Maternal Dietary Protein Restriction Research Articles

Blastocyst trophectoderm endocytic activation, a marker of adverse developmental programming.

The mouse preimplantation embryo is sensitive to its environment, including maternal dietary protein restriction, which can alter the developmental programme and affect lifetime health. Previously, we have shown maternal low-protein diet (LPD) causes a reduction in blastocyst mTORC1 signalling coinciding with reduced availability of branched-chain amino acids (BCAAs) in surrounding uterine fluid. BCAA deficiency leads to increased endocytosis and lysosome biogenesis in blastocyst trophectoderm (TE), a response to promote compensatory histotrophic nutrition. Here, we first investigated the induction mechanism by individual variation in BCAA deficiency in an in vitro quantitative model of TE responsiveness. We found isoleucine (ILE) deficiency as the most effective activator of TE endocytosis and lysosome biogenesis, with less potent roles for other BCAAs and insulin; cell volume was also influential. TE response to low ILE included upregulation of vesicles comprising megalin receptor and cathepsin-B, and the response was activated from blastocyst formation. Secondly, we identified the transcription factor TFEB as mediating the histotrophic response by translocation from cytoplasm to nucleus during ILE deficiency and in response to mTORC1 inhibition. Lastly, we investigated whether a similar mechanism responsive to maternal nutritional status was found in human blastocysts. Blastocysts from women with high body-mass index, but not the method of fertilisation, revealed stimulated lysosome biogenesis and TFEB nuclear migration. We propose TE lysosomal phenotype as an early biomarker of environmental nutrient stress that may associate with long-term health outcomes.

Maternal supplementation with citrulline or arginine during gestation impacts fetal amino acid availability in a model of intrauterine growth restriction (IUGR).

Supplementing maternal diet with citrulline or arginine during gestation was shown to enhance fetal growth in a model of IUGR induced by maternal dietary protein restriction in the rat. The aims of this study were to determine in the same model whether maternal supplementation with citrulline or arginine would increase 1) citrulline and arginine concentration in fetal circulation; 2) the expression of placental amino acid transporters, and 3) the fetal availability of essential amino acids. Pregnant rats (n=8 per group) were fed either an isocaloric control (20% protein, NP) or a low protein (LP, 4% protein) diet, either alone or supplemented with 2g/kg/d of l-citrulline (LP+CIT) or isonitrogenous Arginine (LP+ARG) in drinking water throughout gestation. Fetuses were extracted by C-section on the 21st day of gestation. The gene expression of system A (Slc38a1, Slc38a2, and Slc38a4) and L (Slc7a2, Slc7a5, Slc7a8) amino acid transporters was measured in placenta and amino acid concentrations determined in maternal and fetal plasma. Maternal LP diet decreased fetal (4.01±0.03 vs. 5.45±0.07g, p<0.0001) and placental weight (0.617±0.01 vs. 0.392±0.04g, p<0.001), by 26 and 36% respectively, compared with NP diet. Supplementation with either CIT or ARG increased fetal birth weight by≈5 or 11%, respectively (4.21±0.05 and 4.48±0.05g vs. 4.01±0.03g, p<0.05). CIT supplementation produced a 5- and 2-fold increase in fetal plasma citrulline and arginine, respectively, whereas ARG supplementation only increased fetal arginine concentration. LP diet led to lower placental SNAT 4 mRNA, and higher LAT2 and SNAT1 expression, compared with NP. SNAT4, 4hFC, LAT2 mRNA were up-regulated in LP+CIT and LP+ARG group compared with the un-supplemented LP group. Higher level of LAT1 mRNA was also observed in the LP+CIT group than in the LP group (p<0.01). SNAT2 expression was unchanged in response to CIT or ARG supplementation. Fetal amino acid concentrations were decreased by LP diet, and were not restored by CIT or ARG supplementation. The current findings confirm supplementation with citrulline or arginine enhances fetal growth in a rat model of IUGR. They further suggest that: 1) citrulline and arginine administered orally to the pregnant mother may reach fetal circulation; 2) citrulline effectively raises fetal arginine availability; and 3) although it failed to increase the concentrations of essential amino acids in fetal plasma, citrulline or arginine supplementation upregulates the gene expression of several placental amino acid transporters.

