Project description:Purpose: Subarachnoid hemorrhage (SAH) is fatal in approximately 40% of cases. However, among survivors up to 95% experience permanent disabilities: post-SAH syndrome, which include impaired memory, executive functions, emotional and cognitive disturbances. Up to 45% of SAH patients are unable to continue with their professional activities. The long-term cognitive deficits result from morphological brain damage, including atrophy of the temporomesial/hippocampal area, which correlates with decreased neurocognitive scores. The mechanisms of the remote brain damage following SAH remain unknown, which hinders the progress in identifying new therapeutic targets. To unveil the leading mechanisms of permanent cognitive abnormalities following SAH and origin of atrophy of the temporomesial/hippocampal area, we analyzed SAH-induced specific hippocampal genomic pathways, which may lead to long term morphological damage. methods: Hippocampal RNA of SAH and Control groups, obtained 4 days after SAH induced by perforation of the circle of Willis in mice, was processed and sequenced. Using the next-generation RNA sequencing we determined differentially expressed genes in the bilateral whole hippocampus remote from SAH and applied different functional analyses and clustering tools to determine the main molecular pathways. Results: Differential gene expression analysis detected 642 upregulated and 398 down-regulated genes (false discovery rate <0.10) in SAH compared to Control group. Functional analyses using IPA suite, Gene Ontology terms, REACTOME pathways, and MsigDB Hallmark gene set collections revealed suppression of oligodendrocytes/myelin related genes, and overexpression of genes related to complement system along with genes related to innate and adaptive immunity, and extracellular matrix reorganization. Interferon regulatory factors, TGF-β1 and BMP, were identified as major orchestrating elements in the hippocampal tissue response. The MEME-Suite identified binding motifs of Krüppel-like factors, zinc finger transcription factors, and interferon regulatory factors as overrepresented DNA promoter motifs. Conclusion: Our findings suggest that damage of the entorhinal cortex by the subarachnoid blood remotely triggers specific hippocampal response, which may include suppression of oligodendrocytes functioning due to anterograde degeneration of hippocampal afferents accompanied. Identification of the prominent molecular hippocampal pathways may lead to the development of new therapeutic approaches for the treatment of long-term SAH consequences.

Project description:To investigate the difference proteins after subarachnoid hemorrhage in human CSF.

Project description:The diagnosis of cerebral vasospasm after Subarachnoid-Hemorrhage is currently very difficult, additional tools such as blood biomarkers are necessary. We tested the ability of gene expression profiles of blood cells to predict vasospasm.

Project description: Not available

Project description:We report the altered expression profiles of lncRNA and mRNA in mice cortex after subarachnoid hemorrhage (SAH). Total of 617 lncRNAs transcripts and 444 mRNAs transcripts were aberrantly expressed at 24 hours after SAH.

Project description:We report the altered expression profiles of lncRNA and mRNA in mice cortex after subarachnoid hemorrhage (SAH). Total of 615 lncRNAs transcripts and 441 mRNAs transcripts were aberrantly expressed at 24 hours after SAH. SAH was induced in C57BL/6 mcie. The LncRNA and mRNA expression profiles in cortex of normal mice and SAH mice were examined by RNA-Seq.

Project description:The diagnosis of cerebral vasospasm after Subarachnoid-Hemorrhage is currently very difficult, additional tools such as blood biomarkers are necessary. We tested the ability of gene expression profiles of blood cells to predict vasospasm. 32 patients suffering subarachnoid-hemorrhage were included in this prospective monocentre study. They were grouped according to have a complicated cerebral vasospasm (Vasospasm) or not (Control) and Paired according to age (+/- 10 years), sex, Fisher grade (+/- 1), location, smoking (at least 3 first parameters). Gene expression profiles of blood cells were determined using 25,000~gene microarray. Blood sample: 2.5 mL harvested in PAXgene® Blood RNA tubes (PreAnalytix) RNA extraction: PAXgene® Blood RNA kit (Qiagen). We used a Universel Reference RNA (Stratagene). RNA amplification and labelling: kit Amino Allyl MessageAmp II (Ambion). We hybridized 4 microarrays per patient using pangenomic microarrays from the &quot;Réseau National des Génopôles&quot; (Illkirch, France). 2 slides were hybridized with reference RNA labelled Cy3 and patient RNA labelled Cy5, and 2 slides were hybridized with reference RNA labelled Cy5 and patient RNA labelled Cy3. Hybridation : Agilent protocol with few modifications : 750 ng of each labelled RNA were hubriddized at 60°C during 17 hours in an Aglient hybridization oven. After washings, Slides were scanned with a GenePix 4000B scanner (Molecular Devices). Image intensity data were extracted with GenePix Pro 6.0 analysis software. Quantification of Cy3 and Cy5 and selection of good spots were performed using the MAIA software (Novikov E and Barillot E. Software package for automatic microarray image analysis (MAIA). The ACUITY software was then used to normalize log ratios Cy3/Cy5 with Lowess non linear normalization, to filter out genes not present in at least 3 slides out of 4, to evaluate the reproducibility of the 4 microarrays of each patient (hierarchical clustering, Self Organizing Maps). Statistical analyses to insure reproducibility was performed using Excel (correlation coefficients, ANOVA). Only slides that passed all reprocubility tests were validated.

Project description:Cerebellar vasospasm is a severe complication of aneurysmal subarachnoid hemorrhage (aSAH) occurring for 30% of aSAH patients. To date, no biomarker of vasospasm occurrence exists and thus all aSAH patients undergo a preventive and dangerous treatment. In this study, we explored the miRNome of aSAH patients to detect potential expression differences between the patients developing a vasospasm (VSP+) or not (VSP-). The shared data include raw and normalized count miRNA data in aneurysmal subarachnoid hemorrhage patients with or without vasospasm.

Project description:Microglial necroptosis exacerbates neurodegenerative diseases, central nervous system injury and demonstrates a pro-inflammatory process, but its contribution to subarachnoid hemorrhage (SAH) is poorly characterized. BCL-2 homologous antagonist-killer protein (Bak1), a critical regulatory molecule of endogenous apoptosis, can be involved in the pathological process of necroptosis by regulating mitochondrial permeability. In this study, we revealed microglia undergo necroptosis after subarachnoid hemorrhage in vivo and vitro. We found that Bak1 was elevated at 24h after SAH. Knocked-down of Bak1 by adeno-associated virus attenuates microglial necroptosis, alleviates neuroinflammation, and improves neurological function after SAH. To further explore the corresponding mechanisms, oxyhemoglobin induces necroptosis in BV2 microglia, increasing Bak1 expression and mediating pro-inflammatory phenotype transformation, exacerbating oxidative stress and neuroinflammation. Abrogating BV2 Bak1 reduces necroptosis by downregulating the expression of phosphorylated pseudokinase mixed lineage kinase domain-like protein (p-MLKL), then downregulates pro-inflammatory phenotype gene expression. RNA-Seq shows that disrupting BV2 Bak1 downregulates multiple immune and inflammatory pathways and ameliorates cell injury by elevating Thrombospondin 1 (THBS1) expression. In summary, we identified a critical regulatory role for Bak1 in microglial necroptosis and neuroinflammation after SAH. Bak1 is expected to be a new therapeutic target, and it provides a new idea for the treatment strategy of SAH.

Project description:Hippocampal tissue in SAH mice showed reduced expression of acetyl-coenzyme A synthetase-2 (ACSS2) and abnormalities in the expression of ribosomal-related proteins, energy metabolism and cellular signal transduction.