Evidence for a regulatory role of alpha 4-integrins in the maturation of eosinophils generated from the bone marrow in the presence of dexamethasone.

BACKGROUND: Although eosinophils co-express multiple integrin receptors, the contributions of integrins to eosinophil development have not been explored. We previously described extensive aggregation and cytological immaturity in eosinophils developing in bone-marrow (BM) cultures exposed to dexamethasone. Here we examined the relationship of alpha 4 integrins with these effects of dexamethasone. OBJECTIVES: We evaluated: (a) the effects of exposure to dexamethasone in BM culture on eosinophil expression of alpha 4 integrin receptors and ligands; (b) the contribution of alpha 4 integrins to eosinophil aggregation and maturation. METHODS: Cultures were established with IL-5 (alone or with dexamethasone) for up to 7 days, and eosinophil production, alpha 4 integrin receptor/ligand expression, aggregation and morphology were evaluated before and after targeting alpha 4 integrin-dependent adhesions. Because prostaglandin E2 (PGE2) modifies the effects of dexamethasone on eosinophilopoiesis, PGE2 effects on alpha 4 integrin expression and function were also evaluated. RESULTS: Dexamethasone increased the yield of eosinophils up to day 7. The frequency of eosinophils expressing alpha 4, beta1 and beta 7 integrin receptors at day 7 was also increased by dexamethasone. Eosinophils also expressed the alpha 4 beta 1 ligand, VCAM-1. Dexamethasone increased the expression of alpha 4 integrin and VCAM-1 in aggregates containing eosinophils as early as day 3. PGE2, added up to day 3, modified the effects of dexamethasone to suppress the expression of alpha 4 integrin, decrease aggregation and promote cytological maturation of eosinophils recovered at day 7. Dissociation of immature eosinophils from clusters present at day 3 by reagents targeting alpha 4 or beta1 integrins or VCAM-1 also induced cytological maturation. The concordant effects of targeting alpha 4 integrins with drugs and antibodies support a relationship between alpha 4-mediated aggregation and maturational arrest. CONCLUSIONS: These observations support a novel role for alpha 4 integrin receptors and ligands in eosinophilopoiesis. In addition, increased alpha 4 expression following glucocorticoid exposure may contribute to the retention and accumulation of eosinophils in haemopoietic tissue.

CC-chemokine receptors: a potential therapeutic target for Trypanosoma cruzi-elicited myocarditis.

The comprehension of the pathogenesis of Trypanosoma cruzi-elicited myocarditis is crucial to delineate new therapeutic strategies aiming to ameliorate the inflammation that leads to heart dysfunction, without hampering parasite control. The augmented expression of CCL5/RANTES and CCL3/MIP-1alpha, and their receptor CCR5, in the heart of T. cruzi-infected mice suggests a role for CC-chemokines and their receptors in the pathogenesis of T. cruzi-elicited myocarditis. Herein, we discuss our recent results using a CC-chemokine receptor inhibitor (Met-RANTES), showing the participation of CC-chemokines in T. cruzi infection and unraveling CC-chemokine receptors as an attractive therapeutic target for further evaluation in Chagas disease.

CC-chemokine receptors: a potential therapeutic target for Trypanosoma cruzi-elicited myocarditis

The comprehension of the pathogenesis of Trypanosoma cruzi-elicited myocarditis is crucial to delineate new therapeutic strategies aiming to ameliorate the inflammation that leads to heart dysfunction, without hampering parasite control. The augmented expression of CCL5/RANTES and CCL3/MIP-1alpha, and their receptor CCR5, in the heart of T. cruzi-infected mice suggests a role for CC-chemokines and their receptors in the pathogenesis of T. cruzi-elicited myocarditis. Herein, we discuss our recent results using a CC-chemokine receptor inhibitor (Met-RANTES), showing the participation of CC-chemokines in T. cruzi infection and unraveling CC-chemokine receptors as an attractive therapeutic target for further evaluation in Chagas disease.

