P2 Receptors of microglia: sensors for danger signals in the CNS

Following tissue damage or invasion by pathogens a number of soluble signals are generated to alert the immune system of the impending danger and initiate inflammation. Some danger signals are released from injured or dying cells. Once released, danger signals activate a autocrine/paracrine network that recruits inflammatory cells, stimulates cytokine production, promotes dendritic cell maturations and increases the antigen (Ag) presenting efficiency. These events also occurs in the central nervous system (CNS) where cytokines and cytokine‐releasing cells have a central role in spreading inflammation. P2 receptors of microglia are the focus of increasing interest, especially after they were shown to mediate chemotaxis, cytokine release and cell death in microglia. We propose that P2 receptors may function in microglia as sensors of the ATP/UTP concentration in the pericellular space, and therefore as sensors of danger signals in the CNS. Furthermore, microglia itself can release ATP when stimulated by inflammatory stimuli. Thus extracellular nucleotides may be included in the family of the early inflammatory mediators acting via P2 receptors to spread inflammation in the CNS. References
1. Ferrari D., Villalba M., Chiozzi P., Falzoni S., Ricciardi‐Castagnoli P. and Di Virgilio F. (1996) Mouse microglia cells express a plasma membrane pore gated by extracellular ATP. J. Immunol. 156 , 1531–1539. 2. Ferrari D., Chiozzi P., Falzoni S., Hanau S. and Di Virgilio F. (1997) Purinergic modulation of interleukin‐1B release from microglia cells stimulated with bacterial endotoxin. J. Exp. Med. 185 , 579–582.     

miR‐124 Contributes to the functional maturity of microglia

During early development of the central nervous system (CNS), a subset of yolk‐sac derived myeloid cells populate the brain and provide the seed for the microglial cell population, which will self‐renew throughout life. As development progresses, individual microglial cells transition from a phagocytic amoeboid state through a transitional morphing phase into the sessile, ramified, and normally nonphagocytic microglia observed in the adult CNS under healthy conditions. The molecular drivers of this tissue‐specific maturation profile are not known. However, a survey of tissue resident macrophages identified miR‐124 to be expressed in microglia. In this study, we used transgenic zebrafish to overexpress miR‐124 in the mpeg1 expressing yolk‐sac‐derived myeloid cells that seed the microglia. In addition, a systemic sponge designed to neutralize the effects of miR‐124 was used to assess microglial development in a miR‐124 loss‐of‐function environment. Following the induction of miR‐124 overexpression, microglial motility and phagocytosis of apoptotic cells were significantly reduced. miR‐124 overexpression in microglia resulted in the accumulation of residual apoptotic cell bodies in the optic tectum, which could not be achieved by miR‐124 overexpression in differentiated neurons. Conversely, expression of the miR‐124 sponge caused an increase in the motility of microglia and transiently rescued motility and phagocytosis functions when activated simultaneously with miR‐124 overexpression. This study provides in vivo evidence that miR‐124 activity has a key role in the development of functionally mature microglia. © 2015 Wiley Periodicals, Inc. Develop Neurobiol 76: 507–518, 2016     

Microglia of medicinal leech (Hirudo medicinalis) express a specific activation marker homologous to vertebrate ionized calcium‐binding adapter molecule 1 (Iba1/alias aif‐1)

The Ionized calcium‐Binding Adapter molecule 1 (Iba1), also known as Allograft Inflammatory Factor 1 (AIF‐1), is a 17 kDa cytokine‐inducible protein, produced by activated macrophages during chronic transplant rejection and inflammatory reactions in Vertebrates. In mammalian central nervous system (CNS), Iba1 is a sensitive marker associated with activated macrophages/microglia and is upregulated following neuronal death or brain lesions. The medicinal leech Hirudo medicinalis is able to regenerate its CNS after injury, leading to a complete functional repair. Similar to Vertebrates, leech neuroinflammatory processes are linked to microglia activation and recruitment at the lesion site. We identified a gene, named Hmiba1, coding a 17.8 kDa protein showing high similarity with Vertebrate AIF‐1. The present work constitutes the first report on an Iba1 protein in the nervous system of an invertebrate. Immunochemistry and gene expression analyses showed that HmIba1, like its mammalian counterpart, is modulated in leech CNS by mechanical injury or chemical stimuli (ATP). We presently demonstrate that most of leech microglial cells migrating and accumulating at the lesion site specifically expressed the activation marker HmIba1. While the functional role of Iba1, whatever species, is still unclear in reactive microglia, this molecule appeared as a good selective marker of activated cells in leech and presents an interesting tool to investigate the functions of these cells during nerve repair events. © 2014 Wiley Periodicals, Inc. Develop Neurobiol 74: 987–1001, 2014     

