Project description:We have previously demonstrated functional and molecular changes in hippocampal subfields in individuals with schizophrenia (SZ) psychosis associated with hippocampal excitability. In this study, we use RNA-seq and assess global transcriptome changes in the hippocampal subfields, DG, CA3, and CA1 from individuals with SZ psychosis and controls to elucidate subfield-relevant molecular changes. We also examine changes in gene expression due to antipsychotic medication in the hippocampal subfields from our SZ ON- and OFF-antipsychotic medication cohort. We identify unique subfield-specific molecular profiles in schizophrenia postmortem samples compared to controls, implicating astrocytes in DG, immune mechanisms in CA3, and synaptic scaling in CA1. We show a unique pattern of subfield-specific effects by antipsychotic medication on gene expression levels with scant overlap of genes differentially expressed by SZ disease effect versus medication effect. These hippocampal subfield changes could provide the basis for previously observed hippocampal SZ pathology and explain the lack of full efficacy of conventional antipsychotic medication on SZ symptomatology. With further characterization, the identified distinct molecular profiles of the DG, CA3, and CA1 in SZ psychosis may serve to identify potential hippocampal-based therapeutic targets.

Project description:Accumulating evidence suggests that mitochondrial dysfunction underlies the pathophysiology of bipolar disorder (BD) and schizophrenia (SZ). We performed large-scale DNA microarray analysis of postmortem brains of patients with BD or SZ, and examined expression patterns of mitochondria-related genes. We found a global down-regulation of mitochondrial genes, such as those encoding respiratory chain components, in BD and SZ samples, even after the effect of sample pH was controlled. However, this was likely due to the effects of medication. Medication-free patients with BD showed tendency of up-regulation of subset of mitochondrial genes. Our findings support the mitochondrial dysfunction hypothesis of BD and SZ pathologies. However, it may be the expression changes of a small fraction of mitochondrial genes rather than the global down-regulation of mitochondrial genes. Our findings warrant further study of the molecular mechanisms underlying mitochondrial dysfunction in BD and SZ. Keywords: disease state analysis

Project description:Accumulating evidence suggests that mitochondrial dysfunction underlies the pathophysiology of bipolar disorder (BD) and schizophrenia (SZ). We performed large-scale DNA microarray analysis of postmortem brains of patients with BD or SZ, and examined expression patterns of mitochondria-related genes. We found a global down-regulation of mitochondrial genes, such as those encoding respiratory chain components, in BD and SZ samples, even after the effect of sample pH was controlled. However, this was likely due to the effects of medication. Medication-free patients with BD showed tendency of up-regulation of subset of mitochondrial genes. Our findings support the mitochondrial dysfunction hypothesis of BD and SZ pathologies. However, it may be the expression changes of a small fraction of mitochondrial genes rather than the global down-regulation of mitochondrial genes. Our findings warrant further study of the molecular mechanisms underlying mitochondrial dysfunction in BD and SZ. Keywords: disease state analysis A total of 102 postmortem brains obtained from the Stanley Medical Research Institute were used for DNA microarray analysis. Fresh frozen samples were used for RNA extraction.

Project description:Multiple studies have shown that brain gene expression is disturbed in subjects suffering from schizophrenia. However, disentangling disease effects from alterations caused by neuroleptics is a challenging task. <br> To address the issues of disease heterogeneity and the effect of antipsychotic medication, we use a large collection of 110 brain autopsy samples, subdivided according to the type of antipsychotic medication received. We use global and high-resolution mRNA quantification techniques to analyse gene expression in brain tissues. We also analyse transcription in-vitro, in cell lines before and after treatment with cytokines.<br> Results. We show that inflammation-related genes are up regulated in all groups of patients, including those not treated at the time of death. In particular, four co-expressed genes that are inducible by inflammatory cytokines showed increased mRNA levels, namely IFITM2, IFITM3, SERPINA3, and GBP1 (p-values from qPCR ? 0.01). We also show that these genes are expressed in oligodendrocyte and endothelial cell lines, and transcription is inducible by inflammatory cytokines in both cell lines. Our results give molecular support to the inflammatory theory of schizophrenia and suggest that inflammatory cytokines may stimulate transcription in endothelial brain cells during schizophrenia progression. Unexpectedly, inflammation-related genes may also have a role in myelin producing cells, since they are also inducible by cytokines in oligodendrocyte cell lines. Our findings encourage future research to explore whether anti-inflammatory agents can be used in combination with traditional antipsychotics for a more efficient treatment of schizophrenia.

