ABSTRACT
Microglia, the resident immune cells of the CNS, surveil, detect, and respond to various extracellular signals. Depending on the nature of these signals, an integrative microglial response can be triggered, resulting in a phenotypic transformation. Here, we evaluate whether hypercapnia modifies microglia phenotype in brainstem respiratory-related nuclei. Adult C57BL/6 inbred mice were exposed to 10% CO2 enriched air (hypercapnia), or pure air (control), for 10 or 30 min and immediately processed for immunohistochemistry to detect the ubiquitous microglia marker, ionized calcium binding adaptor molecule 1 (Iba1). Hypercapnia for thirty, but not 10 min reduced the Iba1 labeling percent coverage in the ventral respiratory column (VRC), raphe nucleus (RN), and nucleus tractus solitarius (NTS) and the number of primary branches in VRC. The morphological changes persisted, at least, for 60 min breathing air after the hypercapnic challenge. No significant changes were observed in Iba1+ cells in the spinal trigeminal nucleus (Sp5) and the hippocampus. In CF-1 outbred mice, 10% CO2 followed by 60 min of breathing air, resulted in the reduction of Iba1 labeling percent coverage and the number and length of primary branches in VRC, RN, and NTS. No morphological change was observed in Iba1+ cells in Sp5 and hippocampus. Double immunofluorescence revealed that prolonged hypercapnia increased the expression of CD86, an inflammatory marker for reactive state microglia, in Iba1+ cells in VRC, RN, and NTS, but not in Sp5 and hippocampus in CF-1 mice. By contrast, the expression of CD206, a marker of regulatory state microglia, persisted unmodified. In brainstem, but not in hippocampal microglia cultures, hypercapnia increased the level of IL1ß, but not that of TGFß measured by ELISA. Our results show that microglia from respiratory-related chemosensory nuclei, are reactive to prolonged hypercapnia acquiring an inflammatory-like phenotype.
ABSTRACT
The chemokine fractalkine (FKN, CX3CL1), a member of the CX3C subfamily, contributes to neuron-glia interaction and the regulation of microglial cell activation. Fractalkine is expressed by neurons as a membrane-bound protein (mCX3CL1) that can be cleaved by extracellular proteases generating several sCX3CL1 forms. sCX3CL1, containing the chemokine domain, and mCX3CL1 have high affinity by their unique receptor (CX3CR1) which, physiologically, is only found in microglia, a resident immune cell of the CNS. The activation of CX3CR1contributes to survival and maturation of the neural network during development, glutamatergic synaptic transmission, synaptic plasticity, cognition, neuropathic pain, and inflammatory regulation in the adult brain. Indeed, the various CX3CL1 forms appear in some cases to serve an anti-inflammatory role of microglia, whereas in others, they have a pro-inflammatory role, aggravating neurological disorders. In the last decade, evidence points to the fact that sCX3CL1 and mCX3CL1 exhibit selective and differential effects on their targets. Thus, the balance in their level and activity will impact on neuron-microglia interaction. This review is focused on the description of factors determining the emergence of distinct fractalkine forms, their age-dependent changes, and how they contribute to neuroinflammation and neurodegenerative diseases. Changes in the balance among various fractalkine forms may be one of the mechanisms on which converge aging, chronic CNS inflammation, and neurodegeneration.
ABSTRACT
Recently, the Chilean Senate approved the main ideas of a constitutional reform and a Neuro-rights bill. This bill aims to protect people from the potential abusive use of "neuro-technologies". Unfortunately, a literal interpretation of this law can produce severe negative effects both in the development of neuroscience research and medical practice in Chile, interfering with current treatments in countless patients suffering from neuropsychiatric diseases. This fear stems from the observation of the negative effects that recent Chilean legislations have produced, which share with the Neuro-Rights Law the attempt to protect vulnerable populations from potential abuse from certain medical interventions. In fact, Law 20,584 promulgated in 2012, instead of protecting the most vulnerable patients "incapacitated to consent", produced enormous, and even possibly irreversible, damage to research in Chile in pathologies that require urgent attention, such as many neuropsychiatric diseases. This article details the effects that Law 20.584 had on research in Chile, how it relates to the Neuro-Rights Law, and the potential negative effects that the latter could have on research and medical practice, if it is not formulated correcting its errors.
