Project description:Intrauterine hyperglycemia has been linked to an elevated risk of diabetes in next and further generations. Existing reports about transmission effects of intrauterine hyperglycemia have included both intrauterine and postnatal metabolic exposure factors, the impact of intrauterine hyperglycemia per se has not been separately assessed. To investigate effect of intrauterine hyperglycemia exposure per se on further generations, we selected non-phenotypic F1-GDM and F2-GDM male mice to examin metabolic changes in next generation and performed a methylome on day 13.5 primordial germ cells (PGCs) of F1-GDM male fetus to explore its underlying mechanism. We found that intrauterine hyperglycemia exposure per se resulted in obesity, insulin resistance and/or glucose intolerance in F2 male mice, and no changes in F3 male mice. Methylome of day 13.5 PGCs of F1-GDM male fetus revealed differently methylation genes enriched in obesity and diabetic pathogenesis. Methylation validation of targeted gene Fyn showed consistent hypo-methylation status in F1 PGCs, F1 fetal testis, sperm of F1/N-GDM mice, and somatic cells of F2-GDM male mice. While fetal testis of F2-GDM mice showed no alteration in Fyn methylation. Our data indicates that intrauterine hyperglycemia exposure per se contributes to metabolic changes in F2 but not F3 generation, by altering methylation erasure in PGCs of F1 generation.

Project description:Birth cohort studies and experimental investigations in animals link gestational diabetes mellitus (GDM) with impaired cognitive performance in the first filial generation (F1). We found that intrauterine hyperglycemia exposure resulted in behavior abnormality and cognitional functional disorder of both F1- and F2-GDM male mice. Methylome of sperm of F1 adult male mice from control pregnant mice (F1-C) and GDM pregnant mice (F1-GDM) revealed differentially methylated genes enriched in neurodevelopmental process.

Project description:The pre and postnatal environment can affect both an individual’s risk of adult onset metabolic disease and that of subsequent generations. Although animal models and epidemiological data implicate epigenetic inheritance, little is known of the mechanisms involved. In a robust intergenerational model of developmental programming we demonstrate that the nutritional environment experienced in utero by F1 generation embryos alters the DNA methylome of the F1 adult male germ line in a locus-specific manner, without affecting overall methylation levels. Differentially methylated regions are mostly hypomethylated and are enriched in nucleosome retaining regions in adult sperm. A substantial fraction is resistant to early embryo methylation reprogramming, and thus have the potential to alter F2 generation development. Altered expression of transcripts neighbouring differentially methylated regions are evident in tissues of F2 offspring despite lack of persistence of differential methylation. Transmitted methylation variation in the germline at key regulatory loci may therefore contribute to the development of metabolic disease in the subsequent generation. 2 biological replicates of pooled sperm samples for each control (C) or undernutrition (UN) model

Project description:The pre and postnatal environment can affect both an individual’s risk of adult onset metabolic disease and that of subsequent generations. Although animal models and epidemiological data implicate epigenetic inheritance, little is known of the mechanisms involved. In a robust intergenerational model of developmental programming we demonstrate that the nutritional environment experienced in utero by F1 generation embryos alters the DNA methylome of the F1 adult male germ line in a locus-specific manner, without affecting overall methylation levels. Differentially methylated regions are mostly hypomethylated and are enriched in nucleosome retaining regions in adult sperm. A substantial fraction is resistant to early embryo methylation reprogramming, and thus have the potential to alter F2 generation development. Altered expression of transcripts neighbouring differentially methylated regions are evident in tissues of F2 offspring despite lack of persistence of differential methylation. Transmitted methylation variation in the germline at key regulatory loci may therefore contribute to the development of metabolic disease in the subsequent generation.

Project description:To understand the initiation of DNA methylation and its effects on gene expression, we performed high-throughput sequencing of DNA methylomes of F1 hybrids that were mutant for two genes, Mop1 (mediator of paramutation1) and Lbl1 (leafbladeless1), and their wild type F1 siblings as well as their parents. We first compared the methylation between the two parents (B73 and Mo17), and identified the differentially methylated regions (DMRs) between them. Next, we examined the methylation changes in wilde type F1 (WTF1) and mutant F1 (mop1F1 and lbl1F1) at these parental DMRs. Furthermore, to determine whether the methylation changes in the F1 through hybridization can me maintained to the next generation, we investigated the methylation levels of these DMRs in the BC1 generation.

Project description:We investigated whether exposure to a captive environment during maturation influenced gamete DNA methylation for wild Atlantic Salmon individuals. We then investigated whether these parental effects were detectable in an F1 generation reared in a common environment. We associated DNA methylation with growth and fitness-related phenotypes and demonstrated that intergenerational effects of hatchery exposure during maturation of the parental generation influence fitness-related methylation patterns in the F1 generation.

