Constitutive and visna virus induced expression of class I and II major histocompatibility complex antigens in the central nervous system of sheep and their role in the pathogenesis of visna lesions

Expression of major histocompatibility complex (MHC) antigens was studied in the brains of 10 healthy sheep 2 months to 5 years old and 13 sheep infected with visna virus by intracerebral inoculation and killed one and 6 months post infection (p.i.). In healthy sheep there was prominent expression of class I, mainly on endothelial cells but also detected on ependyma, choroid plexus and in the leptomeninges. Class II expression was sparse. It was observed on perivascular cells, in choroid plexus, leptomeninges and on microglial cells in the white matter. No definite increase with age in the constitutive expression of class I and II was observed, confirming that we are dealing with a true constitutive expression. In visna-infected sheep a considerable induction of MHC antigens on microglia was observed, which correlated with severity of lesions and was mainly found in or adjacent to inflammatory infiltrates of the white matter. Increase in class II antigen expression was detected in all sheep but class I only in sheep with the most severe lesions 6 months p.i., an indication of a higher threshold for induction of class I than class II antigens on microglia. Few cells expressed viral antigens, indicating that direct immune-mediated destruction of infected cells plays a minor role in evolution of lesions. Since the preferential induction of MHC antigens on microglia in the white matter correlated with the lesion pattern, activated microglia may play a considerable role in the pathogenesis of lesions.     

The heterogeneity in the immune response and efficiency of viral dissemination in brain infected with herpes simplex virus type 1 through peripheral or central route

Using immunohistochemistry on adjacent brain sections, we studied the correlation between the dissemination of the virus, the inflammatory responses and the expression of major histocompatibility complex (MHC) proteins in rat brain infected with herpes simplex virus (HSV-1) F strain by either corneal scarification or intracerebral injection. Our results showed that the mortality of the corneally infected rats was much higher than that of the intracerebrally infected rats, due to a more extensive dissemination of the virus in the brain, particularly in the brain stem. The inflammatory responses were similar in brains infected through either route, as demonstrated by the expression of MHC I/II antigens on infiltrating lymphocytes, leukocytes and macrophage/microglia cells. While there was strong immunoreactivity for HSV-1 antigens in the cerebral cortex, the infiltrates were only located in subcortical areas, especially the hippocampus. Therefore, the distribution of these immune cells did not always overlap with the regions of viral infection. These results suggest that HSV-1 disseminate more efficiently from the peripheral to the central nervous system (CNS) than from CNS to CNS, which is independent of the immune responses, and that the cerebral cortex may immunologically respond to HSV-1 infection differently from other brain regions. Received: 16 June 1998 / Revised: 22 October 1998 / Accepted: 11 November 1998     

The expression of major histocompatibility complex (MHC) class I antigens in the brain differs markedly in acute and persistent infections with lymphocytic choriomeningitis virus (LCMV)

Intracranial inoculation of immunocompetent mice with lymphocytic choriomeningitis virus (LCMV) induces a fatal neurologic illness. In this disease a marked increase in MHC class I expression was found, closely associated with viral antigens and inflammatory infiltrates, in meninges, choroid plexus and ventricular ependyma but not within the brain parenchyma. Immunosuppression prevented MHC induction. Mice inoculated at birth had persistent infections, with LCMV antigens found primarily in neurons, but no inflammatory cells or focal increase in MHC class I. Failure of infected neurons to express MHC class I allows them to escape destruction by cytotoxic T cells (CTL) but may increase their susceptibility to be persistently infected by non-lytic viruses.     

Microglia in the immune surveillance of the brain: Human microglia constitutively express HLA-DR molecules

The degree of MHC class II expression in histologically normal human brain biopsy or autopsy tissue is still controversial. According to the generally held view MHC class II expression is rather low in the normal brain with the exception of the white matter. In the present study, HLA-DR expression was examined immunocytochemically in different brain areas obtained from three autopsy cases with short post-mortem times (i.e. 6 h). Based on standard histological evaluation, the brain areas studied appeared as histologically normal tissue. In all brain areas there was a strong constitutive HLA-DR expression on ramified microglia. The number of HLA-DR-immunoreactive microglia was strongest in the white matter (the corpus callosum and the capsula interna for example). The border zone between white matter and grey matter, however, revealed a sharp contrast between a high density of HLA-DR-immunoreactive microglia in the white matter and a rather low number in the grey matter. In the grey matter, HLA-DR-immunoreactive microglia were much less frequent than in the white matter and more pronounced on perivascular cells. The staining and distribution pattern of HLA-DR-immunoreactive microglia was confirmed by immunocytochemistry with a panel of different anti-HLA-DR monoclonal antibodies as well as by quantitative analysis of the immunostaining. Unlike the HLA-DR immunoreactivity, HLA-ABC immunoreactivity (detecting MHC class I antigens) was confined to endothelia and not observed on microglia. In the choroid plexus stromal macrophages expressed both class I and II antigens (i.e. at a location which could provide the peripheral immune system access to CNS antigens). Constitutive HLA-DR expression by microglia qualifies them as the main resident antigen-presenting cell of the brain. The pronounced overall HLA-DR expression by resting microglia questions a central dogma of the brain as an immune-privileged site and further points to the key role of the microglia in brain immune surveillance.     

