Abstract
Background:
Maternal obesity is associated with unfavorable outcomes, which may be reflected in the as yet undiscovered gene expression profiles of the umbilical cord (UC).
Methods:
UCs from 12 lean (pregravid BMI < 24.9) and 10 overweight/obese (pregravid BMI ≥ 25) women without gestational diabetes were collected for gene expression analysis using Human Primeview microarrays. Metabolic parameters were assayed in mother’s plasma and cord blood.
Results:
Although offspring birth weight and adiposity (at 2 wk) did not differ between groups, expression of 232 transcripts was affected in UC from overweight/obese compared with those of lean mothers. Gene-set enrichment analysis revealed an upregulation of genes related to metabolism, stimulus and defense response, and inhibitory to insulin signaling in the overweight/obese group. We confirmed that EGR1, periostin, and FOSB mRNA expression was induced in UCs from overweight/obese mothers, while endothelin receptor B, KLF10, PEG3, and EGLN3 expression was decreased. Messenger RNA expression of EGR1, FOSB, MEST, and SOCS1 were positively correlated (P < 0.05) with mother’s first-trimester body fat mass (%).
Conclusion:
Our data suggest a positive association between maternal obesity and changes in UC gene expression profiles favoring inflammation and insulin resistance, potentially predisposing infants to develop metabolic dysfunction later on in life.
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Main
Currently in the United States, up to 60% of all pregnancies occur in women who are either overweight (OW) or obese (OB) at conception (1). This poses a significant public health concern as maternal obesity adversely affects the immediate health of both the mother and offspring (2,3). It is hypothesized that maternal obesity leads to developmental programming of excessive weight and adiposity in the offspring (4). Epidemiological and clinical studies (5,6) strongly support this hypothesis, including a recent study of 37,000 individuals that showed greater risk of cardiovascular disease and premature death in those born to OW and OB women (7). Also, findings from numerous animal models (8,9,10,11) show that maternal obesity and obesogenic diets program obesity risk in the offspring. Further support for developmental programming imprinted by maternal obesity comes from observations that children born to women following weight loss after bariatric surgery have diminished risk of obesity compared with children born to the same women prior to the surgery when they were OB (5,6). Recent studies confirm that weight loss in these OB women who then become pregnant is associated with changes in gene expression and DNA methylation of glucoregulatory genes in the offspring (12). Despite these findings, markers indicative of metabolic programming remain yet to be identified.
Much of the mechanistic understanding of programming has come from animal models of gestational obesity. Using a rat model of overfeeding-induced obesity, we previously demonstrated that exposure to maternal obesity, from conception to birth, is sufficient to program increased obesity risk in the offspring (8,13,14,15). Offspring of OB dams are “hyper-responsive” to high-fat diets, gaining greater body weight, fat mass, and additional metabolic sequelae (8,14,15), including decreased fatty acid oxidation and impaired metabolic flexibility evident at weaning. These findings indicate that in a controlled model of maternal obesity, alterations in lipid metabolism, and insulin signaling precede the development of obesity in offspring. However, the relevance of these mechanistic findings to human subjects remains unclear. One limitation to clinical studies is access to tissues from infants and offspring. However, recent studies have shown that the umbilical cord (UC) may be an easily accessible surrogate fetal tissue (16). Unlike the placenta, which is chimeric for both maternal and fetal compartments, the UC is purely fetal in nature and is also likely influenced by factors in fetal circulation. Furthermore, studies in human subjects indicate that methylation status of specific CpG sites in the cord can be predictive of offspring adiposity (16,17). Nonetheless, no studies have examined global gene expression changes in the cord, which presumably could reveal important mechanisms relating to maternal obesity-associated fetal effects.
This study was designed to examine the hypothesis that the effect of maternal obesity on the fetus will be reflected by changes in UC gene expression profiles. Using microarrays, we characterized global gene expression in cord tissue from uncomplicated pregnancies in lean and OB women. First, we examined inflammatory mediators and insulin signaling gene expression in cord tissue from women who were OB at conception. Secondly, we conducted anthropometric and body composition assessments, in both the mother and infant, along with the evaluation of metabolic and endocrine parameters normally dysregulated with the OB phenotype. To gain greater mechanistic insights, we also evaluated correlations between gene expression changes and maternal and fetal adiposity and endocrine parameters. Finally, we examined key pathways known to regulate insulin signaling in the cord and the contributions of circulating factors in cord blood (CB) in mediating UC gene expression changes in obesity. Our data strongly suggest that exposure to maternal obesity during fetal development, in the absence of gestational diabetes or any other pregnancy complications, alters fetal gene expression.
