Project description:Little is understood about the underlying cellular and molecular mechanisms related to hippocampus damage and glial activation after severe cerebral hypoperfusion.Efforts to explore the relationship between neuropathological and gene expression changes support a role for identifying novel molecular pathways by transcriptomic mechanisms. To investigate hippocampus-specific transcriptome profiling after severe cerebral hypoperfusion in mice

Project description:White matter damage caused by cerebral hypoperfusion is a major hallmark of subcortical ischemic vascular dementia (SIVD), which is the most common subtype of vascular cognitive impairment and dementia (VCID) syndrome. In an aging society, the number of SIVD patients is expected to increase; however, effective therapies have yet to be developed. To understand the pathological mechanisms, we analyzed the profiles of the cells of the corpus callosum after cerebral hypoperfusion in a preclinical SIVD model. We prepared cerebral hypoperfused mice by subjecting 2-month old male C57BL/6J mice to bilateral carotid artery stenosis (BCAS) operation. BCAS-hypoperfusion mice exhibited cognitive deficits at 4 weeks after cerebral hypoperfusion, assessed by novel object recognition test. RNA samples from the corpus callosum region of sham- or BCAS-operated mice were then processed using RNA sequencing. A gene set enrichment analysis using differentially expressed genes between sham and BCAS-operated mice showed activation of oligodendrogenesis pathways along with angiogenic responses. This database of transcriptomic profiles of BCAS-hypoperfusion mice will be useful for future studies to find a therapeutic target for SIVD.

Project description:Hippocampus-specific transcriptome profiling after severe cerebral hypoperfusion in mice

Project description:Background: Chronic cerebral hypoperfusion (CCH) is commonly accompanied by brain injury and glial activation. In addition to white matter lesions, the intensity of CCH greatly affects the degree of gray matter damage. However, little is understood about the underlying molecular mechanisms related to cortical lesions and glial activation following hypoperfusion. Efforts to investigate the relationship between neuropathological alternations and gene expression changes support a role for identifying novel molecular pathways by transcriptomic mechanisms. Methods: Chronic cerebral ischemic injury model was induced by the bilateral carotid artery stenosis (BCAS) using 0.16/0.18 mm microcoils. Cerebral blood flow (CBF) was evaluated using laser speckle contrast imaging (LSCI) system. Spatial learning and memory were assessed by Morris water maze test. Histological changes were evaluated by Hematoxylin staining. Microglial activation and neuronal loss were further examined by immunofluorescence staining. Cortex-specific gene expression profiling analysis was performed in sham and BCAS mice, and then validated by quantitative RT-PCR and immunohistochemistry (IHC). Results: In our study, compared with the sham group, the right hemisphere CBF of BCAS mice decreased to 69% and the cognitive function became impaired at 4 weeks postoperation. Besides, the BCAS mice displayed profound gray matter damage, including atrophy and thinning of the cortex, accompanied by neuronal loss and increased activated microglia. Gene set enrichment analysis (GSEA) revealed that hypoperfusion-induced upregulated genes were significantly enriched in the pathways of interferon (IFN)-regulated signaling along with neuroinflammation signaling. Ingenuity pathway analysis (IPA) predicted the importance of type I IFN signaling in regulating the CCH gene network. The obtained RNA-seq data were validated by qRT-PCR in cerebral cortex, showing consistency with the RNA-seq results. Also, IHC staining revealed elevated expression of IFN-inducible protein in cerebral cortex following BCAS-hypoperfusion. Conclusion: Overall, the activation of IFN-mediated signaling enhanced our understanding of the neuroimmune responses induced by CCH. The upregulation of IFN-regulated genes (IRGs) might exert a critical impact on the progression of cerebral hypoperfusion. Our improved understanding of cortex-specific transcriptional profiles will be helpful to explore potential targets for CCH.

Project description:Efforts to understand genetic variability involved in hippocampus damage and glial activation support a role for upstream regulation by epigenetic mechanisms. To investigate hippocampus-specific epigenetic profiling after severe cerebral hypoperfusion in mice

Project description:Little is understood about the underlying cellular and molecular mechanisms related to cerebral cortex damage and glial activation after severe cerebral hypoperfusion.Efforts to explore the relationship between neuropathological and gene expression changes support a role for identifying novel molecular pathways by transcriptomic mechanisms. To investigate cortex-specific transcriptome profiling after severe cerebral hypoperfusion in mice

Project description:Little is understood about the underlying cellular and molecular mechanisms related to brain microvessel damage and glial activation after severe cerebral hypoperfusion. Efforts to explore the relationship between neuropathological and gene expression changes support a role for identifying novel molecular pathways by transcriptomic mechanisms.

Project description:Chronic cerebral hypoperfusion (CCH) is a well-known risk factor for vascular dementia and other neurodegenerative disease, for which there are currently no effective medications available. MicroRNA (miRNA) are noncoding RNAS mediating post-translational silencing of genes, and has been extensively studied for their involvement in neurodegenerative disease. However, little is known about their roles in vascular dementia (VaD). In this work, a bilateral common carotid arteries occlusion (2-VO) surgery in rats was employed to induced CCH related cognitive dysfunction. Four months later, the hippocampi were dissected from 2-VO and sham operated rats for high-throughput profiling of miRNAs. Twelve differentially expressed miRNAs were identified according to a cutoff of |log2(Fold Change)|≥1 and p＜0.05. GO analysis of target genes revealed that the most relevant biological processes included the regulatory region nucleic acid binding, histone acetyltransferase binding, organic acid transmembrane transporter activity, L-amino acid transmembrane transporter activity. The cellular structure mainly included histone deacetylation complexes, endosomes, Golgi membranes, etc. And the involved molecular processes mainly included axon development, organ morphogenesis, macromolecular modification, regulation of neuron projection development, neuron development. This study provides a framework for understanding the alternations in hippocampus miRNA profiles underwent hypoxia insult.

Project description:BackgroundVascular cognitive impairment (VCI) is a significant contributor to dementia, yet the precise mechanisms underlying the cognitive decline associated with chronic cerebral hypoperfusion (CCH) remain unclear. This study investigated the molecular and epigenetic changes in the striatum, a brain region critical for motor function and cognition, following chronic hypoperfusion using a bilateral common carotid artery stenosis (BCAS) model in mice.MethodsRNA-seq was utilized to identify differentially expressed genes (DEGs) associated with hypoperfusion. In parallel, ATAC-seq was used to assess changes in chromatin accessibility within the striatum, providing insight into the epigenome and potential regulatory mechanisms. The integration of these datasets allowed us to correlate chromatin accessibility with transcriptional activity and to identify key transcription factors driving the observed gene expression changes.ResultsAnalysis of striatum-specific transcriptome revealed significant upregulation of immune response genes, particularly type II interferon signaling, and downregulation of neural activation pathways. Analysis of striatum-specific epigenome showed increased chromatin accessibility at promoters of immune-related genes. Integrated analysis highlighted PU.1 as a key transcription factor in upregulated pathways, while neural pathways lacked epigenetic regulation, revealing distinct molecular responses in the striatum following chronic hypoperfusion.ConclusionsOur findings indicate that upregulated pathways in the striatum following BCAS-induced CCH are driven by epigenetic changes, while downregulated pathways occur independently of these modifications. Additionally, PU.1 plays a critical role in mediating immune responses, offering a potential target for therapeutic intervention.

Project description:Cortex-specific transcriptome profiling after deeper cerebral hypoperfusion in mice