Trypanosoma cruzi infection: a continuous invader-host cell cross talk with participation of extracellular matrix and adhesion and chemoattractant molecules

Several lines of evidence have shown that Trypanosoma cruzi interacts with host extracellular matrix (ECM) components producing breakdown products that play an important role in parasite mobilization and infectivity. Parasite-released antigens also modulate ECM expression that could participate in cell-cell and/or cell-parasite interactions. Increased expression of ECM components has been described in the cardiac tissue of chronic chagasic patients and diverse target tissues including heart, thymus, central nervous system and skeletal muscle of experimentally T. cruzi-infected mice. ECM components may adsorb parasite antigens and cytokines that could contribute to the establishment and perpetuation of inflammation. Furthermore, T. cruzi-infected mammalian cells produce cytokines and chemokines that not only participate in the control of parasitism but also contribute to the establishment of chronic inflammatory lesions in several target tissues and most frequently lead to severe myocarditis. T. cruzi-driven cytokines and chemokines may also modulate VCAM-1 and ICAM-1 adhesion molecules on endothelial cells of target tissues and play a key role in cell recruitment, especially of activated VLA-4+LFA-1+CD8+ T lymphocytes, resulting in a predominance of this cell population in the inflamed heart, central nervous system and skeletal muscle. The VLA-4+-invading cells are surrounded by a fine network of fibronectin that could contribute to cell anchorage, activation and effector functions. Since persistent "danger signals" triggered by the parasite and its antigens are required for the establishment of inflammation and ECM alterations, therapeutic interventions that control parasitism and selectively modulate cell migration improve ECM abnormalities, paving the way for the development of new therapeutic strategies improving the prognosis of T. cruzi-infected individuals

Trypanosoma cruzi infection: a continuous invader-host cell cross talk with participation of extracellular matrix and adhesion and chemoattractant molecules.

Several lines of evidence have shown that Trypanosoma cruzi interacts with host extracellular matrix (ECM) components producing breakdown products that play an important role in parasite mobilization and infectivity. Parasite-released antigens also modulate ECM expression that could participate in cell-cell and/or cell-parasite interactions. Increased expression of ECM components has been described in the cardiac tissue of chronic chagasic patients and diverse target tissues including heart, thymus, central nervous system and skeletal muscle of experimentally T. cruzi-infected mice. ECM components may adsorb parasite antigens and cytokines that could contribute to the establishment and perpetuation of inflammation. Furthermore, T. cruzi-infected mammalian cells produce cytokines and chemokines that not only participate in the control of parasitism but also contribute to the establishment of chronic inflammatory lesions in several target tissues and most frequently lead to severe myocarditis. T. cruzi-driven cytokines and chemokines may also modulate VCAM-1 and ICAM-1 adhesion molecules on endothelial cells of target tissues and play a key role in cell recruitment, especially of activated VLA-4+LFA-1+CD8+ T lymphocytes, resulting in a predominance of this cell population in the inflamed heart, central nervous system and skeletal muscle. The VLA-4+-invading cells are surrounded by a fine network of fibronectin that could contribute to cell anchorage, activation and effector functions. Since persistent "danger signals" triggered by the parasite and its antigens are required for the establishment of inflammation and ECM alterations, therapeutic interventions that control parasitism and selectively modulate cell migration improve ECM abnormalities, paving the way for the development of new therapeutic strategies improving the prognosis of T. cruzi-infected individuals.

Effect of Trypanosoma cruzi released antigens binding to non-infected cells on anti-parasite antibody recognition and expression of extracellular matrix components.

It has been proposed that antigens released by Trypanosoma cruzi sensitize vertebrate cells leading to their destruction by the immune response raised against the parasite. Here, we characterized antigens released by trypomastigotes of T. cruzi that bind to non-infected cells and investigated biological consequences of this adsorption. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) analysis of antigens released by [(35)S]-methionine-labeled parasites revealed the presence of polypeptides mainly ranging from 85 to 170 kDa that were specifically recognized by sera from chronically T. cruzi infected rabbits. Polypeptides of 85-110 and 160-170 kDa bound to non-infected epithelial, fibroblast and muscle mammalian cell lines, which thus became targets for anti-T. cruzi antibody binding. Cysteine-proteinase, but not trans-sialidase, was detected among the cell-bound antigens, and purified cysteine-proteinase was adsorbed to non-infected cells. Immunoelectron microscopic studies showed that parasite antigens were mainly released as membrane vesicles that adhered to membrane microvilli and were internalized by mammalian cells. We provide evidence that adsorption of parasite antigens induced an increase in expression of extracellular matrix (ECM) components (fibronectin, laminin and type I collagen) by sensitized cells. Thus, our data reinforce the idea that in vivo T. cruzi released antigens might be involved in the establishment of inflammation, sensitizing non-infected host cells and triggering an immune response against parasite antigens. Further, our data showed that antigen sensitization modulates biological cell functions as ECM expression that could mediate cell-cell or parasite-host cell interactions, contributing to the establishment of inflammation.

