Project description:Human cerebral malaria (HCM) is a severe complication of Plasmodium falciparum infection associated with high mortality rates predominantly in children that live in sub-Saharan Africa. Histine rich protein 2 (HRP2) is a diagnostic and prognostic marker that can be detected in peripheral blood, cerebrospinal fluid and cord blood. Recent studies confirm that HRP2 crossess the compromised blood brain barrier (BBB) during HCM and infiltrate brain parenchyma. Treatments with HRP2 in murine experimental cerebral malaria (ECM) model recapitulate these effects. We tested the hypothesis that treatment of induced pluripotent stem cells (iPSC)-derived brain cortical organoids with HRP2 will recapitulate the brain effects. We assessed the effects of HRP2 treatment on ultrastructure, expression of markers of viability and inflammation neurons, astrocytes and microglia in organoids. We tested the neuroprotective effects of Neuregulin 1 (NRG1) against the HRP2 treatment. In the study presented here, we assessed the inflammatory genes induced by HRP2 using the Immunology Panel on the nCounter system (NanoString) and results were analyzed using nSolver softaware.

Project description:Cerebral malaria is a severe complication of Plasmodium falciparum infection characterized by the loss of blood-brain barrier (BBB) integrity, which is associated with brain swelling and mortality in patients. P. falciparum-infected red blood cells and in!ammatory cytokines, like tumor necrosis factor alpha (TNF-a), have been implicated in the development of cerebral malaria, but it is still unclear how they contribute to the loss of BBB integrity. Here, a combination of transcriptomic analysis and cellular assays detecting changes in barrier integrity and endothelial activation were used to distinguish between the effects of P. falciparum and TNF-a on a human brain microvascular endothelial cell (HBMEC) line and in primary human brain microvascular endothelial cells. We observed that while TNF-a induced high levels of endothelial activation, it only caused a small increase in HBMEC permeability. Conversely, P. falciparum-infected red blood cells (iRBCLs) led to a strong increase in HBMEC permeability that was not mediated by cell death. Distinct transcriptomic pro"les of TNF-a and P. falciparum in HBMECs con"rm the differential effects of these stimuli, with the parasite preferentially inducing an endoplasmic reticulum stress response. Our results establish that there are fundamental differences in the responses induced by TNF-a and P. falciparum on brain endothelial cells and suggest that parasite-induced signaling is a major component driving the disruption of the BBB during cerebral malaria, proposing a potential target for much needed therapeutics.

Project description:Acute kidney injury (AKI) represents a common complication in critically ill patients that is associated with an increased morbidity and mortality. Currently, no effective treatment options are available. Here, we show that glutamine significantly attenuates leukocyte recruitment and inflammatory signaling in human and murine tubular epithelial cells (TECs). In a murine AKI model induced by ischemia-reperfusion-injury (IRI) we show that glutamine causes transcriptomic and proteomic reprogramming in renal TECs and neutrophils, resulting in decreased epithelial apoptosis, neutrophil recruitment and improved mitochondrial functionality and respiration provoked by an ameliorated oxidative phosphorylation. We identify the proteins glutamine gamma glutamyltransferase 2 (Tgm2) and apoptosis signal-regulating kinase (Ask1) as the major targets of glutamine in apoptotic signaling. Increased Tgm2 expression and reduced Ask1 activation result in decreased JNK activation leading to a diminished mitochondrial intrinsic apoptosis in kidneys upon IRI-induced AKI and under hypoxia or following TNFα-treatment of TECs. Consequently, glutamine administration attenuated kidney injury in vivo during AKI progression as well as TEC viability in vitro under inflammatory and hypoxic conditions.

Project description:Cerebral ischemia/reperfusion injury (CI/RI), including neurological behavior deficits, cerebral infarction, blood-brain barrier (BBB) dysfunction, and neuroinflammation, et al. is a severe challenge in treatment of ischemic stroke. Traditional Chinese medicine (TCM) with the characteristics of multi-components and multi-functions for multiple targets/pathways has been historically used in the treatment of stroke and post stroke recovery in China. QiShenYiQi (QSYQ), a representative component-based Chinese medicine, is capable of reducing organ injury caused by ischemia/reperfusion via multiple mechanisms. Recently, we have previously reported that the positive action of QSYQ against the acute phase of CI/RI is partly via modulation of neuroinflammatory response. However, the effects and underlying mechanisms of QSYQ on subacute phase of CI/RI remain unknown, which are aimed to investigate in present study. The pharmacological action of QSYQ treatment on brain damage was estimated in the experimental stroke rats underwent 90 min ischemia and 8 days reperfusion by assessing the neurological and locomotor deficits, cerebral infarction, brain edema, and BBB integrity. Furthermore, we used TMT-based quantitative proteomics technology to identify significantly differentially expressed proteins following QSYQ treatment, which could give important clues for revealing the possible mechanism underlying the positive role of QSYQ in CI/RI. Besides, immunohistochemistry, western blot analysis, RT-qPCR, and rat ELISA kits were executed to further verify the accuracy of proteomics analysis results. As a consequence, we found that treatment with QSYQ (600mg/kg) for 7 days obviously improved neurological and behavioral impairment, attenuated infarct volume and brain edema, and alleviated BBB breakdown in stroke rats. Bioinformatics analysis suggested that differentially expressed protein galectin-3 mediated inflammatory response was closely related to the beneficial effect of QSYQ. Results of immunohistochemistry, western blot analysis and RT-qPCR showed that the model rats treated with QSYQ (600mg/kg) markedly downregulated the mRNA and protein expression level of galectin-3 in brain tissues compared to the untreated stroke rats. In addition, the decrease of mRNA level in brain tissues and contents in serum of TNF-α and IL-6 following QSYQ treatment were also observed. These interesting finding manifested that the effective action of QSYQ against subacute phase of CI/RI was partly via regulating galectin-3 mediated inflammatory reaction.

