• Energy Research

AbstractAlcohol during pregnancy can impair fetal development and result in offspring with neurodevelopmental deficits. Less is known about how low to moderate alcohol exposure can affect other organs, such as the kidney. Here, the effects of moderate ethanol exposure throughout pregnancy on kidney development were examined using a rat model. Rats were fed a liquid diet containing 6% ethanol (vol/vol) or control (0% ethanol) throughout pregnancy. Kidneys were collected at embryonic day (E) 20 or postnatal day (PN) 30 and total glomerular (nephron) number determined using unbiased stereology. Kidney function was examined in offspring at 8 and 19 months. At E20, fetuses exposed to ethanol had fewer nephrons with increased apoptosis. Alcohol exposure caused kidney dysregulation of pro‐ (Bax) and anti‐ (Bcl‐2) apoptotic factors, and reduced expression of the cell proliferation marker, Ki67. Prenatal alcohol decreased expression of Gdnf and Tgfb1, important regulators of branching morphogenesis, in male fetuses. At PN30, kidney volume and nephron number were lower in offspring exposed to prenatal alcohol. Urine flow and osmolality were normal in offspring exposed to alcohol however sodium excretion tended to be lower in females prenatally exposed to alcohol. Findings suggest exposure to moderate levels of alcohol during pregnancy results in impaired kidney development and leads to a permanent nephron deficit. Although the impact on adult kidney function was relatively minor, these data highlight that even at moderate levels, alcohol consumption during pregnancy can have deleterious long‐term outcomes and should be avoided.

Prenatal alcohol exposure (PAE), like other pregnancy complications, can result in placental insufficiency and fetal growth restriction, although the linking causal mechanisms are unclear. We previously identified 11 gestationally elevated maternal circulating miRNAs (HEamiRNAs) that predicted infant growth deficits following PAE. Here, we investigated whether theseHEamiRNAs contribute to the pathology of PAE, by inhibiting trophoblast epithelial–mesenchymal transition (EMT), a pathway critical for placental development. We now report for the first time that PAE inhibits expression of placental pro-EMT pathway members in both rodents and primates, and thatHEamiRNAs collectively, but not individually, mediate placental EMT inhibition.HEamiRNAs collectively, but not individually, also inhibited cell proliferation and the EMT pathway in cultured trophoblasts, while inducing cell stress, and following trophoblast syncytialization, aberrant endocrine maturation. Moreover, a single intravascular administration of the pooled murine-expressedHEamiRNAs, to pregnant mice, decreased placental and fetal growth and inhibited the expression of pro-EMT transcripts in the placenta. Our data suggest thatHEamiRNAs collectively interfere with placental development, contributing to the pathology of PAE, and perhaps also, to other causes of fetal growth restriction.

Key points Prenatal alcohol exposure has the potential to affect fetal development and programme chronic disease in offspring. Previous preclinical models typically use high, chronic doses of alcohol throughout pregnancy to examine effects on offspring, particularly on the brain and behaviour. In this study we use a rat model of moderate, acute, prenatal alcohol exposure to determine if this can be detrimental to maintenance of glucose homeostasis in adolescent and adult offspring. Although female offspring were relatively unaffected, there was evidence of insulin resistance in 6‐month‐old male offspring exposed to prenatal alcohol, suggestive of a pre‐diabetic state. This result suggests that even a relatively low‐dose, acute exposure to alcohol during pregnancy can still programme metabolic dysfunction in a sex‐specific manner. AbstractAlcohol consumption is highly prevalent amongst women of reproductive age. Given that approximately 50% of pregnancies are unplanned, alcohol has the potential to affect fetal development and programme chronic disease in offspring. We examined the effect of an acute but moderate prenatal alcohol exposure (PAE) on glucose metabolism, lipid levels and dietary preference in adolescent and/or adult rat offspring. Pregnant Sprague–Dawley rats received an oral gavage of ethanol (1 g kg−1 maternal body weight, n = 9 dams) or an equivalent volume of saline (control, n = 8 dams) at embryonic days 13.5 and 14.5. PAE resulted in a blood alcohol concentration of 0.05–0.06% 1 h post‐gavage in dams. Fasting blood glucose concentration was not affected by PAE in offspring at any age, nor were blood glucose levels during a glucose tolerance test (GTT) in 6‐month‐old offspring (P > 0.5). However, there was evidence of insulin resistance in PAE male offspring at 6 months of age, with significantly elevated fasting plasma insulin (P = 0.001), a tendency for increased first phase insulin secretion during the GTT and impaired glucose clearance following an insulin challenge (P = 0.007). This was accompanied by modest alterations in protein kinase B (AKT) signalling in adipose tissue. PAE also resulted in reduced calorie consumption by offspring compared to controls (P = 0.04). These data suggest that a relatively low‐level, acute PAE programmes metabolic dysfunction in offspring in a sex‐specific manner. These results highlight that alcohol consumption during pregnancy has the potential to affect the long‐term health of offspring.

