Hostname: page-component-89b8bd64d-5bvrz Total loading time: 0 Render date: 2026-05-10T02:42:59.801Z Has data issue: false hasContentIssue false
  • English
  • Français

Induction of altered epigenetic regulation of the hepatic glucocorticoid receptor in the offspring of rats fed a protein-restricted diet during pregnancy suggests that reduced DNA methyltransferase-1 expression is involved in impaired DNA methylation and changes in histone modifications

Published online by Cambridge University Press:  01 June 2007

Karen A. Lillycrop ,
Jo L. Slater-Jefferies ,
Mark A. Hanson ,
Keith M. Godfrey ,
Alan A. Jackson  and
Graham C. Burdge
Karen A. Lillycrop
Affiliation:
Development and Cell Biology, Biomedical Sciences Building, University of Southampton, Bassett Crescent East, Southampton SO16 7PX, UK
Jo L. Slater-Jefferies
Affiliation:
Developmental Origins of Health and Disease Division, University of Southampton, Princess Anne Hospital, Coxford Road, Southampton SO16 5YA, UK
Mark A. Hanson
Affiliation:
Developmental Origins of Health and Disease Division, University of Southampton, Princess Anne Hospital, Coxford Road, Southampton SO16 5YA, UK
Keith M. Godfrey
Affiliation:
Developmental Origins of Health and Disease Division, University of Southampton, Princess Anne Hospital, Coxford Road, Southampton SO16 5YA, UK MRC Epidemiology Resource Centre, Southampton General Hospital, Tremona Road, Southampton SO16 6YD, UK
Alan A. Jackson
Affiliation:
Institute of Human Nutrition, Southampton General Hospital, Tremona Road, Southampton SO16 6YD, UK
Graham C. Burdge*
Affiliation:
Developmental Origins of Health and Disease Division, University of Southampton, Princess Anne Hospital, Coxford Road, Southampton SO16 5YA, UK
*
*Corresponding author: Dr G. C. Burdge, fax +44 (0) 23 80594379,email g.c.burdge@soton.ac.uk
Rights & Permissions [Opens in a new window]

Abstract

Prenatal nutritional constraint induces an altered metabolic phenotype in the offspring which in humans confers an increased risk of non-communicable disease. Feeding a protein-restricted (PR) diet to pregnant rats causes hypomethylation of specific gene promoters in the offspring and alters the phenotype. We investigated how altered epigenetic regulation of the hepatic glucocorticoid receptor (GR) 110 promoter is induced in the offspring. Rats were fed a control (180 g casein/kg) or a PR (90 g casein/kg) diet throughout pregnancy, and chow during lactation. Offspring were killed at postnatal day 34 (n 5 per maternal dietary group). Methylation-sensitive PCR showed that GR110 promoter methylation was 33 % lower (P < 0·001) and GR expression 84 % higher (P < 0·05) in the PR offspring. Reverse transcription–PCR showed that DNA methyltransferase-1 (Dnmt1) expression was 17 % lower (P < 0·05) in PR offspring, while Dnmt3a/b and methyl binding domain protein-2 expression was not altered. Thus hypomethylation of the GR110 promoter may result from lower capacity to methylate hemimethylated DNA during mitosis. Histone modifications which facilitate transcription were increased at the GR110 promoter (147–921 %, P < 0·001), while those that suppress methylation were decreased (54 %, P < 0·01) or similar to controls. In human umbilical cord (n 15), there was a 2-fold difference between the highest and lowest level of GR1-CTotal promoter methylation. Dnmt1, but not Dnmt3a, expression predicted 49 % (P = 0·003) of the variation in GR1-CTotal promoter methylation. These findings suggest that induction in the offspring of altered epigenetic regulation of the hepatic GR110 promoter, and hence metabolic phenotype, may be due to reduced Dnmt1 expression.

Keywords

Fetal programmingEpigeneticRatGlucocorticoid receptorHistonesHuman

Information

Type
Full Papers
Information
British Journal of Nutrition , Volume 97 , Issue 6 , June 2007 , pp. 1064 - 1073
Copyright
Copyright © The Authors 2007

There is an increasing awareness that aspects of the prenatal environment such as maternal nutrition and stress levels provide cues that alter the phenotype of the fetus without overt reductions in fetal growth (Bateson et al. Reference Bateson, Barker, Clutton-Brock, Deb, D'Udine, Foley, Gluckman, Godfrey, Kirkwood, Lahr, McNamara, Metcalfe, Monaghan, Spencer and Sultan2004). Such nutritional cues may operate within the normal range for the human population and contribute to the early origins of risk of chronic diseases such as the metabolic syndrome and CVD (Godfrey & Barker, Reference Godfrey and Barker2001). In rats, variations in phenotype can be induced by maternal undernutrition (Langley & Jackson, Reference Langley and Jackson1994; Vickers et al. Reference Vickers, Gluckman, Coveny, Hofman, Cutfield, Gertler, Breier and Harris2005) or increased intake of specific nutrients (Armitage et al. Reference Armitage, Lakasing, Taylor, Balachandran, Jensen, Dekou, Ashton, Nyengaard and Poston2005). As in humans (Ravelli et al. Reference Ravelli, van der Meulen, Michels, Osmond, Barker, Hales and Bleker1998), the phenotype which is induced is dependent upon the timing of nutrient restriction during pregnancy or lactation (Remacle et al. Reference Remacle, Bieswal and Reusens2004).

Induced changes to the phenotype which persist throughout the life span are likely to involve stable alterations to the expression of the genome. The offspring of rats fed a diet with a moderate reduction in protein content (protein-restricted (PR) diet) during pregnancy show tissue-specific alterations in the expression of transcription factors which regulate a wide range of developmental and metabolic processes, specifically the glucocorticoid receptor (GR) (Bertram et al. Reference Bertram, Trowern, Copin, Jackson and Whorwood2001; Lillycrop et al. Reference Lillycrop, Phillips, Jackson, Hanson and Burdge2005) and peroxisomal proliferator-activated receptors (PPAR) (Burdge et al. Reference Burdge, Phillips, Dunn, Jackson and Lillycrop2004; Lillycrop et al. Reference Lillycrop, Phillips, Jackson, Hanson and Burdge2005), and changes to the expression of genes associated with fatty acid metabolism (Maloney et al. Reference Maloney, Gosby, Phuyal, Denyer, Bryson and Caterson2003; Lillycrop et al. Reference Lillycrop, Phillips, Jackson, Hanson and Burdge2005) and carbohydrate homeostasis (Burns et al. Reference Burns, Desai, Cohen, Hales, Iles, Germain, Going and Bailey1997; Desai et al. Reference Desai, Byrne, Meeran, Martenz, Bloom and Hales1997). Little is known about how information about the availability of nutrients in the extra-uterine environment is transmitted to the offspring or how different phenotypes are induced.

The methylation of CpG dinucleotides clustered at the 5′ promoter regions of genes established during early life confers stable silencing of transcription and is critical for cell differentiation (Bird, Reference Bird2001). Following fertilisation, maternal and paternal genomes undergo extensive demethylation followed by de novo methylation by the activities of DNA methyltransferases (Dnmt) 3a and 3b around the time of implantation (Bird, Reference Bird2001; Reik et al. Reference Reik, Dean and Walter2001). Patterns of DNA methylation are maintained through mitosis by Dnmt1 activity (Bird, Reference Bird2001). Activities of Dnmt1 and Dnmt3a are modified by folic acid and homocysteine (James et al. Reference James, Melnyk, Pogribna, Pogribny and Caudill2002; Ghoshal et al. Reference Ghoshal, Li, Datta, Bai, Pogribny, Pogribny, Huang, Young and Jacob2006). The timing of gene silencing during early development differs between genes and tissues (Grainger et al. Reference Grainger, Hazard-Leonards, Samaha, Hougan, Lesk and Thomsen1983; Benvenisty et al. Reference Benvenisty, Mencher, Meyuhas, Razin and Reshef1985; Gidekel & Bergman, Reference Gidekel and Bergman2002; Hershko et al. Reference Hershko, Kafri, Fainsod and Razin2003). In addition, the phenotype of an embryo can be modified by manipulation of Dnmt1 expression, and hence maintenance of patterns of DNA methylation (Stancheva & Meehan, Reference Stancheva and Meehan2000; Stancheva et al. Reference Stancheva, Hensey and Meehan2001; Biniszkiewicz et al. Reference Biniszkiewicz, Gribnau, Ramsahoye, Gaudet, Eggan, Humpherys, Mastrangelo, Jun, Walter and Jaenisch2002).

