Project description:Genomic plasticity helps adapt to extreme environmental conditions. We tested the hypothesis that exposure to space environment (ESE) impacts the epigenome as marked by DNA hypomethylation to induce genomic plasticity in responders. Murine skin samples from the Rodent Research Reference Mission-1 were procured from the International Space Station (ISS) National Lab. Targeted RNA sequencing to test differential gene expression between the skin of ESE versus ground controls revealed upregulation of VEGF mediated angiogenesis pathways secondary to promoter hypomethylation in responder ESE cohort. Methylome sequencing identified ESE-sensitive candidate hypomethylated genes including developmental angiogenic genes Araf, VegfbandVegfr1. Based on differentially expressed genes, the angiogenesis biofunction was enriched in responders compared to non-responders. The induction of genomic plasticity in response to ESE, as reported herein, may be viewed as a mark of biological resilience that is evident in a minority of organisms, responders but not in non-responders, exposed to the same stressor. Inducible genomic plasticity may be implicated in natural resilience to ESE.

Project description:RNA sequencing analysis of A549 cells that were depleted for ARAF (shARAF) and reconstituted with either empty vector control (+EV) or ARAF wildtype (+ARAF) or dimer deficient ARAF kinase (+R362H) respectively to identify factors that are differentially regulated by ARAF and its kinase activity. In particular, we discovered that ARAF regulates genes that are involved in proliferation and malignant growth by surpressing gene expression of members of the ERBB3/ AKT signaling pathway. At the same time, a functional interpretation of the differentially expressed (DE) genes with topGO indicated an important role of ARAF in regulation of genes involved in, among others, cell adhesion, cell motility, epithelial cell migration.

Project description:Malignant cells show major disruptions in DNA methylation profiles which manifest as aberrant hypermethylation and hypomethylation of gene promoters as well as global genomic hypomethylation. To date, many genes with aberrant promoter hypermethylation have been identified in essentially all forms of cancer including cell cycle regulators, DNA repair genes, genes associated with apoptosis, hormonal regulation, detoxification, metastasis, angiogenesis, and many others We developed an effective high-resolution approach for mapping genome-wide, and cancer-specific DNA methylation profiles. We have used this approach to provide first genomic DNA methylation profiling in human paediatric osteosarcoma tumours

Project description:Alzheimer’s disease (AD), the leading cause of dementia, affects millions of people worldwide. With no disease-modifying medication currently available, the human toll and economic costs are rising rapidly. Under current standards, a patient is diagnosed with AD when both cognitive decline and pathology (amyloid plaques and neurofibrillary tangles) are present. Remarkably, some individuals who have AD pathology remain cognitively normal. Uncovering factors that lead to “cognitive resilience” to AD is a promising path to create new targets for therapies. However, technical challenges discovering novel human resilience factors limit testing, validation, and nomination of novel drugs for AD. In this study, we use single-nucleus transcriptional profiles of postmortem cortex from human individuals with high AD pathology who were either cognitively normal (resilient) or cognitively impaired (susceptible) at time of death, as well as mouse strains that parallel these differences in cognition with high amyloid load. Our cross-species discovery approach highlights a novel role for excitatory layer 4/5 cortical neurons in promoting cognitive resilience to AD, and nominates several resilience genes that include ATP1A1, GRIA3, KCNMA1, and STXBP1. This putative cell type has been implicated in resilience in previous studies on bulk RNA-seq tissue, but our single-nucleus and cross-species approach identifies particular resilience-associated gene signatures in these cells. These novel resilience candidate genes were tested for replication in orthogonal data sets and confirmed to be correlated with cognitive resilience. Based on these gene signatures, we identified several potential mechanisms of resilience, including regulation of synaptic plasticity, axonal and dendritic development, and neurite vesicle transport along microtubules that are potentially targetable by available therapeutics. Because our discovery of resilience-associated genes in layer 4/5 cortical neurons originates from an integrated human and mouse transcriptomic space from susceptible and resilient individuals, we are positioned to test causality and perform mechanistic, validation, and pre-clinical studies in our human-relevant AD-BXD mouse panel.

