Project description:Social anxiety disorder (SAD) is a psychiatric disorder characterized by extensive fear in social situations. Multiple genetic and environmental factors are known to contribute to its pathogenesis. One of the main environmental risk factors is early life adversity (ELA). Evidence is emerging that epigenetic mechanisms such as DNA methylation might play an important role in the biological mechanisms underlying SAD and ELA. To investigate the relationship between ELA, DNA methylation, and SAD, we performed an epigenome-wide association study for SAD and ELA examining DNA from whole blood of a cohort of 143 individuals using DNA methylation arrays. We identified two differentially methylated regions (DMRs) associated with SAD located within the genes SLC43A2 and TNXB. As this was the first epigenome-wide association study for SAD, it is worth noting that both genes have previously been associated with panic disorder. Further, we identified two DMRs associated with ELA within the SLC17A3 promoter region and the SIAH3 gene and several DMRs that were associated with the interaction of SAD and ELA. Of these, the regions within C2CD2L and MRPL28 showed the largest difference in DNA methylation. Lastly, we found that two DMRs were associated with both the severity of social anxiety and ELA, however, neither of them was found to mediate the contribution of ELA to SAD later in life. Future studies are needed to replicate our findings in independent cohorts and to investigate the biological pathways underlying these effects.

Project description:the goal of this experiment is to identify the molecular modules that underlie social phenotypes in A. burtoni Keywords: loop design comparison of dominant (T) subordinate (NT) and brooding female (F) phenotypes 6 individuals of each phenotype under normal mixed population conditions

Project description:ELABELA (ELA) is a peptide hormone required for heart development that signals via the Apelin Receptor (APLNR, APJ). ELA is also abundantly secreted by human embryonic stem cells (hESCs), which do not express APLNR. Here we show that ELA signals in a paracrine fashion in hESCs to maintain self-renewal. ELA inhibition by CRISPR/Cas9-mediated deletion, shRNA or neutralizing antibodies causes reduced hESC growth, cell death and loss of pluripotency. Global phosphoproteomic and transcriptomic analyses of ELA-pulsed hESCs show that it activates PI3K/AKT/mTORC1 signaling required for cell survival. ELA promotes hESC cell cycle progression and protein translation, and blocks stress-induced apoptosis. INSULIN and ELA have partially overlapping functions in hESC medium, but only ELA can potentiate the TGFβ pathway to prime hESCs towards the endoderm lineage. We propose that ELA, acting through an alternate cell-surface receptor, is an endogenous secreted growth factor in human embryos and hESCs that promotes growth and pluripotency. Global Transcriptomic Analysis of INSULIN versus ELA-pulsed human embryonic stem cells was performed to elucidate the functional overlap between these two ligands

Project description:Early-life adversity (ELA) is a major predictor of psychopathology, and is thought to increase lifetime risk by epigenetically regulating the genome. Here, focusing on the lateral amygdala, a major brain site for emotional homeostasis, we described molecular cross-talk among multiple epigenetic mechanisms, including 6 histone marks, DNA methylation and the transcriptome, in subjects with a history of ELA and controls. We first uncovered, in the healthy brain, previously unknown interactions among epigenetic layers, in particular related to non-CG methylation in the CAC context. We then showed that ELA associates with methylomic changes that are as frequent in the CAC as in the canonical CG context, while these two forms of plasticity occur in sharply distinct genomic regions, features, and chromatin states. Combining these multiple data indicated that immune-related and small GTPase signaling pathways are most consistently impaired in the amygdala of ELA individuals. Overall, this work provides new insights into epigenetic brain regulation as a function of early-life experience.

Project description:Individuals with 22q11.2 Deletion Syndrome (22q11.2 DS) are a specific high-risk group for developing schizophrenia (SZ), schizoaffective disorder (SAD) and autism spectrum disorders (ASD). Several genes in the deleted region have been implicated in the development of SZ, e.g., PRODH and DGCR8. However, the mechanistic connection between these genes and the neuropsychiatric phenotype remains unclear. To elucidate the molecular consequences of 22q11.2 deletion in early neural development, we carried out RNA-seq analysis to investigate gene expression in differentiating human neurons derived from induced pluripotent stem cells (iPSCs) of 22q11.2 DS SZ and SAD patients. Eight cases (ten iPSC-neuron samples in total including duplicate clones) and seven controls (nine in total including duplicate clones) were subject to RNA sequencing. Using a systems level analysis, differentially expressed genes/gene-modules and pathway of interests were identified. We observed ~2-fold reduction in expression of almost all genes in the 22q11.2 region in SZ (37 genes reached p-value < 0.05, 36 of which reached a false discovery rate < 0.05). Outside of the deleted region, 745 genes showed significant differences in expression between SZ and control neurons (p<0.05). Function enrichment and network analysis of the differentially expressed genes uncovered converging evidence on abnormal expression in key functional pathways, such as apoptosis, cell cycle and survival, and MAPK signaling in the SZ and SAD samples.

