key: cord-330553-sukrjl22 authors: Stonedahl, Sarah; Clarke, Penny; Tyler, Kenneth L. title: The Role of Microglia during West Nile Virus Infection of the Central Nervous System date: 2020-08-28 journal: Vaccines (Basel) DOI: 10.3390/vaccines8030485 sha: doc_id: 330553 cord_uid: sukrjl22 Encephalitis resulting from viral infections is a major cause of hospitalization and death worldwide. West Nile Virus (WNV) is a substantial health concern as it is one of the leading causes of viral encephalitis in the United States today. WNV infiltrates the central nervous system (CNS), where it directly infects neurons and induces neuronal cell death, in part, via activation of caspase 3-mediated apoptosis. WNV infection also induces neuroinflammation characterized by activation of innate immune cells, including microglia and astrocytes, production of inflammatory cytokines, breakdown of the blood-brain barrier, and infiltration of peripheral leukocytes. Microglia are the resident immune cells of the brain and monitor the CNS for signs of injury or pathogens. Following infection with WNV, microglia exhibit a change in morphology consistent with activation and are associated with increased expression of proinflammatory cytokines. Recent research has focused on deciphering the role of microglia during WNV encephalitis. Microglia play a protective role during infections by limiting viral growth and reducing mortality in mice. However, it also appears that activated microglia are triggered by T cells to mediate synaptic elimination at late times during infection, which may contribute to long-term neurological deficits following a neuroinvasive WNV infection. This review will discuss the important role of microglia in the pathogenesis of a neuroinvasive WNV infection. Knowledge of the precise role of microglia during a WNV infection may lead to a greater ability to treat and manage WNV encephalitis. West Nile Virus (WNV) is a neurotropic, mosquito-borne, single-stranded RNA flavivirus maintained in an enzootic cycle between mosquitos, such as Culex pipiens, and perching birds (order Passeriformes), such as crows, jays, and finches [1, 2] . While birds are the natural reservoir for WNV, an infected mosquito may bite other mammals such as horses and humans and transmit the virus through saliva [2] . After an infected mosquito bites a human, the virus replicates within dendritic cells and macrophages of local tissue near the site of inoculation and subsequently spreads to regional lymph nodes. The resulting viremia then spreads the virus throughout the body [2] . West Nile Virus viremia in humans is not high enough or sustained enough to support subsequent transmission to mosquitoes, thus humans are designated "dead-end" hosts [1, 2] . West Nile Virus infection is now the most common cause of epidemic viral encephalitis in the United States. According to the Center for Disease Control (CDC), since its introduction into North West Nile Virus-induced CNS disease occurs as a result of virus crossing the blood brain barrier (BBB) following systemic infection. Mechanisms of viral entry into the CNS are not yet fully understood. However, theories include a cytokine-mediated increase in permeability of the BBB, hematogenous entry by infection of infiltrating immune cells, and retrograde axonal transport [7, 16, 17] . The greatest risk factor for developing WNV neuroinvasive disease is older age (>64 years), while other risk factors include hypertension and diabetes [18] . Certain genetic factors also dictate increased susceptibility to neuroinvasive disease including single nucleotide polymorphisms in the oligoadenylate synthetase (OAS) gene (involved in antiviral innate immunity) and genetic deficiencies in C-C chemokine receptor type 5 (CCR5), which inhibit lymphocyte trafficking into the CNS [19, 20] . Once within the CNS, WNV directly infects neurons and several studies demonstrate that caspase 3-dependent apoptosis is an important mechanism of neuronal cell death and CNS injury during WNV infection [21, 22] . The pathology of neuroinvasive WNV infection likely results from both apoptosis of neurons and secondary effects of the neuroinflammatory response, including damage to bystander cells and gliosis [22] . A critical component of the neuroinflammatory response induced by WNV infection is the activation of microglia, the innate immune cells of the CNS [23] . In this review, we will discuss the role of microglia in WNV-induced CNS disease as a contributor both to the protective innate immune response and to the development of long-term neurological damage. Microglia are of myeloid