Regulation Of Microglial Function Research Articles

INPP5D inhibition attenuates amyloid pathology through the regulation of microglial functions

AbstractBackgroundAlzheimer’s disease (AD) is a progressive neurodegenerative disorder characterized by accumulated beta‐amyloid (Aβ) deposits and robust microgliosis. Recent genome‐wide association studies have identified genetic risk factors in late‐onset AD (LOAD) which are largely microglia. Among the risk factors, Inositol polyphosphate‐5‐phosphatase D (INPP5D) confers an increased risk of developing AD and is associated with increased plaque deposition. As a microglia‐specific lipid phosphatase, INPP5D negatively regulates signaling via several microglial cell surface receptors, including TREM2; however, the impact of INPP5D inhibition on AD pathology remains unclear.MethodsTo determine the impact of Inpp5d on disease pathogenesis and microglial phenotypes, we utilized the 5xFAD model expressing Inpp5d haplodeficiency.ResultsInpp5d deficiency perturbs microglial intracellular signaling pathways that regulate the immune response, including phagocytosis, microglia‐plaque engagement, and Aβ clearance. Importantly, Inpp5d haploinsufficiency leads to the preservation of cognitive function in 5xFAD mice. Furthermore, a novel spatial transcriptomic analysis revealed genetic profiles altered by Inpp5d haploinsufficiency are related to microglial functions, synaptic regulation, and immune cell activation.ConclusionThese data demonstrate that Inpp5d deficiency enhances microglial functions by increasing plaque clearance and preserves cognitive abilities in 5xFAD mice. Inhibition of INPP5D may serve as a potential therapeutic strategy targeting microglia for AD.

INPP5D inhibition attenuates amyloid pathology through the regulation of microglial functions.

AbstractBackgroundAlzheimer’s disease (AD) is a progressive neurodegenerative disorder characterized by cognitive decline, robust microgliosis, neuroinflammation, and neuronal loss. Genome‐wide association studies recently highlighted a prominent role for microglia in late‐onset AD (LOAD). Specifically, inositol polyphosphate‐5‐phosphatase (INPP5D) is selectively expressed in brain microglia and one of its common intronic variants (rs35349669; OR=1.08, 95%CI=1.06‐1.11) has been reported to be associated with increased risk of LOAD. INPP5D is linked to the triggering receptor expressed on myeloid cells 2 (TREM2) signaling, but little is known about the function of INPP5D in microglia and how INPP5D regulates TREM2‐related AD pathogenesis. Therefore, we aim to understand the role of INPP5D in microglia and AD pathology.MethodWe performed differential gene expression analysis to investigate INPP5D expression in LOAD and its association with plaque density using transcriptomic data from the Accelerating Medicines Partnership for Alzheimer’s Disease (AMP‐AD) cohort. We also performed quantitative real‐time PCR, immunoblotting, and immunofluorescence assays to assess INPP5D expression and microglial markers in the 5xFAD amyloid mouse model with INPP5D deficiency. Behavioral deficits were assessed by the Y‐maze assay in all animal cohorts at 4‐ and 6‐month of age. The primary microglial culture was used the evaluate the amyloid uptake ability of microglia.Result INPP5D gene expression was upregulated in LOAD and positively correlated with amyloid plaque density. Inpp5d expression increased as the disease progressed in the 5xFAD mice, and selectively in plaque‐associated microglia. Inpp5d deficiency mitigated the plaque burdens and neuropathology in the 5xFAD mice and further protected against behavioral deficits induced by amyloid pathology. Inpp5d deficiency modulates the microglial signaling, including Trem2 expression and Syk phosphorylation, and further upregulates the expression of the post‐synaptic marker. In the primary microglial culture, Inpp5d inhibition increased the uptake of fibril amyloid beta‐peptide.ConclusionOur findings show that INPP5D expression increases throughout the AD progression and is predominantly in plaque‐associated microglia. Importantly, INPP5D deficiency reduces Abeta pathology through the regulation of microglial functions, highlighting INPP5D as a potential therapeutic target.

