Immunohistochemical localization of macrophages and microglia in the adult and developing mouse brain

Immunogenetic analysis of cellular interactions governing the recruitment of T lymphocytes and monocytes in lymphocytic choriomeningitis virus-induced immunopathology

The Lyt2+ class I major histocompatibility complex (MHC)-restricted virus-immune T cells that induce murine lymphocytic choriomeningitis (LCM) are targeted onto radiation-resistant cells in the central nervous system of virus-infected mice. The use of appropriate bone marrow radiation chimeras as LCM virus-infected, (immunosuppressed recipients for immune T-cell transfer has established that, though bone marrow-derived cells can stimulate virus-specific cytotoxic T lymphocytes (CTL) in spleen, they do not reconstitute the barrier to T-cell recruitment from blood to cerebrospinal fluid. This is true for chimeras made up to 8 months previously, even though the inflammatory monocytes and macrophages in such chimeras are all of donor bone marrow origin. Radiation-resistant cells in the spleens of these chimeras are also still able to further stimulate virus-immune CTL. There is no requirement for H-2 compatibility between virus-immune T lymphocytes and secondarily recruited monocytes, or T cells of an inappropriate specificity. The key event in LCM immunopathology may thus be localization of T cells to the antigen-presenting endothelium in brain, leading to the secretion of mediators that promote the nonspecific recruitment of monocytes and other T cells.

A fibronectin-like molecule is present in the developing cat cerebral cortex and is correlated with subplate neurons

The subplate is a transient zone of the developing cerebral cortex through which postmitotic neurons migrate and growing axons elongate en route to their adult positions within the cortical plate. To learn more about the cellular interactions that occur in this zone, we have examined whether fibronectins (FNs), a family of molecules known to promote migration and elongation in other systems, are present during the fetal and postnatal development of the cat's cerebral cortex. Three different anti-FN antisera recognized a single broad band with an apparent molecular mass of 200-250 kD in antigen-transfer analyses (reducing conditions) of plasma-depleted (perfused) whole fetal brain or synaptosome preparations, indicating that FNs are present at these ages. This band can be detected as early as 1 mo before birth at embryonic day 39. Immunohistochemical examination of the developing cerebral cortex from animals between embryonic day 46 and postnatal day 7 using any of the three antisera revealed that FN-like immunoreactivity is restricted to the subplate and the marginal zones, and is not found in the cortical plate. As these zones mature into their adult counterparts (the white matter and layer 1 of the cerebral cortex), immunostaining gradually disappears and is not detectable by postnatal day 70. Previous studies have shown that the subplate and marginal zones contain a special, transient population of neurons (Chun, J. J. M., M. J. Nakamura, and C. J. Shatz. 1987. Nature (Lond.). 325:617-620). The FN-like immunostaining in the subplate and marginal zone is closely associated with these neurons, and some of the immunostaining delineates them. Moreover, the postnatal disappearance of FN-like immunostaining from the subplate is correlated spatially and temporally with the disappearance of the subplate neurons. When subplate neurons are killed by neurotoxins, FN-like immunostaining is depleted in the lesioned area. These observations show that an FN-like molecule is present transiently in the subplate of the developing cerebral cortex and, further, is spatially and temporally correlated with the transient subplate neurons. The presence of FNs within this zone, but not in the cortical plate, suggests that the extracellular milieu of the subplate mediates a unique set of interactions required for the development of the cerebral cortex.

Cell recruitment during glial repair: the role of exogenous cells

Selective disruption of the neuroglia in penultimate abdominal connectives of the cockroach nerve is followed by a rapid accumulation of cells in the perineurial layer of the lesion. Subsequently, there is an abrupt, secondary, rise in cell numbers in the undamaged perineurial tissues, anterior to the lesion and adjacent to the 4th abdominal ganglia. By 7 days the increased cell numbers are again effectively confined to the original lesion zone. The initial rise in cell numbers is postulated to result from an invasion by blood-borne haemocytes and the subsequent increase, in undamaged perineurial tissues, from the mobilization of endogenous reactive cells. Recruitment of the endogenous cells is inhibited if the haemocytes are excluded from the lesion. There is a slower mobilization of sub-perineurial cells, which, again, is inhibited following exclusion of haemocytes from the lesion zone. It is postulated that the recruitment of the endogenous reactive cells is initiated by the invading haemocytes which transform to granule-containing cells and release diffusible morphogenic and/or mitogenic factors.

