1,721,033 research outputs found
Microglia and macrophages of the central nervous system: the contribution of microglia priming and systemic inflammation to chronic neurodegeneration
Full text linkMicroglia, the resident immune cells of the central nervous system (CNS), play an important role in CNS homeostasis during development, adulthood and ageing. Their phenotype and function have been widely studied, but most studies have focused on their local interactions in the CNS. Microglia are derived from a particular developmental niche, are long-lived, locally replaced and form a significant part of the communication route between the peripheral immune system and the CNS; all these components of microglia biology contribute to maintaining homeostasis. Microglia function is tightly regulated by the CNS microenvironment, and increasing evidence suggests that disturbances, such as neurodegeneration and ageing, can have profound consequences for microglial phenotype and function. We describe the possible biological mechanisms underlying the altered threshold for microglial activation, also known as 'microglial priming', seen in CNS disease and ageing and consider how priming may contribute to turning immune-to-brain communication from a homeostatic pathway into a maladaptive response that contributes to symptoms and progression of diseases of the CNS
Systemic inflammation accelerates changes in microglial and synaptic markers in an experimental model of chronic neurodegeneration
No full textBacterial infections are a common cause of morbidity and mortality in the elderly, and particularly in individuals with a neurodegenerative disease. Experimental models of neurodegeneration have shown that LPS-induced systemic inflammation increases neuronal damage, a process thought to be mediated by activation of “primed” microglia. The effects of a real systemic bacterial infection on the innate immune cells in the brain and neuronal networks are less well described, and therefore, in this study we use the ME7 prion model to investigate the alterations in microglia activation and phenotype and synaptic markers in response to a low grade, live bacterial infection. Mice with or without a pre-existing ME7 prion-induced neurodegenerative disease were given a single systemic injection of live Salmonella typhimurium at early or mid-stage of disease progression. Immune activation markers CD11b and MHCII and pro-inflammatory cytokines were analyzed 4 weeks post-infection. Systemic infection with S. typhimurium resulted in an exaggerated inflammatory response when compared to ME7 prion mice treated with saline. These changes to inflammatory markers were most pronounced at mid-stage disease. Analysis of synaptic markers in ME7 prion mice revealed a significant reduction of genes that are associated with early response in synaptic plasticity, extracellular matrix structure and post-synaptic density, but no further reduction following systemic infection. In contrast, analysis of activity-related neuronal receptors involved in development of learning and memory, such as Grm1 and Grin2a, showed a significant decrease in response to systemic bacterial challenge. These changes were observed early in the disease progression and associated with reduced burrowing activity. The exaggerated innate immune activation and altered expression of genes linked to synaptic plasticity may contribute to the onset and/or progression of neurodegeneration
Cerebral and systemic inflammation in Dementia with Lewy bodies and Alzheimer's disease
No full textDataset supporting the thesis 'Inflammation in Dementia with Lewy bodies and Alzheimer’s disease' by Amin.
Datasets from two studies: 1) Cerebral inflammation in Dementia with Lewy bodies (CIDL) - a human post-mortem study, and 2) Systemic inflammation in Dementia with Lewy bodies and Alzheimer's disease (SILAD) - an observational clinical study.</span
The sickness behaviour and CNS inflammatory mediator profile induced by systemic challenge of mice with synthetic double-stranded RNA (poly I:C)
No full textPoly inosinic:poly cytidylic acid (poly I:C) is a synthetic double-stranded RNA and is a ligand for the Toll like receptor-3. This receptor is involved in the innate immune response to viral infection and poly I:C has been used to mimic the acute phase of a viral infection. The effects of TLR3 activation on brain function have not been widely studied. In the current study we investigate the spectrum of sickness behavioural changes induced by poly I:C in C57BL/6 mice and the CNS expression of inflammatory mediators that may underlie this. Poly I:C, at doses of 2, 6 and 12 mg/kg, induced a dose–responsive sickness behaviour, decreasing locomotor activity, burrowing and body weight, and caused a mild hyperthermia at 6 h. The 12 mg/kg dose caused significant hypothermia at later times. The Remo400 remote Telemetry system proved a sensitive measure of this biphasic temperature response. The behavioural responses to poly I:C were not significantly blunted upon a second poly I:C challenge either 1 or 3 weeks later. Plasma concentrations of IL-6, TNF-? and IFN-? were markedly elevated and IL-1? was also detectable. Cytokine synthesis within the CNS, as determined by quantitative PCR, was dominated by IL-6, with lesser inductions of IL-1?, TNF-? and IFN-? and there was a clear activation of cyclooxygenase-2 at the brain endothelium. These findings demonstrate clear CNS effects of peripheral TLR3 stimulation and will be useful in studying aspects of the effects of systemic viral infection on brain function in both normal and pathological situations
