The kinetics and morphological characteristics of the macrophage-microglial response to kainic acid-induced neuronal degeneration

Phagocytozing ameboid microglial cells studied in a mouse corpus callosum slice preparation

Highly motile brain macrophages/microglial cells were observed in the cingulum and supraventricular corpus callosum, an area termed by del Rio-Hortega the "fountain of microglia." This is the first study that uses time lapse video microscopy in acute cortical brain slices to analyze directly the motile and phagocytic behaviour of these cells. The cells migrated within minutes to the slice surface and actively screened their surrounding with velum-like processes. Dead/damaged cells on the slice surface were contacted by the processes and phagozytozed within minutes. A method to add red blood cells in a defined density was used to observe the phagocytosis.

Effects of chronic intrahippocampal infusion of lipopolysaccharide in the rat

Astrogliosis and microglial activation are associated with many neurodegenerative disorders including multiple sclerosis, its animal model experimental allergic encephalomyelitis, and Alzheimer's disease. To address the hypothesis that chronic astroglial or microglial activation could be contributing factors to neuronal death or injury, the immunostimulant lipopolysaccharide was infused into the hippocampus for 16 days using Alzet mini-osmotic pumps attached to a cannula. Placement of the cannula and infusion of vehicle for 16 days caused a hippocampal lesion with a volume of 0.5 +/- 0.1 mm3. Infusion of lipopolysaccharide at the dose of 2.0 micrograms/day produced a lesion of 4.9 +/- 1.3 mm3 (P < 0.01, Newman-Keuls), whereas, a lower dose of 0.2 microgram/day caused a lesion of 1.3 +/- 0.3 mm3 (P < 0.05). The lesion was defined as a focal necrotic reaction with fibrin deposits outlining an area at an early stage of encapsulation. No apparent neuronal loss was observed by Cresyl Violet staining outside the encapsulated necrotic area. There was a pronounced astrogliosis and an increase in activated macrophages throughout the lipopolysaccharide-infused hippocampus as determined by glial fibrillary acidic protein and ED-1 immunohistochemistry, respectively. Choline acetyltransferase and glutamic acid decarboxylase enzyme activities, used as functional measures of neuronal viability for cholinergic and GABAergic neurons, respectively, were unaffected in the hippocampus following a 16 day infusion of lipopolysaccharide at the doses of 0.2, 0.6 and 2.0 micrograms/day. In addition, unilateral infusion of lipopolysaccharide into the hippocampus did not affect 24 h locomotion when tested on day 13, body temperature or weight gain. Under the experimental conditions employed in the present study, chronic infusion of lipopolysaccharide into the hippocampus resulted in a dose-dependent focal necrotic lesion at the site of infusion. In tissue surrounding the encapsulated lesion, neurons were present among the reactive astrocytes and increased number of macrophages suggesting that astrocytes and macrophages can be activated without causing neuronal loss.

Expression of non-angiotensin II -125I-CGP 42112 binding sites on activated microglia after kainic acid induced neurodegeneration

[125I]CGP 42112, first developed to identify angiotensin II receptor subtype 2 (AT2), was recently shown to bind to a novel non-angiotensin binding site in injured rat brain tissue. We addressed the question whether non-angiotensin [125I]CGP 42112 binding appears after kainic acid induced hippocampal neurodegeneration, a process of neuronal cell death at a distance from the toxin injection site. After intraventricular kainic acid injection, we found non-angiotensin [125I]CGP 42112 binding in the hippocampal areas CA3 (4 and 14 days after injection), CA1 and CA4 and the subiculum (14 days after injection). In addition, 14 days after kainic acid injection, [125I]CGP 42112 binding was found in 50% of the animals, in the thalamus, amygdala and piriform cortex, areas receiving projections from the hippocampus and suffering kainic acid induced delayed neurodegeneration. The loss of neurons in these regions was accompanied by an accumulation of activated microglia as demonstrated by immunostaining with the specific antibodies OX-42 and ED1. The time course and regional pattern of OX-42/ED1 positive immunostaining was identical with the appearance and distribution of the non-angiotensin [125I]CGP 42112 binding site. The non-angiotensin [125I]CGP 42112 binding was not detected in brain regions unaffected by kainic acid injection. Our findings indicate the expression of a novel [125I]CGP 42112 binding site on activated microglia. This site appears at a distance from the lesion and may be of importance in the process of neuronal death and brain tissue repair.

Inflammation in the nervous system

Earlier studies on inflammation in the CNS have largely focused on conditions with an immune component. Recent evidence has emerged, however, that the innate, acute inflammatory response in the CNS parenchyma is quite unlike that in other tissues. The meninges and ventricular compartments show more typical responses, as does the parenchyma of the brain in immature animals. It is becoming apparent that the cells of the mononuclear phagocyte lineage dominate inflammatory responses in the CNS parenchyma.

Excitotoxin-induced neuronal degeneration and seizure are mediated by tissue plasminogen activator

Neuronal degeneration in the hippocampus, a region of the brain important for acquisition of memory in humans, occurs in various pathological conditions, including Alzheimer's disease, brain ischaemia and epilepsy. When neuronal activity is stimulated in the adult rat and mouse hippocampus, tissue plasminogen activator (tPA), a serine protease that converts inactive plasminogen to the active protease plasmin, is transcriptionally induced. The activity of tPA in neural tissue is correlated with neurite outgrowth, regeneration and migration, suggesting that it might be involved in neuronal plasticity. Here we show that tPA is produced primarily by microglia in the hippocampus. Using excitotoxins to induce neuronal cell loss, we demonstrate that tPA-deficient mice are resistant to neuronal degeneration. These mice are also less susceptible to pharmacologically induced seizures than wild-type mice. These findings identify a role for tPA in neuronal degeneration and seizure.

Adhesion molecule expression on murine cerebral endothelium following the injection of a proinflammagen or during acute neuronal degeneration

The acute inflammatory response in the murine CNS is different from that observed in other tissues. Few polymorphonuclear leukocytes are recruited to the brain parenchyma and there is a delay in the recruitment of monocytes. Leukocyte recruitment to sites of inflammation is dependent on adhesion molecules expressed on the endothelium. The atypical kinetics of leukocyte recruitment to the CNS may be the result of deficient or delayed adhesion molecule expression on the cerebral endothelium. Using immunohistochemistry, the present study demonstrates that following the intracranial injection of a proinflammagen, lipopolysaccharide, or following acute neuronal degeneration elicited with kainic acid, the adhesion molecules ICAM-1 and VCAM were readily upregulated on cerebral endothelium in a time course comparable with that demonstrated on non-CNS endothelium. Both molecules were expressed on vessels, irrespective of their size, at 24 h after kainic acid or 6 h after lipopolysaccharide injection but leukocyte recruitment was negligible. The expression of ICAM-1 was demonstrated not only on endothelium but also on microglia especially in response to nerve terminal degeneration. PECAM was constitutively expressed at high levels on cerebral endothelium and did not change during brain injury. However, PECAM was induced on astrocytes after lipopolysaccharide injection or during acute neuronal degeneration, the latter providing a particularly strong stimulus. This study indicates that the expression of these adhesion molecules on CNS endothelium is neither deficient or delayed and that they are unlikely to be limiting factors in leukocyte recruitment to the CNS.

