. Functionally, non-CpG methylation is responsive to environmental changes and exerts an inhibitory effect on gene expression [40]. Thus, myotubes exposed ex vivo to palmitate for 48-hours demonstrate increase PGC-1α promoter mRNA, non-CpG methylation and PGC-1α expression [20]. Conversely, total non-CpG methylation declined in murine aortic genomic DNA after prolonged diet-induced hyperlipidemia [41]. In our study we demonstrated significant changes in CpT methylation without overall effect on total methylation. This may be explained, in part, by the relative abundance of CpT sites in the PGC-1α promoter relative to other potential methylation sites (29 CpT sites vs. 4 CpG sites; 21 CpA sites and 9 CpC sites) by an as-of-yet undefined CpT specific process, by species differences, i.e. human vs murine, or by the intervention, i.e. lipid infusion.
The present study has several limitations including the relatively small number of subjects, variability between subjects, the lack of control group and the “short” exposure time to increased lipid availability. With respect to the later, the obese T2DM phenotype develops after many years of excess caloric intake. However, with this limitation in mind, our study provides insight into the very early stages of the interaction between excess lipid intake and mitochondrial DNA methylation in development of the obese diabetic phenotype at an early pathophysiologic stage, before overt lipid-associated insulin resistance emerges. As such, these observations provide novel insights that may hold the key to preventing and overcoming the rampant diabetes/obesity pandemic.
Supporting information
S1 Fig. Hyperinsulinemic euglycemic clamp data.
a: pre-clamp fasting insulin levels. p<0.001 n = 9. b: Time course plot of plasma insulin concentrations during the hyperinsulinemic euglycemic clamp. c: Time course plot of plasma glucose concentrations during the hyperinsulinemic euglycemic clamp. d: Basal hepatic glucose production at baseline and after Liposyn treatment.
https://doi.org/10.1371/journal.pone.0188208.s001
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S2 Fig. Two-step hyperglycemic clamp (+125 and +300 mg/dL) with arginine data.
a: Time course plot of plasma glucose concnetrations. b-d: Time course plot of plasma insulin concnetrations during the 1st, 2nd and arginine steps of the clamp.
https://doi.org/10.1371/journal.pone.0188208.s002
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S3 Fig. Individual subject change from baseline in %CT methylation/site strand in the PGC-1α promoter after Liposyn exposure.
https://doi.org/10.1371/journal.pone.0188208.s003
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S4 Fig. Correlation between the change in CpT methylation in the PGC-1α promoter, and mitochondrial H2O2 production function.
a-d: Correlation between the change in CpT methylation in the PGC-1α promoter and change in mitochondrial Complex I and complex II H2O2 production following prolonged lipid infusion (n = 8). e: Correlation between absolute DNMT-3B mRNA expression levels and absolute %CT methylation/site strand in the PGC-1α promoter (data was combined from baseline and post Liposyn exposure)
https://doi.org/10.1371/journal.pone.0188208.s004
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Acknowledgments
We would like to thank Jim King RN, for his excellent care of the patients. We thank Lorrie Albarado for their expert secretarial assistance in preparation of the manuscript.
This study was supported by an NIH grant (R01 DK097554-01) to MAG, and (NIH-DK 24092–42) to RAD. Furthermore, RAD received research support from: Bristol Myers Squibb, Boehringer-Ingelheim, Takeda, and Astra Zeneca. Dr. Ralph A. DeFronzo’s salary is supported, in part, by the South Texas Veterans Health Care System. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
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