Gestational Diabetes Is Characterized by Reduced Mitochondrial Protein Expression and Altered Calcium Signaling Proteins in Skeletal Muscle

Kristen E. Boyle; Hyonson Hwang; Rachel C. Janssen; James M. DeVente; Linda A. Barbour; Teri L. Hernandez; Lawrence J. Mandarino; Martha Lappas; Jacob E. Friedman

doi:10.1371/journal.pone.0106872

Abstract

The rising prevalence of gestational diabetes mellitus (GDM) affects up to 18% of pregnant women with immediate and long-term metabolic consequences for both mother and infant. Abnormal glucose uptake and lipid oxidation are hallmark features of GDM prompting us to use an exploratory proteomics approach to investigate the cellular mechanisms underlying differences in skeletal muscle metabolism between obese pregnant women with GDM (OGDM) and obese pregnant women with normal glucose tolerance (ONGT). Functional validation was performed in a second cohort of obese OGDM and ONGT pregnant women. Quantitative proteomic analysis in rectus abdominus skeletal muscle tissue collected at delivery revealed reduced protein content of mitochondrial complex I (C-I) subunits (NDUFS3, NDUFV2) and altered content of proteins involved in calcium homeostasis/signaling (calcineurin A, α1-syntrophin, annexin A4) in OGDM (n = 6) vs. ONGT (n = 6). Follow-up analyses showed reduced enzymatic activity of mitochondrial complexes C-I, C-III, and C-IV (−60–75%) in the OGDM (n = 8) compared with ONGT (n = 10) subjects, though no differences were observed for mitochondrial complex protein content. Upstream regulators of mitochondrial biogenesis and oxidative phosphorylation were not different between groups. However, AMPK phosphorylation was dramatically reduced by 75% in the OGDM women. These data suggest that GDM is associated with reduced skeletal muscle oxidative phosphorylation and disordered calcium homeostasis. These relationships deserve further attention as they may represent novel risk factors for development of GDM and may have implications on the effectiveness of physical activity interventions on both treatment strategies for GDM and for prevention of type 2 diabetes postpartum.

Citation: Boyle KE, Hwang H, Janssen RC, DeVente JM, Barbour LA, Hernandez TL, et al. (2014) Gestational Diabetes Is Characterized by Reduced Mitochondrial Protein Expression and Altered Calcium Signaling Proteins in Skeletal Muscle. PLoS ONE 9(9): e106872. https://doi.org/10.1371/journal.pone.0106872

Editor: Mauro Salvi, University of Padova, Italy

Received: May 8, 2014; Accepted: August 4, 2014; Published: September 12, 2014

Copyright: © 2014 Boyle 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: The authors confirm that all data underlying the findings are fully available without restriction. All relevant data are within the paper and its Supporting Information files.

Funding: This research was supported by grants from the National Institutes of Health 5R01 DK062155 (J.E.F.), Colorado Nutrition Obesity Research Center, P30 DK048520 (J.E.F.), and R01 DK078645 (L.A.B.) [http://www.nih.gov], and from the Medical Research Foundation for Women and Babies; (M.L.) [http://www.mrfwb.org.au] and the Diabetes Australia Research Trust; (M.L.) [http://www.diabetesaustralia.com.au]. M.L. was supported by a Career Development Fellowship from the National Health and Medical Research Council, grant no. 1047025 [https://www.nhmrc.gov.au]. K.E.B. was supported by the National Institutes of Health F32 DK089743 and K12 HD057022 [http://www.nih.gov]. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing interests: The authors have declared that no competing interests exist.

Introduction

Gestational diabetes mellitus (GDM) is a rapidly growing public health concern. Adoption of new diagnostic criteria recommended by the American Diabetes Association (ADA) [1], [2] estimates a global prevalence of nearly one in five women (∼18%) who are considered at risk for GDM. Obesity occurs in ∼one in three women of child-bearing age [1], [3] and is a driving force accelerating the prevalence of GDM. GDM not only complicates pregnancy by increasing risk of pre-eclampsia and cesarean delivery, but is an independent risk factor for excess fetal growth and childhood obesity [3]–[7], and a consequence of even greater insulin resistance and nutrient availability than associated with maternal obesity alone [4]–[8]. In addition, GDM diagnosis identifies a population of women at markedly increased risk for future diabetes [8], [9], in part due to abnormal skeletal muscle signaling. Up to fifty percent of women diagnosed with GDM will go on to develop type 2 diabetes (T2DM) [9]–[11], and physical activity and dietary interventions to prevent this progression have been disappointing due to compliance difficulties [10]–[13]. Thus, understanding the pathogenesis of GDM is extremely important from a public health perspective for both maternal and child health.

Late in gestation, due to the demands of the placental-fetal unit and rapid depletion of glycogen stores, all women exhibit a shift in metabolism to increase reliance on lipid for metabolic substrate, a term called accelerated starvation. This metabolic shift is accompanied by a large decrease in skeletal muscle insulin sensitivity (−50%), both of which serve to allow for increased glucose supply to the growing fetus [12]–[14]. Women with GDM, however, demonstrate lower rates of whole body lipid oxidation both during early and late gestation [14], [15], with a less robust shift from glucose to lipid metabolism in late pregnancy compared with their normal glucose tolerant (NGT) counterparts [15]–[17]. Skeletal muscle, by virtue of its mass, is the principle site of glucose and lipid oxidation [3], [16]–[18], and therefore plays an important role in whether fuels are utilized by maternal tissues or shunted across the placenta to the developing fetus. The pathways underlying insulin resistance in GDM are well studied and multifactorial. However, little is known about the cellular mechanisms for altered skeletal muscle lipid or glucose metabolism, which is likely to significantly alter nutrient availability, thus increasing risk for increased fetal fat accretion and an increased risk of childhood obesity in offspring of women with GDM [3], [18], [19].

Therefore, the purpose of this study was to employ a discovery proteomic approach to identify candidate proteins that may underlie differences in skeletal muscle metabolism in obese, GDM pregnant women. The advantage of proteomic analysis, as opposed to a transcriptomic approach, is that we are able to measure content of global functional molecules involved in skeletal muscle metabolism rather than expression of genes that may or may not be related to protein content. We used an established quantitative proteomic analysis [19], [20] to compare skeletal muscle of obese pregnant women with GDM (OGDM) with obese pregnant women with NGT (ONGT). We then carried out a functional validation in a second, larger cohort of obese pregnant women with and without GDM. We are the first to demonstrate that several proteins of the mitochondrial electron transport system (ETS) are downregulated in the OGDM women, a factor we corroborated by demonstrating reduced activity of several enzyme complexes of the ETS in the second cohort of women. Proteomic analysis also revealed disruptions in calcium signaling/homeostasis proteins in skeletal muscle of the obese women with GDM, several of which may be related to cellular and mitochondrial stress. Along with a marked reduction in phosphorylated AMPK in the OGDM women, these results suggest that reduced capacity for skeletal muscle lipid or glucose oxidation may play an important role in the pathogenesis of GDM and may contribute to increased nutrient exposure to the fetus, potentially resulting in excess infant adiposity and long-term health consequences in the offspring.

Research Design and Methods

Study 1: Proteomic Analysis

Ethics Statement.

Approval for this study was obtained from the East Carolina University Policy and Review Committee on Human Research and the Colorado Multiple Institutional Review Board at the University of Colorado Hospital. Written informed consent was obtained from all participants prior to cesarean delivery.

Patients and Sample Collection.

Pregnant women over 21 years of age were screened for GDM between 24–28 weeks gestation and were diagnosed according to Carpenter and Coustan (CC) criteria [20], [21] using a 3-hour 100 g oral glucose tolerance test. Women with polycystic ovarian syndrome, pre-eclampsia, and macrovascular complications were excluded. All women with GDM were treated with insulin during the last 10–15 weeks of pregnancy to maintain normoglycemia. Body mass index (BMI) was calculated based on measurements from patients’ first antenatal visit (∼12 weeks gestation) and, in both groups, only those with a BMI of >30 kg/m² were included. Plasma insulin and glucose were measured in samples obtained immediately prior to cesarean delivery.

Between 300–500 mg of rectus abdominus skeletal muscle tissue were obtained from a total of 12 obese pregnant women undergoing elective cesarean delivery (term, ∼37 weeks gestation; 6 ONGT women, 6 OGDM). Rectus abdominus is of mixed muscle fiber type [19], [21]. Dissections of skeletal muscle were obtained within 10 min of delivery, dissected free from visible adipose and connective tissues, and snap frozen in liquid nitrogen and stored at −80°C until further analysis.

Protein Isolation and Mass Spectrometry.

