Study of the transformation of amoeboid microglial cells into microglia labelled with the isolectin Griffonia simplicifolia in postnatal rats.

The transformation of amoeboid microglial cells into ramified microglial cells in the brain of postnatal rats has been studied by labeling the cells with the isolectin Griffonia simplicifolia (GSA1-B4). The latter served as a specific membrane marker of the cell type. Thus, at the light-microscopic level, the amoeboid microglial cells in 1- to 5-day-old rats were intensely stained with GSA1-B4. All the stained cells appeared round. In 10-day-old rats, while most of the stained cells were round, some had assumed an oval appearance. In older rats, i.e. 15-22 days, all the stained cells became flattened or fusiform with long cytoplasmic processes. The present electron-microscopic study confirmed the above features but also added the fact that the reaction for GSA1-B4 was localized at the plasma membrane in the amoeboid microglial cells in all the age groups studied. The reaction for the isolectin was also detected in some vacuoles in the cytoplasm of the round cells. It was concluded from this study that the round amoeboid microglial cells differentiate to become the ramified microglia with age. In the course of this transformation, they retained specific membrane receptors for the isolectin which distinguished them from other glial cell types.     

Microglial Activation Promotes Cell Survival in Organotypic Cultures of Postnatal Mouse Retinal Explants

The role of microglia during neurodegeneration remains controversial. We investigated whether microglial cells have a neurotoxic or neuroprotective function in the retina. Retinal explants from 10-day-old mice were treated in vitro with minocycline to inhibit microglial activation, with LPS to increase microglial activation, or with liposomes loaded with clodronate (Lip-Clo) to deplete microglial cells. Flow cytometry was used to assess the viability of retinal cells in the explants and the TUNEL method to show the distribution of dead cells. The immunophenotypic and morphological features of microglia and their distribution were analyzed with flow cytometry and immunocytochemistry. Treatment of retinal explants with minocycline reduced microglial activation and simultaneously significantly decreased cell viability and increased the presence of TUNEL-labeled cell profiles. This treatment also prevented the migration of microglial cells towards the outer nuclear layer, where cell death was most abundant. The LPS treatment increased microglial activation but had no effect on cell viability or microglial distribution. Finally, partial microglial removal with Lip-Clo diminished the cell viability in the retinal explants, showing a similar effect to that of minocycline. Hence, cell viability is diminished in retinal explants cultured in vitro when microglial cells are removed or their activation is inhibited, indicating a neurotrophic role for microglia in this system.     

myc-Immortalized Microglial Cells Express a Functional Platelet-Activating Factor Receptor

Abstract: The autacoid platelet-activating factor (PAF) takes part in a complex network of interactions regarding the cellular components of nervous tissues. Efforts aimed at characterizing the effects of PAF in the brain have been recently focalized on neurons because PAF exerts pleiotropic effects on these cells. Less attention has instead been paid to the glial component of the brain. We have used microglial cell lines immortalized from 13-day-old mouse embryo brains by a myc -transducing retrovirus. When exposed to physiological doses of PAF, immortalized microglial cells showed increases in intracellular free calcium concentrations due to release of calcium from internal stores, as well as to extracellular calcium influxes. These profiles of reactivity were independent from the immortalizing process, being observable in primary microglial cultures and in immortalized clones showing different proliferative rates. PAF was also able to induce transient expression of the c- fos protooncogene in serum-starved cultures and induced a strong chemotactic response in microglial cells. In contrast with control macrophage cultures, PAF did not promote prostaglandin or leukotriene synthesis in immortalized cells. This was most likely due to the low amount of total arachidonic acid found in immortal microglia, with respect to that observed in freshly isolated cells. Our data suggest that several of the effects observed after PAF stimulation might be independent from PAF-induced arachidonic acid metabolism. The availability of an in vitro microglial model might now help in studying the proinflammatory effects of PAF, both direct or microglia mediated, in the neural environment.     