The long-term effect of maternal dietary protein restriction on 5-HT1A receptor function and behavioral responses to stress in adulthood

Maternal nutrition impacts fetal development, and may play a role in determining resilience to stress and vulnerability to stress-precipitated psychiatric disorders, such as anxiety and depression. In this study, we examined the effect of a reduction in maternal dietary protein during pregnancy on the brain neurochemistry and behavior of offspring. We focused specifically on the serotonin system, the 5-HT1A receptor and the responsivity of offspring as adults to stress. Dams were fed either a low protein diet (10% protein by weight) or isocaloric control diet (20% protein by weight). The low protein diet did not alter maternal food intake and body weight, or litter size and the average birth weight of male or female littermates. 5-HT1A receptor function, as measured by quantitative autoradiography of 8-OH-DPAT (1 μM)-stimulated [35S]GTPγS binding, was markedly reduced in hippocampus of weanling female, but not male offspring (postnatal day, PND 21) of dams fed the low protein diet. The number of serotonergic cell bodies in the rostral raphe, and 5-HT metabolism in the limbic system of weanling offspring was not altered by maternal low protein diet. The deficit in hippocampal 5-HT1A receptor function observed in weanling female offspring persisted into adulthood (PND 112), and was accompanied by an increased sensitivity to stress, specifically increased immobility during a 15-minute forced swim challenge and increased anorexia following 30-minute restraint (PND 97-100). The present work begins to uncover important future directions for understanding the early developmental origins of resilience to stress, and factors that may put individuals at greater risk for stress-related psychiatric disorders.

Hepatic Autophagy Gene Expression Is Induced by Post‐Weaning Diets in Sprague‐Dawley Rats fed with A Low‐Protein Diet During Lactation

BackgroundBoth maternal dietary protein restriction and excess fat intake are associated with numerous metabolic responses including the activation of transcription factor 4 (ATF4). ATF4 is one of the master regulators of stress response pathways, which potentially program autophagy genes expression in the liver of offspring rats.HypothesisThe current study tested the hypothesis that lactational low‐protein (LP) diet and postnatal high‐fat (HF) diet induce a metabolic mismatch that activates autophagy gene expression through the activation of ATF4 in the liver of offspring rats.MethodsTimed‐pregnant Sprague‐Dawley rats were fed a control diet (C, 20% protein) during gestation followed by either a LP diet (8% protein) or the control diet during lactation for 21 days. At weaning, the offspring was fed either C (16% fat) or HF (45% fat) to generate three offspring groups: C/C/C, C/LP/C and C/LP/HF. At 12 weeks of age, liver samples of male and female rats were collected for analysis.ResultsLactational LP diet and post‐weaning HF diet induce autophagy gene expression differentially in the liver of male and female offspring. mRNA expression of Beclin1, p62/sqstm1, LC3b and Atg5, crucial markers of autophagy, was significantly upregulated by lactational LP diet (C/LP/C when compared to C/C/C, p&lt;0.05) in female offspring, but not in male offspring. Consistent with that, mRNA expression of other autophagy related genes including Atg16l1, Atg12 Atg3, Gabarapl2, Atg7, Atg10 and Gabarap increased significantly in the female offspring only. Moreover, autophagy genes Atg16l1, Atg12, Atg3, Beclin1, p62/sqstm1, LC3b, Gabarapl2, Atg7, Atg10, Gabarap, and Atg5 were expressed at a higher level by post‐weaning HF diet (C/LP/HF when compared to C/LP/C, p&lt;0.05) in both male and female offspring. A master regulator of stress pathway, transcription factor ATF4, also displayed differential expression in the mismatched dietary groups.ConclusionLactational low‐protein diet induced autophagy related gene expression in female offspring and the induction was further augmented by a post‐weaning high‐fat diet. On the other hand, in the liver of male offspring, only post‐weaning high‐fat diet induced mRNA expression of autophagy related genes. The differential regulation of autophagy by diets, sex, and developmental periods could be explained by dysregulation of stress response pathway involving transcription factor ATF4. Overall, our data demonstrated that lactational low‐protein diet may impact autophagy pathway more in female offspring than in male offspring rats.This abstract is from the Experimental Biology 2018 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.

