Thiaminepyrophosphatase activity in the plasma membrane of microglia

An intense thiaminepyrophosphatase (TPPase) activity was demonstrated in glial cells and blood vessels in the central nervous system (CNS), when incubation was carried out with thiaminepyrophosphte (TPP, cocarboxylase), using the method of Novikoff and Goldfischer (1961). Glial cells with TPPSase activity were identified as microglia because they were morphologically similar to microglial cells in the sections stained with silver impregnation. TPPase activity was localized in the microglial perikaryon and in the processes, as viewed under a light microscope. Electron microscopically, enzyme activity was localized in the plasma membrane of microglia. We consider this activity to be a true TPPase activity hydrolyzing TPP, and we then went on to examine the substrate specificity, optimum pH, effect of chemical inhibitors and activators, and the effect of glutaraldehyde fixation. Our data are reported herein.     

Histochemical studies of the differentiation of microglial cells in the cerebral hemispheres of chick embryos and chicks

Summary Using histochemical procedures to reveal the presence, of nucleoside diphosphatase (NDPase), thiamine pyrophosphatase (TPPase) and acid phosphatase (AcPase), we investigated the appcarance, distribution and ultrastructure of amoeboid and microglial cells in the cerebral hemispheres of chick embryos and young chicks, in order to clucidate the relationship between these two cell populations. On day 6 of incubation, a few round cells exhibiting NDPase, TPPase and AcPase activity were first detected in the thin mantle layer of the cerebral hemisphere. In the corpus striatum, these round cells increased rapidly in abundance until day 13 of incubation, after which their numbers gradually decreased, so that, on day 19 of incubation, they had entirely disappeared. Between day 10 and day 17 or 18 of incubation, round cells were located mainly in the zone of the mantle layer closest to the lumen. On day 10 of incubation, NDPase-, TPPase-and AcPase-positive cells that had a few short cytoplasmic processes (poorly ramified cells) were detected in the intermediate, and basal zones of mantle layer. They increased in abundance until day 17 or 18 of incubation and thereafter rapidly decreased in number. Round and poorly ramified cells exhibited NDPase activity on their plasma membranes and in their cytoplasmic vacuoles, with TPPase and AcPase activity being localized within their vacuoles. On day 19 of incubation, NDPase-and TPPase-positive cells with long, well-ramified cytoplasmic processes (well-ramified cells) were observed in the corpus striatum, these being mainly localized in the basal zone. After hatching, these cells increased rapidly in abundance and were distributed throughout the corpus striatum. These cells displayed NDPase and TPPase activity on their plasma membranes. These findings suggest that the round, the poorly ramified and the well-ramified cells belong to a single cell population.     

Histochemical studies of the differentiation of microglial cells in the cerebral hemispheres of chick embryos and chicks

Using histochemical procedures to reveal the presence of nucleoside diphosphatase (NDPase), thiamine pyrophosphatase (TPPase) and acid phosphatase (AcPase), we investigated the appearance, distribution and ultrastructure of amoeboid and microglial cells in the cerebral hemispheres of chick embryos and young chicks, in order to elucidate the relationship between these two cell populations. On day 6 of incubation, a few round cells exhibiting NDPase, TPPase and AcPase activity were first detected in the thin mantle layer of the cerebral hemisphere. In the corpus striatum, these round cells increased rapidly in abundance until day 13 of incubation, after which their numbers gradually decreased, so that, on day 19 of incubation, they had entirely disappeared. Between day 10 and day 17 or 18 of incubation, round cells were located mainly in the zone of the mantle layer closest to the lumen. On day 10 of incubation, NDPase-, TPPase- and AcPase-positive cells that had a few short cytoplasmic processes (poorly ramified cells) were detected in the intermediate and basal zones of mantle layer. They increased in abundance until day 17 or 18 of incubation and thereafter rapidly decreased in number. Round and poorly ramified cells exhibited NDPase activity on their plasma membranes and in their cytoplasmic vacuoles, with TPPase and AcPase activity being localized within their vacuoles. On day 19 of incubation, NDPase- and TPPase-positive cells with long, well-ramified cytoplasmic processes (well-ramified cells) were observed in the corpus striatum, these being mainly localized in the basal zone. After hatching, these cells increased rapidly in abundance and were distributed throughout the corpus striatum.(ABSTRACT TRUNCATED AT 250 WORDS)     