Ibotenic acid induced demyelination in the central nervous system: a consequence of a local inflammatory response

We examined the effects of injections of ibotenic acid into the medial septum (MS), dorsal lateral geniculate nucleus (dLGN), caudate-putamen (CP) or fornix-fimbria (FF) on fibres close to the injection site. Injections into the MS and dLGN resulted in demyelination. The area of demyelination correlated with the area of maximal gliosis. The major cell type in the area of gliosis were cells of haemopoietic origin, as revealed by using monoclonal antibodies (Mabs). Demyelination was not observed in the CP or FF. Axonal transport in fibres en passage through the dLGN lesion was also disrupted following injections of horseradish peroxidase (HRP) into the eye contralateral to the lesion. These results show that when ibotenic acid induces cell death it can secondarily damage myelin sheaths and disrupt axonal transport in areas containing diffuse fibre systems. We suggest that this is due to a non-specific effect of the inflammatory response.

Simian immunodeficiency virus-induced meningoencephalitis: natural history and retrospective study

Simian immunodeficiency virus (SIV) is a lentivirus with morphological and antigenic similarities to human immunodeficiency virus, the causative agent of acquired immunodeficiency syndrome (AIDS) of humans. Macaque monkeys infected with SIV show profound immunological impairment, clinically characterized by multiple opportunistic infections and neoplasms. Retrospective examination of autopsy tissue from 27 SIV-infected animals demonstrated that approximately 60% of the experimentally inoculated animals had a meningoencephalitis characterized by perivascular infiltrates of macrophages and multinucleate giant cells in the white and gray matter and leptomeninges. Ultrastructurally, these macrophages contained typical lentiviral particles within membrane-bound intracytoplasmic vacuoles. Other findings in the central nervous system included discrete randomly located neuroglial nodules, endothelial hypertrophy, and leptomeningeal thickening. The results indicate tha the meningoencephalitis induced by SIV in monkeys is similar to the lesions of the central nervous system in patients with AIDS and that SIV infection in the macaque is a useful animal model to study the pathogenesis of human immunodeficiency virus--related subacute encephalitis or AIDS encephalopathy.

Experimental modifications of postnatal differentiation and fate of glial cells related to axo-glial relationships

The fate of glial cell lines following Wallerian degeneration in the rat optic nerve was analysed after pulse labelling with [3H]thymidine. The rats were unilaterally enucleated at the key stages 2, 5, 8 and 20 days after birth. Three hours later, they were injected intraperitoneally with [3H]thymidine and killed after 1, 3, 5, 10 and 20 days survival. Oligodendrocytes were the most affected, being unable to differentiate after 2 days enucleation, dying rapidly or transforming into another cell type after 5, 8 and 20 days enucleation. The apparent stability of the astrocyte population is due to an equilibrium between increased differentiation from glioblasts and increased death, the latter being preponderant at the key stage 2 days. Finally, the steady increase in the number of microglia may be due to the transformation from other cells, either glioblasts for the early time intervals or oligodendrocytes later on. It appears, then, that the interrelation between glial cell lines during differentiation is more intricate than previously suspected and is closely dependent, for each line, upon the integrity of axons.

Functional plasticity of microglia: a review

The present review summarizes recently acquired data in vivo, which support a role of CNS microglia as a source of defense cells in the CNS capable of carrying out certain immune functions autonomously. We have kept the following discussion restricted to microglial cells and have not included work on the immunological functions of astrocytes, which has been recently reviewed elsewhere (Fontana et al.: Immunological Reviews 137:3521-3527, 1987). Resting microglia are scattered uniformly throughout the CNS forming a network of potential immunoeffector cells, which can be activated by stimuli ranging from peripheral nerve injury over viral infections to direct mechanical brain trauma. The term "activated microglia" is used here to describe proliferating cells that demonstrate changes in their immunophenotype but have not undergone transformation into brain macrophages. Such a transformation can be stimulated by neuronal death but not by sublethal neuronal injury. Microglia may function as antigen-presenting cells and may thus represent the effector cell responsible for the recruitment of lymphocytes to the brain resulting in an inflammatory reaction. The recent developments in the understanding of microglial cell function may lead to a redefinition of the often cited "immune privilege" of the brain.