In situ measurement of superoxide and hydroxyl radicals by frequency mixing detection technique

Frequency mixing magnetic detection (FMMD) was used to detect superoxide from hypoxanthine and xanthine reaction and to detect hydroxyl radical from the Fenton reaction. FMMD was also applied to measure the reactive oxygen species (ROS) level released from microglial cells. We could assess the formation and extinction of the free radicals without a spin trap reagent. The FMMD signal amplitude scaled with the concentration of the radicals. It was verified that no signals are obtained from the substrates and reagents. Based on the observations and on previous research, we suggest that the FMMD signals originate from superoxide and hydroxyl radicals, indicating that FMMD can be used to detect O-centered radicals. Subsequent analysis of free radicals generated from living microglial cells showed that there were significant differences between the activated microglial cells and resting ones. The results of this research are promising regarding the applications of FMMD for in situ measurement of free radicals from various sources, including the cell.     

Postanoxic damage of microglial cells is mediated by xanthine oxidase and cyclooxygenase

Brain ischemia and the following reperfusion are important causes for brain damage and leading causes of brain morbidity and human mortality. Numerous observations exist describing the neuronal damage during ischemia/reperfusion, but the outcome of such conditions towards glial cells still remains to be elucidated.

Microglia are resident macrophages in the brain. In this study, we investigated the anoxia/reoxygenation caused damage to a microglial cell line via determination of energy metabolism, free radical production by dichlorofluorescein fluorescence and nitric oxide production by Griess reagent. Consequences of oxidant production were determined by measurements of protein oxidation and lipid peroxidation, as well. By using site-specific antioxidants and inhibitors of various oxidant-producing pathways, we identified major sources of free radical production in the postanoxic microglial cells. The protective influences of these compounds were tested by measurements of cell viability and apoptosis. Although, numerous free radical generating systems may contribute to the postanoxic microglial cell damage, the xanthine oxidase- and the cyclooxygenase-mediated oxidant production seems to be of major importance.     

CD40 expression by microglial cells is required for their completion of a two-step activation process during central nervous system autoimmune inflammation

Microglial cells are monocytic lineage cells that reside in the CNS and have the capacity to become activated during various pathological conditions. Although it was demonstrated that activation of microglial cells could be achieved in vitro by the engagement of CD40-CD40L interactions in combination with proinflammatory cytokines, the exact factors that mediate activation of microglial cells in vivo during CNS autoimmunity are ill-defined. To investigate the role of CD40 in microglial cell activation during experimental autoimmune encephalomyelitis (EAE), we used bone marrow chimera mice that allowed us to distinguish microglial cells from peripheral macrophages and render microglial cells deficient in CD40. We found that the first step of microglial cell activation was CD40-independent and occurred during EAE onset. The first step of activation consisted of microglial cell proliferation and up-regulation of the activation markers MHC class II, CD40, and CD86. At the peak of disease, microglial cells underwent a second step of activation, which was characterized by a further enhancement in activation marker expression along with a reduction in proliferation. The second step of microglial cell activation was CD40-dependent and the failure of CD40-deficient microglial cells to achieve a full level of activation during EAE was correlated with reduced expansion of encephalitogenic T cells and leukocyte infiltration in the CNS, and amelioration of clinical symptoms. Thus, our findings demonstrate that CD40 expression on microglial cells is necessary to complete their activation process during EAE, which is important for disease progression.     