Prenatal alcohol exposure disturbs fetal and placental growth and can alter DNA methylation (DNAm). Supplementation with the methyl donor choline can increase fetal and placental growth and restore DNAm, suggesting converging effects on one-carbon metabolism (1CM). We investigated the impact of periconceptional ethanol (PCE) exposure and prenatal choline supplementation on 1CM in maternal, placental, and fetal compartments. Female Sprague Dawley rats were given a liquid diet containing 12.5% ethanol (PCE) or 0% ethanol (control) for 4 days before and 4 days after conception. Dams were then placed on chow with different concentrations of choline (1.6 g, 2.6 g, or 7.2 g choline/kg chow). Plasma and tissues were collected in late gestation for the analysis of 1CM components by means of mass spectrometry and real-time PCR. PCE reduced placental components of 1CM, particularly those relating to folate metabolism, resulting in a 3–7.5-fold reduction in the ratio of s-adenosylmethionine:s-adenosylhomocysteine (SAM:SAH) (p < 0.0001). Choline supplementation increased placental 1CM components and the SAM:SAH ratio (3.5–14.5-fold, p < 0.0001). In the maternal and fetal compartments, PCE had little effect, whereas choline increased components of 1CM. This suggests that PCE impairs fetal development via altered placental 1CM, highlighting its role in modulating nutritional inputs to optimize fetal development.

AbstractAlcohol exposure during pregnancy disrupts fetal development and programs lifelong disease. We have shown, in rats, that alcohol exposure during the periconceptional period (PC:EtOH), causes placental dysfunction and cardiometabolic disease in offspring. The process of metabolising alcohol can cause oxidative stress and damage mitochondrial DNA (mtDNA). It is unknown whether alcohol metabolism in a rat model of PC:EtOH impacts oxidative stress markers and mitochondrial content in maternal and placental tissues. We aimed to determine whether PC:EtOH induced oxidative stress and reduced mtDNA in maternal liver and the placental labyrinth and junctional zone. Sprague–Dawley rats were given an ethanol liquid (12.5% v/v) or control (0%) diet for one oestrous cycle before mating to embryonic day (E) 4. Maternal livers were collected at E5 and E20. Placentas were collected at E20 and separated into the junctional zone and labyrinth zone. PC:EtOH reduced Cyp2e1 mRNA levels and mtDNA in the E5 liver with lower mtDNA persisting to E20, at which time mitochondrial proteins were also decreased. PC:EtOH also reduced mitochondrial content in the E20 junctional zone, although mitochondrial protein levels were unaffected. Superoxide dismutase activity was increased in the placental junctional zone and there was no evidence of oxidative stress. The present study demonstrates that alcohol exposure around conception, reduces mitochondrial content within the maternal liver and the junctional zone of the placenta towards the end of pregnancy. These prolonged deficits may have disrupted metabolic processes required for a healthy pregnancy. The study further supports avoiding alcohol when planning a pregnancy. imageKey points Even when alcohol is consumed only around conception (PC:EtOH), it can have profound impacts on the developing baby. Here, we use our established rat model to investigate if PC:EtOH causes oxidative stress and reduces mitochondrial content in the maternal liver immediately after exposure on embryonic day (E) 5. We also investigate these parameters at the end of pregnancy (E20) in maternal liver and the placenta. PC:EtOH reduced mitochondrial DNA content in the maternal liver by 77% at E5 and by 40% at E20. At E20, expression of proteins that form the electron transport chain were also reduced. The placenta had a more subtle reduction in mitochondrial DNA content, but protein levels of mitochondrial complexes were unchanged. There was no evidence of oxidative stress in the maternal liver or placenta in response to PC:EtOH. The lack of oxidative stress in the placenta may be a result of compensatory increases in antioxidants.

ABSTRACT The development of pathologies during pregnancy, including pre-eclampsia, hypertension and fetal growth restriction (FGR), often originates from poor functioning of the placenta. In vivo models of maternal stressors, such as nutrient deficiency, and placental insufficiency often focus on inadequate growth of the fetus and placenta in late gestation. These studies rarely investigate the origins of poor placental formation in early gestation, including those affecting the pre-implantation embryo and/or the uterine environment. The current study characterises the impact on blastocyst, uterine and placental outcomes in a rat model of periconceptional alcohol exposure, in which 12.5% ethanol is administered in a liquid diet from 4 days before until 4 days after conception. We show female-specific effects on trophoblast differentiation, embryo-uterine communication, and formation of the placental vasculature, resulting in markedly reduced placental volume at embryonic day 15. Both sexes exhibited reduced trophectoderm pluripotency and global hypermethylation, suggestive of inappropriate epigenetic reprogramming. Furthermore, evidence of reduced placental nutrient exchange and reduced pre-implantation maternal plasma choline levels offers significant mechanistic insight into the origins of FGR in this model.

Fetal alcohol exposure results in well-characterised neurobehavioural deficits in offspring, which form the basis for diagnosing fetal alcohol spectrum disorder. However, there is increasing interest in the full range of health complications that can arise in children and adults with this disorder. We used a systematic review approach to locate all clinical and preclinical studies across a broad range of health outcomes in offspring exposed to prenatal alcohol. Our search encompassed four databases (PubMed, CINAHL, EMBASE and Web of Science) and titles/abstracts from retrieved studies were screened against strict inclusion/exclusion criteria. This review specifically evaluated studies reporting on reproductive outcomes in both males and females. A total of 23 studies were included, 5 clinical and 18 preclinical. Although there was a wide range in the quality of reporting across both clinical and preclinical studies, and variable results, trends emerged amongst the reproductive measures that were investigated. In females, most studies focussed on age at first menarche/puberty onset, with evidence for a significant delay in alcohol-exposed offspring. In males, offspring exposed to prenatal alcohol had altered testosterone levels, reduced testes and accessory gland weights and reduced sperm concentration and semen volume. However, further studies are required due to the paucity of clinical studies, the narrow scope of female reproductive outcomes examined and inconsistencies in outcomes across preclinical studies. We recommend that adolescents and individuals of reproductive age diagnosed with f-etal alcohol spectrum disorder be assessed for reproductive dysfunction to allow appropriate management of their reproductive health and fertility.