Results
Maternal Obesity Increases UC Plasma Leptin and Insulin Levels
A number of maternal anthropometric and metabolic parameters were measured before and during pregnancy ( Table 1 ). As expected, there were significant differences in BMI (22.28 ± 0.46 vs. 31.16 ± 1.11 kg/m2; P < 0.001) and percent body fat (30.65 ± 0.91% vs. 43.80 ± 1.36%; P < 0.001) between lean and overweight/obese (OW/OB) subjects both before and after conception. Moreover, subjects in the OW/OB group continued to be heavier throughout pregnancy (P < 0.001). As part of the study design, all participants (lean and OW/OB) were counseled to maintain weight gain during pregnancy according to the Institute on Medicine guidelines. Since Institute on Medicine–recommended weight gain for OW/OB women is lower than that for lean women, absolute gestational weight gain was significantly lower in OW/OB mothers (P < 0.001) relative to their lean counterparts. Fasting plasma insulin and leptin levels were significantly higher (2.0-fold and 1.5-fold, respectively) at 30 wk of gestation in OW/OB compared with lean mothers, while triglycerides and interleukin-6 were numerically greater in OW/OB mothers, but the difference was not statistically significant ( Table 1 ). OW/OB subjects showed greater insulin resistance, as assessed by homeostatic model-insulin resistance values (1.34 ± 0.2 vs. 2.03 ± 0.3; P = 0.08). There were no differences in fasting glucose or nonesterified fatty acid concentrations between the groups.
Fetal anthropometric parameters and cord plasma (CP) metabolic parameters were also measured ( Table 2 ). There was no difference in birth weight, birth length or percent fat mass at 2 wk of age between offspring of lean and OW/OB mothers. However, CP leptin levels from OW/OB mothers were 2.2-fold higher (P ≤ 0.02) than that of lean mothers. Also, CP insulin was ~1.5-fold higher in infants born to OW/OB mothers compared with the infants born to lean counterparts, though this difference did not attain statistical significance.
Maternal Obesity Significantly Alters Gene Expression in UC
Microarray analysis identified 232 differentially expressed genes in UC tissue (±1.4-fold change; P < 0.05). Hierarchical clustering of microarray results is shown in Figure 1a , b . Gene Ontology terms analysis of biological processes was performed with the list of differentially expressed genes and identified processes related to insulin receptor signaling, response to insulin stimulus, negative regulation of glucose import and transport, and cellular response to fatty acids to be affected in UC tissue due to maternal obesity ( Figure 1c ). Gene set enrichment analysis for biological processes identified immediate/early transcription factors (EGR1, FOS, and FOSB), as well as genes involved in cytokine signaling (SOCS1) and Wnt/β-catenin signaling (MEST) to be upregulated in UC from OW/OB mothers, while genes related to vascular reactivity (EDNRB), angiogenesis (VEGFα), transforming growth factor-β signaling (KLF10), prolyl hydroxylase activity (EGLN3), tumor suppressor activity (PEG3), and Akt signaling (PDK1) were significantly downregulated in UCs from OW/OB mothers ( Figure 1b ).
Maternal Percent Body Fat Correlates Strongly With UC Gene Expression
To examine the relationship between maternal adiposity and UC gene expression, we carried out linear regression between these variables using the list of differentially expressed genes. Maternal pregravid percent body fat was positively correlated with transcript levels of SOCS1, MEST, EGR1, and FOSB ( Figure 2a ), and negatively correlated with transcript levels of KLF10 ( Figure 3a ) and PDK1 (r = −0.42; P = 0.06; data not shown). Quantitative real-time PCR confirmed that mRNA expression of EGR1, POSTN (a cell adhesion molecule), and FOSB was significantly higher in UCs from OW/OB mothers compared with lean mothers ( Figure 2b ), while mRNA expression of EDNRB, KLF10, EGLN3, PEG3, PDK1, and VEGFα was significantly lower in UCs from OW/OB mothers ( Figure 3b ). Expression of PAI-1 (an inhibitor of tissue plasminogen activator), NR4A1 (transcription factor involved in apoptosis), and NEDD9 (cytoskeletal adaptor molecule) tended to be higher in UCs from OW/OB mothers, though the difference between groups was not statistically significant (data not shown).