Subject(s)
Patient Rights , Vulnerable Populations , Chile , HumansABSTRACT
Recently, the Chilean Senate approved the main ideas of a constitutional reform and a Neuro-rights bill. This bill aims to protect people from the potential abusive use of "neuro-technologies". Unfortunately, a literal interpretation of this law can produce severe negative effects both in the development of neuroscience research and medical practice in Chile, interfering with current treatments in countless patients suffering from neuropsychiatric diseases. This fear stems from the observation of the negative effects that recent Chilean legislations have produced, which share with the Neuro-Rights Law the attempt to protect vulnerable populations from potential abuse from certain medical interventions. In fact, Law 20,584 promulgated in 2012, instead of protecting the most vulnerable patients "incapacitated to consent", produced enormous, and even possibly irreversible, damage to research in Chile in pathologies that require urgent attention, such as many neuropsychiatric diseases. This article details the effects that Law 20.584 had on research in Chile, how it relates to the Neuro-Rights Law, and the potential negative effects that the latter could have on research and medical practice, if it is not formulated correcting its errors.
Subject(s)
Humans , Patient Rights , Vulnerable Populations , ChileABSTRACT
Microglia serve key functions in the central nervous system (CNS), participating in the establishment and regulation of synapses and the neuronal network, and regulating activity-dependent plastic changes. As the neuroimmune system, they respond to endogenous and exogenous signals to protect the CNS. In aging, one of the main changes is the establishment of inflamm-aging, a mild chronic inflammation that reduces microglial response to stressors. Neuroinflammation depends mainly on the increased activation of microglia. Microglia over-activation may result in a reduced capacity for performing normal functions related to migration, clearance, and the adoption of an anti-inflammatory state, contributing to an increased susceptibility for neurodegeneration. Oxidative stress contributes both to aging and to the progression of neurodegenerative diseases. Increased production of reactive oxygen species (ROS) and neuroinflammation associated with age- and disease-dependent mechanisms affect synaptic activity and neurotransmission, leading to cognitive dysfunction. Astrocytes prevent microglial cell cytotoxicity by mechanisms mediated by transforming growth factor ß1 (TGFß1). However, TGFß1-Smad3 pathway is impaired in aging, and the age-related impairment of TGFß signaling can reduce protective activation while facilitating cytotoxic activation of microglia. A critical analysis on the effect of aging microglia on neuronal function is relevant for the understanding of age-related changes on neuronal function. Here, we present evidence in the context of the "microglial dysregulation hypothesis", which leads to the reduction of the protective functions and increased cytotoxicity of microglia, to discuss the mechanisms involved in neurodegenerative changes and Alzheimer's disease.
