Abstract
Intrauterine growth restriction (IUGR) enhances risk for adult onset cardiovascular disease (CVD). The mechanisms underlying IUGR are poorly understood, though inadequate blood flow and oxygen/nutrient provision are considered common endpoints. Based on evidence in humans linking IUGR to adult CVD, we hypothesized that in murine pregnancy, maternal late gestational hypoxia (LG-H) exposure resulting in IUGR would result in (1) placental transcriptome changes linked to risk for later CVD, and 2) adult phenotypes of CVD in the IUGR offspring. After subjecting pregnant mice to hypoxia (10.5% oxygen) from gestational day (GD) 14.5 to 18.5, we undertook RNA sequencing from GD19 placentas. Functional analysis suggested multiple changes in structural and functional genes important for placental health and function, with maximal dysregulation involving vascular and nutrient transport pathways. Concordantly, a ~10% decrease in birthweights and ~30% decrease in litter size was observed, supportive of placental insufficiency. We also found that the LG-H IUGR offspring exhibit increased risk for CVD at 4 months of age, manifesting as hypertension, increased abdominal fat, elevated leptin and total cholesterol concentrations. In summary, this animal model of IUGR links the placental transcriptional response to the stressor of gestational hypoxia to increased risk of developing cardiometabolic disease.
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Introduction
Placental insufficiency is a poorly understood complication of pregnancy, affecting up to 10% of pregnancies. It encompasses a myriad of clinical outcomes, including recurrent miscarriage, preterm birth, preeclampsia and intrauterine growth restriction (IUGR). The pathophysiology of placental insufficiency remains poorly understood, but leads to a common result - poor blood flow, and therefore, inadequate nutrient and oxygen provision to the fetus1. Disorders of placental insufficiency pose risks to the fetus and neonate but also have been linked to adverse long-term effects on the offspring2,3,4. Therefore, it is critical to understand the immediate adverse effects of gestational hypoxia on the key organ supporting fetal growth and development, the placenta, as well as the long-term implications on developmental programming of cardiometabolic disease.
Placental blood flow is a key regulator of nutrient and oxygen provision to the growing fetus. In human disease, altered placental vascularization has been linked as a physiologic component of placental insufficiency contributing to obstetric disorders such as preeclampsia and IUGR5,6. Existing in vivo models using various gestational stressors such as maternal food restriction, hypoxia exposure, or uterine artery ligation can all result in a phenotype of placental insufficiency and associated IUGR7,8,9. However, while the food restriction model preferentially affects nutrient transfer culminating in a chronic reduction in uteroplacental blood flow10, the uterine artery ligation model results in abrupt reduction in placental blood flow during late pregnancy. Both these models cause IUGR but potentially may affect different processes than those with chronic gestational hypoxia. Gestational hypoxia has been shown to affect placental structure and function, in a manner dependent on the onset, duration/chronicity, and severity of hypoxia exposure9. Murine models of placental insufficiency secondary to gestational hypoxia exposure have been reported to affect fetal cardiovascular development and programming of adult cardiometabolic disease by affecting inflammation and fat deposition11, as well as endothelial function and hemodynamics12. Maternal food restriction models have been well described as having effects on maternal nutrient transfer across the placenta10,13 and also preferentially affecting long-term endocrine and metabolic adaptations14,15,16,17. Therefore, while poor blood flow, inadequate nutrient provision and hypoxia all contribute towards placental insufficiency as it affects fetal outcomes, it remains important to individually dissect the effect of each of those components both on the placenta as it determines perinatal outcomes, as well as the long term effects on the offspring.
While the association between placental insufficiency exposure in utero resulting in low birth weight or prematurity and risk of adult cardiometabolic disease is well established in the human18, the causative factors and pathophysiology remain largely unknown. Involvement of endothelin, the renin-angiotensin system, and the sympathetic nervous system have all been implicated in the pathophysiology of adult CVD in animal studies19. Recent murine studies have linked gestational hypoxia to programming of adult cardiometabolic disease11,12, specifically with phenotypes of adiposity, altered cholesterol levels, insulin resistance, inflammation, and endothelial dysfunction, as well as renal disease20,21. However, these adult outcomes have not specifically been linked to the placental transcriptome. The advantage of examining the placenta is the future possibility of utilizing it as a biomarker of later disease development, as it shares both the genetic make-up and has resided in the same in-utero environment as the fetus. Therefore, in human pregnancy, examining the placenta, a tissue that is often discarded post-parturient, allows for interrogation of fetal responses to in utero stressors without having to invasively obtain blood or tissue from the offspring. Therefore, our specific research objectives were to evaluate: (1) the effects of gestational hypoxia on the pre-parturient placental transcriptome as specifically related to vascular function, metabolic pathways, and inflammation, and (2) phenotypes of cardiometabolic disease in hypoxia-exposed offspring, thereby providing a foundation for molecular mechanisms by which intra-uterine stressors can be linked to adult cardiometabolic disease.
Results
Placenta weight, birth weight, and litter sizes
There was no difference in placental weight (p = 0.90 by Student’s t-test), fetal weight (p = 0.62 by Student’s t-test) or litter size (p = 0.40 by Mann-Whitney U test) at GD19 between LG-RA (mice exposed to FiO2 0.21 during late gestation, days 14.5–18.5) and LG-H (mice exposed to FiO2 0.105 during late gestation, days 14.5–18.5) groups (Table 1). In our LG-H group, we did not observe a difference in fetal weights (males: 1.21 ± 0.13 g; females: 1.13 ± 0.11 g; p = 0.15 by Student’s t-test) or placental weights (males: 0.13 ± 0.04 g; females: 0.10 ± 0.04 g; p = 0.07 by Student’s t-test) by sex (n = 7–15/sex/group).
In contrast to the placenta, LG-H mice (n = 21) demonstrated an almost 10% decrease in birthweight compared to LG-RA mice (p = 0.002 by Student’s t-test) (Fig. 1A). When comparing litter sizes, the LG-H group had a significant decrease in litter size compared to the LG-RA group, when considering both viable and non-viable pups (p = 0.038 by Mann-Whitney U test) (Fig. 1B), and when considering viable pups only (p = 0.005 by Mann-Whitney U test) (Fig. 1C). There was not a difference in gestational length between the LG-RA and LG-H group (p = 0.21 by Mann-Whitney U test) (Fig. 1D). Given the significant differences in litter sizes and the known effect of litter size on birth weight, we calculated a “corrected” birth weight per litter, by dividing the total litter weight by the average control litter size at birth (mean litter size = 7.43 pups/litter). When adjusting for the difference in litter size in this manner, there is an almost 35% decrease in birthweight (LG-RA, n = 7 litters: median 1.387 g, 95% CI: 1.194–1.512 g; LG-H, n = 5 litters: median 0.817 g, 95% CI: 0.520–1.271 g; p = 0.018 by Mann-Whitney U test).
