Project description:Rheumatoid arthritis (RA) is linked to depression and dementia in later life by inflammatory involvement of the central nervous system (CNS). Regional heterogeneity of brain immunophenotypes was described under homeostasis, but a topographical resolution of CNS immune responses in chronic peripheral inflammatory diseases like RA is missing. We demonstrate regional heterogeneity of CNS susceptibility to chronic peripheral inflammation in the human tumor necrosis factor α transgenic (TNFtg) mouse model of RA. TNFtg mice showed myeloid cell infiltration, microglial activation, and a mutual transcriptomic fingerprint of neuroinflammation in the cortex, striatum, and thalamus. Immune responses were minimal in the hippocampus and cerebellum. We demonstrate regional CNS immune responses to chronic peripheral inflammation, sparing the hippocampus and cerebellum and reversible by peripheral anti-inflammatory treatment. Targeting microenvironmental susceptibility or resilience of brain regions will help to prevent and treat RA-related neuropsychiatric comorbidity. RNA-sequencing was performed from five brain regions (cortex, striatum, thalamus, hippocampus, and cerebellum) from C57Bl6/J wild type mice and TNFtg mice (strain Tg197; kindly provided by George Kollias (Fleming Institute, Vari, Greece).

Project description:Loss-of-function mutations in AKAP11 (a protein kinase A (PKA)-binding protein) greatly increase the risk of bipolar disorder and schizophrenia. To determine the neurobiological functions of AKAP11 and the consequences of its absence, we conducted multi-omic analyses of Akap11 mutant mouse brains. We find that AKAP11 is a key regulator of PKA proteostasis in the brain whose loss leads to dramatically elevated PKA expression and phosphorylation, especially in synapses. Transcriptomic analysis shows extensive gene expression changes throughout the brain, including prominent decreases in synapse-related genes sets. Gene expression is especially affected in spiny projection neurons of the striatum, a brain region implicated in motivation, cognition and psychiatric disorders. In vivo, real-time measurements of PKA activity in ventral striatum of Akap11-/- mice revealed constitutively elevated kinase activity, which distorts dopamine to PKA signaling. Our work reveals the molecular basis of circuit dysfunction in a genetically valid model of psychotic disorder.

Project description:Loss-of-function mutations in AKAP11 (a protein kinase A (PKA)-binding protein) greatly increase the risk of bipolar disorder and schizophrenia. To determine the neurobiological functions of AKAP11 and the consequences of its absence, we conducted multi-omic analyses of Akap11 mutant mouse brains. We find that AKAP11 is a key regulator of PKA proteostasis in the brain whose loss leads to dramatically elevated PKA expression and phosphorylation, especially in synapses. Transcriptomic analysis shows extensive gene expression changes throughout the brain, including prominent decreases in synapse-related genes sets. Gene expression is especially affected in spiny projection neurons of the striatum, a brain region implicated in motivation, cognition and psychiatric disorders. In vivo, real-time measurements of PKA activity in ventral striatum of Akap11-/- mice revealed constitutively elevated kinase activity, which distorts dopamine to PKA signaling. Our work reveals the molecular basis of circuit dysfunction in a genetically valid model of psychotic disorder.

Project description:Schizophrenia is a complex psychiatric disorder encompassing a range of symptoms and etiology dependent upon the interaction of genetic and environmental factors. Several risk genes, such as DISC1, have been associated with schizophrenia as well as bipolar disorder (BPD) and major depressive disorder (MDD), consistent with the hypothesis that a shared genetic architecture could contribute to divergent clinical syndromes. The present study compared gene expression profiles across three brain regions in post-mortem tissue from matched subjects with schizophrenia, BPD or MDD and unaffected controls. Post-mortem brain tissue was collected from control subjects and well-matched subjects with schizophrenia, BPD, and MDD (n=19 from each group). RNA was isolated from hippocampus, Brodmann Area 46, and associative striatum and hybridized to U133_Plus2 Affymetrix chips. Data were normalized by RMA, subjected to pairwise comparison followed by Benjamini and Hochberg False Discovery Rate correction (FDR). Samples derived from patients with schizophrenia exhibited many more changes in gene expression across all brain regions than observed in BPD or MDD. Several genes showed changes in both schizophrenia and BPD, though the magnitude of change was usually larger in schizophrenia. Several genes that have variants associated with schizophrenia were found to have altered expression in multiple regions of brains from subjects with schizophrenia. Continued evaluation of circuit-level alterations in gene expression and gene-network relationships may further our understanding of how genetic variants may be influencing biological processes to contribute to psychiatric disease. Pre-frontal cortex, striatum and hippocampus were obtained from subjects with schizophrenia, bipolar disorder, major depressive disorder and matched controls.

Project description:We report 690K single-cell transcriptomes from nine different brain regions from adult mice (Frontal and Posterior Cortex, Hippocampus, Thalamus, Cerebellum, Striatum, Globus Pallidus externus/Nucleus Basalis, Entopeduncular / Subthalamic Nuclei, & Substantia Nigra / Ventral Tegmental Area).