β‐Lactolin Improves Mitochondrial Dysfunction in Aβ‐treated Mouse Hippocampal Neuronal Cells and a Human iPSC‐Derived Neuronal Cell Model of Alzheimer’s Disease

AbstractBackgroundMitochondrial dysfunctions are a key hallmark of Alzheimer’s disease (AD). β‐Lactolin, a whey‐derived glycine–threonine–tryptophan–tyrosine tetrapeptide, has been previously reported to prevent AD‐like pathologies in an 5×FAD mouse model via regulation of microglial functions. However, the direct effect of β‐lactolin on neuronal cells and neuronal mitochondrial functions remains unknown. Here, we investigated the effects of β‐lactolin on mitochondrial dysfunctions in amyloid β (Aβ)‐treated mouse hippocampal neuronal HT22 cells and human induced‐pluripotent cell (hiPSC)‐derived AD model neurons.MethodMouse hippocampal neuronal HT22 cell line, and hiPSC‐derived AD model neuron (PSEN1 P117L mutation) and its wild‐type control were used in this study. HT22 cells were treated with β‐lactolin (1–100 nM) for 1 hr, and Aβ42 (1–10 μM) was added for the next 23 hrs. Oxygen consumption rate was measured using extracellular flux analyzer. Intracellular ATP level was determined by luciferase activity. Cells were stained with MitoTracker, JC‐1, or MitoSOX fluorescent dye, and then mitochondrial morphologies, membrane potential, and oxidative stress, respectively, were examined by high content image analysis. Cell viability was measured by MTT assay. Gene expression levels were evaluated by RT‐PCR. hiPSC‐derived wild‐type and AD neurons were cultured for 14 days under β‐lactolin treatment, and mitochondrial morphologies and membrane potentials were analyzed.ResultHT22 cells treated with both β‐lactolin and Aβ exhibited increased oxygen consumption rate and cellular ATP concentrations compared to cells treated with Aβ alone, suggesting that β‐lactolin improves mitochondrial respiration and energy production. In high content image analysis, β‐lactolin attenuated Aβ‐induced mitochondrial fragmentation, membrane potential decrease, and excess oxidative stress, eventually preventing neuronal cell death. Treatments with β‐lactolin increased gene expression of mitofusin‐2, which contribute to mitochondrial fusion events. Finally, β‐lactolin attenuated impairment in both mitochondrial morphologies and membrane potentials in hiPSC‐derived AD model neurons, suggesting β‐lactolin shows a suppressing effect on human AD pathologies.Conclusionβ‐lactolin improved AD‐related neuronal mitochondrial dysfunctions and suppressed neuronal cell death in both mouse and human AD model neuronal cells. The dual function of β‐lactolin on both neuron and microglia marks an advantage in AD prevention.

The Innate and Adaptive Immune Cells in Alzheimer's and Parkinson's Diseases.

Alzheimer's disease (AD) and Parkinson's disease (PD) are the most common neurodegenerative disorders of the central nervous system (CNS). Increasing evidence supports the view that dysfunction of innate immune cells initiated by accumulated and misfolded proteins plays essential roles in the pathogenesis and progression of these diseases. The TLR family was found to be involved in the regulation of microglial function in the pathogenesis and progression of AD or PD, making it as double-edged sword in these diseases. Altered function of peripheral innate immune cells was found in AD and PD and thus contributed to the development and progression of AD and PD. Alteration of different subsets of T cells was found in the peripheral blood and CNS in AD and PD. The CNS-infiltrating T cells can exert both neuroprotective and neurotoxic effects in the pathogenesis and progression. Here, we review recent evidences for the roles of innate and adaptive immune cells in the pathogenesis and progression of AD and PD.

