Ammonia is considered to be the main neurotoxin responsible for hepatic encephalopathy resulting from liver failure. Liver failure has been reported to alter expression and activity of P‐glycoprotein (P‐gp) and multidrug resistance‐associated protein 2 (Mrp2) at the blood–brain barrier (BBB). The aim of this study was to investigate whether ammonia is involved in abnormalities of expression and activity of P‐gp and Mrp2 at the BBB. Hyperammonemic rats were developed by an intraperitoneal injection of ammonium acetate (NH4Ac, 4.5 mmol/kg). Results showed that Mrp2 function markedly increased in cortex and hippocampus of rats at 6 h following NH4Ac administration. Significant increase in function of P‐gp was observed in hippocampus of rats. Meanwhile, such alterations were in line with the increase in mRNA and protein levels of P‐gp and Mrp2. Significant increase in levels of nuclear amount of nuclear factor‐κB (NF‐κB) p65 was also observed. Primarily cultured rat brain microvessel endothelial cells (rBMECs) were used for in vitro study. Data indicated that 24 h exposure to ammonia significantly increased function and expression of P‐gp and Mrp2 in rBMECs, accompanied with activation of NF‐κB. Furthermore, such alterations induced by ammonia were reversed by NF‐κB inhibitor. In conclusion, this study demonstrates that hyperammonemia increases the function and expression of P‐gp and Mrp2 at the BBB via activating NF‐κB pathway.
Over‐activation of microglia cells in the brain contributes to neurodegenerative processes promoted by the production of various neurotoxic factors including pro‐inflammatory cytokines and nitric oxide. Recently, accumulating evidence has suggested that mitochondrial dynamics are an important constituent of cellular quality control and function. However, the role of mitochondrial dynamics in microglial activation is still largely unknown. In this study, we determined whether mitochondrial dynamics are associated with the production of pro‐inflammatory mediators in lipopolysaccharide (LPS)‐stimulated immortalization of murine microglial cells (BV‐2) by a v‐raf/v‐myc carrying retrovirus (J2). Excessive mitochondrial fission was observed in lentivirus‐transfected BV‐2 cells stably expressing DsRed2‐mito following LPS stimulation. Furthermore, mitochondrial localization of dynamin‐related protein 1 (Drp1) (a key regulator of mitochondrial fission) was increased and accompanied by de‐phosphorylation of Ser637 in Drp1. Interestingly, inhibition of LPS‐induced mitochondrial fission and reactive oxygen species (ROS) generation by Mdivi‐1 and Drp1 knock‐down attenuated the production of pro‐inflammatory mediators via reduced nuclear factor kappa‐light‐chain‐enhancer of activated B cells (NF‐κB) and mitogen‐activated protein kinase (MAPK) signaling. Our results demonstrated for the first time that mitochondrial fission regulates mitochondrial ROS production in activated microglial cells and influences the expression of pro‐inflammatory mediators through the activation of NF‐κB and MAPK. We therefore suggest that mitochondrial dynamics may be essential for understanding pro‐inflammatory mediator expression in activated microglial cells. This could represent a new therapeutic approach for preventing neurodegenerative diseases.
Mutations in more than 10 genes are reported to cause familial amyotrophic lateral sclerosis (ALS). Among these genes, optineurin (OPTN) is virtually the only gene that is considered to cause classical ALS by a loss‐of‐function mutation. Wild‐type optineurin (OPTNWT) suppresses nuclear factor‐kappa B (NF‐κB) activity, but the ALS‐causing mutant OPTN is unable to suppress NF‐κB activity. Therefore, we knocked down OPTN in neuronal cells and examined the resulting NF‐κB activity and phenotype. First, we confirmed the loss of the endogenous OPTN expression after siRNA treatment and found that NF‐κB activity was increased in OPTN‐knockdown cells. Next, we found that OPTN knockdown caused neuronal cell death. Then, overexpression of OPTNWT or OPTNE50K with intact NF‐κB‐suppressive activity, but not overexpression of ALS‐related OPTN mutants, suppressed the neuronal death induced by OPTN knockdown. This neuronal cell death was inhibited by withaferin A, which selectively inhibits NF‐κB activation. Lastly, involvement of the mitochondrial proapoptotic pathway was suggested for neuronal death induced by OPTN knockdown. Taken together, these results indicate that inappropriate NF‐κB activation is the pathogenic mechanism underlying OPTN mutation‐related ALS.