Resident microglia and hematogenous macrophages as phagocytes in adoptively transferred experimental autoimmune encephalomyelitis: an investigation using rat radiation bone marrow chimeras

Hematogenous macrophages are known to be involved in the induction of tissue damage in the central nervous system (CNS) as well as of clinical symptoms in experimental autoimmune encephalomyelitis (EAE). Although resident microglia can become phagocytic under certain circumstances, little is known about the role of these cells in brain inflammation in vivo. We thus studied EAE in the model of radiation bone marrow chimeras that allows us to distinguish donor-derived hematogenous cells from resident effector cells. Inflammation in the CNS was qualitatively and quantitatively similar in chimeras compared to fully histocompatible Lewis rats. Although activated resident microglial cells were outnumbered four- to sevenfold in EAE lesions by hematogenous macrophages, the number of resident microglia with ingested myelin was equal to that of macrophages containing myelin debris. Phagocytic resident microglia, expressing the macrophage activation marker ED1, showed ramified as well as amoeboid morphology. From our studies the following conclusions can be drawn. First, a considerable proportion of resident microglia upregulated ED1. Second, resident microglia provide a small but substantial source of brain macrophages in EAE as compared to the large influx of macrophages. Third, our results suggest that microglia, due to their strategic position within the CNS, are more effective in removal of myelin debris compared to hematogenous macrophages.

The unique characteristics of inflammatory responses in mouse brain are acquired during postnatal development

The kinetics of leukocyte recruitment during acute inflammation in adult mouse brain differ from the stereotyped response occurring in non-CNS tissues; neutrophil recruitment is minimal and monocyte recruitment occurs after a 48 h delay. One aspect of the CNS microenvironment which may contribute to restricted leukocyte recruitment is the highly differentiated nature of resident CNS macrophages, the microglia. Thus we studied the inflammatory response to intracerebral injections of endotoxin in neonates in which microglia are less differentiated and resemble more closely macrophages of non-CNS tissues. Mice injected with endotoxin on the day of birth exhibited both neutrophil and monocyte recruitment to the parenchyma, but the response differed from that occurring in non-CNS tissues such as skin. Leukocyte recruitment was very slow, the mononuclear phagocyte response peaking 14 days after endotoxin injection. This sluggish inflammatory response was reminiscent of that previously described in fetal wounds. However, when endotoxin was injected into brains of 7-day-old neonates the inflammatory response resembled that seen in non-CNS tissues; i.e. prolific neutrophil recruitment and a brisk mononuclear phagocyte response. Thus the unusual inflammatory cell kinetics are a property of the mature CNS microenvironment; all signals necessary to support typical leukocyte recruitment are present in the brain by 7 days of age but the brain becomes able to restrict leukocyte immigration during subsequent postnatal development. Developmental changes in the host response to identical inflammatory challenges suggest a window during which the brain may be particularly vulnerable to inflammatory bystander damage.

Inhibited breathing decreases renal sodium excretion

This study tested the hypothesis that breathing at the upper end of the normal range of end tidal CO2 decreases renal sodium excretion. Normotensive human subjects learned to self-regulate end tidal CO2 using a respiratory gas monitor and feedback procedure. Urine flow rates were increased by a standardized water drinking regimen. Urinary volume and sodium and potassium excretion were decreased during 30 minutes of inhibited (i.e. high normal end tidal CO2) breathing, compared with levels preceding and after task performance. Blood pressure, but not heart rate, increased during task performance. Plasma volume increase under these conditions is indicated by the observation that urinary excretion of an endogenous digoxin-like factor was increased. The physiological mechanism by which inhibited breathing elicits renal sodium retention remains to be determined. This breathing pattern could mediate the role of behavioral stress in some forms of hypertension.

Temporalspatial patterns of expression of metallothionein-I and -III and other stress related genes in rat brain after kainic acid-induced seizures

Kainic acid-induced seizures in the rat brain cause severe brain damage that is thought to result, in part, from oxidative stress. In this study, we examine the consequences of systemic administration of kainic acid on expression of several genes that encode proteins thought to play roles in protection from oxidative stress, including metallothionein-I, and -III. Kainic acid causes an increase in metallothionein-I and heme oxygenase-I mRNAs, as well as an increase in c-fos, heat shock protein-70, and interleukin-1 beta mRNAs. The induction of these mRNAs is seizure dependent, and is greater in brain areas with extensive damage (e.g. piriform cortex) than in areas with minimal damage (e.g. frontal cortex and cerebellum). In contrast, little or no change in mRNA for metallothionein-III, manganese superoxide dismutase, copper-zinc superoxide dismutase, glutathione-s-transferase ya subunit or glutathione peroxidase occur. The prolonged and robust concordant induction of the metallothionein-I and heme oxygenase-I genes may reflect the oxidative stress produced by kainic acid-induced seizures. In addition, the induction of interleukin-1 beta gene expression suggests an inflammatory response in brain regions damaged by kainic acid-induced seizures. Delineating the regulation of genes associated with oxidative and inflammatory responses can contribute to a fuller understanding of seizures and associated brain damage.

The effect of kainate on protein kinase C, GABA, and the uptake of serotonin in the rabbit retina in vivo

The purpose of this study was to investigate the effect of kainate on protein kinase C (PKC), gamma-aminobutyrate (GABA) and serotonin uptake in the rabbit retina. Kainate when injected into the vitreous humour produces a change in the GABA immunoreactivity within 6 hours. After 3 days, remnants of the normal GABA immunoreactivity still persist and additionally astrocyte and microglia-like elements "stain" positively for GABA. After 7 days exposure to kainate none of the normal GABA immunoreactivity is apparent, instead a number of round-shaped elements which may be reactive astrocytes and/or microglia stain positively for GABA. During these stages kainate does not affect the alpha PKC immunoreactivity associated with the on-bipolar cells. Six hours following kainate treatment the ability of certain GABA amacrine cells to take up exogenous serotonin is unaffected. After three days only a few of these cells can still take up exogenous serotonin and then not avidly. After seven days the GABA/serotonin amacrine cells cannot take up exogenous serotonin suggesting that all of these neurons are irreversibly damaged. One hour after treatment with kainate both calcium-dependent and -independent PKC species are translocated from the cytosolic to membrane compartments. After 5 hours and 7 days there was also evidence from the enzyme assay experiments that kainate caused the calcium-dependent and -independent PKC enzymes to be translocated but because the total enzyme activity was reduced due perhaps to down-regulation of the enzyme this was difficult to assess precisely.(ABSTRACT TRUNCATED AT 250 WORDS)

Reactive microglia in hippocampal sclerosis associated with human temporal lobe epilepsy

An immunoperoxidase method was used to demonstrate expression of HLA-DR (a Class II major histocompatibility antigen) as an indicator of microglial activation in cases of hippocampal sclerosis derived from temporal lobectomy for intractable seizures. HLA-DR-immunoreactive microglia were increased approximately 11-fold in CA1 and 3-fold in CA3, compared to control autopsy hippocampus. The numbers of HLA-DR-immunoreactive perivascular cells were also significantly increased in hippocampal sclerosis cases (9-, 7- and 6-fold increases in CA1, CA3 and CA2, respectively). Since animal studies have found microglial activation to be an acute or subacute response to injury, the results presented here suggest that, contrary to the classical conception of human hippocampal sclerosis as an inert scar, neuronal injury continues to occur as a result of ongoing seizure activity.