Placental gene expression changes induced by late gestational hypoxia
We performed whole-transcriptome RNA sequencing (RNA-Seq) on whole placentas isolated from LG-RA (n = 7) and LG-H (n = 8) mice at GD19. We first compared our data with a reference gene expression dataset comprising 91 mouse tissues (Mouse Gene Atlas, see Methods). All our samples were consistently enriched in the placenta expression signature, with minimal enrichment in other tissues (Fig. 2A and Supplementary Table 2). We next examined the expression profile of housekeeping genes in the mouse placenta, which were shown to be uniformly expressed across different gestational ages and conditions22. These genes showed marginal variability in expression for both LG-RA and LG-H samples (Fig. 2B). Taken together, these observations validate the integrity of the tissue profiled in this study and provide the basis for further differential analysis.
Next, we identified a set of 512 differentially expressed genes between LG-RA and LG-H placentas (Wald test adjusted p-value < 0.001, Supplementary Table 1). Ontology analysis revealed a functional network that allowed us to classify hypoxia-responsive genes into two largely distinct clusters (Fig. 2C, Supplementary Table 2). The first cluster comprised genes involved in tissue structure (including vasculature development, hemostasis, adhesion and extracellular matrix), and in receptor and intracellular signaling (i.e. MAPK, IGF, PI3K-Akt and tyrosine receptor pathways), including genes associated with inflammatory responses. The second cluster resulted from the enrichment of genes annotated in several nutrient and metabolic transport systems. For all functions, a majority of genes were found to be up regulated (higher expression in LG-H as compared to LG-RA) by hypoxia in late gestational placentas (Fig. 2D).
Closer inspection of the expression profiles of hypoxia-induced genes showed that, although up-regulation was consistent across all our LG-H samples, many genes displayed a continuum in their response levels to hypoxia (Fig. 2D, Supplementary Table 1). In fact, principal component analysis (PCA) using the expression levels of all mouse genes provided a clear but continuous segregation between LG-RA and LG-H samples. This consistent but graded response to hypoxia was the dominant source of gene expression variability (PC1, first principal component, Fig. 3A), and accounted for 75% of the total variance in our whole-transcriptome dataset. We further analyzed the set of genes more strongly correlated with PC1 (see Methods). Strikingly, ontology analysis resulted in a highly significant enrichment for genes involved in the regulation of insulin transport (hypergeometric test p-value < 10e-33). This set of responsive genes was also significantly associated with steroid and lipid metabolism and transport, inflammatory response and oxidoreductase activity (Fig. 3A and Supplementary Table 2). The continuous but distinct distribution of expression levels of these genes in LG-RA and LG-H samples (Fig. 3B) suggested a varying yet strong shift in the activity of these pathways under late gestational hypoxia.
RNA sequencing validation by qRT-PCR
RNA sequencing results were validated by real time polymerase chain reaction (RT-PCR). Four genes were chosen for validation –Dio3, Hif3α, Pck1, Hsd11b2–as these genes represent several of the pathways that were strongly affected in the placenta by gestational hypoxia exposure. All four genes demonstrated strong up-regulation in the LG-H groups compared to LG-RA, consistent with RNA sequencing results. For Dio3, relative gene expression calculated by comparative CT method was increased ~30 fold (LG-RA: 1.11 ± 0.51, LG-H: 33.77 ± 35.9, p = 0.03 by Student’s t-test). For Hif3α, relative expression was increased ~2 fold in the LG-H group (LG-RA: 1.13 ± 0.67, LG-H: 2.43 ± 1.34, p = 0.04 by Student’s t-test). For Pck1, relative expression was increased ~75-fold in the LG-H group (LG-RA: 1.55 ± 1.41, LG-H: 118.21 ± 81.53, p = 0.002 by Student’s t-test). For Hsd11b2, relative expression was increased ~20 fold in the LG-H group (LG-RA: 1.19 ± 0.73, LG-H: 24.29 ± 23.20, p = 0.02 by Student’s t-test).
Postnatal weight and milk intake studies
Pup weights taken at 7, 14, and 21 days postnatal age were significantly different between groups at 21 days only (adjusted p-value < 0.001 by Holm-Sidak method) (Fig. 4A). This significant increase in weight in LG-H pups could be explained by an observed ~25% increase in milk intake as extrapolated from weight differences pre- and post- suckling for one hour measured on postnatal day 14 (p = 0.024 by Student’s t-test), even though litter sizes were matched (Fig. 4B).
Body and organ weights and organ morphology with aging
For males and females exposed to hypoxia, there were no significant differences in adult body weights (p > 0.05 by Holm-Sidak testing for multiple comparisons). However, there was an interesting divergent trend by sex; adult male LG-H offspring were non-significantly heavier than male LG-RA offspring (Fig. 5A), while adult female LG-H offspring were non-significantly lighter than female LG-RA offspring (Fig. 5B) at older ages (eight months). There was not a difference in heart weight by hypoxia exposure between the four groups considered (p = 0.076 by two-way ANOVA for interaction; p = 0.0016 for sex; p = 0.6544 by hypoxia exposure). There was no difference in kidney weights between male or female LG-RA and LG-H groups (p = 0.42 by two-way ANOVA for interaction; p < 0.0001 for sex; p = 0.86 for hypoxia exposure). In males, the LG-H group exhibited a significant increase in abdominal fat content by weight, with an almost 2-fold increase in males (p = 0.0061 by Sidak’s multiple comparisons test), though an almost 3-fold increase in abdominal fat weight observed in females did not reach significance by two-way ANOVA testing (p = 0.0865 by Sidak’s multiple comparisons test) (p < 0.0001 by two-ANOVA for sex factor; p = 0.0007 by hypoxia exposure factor) (Table 2).
Blood pressure with aging
We also analyzed the blood pressure of adult animals. At four months of age, both LG-H male and female offspring exhibited a 10–15% increased mean blood pressure (p = 0.2944 for interaction, p = 0.012 for sex, p < 0.0001 for hypoxia exposure by two-way ANOVA) (Fig. 6A), as well as increased heart rate (p = 0.2532 by interaction, p = 0.059 by sex, and p = 0.0010 by hypoxia exposure by two-way ANOVA) (Fig. 6B), when compared to LG-RA groups. This increase in mean blood pressure was persistent at 6 months in males and females (p = 0.0064 by hypoxia exposure, p = 0.0853 by sex, p = 0.9979 for interaction by two-way ANOVA), though a difference in heart rate was not detected (p = 0.8335 for interaction, p = 0.146 by sex, p = 0.3319 by hypoxia exposure by two-way ANOVA) (Supplementary Fig. 1).
Plasma leptin and cholesterol concentrations
Given the changes in abdominal fat, total leptin and cholesterol concentrations were assessed in male and female LG-RA and LG-H groups at four months of age. In both males and females, LG-H groups had elevated leptin (p = 0.0967 by interaction, p = 0.4091 by sex, p = 0.0055 by hypoxia exposure by two-way ANOVA) (Fig. 7A) and total cholesterol concentrations (p = 0.1637 by interaction, p = 0.0005 by sex, p < 0.0001 by hypoxia exposure by two-way ANOVA) (Fig. 7B) compared to LG-RA groups.