DNA methylation can induce transcriptional silencing by blocking transcription factor binding and/or through the methyl CpG-binding protein (MeCP2) that binds to methylated cytosines and which, in turn, recruits the histone deacetylase–histone methyltransferase (HDAC–HMT) complex to the DNA (Fuks et al. Reference Fuks, Hurd, Wolf, Nan, Bird and Kouzarides2003). Covalent modifications to histones, such as acetylation and methylation of specific lysine residues in the N-terminal regions of histones, influence chromatin structure and hence the ability of the basal transcriptional machinery to gain access to the DNA (Strahl et al. Reference Strahl, Ohba, Cook and Allis1999; Turner, Reference Turner2000; Lachner et al. Reference Lachner, O'Carroll, Rea, Mechtler and Jenuwein2001; Litt et al. Reference Litt, Simpson, Gaszner, Allis and Felsenfeld2001; Nakayama et al. Reference Nakayama, Rice, Strahl, Allis and Grewal2001; Zegerman et al. Reference Zegerman, Canas, Pappin and Kouzarides2002).

Since epigenetic regulation of gene promoters which is established during development and is retained throughout the life span of the organism confers patterns of transcriptional expression and silencing, perturbations to such processes represent one possible molecular mechanism for induction of an altered phenotype. Feeding a PR diet to rats during pregnancy induces hypomethylation and increased expression of the GR and PPARα promoters in the liver of the adult offspring (Lillycrop et al. Reference Lillycrop, Phillips, Jackson, Hanson and Burdge2005), but was prevented by supplementation of the PR diet with folic acid. Supplementation of the PR diet with glycine or folic acid prevented induction of an altered phenotype (Jackson et al. Reference Jackson, Dunn, Marchand and Langley-Evans2002; Torrens et al. Reference Torrens, Brawley, Anthony, Dance, Dunn, Jackson, Poston and Hanson2006). Thus 1-carbon metabolism is central to the induction of an altered phenotype in this model, which is consistent with the transient increase in plasma homocysteine, a marker of impaired 1-carbon metabolism, in early pregnancy when rats were fed a PR diet (Petrie et al. Reference Petrie, Duthie, Rees and McConnell2002).

We have tested the hypothesis that the transmission to the fetus of information regarding maternal nutrition and induction of altered DNA methylation involves modulation of Dnmt action. We investigated the effect of altered maternal protein intake during pregnancy on the epigenetic regulation of the hepatic GR promoter in the adult offspring. Specifically, we determined the effect of feeding a PR diet to pregnant rats on the methylation status and the level of histone modification at the hepatic GR promoter. In order to determine the mechanism which modifies the epigenetic regulation of the GR promoter, we investigated whether prenatal undernutrition alters the expression of enzymes that catalyse DNA methylation de novo, methylation of hemimethylated DNA or active demethylation of DNA. As a result of our findings, we also investigated the relationship between the expression of Dnmt and the methylation of the GR promoter that is expressed in human umbilical cord (UC).

Materials and methods

Animal procedures

Virgin Wistar rats (n 5 per dietary group) were fed isocaloric diets containing either 180 g/kg casein and 1 mg/kg folic acid (control) or 90 g/kg casein and 1 mg/kg folic acid (PR). In some experiments, livers from the offspring of rats fed 90 g/kg casein and 5 mg/kg folic acid were studied (Lillycrop et al. Reference Lillycrop, Phillips, Jackson, Hanson and Burdge2005) (Table 1). Dams were fed standard chow (AIN 76A) from delivery (Lillycrop et al. Reference Lillycrop, Phillips, Jackson, Hanson and Burdge2005). Litters were reduced to eight at birth, equal numbers of males and females, and offspring were weaned onto standard chow (AIN 76A) at 28 d and were killed 6 d later. Livers were excised immediately, frozen in liquid nitrogen and stored at − 80°C. One liver from each litter was selected for analysis, male to female ratio 3:2. All animal procedures were conducted in accordance with the UK Home Office Animals (Scientific Procedures) Act (1986).

Table 1

Composition of the diets fed during pregnancy, lactation and after weaning

* Vitamin mix: thiamine hydrochloride 2·4 mg/kg; riboflavin 2·4 mg/kg; pyridoxine hydrochloride 2·8 mg/kg; nicotinic acid 12·0 mg/kg; d-calcium pantothenate 6·4 mg/kg; biotin 0·01 mg/kg; cyanocobalamin 0·003 mg/kg; retinyl palmitate 6·4 mg/kg; dl-α-tocopherol acetate 79·9 mg/kg; cholecalciferol 1·0 g/kg; menaquinone 0·02 mg/kg.

Mineral mix: calcium phosphate dibasic 11·3 g/kg; sodium chloride 1·7 g/kg; potassium citrate monohydrate 5·0 g/kg; potassium sulphate 1·2 g/kg; magnesium sulphate 0·5 g/kg; magnesium carbonate 0·1 g/kg; ferric citrate 0·1 g/kg; zinc carbonate 36·2 mg/kg; cupric carbonate 6·8 mg/kg; potassium iodate 0·2 mg/kg; sodium selenite 0·2 mg/kg; chromium potassium sulphate 12·5 mg/kg.

Measurement of DNA methylation of the GR110 promoter in rat

DNA methylation was carried out essentially as described (Lillycrop et al. Reference Lillycrop, Phillips, Jackson, Hanson and Burdge2005). Genomic DNA (5 mg) isolated from the livers of rats (n 5 per maternal dietary group) was incubated with the methylation-sensitive restriction endonucleases AciI and HpaII, as instructed by the manufacturer (New England Biolabs, Hitchin, Hertfordshire, UK). The resulting DNA was amplified using real-time PCR, which was performed in a total volume of 25 ml with SYBR® Green Jumpstart Ready Mix (Sigma, Poole, Dorset, UK) as described by the manufacturer. Cycle parameters were 55°C for 5 min, 95°C for 10 min, then 40 cycles of 95°C for 30 s, 60°C for 1 min and 72°C for 1 min. Single bands of the correct size were verified by gel electrophoresis. Primers were designed to amplify the CpG island spanning the GR110 promoter used in rat liver (McCormick et al. Reference McCormick, Lyons, Jacobson, Noble, Diorio, Nyirenda, Weaver, Ester, Yau, Meaney, Seckl and Chapman2000). Primer sequences are listed in Table 2. The promoter region from the rat PPARγ2 promoter which does not contain AciI or HpaII cleavage sites was used as an internal control (Lillycrop et al. Reference Lillycrop, Phillips, Jackson, Hanson and Burdge2005). All Ct values were normalised to the internal control and each sample analysed in duplicate.

Table 2

PCR primers for analysis of mRNA expression and promoter methylation

GR110, glucocorticoid receptor 110 promoter; hPPARα, human peroxisomal proliferator-activated receptor-α; hGR1-CTotal, human GR1-CTotal promoter; Dnmt1, DNA methyltransferase-1; Dnmt3a, DNA methyltransferase-3a; Dnmt3b, DNA methyltransferase-3b; MeCP2; methyl CpG-binding protein-2; MDB2; methyl binding domain protein-2.