Flavivirus infection up-regulates the expression of class I and class II major histocompatibility antigens on and enhances T cell recognition of astrocytes in vitro

West Nile virus (WNV) infection of astrocytes can up-regulate their expression of both class I and class II major histocompatibility complex (MHC) antigens as determined by flow cytometry with monoclonal antibodies specific for class I and class II MHC antigens. The up-regulation of class I MHC antigen expression could be partly caused by interferon secreted after WNV infection because the synthetic interferon inducer polyinosinic-polycytidylic acid (poly I:C) has similar effects. In contrast the up-regulation of class II MHC antigen expression was not induced by poly I:C. The increased MHC antigen expression by WNV infection had significant effects on T cell recognition. Thus, WNV and influenza virus A/WSN double-infected astrocytes but not astrocytes infected by A/WSN alone were lysed by influenza virus-immune cytotoxic T cells. Similarly, WNV-infected astrocytes were better stimulators than normal astrocytes for a class II MHC-reactive T cell line, both in terms of T cell proliferation and interleukin release.     

Expression of major histocompatibility complex antigens in the brains of patients with progressive multifocal leukoencephalopathy.

Progressive multifocal leukoencephalopathy (PML) is caused by JC virus (JCV) infection of the central nervous system (CNS) in immunosuppressed patients. The immunopathogenesis of this chronic encephalitis is unknown. Because major histocompatibility (MHC) class I and class II antigens are important in modulating the immune response and viral clearance, we examined the tissue expression of MHC molecules in relation to CNS damage and presence of virus. By immunocytochemical staining, both MHC class I and class II antigens were expressed at high levels within PML lesions. Beta-2 microglobulin (beta-2m) was present on endothelial cells and JCV-infected oligodendroglia within the lesions. Also, many astrocytes with bizarre morphology expressed MHC class I antigens. In histologically normal regions of PML brains expression of beta-2m was noted only on endothelial cells. Expression of MHC class II also was focused within demyelinating lesions and was restricted to macrophages/microglia and occasional endothelial cells. When compared to other viral encephalitides (e.g. human immunodeficiency virus) these findings suggest that intra-CNS immune response to JCV is appropriate for antigenic presentation; however, the absence of responsive systemic T-cells may lead to chronic viral infection with progressive neuropathology.     

Major histocompatibility complex antigen expression on rat microglia following epidural kainic acid lesions

Vigorous expression of major histocompatibility complex (MHC) class I and class I surface glycoproteins was observed on reactive microglia but not on astrocytes in the rat brain following lesions induced by epidural kainic acid (KA) on the cerebral cortex. The monoclonal antibodies used were OX18 against MHC class I, OX6 against MHC class II, OX1 against leukocyte common antigen (LCA), and W3/13 against pan-T lymphocytes. Astrocytes were marked by antibodies to glial fibrillary acidic protein (GFA) and S100b protein. The lesion differentially affected four zones: the central area of the lesion where most cells died; the peripheral zone surrounding the lesion where selective damage occurred; projection tracts from the lesioned area; and terminal fields of damaged neurons. In nonlesioned animals, class I expression was confined to vascular endothelial cells and some small glial cells. Following KA treatment, class I-positive round cells appeared in the central zone at day 1, peaked about day 5, and then slowly declined. In the peripheral zone, class I-positive microglia were present fron day 2 on. They demonstrated classical morphology for such cells, and in some cases arranged themselves in pyramidal profiles surrounding neurons. Reactive microglia were also class I positive along tracts of damaged neurons and in the terminal areas. The reaction was reduced to control levels 16-20 weeks after lesioning although some vascular endothelial cells and a few round cells still stained positively in the cystic area, which was the remnant of the central zone. Class II antigen expression first appeared in the form of round cells in the central zone of the lesion on day 1. These peaked at 5-7 days and declined thereafter. In the peripheral zone on day 5, some positive round or ameboid cells were found intermingled with typical reactive microglia. This reaction peaked at about 1-2 weeks and decreased thereafter. Class II-positive microglia appeared in fiber tracts and in the terminal areas on day 5, peaked after 2-3 weeks, and declined thereafter. Double immunostaining for class I and II antigens showed that there were significantly fewer class II- than class I-positive cells, but the morphology of the two groups was similar. No astrocytes stained positively for either group I or group II antigen. In both the primary and secondary lesioned areas, LCA staining was observed on the surface of reactive microglia. In the primary lesions there were also LCA-positive round cells in the central zone, but these were rare in the peripheral zone and the secondary lesioned areas.(ABSTRACT TRUNCATED AT 400 WORDS)     