Discussion
Our animal study demonstrates that late gestational hypoxia exposure mimics placental insufficiency resulting in decreased birth weight and litter sizes, and moreover, an increased risk of cardiovascular disease in adulthood for the hypoxia-exposed offspring. Both male and female hypoxia-exposed offspring demonstrated evidence of hypertension, hypercholesterolemia, and increased leptin concentrations. There were sex-specific changes seen as well; male offspring exposed to prenatal hypoxia did not demonstrate differences in somatic weights compared to normoxia-exposed control males, but had significantly increased abdominal fat deposition. Hypoxia-exposed female offspring did not demonstrate significant increases in somatic or abdominal fat weights compared to normoxic controls. Importantly, we utilized this animal model to interrogate whether placental transcriptomic changes can serve as a surrogate for fetal genetic responses to in utero environmental exposures, and whether those changes specifically parallel alterations in cardiovascular and metabolic processes.
There are several existing murine models of placental insufficiency and IUGR, including maternal food restriction, uterine artery ligation, and maternal hypoxia exposure. Though poor nutrient provision and blood flow to the fetus are certainly implicated as important components of the IUGR condition, we chose to parse out and focus on chronic maternal hypoxia exposure as it mimics the common end point of poor oxygen delivery to the fetus thought to incur adverse fetal effects as seen in idiopathic human placental insufficiency/IUGR. Varying degrees of hypoxia, duration of hypoxia exposure, and timing of exposure all lead to differing effects on birth weight and litter size9. We selected the 10.5% oxygen levels from GD 14.5–18.5 in order to mimic human IUGR, which demonstrates lagging fetal growth predominantly in the third trimester. We found that this level of hypoxia, timing and duration of exposure not only generated growth-restricted pups, but also allowed for survival of the pups in order to study adult phenotypes. It should be noted that gestational hypoxia has been reported to decrease maternal food intake23, so it is likely that our findings are due to both a combination of hypoxia as well as nutrient restriction. We did observe decreased food intake (~60%) (measured in grams/gram of maternal body weight) in our hypoxia-exposed mothers, though this was measured in a small subset of mothers (2 mothers/group) and this observation was not powered to report a difference. Though we did find a difference in birth weight in offspring, we did not demonstrate a difference in fetal or placental weights at GD19, though the number of litters assessed at GD19 (n = 4–5 litters/group) was powered to detect difference by hypoxia exposure, but not by sex. Interestingly, our model allowed for observation of the natural “catch-up” growth phenomenon seen in human IUGR24. Even when controlling for litter size and therefore maternal milk availability, our hypoxia-exposed pups demonstrated increased milk intake and increased weight attrition postnatally during the suckling phase. Some studies utilize an altered diet postnatally12 in order to mimic conditions seen in Western countries and generate a phenotype of later cardiovascular disease. Our study supports the observation that this effect exists even without diet modification. “Catch-up growth” may be a persistent biologically programmed phenomenon after IUGR24 contributing to later adverse outcomes that should potentially be monitored closely, in order to protect against developmental programming of disease25.
Existing studies utilizing a similar gestational hypoxia exposure describe the effects of hypoxia on placental structure, function26,27, and specific pathways linked to cardiovascular disease28, though not on global transcriptomic changes. Other groups describe adult phenotypes of cardiometabolic and renal disease after hypoxia exposure11,20,21 in various wild-type and transgenic mouse models. Our findings are similar and complimentary to these previously published reports. The magnitude of our observed blood pressure differences between LG-RA and LG-H groups were similar to those reported by Walton et al.20, who utilized radiotelemetry in twelve month old mice to measure blood pressure. The consistency in results is reassuring, as we utilized tail cuff measurements which can be prone to error due to being operator dependent, requiring mouse acclimation/repeated training, and movement artifact29,30, which we minimized as much as possible. However, none of these studies link the two specifically – placental transcriptomic changes and adult outcomes. This linkage was a key objective in our study, given that the placenta, an organ often discarded after the delivery of a newborn, has both the identical genetic material as well as the same in-utero exposures as the fetus. Therefore, the study of the placenta potentially allows for non-invasive evaluation of fetal responses to adverse in-utero conditions, and can be mined for biomarkers that change as a response to the very processes that are mismatched pre- and post-natally, leading to developmental programming of cardiovascular disease.
In order to do this, our study utilized RNA sequencing to evaluate in a non-biased global manner, what the preferentially affected pathways were in the placenta after hypoxia exposure. Overall, our data revealed that both vascular and nutrient/metabolic transport pathways are strongly affected at the transcriptional level in our model of gestational hypoxia exposure (Fig. 2). Our differential expression results recapitulated the consistent dysregulation of genes previously associated with placental development and structure. For example, several members of the prolactin gene family (Prl4a1, Prl7a1, Prl2c3, Prl2c2) were downregulated in our models. These genes are coordinately involved on the response to physiological stress in the placenta31, and deficiency in Prl4a1has been linked to an impaired capacity of adaptation to hypoxia32. The parallelism between late gestational hypoxia and conditions associated with placental deficiency is further supported by the observed down-regulation of genes essential for vasculature and cardiovascular development such as Mmp12, Vhl, F11, Fbxw7, and Bcl332,33,34,35,36. In the context of the signaling cascades induced by vascular injury, we also found a significant enrichment for genes involved in inflammatory response, and in particular, both Cd74 and Ccl8 are transcriptionally regulated in human pre-eclamptic placentas37. The consistent down-regulation of the heme oxygenase 1 gene (Hmox1) along with the upregulation of multiple serpin peptidase inhibitors (Serpin1f and Serpinb5 among others) is in agreement with previous reports on the role of these hypoxia-related genes on placental development, IUGR and preeclampsia in humans and animal models38,39.
Gene expression analysis in our model also provided additional insights into the metabolic and homeostatic challenges induced by late gestational hypoxia. Of note, the most up-regulated gene (>16 fold) was phosphoenolpyruvate carboxykinase (Pck1), which plays a major role on the maintenance of lipid metabolism, glucose homeostasis and insulin resistance40. Another example is a marked upregulation of the adenylate cyclase 5 (Adcy5) gene, whose expression correlates with BMI, body fat mass, circulating leptin and fat distribution in both human and mice41. Fewer genes were found to be down-regulated in LG-H as compared to LG-RA placentas. However, these genes were also significantly associated with homeostatic processes. For instance, loss of function mutations on the Mgat4a gene are known to disrupt glucose and insulin homeostasis42, and this gene was found to be moderately but consistently downregulated in LG-H placentas. Finally, it is worth mentioning that classical members of the generic response to hypoxia including Hif3a, Vegfc, Vegfd were significantly induced in LG-H samples. As opposed to other members of the HIF and VEGF families, these less characterized genes are specifically associated with signaling pathways in adipose tissue. In fact, Vegfc and Vegfd are activators of lymphatic vessel growth and are involved in adipose tissue inflammation and obesity-related insulin resistance43. Hif3a was reported as the most significantly associated gene in a genome-wide study of DNA methylation and BMI44, and our up-regulation of this gene after hypoxia exposure parallels the role of Hif3a in the cellular response to glucose and insulin45. Combined, these examples underscore the departure from homeostatic equilibrium of the placenta under late gestational hypoxia.