Maternal and CP Plasma Metabolic Factors Correlate With EGR1, FOSB, PDK1, and SOCS1 Expression
We also carried out correlation analysis of UC gene expression with various maternal and CP metabolic factors. In the UC, expression of EGR1 and FOSB positively correlated with maternal fasting insulin ( Figure 4a ) and CP insulin levels ( Figure 4c ), while PDK1 negatively correlated with maternal insulin ( Figure 4a ) and CP insulin levels ( Figure 4c ). Expression of SOCS1 positively correlated with maternal leptin levels ( Figure 4b ).
Basal Akt Activation, But Not Erk1/2 Activation Is Higher in UC From OW/OB Mothers
Since CB leptin and insulin levels were higher in OW/OB mothers compared with lean mothers, we next examined the phosphorylation of Akt, a pathway common to both leptin and insulin signal transduction. Western blot analysis demonstrated that phosphorylated Akt (pAkt Ser473) levels were greater in UCs from OW/OB mothers. Likewise, when pAkt was normalized to total Akt, it was significantly higher in UC from OW/OB mothers compared with lean mothers ( Figure 5a ). Insulin also has mitogenic effects, via activation of Erk1/2. However, no statistical differences were observed in pErk1/2 or total Erk1/2 expression in UCs between both groups ( Figure 5a ), suggesting that maternal obesity-associated changes specifically affect certain insulin signaling pathways.
CP From OW/OB Mothers Alters In Vitro Endothelial Cell Gene Expression
As the composition of UC plasma varied between lean and OW/OB mothers, we hypothesized that circulating factors in the CP of offspring from OW/OB mothers could be driving changes in UC gene expression. Endothelial cells, the innermost layer of cells in blood vessels that are in direct contact with circulating blood, and smooth muscle cells of the umbilical blood vessels contribute largely to total RNA isolated from UCs. Thus, cultured human umbilical vein endothelial cells and human umbilical vein smooth muscle cells were used to study CP/blood vessel interactions. Akin to changes seen in vivo, EGR1 mRNA expression was significantly increased when human umbilical vein endothelial cells and human umbilical vein smooth muscle cells were cultured in the presence of CP from OW/OB mothers compared with CP from lean mothers ( Figure 5b ).
Discussion
The risk of obesity in adulthood is subject to programming in utero. Evidence from both experimental and clinical studies suggests that maternal obesity is an important determinant of weight gain and adiposity in offspring (4). In this study, we leveraged microarray-based gene expression profiling to identify the major transcriptomic differences in UC tissue at term associated with maternal obesity. The UC offers several distinct advantages, including being an easily accessible fetal tissue and containing cell types relevant to developmental programming (endothelial, smooth muscle, and mesenchymal stem cells). To our knowledge, this is the first report to examine global gene expression in the UC. Several novel findings from this study include: (i) maternal obesity alters global gene expression in the offspring at birth, despite no differences in birth weight, birth length, and fat-free mass in the offspring; (ii) changes in the UC, specifically appear to be related to insulin and cytokine signaling, immediate/early transcription factors, angiogenesis, and vascular reactivity; and (iii) identification of specific genes that are associated with maternal fat mass. Furthermore, we identified modulation of imprinted genes (MEST and PEG3) known to regulate fat mass and energy expenditure to be affected by maternal obesity. Our data suggest that gene expression profiles of infants born to OW/OB women differ significantly from those of lean women, even in the absence of group differences in offspring body composition.
