Project description:We are using induced pluripotent stem cell (iPSC) technology to study neuropsychiatric disorders associated with 22q11.2 microdeletions (del), the most common known schizophrenia (SZ) -associated genetic factor. Several genes in the deleted region have been implicated; one of the more promising candidates is DGCR8, which codes for a protein involved in microRNA (miRNA) biogenesis. We carried out miRNA expression profiling (miRNA-seq) on neurons generated from iPSCs derived from controls and SZ patients with 22q11.2 del. miRNA profiling of 7 SZ samples and 9 Control samples derived from iPSCs

Project description:We are using induced pluripotent stem cell (iPSC) technology to study neuropsychiatric disorders associated with 22q11.2 microdeletions (del), the most common known schizophrenia (SZ) -associated genetic factor. Several genes in the deleted region have been implicated; one of the more promising candidates is DGCR8, which codes for a protein involved in microRNA (miRNA) biogenesis. We carried out miRNA expression profiling (miRNA-seq) on neurons generated from iPSCs derived from controls and SZ patients with 22q11.2 del.

Project description:Purpose: To identify and compare all the cell subsets present in Normal and 22q11.2 DS Hypoplastic thymus We have identified 17 distinct cell clusters in normal e13 embronic thymus. While both normal and 22q11.2 DS Hypoplastic thymus have same number of cell clusters, the trancriptome pattern varies significantly between them. Our scRNA sequencing results provide mesenchymal cells driven thymus hypoplasticity in 22q11.2 DS thymus.

Project description:Induced pluripotent stem cell (iPSC) technology presents a unique opportunity to model schizophrenia (SCZ) and other neuropsychiatric disorders in vitro by providing investigators with the means to grow patient-specific neurons. Three approaches are possible regarding disease modeling for a genetically heterogenous disorder, like SCZ. One is the draw subjects from the general patient population who have suspected but undefined disease-causing genetic variants. Another is to focus on a common phenotype, such as clinical presentation, response to medications or age of onset. The third is to use patients who have on a common genetic etiology. We have chosen the latter approach and are developing a library of iPSCs from patients with SCZ who harbor chromosome 22q11.2 microdeletions. In this preliminary study involving 4 patients and 4 controls, gene expression profiling was carried out on early differentiating neurons using RNA-seq. Several important observations were made. First, despite the dramatic molecular changes that occur during the reprogramming of a somatic cell into an iPSC, and its subsequent differentiation into neurons, processes that require months of cultivation with multiple changes in growth medium and treatment with a variety of growth factors, we show that 22q11.2 haploinsufficiency at the DNA level is recapitulated in vitro by substantial decreases in the expression of nearly every gene in the deleted region. Overall, transcriptome profiling revealed significant changes in the expression of 604 genes (423 increased in the SCZ samples, 181 decreased; >1.5-fold change, uncorrected p<0.05). Among the differentially expressed genes were a number of SCZ candidates and genes involved in retinoic acid (RA) signaling. In addition, there was some overlap with the differentially expressed genes found in another study using SCZ patients who do not have 22q11.2 del, one of which was CYP26A1, which codes for one of the major enzymes involved in RA metabolism. Although the sample size in this preliminary study is small, the findings support the idea that dysregulated RA-signaling could be a potential target for therapeutic intervention in SZ associated with 22q11.2 del, and perhaps other subgroups of patients. 4 controls and 4 patients

Project description:Social anxiety disorder (SAD) is a psychiatric disorder characterized by severe fear in social situations and avoidance of these. Multiple genetic as well as environmental factors contribute to the etiopathology of SAD. One of the main risk factors for SAD is stress, especially during early periods of life (early life adversity; ELA). ELA leads to structural and regulatory alterations contributing to disease vulnerability. This includes the dysregulation of the immune response. However, the molecular link between ELA and the risk for SAD in adulthood remain largely unclear. Evidence is emerging that long-lasting changes of gene expression patterns play an important role in the biological mechanisms linking ELA and SAD. Therefore, we conducted a transcriptome study of SAD and ELA performing RNA sequencing in peripheral blood samples. Analyzing differential gene expression between individuals suffering from SAD with high or low levels of ELA and healthy individuals with high or low levels of ELA, 13 significantly differentially expressed genes (DEGs) were identified with respect to SAD whilst no significant differences in expression were identified with respect to ELA. The most significantly expressed gene was MAPK3 (p=0.003) being upregulated in the SAD group compared to control individuals. In contrary, weighted gene co-expression network analyses (WGCNA) identified only modules significantly associated with ELA (p≤0.05), not with SAD. Furthermore, analyzing interaction networks of the genes from the ELA-associated modules and the SAD-related MAPK3) revealed complex interactions of those genes. Gene functional enrichment analyses indicate a role of signal transduction pathways as well as inflammatory responses supporting an involvement of the immune system in the association of ELA and SAD. In conclusion, we did not identify a direct molecular link between ELA and adult SAD by transcriptional changes. However, our data indicate an indirect association of ELA and SAD mediated by the interaction of genes involved in immune-related signal transduction.