Cell death, gliosis, and synaptic remodeling in the hippocampus of epileptic rats

Seizures set in motion complex molecular and morphological changes in vulnerable structures, such as the hippocampal complex. A number of these changes are responsible for neuronal death of CA3 and hilar cells, which involves necrotic and apoptotic mechanisms. In surviving dentate granule cells seizures induce an increased expression of tubulin subunits and microtubule-associated proteins, suggesting that an overproduction of tubulin polymers would lead to a remodeling of mossy fibers (the axons of granule cells). In fact, these fibers sprout in the dentate gyrus to innervate granule cell dendrites, creating recurrent excitatory circuits. In contrast, terminal mossy fibers do not sprout in the CA3 field. Navigation of mossy fiber's growth cones may be facilitated by astrocytes, which would exert differential effects by producing and excreting cell adhesion and substrate molecules. In the light of the results discussed here, we suggest that in adult brain activated-resident astrocytes (nonproliferating, tenascin-negative, neuronal cell-adhesion molecule-positive astrocytes) could contribute to the process of axonal outgrowth and synaptogenesis in the dentate gyrus, while proliferating astrocytes, tenascin-positive, could impede any axonal rearrangement in CA3.

Regional and temporal profiles of calcium accumulation and glial fibrillary acidic protein levels in rat brain after systemic injection of kainic acid

Cerebral calcium accumulation and increases in the astroglial intermediate filament protein, glial fibrillary acidic protein (GFAP), have been used as markers of neurotoxic and ischemic brain damage. The present study was aimed at quantitatively investigating the regional and temporal relationship of those indices following a neurotoxic insult. For this purpose, regional changes in 45Ca uptake and GFAP levels, using ELISA, were evaluated in rat brains at both early (several hours) and late time points (up to 6 months) after a single systemic injection of kainic acid (12 mg/kg). After 4 h, limbic brain areas were already heavily labelled by 45Ca. In most investigated brain areas 45Ca accumulation peaked at day 4 (maximum 5 fold increase in amygdala) and returned to normal levels within 1 week (cerebellum, pons/medulla, occipital cortex), 2 weeks (striatum, frontal cortex), 2 or 4 months (limbic brain areas), or remained significantly elevated until 6 months (thalamus). In contrast, in all investigated brain areas, except cerebellum and pons/medulla, GFAP was increased from day 2, reaching maximum levels at day 28 in most limbic structures and remained significantly elevated at the same high level (15 fold increase) in amygdala, or somewhat lower levels in other affected regions (2-7 fold), but not in the thalamus. In all brain areas with 45Ca accumulation, GFAP was increased and the peak responses were highly correlated. Thus, both indices are useful quantitative biochemical markers of acute or subchronic neurotoxicity.

Quantification of the mononuclear phagocyte response to Wallerian degeneration of the optic nerve

We investigated the numbers, origin and phenotype of mononuclear phagocytes (macrophages/microglia) responding to Wallerian degeneration of the mouse optic nerve in order to compare it with the response to Wallerian degeneration in the PNS, already described. We found macrophage/microglial numbers elevated nearly four fold in the distal segments of crushed optic nerves and their projection areas in the contralateral superior colliculus 1 week after unilateral optic nerve crush. This relative increase in mononuclear phagocyte numbers compared well with the four-to-five-fold increases reported in the distal segments of transected saphenous or sciatic nerves. Moreover, maximum numbers are reached at 3, 5 and 7 days in the saphenous, sciatic and optic nerves respectively, suggesting that the very slow clearance of axonal debris and myelin in CNS undergoing Wallerian degeneration is not simply due to a slow or small mononuclear phagocyte response. The apparent delay in the response in the CNS occurs because the mononuclear phagocytes respond to the Wallerian degeneration of axons, which is slightly slower in the CNS than the PNS, rather than to events associated with the crush itself, such as the abolition of normal electrical activity in the distal segment. This was demonstrated by the protracted time course of the mononuclear phagocyte response in the distal segment following optic nerve crush in mice carrying the Wlds mutation which dramatically slows the rate at which the axons undergo Wallerian degeneration. By [3H]-Thymidine labelling or by blocking microglial proliferation by X-irradiation of the head prior to optic nerve crush, we showed that the majority of macrophages/microglia initiating the response to Wallerian degeneration were of local, CNS origin but these cells rapidly (from 3 days post crush) upregulate endocytic and phagocytic functional markers although they do not resemble rounded myelin-phagocytosing macrophages observed in degenerating peripheral nerves. We speculate that the poor clearance of myelin in CNS fibre tracts undergoing Wallerian degeneration compared to the PNS, in the face of a mononuclear phagocyte response which is similar in relative magnitude and time course, is because Schwann cells in degenerating peripheral nerves promptly modify their myelin sheaths such that they can be recognized and phagocytosed by macrophages, whilst in the CNS oligodendrocytes do not.

Upregulation of the macrophage scavenger receptor in response to different forms of injury in the CNS

The monoclonal antibody 2F8 was used to localize the macrophage scavenger receptor by immunohistochemistry. In control adult mice, macrophage scavenger receptor expression in the brain was restricted to stromal and epiplexus macrophages of the choroid plexus, meningeal macrophages and to perivascular sites. Microglia did not express the receptor. In the developing mouse brain, macrophage scavenger receptor expression was high on meningeal macrophages and detectable on immature microglia in the supraventricular corpus callosum, cingulum, cavum septum and the periaqueductal area. In the aged mouse brain, the pattern of macrophage scavenger receptor expression was no different from that in the young adult brain. Macrophage scavenger receptor expression on resident microglia and recruited macrophages was detected 24 h after an intrahippocampal injection of either lipopolysaccharide or kainic acid. Macrophage scavenger receptor expression was also detected in microglia 3 days after optic nerve crush both in the nerve segment distal to the crush site and in the superior colliculus. These studies indicate a potential role for the macrophage scavenger receptor in the CNS in the clearance of debris during acute neuronal degeneration.

Glial reaction after seizure induced hippocampal lesion: immunohistochemical characterization of proliferating glial cells

Kainic acid treatment (a model of temporal lobe epilepsy) induces Ammon's horn sclerosis, which is characterized by degeneration of CA3 pyramidal neurons and reactive gliosis. In the present study we have combined autoradiographic analysis of 3H-thymidine incorporation and immunocytochemistry to investigate this glial scarring phenomenon. The present results demonstrate that in the fields showing neuronal degeneration (i.e. CA3-CA4 fields of Ammon's horn and dentate hilus) the glial reaction consists of a proliferation and hypertrophy of astrocytes and microglia-macrophages. In the regions showing exclusively terminal axonal degeneration (i.e. the molecular layer of kainate-treated rats), glial cells do not proliferate but astrocytes show a transient hypertrophy. These results also demonstrate that oligodendrocytes do not proliferate in the hippocampus of kainate-treated rats. In agreement with our previous report we find that hippocampal astrocytes from kainate-treated rats express A2B5 immunoreactivity, a marker of type-2 astrocytes. A2B5 immunoreactivity was expressed by astrocytes not only in areas showing glial proliferation such as CA3-CA4 fields, but also in the molecular layer, where astrocytes do not proliferate. This suggests that in the CNS, normal resident astrocytes acquire the phenotypic properties of type-2 astrocytes.

