The choroid plexus is modulated by various peripheral stimuli: implications to diseases of the central nervous system

The blood brain barrier (BBB) and the blood cerebrospinal fluid barrier (BCSFB) form the barriers of the brain. These barriers are essential not only for the protection of the brain, but also in regulating the exchange of cells and molecules in and out of the brain. The choroid plexus (CP) epithelial cells and the arachnoid membrane form the BCSFB. The CP is structurally divided into two independent compartments: one formed by a unique and continuous line of epithelial cells that rest upon a basal lamina; and, a second consisting of a central core formed by connective and highly vascularized tissue populated by diverse cell types (fibroblasts, macrophages and dendritic cells). Here, we review how the CP transcriptome and secretome vary depending on the nature and duration of the stimuli to which the CP is exposed. Specifically, when the peripheral stimulation is acute the CP response is rapid, strong and transient, whereas if the stimulation is sustained in time the CP response persists but it is weaker. Furthermore, not all of the epithelium responds at the same time to peripheral stimulation, suggesting the existence of a synchrony system between individual CP epithelial cells.

Schistosomiasis protects against multiple sclerosis

The incidences of schistosomiasis and multiple sclerosis (MS) are mutually exclusive worldwide suggesting that schistosomiasis may offer protection against the induction of the immune-mediated disease, MS. Recent studies using the mouse model of MS, experimental autoimmune encephalomyelitis, support a direct suppression of the onset of MS by chronic Schistosoma mansoni infection. Self-reactive Th1 but not Th2 responses develop in infected mice immunized with myelin oligodendrocyte glycoprotein albeit at reduced levels indicating that the induction of auto-reactive T cells is not abolished nor phenotypically altered. CNS infiltration by inflammatory cells, particularly macrophages, is significantly reduced in S. mansoni-infected, immunized mice compared to uninfected, immunized mice. Because activated macrophages are crucial to the induction of clinical disease, these findings support the hypothesis that differences in macrophage activation may contribute to the reduced incidence and delayed progression of experimental autoimmune encephalomyelitis during schistosomiasis.

Increased numbers of circulating polyfunctional Th17 memory cells in patients with seronegative spondylarthritides

OBJECTIVE: A distinct subset of proinflammatory CD4+ T cells that produce interleukin-17 was recently identified. These cells are implicated in different autoimmune disease models, such as experimental autoimmune encephalomyelitis and collagen-induced arthritis, but their involvement in human autoimmune disease has not yet been clearly established. The purpose of this study was to assess the frequency and functional properties of Th17 cells in healthy donors and in patients with different autoimmune diseases. METHODS: Peripheral blood was obtained from 10 psoriatic arthritis (PsA), 10 ankylosing spondylitis (AS), 10 rheumatoid arthritis (RA), and 5 vitiligo patients, as well as from 25 healthy donors. Synovial tissue samples from a separate group of patients were also evaluated (obtained as paraffin-embedded sections). Peripheral blood cells were analyzed by multiparameter flow cytometry and immunohistochemistry. Cytokine production was examined by enzyme-linked immunosorbent assay and intracellular cytokine staining using specific monoclonal antibodies. Synovial tissue was examined for infiltrating T cells by immunohistochemical analysis. RESULTS: We found increased numbers of circulating Th17 cells in the peripheral blood of patients with seronegative spondylarthritides (PsA and AS), but not in patients with RA or vitiligo. In addition, Th17 cells from the spondylarthritis patients showed advanced differentiation and were polyfunctional in terms of T cell receptor-driven cytokine production. CONCLUSION: These observations suggest a role of Th17 cells in the pathogenesis of certain human autoimmune disorders, in particular the seronegative spondylarthritides.

Minocycline promotes remyelination in aggregating rat brain cell cultures after interferon-γ plus lipopolysaccharide-induced demyelination.