Project description:We report the miRNA-Seq and Nanostring mRNA data from regional brain samples after neonatal hypoxic-ischemic brain injury (induced by unilateral carotid artery ligation and 30 minutes at 8% oxygen in CD1 mice at postnatal day 9). Analyses are perfomed in the cerebellum, striatum/thalamus, and whole cortex.

Project description:We predicted that eGenes linked to schizophrenia would share substantial downstream transcriptomic changes with a common direction of effect (termed “convergence”). Although convergence has been described in the context of loss-of-function autism spectrum disorder risk genes, these rare mutations almost never co-occur in the same individual. The convergent impact of common variants which are frequently inherited together, and the impacts of which are apparent only in aggregate remain unknown. We targeted twenty-one schizophrenia eGenes in iGLUTs using pooled and arrayed CRISPR-based approaches, significantly perturbing seventeen (CALN1, CLCN3, DOC2A, FES, FURIN, GATAD2A, NAGA, PCCB, PLCL1, THOC7, TMEM219, SF3B1, SNAP91, SNCA, UBE2Q2L, ZNF823, ZNF804A), and resolving convergent impacts robust to experimental and donor effects. To test if convergence influenced the outcome when eGenes were inherited in combination (i.e. if eGene effects sum linearly according to the additive model), we compared manipulation of eGenes one at a time and in groups defined by annotated functions at the synapse (“synaptic”: SNAP91, CLCN3, PLCL1, DOC2A, SNCA), or regulating transcription (“regulatory”: ZNF823, INO80E, SF3B1, THOC7, GATAD2A), or with un-related non-synaptic, non-regulatory biology (“multi-function”: CALN1, CUL9, TMEM219, PCCB, FURIN), and random combinations thereof. Altogether, with broad relevance across complex polygenic disease our work begins to experimentally determine answers to the long-standing question of how risk variants interact in human neurons.

Project description:G72 transgenic (TG, transgenic mice carrying the G72/G30 locus) and wildtype (WT) mice with a CD1 background were used for transcriptome data acquisition. Importantly, three different brain regions, i.e., the retrosplenial cortex, the hippocampus and thalamus, of animals from both sexes were investigated. In total, eight WT control animals (four ♂, age: 23.14 ± 0.00 wks; four ♀, age: 23.46 ± 0.11 wks) and eight G72 transgenic mice (four ♂, age: 23.14 ± 0.00 wks; four ♀, age: 23.14 ± 0.00 wks) were used for dissection of the cortex, thalamus and hippocampus for subsequent transcriptome analysis. Our data allow new insight into relevant alterations in gene transcript levels in G72 mice and allow the reader/user to carry out additional complex analyses to characterize potential sex-, age- and brain-region-specific profiles in gene expression and related pathways. These analyses could trigger biomarker identification and drug research and development in schizophrenia research in the future.

Project description:The thalamus of the brain acts as a relay station; taking inputs from several parts of the brain and then sending the information to the cortex and vice versa. It is also the structure know to affected in several brain developmental disorders such as schizophrenia, autism spectrum disorders, bipolar disorders etc. Upon in situ hybridisation one can visualise the expression of the transcription factor Tcf7l2 to be highest in prosomeric regions of the thalamus throughout development. With this information in mind we set out to find out, if the expression of Tcf7l2 is essential for the identity of the thalamic structure. Therefore, Tcf7l2 was knocked (KO) out using Cre+mice at embryonic stage E18.5 and postnatal adult stage P60. The E18.5 Tcf7l2 KO is a total knockout and the P60 Tcf7l2 KO is neuron-specific knockout. Total RNA was extracted and sent for sequencing using Illumina 2500. The data obtained was aligned by HISAT2 alignment tool, and the excon read counts were gathered using htseq counts, and expression normalization and differential gene expression was analysed using DESeq2.

Project description:Genetic association studies provide evidence for a substantial polygenic component to schizophrenia, although the neurobiological mechanisms underlying the disorder remain largely undefined. Building on recent studies supporting a role for developmentally regulated epigenetic variation in the molecular etiology of schizophrenia, this study aimed to identify epigenetic variation associated with both a diagnosis of schizophrenia and elevated polygenic risk burden for the disease across multiple brain regions. Genome-wide DNA methylation was quantified in 262 post-mortem brain samples, representing tissue from four brain regions (prefrontal cortex, striatum, hippocampus and cerebellum) from 41 schizophrenia patients and 47 controls. We identified multiple disease-associated and polygenic risk score-associated differentially methylated positions and regions, many residing in the vicinity of genes previously implicated in schizophrenia including NCAM1, SYNPO, GBP4, PRDM9, GADD45B and DISC1. Our study represents the first analysis of epigenetic variation associated with schizophrenia across multiple brain regions and highlights the utility of polygenic risk scores for identifying molecular pathways associated with etiological variation in complex disease.