Absence of donor-type major histocompatibility complex class I antigen-bearing microglia in the rat central nervous system of radiation bone marrow chimeras

Localization of bone marrow-originated cells in the central nervous system (CNS) of the rat was investigated by using bone marrow chimeras. In order to do this, Lewis rats which carry major histocompatibility complex (MHC) class I antigens haplotype 1 (RT1.Al) were reconstituted with (Lew X PVG)F1 (RT1.Al/c) bone marrow cells after lethal irradiation. Transferred bone marrow cells were detected by immunohistochemical staining using a monoclonal antibody, OX27, specific for haplotype c of rat MHC class I antigens (RT1.Ac). The spleen and thymus of chimeric rats were fully reconstituted with transferred F1 cells 4 weeks after bone marrow transplantation. At this stage, mononuclear cells in the subarachnoid space of the CNS expressed OX27 antigen indicating that they were of bone marrow origin. A few OX27-positive blood cells were scattered in the CNS parenchyma 4-12 weeks after reconstitution. Ramified microglia, however, remained OX27-negative. Bone marrow-derived microglia were not observed throughout the period of examination until 24 weeks. In addition, experimental allergic encephalomyelitis (EAE) was induced in chimeric rats in order to augment the expression of MHC class I antigens on microglia. Even under this condition, no OX27-positive microglia were observed. Taken together, ramified microglia might be of neuroectodermal origin and there is little possibility that the microglia are derived from the bone marrow. However, if the ramified microglia are derived from blood cells, the microglia may be expected to have characteristic cell kinetics from the following points: (1) the precursor cells of the microglia may enter the CNS only at the perinatal stage; and (2) even under the condition in which lymphocytes and macrophages enter the CNS as observed in EAE, the precursor cells of the microglia are not supplied from the blood.

Production of superoxide anions by a CNS macrophage, the microglia

Microglia have been implicated in both physiological and pathological processes of the brain. Their possible roles have been compared to those of macrophages and granulocytes. Here we demonstrate that specific ability of microglia to secrete the superoxide radical ion in response to a complement activated agent, opsonized zymosan, and to phorbol myristate acetate. As in other organs, this endogenously produced reactive oxygen intermediate could have both beneficial and deleterious effects.

Modulation of CD4 antigen on macrophages and microglia in rat brain

Mononuclear phagocytes which express the HIV entry receptor CD4 have been implicated as possible sites of virus replication in brain, but there is still considerable uncertainty as to which cells in the CNS express CD4 Ag. Although it is not susceptible to HIV infection the rat provides a model to define expression of the CD4 Ag on MO in brain. We report that the CD4 epitopes W3/25 and OX35 are found only on monocytes, MO, microglia, and occasional lymphocytes and not on neurons, other glia, or endothelium. CD4 Ag levels are modulated during microglial differentiation, after reactivation after local inflammation, and within the intact blood brain barrier. MO and microglia also express other potential plasma membrane binding and entry sites for HIV viz Fc and complement receptors that are regulated independently of CD4.

Antigen presentation and tumor cytotoxicity by interferon-gamma-treated microglial cells

In this study microglial cells isolated from brain cell cultures of newborn mice were characterized and investigated for morphology, their responses to growth factors and their functional properties. The microglial cells were phagocytic, contained nonspecific esterase activity and expressed Fc (IgG1/2b) and type-3 complement receptors. Scanning electron microscopy revealed that in analogy to brain tissue two types of microglial cells are present in the cultures: the ameboid and the ramified type which both display similar appearance by transmission electron microscopy. Interleukin 3 and the granulocyte-macrophage colony-stimulating factor were potent growth factors for the cultured microglial cells. The cells were negative for class II antigens (Ia) of the major histocompatibility antigen complex. However, upon treatment with interferon-gamma (IFN-gamma) microglial cells became Ia+ and functioned as antigen-presenting cells when tested on ovalbumin-specific Ia-restricted helper T cells. Furthermore, microglial cells exposed to IFN-gamma and endotoxin developed tumor cell cytotoxicity and produced tumor necrosis factor alpha. Taken together, microglial cells share the characteristics of cells of the macrophage lineage.