origin and arise from the yolk sac during early development [24] [25] [26] . These cells are the resident mononuclear phagocytic cells of the CNS and play multiple roles in the CNS such as immune defense, maintenance of homeostasis, and synaptic pruning during early development [27] [28] [29] . Importantly they continually monitor the CNS for signals of injury and infection [28, 30, 31] . Microglia express a spectrum of activation states in response to environmental and pathogenic cues [32, 33] . Morphological changes of activated microglia include a shift from a ramified state, characterized by long extending processes, to a larger more amoeboid phenotype [34] . In addition, activated microglia display increased motility, proliferation and production of inflammatory cytokines and chemokines [29, [35] [36] [37] . In neuroinflammatory and neurodegenerative conditions, microglia are thought to contribute to pathogenicity [36, 38, 39] , however, in the case of viral encephalitis, it remains unclear whether microglia are beneficial or detrimental to disease outcomes, or possibly both. Classically, macrophages and microglia have been defined as being polarized, meaning they express two major activation states: pro-inflammatory M1 and anti-inflammatory M2 [40] . While some individuals feel that this is not an accurate description of microglial activation [32] , it remains important to consider the role of microglia polarization in the pathogenesis of WNV infections. The ability to shift phenotypes allows microglia to maintain homeostasis within the CNS. Following infection of the CNS, microglia express markers characteristic of M1 activation including increased expression of Iba-1, as well as chemokines such as C-C motif cytokine 2 (CCL2), CCL3, CCL5, and CCL7 [41] . The anti-inflammatory drug minocycline reduces the expression of M1 inflammatory genes and increases the expression of M2 genes, following WNV infection of CNS tissue [42] . This shift of microglia towards a more anti-inflammatory M2 state was neuroprotective [42] and suggests that M1 microglia are required for initial control of WNV infection; however, switching to an M2 phenotype may be critical in preventing excessive damage due to inflammatory processes. For the purpose of this review, we will mostly be referring to M1 microglial polarization when discussing activation of microglia. Several neurotropic viruses have been shown to induce microglia activation in the CNS following infection, including Japanese encephalitis virus [43, 44] , Dengue Virus [45] , Zika virus [46] , Tick-borne encephalitis virus [47] , reovirus [48] , and mouse hepatitis virus [49, 50] . Evidence that microglia are activated during WNV-induced CNS disease in humans includes the presence of microglial nodules and increased proliferation [51, 52] . Activated microglia are also seen in the CNS of mice infected with WNV [53] [54] [55] and in WNV-infected ex vivo brain and spinal cord slice cultures [21, 41] . The use of ex vivo slice cultures allows for isolation of the CNS immune system from the peripheral immune response. In this method, spinal cords or brains are harvested from neonatal mice and used to create 300-µm-thick slice cultures, which are incubated on culture inserts prior to infection. Using this model, activated microglia were identified following WNV infection by increased expression of ionized calcium binding adaptor molecule 1 (Iba1) [21, 41] , a microglia-specific marker [56] . In addition, microglia in WNV-infected ex vivo slices were increased in both size and number compared to uninfected slices and displayed an amoeboid phenotype [21, 41] . Distinct microglia cell processes related to cell motility and phagocytosis of WNV-infected cells and antigenic debris were seen in WNV-infected ex vivo slice cultures (Figure 1 ), including microglial cellular projections stretching over a range of distances to reach WNV-infected cells, which were often filopodial/lamellipodial in appearance ( Figure 1A ), reflecting microglia with amoeboid morphology [41] . These microglia cell processes were observed contacting infected cells and initiating engulfment activity ( Figure 1B -E). The formation of phagosomes was also prevalent ( Figure 1F ). Notably, microglia virtually never appeared to be infected themselves, despite taking in material (cells and debris) that stained positive for WNV antigens. Intercellular communication via cytokine/chemokine signaling drives inflammatory responses during viral infections of the CNS [40, 57] . Infection of CNS tissue with WNV in vivo [21, 58] and in ex vivo [41] and in vitro [23] models of