Morphological studies on neuroglia

The postnatal development of microglial cells was investigated in the neonatal rat brain by use of light- and electron microscopy, including enzyme-histochemical techniques. Microglial cells were selectively stained by demonstration of their nucleoside diphosphatase (NDPase) activity and classified into three types: 1) In the early postnatal period "primitive microglial cells" showing scantily ramified processes were found in the cerebral cortex, the hippocampal formation, and the hypothalamus. During the course of the first postnatal week the processes of this cell type developed gradually and the cells were transformed into typical ramified microglial cells, called "resting microglial cells". 2) "Amoeboid microglial cells "showing typical features of macrophages were characteristic of the cerebral white matter. 3) "Round microglial cells" possessing a round soma and few pseudopodia but no characteristic processes occurred in large numbers in the subventricular zone of the lateral ventricle and as single elements in the vicinity of blood vessels. Histochemically, thiamine pyrophosphatase (TPPase) was demonstrated only in the fully developed, ramified microglial cells ("resting microglial cells"), which could be readily observed in the central nervous tissue from the age of 14 day. "Round and amoeboid microglial cells" did not show TPPase activity and disappeared after 14 days of postnatal life. By use of electron microscopy, in neonatal rats NDPase activity was apparent in the plasma membrane of the three types of microglial cells ("primitive, round, and amoeboid" types). They showed basically similar submicroscopic characteristics, i.e., well-developed Golgi apparatus, long strands of rough-surfaced endoplasmic reticulum, single dense bodies and vacuoles, and numerous ribosomes. "Amoeboid microglial cells" were characterized by their well-developed cytoplasmic vacuoles and phagocytic inclusion bodies. The present study strongly suggests a mesodermal origin for these microglial elements.     

A histochemical study of the microglial cells in the brain of Salamandra salamandra by lectin binding.

Seven biotinylated lectins were utilized as histochemical markers for the study of microglial cells in the brain of Salamandra salamandra. It has been demonstrated that SBA, BSA-I, BSA-I-B4 and RCA120 label the microglial cells and, on the basis of the binding selectivity of the single lectins for specific carbohydrates, it was found that alpha-galactosyl residues are present in high density on the microglial membrane of S. salamandra. The reaction was localized not only to the ramified microglial cells, but also to other round cells without extensions, interpreted as ameboid microglial cells. The results show that lectin binding is a reliable molecular probe for identifying microglial cells in urodels.     

Specific immunolabeling of brain macrophages and microglial cells in the developing and mature chick central nervous system.

The present study showed that the HIS-C7 monoclonal antibody, which recognizes the chick form of CD45, is a specific marker for macrophages/microglial cells in the developing and mature chick central nervous system (CNS). HIS-C7-positive cells were characterized according to their morphological features and chronotopographical distribution patterns within developing and adult CNS, similar to those of macrophages/microglial cells in the quail CNS and confirmed by their histochemical labeling with Ricinus communis agglutinin I, a lectin that recognizes chick microglial cells. Therefore, the HIS-C7 antibody is a valuable tool to identify brain macrophage and microglial cells in studies of the function, development, and pathology of the chick brain. CD45 expression differed between chick microglia (as revealed with HIS-C7 antibody) and mouse microglial cells (as revealed with an antibody against mouse form of CD45). Thus, a discontinuous label was seen on mouse microglial cells with the anti-mouse CD45 immunostaining, whereas the entire surface of chick microglial cells was labeled with the anti-chick CD45 staining. The functional relevance of these differences between species has yet to be determined.     

Potassium channel blockers tetraethylammonium and 4-aminopyridine fail to prevent microglial activation induced by elevated potassium concentration

The effect of potassium channel blocker tetraethylammonium and 4-aminopyridine was examined on the elevated K+ concentration-induced microglial activation on rat hippocampal slice preparations. Microglial cells were detected by immunohistochemisty with a monoclonal antibody (OX 42) raised against a type 3 complement receptor. During activation the morphology of the microglial cells changes and the staining intensity increases. The degree of microglial activation was determined by measuring the integrated optical density of the cells. Tetraethylammonium and 4-aminopyridine failed to reduce the elevated K+ concentration-induced microglial activation. Both potassium channel blockers, when applied on the hippocampal slices without K+, caused significantly increased microglial activation as compared to the control slices. In order to check whether the functional alteration of the neuronal population induced by 4-aminopyridine caused the activation of the microglial cells, Schaffer collaterals were cut to block spreading of epileptiform hyperactivity of the CA3 pyramidal cells to the CA1 region. No significant differences were found in microglial activation between the CA3 and CA1 regions, indicating that the effect of 4-aminopyridine on microglial cells is independent of the epileptiform activity caused by the drug.     