Role of cell death in the topogenesis of neuronal distributions in the developing cat retinal ganglion cell layer

The neurons of the developing and adult ganglion cell layer of the cat retina may be morphologically divided into two major populations. One population, the classic neurons, is mainly composed of ganglion cells, and of a small percentage of displaced amacrines, the bar cells. The remaining neurons are microneurons, which make up the majority of the displaced amacrine population. The loss of ganglion cells during the development has been attributed to cell death. It has alternatively been suggested that some ganglion cells may lose their axon and be transformed into displaced amacrine cells, without degeneration of the cell soma. Reexamination of foetal and postnatal cat retinas confirms the presence of degenerating cells in the ganglion cell layer. Their number appears to be at a maximum on embryonic day (E) 57 but declines rapidly until birth. The peak of cell death thus coincides with the decline in optic nerve fibre counts and classical neuron or ganglion cell numbers. Some cells in early stages of degeneration resemble classical neurons, but the original morphology of those advanced stages of degeneration could not be identified, nor was it possible to identify pyknotic microneurons at any stage. Substantial degeneration of the microneurons is not suggested but if it occurs, it is masked by an overall increase in the population of these cells before birth. Cell death in the microneuron population thus cannot yet be ruled out. It has been argued in the literature that fragments of degenerating cells in developing neural tissue are cleared by microglia within 10-14 hours. In order to test the hypothesis that operation of cell death can alone account for the observed loss of classical neurons in the foetal cat retina, we have modelled the effect of various presumed clearance times on corresponding neuronal population magnitudes. It is found that a constant clearance time of 10-24 hours would be consistent with the observed loss of classical neurons before birth. If this is true, then no ganglion cells would remain for transformation into amacrine cells. The absolute density of degenerating or pyknotic cells is found to be relatively constant across the retina. However their density expressed as a percentage of the local population of classical neurons is markedly higher in peripheral than central retina. In the former region, they compose more than 10% of classical neurons at stage E57. On the same day, the percentage distribution maps define an elongated central area containing only 3-5% pyknotic profiles. This region corresponds to the location of the future visual streak.(ABSTRACT TRUNCATED AT 400 WORDS)

Microglia are the major cell type expressing MHC class II in human white matter

In normal human white matter the predominant cell type expressing MHC Class II is the microglia. This population of cells reacts with the pan macrophage marker, EBM/11, and constitutes about 13% of the glial cell population. The intensity of staining was enhanced and the absolute number of Class II+ microglia increased in normal appearing white matter from multiple sclerosis (MS) brain. As T cell activation in MS may occur in the brain the upregulation of microglia bearing MHC Class II may reflect their function as antigen presenting cells in the development of inflammatory lesions.

Phenotypic analysis of the inflammatory exudate in murine lymphocytic choriomeningitis

The massive inflammation of the cerebrospinal fluid (CSF) which occurs in adult mice injected with lymphocytic choriomeningitis virus (LCMV) has been analyzed by flow microfluorometry (FMF). The great majority of the T cells detected by direct examination of freshly obtained CSF were found to be Lyt-2+, with an almost total absence of L3T4+ lymphocytes. The Lyt-2/L3T4 ratio of lymphocytes in blood was within normal limits. Predominance of the Lyt-2+ subset was confirmed by culturing the CSF cells after mitogenic stimulation. In addition, the T lymphocytes in CSF of cyclophosphamide-suppressed, virus-infected recipients that had been injected 4 d previously with LCMV-immune spleen cells were almost entirely donor Lyt-2+ cells, while the nonlymphoid elements were exclusively of host origin. However this pattern of donor and host T cell distribution was reversed when the LCMV-infected recipients were not immunosuppressed. The frequency of LCMV-specific CTL precursors in CSF taken immediately before the development of symptoms was as low as 1:3,000 cells. Thus most of the T lymphocytes extravasating into the CSF of mice with LCM are passive participants recruited as a consequence of the function of relatively few LCMV-specific effector T cells. The dominance of the Lyt-2+ T cell subset in the CSF of mice with LCM is intriguing.