WNV pathogenesis results in increased expression of proinflammatory cytokines and chemokines associated with microglial activation including C-X-C motif chemokine 10 (CXCL10), CXCL1, CCL5, CCL3, CCL2, tumor necrosis factor alpha (TNF-α), TNF-related apoptosis-inducing ligand (TRAIL), and interleukin-6 (IL-6) [40] . These cytokines are involved in inflammatory processes and activating/recruiting immune cells such as T cells [59] . Inhibition of these chemokines/cytokines following treatment with minocycline resulted in decreased neuronal cell death following WNV infection of ex vivo spinal cord slice cultures [42] , suggesting they contribute to disease; however, depletion of microglia did not significantly change chemokine/cytokine expression in the brains of WNV-infected mice [60] so it is unclear what role microglia play in the production of these proteins. Based on the evidence presented above, it can be concluded that microglia become activated following infection of the CNS with WNV. These activated microglia can initiate an immune response that is intrinsic to the CNS and does not require input from the peripheral immune system as seen in the ex vivo slice culture model. Activation of the microglia is characterized by morphological changes and is associated with the increased production of inflammatory cytokines/chemokines. Based on the evidence presented above, it can be concluded that microglia become activated following infection of the CNS with WNV. These activated microglia can initiate an immune response that is intrinsic to the CNS and does not require input from the peripheral immune system as seen in the ex vivo slice culture model. Activation of the microglia is characterized by morphological changes and is associated with the increased production of inflammatory cytokines/chemokines. Toll-Like Receptors (TLRs) are membrane spanning receptors commonly expressed by cells such as macrophages, dendritic cells, and microglia, which monitor the body for signs of infection. They play key roles in the innate immune system [61] and have the ability to recognize structurally conserved pathogen-associated molecular patterns (PAMPS) present on pathogens [61] [62] [63] . Microglial expression of TLR3, which recognizes double-stranded viral RNA, is thought to play an important role in the detection of viruses, including WNV, in the CNS [64] . Several studies have shown that TLR3 signaling plays a protective role in preventing lethal WNV encephalitis [54, 65, 66] . For example, mice deficient in the expression of TLR3 [63, 64] and Myeloid Differentiation Primary Response 88 (MyD88), which functions downstream of TLR3 [54] , show increased susceptibility to WNV that is associated with higher viral loads in the brain and increased expression of inflammatory cytokines. While these studies present evidence for a protective effect of TLR3 following WNV infection, an earlier study showed increased survival from WNV infections in TLR3-deficient mice [65] . In this study, TLR3-deficient mice were more resistant to lethal WNV infection and showed impaired cytokine production along with enhanced viral load in the periphery. However, in the brain, viral load, inflammatory responses and neuropathology were reduced compared to wild-type, indicating TLR3 may mediate entry of WNV into the brain [67] . It has been suggested that the difference in outcome seen in TLR3-deficient mice could be explained by the distinct route of inoculation (subcutaneous versus intraperitoneal), passage history of the virus (mammalian Vero cell versus insect-cell derived), and/or the virus dose [63] . More research will need to be done to achieve a full understanding of the role of TLR3 signaling in WNV encephalitis. Retinoic Acid Inducible Gene I (RIG-I) and Melanoma Differentiation Antigen 5 (MDA5) are cytosolic pattern recognition receptors (PRRs), which recognize viral RNA products, including WNV genetic material, and are critical for initiating an innate immune defense [68, 69] . Lack of either RIG-I or MDA5 in mice results in decreased innate immune signaling and control of viral growth. A double knockout of both receptors leads to complete loss of innate immunity gene function in WNV-infected cells and severe disease in mice [68] . Microglia constitutively express both RIG-I and MDA5 [70] . The downstream central adaptor molecule mitochondrial antiviral-signaling protein (MAVS) is also essential for control of WNV infections. A deficiency in MAVS in hematopoietic cells, such as microglia and macrophages, leads to increased mortality in mice infected with WNV [71] . These findings indicate