Mechanistic Role of Jak3 in Obesity-Associated Cognitive Impairments

Background and Aims: A compromise in intestinal mucosal functions is associated with several chronic inflammatory diseases. Previously, we reported that obese humans have a reduced expression of intestinal Janus kinase-3 (Jak3), a non-receptor tyrosine kinase, and a deficiency of Jak3 in mice led to predisposition to obesity-associated metabolic syndrome. Since meta-analyses show cognitive impairment as co-morbidity of obesity, the present study demonstrates the mechanistic role of Jak3 in obesity associated cognitive impairment. Our data show that high-fat diet (HFD) suppresses Jak3 expression both in intestinal mucosa and in the brain of wild-type mice. Methodology: Recapitulating these conditions using global (Jak3-KO) and intestinal epithelial cell-specific conditional (IEC-Jak3-KO) mice and using cognitive testing, western analysis, flow cytometry, immunofluorescence microscopy and 16s rRNA sequencing, we demonstrate that HFD-induced Jak3 deficiency is responsible for cognitive impairments in mice, and these are, in part, specifically due to intestinal epithelial deficiency of Jak3. Results: We reveal that Jak3 deficiency leads to gut dysbiosis, compromised TREM-2-functions-mediated activation of microglial cells, increased TLR-4 expression and HIF1-α-mediated inflammation in the brain. Together, these lead to compromised microglial-functions-mediated increased deposition of β-amyloid (Aβ) and hyperphosphorylated Tau (pTau), which are responsible for cognitive impairments. Collectively, these data illustrate how the drivers of obesity promote cognitive impairment and demonstrate the underlying mechanism where HFD-mediated impact on IEC-Jak3 deficiency is responsible for Jak3 deficiency in the brain, reduced microglial TREM2 expression, microglial activation and compromised clearance of Aβ and pTau as the mechanism during obesity-associated cognitive impairments. Conclusion: Thus, we not only demonstrate the mechanism of obesity-associated cognitive impairments but also characterize the tissue-specific role of Jak3 in such conditions through mucosal tolerance, gut–brain axis and regulation of microglial functions.

Both heat-sensitive TRPV4 and cold-sensitive TRPM8 ion channels regulate microglial activity

Microglia, the brain-resident macrophages, perform a myriad of functions directed towards development of neural circuits, and their maintenance. A plethora of ion channels aid in microglial activities that are critical for overall brain functioning. Notably, different functions of microglial cells are sensitive to minute temperature changes, as well as mechanical forces. Therefore, among all the players involved in the regulation of microglial functions, thermosensitive TRP ion channels are potentially important. In this study, we report the endogenous and functional presence of a heat-sensitive ion channel TRPV4 and a cold-sensitive ion channel TRPM8 in primary rat microglia and microglial cell line, N9. We demonstrate that pharmacological modulations of both these channels affect intracellular Ca2+-levels, cellular morphology, migration, and motility. Thus, TRPV4 and TRPM8 act as potential regulators of microglial activities. These findings may have broad implications in understanding neuro-glia interactions in neurodevelopmental and neurodegenerative pathologies with overall bio-medical applications.

β-Lactolin improves mitochondrial function in Aβ-treated mouse hippocampal neuronal cell line and a human iPSC-derived neuronal cell model of Alzheimer's disease.

Mitochondrial dysfunctions are a key hallmark of Alzheimer's disease (AD). β-Lactolin, a whey-derived glycine-threonine-tryptophan-tyrosine tetrapeptide, has been previously reported to prevent AD-like pathologies in an AD mouse model via regulation of microglial functions. However, the direct effect of β-lactolin on neuronal cells and neuronal mitochondrial functions remains unknown. Here, we investigated the effects of β-lactolin on mitochondrial functions in amyloid β (Aβ)-treated mouse hippocampal neuronal HT22 cells and human induced-pluripotent cell (hiPSC)-derived AD model neurons. Adding β-lactolin to Aβ-treated HT22 cells increased both the oxygen consumption rate and cellular ATP concentrations, suggesting that β-lactolin improves mitochondrial respiration and energy production. Using high content image analysis, we found that β-lactolin improved mitochondrial fragmentation, membrane potential, and oxidative stress in Aβ-treated cells, eventually preventing neuronal cell death. From a mechanistic perspective, we found that β-lactolin increased gene expression of mitofusin-2, which contributes to mitochondrial fusion events. Finally, we showed that β-lactolin improves both mitochondrial morphologies and membrane potentials in hiPSC-derived AD model neurons. Taken together, β-lactolin improved mitochondrial functions AD-related neuronal cell models and prevented neuronal cell death. The dual function of β-lactolin on both neuron and microglia marks an advantage in maintaining neuronal health.