Attenuation of Dichlorvos-Induced Microglial Activation and Neuronal Apoptosis by 4-Hydroxy TEMPO

The neurotoxic consequences of acute high-level as well as chronic low-level organophosphates exposure are associated with a range of abnormalities in nerve functions. Previously, we have shown that after 24 h of dichlorvos exposure, microglia become activated and secrete pro-inflammatory molecules like nitric oxide, tumour necrosis factor-α and interleukin-1β. Here, we extended our findings and focused on the neuronal damage caused by dichlorvos via microglial activation. For this, neurons and microglia were isolated separately from 1-day-old Wistar rat pups. Microglia were treated with dichlorvos for 24 h and supernatant was collected (dichlorvos-induced conditioned medium, DCM). However, when 4-hydroxy TEMPO (4-HT) pretreatment was given, we observed significant attenuation of dichlorvos-induced microglial activation; we also collected the supernatant of this culture (4-HT + DCM, TDCM). Next, we checked the effects of DCM on neurons and found heavy loss in viability as evident from NF-H immunostaining and MTT results, whereas dichlorvos alone-treated neurons showed comparatively less damage. However, we observed significant increase in neuronal viability when cells were treated with TDCM. Semi-quantitative PCR and western blot results revealed significant increase in p53, Bax and cytochrome c levels along with caspase 3 activation after 24 h of DCM treatment. However, TDCM-treated neurons showed significant decrease in the expression of these pro-apoptotic molecules. Taken together, these findings suggest that 4-HT can significantly attenuate dichlorvos-induced microglial activation and prevent apoptotic neuronal cell death.     

Degradation of oxidized extracellular proteins by microglia

In living organisms a permanent oxidation of protein oxidation occurs. The degradation of intracellular oxidized proteins is intensively studied, but knowledge about the fate of oxidatively modified extracellular proteins is still limited. We studied the fate of exogenously added oxidized proteins in microglial cells. Both primary microglial cells and RAW cells are able to remove added oxidized laminin and myelin basic protein from the extracellular environment. Moderately oxidized proteins are degraded most efficiently, whereas strongly oxidized proteins are taken up by the microglial cells without an efficient degradation. Activation of microglial cells enhances the selective recognition and degradation of moderately oxidized protein substrates by proteases. Inhibitor studies also revealed an involvement of the lysosomal and the proteasomal system in the degradation of extracellular proteins. These studies let us conclude that microglial cells are able to remove oxidized proteins from the extracellular environment in the brain.     

Tocopherol-mediated modulation of age-related changes in microglial cells: turnover of extracellular oxidized protein material

Proteins accumulate during aging and form insoluble protein aggregates. Microglia are responsible for their removal from the brain. During aging, changes within the microglia might play a crucial role in the malfunctioning of these cells. Therefore, we isolated primary microglial cells from adult rats and compared their activation status and their ability to degrade proteins to that of microglial cells isolated from newborn animals. The ability of adult microglial cells to degrade proteins is substantially decreased. However, the preincubation of microglial cells with vitamin E improves significantly the degradation of such modified proteins. The degradation of proteins from apoptotic vesicles is decreased in microglia isolated from adult rats. This might be the result of a suppression of the CD36 receptor due to vitamin E treatment. We concluded that microglial cells isolated from adult organisms have different metabolic properties and seem to be a more valuable model to study age-related diseases.     

Role of very-late antigen-4 (VLA-4) in myelin basic protein-primed T cell contact-induced expression of proinflammatory cytokines in microglial cells

The presence of neuroantigen-primed T cells recognizing self-myelin antigens within the CNS is necessary for the development of demyelinating autoimmune disease like multiple sclerosis. This study was undertaken to investigate the role of myelin basic protein (MBP)-primed T cells in the expression of proinflammatory cytokines in microglial cells. MBP-primed T cells alone induced specifically the microglial expression of interleukin (IL)-1beta, IL-1alpha tumor necrosis factor alpha, and IL-6, proinflammatory cytokines that are primarily involved in the pathogenesis of MS. This induction was primarily dependent on the contact between MBP-primed T cells and microglia. The activation of microglial NF-kappaB and CCAAT/enhancer-binding protein beta (C/EBPbeta) by MBP-primed T cell contact and inhibition of contact-mediated microglial expression of proinflammatory cytokines by dominant-negative mutants of p65 and C/EBPbeta suggest that MBP-primed T cells induce microglial expression of cytokines through the activation of NF-kappaB and C/EBPbeta. In addition, we show that MBP-primed T cells express very late antigen-4 (VLA-4), and functional blocking antibodies to alpha4 chain of VLA-4 (CD49d) inhibited the ability of MBP-primed T cells to induce microglial proinflammatory cytokines. Interestingly, the blocking of VLA-4 impaired the ability of MBP-primed T cells to induce microglial activation of only C/EBPbeta but not that of NF-kappaB. This study illustrates a novel role of VLA-4 in regulating neuroantigen-primed T cell-induced activation of microglia through C/EBPbeta     