Subject(s)
Aging/metabolism , Brain/metabolism , Cellular Senescence/physiology , Microglia/metabolism , Neurodegenerative Diseases/metabolism , Synapses/metabolism , Aging/pathology , Animals , Brain/pathology , Humans , Inflammation Mediators/metabolism , Microglia/pathology , Neurodegenerative Diseases/pathology , Oxidative Stress/physiology , Synapses/pathologyABSTRACT
The aging process is driven by multiple mechanisms that lead to changes in energy production, oxidative stress, homeostatic dysregulation and eventually to loss of functionality and increased disease susceptibility. Most aged individuals develop chronic low-grade inflammation, which is an important risk factor for morbidity, physical and cognitive impairment, frailty, and death. At any age, chronic inflammatory diseases are major causes of morbimortality, affecting up to 5-8% of the population of industrialized countries. Several environmental factors can play an important role for modifying the inflammatory state. Genetics accounts for only a small fraction of chronic-inflammatory diseases, whereas environmental factors appear to participate, either with a causative or a promotional role in 50% to 75% of patients. Several of those changes depend on epigenetic changes that will further modify the individual response to additional stimuli. The interaction between inflammation and the environment offers important insights on aging and health. These conditions, often depending on the individual's sex, appear to lead to decreased longevity and physical and cognitive decline. In addition to biological factors, the environment is also involved in the generation of psychological and social context leading to stress. Poor psychological environments and other sources of stress also result in increased inflammation. However, the mechanisms underlying the role of environmental and psychosocial factors and nutrition on the regulation of inflammation, and how the response elicited for those factors interact among them, are poorly understood. Whereas certain deleterious environmental factors result in the generation of oxidative stress driven by an increased production of reactive oxygen and nitrogen species, endoplasmic reticulum stress, and inflammation, other factors, including nutrition (polyunsaturated fatty acids) and behavioral factors (exercise) confer protection against inflammation, oxidative and endoplasmic reticulum stress, and thus ameliorate their deleterious effect. Here, we discuss processes and mechanisms of inflammation associated with environmental factors and behavior, their links to sex and gender, and their overall impact on aging.
Subject(s)
Aging/physiology , Inflammation/immunology , Biological Factors , Chronic Disease , Environmental Exposure/adverse effects , Gene-Environment Interaction , Homeostasis , Humans , Oxidative Stress , Risk FactorsABSTRACT
The catastrophic emergency experienced by many countries with the COVID-19 pandemic emphasized the importance of bioethics for decision-making, both at the public health (equitable and effective policies) and at the clinical level. At the clinical level, the issues are the fulfillment of medical care demand with adequate health care teams, infrastructure, and supplies, and to cover critical care demands that surpass the available resources. Therefore, ethically correct approaches are required for the allocation of life sustaining resources. There are recommendations for the allocating life support during disasters based on multiple considerations, including ethical ones. However, the ethical criteria of existing guidelines are variable. Ethical principles usually considered are saving the greatest number of lives, saving the greatest number of years of life and the principle of the life cycle or the goal to give each individual equal opportunity to live through the various phases of life. However, the centrality of the human being and the search for the common good should be considered. Knowledge of public perspectives and moral benchmarks on these issues is essential. A successful assignment effort will require everyone's trust and cooperation. Decision making should be planned and discussed in advance, since in-depth deliberation will be extremely complex during the disaster. Our goal is to help the health care teams to wisely allocate resources in shortage periods.
Subject(s)
Clinical Decision-Making/ethics , Coronavirus Infections/epidemiology , Coronavirus Infections/therapy , Health Care Rationing/ethics , Pandemics , Pneumonia, Viral/epidemiology , Pneumonia, Viral/therapy , COVID-19 , Chile/epidemiology , Humans , Practice Guidelines as TopicABSTRACT
d-serine is synthesized by serine racemase (SR), a fold type II class of pyridoxal-5'-phosphate (PLP)-dependent enzyme. Whereas X-ray crystallography reveals that SR can be monomeric, reversible dimers having the highest racemase activity, or stable SR dimers resistant to both denaturation and reductive treatment, showing reduced racemase activity have been detected in microglia and astrocytes; the latter especially in oxidative or inflammatory environments. The microglial inflammatory environment depends largely on the TGFß1-mediated regulation of inflammatory cytokines such as TNFα and IL1ß. Here we evaluated the participation of TGFß1 in the regulation of SR, and whether that regulation is associated with the induction of stable SR dimers in the microglia from adult mice. In contrast to the effect of lipopolysaccharide (LPS), TGFß1 increased the formation of stable SR dimers and reduced the detection of monomers in microglia in culture. LPS or TGFß1 did not change the amount of total SR. The increase of stable SR dimer was abolished when TGFß1 treatment was done in the presence of the Smad inhibitor SIS3, showing that Smad3 has a role in the induction of stable dimers. Treatment with TGFß1â¯+â¯SIS3 also reduced total SR, indicating that the canonical TGFß1 pathway participates in the regulation of the synthesis or degradation of SR. In addition, the decrease of IL1ß, but not the decrease of TNFα induced by TGFß1, was mediated by Smad3. Our results reveal a mechanism for the regulation of d-serine through the induction of stable SR dimers mediated by TGFß1-Smad3 signaling in microglia.