Project description:Transcription profiling by array of pancreas from KrasG12D, Ela-Tgfa and KrasG12D Ela-Tgfa mice

Project description:ELABELA (ELA) is a peptide hormone required for heart development that signals via the Apelin Receptor (APLNR, APJ). ELA is also abundantly secreted by human embryonic stem cells (hESCs), which do not express APLNR. Here we show that ELA signals in a paracrine fashion in hESCs to maintain self-renewal. ELA inhibition by CRISPR/Cas9-mediated deletion, shRNA or neutralizing antibodies causes reduced hESC growth, cell death and loss of pluripotency. Global phosphoproteomic and transcriptomic analyses of ELA-pulsed hESCs show that it activates PI3K/AKT/mTORC1 signaling required for cell survival. ELA promotes hESC cell cycle progression and protein translation, and blocks stress-induced apoptosis. INSULIN and ELA have partially overlapping functions in hESC medium, but only ELA can potentiate the TGFβ pathway to prime hESCs towards the endoderm lineage. We propose that ELA, acting through an alternate cell-surface receptor, is an endogenous secreted growth factor in human embryos and hESCs that promotes growth and pluripotency.

Project description:In a systemic effort to survive environmental stress, organ systems fluctuate and adapt to overcome external pressures. The evolutionary drive back towards homeostasis, makes it difficult to determine if an organism experienced a toxic exposure to stress, especially in early prenatal and neonatal periods of development. Previous studies indicate that primary human teeth may provide historical records of experiences related to stressors during that early time window. To assess the molecular effects of early life adversity on enamel formation, we used a limited bedding and nesting (LBN) mouse model of early life adversity (ELA), to assess changes in enamel organ gene expression and enamel mineralization. Enamel of postnatal day 12 (P12) weight-matched ELA mice was more mineralized as compared control enamel. RNAseq showed 724 genes significantly upregulated in ELA enamel organs as compared to controls, and 574 significantly downregulated genes (DESeq2 p-value <= 0.05). Transcripts expressing the enamel matrix proteins amelogenin (Amelx) and enamelin (Enam) were among the top 4 most differentially expressed genes. The most significantly enriched GO and Reactome pathway was Extracellular Matrix Organization, while the most significantly enriched KEGG Pathways were Butanoate metabolism and Synthesis and Degradation of Ketone Bodies. qPCR analysis of weight-matched ELA and control enamel organs confirmed that expression of the ameloblast-specific proteins Amelx and Enam were highly upregulated in ELA mice. When evaluating molecular mechanisms for amelogenin upregulation, we found significantly increased expression of Dlx3, while transcripts for clock genes Per1 and Nrd1, which have also positively associated with amelogenin expression, were downregulated. These findings suggest that the developing enamel organs are sensitive to the pressures of early life adversity and produce structural biomarkers in tooth enamel mineral to reflect these changes. Together these results support the possibility that tooth enamel may contain biomarkers of cellular effects associated with systemic early life adversity.

Project description:Comparison of social dominance phenotypes induced in the cichlid A. burtoni females with the goal of comparing to other gene expression profiles of social dominance Used platform GPL928 In many species, under varying ecological conditions, social interactions among individuals result in the formation dominance hierarchies. Despite general similarities, there are substantial differences across species, populations, environments, life stages, sexes, and individuals. Understanding the proximate mechanisms of this variation is an important step toward understanding the evolution of social behavior. However, physiological changes associated with dominance such as gonadal maturation and somatic growth, often complicate efforts to identify the specific underlying mechanisms. We demonstrate complementary analysis tools to allow a comparative approach to high-throughput expression profiling that allow us to both test a priori hypotheses and generate new hypotheses about the mechanisms and evolution of social dominance. Using experimental manipulation to produce female dominance hierarchies in the cichlid A. burtoni, heralded as a genomic model of social dominance, we generate gene lists, and assess molecular gene modules. We demonstrate a general pattern of “masculinization” of the female neural gene expression profile and compare expression biases between male and female dominance hierarchies. Using a threshold-free approach to identify correlation throughout gene ranked lists, we query previously published datasets from maternal behavior, alternative reproductive tactics, cooperative breeding and sex-role reversal to describe correlations among neural gene expression profiles. These complementary approaches capitalize on the high-throughput gene expression profiling from similar behavioral phenotypes in order to address the mechanism associated with social dominance behavioral phenotypes.

Project description:Early-life adversity (ELA) is associated with lifelong memory deficits, yet the responsible mechanisms remain unclear. We imposed ELA by rearing rat pups in simulated poverty, assessed hippocampal memory, and probed changes in gene expression, their transcriptional regulation and the consequent changes in hippocampal neuronal structure. ELA rats had poor hippocampal memory and stunted hippocampal pyramidal neurons, associated with ~140 differentially expressed genes. Upstream regulators of the altered genes included glucocorticoid receptor and, unexpectedly, the transcription factor neuron-restrictive silencer factor (NRSF/REST). NRSF contributed critically to the memory deficits because blocking its function transiently following ELA rescued spatial memory and restored the dendritic arborization of hippocampal pyramidal neurons in ELA rats. Blocking NRSF function in vitro augmented dendritic complexity of developing hippocampal neurons, suggesting that NRSF represses genes involved in neuronal maturation. These findings establish important, surprising contributions of NRSF to ELA-induced transcriptional programming that disrupts hippocampal maturation and memory function.