Encephalitis ; metabolism ; pathology ; Microglia ; metabolism ; pathology ; Receptors, Leukotriene ; metabolism ; physiology

Alzheimer Disease/pathology* ; Animals ; C9orf72 Protein/metabolism* ; Mice ; Microglia/pathology* ; Neuronal Plasticity ; Neurons/pathology* ; Synapses/pathology*

OBJECTIVE: To explore the distribution of inflammatory cells and positive expression of P-se- lectin glycoprotein ligand-1 (PSGL-1) in infant brainstem tissue from hand-foot-mouth disease related fatal brainstem encephalitis. METHODS: Twenty brainstem samples from infants suffered from brainstem en- cephalitis were collected as the experimental group. Ten brainstem samples from infants died of non- brain diseases and injuries were collected as the control group. The distribution of inflammatory cells and the expression of PSGL-1 in the two groups were examined by immunohistochemical method. The characteristics of the positive cells were observed. RESULTS: In brainstem tissue of the experimental group, there were sleeve infiltrations of inflammatory cells around the vessels and in the glial nodule. Microglia was the most and following was neutrophils around the vessels and in the glial nodule. There was a significant statistical difference among microglias, neutrophils and lymphocytes (P < 0.05). There was no sleeve infiltration in the control group. PSGL-1 protein was expressed widely in inflammatory cells in the experimental group, especially in the inflammatory cells around the vessels and in the glial nodule. But PSGL-1 positive staining could be observed significantly less in the control group comparing with the experimental group (P < 0.05). CONCLUSION Microglia is the main type of inflammatory cells involved in the progress of the fatal disease. Moreover, PSGL-1 could participate in the pathogenesis of hand-foot-mouth disease related fatal brainstem encephalitis.
Brain Stem/pathology* ; Encephalitis/pathology* ; Hand, Foot and Mouth Disease/pathology* ; Humans ; Infant ; Membrane Glycoproteins/metabolism* ; Microglia/pathology* ; Neutrophils/pathology*

Parkinson's disease (PD), a progressive neurodegenerative disorder, is pathologically characterized by the progressive loss of dopaminergic neurons in the substantia nigra pars compacta (SNpc) and the presence of deposits of aggregated α-synuclein in intracellular inclusions known as Lewy bodies (LB). A highly localized inflammatory response mediated by reactive microglia is prominent in PD brains, but the mechanisms underlying the microglial activation are poorly understood. Recently some lines of evidences have shown that monomeric, or aggregated α-synuclein can activate microglia, the toxic factors released from activated microglia may lead to the cell death of dopaminergic neurons. This review is to summarize the recent progress on the role of α-synuclein induced microglia activation on the PD pathogenesis and progression, and to discuss the possible mechanisms involved.
Humans ; Microglia ; pathology ; Parkinson Disease ; etiology ; metabolism ; pathology ; alpha-Synuclein ; chemistry ; metabolism ; physiology

Parkinson's disease (PD) is the second most common neurodegenerative disease, characterized by loss of dopaminergic (DA) neurons in the dense part of the substantia nigra (SNpc). Postmortem analysis of PD patients and experimental animal studies found that microglial cell activation and increased levels of pro-inflammatory factors were common features of PD brain tissue. At the same time, the invasion and accumulation of peripheric immune cells were detected in the brain of PD patients. In this paper, peripheral inflammation across the blood-brain barrier (BBB), the misfolded α-synuclein (α-syn)-induced microglial cell activation and intracerebral inflammation in PD are summarized, providing potential therapeutic measures for delaying the onset of PD.
Animals ; Blood-Brain Barrier ; Dopaminergic Neurons ; pathology ; Humans ; Inflammation ; pathology ; Microglia ; Parkinson Disease ; pathology ; Substantia Nigra ; pathology ; alpha-Synuclein

OBJECTIVETo investigate the characteristics of microglial activation of hippocampus in experimental epileptic rats.

METHODSMorphological changes and proliferation of OX-42 positive cells were compared at different time points after status of epilepticus (SE) in lithium-pilocarpine induced epileptic rats.

RESULTSOX-42 positive cells were activated after SE, which increased to a peak at 3-7 d and in a relatively stable state at 7-14 d; then gradually decreased after 14d and returned to slightly higher level than previously at 21 d.

CONCLUSIONInflammatory injury, microglial activation and cell proliferation are closely related after seizures, microglial activation may be an important mechanism in the inflammatory injury of epilepsy.

Animals ; Cell Proliferation ; Disease Models, Animal ; Hippocampus ; cytology ; pathology ; Male ; Microglia ; pathology ; Rats ; Rats, Sprague-Dawley ; Status Epilepticus ; pathology

Alzheimer's disease (AD) is a most common neurodegenerative disease. The mechanisms underlying AD, especially late-onset AD, remain elusive. In the past few years, results from genome-wide association studies (GWAS) and systems approaches indicated that innate immune responses mediated by microglia played critical roles in AD. Functional analysis on animal models also showed that immune receptors or proteins expressed in microglia mediated Abeta-induced inflammation, or Abeta phagocytosis by microglia. Microglia plays double sword roles in AD. More work is warranted to elucidate the exact roles of microglia in AD, which will facilitate our better understanding of the mechanisms underlying AD.
Alzheimer Disease ; pathology ; Animals ; Disease Models, Animal ; Genome-Wide Association Study ; Humans ; Inflammation ; pathology ; Microglia ; physiology ; Phagocytosis ; Receptors, Immunologic ; physiology

OBJECTIVETo investigate the effects of aquaporin-4 (AQP4) gene knockout on the behavior changes and cerebral morphology during aging in mice,and to compare that of young and aged mice between AQP4 knockout mice (AQP4(-/-)) and wild type mice (AQP4(+/+)).