Subject(s)
Microglia/metabolism , Racemases and Epimerases/metabolism , Signal Transduction/physiology , Smad3 Protein/metabolism , Transforming Growth Factor beta1/metabolism , Animals , Astrocytes/metabolism , Cell Culture Techniques , Cell Line , Crystallography, X-Ray , Cytokines/metabolism , Interleukin-1beta/metabolism , Lipopolysaccharides/adverse effects , Mice , Mice, Inbred C57BL , Microglia/drug effects , Racemases and Epimerases/chemistry , Signal Transduction/drug effects , Tumor Necrosis Factor-alpha/metabolismABSTRACT
The catastrophic emergency experienced by many countries with the COVID-19 pandemic emphasized the importance of bioethics for decision-making, both at the public health (equitable and effective policies) and at the clinical level. At the clinical level, the issues are the fulfillment of medical care demand with adequate health care teams, infrastructure, and supplies, and to cover critical care demands that surpass the available resources. Therefore, ethically correct approaches are required for the allocation of life sustaining resources. There are recommendations for the allocating life support during disasters based on multiple considerations, including ethical ones. However, the ethical criteria of existing guidelines are variable. Ethical principles usually considered are saving the greatest number of lives, saving the greatest number of years of life and the principle of the life cycle or the goal to give each individual equal opportunity to live through the various phases of life. However, the centrality of the human being and the search for the common good should be considered. Knowledge of public perspectives and moral benchmarks on these issues is essential. A successful assignment effort will require everyone's trust and cooperation. Decision making should be planned and discussed in advance, since in-depth deliberation will be extremely complex during the disaster. Our goal is to help the health care teams to wisely allocate resources in shortage periods.
Subject(s)
Humans , Pneumonia, Viral/therapy , Pneumonia, Viral/epidemiology , Health Care Rationing/ethics , Coronavirus Infections/therapy , Coronavirus Infections/epidemiology , Pandemics , Clinical Decision-Making/ethics , Chile/epidemiology , Practice Guidelines as TopicABSTRACT
The mechanics of ß-amyloid (Aß) clearance by astrocytes has not been univocally described, with different mediators appearing to contribute to this process under different conditions. Our laboratory has demonstrated neuroprotective effects of astroglial subtype 3 metabotropic glutamate receptor (mGlu3R), which are dependent on the secreted form of the amyloid precursor protein (sAPPα) as well as on Aß clearance; however, the mechanism underlying mGlu3R-induced Aß uptake by astrocytes remains unclear. The present study shows that conditioned medium from mGlu3R-stimulated astrocytes increased Aß uptake by naïve astrocytes through a mechanism dependent on sAPPα, since sAPPα depletion from conditioned medium inhibited Aß phagocytosis. Concordantly, recombinant sAPPα also increased Aß uptake. Since we show that both sAPPα and the mGlu3R agonist LY379268 increased expression of class-A scavenger receptor (SR-A) in astrocytes, we next determined whether SR-A mediates mGlu3R- or sAPPα-induced Aß uptake by using astrocyte cultures derived from SR-A knockout mice. We found that the effects of LY379268 as well as sAPPα on Aß uptake were abolished in SR-A-deficient astrocytes, indicating a major role for this scavenger receptor in LY379268- and sAPPα-stimulated Aß clearance by astrocytes. We also show results of coimmunoprecipitation and functional assays offering evidence of possible heterotrimerization of sAPPα with Aß and SR-A which could allow Aß to enter the astrocyte. In conclusion the present paper describes a novel pathway for Aß clearance by astrocytes involving sAPPα as an enhancer of SR-A-dependent Aß phagocytosis.
