Subhabrata Basu

Obesity in pregnancy stimulates macrophage accumulation and inflammation in the placenta

Abstract Obesity and pregnancy are associated with a combination of insulin resistance and inflammatory changes which exacerbate in combination. Based on the similarity between the inflammatory transcriptomes of adipose tissue and placenta, we hypothesized that the placenta develops exaggerated inflammation in response to obesity. The aim of this study was to characterize placental inflammatory mediators and macrophage accumulation in relation to peripheral inflammation in obesity. Placental macrophages and maternal peripheral blood mononuclear cells (PBMC) from 20 obese and 15 lean women were functionally and phenotypically characterized using immunohistochemistry, flow cytometry and expression for macrophage markers and inflammatory cytokines. The number of resident CD68+ and CD14+ cells was increased 2–3 fold in the placenta of obese as compared to lean women. The macrophage population was characterized by a marked phenotypic heterogeneity with complex subsets of CD14+, CD68+ and CD11b+ (mac-1) cells and by an increased expression of the pro-inflammatory cytokines IL-1, TNF-alpha, IL-6. Placental inflammation was associated with an activation of PBMC gene expression with an increase in the monocyte differentiation and maturation markers CD14 and CD68 in maternal but not fetal PBMC. The inflammatory changes were associated with higher plasma concentrations of C-reactive protein and IL-6 in obese compared to lean women. In conclusion, the chronic inflammation state of pre-gravid obesity is extending to in utero life with accumulation of a heterogeneous macrophage population and pro-inflammatory mediators in the placenta. The resulting inflammatory milieu in which the fetus develops may have critical consequences for short and long term programming of obesity.

Pregravid obesity associates with increased maternal endotoxemia and metabolic inflammation.

Obese pregnant women develop severe insulin resistance and enhanced systemic and placental inflammation, suggesting associated modifications of endocrine and immune functions. Activation of innate immunity by endotoxins/lipopolysaccharides (LPS) has been proposed as a mechanism for enhancing metabolic alterations in disorders with insulin resistance. The aim of this study was to characterize the immune responses developed by the adipose tissue (AT) and their potential links to maternal endotoxemia in pregnancy with obesity. Blood and subcutaneous abdominal AT were obtained from 120 lean and obese women (term pregnancy) recruited at delivery. Gene expression was assessed in AT and stromal vascular cells isolated from a subset of 24 subjects from the same cohort. Doubling of plasma endotoxin concentrations indicated subclinical endotoxemia in obese compared with lean women. This was associated with significant increase in systemic C‐reactive protein and interleukin‐6 (IL‐6) but not tumor necrosis factor‐α (TNF‐α) concentrations. AT inflammation was characterized by accumulation of CD68+ macrophages with a threefold increased gene expression of the macrophage markers CD68, EMR1, and CD14. Gene expression for cytokines IL‐6, TNF‐α, IL‐8, and monocyte chemotactic protein‐1 (MCP1) and for LPS—sensing CD14, toll‐like receptor 4 (TLR4), translocating chain‐associated membrane protein 2 was 2.5‐5‐fold higher in stromal cells of obese compared to lean. LPS‐treated cultured stromal cells of obese women expressed a 5–16‐fold stimulation of the same cytokines upregulated in vivo. Our data demonstrate that subclinical endotoxemia is associated with systemic and AT inflammation in obese pregnant women. Recognition of bacterial pathogens may contribute to the combined dysfunction of innate immunity and the metabolic systems in AT.

Protease-Resistant Human Prion Protein and Ferritin Are Cotransported across Caco-2 Epithelial Cells: Implications for Species Barrier in Prion Uptake from the Intestine