Pivotal role of interleukin-12 and interferon-gamma axis in controlling tissue parasitism and inflammation in the heart and central nervous system during Trypanosoma cruzi infection.

The role of cytokines in the control of tissue parasitism and pathogenesis of experimental Chagas' disease was investigated. Wild-type and different cytokine as well as inducible nitric oxide synthase (iNOS) knockout mice were infected with the Colombian strain of Trypanosoma cruzi, and the kinetics of tissue parasitism, inflammatory reaction, parasitemia, and mortality were determined. We demonstrate the pivotal role of the interleukin (IL)-12/interferon (IFN)-gamma/iNOS axis and the antagonistic effect of IL-4 in controlling heart tissue parasitism, inflammation, and host resistance to acute infection with T. cruzi. Further, the heart and central nervous system were shown the main sites of reactivation of T. cruzi infection in mice lacking functional genes for IFN-gamma and IL-12, respectively. Our results also show that in contrast to IFN-gamma knockout (KO) mice, splenocytes from IL-12 KO mice infected with T. cruzi produced low levels of IFN-gamma upon stimulation with antigen. Consistently, high levels of anti-T. cruzi IgG2a antibodies were detected in the sera from IL-12 KO, but not from IFN-gamma KO mice, infected with the Colombian strain of T. cruzi. Thus, our results suggest that the level of IFN-gamma deficiency is a major determinant of the site of reactivation of T. cruzi infection in immunocompromised host.

Prevalence of CD8(+)alpha beta T cells in Trypanosoma cruzi-elicited myocarditis is associated with acquisition of CD62L(Low)LFA-1(High)VLA-4(High) activation phenotype and expression of IFN-gamma-inducible adhesion and chemoattractant molecules.

The determinants of the prevalence of CD8(+) T cells in the inflamed myocardium of Trypanosoma cruzi-infected patients and experimental animals are undefined. Using C3H/He mice infected with the Colombiana strain of T. cruzi, we found that the distribution of CD4(+)/CD8(-) and CD4(-)/CD8(+) T cells in the myocardium mirrors the frequency of cells expressing the CD62L(Low)LFA-1(High)VLA-4(High) activation phenotype among CD4(+)/CD8(-) and CD4(-)/CD8(+ )peripheral blood T cells. Consistently, vascular cell adhesion molecule-1-positive endothelial cells and a fine fibronectin network surrounding VLA-4(+) mononuclear cells were found in the inflamed myocardium. Further, interferon gamma (IFN-gamma) and IFN-gamma-induced chemokines (RANTES, MIG and CRG-2/IP-10), as well as JE/MCP-1 and MIP1-alpha, were found to be the dominant cytokines expressed in situ during acute and chronic myocarditis elicited by T. cruzi. In contrast, interleukin 4 mRNA was only detected during the chronic phase. Altogether, the results indicate that the distribution of T-cell subsets in the myocardium of T. cruzi-infected mice reflects the particular profile of adhesion molecules acquired by most peripheral CD8(+) T lymphocytes and point to the possibility that multiple IFN-gamma-inducible molecules present in the inflamed tissue contribute to the establishment and maintenance of T. cruzi-induced myocarditis.

Modulation of chemokine production and inflammatory responses in interferon-gamma- and tumor necrosis factor-R1-deficient mice during Trypanosoma cruzi infection.