Perinatal supplementation of 4-phenylbutyrate and glutamine attenuates endoplasmic reticulum stress and improves colonic epithelial barrier function in rats born with intrauterine growth restriction

Intrauterine growth restriction (IUGR) can affect the structure and function of the intestinal barrier and increase digestive disease risk in adulthood. Using the rat model of maternal dietary protein restriction (8% vs. 20%), we found that the colon of IUGR offspring displayed decreased mRNA expression of epithelial barrier proteins MUC2 and occludin during development. This was associated with increased mRNA expression of endoplasmic reticulum (ER) stress marker XBP1s and increased colonic permeability measured in Ussing chambers. We hypothesized that ER stress contributes to colonic barrier alterations and that perinatal supplementation of dams with ER stress modulators, phenylbutyrate and glutamine (PG) could prevent these defects in IUGR offspring. We first demonstrated that ER stress induction by tunicamycin or thapsigargin increased the permeability of rat colonic tissues mounted in Ussing chamber and that PG treatment prevented this effect. Therefore, we supplemented the diet of control and IUGR dams with PG during gestation and lactation. Real-time polymerase chain reaction and histological analysis of colons from 120-day-old offspring revealed that perinatal PG treatment partially prevented the increased expression of ER stress markers but reversed the reduction of crypt depth and goblet cell number in IUGR rats. In dextran sodium sulfate-induced injury and recovery experiments, the colon of IUGR rats without perinatal PG treatment showed higher XBP1s mRNA levels and histological scores of inflammation than IUGR rats with perinatal PG treatment. In conclusion, these data suggest that perinatal supplementation with PG could alleviate ER stress and prevent epithelial barrier dysfunction in IUGR offspring.

Use of water turnover method to measure mother's milk flow in a rat model: Application to dams receiving a low protein diet during gestation and lactation.

Assessment of milk production is of utmost relevance for pediatricians and scientists interested in early life nutrition. The weight-suckle-weight (WSW) method, which consists of weighing babies before and after they suckle their mother, uses the difference in body weight as an estimate of milk intake. However, this is prone to many sources of error. In the current study, we used for the first time the water turnover method and compartmental analysis with deuterated water (D2O) as a non-toxic tracer to quantify in vivo milk production in a rat model. We assessed the effect of a nutritional intervention presumed to affect milk production, a maternal dietary protein restriction during gestation and lactation, which results in the birth of pups with intrauterine growth restriction. The specific aim of this study was to determine milk production with the body water turnover method in rat dams receiving during gestation and lactation, either a control diet (NP) or an iso-caloric low-protein diet (LP). In NP dams, mass of dam’s total body water, output flow constant from dam to litter (K21) and median milk flow, calculated between days 11 to 14 after pup birth, were 282.1 g, 0.0122 h-1 and 3.30 g/h for NP dams, respectively. Maternal dietary protein restriction (-59%) during perinatal period led to a 34% reduction in milk flow (NP versus LP). With the WSW method, milk flow varied from 1.96 g/h to 2.37 g/h between days 11 to 14 for NP dams. The main advantage of the D20 method compared to the WSW method stems from its higher precision, as attested by the narrowest range of measured values of milk flow ([2.90; 3.75] and [0.98; 6.85] g/h, respectively) for NP group. This method could be suitable for testing the effectiveness of candidate galactologue molecules presumed to enhance milk production in the lactating rat model.