Pinocytosis as a select marker of ramified microglia in vivo and in vitro

Based on previous observations in tissue culture, we investigated pinocytotic activity as a potential cell marker for brain microglia. This functional activity was assessed in three different preparations derived from rat: primary cultures of mixed cerebral cortical cells, tissue slabs of whole cerebrum, and cultures of isolated or enriched microglial cells. Each preparation was incubated with the fluorescent dye lucifer yellow as a soluble tracer and then processed for light microscopy. Under the conditions utilized, ramified microglia specifically exhibited differentially high pinocytotic labeling in all cases; the dye was mainly localized within the cell somata, where it was sequestered in pinocytotic vesicles. In each preparation, the identity of the labeled cell population was confirmed as microglia through immunohistochemical staining with the monoclonal antibody (MAb) OX-42, a specific microglial marker. Therefore, pinocytotic labeling is proposed as a select cell marker for microglia, which may be extremely useful in the identification and study of ramified microglial cells.     

Ultrastructural localization of phosphatase activity in the guinea pig pineal gland by the cerium technique

Thiamine pyrophosphatase (TPPase), nucleoside diphosphatase (NDPase), and glucose-6-phosphatase (G-6-Pase) were localized by the cerium technique in guinea pig pinealocytes and compared with the corresponding lead technique. NDPase and TPPase were also compared at different pH values using the cerium technique. Vibratome sections of perfusion-fixed tissue were incubated with cerium chloride or lead nitrate. Substrates used were thiamine pyrophosphate (for TPPase), sodium inosine diphosphate (NDPase), and disodium glucose-6-phosphate (G-6-Pase). The 1-2 trans saccules of the Golgi apparatus showed TPPase and NDPase activity but none for G-6-Pase. The endoplasmic reticulum (ER) cisternae and perinuclear space had NDPase and G-6-Pase activity but not TPPase. The abluminal plasmalemma of endothelial cells and the plasmalemma of Schwann cells demonstrated TPPase and NDPase activity but the luminal plasmalemma of the endothelial cells and the plasmalemma of pinealocyte processes showed only NDPase activity. TPPase was active at all pH values tested, but NDPase was most active at pH values of 6.5 and 7.0. Lead phosphate precipitate was frequently seen in nuclei, perinuclear space, ER cisternae, and "synaptic" vesicles when lead was used as the capturing agent. These sites were usually not labeled when cerium was used.     

Dynamic distribution of the Golgi marker thiamine pyrophosphatase is modulated by brefeldin A in rat hepatoma cells

Cytochemical electron microscopy of cultured rat hepatoma cells (AH-130) demonstrated that thiamine pyrophosphatase (TPPase) activity was localized in the Golgi complex. When the cells were treated with brefeldin A (BFA, 2.5 micrograms/ml) for 10 min, the characteristic structure of the Golgi stack was no longer observed, and TPPase was cytochemically stained in the vesicular and tubular structures scattered in the cytoplasm. A longer exposure of the cells to the drug (20 min to 1 h) resulted in the distribution of the TPPase activity in the endoplasmic reticulum (ER) and nuclear envelope. Such an unusual distribution of the enzyme activity, however, was reversible even in the presence of BFA. At 2 h after the exposure, the TPPase activity disappeared from the ER and was concentrated again in the vesicular and tubular structures. The enzyme activity was finally localized in the Golgi complex which was reassembled by 4 h after the exposure. The reversible effect of BFA may be due to a possible metabolism of the drug into an inert form during the incubation. Taken together, these results indicate that BFA causes a rapid disassembly of the Golgi complex and redistribution of the marker enzyme TPPase into the ER including the nuclear envelope. The spontaneous reversibility of the drug effect also favors a dynamic recycling of the Golgi marker between the ER and the Golgi complex under the conditions used.     