Long term impact of systemic bacterial infection on the cerebral vasculature and microglia
No full textBackground: Systemic infection leads to generation of inflammatory mediators that result in metabolic and behavioural changes. Repeated or chronic systemic inflammation leads to a state of innate immune tolerance: a protective mechanism against over-activity of the immune system. In this study we investigated the immune adaptation of microglia and brain vascular endothelial cells in response to systemic inflammation or bacterial infection. Methods: Mice were given repeated doses of lipopolysaccharide (LPS) or a single injection of live Salmonella typhimurium. Inflammatory cytokines were measured in serum, spleen and brain, and microglial phenotype studied by immunohistochemistry.mice were infected with Salmonella typhimurium and subsequently challenged with a focal unilateral, intracerebral injection of LPS. Results: Repeated systemic LPS challenges resulted in increased brain IL-1?, TNF? and IL-12 levels, despite attenuated systemic cytokine production. Each LPS challenge induced significant changes in burrowing behaviour. In contrast, brain IL-1? and IL-12 levels in Salmonella typhimurium infected mice increased over three weeks, with high interferon-? levels in the circulation. Behavioural changes were only observed during the acute phase of the infection. Microglia and cerebral vasculature display an activated phenotype, and focal intracerebral injection of LPS 4 weeks after infection results in an exaggerated local inflammatory response when compared to non-infected mice. Conclusions: These studies reveal that the innate immune cells in the brain do not become tolerant to systemic infection, but are primed instead. This may lead to prolonged and damaging cytokine production that may have aprofound effect on the onset and/ or progression of pre-existing neurodegenerative disease.Humans and animals are regularly exposed to bacterial and viral pathogens that can have a considerable impact on our day-to-day living [1]. Upon infection, a set of immune, physiological, metabolic, and behavioural responses is initiated, representing a highly organized strategy of the organism to fight infection. Pro-inflammatory mediators generated in peripheral tissue communicate with the brain to modify behaviour [2], which aids our ability to fight and eliminate the pathogen. The communication pathways from the site of inflammation to the brain have been investigated in animal models and systemic challenge with lipopolysaccharide (LPS) or double stranded RNA (poly I:C) have been widely used to mimic aspects of bacterial and viral infection respectively [3, 4]. These studies have provided evidence that systemically generated inflammatory mediators signal to the brain via both neural and humoral routes, the latter signalling via the circumventricular organs or across the blood-brain barrier (BBB). Signalling into the brain via these routes evokes a response in the perivascular macrophages (PVMs) and microglia, which in turn synthesise diverse inflammatory mediators including cytokines, prostaglandins and nitric oxide [2, 5, 6]. Immune-to-brain communication also occurs in humans who show changes in mood and cognition following systemic inflammation or infection, which are associated with changes in activity in particular regions of the CNS [7-9]. While these changes are part of our normal homeostasis, it is increasingly evident that systemic inflammation has a detrimental effect in animals and also humans, that suffer from chronic neurodegeneration [10, 11]. We, and others, have shown that microglia become primed by on-going neuropathology in the brain, which increases their response towards subsequent inflammatory stimuli, including systemic inflammation [12, 13] Similar findings have been made in aged rodents [14, 15], where it has been shown that there is an exaggerated behavioural and innate immune response in the brainto systemic bacterial and viral infections, but the molecular mechanisms underlying the microglial priming under these conditions is far from understood.Humans and animals are rarely exposed to a single acute systemic inflammatory event: they rather encounter infectious pathogens that replicate in vivo or are exposed to low concentrations of LPS over a prolonged period of time. There is limited information on the impact of non-neurotrophic bacterial infections on the CNS and whether prolonged systemic inflammation will give rise to either a hyper-(priming) or hypo-(tolerance) innate immune response in the brain in response to a subsequent inflammatory stimulus.In this study we measured the levels of cytokines in the serum, spleen and brain as well as assessing sickness behaviour following a systemic bacterial infection using attenuated Salmonella typhimurium SL3261: we compared the effect to that of repeated LPS injections. We show that Salmonella typhimurium caused acute, transient behavioural changes and a robust peripheral immune response that peaks at day 7. Systemic inflammation resulted in a delayed increase in cytokine production in the brain and priming of microglia, which persisted up to four weeks post infection. These effects were not mimicked by repeated LPS challenges. It is well recognised that systemic bacterial and viral infections are significant contributors to morbidity in the elderly [16], and it has been suggested that primed microglia play a role in the increased clinical symptoms seen in patients with Alzheimer’s disease who have systemic inflammation or infections [11, 17]. We show here that systemic infection leads to prolonged cytokine synthesis in the brain and also priming of brain innate immune cells to a subsequent focal inflammatory challenge in the brain parenchyma