Subject(s)
Amyloid beta-Protein Precursor/metabolism , Astrocytes/metabolism , Receptors, Metabotropic Glutamate/metabolism , Scavenger Receptors, Class A/metabolism , Amino Acids/pharmacology , Amyloid beta-Protein Precursor/genetics , Animals , Bridged Bicyclo Compounds, Heterocyclic/pharmacology , Cell Survival , Cells, Cultured , Culture Media, Conditioned , Humans , Mice , Mice, Inbred ICR , Mice, Knockout , Phagocytosis , Primary Cell Culture , Rats, Wistar , Receptors, Metabotropic Glutamate/agonists , Scavenger Receptors, Class A/drug effects , Scavenger Receptors, Class A/geneticsABSTRACT
A mild chronic inflammatory state, like that observed in aged individuals, affects microglial function, inducing a dysfunctional phenotype that potentiates neuroinflammation and cytotoxicity instead of neuroprotection in response to additional challenges. Given that inflammatory activation of microglia promotes increased release of D-serine, we postulate that age-dependent inflammatory brain environment leads to microglia-mediated changes on the D-serine-regulated glutamatergic transmission. Furthermore, D-serine dysregulation, in addition to affecting synaptogenesis and synaptic plasticity, appears also to potentiate NMDAR-dependent excitotoxicity, promoting neurodegeneration and cognitive impairment. D-serine dysregulation promoted by microglia could have a role in age-related cognitive impairment and in the induction and progression of neurodegenerative processes like Alzheimer's disease.
Subject(s)
Aging/physiology , Central Nervous System/metabolism , Microglia/metabolism , Serine/metabolism , Animals , Humans , Neurodegenerative Diseases/metabolismABSTRACT
Late onset Alzheimer disease's (LOAD) main risk factor is aging. Although it is not well known which age-related factors are involved in its development, evidence points out to the involvement of an impaired amyloid-ß (Aß) clearance in the aged brain among possible causes. Glial cells are the main scavengers of the brain, where Scavenger Receptor class A (SR-A) emerges as a relevant player in AD because of its participation in Aß uptake and in the modulation of glial cell inflammatory response. Here, we show that SR-A expression is reduced in the hippocampus of aged animals and APP/PS1 mice. Given that Aß deposition increases in the aging brain, we generated a triple transgenic mouse, which accumulates Aß and is knockout for SR-A (APP/PS1/SR-A-/-) to evaluate Aß accumulation and the inflammatory outcome of SR-A depletion in the aged brain. The lifespan of APP/PS1/SR-A-/- mice was greatly reduced, accompanied by a 3-fold increase in plasmatic pro-inflammatory cytokines, and reduced performance in a working memory behavioral assessment. Microglia and astrocytes lacking SR-A displayed impaired oxidative response and nitric oxide production, produced up to 7-fold more pro-inflammatory cytokines and showed a 12-fold reduction in anti-inflammatory cytokines release, with conspicuous changes in lipopolysaccharide-induced glial activation. Isolated microglia from young and adult mice lacking SR-A showed a 50% reduction in phagocytic activity. Our results indicate that reduced expression of SR-A can deregulate glial inflammatory response and potentiate Aß accumulation, two mechanisms that could contribute to AD progression.
Subject(s)
Alzheimer Disease/metabolism , Astrocytes/metabolism , Brain/metabolism , Microglia/metabolism , Scavenger Receptors, Class A/metabolism , Alzheimer Disease/genetics , Alzheimer Disease/pathology , Amyloid beta-Peptides/metabolism , Amyloid beta-Protein Precursor/metabolism , Animals , Astrocytes/pathology , Brain/pathology , Cytokines/metabolism , Disease Models, Animal , Memory, Short-Term/physiology , Mice , Mice, Transgenic , Microglia/pathology , Nitric Oxide/metabolism , Oxidative Stress/physiology , Scavenger Receptors, Class A/geneticsABSTRACT
"Neural plasticity" refers to the capacity of the nervous system to modify itself, functionally and structurally, in response to experience and injury. As the various chapters in this volume show, plasticity is a key component of neural development and normal functioning of the nervous system, as well as a response to the changing environment, aging, or pathological insult. This chapter discusses how plasticity is necessary not only for neural networks to acquire new functional properties, but also for them to remain robust and stable. The article also reviews the seminal proposals developed over the years that have driven experiments and strongly influenced concepts of neural plasticity.