Obesity is associated with dysregulation of a number of metabolic pathways, most notably by the insulin signaling pathway (18). This is thought to be due in a large part to the chronic low-grade inflammation present both systemically and in insulin-sensitive tissues like skeletal muscle and adipose tissue. As anticipated, maternal plasma insulin and homeostatic model-insulin resistance was higher in OW/OB mothers compared with lean mothers as expected, while fasting plasma glucose did not differ. While OW/OB women did not meet the clinical criteria of gestational diabetes, insulin resistance was evident. Consequently, CP insulin levels tended to be higher for infants of OW/OB mothers, compared with that of lean mothers. These effects did not attain statistical significance, possibly due to the small sample size. Nevertheless, the increase of CP insulin levels in OW mothers is consistent with a previous report in a larger cohort (53 lean and 68 OB participants), which considers more pronounced gestational obesity (2). Consistent with our findings, these researchers also observed that OW/OB mothers were more insulin resistant than lean mothers, and at birth, offspring from OW/OB mothers were insulin resistant compared with offspring from lean mothers. Since maternal insulin does not cross the blood/placental barrier (19), the fetal pancreas is the primary source of fetal insulin, suggesting that maternal obesity is driving dysregulation of insulin signaling in utero.
Another important obesity-related peptide is leptin, which is a proinflammatory cytokine involved in the regulation of food intake and energy balance, and is mainly produced in white adipose tissue and, to a lesser extent, in the placenta (20). Leptin levels correlate with adiposity and increase during the first two trimesters of pregnancy (20). Similar to insulin, leptin does not cross the blood/placental barrier (21), suggesting that CP leptin levels are indeed a marker of fetal adipocyte function. Maternal leptin levels in late pregnancy are positively correlated with infant birth weight (22); however, higher CP leptin levels correspond with less weight gain in the first 6 mo of life and lower BMI at the age of 3 years (23). Not surprisingly, in our cohort, maternal leptin was significantly higher in OW/OB mothers compared with lean mothers. Interestingly, even though fat mass of 2-wk-old offspring was not different between OW/OB and lean mothers, CP leptin levels were higher in offspring of OW/OB mothers which suggests alterations in adipocyte function in offspring of OW mothers at birth. We also observed that UC mRNA expression of SOCS1, a protein downstream of inflammatory cytokine receptor activation, positively correlates with maternal fat mass and maternal leptin levels. SOCS1 expression is induced by both cytokines and insulin (24) and functions as a negative regulator of cytokine signal transduction. The correlation of SOCS1 expression with maternal leptin levels may reflect a fetal response to limit the actions of increased leptin and insulin signaling.
Chronic subclinical inflammation is an important recurring feature in obesity that affects insulin sensitivity. Studies in animal models of obesity and in pregnant women with obesity have clearly shown that a proinflammatory milieu extends to the maternal–fetal interface in the early periimplantation period and in the placenta in late gestation. Likewise, maternal obesity in sheep and nonhuman primates has been shown to induce inflammation in the placenta, fetal liver, heart, and intestine (25,26,27). The placenta in OB women is likewise characterized by inflammation and associated with increased systemic lipopolysaccharide levels (28,29,30,31). Our previous studies demonstrated activation of c-Jun N-terminal kinase and NF-κB pathways in placenta from OB women (32). Obesity is associated with several physiological changes (hyperinsulinemia, elevated acute phase proteins, and subclinical endotoxemia) that could potentially contribute to placental inflammation. Also, in OB pregnancies it has been reported elevated levels of fatty acids and cytokines that induce pro-inflammatory responses in a variety of cellular contexts (28,33). Recently, we identified c-Jun N-terminal kinase/EGR1 signaling as a key pathway through which lipotoxicity induces inflammation in placenta cells and in term placenta from OB women (32). Early growth response-1 is a proinflammatory transcription factor activated by numerous signals, including cytokines, hypoxia, growth factors, and hormones (34). In the context of obesity and metabolic syndrome, insulin stimulates EGR1 expression and reduces insulin sensitivity by altering PI3K/Akt and Erk/MAPK signaling (35). In humans, EGR1 expression positively correlates with BMI and is highly expressed in adipocytes (36). Our report is the first to observe that UC EGR1 expression is strongly correlated with maternal fat mass, maternal insulin levels, and fetal insulin levels, suggesting that maternal obesity per se drives the increases in maternal and fetal insulin, which in turn up-regulates EGR1 expression, and possibly contributing to alterations in fetal inflammatory markers and insulin sensitivity. Moreover, CP from OW/OB mothers increased EGR1 expression in endothelial and smooth muscle cell cultures, demonstrating the presence of factor(s) that can induce changes in gene expression in cells present in the UC. Interestingly, in mature adipocytes made insulin resistant with TNFα, a number of genes remained insulin-responsive, including EGR1 (37). Thus it is possible to envision that EGR1 transcriptional activity is maintained even in the face of elevated maternal and fetal insulin levels associated with maternal obesity.