Muscle protein content was determined as previously described [19], [22]. Approximately 30 mg of muscle tissue was homogenized in ice-cold lysis buffer as described [19], [22]. Tissue was homogenized while still frozen in an ice-cold buffer (10 µl/mg tissue) consisting of (final concentrations): 20 mM HEPES, pH 7.6; 1 mM EDTA; 250 mM sucrose, 2 mM Na₃VO₄; 10 mM NaF; 1 mM sodium pyrophosphate; 1 mM ammonium molybdate; 250 µM PMSF; 10 µg/ml leupeptin; and 10 µg/ml aprotinin. After homogenized by a polytron homogenizer on maximum speed for 30 sec, the homogenate was cooled on ice for 20 min and then centrifuged at 10,000×g for 20 min at 4°C; the resulting supernatant containing 60 µg of lysate supernatant proteins was used for in-gel digestion. Protein concentrations were determined by the method of Lowry method. Muscle lysate proteins were separated on 4–20% 1D linear gradient SDS polyacrylamide gels and each lane was cut into 20 separate slices. Gel pieces were treated with trypsin to digest proteins; the resulting mixture was desalted and subjected to mass spectrometry.

HPLC-ESI-MS/MS was performed on a hybrid linear ion trap (LTQ)-Fourier Transform Ion Cyclotron Resonance (FTICR) mass spectrometer (LTQ FT; Thermo Fisher, San Jose, CA) fitted with a PicoViewTM nanospray source (New Objective, Woburn, MA). On-line capillary HPLC was performed using a Michrom BioResources Paradigm MS4 micro HPLC (Auburn, CA) with a PicoFritTM column (New Objective; 75 µm i.d., packed with ProteoPepTM II C18 material, 300 Å). Samples were desalted using an on-line Nanotrap (Michrom BioResources, Auburn, CA) before being loaded onto the PicoFritTM column. HPLC separations were accomplished with a linear gradient of 2 to 27% ACN in 0.1% FA in 70 min, a hold of 5 min at 27% ACN, followed by a step to 50% ACN, hold 5 min and then a step to 80%, hold 5 min; flow rate, 300 nl/min. A “top-10” data-dependent tandem mass spectrometry approach was utilized to identify peptides in which a full scan spectrum (survey scan) was acquired followed by collision-induced dissociation (CID) mass spectra of the 10 most abundant ions in the survey scan. The survey scan was acquired using the FTICR mass analyzer in order to obtain high resolution and high mass accuracy data.

Data Analysis and Bioinformatics.

Tandem mass spectra were extracted from Xcalibur “RAW” files and charge states were assigned using the Extract_MSN script (Thermo Fisher, San Jose, CA). The fragment mass spectra were then searched against the IPI_HUMAN_v3.59 database (80,128 entries, http://www.ebi.ac.uk/IPI/) using Mascot (Matrix Science, London, UK; version 2.2). The false discovery rate was determined by selecting the option to search the decoy randomized database. The search parameters used were: 10 ppm mass tolerance for precursor ion masses and 0.5 Da for production masses; digestion with trypsin; a maximum of two missed tryptic cleavages; fixed modification of carboamidomethylation; variable modifications of oxidation of methionine and phosphorylation of serine, threonine and tyrosine. Probability assessment of peptide assignments and protein identifications were made through use of Scaffold (version Scaffold_2_00_06, Proteome Software Inc., Portland, OR). Only peptides with ≥95% probability were considered. Proteins that contained identical peptides and could not be differentiated based on MS/MS analysis alone were grouped.

Protein and gene ontology annotation were performed as described, as were extraction of tandem mass spectra and verification of charge states and monoisotopic peak assignments [19]. To quantify protein abundance, normalized spectral abundance factors (NSAF)s were used [19]. Briefly, MS/MS spectra assigned to a protein were normalized to the number of amino acids for that protein, resulting in a spectral abundance factor (SAF). Each SAF was normalized against the sum of all SAFs in one sample, resulting in the NSAF value. This calculation is represented by the following equation, where N is equal to the number of proteins detected in a sample:Thus, NSAF values allow for direct comparison of a protein’s abundance between individual runs in a fashion similar to microarray data analysis. The reproducibility and linearity of this method are described previously [19], [23].

Study 2: Metabolic Analysis

Ethics Statement.

Approval for this study was obtained from the Mercy Hospital for Women’s Research and Ethics Committee and written informed consent was obtained from all participants prior to cesarean delivery.

Patients and Sample Collection.

To extend our observations from Study 1, a larger cohort of ONGT and OGDM subjects were studied. Pregnant women over 21 years of age were screened for GDM at 24–28 weeks gestation and were diagnosed according to the criteria set by the Australasian Diabetes in Pregnancy Society (ADIPS), by either a fasting venous plasma glucose level of 5.5 (compared to 5.3 using CC criteria) and/or greater than 8.0 mmol/L (8.6 using CC criteria) glucose 2 h after a 75 g oral glucose tolerance test. Applying these criteria results in a prevalence of GDM of ∼18% [23], [24]. Only GDM patients treated with insulin to control blood glucose levels were included. Women with polycystic ovarian syndrome, pre-eclampsia, and macrovascular complications were excluded. BMI was similarly calculated from patients’ first antenatal visit (∼12 weeks gestation) and only women in both groups with a BMI of >30 kg/m² were included.

Between 300 and 500 mg of pyramidalis skeletal muscle was obtained from a total of 18 pregnant women undergoing elective caesarean delivery (term, ∼37 weeks gestation; 10 ONGT and 8 OGDM). The pyramidalis muscle is located anterior to the rectus abdominus and is also of mixed fiber type [24], [25]. Dissections of skeletal muscle were obtained within 10 min of delivery and snap frozen in liquid nitrogen and stored at −80°C until further analysis. Tissues were also imbedded for histology to verify that they were free from adipose or connective tissue contamination by hemotoxylin and eosin staining as previously described [25], [26].

For all deliveries in Study 2, spinal anesthesia and/or epidural were used. All muscle samples were taken at the time of cesarean delivery (between 0830 and 1500). Women delivering in the morning hours were fasted overnight, women delivering after 1200 were fasted from 0730.

Plasma Measures.

Maternal blood was collected by venipuncture at the time of diagnosis (fasting sample, oral glucose tolerance test). Blood samples were immediately centrifuged at 1,500 g for 10 min and the plasma aliquoted into microfuge tubes and samples were immediately stored at −80°C until assayed for glucose and insulin. Blood glucose determination was performed by the hospital pathology department using an automated glucose oxidase/oxygen-rate method. Standard ELISA assay kit for insulin (Diagnostic Systems Laboratories, Webster, TX; limit of detection 0.26 IU/mL) was purchased and used according to the manufacturer's instructions. Insulin resistance at time of diagnosis was calculated using the homeostasis model assessment for insulin resistance (HOMA-IR) method where HOMA-IR = fasting plasma glucose (mmol/l) times fasting plasma insulin (µU/mL) divided by 22.5 [26], [27].

Mitochondrial Enzyme Activity Assays.

Mitochondrial-enriched supernatants (post 600 g) were prepared from frozen skeletal muscle samples, as described [27]. Supernatants were used to assay activity of respiratory chain enzyme complexes I, II, III, and IV (C-I through C-IV, respectively); and citrate synthase (CS), spectrophotometrically on a Synergy H1 microplate reader (Biotek, Winooski, VT). Enzyme assays for respiratory chain complexes and CS were performed as described [27], [28] with minor modifications for microplate reading. For C-I and C-II, enzyme activities were calculated as initial rates (nmol/min). For complexes III and IV, enzyme activities were calculated as the first-order rate constants derived within 2–3 min of reaction initiation. All assays were performed in duplicate. The protein content of each sample was determined using a BCA assay. All activities were normalized to the total protein content and to CS activity (calculated as initial rate of reaction as nmol/min) of each sample and expressed relative to the mean for NGT women.

Western Blot.

Protein levels of MitoProfile total OXPHOS antibody cocktail, AMPK, phosphoAMPK, PGC-1α and PPARα were determined in the muscle biopsy samples with calnexin as loading control as previously described [28]. OXPHOS antibody cocktail measured specific subunits of C-I, C-II, C-III, and C-IV (NDUFB8, SDHB, UQCRC2, and MT-CO1, respectively). All antibody dilutions were 1∶1,000 for primary antibodies and 1∶10,000 for secondary antibodies, unless otherwise stated. All results were expressed relative to the mean for NGT women. OXPHOS antibody cocktail (host: mouse), calnexin (host: rabbit), PGC-1α (host: rabbit), and PPARα (host: rabbit) antibodies were purchased from Abcam (Cambridge, MA). AMPK (host: rabbit) and phospho-AMPK (Thr172) (host: rabbit) antibodies were from Cell Signaling Technology (Danvers, MA). Secondary antibodies were purchased from Bio-Rad (Hercules, CA).

Mitochondrial DNA Copy Number.

Approximately 15 mg of skeletal muscle was homogenized and DNA was isolated by phenol/chloroform extraction with ethanol precipitation. Mitochondrial DNA (mtDNA) copy number was then measured as previously described [28].