Project description:Antipsychotics are the main line of treatment for schizophrenia, despite being effective only in about 50% of patients. Additionally, serious side effects may cause medication drop-out, aggravated by a lack of understanding about how these drugs act at molecular level. As proteomics is a suitable tool for studying multifactorial disorders, the main goal was to unravel signaling pathways in blood plasma associated with a positive treatment outcome for the atypical antipsychotics olanzapine and risperidone. Blood plasma was collected from schizophrenia patients six weeks after treatment (T6), and patients were classified as good or poor responders to olanzapine or risperidone, and then samples were compared to each patient's baseline (T0). All samples were analyzed using label-free quantitative shotgun proteomics. Samples were depleted of the 14 most abundant proteins in plasma, were digested, and then submitted to M-Class two-dimensional nano-liquid chromatography, coupled online to a Synapt G2-Si mass spectrometer. Data was obtained in MSE mode (data- independent acquisition) in combination with ion-mobility (HDMSE). The proteins found to be differentially abundant in good responders compared to poor responders for risperidone and olanzapine were functionally analyzed in silico using Ingenuity® Pathway Analysis and were found to be mostly involved with immune system functions. This data can contribute to better understand the biochemical signaling peripherally triggered by antipsychotic medication, and can eventually be used to help improve treatment outcome by predicting patient response as well as through the development of new medication or a combination of drugs that act on the immune system to reduce the duration of poor response periods in patients suffering with schizophrenia.

Project description:This SuperSeries is composed of the following subset Series: GSE38481: A gene co-expression network in whole blood of schizophrenia patients is independent of antipsychotic-use and enriched for brain-expressed genes [HumanRef-8 v3.0] GSE38484: A gene co-expression network in whole blood of schizophrenia patients is independent of antipsychotic-use and enriched for brain-expressed genes [HumanHT-12 V3.0] Refer to individual Series

Project description:Schizophrenia (SZ) and bipolar disorder (BD) are severe psychiatric conditions, with a lifetime prevalence of about 1%. Both disorders have a neurodevelopment component, with onset of symptoms occurring most frequently during late adolescence or early adulthood. Genetic findings indicate the existence of an overlap in genetic susceptibility across the disorders. These gene expression profiles were used to identify the molecular mechanisms that differentiate SZ and BP from healthy controls but also that distinguish both from healthy individuals. They were also used to expand an analysis from an experiment that searched molecular alterations in human induced pluripotent stem cells derived from fibroblasts from control subject and individual with schizophrenia and further differentiated to neuron to identify genes relevant for the development of schizophrenia (GSE62105). Brain tissue (frontal cortex) from 30 healthy controls, 29 bipolar disorder patients and 29 schizophrenia patients were analyzed. The reference is an in-house pool of RNA extracted from 15 human cell lines.

Project description:Schizophrenia patients vary in their response to antipsychotic (AP) treatment and predicting if and which therapy will be efficient is of high clinical and social importance. Here, we set out to analyze blood methylomes of 28 schizophrenia patients just before starting (baseline) risperidone treatment and four weeks later (follow-up) in order to look for differences that may help predict variation in response. We were not able to identify CpGs whose baseline methylation could be used as a predictive biomarker, but our analysis suggests the role of methylation status of genes involved in immunity, neurotransmission and neuronal development in the treatment response.

Project description:Schizophrenia is a debilitating neurological disorder for which no cure exists. Few defining characteristics of schizophrenic neurons have been identified and the molecular mechanisms responsible for schizophrenia are not well understood, in part due to the lack of patient material for study. Human induced pluripotent stem cells (hiPSCs) offer a new strategy for studying schizophrenia. We have created the first cell-based human model of a complex genetic psychiatric disease by generating hiPSCs from schizophrenic patients and subsequently differentiating these cells to hiPSC-derived neurons in vitro. Schizophrenic hiPSC-derived neurons showed diminished neuronal connectivity in conjunction with decreased neurite number, PSD95-protein levels and glutamate receptor expression. Gene expression profiles of schizophrenic hiPSC-derived neurons identified altered expression of many components of the cAMP and WNT signaling pathways. Key cellular and molecular elements of the schizophrenic phenotype were ameliorated following treatment of schizophrenic hiPSC-derived neurons with the antipsychotic loxapine. 3 independent differentiations (biological replicates) for each of four control and four schizophrenic patients were analyzed.

Project description:We conducted proteomic profiling of plasma, identifying both overlapping and unique differential proteins in adolescent patients diagnosed with major depressive disorder (MDD), bipolar disorder (BD), and schizophrenia (SZ). Our results showed that the protein signatures of adolescent psychiatric disorders differ significantly from those of adults. We propose potential targets for drug development aimed at the prevention or precision therapy of these psychiatric disorders. These findings enhance our understanding of the molecular etiology of adolescent psychiatric disorders. The specific biomolecular signatures of MDD, BD, and SZ could potentially serve as targets for the development of novel interventions aimed at prevention, early diagnosis, and treatment of these mental health conditions.