Microglial functions and proteases

There is accumulating evidence that intracellular and extracellular proteases of microglia contribute to various events in the central nervous system (CNS) through both nonspecific and limited proteolysis. Cathepsin E and cathepsin S, endosomal/lysosomal proteases, have been shown to play important roles in the major histocompatibility complex (MHC) class II-mediated antigen presentation of microglia by processing of exogenous antigens and degradation of the invariant chain associated with MHC class II molecules, respectively. Some members of cathepsins are also involved in neuronal death after secreted from microglia and clearance of phagocytosed amyloid-β peptides. Tissue-type plasminogen activator, a serine protease, secreted from microglia participates in neuronal death, enhancement of N-methyl-d-aspartate receptor-mediated neuronal responses, and activation of microglia via either proteolytic or nonproteolytic activity. Calpain, a calcium-dependent cysteine protease, has been shown to play a pivotal role in the pathogenesis of multiple sclerosis by degrading myelin proteins extracellulary. Furthermore, matrix metalloproteases secreted from microglia also receive great attention as mediators of inflammation and tissue degradation through processing of pro-inflammatory cytokines and damage to the blood-brain barrier. The growing knowledge about proteolytic events mediated by microglial proteases will not only contribute to better understanding of microglial functions in the CNS but also may aid in the development of protease inhibitors as novel neuroprotective agents.     

Embryonic Medaka Model of Microglia in the Developing CNS Allowing In Vivo Analysis of Their Spatiotemporal Recruitment in Response to Irradiation

Radiation therapy (RT) is pivotal in the treatment of many central nervous system (CNS) pathologies; however, exposure to RT in children is associated with a higher risk of secondary CNS tumors. Although recent research interest has focused on the reparative and therapeutic role of microglia, their recruitment following RT has not been elucidated, especially in the developing CNS. Here, we investigated the spatiotemporal dynamics of microglia during tissue repair in the irradiated embryonic medaka brain by whole-mount in situ hybridization using a probe for Apolipoprotein E (ApoE), a marker for activated microglia in teleosts. Three-dimensional imaging of the distribution of ApoE-expressing microglia in the irradiated embryonic brain clearly showed that ApoE-expressing microglia were abundant only in the late phase of phagocytosis during tissue repair induced by irradiation, while few microglia expressed ApoE in the initial phase of phagocytosis. This strongly suggests that ApoE has a significant function in the late phase of phagocytosis by microglia in the medaka brain. In addition, the distribution of microglia in p53-deficient embryos at the late phase of phagocytosis was almost the same as in wild-type embryos, despite the low numbers of irradiation-induced apoptotic neurons, suggesting that constant numbers of activated microglia were recruited at the late phase of phagocytosis irrespective of the extent of neuronal injury. This medaka model of microglia demonstrated specific recruitment after irradiation in the developing CNS and could provide a useful potential therapeutic strategy to counteract the detrimental effects of RT.     

Expression of OX40 ligand in microglia activated by IFN-gamma sustains a protective CD4+ T-cell response in vitro

T-cell-dependent immunity in the central nervous system (CNS) is beneficial for neuroprotection, neurogenesis and even behavior. As a highly specialized site, the CNS is speculated to possess the means to maintain T-cell immune responses through its own resident cells. Therefore, we investigated whether microglia, the most potent antigen-presenting cells residing in the CNS, could sustain T-cell responses in vitro. We showed that interferon-γ (IFN-γ)-activated microglia (MG_IFN-γ) inducibly expressed an important immune co-stimulatory molecule, OX40 ligand (OX40L). Co-culture of activated CD4⁺ T cells with MG_IFN-γ significantly increased T-cell proliferation and decreased apoptosis, and these effects were markedly inhibited by addition of a neutralizing anti-OX40L monoclonal antibody. In addition, ligation of OX40L in MG_IFN-γ enhanced their production of insulin-like growth factor I (IGF-I). These results suggest that the expression of OX40L in microglia provides a molecular basis for the maintenance of T-cell survival, expansion of T cells and increased secretion of remedial growth factor from MG_IFN-γ, which may contribute to the protective effect in the CNS.     