Likely as a consequence of a disruption in placenta function and homeostasis was the dramatic upregulation in LG-H samples of multiple genes that regulate endocrine pathways. Among the most up-regulated genes was 11β-hydroxysteroid dehydrogenases 2 (Hsd11b2), which controls the amount of exposure to maternal glucocorticoids in the fetus46. Hsd11b2 expression levels in the placenta has been shown to be dynamically regulated during cycles of acute and chronic stress, and its association with a long-term susceptibility of the offspring to neuroendocrine disorders is thought to be mediated by epigenetic mechanisms47. Consistent with our findings, alterations in Hsd11b2 expression has been previously associated with other mouse models of growth restriction27,48. Another relevant example is the strong up-regulation of the hypoxia-inducible Dio3 gene, an imprinted gene that is involved in thyroid hormone metabolism, potentially indirectly influencing fetal exposure to thyroid hormones. Alterations in fetal thyroid hormone concentrations have been suggested to play a role in programmed postnatal disease49. It is therefore tempting to speculate that the observed upregulation of these genes is a fingerprint of a generic stress-sensing mechanism in the placenta, with a potential role in the onset of developmental programming.
The previous results highlight the complex functional interactions that are integrated and tightly regulated in the placenta. The phenotypes in both the placenta and the offspring that result from our model will most likely be influenced by additional factors (e.g. diet, food intake and sex, among others). One could therefore anticipate that the transcriptional response to hypoxia will also be modulated by those extrinsic factors7. In fact, beyond the consistency imposed by our stringent statistical thresholds, we observed that many of the gene expression changes between LG-RA and LG-H samples discussed above were not discrete, with specific samples showing a more dramatic transcriptional response. However, further analyses revealed that this gradual shift in expression across different hypoxic placentas was not accidental. On the contrary, it was remarkably correlated with a shift in the activity of the regulation of insulin and lipid transport and metabolism, along with a marked enrichment of protective genes. Therefore, our transcriptional data support the results from recent reports on the role of the insulin-IGF pathway on the integration of nutrient and oxygen signals in the placenta23, and the role that multiple transport and endocrine systems might have in these processes50,51, as discussed above. The role that the specific transcriptional changes found in our model might have on the onset of developmental programming warrants additional studies. In this respect, it will be interesting to analyze the role of genes previously associated with epigenetic modifications during pregnancy like Mfap4, Hif3a, Nnat and Pmaip152,53, as they were strongly correlated with the hypoxia-induced shifts reported here.
The fact that significant sex-specific differences in the placental transcriptome are not reported here could be attributed to the small sample size. Also, sex-specific biologic programming of responses to in-utero stress may be more postnatally mediated. Consistent with several animal studies11,20,21,54,55 that suggest that while all offspring are at increased risk of later disease, we found that males are more susceptible to risk of developmental programming of cardiovascular disease after various in utero insults. We found in our model that both adult males and females demonstrate elevated blood pressure, total cholesterol levels, and elevated leptin, but males demonstrated tendency towards obesity with increased abdominal fat deposition, whereas females do not demonstrate tendency to obesity after hypoxia exposure in utero. The development of these adverse outcomes in females that are not outwardly apparent in overall body weight, suggests that cardiovascular risk may be “overlooked” in females. It is tantalizing to hypothesize that these adverse effects may become exaggerated and even “unmasked” in pregnancy, where rapid weight gain and insulin resistance are physiologic, perhaps contributing towards gestational hypertension and diabetes conditions, as has been seen previously56.
Lastly, we probed our RNA-sequencing data for biologic plausibility and comparability to the human condition of placental insufficiency. In humans, placental insufficiency has been linked to recurrent miscarriage, preterm birth, pre-eclampsia as well as IUGR. As discussed previously, a number of the differentially expressed genes in our LG-H group have been shown to be associated with pre-eclampsia in human cohorts33,57. A recent large genome-wide association study in humans reported a handful of genes – EBF1, EEFSEC, AGTR2, WNT4, ADCY5, and RAP2C - that were significantly associated with length of gestational or risk of delivery prior to 37 weeks’ gestation58 in a genetically homogeneous population. Of the six gene variants, three of these genes – EBF1, AGTR2, ADCY5 - are differentially expressed in our murine model of gestational hypoxia exposure, potentially implicating pathways upregulated in hypoxia-induced stress in the condition of premature birth.
We present here the first study to specifically link the placental transcriptome to risk of developing adult cardiovascular disease in a murine model of IUGR caused by late gestational hypoxia exposure. This in vivo model of developmental programming of CVD allows for future evaluation of the utility of the placental genome and epigenome as a reflection of both the genetic and prenatal environmental influences seen by the fetus. This model can be used in future studies to probe for epigenetic mechanisms linking in utero stressors to developmental programming of adult CVD in a sex-specific manner, as well as to potentially test future prevention modalities and intervention strategies against the developmental programming of disease in the IUGR murine offspring.
Methods and Materials
Ethical Approval
This study was conducted per established guidelines and all protocols were approved by the Animal Research Committee of the University of California Los Angeles in accordance with the National Institutes of Health. C57BL/6 mice obtained from the UCLA Division of Laboratory and Animal Medicine colony (RRID:IMSR_JAX:000664) were housed in 12:12 hour light-dark cycles with ad libitum access to a standard rodent chow diet (Pico Lab Rodent Diet 20, cat# 5053, Lab Diet, St. Louis, MO) and water. At the end of the experimental period, mice underwent brief anesthesia using inhaled isofluorane (2–3 minutes) followed by cervical dislocation. The tissues of interest were dissected within 5 minutes of euthanasia, and immediately stored for downstream processing (quick frozen in liquid nitrogen and stored at −80 °C until RNA extraction). All efforts were made to reduce the number of animals used for experiments, and to minimize animal suffering. The investigations presented here comply with the animal ethics policy and regulations set out in the editorial, abiding with the principles under which this journal operates.
Placental samples
At 2–3 months of age, male and female mice were mated overnight, and pregnant female mice were identified by the presence of a vaginal plug the following morning (designed as gestational day 0.5). Pregnant females were transferred to individual cages and reared on the same chow diet ad libitum until gestational day 14.5, at which point they were randomly assigned to two groups: 1) late gestation-room air (LG-RA) pregnant mice which were housed in standard conditions of 0.21 FiO2, and 2) late gestation-hypoxia (LG-H) pregnant mice were exposed to hypoxia (0.105 FiO2) for 4 days (days 14.5 to 18.5 of gestation). Hypoxia exposure consisted of 10.5% fractional inspired oxygen concentrations continuously, which was maintained using a commercially available environmental system (Biospherix ProOx model P360, Parish, NY, USA). For placental studies, on GD 19, animals were euthanized by brief exposure to isofluorane followed by cervical dislocation. Under laparotomy followed by hysterotomy, the placentas inclusive of the maternal decidua, were separated from the respective fetuses and collected (n = 7–30 placentas/group, arising from 5 litters for LG-RA conditions and 4 litters from LG-H conditions). The placentas and fetuses were weighed in a Mettler AB104 precision balance (0.01 mg sensitivity), and then immediately snap-frozen and stored at −80 °C until further analysis. For offspring studies, pregnant females were removed from the chamber and allowed to deliver pups normally, and measurements taken accordingly (for birth weight, litter size, genotyping measurements, n = 7 litters for LG-RA and LG-H groups).