Minocycline has been shown to inhibit microglia reactivity, and to decrease the severity and progression of experimental autoimmune encephalomyelitis, an animal model of multiple sclerosis. It remained to be examined whether minocycline was also able to promote remyelination. In the present study, myelinating aggregating brain cell cultures were used as a model to study the effects of minocycline on microglial reactivity, demyelination, and remyelination. Cultures were treated simultaneously with two inflammatory agents, interferon-γ (IFN-γ) and lipopolysaccharide (LPS), which caused an inflammatory response accompanied by demyelination. The inflammatory response was characterized by microglial reactivity, upregulation of inflammatory cytokines and iNOS, and increased phophorylation of P38 and P44/42 mitogen activated protein (MAP) kinases. Minocycline inhibited microglial reactivity, and attenuated the increased phophorylation of P38 and P44/42 MAP kinases. Demyelination, determined by a decrease in myelin basic protein (MBP) content and immunoreactivity 48 h after the treatment with the inflammatory agents, was not prevented by minocycline. However, 1 week after demyelination was assessed, the MBP content was restored in presence of minocycline, indicating that remyelination was promoted. Concomitantly, in cultures treated with minocycline, the markers of oligodendrocyte precursors cells (OPCs) and immature oligodendrocytes NG2 and O4, respectively, were decreased compared to cultures treated with the inflammatory agents only. These results suggest that minocycline attenuates microglial reactivity and favors remyelination by enhancing the differentiation of OPCs and immature oligodendrocytes.