Infection with Trypanosoma cruzi causes a strong inflammatory reaction at the inoculation site and, later, in the myocardium. The present study investigates the role of cytokines as modulators of T. cruzi-induced chemokine expression in vivo and in vitro. In macrophage cultures, although the stimulation with interferon (IFN)-gamma increases the expression of IP-10, it blocks KC expression. Tumor necrosis factor (TNF)-alpha, on the other hand, potentiates KC, IP-10, macrophage inflammatory protein-1alpha, and JE/monocyte chemotatic protein-1 expression. Interleukin-10 and transforming growth factor-beta inhibited almost all chemokines tested. The role of IFN-gamma and TNF-alpha in chemokine modulation during infection was investigated in T. cruzi-infected IFN-gamma-deficient (GKO) or TNF-R1/p55-deficient (p55-/-) mice. The expression of chemokines detected in the inoculation site correlated with the infiltrating cell type observed. Although GKO mice had a delayed and intense neutrophilic infiltrate correlating with the expression of KC and macrophage inflammatory protein-2, none of the above was observed in p55-/- mice. The detection of infiltrating T cells, Mig, and IP-10 in the myocardium was observed in wild-type and p55-/-, but not in GKO mice. Together, these results suggest that the regulatory roles of IFN-gamma and TNF-alpha on chemokine expression may play a crucial role in the modulation of the inflammatory response during T. cruzi infection and mediate resistance to infection.

Kinetics of cytokine gene expression in experimental chagasic cardiomyopathy: tissue parasitism and endogenous IFN-gamma as important determinants of chemokine mRNA expression during infection with Trypanosoma cruzi.

We investigated the kinetics of parasite replication, leukocyte migration, and cytokine/chemokine mRNA expression in the heart tissue from animals infected with the Colombiana strain of Trypanosoma cruzi. Cardiac tissue parasitism was noticeable at 15 days, peaked around 30 days and was dramatically reduced at 120 days postinfection (p.i.). Kinetic studies showed that the inflammatory infiltrate was dominated by the presence of alphabetaT CD3(+ )CD4(+ )CD8(-), alphabetaT CD3(+ )CD4(-)CD8(+ )lymphocytes and macrophages. The mRNA expression of the monokines IL-1beta and IL-12(p40) was elevated at 15 days p.i. and controlled at later time points. In contrast, TNF-alpha mRNA was expressed throughout the infection. Interestingly, we found that at 15 and 30 days p.i. cytokine expression was dominated by the presence of IFN-gamma mRNA, whereas at 60 days or later time points the balance of type 1 and type 2 cytokines was switched in favor of IL-4 and IL-10 mRNAs. The chemokine mRNAs encoding JE, MIP-1alpha, MIP-1beta, KC, and MIP-2 were all mainly expressed at 15 and/or 30 days p.i. and diminished thereafter. In contrast, the expression of RANTES, MIG and IP-10 mRNAs was augmented at 15 days p.i. and persisted at high levels up to 120 days p.i. Taken together, our results indicate that regulation of IFN-gamma and chemokine expression, associated with decreased tissue parasitism, may be largely responsible for the control of inflammation and immunopathology observed in the cardiac tissue of animals infected with T. cruzi.

Trypanosoma cruzi: lack of T cell abnormalities in mice vaccinated with live trypomastigotes.

We have previously shown that inoculation of Trypanosoma cruzi clone-CL-14 generates efficient protective immunity against virulent T. cruzi and no infection or histopathology per se, indicating that it induces an immune state different from that exhibited by infected animals. To understand the basis of this difference, we screened CL-14-vaccinated mice for T cell abnormalities thought to be involved in the genesis of pathology. Lymphocytes from vaccinated mice present normal proliferative responses to concanavalin A; enhanced responses to T. cruzi antigens; do not show evidence of polyclonal activation (increased blast transformation and lymphocyte numbers) or changes in the density of CD4, CD8 and TCR-beta expression. Also, vaccinated mice display transient expansion of CD8+ lymphocytes expressing activated phenotypes (CD11a(hi) CD45RBlo CD62Llo). In view of the absence of pathology in vaccinated animals, the absence of immunosuppression and the restoration of a resting immune state reinforce the benign nature of this immunization.