Measurement of mRNA expression in rat

Total RNA was isolated from liver (n 5 per maternal dietary group) samples using Tri® Reagent (Sigma) according to the manufacturer's instructions. cDNA was prepared as described (Lillycrop et al. Reference Lillycrop, Phillips, Jackson, Hanson and Burdge2005) and amplified using real-time PCR (Harris et al. Reference Harris, White, Phillips and Lillycrop2002) which was performed in a total volume of 25 ml with SYBR® Green Jumpstart Ready Mix (Sigma) as described by the manufacturer. PCR primers are listed in Table 2. Samples were analysed in duplicate, and the expression of GR110 promoter transcript, Dnmt1, Dnmt3a, Dnmt3b, MeCP2 and methyl binding domain protein-2 (MBD-2) was normalised to the housekeeping gene cyclophilin (Bustin, Reference Bustin2000). Dnmt1, 3a and 3b were measured using primer kits from QIAGEN Ltd UK (Crawley, Sussex, UK). Cycle parameters were 55°C for 5 min, 95°C for 10 min, then 40 cycles of 95°C for 30 s, 60°C (cyclophilin, phoephoenolpyruvate carboxykinase (PEPCK), Dnmt1, Dnmt 3a, Dnmt3b, MeCP2 and MBD2) or 65°C (GR) for 1 min and 72°C for 1 min. Single bands of the correct size were verified by gel electrophoresis (data not shown).

Measurement of histone acetylation and methylation at the GR promoter in rat

Histone modification, and MeCP2 and Dnmt1 binding at the GR110 promoter was analysed by chromatin immunoprecipitation (ChIP) assay (Boyd & Farnham, Reference Boyd and Farnham1999). A 100 mg aliquot of liver tissue (n 5 per maternal dietary group, one per litter) was ground in liquid nitrogen and fixed with formaldehyde (1 % (v/v)) for 10 min. The chromatin was sonicated to yield DNA fragments of 100–400 bp in length. The sonicated chromatin was quantified on the basis of DNA content at A 260 nm. The chromatin equivalent of 40 μg of DNA was used in each immunoprecipitation. The sonicated supernatant was diluted 10-fold in ChIP dilution buffer (0·01 % (w/v) SDS, 1·1 % (v/v) Triton X-100, 1·2 mm-EDTA, 16·7 mm-NaCl, 20 mm-Tris–HCl pH 8·1) and pre-cleared with salmon sperm DNA–protein A agarose (50 % (w/v) slurry). Pre-cleared chromatin was then incubated overnight with 2 mg of antibody at 4°C. Anti-β-galactosidase (c-20) antibodies were obtained from Santa Cruz Biotechnology Inc. (Santa Cruz, CA, USA). Anti-acetyl histone H3 (06–599), anti-acetyl H4 (06–866), di-methylated H3K4 (07–030), di-methylated H3K9 (07–441) were from Upstate Biotechnology (Dundee, UK) and tri-methylated H3K9 (ab8898), Dnmt1 (ab5208) and MeCP2 (ab3752) were from Abcam (Cambridge, UK). The immunocomplexes were collected by the addition of salmon sperm DNA–protein A agarose slurry, washed with 0·1 % (w/v) SDS, 1 % (v/v) Triton X-100, 2 mm-EDTA, Tris–HCl pH 8·1, 150 mm-NaCl, Tris–HCl pH 8·1 and then with 0·1 % (w/v) SDS, 1 % (v/v) Triton X-100, 2 mm-EDTA, 500 mm-NaCl, 20 mm-Tris–HCl pH 8·1 followed by 0·25 m-LiCl, 1 % (v/v) NP-40, 1 % (w/v) sodium deoxycholate, 1 mm-EDTA, 10 mm-Tris–HCl pH 8·1 and twice with 10 mm-Tris–HCl pH 7·5, 1 mm-EDTA). DNA was eluted by the addition of a solution of 1 % (w/v) SDS and 0·1 m-NaHCO3, the cross-links reversed, and the DNA purified. The ChIP-precipitated DNA and the input DNA were subjected to real-time PCR using SYBR® Green Jumpstart Ready Mix (Sigma). The PCR primers used for the GR110 promoter were 5′-CGTCTTGTTCCACCCACT-3′ and 5′-CCTTGCAGTTGCCGACAG. All values were normalised with respect to the input DNA and expressed as a percentage of the control group. To demonstrate the specificity of the immunoprecipitation reactions, an antibody directed against β-galactosidase and a negative antibody control were used in each experiment (data not shown).

Human umbilical cord samples

These studies utilised samples of UC from a stratified random sample of fifteen term infants in the Birthright Fetal Growth Rates Study. This study of nutrition during pregnancy and fetal growth recruited Caucasian women with singleton pregnancies and known menstrual dates who registered in early pregnancy with participating obstetricians at the Princess Anne Maternity Hospital, Southampton UK (Godfrey et al. Reference Godfrey, Walker-Bone, Robinson, Taylor, Shore, Wheeler and Cooper2001). Samples were stored at − 80°C. Birthweights of the infants were in the normal range (range 2665–4430 g, mean 3426 g). Collection and analysis of human UC samples was carried out with written informed consent from all subjects and under IRB approval from the Southampton and South West Hampshire Joint Research Ethics Committee.

DNA methyltransferase mRNA expression in human umbilical cord

Total RNA was isolated from human UC using Tri® Reagent (Sigma, Poole, Dorset, UK) according to the manufacturer's instructions. cDNA was prepared as described (Lillycrop et al. Reference Lillycrop, Phillips, Jackson, Hanson and Burdge2005) and amplified using real-time reverse transcription–PCR (RT–PCR), which was performed in a total volume of 25 ml with SYBR® Green Jumpstart Ready Mix (Sigma) as described by the manufacturer. Human Dnmt1 shows 80 % identity to rat Dnmt1, and human Dnmt3a shows 91 % identity to rat Dnmt3a. There was 100 % identity between rat and human Dnmt1 and between rat and human Dnmt3a within the primer sequences. Therefore, we used the same RT–PCR primers to measure Dnmt1 and Dnmt3a expression in human UC and rat liver. PCR primers are listed in Table 2. Samples were analysed in duplicate and the expression of Dnmt1 and Dnmt3a was normalised to the housekeeping gene cyclophilin (Bustin, Reference Bustin2000). Cycle parameters were 94°C for 2 min, then 40 cycles of 95°C for 30 s, 60°C (cyclophilin and Dnmt1) or 62°C (Dnmt3a) for 1 min and 72°C for 1 min.

Measurement of DNA methylation of the GR1-CTotal promoter in human umbilical cord

To confirm that the GR1-CTotal promoter is expressed in human UC, total RNA was isolated from UC and human blood using Tri® Reagent (Sigma) as described by the manufacturers. The size of the GR1-CTotal promoter RT–PCR transcript from UC on agarose gel electrophoresis was compared with the blood reference transcript (Turner & Muller, Reference Turner and Muller2005) (Fig. 2A). PCR primers are listed in Table 2. Cycle parameters were 94°C for 2 min, then 40 cycles of 95°C for 30 s, 62°C for 1 min and 72°C for 1 min.

For analysis of GR1-CTotal promoter methylation, genomic DNA (400 ng) was incubated with the methylation-sensitive restriction endonucleases AciI and HpaII as instructed by the manufacturer (New England Biolabs, Hitchin, Hertfordshire, UK). The resulting DNA was amplified using real-time PCR, which was performed in a total volume of 25 ml with SYBR® Green Jumpstart Ready Mix (Sigma) according to the manufacturer's instructions. A fragment of the human PPARα exon 7 which does not contain AciI or HpaII cleavage sites was used as an internal control gene. Primers were designed to amplify the CpG island spanning the GR1-CTotal promoter (Turner & Muller, Reference Turner and Muller2005). Primer sequences are listed in Table 2. Cycle parameters were 94°C for 2 min, then 40 cycles of 95°C for 30 s, 59·3°C (GR1-CTotal) or 66°C (PPARα) for 1 min and 72°C for 1 min. All Ct values were normalised to the internal control and each sample analysed in duplicate. Single bands of the correct size were verified by gel electrophoresis (not shown).