METHODSFifty-eight CD-1 mice were divided into four groups: young (2-3 months old) AQP4(-/-), aged (17-19 months old) AQP4(-/-), young AQP4(+/+) and aged AQP4(+/+). The activity levels and exploring behavior of mice were tested in open field. The neurons were stained with toluidine blue and NeuN, the astrocytes and microglia were stained with GFAP and Iba-1, respectively. The morphological changes of neuron, astrocyte and microglia were then analyzed.

RESULTSCompared with young mice, the total walking distance in open field of aged AQP4(+/+) mice and aged AQP4(-/-) mice decreased 41.2% and 44.1%, respectively (P<0.05); while there was no difference in the ratio of distance and retention time in the central area of open field. The density of neuron in cortex of aged AQP4(+/+) mice and aged AQP4(-/-) mice decreased 19.6% and 15.8%, respectively (P<0.05), while there was no difference in the thickness of neuron cell body in hippocampus CA1 region. The density of astrocyte in hippocampus CA3 region of aged AQP4(+/+) mice and aged AQP4(-/-) mice increased 57.7% and 64.3%, respectively (P<0.001), while there was no difference in the area of astrocyte. The area of microglia in hippocampus CA3 region of aged AQP4(+/+) mice and aged AQP4(-/-) mice increased 46.9% and 52.0%, respectively (P<0.01), while there was no difference in the density of microglia. Compared with AQP4(+/+) mice, the young and aged AQP4(-/-) mice showed smaller area of astrocyte in hippocampus CA3 region, reduced 18.0% in young mice and 23.6% in aged mice. There was no difference between AQP4(+/+) mice and AQP4(-/-) mice for other observed indexes.

CONCLUSIONAQP4 may be involved in change of astrocyte and astrocyte-related behaviors during aging. AQP4 gene knockout may have limited effects on the change of neuron, microglia and most neuronal behaviors in aging process.

Aging ; pathology ; Animals ; Aquaporin 4 ; genetics ; Astrocytes ; pathology ; Behavior, Animal ; Brain ; pathology ; Female ; Male ; Mice ; Mice, Knockout ; Microglia ; pathology ; Neurons ; pathology

It has been suggested that brain inflammation is important in aggravation of brain damage and/or that inflammation causes neurodegenerative diseases including Parkinson's disease (PD). Recently, systemic inflammation has also emerged as a risk factor for PD. In the present study, we evaluated how systemic inflammation induced by intravenous (iv) lipopolysaccharides (LPS) injection affected brain inflammation and neuronal damage in the rat. Interestingly, almost all brain inflammatory responses, including morphological activation of microglia, neutrophil infiltration, and mRNA/protein expression of inflammatory mediators, appeared within 4-8 h, and subsided within 1-3 days, in the substantia nigra (SN), where dopaminergic neurons are located. More importantly, however, dopaminergic neuronal loss was not detectable for up to 8 d after iv LPS injection. Together, these results indicate that acute induction of systemic inflammation causes brain inflammation, but this is not sufficiently toxic to induce neuronal injury.
Animals ; Astrocytes/pathology ; Cell Death ; Encephalitis/chemically induced/immunology/*pathology ; Injections, Intravenous ; Lipopolysaccharides/*pharmacology ; Male ; Microglia/pathology ; Neutrophil Infiltration ; Rats ; Rats, Sprague-Dawley ; Substantia Nigra/immunology/*pathology

BACKGROUND: Endothelin (ET), potent vasoconstricting peptide, are produced by endothelial cells after brain insults such as ischemia or infection and may play a role in the amplification or regulation of the microglia. In pathology of central nervous system, microglia might become activated leading to altered cellular function in response to brain injury. METHODS: Whole-cell patch clamp technique was used to study the effects of endothelin on changes of potassium currents in cultured rat microglia. Outward and inward rectifying potassium currents were recorded after application of depolarization and hyperpolarization pulses from -60 mV holding potential, respectively. RESULT: ET (100 nM) decreased the amplitude of outward rectifying potassium current and ET-3 was the most potent isoform. Both amplitude and slope conductance of inward rectifying potassium current were increased by ET. After application of ET, the reversal potential of inward potassium current was shifted to left relative to control. CONCLUSION: These results suggest that ET changes the potassium currents and membrane potential of microglia and this depolarizing effect of ET is related with the activation of microglia under pathological conditions of brain
Animals ; Brain ; Brain Injuries ; Central Nervous System ; Endothelial Cells ; Endothelins* ; Ischemia ; Membrane Potentials ; Microglia* ; Pathology ; Potassium* ; Rats*