Expression of extracellular matrix components and their receptors in the central nervous system during experimental Toxoplasma gondii and Trypanosoma cruzi infection.

Alterations in extracellular matrix (ECM) expression in the central nervous system (CNS) usually associated with inflammatory lesions have been described in several pathological situations including neuroblastoma and demyelinating diseases. The participation of fibronectin (FN) and its receptor, the VLA-4 molecule, in the migration of inflammatory cells into the CNS has been proposed. In Trypanosoma cruzi infection encephalitis occurs during the acute phase, whereas in Toxoplasma infection encephalitis is a chronic persisting process. In immunocompromised individuals such as AIDS patients. T. cruzi or T. gondii infection can lead to severe CNS damage. At the moment, there are no data available regarding the molecules involved in the entrance of inflammatory cells into the CNS during parasitic encephalitis. Herein, we characterized the expression of the ECM components FN and laminin (LN) and their receptors in the CNS of T. gondii- and T. cruzi-infected mice. An increased expression of FN and LN was detected in the meninges, leptomeninges, choroid plexus and basal lamina of blood vessels. A fine FN network was observed involving T. gondii-free and T. gondii-containing inflammatory infiltrates. Moreover, perivascular spaces presenting a FN-containing filamentous network filled with alpha 4+ and alpha 5+ cells were observed. Although an increased expression of LN was detected in the basal lamina of blood vessels, the CNS inflammatory cells were alpha 6-negative. Taken together, our results suggest that FN and its receptors VLA-4 and VLA-5 might be involved in the entrance, migration and retention of inflammatory cells into the CNS during parasitic infections.

Chagas' disease encephalitis: intense CD8+ lymphocytic infiltrate is restricted to the acute phase, but is not related to the presence of Trypanosoma cruzi antigens.

Central nervous system (CNS) damage can occur during Chagas' disease, especially in children and immunosuppressed patients. During the acute phase, amastigotes are rarely found, but inflammatory infiltrates are scattered throughout the CNS. Moreover, peripheral lymphocytes and antibodies recognizing neural components were described, suggesting the participation of the immune system in the genesis of neural lesions. Herein, we performed a histopathological study of Colombian-infected C3H/He mice, comparing the distribution of CNS-inflammatory infiltrates versus Trypanosoma cruzi antigens. Inflammatory infiltrates were observed during the acute phase, but did not correlate with the presence of detectable T. cruzi antigens. Infiltrates consisted mainly of CD8+ lymphocytes, although macrophages and a few CD4+ cells were observed. In the chronic stage of infection, although neuropathies were a common finding, only mild inflammatory infiltrates could be detected. Our results suggest that the presence of CNS inflammatory infiltrates is not directly related to the presence of parasite antigens and indicate that, different from chronic myocarditis, encephalitis resolves during the acute phase of Chagas' disease.

Expression of extracellular matrix components and their receptors in the central nervous system during experimental Toxoplasma gondii and Trypanosoma cruzi infection

Alterations in extracellular matrix (ECM) expression in the central nervous system (CNS) usually associated with inflammatory lesions have been described in several pathological situations including neuroblastoma and demyelinating diseases. The participation of fibronectin (FN) and its receptor, the VLA-4 molecule, in the migration of inflammatory cells into the CNS has been proposed. In Trypanosoma cruzi infection encephalitis occurs during the acute phase, whereas in Toxoplasma infection encephalitis is a chronic persisting process. In immunocompromised individuals such as AIDS patients, T. cruzi or T. gondii infection can lead to severe CNS damage. At the moment, there are no data available regarding the molecules involved in the entrance of inflammatory cells into the CNS during parasitic encephalitis. Herein, we characterized the expression of the ECM components FN and laminin (LN) and their receptors in the CNS of T. gondii- and T. cruzi-infected mice. An increased expression of FN and LN was detected in the meninges, leptomeninges, choroid plexus and basal lamina of blood vessels. A fine FN network was observed involving T. gondii-free and T. gondii-containing inflammatory infiltrates. Moreover, perivascular spaces presenting a FN-containing filamentous network filled with Alpha 4+ and Alpha 5+ cells were observed. Although an increased expression of LN was detected in the basal lamina of blood vessels, the CNS inflammatory cells were alpha 6-negative. Taken together, our results suggest that FN and its receptors VLA-4 and VLA-5 might be involved in the entrance, migration and retention of inflammatory cells into the CNS during parasitic infections

Trypanosoma cruzi: protective response of vaccinated mice is mediated by CD8+ cells, prevents signs of polyclonal T lymphocyte activation, and allows restoration of a resting immune state after challenge.