Statistical analysis

Data are presented as mean (SEM). Statistical comparisons were by Student's unpaired t test or one-way ANOVA with Bonferroni's post hoc analysis as indicated in the text. The relationship between DNA methylation and gene expression in human UC was determined by calculation of Pearson's correlation coefficient.

Results

GR promoter methylation, and expression of GR and PEPCK in rat liver

Hepatic GR110 promoter methylation was 33 % lower (Table 3) at postnatal day 34 in the offspring of dams fed a PR diet compared with offspring of the control group. Hypomethylation of the GR110 promoter was associated with higher mRNA expression of GR110 (84 %). The expression of the GR target gene PEPCK was also increased by 16 % in the offspring of the PR group (Table 3).

Table 3

Glucocorticoid receptor promoter methylation, and glucocorticoid receptor and phosphoenolpyruvate carboxykinase mRNA expression in the liver of day 34 offspring (Mean values with their standard errors of the mean)

PR, protein-restricted; GR110, glucocorticoid receptor 110 promoter; PEPCK, phosphoenolpyruvate carboxykinase.

Values are the results of RT–PCR analysis for n 5 samples/maternal dietary group. Statistical comparison was by Student's unpaired t test.

MeCP2 expression in rat liver

Having shown GR hypomethylation in PR offspring, we then investigated whether the expression and recruitment of MeCP2 to the GR110 promoter was also altered in response to maternal diet. MeCP2 mRNA expression was 29 % lower in the liver of the PR offspring versus controls (Table 4). Binding of MeCP2 to the GR promoter in the liver of control and PR offspring was assessed using a ChIP assay. Binding of MeCP2 to the GR110 promoter was reduced by 43 % (P < 0·05) in PR offspring compared with control offspring (Table 4). No signal was obtained when chromatin was precipitated with an anti-β-galactosidase antibody or with a negative antibody control. This demonstrates that the immunoprecipitation reactions were specific.

Table 4

MeCP2 mRNA expression, binding of MeCP2 and histone modifications at the glucocorticoid receptor promoter (Mean values with their standard error of the mean)

MeCP2, methyl CpG-binding protein; PR, protein-restricted.

Values are for n 5 samples/maternal dietary group. Statistical comparison was by Student's unpaired t test. Expression of MeCP2 and binding of MeCP2 at the glucocorticoid receptor 110 (GR110) promoter in liver from 34-day-old offspring of rats fed either a control or PR diet during pregnancy. Binding of MeCP2 and the extent of histone modifications at the GR110 promoter were determined by chromatin immunoprecipitation assay.

Analysis of histone modifications at the hepatic GR110 promoter in rats

In order to determine whether the hypomethylation of the GR110 promoter, and reduced expression and binding of MeCP2 were associated with altered covalent modifications of histones bound to the GR promoter, ChIP assays were used to measure the acetylation and methylation of specific histone lysine residues at the GR110 promoter. The level of histone modifications which facilitate transcription was higher at the hepatic GR110 promoter in the PR versus control offspring, namely acetylation of H3K9 (174 %) and H4K9 (302 %), and methylation of H3K4 (925 %) (all P < 0·001) (Table 4). Di-methylation and tri-methylation of H3K9, which are associated with suppression of transcription, were 54 % lower (P < 0·01) or not statistically significantly different, respectively, in the PR offspring versus controls at the GR110 promoter (Table 4).

Analysis of the expression of genes which regulate DNA methylation in the liver of rats

There are three possible mechanisms underlying hypomethylation of the GR110 promoter: (1) impaired methylation de novo by Dnmt 3a and 3b; (2) failure to maintain CpG methylation through mitosis by Dnmt1; or (3) active demethylation by the putative DNA demethylase MBD2 (Detich et al. Reference Detich, Theberge and Szyf2002). To examine which of these mechanisms may be responsible for the hypomethylation of GR, the expression of Dnmt1, Dnmt3a/b and the demethylase MBD2 was measured using real-time RT–PCR. Expression of Dnmt1 mRNA was 17 % lower (P < 0·05) in PR versus control offspring (Fig. 1A). There were no significant differences between PR and control offspring in the expression of Dnmt 3a and 3b, or MBD2 (Fig. 1B–D). ChIP assays using an anti-Dnmt1 antibody showed that binding of Dnmt1 at the GR110 promoter was significantly lower (12 %, P < 0·05) in the PR offspring compared with controls (Fig. 1E).

Fig. 1

mRNA expression of DNA methyltransferases (Dnmt) in liver from 34-day-old offspring of rats fed either a control or protein-restricted (PR) diet, or the PR diet supplemented with folic acid (PRF) during pregnancy. Data from RT–PCR analysis are means (with sem) relative to the control group (n 5 per maternal dietary group). (A) Dnmt1 expression. (B) Dnmt3a expression. (C) Dnmt3b expression. Statistical comparisons were by one-way ANOVA with Bonferroni's post hoc analysis. One-way ANOVA showed a significant difference (P < 0·05) between groups for Dnmt1, but not for the other DNA methyltransferases. *P < 0·05 compared with the control group. (D) Expression of the methyl binding domain protein-2 from 34-day-old offspring of rats fed either a control or PR diet. Data are means (with sem) relative to the control group (n 5 per maternal dietary group). Statistical analysis was by Student's unpaired t test. (E) Binding of Dnmt1 at the glucocorticoid receptor 110 promoter in liver from 34-day-old offspring of rats fed either a control or PR diet measured by chromatin immunoprecipitation assay. Data are means (with sem) relative to the control group (n 5 per maternal dietary group). Statistical analysis was by Student's unpaired t test. *P < 0·05 compared with the control group.

Since 1-carbon metabolism appears to be involved centrally for the induction of an altered phenotype by variations in maternal protein intake during pregnancy (Petrie et al. Reference Petrie, Duthie, Rees and McConnell2002; Torrens et al. 2006), and hypomethylation of the hepatic GR is prevented by supplementation of the PR diet with folic acid (Lillycrop et al. Reference Lillycrop, Phillips, Jackson, Hanson and Burdge2005), we next investigated the effect of supplementation of the PR diet with 5-fold more folic acid than was present in the control or PR diet. Supplementing the PR diet with folic acid prevented reduced Dnmt1 expression compared with the control group (Fig. 1A), but did not alter Dnmt 3a or 3b expression (Fig. 1B, C).

Analysis of GR promoter methylation and Dnmt1 expression in human umbilical cord

Since Dnmt1 mRNA expression appeared to be related to the level of methylation of the hepatic GR promoter, we investigated whether Dnmt1 expression was also related to the level of GR methylation in fetal human tissue. The human GR1-CTotal promoter, like the rat GR110 promoter, contains a CpG island which spans the 5′-untranslated region of the gene and which contains eleven different heterogeneous non-coding first exons (Turner & Muller, Reference Turner and Muller2005). In the human fetal UC samples, we examined the methylation status of the GR1-CTotal promoter, which shows 70·6 % homology with the rat GR110 promoter (Turner & Muller, Reference Turner and Muller2005). We showed that transcripts from the GR1-CTotal promoter are expressed in human UC (Fig. 2A). Using a methylation-sensitive restriction enzyme PCR assay, we found that there was variation in the level of methylation of the GR1-Ctotal promoter between human fetal cord samples such that the highest level of methylation was approximately 2-fold greater than the lowest (Fig. 2D).

Fig. 2

Methylation status and mRNA expression of glucocorticoid receptor (GR) 1-CTotal promoter and mRNA expression of DNA methyltransferase (Dnmt)-1 and Dnmt3a in human umbilical cord (UC). (A) Expression of the transcript of the GR1-CTotal in human UC by real-time RT–PCR using adult human blood as reference. The same primers were used to detect (B) Dnmt1 and (C) Dnmt3a in human (H) UC as used with rat (R) liver. Transcripts of the appropriate size were identified by analysis of the RT–PCR products by agarose gel electrophoresis. The methylation status of the GR1-CTotal promoter and the mRNA expression of Dnmt1 and Dnmt3a were measured in human UC samples from fifteen pregnancies. The association between GR1-CTotal promoter methylation and Dnmt expression was analysed by calculation of Pearson's correlation coefficient. (D) The relationship between Dnmt1 expression and GR1-CTotal promoter methylation, r = 0·70, P = 0·03. (E) The relationship between Dnmt3a expression and GR1-CTotal promoter methylation, r = 0·001, P = 0·89).

