Project description:Maternal exposure to particulate air pollution increases the incidence and severity of asthma in offspring, yet the mechanisms for this are unclear. Known susceptibility loci are a minor component of this effect. We interrogate a mouse allergic airway disease model to assess epigenetic associations between maternal air pollution exposure and asthma-like responses in offspring. Maternal air pollution exposure increased allergic airway disease severity in adult offspring associated with a suppressed transcriptomic response to allergen. Control progeny showed differential expression of 2842 genes across several important pathways, including the SMAD and TGFβR pathways, whilst air pollutant progeny showed an 80% reduction in differentially expressed genes and abrogation of many pathway associations. Whole genome CpG methylome analysis following allergen challenge detected differential methylation regions across the genome. Approximately 20% of differentially expressed genes were associated with differential methylation. Differentially methylated regions were markedly reduced in offspring of air pollution exposed mothers, and this was most evident in intronic regions and some transposable element classes. This study shows that allergic airways disease in adult offspring of PM2.5 exposed mothers had a markedly repressed transcriptomic response, a proportion of which was associated with identifiable changes in the lung’s methylome. The results point to an epigenetic contribution to the severity of asthma in offspring of mothers exposed to particulate air pollution.

Project description:RATIONALE: In a mouse model of maternal transmission of asthma risk (J. Immunol 170:1683, 2003), baby mice of asthmatic (As), but not normal (Nrm), mothers show increased susceptibility to allergy. We previously showed that adoptive transfer to normal baby mice of dendritic cells (DCs) harvested from asthma-susceptible but allergen-naïve neonates reproduces the increased susceptibility to asthma. Hence, the maternal effect is mediated by altered neonatal DCs, which skew immune responses towards a pro-allergic Th2 phenotype. To identify potential molecular mechanisms, we performed epigenomic profiling of isolated neonatal DCs. METHODS: BALB/c mice were sensitized by 2 i.p. injections of ovalbumin (OVA) in alum and repeatedly challenged with OVA aerosols (As) prior to mating with normal males. Purified splenic CD11c+ DCs of 14-day old allergen-naïve offspring from these As and control Nrm mothers were isolated using magnetic beads. Methylation profiles of genomic DNA were obtained using Switchgear epigenomic chip arrays. After normalization and background correction analysis using significance analysis for microarrays (SAM) and ANOVA was performed. RESULTS: We identified 300 to 6000 (depending on stringency) chromosomal regions with significantly different methylation status, (2 – 10 fold). Clustering methods and pathway analysis identified several interrelated gene groups that merit further study. CONCLUSION: Maternal asthma causes multiple significant epigenetic changes in neonatal dendritic cells. Keywords: Dendritic cells, genomic DNA, DNA methylation, allergy, asthma The analysis includes 9 samples of genomic DNA from isolated splenic CD11c+ dendritic cells (>95% pure) per group. The two groups are neonates born to mothers with induced allergy to ovalbumin, and normal control neonates. All neonates are genetically and environmentally identical, and allergen-naive.

Project description:This study aims to demonstrate the link between epigenome-wide methylation aberrations at birth and genomic transcriptional changes upon allergen sensitization that occur in the neonatal dendritic cells (DC) due to maternal asthma. In an in vivo model reproducing human epidemiology findings, maternal but not paternal asthma predisposes the neonate to increased asthma risk, the effect is allergen-independent and is not genetic or environmental. Earlier we demonstrated that neonates of asthmatic mothers are born with a functional skew in splenic DCs that mediates the early-life asthma origin. These allergen-naive cells convey allergy responses to normal recipients, however minimal to no transcriptional or phenotypic changes were found to explain the functional pro-allergic alterations. In this study we profiled both allergen-naïve dendritic cells, and cells after allergen sensitization in vivo. We found that while allergen-naive DCs from asthma-at-risk neonates have minimal transcriptional change compared to controls, upon allergen sensitization, multiple genes with pre-existing epigenetic alterations show significant transcriptional change. . 24 samples from 2 batches, 3-4 replicates in each of 4 groups