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.     

Enzyme modulation of the Golgi apparatus and GERL: a cytochemical study of parotid acinar cells

The distribution of thiamine pyrophosphatase (TPPase) and acid phosphatase (AcPase) has been examined in resting parotid acinar cells as well as during decreased and increased secretory granule production. In resting acinar cells, TPPase activity was restricted to the trans Golgi saccules and AcPase activity was localized in GERL and immature secretory granules. Although secretory granule production is diminished during ethionine intoxication, no significant alteration in the distribution of either TPPase or AcPase was noted. However, marked changes in enzyme localization, especially of TPPase, occurred during accelerated secretory granule production. The alterations were essentially the same for all of the conditions studied (recovery from ethionine treatment, recovery from a protein depletion diet, secretory stimulation with isoproterenol, and postnatal maturation of the parotid gland). During maximal secretory granule production, TPPase activity was localized not only in the trans Golgi saccules, but also in GERL-like cisternae and immature secretory granules. The immature secretory granules were often in continuity with the GERL-like cisternae. At the same time that the TPPase activity was increased, the AcPase activity was frequently diminished. These modulations in enzyme activity provide evidence that GERL is derived from the trans Golgi saccule.     

Ultrastructural localization of thiamine pyrophosphatase activity in the epitheliocytes of duodenal biopsies in peptic ulcer

Using electron microscopic studies the location of thiamine pyrophosphatase (TPPase) activity in the epithelial cells of duodenal mucosa was investigated in 39 patients with ulcer exacerbation and during the disease remission. The biopsy material was studied before and after the administration of physiological and therapeutic doses of thiamine. TPPase activity was detected on the membranes of Golgi complex, lateral cell membrane and microvilli. The possibility of intra- and extracellular localization of TPPase activity and the activity of various enzymes depending on the mechanism of thiamine absorption across the epithelial barrier is discussed.     

Morphological studies on neuroglia

Summary Electron-microscopic survey of selectively stained microglial cells in the cerebral cortex of the rat reveals that the processes of this cell type often encircle axo-dendritic synapses. Enzyme-histochemical methods for thiamine pyrophosphatase (TPPase) or nucleoside diphosphatase (NDPase) were used for the selective marking of the microglial cells; TPPase and NDPase activities were observed in the plasma membrane of microglial cells. The synapses encircled by microglial processes displayed presynaptic structures containing round clear vesicles (50 nm in diameter) and a prominent thickening of the postsynaptic membrane. In vitro, the above-mentioned enzymatic activities were completely suppressed by neuroactive agents such as catecholamines and phenothiazine derivatives. Examination using enzyme-histochemical techniques suggests that a single enzyme may be responsible for both above-mentioned enzymatic reactions. The functional significance of microglial cells in the normal central nervous tissue is discussed.This work was supported by grant No. 437002 from the Ministry of Education, Science and Culture, Japan     

Bone Marrow-Derived Mesenchymal Stem Cells Maintain the Resting Phenotype of Microglia and Inhibit Microglial Activation