Characterization of immunoglobulin G-Fc receptor activity in the outflow system of the cerebrospinal fluid

We have examined IgG Fc receptor (FcR) activity of human and rabbit arachnoid granulations and leptomeninges using antibody (IgG)-coated erythrocytes (EIgG), covalently crosslinked IgG dimers, trimers and oligomers, immune complexes, aggregated Fc fragments and a monoclonal anti-human neutrophil Fc receptor antibody, 3G8. EIgG bound specifically to cells of the leptomeninges and arachnoid granulations; uncoated erythrocytes, F(ab')2-coated, or IgM-coated erythrocytes failed to bind. The specificity of this interaction was demonstrated by inhibition studies. Monomeric IgG and Fc fragments blocked EIgG adherence, whereas bovine serum albumin (BSA), Fab fragments of IgG and the monoclonal anti-neutrophil FcR antibody failed to inhibit EIgG adherence. Monomeric IgG inhibited FcR function in a dose-dependent fashion; maximal inhibition was achieved at 1.7 X 10(-5)M IgG, indicating a relatively low avidity receptor. Oligomers of IgG inhibited EIgG adherence more effectively and inhibition was directly related to oligomer size. Additionally, these tissues were positive for specific and non-specific esterases. These studies suggest that the CSF pathway from the perivascular spaces to the arachnoid granulations plays a protective role in the clearance of IgG and IgG immune complexes in infections and immune-mediated disorders.

Hydrocortisone administration alters glial reaction to entorhinal lesion in the rat dentate gyrus

Young adult male rats received subcutaneous implants of Alzet osmotic minipumps which delivered 400 micrograms hydrocortisone per day. Untreated rats received no pumps or pumps containing the vehicle. Five days after receiving the implantation, both groups of rats were subjected to unilateral entorhinal lesion. Seven days after surgery, brains were analyzed quantitatively for glial changes in the denervated dentate outer molecular layer. Numerical densities of astrocytes and nonastrocytic glia were calculated by cell counting using 1.0-micron toluidine blue-stained sections. Glial acid phosphatase staining was quantitated using computer-assisted cytophotometric measurement of individual glial cells. Hydrocortisone-treated animals demonstrated 31% more astrocytes and 22.4% less nonastrocytes in the dentate outer molecular layer compared with untreated animals. Glia in the treated animals also showed a 33% decrease in average optical density of cytoplasmic acid phosphatase staining. These findings suggest that hydrocortisone treatment prior to and following an entorhinal lesion accelerates lesion-induced migration of astrocytes to the outer molecular layer, and reduces the increase in microglial number resulting from the lesion. The observed effect on microglia may result from a direct hormonal inhibition of local proliferation of microglia or from the well known systemic anti-inflammatory action of glucocorticoids on monocytes, the putative precursors of brain microglia. Our findings suggest that glucocorticoid hormones significantly alter the response of non-neuronal cells to neural tissue damage.

Lectin binding by resting and reactive microglia

Conjugates of the B4 isolectin from Griffonia simplicifolia seeds and horseradish peroxidase were used as a histochemical reagent for the specific visualization of microglial cells in the rat CNS. Resident microglia bearing galactose-containing glycoconjugates were stained throughout the brainstem and cerebellum. In the first week following axotomy of the facial nerve, a profound and rapid accumulation of reactive microglia, as evidenced by increasing lectin reactivity, was seen to take place in the facial nucleus. Light microscopy of paraffin sections demonstrated binding of lectin-horseradish peroxidase conjugates to microglial cytoplasmic processes. When ultrastructural cytochemistry was performed, reaction product was found localized on microglial plasma membranes, as well as on intracytoplasmic membranes. The glial reaction to axotomy was studied further with double labelling of microglia and astrocytes by lectin histochemistry and immunostaining for glial fibrillary acidic protein, respectively. Our results demonstrated the presence of membrane-associated glycoconjugates containing terminal alpha-D-galactose residues on microglia, but not on other glial cell types. The possible nature and function of these glycoconjugates are discussed.

The macrophage response to central and peripheral nerve injury. A possible role for macrophages in regeneration

Using mAbs and immunocytochemistry we have examined the response of macrophages (M phi) after crush injury to the sciatic or optic nerve in the mouse and rat. We have established that large numbers of M phi enter peripheral nerves containing degenerating axons; the M phi are localized to the portion containing damaged axons, and they phagocytose myelin. The period of recruitment of the M phi in the peripheral nerve is before and during the period of maximal proliferation of the Schwann cells. In contrast, the degenerating optic nerve attracts few M phi, and the removal of myelin is much slower. These results show the clearly different responses of M phi to damage in the central and peripheral nervous systems, and suggest that M phi may be an important component of subsequent repair as well as myelin degradation.