Project description:This study aims to demonstrate the link between epigenome-wide methylation aberrations at birth and genomic transcriptional changes upon allergen sensitization that occur in the neonatal dendritic cells (DC) due to maternal asthma. In an in vivo model reproducing human epidemiology findings, maternal but not paternal asthma predisposes the neonate to increased asthma risk, the effect is allergen-independent and is not genetic or environmental. Earlier we demonstrated that neonates of asthmatic mothers are born with a functional skew in splenic DCs that mediates the early-life asthma origin. These allergen-naive cells convey allergy responses to normal recipients, however minimal to no transcriptional or phenotypic changes were found to explain the functional pro-allergic alterations. In this study we profiled both allergen-naïve dendritic cells, and cells after allergen sensitization in vivo. We found that while allergen-naive DCs from asthma-at-risk neonates have minimal transcriptional change compared to controls, upon allergen sensitization, multiple genes with pre-existing epigenetic alterations show significant transcriptional change. .

Project description:RATIONALE: In a mouse model of maternal transmission of asthma risk (J. Immunol 170:1683, 2003), baby mice of asthmatic (As), but not normal (Nrm), mothers show increased susceptibility to allergy. We previously showed that adoptive transfer to normal baby mice of dendritic cells (DCs) harvested from asthma-susceptible but allergen-naïve neonates reproduces the increased susceptibility to asthma. Hence, the maternal effect is mediated by altered neonatal DCs, which skew immune responses towards a pro-allergic Th2 phenotype. To identify potential molecular mechanisms, we performed epigenomic profiling of isolated neonatal DCs. METHODS: BALB/c mice were sensitized by 2 i.p. injections of ovalbumin (OVA) in alum and repeatedly challenged with OVA aerosols (As) prior to mating with normal males. Purified splenic CD11c+ DCs of 14-day old allergen-naïve offspring from these As and control Nrm mothers were isolated using magnetic beads. Methylation profiles of genomic DNA were obtained using Switchgear epigenomic chip arrays. After normalization and background correction analysis using significance analysis for microarrays (SAM) and ANOVA was performed. RESULTS: We identified 300 to 6000 (depending on stringency) chromosomal regions with significantly different methylation status, (2 – 10 fold). Clustering methods and pathway analysis identified several interrelated gene groups that merit further study. CONCLUSION: Maternal asthma causes multiple significant epigenetic changes in neonatal dendritic cells. Keywords: Dendritic cells, genomic DNA, DNA methylation, allergy, asthma

Project description:Rationale: DNA methylation plays a critical role in asthma development, but differences in DNA methylation associated with asthma severity, especially among adults, are less well-defined. Changes in DNA methylation are influenced by exposure to air pollution, which is a risk factor for asthma exacerbation and severity. Here, we examined how DNA methylomic patterns in adult asthmatics differ by asthma severity and exposure to different components of air pollution. Methods: Peripheral blood CD3+ T cells from adult asthmatics in Beijing, China were serially collected from 37 patients (130 samples total) and analyzed for global DNA methylation using the Illumina MethylationEPIC Array. Measurements and Main Results: Significant differences in DNA methylation were noted among subjects with different degrees of asthma severity, as measured by fraction of exhaled nitric oxide, forced expiratory volume, and asthma control test scores. Differences in DNA methylation were annotated to genes that were enriched in pathways related to asthma or T cell function, and included gene ontology categories related to cellular adhesion, developmental pathways, and calcium signaling. Notable genes that were differentially methylated based on asthma severity included RUNX3, several members of the HLA family, PDGFRA, CDH1, CAV1, and NOTCH4. Differences in DNA methylation also varied by exposure to ambient air pollution, with different components of pollution effecting methylation of different groups of genes. Conclusion: These findings demonstrate how adult asthmatics possess widespread differences in the DNA methylation that associated with varying asthma severity and how air pollution might contribute to more severe asthma via changes in DNA methylation.