Subject(s)
Brain/physiology , Nerve Net/physiology , Neuronal Plasticity/physiology , Synapses/physiology , Animals , Homeostasis/physiology , Humans , Neural Networks, Computer , Neurons/physiologyABSTRACT
Today, there is enormous progress in understanding the function of glial cells, including astroglia, oligodendroglia, Schwann cells, and microglia. Around 150 years ago, glia were viewed as a glue among neurons. During the course of the twentieth century, microglia were discovered and neuroscientists' views evolved toward considering glia only as auxiliary cells of neurons. However, over the last two to three decades, glial cells' importance has been reconsidered because of the evidence on their involvement in defining central nervous system architecture, brain metabolism, the survival of neurons, development and modulation of synaptic transmission, propagation of nerve impulses, and many other physiological functions. Furthermore, increasing evidence shows that glia are involved in the mechanisms of a broad spectrum of pathologies of the nervous system, including some psychiatric diseases, epilepsy, and neurodegenerative diseases to mention a few. It appears safe to say that no neurological disease can be understood without considering neuron-glia crosstalk. Thus, this book aims to show different roles played by glia in the healthy and diseased nervous system, highlighting some of their properties while considering that the various glial cell types are essential components not only for cell function and integration among neurons, but also for the emergence of important brain homeostasis.
Subject(s)
Astrocytes/physiology , Microglia/physiology , Nervous System Physiological Phenomena , Neurons/physiology , Oligodendroglia/physiology , Schwann Cells/physiology , Astrocytes/cytology , Epilepsy/pathology , Epilepsy/physiopathology , Humans , Microglia/cytology , Multiple Sclerosis/pathology , Multiple Sclerosis/physiopathology , Nervous System/pathology , Nervous System/physiopathology , Neurodegenerative Diseases/pathology , Neurodegenerative Diseases/physiopathology , Neurons/cytology , Nitric Oxide/physiology , Oligodendroglia/cytology , Oxidative Stress , Schwann Cells/cytology , Synapses/physiology , Synaptic Transmission/physiologyABSTRACT
The activation of microglia has been recognized for over a century by their morphological changes. Long slender microglia acquire a short sturdy ramified shape when activated. During the past 20 years, microglia have been accepted as an essential cellular component for understanding the pathogenic mechanism of many brain diseases, including neurodegenerative diseases. More recently, functional studies and imaging in mouse models indicate that microglia are active in the healthy central nervous system. It has become evident that microglia release several signal molecules that play key roles in the crosstalk among brain cells, i.e., astrocytes and oligodendrocytes with neurons, as well as with regulatory immune cells. Recent studies also reveal the heterogeneous nature of microglia diverse functions depending on development, previous exposure to stimulation events, brain region of residence, or pathological state. Subjects to approach by future research are still the unresolved questions regarding the conditions and mechanisms that render microglia protective, capable of preventing or reducing damage, or deleterious, capable of inducing or facilitating the progression of neuropathological diseases. This novel knowledge will certainly change our view on microglia as therapeutic target, shifting our goal from their general silencing to the generation of treatments able to change their activation pattern.