Single bands of the correct size for the PCR products of the Dnmt1 and Dnmt3a primers in human and rat tissue were verified by gel electrophoresis (Fig. 2B, C). Dnmt1 expression predicted 49 % (P = 0·003) of the variation in GR1-CTotal methylation (Fig. 2D), while Dnmt3a expression was not related to GR1-CTotal methylation (Fig. 2E).

Discussion

The results of this study show for the first time that hypomethylation and increased expression of the GR110 promoter induced in the liver of the offspring of rats fed a PR diet during pregnancy are associated with reduced Dnmt1 expression and altered covalent modifications to histones at the GR promoter.

Feeding a PR diet to pregnant rats increases hepatic gluconeogenesis in the adult offspring (Burns et al. Reference Burns, Desai, Cohen, Hales, Iles, Germain, Going and Bailey1997; Desai et al. Reference Desai, Byrne, Meeran, Martenz, Bloom and Hales1997), which reflects increased expression of hepatic GR and PEPCK expression (Bertram et al. Reference Bertram, Trowern, Copin, Jackson and Whorwood2001, Lillycrop et al. Reference Lillycrop, Phillips, Jackson, Hanson and Burdge2005). This is consistent with increased corticosteroid activity in the offspring of rats fed a PR diet during pregnancy (Langley-Evans et al. Reference Langley-Evans, Gardner and Jackson1996). Our current and previous findings (Lillycrop et al. Reference Lillycrop, Phillips, Jackson, Hanson and Burdge2005) show that increased hepatic GR expression in the PR offspring is associated with hypomethylation of the GR110 promoter. The livers of these rats also show hypomethylation of the PPARα promoter and increased expression of its target gene acyl-CoA oxidase (Lillycrop et al. Reference Lillycrop, Phillips, Jackson, Hanson and Burdge2005). Together, these findings suggest that feeding a PR diet during pregnancy induces in the liver of the offspring a metabolic phenotype characterised by altered regulation of energy balance, with increased capacity for gluconeogenesis and peroxisomal fatty acid β-oxidation. Moreover, since promoter methylation status may be modified at different stages of development in a gene- and tissue-specific manner (Grainger et al. Reference Grainger, Hazard-Leonards, Samaha, Hougan, Lesk and Thomsen1983; Benvenisty et al. Reference Benvenisty, Mencher, Meyuhas, Razin and Reshef1985; Gidekel & Bergman, Reference Gidekel and Bergman2002; Hershko et al. Reference Hershko, Kafri, Fainsod and Razin2003), this suggests a mechanism by which timing of nutritional constraint may influence the induced phenotype (Ravelli et al. Reference Ravelli, van der Meulen, Michels, Osmond, Barker, Hales and Bleker1998; Remacle et al. Reference Remacle, Bieswal and Reusens2004).

The stable silencing of genes by DNA methylation is critical for cellular differentiation (Bird, Reference Bird2001; Hershko et al. Reference Hershko, Kafri, Fainsod and Razin2003) and for the developmental regulation of the activities of metabolic pathways (Grainger et al. Reference Grainger, Hazard-Leonards, Samaha, Hougan, Lesk and Thomsen1983; Benvenisty et al. Reference Benvenisty, Mencher, Meyuhas, Razin and Reshef1985). Induction of hypomethylation of the hepatic GR promoter in the PR offspring may occur by either impaired methylation de novo during cell differentiation in the early embryo, failure to maintain DNA methylation during mitosis or active demethylation. Failure to maintain methylation or active demethylation may result in the activation of genes not normally expressed in adult tissues, or accelerated or more extensive demethylation of genes that are induced during tissue maturation. Our findings show that, while the expression of Dnmt3a and 3b and the demethylase MDB2 was not altered, Dnmt1 expression was significantly lower in the liver of the PR offspring compared with controls. Thus hypomethylation of the GR110 promoter, and in turn altered regulation of hepatic glucose metabolism, may be induced by reduced capacity to methylate hemimethylated DNA during mitosis rather than failure of DNA methylation de novo or active demethylation. This conclusion is supported by lower binding of Dnmt1 at the GR110 promoter in the PR offspring. These findings agree with those showing induction of DNA hypomethylation and altered phenotype by depletion of xDnmt1 in Xenopus embryos (Stancheva & Meehan, Reference Stancheva and Meehan2000; Stancheva et al. Reference Stancheva, Hensey and Meehan2001) and promoter demethylation by Dnmt1 knockdown (Leu et al. Reference Leu, Rahmatpanah, Shi, Wei, Liu, Yan and Huang2003).

Altered 1-carbon metabolism plays a central role in phenotype induction in this model (Jackson et al. Reference Jackson, Dunn, Marchand and Langley-Evans2002; Petrie et al. Reference Petrie, Duthie, Rees and McConnell2002; Lillycrop et al. Reference Lillycrop, Phillips, Jackson, Hanson and Burdge2005; Torrens et al. Reference Torrens, Brawley, Anthony, Dance, Dunn, Jackson, Poston and Hanson2006). Our findings show that lowering of Dnmt1 expression by the PR diet was prevented by maternal folic acid supplementation, while expression of Dnmt3a was unaltered. Hence Dnmt1 expression in the offspring is modified by maternal folic acid intake, which is consistent with the modulation of Dnmt1 expression in adult rats by folic acid intake (Ghoshal et al. Reference Ghoshal, Li, Datta, Bai, Pogribny, Pogribny, Huang, Young and Jacob2006) and the inhibition of Dnmt1 and induction of DNA hypomethylation by hyperhomocysteinaemia (James et al. Reference James, Melnyk, Pogribna, Pogribny and Caudill2002). Thus, the effects of differences in maternal folic acid intake, and in turn capacity for metabolism of methyl groups, during pregnancy could explain the induction or prevention of GR110 hypomethylation in the liver of the offspring. These findings also emphasise the importance of adequate dietary intake of folic acid during pregnancy for optimal fetal development.

One possible mechanism for induction of an altered metabolic phenotype in the liver of the offspring of rats fed a PR diet during pregnancy is impairment of 1-carbon metabolism leading to down-regulation of Dnmt1 expression and progressive loss of methyl groups from the GR110 promoter. Reduced expression of Dnmt1 may be expected to result in decreased methylation of all promoters containing CpG dinucleotides. However, studies in cells lacking Dnmt1 show only a 20 % decrease in genomic methylation and no changes to the methylation status of specific genes (Rhee et al. Reference Rhee, Jair, Yen, Lengauer, Herman, Kinzler, Vogelstein, Baylin and Schuebel2000). This suggests that Dnmt1 activity is targeted to specific genes, possibly through binding to transcription factors such as E2F1 (Robertson et al. Reference Robertson, Ait-Si-Ali, Yokochi, Wade, Jones and Wolffe2000). Thus because binding of Dnmt1 to the GR promoter was reduced in addition to an overall reduction in Dnmt1 expression, the proposed pathway is consistent with gene-specific hypomethylation in the liver in the offspring of dams fed a PR diet (Lillycrop et al. Reference Lillycrop, Phillips, Jackson, Hanson and Burdge2005). Dnmt1 activity is also required for progression through mitosis (Milutinovic et al. Reference Milutinovic, Zhuang, Niveleau and Szyf2003). Thus it is possible that suppression of Dnmt1 activity or expression by altered 1-carbon metabolism in the pre-implantation period could also account for the reduction in cell number during the early development in this model (Kwong et al. Reference Kwong, Wild, Roberts, Willis and Fleming2000).