Statistical Analyses

Statistical analyses were performed using IBM SPSS Statistics, Version 22 (IBM Corp., Armonk, NY). For the Study 1 proteomic analysis, a large number of proteins were assigned in at least one of 12 subjects studied (979 proteins; Table S1). A series of filters were used to narrow the number of proteins that were used in comparisons between groups (Figure 1). First only those proteins with representation in at least three subjects from each group were chosen (415 proteins). Of these, only those proteins with greater than 1.5-fold difference between groups (22 proteins) were examined for statistically significant differences between groups. First, data were tested for normality using the Shapiro-Wilk test, which were performed for ONGT and OGDM separately. Differences between groups were tested using non-parametric Mann Whitney U tests where data were not normally distributed, and remaining proteins were subjected to independent t-tests.

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Figure 1. Work flow of statistical analysis of single proteins.

https://doi.org/10.1371/journal.pone.0106872.g001

Study 2 was powered off our previous analysis of skeletal muscle enzyme activity in pregnant women [28]–[30], which showed a calculated effect size of 1.32 (averaged for C-I, C-II, and C-III) for differences between NGT and GDM women. We calculated 80% power with n = 10 subjects per group where α = 0.05 for two-sided independent t-tests. Data were tested for normality using the Shapiro-Wilk test, which were performed for ONGT and OGDM separately. Independent t-tests were performed on raw or log-transformed data where data were not normally distributed. Statistical difference is indicated by P≤0.05. Data are expressed as the mean ± SEM.

Results

Study 1: Proteomic Analysis

Patient Characteristics.

Patient characteristics for the women in Study 1 are shown in Table 1. Women in the ONGT (n = 6) and OGDM (n = 6) groups were of similar BMI. As expected, OGDM women had higher fasting blood glucose and insulin values, which translated to higher HOMA-IR scores (P<0.05).

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Table 1. Clinical characteristics of the subjects for Study 1.

https://doi.org/10.1371/journal.pone.0106872.t001

Mitochondrial and Calcium Signaling Proteins are Altered in Women with GDM.

Of the 979 unique proteins identified by tandem MS/MS mass spectrometry and NSAF analysis (Table S1), 22 met our criteria for statistical comparison between the OGDM and ONGT participants (protein detectable in at least three subjects per group and greater than 1.5-fold difference between groups; Table 2). Of these, eight proteins were statistically different between the groups (P≤0.05). Two of these proteins were subunits of ETS Complex I (C-I; NDUFV2 and NDUFS3), which were reduced by 60% in women with OGDM (P<0.05), while a third subunit of C-I (NDUFS8) tended to be reduced by 75% in the women with OGDM, compared with ONGT women (P = 0.07). Fatty acid transporter CD36 was increased by almost 75% in women with OGDM (P = 0.05). In addition, proteasome subunit alpha-1, a protein involved in protein degradation, was reduced by nearly 2-fold in women with OGDM (P<0.05). Surprisingly, several proteins involved in calcium homeostasis and calcium-dependent cellular signaling were also altered in skeletal muscle of women with OGDM, including calmodulin-dependent calcineurin A β (PPP3CB), which was increased by over 2-fold in women with OGDM compared with ONGT women (P<0.05). Similarly, calcium/calmodulin-dependent protein kinase type II, subunit A (CaMKIIa), tended to be higher in women with OGDM, though this was not significantly different between groups (+2-fold in GDM, P = 0.15). Furthermore, annexin A4, a calcium binding protein, was decreased by 65% in the women with OGDM (P = 0.05) and α1-syntrophin, a cellular localization protein involved in ion transport and cellular signaling, including calcium ion flux, was decreased by nearly 3-fold in women with OGDM (P<0.05).

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Table 2. Proteins with 1.5-fold difference between ONGT and OGDM, Study 1.

https://doi.org/10.1371/journal.pone.0106872.t002

Study 2: Metabolic Analysis

Patient Characteristics.

For Study 2, we followed up the results from Study 1 in a larger, separate cohort of OGDM and ONGT women (Table 3). The ONGT (n = 10) tended to be more obese than the OGDM women (n = 8; P = 0.06), though fasting blood glucose and 1 and 2 hour OGTT glucose values were higher in OGDM than ONGT women (P<0.05).

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Table 3. Clinical characteristics of the subjects for Study 2.

https://doi.org/10.1371/journal.pone.0106872.t003

Mitochondrial Enzyme Activity is Reduced in Women with GDM.

Because we observed reduced protein content of mitochondrial oxidative phosphorylation subunits (Study 1, Table 2), we measured two common markers of mitochondrial content (mitochondrial DNA copy number [mtDNA] and CS activity) in Study 2. However, mtDNA tended to be 30% lower in OGDM compared to ONGT women (P = 0.10; Figure 2A), while CS activity tended to be 30% higher in the women with OGDM (P = 0.06; Figure 2B).

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Figure 2. Mitochondrial enzyme activity is reduced in skeletal muscle of OGDM women.

Quantitative bar graphs of mitochondrial DNA copy number (A) and enzyme activity of citrate synthase (B) complex I (C), complex II (D), complex III (E), and complex IV (F) of the respiratory chain in pyramidalis muscle collected during scheduled cesarean section. Data are mean ± SEM. *P<0.05 vs. NGT.

https://doi.org/10.1371/journal.pone.0106872.g002

Next, given the reduced content of several C-I subunits (NDUFV2, NDUFS3) in skeletal muscle of OGDM compared to ONGT women (Study 1), we determined whether the activity of key enzymes involved in mitochondrial oxidative phosphorylation was also different between groups in Study 2. We found that women OGDM women exhibit reduced activity of C-I and C-III, (by 45% and 45%, and 30%, respectively; Figure 2C & E; P<0.05) and a trend for reduced C-IV activity (by 30%; Figure 2F; P = 0.06) compared to ONGT women. However, OXPHOS protein content was not similarly reduced (Figure 3A, C, & D). There were no differences in C-II activity or protein content (Figure 2D & 3B).

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Figure 3. Mitochondrial respiratory chain complex proteins are not different between ONGT and OGDM women.

Complex I (A), complex II (B), complex III (C), complex IV (D). Representative Western blots where calnexin is used as loading control (E).

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To examine whether transcriptional regulators of mitochondrial biogenesis were affected, we measured PPARα and PGC-1α protein content, though these were not different between ONGT and OGDM women (Figure 4A & B; ns). Lastly, because AMPK is a calcium-dependent protein involved in cellular metabolism and mitochondrial biogenesis [29]–[33], we then measured AMPK phosphorylation and found that Thr172 phosphorylation of AMPK was markedly downregulated by 75% in OGDM compared to ONGT women (Figure 4C & D).

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Figure 4. AMPK phosphorylation is reduced in OGDM women, though regulators of mitochondrial biogenesis are not.

Quantitative bar graphs of PPARα (A) and PGC-1α (B), total AMPK (C), and phospho-AMPK (D) protein content in pyramidalis muscle collected during scheduled cesarean section. Representative Western blots where calnexin is used as loading control (E). Data are mean ± SEM. *P<0.05 vs. NGT.

https://doi.org/10.1371/journal.pone.0106872.g004

Discussion

The present study is the first proteomic analysis of skeletal muscle tissue from obese, pregnant women with GDM compared with their obese, NGT counterparts. In this hypothesis-generating analysis we found that several proteins of the mitochondrial ETS were downregulated in the women with GDM, a factor that was corroborated by reduced activity of several enzyme complexes of the ETS in a similar, larger cohort of both OGDM and ONGT women. Proteomic analysis also revealed disrupted calcium signaling/homeostasis proteins in skeletal muscle of OGDM women. Subsequent measures also showed a pronounced reduction in the phosphorylation of AMPK in skeletal muscle in OGDM compared to ONGT women, which has been linked to both calcium homeostasis and reduced oxidative metabolism.

Obese, insulin resistant humans often exhibit reduced skeletal muscle mitochondrial function when compared with normal weight, insulin sensitive individuals, generally in the form of reduced electron transport flux or ATP turnover [31]–[34]. We found that obese women diagnosed with GDM showed significantly lower skeletal muscle mitochondrial C-I subunit protein content (Study 1) and enzyme activity (Study 2) compared to obese, NGT women. Even though there was a trend for reduced mtDNA copy number in the OGDM women, the trend for increased CS activity in these same women, makes it difficult to determine whether mitochondrial content was reduced in the women with GDM. However, given that enzyme activity data were normalized to CS activity in Study 2, the lower enzyme activities in the OGDM women do not appear to be the result of lower mitochondrial content and these discrepancies in mitochondrial content simply highlight the fact that these data are markers of mitochondrial content, not direct measures. For this reason we also measured upstream regulators of oxidative metabolism and mitochondrial biogenesis (PGC-1α and PPARα) and found that they were not different between the OGDM and ONGT women. These data indicate that mitochondrial functional capacity may be linked to specific subunit protein content rather than global mitochondrial deficits in the skeletal muscle of women with OGDM. Thus, in this cohort where the principal differences between the OGDM and ONGT women is impaired glucose tolerance, these results suggest that reduced mitochondrial enzyme capacity may be an important determinant of excessive glucose intolerance during pregnancy, perhaps contributing to postpartum diabetes risk. However, the association between reduced skeletal muscle mitochondrial capacity and T2DM is not universally reported. For example, Asian Indians with T2DM show greater skeletal muscle mitochondrial activity than their non-diabetic counterparts [34], [35], and Boushel et al. [35]–[37] report similar mitochondrial respiration rates in permeabilized muscle fibers from obese, type 2 diabetics compared with non-diabetic, overweight counterparts, suggesting that the relationship between T2DM and reduced mitochondrial capacity is not causal. Gestational diabetes, like T2DM, is characterized by both insulin resistance and pancreatic beta cell dysfunction [8], [36], [37]. Therefore, in addition to factors such as skeletal muscle mitochondrial dysfunction and skeletal muscle insulin signaling [8], [38]–[40], which can exacerbate insulin resistance, factors determining beta cell function likely play a prominent role in the development of GDM and subsequent T2DM postpartum.