Subject(s)
Brain/physiology , Cell Communication/physiology , Microglia/physiology , Neurodegenerative Diseases/physiopathology , Neurons/physiology , Animals , Astrocytes/cytology , Astrocytes/physiology , Brain/cytology , Calcium-Binding Proteins/genetics , Calcium-Binding Proteins/metabolism , Cell Movement , Cytokines/genetics , Cytokines/metabolism , Gene Expression , Humans , Mice , Microfilament Proteins/genetics , Microfilament Proteins/metabolism , Microglia/cytology , Neurodegenerative Diseases/genetics , Neurodegenerative Diseases/metabolism , Neurons/cytology , Neurotransmitter Agents/genetics , Neurotransmitter Agents/metabolism , Oligodendroglia/cytology , Oligodendroglia/physiology , Phagocytosis , Receptors, Cell Surface/genetics , Receptors, Cell Surface/metabolismABSTRACT
As we age, a large number of physiological and molecular changes affect the normal functioning of cells, tissues, and the organism as a whole. One of the main changes is the establishment of a state of systemic inflammatory activation, which has been termed "inflamm-aging"; a mild chronic inflammation of the aging organism that reduces the ability to generate an efficient response against stressor stimuli. As any other system, the nervous system undergoes these aging-related changes; the neuroinflammatory state depends mainly on the dysregulated activation of microglia, the innate immune cells of the central nervous system (CNS) and the principal producers of reactive oxygen species. As the brain ages, microglia acquire a phenotype that is increasingly inflammatory and cytotoxic, generating a hostile environment for neurons. There is mounting evidence that this process facilitates development of neurodegenerative diseases, for which the greatest risk factor is age. In this chapter, we will review key aging-associated changes occurring in the central nervous system, focusing primarily on the changes that occur in aging microglia, the inflammatory and oxidative stressful environment they establish, and their impaired regulation. In addition, we will discuss the effects of aged microglia on neuronal function and their participation in the development of neurodegenerative pathologies such as Parkinson's and Alzheimer's diseases.
Subject(s)
Aging/metabolism , Alzheimer Disease/metabolism , Central Nervous System/metabolism , Microglia/metabolism , Neurons/metabolism , Parkinson Disease/metabolism , Aged , Aged, 80 and over , Aging/genetics , Aging/pathology , Alzheimer Disease/genetics , Alzheimer Disease/pathology , Central Nervous System/pathology , Cytokines/biosynthesis , DNA Methylation , Histones/genetics , Histones/metabolism , Humans , I-kappa B Kinase/genetics , I-kappa B Kinase/metabolism , Inflammation , Microglia/pathology , Neurons/pathology , Oxidative Stress , Parkinson Disease/genetics , Parkinson Disease/pathology , Reactive Oxygen Species/metabolism , Shelterin Complex , Telomere-Binding Proteins/genetics , Telomere-Binding Proteins/metabolismABSTRACT
One of the pathological hallmarks of Alzheimer's disease (AD) is the presence of amyloid plaques, which are deposits of misfolded and aggregated amyloid-beta peptide (Aß). The role of the c-Abl tyrosine kinase in Aß-mediated neurodegeneration has been previously reported. Here, we investigated the therapeutic potential of inhibiting c-Abl using imatinib. We developed a novel method, based on a technique used to detect prions (PMCA), to measure minute amounts of misfolded-Aß in the blood of AD transgenic mice. We found that imatinib reduces Aß-oligomers in plasma, which correlates with a reduction of AD brain features such as plaques and oligomers accumulation, neuroinflammation, and cognitive deficits. Cells exposed to imatinib and c-Abl KO mice display decreased levels of ß-CTF fragments, suggesting that an altered processing of the amyloid-beta protein precursor is the most probable mechanism behind imatinib effects. Our findings support the role of c-Abl in Aß accumulation and AD, and propose AD-PMCA as a new tool to evaluate AD progression and screening for drug candidates.