Currently, there is no vaccine available against Chagas' disease. Immune abnormalities induced by T. cruzi pose particular difficulties for vaccine development, since immunological memory must be able to overcome them to prevent spread of infection/sequelae. We have previously demonstrated that experimental vaccination with live CL-14 trypomastigotes does not induce polyclonal lymphocyte activation, immunosuppression, or pathology and efficiently immunizes against virulent T. cruzi. Herein we show that: (1) expansion of CD4+ and CD8+ subsets peaks 2 weeks after infective challenge in both challenged-vaccinated mice and infected controls, but the former exhibit a smaller increase in blastogenesis and in the numbers of activated CD11a(hi)CD4+ and CD11a(hi)CD8+ cells; (2) in long-term-vaccinated mice, expansion of activated subsets (CD62Llo/- and CD11a(hi)) is accelerated among CD8+ PBL 1 week after challenge; (3) challenged-vaccinated mice retract the CD8+-activated subset 5 weeks after challenge, different from infected controls; (4) protection conferred by CL-14 immunization can be adoptively transferred to naïve recipients with lymphocyte suspensions, and prior depletion of CD8+ (but not of CD4+) cells abolishes protective immunity. Our findings indicate that protective immunity generated by CL-14 immunization involves a transient CD8+ recall response and is capable of preventing the signs of polyclonal lymphocyte activation induced by virulent challenge.

Differential expression of fibroblast growth factor-2 and receptor by glial cells in experimental autoimmune encephalomyelitis (EAE)

To assess the expression pattern of basic fibroblast growth factor (FGF-2) and one of its receptors (FGFR-1/flg) during autoimmune inflammation of the CNS, FGF-2, and FGFR1/flg peptide and mRNA levels were examined by immunocytochemistry, by in situ hybridisation and by Northern blot analysis in T cell-mediated EAE of the Lewis rat. In naive control animals as well as in animals injected with non-encephalitogenic, PPD-reactive T lymphocytes, FGF-2 immunoreactivity was low and confined to blood vessels and to a few spinal cord neurons. In rats injected with encephalitogenic, MBP-reactive T lymphocytes, however, FGF-2-immunoreactive cells were detected from day 4 after T cell transfer onward, i.e., from the onset of clinical symptoms. The number of FGF-2 immunoreactive cells was highest between days 6 and 10 after T cell transfer. Increased FGF-2 peptide expression was paralleled by increased FGF-2 mRNA expression on macrophages/microglia in the spinal cord. By 21 days after T cell transfer, i.e. after complete recovery, FGF-2 peptide and mRNA expression had fully subsided. Based on morphological criteria and on double labeling with the macrophage/microglia-binding lectin GSI-B4 two cell types expressed FGF-2: 1) round macrophages within the core, and 2) activated microglia at the edges of white and grey matter perivascular lesions. Paralleling the temporal and spatial expression pattern of FGF-2, FGFR-1/flg immunoreactivity was induced on activated macrophages/microglia but also on reactive astrocytes bordering perivascular inflammatory lesions. In situ hybridisation analysis furthermore showed that macrophages/microglia expressed the FGFR-1/flg mRNA, and that receptor mRNA expression paralleled ligand mRNA expression. Macrophage/microglia-derived FGF-2 could serve two main functions in EAE: 1) regulate microglial activation in an autocrine fashion, and 2) help to target astrocyte-derived insulin-like growth factor-I (IGF-I) to potentially injured oligodendrocytes in demyelination.

Inflammatory reaction in experimental autoimmune encephalomyelitis (EAE) is accompanied by a microglial expression of the beta A4-amyloid precursor protein (APP).