Ultrastructure of the proliferation of astrocytes and microglia]

Glial cell proliferation was studied during axonal reaction of hypoglossal nerve, and around stab wound in the brain cortex of the rat. The cytoplasm and chromosomes of astroglial mitoses were pale. Lipid droplets, few sparse dense bodies with heterogenous structure were present in the cytoplasm. The mitotic astrocytes had irregular outlines. The ultrastructure of "light microglial" cells was described; it was found that these cells divided and gave rise to microglial cells. The cytoplasm and the chromosomes of microglial mitoses were dense; the cytoplasm contained always groups of dense bodies and lipfuscine granules. The outlines of mitotic microglial cells were more regular.     

Myelin basic protein-primed T cells induce nitric oxide synthase in microglial cells. Implications for multiple sclerosis

The presence of autoreactive T cells recognizing self myelin antigens is necessary for the development of central nervous system autoimmune diseases such as multiple sclerosis (MS). The present study was undertaken to investigate the role of myelin basic protein (MBP)-primed T cells in the expression of inducible nitric oxide synthase (iNOS) in microglial cells. MBP-primed T cells alone markedly induced the production of NO and the expression of iNOS protein and mRNA in mouse BV-2 microglial cells. Similarly, MBP-primed T cells also induced the production of NO in mouse primary microglia. This induction of NO production was primarily dependent on the contact between MBP-primed T cells and microglia. The expression of very late antigen-4 (VLA-4) on the surface of MBP-primed T cells and inhibition of MBP-primed T cell-induced microglial NO production by functional blocking of antibodies to the alpha(4) chain of VLA-4 (CD49d) suggest that VLA-4 integrin on MBP-primed T cells plays an important role in contact-mediated induction of iNOS. Since IFN-beta has been used to treat MS patients, we examined the effect of IFN-beta on MBP-primed T cell-induced the production of NO. Surprisingly, IFN-beta alone induced the production of NO in microglial cells. However, the pretreatment of MBP-primed T cells with IFN-beta inhibited the expression of VLA-4 integrin on the surface of MBP-primed T cells and thereby inhibited the ability of those T cells to induce the production of NO in microglial cells. This study illustrates a novel role of neuroantigen-primed T cells in inducing contact-mediated expression of iNOS in microglial cells that may participate in the pathogenesis of MS.     

Modulation of NO and cytokines in microglial cells by Cu/Zn-superoxide dismutase.

The activation of microglial cells in response to neuropathological stimuli is one of the prominent features of human neurodegenerative diseases. Cytokines such as IL-1 beta and TNF-alpha and inflammation-related enzymes such as inducible nitric oxide synthase are usually induced during the activation of microglial cells. We investigated the modulation of the activation of microglial cell by transfecting a Cu/Zn-SOD cDNA into BV-2 cells. Parental and transfected BV-2 cells were then subjected to LPS stimulation. The results showed that in Cu/Zn-SOD-transfected BV-2 cells, the expression and activity of Cu/Zn-SOD increased. On the other hand, upon activation by LPS, these cells produced less NO, IL-1 beta, and TNF-alpha than the parental microglial cells. This finding suggests that superoxide may be an early signal triggering the induction of cytokines and that the transfected Cu/Zn-SOD may provide a neuroprotective function via suppression of microglial activation. In addition, this approach may provide a rationale for the development of treatments for neurodegenerative diseases.