the importance of the MAVS signaling pathway in the microglial response to WNV particles within the CNS. As documented above, microglia recognize and become activated in response to WNV infection. However, it remains unclear if this process is essential to effective host protection against WNV or whether activated microglia contribute to pathogenesis. For example, following infection with WNV, both decreased [53] and increased [54, 64] microglial activation have been associated with increased neuronal death and susceptibility to disease. To address this disparity, the effect of WNV infection on mice lacking microglia has been investigated. Mice deficient in the expression of interleukin 34 (IL-34), which lack microglia but retain bone marrow-derived macrophages, have increased susceptibility to WNV, suggesting a role for microglia in antiviral defense [72] . In addition, recent studies performed in mice in which microglia were depleted using Plexxicon 5622 (PLX5622), an inhibitor of colony-stimulating factor 1 receptor (CSF1R), demonstrated a significant increase in susceptibility to WNV-induced CNS disease [60] . Colony-stimulating factor 1 is critical for microglia survival [72] [73] [74] , and PLX5622 has been shown to have specificity towards microglia without affecting other cell populations such as brain-specific macrophages, peripheral macrophages, or lymphocytes [49, 75, 76] . Microglial depletion using PLX5622 does not alter brain size, cognition, or motor function in mice [76] . To deplete microglia, mice were fed a diet containing PLX5622 for 10 days resulting in greater than 80% depletion of their microglia population throughout the brain when compared to mice fed a control diet [60] . Following infection of PLX5622-treated mice with WNV, brain titers were significantly (10-100-fold) higher than in control mice at days 6, 9, and 10 post infection. In addition, mortality dramatically increased. Of the mice infected with WNV, 100% of PLX-treated microglia-depleted mice died compared to only 25% of the control fed mice [60] . These studies indicate that microglia play a critical role in controlling WNV infection and limiting WNV-induced mortality. Results in WNV-infected PLX5622-treated mice were remarkably similar to another recent study, which found that microglia are crucial for protection of mice from neurotropic coronavirus encephalitis and may be required for the generation of an efficient T cell response [49] . This study also showed that microglial protection was time dependent [49] . Elimination of microglia using PLX5622 between days 0 and 6 post-infection resulted in increased mortality in infected mice; however, microglial depletion after the first 6 days showed no effect on mortality [49] . This data indicates that microglia are essential for limiting viral growth and neuronal cell death during the initial phase of a neuroinvasive viral infection but become less important during later infection, when adaptive immune responses have developed. Determination of whether microglia follow a similar time-dependent role following WNV infection in the CNS and whether this is associated with changes in the T cell response remains to be determined. Collectively, the studies discussed above reveal the critical role microglia play in protecting the host from WNV-induced CNS disease. Elimination of microglia during WNV encephalitis led to increased viral titers within the brain and increased mortality in mice. Further studies are needed to determine the mechanism by which microglia protect the CNS from WNV infection. Potential mechanisms include phagocytosis of WNV-infected neurons, production of inflammatory cytokines/chemokines, and signaling to the adaptive immune system. Matrix metalloproteinases (MMPs) are a family of proteins whose major function is remodeling the extracellular complex (EC) of the BBB [77, 78] . They have also been shown to play a role in immunity by modulating the trafficking of immune cells into the CNS [79] . MMP9, is expressed by microglia [78] , and has been shown to be important for WNV entry into the brain [77] . MMP9 knockout mice infected with WNV show decreased viral loads in the brain, but not the periphery, and increased survival when compared to wild-type (WT) mice [77] . Resistance to lethal WNV infection coincided with an intact BBB as shown by reduced Evan's Blue Dye leakage into the brain, indicating a role for MM9P in altering permeability of the BBB during a WNV infection [77] . An additional mechanism by which microglia may contribute to WNV entry into the brain involves intercellular adhesion molecule (ICAM-1), a