Nuclear receptors of NR1 and NR4 subfamilies in the regulation of microglial functions and pathology.

This review provides an overview of researches on the NR1 and NR4 nuclear receptors involved in the regulation of microglial functions. Nuclear receptors are attractive candidates for drug targets in the therapies of the central nervous system disorders, because the activation of these receptors is expected to regulate the functions and the phenotypes of microglia, by controlling the expression of specific gene subsets and also by regulating the cellular signaling mechanisms in a nongenomic manner. Several members of NR1 nuclear receptor subfamily have been examined for their ability to regulate microglial functions. For example, stimulation of vitamin D receptor inhibits the production of pro‐inflammatory factors and increases the production of anti‐inflammatory cytokines. Similar regulatory actions of nuclear receptor ligands on inflammation‐related genes have also been reported for other NR1 members such as retinoic acid receptors, peroxisome proliferator‐activated receptors (PPARs), and liver X receptors (LXRs). In addition, stimulation of PPARγ and LXRs may also result in increased phagocytic activities of microglia. Consistent with these actions, the agonists at nuclear receptors of NR1 subfamily are shown to produce therapeutic effects on animal models of various neurological disorders such as experimental allergic encephalomyelitis, Alzheimer's disease, Parkinson's disease, and ischemic/hemorrhagic stroke. On the other hand, increasing lines of evidence suggest that the stimulation of NR4 subfamily members of nuclear receptors such as Nur77 and Nurr1 also regulates microglial functions and alleviates neuropathological events in several disease models. Further advancement of these research fields may prove novel therapeutic opportunities.

Compound AD16 Reduces Amyloid Plaque Deposition and Modifies Microglia in a Transgenic Mouse Model of Alzheimer's Disease.

Microglial dysfunction is involved in the pathological cascade of Alzheimer's disease (AD). The regulation of microglial function may be a novel strategy for AD therapy. We previously reported the discovery of AD16, an antineuroinflammatory molecule that could improve learning and memory in the AD model. Here, we studied its properties of microglial modification in the AD mice model. In this study, AD16 reduced interleukin-1β (IL-1β) expression in the lipopolysaccharide-induced IL-1β-Luc transgenic mice model. Compared with mice receiving placebo, the group treated with AD16 manifested a significant reduction of microglial activation, plaque deposition, and peri-plaques microgliosis, but without alteration of the number of microglia surrounding the plaque. We also found that AD16 decreased senescent microglial cells marked with SA-β-gal staining. Furthermore, altered lysosomal positioning, enhanced Lysosomal Associated Membrane Protein 1 (LAMP1) expression, and elevated adenosine triphosphate (ATP) concentration were found with AD16 treatment in lipopolysaccharide-stimulated BV2 microglial cells. The underlying mechanisms of AD16 might include regulating the microglial activation/senescence and recovery of its physiological function via the improvement of lysosomal function. Our findings provide new insights into the AD therapeutic approach through the regulation of microglial function and a promising lead compound for further study.

Regulation of Microglial Functions by Purinergic Mechanisms in the Healthy and Diseased CNS.

