Project description:Gain-of-function PPM1D mutations attenuate ischemic stroke

Project description:Elderly patients suffer more brain damage in comparison with young patients from the same ischemic stroke. In that regard, it is imperative to investigate the factors responsible for decreased resistance to anti-ischemic/hypoxic injury in the aged brain. We conducted analysis of the gene expression pattern on our samples (Transient MCAO for 60 minutes established acute ischemic stroke followed by 3 days reperfusion) by the Affymetrix rat 230 2.0 chip.

Project description:The high incidence, mortality, and disability rate of ischemic stroke impose huge economic burdens on patients and social health care systems.N6-methyladenosine (m6A) is one of the most extensive RNA methylation modifications in eukaryotes and participates in the pathogenesis of numerous diseases including ischemic stroke. Peripheral blood neutrophils are forerunners after ischemic brain injury and exert crucial functions.However, the underlying mechanisms of neutrophils in ischemic stroke need to be further clarified. This study aims to explore the transcriptional profiles of m6A modification in neutrophils of patients with ischemic stroke. The Arraystar Human m6A-mRNA&lncRNA Epitranscriptomic microarray analysis was performed on the peripheral blood neutrophils of 3 patients with ischemic stroke and 3 healthy controls, providing the clinical significance of m6A modification on ischemic stroke.

Project description:Background: Previous study showed that stroke may be a potential first sign of neoplasia. But the relationship between them remains unclear. Besides, ischemic stroke is a complex brain disease, which involves cell death or complex immune regulation. Thus, it is necessary to reveal the association of tumor immune microenvironment and cell death with ischemic stroke. Methods: Here, a photothrombosis-induced ischemic injury models of brain and skull was established. We compared and analyzed the pattern of gene expression profile between brain and skull after ischemic injury by transcriptome analysis. Further, we investigated the enrichment of relevant differential genes in cancer pathways and cell death pathways, and analyzed changes in the immune microenvironment after ischemic injury. Moreover, the pan-cancer genomic and prognosis analysis of ischemic injury related gene set were performed. Results: The results showed that the gene expression patterns were different in temporal and spatial locations after ischemic injury. We found that the effect on the transcriptome of the brain after skull ischemic injury was particularly large, but it could be recovered in a short period, while the effect on the skull after brain ischemic injury was long-lasting. The expression of genes related to ischemic injury is also associated with cell death and cancer hallmark pathways. In addition, changes in the abundance of immune cells indicate that brain ischemic injury may disrupt its immune microenvironment for a longer time, while skull can better balance the stability of immune microenvironment. Moreover, the brain ischemic injury-related gene sets are highly correlated with a variety of tumors, especially GBM, KIRC, LGG and UVM after stroke have a greater risk of death. Conclusion: This study gives us a new understanding of the role of the skull in brain ischemic injury, and reveals the association of tumor immune microenvironment and cell death with ischemic stroke.

Project description:Recent work has revealed that clonal hematopoiesis (CH) is associated with a higher risk of numerous age-related diseases, including ischemic stroke, however little is known about whether it influences stroke outcome. Studies suggest that leukocytes carrying CH driver mutations have an enhanced inflammatory profile, which could conceivably exacerbate brain injury after a stroke. Using a mouse model of Tet2-mediated CH, we tested the hypothesis that CH would lead to a poorer outcome after ischemic stroke by augmenting brain inflammation. In contrast to our hypothesis, Tet2-mediated CH had no effect on acute stroke outcome but led to reduced neurological deficits during the subacute phase. This improved neurological outcome was associated with lower levels of brain inflammation during this time, suggesting that Tet2-mediated CH may promote inflammation resolution in the brain post-stroke. While additional mechanistic studies are required, these findings may suggest that Tet2-mediated CH has beneficial actions on the post-stroke brain.

Project description:The secondary immune response to ischemic stroke progresses for days to weeks and involves glial and brain endothelium activation, recruitment of peripheral immune cells, and release of cytokines and chemokines. Whereas there is evidence that the acute inflammatory response contributes to the progression of ischemic brain injury, on the other hand, recent research points at a more multifaceted role of immune cells in brain ischemia, where immune cells participate in repair processes during the sub-acute and chronic stages. Here we used single-cell sequencing to gain deeper insights into the impact of ischemic stroke on signature and the heterogeneity of brain immune cells, endothelial cells and circulating leukocytes in mice.