The specific link between reduced protein intake and altered 1-carbon metabolism cannot be deduced from the present data. However, we offer two possible explanations. First, it is possible that it may result from decreased availability of glycine, leading to altered flux of methyl groups between different metabolic fates. Secondly, increased maternal corticosteroid activity (Langley-Evans et al. Reference Langley-Evans, Gardner and Jackson1996), possibly as a result of stress induced by constrained nutrient availability, may reduce folic acid availability (Terzolo et al. Reference Terzolo, Allasino, Bosio, Brusa, Daffara, Ventura, Aroasio, Sacchetto, Reimondo, Angeli and Camaschella2004). The second mechanism could explain how maternal corticosteroid blockade prevents induction of hypertension in the PR offspring (Langley-Evans et al. 1997) as well as prevention of altered phenotype by folic acid administration (Lillycrop et al. Reference Lillycrop, Phillips, Jackson, Hanson and Burdge2005; Torrens et al. Reference Torrens, Brawley, Anthony, Dance, Dunn, Jackson, Poston and Hanson2006).

Analysis of GR1-CTotal in human UC samples showed for the first time that among individuals within the normal birthweight range, there is considerable variation in the methylation status of a gene expressed in human fetal tissue. Dnmt1 expression predicted 49 % of the variation in methylation of the GR1-CTotal promoter expressed in human UC. Because the UC were frozen, we were unable to dissect and measure Dnmt1 expression and GR1-CTotal methylation in specific tissues. However, these data suggest that methylation of the GR1-CTotal promoter in human UC is associated with the capacity of Dnmt1 to maintain methylation of CpG dinucleotides rather than the capacity for DNA methylation de novo. The extent to which maternal diet during pregnancy determines Dnmt1 expression cannot be examined within this small group of infants. However, these findings are consistent with our observations in the rat and so suggest the hypothesis that induction of different phenotypes in humans by prenatal nutrition may involve variations in Dnmt1 expression and, in turn, DNA methylation.

Covalent modifications of specific residues in the N-terminal domain of histones also confer epigenetic regulation of transcription (Turner, Reference Turner2000). Such modifications are closely linked to promoter methylation as methylated CpG nucleotides are required for binding of MeCP2 and recruitment of the HDAC–HMT complex. Binding of MeCP2–HDAC–HMT to methylated CpGs causes histone deacetylation and methylation of specific lysine resides, leading to suppression of transcription. We found higher levels of histone modifications which facilitate transcription, while modifications that suppress transcription were reduced, at the GR110 promoter in the offspring of rats fed the PR diet compared with controls. One possible explanation is that hypomethylation of the GR110 promoter reduced binding of MeCP2 and, in turn, the HDAC–HMT complex. If so, this suggests that lower Dnmt1 expression is the primary process in inducing increased GR110 expression, and altered histone modifications are a secondary effect. This may be exacerbated by lower hepatic MeCP2 expression in these offspring. Such changes to the regulation of transcription of the GR110 promoter are consistent with the higher level of transcription in the PR offspring.

We therefore propose a mechanism for the induction of an altered metabolic phenotype in the offspring of rats fed a PR diet during pregnancy based upon our findings for the GR110 promoter (Fig. 3). Promoter methylation is induced in a gene-specific manner during the development of the early embryo by the activities of Dnmt 3a and 3b. Impaired 1-carbon metabolism, either as a direct result of constrained maternal nutrition or by increased corticosteroid activity, reduces Dnmt1 expression, resulting in progressive hypomethylation of specific genes during successive mitotic cycles. The hypomethylated GR110 promoter would result in the reduced binding of the MeCP2–HDAC–HMT complex which facilitates persistence of histone modifications that permit transcription. In turn, gluconeogenesis increases due to upregulation of PEPCK expression by the action of the GR. The pathway may also explain hypomethylation of PPARα and increased expression of acyl-CoA oxidase in the liver of the PR offspring (Lillycrop et al. Reference Lillycrop, Phillips, Jackson, Hanson and Burdge2005). If this pathway acts primarily by altering the epigenetic regulation of specific transcription factors, then changes in the activities of a number of metabolic pathways may be induced. However, the proposed pathway does not exclude the possibility that other genes may also be hypomethylated by this process. This pathway also explains how administration of glucocorticoids during pregnancy induces persistent changes to gluconeogenic enzymes in the offspring as a result of increasing GR expression (Nyirenda et al. Reference Nyirenda, Lindsay, Kenyon, Burchell and Seckl1998).

Fig. 3

A diagram of the proposed pathway for induction of altered glucose homeostasis in the offspring of rats fed a protein-restricted (PR) diet during pregnancy. A full explanation is given in the text. (a) Glucocorticoid receptor (GR) expression is silenced in the early embryo in cells destined to become hepatocytes by the activities of DNA methyltransferases (Dnmt) 3a and 3b. (b) In the offspring of rats fed a PR diet, 1-carbon metabolism is impaired either as a direct consequence of the restricted diet or by increased glucocorticoid exposure. This downregulates Dnmt1 expression (c). Lower Dnmt1 expression results in a impaired capacity to methylate hemimethylated DNA during mitosis (d). After sequential mitotic cycles, this results in hypomethylation of the GR promoter and loss of epigenetic memory of gene silencing, such that, in the liver of the adult offspring, expression of GR is induced in cells which do not express GR in control animals. The increased expression of GR is facilitated by lower binding and expression of methyl CpG-binding protein (MeCP)-2 and reduced recruitment of the histone deactylase (HDAC)–histone methyltransferase (HMT) complex, resulting in higher levels of histone modifications which permit transcription. (e) This results in increased phosphoenolpyruvate carboxykinase (PEPCK) expression and increased gluconeogenesis.

In conclusion, the present findings suggest a pathway for induction of an altered phenotype or fetal programming. In humans, this may provide a basis for interventions in early life to reduce risk of later metabolic disease.

Acknowledgements

G. C. B. and M. A. H. are supported by the British Heart Foundation. Collection of human umbilical cord specimens was supported by the Medical Research Council.

