Project description:Objective Recent evidence indicates that the adult hematopoietic system is susceptible to diet-induced lineage skewing. It is not known whether the developing hematopoietic system is subject to metabolic programming via in utero high fat diet (HFD) exposure, an established mechanism of adult disease in several organ systems. We previously reported substantial losses in offspring liver size with prenatal HFD. As the liver is the main hematopoietic organ in the fetus, we asked whether the developmental expansion of the hematopoietic stem and progenitor cell (HSPC) pool is compromised by prenatal HFD and/or maternal obesity. Methods We used quantitative assays, progenitor colony formation, flow cytometry, transplantation, and gene expression assays with a series of dietary manipulations to test the effects of gestational high fat diet and maternal obesity on the day 14.5 fetal liver hematopoietic system. Results Maternal obesity, particularly when paired with gestational HFD, restricts physiological expansion of fetal HSPCs while promoting the opposing cell fate of differentiation. Importantly, these effects are only partially ameliorated by gestational dietary adjustments for obese dams. Competitive transplantation reveals compromised repopulation and myeloid-biased differentiation of HFD-programmed HSPCs to be a niche-dependent defect, apparent in HFD-conditioned male recipients. Fetal HSPC deficiencies coincide with perturbations in genes regulating metabolism, immune and inflammatory processes, and stress response, along with downregulation of genes critical for hematopoietic stem cell self-renewal and activation of pathways regulating cell migration. Conclusions Our data reveal a previously unrecognized susceptibility to nutritional and metabolic developmental programming in the fetal HSPC compartment, which is a partially reversible and microenvironment-dependent defect perturbing stem and progenitor cell expansion and hematopoietic lineage commitment. Examination of differentially expressed genes between gestational day 15 (+/- 0.5 days) C57BL/6 mouse fetal livers from diet-induced (60% fat diet) obese or control female mice.

Project description:Background: Maternal enviromnetal exposures during pregnancy can transplacentally train the developing fetal immune system. We have proviously shown that treatment of pregnant mice with the microbial-derived OM-85 can protect their offspring against allergic airways disease. Purpose: To characterise the cellular/molecular mechanisms underpinning this protection, focusing on the fetal bone marrow as a potential mechanistic target. Methods: Pregnant mice were orally treated with OM-85 from gestation day (GD) 9.5-17.5. Fetal bone marrow and thymus was collected from OM-85 treated and non-treated mothers at GD18.5. Cellular and molecular profiles were characterised by multi-colour flow cytometry and transcriptomics (RNA-Seq) respectively.. Molecular profiling utilised upstream regulator analysis .Protein-level validation of upstream regulator analysis results was performed by multi-colour flow cytometry. Results: Maternal OM-85 treatment induces transplacental signals that manifest in fetal bone marrow as an enriched population of conventional dendric cells (cDC) displaying enhanced functional maturation. Moreover, the myeloid progenitor populations directly upstream of this cDC pool were significantly boosted in response to maternal treatment. Transcriptomic analysis of fetal bone marrow identified maternal OM-85-induced activation of X-box binding protein 1 (XBP1), with upregulation of active XBP1 localised to cDC precursors. Conclusions: Maternal OM-85 treatment during pregnancy transplacentally accelerates functional immunocompetence of fetal bone marrow cDCs and for the first time we identify the transcription factor XBP1 as a putative driver of this immune training mechanism.

Project description:Myostatin (gene symbol: <i>Mstn</i>) is an autocrine and paracrine inhibitor of muscle growth. Pregnant mice with genetically reduced levels of myostatin give birth to offspring with greater adult muscle mass and bone biomechanical strength. However, maternal myostatin is not detectable in fetal circulations. Fetal growth is dependent on the maternal environment, and the provisioning of nutrients and growth factors by the placenta. Thus, this study examined the effect of reduced maternal myostatin on maternal and fetal serum metabolomes, as well as the placental metabolome. Fetal and maternal serum metabolomes were highly distinct, which is consistent with the role of the placenta in creating a specific fetal nutrient environment. There was no effect from myostatin on maternal glucose tolerance or fasting insulin. In comparisons between pregnant control and <i>Mstn</i>^+/- mice, there were more significantly different metabolite concentrations in fetal serum, at 50, than in the mother's serum at 33, confirming the effect of maternal myostatin reduction on the fetal metabolic milieu. Polyamines, lysophospholipids, fatty acid oxidation, and vitamin C, in fetal serum, were all affected by maternal myostatin reduction.