Expression of a novel non-angiotensin II [125I]CGP 42112 binding site in healing wounds of the rat brain

We characterized a novel non-angiotensin II binding site that is recognized by the angiotensin II AT2 receptor ligand [125I]CGP 42112, in healing brain wounds of adult rats. The binding, which was highest at 3 days after injury, appears to be localized to activated microglia surrounding the wound. The novel CGP 42112 binding site may have a role in the function of microglia and in mechanisms of tissue repair in the brain.

Astrocyte and microglial motility in vitro is functionally dependent on the hyaluronan receptor RHAMM

RHAMM (Receptor for Hyaluronic Acid Mediated Motility) has been identified as a receptor for the extracellular matrix component hyaluronan (HA) and was recently shown to be essential for the locomotion of normal and transformed peripheral cells. Until now the potential role of RHAMM in the motility of neural-derived cells has not been investigated. Here, we report that cultured primary astrocytes, astrocyte cell lines, and microglia express this receptor and exhibit RHAMM-dependent motility. Immunocytochemical localization of RHAMM showed that it was often present as aggregates at the periphery of cells in contact with one another or concentrated on protruding processes of isolated cells. Glial cells contained 50 and 72 kDa forms of RHAMM, and both of these forms were found to have HA binding capacity. Time lapse imaging of cell locomotion revealed a significant inhibition of motility and process elongation by neutralizing anti-RHAMM antibodies and by peptides corresponding to the HA binding domains of RHAMM. These results demonstrate that RHAMM serves a role in glial cell locomotion in vitro and provide the basis for investigations of the motile behavior of glial cells in vivo after CNS injury.

Transitory disappearance of microglia during the regeneration of the lizard medial cortex

In normal lizards, microglial cells populate the medial cortex (a zone homologous to the hippocampal fascia dentata), with a preferential distribution along the border between the granular cell layer and the plexiform layers. Intraperitoneal injection of the neurotoxin 3-acetylpyridine (3AP) induces a selective lesion in the medial cortex with a rapid degeneration of the granular layer and its zinc-enriched axonal projection. Within 6-8 weeks, the granular layer is, however, repopulated by a new set of neurons generated in the subjacent ependyma and the cell debris is removed. The aim of this study was to determine to what extent microglia were involved in the scavenging processes during the regeneration process. To this end we studied the brains of regenerating lizards at different times after 3AP lesion, visualising microglial cells by the nucleoside diphosphatase (NDPase) histochemical reaction. Surprisingly, we found that stained microglial cells disappeared 6-8 hours after 3AP injection and remained absent until 10-15 days after injection. One month postlesion an increased population of microglial cells was found scattered throughout all plexiform layers of the cortex. Thorough examination of semithin and ultrathin sections confirmed the absence of microglia in the medial cortex of recent lesioned animals but the presence of an exuberant population after 1 month postlesion. In the tissue, phagocytotic scavenging was carried out by radial ependymocytes, not by microglia.

Brain macrophages stimulate neurite growth and regeneration by secreting thrombospondin

The presence of macrophages in the developing or lesioned central nervous system (CNS) led us to study the influence of these cells on neuronal growth. Macrophages were isolated from embryonic rat brain and we observed that factors released in vitro by these cells stimulate neurite growth and regeneration of cultured CNS neurons. This effect was inhibited by antibodies directed against thrombospondin, an extracellular matrix protein that we found to be synthesized and released by brain macrophages. Immunodetection of thrombospondin in the adult rat brain lesioned by kainic acid confirmed the production of this protein by brain macrophages and indicated an early intraparenchymal accumulation of thrombospondin following injury. These results suggest that brain macrophages contribute actively to neurite growth or regeneration during the development or in pathological contexts.

Effects of silica on the outcome from experimental spinal cord injury: implication of macrophages in secondary tissue damage

A model of spinal cord trauma in guinea-pigs, using lateral compression to a set thickness, produces a delayed functional loss at one to two days, followed by a partial recovery over several weeks, as measured using hindlimb motor behavior, vestibulospinal reflex testing, and mapping the receptive field of the cutaneous trunci muscle reflex. The role of inflammatory events in these secondary changes, was investigated with intraperitoneal injections of the macrophage toxin, silica. In one experiment, 11 matched pairs of animals were injured. One of each pair was selected randomly and injected with a suspension of 1.2 g of silica dust in sterile saline, immediately after injury and surgical closure. In a second experiment, involving 10 pairs of guinea-pigs, a similar dose of silica was administered to one of each pair at either one or two days before the injury. The animals survived up to three months, then were fixed by perfusion with glutaraldehyde. Histopathology of the lesion was quantified by line sampling of myelinated axons, and by measurement of blood vessels, in plastic sections through the center of the lesion. Surgery, injury, analysis of behavior and histology were all performed without knowledge of the experimental status of the animal. The secondary onset of functional loss below the lesion appeared to be delayed by one to two days in silica-treated animals with respect to controls. The number of myelinated axons at the center of the lesion, examined at two weeks to three months after injury was higher in the animals injected with silica immediately after surgery, most significantly in the dorsal quadrant of the cord. Myelin sheath thickness and axon caliber distribution were not different. Hypervascularity of the lesion was significantly reduced in animals injected with silica within one day of injury. These findings support the hypothesis that inflammatory activity plays an important role in secondary tissue damage, and that it may be responsible for some proportion of long-term neurological deficits, but do not suggest a prominent role for early macrophage activity in the mechanisms of demyelination.