Genotyping
DNA was isolated from ~0.2 cm tail samples using the Bioland Quick Genotyping DNA preparation kit (Bioland Scientific, Paramount, CA, USA), according to the manufacturer’s protocol. DNA was quality checked using Nanodrop prior to genotyping. Genotyping was performed on ~50 ng of DNA per sample via PCR using standard primers for genetic sex determination in mice (B451: Forward primer, 5′-GATGATTTGAGTGGAAATGTGAGGTA-3′; B452: Reverse primer, 5′-CTTATGTTTATAGGCATGCACCATGTA-3′)59 and Dream Taq hot start green master mix (Thermo Scientific, cat#K9021, Waltham, MA, USA). Primers were brought to a working concentration of 0.4 µM. PCR conditions were as follows: denaturing at 95° for 2 minutes, followed by 35 cycles of the following–denaturation at 95 °C for 30 seconds, annealing at 59 °C for 30 seconds, and extension at 72 °C for 60 seconds. This was followed by a final extension at 72 °C for 5 minutes. Samples were then visualized on a 1.2% agarose gel with green safe gel stain (Bioland Scientific, cat# SAFE01-01, Paramount, CA, USA). Males were verified with Y chromosome visualization at band length 280 bp, while females demonstrated bands at 480 bp (weak) and 660 bp (strong).
RNA sequencing libraries and data analysis
Sample sizes for RNA sequencing were based upon previously published data evaluating placental gene expression using a murine model of maternal food restriction resulting in IUGR7. Power analyses conducted using gene expression data (by qRT-PCR) from that study, which showed mean relative expression = 1.0 with SD = 0.1, indicate that 5–8 animals per experimental group can detect a difference of at least 25–35% using the Hsu (with Best) multiple comparison test with 89% power at a 0.05 overall significance level.
Frozen whole placental tissues, including the maternal decidua, obtained from LG-RA and LG-H groups (n = 7–8/group from 7 litters for LG-RA and from 4 litters for LG-H) were employed. Briefly, tissue from single placentas was homogenized and RNA extracted using the Zymo Direct-Zol RNA MiniPrep Plus (Zymo, cat# R2070, Irvine, CA) as per the manufacturer’s instructions. Total RNA was quantified and 260/280 ratios determined using Nanodrop (all samples with a 260/280 = >1.97). One μg of total RNA was used as starting material for each sample. RNA sequencing and library preparation was performed by the UCLA Technology Center for Genomics and Bioinformatics using the KAPA Stranded mRNA-seq kit (Roche Sequencing, cat#KK8421, Pleasanton, CA, USA), according to the manufacturer’s instructions. The work flow consisted of mRNA enrichment, cDNA generation, end repair to generate blunt ends, A-tailing, adaptor ligation and PCR amplification. Different adaptors were used for multiplexing samples in one lane. Sequencing was performed on the HiSeq. 3000 System for a single-read 50 run (Illumina). The raw data has been deposited into the NCBI’s Gene Expression Omnibus (GSE112755).
Data quality check was done on an Illumina SAV. Demultiplexing was performed with the Illumina Bcl2fastq2 v 2.17 program. The STAR ultrafast universal RNA-seq aligner v2.5.2b60 was used to generate the genome index and to perform paired-end alignments. Reads were aligned to a genome index that includes both the genome sequence (GRCm38 primary assembly) and the exon/intron structure of known gene models (Gencode M12 genome annotation). Alignment files were used to generate strand-specific, gene-level count summaries with STAR’s built-in gene counter. Only protein-coding genes in the Gencode M12 annotation were considered (95% of total counts on average). Independent filtering was applied as follows: genes with less than 15 counts across all samples, count outliers or low mappability (<100 bp) were filtered out for downstream analysis61,62. Expression estimates were computed in units of fragments per kilobase of mappable length and million counts (FPKMs). The table of expression estimates (FPKM) was used as input for SaVanT63 to compute enrichment scores on mouse gene expression signatures (Mouse MOE430 Gene Atlas (http://biogps.org/)) and relative expression profiles. Non-default parameters for SaVanT were “Convert matrix values to ranks” and “Compute null distribution with 10000 iterations”. Differential expression analysis was performed with DESeq. 2 (Bioconductor, v3.7, RRID:SCR_015687)62. Count data was fitted to additive models using Sex (female/male) and experimental group (LG-RA/LG-H) as explanatory factors. The individual effect of each factor on the expression of each gene was tested using a contrast with reduced models (likelihood ratio test). Additional models including a Sex:Group interaction term were used to fit the data and identify genes with a sex-specific response to hypoxia. Pairwise differential expression was performed to classify genes as differentially expressed (Wald adjusted p-value < 0.001) between LG-RA and LG-H placentas (512 genes). Unfiltered differential expression results are provided in Supplementary Table S2. Functional enrichment was performed with Metascape (http://metascape.org) and visualized in Cytoscape (Cytoscape, v3.6.1, RRID:SCR_003032)64. Principal component analysis (PCA) was performed in R (R project for statistical Computing, v 3.4.4, RRID:SCR_001905) on variance-stabilized expression data from DESEq. 2. Genes with high PC1 loadings were further analyzed with Metascape, and distributions of variance-stabilized expression z-scores for genes in specific functional categories was visualized as box plots. With the exception of Fig. 2B, all figures were generated in Matlab (MATLAB, version release 2017a, The MathWorks, Inc, RRID:SCR_001622).
RNA sequencing validation by real time quantitative PCR (RT-PCR)
For RT-PCR analysis, total cellular RNAs were isolated using the RNeasy mini kit (Qiagen, cat #74104, Valencia, CA. USA) according to the manufacturers’ instructions. Quantitative and qualitative analyses of isolated RNA were assessed by the ratio of absorbance at 260 and 280 nm. cDNA was generated from 1 μg of total RNA from placental tissue using reverse transcription (RT) using a Superscript III Reverse Transcriptase kit (Invitrogen, cat#18080093, San Diego, CA, USA) following the manufacturer’s instructions. The reverse transcription was performed at 50 °C using 5 μg/μl of random hexamers. Real-time PCR amplification was performed in triplicate using Taqman-based detection according to the manufacturer’s instructions on a Step One real-time quantitative PCR thermocycler (Applied Biosystems, Foster City, CA, USA). Four genes with clinical relevance to the pathways most affected by gestational hypoxia exposure by RNA sequencing results were chosen for validation: Dio3, Hif3α, Pck1, and Hsd11b2. Commercially available Taqman gene expression assay kits were used to quantitate gene expression (Thermofisher, cat#4448892 and 4453329, Waltham, MA, USA). Relative gene expression was calculated using the comparative CT method with 18 S (Applied Biosystems, #4319413E, Foster City, CA, USA) expression used as the internal control for normalization. The amplification cycles consisted of: 50 °C for 2 minutes, 95 °C for 20 seconds, then 45 cycles of 95 °C for 1 second (denaturation), annealing for 20 seconds.
Offspring birthweights, litter counts and adult body and organ weights
Given the variable effects on pup viability after hypoxia exposure, litter numbers were counted within 12 hours of delivery and the number of viable versus stillborn pups determined at that time. Birthweight was also obtained at that time. Mothers were maintained on the standard rodent chow diet throughout pregnancy and during lactation (Pico Lab Rodent Diet 20, cat# 5053, Lab Diet, St. Louis, MO). Pups were weighed at 7, 14, and 21 days (n = 23–52 pups/group/time point from 7 litters each for LG-RA and LG-H groups). Pups were weaned from their nursing dams at 21 days after birth, and males and females were caged separately. Offspring were maintained on the same standard rodent chow diet (Pico Lab Rodent Diet 20, cat# 5053, Lab Diet, St. Louis, MO). Offspring were then weighed at 4, 8, 12, 16, 20, 24, 28, and 32 weeks of age (n = 6–24/group/time point for males and females separately). In an arbitrarily selected subset of mice (n = 6 litters for LG-RA and 3 litters for LG-H), at 4 months of age, mice were euthanized with isofluorane and blood was collected after cervical dislocation. Organs of interest – heart, kidneys, and abdominal fat–were also collected and weighed, then snap frozen in liquid nitrogen and stored at -80 °C until further processing (n = 8–13/group for males, and n = 7–11/group for females).