Microglia in the hypendyma of the rat subcommissural organ following brain lesion with serotonin neurotoxin

The population of microglial cells in the subependymal layer of the subcommissural organ is sparse in normal adult rats. The number of microglial cells was substantially increased in this area following intraventricular injection of the serotonin neurotoxin 5,6-dihydroxytryptamine (5,6-DHT). In sections of plastic embedded material, 1 micron thick, the majority of phagocytic cells scattered in the subependymal layer had an appearance similar to that described in classical studies of microglial cells. At the electron microscopic level microglial cells exhibited the characteristic elongate nucleus with peripheral chromatin condensation. The perikaryon was scanty, containing strands of rough endoplasmic reticulum. The abundant organelles in the processes included Golgi complexes, mitochondria, rough and smooth endoplasmic reticulum as well as dense and multivesicular bodies. In addition, the processes contained phagocytosed axon terminals originating from the dense serotoninergic input to the subcommissural organ, which had degenerated on accumulating the serotonin neurotoxin. A fraction of the phagocytosed material was contained in subependymal subcommissural organ cells, astrocytes and oligodendrocytes. At the light microscopic level the phagocytosed terminals were visualized histochemically with Schmorl's reaction, which resulted in Prussian Blue precipitates. This allowed screening of microglial cells in complete series of sections through the well-defined subependymal layer of the subcommissural organ.

Macrophages in the central nervous system of the rat

In an immunohistochemical study using monoclonal antibodies, which exclusively recognize cells of the monocyte-macrophage lineage, and monoclonal antibodies against the Ia-antigen, we describe the occurrence of macrophages in the developing and adult central nervous system (CNS). In normal adult brain, no macrophages could be detected in the CNS parenchyma; only in the meninges and the choroid plexes were a few macrophages found. During ontogeny, numerous phagocytic cells infiltrated the CNS parenchyma; these cells which did not express Ia are blood-borne. About three weeks after birth, all macrophages had disappeared from the CNS. As microglia in adult and developing brain do not stain with the anti-macrophage antibodies, we suggest that microglial cells are not related to the mononuclear phagocyte system and do not have a hematogenous origin.

Ameboid microglia as effectors of inflammation in the central nervous system

Techniques for selective isolation, labeling, stimulation, and destruction of ameboid microglia allow study of some fundamental questions in neuroimmunology. Examination of surface morphology, proliferative capacity, and cytochemistry suggests that microglia are a class of brain mononuclear phagocytes distinct from blood monocytes, spleen macrophages, or resident peritoneal macrophages. Moreover, cultured ameboid microglia isolated from newborn brain can be induced to grow thin cytoplasmic projections several hundred microns in length; these process-bearing cells resemble a differentiated form of microglia found in adult brain. Ameboid microglia may contribute to brain inflammation by engulfing debris, by releasing cytotoxins, by killing neighboring cells, and by secreting astroglial growth factors. Importantly, ameboid microglia are closely tied to a network of immunomodulators that include colony-stimulating factors and Interleukin-1. The presence of activated microglia during normal embryogenesis and at sites of penetrating brain injury suggests that these cells serve as important effectors linking the immune system with growth and repair of the CNS.

Differential effect of hybrid resistance on the localization of virus-immune effector T cells to spleen and brain