Tolerogenic dendritic cells and their role in induction of immune tolerance

Les cellules dendritiques sont des cellules du système immunitaire qui permettent d'instruire les lymphocytes T, autres cellules de ce système, pour mettre en place une réponse immunitaire adaptée afin de combattre et vaincre une infection. Ces cellules dendritiques vont reconnaître des motifs spécifiquement exprimés par des pathogènes par l'intermédiaire de récepteurs exprimés à leur surface. En détectant ces molécules, elles vont s'activer et subir diverses modifications pour pouvoir activer les lymphocytes T. Elles vont alors interagir avec les lymphocytes Τ et transférer les informations nécessaires pour que ces cellules s'activent à leur tour et produisent différentes protéines de façon à éliminer le pathogène. En fonction du type de pathogène, les informations transférées entre les cellules dendritiques et les lymphocytes seront différentes de manière à produire la réponse immunitaire la mieux adaptée pour supprimer l'élément infectieux. Dans le corps, les cellules dendritiques circulent continuellement afin de détecter les éléments étrangers. Quand elles reconnaissent une protéine étrangère, elles la phagocytent, c'est-à-dire qu'elles la mangent afin de pouvoir la présenter aux lymphocytes T. Mais quand elles phagocytent un élément étranger, elles peuvent également prendre des éléments du soi, comme par exemple quand elles phagocytent une cellule infectée par un virus. Les cellules dendritiques doivent alors être capables de différentier les molécules du soi et du non-soi de façon à ne pas induire une réponse en présentant un antigène du soi aux lymphocytes T. D'autant plus que lors de leur développement, les lymphocytes Τ qui sont capables de reconnaître le soi sont éliminés mais ce système n'est pas parfait et donc certains lymphocytes Τ auto-reactifs peuvent se trouver dans le corps. Il existe ainsi d'autres mécanismes en périphérie du site de développement pour inhiber ces lymphocytes Τ auto-reactifs. Ce sont les mécanismes de tolérance. Quand les lymphocytes Τ induisent une réponse aux antigènes du soi, cela résulte à des maladies auto-immunes. Dans mon projet de recherche, nous avons travaillé avec des lignées de cellules dendritiques, c'est-à-dire des cellules dendritiques semblables à celles que l'on peut trouver in vivo mais qui sont immortalisées, elles peuvent donc être cultiver et manipuler in vitro. Nous avons génétiquement modifiées ces lignées cellulaires pour qu'elles expriment des molécules immunosuppressives afin d'étudier comment induire une tolérance immunitaire, c'est-à-dire si l'expression de ces molécules permet d'éviter de générer une réponse immunitaire. Pour cela, nous avons utilisé des modèles murins de tumeurs et de maladies auto-immunes. Nous avons démontré que ces lignées de cellules dendritiques peuvent être un grand outil de recherche pour étudier les bénéfices de différentes molécules immuno-modulatrices afin d'induire une tolérance immunitaire à différents antigènes. - Les cellules dendritiques sont responsables de l'induction des réponses immunitaires adaptatives. Suite à une infection microbienne, les cellules dendritiques s'activent, elles induisent l'expression de molécules de costimulation à leur surface, sécrètent des cytokines et induisent la différentiation des cellules Τ effectrices et mémoires. De plus, les cellules dendritiques ont un rôle important dans l'induction et la maintenance de la tolérance immunitaire au niveau du thymus et en périphérie, en induisant l'anergie, la délétion ou la conversion des cellules Τ naïves en cellules régulatrices. Dans notre groupe, une nouvelle lignée de cellules dendritiques appelée MuTu a été crée par la culture de cellules dendritiques tumorales isolées à partir d'une rate d'une souris transgénique, dans laquelle l'expression de l'oncogène SV40 et du GFP sont sous le contrôle du promoteur CD1 le, et sont ainsi spécifiquement exprimés dans les cellules dendritiques. Ces nouvelles lignées appartiennent au sous-type des cellules dendritiques conventionnelles exprimant CD8a. Elles ont conservé leur capacité d'augmenter l'expression des marqueurs de costimulation à leur surface ainsi que le production de cytokines en réponse à des ligands des récepteurs Toll, ainsi que leur capacité à présenter des antigènes associés aux molécules du complexe majeur d'histocompatibilité (CMH) de classe I ou II pour activer la prolifération et la différentiation des lymphocytes T. En utilisant un système de transduction de lentivirus de seconde génération, ces nouvelles lignées de cellules dendritiques ont été génétiquement modifiées pour sur-exprimer des molécules immunosuppressives (IL-10, TGFP latent, TGFp actif, Activin A, Arginase 1, IDO, B7DC et CTLA4). Ces lignées permettent d'étudier de manière reproductible le rôle de ces molécules potentiellement tolérogènes sur les réponses immunitaires in vitro et in vivo. Ces lignées potentiellement tolérogènes ont été testées, tout d'abord, in vitro, pour leur capacité à inhiber l'activation des cellules dendritiques, à bloquer la prolifération des cellules Τ ou à modifier leur polarisation. Nos résultats démontrent qu'en réponse à une stimulation, la sur-expression des molécules costimulatrices et la sécrétion de molécules pro- inflammatoires est réduite quand les cellules dendritiques sur-expriment l'IL-10. La sur¬expression de TGFp sous sa forme active induit le développement de cellules régulatrices CD4+ CD25+ Foxp3+ et bloque la réponse CD8 cytotoxique tandis que la sur-expression de CTLA4 à la surface des cellules dendritiques inhibe une réponse Thl et induit des lymphocytes Τ anergiques. Ces lignées ont également été utilisées pour étudier l'induction de tolérance in vivo. Tout d'abord, nous avons étudié l'induction de tolérance dans un modèle de développement de tumeurs. En effet, quand les lignées tumorales sont transférées dans les lignées de souris C57BL/6, elles sont reconnues comme du non-soi du à l'expression de l'oncogène SV40 et du GFP et sont éliminées. Ce mécanisme d'élimination a été étudié en utilisant une lignée de cellules dendritiques modifiée pour exprimer la luciférase et qui a permis de suivre le développement des tumeurs par de l'imagerie in vivo dans