Maternal protein restriction depresses the duodenal expression of iron transporters and serum iron level in male weaning piglets.

To investigate the effects of maternal dietary protein restriction on offspring Fe metabolism, twenty-four second-parity Landrace×Yorkshire sows were randomly allocated to standard-protein (SP) and low-protein (LP) groups. The SP sows were fed diets containing 15 and 18 % crude protein throughout pregnancy and lactation, respectively, whereas the LP sows were subjected to 50 % dietary protein restriction. Offspring birth weight was not affected, but the body weight at weaning (P=0·06) and average daily gain (P=0·01) of the female piglets were significantly decreased. Serum Fe level in the LP piglets was markedly decreased at weaning, especially in males (P=0·03). Serum ferritin level (P=0·08) tended to be lower, yet serum transferrin was greatly higher (P=0·01) in male weaning piglets of the LP group. Duodenal expression of the divalent metal transporter 1 (DMT1) and ferroportin (FPN) was surprisingly reduced (P<0·05) at the level of protein, but not at the mRNA level, in male weaning piglets of the LP group. Male weaning piglets born to the LP sows exhibited higher hepatic hepcidin levels (P=0·09), lower hepatic expression of transferrin (P<0·01) and transferrin receptor 1 (P<0·05) at the level of mRNA. However, no significant differences were observed for hepatic Fe storage, ferritin, transferrin and transferrin receptor 1 protein expression in male weaning piglets of the two groups. These results indicate that maternal protein restriction during pregnancy and lactation influences growth of female offspring at weaning, reduces duodenal expression of Fe transporters (DMT1 and FPN) and decreases serum Fe level in male weaning piglets.

Loss of Vagal Sensitivity to Cholecystokinin in Rats Born with Intrauterine Growth Retardation and Consequence on Food Intake.

Perinatal malnutrition is associated with low birth weight and an increased risk of developing metabolic syndrome in adulthood. Modification of food intake (FI) regulation was observed in adult rats born with intrauterine growth retardation induced by maternal dietary protein restriction during gestation and maintained restricted until weaning. Gastrointestinal peptides and particularly cholecystokinin (CCK) play a major role in short-term regulation of FI by relaying digestive signals to the hindbrain via the vagal afferent nerve (VAN). We hypothesized that vagal sensitivity to CCK could be affected in rats suffering from undernutrition [low protein (LP)] during fetal and postnatal life, leading to an altered gut–brain communication and impacting satiation. Our aim was to study short-term FI along with signals of appetite and satiation in adult LP rats compared to control rats. The dose–response to CCK injection was investigated on FI as well as the associated signaling pathways activated in nodose ganglia. We showed that LP rats have a reduced first-meal satiety ratio after a fasting period associated to a higher postprandial plasmatic CCK release, a reduced sensitivity to CCK when injected at low concentration and a reduced presence of CCK-1 receptor in nodose ganglia. Accordingly, the lower basal and CCK-induced phosphorylation of calcium/calmodulin-dependent protein kinase in nodose ganglia of LP rats could reflect an under-expressed vanilloid family of transient receptor potential cation channels on VAN. Altogether, the present data demonstrated a reduced vagal sensitivity to CCK in LP rats at adulthood, which could contribute to deregulation of FI reported in this model.

Green tea extract intake during lactation modified cardiac macrophage infiltration and AMP-activated protein kinase phosphorylation in weanling rats from undernourished mother during gestation and lactation.