Foodborne transmission of bovine spongiform encephalopathy (BSE) to humans as variant Creutzfeldt-Jakob disease (CJD) has affected over 100 individuals, and probably millions of others have been exposed to BSE-contaminated food substances. Despite these obvious public health concerns, surprisingly little is known about the mechanism by which PrP-scrapie (PrPSc), the most reliable surrogate marker of infection in BSE-contaminated food, crosses the human intestinal epithelial cell barrier. Here we show that digestive enzyme (DE) treatment of sporadic CJD brain homogenate generates a C-terminal fragment similar to the proteinase K-resistant PrPSc core of 27-30 kDa implicated in prion disease transmission and pathogenesis. Notably, DE treatment results in a PrPSc-protein complex that is avidly transcytosed in vesicular structures across an in vitro model of the human intestinal epithelial cell barrier, regardless of the amount of endogenous PrPC expression. Unexpectedly, PrPSc is cotransported with ferritin, a prominent component of the DE-treated PrPSc-protein complex. The transport of PrPSc-ferritin is sensitive to low temperature, brefeldin-A, and nocodazole treatment and is inhibited by excess free ferritin, implicating a receptor- or transporter-mediated pathway. Because ferritin shares considerable homology across species, these data suggest that PrPSc-associated proteins, in particular ferritin, may facilitate PrPSc uptake in the intestine from distant species, leading to a carrier state in humans.

Differential regulation of genes for fetoplacental lipid pathways in pregnancy with gestational and type 1 diabetes mellitus.

OBJECTIVE Changes in metabolic homeostasis in pregnant diabetic women are potential determinants of increased adiposity of the fetus. The aim of this study was to characterize diabetes mellitus-induced changes in genes for fetoplacental energy metabolism in relation to fetal adiposity. STUDY DESIGN Placentas of women with type 1 diabetes mellitus, gestational diabetes mellitus (GDM), or no complications were analyzed by microarray profiling. The pattern of gene expression was assessed in primary placental cell cultures. RESULTS Diabetes mellitus was associated with 49 alterations in gene expression at key steps in placental energy metabolism, with 67% of the alterations related to lipid pathways and 9% of the alterations related to glucose pathways. Preferential activation of lipid genes was observed in pregnancy with GDM. Type 1 diabetes mellitus induced fewer lipid modifications but an enhancement of glycosylation and acylation pathways. Oleate enhanced expression of genes for fatty acid esterification and the formation of lipid droplets 3 times as much as glucose in cultured placental cells. CONCLUSION These results point to fatty acids as preferential lipogenic substrates for placental cells and suggest that genes for fetoplacental lipid metabolism are enhanced selectively in GDM. The recruited genes may be instrumental in increasing transplacental lipid fluxes and the delivery of lipid substrates for fetal use.

Increased Death of Adipose Cells, a Path to Release Cell‐Free DNA Into Systemic Circulation of Obese Women

Remodeling of adipose tissue is required to support the expansion of adipose mass. In obesity, an increased death of adipocytes contributes to the accelerated cellular turnover. We have shown that obesity in pregnancy is associated with metabolic and immune alterations in the adipose tissue. In this study, we characterized the mechanisms responsible for increased death of adipose cells of pregnant obese women and its functional consequences. We postulated that a higher turnover of dead cells in white adipose tissue of obese women would translate into release of cell‐free DNA (cfDNA) into their systemic circulation. Increase in adipose mass of obese compared to lean women results from a lesser number of hypertrophic adipocytes and an accumulation of macrophages in the stromal vascular fraction (SVF). The adipocytes of obese displayed enhanced necrosis with a loss of perilipin staining at the plasma membrane. Apoptosis was prominent in SVF cells with an increased expression of caspase 9 and caspase 3 and a higher rate of terminal deoxynucleotidyl transferase‐mediated deoxyuridine triphosphate nick end‐labeling (TUNEL) positive CD68 macrophages in obese vs. lean. Whereas circulating fetal cfDNA concentrations were not changed, there was a twofold increase in circulating glyceraldehyde‐3‐phosphate dehydrogenase (GAPDH) cfDNA and adipose tissue GAPDH mRNA in obese women. The maternal systemic GAPDH cfDNA was positively correlated with BMI and gestational weight gain. These data suggest that the active remodeling of adipose tissue of obese pregnant women results in an increased release of cfDNA of maternal origin into the circulation.