Many studies have shown that microglia in the activated state may be neurotoxic. It has been proven that uncontrolled or over-activated microglia play an important role in many neurodegenerative disorders. Bone marrow-derived mesenchymal stem cells (BMSCs) have been shown in many animal models to have a therapeutic effect on neural damage. Such a therapeutic effect is attributed to the fact that BMSCs have the ability to differentiate into neurons and to produce trophic factors, but there is little information available in the literature concerning whether BMSCs play a therapeutic role by affecting microglial activity. In this study, we triggered an inflammatory response situation in vitro by stimulating microglia with the bacterial endotoxin lipopolysaccharide (LPS), and then culturing these microglia with BMSC-conditioned medium (BMSC-CM). We found that BMSC-CM significantly inhibited proliferation and secretion of pro-inflammatory factors by activated microglia. Furthermore, we found that the phagocytic capacity of microglia was also inhibited by BMSC-CM. Finally, we investigated whether the induction of apoptosis and the production of nitric oxide (NO) were involved in the inhibition of microglial activation. We found that BMSC-CM significantly induced apoptosis of microglia, while no apoptosis was apparent in the LPS-stimulated microglia. Our study also provides evidence that NO participates in the inhibitory effect of BMSCs. Our experimental results provide evidence that BMSCs have the ability to maintain the resting phenotype of microglia or to control microglial activation through their production of several factors, indicating that BMSCs could be a promising therapeutic tool for treatment of diseases associated with microglial activation.     

Microglial calcium signal acts as a rapid sensor of single neuron damage in vivo

In the healthy adult brain microglia, the main immune-competent cells of the CNS, have a distinct (so-called resting or surveying) phenotype. Resting microglia can only be studied in vivo since any isolation of brain tissue inevitably triggers microglial activation. Here we used in vivo two-photon imaging to obtain a first insight into Ca(2+) signaling in resting cortical microglia. The majority (80%) of microglial cells showed no spontaneous Ca(2+) transients at rest and in conditions of strong neuronal activity. However, they reliably responded with large, generalized Ca(2+) transients to damage of an individual neuron. These damage-induced responses had a short latency (0.4-4s) and were localized to the immediate vicinity of the damaged neuron (< 50 μm cell body-to-cell body distance). They were occluded by the application of ATPγS as well as UDP and 2-MeSADP, the agonists of metabotropic P2Y receptors, and they required Ca(2+) release from the intracellular Ca(2+) stores. Thus, our in vivo data suggest that microglial Ca(2+) signals occur mostly under pathological conditions and identify a Ca(2+) store-operated signal, which represents a very sensitive, rapid, and highly localized response of microglial cells to brain damage. This article is part of a Special Issue entitled: 11th European Symposium on Calcium.     

The relationships between the Golgi apparatus, GERL, and lysosomes of fetal rat liver Kupffer cells examined by ultrastructural phosphatase cytochemistry

Kupffer cells are the sinusoidal macrophages of the liver. Using ultrastructural phosphatase cytochemical methods, we examined the relationship between the Golgi apparatus, GERL, and lysosomes of Kupffer cells in fetal rat livers identified, in part, by their ability to phagocytize intravenously injected latex spheres. Thiamine pyrophosphatase (TPPase) activity was localized to the inner Golgi saccules and some vesicles in the Golgi region but not to GERL. A TPPase-like activity, demonstrable in lysosomes, was abolished by sodium fluoride but not suppressed by the alkaline phosphatase inhibitors L-cysteine and L-p-bromotetramisole. Acid phosphatase (AcPase) was localized by GERL, some coated vesicles, and in lysosomes, but not to the Golgi stacks. Continuities between GERL and lysosomes were observed. Phagosomes containing internalized latex spheres received TPPase and AcPase sequentially. TPPase was localized in phagosomes immediately after latex administration. AcPase activity was not found here until at least 10 minutes following the injection of the particulates. Our findings indicate that Kupffer cell lysosomes are derived from GERL, but also suggest that phagosomes may receive material packaged by the Golgi apparatus as well as GERL.     