Project description:one-carbon metabolism in the liver plays a critical role in placental and fetal growth. Impaired functioning of one-carbon metabolism is associated with increased homocysteine (Hcy) levels. In this study, we applied a comprehensive proteomic approach to identify differential expression of proteins related to one-carbon metabolism in the livers of rat offspring as an effect of maternal food restriction during gestation. We determined that betaine-homocysteine S-methyltransferase 1 (BHMT1), methylenetetrahydrofolate dehydrogenase 1 (MTHFD1), and ATP synthase subunit beta mitochondrial (ATP5B) expression levels were significantly reduced in the livers of rat offspring exposed to maternal food restriction during gestation compared with in the offspring of rats fed a normal diet (p<0.05).

Project description:Loss of polycomb-group gene Ezh2 causes activation of fetal gene signature in adult mouse bone marrow (BM) hematopoietic stem and progenitor cells (HSPCs). Ezh2 directly represses fetal-specific let-7 target genes, including Lin28, thereby cooperates with let-7 microRNAs in silencing fetal gene signature in BM HSPCs. We purified Lineage-Sca-1+c-Kit+ (LSK) HSPCs from E14.5 FL and adult BM and subjected them to microarray analysis.

Project description:Objective Recent evidence indicates that the adult hematopoietic system is susceptible to diet-induced lineage skewing. It is not known whether the developing hematopoietic system is subject to metabolic programming via in utero high fat diet (HFD) exposure, an established mechanism of adult disease in several organ systems. We previously reported substantial losses in offspring liver size with prenatal HFD. As the liver is the main hematopoietic organ in the fetus, we asked whether the developmental expansion of the hematopoietic stem and progenitor cell (HSPC) pool is compromised by prenatal HFD and/or maternal obesity. Methods We used quantitative assays, progenitor colony formation, flow cytometry, transplantation, and gene expression assays with a series of dietary manipulations to test the effects of gestational high fat diet and maternal obesity on the day 14.5 fetal liver hematopoietic system. Results Maternal obesity, particularly when paired with gestational HFD, restricts physiological expansion of fetal HSPCs while promoting the opposing cell fate of differentiation. Importantly, these effects are only partially ameliorated by gestational dietary adjustments for obese dams. Competitive transplantation reveals compromised repopulation and myeloid-biased differentiation of HFD-programmed HSPCs to be a niche-dependent defect, apparent in HFD-conditioned male recipients. Fetal HSPC deficiencies coincide with perturbations in genes regulating metabolism, immune and inflammatory processes, and stress response, along with downregulation of genes critical for hematopoietic stem cell self-renewal and activation of pathways regulating cell migration. Conclusions Our data reveal a previously unrecognized susceptibility to nutritional and metabolic developmental programming in the fetal HSPC compartment, which is a partially reversible and microenvironment-dependent defect perturbing stem and progenitor cell expansion and hematopoietic lineage commitment.

Project description:Genes with increased H3K27ac marks in their promoters were found in mice embryonic calvaria cells using H3K27ac ChIP-Seq. Recent data suggests that in animals and humans that a maternal diet high in fat leads to poor bone growth and development in offspring. Genes with increased H3K27ac epigenetic marks normally have higher levels of expression. Understanding which genes are being upregulated in the offspring due to maternal diet would allow for better treatments to combat bone loss to be developed.

Project description:Genes with increased H3K27me3 marks in their promoters were found in mice embryonic calvaria cells using H3K27me3 ChIP-Seq. Recent data suggests that in animals and humans that a maternal diet high in fat leads to poor bone growth and development in offspring. Genes with increased H3K27me3 epigenetic marks normally have lower levels of expression. Understanding which genes are being downregulated in the offspring due to maternal diet would allow for better treatments to combat bone loss to be developed.

Project description:Genes with increased H3K27ac marks in their promoters were found in adult mice L4 vertebrae from mice using H3K27ac ChIP-Seq. Recent data suggests that in animals and humans that a maternal diet high in fat leads to poor bone growth and development in offspring. Genes with increased H3K27ac epigenetic marks normally have higher levels of expression. Understanding which genes are being upregulated due to maternal or offspring high fat diet would allow for better treatments to combat bone loss to be developed.

Project description:Loss of polycomb-group gene Ezh2 causes activation of fetal gene signature in adult mouse bone marrow (BM) hematopoietic stem and progenitor cells (HSPCs). Ezh2 directly represses fetal-specific let-7 target genes, including Lin28, thereby cooperates with let-7 microRNAs in silencing fetal gene signature in BM HSPCs.