Neuropathological studies of the amyloid depositions and senile plaques in the brains of elderly patients or patients diagnosed with Alzheimer's disease reveal the conspicuous presence of numerous proteins which are usually expressed during reactions of the immune system. This has led to speculations that the pathomechanism of neurodegenerative diseases might involve inflammatory processes. These considerations constitute the theoretical basis for therapeutic intervention with antiinflammatory drugs in neurodegenerative diseases. Here, we show that the beta A4-amyloid precursor (APP) is rapidly induced in microglia in a model of experimental autoimmune encephalomyelitis (EAE). Using specific monoclonal antibodies against APP, the first glial cells newly expressing APP immunoreactivity were found at an early preclinical stage, i.e., 24 h after T-cell transfer. At the peak of clinical disease (6 days after T-cell transfer), numerous characteristically ramified cells were strongly positive for APP. Based on morphology and double-labeling, most of the de novo APP-expressing cells were identified as microglia. Additionally, APP-immunoreactive round cells were detected in and around perivascular infiltrates. Reflecting the course of the clinical disease, the induction of APP immunoreactivity terminated in the postclinical stage, i.e., 14 days after T-cell transfer. These results support earlier work demonstrating that microglia can rapidly de novo synthesise APP not only in response to direct nerve injury (Banati et al: Glia 9:199, 1993a) but also in immune-mediated disease. Apart from its possible therapeutic relevance, such a production of APP--reminiscent of an acute phase protein-suggests a role of APP in immune and repair mechanisms of the central nervous system.

Transcription factor NF-kappa B is activated in microglia during experimental autoimmune encephalomyelitis.

NF-kappa B is an inducible transcription factor involved in the induction of multiple genes during inflammatory processes. So far the information pertaining to the role of NF-kappa B in autoimmune processes has been restricted to in vitro analysis. To further characterize the role of NF-kappa B in vivo, the involvement of NF-kappa B has been studied by immunocytochemistry in T cell-mediated autoimmune encephalomyelitis (EAE) of the Lewis rat. In non-diseased animals, immunoreactivity for the DNA-binding subunit p50 and for the DNA-binding and transactivating subunit p65 was low and restricted to the surface of small to medium-sized blood vessels. Strong immunoreactivities for p50 and p65 were detected at the peak of clinical disease. At the recovery stage of EAE, p50 and p65 immunoreactivities had declined to base line levels. Within the resident glial cell population, p50 and p65-immunoreactive cells were identified as OX-42-positive microglia. GFAP-positive astrocytes did not show significant p50 or p65 immunoreactivity. In the core and the vicinity of perivascular inflammatory lesions, both ED-1-positive macrophages and W3/13-positive T lymphocytes and monocytes were strongly immunoreactive for NF-kappa B. Our data suggest a crucial involvement of the transcription factor NF-kappa B in autoimmune diseases of the central nervous system. Furthermore, NF-kappa B appears as a useful marker for inflammatory processes in vivo.

Animal models.

Different models of experimental autoimmune encephalomyelitis (EAE) have been successfully applied to investigate and manifold aspects of the autoimmune pathogenesis of multiple sclerosis. Studies using myelin-specific T-cell lines that transfer EAE to naive recipient animals established that only activated lymphocytes are able to cross the endothelial blood-brain barrier and cause autoimmune disease within the local parenchyma. All encephalitogenic T cells are CD4+ Th1-type lymphocytes that recognize autoantigenic peptides in the context of MHC class II molecules. In the case of myelin basic protein (MBP) specific EAE in the Lewis rat, the T-cell response is directed against one strongly dominant peptide epitope. The encephalitogenic T cells preferentially use one particular set of T-cell receptor genes. Although MBP is a strong encephalitogen in many species, a number of other brain protein are now known to induce EAE. These include mainly myelin components (PLP, MAG, and MOG), but also, the astroglial S-100 beta protein. Encephalitogenic T cells produce only inflammatory changes in the central nervous system, without extensive primary demyelination. Destruction of myelin and oligodendrocytes in these models requires additional effector mechanisms such as auto-antibodies binding to myelin surface antigens such as the myelin-oligodendrocyte glycoprotein.