There are a number of limitations to our study. First, we used a relatively small sample size. Nevertheless, we were able to identify significant differences in gene expression as a function of maternal body composition. Second, the validity of using the UC as a measure of offspring gene expression is not well established. However, recent reports suggest that the cord is a suitable surrogate for fetal tissue (16). While our results provide a unique snapshot of offspring gene expression at birth, it is unclear whether UC gene expression correlates with gene expression and function in metabolically important tissues such as liver, adipocytes, and skeletal muscle. However, mesenchymal stem cells present in Wharton’s jelly of the UC are able to differentiate into all mesoderm-derived tissues, including the aforementioned metabolically relevant cell types (38,39). Further, recent studies have shown that methylation status of specific CpG sites in the cord can be predictive of offspring adiposity, suggesting that alterations in the cord may be reflective of meaningful changes in metabolic tissues. A third limitation is that we used UC samples that likely contained all cell types within the UC and thus we are unable to determine changes in gene expression for specific cell subtypes. Despite these limitations, this study identifies specific mechanistic targets in offspring at birth that are affected by maternal obesity. We demonstrate that maternal obesity alters global gene expression in the offspring at birth, despite no differences in birth weight and fat-free mass in the offspring, and these changes in UC gene expression specifically appear to be related to insulin and cytokine signaling, immediate/early transcription factors, angiogenesis, and vascular reactivity. Lastly, we identified specific genes that are associated with maternal fat mass. Our findings suggest that maternal obesity is responsible for development changes that may contribute to the offspring’s risk of becoming OB and provide a starting point for identifying key pathways important in the development of obesity.
Methods
Sample Collection and Processing
The study protocol was approved by the Institutional Review Board at the University of Arkansas for Medical Sciences (UAMS) (NCT01131117) and informed consent was obtained from all participants. We studied participants enrolled in an ongoing longitudinal study of lean and OB pregnant women and their term infants (the Glowing study) designed to investigate the effect of maternal obesity on offspring metabolism, adiposity, and growth. For this report, UC and CB were collected from 12 lean (pregravid BMI < 25 kg/m2) and 10 OW/OB (BMI ≥ 25 kg/m2) mothers. All study visits were conducted at the Arkansas Children’s Nutrition Center, UC and CB were collected at delivery in one of five local area hospitals. All subjects were either recruited prepregnancy or <10 wk of pregnancy and were second parity (because multiparity is a risk factor for obesity) nonsmoking mothers, without preexisting or gestational diabetes, preeclampsia, or other pregnancy complications. Maternal body composition was assessed between 4 and 10 wk of pregnancy (Bodpod; Cosmed, Rome, Italy), and blood was collected at 30 wk of pregnancy for measurement of various metabolic parameters in plasma. Infant body composition was determined 2 wk after birth using Peapod (Cosmed). After collection, UCs were rinsed three times in PBS, snap frozen in liquid nitrogen, and stored at −70 °C. While still frozen, the outer membrane of the UC was removed with a sterile blade, leaving UC arteries, vein, and Wharton’s jelly. Venous CB was collected in heparinized tubes, and CP was isolated by centrifugation and stored at −70 °C.
Metabolic and Cytokine Measurements in Plasma
Insulin, leptin, and interleukin-6 were measured in maternal and CP using ELISA (EMD Millipore, Boston, MA). Plasma glucose and triglycerides were assayed using colorimetric reagents (Fisher Scientific, Waltham, MA). Nonesterified fatty acids were quantitated with nonesterified fatty acid-C reagents (Wako Chemicals USA, Richmond, VA). Homeostatic model-insulin resistance values were calculated using the HOMA Calculator (Diabetes Trials Unit, The University of Oxford, Oxford, UK)(40). Cytokine and metabolite measurements were performed in duplicate for all CP samples.
UC RNA Isolation and Microarray Analysis
Total UC RNA was isolated from 100 mg of dissected cord tissue using TRI reagent (Molecular Research Center, Cincinnati, OH) and purified using RNeasy Mini columns including DNase digestion (Qiagen, Valencia, CA). For gene expression profiling, individual microarrays (GeneChip Primeview Human Gene Expression Array; Affymetrix, Santa Clara, CA) were used for each UC sample. Briefly, 0.5 μg of purified RNA was used to synthesize cDNA. Biotin-labeled aRNA was synthesized from double-stranded cDNA using the GeneChip 3′ IVT labeling kit (Affymetrix). The wash and staining protocols were performed with GeneChip Scanner 3000 according to the manufacturer’s instructions, and the probe arrays were scanned directly after hybridization.