The hybrid resistance (Hr) effect operates in the lymphocytic choriomeningitis (LCM) in vivo transfer model to inhibit both the level of cytotoxicity T lymphocyte (CTL) generation in spleen and the induction of inflammation in cerebrospinal fluid (CSF). The effect is seen when LCM virus-immune T cells that are homozygous for H-2Db are injected into virus-infected, immunosuppressed recipients that are heterozygous for this allele, or into radiation chimeras that express an appropriate F1 phenotype. Evidence that Hr to T-cell transfer is cell-dose-dependent and tends to diminish with age was found in both chimeric and normal F1 mice. Inhibition of the capacity of injected T cells to cause meningitis is a more sensitive measure of Hr than is the further stimulation of CTL effectors in recipient lymphoid tissue. The injection of large numbers of H-2b virus-immune T cells into (H-2k X H-2bF1----H-2k) virus-infected recipients did not induce any cellular extravasation into CSF, though potent H-2b-restricted CTL effectors were generated in recipient spleen. Evidence of minimal inflammatory process was found in one experiment where these chimeras were given a comparable dose of (H-2b X H-2d)F1 immune spleen cells. Development of this T-cell-mediated immunopathological process depends essentially on the expression of the appropriate H-2 restriction element on radiation-resistant host cells which, in this case, presumably constitute part of the physiological barrier between blood and CSF.

Role of the major histocompatibility complex in targeting effector T cells into a site of virus infection

Bone marrow radiation chimeras have been used as virus-infected, cyclophosphamide-suppressed recipients to analyze the major histocompatibility complex (MHC) restriction constraints on the adoptive transfer of lymphocytic choriomeningitis by immune T cells. The basic protocol employed [(A X B)F1----(A X C)F1] chimeras, where A, B, C are different MHC haplotypes, and the establishment of appropriate chimerism was measured by the capacity of, for instance, the transferred A, T cells to generate MHC-restricted, virus-specific cytotoxic T lymphocytes (CTL) in the spleen of the [(A X B)F1----(B X C)F1] recipients. The experiments show quite clearly that maximal inflammatory process is only induced when donor bone marrow, irradiated recipient and transferred T cells share at least one MHC haplotype. Compatibility of the T cells and the radiation-resistant phenotype alone in, for instance, transfer of C immune lymphocytes into [(A X B)F1----(B X C)F1] recipients produced little inflammation if the chimeras had been established for at least 10 weeks. These results are compatible with a model which proposes that the transferred T cells first replicate in MHC-compatible lymphoid tissue and are then targeted onto the appropriate MHC plus virus expressed on cells in the blood-cerebrospinal fluid (CSF) barrier. An alternative postulate, that all that is required for the development of inflammatory process is MHC-restricted T cell replication in lymphoid tissue, with subsequent nonspecific localization to the central nervous system (CNS), was explored by transferring B, immune T cells into [(A X B)F1----A] recipients. The finding was that H-2b effectors did not cause any meningitis in [H-2kXb F1----H-2k] recipients, though potent H-2b-restricted CTL were generated in the spleens of comparable chimeras. However, in the H-2k immune----[H-2kXbF1----H-2b] transfer there was evidence of moderate inflammation that was about 9 times less severe than that caused by the H-2b effectors in comparable recipients. This indicates that, for maximal inflammatory process to occur, the T cells must encounter MHC-compatible, virus-infected cells in the CNS, with the effect being absolute in one strain combination and partial in another. Possible mechanisms underlying this divergence are discussed.

Immunocytochemical characterisation of the immune reaction in the central nervous system in multiple sclerosis. Possible role for microglia in lesion growth

As there is evidence that in multiple sclerosis T-cell activation occurs in the central nervous system rather than outside, the inflammatory lesion may be extended through antigen presentation by cells at the edge of the plaque. In this study we present an immunocytochemical report on CNS tissue from an active case of MS, with an analysis of the distribution of CD4 and CD8 binding T cells and the expression of class I and II MHC determinants in plaques and white matter. Perivascular cuffs of early lesions, as judged by hypercellularity and minimal demyelination, contained activated T (Tac+) cells, which reacted with an anti-IL-2 monoclonal antibody. Thus sufficient T-cell growth factor would appear to be present to fuel the immune reaction in a growing lesion. The preponderance of T cells of the cytotoxic/suppressor (CD8) phenotype in the CNS parenchyma was found in conjunction with widespread staining of class I MHC antigen, a prerequisite for activity of cytotoxic T cells. Potential antigen presenting cells were demonstrated in MS plaques with a monoclonal antibody against the cytoplasmic, invariant chain of class II MHC. Macrophages and astrocytes, contributed to the staining in the hypercellular plaque border while the distribution of class II+ microglia in white matter suggest they may also be of importance in local antigen presentation.