surface glycoprotein involved in cellular extravasation into sites of inflammation. ICAM-1 is expressed by several cell types including microglia [80] . The expression of ICAM-1 on microglia may contribute to extravasation of leukocytes via the "Trojan horse" method, in which the virus gains access to the CNS through infected leukocytes [17, 81] . Indeed, WNV infection has been shown to induce ICAM-1 expression in human endothelial cells and mouse brains, leading to disruption of the BBB and increased leukocyte infiltration [82] . It was also found that this process can be reversed through the use of blocking antibodies against ICAM-1 [82]. Individuals recovering from WNV encephalitis may experience long-term neurological deficits resulting from the infection [3] . This effect of WNV infection of the CNS is being extensively studied as an increased understanding of why these impairments occur will likely lead to an improvement in the long-term outcomes of recovering patients. A predominant theory is that microglia activated by memory T cells may contribute to neuronal damage following infection with WNV [83, 84] . Following initiation of innate immune responses, activated microglia release cytokines that signal the peripheral immune cells to infiltrate the CNS to clear the viral infection [24, 28] . CD8 + T cells mediate viral control through the secretion of effector molecules such as granzymes, perforin, and interferon-γ (IFNγ) [85] . While CD8 + T cells are necessary for proper clearance of virus from the CNS [86, 87] , they also seem to contribute to neurological deficits following WNV infection [83, 84, 88] . Once in the CNS, CD8 + T cells will differentiate into brain resident memory T cells, which are important for protection from reinfection [85] . These T cells remain within the CNS for months to years following neurotropic viral infections and studies have shown that these memory T cells promote microglia-mediated synaptic elimination following neuroinvasive WNV infections contributing to cognitive impairment. [83, 88, 89] . A recent study used a mouse model of viral encephalitis to show that T cells promote microglia-mediated loss of synapses following infection with WNV [83] . This study found an increase in the number of microglia-expressing markers indicative of activation induced by the T cell cytokine IFN-γ [83] . Analysis by qPCR also revealed increased expression IFN-γ in the hippocampus following infection and throughout recovery. In addition, mice deficient in the expression of IFN-γ and WT mice were infected with WNV. Mice lacking IFN-γ showed no differences in survival or weight loss when compared to WT mice [83] . However, WT mice showed special learning deficits on the Barnes maze test, while Ifngr1-/mice were protected from this outcome [83] . This study shows that during the process of viral clearance following WNV infection, IFN-γ produced by memory T cells can alter the function of microglia leading to elimination of synapses. The complement cascade is a component of the innate immune response, which plays a key role in defense from pathogens. During early development, microglia are involved in the process of synaptic pruning within the nervous system, which is dependent on the classical complement cascade [90] [91] [92] [93] . The mechanism by which the IFN-γ activated microglia eliminate synapses seems to be dependent on the complement system. It was found that brain regions retrieved from mice that had recovered from WNV showed increased expression of genes involved in microglial synaptic elimination by components of the complement system such as C1QA [84] . Mice with either fewer microglia (due to lacking the CSF1R ligand IL-34) or a deficiency in the C3 complement receptor showed increased protection from microglia-mediated synapse elimination [84] . This study suggests that the complement cascade and especially microglial-C3 is responsible for synaptic elimination seen in mice following WNV infection in the brain. Collectively, the studies discussed in this section provide evidence for a mechanism of neuronal damage following neuroinvasive WNV infection involving interactions in which microglia are promoted by memory T cells to eliminate synapses that have been targeted by the complement cascade. Understanding the dynamics between T cells and microglia following WNV infection of the CNS and how microglia may contribute to neurological sequalae could provide important insight into potential treatments for patients recovering from WNV encephalitis. Microglia maintain a variety of functions within the CNS, which are critical for