Microglial cells, the resident macrophages of the central nervous system (CNS), exist in a process-bearing, ramified/surveying phenotype under resting conditions. Upon activation by cell-damaging factors, they get transformed into an amoeboid phenotype releasing various cell products including pro-inflammatory cytokines, chemokines, proteases, reactive oxygen/nitrogen species, and the excytotoxic ATP and glutamate. In addition, they engulf pathogenic bacteria or cell debris and phagocytose them. However, already resting/surveying microglia have a number of important physiological functions in the CNS; for example, they shield small disruptions of the blood–brain barrier by their processes, dynamically interact with synaptic structures, and clear surplus synapses during development. In neurodegenerative illnesses, they aggravate the original disease by a microglia-based compulsory neuroinflammatory reaction. Therefore, the blockade of this reaction improves the outcome of Alzheimer’s Disease, Parkinson’s Disease, multiple sclerosis, amyotrophic lateral sclerosis, etc. The function of microglia is regulated by a whole array of purinergic receptors classified as P2Y12, P2Y6, P2Y4, P2X4, P2X7, A2A, and A3, as targets of endogenous ATP, ADP, or adenosine. ATP is sequentially degraded by the ecto-nucleotidases and 5′-nucleotidase enzymes to the almost inactive inosine as an end product. The appropriate selective agonists/antagonists for purinergic receptors as well as the respective enzyme inhibitors may profoundly interfere with microglial functions and reconstitute the homeostasis of the CNS disturbed by neuroinflammation.

Valproic acid affects neuronal fate and microglial function via enhancing autophagic flux in mice after traumatic brain injury.

In recent years, many studies have focused on autophagy, an evolutionarily conserved mechanism that relies on lysosomes to achieve cellular metabolic requirements and organelle turnover, and revealed its important role in animal models of traumatic injury. Autophagy is a double-edged sword. Appropriate levels of autophagy can promote the removal of abnormal proteins or damaged organelles, while hyperactivated autophagy can induce autophagic apoptosis. However, recent studies suggest that autophagic flux seems to be blocked after traumatic brain injury (TBI), which contributes to the apoptosis of brain cells. In this study, valproic acid (VPA), which was clinically used for epilepsy treatment, was used to treat TBI. The Morris water maze test, hematoxylin & eosin staining and Nissl staining were first conducted to confirm that VPA treatment had a therapeutic effect on mice after TBI. Western blotting, enzyme-linked immunosorbent assay and immunofluorescence staining were then performed to reveal that VPA treatment reversed TBI-induced blockade of autophagic flux, which was accompanied by a reduced inflammatory response. In addition, the variations in activation and phenotypic polarization of microglia were observed after VPA treatment. Nevertheless, the use of the autophagy inhibitor 3-methyladenine partially abolished VPA-induced neuroprotection and the regulation of microglial function after TBI, resulting in the deterioration of the central nervous system microenvironment and neurological function. Collectively, VPA treatment reversed the TBI-induced blockade of autophagic flux in the mouse brain cortex, subsequently inhibiting brain cell apoptosis and affecting microglial function to achieve the promotion of functional recovery in mice after TBI. Cover Image for this issue: doi: 10.1111/jnc.14755.

Effects of alpha-7 nicotinic allosteric modulator PNU 120596 on depressive-like behavior after lipopolysaccharide administration in mice

Evidence suggests that α7 nicotinic acetylcholine receptor (α7 nAChR) in the central nervous system has a critical role in the regulation of microglial function and neuroinflammation associated with the pathophysiology of major depressive disorder. The objectives of the present study were to determine the effects of PNU 120596, an α7 nAChR positive allosteric modulator (PAM), on depressive-like behavior and expression of ionized calcium binding adaptor molecule 1 (Iba-1), a microglial marker, in male C57BL/6J mice following lipopolysaccharide (LPS) administration, an animal model for depressive-like behavior. Forced swim test (FST), tail suspension test (TST), and sucrose preference test were used to determine the effects of PNU 120596 on depressive-like behavior, measured by increased immobility time or decreased sucrose preference. We also examined the effects of PNU 120596 on Iba-1 expression by using Western blot analysis and immunofluorescence staining in the hippocampus and prefrontal cortex, the brain regions implicated in major depressive disorder. Administration of LPS (1 mg/kg, i.p.) significantly increased immobility time during FST and TST and decreased sucrose preference. The PNU 120596 (1 or 4 mg/kg, i.p.) dose-dependently prevented LPS-induced depressive-like behavior during FST, TST, and sucrose preference test. The PNU 120596 (1 or 4 mg/kg) alone did not show any significant alteration on immobility time and sucrose preference. Pretreatment of methyllycaconitine (3 mg/kg, i.p.), an α7 nAChR antagonist, significantly prevented the antidepressant-like effects of PNU (4 mg/kg). Similarly, the PNU 120596 (4 mg/kg, i.p.) significantly reduced LPS-induced increased expression of Iba-1 in the hippocampus or prefrontal cortex. Overall, these results suggest that PNU 120596 reduces LPS-induced depressive-like behavior and microglial activation in the hippocampus and prefrontal cortex in mice. Therefore, α7 nAChR PAMs could be developed as potential therapeutic utility for the treatment of major depressive disorder in humans.