Project description:Background: Asthma is highly heterogeneous and severity evaluation is key to asthma management. DNA methylation (DNAm) contributes to asthma pathogenesis. This study aimed to identify nasal epithelial DNAm differences between severe and non-severe asthmatic children and evaluate the impact of environmental exposures. Methods: Thirty-three non-severe and 22 severe asthmatic African-American children were included in an epigenome-wide association study. Genome-wide nasal epithelial DNAm and gene expression were measured. CpG sites associated with asthma severity and environmental exposures and predictive of severe asthma were identified. DNAm was correlated with gene expression. Enrichment for transcription factor (TF) binding sites or histone modifications surrounding DNAm differences were determined. Results: We identified 816 differentially methylated CpG positions (DMPs) and 10 differentially methylated regions (DMRs) associated with asthma severity. Three DMPs exhibited discriminatory ability for severe asthma. Intriguingly, six DMPs were simultaneously associated with asthma, allergic asthma, total IgE, environmental IgE, and FeNO in an independent cohort of children. 27 DMPs were associated with traffic-related air pollution or secondhand smoke. DNAm at 22 DMPs were altered by diesel particles or allergen in human bronchial epithelial cells. DNAm levels at 39 DMPs were correlated with mRNA expression. Proximal to 816 DMPs, three histone marks and several TFs involved in asthma pathogenesis were enriched. Conclusions: Significant differences in nasal epithelial DNAm were observed between non-severe and severe asthma in African-American children, a subset of which may be useful to predict disease severity. These CpG sites are subject to the influences of environmental exposures and may regulate gene expression.

Project description:Rationale: Maternal immune responses can promote allergy development in offspring. Pilot data show that neonates of mother mice exposed during pregnancy to air pollution particles have increased allergic susceptibility. Objective: We investigated whether inflammatory response to titanium dioxide (TiO2) particles earlier considered immunologically ‘inert’ is enhanced during pregnancy. Methods: Pregnant BALB/c mice (or non-pregnant controls) received particle suspensions intranasally at day 14 of pregnancy. Lung inflammatory responses were evaluated 19 and 48 h after exposure. Results: Pregnant mice showed robust and persistent acute inflammatory responses after exposure to TiO2, while non-pregnant females had the expected minimal responses. Genomic profiling identified genes differentially expressed in pregnant lungs exposed to TiO2. Neonates of mothers exposed to TiO2 (but not PBS) developed increased susceptibility to allergens. Conclusion: Pregnancy enhances lung inflammatory responses to otherwise relatively innocuous inert particles. Keywords: Particles exposure, pregnancy vs normal

Project description:We reported the gene expression profile of T47D cells treated with the organic extract of Particulate matter 2.5 (PM2.5) sampled next to the municipal solid waste incineration plant of Bologna city. Based on a air pollution distribution model that takes the incinaration plant as point source of emission, two sites were chosen to sample particulate matter near incineration plant: "FrulloEst" representing the maximum effect of the incineration plant, "Calamosco" representing the negative control of "FrulloEst" (minimun effect of incineration plant, same effect of other air pollution fonts). Another site, "Giardini Margherita", is chosen to sample the urban background air pollution. for each site sample collection was performed in winter and in summer season.

Project description:We used a mouse model of allergic lung disease to examine the effects of pre- and perinatal house dust mite (HDM) allergen exposure on offspring lung phenotypic and transcriptional outcomes. We showed that maternal HDM exposure (F0) acts synergistically with adult HDM exposure, leading to enhanced airway hyperresponsiveness (AHR) and lung inflammation when compared to mice exposed solely in adulthood. To examine the role of epigenetic inheritance of asthma susceptibility induced by maternal HDM exposure, we utilized a genome-wide MeDIP-seq and hMeDIP-seq analysis to identify genes differentially methylated (DMG) and hydroxymethylated (DHG), and their association with the enhanced AHR. In addition, we validated the relationship between DNA methylation and mRNA expression of the DMGs and DHGs in the male progenies.