The intrathecal CD163-haptoglobin-hemoglobin scavenging system in subarachnoid hemorrhage
No full textDelayed cerebral ischemia resulting from extracellular hemoglobin is an important determinant of outcome in subarachnoid hemorrhage. Hemoglobin is scavenged by the CD163-haptoglobin system in the circulation, but little is known about this scavenging pathway in the human central nervous system. The components of this system were analyzed in normal cerebrospinal fluid and after subarachnoid hemorrhage. The intrathecal presence of the CD163-haptoglobin-hemoglobin scavenging system was unequivocally demonstrated. The resting capacity of the CD163-haptoglobin-hemoglobin system in the normal central nervous system was 50,000 fold lower than that of the circulation. After subarachnoid hemorrhage, the intrathecal CD163-haptoglobin-hemoglobin system was saturated, as shown by the presence of extracellular hemoglobin despite detectable haptoglobin. Hemoglobin efflux from the central nervous system was evident, enabling rescue hemoglobin scavenging by the systemic circulation. Therefore, the central nervous system is not capable of dealing with significant intrathecal hemolysis. Potential therapeutic options to prevent delayed cerebral ischemia ought to concentrate on augmenting the capacity of the intrathecal CD163-haptoglobin-hemoglobin scavenging system and strategies to encourage Hb efflux from the brain
NEW ROLES FOR FC RECEPTORS IN NEURODEGENERATION-THE IMPACT ON IMMUNOTHERAPY FOR ALZHEIMER’S DISEASE
No full textThere are an estimated 18 million Alzheimer’s disease (AD) sufferers worldwide and with no disease modifying treatment currently available, development of new therapies represents an enormous unmet clinical need. AD is characterised by episodic memory loss followed by severe cognitive decline and is associated with many neuropathological changes. AD is characterised by deposits of amyloid beta (Aβ), neurofibrillary tangles, and neuroinflammation. Active immunisation or passive immunisation against Aβ leads to the clearance of deposits in transgenic mice expressing human Aβ. This clearance is associated with reversal of associated cognitive deficits, but these results have failed to translate to humans, with both active and passive immunotherapy failing to improve memory loss. One explanation for these observations is that certain anti-Aβ antibodies mediate damage to the cerebral vasculature limiting the top dose and potentially reducing efficacy. Fc gamma receptors (Fcγ) are a family of immunoglobulin like receptors which bind to the Fc portion of IgG, and mediate the response of effector cells to immune complexes. Data from both mouse and human studies suggest that cross-linking Fc receptors by therapeutic antibodies and the subsequent pro-inflammatory response mediates the vascular side effects seen following immunotherapy. Increasing evidence is emerging that Fc receptor expression on CNS resident cells, including microglia and neurons, is increased during aging and functionally involved in the pathogenesis of age-related neurodegenerative diseases. We propose that increased expression and ligation of Fc receptors in the CNS, either by endogenous IgG or therapeutic antibodies, has the potential to induce vascular damage and exacerbate neurodegeneration. To produce safe and effective immunotherapies for AD and other neurodegenerative diseases it will be vital to understand the role of Fc receptors in the healthy and diseased brain
Progress in developing rodent models of age-related macular degeneration (AMD)
No full textAge-related macular degeneration (AMD) is the leading cause of irreversible central vision loss, typically affecting individuals from mid-life onwards. Its multifactorial aetiology and the lack of any effective treatments has spurred the development of animal models as research and drug discovery tools. Several rodent models have been developed which recapitulate key features of AMD and provide insights into its underlying pathology. These have contributed to making significant progress in understanding the disease and the identification of novel therapeutic targets. However, a major caveat with existing models is that they do not demonstrate the full disease spectrum. In this review, we outline advances in rodent AMD models from the last decade. These models feature various hallmarks associated with AMD, including oxidative stress, hypoxia, immune dysregulation, genetic mutations and environmental risk factors. The review summarises the methods by which each model was created, its pathological characteristics as well as its relation to the disease in humans
The role of adrenal morphology in high fat diet-induced anxiety in mature adult mice
No full textBackground/Aims: We have shown effects of both maternal and postweaning HF diet-induced obesity to increase anxiety and corticosterone output in mature adult mice, suggesting changes in the regulation of the hypothalamo-pituitary adrenal (HPA) axis. The current study investigated glucocorticoid (GR) and mineralocorticoid (MR) receptors in key brain regions of these mice, as well as FKBP51, a negative modulator of these receptors that is associated with anxiety-related disorders.