protection from pathogens, homeostatic maintenance, and early development of the CNS. These roles are summarized in Table 1 . In this review, we have highlighted the important role microglia play during a neuroinvasive WNV infection. Although it is evident that microglia are essential for protection from WNV, the mechanism behind how microglia limit viral growth and mortality remains unclear. The multiple and complex roles of microglia during WNV infections are pictured in Figure 2 . Future studies should focus on the precise mechanisms by which microglia protect from WNV and enhancing the understanding of neuroinflammatory processes that accompany neuroinvasive WNV infections. It still remains to be determined which cytokines/chemokines are produced by microglia during a WNV infection and why a decrease in the expression of inflammatory cytokines/chemokines in not observed in the CNS of mice following WNV infection in the presence of PLX5622. which may lead to altered outcomes when comparing human and mouse infections [96] . It is vital to the complete understanding of the role of microglia during a WNV infection to use mouse studies as a compliment to human studies and not a replacement. Understanding exactly how microglia influence the progression and recovery of WNV neuroinvasive infections will allow for the development of specific treatments, which could provide the optimal outcome to patients recovering from this infection. [3] . Activated microglia control viral growth and reduce mortality in mice infected with WNV [4] , likely due to a combination of microglial phagocytosis of infected neurons and the release of inflammatory cytokines, which contribute to neuroinflammation and the recruitment of lymphocytes [3, 5] . In some cases, released cytokines may contribute to WNV-induced pathogenesis. MMP9 and ICAM-1 expression by microglia may enhance viral entry into the CNS through breakdown of the BBB and extravasation of potentially infected leukocytes [6, 7] . LONG TERM EFFECTS: Following infiltration of T cells into the CNS, microglia may contribute to synaptic damage triggered by IFNγ produced by memory CD8 + T cells and enhanced by the complement cascade [8, 9] . This synaptic elimination leads to neurological damage during recovery from WNV encephalitis [9] . Green and Red indicator arrows designate protective (green) and non-protective (red) microglial responses. [83, 84] While microglia are protective during the initial infection and vital for resolution of the infection, potentially dysregulated microglia responses driven by T cells may contribute to neurological damage and long-term impairment during the recovery stages. Targeting microglial responses during both the initial and late stages of infections may offer new therapeutic options for human patients with neuroinvasive WNV infections. For example, it may be beneficial to enhance the activity of microglia during the initial infection to provide enhanced protection but then limit microglial activation during the recovery stages of infection to improve long-term outcomes. One promising treatment that may be used during the initial WNV infection to improve survival is the use of granulocyte-macrophage colony-stimulating factor (GM-CSF), which promotes growth and activation of microglia, macrophages, and other myeloid cells [75, 94] . This drug is currently available (Leukine) and is used to treat leucopenic patients as well as being investigated as a treatment for Alzheimer's disease [95] . Another study showed that the anti-inflammatory drug minocycline may be beneficial in recovery from a WNV infection of the CNS [42] . Most of the studies presented in this review utilized a knockout mouse model or mouse tissue model to investigate microglia. However, it is important to understand the limitations of using mouse models when studying microglia and WNV pathology. Human microglia exhibit several differences to mouse microglia including increased levels of several immune genes and being longer-lived, which may lead to altered outcomes when comparing human and mouse infections [96] . It is vital to the complete understanding of the role of microglia during a WNV infection to use mouse studies as a compliment to human studies and not a replacement. Understanding exactly how microglia influence the progression and recovery of WNV neuroinvasive infections will allow for the development of specific treatments, which could provide the optimal outcome to patients recovering from this infection. Author Contributions: S.S. was the primary author of this review with contributions by P.C. P.C. and K.L.T. were