MHC class II-positive perivascular microglial cells mediate resistance to Cryptococcus neoformans brain infection

Acquired resistance to the CNS pathogen Cryptococcus neoformans is mediated by CD4(+) T lymphocytes primed by exposure to antigen in the context of major histocompatibility class II (MHC II) molecules. In mouse brain, parenchymal and perivascular microglial cells may express interferon-gamma (IFN-gamma)-inducible MHC class II marker and thus interact with CD4(+) T cells. Primed effector T cells are retained in the infected CNS if antigen is encountered in proper MHC context and may deliver signals that potentiate microglia to enhanced fungistasis. Vaccinated C57BL6/J mice resist an ordinarily lethal C. neoformans rechallenge, but identically treated congenic Abeta(o/o) mice (MHC class II-deficient; CD4(+) T-cell-deficient) do not. Nor can Abeta(o/o) mice be adoptively immunized by infusion of lymphocytes from vaccinated C57BL6/J donors, as are severe combined immunodeficient (SCID) mice (MHC class II-intact, lymphocyte-deficient). Chimeric (C57BL/6J:Abeta(o/o)) mice with class II expression likely on perivascular microglia only were, like SCID mice, capable of adoptive immunization against C. neoformans brain infection. To the contrary, chimeric mice with class II expression likely only on parenchymal microglia were not capable of effective adoptive immunization against C. neoformans brain infection. Therefore, in order to mediate resistance to infection, primed CD4(+) T cells must interact with the replenishable perivascular microglial subset that lies in close proximity to cerebral vasculature. Although T cells may supply help in the form of inflammatory cytokines to parenchymal microglia, expression of class II on these cells appears unnecessary for antifungal activity.     

Distribution and Temporal Regulation of the Immune Response in the Rat Brain to Intracerebroventricular Injection of Interferon-γ

The response to intracerebroventricular administration of interferon (IFN)-γ was examined in the adult Wistar rat brain: major histocompatibility complex (MHC) antigens class I and II, CD8 and CD4 antigens, and the macrophage/microglia antigen OX42 were analyzed in respect to saline-injected cases over 1 week. The glial cell type expressing MHC antigens was characterized with double labeling. IFN-γ was thus found to induce MHC class I and II expression in microglia, identified by tomato lectin histochemistry, and not in GFAP-immunostained astrocytes. MHC antigen-expressing microglia was detected in the periventricular parenchyma, several fields of the cerebral cortex, cerebellum, major fiber tracts, and brainstem superficial parenchyma. Different gradients of density and staining intensity of the MHC-immunopositive elements were observed in these regions, in which MHC class I antigens persisted up to 1 week, when MHC class II induction had declined. Quantitative analysis pointed out the proliferation of OX42-immunoreactive cells in periventricular and basal brain regions. CD8+ T cells were observed in periventricular regions, basal forebrain, and fiber tracts 3 days after IFN-γ injection and their density markedly increased by 7 days. CD4+ T cells were also seen and they were fewer than CD8+ ones. However, numerous CD4+ microglial cells were observed in periventricular and subpial regions, especially 1 week after IFN-γ injection. Our data indicate that this proinflammatory cytokine mediatesin vivomicroglia activation and T cell infiltration in the brain and that the cells involved in this immune response display a regional selectivity and a different temporal regulation of antigen expression.     