Milk intake studies
Milk intake studies were performed on litters matched for size (litters that were naturally born of similar numbers were examined; n = 3 LG-RA litters, 2 LG-H litters), such that each litter considered had 6–7 pups/litter. Fourteen day-old suckling pups were isolated from their mothers in the morning and maintained in their cages on a heated pad for five hours. They were then placed back with their mothers for suckling. They were individually weighed at the time of separation, just prior to replacement with the mothers, and then one hour after suckling with their mothers as described above. The difference in pup weights (mg) was used as a surrogate for milk intake (ml)65.
Blood pressure tail-cuff measurements
At four months of age, blood pressure measurements of males and females from both groups (taken from n = 5 litters for LG-RA and 7 litters for LG-H) were obtained using tail-cuff blood pressure measurements taken using the BP2000 Series II Blood Pressure Analysis System (Visitech Systems, Apex, NC, USA). To perform these studies, mice were restrained inside a container placed on top of a heated platform. The mouse tail was placed into a tail blood pressure cuff and tail blood pressure measurements were taken every two minutes for twenty minutes to allow for an acclimation period (n = 13–15/group for males, n = 9–17/group for females). Blood pressures were taken at the same time on various days for all mice, and measurements were performed in a room where minimal noise could be assured.
Plasma leptin and cholesterol levels
Plasma was collected by obtaining whole blood after euthanasia of mice at four months of age (n = 6 litters for LG-RA and 3 litters for LG-H). Whole blood was collected into EDTA tubes (BD, Franklin Lakes, NJ, USA) and then centrifuged at 8,000 rpm for 10 minutes. The top layer of plasma was pipetted into a separate EDTA tube and all samples were stored at − 80 °C (n = 8–9/group for males, n = 7–11/group for females). Leptin concentrations were measured using a mouse leptin ELISA kit (Thermo Fisher Scientific, cat#KMC2281, Waltham, MA), according to the manufacturer’s instructions, at a dilution of 1:32 for males and 1:16 for females. Standard curves were constructed with R values of 0.95–0.99, and concentrations (in ng/mL) were determined based upon the standard curve. Values outside the range of the standard curve were excluded from analysis. For the leptin assay, the appropriate range was 93.8–6000 pg/mL, with the sensitivity threshold at 50 pg/mL, and intra- and interassay variations at 2.75% and 3.54%, respectively, within the assay range, and coefficient of variation 2.46.
Total cholesterol concentrations were measured on 10 μL plasma samples obtained from mice (n = 8 = 11/group for males, n = 6–10/group for females). These samples were processed by the UCLA Division of Laboratory Animal Medicine, using the ACE Cholesterol reagent kit (Alfa Wassermann, ref #SA1010, West Caldwell, NJ, USA), with a reported sensitivity of detection between the concentration range of 6–600 mg/dL (correlation coefficient = 0.9990).
Statistical Analysis
All statistical analyses described in sections 2.2 were conducted in GraphPad Prism software (version 5, GraphPad Software Inc., La Jolla, CA) and data are presented as means ± SD when data were normally distributed, and as median and quartile ranges or 95% confidence intervals provided when not normally distributed, unless otherwise indicated. Birthweights were normally distributed, as has been previously reported in C57BL/6 mice66, but litter sizes were not67, using the D’Agostino and Pearson normality test. Somatic weight at 4 weeks of age in male mice was normally distributed, so we assumed normal distribution for all weight data sets subsequently in males and females. Normality was also tested using the data obtained from control LG-RA groups for other tests (blood pressure, cholesterol, leptin, milk intake). If the sample size was too small to test for normality, we assumed data were not normally distributed (e.g. sex-specific placental and fetal weight differences in the LG-H group, and gestation length). All data sets with adequate sample size, except for leptin concentrations, demonstrated a normal distribution. To test for significant differences between two groups (LG-RA- and LG-H) for normally distributed data (e.g. birthweight data, milk intake, qRT-PCR), we analyzed results using the Student’s t-test for un-paired parametric data. To compare un-paired data that demonstrated a skewed distribution (litter sizes), Mann-Whitney U test was used. For body weights over time (at one month increments), multiple comparison testing was employed using the Holm-Sidak method. For multiple comparison groups (e.g. organ weights, blood pressure, cholesterol and leptin concentrations), to analyze the effect of sex and treatment, two-way ANOVA testing was performed and Sidak’s multiple comparison testing used to distinguish hypoxia-exposure effect by sex. All p-values are reported as 2-tailed with statistical significance set at <0.05 for all comparisons.
Sample sizes for physiologic blood pressure were based upon previously published data evaluating adult mouse blood pressures after postnatal hypoxia exposure in the mouse68. Power analyses conducted using blood pressure data from that study, showing mean systolic blood pressure = 115, with SD = 5.5, indicate that 8 animals per group was sufficient to detect a 10 mmHg change in blood pressure, achieving >99% power with an overall significance level set at 0.05.
Sample sizes for plasma leptin and cholesterol concentrations were based upon previously published data evaluating plasma leptin concentrations after intermittent gestational hypoxia exposure in the mouse11. Power analyses conducted using reported leptin concentrations from that study, showing mean plasma leptin concentrations of 2.8 ng/mL with SD = 0.83, indicate that 7–10 animals per group was sufficient to detect a 25% change in leptin concentrations, achieved an ~80% power with overall significant level set at 0.05.
Data Availability
All data generated or analyzed during this study are included in this published article (and its Supplementary Information files).
References
Hunt, K., Kennedy, S. H. & Vatish, M. Definitions and reporting of placental insufficiency in biomedical journals: a review of the literature. Eur. J. Obstet. Gynecol. Reprod. Biol. 205, 146–149 (2016).
Luyckx, V. A. et al. Effect of fetal and child health on kidney developmental and long-term risk of hypertension and kidney disease. Lancet. 382, 273–283 (2013).
Paauw, N. D., van Rijn, B. B., Lely, A. T. & Joles, J. A. Pregnancy as a critical window for blood pressure regulation in mother and child: programming and reprogramming. Acta Physiol. (Oxf.). 219(1), 241–259 (2017).
Thornburg, K. L., O’Tierney, P. F. & Louey, S. Review: the placenta is a programming agent for cardiovascular disease. Placenta. 31(Suppl), S54–59 (2010).
Cross, J. C. et al. Trophoblast functions, angiogenesis and remodeling of the maternal vasculature in the placenta. Mol. Cell. Endocrinol. 187(1-2), 207–212 (2002).
Herr, F., Baal, N., Widmer-Teske, R., McKinnon, T. & Zygmunt, M. How to study placental vascular development? Theriogenology. 73(6), 817–827 (2010).