Project description:Post-traumatic neuroinflammation is a key driver of secondary injury after traumatic brain injury (TBI). Pyroptosis, a proinflammatory form of programmed cell death, considerably activates strong neuroinflammation and amplifies the inflammatory response by releasing inflammatory contents. Therefore, treatments targeting pyroptosis may beneficially effects for the treatment of secondary brain damage after TBI. Herein, a cysteine-alanine-glutamine-lysine (CAQK) peptide-modified β-lactoglobulin (β-LG) nanoparticle was constructed to deliver disulfiram (DSF), C-β-LG/DSF, to inhibit pyroptosis and decrease neuroinflammation, thereby preventing TBI-induced secondary injury. In the post-TBI mice model, C-β-LG/DSF selectively targets the injured brain, increases DSF accumulation, and extends the time of the systemic circulation of DSF. C-β-LG/DSF can alleviate brain edema and inflammatory response, inhibit secondary brain injury, promote learning, and improve memory recovery in mice after trauma. Therefore, this study likely provided a new approach for reducing the secondary spread of TBI.

Project description:Plasmodium falciparum HRP2-induced damage to brain cortical organoids damage is Toll-Like Receptor dependent and is attenuated via Neuregulin-1/ErbB4 signaling

Project description:The brain and spinal cord are endowed with particular vascular systems, known as the blood-brain barrier (BBB) and blood-spinal cord barrier (BSCB) respectively, which maintain homeostasis between nervous parenchyma and peripheral circulation. Despite these common features, the BSCB presents structural and functional differences resulting in distinct vulnerability to pathological insults when compared to the BBB. Although, the heterogeneity of endothelial cell types underlies their remarkable ability to sub-specialize and provide specific requirements for a given vascular bed, very little is known concerning intrinsic differences between microvascular endothelial cells (MECs) derived from brain (BMECs) and spinal cord (SCMECs), including their response to inflammation. We used Agilent Whole Rattus Genome Microarray 4X44K to compare rat BMECs and SCMECs in both basal and inflammatory conditions; TNF-α-induced, TWEAK-induced and LPS-induced gene expression after 6 hr, 12 hr, 24 hr and 48 hr incubation.

Project description:Our study showed that fibroblasts significantly attenuated blood-brain barrier (BBB) disruption in an in vitro intracerebral hemorrhage (ICH) model. Since fibroblasts and brain microvascular endothelial cells were not in direct contact in this model, we reasoned that fibroblasts did so by secreting molecules with BBB-protective function. Here, we further screened fibroblast-secreted molecules in this in vitro ICH model by mass spectrometry.

Project description:Vascular disruption has been implicated in COVID-19 pathogenesis, and may predispose to the neurological sequelae associated with the condition (known as Long COVID), yet it remains unclear how blood-brain barrier (BBB) function is affected in these conditions. Here, we show that BBB disruption is evident during acute infection and in Long COVID patients with cognitive impairment, commonly referred to as brain fog. Using dynamic contrast-enhanced magnetic resonance imaging (DCE-MRI), we show BBB disruption correlated with brain volume changes. Transcriptomic analysis of peripheral blood mononuclear cells (PBMCs) revealed dysregulation of the coagulation system and a dampened adaptive immune response in individuals with brain fog. Accordingly, PBMCs showed increased adhesion to human brain endothelial cells in vitro, while exposure of endothelial cells to serum from Long COVID patients induced expression of inflammatory markers. Together, our data suggest that sustained systemic inflammation and persistent localised BBB dysfunction is a key feature of Long COVID-associated brain fog.

Project description:Neurobiological consequences of traumatic brain injury (TBI) result from a complex interplay of secondary injury responses and sequela that mediates chronic disability. Endothelial cells are important regulators of the cerebrovascular response to TBI. Our work demonstrates that genetic deletion of endothelial cell (EC)-specific EPH receptor A4 (EphA4) using conditional EphA4f/f/Tie2-Cre and EphA4f/f/VE-Cadherin-CreERT2 knockout (KO) mice, promotes blood-brain barrier (BBB) integrity and tissue protection, which correlates with improved motor function and cerebral blood flow recovery following controlled cortical impact (CCI) injury. scRNAseq of capillary-derived KO ECs showed increased differential gene expression of BBB-related junctional and actin cytoskeletal regulators, namely, A-kinase anchor protein 12, Akap12, whose presence at Tie2 clustering domains is enhanced in KO microvessels. Transcript and protein analysis of CCI-injured whole cortical tissue or cortical-derived ECs suggests EphA4 limits the expression of Cldn5, Akt, and Akap12 and promotes Ang2. Blocking the Tie2 receptor using sTie2-Fc, attenuated BBB and tissue protection and reversed Akap12 mRNA and protein levels in KO compared to WT cortical-derived ECs. Conversely, direct stimulation of Tie2 using Vasculotide, an angiopoietin-1 memetic peptide, phenocopied the neuroprotection. Finally, we report a noteworthy rise in soluble Ang2 in the sera of individuals with acute TBI, highlighting its promising role as a vascular biomarker for early detection of BBB disruption. Overall, we describe a novel contribution of the axon guidance molecule, EphA4, in mediating TBI microvascular dysfunction through negative regulation of Tie2/Akap12 signaling.