A multifactorial relationship exists between total circulating cell-free DNA levels and maternal BMI

Maternal obesity affects 1 in 5 pregnant women in the United States1. Maternal obesity is associated with increased circulating total, but not fetal, cf DNA2. This may be a result of increased production or decreased clearance of cf DNA in obese women. It is more likely that this is due to increased production of total cfDNA, because decreased clearance would also likely lead to an increase in cell-free fetal cfDNA. In a prior study performed on obese pregnant women, we showed that active remodeling of adipose tissue via adipocyte necrosis and/or apoptosis of the stromal vascular fraction results in an increased release of cfDNA of maternal origin into the circulation3. The focus of the prior study was on the mechanisms underlying the release of the cfDNA. In this study we more closely examined the correlation between maternal weight and total DNA levels. This study was approved by the Institutional Review Boards at Tufts Medical Center and Metrohealth Medical Center. The samples are from the same cohort reported previously3, but the analysis is different. Briefly, sixteen obese (mean=39.2; pre-gravid BMI range 31–51) and 14 lean (mean 21.8; pre-gravid BMI range 17–24) women carrying male fetuses and 10 women carrying female fetuses (negative controls) were recruited at term (37–40 weeks) prior to an elective cesarean section. Written informed consent was obtained prior to obtaining the samples. Women with a multiple gestations, placenta previa or invasive placentation, labor, infection, fetal anomalies or aneuploidy, intrauterine growth restriction, or preeclampsia were excluded. Maternal peripheral venous blood was collected at MetroHealth Medical Center on admission to labor and delivery, prior to placement of an intravenous line for hydration. All subjects had the same instructions prior to admission and had nothing to eat or drink for 6–8 hours prior to the blood draw. The blood was collected in an EDTA tube and plasma was separated by centrifugation and kept frozen at −20°C prior to being shipped to Tufts Medical Center for further analysis. DNA was extracted from 400 uL of plasma using the QIAamp DNA Blood Mini Kit (Qiagen, Valencia, CA) according to the blood and body fluid protocol. DNA was eluted in 50 μL of the elution buffer. Real time quantitative PCR amplification was performed as previously described4 to amplify glyceraldehyde-3-phosphate dehydrogenase (GAPDH) and the Y chromosome sequence DYS14 as markers of total and fetal DNA, respectively. All samples were analyzed in triplicate. Analysis was blinded, and a female processed and handled all samples so that there was no risk of contaminating samples with male DNA. Conversion of raw PCR data to genome equivalents per mL of plasma was performed using the methods of Lo et al.5 The levels of total and fetal cf DNA in plasma from lean and obese women were compared using the t test. In addition, the maternal plasma volume from both obese and lean subjects was adjusted for blood volume6 and compared using the t test, as prior experiments in our laboratory suggested an increased blood volume as a function of weight7. Finally, we performed a regression analysis between total and fetal cf DNA and maternal BMI. Analysis of the raw data from all subjects showed that there was a 1.7% increase in total cell-free DNA per BMI unit (kg/m2). Following adjustment for blood volume, there was a 3.2% increase per BMI unit (Table 1). When the subjects were categorized into lean and obese groups, however, there was a decrease in total cf DNA per BMI unit in lean women and an increase in obese women (Table 1 and Figure 1). Neither of these changes were statistically significant. However, this lack of significance may be a function of the small sample size. Further studies with more subjects are warranted to further characterize this relationship between cf DNA and BMI. Figure 1 Graph showing relationship between total cell-free DNA levels and body mass index [BMI]. The correlation coefficient between BMI and cfDNA for the lean population is -0.061 (p=0.41) and for the obese population is 0.23 (p=0.20). Table 1 Change in maternal cell-free DNA by body mass index In this study, we found a correlation between BMI and total DNA levels. In lean women, the decrease in total cf DNA likely reflects a dilutional effect seen in all pregnant women due to increasing plasma volume. Conversely, in obese women, the increased levels of total cf DNA may reflect the increased adipocyte necrosis3 and stromal vascular apoptosis that is significant enough to overcome the dilutional effect that occurs in pregnant women. Our results are similar to a previous study by Lapaire et al.2, in which a correlation was found between maternal BMI and total, but not fetal, second trimester cf DNA levels. There are several differences between our study and the Lapaire study, however. Firstly, the gestational ages of the study subjects were different. In the present study, maternal blood samples were drawn at term, in contrast to 20 to 21 weeks. Secondly, in the Lapaire et al. study there was no adjustment for maternal weight. We adjusted for the effect of maternal weight on blood volume using the method described by Lemmens et al.6 The present study and that of Wataganara et al.7 suggest that a correction factor for maternal weight is needed when cf DNA analyses are performed. It is standard practice to correct for maternal weight when performing serum screening for Down syndrome. Diagnostic laboratories typically derive their own regression curves for the relationship between serum analytes and maternal weight because of several factors, including differences in instrument sensitivity in the measurement of serum analytes, as well as differences in maternal weight distribution among centers8. Review of the literature, however, indicates that there is no consensus as to the best method to adjust serum markers, including cf nucleic acids, for maternal weight in cases of extreme obesity. We selected the Lemmens et al.6 formula because it correlated total blood volume with BMI, although that formula was used for quantification of blood volume in non-pregnant surgical patients. In summary, we show here that maternal BMI affects total cf DNA levels in both lean and obese pregnant women. In the future, raw DNA values may need to be adjusted for maternal BMI for adequate interpretation of clinical tests that involve assessment of the fetal fraction9. In addition, the presence of increased total cf DNA levels in obese pregnant women suggests that this analyte may be a biomarker for systemic problems during gestation that may impact both maternal and fetal health.