Chu, A. et al. Gestational food restriction decreases placental interleukin-10 expression and markers of autophagy and endoplasmic reticulum stress in murine intrauterine growth restriction. Nutr. Res. 36(10), 1055–1067 (2016).
Dodson, R. B. et al. Intrauterine growth restriction influences vascular remodeling and stiffening in the weanling rat more than sex or diet. Am. J. Physiol. Heart Circ. Physiol. 312(2), H250–H264 (2017).
Jang, E. A., Longo, L. D. & Goyal, R. Antenatal maternal hypoxia: criterion for fetal growth restriction in rodents. Front. Physiol. 6, 176 (2015).
Ganguly, A., Touma, M., Thamotharan, S., De Vivo, D. C. & Devaskar, S. U. Maternal calorie restriction causing uteroplacental insufficiency differentially affects mammalian placental glucose and leucine transport molecular mechanisms. Endocrinology. 157(10), 4041–4054 (2016).
Khalyfa, A. et al. Late gestational intermittent hypoxia induces metabolic and epigenetic changes in male adult offspring mice. J. Physiol. 595(8), 2551–2568 (2017).
Walton, S. L., Singh, R. R., Tan, T., Paravicini, T. M. & Moritz, K. M. Late gestational hypoxia and a postnatal high salt diet programs endothelial dysfunction and arterial stiffness in adult mouse offspring. J. Physiol. 594(5), 1451–1463 (2016).
Ganguly, A., Chen, Y., Shin, B. C. & Devaskar, S. U. Prenatal caloric restriction enhances DNA methylation and MeCP2 recruitment with reduced murine placental glucose transporter isoform 3 expression. J. Nutr. Biochem. 25(2), 259–266 (2014).
Garg, M. et al. Glucose intolerance and lipid metabolic adaptations in response to intrauterine and postnatal calorie restriction in male adult rats. Endocrinology. 154(1), 102–113 (2013).
Garg, M. et al. Early postnatal caloric restriction protects adult male intrauterine growth-restricted offspring from obesity. Diabetes. 61(6), 1391–1398 (2012).
Li, T. et al. Calorie restriction prevents the development of insulin resistance and impaired lipid metabolism in gestational diabetes offspring. Pediatr. Res. 81(4), 663–671 (2017).
Chavey, A., Ah Kioon, M. D., Bailbé, D., Movassat, J. & Portha, B. Maternal diabetes, programming of beta-cell disorders and intergenerational risk of type 2 diabetes. Diabetes Metab. 40(5), 323–330 (2014).
Fleming, T. P. et al. Origins of lifetime health around the time of conception: causes and consequences. Lancet. 391(10132), 1842–1852 (2018).
Dasinger, J. H., Davis, G. K., Newsome, A. D. & Alexander, B. T. Developmental programming of hypertension: physiologic mechanisms. Hypertension. 68(4), 826–831 (2016).
Walton, S. L. et al. Prenatal hypoxia leads to hypertension, renal renin-angiotensis system activation and exacerbates salt-induced pathology in a sex-specific manner. Sci. Rep. 7(1), 8241 (2017).
Walton, S. L. et al. Prolonged prenatal hypoxia selectively disrupts collecting duct patterning and postnatal function in male mouse offspring. J. Physiol. https://doi.org/10.1113/JP275918 (2018). [epub ahead of print].
Solano, M. E., Thiele, K., Kowal, M. K. & Arck, P. C. Identification of suitable reference genes in the mouse placenta. Placenta. 39, 7–15 (2016).
Higgins, J. S. & Vaughan, O. R. Fernandez de Liger, E., Fowden, A. L. & Sferruzzi-Perri, A. N. Placental phenotype and resource allocation to fetal growth are modified by the timing and degree of hypoxia during mouse pregnancy. J. Physiol. 594(5), 1341–1356 (2016).
Singhal, A. et al. Nutrition in infancy and long-term risk of obesity: evidence from 2 randomized controlled trials. Am. J. Clin. Nutr. 92, 1133–1144 (2010).
Spiroski, A. M. et al. Postnatal effects of intrauterine treatment of the growth-restricted ovine fetus with intra-amniotic insulin-like growth factor-1. J. Physiol. https://doi.org/10.1113/JP274999 (2017). [epub ahead of print].
Rueda-Clausen, C. F. et al. Effect of prenatal hypoxia in transgenic mouse models of preeclampsia and fetal growth restriction. Reprod. Sci. 21(4), 492–502 (2014).
Cuffe, J. S. et al. Mid- to late term hypoxia in the mouse alters placental morphology, glucocorticoid regulatory pathways and nutrient transporters in a sex-specific manner. J. Physiol. 592(14), 3127–41 (2014).
Cuffe, J. S. et al. The effects of gestational age and maternal hypoxia on the placental renin angiotensin system in the mouse. Placenta. 35(11), 953–61 (2014).
Whitesall, S. E., Hoff, J. B., Vollmer, A. P. & D’Alecy, L. G. Comparison of simultaneous measurement of mouse systolic arterial blood pressure by radiotelemetry and tail-cuff methods. Am. J. Physiol. Heart. Circ. Physiol. 288(6), H2408–2415 (2004).
Feng, M., Whitesall, S., Zhang, Y., Beibel, M., D’Alecy, L. & Dipetrillo, K. Validation of volume-pressure recording tail-cuff blood pressure measurements. Am. J. Hypertens. 21(12), 1288–1291 (2008).
Simmons, D. G., Rawn, S., Davies, A., Hughes, M. & Cross, J. C. Spatial and temporal expression of the 23 murine prolactin/placental lactogen-related genes is not associated with their position in the locus. B. M. C. Genomics. 9, 352 (2008).
Soares, M. J., Igbal, K. & Kozai, K. Hypoxia and placental development. Birth Defects Res. 109(17), 1309–1329 (2017).
Alahari, S., Post, M., Rolfo, A., Weksberg, R. & Caniggia, I. Compromised JMJD6 histone demethylase activity impacts on VHL gene repression in preeclampsia. J. Clin. Endocrinol. Metab. 103(4), 1545–1557 (2018).
Tetzlaff, M. T. et al. Defective cardiovascular development and elevated cyclin E and Notch proteins in mice lacking the Fbw7 F-box protein. Proc. Natl. Acad. Sci. USA 101(10), 3338–3345 (2004).
Herrer, I. et al. Gene expression network analysis reveals new transcriptional regulators as novel factors in human ischemic cardiomyopathy. B. M. C. Med. Genomics. 8, 14 (2015).
Lee, S. H. et al. Hypoxia accelerates vascular repair of endothelial colony-forming cells on ischemic injury via STAT3-BCL3 axis. Stem Cell Res. Ther. 6, 139 (2015).
Centlow, M., Wingren, C., Borrebaeck, C., Brownstein, M. J. & Hansson, S. R. Differential gene expression analysis of placentas with increased vascular resistance and pre-eclampsia using whole-genome microarrays. J. Pregnancy. 2011, 472354 (2011).
Mahany, E. B. et al. Obesity and high-fat diet induce distinct changes in placental gene expression and pregnancy outcome. Endocrinology. 159(4), 1718–1733 (2018).