Secondary cell death and the inflammatory reaction after dorsal hemisection of the rat spinal cord

Local spinal cord lesions are often greatly enlarged by secondary damage, a process which leads to massive additional cell death. This process is poorly understood. In order to investigate which types of cells could play a role in increasing the size of the lesion, we have analysed the events occurring at rat spinal cord lesion sites from 1 h to 3 months after partial transection using cell type-specific markers. One hour after transection, the lesion site was small and corresponded to the zone of primary mechanical damage. Extravasation of blood and an opening of the blood-brain barrier occurred. Rapidly thereafter, at 3 and 6 h, an area of secondary cell death developed around the zone of the primary lesion. This secondary cell death, which was probably largely of the necrotic type, affected neurons, macroglia and microglial cells indiscriminately. It was virtually complete at 12 h. Recruitment of inflammatory cells followed a time course which lagged behind that of secondary cell death. Adhesion of neutrophils to the inside of blood vessels was observed at 3 h. They appeared in large numbers at 6 h at the site of the primary lesion, but not yet in the area of secondary cell death. They were numerous throughout the lesion site at 24 h and then disappeared rapidly. Proliferation and recruitment of macrophages and microglial cells became predominant 2 days after injury. Their density was highest within the lesion site between 4 and 8 days. Very few astrocytes were present in the lesion site during the first week.(ABSTRACT TRUNCATED AT 250 WORDS)

Microglial aggregation in the dentate gyrus: a marker of mild hypoxic-ischaemic brain insult in human infants

There are many reports in experimental animals indicating that microglia are activated in the dentate gyrus and hippocampus following hypoxic-ischaemic brain injury. The hippocampi of brains removed at autopsy from 178 children were studied retrospectively and the quantity of microglia in the polymorphous layer of the dentate gyrus was assessed. Up to the age of 8-9 months, patients with proven hypoxic or hypotensive episodes due to perinatal asphyxia, congenital heart defects, or chronic pulmonary dysfunction often had a dense infiltrate of microglial cells. A comparable microglial infiltrate was seen in most children dying under circumstances consistent with sudden infant death syndrome. Children under 9 months of age dying of other acute causes, for example trauma or sepsis either suddenly or with survival of less than 4 days in the intensive care unit, had significantly fewer microglia. After the age of 9 months a dense microglial infiltrate was never seen regardless of the cause of death. We conclude that the presence of abundant microglia in the polymorphous layer of the dentate gyrus of human infants is a marker of chronic illness or mild hypoxic-ischaemic brain injury which takes several days to develop.

[125I]CGP 42112 reveals a non-angiotensin II binding site in 1-methyl-4-phenylpyridine (MPP+)-induced brain injury

1. Intracerebral injection of the oxidative metabolite of 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP), 1-methyl-4-phenylpyridine (MPP+), into the substantia nigra of adult rats resulted in a lesion at the injection site. 2. Using autoradiography, we localized specific [125I]CGP 42112 binding that was not recognized by angiotensin II or angiotensin II AT1 or AT2 receptor-selective ligands. 3. Our results suggest that [125I]CGP 42112 may be binding to activated microglia that appear at the lesion site.

Early response of brain resident microglia to kainic acid-induced hippocampal lesions

We investigated the early response of microglia with complement and other proteins in well controlled rat central nervous system lesions. A selective neuronal degeneration in the hippocampal CA3 region was induced without direct tissue damage by an intraventricular injection of a small amount of kainic acid. As early as 1 h post injection, complement proteins C1q, C4, and C3 and immunoglobulin(Ig)G were found in the lesioned area. After 2 h, non-specific leakage of other plasma proteins occurred. By 3 h, reactive microglia gathered around the injured pyramidal neurons. Areas surrounding the lesions were depleted, on the other hand, indicating that these reactive microglia had originally resided in and migrated from such vacant areas. Upregulation of ICAM-1 expression by vascular endothelial cells commenced after 6 h. LFA-1-positive leucocytes were, then, accumulated in the vasculature, which was followed by an infiltration of leucocytes into the lesioned brain parenchyma. These results indicate that, following an acute neuronal injury, the response of the humoral factors such as complement proteins and IgG precedes the microglial reaction. Activation of vascular endothelial cells and subsequent infiltration of blood leucocytes occurs much later than the activation and migration of brain resident microglia. The origin of complement proteins and IgG in the lesioned brain parenchyma remains to be determined, although the production of complement proteins by microglia is suggested.

Time course of purine protection against kainate-induced increase in hippocampal [3H]-PK11195 binding

Binding of a peripheral benzodiazepine receptor ligand was used to quantify the reactive gliosis resulting from neuronal damage induced by systemic injections of kainic acid 7 days previously. The enhancement of binding in rat hippocampus could be prevented by injections of the purine analogue (R)-N6-phenylisopropyladenosine at 25 microgram/kg up to 2 h before or after the toxin. These results indicate that the purine is able to prevent neurotoxicity by interrupting events occurring some time after kainate administration.

Immediate early gene activation during the initial phases of the excitotoxic cascade

Direct brain injections of the N-methyl-D-aspartate receptor agonist quinolinic acid (QA) trigger an excitotoxic cascade characterized by rapid neuronal death and glial/immune cell activation. The present study compared the timing of immediate early gene (IEG; c-fos, c-jun, jun-B, and zif/268) induction with the response of neuronal transcripts during the first 24 hr of a QA lesion within the rodent striatum. Following QA exposure, IEG mRNA induction periods extended from 30 min to 24 hr. Several characteristics of this prolonged transcriptional response suggest that separate cell populations (neuronal vs. glial) originate individual IEG phases during the first day of the lesion. The first IEG phase was rapid and peaked at 60 min. This initial IEG phase, likely neuronal in origin, was dominated by robust increases in the expression of c-fos, jun-B, and zif/268 mRNAs in contrast to small increases in c-jun expression. A second, delayed IEG phase was initiated after the first hour and extended to 24 hr. This IEG phase was more intense and continued beyond the period of neuronal survival as detected by the loss of neurotransmitter-specific mRNAs (preprotachykinin, preproenkephalin, and glutamic acid decarboxylase). During this phase, c-jun mRNA levels coordinately increased with c-fos. Interestingly, the transcriptional peak of the delayed IEG phase occurred between 4 and 12 hr, the time which corresponded to the rapid decline of neuronal transcripts.(ABSTRACT TRUNCATED AT 250 WORDS)

Autoradiographical evaluation of [3H]glycine uptake in rat forebrain: cellular localization in the hippocampus

The cellular elements responsible for the uptake of [3H]glycine into rat hippocampal slices were investigated. The diffuse laminar distribution of labelling observed under control conditions was greatly reduced seven days after intrahippocampal injection of a neurotoxic dose of quinolinic acid, suggesting a neuronal localization. Glycine was also taken up into glial cells, since dense clusters of silver grains were present on small sized cells throughout the hippocampus which were apparently increased in number after the lesion. The pattern of [3H]glycine uptake into rat cerebral cortex and cerebellar slices was also consistent with both neuronal and glial localization. These glycine transport sites may be strategically located to control excitatory neurotransmission mediated by the N-methyl-D-aspartate sub-type of glutamate receptors.

Loss of serotonin uptake sites and immunoreactivity in rat cortex after dexfenfluramine occur without parallel glial cell reactions

The frontal cortices of rats which received either D,L- or D-fenfluramine (DFEN) for 4 days were examined 18 h to 2 weeks following treatment for changes in synaptosomal uptake of serotonin (5HT), paroxetine binding, 5HT-immunoreactivity (5HT-IR), and both astrocytic (GFAP) and microglial markers. Additional rats received intracerebroventricular injections of the neurotoxin 5,7-dihydroxytryptamine (DHT). Consistent with previous reports, D,L- and DFEN produced dose-dependent losses of both 5HT uptake and paroxetine binding, and loss of 5HT-IR which coincided with an abnormal or 'swollen' appearance of immunoreactive axon processes. Recovery of these serotonergic indices was greatest following the lowest doses of DFEN, but was absent after 5,7-DHT treatment. No evidence for an increase in GFAP synthesis or microglial activation was observed in frontal cortices of rats treated with either DFEN or 5,7-DHT. We conclude that the presence of swollen 5HT-IR axons in the cortices of both the 5,7-DHT and DFEN groups is insufficient to trigger the glial responses often associated with neuronal degeneration. Thus, it remains to be determined if swollen 5HT-IR axons are a prelude to neurodegeneration, or whether they represent reversible changes in axonal immunochemistry associated with decreases in 5HT levels. The implications of the data for the clinical safety of DFEN are briefly discussed.