Subject(s)
Alzheimer Disease/blood , Alzheimer Disease/enzymology , Amyloid beta-Peptides/blood , Protein Kinase Inhibitors/pharmacology , Proto-Oncogene Proteins c-abl/antagonists & inhibitors , Proto-Oncogene Proteins c-abl/blood , Alzheimer Disease/pathology , Animals , Cell Line , Hippocampus/drug effects , Hippocampus/metabolism , Hippocampus/pathology , Mice , Mice, Knockout , Mice, TransgenicABSTRACT
The pathological hallmarks of Alzheimer's disease (AD) are amyloid-ß (Aß) plaques, neurofibrillary tangles, and glia activation. The pathology also includes vascular amyloidosis and cerebrovascular disease. Vascular compromise can result in hypoperfusion, local tissue hypoxia, and acidosis. Activated microglia and astrocytes can phagocytose Aß through membrane receptors that include scavenger receptors. Changes in glial cells induced by extracellular acidosis could play a role in the development of AD. Here, we assess whether extracellular acidosis changes glial cell properties relevant for Aß clearance capacity. Incubation of glial cells on acidified culture medium (pH 6.9 or 6.5) for 24-48âh resulted in decreased cell diameter, with thinner branches in astrocytes, slight reduction in cell body size in microglia, a transient decrease in astrocyte adhesion to substrates, and a persistent decrease in microglia adhesion compared with control media (pH 7.4). Astrocyte Aß phagocytosis decreased at pH 6.9 and 6.5, whereas microglia phagocytosis only transiently decreased in acidified media. Scavenger receptors class B member I (SR-BI) increased and scavenger receptors-macrophage receptors with collagenous structures (SR-MARCO) decreased in astrocytes cultured at pH 6.5. In contrast, in microglia exposed to pH 6.5, expression of SR-BI and SR-MARCO increased and fatty acid translocase (CD-36) decreased. In conclusion, the acidic environment changed the adhesiveness and morphology of both microglia and astrocytes, but only astrocytes showed a persistent decrease in Aß clearance activity. Expression of scavenger receptors was affected differentially in microglia and astrocytes by acidosis. These changes in scavenger receptor patterns can affect the activation of glia and their contribution to neurodegeneration.
Subject(s)
Acidosis/physiopathology , Amyloid beta-Peptides/metabolism , Astrocytes/metabolism , Gene Expression Regulation/physiology , Microglia/metabolism , Phagocytosis/physiology , Receptors, Scavenger/genetics , Animals , Animals, Newborn , Astrocytes/drug effects , Cell Adhesion/drug effects , Cells, Cultured , Cerebral Cortex/cytology , Culture Media, Conditioned/pharmacology , Culture Media, Conditioned/toxicity , Gene Expression Regulation/drug effects , Glial Fibrillary Acidic Protein/metabolism , Microglia/drug effects , Nitric Oxide Synthase Type II/metabolism , Phagocytosis/drug effects , Rats , Receptors, Scavenger/metabolism , Time Factors , Vesicular Transport Proteins/metabolismABSTRACT
Aging is the main risk factor for Alzheimer's disease (AD); being associated with conspicuous changes on microglia activation. Aged microglia exhibit an increased expression of cytokines, exacerbated reactivity to various stimuli, oxidative stress, and reduced phagocytosis of ß-amyloid (Aß). Whereas normal inflammation is protective, it becomes dysregulated in the presence of a persistent stimulus, or in the context of an inflammatory environment, as observed in aging. Thus, neuroinflammation can be a self-perpetuating deleterious response, becoming a source of additional injury to host cells in neurodegenerative diseases. In aged individuals, although transforming growth factor ß (TGFß) is upregulated, its canonical Smad3 signaling is greatly reduced and neuroinflammation persists. This age-related Smad3 impairment reduces protective activation while facilitating cytotoxic activation of microglia through several cellular mechanisms, potentiating microglia-mediated neurodegeneration. Here, we critically discuss the role of TGFß-Smad signaling on the cytotoxic activation of microglia and its relevance in the pathogenesis of AD. Other protective functions, such as phagocytosis, although observed in aged animals, are not further induced by inflammatory stimuli and TGFß1. Analysis in silico revealed that increased expression of receptor scavenger receptor (SR)-A, involved in Aß uptake and cell activation, by microglia exposed to TGFß, through a Smad3-dependent mechanism could be mediated by transcriptional co-factors Smad2/3 over the MSR1 gene. We discuss that changes of TGFß-mediated regulation could at least partially mediate age-associated microglia changes, and, together with other changes on inflammatory response, could result in the reduction of protective activation and the potentiation of cytotoxicity of microglia, resulting in the promotion of neurodegenerative diseases.