Developmental Regulation of TREM2 and DAP12 Expression in the Murine CNS: Implications for Nasu-Hakola Disease

Trem2 is an orphan, DAP12 associated receptor constitutively expressed in vivo by subsets of microglia in the healthy adult murine CNS and in vitro by subsets of oligodendrocytes in neonatal mixed glial cultures. Loss of a functional Trem2 signaling pathway is the genetic cause of Nasu-Hakola disease. Whether the early onset cognitive dementia and myelin-pallor associated with this disorder are due to deficits in functional Trem2 signaling in microglia and/or oligodendrocytes is still being debated. Here, we find that Trem2/DAP12 expression is detected in embryonic day 14 CNS mRNA. Using dual immunohistochemistry/in situ hybridization, we find that both Trem2 and DAP12 expression always co-localized with markers of microglia/macrophages. However, Trem2/DAP12 positive microglia are found in very close apposition with CNP+ oligodendrocytes prior to myelination (post-natal day 1). In addition, CNS expression of TREM2 and DAP12 are not detected in PU.1KO which lack microglia and macrophages. Our data provide continuing support for Nasu-Hakola disease being identified as a cognitive disorder caused by a primary dysfunction of CNS microglia. Special issue article in honor of Dr. George DeVries.     

ATP and NO dually control migration of microglia to nerve lesions

Microglia migrate rapidly to lesions in the central nervous system (CNS), presumably in response to chemoattractants including ATP released directly or indirectly by the injury. Previous work on the leech has shown that nitric oxide (NO), generated at the lesion, is both a stop signal for microglia at the lesion and crucial for their directed migration from hundreds of micrometers away within the nerve cord, perhaps mediated by a soluble guanylate cyclase (sGC). In this study, application of 100 μM ATP caused maximal movement of microglia in leech nerve cords. The nucleotides ADP, UTP, and the nonhydrolyzable ATP analog AMP‐PNP (adenyl‐5′‐yl imidodiphosphate) also caused movement, whereas AMP, cAMP, and adenosine were without effect. Both movement in ATP and migration after injury were slowed by 50 μM reactive blue 2 (RB2), an antagonist of purinergic receptors, without influencing the direction of movement. This contrasted with the effect of the NO scavenger cPTIO (2‐(4‐carboxyphenyl)‐4,4,5,5‐teramethylimidazoline‐oxyl‐3‐oxide), which misdirected movement when applied at 1 mM. The cPTIO reduced cGMP immunoreactivity without changing the immunoreactivity of eNOS (endothelial nitric oxide synthase), which accompanies increased NOS activity after nerve cord injury, consistent with involvement of sGC. Moreover, the sGC‐specific inhibitor LY83583 applied at 50 μM had a similar effect, in agreement with previous results with methylene blue. Taken together, the experiments support the hypothesis that ATP released directly or indirectly by injury activates microglia to move, whereas NO that activates sGC directs migration of microglia to CNS lesions. © 2008 Wiley Periodicals, Inc. Develop Neurobiol, 2009     

Chronic Intermittent Hypoxia Exerts CNS Region-Specific Effects on Rat Microglial Inflammatory and TLR4 Gene Expression

Intermittent hypoxia (IH) during sleep is a hallmark of sleep apnea, causing significant neuronal apoptosis, and cognitive and behavioral deficits in CNS regions underlying memory processing and executive functions. IH-induced neuroinflammation is thought to contribute to cognitive deficits after IH. In the present studies, we tested the hypothesis that IH would differentially induce inflammatory factor gene expression in microglia in a CNS region-dependent manner, and that the effects of IH would differ temporally. To test this hypothesis, adult rats were exposed to intermittent hypoxia (2 min intervals of 10.5% O₂) for 8 hours/day during their respective sleep cycles for 1, 3 or 14 days. Cortex, medulla and spinal cord tissues were dissected, microglia were immunomagnetically isolated and mRNA levels of the inflammatory genes iNOS, COX-2, TNFα, IL-1β and IL-6 and the innate immune receptor TLR4 were compared to levels in normoxia. Inflammatory gene expression was also assessed in tissue homogenates (containing all CNS cells). We found that microglia from different CNS regions responded to IH differently. Cortical microglia had longer lasting inflammatory gene expression whereas spinal microglial gene expression was rapid and transient. We also observed that inflammatory gene expression in microglia frequently differed from that in tissue homogenates from the same region, indicating that cells other than microglia also contribute to IH-induced neuroinflammation. Lastly, microglial TLR4 mRNA levels were strongly upregulated by IH in a region- and time-dependent manner, and the increase in TLR4 expression appeared to coincide with timing of peak inflammatory gene expression, suggesting that TLR4 may play a role in IH-induced neuroinflammation. Together, these data indicate that microglial-specific neuroinflammation may play distinct roles in the effects of intermittent hypoxia in different CNS regions.     