In situ hybridization study of interleukin-1 beta mRNA induced by kainic acid in the rat brain

The distribution patterns of interleukin-1 beta (IL-1 beta) mRNA in various brain regions of saline- and kainic acid-treated rats were examined using in situ hybridization technique. In normal rat brain, the signals of IL-1 beta mRNA were observed in the cerebellar Purkinje cells and in dispersed cells in the hypothalamus. In the case of the kainic acid treatment, IL-1 beta mRNA was intensely induced in the olfactory bulb, lateral septum, thalamus, hypothalamus, polymorphic layers of hippocampus, piriform cortex, amygdala, entorhinal cortex and cerebral cortex at 2 h after the injection of kainic acid. In the hypothalamic region, we observed the induction of IL-1 beta mRNA around the paraventricular hypothalamic nucleus, anterior hypothalamic area, dorsomedial and ventromedial hypothalamic nucleus, mammillary regions and arcuate nucleus. The signal of IL-1 beta mRNA was still expressed 4 h after treatment with kainic acid, less intensely than at 2 h, but above the control level. In these regions, IL-1 beta mRNA was expressed mainly in the glial cells, which were densely stained by Cresyl violet and did not contain glial fibrillary acidic protein. These results suggest that IL-1 beta is produced by a certain type of glial cells, maybe microglia, and might have regulatory functions in the central nervous system.

Microglial responses to physiological change: osmotic stress elevates DNA synthesis of neurohypophyseal microglia

We were interested to discover whether microglia could play a role in the remodelling of the adult CNS or participate in adaptations to physiological rather than pathological changes. We have studied microglia in the neurohypophysis of adult mice since microglia normally interact with neurons in this tissue and the biochemical and anatomical consequences of osmotic stress on the neurohypophysis are well known. In this study, we have examined microglial immuno-phenotype and numbers synthesizing DNA in the neurohypophysis of adult mice to establish whether these cells respond to progressive osmotic stress. Neurohypophyseal F4/80+ microglia underwent a large synchronous burst of DNA synthesis 48 h after initiation of osmotic stress (drinking 2.5% saline). The labelling index (percentage of F4/80+ cells labelled by [3H]thymidine) 1 h after injection the isotope rose to 17% from a control value of less than 1%. On the third day of treatment the labelling index had returned to control levels. In contrast, non-microglia cells in the neurohypophysis and microglial cells elsewhere in the brain did not show this response. The increase in DNA synthesis was not accompanied by signs of microglia activation commonly observed in inflammatory models. They did not acquire an "activated" or "hypertrophic" morphology, nor was their staining with a panel of antibodies greatly altered. A small up-regulation of CD45 expression was the only phenotypic change detected. Thus, neurohypophyseal microglia respond to increased neurosecretory activity during the adaptation to osmotic stress in a distinctive way which differs from microglia reactions to inflammatory stimuli elsewhere in the CNS.

Functional roles of microglia in the brain

It has been suggested that microglia, a type of glial cells in the central nervous system, play various important roles in normal and pathologic brains. In this article, we discussed the association or roles of microglia in injury and in brain diseases such as Alzheimer's disease, AIDS dementia complex, multiple sclerosis and ischemia. Furthermore, microglia-derived cytotoxic products and other secretory factors were summarized. In addition to the pathological aspects, secretory factors that showed neurotrophic effects were described with special reference to their physiological significance in the neuronal growth, neuronal function and regeneration processes. Accumulated evidence suggests that microglia are associated with not only brain pathology but also normal physiology in the brain.

Macrophages and inflammation in the central nervous system

Acute inflammation plays an important role in host tissue defense against injury and infection, and also subsequent tissue repair. In the central nervous system parenchyma, following many types of insults, the acute inflammatory response to rapid neuronal degeneration or challenge with inflammatory substances differs dramatically from that of other tissues. The rapid recruitment of neutrophils is virtually absent and monocytes are only recruited after a delay of several days. It appears that the microenvironment of the central nervous system has evolved mechanisms to protect it from the potentially damaging consequences of some aspects of the acute inflammatory response.

Inhibition by the adenosine analogue, (R-)-N6-phenylisopropyladenosine, of kainic acid neurotoxicity in rat hippocampus after systemic administration

1. Binding of the peripheral benzodiazepine receptor ligand, [3H]-PK 11195, to rat hippocampal membranes has been used to quantify the reactive gliosis resulting from neuronal death induced by intraperitoneally administered kainic acid. 2. Intraperitoneal administration of kainic acid (10 mg kg-1) caused a 350-500% increase in [3H]-PK 11195 binding measured in rat hippocampal P2 membranes 7 days later. Co-treatment with the adenosine derivative R-phenylisopropyladenosine (R-PIA) (100, 25 or 10 micrograms kg-1, i.p.) abolished this elevation. The protective action of R-PIA could itself be abolished by co-treatment with 8-phenyltheophylline (1 mg kg-1). 3. Body temperatures were recorded in the antagonist experiments and no significant changes were recorded, suggesting that the protective action of R-PIA was not mediated by hypothermia. 4. Since systemic kainic acid-induced neurotoxicity has been claimed as a good model of neuronal death in temporal lobe epilepsy, the results suggest that the systemic administration of purines in low doses may provide protection against certain neurodegenerative insults.

Early changes of macrophage-like immunoreactivity in the rat inferior olive after intraperitoneal 3-acetylpyridine injection

Early changes of macrophage-like immunoreactivity were observed in the inferior olive after intraperitoneal injection of 3-acetylpyridine (3AP) using seven monoclonal antibodies recognizing macrophage subpopulations (OX-42, OX-6, ED-1, RM-1, TRPM-1, TRPM-2, and TRPM-3). Both resting and activated forms of microglia were stained with OX-42 and TRPM-2. Some of activated microglia reacted to OX-6 and/or ED-1. Neither resting nor activated microglia reacted to any of RM-1, TRPM-1, and TRPM-3. Four h after 3AP injection, the processes of OX-42-positive microglia had increased in number and became thicker than resting microglia. Between 24 h and the 7th day after 3AP injection (day 7), OX-42-positive microglia gradually increased in number. At 24 h after 3AP injection, round cells appeared that stained with all seven antibodies. These disappeared by day 3. Double staining indicated that OX-42-positive activated microglia on day 7 were divided into subpopulations by their immunoreactivity to ED-1. We suggest that the round cells derived from blood monocytes and entered the brain only transiently while OX-42-positive activated microglia originated from parenchymal resting microglia and continued to increase in number after the disappearance of the round cells.