Zhao, H., Azuma, J., Kalish, F., Wong, R. J. & Stevenson, D. K. Maternal heme oxygenase 1 regulates placental vasculature development via angiogenic factors in mice. Biol. Reprod. 85(5), 1005–1012 (2011).
Millward, C. A. et al. Phosphoenolpyruvate carboxykinase (Pck1) helps regulate the triglyceride/fatty acid cycle and development of insulin resistance in mice. J. Lipid Res. 51(6), 1452–1463 (2010).
Knigge, A. et al. ADCY5 gene expression in adipose tissue is related to obesity in men and mice. PLoS One. 10(3), e0120742 (2015).
Ryczko, M. C. et al. Metabolic reprogramming by hexosamine biosynthetic and golgi N-glycan branching pathways. Sci. Rep. 6, 23043 (2016).
Karaman, S. et al. Blockade of VEGF-C and VEGF-D modulates adipose tissue inflammation and improves metabolic parameters under high-fat diet. Mol. Metab. 4(2), 93–105 (2014).
Dick, K. J. et al. DNA methylation and body-mass index: a genome-wide analysis. Lancet. 383(9933), 1990–1998 (2014).
Heidbreder, M. et al. Non-hypoxic induction of HIF-3alpha by 2-deoxy-D-glucose and insulin. Biochem. Biophys. Res. Commun. 352(2), 437–443 (2007).
Choi, J. H., Ishida, M., Matsuwaki, T., Yamanouchi, K. & Nishihara, M. Involvement of 20alpha-hydroxysteroid dehydrogenase in the maintenance of pregnancy in mice. J. Reprod. Dev. 54(6), 408–412 (2008).
Togher, K. L. et al. Epigenetic regulation of the placental HSD11B2 barrier and its role as a critical regulatory of fetal development. Epigenetics. 9(6), 816–822 (2014).
Wyrwoll, C. S. et al. Pravastatin ameliorates placental vascular defects, fetal growth, and cardiac function in a model of glucocorticoid excess. Proc. Natl. Acad. Sci. USA 113(22), 6265–6270 (2016).
Simonides, W. S. et al. Hypoxia-inducible factor induces local thyroid hormone inactivation during hypoxia-ischemic disease in rats. J. Clin. Invest. 118(3), 975–983 (2008).
Constância, M. et al. Adaptation of nutrient supply to fetal demand in the mouse involves interaction between the Igf2 gene and placental transporter systems. Proc. Natl. Acad. Sci. USA 102(52), 19219–19224 (2005).
Pringle, K. G., Kind, K. L., Sferruzzi-Perri, A. N., Thompson, J. G. & Roberts, C. T. Beyond oxygen: complex regulation and activity of hypoxia inducible factors in pregnancy. Hum. Reprod. Update. 16(4), 415–431 (2010).
Haertle, L. et al. Epigenetic signatures of gestational diabetes mellitus on cord blood methylation. Clin. Epigenetics. 9, 28 (2017).
McGraw, S. et al. Transient DNMT1 suppression reveals hidden heritable marks in the genome. Nucleic Acids Res. 43(3), 1485–1497 (2015).
Bourque, S. L. et al. Prenatal hypoxia causes long-term alterations in vascular endothelin-1 function in aged male, but not female, offspring. Hypertension. 62, 753–758 (2013).
Alexander, B. T. Placental insufficiency leads to development of hypertension in growth-restricted offspring. Hypertension. 41, 457–462 (2013).
Garg, M., Thamotharan, M., Pan, G., Lee, P. W. & Devaskar, S. U. Early exposure of the pregestational intrauterine and postnatal growth-restricted female offspring to a peroxisome proliferator-activated receptor-{gamma} agonist. Am. J. Physiol. Endocrinol. Metab. 298(3), E489–E498 (2010).
Liu, Q. et al. Promoter hypomethylation and increased maspin expression in preeclamptic placentas in a Chinese population. Placenta. 35(11), 876–882 (2014).
Zhang, G. et al. Genetic associations with gestational duration and spontaneous preterm birth. N. Eng. J. Med. 377(12), 1156–1167 (2017).
McFarlane, L., Truong, V., Palmer, J. S. & Wilhelm, D. Novel PCR assay for determining the genetic sex of mice. Sex. Dev. 7(4), 207–211 (2013).
Dobin, A. et al. STAR: ultrafast universal RNA-seq aligner. Bioinformatics. 29(1), 15–21 (2013).
Casero, D. et al. Long non-coding RNA profiling of human lymphoid progenitor cells reveals transcriptional divergence of B cell and T cell lineages. Nat. Immunol. 16(12), 1282–1291 (2015).
Love, M. I., Huber, W. & Anders, S. Moderated estimation of fold change and dispersion for RNA-seq data with DESeq. 2. Genome Biol. 15(12), 550 (2014).
Lopez, D. et al. SaVanT: a web-based tool for the sample-level visualization of molecular signatures in gene expression profiles. B. M. C. Genomics. 18(1), 824 (2017).
Shannon, P. et al. Cytoscape: a software environemnt for integrated models of biomolecular interaction networks. Genome Research. 13(11), 2498–2504 (2003).
Gibson, L. C. et al. Early leptin intervention reverses perturbed energy balance regulating hypothalamic neuropeptides in the pre- and postnatal calorie-restricted female rat offspring. J. Neurosci. Res. 93(6), 902–912 (2015).
Hermann, G. M. et al. Neonatal catch up growth increases diabetes susceptibility but improved behavioral and cardiovascular outcomes of low birth weight male mice. Pediatr. Res. 66(1), 53–58 (2009).
Suto, J. Genetic analysis of litter size in mice. J. Vet. Med. Sci. 77(3), 353–358 (2015).
Chu, A., Gozal, D., Cortese, R. & Wang, Y. Cardiovascular dysfunction in adult mice following postnatal intermittent hypoxia. Pediatr. Res. 77(3), 425–433 (2015).
Acknowledgements
Thank you to Dr. Mansoureh Eghbali and Dr. Yibin Wang for the use of their equipment (hypoxia chamber, cuff blood pressure system). Thank you to Meng-Chin Lin for her assistance in conducting additional experiments for revisions. This work was supported by the UCLA Children’s Discovery and Innovation Institute [CDI-SGA-01012016 (AC)], the American Heart Association [15BGIA25710060 (AC)], and the National Institutes of Health [1K08HD093874-01 (AC), KL2TR001882-01 (Mitchell Wong), HD-41230 (SUD), and HD-081206 (SUD)].
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This work was conducted at the University of California-Los Angeles, Los Angeles, CA, USA. Conceived and designed experiments: A.C., M.W., S.U.D. Acquired, analysed and interpreted data: A.C., D.C., S.T., A.C., S.U.D. Drafted or revised manuscript: A.C., D.C., A.C., M.W., S.U.D. All authors have approved the final version of the manuscript, and agree to be accountable for all aspects of the work.
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Chu, A., Casero, D., Thamotharan, S. et al. The Placental Transcriptome in Late Gestational Hypoxia Resulting in Murine Intrauterine Growth Restriction Parallels Increased Risk of Adult Cardiometabolic Disease. Sci Rep 9, 1243 (2019). https://doi.org/10.1038/s41598-018-37627-y
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DOI: https://doi.org/10.1038/s41598-018-37627-y
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