Maternal dietary restriction is often associated with cardiovascular disease in offspring. The aim of this study was to investigate the effect of green tea extract (GTE) intake during lactation on macrophage infiltration, and activation of adenosine monophosphate (AMP)-activated protein kinase (AMPK) and serine-threonine kinase Akt (Akt) in the hearts of weanlings exposed to maternal dietary protein restriction. Pregnant Wistar rats were fed control (C) or low-protein diets (LP) throughout gestation. Following delivery, the dams received a control or a GTE-containing control diet during lactation: control diet during gestation and lactation (CC), low-protein diet during gestation and lactation (LPC), low-protein diet during gestation and 0.12% GTE-containing low-protein diet during lactation (LPL), and low-protein diet during gestation and 0.24% GTE-containing low-protein diet during lactation (LPH). The female offspring were sacrificed at day 22. Biochemical parameters in the plasma, macrophage infiltration, degree of fibrosis and expression levels of AMPK and Akt were examined. The plasma insulin level increased in LPH compared with LPC. Percentage of the fibrotic areas and the number of macrophages in LPC were higher than those in CC. Conversely, the fibrotic areas and the macrophage number in LPH were smaller (21 and 56%, respectively) than those in LPC. The levels of phosphorylated AMPK in LPL and LPH, and Akt in LPH were greater than those in LPC. In conclusion, maternal protein restriction may induce macrophage infiltration and the decrease of insulin levels. However, GTE intake during lactation may suppress macrophage infiltration and restore insulin secretion function via upregulation of AMPK and insulin signaling in weanlings.

Maternal dietary protein restriction had no adverse effect on fetal ovarian morphology and germ cell markers on day 65 of gestation in sheep

Maternal dietary protein restriction had no adverse effect on fetal ovarian morphology and germ cell markers on day 65 of gestation in sheep

Role of renal sympathetic nerve activity in prenatal programming of hypertension.

Prenatal insults, such as maternal dietary protein deprivation and uteroplacental insufficiency, lead to small for gestational age (SGA) neonates. Epidemiological studies from many different parts of the world have shown that SGA neonates are at increased risk for hypertension and early death from cardiovascular disease as adults. Animal models, including prenatal administration of dexamethasone, uterine artery ligation and maternal dietary protein restriction, result in SGA neonates with fewer nephrons than controls. These models are discussed in this educational review, which provides evidence that prenatal insults lead to altered sodium transport in multiple nephron segments. The factors that could result in increased sodium transport are discussed, focusing on new information that there is increased renal sympathetic nerve activity that may be responsible for augmented renal tubular sodium transport. Renal denervation abrogates the hypertension in programmed rats but has no effect on control rats. Other potential factors that could cause hypertension in programmed rats, such as the renin-angiotensin system, are also discussed.

Maternal protein restriction reduces perlecan at mid-metanephrogenesis in rats.

Maternal dietary protein restriction reduces nephron number in offspring and increases the risk of cardiovascular and chronic kidney diseases. Perlecan is the major basement membrane/extracellular matrix heparan sulfate proteoglycan (HSPG) that plays a crucial role in nephron formation. This study was to determine whether maternal dietary protein restriction during pregnancy leads to an abnormal perlecan expression pattern during kidney development and a correlation with aberrant cell proliferation and apoptosis. Pregnant Sprague-Dawley rats were divided into two groups, maintained on either a low-protein diet (MLP group) or a normal-protein diet (MNP group). Kidneys were dissected from embryos of different kidney development stages. Real-time PCR and immunohistochemistry were performed to detect the transcript level of rHSPG2, the coding gene of perlecan, and its protein expression pattern. Apoptosis and proliferation cell were detected by TUNEL system and Ki67 marker. Embryonic weights and nephron number were significantly affected by maternal low protein diets. The transcript level of rHSPG2 in the MLP group was significantly lower at embryonic day 18 and the neonatal period. Immunohistochemistry study was consistent with the RT-PCR results. The proliferation level of the MLP group was significantly lower than the MNP group at E18 and more apoptotic cells was detected in MLP newborn. Maternal protein restriction reduced the expression of perlecan and lead aberrant cell proliferation and apoptosis during mid-metanephrogenesis in offspring. This data may provide new evidence to understand the mechanism of reduced nephron number due to maternal protein restriction and enlighten solution.