des animaux vivants. Ces lignées de cellules dendritiques MuTu sont éliminées dans la souris C57BL/6 par les lymphocytes CD8 et l'action cytotoxique de la perforine. Après plusieurs injections, les cellules dendritiques sur-exprimant CTLA4 ou l'actif TGFp peuvent casser cette réponse immunitaire inhérente aux antigènes de la lignée et induire le développement de la tumeur dans la souris C57BL/6. Le développement tumoral a pu être suivi en mesurant la bioluminescence émise par des cellules dendritiques modifiées pour exprimer à la fois l'actif TGFp et la luciférase. Ces tumeurs ont pu se développer grâce à la mise en place d'un microenvironnement suppressif pour échapper à l'immunité en recrutant des cellules myéloïde suppressives, des lymphocytes CD4 régulateurs et en induisant l'expression d'une molécule inhibitrice PD-1 à la surface des lymphocytes CD8 infiltrant la tumeur. Dans un deuxième temps, ces lignées tolérogènes ont également été testées dans un modèle murin de maladies auto-immunes, appelé l'encéphalomyélite auto-immune expérimental (EAE), qui est un modèle pour la sclérose en plaques. L'EAE a été induite dans la souris par le transfert de cellules de ganglions prélevées d'une souris donneuse préalablement immunisée avec une protéine du système nerveux central, la glycoprotéine myéline oligodendrocyte (MOG) émulsifiée dans de l'adjuvant complet de Freund. La vaccination des souris donneuses et receveuses avec les cellules sur-exprimant l'actif TGFP préalablement chargées avec la protéine MOG bloque l'induction de l'EAE. Nous sommes actuellement en train de définir les mécanismes qui permettent de protéger la souris du développement de la maladie auto-immune. Dans cette étude, nous avons ainsi démontré la possibilité d'induire la tolérance in vivo et in vitro à différents antigènes en utilisant nos nouvelles lignées de cellules dendritiques et en les modifiant pour exprimer des molécules immunosuppressives. En conséquence, ces nouvelles lignées de cellules dendritiques représentent un outil pour explorer les bénéfices de différentes molécules ayant des propriétés immuno-modulatrices pour manipuler le système immunitaire vers un phénotype tolérogène. - Dendritic cells (DC) are widely recognized as potent inducers of the adaptive immune responses. Importantly, after microbial infections, DC become activated, induce co- stimulation, secrete cytokines and induce effector and memory Τ cells. DC furthermore play an important role in inducing and maintaining central and peripheral tolerance by inducing anergy, deletion or commitment of antigen-specific naïve Τ cells into regulatory Τ cells. In our group, stable MuTu DC lines were generated by culture of splenic DC tumors from transgenic mice expressing the SV40 large Τ oncogene and the GFP under DC-specific CDllc promoter. These transformed DC belong to the CD8a+ conventional DC subtype and have fully conserved their capacity to upregulate co-stimulatory markers and produce cytokines after activation with Toll Like Receptors-ligands, and to present Major Histocompatibility class-I or MHCII-restricted antigens to activate Τ cell expansion and differentiation. Using a second- generation lentiviral transduction system, these newly developed MuTu DC lines were genetically modified to overexpress immunosuppressive molecules (IL-10, latent TGFp, active TGFp, Activin A, Arginase 1, IDO, B7DC and CTLA4). This allows to reproducibly investigate the role of these potentially tolerogenic molecules on in vitro and in vivo immune responses. These potentially tolerogenic DC were tested in vitro for their ability to inhibit DC activation, to prevent Τ cell proliferation and to modify Τ cell polarization. Our results show that the upregulation of costimulatory molecules and the secretion of pro-inflammatory cytokines were reduced upon stimulation of DC overexpressing IL-10. The overexpression of active TGFP induced the development of CD4+ CD25+ Foxp3+ regulatory Τ cells and inhibited the cytotoxic CD8 Τ cell response as shown by using the OT-II Τ cell system whereas the surface expression of CTLA-4 on DC prevented the Thl response and prompted an anergic antigen-specific Τ cell response. These MuTu DC lines were also used in vivo in order to study the induction of tolerance. First we addressed the induction of tolerance in a model of tumorogenesis. The adoptively transferred tumor cell lines were cleared in C57BL/6 mice due to the foreign expression of SV40 LargeT and GFP. The mechanism of clearance of MuTu DC line into C57BL/6 mice was investigated by using luciferase-expressing DC line. These DC line allowed to follow, by in vivo imaging, the tumor development in living animals and determined that MuTu DC lines were eliminated in a perforin-mediated CD8 Τ cell dependent and CD4 Τ cell independent response. After multiple injections, DC overexpressing CTLA4 or active TGFp could break the immune response to these inherent antigens and induced DC tumorogenesis in wild type mice. The tumor outgrowth in C57BL/6 mice was nicely observed by double-transduced DC lines to express both luciferase and active TGFp. actTGFp-DC tumor was shown to recruit myeloid-derived suppressor cells, induce CD4+ CD25+ Foxp3+ regulatory Τ cells and induce the expression of the inhibitory receptor PD-1 on tumor- infiltrating CD8+ Τ cells in order to escape tumor immunity. Tolerogenic DC lines were also tested for the induction of tolerance in a murine model of autoimmune disease, the experimental autoimmune encephalitis (EAE) model for human multiple sclerosis. EAE was induced in C57BL/6 mice by the adoptive transfer of lymph node cells isolated from donor mice previously immunized by a protein specific to the central nervous system, the myelin oligodendrocyte glycoprotein (MOG) emulsified in the complete freund adjuvant. The vaccination of donor and recipient mice with MOG-pulsed actTGFP-DC line prevented EAE induction. We are still investigating how the active TGFP protect mice from EAE development. We generated tolerogenic DC lines inducing tolerance in vitro and in vivo. Thereby these MuTu DC lines represent a great tool to explore the benefits of various immuno-modulatory molecules to manipulate the immune system toward a tolerogenic phenotype.