Project description:Gestating F0 generational female rats were transiently exposed to DDT during fetal gonadal sex determination and the incidence of adult onset pathologies was assessed in the subsequent F1, F2, and F3 generations. In addition, sperm differential DNA methylation regions (DMRs) that were associated with specific pathologies in the F3 generation males were investigated. No pathology was observed in the F1 generation DDT lineage males or females compared with F1 generation controls (vehicle exposure). There was an increase of testis disease and early onset puberty in the F2 generation DDT lineage males. The F3 generation DDT males had significant increases in testis disease, prostate disease, and late onset puberty. The F3 generation DDT females had significant increases in ovarian and kidney disease. Both the F3 generation males and females had significant increases in the frequency of obesity and multiple disease. The F3 generation sperm was collected to examine DMRs for the ancestrally exposed DDT male population. Unique sets of DMRs were associated with late onset puberty, kidney disease, and multiple disease pathologies.

Project description:5, 10-Methylenetetrahydrofolate reductase (MTHFR) is a crucial enzyme in the folate metabolic pathway with a key role in generating methyl groups. As MTHFR deficiency impacts male fertility and sperm DNA methylation, there is the potential for epimutations to be passed to the next generation. Here, we assessed whether the impact of MTHFR deficiency on testis morphology and sperm DNA methylation is exacerbated across generations. While MTHFR deficiency in F1 fathers has only minor effects on sperm counts and testis weights and histology, F2 generation sons show further deterioration in reproductive parameters. Extensive loss of DNA methylation is observed in both F1 and F2 sperm, with >80% of sites shared between generations, suggestive of regions consistently susceptible to MTHFR deficiency. These regions are generally methylated during late prenatal germ cell development and are enriched in young retrotransposons. As retrotransposons are resistant to reprogramming of DNA methylation in prenatal germ cells, their hypomethylated state in the sperm of F1 males could contribute to the worsening reproductive phenotype observed in F2 MTHFR- deficient males, findings compatible with the intergenerational passage of epimutations.

Project description:Increasing evidence has demonstrated that epigenetic factors can profoundly influence gene expression and, in turn, influence resistance or susceptibility to disease. Epigenetic drugs, such as histone deacetylase (HDAC) inhibitors, are finding their way into clinical practice, although their exact mechanisms of action are unclear. To identify mechanisms associated with HDAC inhibition, we performed microarray analysis on brain and muscle samples treated with the HDAC1/3-targeting inhibitor, HDACi 4b. Pathways analyses of microarray datasets implicate DNA methylation as significantly associated with HDAC inhibition. Further assessment of DNA methylation changes elicited by HDACi 4b in human fibroblasts from normal controls and patients with Huntington's disease (HD) using the Infinium HumanMethylation450 BeadChip revealed a limited, but overlapping, subset of methylated CpG sites that were altered by HDAC inhibition in both normal and HD cells. Among the altered loci of Y chromosome-linked genes, KDM5D, which encodes Lys (K)-specific demethylase 5D, showed increased methylation at several CpG sites in both normal and HD cells, as well as in DNA isolated from sperm from drug-treated male mice. Further, we demonstrate that first filial generation (F1) offspring from drug-treated male HD transgenic mice show significantly improved HD disease phenotypes compared with F1 offspring from vehicle-treated male HD transgenic mice, in association with increased Kdm5d expression, and decreased histone H3 Lys4 (K4) (H3K4) methylation in the CNS of male offspring. Additionally, we show that overexpression of Kdm5d in mutant HD striatal cells significantly improves metabolic deficits. These findings indicate that HDAC inhibitors can elicit transgenerational effects, via cross-talk between different epigenetic mechanisms, to have an impact on disease phenotypes in a beneficial manner. Bisulphite converted DNA from the 12 samples were hybridised to the Illumina Infinium 27k Human Methylation Beadchip v1.2. We demonstrate that histone deacetylase (HDAC) inhibition can elicit changes in DNA methylation in Huntington’s disease (HD) human fibroblasts, as well as in sperm from HD transgenic mice, in association with DNA methylation-related gene expression changes. We suggest that alterations in sperm DNA methylation lead to transgenerational effects, and, accordingly, we show that first filial generation (F1) offspring of HDAC inhibitor-treated male HD transgenic mice show improved HD disease phenotypes compared with F1 offspring from vehicle-treated male HD transgenic mice. These findings have significant implications for human health because they enforce the concept that ancestral drug exposure may be a major molecular factor that can affect disease phenotypes, yet in a positive manner. Further, we implicate Lys (K)-specific demethylase 5d expression in this phenomenon.

Project description:We examined whether paternal diet from weaning to puberty induces sperm DNA methylation changes that can be transmitted to subsequent generations. Over 100 methylated cytosines environmentally altered in the F0 generation were inherited by the F1 and F2 generations. Furthermore, the F0 paternal diet was associated with growth and male fertility phenotypes in these generations. Differentially methylated genes also showed correlations with gene expression.