Influenza a virus infection of primary cultured cells from rat fetal brain

We previously reported that the neurovirulent influenza A virus strain, AIWSN/33 has strong affinity for the substantia nigra (SN) in mouse brain. In this study, we used a neuron-glia co-culture system in order to observe the cellular responses to viral infection. Co-cultured cells were infected with the A/WSN/33 strain and were examined immunohistochemically. Viral antigens were strictly confined to the neuronal cell bodies and their neurites. More than 90% of tyrosine hydroxylase (TH)-positive neurons in the SN were also positive to anti-WSN antibody. There was no increase in class I major histocompatibility complex (MHC) expression in virus antigen positive cells. Thus, we can conclude that the virus preferentially infects neurons, mainly TH-positive neurons in the SN. An antigen presenting response mediated by class I MHC was not observed in infected neurons.     

Differential expression of class I and class II major histocompatibility complex antigen in early postnatal rats

Cells expressing major histocompatibility complex (MHC) antigens are rarely found in normal mature brains, but cells resembling microglia can be induced to express these antigens following the onset of neural degeneration. In young rats, these cells show spontaneous expression of class I MHC antigens, which is further enhanced in the superior colliculus by the degeneration resulting from eye removal. By contrast, class II MHC antigen expression does not occur spontaneously and can only be induced by eye removal when the lesion is performed after the first postnatal week, when the optic tract begins to myelinate. We suggest that different signals are responsible for induction of class I and of class II MHC antigen expression.     

Peripheral nerve lesion produces increased levels of major histocompatibility complex antigens in the central nervous system

Proliferation of central nervous system (CNS) glia in response to peripheral nerve injury occurs without apparent participation of cells of the immune system. It is shown here that following transection of the rat facial nerve there is strongly elevated expression of class I, and to a lesser extent, class II antigens of the major histocompatibility complex (MHC) in the facial nucleus. It is demonstrated by double-immunofluorescence studies that the cells responsible for increased levels of MHC class I antigens are endogenous brain microglia. These findings emphasize the thought that microglia are immunocompetent cells, but, at the same time, raise the possibility for a non-immunological function of MHC antigens under conditions of neural regeneration.     

Microglial cell activation in demyelinating canine distemper lesions

Microglia cells are the principal immune effector elements of the brain responding to any pathological event. To elucidate the possible role of microglia in initial non-inflammatory demyelination in canine distemper virus (CDV) infection, microglia from experimentally CDV infected dogs were isolated ex vivo by density gradient centrifugation and characterized immunophenotypically and functionally using flow cytometry. Results from dogs with demyelinating lesions were compared to results from recovered dogs and two healthy controls. CDV antigen could be detected in microglia of dogs with histopathologically confirmed demyelination. Microglia of these dogs showed marked upregulation of the surface molecules CD18, CD11b, CD11c, CD1c, MHC class I and MHC class II and a tendency for increased expression intensity of ICAM-1 (CD54), B7-1 (CD80), B7-2 (CD86), whereas no increased expression was found for CD44 and CD45. Functionally, microglia exhibited distinctly enhanced phagocytosis and generation of reactive oxygen species (ROS). It was concluded that in CDV infection, there is a clear association between microglial activation and demyelination. This strongly suggests that microglia contribute to acute myelin destruction in distemper.     

Optic nerve degeneration induces the expression of MHC antigens in the rat visual system

The brain has long been considered to be an immunologically privileged site. However, privilege is not absolute, as has been shown by the inability of foreign tissue grafts to survive indefinitely in the brain. The rejection of this tissue is accompanied by the upregulation of major histocompatibility complex (MHC) antigen expression. Therefore it is essential to define conditions that influence the expression of these antigens in the brain, especially since such a definition may further the understanding of disease processes that lead to the autoimmune destruction of the central nervous system. Here we show that both MHC class l and class II antigens are expressed within 1 or 2 days of eye removal by cells showing the morphological characteristics of microglia. Expression is seen along the optic pathway and within the brainstem centers to which optic axons project. In the early stages of the reaction, MHC class I antigen expression is seen throughout the optic pathway, including the terminal distribution areas of the subcortical visual centers, while MHC cells class II are localised mainly to degenerating myelinated fiber systems. These changes are not accompanied by any alteration in the integrity ofthe blood-brain barrier. During the second week postlesion, class l positive cells are found beyond the confines of the degenerating pathways, while class II positive cells are seen within regions such as the stratum griseum superficiale of the superior colliculus, where few myelinated axons are present. There is subsequent diminution of MHC positive cells, but a small number of cells are still seen 60 days post-lesion. Focal lesions within the eye show that at early survival times, while class l MHC positive cells are distributed throughout the nerve, class II positive cells are largely absent from the unmyelinated segment of the nerve. Retrograde changes in the retina after nerve section are accompanied only by MHC class l antigen expression. These observations show that neural degeneration is accompanied by a rigid sequence of events involving expression of MHC antigens by microglia. If foreign antigens were present in the brain while these events were taking place, it is possible that such antigens would be recognised and destroyed by the host immune system. © 1993 Wiley-Liss, Inc.     

