Project description:Microglia are resident CNS immune cells that are active sensors in healthy brain and versatile effectors under pathological conditions. Cerebral ischemia induces a robust neuroinflammatory response that includes marked changes in the gene expression and phenotypic profile of a variety of endogenous CNS cell types (astrocytes, neurons, microglia) as well as an influx of leukocytic cells (neutrophils, macrophages, T-cells) from the periphery. Many molecules and conditions can trigger a transformation of “resting” (or surveying) microglia to an “activated” (alerted/reactive) state. Here we review recent developments in the literature that relate to microglial activation in the experimental setting of in vitro and in vivo ischemia. We also present new data from our own laboratory demonstrating the direct effects of in vitro ischemic conditions on the microglial phenotype and genomic profile. Emphasis is placed on the role of specific molecular signaling systems such as hypoxia inducible factor-1 (HIF-1) and toll-like receptor-4 (TLR4) in regulating the microglial response in this setting. We then review histological and recent novel radiological data that confirms a key role for microglial activation in the setting of ischemic stroke in humans. We discuss recent progress in the pharmacological and molecular targeting of microglia in acute ischemic stroke. Finally, we explore how recent studies on ischemic preconditioning have increased interest in preemptively targeting microglial activation in order to reduce stroke severity. 12 arrays, 4 experimental groups, 3 replicates in each group, CN is control normoxia, CH is control hypoxia, TN is TLR4 knockout normoxia, TH is TLR4 knockout hypoxia.

Project description:PGC-1α overexpression in microglia protects against ischemia-induced brain damage in mice. To investigate the underlying mechanism of PGC-1α, we have employed whole mRNA microarray expression profiling as a discovery platform to identify genes with the potential to change the microglial function. Indeed, PGC-1α overexpression alters the gene expression profiles of microglia after AIS, this suggested that microglial PGC-1α might play an important role after ischemic stroke.

Project description:Many hospitals lack facilities for accurate diagnosis of acute ischemic stroke (AIS). Circular RNA (circRNA) is highly expressed in the brain and is closely associated with stroke. In this study, we examined whether the blood-borne circRNAs can be promising candidates as adjunctive diagnostic biomarkers and their pathophysiological roles after stroke. We profiled the blood circRNA expression in mice subjected to experimental focal cerebral ischemia, and validated the selected circRNAs in AIS patients. We demonstrated that 128, 198 and 789 circRNAs were significantly altered at 5 min, 3 h and 24 h after ischemic stroke, respectively.

Project description:Microglia are resident CNS immune cells that are active sensors in healthy brain and versatile effectors under pathological conditions. Cerebral ischemia induces a robust neuroinflammatory response that includes marked changes in the gene expression and phenotypic profile of a variety of endogenous CNS cell types (astrocytes, neurons, microglia) as well as an influx of leukocytic cells (neutrophils, macrophages, T-cells) from the periphery. Many molecules and conditions can trigger a transformation of “resting” (or surveying) microglia to an “activated” (alerted/reactive) state. Here we review recent developments in the literature that relate to microglial activation in the experimental setting of in vitro and in vivo ischemia. We also present new data from our own laboratory demonstrating the direct effects of in vitro ischemic conditions on the microglial phenotype and genomic profile. Emphasis is placed on the role of specific molecular signaling systems such as hypoxia inducible factor-1 (HIF-1) and toll-like receptor-4 (TLR4) in regulating the microglial response in this setting. We then review histological and recent novel radiological data that confirms a key role for microglial activation in the setting of ischemic stroke in humans. We discuss recent progress in the pharmacological and molecular targeting of microglia in acute ischemic stroke. Finally, we explore how recent studies on ischemic preconditioning have increased interest in preemptively targeting microglial activation in order to reduce stroke severity.

Project description:Senescence-associated alterations in microglia may have profound impact on cerebral homeostasis and stroke outcomes. However, the lack of a transcriptome-wide comparison between young and aged microglia in the context of ischemia limits our understanding of aging-related mechanisms. Herein, we performed bulk RNA sequencing analysis of microglia purified from cerebral hemispheres of young adult (10-week-old) and aged (18-month-old) mice 5 days after distal middle cerebral artery occlusion or sham operation. Considerable transcriptional differences were observed between young and aged microglia in healthy brains, indicating heightened chronic inflammation in aged microglia. Following stroke, the overall transcriptional activation was more robust in young microglia than in aged microglia. Gene clusters with functional implications in immune inflammatory responses, immune cell chemotaxis, tissue remodeling, and cell-cell interactions were markedly activated in microglia of young but not aged stroke mice. These alterations in microglial gene response may contribute to aging-driven vulnerability and poorer recovery after ischemic stroke.

Project description:We report the application of RNA sequencing technology for high-throughput profiling of brain transcriptomes in ischemic stroke mice. We find that changes in gene expression were detected in vehicle-treated ischemic brains when compared with the sham groups, with 1159 upregulated genes and 529 downregulated genes. While, the lactate preconditioning further enlarged the changes in gene expression of ischemic brains, with 2071 upregulated genes and 1003 downregulated genes. Finally, we show that the ischemic brains are much more immunologically activated by the lactate treatment. This study shows that the contributing roles of lactate in the brain injury after cerebral ischemia are complex and immunological mechanisms may be the major effects that exacerbate the brain injury of mice with cerebral ischemia.