Sexually dimorphic effects of maternal dietary protein restriction on fetal growth and placental expression of 11β-HSD2 in the pig

Placental 11β-hydroxysteroid dehydrogenase 2 (11β-HSD2) inactivates glucocorticoids (GCs) to protect fetuses from over-exposure to maternal GCs, yet how maternal malnutrition affects placental 11β-HSD2 expression is unknown. In this study, Meishan sows were fed standard-protein (SP) or low-protein (LP, 50% of SP) diets and fetuses/newborn piglets were weighed and the corresponding placenta and umbilical cord blood were collected on gestational day 70 and the day of parturition. Significant growth retardation was observed in female, but not male, fetuses (P<0.05) and the newborns (P<0.01) of the LP group, which was accompanied by sexually dimorphic expression of 11β-HSD2 in placentas. Female fetuses in LP group showed significant decrease in placental 11β-HSD2 protein content (P<0.05) and enzyme activity (P<0.05), whereas male fetuses demonstrated significantly enhanced placental 11β-HSD2 activity (P<0.05). Serum cortisol levels were significantly higher (P<0.05) in male piglets compared to females, and the effects of maternal protein restriction on thyroid hormones (T3 and T4) in the umbilical cord blood were also sex dimorphic. Male piglets in LP group had significantly higher T3 (P<0.01) and lower T4 (P<0.01), whereas female piglets showed significantly lower T4 (P<0.01) with no change in T3. As a result, male piglets in LP group exhibited significantly higher T3/T4 ratio compared to female counterparts. These results indicate that the effects of maternal protein restriction on placental 11β-HSD2 expression are gender-dependent in the pig, and thyroid hormones may be involved in such effects.

Do little embryos make big decisions? How maternal dietary protein restriction can permanently change an embryo's potential, affecting adult health.

Periconceptional environment may influence embryo development, ultimately affecting adult health. Here, we review the rodent model of maternal low-protein diet specifically during the preimplantation period (Emb-LPD) with normal nutrition during subsequent gestation and postnatally. This model, studied mainly in the mouse, leads to cardiovascular, metabolic and behavioural disease in adult offspring, with females more susceptible. We evaluate the sequence of events from diet administration that may lead to adult disease. Emb-LPD changes maternal serum and/or uterine fluid metabolite composition, notably with reduced insulin and branched-chain amino acids. This is sensed by blastocysts through reduced mammalian target of rapamycin complex 1 signalling. Embryos respond by permanently changing the pattern of development of their extra-embryonic lineages, trophectoderm and primitive endoderm, to enhance maternal nutrient retrieval during subsequent gestation. These compensatory changes include stimulation in proliferation, endocytosis and cellular motility, and epigenetic mechanisms underlying them are being identified. Collectively, these responses act to protect fetal growth and likely contribute to offspring competitive fitness. However, the resulting growth adversely affects long-term health because perinatal weight positively correlates with adult disease risk. We argue that periconception environmental responses reflect developmental plasticity and 'decisions' made by embryos to optimise their own development, but with lasting consequences.

Influence of angiotensin II type 1 receptor-associated protein on prenatal development and adult hypertension after maternal dietary protein restriction during pregnancy

An adverse relationship between suboptimal fetal environments and the development of adult diseases, such as hypertension, type II diabetes, and cardiovascular disease, has been reported in numerous studies. The purpose of this study was to investigate the strain difference of offspring’s response to maternal malnutrition during pregnancy and the involvement of the renin-angiotensin system (RAS) in the development of adult hypertension using C57BL/6J (C57) mice and angiotensin II (Ang II) type 1 receptor-associated protein-transgenic (ATRAP-Tg) mice. Pregnant dams were fed an isocaloric diet containing either 20% (normal protein; NP) or 8% (low protein; LP) protein. Birth weight was significantly reduced in C57-LP offspring, but not in ATRAP-Tg-LP offspring. Arterial blood pressure was higher in C57-LP offspring than in the other groups. In contrast, ATRAP-Tg-LP offspring did not show an increase in blood pressure compared with NP offspring. Renal angiotensin II type 1 (AT1) receptor expression was not altered by maternal malnutrition, whereas angiotensin II type 2 receptor expression was significantly decreased in C57-LP offspring. In conclusion, these findings suggest that a suboptimal intrauterine environment induces adult hypertension because of an alteration of expression of RAS components, which was partly suppressed by sustained ATRAP overexpression via attenuation of the AT1 receptor-mediated pathological response.