Calcium homeostasis and calcium-dependent signaling play important roles in many skeletal muscle processes in addition to muscle contraction, such as insulin-mediated glucose uptake, AMPK signaling and mitochondrial biogenesis [38]–[41]. Our proteomic analysis revealed decreased α1-syntrophin and annexin A4, proteins involved in intracellular calcium signaling/homeostasis. In addition, we observed large increases in both calcineurin A and CaMKIIα in OGDM compared with ONGT women, though differences in CaMKIIα did not reach statistical significance. Such data suggest a disruption in calcium handling in skeletal muscle of women with GDM that warrants further investigation into its role in insulin signaling and mitochondrial capacity.

Alpha 1-syntrophin is a member of the syntrophin family of scaffold proteins that interacts with many signaling proteins, linking them with various cell surface receptors, ion channels, and downstream effectors [41]–[43]. In particular, α1-syntrophin, interacts with dystrophin and related proteins [38], [41]–[44] and disruption of the dystrophin-syntrophin complex has been suggested to promote the excessive calcium influx and altered MAPK and GTPase signaling observed in muscular dystrophy [38], [41], [44]–[46]. In this context, silencing of α1-syntrophin in myotube cultures induces cellular calcium influx via store-operated calcium channels [39], [40], [45], [46]. Thus, the observed reduction in α1-syntrophin in the skeletal muscle of OGDM women in our study may affect myocellular calcium levels. Contrary to transient increases in intramyocellular calcium that induce AMPK phosphorylation, such as occurs with muscle contraction, sustained elevations of intramyocellular calcium can reduce AICAR-induced AMPK phosphorylation in myotube cultures, which appears to be regulated by elevated CaMKII [29], [39], [40]. Thus, sustained elevations in cellular calcium may induce CaMKII to inhibit AMPK phosphorylation. As a potent activator of lipid oxidation and mitochondrial biogenesis [10], [11], [29], the reduced AMPK phosphorylation observed in Study 2 could explain their reduced mitochondrial enzyme capacity via calcium regulatory mechanisms. Though we did not observe differences in overall mitochondrial content in Study 2, as estimated by mtDNA copy number and citrate synthase activity, it is possible that there was a deficit in content of specific subunit proteins, which contributed to reduced enzyme activity. For example, the C-I molecule contains 45 subunit proteins [47]. Our proteomic analysis only identified 24 C-I subunit proteins assigned in at least 1 individual (Table S1), of which only two were statistically different between groups. This suggests that, while overall subunit content of C-I is not different in skeletal muscle of the OGDM women, content of specific, important C-I subunit proteins is reduced, resulting in reduced mitochondrial enzyme activity. Indeed, gene silencing of NDUFS3 and mutations in the NDUFV2 gene have been shown to lead to mitochondrial dysfunction, hypertrophic cardiomyopathy, and Leigh’s Syndrome [48], [49]. Thus, calcium regulatory control of AMPK phosphorylation and mitochondrial enzyme capacity may have clinical implications that may partially explain why physical activity interventions in women with GDM, for the control glycemia and prevention of its progression to T2DM, are disappointing and often associated with a high non-compliance rate [10], [11], [50]. While this is the first report of reduced α1-syntrophin in human insulin resistant skeletal muscle, similar observations have been made in diabetic Goto-Kakizaki rats, where skeletal muscle dystrophin and α1-syntrophin content was markedly reduced and thought to be a contributor to the excessive insulin resistance observed in these animals [50], [51].

Annexin A4 is a lipid-binding protein involved in exocytosis and ion transport in a calcium-dependent manner [51], [52]. Among its many functions, annexin A4 interacts with the p50 subunit of NF-kB, reducing is transcriptional activity [8], [52], [53]. Thus, the inflammatory cascade may be enhanced in skeletal muscle where annexin A4 protein is reduced. This may be one mechanism whereby inflammation is elevated in skeletal muscle of women with GDM, as we have shown previously [8], [53]. As a result, serine phosphorylation of JNK and/or p70S6 kinase may link inflammation with disrupted insulin signaling in skeletal muscle of women with GDM [8], [53], [54]. While this is the first report of reduced annexin A4 in skeletal muscle of GDM patients, members of our group have recently reported reduced content of other annexin proteins (A2, A5, A6) in placental tissue from obese GDM patients [54], [55], suggesting a universal disruption of annexin protein content in pregnant women with GDM.

Calcineurin A was reduced in skeletal muscle of OGDM women. Calcineurin A is the catalytic subunit of calcineurin that forms a heterodimer with the calcineurin B regulatory subunit [55], [56]. Once activated by calcium/calmodulin, calcineurin stimulates insulin sensitizing pathways and has also been shown to induce lipid oxidation and mitochondrial biogenesis pathways, including increased expression of CD36 and all of the ETS complexes [56], [57], which may explain increased CD36 protein in OGDM women in the proteomic analysis. Increased calcineurin A may also account for the slight, yet non-significant increases in electron transport complex proteins measured in the OGDM women (Study 2). However, studies show that calcineurin expression is induced in response to mitochondrial stress and mtDNA damage [57], [58]. For example, in early stage diabetic cardiomyopathy, mitochondrial stress is commonly observed, along with disrupted calcium homeostasis, elevated calcineurin, and insulin resistance [28], [58]. While these observations may seem paradoxical given calcineurin action, they seem to suggest a compensatory function of calcineurin, with regard to mitochondrial biogenesis and insulin sensitivity, which may be precluded in cardiac muscle of diabetic cardiomyopathy patients. Perhaps a similar compensatory increase in calcium is observed in skeletal muscle of GDM patients in response to mitochondrial stress.

We have previously reported that obese women with mild, diet-treated GDM have similar skeletal muscle mitochondrial enzyme activity to obese NGT pregnant women [28], [59], [60]. Here, we have found that those with more severe GDM (insulin-treated) exhibit lower mitochondrial enzyme activity for C-I and C-III than obese NGT pregnant women, despite the tendency for lower BMI, suggesting that the extent of glucose intolerance may play a more important role in skeletal muscle mitochondrial enzyme capacity than BMI in these women. This is further corroborated by the fact that the women with insulin treated GDM presented here had similar BMIs as the women with diet-treated GDM reported previously [28]. While it is possible that exogenous insulin administration may have induced the observed proteomic or enzymatic differences in the OGDM women, it is equally plausible that, due to skeletal muscle insulin resistance of the OGDM women, exogenous insulin simply equalized the effect of insulin on skeletal muscle tissues to those observed in the non-insulin treated women. Nevertheless, reduced mitochondrial enzyme activity in the OGDM women does not appear to be the result of differences in total mitochondrial content, but rather may be the result of reduced subunit protein content. Even though we discovered reduced content of two C-I subunits, and a trend for reduced content of a third C-I subunit in our proteomic analysis, we did not observe differences in total OXPHOS content, which is likely due to the fact that the OXPHOS antibody cocktail only measures the NDUFB8 C-I subunit. Nevertheless, we must recognize that these observations can only be extended to obese women diagnosed with GDM, and may differ for those women with less severe GDM (diet-treated).

GDM women and their offspring are a population which globally and significantly contributes to the escalation of T2DM and childhood obesity and our proteomic analysis of skeletal muscle from obese pregnant women revealed that proteins involved in mitochondrial oxidative phosphorylation are reduced in OGDM compared to their ONGT counterparts. These observations were corroborated by reduced skeletal muscle mitochondrial enzyme activity in a larger cohort of obese pregnant women. We further demonstrated that several proteins involved in calcium homeostasis/signaling were altered in obese women with GDM, several of which may be linked to disrupted insulin signaling and reduced mitochondrial activity. Such disturbances in calcium homeostasis proteins could contribute to the inflammation, insulin resistance, and altered substrate metabolism observed in skeletal muscle of OGDM patients, consequently shunting maternal nutrients to the growing fetus. Furthermore, disruption of calcium homeostasis could help explain the high failure rate of exercise intervention studies designed to treat women with GDM during pregnancy and/or to prevent the development of T2DM postpartum [59], [60].