Project description:Ischemic stroke is a common acute CNS disorder leading to nearly half a million deaths per year in Europe. The high mortality is primarily owed to the limited treatment options of restoring blood flow in a narrow time window of several hours. Furthermore, inflammatory processes in the days and weeks after ischemic stroke contribute to tissue loss and neurological deficits. The key cells that influence and control this inflammatory cascade are microglia, the innate immune cells of the CNS. Microglia can be influenced and activated by e.g. lipopolysaccharide (LPS),a bacterial cell membrane component. It has been previously shown, that repetitive LPS stimuli prior to infarction (termed immunological preconditioning) lead to reduced infarct volumina in mouse models of ischemic stroke. Furthermore, our laboratory has shown, that phosphoinositide-3 kinase gamma mediates microglial functions after LPS-preconditioning. Hence, the aim of this work was to characterize proteomic alterations in microglia with (I) ischemic stroke in general in the tMCAO (transient middle cerebral artery occlusion) mouse model of ischemic stroke, (II) the influence of LPS-preconditioning on microglial proteomic alterations after tMCAO and (III) the role of PI3Ky in the microglial proteomic changes after tMCAO and preconditioning. This was done by a single LPS injection 3 days before tMCAO in wildtype mice and mice with PI3Ky knockout or knockin of the kinase dead form of PI3Ky.

Project description:Molecular changes caused by metabolic reprogramming in ischemia and reperfusion cortex remain an unaddressed issue. Applying the quantitative proteomic and lactylproteomic analysis, we found that the molecular changes of ischemic brain tissues are quite different between ischemia and reperfusion stages. Conjoint analysis with a previous published transcriptome data further showed that the significant changes in protein levels and protein lactylations were mainly correlated with neurons in the reperfusion and ischemia stages, respectively. The significant upregulated lactylation of Aldoc, one of the glycolytic enzymes, at lysine 230 may contribute to the metabolic reprogramming by regulating glycolysis of astrocyte in ischemia phase, and which may further promote the lactate-derived lactylation of protein lysine residues. Our findings lay the foundation for future mechanistic studies of metabolic reprogramming from a novel perspective of lactylation, and illustrate that protein lactylations may play important roles in regulating the biological functions of neural cells after ischemic stroke.

Project description:Hypoxia-induced M1 polarization of microglia and the resultant inflammatory response are pivotal mechanisms in the development of hypoxic-ischemic encephalopathy (HIE). Recent studies have identified lactylation of histones as a novel epigenetic modification, in which lactate groups are added to lysine residues on histones. Lactate, a product of cellular respiration, accumulates in the cytoplasm when cells experience hypoxia due to the conversion of pyruvate by lactate dehydrogenase. Therefore, histone lactylation may be involved in the pathogenesis of HIE. This study aims to investigate the role and mechanism of histone lactylation in hypoxia-induced M1 polarization of microglia and the associated inflammation, with the goal of providing new insights for the research and treatment of HIE.

Project description:Background: Characterized by high incidence, mutilation, and death rate, acute ischemic stroke (AIS) has threatened people’s health seriously. Therefore, there is an urge need for early diagnosis and effective treatment of AIS. The purpose of this study was to clarify the regulatory role and potential molecular mechanism of miR-342-5p and circRNA_0008146 in AIS. Materials and Methods: Small RNA sequencing analysis was performed to screen differentially expressed miRNAs between the AIS and control group. Middle cerebral artery occlusion/reperfusion (MCAO/R) models were constructed in C57BL/6J mice. The circRNA_0008146 and miRNA expression levels were detected by quantitative real-time PCR. Assay kits were used to determine Fe2+ levels and assess a battery of oxidative stress indicators, including ROS, MDA, LPO, SOD, and GSH/GSSG. The content of ACSL4 was measured by Western blot. The neurobehavioral manifestation was evaluated using the modified Neurological Severity (mNSS) Score, rotarod test, and corner test. TTC staining was employed to detect cerebral infarction volume. Nissl staining was adapted to detect histological change and neuronal damage. Results: RNA sequencing analysis revealed miR-342-5p was significantly downregulated in the plasma of AIS patients. MiR-342-5p inhibited oxidative stress and RSL3-induced ferroptosis after cerebral ischemic-reperfusion injury in vivo by targeting ferroptosis-related gene ACSL4. CircRNA_0008146 acted as a sponge of miR-342-5p, and overexpression of circRNA_0008146 increased brain damage in stroke mice. CircRNA_0008146 contributed to ferroptosis in cerebral infraction via sponging miR-342-5p to regulate ACSL4. Conclusion: CircRNA_0008146/miR-342-5p/ACSL4 axis regulate ferroptosis after cerebral ischemia-reperfusion, which may be a potential therapeutic target for ischemic stroke.