High Molecular Mass Multimer Complexes and Vascular Expression Contribute to High Adiponectin in the Fetus

CONTEXT High plasma adiponectin concentrations in human fetuses and neonates are unique features of early developmental stages. Yet, the origins of the high adiponectin concentrations in the perinatal period remain elusive. OBJECTIVE This study was undertaken to identify the sources and functional properties of adiponectin in utero. DESIGN AND METHODS Tissue specimens were obtained at autopsy from 21- to 39-wk-old stillborn human fetuses. Adipose tissue and placenta were obtained at term elective cesarean section. Adiponectin complexes and expression were measured by immunodetection and real-time PCR. RESULTS Adiponectin mRNA transcripts were detected in fetal sc and omental adipose depots at lower concentrations than in maternal adipose tissue. Immunoreactive adiponectin was also observed in vascular endothelial cells of fetal organs, including skeletal muscle, kidney, and brain. The absence of adiponectin in all placental cell types and lack of correlation between maternal and umbilical adiponectin indicate that umbilical adiponectin reflects its exclusive production by fetal tissues. The most prominent forms of adiponectin in fetal plasma were high and low molecular mass (HMW and LMW) multimers of 340 and 160 kDa, respectively. The proportion of the HMW complexes was 5-fold (P < 0.001) higher in umbilical plasma than in adult. The high HMW and total adiponectin levels were associated with lower insulin concentration and lower homeostasis model of assessment of insulin resistance indices in umbilical plasma, reflecting higher insulin sensitivity of the fetus compared with adult. CONCLUSIONS The abundance of HMW adiponectin and its vascular expression are characteristics of human fetal adiponectin. Combined with high insulin sensitivity, fetal adiponectin may be a critical determinant of in utero growth.

Patterns of Adiponectin Expression in Term Pregnancy: Impact of Obesity

CONTEXT Adiponectin (adpN) production is down-regulated in several situations associated with insulin resistance. The hypoadiponectinemia, which develops in late pregnancy, suggests a role of adpN in pregnancy-induced insulin resistance. OBJECTIVE In obese pregnancy there is a decreased systemic adpN, which results from down-regulation of gene expression in adipose tissue. SETTING AND DESIGN One hundred and thirty-three women with uncomplicated pregnancies and a wide range in pre-gravid body mass index (18-62 kg/m(2)) were recruited at term for a scheduled cesarean delivery. Maternal blood, placenta, and sc abdominal adipose tissue were obtained in the fasting state. DNA methylation was analyzed by MBD-based genome-wide methylation sequencing and methyl-specific PCR of placenta and maternal adipose tissue. mRNA and protein expression were characterized by real-time RT-PCR and immunodetection. Plasma adpN, leptin, and insulin were assayed by ELISA. RESULTS Maternal adipose tissue was the prominent site of adpN gene expression with no detectable mRNA or protein in placenta. In obese women, adipose tissue adpN mRNA was significantly decreased (P < .01) whereas DNA methylation was significantly increased (P < .001) compared with lean women. The decreased adipose tissue expression resulted in normal-weight women having significantly greater plasma adpN compared with the severely obese (12.8 ± 4.3 ng/mL vs 8.6 ± 3.1, P < .001). Plasma adpN was negatively correlated with maternal body mass index (r = -0.28, P < .001) and homeostasis model assessment indices of insulin sensitivity (r = -0.32, P < .001) but not with gestational weight gain. CONCLUSIONS Maternal adipose tissue is the primary source of circulating adpN during pregnancy. Further, based on our results, the placenta does not synthesize adiponectin at term. Obesity in pregnancy is associated with negative regulation of adpN adipose expression with increase in adpN DNA methylation associated with lower mRNA concentrations and hypoadiponectinemia. Maternal hypoadiponectinemia may have functional consequences in down-regulating biological signals transmitted by adpN receptors in various tissues, including the placenta.