Is regulation of microglial functions by T3 dependent on the micro‐environment?: Insights from the brainstem respiratory control network of newborn mice

We previously showed that thyroid hormones (THs) facilitate respiratory control development in newborn rodents. To understand the underlying mechanisms, we tested the hypotheses that TH, more precisely T3, 1) influences microglial functions in the brainstem of newborn mice and 2) this effect is region dependent. Measurements were performed on primary cultured mouse microglia isolated from the mixed glial cultures of postnatal day 3 C57BL/6J mice. Primary cultured neurons from cortex and brainstem were obtained from embryonic day 14–16 C57BL/6J mice. Microglia from cortex and brainstem were either cultured alone (DMEM) or co‐cultured with respective neurons (DMEM + neurobasal medium) under standard conditions (37°C, 5% CO2 / 90% humidity). Microglial motility (μm traveled) was monitored using a time‐lapse video‐microscopy system over 3h with or without T3 (1μM). Phagocytosis was quantified and observed in brainstem microglial cells pre‐incubated with 54 μg/ml Dextran, Rhodamine B (10 000 MW, neutral) in DMEM for 1h followed by incubation in DMEM with or without T3 (1 μM) for 3h. The cells were then fixed by 4% PFA. In the presence of neurons, but not in single culture, exposure to T3 increased brainstem microglial motility by 350% relative to control over the 3 h period (13.0 ± 4.5 vs 45.2 ± 7.8 μm; P=0.004). Exposing cortex cells to T3 also increased microglial motility; however, the effect was less important (156%; 46.0 ± 4.9 vs 72.1 ± 8.8 μm; P=0.009). The region of origin could also influence microglial functions in co‐culture as brainstem microglia showed decreased motility compared to cortex microglia (with and without T3). By comparison with controls, brainstem microglial cells cultured alone responded to T3 exposure by a ~4‐fold increase in phagocytosis as indicated by the fluorescence intensity of Dextran Rhodamine B (average arbitrary unit/area; 5.4 ± 1.1 vs 1.3 ± 0.2 AU/μm2; P=0.001). We conclude that 1) T3 facilitates multiple functional responses of microglia including motility and phagocytosis; both functions are important in regulation of synaptic function during development. 2) Microglial activation is specific to the surrounding environment, such as presence of thyroid hormones and brain regions. Microglia therefore appear as important effectors of TH action in the development of the respiratory network. Understanding the mechanisms by which these cells influence the generation and regulation of respiratory activity offers new approaches to alleviate respiratory disorders in newborn, especially those born pre‐term.Support or Funding InformationSupported by NSERC, Fonds de Recherche en Santé du Québec and Research Support Center, Graduate School of Medical Sciences, Kyushu University.This abstract is from the Experimental Biology 2018 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.

γ‐Secretase in microglia – implications for neurodegeneration and neuroinflammation

γ-Secretase is an intramembrane cleaving protease involved in the generation of the Alzheimer's disease (AD)-associated amyloid β peptide (Aβ). γ-Secretase is ubiquitously expressed in different organs, and also in different cell types of the human brain. Besides the involvement in the proteolytic generation of Aβ from the amyloid precursor protein, γ-secretase cleaves many additional protein substrates, suggesting pleiotropic functions under physiological and pathophysiological conditions. Microglia exert important functions during brain development and homeostasis in adulthood, and accumulating evidence indicates that microglia and neuroinflammatory processes contribute to the pathogenesis of neurodegenerative diseases. Recent studies demonstrate functional implications of γ-secretase in microglia, suggesting that alterations in γ-secretase activity could contribute to AD pathogenesis by modulation of microglia and related neuroinflammatory processes during neurodegeneration. In this review, we discuss the involvement of γ-secretase in the regulation of microglial functions, and the potential relevance of these processes under physiological and pathophysiological conditions. This article is part of the series "Beyond Amyloid".