Statistical strategies for relating metabolomics and proteomics data: a real case study in nutrition research area

The current investigations were carried out in the context of a nutritional case study aiming at assessing the postnatal impact of maternal dietary protein restriction during pregnancy and lactation on rat offspring plasma metabolome and hypothalamic proteome. Although data generated by different “Omics” technologies are usually considered and analyzed separately, their interrelation may offer a valuable opportunity for assessing the emerging ‘integrated biology’ concept. The overall strategy of analysis first investigated data pretreatment and variable selection for each dataset. Then, three multivariate analyses were applied to investigate the links between the abundance of metabolites and the expression of proteins collected on the same samples. Unfold principal component analysis and regularized canonical correlation analysis did not take into account the presence of groups of individuals related to the intervention study. On the contrary, the predictive MultiBlock Partial Least Squares method used this information. Regularized canonical correlation analysis appeared as a relevant approach to investigate of the relationships between the two datasets. However, in order to highlight the molecular compounds, proteins and metabolites, associated in interacting or common metabolic pathways for the experimental groups, MultiBlock partial least squares was the most appropriate method in the present nutritional case study.

Maternal dietary protein restriction and excess affects offspring gene expression and methylation of non-SMC subunits of condensin I in liver and skeletal muscle

Recent evidence indicates that maternal nutrition during pregnancy influences gene expression in offspring through epigenetic alterations. In the present study we evaluated the effect of protein excess and deficiency during porcine pregnancy on offspring hepatic and skeletal muscular expression patterns of key genes of methionine metabolism (DNMT1, DNMT3a, DNMT3b, BHMT, MAT2B and AHCYL1), condensin I subunit genes (NCAPD2, NCAPG and NCAPH), important for chromosome condensation and segregation, global DNA methylation and gene-specific DNA methylation. German Landrace sows were randomly assigned to control (CO), high protein (HP) and low protein (LP) diet groups. Tissue samples of offspring were collected from fetal (dpc95), newborn (dpn1), weanling (dpn28) and finisher pigs (dpn188). Gene expression of DNMT1, DNMT3a and DNMT3b was influenced by both HP and LP diets, indicating an involvement of DNA methylation in fetal programming by maternal protein supply. Moreover, hepatic global methylation was significantly affected by protein restriction at dpc95 (p = 0.004) and by protein excess at dpn188 (p = 0.034). Gene expression in fetal liver was significantly different between CO and LP for NCAPD2 (p = 0.0005), NCAPG (p = 0.0009) and NCAPH (p < 0.0001). In skeletal muscle, LP fetuses had significantly altered gene expression of NCAPD2 (p = 0.020) and NCAPH (p = 0.001), compared with CO. Furthermore, NCAPG was differentially methylated among LP, HP and CO; indeed, a significant positive correlation was detected with transcript amount in fetal pigs (r = 0.47, p = 0.002). These data demonstrate that both restriction and excess dietary protein during pregnancy alters the offspring’s epigenetic marks and influences gene expression.

Chronic Maternal Protein Deprivation in Mice Is Associated with Overexpression of the Cohesin-Mediator Complex in Liver of Their Offspring