In conclusion, this exploratory analysis identifies several calcium regulatory proteins that could represent novel risk factors for both the development of GDM and the progression to T2DM. Larger, more targeted studies are required to confirm these exploratory analyses. Further examination of calcium regulatory proteins could reveal an important link between insulin resistance and reduced mitochondrial activity in obese women with GDM that could potentially be targeted for strategies geared toward prevention and treatment of T2DM in this rapidly growing cohort of at risk women.

Supporting Information

Table S1.

Spectral counts and NSAF values for 979 proteins identified in at least 1 subject.

https://doi.org/10.1371/journal.pone.0106872.s001

(XLSX)

Acknowledgments

The clinical research midwives Genevieve Christophers, Debra Jinks, Rachel Murdoch and Gabrielle Fleming, are gratefully acknowledged for assistance with sample collection. The Obstetrics and Midwifery staff of the Mercy Hospital for Women is also thanked for their co-operation.

Author Contributions

Conceived and designed the experiments: KEB JEF JMD TLH LAB. Performed the experiments: HH KEB RCJ JMD TLH LAB ML. Analyzed the data: HH KEB RCJ. Contributed reagents/materials/analysis tools: JEF LJM LAB ML JMD. Contributed to the writing of the manuscript: KEB JEF.

References

1. Flegal KM, Carroll MD, Kit BK, Ogden CL (2012) Prevalence of obesity and trends in the distribution of body mass index among US adults, 1999–2010. JAMA 307: 491–497
- View Article
- Google Scholar
2. International Association of Diabetes and Pregnancy Study Groups Consensus Panel, Metzger BE, Gabbe SG, Persson B, Buchanan TA, et al (2010) International association of diabetes and pregnancy study groups recommendations on the diagnosis and classification of hyperglycemia in pregnancy. Diabetes Care 33: 676–682
- View Article
- Google Scholar
3. Heerwagen MJR, Miller MR, Barbour LA, Friedman JE (2010) Maternal obesity and fetal metabolic programming: a fertile epigenetic soil. Am J Physiol Regul Integr Comp Physiol 299: R711–R722
- View Article
- Google Scholar
4. Saydah SH, Chandra A, Eberhardt MS (2005) Pregnancy experience among women with and without gestational diabetes in the U.S., 1995 National Survey Of Family Growth. Diabetes Care 28: 1035–1040.
- View Article
- Google Scholar
5. Bentley-Lewis R, Powe C, Ankers E, Wenger J, Ecker J, et al.. (2014) Effect of Race/Ethnicity on Hypertension Risk Subsequent to Gestational Diabetes Mellitus. Am J Cardiol. doi:10.1016/j.amjcard.2014.01.411.
6. Hartling L, Dryden DM, Guthrie A, Muise M, Vandermeer B, et al. (2014) Diagnostic thresholds for gestational diabetes and their impact on pregnancy outcomes: a systematic review. Diabet Med 31: 319–331
- View Article
- Google Scholar
7. Barbour LA, McCurdy CE, Hernandez TL, Kirwan JP, Catalano PM, et al. (2007) Cellular mechanisms for insulin resistance in normal pregnancy and gestational diabetes. Diabetes Care 30 Suppl 2S112–S119
- View Article
- Google Scholar
8. Barbour LA, McCurdy CE, Hernandez TL, Friedman JE (2011) Chronically increased S6K1 is associated with impaired IRS1 signaling in skeletal muscle of GDM women with impaired glucose tolerance postpartum. J Clin Endocrinol Metab 96: 1431–1441
- View Article
- Google Scholar
9. Kim C, Newton KM, Knopp RH (2002) Gestational diabetes and the incidence of type 2 diabetes: a systematic review. Diabetes Care 25: 1862–1868.
- View Article
- Google Scholar
10. Ratner RE, Christophi CA, Metzger BE, Dabelea D, Bennett PH, et al. (2008) Prevention of diabetes in women with a history of gestational diabetes: effects of metformin and lifestyle interventions. J Clin Endocrinol Metab 93: 4774–4779
- View Article
- Google Scholar
11. Ruchat S-M, Mottola MF (2013) The important role of physical activity in the prevention and management of gestational diabetes mellitus. Diabetes Metab Res Rev 29: 334–346
- View Article
- Google Scholar
12. Catalano PM, Nizielski SE, Shao J, Preston L, Qiao L, et al. (2002) Downregulated IRS-1 and PPARgamma in obese women with gestational diabetes: relationship to FFA during pregnancy. Am J Physiol Endocrinol Metab 282: E522–E533
- View Article
- Google Scholar
13. Herrera E (2000) Metabolic adaptations in pregnancy and their implications for the availability of substrates to the fetus. Eur J Clin Nutr 54 Suppl 1S47–S51.
- View Article
- Google Scholar
14. Okereke NC, Huston-Presley L, Amini SB, Kalhan S, Catalano PM (2004) Longitudinal changes in energy expenditure and body composition in obese women with normal and impaired glucose tolerance. Am J Physiol Endocrinol Metab 287: E472–E479
- View Article
- Google Scholar
15. Catalano PM, Huston L, Amini SB, Kalhan SC (1999) Longitudinal changes in glucose metabolism during pregnancy in obese women with normal glucose tolerance and gestational diabetes mellitus. Am J Obstet Gynecol 180: 903–916.
- View Article
- Google Scholar
16. DeFronzo RA, Gunnarsson R, Björkman O, Olsson M, Wahren J (1985) Effects of insulin on peripheral and splanchnic glucose metabolism in noninsulin-dependent (type II) diabetes mellitus. J Clin Invest 76: 149–155
- View Article
- Google Scholar
17. Ghanassia E, Brun J-F, Mercier J, Raynaud E (2007) Oxidative mechanisms at rest and during exercise. Clin Chim Acta 383: 1–20
- View Article
- Google Scholar
18. Dabelea D, Crume T (2011) Maternal environment and the transgenerational cycle of obesity and diabetes. Diabetes 60: 1849–1855
- View Article
- Google Scholar
19. Hwang H, Bowen BP, Lefort N, Flynn CR, De Filippis EA, et al. (2010) Proteomics analysis of human skeletal muscle reveals novel abnormalities in obesity and type 2 diabetes. Diabetes 59: 33–42
- View Article
- Google Scholar
20. Carpenter MW, Coustan DR (1982) Criteria for screening tests for gestational diabetes. Am J Obstet Gynecol 144: 768–773.
- View Article
- Google Scholar
21. Tanner CJ, Barakat HA, Dohm GL, Pories WJ, MacDonald KG, et al. (2002) Muscle fiber type is associated with obesity and weight loss. Am J Physiol Endocrinol Metab 282: E1191–E1196
- View Article
- Google Scholar
22. McCurdy CE, Bishop JM, Williams SM, Grayson BE, Smith MS, et al. (2009) Maternal high-fat diet triggers lipotoxicity in the fetal livers of nonhuman primates. J Clin Invest 119: 323–335
- View Article
- Google Scholar
23. Reece EA, Leguizamón G, Wiznitzer A (2009) Gestational diabetes: the need for a common ground. Lancet 373: 1789–1797
- View Article
- Google Scholar
24. Lovering RM, Anderson LD (2008) Architecture and fiber type of the pyramidalis muscle. Anat Sci Int 83: 294–297
- View Article
- Google Scholar
25. Colomiere M, Permezel M, Lappas M (2010) Diabetes and obesity during pregnancy alter insulin signalling and glucose transporter expression in maternal skeletal muscle and subcutaneous adipose tissue. J Mol Endocrinol 44: 213–223
- View Article
- Google Scholar
26. Matthews DR, Hosker JP, Rudenski AS, Naylor BA, Treacher DF, et al. (1985) Homeostasis model assessment: insulin resistance and beta-cell function from fasting plasma glucose and insulin concentrations in man. Diabetologia 28: 412–419.
- View Article
- Google Scholar
27. Frazier AE, Thorburn DR (2012) Biochemical analyses of the electron transport chain complexes by spectrophotometry. Methods Mol Biol 837: 49–62
- View Article
- Google Scholar
28. Boyle KE, Newsom SA, Janssen RC, Lappas M, Friedman JE (2013) Skeletal muscle MnSOD, mitochondrial complex II, and SIRT3 enzyme activities are decreased in maternal obesity during human pregnancy and gestational diabetes mellitus. J Clin Endocrinol Metab 98: E1601–E1609
- View Article
- Google Scholar
29. Reznick RM, Shulman GI (2006) The role of AMP-activated protein kinase in mitochondrial biogenesis. J Physiol (Lond) 574: 33–39
- View Article
- Google Scholar
30. Ruderman NB, Carling D, Prentki M, Cacicedo JM (2013) AMPK, insulin resistance, and the metabolic syndrome. J Clin Invest 123: 2764–2772
- View Article
- Google Scholar
31. Petersen KF, Befroy D, Dufour S, Dziura J, Ariyan C, et al. (2003) Mitochondrial dysfunction in the elderly: possible role in insulin resistance. Science 300: 1140–1142
- View Article
- Google Scholar
32. Koves TR, Ussher JR, Noland RC, Slentz D, Mosedale M, et al. (2008) Mitochondrial overload and incomplete fatty acid oxidation contribute to skeletal muscle insulin resistance. Cell Metab 7: 45–56
- View Article
- Google Scholar
33. Anderson EJ, Lustig ME, Boyle KE, Woodlief TL, Kane DA, et al. (2009) Mitochondrial H2O2 emission and cellular redox state link excess fat intake to insulin resistance in both rodents and humans. J Clin Invest 119: 573–581
- View Article
- Google Scholar
34. Nair KS, Bigelow ML, Asmann YW, Chow LS, Coenen-Schimke JM, et al. (2008) Asian Indians have enhanced skeletal muscle mitochondrial capacity to produce ATP in association with severe insulin resistance. Diabetes 57: 1166–1175
- View Article
- Google Scholar
35. Boushel R, Gnaiger E, Schjerling P, Skovbro M, Kraunsøe R, et al. (2007) Patients with type 2 diabetes have normal mitochondrial function in skeletal muscle. Diabetologia 50: 790–796
- View Article
- Google Scholar
36. Buchanan TA, Xiang AH (2005) Gestational diabetes mellitus. J Clin Invest 115: 485–491
- View Article
- Google Scholar
37. Buchanan TA, Xiang AH, Page KA (2012) Gestational diabetes mellitus: risks and management during and after pregnancy. Nat Rev Endocrinol 8: 639–649
- View Article
- Google Scholar
38. Berchtold MW, Brinkmeier H, Müntener M (2000) Calcium ion in skeletal muscle: its crucial role for muscle function, plasticity, and disease. Physiol Rev 80: 1215–1265.
- View Article
- Google Scholar
39. Park S, Scheffler TL, Rossie SS, Gerrard DE (2013) AMPK activity is regulated by calcium-mediated protein phosphatase 2A activity. Cell Calcium 53: 217–223
- View Article
- Google Scholar
40. Park S, Scheffler TL, Gerrard DE (2011) Chronic high cytosolic calcium decreases AICAR-induced AMPK activity via calcium/calmodulin activated protein kinase II signaling cascade. Cell Calcium 50: 73–83
- View Article
- Google Scholar
41. Constantin B (2014) Dystrophin complex functions as a scaffold for signalling proteins. Biochim Biophys Acta 1838: 635–642
- View Article
- Google Scholar
42. Campbell KP, Kahl SD (1989) Association of dystrophin and an integral membrane glycoprotein. Nature 338: 259–262
- View Article
- Google Scholar
43. Vandebrouck A, Sabourin J, Rivet J, Balghi H, Sebille S, et al. (2007) Regulation of capacitative calcium entries by alpha1-syntrophin: association of TRPC1 with dystrophin complex and the PDZ domain of alpha1-syntrophin. FASEB J 21: 608–617
- View Article
- Google Scholar
44. Mallouk N, Jacquemond V, Allard B (2000) Elevated subsarcolemmal Ca2+ in mdx mouse skeletal muscle fibers detected with Ca2+-activated K+ channels. Proc Natl Acad Sci USA 97: 4950–4955.
- View Article
- Google Scholar
45. Sabourin J, Lamiche C, Vandebrouck A, Magaud C, Rivet J, et al. (2009) Regulation of TRPC1 and TRPC4 cation channels requires an alpha1-syntrophin-dependent complex in skeletal mouse myotubes. J Biol Chem 284: 36248–36261
- View Article
- Google Scholar
46. Sabourin J, Harisseh R, Harnois T, Magaud C, Bourmeyster N, et al. (2012) Dystrophin/α1-syntrophin scaffold regulated PLC/PKC-dependent store-operated calcium entry in myotubes. Cell Calcium 52: 445–456
- View Article
- Google Scholar
47. Murray J, Zhang B, Taylor SW, Oglesbee D, Fahy E, et al. (2003) The subunit composition of the human NADH dehydrogenase obtained by rapid one-step immunopurification. J Biol Chem 278: 13619–13622
- View Article
- Google Scholar
48. Suhane S, Kanzaki H, Arumugaswami V, Murali R, Ramanujan VK (2013) Mitochondrial NDUFS3 regulates the ROS-mediated onset of metabolic switch in transformed cells. Biol Open 2: 295–305
- View Article
- Google Scholar
49. Liu H-Y, Liao P-C, Chuang K-T, Kao M-C (2011) Mitochondrial targeting of human NADH dehydrogenase (ubiquinone) flavoprotein 2 (NDUFV2) and its association with early-onset hypertrophic cardiomyopathy and encephalopathy. J Biomed Sci 18: 29
- View Article
- Google Scholar
50. Mulvey C, Harno E, Keenan A, Ohlendieck K (2005) Expression of the skeletal muscle dystrophin-dystroglycan complex and syntrophin-nitric oxide synthase complex is severely affected in the type 2 diabetic Goto-Kakizaki rat. Eur J Cell Biol 84: 867–883
- View Article
- Google Scholar
51. Gerke V, Creutz CE, Moss SE (2005) Annexins: linking Ca2+ signalling to membrane dynamics. Nat Rev Mol Cell Biol 6: 449–461
- View Article
- Google Scholar
52. Jeon Y-J, Kim D-H, Jung H, Chung SJ, Chi S-W, et al. (2010) Annexin A4 interacts with the NF-kappaB p50 subunit and modulates NF-kappaB transcriptional activity in a Ca2+-dependent manner. Cell Mol Life Sci 67: 2271–2281
- View Article
- Google Scholar
53. Friedman JE, Kirwan JP, Jing M, Presley L, Catalano PM (2008) Increased skeletal muscle tumor necrosis factor-alpha and impaired insulin signaling persist in obese women with gestational diabetes mellitus 1 year postpartum. Diabetes 57: 606–613
- View Article
- Google Scholar
54. Oliva K, Barker G, Rice GE, Bailey MJ, Lappas M (2013) 2D-DIGE to identify proteins associated with gestational diabetes in omental adipose tissue. J Endocrinol 218: 165–178
- View Article
- Google Scholar
55. Rusnak F, Mertz P (2000) Calcineurin: form and function. Physiol Rev 80: 1483–1521.
- View Article
- Google Scholar
56. Long YC, Glund S, Garcia-Roves PM, Zierath JR (2007) Calcineurin regulates skeletal muscle metabolism via coordinated changes in gene expression. J Biol Chem 282: 1607–1614
- View Article
- Google Scholar
57. Guha M, Srinivasan S, Biswas G, Avadhani NG (2007) Activation of a novel calcineurin-mediated insulin-like growth factor-1 receptor pathway, altered metabolism, and tumor cell invasion in cells subjected to mitochondrial respiratory stress. J Biol Chem 282: 14536–14546
- View Article
- Google Scholar
58. Battiprolu PK, Gillette TG, Wang ZV, Lavandero S, Hill JA (2010) Diabetic Cardiomyopathy: Mechanisms and Therapeutic Targets. Drug Discov Today Dis Mech 7: e135–e143
- View Article
- Google Scholar
59. Fitts RH (2011) New insights on sarcoplasmic reticulum calcium regulation in muscle fatigue. J Appl Physiol 111: 345–346
- View Article
- Google Scholar
60. Rullman E, Andersson DC, Melin M, Reiken S, Mancini DM, et al. (2013) Modifications of skeletal muscle ryanodine receptor type 1 and exercise intolerance in heart failure. J Heart Lung Transplant 32: 925–929
- View Article
- Google Scholar