Reactive astrocytes in the kainic acid-damage hippocampus have the phenotypic features of type-2 astrocytes

Kainic acid treatment, a model of temporal lobe epilepsy, induces Ammon's horn sclerosis characterized by degeneration of CA3 pyramidal neurons and reactive gliosis. We now report that in kainic acid treated rats, reactive astrocytes in the hippocampus are A2B5 immunopositive and express GAP-43 immunoreactivity. A2B5 is a cell surface ganglioside selectively expressed in the glial O-2A lineage (oligodendrocytes and type-2 astrocytes in vitro). Since A2B5-positive cells were also GFAP immunoreactive, our observation suggest that hippocampal-reactive astrocytes in the epileptic process are type-2 astrocytes. GAP-43 is a membrane-associated phosphoprotein involved in neurite outgrowth. In vitro analysis showed that the glial O-2A lineage may express this phosphoprotein. In this study, we found that GAP-43 was coexpressed in astrocytes with A2B5 suggesting that in vivo as in vitro type-2 astrocytes express GAP-43.

Neurotoxicity of peptide analogues of the transactivating protein tat from Maedi-Visna virus and human immunodeficiency virus

Infection by lentiviruses such as human immunodeficiency virus, Maedi-Visna virus and Caprine Arthritis Encephalitis Virus, is associated with a variety of neurological syndromes, but the mechanism by which the damage occurs to the nervous system is not known. The viruses do not infect neurons and so the neurotoxic actions must be mediated indirectly. Here we applied synthetic peptide analogues derived from basic regions of Maedi-Visna virus and human immunodeficiency virus transactivating protein, tat, to rat brain in vivo and found them to be potent neurotoxins. The toxicity of the Maedi-Visna virus peptide was demonstrated to be reduced by blockade of nitric oxide synthase and of N-methyl-D-aspartate channel opening. These experiments suggest that peptides derived from lentiviral tat may share a common neurotoxic action.

Mechanism of delayed increases in kynurenine pathway metabolism in damaged brain regions following transient cerebral ischemia

Delayed increases in the levels of an endogenous N-methyl-D-aspartate receptor agonist, quinolinic acid (QUIN), have been demonstrated following transient ischemia in the gerbil and were postulated to be secondary to induction of indoleamine-2,3-dioxygenase (IDO) and other enzymes of the L-tryptophan-kynurenine pathway. In the present study, proportional increases in IDO activity and QUIN concentrations were found 4 days after 10 min of cerebral ischemia, with both responses in hippocampus > striatum > cerebral cortex > thalamus. These increases paralleled the severity of local brain injury and inflammation. IDO activity and QUIN concentrations were unchanged in the cerebellum of postischemic gerbils, which is consistent with the preservation of blood flow and resultant absence of pathology in this region. Blood QUIN and L-kynurenine concentrations were not affected by ischemia. Brain tissue QUIN levels at 4 days postischemia exceeded blood concentrations, minimizing a role for breakdown of the blood-brain barrier. Marked increases in the activity of kynureninase, kynurenine 3-hydroxylase, and 3-hydroxyanthranilate-3,4-dioxygenase were also detected in hippocampus but not in cerebellum on day 4 of recirculation. In vivo synthesis of [13C6]QUIN was demonstrated, using mass spectrometry, in hippocampus but not in cerebellum of 4-day postischemic animals 1 h after intracisternal administration of L-[13C6]tryptophan. However, accumulation of QUIN was demonstrated in both cerebellum and hippocampus of control gerbils following an intracisternal injection of 3-hydroxyanthranilic acid, which verifies the availability of precursor to both regions when administered intracisternally. Notably, although IDO activity and QUIN concentrations were unchanged in the cerebellum of ischemic gerbils, both IDO activity and QUIN content were increased in cerebellum to approximately the same degree as in hippocampus, striatum, cerebral cortex, and thalamus 24 h after immune stimulation by systemic pokeweed mitogen administration, demonstrating that the cerebellum can increase IDO activity and QUIN content in response to immune activation. No changes in kynurenic acid concentrations in either hippocampus, cerebellum, or cerebrospinal fluid were observed in the postischemic gerbils compared with controls, in accordance with the unaffected activity of kynurenine aminotransferase activity. Collectively, these results support roles for IDO, kynureninase, kynurenine 3-hydroxylase, and 3-hydroxyanthranilate-3,4-dioxygenase in accelerating the conversion of L-tryptophan and other substrates to QUIN in damaged brain regions following transient cerebral ischemia. Immunocytochemical results demonstrated the presence of macrophage infiltrates in hippocampus and other brain regions that parallel the extent of these biochemical changes.(ABSTRACT TRUNCATED AT 400 WORDS)

Altered antigen expression of microglia in the aged rodent CNS

Microglia, the resident macrophages of the central nervous system, are characterised by a highly specialized morphology and unusual antigenic phenotype. Microglia appear to be downregulated by their microenvironment when compared to other tissue macrophages. We have studied the microglia in brains of healthy, aged rats with a panel of monoclonal antibodies. We have found that microglia in the brains of these aged rats express antigens that are downregulated or absent from microglia of juvenile rats. The stimuli which give rise to this upregulated phenotype are not known. Age related changes in the phenotype of microglia should be taken into account when considering the possible role of microglia in neuropathological conditions.

Increased levels of the Kunitz protease inhibitor-containing beta APP mRNAs in rat brain following neurotoxic damage

Deposits of beta-amyloid are one of the main pathological characteristics of Alzheimer's disease. The beta-amyloid peptide (or beta/A4) constituent of these deposits is derived from the beta-amyloid precursor protein (beta APP), which is expressed in several isoforms. It has been suggested that an imbalance in the normal ratio between the Kunitz protease inhibitor (KPI)-containing beta APPs versus the non containing forms could result in altered processing of beta APP and progressive beta/A4 deposition. We have studied the expression of four beta APP isoforms in the rat brain after intracerebroventricular application of kainic acid. Increased levels of the KPI-containing beta APP and GFAP mRNAs were observed in tissues surrounding areas of neuronal damage. A parallel increase of beta APP and GFAP immunoreactivity was observed in reactive astrocytes in these areas. These results suggest that the normal ratio of beta APP isoforms may be profoundly altered as a result of neuronal damage and that non-neuronal cells may respond to neuronal injury by increased expression of the KPI-containing beta APP isoforms.

