Project description:Bacterial pulmonary infections are a major cause of morbidity and mortality in neonates, with less severity in older children (juveniles). Previous studies demonstrated that CD4+ T cells in the mouse lung, whose primary responsibility is coordinating the immune response foreign pathogens, are differentially methylated in neonates compared with juveniles. Nevertheless, the effect of this differential methylation on CD4+ T cell gene expression and response to infection remains unclear. We treated E. coli-infected neonatal (4-day-old) and juvenile (13-day-old) mice with decitabine (DAC), a DNA methyltransferase inhibitor with broad-spectrum DNA demethylating activity, and performed simultaneous genome-wide DNA methylation and transcriptional profiling on lung CD4+ T cells. Juvenile and neonatal mice experienced differential demethylation in response to DAC treatment, with larger methylation differences observed in neonates. By cross-filtering differentially expressed genes between juveniles and neonates with those sites that were demethylated in neonates, we found that interferon-responsive genes such as Ifit1 are the most down-regulated methylation-sensitive genes in neonatal mice. DAC treatment shifted neonatal lung CD4+ T cells toward a gene expression program similar to that of juveniles. Following lung infection with E. coli, lung CD4+ T cells in neonatal mice exhibit epigenetic repression of important host defense pathways, which are activated by inhibition of DNA methyltransferase activity to resemble a more mature profile.

Project description:Lung CD4+ T cell responses may determine outcomes in pediatric pnuemonia. We therefore sought to define the transcriptional response and underlying DNA methyaltion landscape of lung CD4+ T cells by treating neonatal (~5 days of age) and juvenile (~15 days of age) mice with 2.8 million CFUs of E. coli or PBS (control) by aspiration. 48 hours later, lung CD4+ T cells were isolated by magnetic bead pre-enrichment and fluorescence-activated cell sorting for RNA-sequencing (RNA-seq) and modified reduced representation bisulfite sequencing (mRRBS).

Project description:Lung CD4+ T cell responses may determine outcomes in pediatric pnuemonia. We therefore sought to define the transcriptional response and underlying DNA methyaltion landscape of lung CD4+ T cells by treating neonatal (~5 days of age) and juvenile (~15 days of age) mice with 2.8 million CFUs of E. coli or PBS (control) by aspiration. 48 hours later, lung CD4+ T cells were isolated by magnetic bead pre-enrichment and fluorescence-activated cell sorting for RNA-sequencing (RNA-seq) and modified reduced representation bisulfite sequencing (mRRBS).

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:Respiratory viral infections contribute substantially to global infant losses and disproportionately affect preterm neonates. Using our previously established neonatal murine model of influenza infection, we demonstrate that three-day old mice are exceptionally sensitive to influenza virus infection and exhibit high mortality and viral load. Intranasal pre- and post-treatment of neonatal mice with Lactobacillus rhamnosus GG (LGG), an immune modulator in respiratory viral infection of adult mice and human preterm neonates, considerably improves neonatal mice survival after influenza virus infection. We determine that both live and heat-killed intranasal LGG are equally efficacious in protection of neonates. Early in influenza infection, neonatal transcriptional responses in the lung are delayed compared to adults. These responses increase by 24 hours post-infection, demonstrating a delay in the kinetics of the neonatal anti-viral response. LGG pretreatment improves immune gene transcriptional responses during early infection and specifically upregulates type I IFN pathways.

Project description:Studies of radiation exposed populations have shown that children are at greater overall risk of radiation-induced cancer, although there is considerable debate relating to heterogeneity of the effect in different tissues. Given public concern around increasing radiation doses received by children from advanced diagnostic imaging, and the use of radiotherapy to treat childhood cancers, understanding the relationship between age-at-exposure and radiation-induced cancer risk is a priority of radiation protection research. Although tobacco smoking accounts for up to 90% of lung cancers in some countries, epidemiological studies and animal experiments show that exposure to ionizing radiation is also a risk factor for developing cancers of the lung. Female Wistar rats are susceptible to lung cancer upon thoracic X-ray irradiation, developing adenocarcinomas (AC) and squamous cell carcinomas (SCC) similar to those seen in humans, and have been used previously to evaluate the interaction of radiation and a chemical carcinogen in neonatal, juvenile and young adult rats. In the present study, the induction of lung tumors was analyzed in female Wistar rats exposed to increasing doses of thoracic X-rays as neonates, juveniles or adults, to allow the effect of age-at-exposure to be observed in the absence of interaction with smoking. Histology was used to compare tumor subtypes between groups, and genomic DNA copy number alterations in a number of tumors arising after exposure to radiation at different ages were examined.

Project description:The adaptive immune response is coordinated by CD4+ T cells, which determine the type and strength of the immune response and the effector cells involved. It has been reported that CD4+ T cells are less responsive in neonates, leading to low activation of the cellular response and poor antibody production by B cells. This low response is essential for the tolerant window that favors birth transition from the sterile environment in the womb to the outside world but leaves neonates vulnerable to infection, which is still an important health issue. Neonates have a high morbidity and mortality rate due to infections, and the molecular reasons are still understudied. We asked whether the neonatal naive CD4+ T cells have a genomic program that predisposes them to a low response. Therefore, we evaluated the transcriptome and epigenome of human neonatal and adult naive CD4+ T cells. Our results point to a gene expression profile forming a distinct regulatory network in neonatal cells, which favors proliferation and a low T-cell response. Such expression profile is supported by a characteristic epigenetic landscape of neonatal CD4+ T cells, which correlates with the characteristic transcriptome of the neonatal cells. These results were confirmed by experiments showing a low response to activation signals, higher proliferation, and lower expression of cytokines of neonatal CD4+ T cells as compared to adult cells. Understanding this network could lead to novel vaccine formulations and better deal with life-threatening diseases during this highly vulnerable period of our lives.

Project description:Genome wide DNA methylation profiling of AML patient samples treated with PBS or DAC. The Illumina Infinium 450 Human DNA methylation was used to examine the methylation profile of 8 patient samples and 2 cell lines. Genome wide DNA methylation profiling of AML xenografts treated with either PBS control or with decitacine (DAC) alone, cytarabine (Ara-C) alone, DAC and Ara-C together (D+A), DAC followed by Ara-C (D/A) or with Ara-C followed by DAC (A/D).

Project description:DNA methylation regulates the neonatal CD4+ T-cell response to pneumonia in mice

Project description:DNA methylation regulates the neonatal CD4+ T-cell response to pneumonia in mice