Microglial calcium signal acts as a rapid sensor of single neuron damage in vivo

In the healthy adult brain microglia, the main immune-competent cells of the CNS, have a distinct (so-called resting or surveying) phenotype. Resting microglia can only be studied in vivo since any isolation of brain tissue inevitably triggers microglial activation. Here we used in vivo two-photon imaging to obtain a first insight into Ca²⁺ signaling in resting cortical microglia. The majority (80%) of microglial cells showed no spontaneous Ca²⁺ transients at rest and in conditions of strong neuronal activity. However, they reliably responded with large, generalized Ca²⁺ transients to damage of an individual neuron. These damage-induced responses had a short latency (0.4-4 s) and were localized to the immediate vicinity of the damaged neuron (< 50 μm cell body-to-cell body distance). They were occluded by the application of ATPγS as well as UDP and 2-MeSADP, the agonists of metabotropic P2Y receptors, and they required Ca²⁺ release from the intracellular Ca²⁺ stores. Thus, our in vivo data suggest that microglial Ca²⁺ signals occur mostly under pathological conditions and identify a Ca²⁺ store-operated signal, which represents a very sensitive, rapid, and highly localized response of microglial cells to brain damage. This article is part of a Special Issue entitled: 11th European Symposium on Calcium.     

Ultrastructural localization of CMPase, TPPase, and NADPase activity in neurons, satellite cells, and Schwann cells in frog dorsal root ganglia

Sections of bullfrog dorsal root ganglia were analyzed for cytidine monophosphatase (CMPase), thiamine pyrophosphatase (TPPase), and nicotinamide adenine dinucleotide phosphatase (NADPase) activity, and the distributions of these enzymatic activities were compared with those traditionally found in other cell types (e.g., CMPase: Golgi trans-sacculotubular network; TPPase: trans-Golgi saccule(s); NADPase: intermediate Golgi saccules). In the present study, CMPase activity in neurons was localized mainly to the Golgi trans-sacculotubular network and lysosomes, but sometimes also occurred at the ends of the trans and most distal intermediate Golgi saccules. A similar distribution was found in satellite and Schwann cells. TPPase activity in neurons occurred not only in the trans-Golgi saccule but also in the trans-sacculotubular network, lysosomes, and scattered tubular elements. In satellite and Schwann cells, activity was found in both the trans saccule and trans-sacculotubular network, and substantial activity often appeared in the more distal of the intermediate saccules. NADPase activity in neurons was usually absent from the intermediate Golgi saccules and was confined to the trans-sacculotubular network and lysosomes; however, activity was sometimes also found in the intermediate and/or trans-Golgi saccules. In satellite and Schwann cells, activity appeared consistently in both the trans-sacculotubular network and intermediate saccules, as well as in lysosomes. These distributions, especially in the case of TPPase and NADPase, differ substantially from the most frequently reported localizations of the above enzymes, indicating that the Golgi complex may exhibit considerable plasticity of structure and function in different cell types.     

ATP mediates calcium signaling between astrocytes and microglial cells: modulation by IFN-gamma

Calcium-mediated intercellular communication is a mechanism by which astrocytes communicate with each other and modulate the activity of adjacent cells, including neurons and oligodendrocytes. We have investigated whether microglia, the immune effector cells involved in several diseases of the CNS, are actively involved in this communication network. To address this issue, we analyzed calcium dynamics in fura-2-loaded cocultures of astrocytes and microglia under physiological conditions and in the presence of the inflammatory cytokine IFN-gamma. The intracellular calcium increases in astrocytes, occurring spontaneously or as a result of mechanical or bradykinin stimulation, induced the release of ATP, which, in turn, was responsible for triggering a delayed calcium response in microglial cells. Repeated stimulations of microglial cells by astrocyte-released ATP activated P2X(7) purinergic receptor on microglial cells and greatly increased membrane permeability, eventually leading to microglial apoptosis. IFN-gamma increased ATP release and potentiated the P2X(7)-mediated cytolytic effect. This is the first study showing that ATP mediates a form of calcium signaling between astrocytes and microglia. This mechanism of intercellular communication may be involved in controlling the number and function of microglial cells under pathophysiologic CNS conditions.     