Molecular inflammation and adipose tissue matrix remodeling precede physiological adaptations to pregnancy

Changes in adipose tissue metabolism are central to adaptation of whole body energy homeostasis to pregnancy. To gain insight into the molecular mechanisms supporting tissue remodeling, we have characterized the longitudinal changes of the adipose transcriptome in human pregnancy. Healthy nonobese women recruited pregravid were followed in early (8-12 wk) and in late (36-38 wk) pregnancy. Adipose tissue biopsies were obtained in the fasting state from the gluteal depot. The adipose transcriptome was examined via whole genome DNA microarray. Expression of immune-related genes and extracellular matrix components was measured using real-time RT-PCR. Adipose mass, adipocyte size, and cell number increased in late pregnancy compared with pregravid measurements (P < 0.001) but remained unchanged in early pregnancy. The adipose transcriptome evolved during pregnancy with 10-15% of genes being differently expressed compared with pregravid. Functional gene cluster analysis revealed that the early molecular changes affected immune responses, angiogenesis, matrix remodeling, and lipid biosynthesis. Increased expression of macrophage markers (CD68, CD14, and the mannose-6 phosphate receptor) emphasized the recruitment of the immune network in both early and late pregnancy. The TLR4/NF-κB signaling pathway was enhanced specifically in relation to inflammatory adipokines and chemokines genes. We conclude that early recruitment of metabolic and immune molecular networks precedes the appearance of pregnancy-related physiological changes in adipose tissue. This biphasic pattern suggests that physiological inflammation is an early step preceding the development of insulin resistance, which peaks in late pregnancy.

In utero gender dimorphism of adiponectin reflects insulin sensitivity and adiposity of the fetus.

Circulating adiponectin reflects the degree of energy homeostasis and insulin sensitivity of adult individuals. Low abundance of the high molecular weight (HMW) multimers, the most active forms mediating the insulin‐sensitizing effects of adiponectin, is indicative of impaired metabolic status. The increase in fetal adiponectin HMW compared with adults is a distinctive features of human neonates. To further understand the functional properties of adiponectin during fetal life, we have evaluated the associations of adiponectin with insulin sensitivity, body composition, and gender. Umbilical cord adiponectin, adiponectin complexes, and metabolic parameters were measured at term by elective cesarean delivery. The associations between adiponectin, measures of body composition, and insulin sensitivity were evaluated in relation to fetal gender in 121 singleton neonates. Higher total adiponectin concentrations in female compared with male fetuses (34.3 ± 9.5 vs. 24.9 ± 8.6, P < 0.001) were associated with a 3.2‐fold greater abundance in circulating HMW complexes (0.20 ± 0.03 vs. 0.08 ± 0.03, P < 0.001, n = 9). Adiponectin was positively correlated with neonatal fat mass (r = 0.27, P < 0.04) and percent body fat in female fetuses (r = 0.28, P < 0.03) and with lean mass in males (r = 0.28, P < 0.03). There was no significant correlation between cord adiponectin and fasting insulin concentrations or fetal insulin sensitivity as estimated by homeostasis model assessment of insulin resistance (HOMA‐IR). The gender dimorphism for plasma adiponectin concentration and complex distribution first appears in utero. In sharp contrast to the inverse correlation found in adults, the positive relationship between adiponectin and body fat is a specific feature of the fetus.