[ref1] 1. Flegal KM, Carroll MD, Kit BK, Ogden CL (2012) Prevalence of obesity and trends in the distribution of body mass index among US adults, 1999–2010. JAMA 307: 491–497
View Article
Google Scholar

[2] View Article

[3] Google Scholar

[ref2] 2. International Association of Diabetes and Pregnancy Study Groups Consensus Panel, Metzger BE, Gabbe SG, Persson B, Buchanan TA, et al (2010) International association of diabetes and pregnancy study groups recommendations on the diagnosis and classification of hyperglycemia in pregnancy. Diabetes Care 33: 676–682
View Article
Google Scholar

[5] View Article

[6] Google Scholar

[ref3] 3. Heerwagen MJR, Miller MR, Barbour LA, Friedman JE (2010) Maternal obesity and fetal metabolic programming: a fertile epigenetic soil. Am J Physiol Regul Integr Comp Physiol 299: R711–R722
View Article
Google Scholar

[8] View Article

[9] Google Scholar

[ref4] 4. Saydah SH, Chandra A, Eberhardt MS (2005) Pregnancy experience among women with and without gestational diabetes in the U.S., 1995 National Survey Of Family Growth. Diabetes Care 28: 1035–1040.
View Article
Google Scholar

[11] View Article

[12] Google Scholar

[ref5] 5. Bentley-Lewis R, Powe C, Ankers E, Wenger J, Ecker J, et al.. (2014) Effect of Race/Ethnicity on Hypertension Risk Subsequent to Gestational Diabetes Mellitus. Am J Cardiol. doi:10.1016/j.amjcard.2014.01.411.