Inosine diphosphatase as a histochemical marker of retinal microvasculature,with special reference to transformation of microglia

Summary Nucleoside diphosphatase (IDPase), localized using inosine diphosphate as substrate, allows the selective staining of blood vessels and cells of vascular origin, such as macrophages and microglia, whereas the neuroglial, the neuronal and the pigment epithelial cells remain unstained. The staining pattern observed in the retina of mouse, rat, cat and monkey are similar; some apparent quantitative differences reflect species differences in the distribution of retinal microvasculature. At the electron-microscopic level, most of the enzyme activity in the blood vessels appears to be located along the outer wall. The cell membrane, parts of the smooth endoplasmic reticulum and the nuclear membrane in the microglial perikarya appear positive; profiles of microglial processes are intensely stained.In the developing eyes of rats and mice, the blood vessels are stainable from the earliest stage of their appearance. An array of amoeboid cells precede the growing blood vessels and spread out over the future vascularized part of the retina. These cells eventually develop characteristic microglial features, and extend many elongated and branched processes between the neuroepithelial cells while remaining in contact with, or in close proximity to, the blood vessels. Intense IDPase activity in the microglial cells, in contrast to the absence of the enzyme in the neuroglial Müller cells, suggests that microglia are involved in phosphate metabolism and indicates functional compartmentalization within the glial tissue lying between the blood retinal barrier and the retinal neurons.     

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.     

Role of Ciliary Neurotrophic Factor in Microglial Phagocytosis

Microglia, CNS-resident macrophages, serve as scavengers to remove cellular debris and facilitate tissue remodeling in the developing and injured CNS. Little is known as what and how microenvironmental factors mediate the phagocytotic ability of microglia. Our previous study has indicated that treatment with glial cell line-derived neurotrophic factor (GDNF) increased the phagocytotic activity of primary rat microglia possibly through the upregulation of α5 integrin. In the present study, ciliary neurotrophic factor (CNTF), which has been reported to be produced by glia, was shown to have stimulatory effect on the phagocytosis of primary rat microglia and mouse microglial cell line BV2. Ca²⁺ imaging analysis and the application of intracellular calcium chelator BAPTA-AM revealed that CNTF-induced increase in microglial phagocytosis was mediated by a calcium signaling pathway. Furthermore, treatment with CNTF led to an increase in the expression of αv integrin, which has been reported to be involved in the phagocytosis of the apoptotic cells. In summary, we have provided evidence that CNTF can increase microglial phagocytosis through a calcium-mediated pathway. Our results also suggest that the upregulation of αv integrin by CNTF could be involved in the increased phagocytotic activity of microglia. Special issue article in honor of Dr. George DeVries.     

Methylene blue blocks cGMP production and disrupts directed migration of microglia to nerve lesions in the leech CNS

Migration and accumulation of microglial cells at sites of injury are important for nerve repair. Recent studies on the leech central nervous system (CNS), in which synapse regeneration is successful, have shown that nitric oxide (NO) generated immediately after injury by endothelial nitric oxide synthase (eNOS) stops migrating microglia at the lesion. The present study obtained results indicating that NO may act earlier, on microglia migration, and aimed to determine mechanisms underlying NO's effects. Injury induced cGMP immunoreactivity at the lesion in a pattern similar to that of eNOS activity, immunoreactivity, and microglial cell accumulation, which were all focused there. The soluble guanylate cyclase (sGC) inhibitor methylene blue (MB) at 60 microM abolished cGMP immunoreactivity at lesions and blocked microglial cell migration and accumulation without interfering with axon conduction. Time-lapse video microscopy of microglia in living nerve cords showed MB did not reduce cell movement but reduced directed movement, with significantly more cells moving away from the lesion or reversing direction and fewer cells moving toward the lesion. The results indicate a new role for NO, directing the microglial cell migration as well as stopping it, and show that NO's action may be mediated by cGMP.