Microglial Interferon Signaling and White Matter.

Microglia, the resident immune cells of the CNS, are primary regulators of the neuroimmune response to injury. Type I interferons (IFNs), including the IFNαs and IFNβ, are key cytokines in the innate immune system. Their activity is implicated in the regulation of microglial function both during development and in response to neuroinflammation, ischemia, and neurodegeneration. Data from numerous studies in multiple sclerosis (MS) and stroke suggest that type I IFNs can modulate the microglial phenotype, influence the overall neuroimmune milieu, regulate phagocytosis, and affect blood-brain barrier integrity. All of these IFN-induced effects result in numerous downstream consequences on white matter pathology and microglial reactivity. Dysregulation of IFN signaling in mouse models with genetic deficiency in ubiquitin specific protease 18 (USP18) leads to a severe neurological phenotype and neuropathological changes that include white matter microgliosis and pro-inflammatory gene expression in dystrophic microglia. A class of genetic disorders in humans, referred to as pseudo-TORCH syndrome (PTS) for the clinical resemblance to infection-induced TORCH syndrome, also show dysregulation of IFN signaling, which leads to severe neurological developmental disease. In these disorders, the excessive activation of IFN signaling during CNS development results in a destructive interferonopathy with similar induction of microglial dysfunction as seen in USP18 deficient mice. Other recent studies implicate "microgliopathies" more broadly in neurological disorders including Alzheimer's disease (AD) and MS, suggesting that microglia are a potential therapeutic target for disease prevention and/or treatment, with interferon signaling playing a key role in regulating the microglial phenotype.

The protein-tyrosine phosphatase DEP-1 promotes migration and phagocytic activity of microglial cells in part through negative regulation of fyn tyrosine kinase.

Microglia cells are brain macrophages whose proper functioning is essential for maintenance and repair processes of the central nervous system (CNS). Migration and phagocytosis are critical aspects of microglial activity. By using genetically modified cell lines and knockout mice we demonstrate here that the receptor protein-tyrosine phosphatase (PTP) DEP-1 (also known as PTPRJ or CD148) acts as a positive regulator of both processes in vitro and in vivo. Notably, reduced microglial migration was detectable in brains of Ptprj-/- mice using a wounding assay. Mechanistically, density-enhanced phosphatase-1 (DEP-1) may in part function by inhibiting the activity of the Src family kinase Fyn. In the microglial cell line BV2 DEP-1 depletion by shRNA-mediated knockdown resulted in enhanced phosphorylation of the Fyn activating tyrosine (Tyr420 ) and elevated specific Fyn-kinase activity in immunoprecipitates. Moreover, Fyn mRNA and protein levels were reduced in DEP-1 deficient microglia cells. Consistent with a negative regulatory role of Fyn for microglial functions, which is inhibited by DEP-1, microglial cells from Fyn-/- mice exhibited elevated migration and phagocytosis. Enhanced microglia migration to a site of injury was also observed in Fyn-/- mice in vivo. Taken together our data revealed a previously unrecognized role of DEP-1 and suggest the existence of a potential DEP-1-Fyn axis in the regulation of microglial functions. GLIA 2017;65:416-428.

ミクログリア細胞機能における活性酸素シグナリング～TRPチャネルを介した新しい細胞制御機構～

ミクログリア細胞機能における活性酸素シグナリング～TRPチャネルを介した新しい細胞制御機構～

MicroRNA-Let-7a regulates the function of microglia in inflammation.