Effects of dexamethasone on microglial activation in vivo: selective downregulation of major histocompatibility complex class II expression in regenerating facial nucleus

Following axotomy of the facial nerve microglial cells in the facial nucleus become activated, proliferate, and newly express class I and class II major histocompatibility complex (MHC) antigens. Dexamethasone treatment, starting 2 days prior to axotomy at 1 mg/kg/day, selectively inhibited axotomy-induced MHC class II expression on microglial and perivascular cells. In contrast, MHC class I expression was not significantly affected, nor was the expression of other microglial activation markers and the light microscopic morphology of activated microglia. A recently suggested inducer of MHC expression in rat nervous tissue, neuronal gamma interferon-like immunoreactive material, was also unaffected, as was glial fibrillary acidic protein immunoreactivity as a marker for concomitant astroglial activation. The differential effects of the drug suggest the presence of distinct regulatory pathways for different aspects of microglial activation. Inhibition of class II expression on activated microglia might be one mechanism how glucocorticoids act in the suppression of neuroinflammatory disease.     

Distinct regulation of MHC molecule expression on astrocytes and microglia during viral encephalomyelitis

The potential interplay of glial cells with T cells during viral induced inflammation was assessed by comparing major histocompatibility complex molecule upregulation and retention on astrocytes and microglia. Transgenic mice expressing green fluorescent protein under control of the astrocyte-specific glial fibrillary acidic protein promoter were infected with a neurotropic coronavirus to facilitate phenotypic characterization of astrocytes and microglia using flow cytometry. Astrocytes in the adult central nervous system up-regulated class I surface expression, albeit delayed compared with microglia. Class II was barely detectable on astrocytes, in contrast to potent up-regulation on microglia. Maximal MHC expression in both glial cell types correlated with IFN-gamma levels and lymphocyte accumulation. Despite a decline of IFN-gamma concomitant to virus clearance, MHC molecule expression on glia was sustained. These data demonstrate distinct regulation of both class I and class II expression by microglia and astrocytes in vivo following viral induced inflammation. Furthermore, prolonged MHC expression subsequent to viral clearance implies a potential for ongoing presentation.     

An immunoelectron microscopical study of the expression of class II major histocompatibility complex during chronic relapsing experimental allergic encephalomyelitis in Biozzi AB/H mice

Immunoelectron microscopical techniques have been used to study class II major histocompatibility complex (MHC) expression by cells in the spinal cords of Biozzi AB/H mice with chronic relapsing experimental allergic encephalomyelitis. Throughout the course of disease both astrocytes and endothelia failed to express significant levels of class II MHC antigens. The major central nervous system resident cell types found to express class II MHC antigens were the perivascular microglia, with infiltrating macrophages and some lymphocytes being strongly positive.     

Rat ependyma and microglia cells express class II MHC antigens after intravenous infusion of recombinant gamma interferon

Recombinant rat gamma-interferon was administered to Lewis rats by continuous intravenous infusion. After a 3-day administration period, at various dosages, a constant pattern of class II major histocompatibility complex (MHC) antigen induction was found in the brains and cerebella. Immunohistological double staining for class II antigens and glial fibrillary acidic protein showed that the majority of newly induced cells were microglia. The endothelium of large blood vessels and ependymal cells also expressed class II antigens. These findings demonstrate that systemically raised interferon levels can affect MHC antigen expression in the brain. Astrocytes are obviously not the primary cell type to acquire class II reactivity, and thus potential antigen-presenting capacity, in this situation.     

Human immunodeficiency virus infection in microglia: correlation between cells infected in the brain and cells cultured from infectious brain tissue.

In acquired immunodeficiency syndrome, the lesions of the central nervous system in association with the human immunodeficiency virus are thought to be related to an infection of microglia, although no studies are available in which cultured and physiological characteristics of microglia cells infected in vivo have been examined. In this report, we used brain tissue from a child dying of human immunodeficiency virus infection and show that microglia cells were the main cell population being infected. Moreover, isolated macrophage-like cells from fresh brain material revealed a close resemblance to peripheral blood macrophages in their content of surface and intracellular antigens. No virus particles or viral antigens were produced by these cells during the first week of cultivation. Productive infection was readily apparent, however, by day 30. This finding illustrates the slow nature of the virus life cycle in these cells and the minimal cytopathology that accompanied the infection.