Selective activation of microglia in spinal cord but not higher cortical regions following nerve injury in adult mouse

Neuronal plasticity along the pathway for sensory transmission including the spinal cord and cortex plays an important role in chronic pain, including inflammatory and neuropathic pain. While recent studies indicate that microglia in the spinal cord are involved in neuropathic pain, a systematic study has not been performed in other regions of the central nervous system (CNS). In the present study, we used heterozygous Cx3cr1 ^GFP/+mice to characterize the morphological phenotypes of microglia following common peroneal nerve (CPN) ligation. We found that microglia showed a uniform distribution throughout the CNS, and peripheral nerve injury selectively activated microglia in the spinal cord dorsal horn and related ventral horn. In contrast, microglia was not activated in supraspinal regions of the CNS, including the anterior cingulate cortex (ACC), prefrontal cortex (PFC), primary and secondary somatosensory cortex (S1 and S2), insular cortex (IC), amygdala, hippocampus, periaqueductal gray (PAG) and rostral ventromedial medulla (RVM). Our results provide strong evidence that nerve injury primarily activates microglia in the spinal cord of adult mice, and pain-related cortical plasticity is likely mediated by neurons.     

Osteopontin alters the functional profile of porcine microglia in vitro

OPN (osteopontin) is a secreted glycoprotein predominantly expressed in bone matrix and kidney tissue. More recently, a neuroprotective role has been attributed to this cytokine since it can be up‐regulated by microglia in neurodegeneration and inflammation. We demonstrate the expression of OPN within primary cultured microglia. Microglia incubated in vitro with different concentrations (0.1 fM–1 nM) of recombinant OPN showed increased proliferation at 10 fM. Moreover, conditioned medium of LLC‐PK1 cells, a pig renal epithelial cell line and a known source of secreted OPN, more than doubled the rate of proliferation of microglia. Addition of an anti‐OPN polyclonal antibody completely reversed this effect. Treatment with OPN dose‐dependently also inhibited microglial superoxide production. In contrast, phagocytosis of fluorescent‐labelled beads was enhanced by OPN. In conclusion, OPN shifts microglia, at least in vitro, to an alternative functional profile more fit to the immune‐balanced microenvironment of the CNS (central nervous system).     

Resident and infiltrating central nervous system APCs regulate the emergence and resolution of experimental autoimmune encephalomyelitis

During experimental autoimmune encephalomyelitis (EAE), autoreactive Th1 T cells invade the CNS. Before performing their effector functions in the target organ, T cells must recognize Ag presented by CNS APCs. Here, we investigate the nature and activity of the cells that present Ag within the CNS during myelin oligodendrocyte glycoprotein-induced EAE, with the goal of understanding their role in regulating inflammation. Both infiltrating macrophages (Mac-1(+)CD45(high)) and resident microglia (Mac-1(+)CD45(int)) expressed MHC-II, B7-1, and B7-2. Macrophages and microglia presented exogenous and endogenous CNS Ags to T cell lines and CNS T cells, resulting in IFN-gamma production. In contrast, Mac-1(-) cells were inefficient APCs during EAE. Late in disease, after mice had partially recovered from clinical signs of disease, there was a reduction in Ag-presenting capability that correlated with decreased MHC-II and B7-1 expression. Interestingly, although CNS APCs induced T cell cytokine production, they did not induce proliferation of either T cell lines or CNS T cells. This was attributable to production by CNS cells (mainly by macrophages) of NO. T cell proliferation was restored with an NO inhibitor, or if the APCs were obtained from inducible NO synthase-deficient mice. Thus, CNS APCs, though essential for the initiation of disease, also play a down-regulatory role. The mechanisms by which CNS APCs limit the expansion of autoreactive T cells in the target organ include their production of NO, which inhibits T cell proliferation, and their decline in Ag presentation late in disease.     