Microglia have multiple functions in cerebrovascular and neurodegenerative diseases. Regulation of microglial function during inflammatory stress is important for treatment of central nervous system (CNS) diseases because microglia secrete various substances that affect neurons and glia. MicroRNA-Let-7a (miR-Let-7a) is a tumor suppressor miRNA that has been reported to target transcripts that encode proteins involved in apoptosis. In the present study, we examined the essential role of miR-Let-7a in inflammatory stress by over-expressing miR-Let-7a to investigate its role in determining the BV2 microglial phenotype, a cell line often used as a model of activated microglia. We found that inflammatory factors and Reactive Oxygen Species (ROS) production levels were altered according to miR-Let-7a expression level as measured by Western blot analysis, reverse transcription PCR, quantitative real time PCR, the measurement of nitrite (indicative of the nitric oxide (NO) pathway), and immunocytochemistry (ICC). Our results suggest that miR-Let-7a is involved in the function of microglia in the setting of inflammatory injury. In response to inflammation, miR-Let-7a participates in the reduction of nitrite production and the expression of inducible nitric oxide synthase (iNOS), interleukin (IL)-6 and is involved in increased expression of brain derived neurotrophic factor (BDNF), interleukin (IL)-10, and IL-4 in microglia. Thus, miRNA-Let-7a could act as a regulator of the function of microglia in inflammation.

Neuropeptide Y inhibits interleukin‐1 beta‐induced microglia motility

Increasing evidences suggest that neuropeptide Y (NPY) may act as a key modulator of the cross-talk between the brain and the immune system in health and disease. In the present study, we dissected the possible inhibitory role of NPY upon inflammation-associated microglial cell motility. NPY, through activation of Y(1) receptors, was found to inhibit lipopolysaccharide (LPS)-induced microglia (N9 cell line) motility. Moreover, stimulation of microglia with LPS was inhibited by IL-1 receptor antagonist (IL-1ra), suggesting the involvement of endogenous interleukin-1 beta (IL-1β) in this process. Direct stimulation with IL-1β promoted downstream p38 mitogen-activated protein kinase mobilization and increased microglia motility. Moreover, consistently, p38 mitogen-activated protein kinase inhibition decreased the extent of actin filament reorganization occurring during plasma membrane ruffling and p38 phosphorylation was inhibited by NPY, involving Y(1) receptors. Significantly, the key inhibitory role of NPY on LPS-induced motility of CD11b-positive cells was further confirmed in mouse brain cortex explants. In summary, we revealed a novel functional role for NPY in the regulation of microglial function that may have important implications in the modulation of CNS injuries/diseases where microglia migration/motility might play a role.

Role of the peroxisome proliferator-activated receptor-gamma (PPAR-gamma) and its natural ligand 15-deoxy-Delta12, 14-prostaglandin J2 in the regulation of microglial functions.

The peroxisome proliferator-activated receptor-gamma (PPAR-gamma) is a member of a large group of nuclear receptors controlling the proliferation of peroxisomes that is involved in the downregulation of macrophage functions. Here, we report that PPAR-gamma was constitutively expressed in rat primary microglial cultures and that such expression was downregulated during microglial activation by endotoxin (LPS). The presence of the PPAR-gamma natural ligand 15-deoxy-Delta12,14-prostaglandin J2 (15d-PGJ2) counteracted the repression of PPAR-gamma expression caused by LPS. In microglial cultures stimulated by LPS, interferon-gamma (IFN-gamma) or by their combination, 15d-PGJ2 reduced the production of nitric oxide (NO) and the expression of inducible NO synthase (iNOS). The inhibitory effect was dose-dependent and did not involve an elevation of cyclic AMP, a second messenger known to inhibit NOS expression in microglia. In addition, 15d-PGJ2 down-regulated other microglial functions, such as tumour necrosis factor-alpha (TNF-alpha) synthesis and major histocompatibility complex class II (MHC class II) expression. The effects of 15d-PGJ2 occurred, at least in part, through the repression of two important transcription factors, the signal transducer and activator of transcription 1 and the nuclear factor kappaB, known to mediate IFN-gamma and LPS cell signalling. Our observations suggest that 15d-PGJ2, the synthesis of which is likely to occur within the brain, could play an important role in preventing brain damage associated with excessive microglial activation.