Rats with pre‐hepatic portal hypertension because of partial portal vein ligation develop minimal hepatic encephalopathy (MHE) with hyperammonemia, impaired blood–brain barrier, mild brain edema, and severe mitochondrial changes in the hippocampus. The aim of this study was to evaluate changes of different neural cells in the cerebral cortex and the hippocampus. Animals were divided into two groups, MHE and sham. Astrocytes were studied by immunostaining with glial fibrillary acidic protein and S100β protein; neurons were immunostained with neuronal nuclear marker, microtubule associated protein‐2, and NF‐200 and capillaries with Nestin. The hypoxia‐inducible factor 1α (HIF‐1α) and its downstream proteins, P‐glycoprotein (P‐gp) and erythropoietin receptor (Epo‐R), were also evaluated. Astrocytes were increased in area and number only in the hippocampus, while S100β increased in both brain areas in MHE animals. Microtubule associated protein‐2 and NF‐200 immunoreactivities (‐ir) were significantly reduced in both areas. Hippocampal Nestin‐ir was increased in MHE animals. These cellular changes were similar to those described in ischemic conditions, thus HIF‐1α, P‐gp, and Epo‐R were also evaluated. A high expression of HIF‐1α in cortical neurons was observed in the MHE group. It is likely that this hypoxia‐like state is triggered via ammonia occupying the binding domain of HIF‐1α and thereby preventing its degradation and inducing its stabilization, leading to the over‐expression of P‐gp and the Epo‐R.
By using two structurally unrelated hydrogen sulfide (H2S) donors 5‐(4‐methoxyphenyl) ‐3H‐1, 2‐dithiole‐3‐thione (ADT) and sodium hydrosulfide (NaHS), this study investigated if H2S protected blood–brain barrier (BBB) integrity following middle cerebral artery occlusion (MCAO). ICR mice underwent MCAO and received H2S donors at 3 h after reperfusion. Infarction, neurological scores, brain edema, Evans blue (EB) extravasation, and tight junction protein expression were examined at 48 h after MCAO. We also investigated if ADT protected BBB integrity by suppressing post‐ischemic inflammation‐induced Matrix Metalloproteimase‐9 (MMP9) and Nicotinamide adenine dinucleotide phosphate (NADPH) oxidase (NOX). ADT increased blood H2S concentrations, decreased infarction, and improved neurological deficits. Particularly, ADT reduced EB extravasation, brain edema and preserved expression of tight junction proteins in the ischemic brain. NaHS also increased blood H2S levels and reduced EB extravasation following MCAO. Moreover, ADT inhibited expression of pro‐inflammatory markers induced Nitric Oxide Synthase (iNOS) and IL‐1β while enhanced expression of anti‐inflammatory markers arginase 1 and IL‐10 in the ischemic brain. Accordingly, ADT attenuated ischemia‐induced expression and activity of MMP9. Moreover, ADT reduced NOX‐4 mRNA expression, NOX activity, and inhibited nuclear translocation of Nuclear Factor Kappa‐B (NF‐κB) in the ischemic brain. In conclusion, H2S donors protected BBB integrity following experimental stroke possibly by acting through NF‐κB inhibition to suppress neuroinflammation induction of MMP9 and NOX4‐derived free radicals.
Recent studies have shown that sigma‐1 receptor orthodox agonists can inhibit neuroinflammation. SKF83959 (3‐methyl‐6‐chloro‐7,8‐hydroxy‐1‐[3‐methylphenyl]‐2,3,4,5‐tetrahydro‐1H‐3‐benzazepine), an atypical dopamine receptor‐1 agonist, has been recently identified as a potent allosteric modulator of sigma‐1 receptor. Here, we investigated the anti‐inflammatory effects of SKF83959 in lipopolysaccharide (LPS)‐stimulated BV2 microglia. Our results indicated that SKF83959 significantly suppressed the expression/release of the pro‐inflammatory mediators, such as tumor necrosis factor‐α (TNF‐α), interleukin‐1β (IL‐1β), inducible nitric oxide synthase (iNOS), and inhibited the generation of reactive oxygen species. All of these responses were blocked by selective sigma‐1 receptor antagonists (BD1047 or BD1063) and by ketoconazole (an inhibitor of enzyme cytochrome c17 to inhibit the synthesis of endogenous dehydroepiandrosterone, DHEA). Additionally, we found that SKF83959 promoted the binding activity of DHEA with sigma‐1 receptors, and enhanced the inhibitory effects of DHEA on LPS‐induced microglia activation in a synergic manner. Furthermore, in a microglia‐conditioned media system, SKF83959 inhibited the cytotoxicity of conditioned medium generated by LPS‐activated microglia toward HT‐22 neuroblastoma cells. Taken together, our study provides the first evidence that allosteric modulation of sigma‐1 receptors by SKF83959 inhibits microglia‐mediated inflammation.