Interleukin-10 inhibits both production of cytokines and expression of cytokine receptors in microglia

Microglia, macrophage-like cells in the CNS, are multifunctional cells; they play an important role in removal of dead cells or their remnants by phagocytosis in the CNS degeneration and are one of important cells in the CNS cytokine network to produce and respond to a variety of cytokines. The functions of microglia are regulated by inhibitory cytokines. We have reported the expression of interleukin (IL)-10, one of the inhibitory cytokines, and its receptor in mouse microglia; therefore, IL-10 may affect microglial functions. In this study, we investigated the effects of IL-10 on purified microglia in culture. IL-10 inhibited lipopolysaccharide-induced IL-1beta and tumor necrosis factor-alpha production, lysosomal enzyme activity, and superoxide anion production in a dose-dependent manner, but did not affect granulocyte/ macrophage colony-stimulating factor-dependent proliferation of microglia. IL-10 also decreased the expression of both IL-6 receptor and lipopolysaccharide-induced IL-2 receptor but not IL-4 receptor on microglia as measured by flow cytometric analysis with an indirect immunofluorescence technique. IL-10 also decreased mRNA expression of IL-2 and IL-6 cytokine receptors. These results suggest that IL-10 is a unique and potent inhibitory factor in the CNS cytokine network involved in decreasing the expression of cytokine receptors as well as cytokine production by microglia.     

Detection of MicroRNAs in Microglia by Real-time PCR in Normal CNS and During Neuroinflammation

Microglia are cells of the myeloid lineage that reside in the central nervous system (CNS)¹. These cells play an important role in pathologies of many diseases associated with neuroinflammation such as multiple sclerosis (MS)². Microglia in a normal CNS express macrophage marker CD11b and exhibit a resting phenotype by expressing low levels of activation markers such as CD45. During pathological events in the CNS, microglia become activated as determined by upregulation of CD45 and other markers³. The factors that affect microglia phenotype and functions in the CNS are not well studied. MicroRNAs (miRNAs) are a growing family of conserved molecules (~22 nucleotides long) that are involved in many normal physiological processes such as cell growth and differentiation⁴ and pathologies such as inflammation⁵. MiRNAs downregulate the expression of certain target genes by binding complementary sequences of their mRNAs and play an important role in the activation of innate immune cells including macrophages⁶ and microglia⁷. In order to investigate miRNA-mediated pathways that define the microglial phenotype, biological function, and to distinguish microglia from other types of macrophages, it is important to quantitatively assess the expression of particular microRNAs in distinct subsets of CNS-resident microglia. Common methods for measuring the expression of miRNAs in the CNS include quantitative PCR from whole neuronal tissue and in situ hybridization. However, quantitative PCR from whole tissue homogenate does not allow the assessment of the expression of miRNA in microglia, which represent only 5-15% of the cells of neuronal tissue. Hybridization in situ allows the assessment of the expression of microRNA in specific cell types in the tissue sections, but this method is not entirely quantitative. In this report we describe a quantitative and sensitive method for the detection of miRNA by real-time PCR in microglia isolated from normal CNS or during neuroinflammation using experimental autoimmune encephalomyelitis (EAE), a mouse model for MS. The described method will be useful to measure the level of expression of microRNAs in microglia in normal CNS or during neuroinflammation associated with various pathologies including MS, stroke, traumatic injury, Alzheimer''s disease and brain tumors.     

Microglia and Microglia-Like Cell Differentiated from DC Inhibit CD4 T Cell Proliferation

The central nervous system (CNS) is generally regarded as a site of immune privilege, whether the antigen presenting cells (APCs) are involved in the immune homeostasis of the CNS is largely unknown. Microglia and DCs are major APCs in physiological and pathological conditions, respectively. In this work, primary microglia and microglia-like cells obtained by co-culturing mature dendritic cells with CNS endothelial cells in vitro were functional evaluated. We found that microglia not only cannot prime CD4 T cells but also inhibit mature DCs (maDCs) initiated CD4 T cells proliferation. More importantly, endothelia from the CNS can differentiate maDCs into microglia-like cells (MLCs), which possess similar phenotype and immune inhibitory function as microglia. Soluble factors including NO lie behind the suppression of CD4 T cell proliferation induced by both microglia and MLCs. All the data indicate that under physiological conditions, microglia play important roles in maintaining immune homeostasis of the CNS, whereas in a pathological situation, the infiltrated DCs can be educated by the local microenvironment and differentiate into MLCs with inhibitory function.     