involved in reviewing and editing the manuscript. All authors have read and agreed to the published version of the manuscript. Funding: This research was funded by the National Institute of Health, grant number NS101208 and the Department of Veterans Affairs, grant number BX000963. Nile Virus: Review of the Literature Long-Term Prognosis for Clinical West Nile Virus Infection The Global Ecology and Epidemiology of West Nile Virus West Nile virus Clinical features of West Nile virus epidemic in Dallas West Nile Virus Infection in the Central Nervous System Matrix-M TM adjuvanted envelope protein vaccine protects against lethal lineage 1 and 2 West Nile virus infection in mice Vaccination of Mice Using the West Nile Virus E-Protein in a DNA Prime-Protein Boost Strategy Stimulates Cell-Mediated Immunity and Protects Mice against a Lethal Challenge The live attenuated chimeric vaccine rWN/DEN4∆30 is well-tolerated and immunogenic in healthy flavivirus-naïve adult volunteers A Hydrogen Peroxide-Inactivated Virus Vaccine Elicits Humoral and Cellular Immunity and Protects against Lethal West Nile Virus Infection in Aged Mice Phase II, dose ranging study of the safety and immunogenicity of single dose West Nile vaccine in healthy adults ≥50 years of age A West Nile Virus DNA Vaccine Utilizing a Modified Promoter Induces Neutralizing Antibody in Younger and Older Healthy Adults in a Phase I Clinical Trial A West Nile Virus DNA Vaccine Induces Neutralizing Antibody in Healthy Adults during a Phase 1 Clinical Trial A live, attenuated recombinant West Nile virus vaccine Viral Pathogen-Associated Molecular Patterns Regulate Blood-Brain Barrier Integrity via Competing Innate Cytokine Signals Mechanism of West Nile Virus Neuroinvasion: A Critical Appraisal Risk Factors for West Nile Virus Neuroinvasive Disease, California Single Nucleotide Polymorphisms in Genes for 2 -5 -Oligoadenylate Synthetase and RNase L in Patients Hospitalized with West Nile Virus Infection Genetic Deficiency of Chemokine Receptor CCR5 Is a Strong Risk Factor for Symptomatic West Nile Virus Infection: A Meta-Analysis of 4 Cohorts in the US Epidemic Death Receptor-Mediated Apoptotic Signaling Is Activated in the Brain following Infection with West Nile Virus in the Absence of a Peripheral Immune Response Caspase 3-Dependent Cell Death of Neurons Contributes to the Pathogenesis of West Nile Virus Encephalitis Differential responses of human brain cells to West Nile virus infection Microglia across the lifespan: From origin to function in brain development, plasticity and cognition Origin and Functions of Tissue Macrophages Origin and differentiation of microglia Microglia Development and function The Role of Microglia in the Healthy Brain The Role of Microglia in Central Nervous System Immunity and Glioma Immunology Microglial Physiology and Pathophysiology: Insights from Genome-wide Transcriptional Profiling Features of Microglia and Neuroinflammation Relevant to Environmental Exposure and Neurotoxicity A polarizing question: Do M1 and M2 microglia exist? Alternatively activated microglia and macrophages in the central nervous system Review: Activation patterns of microglia and their identification in the human brain Sequential Activation of Microglia and Astrocyte Cytokine Expression Precedes Increased Iba-1 or GFAP Immunoreactivity following Systemic Immune Challenge Immune phenotypes of microglia in human neurodegenerative disease: Challenges to detecting microglial polarization in human brains Long-Distance Interferon Signaling within the Brain Blocks Virus Spread Neurophagy, the phagocytosis of live neurons and synapses by glia, contributes to brain development and disease Microglia-Mediated Inflammation and Neurodegenerative Disease Microglial M1/M2 polarization and metabolic states Activation of Intrinsic Immune Responses and Microglial Phagocytosis in an Ex Vivo Spinal Cord Slice Culture Model of West Nile Virus Infection Minocycline Has Anti-inflammatory Effects and Reduces Cytotoxicity in an Ex Vivo Spinal Cord Slice Culture Model of West Nile Virus Infection Impaired Autophagy Flux is Associated with Proinflammatory Microglia Activation Following Japanese Encephalitis Virus Infection Recent advances in understanding Japanese encephalitis Dengue virus infection increases microglial cell migration Role of microglia in the dissemination of Zika virus from mother to fetal brain A Tick-Borne Encephalitis Model in Infant Rats Infected With Langat Virus Activation of Innate Immune Responses in the Central Nervous System during Reovirus Myelitis Microglia are required for protection against lethal