Human immunodeficiency virus‐1 (HIV) is a public health issue and a major complication of the disease is NeuroAIDS. In vivo, microglia/macrophages are the main cells infected. However, a low but significant number of HIV‐infected astrocytes has also been detected, but their role in the pathogenesis of NeuroAIDS is not well understood. Our previous data indicate that gap junction channels amplify toxicity from few HIV‐infected into uninfected astrocytes. Now, we demonstrated that HIV infection of astrocytes results in the opening of connexin43 hemichannels (HCs). HIV‐induced opening of connexin43 HCs resulted in dysregulated secretion of dickkopf‐1 protein (DKK1, a soluble wnt pathway inhibitor). Treatment of mixed cultures of neurons and astrocytes with DKK1, in the absence of HIV infection, resulted in the collapse of neuronal processes. HIV infection of mixed cultures of human neurons and astrocytes also resulted in the collapse of neuronal processes through a DKK1‐dependent mechanism. In addition, dysregulated DKK1 expression in astrocytes was observed in human brain tissue sections of individuals with HIV encephalitis as compared to tissue sections from uninfected individuals. Thus, we demonstrated that HIV infection of astrocytes induces dysregulation of DKK1 by a HC‐dependent mechanism that contributes to the brain pathogenesis observed in HIV‐infected individuals.
Microglia are the resident macrophages of the central nervous system that survey the microenvironment for signals of injury or infection. The response to such signals induces an inflammatory response involving macrophages derived from both resident microglia and recruited circulating monocytes. Although implicated as contributors to autoimmune‐mediated injury, microglia/ macrophages have recently been shown to be critical for the important central nervous system regenerative process of remyelination. This functional dichotomy may reflect their ability to be polarized along a continuum of activation states including the well‐characterized cytotoxic M1 and regenerative M2 phenotypes. Here, we review the roles of microglia, monocytes and the macrophages which they give rise to in creating lesion environments favourable to remyelination, highlighting the specific roles of M1 and M2 phenotypes and how the pro‐regenerative role of the innate immune system is altered by ageing.
The receptor for advanced glycation end products (RAGE) gene expresses two major alternative splicing isoforms, full‐length membrane‐bound RAGE (mRAGE) and secretory RAGE (esRAGE). Both isoforms play important roles in Alzheimer's disease (AD) pathogenesis, either via interaction of mRAGE with β‐amyloid peptide (Aβ) or inhibition of the mRAGE‐activated signaling pathway. In the present study, we showed that heterogeneous nuclear ribonucleoprotein A1 (hnRNP A1) and Transformer2β‐1 (Tra2β‐1) were involved in the alternative splicing of mRAGE and esRAGE. Functionally, two factors had an antagonistic effect on the regulation. Glucose deprivation induced an increased ratio of mRAGE/esRAGE via up‐regulation of hnRNP A1 and down‐regulation of Tra2β‐1. Moreover, the ratios of mRAGE/esRAGE and hnRNP A1/Tra2β‐1 were increased in peripheral blood mononuclear cells from AD patients. The results provide a molecular basis for altered splicing of mRAGE and esRAGE in AD pathogenesis.