Hierarchical interactions among cytokines establish the functional state of microglia

Microglia rapidly respond to CNS injury yet the mechanisms leading to their activation and inactivation remain poorly defined. In particular, few studies have established how interactions among inflammatory mediators affect the innate immune response of microglia. To begin to understand the hierarchy of cytokine signalling we examined the effects of several cytokines on purified newborn and adult rat microglia in vitro, and we have examined the microglial response to injury in mice deficient in the IL‐1 type 1 receptor (IL‐1R1). Using several indices of activation, we find that IL‐1β, TNF‐α, and IL‐6 are potent microglial activators. By contrast, TGF‐β1 did not activate the cells and when TGFβ1 was administered prior to IL‐1β, it blocked the effects of IL‐1β. However, TGFβ1 was ineffective in antagonizing IL‐6. In null mice lacking the IL‐1R1, microglia inefficiently responded to injury, and IL‐6 induction was severely curtailed. These data establish a model of hierarchical signalling, whereby constitutive expression of TGF‐β1 in the CNS maintains microglia in a resting state. IL‐1, while an important microglial activator, is modifiable, whereas, the downstream cytokine, IL‐6, is a strong stimulus that is unaffected by other modifiers of the innate immune response. Acknowledgements: Supported by NMSS award #RG 3837.     

Molecular consequences of activated microglia in the brain: overactivation induces apoptosis

Microglia, the resident immune cells in the brain, play a pivotal role in immune surveillance, host defense, and tissue repair in the CNS. In response to immunological challenges, microglia readily become activated as characterized by morphological changes, expression of surface antigens, and production of immune modulators that impact on neurons to induce neurodegeneration. However, little is known concerning the fate of activated microglia. In the present study, stimulation of cultured rat primary microglia with 1 ng/mL of the inflammagen lipopolysaccharide (LPS) resulted in a maximal activation as measured by the release of tumor necrosis factor alpha (TNF alpha). However, treatment with higher concentrations of LPS resulted in significantly lower quantities of detectable TNF alpha. Further analysis revealed that overactivation of microglia with higher concentrations of LPS (> 1 ng/mL) resulted in a time- and dose-dependent apoptotic death of microglia as defined by DNA strand breaks, surface expression of apoptosis-specific markers (phosphatidylserine), and activation of caspase-3. In contrast, astrocytes were insensitive to LPS-induced cytotoxicity. In light of the importance of microglia and the limited replenishment mechanism, depletion of microglia from the brain may severely hamper its capacity for combating inflammatory challenges and tissue repair. Furthermore, overactivation-induced apoptosis of microglia may be a fundamental self-regulatory mechanism devised to limit bystander killing of vulnerable neurons.     

Protein 4.1 G localizes in rodent microglia

Although it was reported that protein 4.1 G, a cytoskeletal protein characterized by its general expression in the body, interacts with some signal transduction molecules in the central nervous system (CNS), its distribution and significance in vivo remained to be elucidated. In the present study, we have identified 4.1 G-positive cells in the rodent CNS, and demonstrated its immunolocalization in the developing mouse CNS. In the rodent CNS, 4.1 G was colocalized with markers for microglia, such as CD45, OX-42 and ionized calcium-binding adapter molecule 1 (Iba1), but not with markers for neuronal or other glial cells. Additionally, colocalization of 4.1 G and A1 adenosine receptor was observed in the mouse cerebrum. In a mixed glial culture, most OX-42-positive microglia were positive for 4.1 G, and 4.1 G isoforms of the same molecular weight as in the rat brain were expressed in cultured microglia, where 4.1 G mRNA was detected by RT-PCR. In the developing mouse cerebral cortex, 4.1 G was detected in immature microglia, which were positive for Iba1. These results indicate that 4.1 G in the CNS is mainly distributed in microglia in vivo. Considering the interactions between 4.1 G and the signal transduction molecules, putative roles have been propsed for 4.1 G in microglial functions in the CNS.