Project description:Human nontransformed retinal pigment epithelia RPE-PPM1D-T2 cells carrying a truncating mutation in exon 6 of the PPM1D were exposed to ionising radiation (3 Gy) and subsequently were grown in semisolid media for 8 weeks. Six spheroid clones (RPE-PPM1D-T2-SA clones 1-6) were recovered and then were cultivated in adherent conditions. DNA was isolated from asynchronically growing parental RPE-PPM1D-T2 and transformed RPE-PPM1D-T2-SA-1 to 6 cells and was subjected to whole exome sequencing. DNA sequencing libraries were prepared using KAPA EvoPlus Kit (Roche) and were sequenced on the NovaSeq 6000 system using NovaSeq S1 Reagent Kit v1.5, 200 cycles (Illumina) with mean coverage >35 DNA samples, respectively. DNA fastq files were mapped to the hg19 reference using Novoalign (novoalign_2.08.03). PCR duplicates were removed from the BAM files using Picard Tools (picard-tools 1.129), and variant calling was performed using GATK HaplotypeCaller (3.8). Copy number variations (CNV) were analyzed using CNVkit version 0.7.4. Areas with median coverage >20 were included in the analysis. RNA fastq files were mapped to the hg19 reference using STAR (STAR-2.5.2b). The PCR duplicates were removed using Picard Tools (picard-tools 1.129).

Project description:The human immortalized brain endothelial cell line hCMEC/D3 is considered an in vitro model of the blood-brain-barrier. We aimed to characterize changes in the secretome of hCMEC/D3 subjected to oxygen and glucose deprivation (OGD) by SILAC, in order to identify new proteins involved in ischemia-triggered blood-brain-barrier disruption and test their potential as blood biomarkers for ischemic stroke diagnosis. After SILAC analysis, 19 proteins were found differentially secreted between OGD and normoxia/normoglycemia conditions (Fold Change>|1.4| and peptide count≥2). Protein folding and nucleic acid binding were the main molecular functions and epithelial adherens junctions and aldosterone signaling appeared as the main canonical pathways represented by OGD-secreted proteins. ANXA1, CLUS, IGFBP2, PRDX3, TIMP2 and COL1A2 were replicated by western blotting in 9 independent cell cultures. Five replicated proteins were analyzed in human serum samples of 38 ischemic stroke patients compared to 18 stroke-mimicking conditions and 18 healthy controls by ELISA. IGFBP2 showed increased blood levels when strokes were compared with stroke-mimicking patients (p<0.1). In conclusion, we characterized changes in the secretome of hCMEC/D3 after an ischemic insult and highlighted some candidates to become biomarkers for ischemic stroke diagnosis related to blood-brain-barrier disruption.

Project description:Human nontransformed retinal pigment epithelia RPE-PPM1D-T2 cells carrying a truncating mutation in exon 6 of the PPM1D were exposed to ionising radiation (3 Gy) and subsequently were grown in semisolid media for 8 weeks. Six spheroid clones (RPE-PPM1D-T2-SA clones 1-6) were recovered and then were cultivated in adherent conditions. RNA was isolated from asynchronically growing parental RPE-PPM1D-T2 and transformed RPE-PPM1D-T2-SA-1 to 6 cells and was subjected to whole exome sequencing. RNA sequencing libraries were prepared using KAPA RNA HyperPrep Kit (Roche) and were sequenced on the NovaSeq 6000 system using NovaSeq S1 Reagent Kit v1.5, 200 cycles (Illumina) with mean coverage >120 for RNA samples, respectively. RNA fastq files were mapped to the hg19 reference using Novoalign (novoalign_2.08.03). PCR duplicates were removed from the BAM files using Picard Tools (picard-tools 1.129), and variant calling was performed using GATK HaplotypeCaller (3.8). RNA fastq files were mapped to the hg19 reference using STAR (STAR-2.5.2b). The PCR duplicates were removed using Picard Tools (picard-tools 1.129). All parts of RNAseq data analysis were conducted in R, version 4.3.2. and RNAseq read counts were normalized using R package DESeq2. Fold change (FC) and log2FC were calculated from normalized reads, nontransformed RPE-PPM1D-T1 cells were considered a reference. Significance of differential expression for each gene was evaluated by Fisher's t-test with simulated p-values and Holm's p-value correction for multiple comparisons.

Project description:Stroke places a huge burden on society today, and great of studies were devoted for seeking safe and effective therapeutic strategy to improve the prognosis of stroke. Plasma exosome has exhibited its therapeutic potential against ischemia and reperfusion injury via ameliorating inflammation. To enhance therapeutic potential in patients with ischemic injury, we isolated exosomes from melatonin pretreated rat plasma and assessed the neurological protective effect in a rat model of focal cerebral ischemia. Treatment with melatonin enhanced plasma exosome therapeutic effect against ischemia induced inflammatory response and inflammasome mediated pyroptosis. In addition, we confirmed ischemic stroke induced pyroptotic cell death mainly occurred in microglia, while administration of melatonin treated exosome further effectively decreased infract volume and improved function recovery via regulation of TLR-4/NF-κB signaling pathway. Finally, the altered miRNAs profile in melatonin treated plasma exosomes demonstrated the regulatory mechanisms. This study suggests plasma exosome with melatonin pretreatment might be a more effective strategy for patients with ischemic brain injury. Further exploration of key molecules in plasma exosome may devote more therapeutic value for cerebral ischemic injury.