Microglial MHC antigen expression after ischemic and kainic acid lesions of the adult rat hippocampus

By taking advantage of the specific neuronal and connective organization of the hippocampus and the different susceptibility of hippocampal neurons to transient cerebral ischemia or intraventricular injections of kainic acid (KA), we examined the microglial reactions to different types of neuronal injury. In all areas with neuronal or axonal degeneration, the microglial cells reacted by specific degeneration-related morphological transformations and expression of class I major histocompatibility complex (MHC) antigen. Subpopulations of microglial cells also expressed class II MHC antigen and leukocyte common antigen (LCA) in relation to (1) degenerating nerve cell bodies in the dentate hilus and the CA1 and CA3 pyramidal cell layers, (2) postischemic degeneration of dendrites in the stratum radiatum of CA1, and (3) combined dendritic and axonal degeneration in the stratum radiatum of the KA-lesioned CA3. MHC II and LCA expression was not observed in relation to degeneration of the CA3-derived Schaffer collaterals in CA1 after KA-induced CA3 lesions. In the case of ischemia the degeneration-related reactions were preceded by an early, generalized microglial reaction, which also included areas without subsequent signs of neural degeneration. This reaction, which was transient and characterized by subtle morphological changes and induction of class I MHC antigen only, was presumably triggered by a general postischemic perturbation of the cerebral microenvironment, and not by actual neural degeneration. In conclusion, we found that microglial expression of class I MHC antigen was a sensitive marker of both the general perturbation after ischemia and axonal degeneration distant from the areas of actual nerve cell death.(ABSTRACT TRUNCATED AT 250 WORDS)

The inflammatory response in the CNS

In recent years it has been recognized that cells of the mononuclear phagocyte lineage, macrophages and microglia, are a major component of gliosis. We review here studies on the kinetics of the myelomonocytic response to acute excitotoxin induced neuronal degeneration and following the injection of endotoxin (LPS) into the parenchyma of the central nervous system. These studies have shown that the kinetics of myelomonocytic recruitment to the parenchyma of the central nervous system is quite unlike that of other tissues; the polymorphonuclear cells are largely excluded and monocytes are only recruited after a delay of several days. The unusual nature of the inflammatory response in the central nervous system needs to be considered when drawing parallels with the acute inflammatory response in other tissues.

Seizure activity-induced changes in polyamine metabolism and neuronal pathology during the postnatal period in rat brain

Systemic injection of kainic acid (KA) does not cause neuronal pathology in limbic structures in rat brain prior to postnatal day (PND) 21. The present study tested if the development of the pathogenic response is associated with the maturation of a link between seizure activity and polyamine metabolism. Pathology was assessed with histological techniques and with the binding of [3H]Ro5-4864, a ligand for the peripheral type benzodiazepine binding sites (PTBBS), a marker of glial cell proliferation. In agreement with previous results, peripherally administered kainate at doses sufficient to induce intense behavioral seizures produced a loss of Nissl staining in hippocampus after PND 21 but not at earlier ages. The pattern of neuronal damage observed after PND 21 resembled that found in adult animals: extensive losses of Nissl staining in area CA3 of hippocampus and in piriform cortex, more modest effects in CA1 and sparing of the granule cells of the dentate gyrus. Similarly, no increase in [3H]Ro5-4864 binding as a result of KA administration was observed in hippocampus and piriform cortex until PND 21. Ornithine decarboxylase (ODC) activity and putrescine levels were high in the neonatal brain and decreased to reach adult values by PND 21. KA-induced seizure activity did not significantly alter both variables until PND 21. After PND 21, ODC activity and putrescine levels markedly increased 16 h after KA-induced seizure activity in hippocampus and piriform cortex. The magnitude of the effects increased between PND 21 and PND 30, at which point the changes in both parameters were comparable to those found in adults. Polyamines stimulate the activity of the calcium-dependent proteases calpain in brain fractions and may increase calpain-mediated proteolysis in situ. In accord with this, kainate-induced breakdown of spectrin, a preferred substrate of calpain, measured 16 h after KA injection followed a developmental curve parallel to that for kainate-induced increases in putrescine levels. These results indicate that the onset of vulnerability to seizure activity triggered by kainic acid is correlated with the development of an ODC/polyamine response to the seizures and further support a critical role for the ODC/polyamine pathway in neuronal pathology following a variety of insults.

A novel neuronal messenger molecule in brain: the free radical, nitric oxide

Understanding of the organization and function of a newly identified neuronal messenger molecule, nitric oxide, has progressed rapidly. Nitric oxide synthase has been purified and molecularly cloned from brain. Its localization is exclusively neuronal and endothelial. The catalytic activity of nitric oxide synthase accounts for the NADPH diaphorase staining of neurons that are uniquely resistant to toxic insults and neurodegenerative disorders. Nitric oxide has diverse functions. In platelets it inhibits their aggregation, in macrophages it mediates cytotoxicity, and in blood vessels it acts as a vasodilator. In the nervous system nitric oxide may be the retrograde transmitter in long-term potentiation. It is the "neurotransmitter" of cerebral vasodilator nerves and the inhibitory "neurotransmitter" of the motor neurons of the intestines. Nitric oxide in situations of excessive production may function as a neurotoxin, suggesting a role for nitric oxide in neurodegenerative disorders.

Intracerebral injection of proinflammatory cytokines or leukocyte chemotaxins induces minimal myelomonocytic cell recruitment to the parenchyma of the central nervous system

Neither excitotoxic neurodegeneration nor lipopolysaccharide induces an acute myelomonocytic exudate in the murine central nervous system (CNS) parenchyma (Andersson, P.-B., V. H. Perry, and S. Gordon. 1991. Neuroscience, 42:201; Andersson, P.-B., V. H. Perry, and S. Gordon. 1992. Neuroscience 48:169). In this study formyl-methionyl-leucyl-phenylalanine, platelet-activating factor, interleukin 8 (IL-8), IL-1, or tumor necrosis factor alpha were injected into the hippocampus to assess whether these leukocyte chemotaxins and known mediators of recruitment could bypass this block. They induced morphologic activation of microglia and widespread leukocyte margination but little or no cell exudation into the CNS parenchyma. By contrast, there was acute myelomonocytic cell recruitment to the choroid plexus, meninges, and ventricular system, comparable to that in the skin after subcutaneous injection. The normal CNS parenchyma appears to be a tissue unique in its resistance to leukocyte diapedesis, which is shown here to be at a step beyond chemotactic cytokine secretion or induction of leukocyte adhesion to cerebral endothelium.

Consequences of slow Wallerian degeneration for regenerating motor and sensory axons

The time course of Wallerian degeneration in the tibial and saphenous nerves was compared in Balb/c mice and mice of the C57BL/Ola strain (Lunn et al., 1989). Axons, particularly myelinated ones, in nerves of C57BL/Ola mice are very slow to degenerate, many still being present 3 weeks after axotomy. Nuclear numbers in the distal stump peak much later and do not reach the levels found in Balb/c mice; debris removal is very slow, and Schwann cell numbers only rise slightly above normal levels in the long term. Regeneration was investigated electrophysiologically and by electron microscopy (EM). Myelinated sensory axons regenerated slowly and incompletely compared with motor ones which were only slightly slowed after nerve crush (although they were significantly hindered after nerve section). Total myelinated axon numbers were still some 20% less than normal even after 200 days in sensory nerves. Even after all axons had degenerated in C57BL/Ola mice, regeneration rates of neither myelinated nor unmyelinated sensory axons reached those achieved in Balb/c mice. It is concluded that while regeneration can eventually proceed slowly when Wallerian degeneration is much delayed, the usual rapid time course of Wallerian degeneration is necessary if axons, particularly sensory ones, are to regenerate at optimal rates and to maximum extent. While local obstruction to axon growth probably impedes the early phase of regeneration in C57BL/Ola mice, it seems possible that a lack of adequate early signals affects regeneration permanently by minimizing the cell body reaction to injury.