Epigenetic mechanisms may play an important role in the developmental programming of adult-onset chronic metabolic diseases resulting from suboptimal fetal nutrition, but the exact molecular mechanisms are incompletely understood. Given the central role of the liver in metabolic regulation, we investigated whether chronic maternal dietary protein restriction has long-term effects on liver gene expression in the offspring. We fed adult C57BL/6J dams ad libitum an 8% maternal low-protein (MLP) or 20% protein control diet (C) from 4 wk prior to mating until the end of lactation. Male pups were weaned to standard nonpurified diet and singly housed at 21 d of age (d 21). Body weights were followed to 1 y of age (1 y). At d 21 and 1 y, organs were quantitatively dissected and analyzed. MLP offspring had significantly lower body weights at all ages and significantly lower serum activity of alanine aminotransferase and lactate dehydrogenase at 1 y. Gene expression profiling of liver at 1 y showed 521 overexpressed and 236 underexpressed genes in MLP compared to C offspring. The most important novel finding was the overexpression of genes found in liver that participate in organization and maintenance of higher order chromatin architecture and regulation of transcriptional activation. These included members of the cohesin-mediator complex, which regulate gene expression by forming DNA loops between promoters and enhancers in a cell type-specific fashion. Thus, our findings of increased expression of these factors in liver of MLP offspring implicate a possible novel epigenetic mechanism in developmental programming.

Somatic cytochromec(CYCS) gene expression and promoter-specific DNA methylation in a porcine model of prenatal exposure to maternal dietary protein excess and restriction

There is growing evidence that maternal nutrition during gestation has an important effect on offspring development as well as on their gene expression with long-term effects on the metabolic state. A potential mechanism forming long-lasting gene expression patterns is DNA methylation of cytosine in CpG dinucleotides within the promoter region of distinct genes. There has been special focus on mitochondrial dysfunction by prenatal malnourishment over the recent years. To this end, we investigated the gene expression of somatic cytochrome c (CYCS), an important member of the respiratory chain, in a porcine model of gestational protein over- and undersupply at 94 d post-conception and 1, 28 and 188 d of age, and analysed the association with the DNA methylation status within the CYCS promoter. Gene expression on day 1 post natum showed a significant increase in the low protein (LP) group (P = 0·0005) and a slight increase in the high protein (HP) group (P = 0·079) compared with the control (CO) group in the liver. The mean of the methylation level over forty-seven CpG sites from nucleotide (nt) - 417 to - 10 was significantly decreased in the LP (P = 0·007) and HP (P = 0·009) groups compared with that in the CO group. Excess and restricted protein supply during pregnancy led to hypomethylation of a number of CpG sites in the CYCS promoter, including those representing putative transcription factor-binding sites, associated with elevated expression levels. However, the impact of the low-protein gestation diet is more pronounced, indicating that the offspring could better adapt to excess rather than restricted protein supply.

Protein restriction in the pregnant mouse modifies fetal growth and pulmonary development: role of fetal exposure to β-hydroxybutyrate

Maternal undernutrition during sensitive periods of pregnancy results in offspring predisposed towards the development of a number of diseases of adulthood, including hypertension and diabetes. In order to determine the nature of any gross alterations in fetal growth during early organogenesis, we supplied timed-mated pregnant mice with diets containing 6% protein (6%P), 9% protein (9%P) or 18% protein (18%P; control) from day 0 of pregnancy. At embryonic days 11 (E11), 12 (E12) and 13 (E13), females were killed and fetuses removed. Gross morphological analysis revealed that fetal limb growth was impaired between E11 and E12 in 6%P animals, but this recovered by E13. Likewise, fetal liver growth and lung branching morphogenesis were seen to exhibit an initial growth impairment at E12 followed by a rapid recovery by E13. Coincident with the observed changes in fetal growth, we noted an elevation in maternal hepatic triglyceride content, expression of the ketogenic 3-hydroxy-3-methylglutaryl-CoA synthase 2 (Hmgcs2) and circulating plasma β-hydroxybutyrate (BOHB). In addition, fetal liver Hmgcs2 expression was switched on by E13 in both 6%P- and 9%P-exposed animals. Exogenous BOHB did not influence branching morphogenesis in fetal lung explant cultures; however, we cannot rule out the possibility that this may occur in vivo. In conclusion, we find that disturbance of fetal growth by maternal dietary protein restriction is associated and therefore potentially indicated by changes in maternal and fetal ketone body metabolism.