IL-27 Induces Th17 Differentiation in the Absence of STAT1 Signaling.

It is known that differentiation of Th17 cells is promoted by activation of STAT3 and inhibited by activation of STAT1. Although both transcription factors are activated by several cytokines, including IL-6, IL-21, and IL-27, each of these cytokines has a very different effect on Th17 differentiation, ranging from strong induction (IL-6) to strong inhibition (IL-27). To determine the molecular basis for these differences, we measured STAT3 and STAT1 activation profiles for IL-6, IL-21, and IL-27, as well as for cytokine pairs over time. We found that the ratio of activated STAT3/activated STAT1 is crucial in determining whether cytokines promote or inhibit Th17 differentiation. IL-6 and IL-21 induced p-STAT3/p-STAT1 ratios > 1, leading to the promotion of Th17 differentiation, whereas IL-27 or IL-6+IL-27 induced p-STAT3/p-STAT1 ratios < 1, resulting in inhibition of Th17 differentiation. Consistent with these findings, we show that IL-27 induces sufficient p-STAT3 to promote Th17 differentiation in the absence of STAT1. Furthermore, IL-27-induced STAT1-deficient T cells were indistinguishable from bona fide highly proinflammatory Th17 cells because they induced severe experimental autoimmune encephalomyelitis upon adoptive transfer. Our results suggest that the ratio of p-STAT3/p-STAT1 induced by a cytokine or cytokine pairs can be used to predict whether they induce a competent Th17-differentiation program.

Modulation de la réponse immunitaire dans le cerveau par la barrière hémato-encéphalique : implication en sclérose en plaques