[ref6] 6. Hartling L, Dryden DM, Guthrie A, Muise M, Vandermeer B, et al. (2014) Diagnostic thresholds for gestational diabetes and their impact on pregnancy outcomes: a systematic review. Diabet Med 31: 319–331
View Article
Google Scholar

[15] View Article

[16] Google Scholar

[ref7] 7. Barbour LA, McCurdy CE, Hernandez TL, Kirwan JP, Catalano PM, et al. (2007) Cellular mechanisms for insulin resistance in normal pregnancy and gestational diabetes. Diabetes Care 30 Suppl 2S112–S119
View Article
Google Scholar

[18] View Article

[19] Google Scholar

[ref8] 8. Barbour LA, McCurdy CE, Hernandez TL, Friedman JE (2011) Chronically increased S6K1 is associated with impaired IRS1 signaling in skeletal muscle of GDM women with impaired glucose tolerance postpartum. J Clin Endocrinol Metab 96: 1431–1441
View Article
Google Scholar

[21] View Article

[22] Google Scholar

[ref9] 9. Kim C, Newton KM, Knopp RH (2002) Gestational diabetes and the incidence of type 2 diabetes: a systematic review. Diabetes Care 25: 1862–1868.
View Article
Google Scholar

[24] View Article

[25] Google Scholar

[ref10] 10. Ratner RE, Christophi CA, Metzger BE, Dabelea D, Bennett PH, et al. (2008) Prevention of diabetes in women with a history of gestational diabetes: effects of metformin and lifestyle interventions. J Clin Endocrinol Metab 93: 4774–4779
View Article
Google Scholar

[27] View Article

[28] Google Scholar

[ref11] 11. Ruchat S-M, Mottola MF (2013) The important role of physical activity in the prevention and management of gestational diabetes mellitus. Diabetes Metab Res Rev 29: 334–346
View Article
Google Scholar

[30] View Article

[31] Google Scholar

[ref12] 12. Catalano PM, Nizielski SE, Shao J, Preston L, Qiao L, et al. (2002) Downregulated IRS-1 and PPARgamma in obese women with gestational diabetes: relationship to FFA during pregnancy. Am J Physiol Endocrinol Metab 282: E522–E533
View Article
Google Scholar

[33] View Article

[34] Google Scholar

[ref13] 13. Herrera E (2000) Metabolic adaptations in pregnancy and their implications for the availability of substrates to the fetus. Eur J Clin Nutr 54 Suppl 1S47–S51.
View Article
Google Scholar

[36] View Article

[37] Google Scholar

[ref14] 14. Okereke NC, Huston-Presley L, Amini SB, Kalhan S, Catalano PM (2004) Longitudinal changes in energy expenditure and body composition in obese women with normal and impaired glucose tolerance. Am J Physiol Endocrinol Metab 287: E472–E479
View Article
Google Scholar

[39] View Article

[40] Google Scholar

[ref15] 15. Catalano PM, Huston L, Amini SB, Kalhan SC (1999) Longitudinal changes in glucose metabolism during pregnancy in obese women with normal glucose tolerance and gestational diabetes mellitus. Am J Obstet Gynecol 180: 903–916.
View Article
Google Scholar

[42] View Article

[43] Google Scholar

[ref16] 16. DeFronzo RA, Gunnarsson R, Björkman O, Olsson M, Wahren J (1985) Effects of insulin on peripheral and splanchnic glucose metabolism in noninsulin-dependent (type II) diabetes mellitus. J Clin Invest 76: 149–155
View Article
Google Scholar

[45] View Article

[46] Google Scholar

[ref17] 17. Ghanassia E, Brun J-F, Mercier J, Raynaud E (2007) Oxidative mechanisms at rest and during exercise. Clin Chim Acta 383: 1–20
View Article
Google Scholar

[48] View Article

[49] Google Scholar

[ref18] 18. Dabelea D, Crume T (2011) Maternal environment and the transgenerational cycle of obesity and diabetes. Diabetes 60: 1849–1855
View Article
Google Scholar

[51] View Article

[52] Google Scholar

[ref19] 19. Hwang H, Bowen BP, Lefort N, Flynn CR, De Filippis EA, et al. (2010) Proteomics analysis of human skeletal muscle reveals novel abnormalities in obesity and type 2 diabetes. Diabetes 59: 33–42
View Article
Google Scholar

[54] View Article

[55] Google Scholar

[ref20] 20. Carpenter MW, Coustan DR (1982) Criteria for screening tests for gestational diabetes. Am J Obstet Gynecol 144: 768–773.
View Article
Google Scholar

[57] View Article

[58] Google Scholar

[ref21] 21. Tanner CJ, Barakat HA, Dohm GL, Pories WJ, MacDonald KG, et al. (2002) Muscle fiber type is associated with obesity and weight loss. Am J Physiol Endocrinol Metab 282: E1191–E1196
View Article
Google Scholar

[60] View Article

[61] Google Scholar

[ref22] 22. McCurdy CE, Bishop JM, Williams SM, Grayson BE, Smith MS, et al. (2009) Maternal high-fat diet triggers lipotoxicity in the fetal livers of nonhuman primates. J Clin Invest 119: 323–335
View Article
Google Scholar

[63] View Article

[64] Google Scholar

[ref23] 23. Reece EA, Leguizamón G, Wiznitzer A (2009) Gestational diabetes: the need for a common ground. Lancet 373: 1789–1797
View Article
Google Scholar

[66] View Article

[67] Google Scholar

[ref24] 24. Lovering RM, Anderson LD (2008) Architecture and fiber type of the pyramidalis muscle. Anat Sci Int 83: 294–297
View Article
Google Scholar

[69] View Article

[70] Google Scholar

[ref25] 25. Colomiere M, Permezel M, Lappas M (2010) Diabetes and obesity during pregnancy alter insulin signalling and glucose transporter expression in maternal skeletal muscle and subcutaneous adipose tissue. J Mol Endocrinol 44: 213–223
View Article
Google Scholar

[72] View Article

[73] Google Scholar

[ref26] 26. Matthews DR, Hosker JP, Rudenski AS, Naylor BA, Treacher DF, et al. (1985) Homeostasis model assessment: insulin resistance and beta-cell function from fasting plasma glucose and insulin concentrations in man. Diabetologia 28: 412–419.
View Article
Google Scholar

[75] View Article

[76] Google Scholar

[ref27] 27. Frazier AE, Thorburn DR (2012) Biochemical analyses of the electron transport chain complexes by spectrophotometry. Methods Mol Biol 837: 49–62
View Article
Google Scholar

[78] View Article

[79] Google Scholar

[ref28] 28. Boyle KE, Newsom SA, Janssen RC, Lappas M, Friedman JE (2013) Skeletal muscle MnSOD, mitochondrial complex II, and SIRT3 enzyme activities are decreased in maternal obesity during human pregnancy and gestational diabetes mellitus. J Clin Endocrinol Metab 98: E1601–E1609
View Article
Google Scholar

[81] View Article

[82] Google Scholar

[ref29] 29. Reznick RM, Shulman GI (2006) The role of AMP-activated protein kinase in mitochondrial biogenesis. J Physiol (Lond) 574: 33–39
View Article
Google Scholar

[84] View Article

[85] Google Scholar

[ref30] 30. Ruderman NB, Carling D, Prentki M, Cacicedo JM (2013) AMPK, insulin resistance, and the metabolic syndrome. J Clin Invest 123: 2764–2772
View Article
Google Scholar

[87] View Article

[88] Google Scholar

[ref31] 31. Petersen KF, Befroy D, Dufour S, Dziura J, Ariyan C, et al. (2003) Mitochondrial dysfunction in the elderly: possible role in insulin resistance. Science 300: 1140–1142
View Article
Google Scholar

[90] View Article

[91] Google Scholar

[ref32] 32. Koves TR, Ussher JR, Noland RC, Slentz D, Mosedale M, et al. (2008) Mitochondrial overload and incomplete fatty acid oxidation contribute to skeletal muscle insulin resistance. Cell Metab 7: 45–56
View Article
Google Scholar

[93] View Article

[94] Google Scholar

[ref33] 33. Anderson EJ, Lustig ME, Boyle KE, Woodlief TL, Kane DA, et al. (2009) Mitochondrial H2O2 emission and cellular redox state link excess fat intake to insulin resistance in both rodents and humans. J Clin Invest 119: 573–581
View Article
Google Scholar

[96] View Article

[97] Google Scholar

[ref34] 34. Nair KS, Bigelow ML, Asmann YW, Chow LS, Coenen-Schimke JM, et al. (2008) Asian Indians have enhanced skeletal muscle mitochondrial capacity to produce ATP in association with severe insulin resistance. Diabetes 57: 1166–1175
View Article
Google Scholar