Microarray Data Normalization and Analysis
Microarray data analysis was carried out using GeneSpring v11 software (Agilent Technologies, Santa Clara, CA). CEL files containing the probe level intensities were processed using the robust multiarray analysis algorithm, for background adjustment, normalization, and log2 transformation of perfect match values. Subsequently, the data were subjected to normalization by setting measurements less than 0.01 to 0.01 and by per-chip and per-gene normalization using GeneSpring normalization algorithms. The normalized data were used to generate lists of differentially expressed genes between UCs from lean and OB mothers. Genes were filtered based on minimum ±1.4-fold change (lean vs. OW/OB) and P ≤ 0.05 using Student’s t-test. A list of transcripts that were differentially expressed as a function of treatment was generated, and correlation-based hierarchical clustering between groups was performed. Enrichment of Gene Ontology terms for biological processes was performed using GeneSpring and GoRilla. Finally, gene-set enrichment analysis was utilized to identify molecular functions and transcription factors enriched in UC from OB mothers. Gene-set enrichment analysis does not rely on an arbitrary cutoff (such as fold change between groups) and is a computational method that determines whether an a priori-defined set of genes shows statistically significant and concordant differences between two biological states.
Cell Culture
Human umbilical vein endothelial cells and human umbilical vein smooth muscle cells were purchased from Cell Applications (San Diego, CA), grown in Endothelial Cell Growth Medium or Smooth Muscle Growth Medium (Cell Applications), respectively, and used between passages 2 and 8. Cells were switched to serum-free growth medium (Cell Applications, supplemented with 0.25% heat-inactivated bovine serum albumin) upon reaching ~80% confluency in six-well plates and treated with either lean or OW/OB CP (1%) for 48 h. Pooled plasma from each group (lean and OW/OB) was utilized for cell treatment experiments. After 48 h of treatment, human umbilical vein endothelial cells and human umbilical vein smooth muscle cells were washed once with PBS and then RNA was isolated using the RNeasy Mini kit (Qiagen) with oncolumn DNase treatment.
Real-Time Reverse-Transcriptase PCR
One microgram of total RNA was reverse transcribed using the iScript cDNA synthesis kit (Biorad, Hercules, CA), and subsequent real-time PCR analysis was performed using the ABI Prism 7500 sequence detection system (Applied Biosystems, Foster City, CA). Gene-specific primers were designed using Primer Express Software (Applied Biosystems) for endothelin receptor B (EDNRB, Fwd: 5′-CAGATATCGAGCTGTTGCTTCTTG-3′, Rev: 5′-GAACCACAGAGACCACCCAAAT-3′), egl nine homolog 3 (Caenorhabditis elegans) (EGLN3, Fwd: 5′-AGAAAGGGCAGAAGCCAAAAAG-3′, Rev: 5′-AGAAAGGGCAGAAGCCAAAAAG-3′), early growth response 1 (EGR1, Fwd: 5′-AGGCCGAGATGCAGCTGAT-3′, Rev: 5′-CATCTCCTCCAGCTTAGGGTAGTT-3′), FBJ murine osteosarcoma viral oncogene homolog B (FOSB, Fwd: 5′-GTCCTACGGAGCCTGCACTTT-3′, Rev: 5′-AACGTCCCGTTCCAACAATG-3′), Kruppel-like factor 10 (KLF10, Fwd: 5′-AATGAAAGCAGCCAGCATCCT-3′, Rev: 5′-CAGCGGCACATGGTATGTTCT-3′), mesoderm expression transcript (MEST, Fwd: 5′-CCATCCTCACACGACTGATGAA-3′, Rev: 5′-CATGTCCCACAGCTCACTCTCA-3′), neural precursor cell expressed, developmentally downregulated 9 (NEDD9, Fwd: 5′-CTTATGGCAAGGGCCTTATATGA-3′, Rev: 5′-CCCCCTGTGTTCTGCTCTATG-3′), nuclear receptor subfamily 4 group A member 1 (NR4A1, Fwd: 5′-AAGGCCGCTGTGCTGTGT-3′, Rev: 5′-GCACTGTGCGCTTGAAGAAG-3′), plasminogen