La sclérose en plaques (SEP) est une maladie inflammatoire du système nerveux central (SNC) caractérisée par une infiltration périvasculaire de cellules mononucléaires, telles que les lymphocytes T CD4+ et CD8+, les lymphocytes B ainsi que les cellules myéloïdes qui comprend les monocytes, les macrophages et les cellules dendritiques (DCs). Ce phénomène d’infiltration est dû à une fragilisation de la barrière hémato-encéphalique (BHE). L’entrée des cellules immunitaires au SNC va mener à la destruction de la gaine de myéline et donc à l’apparition de plaques de démyélinisation. Ainsi, nous avons émis l’hypothèse que la migration des divers sous-types de cellules immunitaires du sang périphérique à travers la BHE est contrôlée par des mécanismes moléculaires distincts et spécifiques à chaque type cellulaire. Afin de répondre à cette hypothèse, quatre différentes études ont été mises sur pieds. En premier lieu, nous démontrons un effet bénéfique des statines sur la BHE en SEP, en diminuant la migration des lymphocytes T et des monocytes, et en diminuant la diffusion de marqueurs moléculaire soluble. Ce phénomène s’opère via la suppression du processus d’isoprenylation, et en empêchant probablement la contraction des cellules endothéliales de la BHE. De plus, nous démontrons que les monocytes qui migrent au SNC en condition inflammé sont en mesures de se différencier en DCs et d’induire une réponse inflammatoire de la part des lymphocytes T CD4+. La migration des monocytes à travers la BHE est contrôlée par une nouvelle molécule d’adhérence nommée Ninjurin-1. Le blocage de Ninjurin-1 conduit à une inhibition spécifique de la migration des monocytes in vitro, ainsi qu’à une amélioration des signes cliniques du modèle animal de la SEP, soit l’encéphalomyélite auto-immune expérimentale (EAE). Finalement, nous démontrons que la migration des lymphocytes T CD8+ au SNC s’effectue via l’intégrine alpha-4. De plus, la majorité des lymphocytes T CD8+ que l’on retrouve dans le liquide céphalo-rachidien de patients SEP, dans le SNC de souris EAE ainsi que dans le SNC de souris infectée au virus de l’hépatite murine portent un phénotype effecteur mémoire. Ces données pourraient expliquer l’émergence de leucoencéphalopathie multifocale progressive observée chez certains patients SEP traités au natalizumab, un anticorps dirigé contre l’intégrine alpha-4. En conclusion, notre étude a permis de démontrer l’importance des monocytes provenant de la périphérie dans le processus inflammatoire prenant part au SNC en SEP. L’inhibition d’entrée de ces cellules pourrait s’avérer bénéfique en SEP tout en permettant l’immuno-surveillance du cerveau, ce que l’anti-alpha-4 intégrine ne permet pas. Les statines pourraient s’avérer une autre option intéressante puisqu’elles agissent sur les processus inflammatoires impliqués dans la SEP.

The Immunomodulatory Action of Sialostatin L on Dendritic Cells Reveals Its Potential to Interfere with Autoimmunity

Sialostatin L (SialoL) is a secreted cysteine protease inhibitor identified in the salivary glands of the Lyme disease vector Ixodes scapularis. In this study, we reveal the mechanisms of SialoL immunomodulatory actions on the vertebrate host. LPS-induced maturation of dendritic cells from C57BL/6 mice was significantly reduced in the presence of SialoL. Although OVA degradation was not affected by the presence of SialoL in dendritic cell cultures, cathepsin S activity was partially inhibited, leading to an accumulation of a 10-kDa invariant chain intermediate in these cells. As a consequence, in vitro Ag-specific CD4(+) T cell proliferation was inhibited in a time-dependent manner by SialoL, and further studies engaging cathepsin S(-/-) or cathepsin L(-/-) dendritic cells confirmed that the immunomodulatory actions of SialoL are mediated by inhibition of cathepsin S. Moreover, mice treated with SialoL displayed decreased early T cell expansion and recall response upon antigenic stimulation. Finally, SialoL administration during the immunization phase of experimental autoimmune encephalomyelitis in mice significantly prevented disease symptoms, which was associated with impaired IFN-gamma and IL-17 production and specific T cell proliferation. These results illuminate the dual mechanism by which a human disease vector protein modulates vertebrate host immunity and reveals its potential in prevention of an autoimmune disease. The Journal of Immunology, 2009, 182: 7422-7429.