References

Armitage, JA, Lakasing, L, Taylor, PD, Balachandran, AA, Jensen, RI, Dekou, V, Ashton, N, Nyengaard, JR & Poston, L (2005) Developmental programming of aortic and renal structure in offspring of rats fed fat-rich diets in pregnancy. J Physiol. 565, 171184.Google Scholar
Bateson, P, Barker, D, Clutton-Brock, T, Deb, D, D'Udine, B, Foley, RA, Gluckman, P, Godfrey, K, Kirkwood, T, Lahr, MM, McNamara, J, Metcalfe, NB, Monaghan, P, Spencer, HG & Sultan, SE (2004) Developmental plasticity and human health. Nature 430, 419421.CrossRefGoogle ScholarPubMed
Benvenisty, N, Mencher, D, Meyuhas, O, Razin, A & Reshef, L (1985) Sequential changes in DNA methylation patterns of the rat phosphoenolpyruvate carboxykinase gene during development. Proc Natl Acad Sci USA 82, 267271.CrossRefGoogle ScholarPubMed
Bertram, C, Trowern, AR, Copin, N, Jackson, AA & Whorwood, CB (2001) The maternal diet during pregnancy programs altered expression of the glucocorticoid receptor and type 2 11beta-hydroxysteroid dehydrogenase: potential molecular mechanisms underlying the programming of hypertension in utero. Endocrinology 142, 28412853.CrossRefGoogle ScholarPubMed
Bird, A (2001) DNA methylation patterns and epigenetic memory. Genes Dev 16, 621.Google Scholar
Biniszkiewicz, D, Gribnau, J, Ramsahoye, B, Gaudet, F, Eggan, K, Humpherys, D, Mastrangelo, MA, Jun, Z, Walter, J & Jaenisch, R (2002) Dnmt1 overexpression causes genomic hypermethylation, loss of imprinting, and embryonic lethality. Mol Cell Biol 22, 21242135.CrossRefGoogle ScholarPubMed
Boyd, KE & Farnham, P (1999) Coexamination of site-specific transcription factor binding and promoter activity in living cells. Mol Cell Biol 19, 83938399.CrossRefGoogle ScholarPubMed
Burdge, GC, Phillips, ES, Dunn, RL, Jackson, AA & Lillycrop, KA (2004) Effect of reduced maternal protein consumption during pregnancy in the rat on plasma lipid concentrations and expression of peroxisomal proliferator-activated receptors in the liver and adipose tissue of the offspring. Nutr Res 24, 639646.Google Scholar
Burns, SP, Desai, M, Cohen, RD, Hales, CN, Iles, RA, Germain, JP, Going, TC & Bailey, RA (1997) Gluconeogenesis, glucose handling, and structural changes in livers of the adult offspring of rats partially deprived of protein during pregnancy and lactation. J Clin Invest 100, 17681774.Google Scholar
Bustin, SA (2000) Absolute quantification of mRNA using real-time reverse transcription polymerase chain reaction assays. J Mol Endocrinol 25, 169193.CrossRefGoogle ScholarPubMed
Desai, M, Byrne, CD, Meeran, K, Martenz, ND, Bloom, SR & Hales, CN (1997) Regulation of hepatic enzymes and insulin levels in offspring of rat dams fed a reduced-protein diet. Am J Physiol 273, G899G904.Google ScholarPubMed
Detich, N, Theberge, J & Szyf, M (2002) Promoter-specific activation and demethylation by MBD2/demethylase. J Biol Chem 277, 3579135794.CrossRefGoogle ScholarPubMed
Fuks, F, Hurd, PJ, Wolf, D, Nan, X, Bird, AP & Kouzarides, T (2003) The methyl-CpG-binding protein MeCP2 links DNA methylation to histone methylation. J Biol Chem 278, 40354040.CrossRefGoogle ScholarPubMed
Ghoshal, K, Li, X, Datta, J, Bai, S, Pogribny, I, Pogribny, M, Huang, Y, Young, D & Jacob, ST (2006) A folate- and methyl-deficient diet alters the expression of DNA methyltransferases and methyl CpG binding proteins involved in epigenetic gene silencing in livers of F344 rats. J Nutr 136, 15221527.CrossRefGoogle ScholarPubMed
Gidekel, S & Bergman, Y (2002) A unique developmental pattern of Oct-3/4 DNA methylation is controlled by a cis-demodification element. J Biol Chem 277, 3452134530.CrossRefGoogle ScholarPubMed
Godfrey, KM & Barker, DJ (2001) Fetal programming and adult health. Public Health Nutr 4, 611624.CrossRefGoogle ScholarPubMed
Godfrey, K, Walker-Bone, K, Robinson, S, Taylor, P, Shore, S, Wheeler, T & Cooper, C (2001) Neonatal bone mass: influence of parental birthweight, maternal smoking, body composition, and activity during pregnancy. J Bone Min Res 16, 16941703.CrossRefGoogle ScholarPubMed
Grainger, RM, Hazard-Leonards, RM, Samaha, F, Hougan, LM, Lesk, MR & Thomsen, GH (1983) Is hypomethylation linked to activation of delta-crystallin genes during lens development? Nature 306, 8891.CrossRefGoogle ScholarPubMed
Harris, RG, White, E, Phillips, ES & Lillycrop, KA (2002) The expression of the developmentally regulated proto-oncogene Pax-3 is modulated by N-Myc. J Biol Chem 277, 3481534825.Google Scholar
Hershko, AY, Kafri, T, Fainsod, A & Razin, A (2003) Methylation of HoxA5 and HoxB5 and its relevance to expression during mouse development. Gene 302, 6572.CrossRefGoogle ScholarPubMed
Jackson, AA, Dunn, RL, Marchand, MC & Langley-Evans, SC (2002) Increased systolic blood pressure in rats induced by a maternal low-protein diet is reversed by dietary supplementation with glycine. Clin Sci (Lond) 103, 633639.CrossRefGoogle ScholarPubMed
James, SJ, Melnyk, S, Pogribna, M, Pogribny, IP & Caudill, MA (2002) Elevation in S-adenosylhomocysteine and DNA hypomethylation: potential epigenetic mechanism for homocysteine-related pathology. J Nutr 132, Suppl, 2361S2366S.CrossRefGoogle ScholarPubMed
Kwong, WY, Wild, AE, Roberts, P, Willis, AC & Fleming, TP (2000) Maternal undernutrition during the preimplantation period of rat development causes blastocyst abnormalities and programming of postnatal hypertension. Development 127, 41954202.CrossRefGoogle ScholarPubMed
Lachner, M, O'Carroll, D, Rea, S, Mechtler, K & Jenuwein, T (2001) Methylation of histone H3 lysine 9 creates a binding site for HP1 proteins. Nature 410, 116120.Google Scholar
Langley, SC & Jackson, AA (1994) Increased systolic blood pressure in adult rats induced by fetal exposure to maternal low protein diets. Clin Sci (Lond) 86, 217222.CrossRefGoogle ScholarPubMed
Langley-Evans, SC (1997) Hypertension induced by fetal exposure to a maternal low-protein diet, in the rat, is prevented by pharmacological blockade of maternal glucocorticoid synthesis. J Hypertens 15, 537544.CrossRefGoogle ScholarPubMed
Langley-Evans, SC, Gardner, DS & Jackson, AA (1996) Maternal protein restriction influences the programming of the rat hypothalamic-pituitary-adrenal axis. J Nutr 126, 15781585.CrossRefGoogle ScholarPubMed
Leu, YW, Rahmatpanah, F, Shi, H, Wei, SH, Liu, JC, Yan, PS & Huang, TH (2003) Double RNA interference of DNMT3b and DNMT1 enhances DNA demethylation and gene reactivation. Cancer Res 63, 61106115.Google ScholarPubMed
Lillycrop, KA, Phillips, ES, Jackson, AA, Hanson, MA & Burdge, GC (2005) Dietary protein restriction of pregnant rats induces and folic acid supplementation prevents epigenetic modification of hepatic gene expression in the offspring. J Nutr 135, 13821386.CrossRefGoogle ScholarPubMed
Litt, MD, Simpson, M, Gaszner, M, Allis, CD & Felsenfeld, G (2001) Correlation between histone lysine methylation and developmental changes at the chicken beta-globin locus. Science 293, 24532455.Google Scholar
Maloney, CA, Gosby, AK, Phuyal, JL, Denyer, GS, Bryson, JM & Caterson, ID (2003) Site-specific changes in the expression of fat-partitioning genes in weanling rats exposed to a low-protein diet in utero. Obes Res 11, 461468.Google Scholar
McCormick, JA, Lyons, V, Jacobson, MD, Noble, J, Diorio, J, Nyirenda, M, Weaver, S, Ester, W, Yau, JL, Meaney, MJ, Seckl, JR & Chapman, KE (2000) 5′-Heterogeneity of glucocorticoid receptor messenger RNA is tissue specific: differential regulation of variant transcripts by early-life events. Mol Endocrinol 14, 506517.Google Scholar
Milutinovic, S, Zhuang, Q, Niveleau, A & Szyf, M (2003) Epigenomic stress response. Knockdown of DNA methyltransferase 1 triggers an intra-S-phase arrest of DNA replication and induction of stress response genes. J Biol Chem 278, 1498514995.CrossRefGoogle ScholarPubMed
Nakayama, J, Rice, JC, Strahl, BD, Allis, CD & Grewal, SI (2001) Role of histone H3 lysine 9 methylation in epigenetic control of heterochromatin assembly. Science 292, 110113.CrossRefGoogle ScholarPubMed
Nyirenda, MJ, Lindsay, RS, Kenyon, CJ, Burchell, A & Seckl, JR (1998) Glucocorticoid exposure in late gestation permanently programs rat hepatic phosphoenolpyruvate carboxykinase and glucocorticoid receptor expression and causes glucose intolerance in adult offspring. J Clin Invest 101, 21742181.CrossRefGoogle ScholarPubMed
Petrie, L, Duthie, SJ, Rees, WD & McConnell, JM (2002) Serum concentrations of homocysteine are elevated during early pregnancy in rodent models of fetal programming. Br J Nutr 88, 471477.Google Scholar
Ravelli, AC, van der Meulen, JH, Michels, RP, Osmond, C, Barker, DJ, Hales, CN & Bleker, OP (1998) Glucose tolerance in adults after prenatal exposure to famine. Lancet 351, 173177.CrossRefGoogle ScholarPubMed
Reik, W, Dean, W & Walter, J (2001) Epigenetic reprogramming in mammalian development. Science 293, 10891093.CrossRefGoogle ScholarPubMed
Remacle, C, Bieswal, F & Reusens, B (2004) Programming of obesity and cardiovascular disease. Int J Obes Relat Metab Disord 28, Suppl 3, S46S53.CrossRefGoogle ScholarPubMed
Rhee, I, Jair, KW, Yen, RW, Lengauer, C, Herman, JG, Kinzler, KW, Vogelstein, B, Baylin, SB & Schuebel, KE (2000) CpG methylation is maintained in human cancer cells lacking DNMT1. Nature 404, 10031007.CrossRefGoogle ScholarPubMed
Robertson, KD, Ait-Si-Ali, S, Yokochi, T, Wade, PA, Jones, PL & Wolffe, AP (2000) Dnmt1 forms a complex with Rb, E2F1 and HDAC1 and represses transcription from E2F-responsive promoters. Nat Genet 25, 338342.Google Scholar
Stancheva, I, Hensey, C & Meehan, RR (2001) Loss of the maintenance methyltransferase, xDnmt1, induces apoptosis in Xenopus embryos. EMBO J 20, 19631973.CrossRefGoogle ScholarPubMed
Stancheva, I & Meehan, RR (2000) Transient depletion of xDnmt1 leads to premature gene activation in Xenopus embryos. Genes Dev 14, 313327.CrossRefGoogle ScholarPubMed
Strahl, BD, Ohba, R, Cook, RG & Allis, CD (1999) Methylation of histone H3 at lysine 4 is highly conserved and correlates with transcriptionally active nuclei in Tetrahymena. Proc Natl Acad Sci USA 96, 1496714972.CrossRefGoogle ScholarPubMed
Terzolo, M, Allasino, B, Bosio, S, Brusa, E, Daffara, F, Ventura, M, Aroasio, E, Sacchetto, G, Reimondo, G, Angeli, A & Camaschella, C (2004) Hyperhomocysteinemia in patients with Cushing's syndrome. J Clin Endocrinol Metab 89, 37453751.Google Scholar
Torrens, C, Brawley, L, Anthony, FW, Dance, CS, Dunn, R, Jackson, AA, Poston, L & Hanson, MA (2006) Folate supplementation during pregnancy improves offspring cardiovascular dysfunction induced by protein restriction. Hypertension 47, 982987.CrossRefGoogle ScholarPubMed
Turner, BM (2000) Histone acetylation and an epigenetic code. Bioessays 22, 836845.3.0.CO;2-X>CrossRefGoogle Scholar
Turner, JD & Muller, CP (2005) Structure of the glucocorticoid receptor (NR3C1) gene 5′ untranslated region: identification, and tissue distribution of multiple new human exon 1. J Mol Endocrinol 35, 283292.CrossRefGoogle ScholarPubMed
Vickers, MH, Gluckman, PD, Coveny, AH, Hofman, PL, Cutfield, WS, Gertler, A, Breier, BH & Harris, M (2005) Neonatal leptin treatment reverses developmental programming. Endocrinology 146, 42114216.Google Scholar
Zegerman, P, Canas, B, Pappin, D & Kouzarides, T (2002) Histone H3 lysine 4 methylation disrupts binding of nucleosome remodeling and deacetylase (NuRD) repressor complex. J Biol Chem 277, 1162111624.CrossRefGoogle ScholarPubMed
Figure 0