activator inhibitor-1 (PAI1, Fwd: 5′-ATGTTCATTGCTGCCCCTTATG-3′, Rev: 5′-CTGGTCATGTTGCCTTTCCA-3′), phosphoinositide-dependent kinase-1 (PDK1, Fwd: 5′-CTGGCTGGTTTTGGTTATGGAT-3′, Rev: 5′-GCATCTGTCCCGTAACCCTCTA-3′), paternally expressed 3 (PEG3, Fwd: 5′-GACCCTGATCAAACTCCGAAAC-3′, Rev: 5′-TCAGGTACTGCTCAAGGACCAA-3′), periostin (POSTN, Fwd: 5′-TGGAAGAGACGGTCACTTCACA-3′, Rev: 5′-AAGCCACTTTGTCTCCCATGAT-3′), suppressor of cytokine signaling 1 (SOCS1, Fwd: 5′-AGCTCCTTCCCCTTCCAGATT-3′, Rev: 5′-CCACATGGTTCCAGGCAAGTA-3′), signal recognition particle 14 kDa (SRP14, Fwd: 5′-TGACGGAGCTGACCAGACTTT-3′, Rev: 5′-CTTCTTTGGAATGGGTTTGGTT-3′), and vascular endothelial growth factor α (VEGFα, Fwd: 5′-TCTACCTCCACCATGCCAAGT-3′, Rev: 5′-GCGCTGATAGACATCCATGAAC-3′). The relative amounts of mRNA were quantified using a standard curve and normalized to the expression of human SRP14 mRNA.
Western Blot Analysis
Total cell and tissue lysates were prepared in radioimmunoprecipitation assay buffer (25 mmol/l Tris–HCl; 150 mmol/l NaCl; 1.0% NP-40; 1.0% deoxycholic acid; 0.1% sodium dodecyl sulfate; and 2 mmol/l EDTA; Cell Signaling, Danvers, MA) containing 1 mmol/l phenylmethanesulfonyl fluoride, protease inhibitor cocktail, and phosphatase inhibitor cocktail. Proteins were resolved by sodium dodecyl sulfate PAGE and immunoblotting was carried out using standard procedures. Membranes were incubated with primary antibodies against pAkt, Akt, pErk1/2, and Erk1/2 (Cell Signaling), and α-tubulin (Active Motif, Carlsbad, CA) overnight at 4 °C. Horseradish peroxidase-conjugated secondary antibodies against rabbit and mouse IgG (GE Healthcare, Pittsburgh, PA) were used for protein detection. Densitometric analysis of immunoblots was performed using ImageJ software (v 1.47t, National Institutes of Health, Bethesda, MD).
Data Analysis
Data are presented as mean ± SEM. Real-time reverse-transcriptase PCR data are expressed as mean fold change from lean ± SEM and western blot data are expressed as mean ± SEM. As the data were normally distributed, correlations were calculated using Pearson’s correlation coefficient (r). Statistical differences between UC from lean and OW/OB mothers were determined using a two-tailed student’s t-test. In cases where three or more groups were compared, a one-way ANOVA followed by all-pair wise comparison by the Student–Neuman–Keuls method was performed. P ≤ 0.05 was considered statistically significant. Statistical analyses were performed using GraphPad Prism 6 (v 6.02; La Jolla, CA).
Statement of Financial Support
These studies were supported by the US Department of Agriculture-ARS-CRIS 6251-51000-005-00D. Nursing support for these studies was provided in part by the University of Arkansas for Medical Sciences Translational Research Institute funded by the National Institutes of Health Clinical and Translational Science Award program, grants UL1-TR-000039 and KL2-TR-000063. The funding agencies had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Disclosures
None.
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We gratefully acknowledge the members of the Arkansas Children’s Nutrition Center Human Studies Core for their assistance in these studies.
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Thakali, K., Saben, J., Faske, J. et al. Maternal pregravid obesity changes gene expression profiles toward greater inflammation and reduced insulin sensitivity in umbilical cord. Pediatr Res 76, 202–210 (2014). https://doi.org/10.1038/pr.2014.72
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DOI: https://doi.org/10.1038/pr.2014.72
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