Leukotrienes Are Upregulated and Associated with Human T-Lymphotropic Virus Type 1 (HTLV-1)-Associated Neuroinflammatory Disease

Leukotrienes (LTs) are lipid mediators involved in several inflammatory disorders. We investigated the LT pathway in human T-lymphotropic virus type 1 (HTLV-1) infection by evaluating LT levels in HTLV-1-infected patients classified according to the clinical status as asymptomatic carriers (HACs) and HTLV-1-associated myelopathy/tropical spastic paraparesis (HAM/TSP) patients. Bioactive LTB4 and CysLTs were both increased in the plasma and in the supernatant of peripheral blood mononuclear cell cultures of HTLV-1-infected when compared to non-infected. Interestingly, CysLT concentrations were increased in HAM/TSP patients. Also, the concentration of plasma LTB4 and LTC4 positively correlated with the HTLV-1 proviral load in HTLV-1-infected individuals. The gene expression levels of LT receptors were differentially modulated in CD4(+) and CD8(+) T cells of HTLV-1-infected patients. Analysis of the overall plasma signature of immune mediators demonstrated that LT and chemokine amounts were elevated during HTLV-1 infection. Importantly, in addition to CysLTs, IP-10 was also identified as a biomarker for HAM/TSP activity. These data suggest that LTs are likely to be associated with HTLV-1 infection and HAM/TSP development, suggesting their putative use for clinical monitoring.

Exploring the Role of Soluble Factors Associated with Immune Regulatory Properties of Mesenchymal Stem Cells

Mesenchymal stem cells (MSCs) are characterized as multipotent stromal cells with the capacity for both self-renewal and differentiation into mesodermal cell lineages. MSCs also have a fibroblast-like phenotype and can be isolated from several tissues. In recent years, researchers have found that MSCs secrete several soluble factors that exert immunosuppressive effects by modulating both innate (macrophages, dendritic and NK cells) and adaptive (B cells and CD4+ and CD8+ T cells) immune responses. This review summarizes the principal trophic factors that are related to immune regulation and secreted by MSCs under both autoimmune and inflammatory conditions. The understanding of mechanisms that regulate immunity in MSCs field is important for their future use as a novel cellular-based immunotherapy with clinical applications in several diseases.

Going against the tide--how encephalitogenic T cells breach the blood-brain barrier

During multiple sclerosis or its animal model, experimental autoimmune encephalomyelitis, circulating immune cells enter the central nervous system (CNS) causing neuroinflammation. Extravasation from the blood circulation across the vessel wall occurs through a multistep process regulated by adhesion and signal transducing molecules on the immune cells and on the endothelium. Since the CNS is shielded by the highly specialized blood-brain barrier (BBB), immune cell extravasation into the CNS requires breaching this particularly tight endothelial border. Consequently, travelling into the CNS demands unique adaptations which account for the extreme tightness of the BBB. Modern imaging tools have shown that after arresting on BBB endothelium, in vivo or in vitro encephalitogenic effector/memory T cells crawl for long distances, possibly exceeding 150 µm along the surface of the BBB endothelium before rapidly crossing the BBB. Interestingly, in addition to the distance of crawling, the preferred direction of crawling against the flow is unique for T cell crawling on the luminal surface of CNS microvessels. In this review, we will summarize the cellular and molecular mechanisms involved in the unique T cell behavior that is obviously required for finding a site permissive for diapedesis across the unique vascular bed of the BBB.

T-cell trafficking in the central nervous system

To perform their distinct effector functions, pathogen-specific T cells have to migrate to target tissue where they recognize antigens and produce cytokines that elicit appropriate types of protective responses. Similarly, migration of pathogenic self-reactive T cells to target organs is an essential step required for tissue-specific autoimmunity. In this article, we review data from our laboratory as well as other laboratories that have established that effector function and migratory capacity are coordinately regulated in different T-cell subsets. We then describe how pathogenic T cells can enter into intact or inflamed central nervous system (CNS) to cause experimental autoimmune encephalomyelitis or multiple sclerosis. In particular, we elaborate on the role of CCR6/CCL20 axis in migration through the choroid plexus and the involvement of this pathway in immune surveillance of and autoimmunity in the CNS.