Project description:Malignant cells show major disruptions in DNA methylation profiles which manifest as aberrant hypermethylation and hypomethylation of gene promoters as well as global genomic hypomethylation. To date, many genes with aberrant promoter hypermethylation have been identified in essentially all forms of cancer including cell cycle regulators, DNA repair genes, genes associated with apoptosis, hormonal regulation, detoxification, metastasis, angiogenesis, and many others We developed an effective high-resolution approach for mapping genome-wide, and cancer-specific DNA methylation profiles. We have used this approach to provide first genomic DNA methylation profiling in osteosarcoma cells Keywords: comparative profiling

Project description:Tracking resilience to infections by mapping disease space

Project description:Background: Examining transcriptional regulation by existing antidepressants in key neural circuits implicated in depression, and understanding the relationship to transcriptional mechanisms of susceptibility and natural resilience, may help in the search for new therapeutics. Further, given the heterogeneity of treatment response in human populations, examining both treatment response and non-response is critical. Methods: We compared the effects of a conventional monoamine-based tricyclic antidepressant, imipramine (14 daily injections), and a rapidly acting, experimental, non-monoamine-based antidepressant, ketamine (single injection), in mice subjected to chronic social defeat stress, a validated model of depression, and used RNA-sequencing to analyze transcriptional profiles associated with susceptibility, resilience and antidepressant response and non-response in prefrontal cortex (PFC), nucleus accumbens, hippocampus, and amygdala. Results: We identified approximately equal numbers of responder and non-responder mice following ketamine or imipramine treatment. Ketamine induced more expression changes in hippocampus than other brain regions; imipramine induced more expression changes in nucleus accumbens and amygdala. Transcriptional profiles in ketamine and imipramine responders were most similar in PFC, where the least transcriptional regulation occurred for each drug. Non-response reflected both the lack of response-associated gene expression changes and unique gene regulation. In responders, both drugs reversed susceptible associated transcriptional changes as well as induced resilient associated transcription in PFC, with effects varying by drug and brain region studied. Conclusions: We generated a uniquely large resource of gene expression data in four inter-connected limbic brain regions implicated in depression and its treatment with imipramine or ketamine. Our analyses highlight the PFC as a key site of common transcriptional regulation by both antidepressant drugs and in both reversing susceptibility and inducing resilience associated molecular adaptations. In addition, we found region-specific effects of each drug suggesting both common and unique effects of imipramine versus ketamine. mRNA profiles of susceptibility to chronic social defeat stress as well as treatment response were generated across 4 separate brain regions, with a sample size of 3-5 per group.

Project description:Although tyrosine kinase inhibitors (TKIs) targeting Epidermal Growth Factor Receptor (EGFR) activating mutations have significantly improved outcomes in EGFR-mutant non-small cell lung cancer, resistance inevitably develops. Despite the heterogeneity of resistance mechanisms, many induce activation of MAPK signaling in the presence of EGFR-TKIs. ARAF gene amplification is identified as one such mechanism that activates MAPK signaling by directly interacting with RAS, yet its clinicopathologic characteristics remain poorly understood. We characterized five cases with ARAF amplification resistant to first- or second-generation EGFR-TKIs and screened an additional 48 re-biopsied specimens following resistance to Osimertinib. Among Osimertinib-resistant tumors, we identified four cases with ARAF amplification. Overall, these nine ARAF-amplified resistant tumors retained their original founder EGFR mutation and lacked secondary alterations. Furthermore, we identified two cases showing histologic transformation from lung adenocarcinoma to small cell lung cancer (SCLC). SCLC can be classified into four subtypes defined by transcriptional signatures driven by specific transcription factors. To estimate the subtypes of these resistant tumors, RNA sequencing analysis was performed in paired samples before and after treatment with EGFR-TKIs.

Project description:Naive pluripotent epiblast cells of the preimplantation murine embryo and their in vitro counterpart, embryonic stem (ES) cells, have the capacity to give rise to all cells of the adult. Such developmental plasticity is associated with global genome hypomethylation. It is unclear whether genome methylation is dynamically regulated only via differential expression of DNA methyltransferases (DNMTs) and Ten-eleven Translocation (TET) enzymes, which oxidase methylated DNA. Here we show that LIF/Stat3 signalling induces genomic hypomethylation via metabolic reconfiguration. In Stat3-/- ES cells we observed decreased alpha-ketoglutarate (ɑKG) production from reductive Glutamine metabolism, leading to decreased TET activity, increased Dnmt3a/b expression and to a global increase in DNA methylation. Notably, genome methylation is dynamically controlled by simply modulating αKG availability, mitochondrial activity or Stat3 activation in mitochondria, indicating effective crosstalk between metabolism and the epigenome. Stat3-/- ES cells also show increased methylation at Imprinting Control Regions accompanied with differential expression of >50% of imprinted genes. Single-cell transcriptome analysis of Stat3-/- embryos confirmed dysregulated expression of Dnmt3a/b, Tet2, and imprinted genes in vivo. Our results reveal that the LIF/Stat3 signal bridges the metabolic and epigenetic profiles of naive pluripotent cells, ultimately controlling genome methylation and imprinted gene expression. Several imprinted genes regulate cell proliferation and are often misregulated in tumors. Moreover, a wide range of cancers display Stat3-overactivation, raising the possibility that the molecular module we described here is exploited under pathological conditions.

Project description:LCH sequencing - ARAF gene