Mutation in TAR DNA binding protein 43 (TDP‐43) is a causative factor of amyotrophic lateral sclerosis and frontotemporal lobar degeneration. Neurodegeneration may not require the presence of pathogenic TDP‐43 in all types of relevant cells. Rather, expression of pathogenic TDP‐43 in neurons or astrocytes alone is sufficient to cause cell‐autonomous or non‐cell‐autonomous neuron death in transgenic rats. How pathogenic TDP‐43 in astrocytes causes non‐cell‐autonomous neuron death, however, is not clear. Here, we examined the effect of pathogenic TDP‐43 on gene expression in astrocytes. Microarray assay revealed that pathogenic TDP‐43 in astrocytes preferentially altered expression of the genes encoding secretory proteins. Whereas neurotrophic genes were down‐regulated, neurotoxic genes were up‐regulated. Representative genes Lcn2 and chitinase‐3‐like protein 1 were markedly up‐regulated in astrocytes from primary culture and intact transgenic rats. Furthermore, synthetic chitinase‐3‐like protein 1 induced neuron death in a dose‐dependent manner. Our results suggest that TDP‐43 pathogenesis is associated with the simultaneous induction of multiple neurotoxic genes in astrocytes, which may synergistically produce adverse effects on neuronal survival and contribute to non‐cell‐autonomous neuron death.
Accumulating evidence indicates that activated microglia contribute to the neuropathology involved in many neurodegenerative diseases and after traumatic injury to the CNS. The cytokine transforming growth factor‐beta 1 (TGF‐β1), a potent deactivator of microglia, should have the potential to reduce microglial‐mediated neurodegeneration. It is therefore perplexing that high levels of TGF‐β1 are found in conditions where microglia are chronically activated. We hypothesized that TGF‐β1 signaling is suppressed in activated microglia. We therefore activated primary rat microglia with lipopolysaccharide (LPS) and determined the expression of proteins important to TGF‐β1 signaling. We found that LPS treatment decreased the expression of the TGF‐β receptors, TβR1 and TβR2, and reduced protein levels of Smad2, a key mediator of TGF‐β signaling. LPS treatment also antagonized the ability of TGF‐β to suppress expression of pro‐inflammatory cytokines and to induce microglial cell death. LPS treatment similarly inhibited the ability of the TGF‐β related cytokine, Activin‐A, to down‐regulate expression of pro‐inflammatory cytokines and to induce microglial cell death. Together, these data suggest that microglial activators may oppose the actions of TGF‐β1, ensuring continued microglial activation and survival that eventually may contribute to the neurodegeneration prevalent in chronic neuroinflammatory conditions.
Parkinson's disease is the second most common neurodegenerative disease and its pathogenesis is closely associated with oxidative stress. Deposition of aggregated α‐synuclein (α‐Syn) occurs in familial and sporadic forms of Parkinson's disease. Here, we studied the effect of oligomeric α‐Syn on one of the major markers of oxidative stress, lipid peroxidation, in primary co‐cultures of neurons and astrocytes. We found that oligomeric but not monomeric α‐Syn significantly increases the rate of production of reactive oxygen species, subsequently inducing lipid peroxidation in both neurons and astrocytes. Pre‐incubation of cells with isotope‐reinforced polyunsaturated fatty acids (D‐PUFAs) completely prevented the effect of oligomeric α‐Syn on lipid peroxidation. Inhibition of lipid peroxidation with D‐PUFAs further protected cells from cell death induced by oligomeric α‐Syn. Thus, lipid peroxidation induced by misfolding of α‐Syn may play an important role in the cellular mechanism of neuronal cell loss in Parkinson's disease.
Spinocerebellar ataxia type 3 (SCA3) is one of at least nine inherited neurodegenerative diseases caused by an expansion of a polyglutamine tract within corresponding disease‐specific proteins. In case of SCA3, mutation of Ataxin‐3 results in aggregation of misfolded protein, formation of intranuclear as well as cytosolic inclusion bodies and cell death in distinct neuronal populations. Since cyclin‐dependent kinase‐5 (CDK5) has been shown to exert beneficial effects on aggregate formation and cell death in various polyglutamine diseases, we tested its therapeutic potential for SCA3. Our data show increased caspase‐dependent Ataxin‐3 cleavage, aggregation, and neurodegeneration in the absence of sufficient CDK5 activity. This disease‐propagating effect could be reversed by mutation of the caspase cleavage site in Ataxin‐3. Moreover, reduction of CDK5 expression levels by RNAi in vivo enhances SCA3 toxicity as assayed in a Drosophila model for SCA3. In summary, we present CDK5 as a potent neuroprotectant, regulating cleavage and thereby toxicity of Ataxin‐3 and other polyglutamine proteins.
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