Project description:To identify the genes, which led to the augmented hematopoiesis in DS-iPS cells, we performed gene expression profiling of D12-DS-iPS cells (DS-iPS-T32, DS-iPS-T33 and DS-iPS-T31) and control hiPS cells (253G1, 253G4 and A31) generated by 3 factors. In the comparison of gene expression levels in each DS-iPS cell clone with the average of these in control iPS cell clones, 972 genes showed more than 2-fold increased expression, and 1118 genes showed decreased expression in all DS-iPS cell clones. Among these upregulated genes, 61 genes including GATA1 were involved in hematopoiesis-related genes according to Ingenuity Pathways Analysis (IPA). Among the above 2-fold more upregulated genes in DS-iPS cells, 18 genes were on Hsa21. The expression of RUNX1 on Hsa21, a hematopoiesis-related gene, was significantly upregulated in DS-iPS cells. The high expressions of GATA1 and RUNX1 were also identified in 4-factor DS-iPS cells.

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:To identify the genes, which led to the augmented hematopoiesis in DS-iPS cells, we performed gene expression profiling of D12-DS-iPS cells (DS-iPS-T32, DS-iPS-T33 and DS-iPS-T31) and control hiPS cells (253G1, 253G4 and A31) generated by 3 factors. In the comparison of gene expression levels in each DS-iPS cell clone with the average of these in control iPS cell clones, 972 genes showed more than 2-fold increased expression, and 1118 genes showed decreased expression in all DS-iPS cell clones. Among these upregulated genes, 61 genes including GATA1 were involved in hematopoiesis-related genes according to Ingenuity Pathways Analysis (IPA). Among the above 2-fold more upregulated genes in DS-iPS cells, 18 genes were on Hsa21. The expression of RUNX1 on Hsa21, a hematopoiesis-related gene, was significantly upregulated in DS-iPS cells. The high expressions of GATA1 and RUNX1 were also identified in 4-factor DS-iPS cells. Gene expression in blood cells differentiated from human induced pluripotent stem cells derived from patients with Down syndrome and healthy donor was measured in 12 days after induction of differentiation. Eight cell lines were used.

Project description:Down Syndrome (DS) results from the trisomy of human chromosome 21 (HSA21). It is still the most frequent intellectual disability, affecting 1 newborn per 700 births. Among candidate genes explaining intellectual disabilities seen in DS patients, the dual specificity tyrosine-phosphorylation regulated kinase 1A, DYRK1A, is located in the DS critical region of chromosome 21. DYRK1A has become a major screening target for the development of selective and potent pharmacological inhibitors. We here investigated the effects of a relatively selective DYRK1A inhibitor, Leucettine 41 (hereafter L41) in three different trisomic mouse models with increasing genetic complexity, Tg(Dyrk1a), Ts65Dn and Dp1Yey. Leucettines are derived from the marine sponge alkaloid Leucettamine B.

Project description:The 22q11.2 deletion syndrome (22q11.2DS) is the most common copy number variant (CNV)-associated syndrome, leading to congenital, cognitive, and neuropsychiatric anomalies in patients. The clinical presentation of the disease phenotypes is variable, posing significant challenges for prognosis of inheritance risk and clinical outcomes for the CNV carriers. ~85% of patients and almost all available human-centered models of this condition reflect the ~2.7 Mb “A-D” deletion at this locus. Leveraging a CRISPR/Cas9-based engineering strategy and induced pluripotent stems cells, we generated novel isogenic models for the smaller, commonly inherited 1.5 Mb “A-B” deletion found in ~5-10% of 22q11.2DS patients. The bulk RNA-seq data included here reflects paired-end 100 bp sequencing of iPSC-derived neuronal progenitor cells and excitatory neurons. These data reflect three independent clones either carrying the designed 22q11.2 deletion or control comparators (2 clones nucleofected with same sgRNA but with no deletion generated; 1 clone derived from the parental Cas9-expressing iPSC line). We anticipate that these novel, isogenic models will carry significant utility for the study of 22q11.2 deletion syndrome.