Table 1 Composition of the diets fed during pregnancy, lactation and after weaning

Figure 1

Table 2 PCR primers for analysis of mRNA expression and promoter methylation

Figure 2

Table 3 Glucocorticoid receptor promoter methylation, and glucocorticoid receptor and phosphoenolpyruvate carboxykinase mRNA expression in the liver of day 34 offspring (Mean values with their standard errors of the mean)

Figure 3

Table 4 MeCP2 mRNA expression, binding of MeCP2 and histone modifications at the glucocorticoid receptor promoter (Mean values with their standard error of the mean)

Figure 4

Fig. 1 mRNA expression of DNA methyltransferases (Dnmt) in liver from 34-day-old offspring of rats fed either a control or protein-restricted (PR) diet, or the PR diet supplemented with folic acid (PRF) during pregnancy. Data from RT–PCR analysis are means (with sem) relative to the control group (n 5 per maternal dietary group). (A) Dnmt1 expression. (B) Dnmt3a expression. (C) Dnmt3b expression. Statistical comparisons were by one-way ANOVA with Bonferroni's post hoc analysis. One-way ANOVA showed a significant difference (P < 0·05) between groups for Dnmt1, but not for the other DNA methyltransferases. *P < 0·05 compared with the control group. (D) Expression of the methyl binding domain protein-2 from 34-day-old offspring of rats fed either a control or PR diet. Data are means (with sem) relative to the control group (n 5 per maternal dietary group). Statistical analysis was by Student's unpaired t test. (E) Binding of Dnmt1 at the glucocorticoid receptor 110 promoter in liver from 34-day-old offspring of rats fed either a control or PR diet measured by chromatin immunoprecipitation assay. Data are means (with sem) relative to the control group (n 5 per maternal dietary group). Statistical analysis was by Student's unpaired t test. *P < 0·05 compared with the control group.

Figure 5

Fig. 2 Methylation status and mRNA expression of glucocorticoid receptor (GR) 1-CTotal promoter and mRNA expression of DNA methyltransferase (Dnmt)-1 and Dnmt3a in human umbilical cord (UC). (A) Expression of the transcript of the GR1-CTotal in human UC by real-time RT–PCR using adult human blood as reference. The same primers were used to detect (B) Dnmt1 and (C) Dnmt3a in human (H) UC as used with rat (R) liver. Transcripts of the appropriate size were identified by analysis of the RT–PCR products by agarose gel electrophoresis. The methylation status of the GR1-CTotal promoter and the mRNA expression of Dnmt1 and Dnmt3a were measured in human UC samples from fifteen pregnancies. The association between GR1-CTotal promoter methylation and Dnmt expression was analysed by calculation of Pearson's correlation coefficient. (D) The relationship between Dnmt1 expression and GR1-CTotal promoter methylation, r = 0·70, P = 0·03. (E) The relationship between Dnmt3a expression and GR1-CTotal promoter methylation, r = 0·001, P = 0·89).

Figure 6

Fig. 3 A diagram of the proposed pathway for induction of altered glucose homeostasis in the offspring of rats fed a protein-restricted (PR) diet during pregnancy. A full explanation is given in the text. (a) Glucocorticoid receptor (GR) expression is silenced in the early embryo in cells destined to become hepatocytes by the activities of DNA methyltransferases (Dnmt) 3a and 3b. (b) In the offspring of rats fed a PR diet, 1-carbon metabolism is impaired either as a direct consequence of the restricted diet or by increased glucocorticoid exposure. This downregulates Dnmt1 expression (c). Lower Dnmt1 expression results in a impaired capacity to methylate hemimethylated DNA during mitosis (d). After sequential mitotic cycles, this results in hypomethylation of the GR promoter and loss of epigenetic memory of gene silencing, such that, in the liver of the adult offspring, expression of GR is induced in cells which do not express GR in control animals. The increased expression of GR is facilitated by lower binding and expression of methyl CpG-binding protein (MeCP)-2 and reduced recruitment of the histone deactylase (HDAC)–histone methyltransferase (HMT) complex, resulting in higher levels of histone modifications which permit transcription. (e) This results in increased phosphoenolpyruvate carboxykinase (PEPCK) expression and increased gluconeogenesis.