[99] View Article

[100] Google Scholar

[ref35] 35. Boushel R, Gnaiger E, Schjerling P, Skovbro M, Kraunsøe R, et al. (2007) Patients with type 2 diabetes have normal mitochondrial function in skeletal muscle. Diabetologia 50: 790–796
View Article
Google Scholar

[102] View Article

[103] Google Scholar

[ref36] 36. Buchanan TA, Xiang AH (2005) Gestational diabetes mellitus. J Clin Invest 115: 485–491
View Article
Google Scholar

[105] View Article

[106] Google Scholar

[ref37] 37. Buchanan TA, Xiang AH, Page KA (2012) Gestational diabetes mellitus: risks and management during and after pregnancy. Nat Rev Endocrinol 8: 639–649
View Article
Google Scholar

[108] View Article

[109] Google Scholar

[ref38] 38. Berchtold MW, Brinkmeier H, Müntener M (2000) Calcium ion in skeletal muscle: its crucial role for muscle function, plasticity, and disease. Physiol Rev 80: 1215–1265.
View Article
Google Scholar

[111] View Article

[112] Google Scholar

[ref39] 39. Park S, Scheffler TL, Rossie SS, Gerrard DE (2013) AMPK activity is regulated by calcium-mediated protein phosphatase 2A activity. Cell Calcium 53: 217–223
View Article
Google Scholar

[114] View Article

[115] Google Scholar

[ref40] 40. Park S, Scheffler TL, Gerrard DE (2011) Chronic high cytosolic calcium decreases AICAR-induced AMPK activity via calcium/calmodulin activated protein kinase II signaling cascade. Cell Calcium 50: 73–83
View Article
Google Scholar

[117] View Article

[118] Google Scholar

[ref41] 41. Constantin B (2014) Dystrophin complex functions as a scaffold for signalling proteins. Biochim Biophys Acta 1838: 635–642
View Article
Google Scholar

[120] View Article

[121] Google Scholar

[ref42] 42. Campbell KP, Kahl SD (1989) Association of dystrophin and an integral membrane glycoprotein. Nature 338: 259–262
View Article
Google Scholar

[123] View Article

[124] Google Scholar

[ref43] 43. Vandebrouck A, Sabourin J, Rivet J, Balghi H, Sebille S, et al. (2007) Regulation of capacitative calcium entries by alpha1-syntrophin: association of TRPC1 with dystrophin complex and the PDZ domain of alpha1-syntrophin. FASEB J 21: 608–617
View Article
Google Scholar

[126] View Article

[127] Google Scholar

[ref44] 44. Mallouk N, Jacquemond V, Allard B (2000) Elevated subsarcolemmal Ca2+ in mdx mouse skeletal muscle fibers detected with Ca2+-activated K+ channels. Proc Natl Acad Sci USA 97: 4950–4955.
View Article
Google Scholar

[129] View Article

[130] Google Scholar

[ref45] 45. Sabourin J, Lamiche C, Vandebrouck A, Magaud C, Rivet J, et al. (2009) Regulation of TRPC1 and TRPC4 cation channels requires an alpha1-syntrophin-dependent complex in skeletal mouse myotubes. J Biol Chem 284: 36248–36261
View Article
Google Scholar

[132] View Article

[133] Google Scholar

[ref46] 46. Sabourin J, Harisseh R, Harnois T, Magaud C, Bourmeyster N, et al. (2012) Dystrophin/α1-syntrophin scaffold regulated PLC/PKC-dependent store-operated calcium entry in myotubes. Cell Calcium 52: 445–456
View Article
Google Scholar

[135] View Article

[136] Google Scholar

[ref47] 47. Murray J, Zhang B, Taylor SW, Oglesbee D, Fahy E, et al. (2003) The subunit composition of the human NADH dehydrogenase obtained by rapid one-step immunopurification. J Biol Chem 278: 13619–13622
View Article
Google Scholar

[138] View Article

[139] Google Scholar

[ref48] 48. Suhane S, Kanzaki H, Arumugaswami V, Murali R, Ramanujan VK (2013) Mitochondrial NDUFS3 regulates the ROS-mediated onset of metabolic switch in transformed cells. Biol Open 2: 295–305
View Article
Google Scholar

[141] View Article

[142] Google Scholar

[ref49] 49. Liu H-Y, Liao P-C, Chuang K-T, Kao M-C (2011) Mitochondrial targeting of human NADH dehydrogenase (ubiquinone) flavoprotein 2 (NDUFV2) and its association with early-onset hypertrophic cardiomyopathy and encephalopathy. J Biomed Sci 18: 29
View Article
Google Scholar

[144] View Article

[145] Google Scholar

[ref50] 50. Mulvey C, Harno E, Keenan A, Ohlendieck K (2005) Expression of the skeletal muscle dystrophin-dystroglycan complex and syntrophin-nitric oxide synthase complex is severely affected in the type 2 diabetic Goto-Kakizaki rat. Eur J Cell Biol 84: 867–883
View Article
Google Scholar

[147] View Article

[148] Google Scholar

[ref51] 51. Gerke V, Creutz CE, Moss SE (2005) Annexins: linking Ca2+ signalling to membrane dynamics. Nat Rev Mol Cell Biol 6: 449–461
View Article
Google Scholar

[150] View Article

[151] Google Scholar

[ref52] 52. Jeon Y-J, Kim D-H, Jung H, Chung SJ, Chi S-W, et al. (2010) Annexin A4 interacts with the NF-kappaB p50 subunit and modulates NF-kappaB transcriptional activity in a Ca2+-dependent manner. Cell Mol Life Sci 67: 2271–2281
View Article
Google Scholar

[153] View Article

[154] Google Scholar

[ref53] 53. Friedman JE, Kirwan JP, Jing M, Presley L, Catalano PM (2008) Increased skeletal muscle tumor necrosis factor-alpha and impaired insulin signaling persist in obese women with gestational diabetes mellitus 1 year postpartum. Diabetes 57: 606–613
View Article
Google Scholar

[156] View Article

[157] Google Scholar

[ref54] 54. Oliva K, Barker G, Rice GE, Bailey MJ, Lappas M (2013) 2D-DIGE to identify proteins associated with gestational diabetes in omental adipose tissue. J Endocrinol 218: 165–178
View Article
Google Scholar

[159] View Article

[160] Google Scholar

[ref55] 55. Rusnak F, Mertz P (2000) Calcineurin: form and function. Physiol Rev 80: 1483–1521.
View Article
Google Scholar

[162] View Article

[163] Google Scholar

[ref56] 56. Long YC, Glund S, Garcia-Roves PM, Zierath JR (2007) Calcineurin regulates skeletal muscle metabolism via coordinated changes in gene expression. J Biol Chem 282: 1607–1614
View Article
Google Scholar

[165] View Article

[166] Google Scholar

[ref57] 57. Guha M, Srinivasan S, Biswas G, Avadhani NG (2007) Activation of a novel calcineurin-mediated insulin-like growth factor-1 receptor pathway, altered metabolism, and tumor cell invasion in cells subjected to mitochondrial respiratory stress. J Biol Chem 282: 14536–14546
View Article
Google Scholar

[168] View Article

[169] Google Scholar

[ref58] 58. Battiprolu PK, Gillette TG, Wang ZV, Lavandero S, Hill JA (2010) Diabetic Cardiomyopathy: Mechanisms and Therapeutic Targets. Drug Discov Today Dis Mech 7: e135–e143
View Article
Google Scholar

[171] View Article

[172] Google Scholar

[ref59] 59. Fitts RH (2011) New insights on sarcoplasmic reticulum calcium regulation in muscle fatigue. J Appl Physiol 111: 345–346
View Article
Google Scholar

[174] View Article

[175] Google Scholar

[ref60] 60. Rullman E, Andersson DC, Melin M, Reiken S, Mancini DM, et al. (2013) Modifications of skeletal muscle ryanodine receptor type 1 and exercise intolerance in heart failure. J Heart Lung Transplant 32: 925–929
View Article
Google Scholar

[177] View Article

[178] Google Scholar

Figures

Abstract

Introduction

Research Design and Methods

Study 1: Proteomic Analysis

Ethics Statement.

Patients and Sample Collection.

Protein Isolation and Mass Spectrometry.

Data Analysis and Bioinformatics.

Study 2: Metabolic Analysis

Ethics Statement.

Patients and Sample Collection.

Plasma Measures.

Mitochondrial Enzyme Activity Assays.

Western Blot.

Mitochondrial DNA Copy Number.

Statistical Analyses

Results

Study 1: Proteomic Analysis

Patient Characteristics.

Mitochondrial and Calcium Signaling Proteins are Altered in Women with GDM.

Study 2: Metabolic Analysis

Patient Characteristics.

Mitochondrial Enzyme Activity is Reduced in Women with GDM.

Discussion

Supporting Information

Table S1.

Acknowledgments

Author Contributions

References