Method: Female C57BL/6 mice were fed either HF (HF: 45% kcal fat) or control diet (C: 7% kcal fat) 6 weeks before mating and throughout pregnancy and lactation. Male and female offspring were fed C or HF diet from weaning (3 weeks) (CC: n=7-8; CHF: n=4-7; HFC: n=7-9; HFHF: n=6-8/sex). In 52-week offspring brain (hippocampus [CA3] and hypothalamus [PVN]), GR, MR and FKBP51 mRNA levels were measured (RT-PCR). Data were analysed by mixed effects model (SPSS).
Results: In 52 week males, maternal HF diet reduced MR (P<0.001) and increased FKBP51 (P<0.01) in CA3. Postweaning HF diet also increased FKBP51 (P<001) in CA3 in males. In females, postweaning HF diet reduced MR (P<0.01) in CA3 but increased MR (P<0.05) and FKBP51 (P<0.001) in PVN. GR was unaffected in either sex by maternal or postweaning HF diet in PVN or CA3.
Conclusions: Changes in key factors in feedback mechanisms of the HPA axis in the mature adult brain suggest that maternal and postweaning HF diets may have long-term effects on stress responsiveness in a sex-specific manner. The increase in FKBP51 in both males and females following postweaning HF diet could be linked to the increased basal corticosterone we have previously observed in these animals, contributing to their heightened anxiety
Increase in Matrix Metaloproteinase‐10 is associated with tau, neurodegeneration and reduced brain perfusion in the right temporal lobe
No full textBackground: blood brain barrier dysfunction amplifies neuroinflammation, which may drive Alzheimer’s Dementia (AD) pathology. Regional cerebral blood flow (RCBF), measured by HMPAO SPECT, is an established biomarker for AD diagnosis. Matrix Metalloproteinase-10 (MMP-10), an enzyme involved in blood brain barrier function through regulating the breakdown of extracellular matrix, was recently proposed as a biomarker of progression to AD. In this study, we examine the relationship between RCBF and levels of MMP-10 in the cerebrospinal fluid (CSF).Materials and methods: datasets of 91 participants from a heterogenous clinical cohort, investigated for dementia due to cognitive complaints were analysed. CSF levels of MMP-10 were measured using the OLINK proximity extension array platform. HMPAO SPECT scans were analysed using Statistical Parametric Mapping (SPM). A univariate linear regression model was used in SPM to quantify the impact of MMP-10 changes on brain perfusion.Results: SPM results showed that higher levels of MMP-10 in CSF are associated with significant reduction in RCBF (family-wise error corrected pConclusion: increased levels of MMP-10 in CSF have been associated with blood brain barrier vulnerability and faster cognitive decline in AD. Here we identified a right sided neuroimaging signature in RCBF with increasing levels MMP-10. This may indicate that by the time of symptoms onset the right side is the fastest progressing as it is catching up with the left side. Right sided changes have been previously associated with delusions, disinhibition and irritability in AD and linked with increased carer burden. The significant reduction in RCBF of the right temporal lobe identified in our study, further reinforces a role for MMP-10 as a marker of progression to AD
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