coronavirus encephalitis in mice Microglia influence host defense, disease, and repair following murine coronavirus infection of the central nervous system Spinal cord neuropathology in human West Nile virus infection Virology, Pathology, and Clinical Manifestations of West Nile Virus Disease The immune adaptor molecule SARM modulates tumor necrosis factor alpha production and microglia activation in the brainstem and restricts West Nile Virus pathogenesis TLR signaling controls lethal encephalitis in WNV-infected brain West Nile Virus spread and differential chemokine response in the central nervous system of mice: Role in pathogenic mechanisms of encephalitis Microglia-specific localisation of a novel calcium binding protein, Iba1 Intercellular Communication Is Key for Protective IFNα/β Signaling during Viral Central Nervous System Infection Interleukin 17 Receptor A, and Glutamate Signaling as Well as Flavivirus-Specific Upregulation of tRNA Synthetases Microglia in central nervous system repair after injury Pharmacologic Depletion of Microglia Increases Viral Load in the Brain and Enhances Mortality in Murine Models of Flavivirus-Induced Encephalitis Toll-like receptors and innate immunity Toll-like receptors in health and disease in the brain: Mechanisms and therapeutic potential Microglia Recognize Double-Stranded RNA via TLR3 Toll-Like Receptor 3 Has a Protective Role against West Nile Virus Infection Role of NS1 and TLR3 in Pathogenesis and Immunity of WNV Toll-like receptor 3 mediates West Nile virus entry into the brain causing lethal encephalitis The Essential, Nonredundant Roles of RIG-I and MDA5 in Detecting and Controlling West Nile Virus Infection Distinct RIG-I and MDA5 Signaling by RNA Viruses in Innate Immunity Characterization of retinoic acid-inducible gene-I expression in primary murine glia following exposure to vesicular stomatitis virus MAVS Expressed by Hematopoietic Cells Is Critical for Control of West Nile Virus Infection and Pathogenesis IL-34 is a tissue-restricted ligand of CSF1R required for the development of Langerhans cells and microglia CSF1R Ligands IL-34 and CSF1 Are Differentially Required for Microglia Development and Maintenance in White and Gray Matter Brain Regions CSF-1 controls cerebellar microglia and is required for motor function and social interaction Colony-stimulating factor 1 receptor inhibition prevents microglial plaque association and improves cognition in 3xTg-AD mice CSF1 receptor signaling is necessary for microglia viability, which unmasks a cell that rapidly repopulates the microglia-depleted adult brain Matrix Metalloproteinase 9 Facilitates West Nile Virus Entry into the Brain The Role of Microglia and Matrix Metalloproteinases Involvement in Neuroinflammation and Gliomas Matrix metalloproteinases as modulators of inflammation and innate immunity Intercellular adhesion molecule-1 gene expression by glial cells. Differential mechanisms of inhibition by IL-10 and IL-6 Dual microglia effects on blood brain barrier permeability induced by systemic inflammation West Nile Virus-Induced Cell Adhesion Molecules on Human Brain Microvascular Endothelial Cells Regulate Leukocyte Adhesion and Modulate Permeability of the In Vitro Blood-Brain Barrier Model T cells promote microglia-mediated synaptic elimination and cognitive dysfunction during recovery from neuropathogenic flaviviruses A complement-microglial axis drives synapse loss during virus-induced memory impairment To Go or Stay: The Development, Benefit, and Detriment of Tissue-Resident Memory CD8 T Cells during Central Nervous System Viral Infections Update on T cells in the virally infected brain: Friends and foes CD4+ T-Cell Responses Are Required for Clearance of West Nile Virus from the Central Nervous System Microglia in Memory Decline from Zika Virus and West Nile Virus Infection The role of microglia in viral encephalitis: A review The Complement System: An Unexpected Role in Synaptic Pruning During Development and Disease The Classical Complement Cascade Mediates CNS Synapse Elimination Microglia Sculpt Postnatal Neural Circuits in an Activity and Complement-Dependent Manner Chapter Two-Complement System in Neural Synapse Elimination in Development and Disease Granulocyte Macrophage Colony Stimulating Factor Treatment is Associated with Improved Cognition in Cancer Patients GM-CSF Upregulated in Rheumatoid Arthritis Reverses Cognitive Impairment and Amyloidosis in Alzheimer Mice The Kaleidoscope of Microglial Phenotypes This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license The authors declare no conflict of interest.Vaccines 2020, 8, 485