Dysferlin is a new marker for leaky brain blood vessels in multiple sclerosis

Dysferlin is a muscle protein involved in cell membrane repair and its deficiency is associated with muscular dystrophy. We describe that dysferlin is also expressed in leaky endothelial cells. In the normal central nervous system (CNS), dysferlin is only present in endothelial cells of circumventricular organs. In the inflamed CNS of patients with multiple sclerosis (MS) or in animals with experimental autoimmune encephalomyelitis, dysferlin reactivity is induced in endothelial cells and the expression is associated with vascular leakage of serum proteins. In MS, dysferlin expression in endothelial cells is not restricted to vessels with inflammatory cuffs but is also present in noninflamed vessels. In addition, many blood vessels with perivascular inflammatory infiltrates lack dysferlin expression in inactive lesions or in the normal-appearing white matter. In vitro, dysferlin can be induced in endothelial cells by stimulation with tumor necrosis factor-alpha. Hence, dysferlin is not only a marker for leaky brain vessels, but also reveals dissociation of perivascular inflammatory infiltrates and blood-brain barrier disturbance in multiple sclerosis.

Natalizumab: targeting alpha4-integrins in multiple sclerosis

In 1992, it was shown that monoclonal antibodies blocking alpha(4)-integrins prevent the development of experimental autoimmune encephalomyelitis, an animal model for multiple sclerosis (MS). As alpha(4)beta(1)-integrin was demonstrated to mediate the attachment of immune-competent cells to inflamed brain endothelium in experimental autoimmune encephalomyelitis, the therapeutic effect was attributed to the inhibition of immune cell extravasation and inflammation in the central nervous system. This novel therapeutic approach was rapidly and successfully translated into the clinic. The humanized anti-alpha(4)-integrin antibody natalizumab demonstrated an unequivocal therapeutic effect in preventing relapses and slowing down the pace of neurological deterioration in patients with relapsing-remitting MS in phase II and phase III clinical trials. The occurrence of 3 cases of progressive multifocal leukoencephalopathy in patients treated with natalizumab led to the voluntary withdrawal of the drug from the market. After a thorough safety evaluation of all patients receiving this drug in past and ongoing studies for MS and Crohn's disease, natalizumab again obtained approval in the US and the European Community. A treatment targeting leukocyte trafficking in MS has now re-entered the clinic. Further thorough evaluation is necessary for a better understanding of the risk-benefit balance of this new treatment option for relapsing MS. In this review, we discuss the basic mechanism of action, key clinical results of clinical trials and the emerging indication of natalizumab in MS.

Kindlin-3 regulates integrin activation and adhesion reinforcement of effector T cells

Activated T cells use very late antigen-4/α4β1 integrin for capture, rolling on, and firm adhesion to endothelial cells, and use leukocyte function-associated antigen-1/αLβ2 integrin for subsequent crawling and extravasation. Inhibition of α4β1 is sufficient to prevent extravasation of activated T cells and is successfully used to combat autoimmune diseases, such as multiple sclerosis. Here we show that effector T cells lacking the integrin activator Kindlin-3 extravasate and induce experimental autoimmune encephalomyelitis in mice immunized with autoantigen. In sharp contrast, adoptively transferred autoreactive T cells from Kindlin-3-deficient mice fail to extravasate into the naïve CNS. Mechanistically, autoreactive Kindlin-3-null T cells extravasate when the CNS is inflamed and the brain microvasculature expresses high levels of integrin ligands. Flow chamber assays under physiological shear conditions confirmed that Kindlin-3-null effector T cells adhere to high concentrations of vascular cell adhesion molecule-1 and intercellular adhesion molecule-1, albeit less efficiently than WT T cells. Although these arrested T cells polarize and start crawling, only few remain firmly adherent over time. Our data demonstrate that the requirement of Kindlin-3 for effector T cells to induce α4β1 and αLβ2 integrin ligand binding and stabilization of integrin-ligand bonds is critical when integrin ligand levels are low, but of less importance when integrin ligand levels are high.