Reversible and irreversible neuronal damage caused by excitatory amino acid analogues in rat cerebellar slices

Slice preparations of the developing rat cerebellum were used to investigate the light and electron microscopic correlates of reversible and irreversible neuronal injury caused by the neurotoxic excitatory amino acid receptor agonists, kainate and N-methyl-D-aspartate. The slices were examined after various periods of exposure to the agonists (up to 30 min) with or without a 90 min recovery period in agonist-free medium. N-Methyl-D-aspartate (100 microM) caused necrosis of deep nuclear neurons and differentiating granule cells, the exposure times necessary to induce non-recoverable damage (leading to necrosis), being, respectively, 10 min and 20-30 min. Exposure periods of only 2-4 min with kainate (100 microM) were needed for Golgi cells to subsequently undergo necrosis. Other cell types (Purkinje, granule and deep nuclear neurons) were altered histologically by kainate but most recovered fully from 30 min exposures. Before the recovery period, the worst affected of these cells (deep nuclear neurons) displayed increased cytoplasmic and nuclear electron density and microvacuolation due to swelling of Golgi cisterns but little or no chromatin clumping or mitochondrial expansion. The neurons which were injured irreversibly by the agonists within 30 min displayed, near the time of lethal injury, increased cytoplasmic and nuclear electron lucency, marked focal aggregation of chromatin and swelling of Golgi apparatus. Mitochondrial swelling did not appear to precede lethal injury and even after exposure times sufficient, or more than sufficient, to lead to necrosis, large numbers of mitochondria remained in a condensed configuration. The significance of the histological changes is discussed and they are compared with those occurring in other pathological conditions. The time scales required for the receptor agonists to induce irreversible cellular lesions would be consistent with this being a process which is responsible for acute neuronal necrosis in the brain.

Monoclonal antibody to macrophages (EMB/11) labels macrophages and microglial cells in human brain

Normal and diseased human central nervous system (CNS) tissues were studied immunohistochemically by a monoclonal antibody to human macrophages (EBM/11), antisera to glial fibrillary acidic protein (anti-GFAP), and alpha-1-antichymotrypsin (alpha 1-ACT). EBM/11 reacted with brain macrophages located mainly around blood vessels in normal brain; it also reacted with resting microglia in normal brain and with numerous reactive microglia and macrophages in brain tumours and inflammatory lesions. Microglia did not react with anti-GFAP or alpha 1-ACT. An EBM/11 positive phenotype, therefore, is shared by microglia and macrophages and suggests that microglial cells form a specialised part of the mononuclear phagocyte system.

Immunohistochemical analysis of murine mononuclear phagocytes that express class II major histocompatibility antigens

Expression of class II major histocompatibility antigen(s) was analyzed in mouse tissue sections using an immunocytochemical technique. Parallel sections were stained for the macrophage-specific antigen F4/80. MHCII antigen(s) were absent from the majority of F4/80+ cells in liver, bone marrow, splenic red pulp, and brain (microglia) but were present on intraepithelial, periepithelial, and free (e.g. alveolar) cells in gastrointestinal, urogenital, respiratory, and endocrine tissues. The staining pattern in such tissues was not distinguishable from that of F4/80. The results suggest that a major subpopulation of mononuclear phagocytes express MHCII antigen(s) constitutively.

Expression of major histocompatibility complex antigens in neonate rat primary mixed glial cultures

Primary mixed glial cultures containing astrocytes, oligodendrocytes and macrophages have been cultured from cerebral hemispheres of neonate rats and examined by indirect immunofluorescence for the expression of class I and II RT1 major histocompatibility complex-coded antigens. None of these cells expressed detectable levels of either class I or II antigens except for the macrophages which were weakly class I positive. Treatment with lymphokine-containing supernatant from concanavalin A-activated splenic lymphocytes resulted in increased expression of class I antigens on all cells together with the appearance of class II RT1.B and RT1.D antigens on macrophages and a small proportion of type 1/protoplasmic astrocytes. The identity of the Ia antigens was confirmed by immunoprecipitation from lysates of surface-iodinated cells. The ability of lymphokine-treated mixed glial cultures to stimulate proliferation of allogeneic lymphocytes provides additional evidence of Ia induction. A possible role for these Ia+, putative antigen-presenting cells in delayed type hypersensitivity in the central nervous system is discussed.