In situ processing and distribution of intracerebrally injected OVA in the CNS

Drainage and retention of brain-derived antigens are important factors in initiating and regulating immune responses in the central nervous system (CNS). We investigated distribution, immunological processing and retention of intracerebrally infused protein antigen, ovalbumin (OVA), and the subsequent recruitment of CD8(+) T cells into the CNS. We found that protein antigens infused into the CNS can drain rapidly into the cervical lymph node and initiate antigen-specific immune response in the periphery. A portion of the antigens are also retained by CD11b/MAC-1(+) cells in the brain parenchyma where they are recognized by antigen-specific CD8(+) T cells.     

Antigen-specific T cell trafficking into the central nervous system

The initiation step of cell-mediated immune responses in the central nervous system (CNS) involves the trafficking of the antigen-specific T cells into the brain. To study this trafficking, we developed an in vivo system for studying antigen-specific responses in the CNS. In this assay, T cell receptor (TCR) transgenic mice having 95% of T cells specific for a defined antigen-pigeon cytochrome c (PCC) were cannulated intraventricularly for PCC antigen infusion and cerebrospinal fluid (CSF) sampling. Upon PCC infusion into the CNS, the number of alpha/beta TCR(+) Vbeta3(+) Mac1(-) cells in the CSF was characterized. We found that infusion of antigen into the CSF induced an increased number of antigen-specific T cells in the CNS and activation of antigen-specific T cells in the peripheral blood. Hence, the drainage of CNS antigen into the periphery might play an important role in sustaining autoimmune reactivity in CNS inflammatory diseases.     

Peripheral tolerance limits CNS accumulation of CD8 T cells specific for an antigen shared by tumor cells and normal astrocytes

T cell mediated immunotherapies are proposed for many cancers including malignant astrocytoma. As such therapies become more potent, but not necessarily more tumor-specific, the risk of collateral autoimmune damage to normal tissue increases. Tumors of the brain present significant challenges in this respect, as autoimmune destruction of brain tissue could have severe consequences. To investigate local immune reactivity toward a tumor-associated antigen in the brain, transgenic mice were generated that express a defined antigen (CW3 170-179) in astroglial cells. The resulting six transgenic mouse lines expressed the transgenic self-antigen in cells of the gastrointestinal tract and CNS compartments, or in the CNS alone. By challenging transgenic mice with tumor cells that express CW3, self/tumor-specific immune responses were visualized within a normal polyclonal T cell repertoire. A large expansion of the endogenous CW3 170-179-specific CD8 T cell population was observed in nontransgenic mice after both subcutaneous and intracerebral implantation of tumor cells. In contrast, CW3 170-179-specific immune responses were not observed in transgenic mice that exhibited extracerebral transgene expression. Importantly, in certain groups of mice in which transgene expression was restricted to the CNS, antigen-specific immune responses occurred when tumor was implanted subcutaneously, but not intracerebrally. This local immune tolerance in the brain was induced via peripheral (extrathymic) rather than central (thymic) tolerance mechanisms. Thus, this study highlights the role of regional immune regulation in the prevention of autoimmunity in the brain, and the potential impact of these mechanisms for brain tumor immunotherapy.     

Immunological reactions to neural grafts in the central nervous system

Immunological rejection is a lasting, although highly variable, threat to allo- and xenogeneic neural tissue grafted to the CNS of rodents, monkeys and man. One major determinant for rejection of intracerebral CNS grafts appears to be induction of major histocompatibility complex (MHC) antigens on the donor CNS cells. We have previously examined the cellular immune response against neural mouse xenografts undergoing rejection in the adult rat brain. In this study we focus on the astro- and microglial reactions within and around the graft, and the potential of individual host rat and donor mouse brain cells to express MHC antigens. Previous light microscopical observations of expression of rat MHC antigen class I by endothelial cells, microglial cells, and invading leukocytes were extended to the ultrastructural level and found to include a few astrocytes. Rat and mouse MHC antigen class II was only detected on leukocytes and activated microglial cells. The findings imply that within grafts of brain or spinal cord tissue donor astrocytes, microglial cells and endothelial cells can be induced to act as target cells for class I specific host T cytotoxic cells, while only (graft and host) microglial cells can be induced to express MHC antigen class II and present antigen to sensitized (and possibly also resting) host T helper cells.     

Neonatal and adult microglia cross-present exogenous antigens

Some observations have suggested that cells from the central nervous system (CNS) could present exogenous antigens on major histocompatibility complex (MHC) class I molecules to CD8(+) T cells (a process called cross-presentation). Microglia are the major myeloid immunocompetent cells of the CNS. When activated, following the injury of the nervous parenchyma, they become fully competent antigen-presenting cells (APC) that prime CD4(+) T lymphocytes. We therefore tested the cross-presentation capacity of murine microglia. We report that a microglial cell line (C8-B4), neonatal microglia, and interestingly adult microglia cross-present soluble exogenous antigen (ovalbumin) to a OVA-specific CD8(+) T-cell hybridoma and cross-prime OVA-specific naive OT-1 CD8(+) T cells. In both these cases, C8-B4 and neonatal microglia cross-present OVA as well as peritoneal macrophages. Although cross-presentation by adult microglia is less efficient, it is increased by GM-CSF and CpG oligodeoxynucleotide (ODN) stimulation. Using microglial cells either exposed to an inhibitor of proteasome, lactacystin, or purified from TAP(-/-) mice, we demonstrate that the microglia cross-present antigen in proteasome- and TAP-dependant pathways, respectively. Last, microglia purified from adult mice injected intracerebrally with OVA efficiently stimulate OVA-specific CD8(+) T cells, thereby showing that microglia take up and process exogenous antigen into MHC class I in vivo. This first demonstration of the cross-presentation property of microglia offers novel therapeutic approaches to modulate CD8 T-cell responses in the brain.     

Time limited immunomodulatory functions of transplanted neural precursor cells

Fetal neural stem/precursor cells (NPCs) possess powerful immunomodulatory properties which enable them to protect the brain from immune‐mediated injury. A major issue in developing neural stem/precursor cell (NPC) therapy for chronic neuroinflammatory disorders such as multiple sclerosis is whether cells maintain their immune‐regulatory properties for prolonged periods of time. Therefore, we studied time‐associated changes in NPC immunomodulatory properties. We examined whether intracerebrally‐transplanted NPCs are able to inhibit early versus delayed induction of autoimmune brain inflammation and whether allogeneic NPC grafts continuously inhibit host rejection responses. In two experimental designs, intraventricular fetal NPC grafts attenuated clinically and pathologically brain inflammation during early EAE relapse but failed to inhibit the disease relapse if induced at a delayed time point. In correlation, long‐term cultured neural precursors lost their capacity to inhibit immune cell proliferation in vitro. Loss of NPC immune functions was associated with transition into a quiescent undifferentiated state. Also, allogeneic fetal NPC grafts elicited a strong immune reaction of T cell and microglial infiltration and were rejected from the host brain. We conclude that long‐term functional changes in transplanted neural precursor cells lead to loss of their therapeutic immune‐regulatory properties, and render allogeneic grafts vulnerable to immunologic rejection. Thus, the immunomodulatory effects of neural precursor cell transplantation are limited in time. © 2012 Wiley Periodicals, Inc.     

Immunohistochemical analysis on the rejection of xenogeneic brain grafts

The central nervous system (CNS) of mammals has long been thought of as an immunologically privileged site. However, this concept is now changing because the rejection of histo-incompatible neural grafts has been frequently observed in the CNS. In neural transplantation used as therapy for some human neurodegenerative diseases, it is important to determine which factors are related to brain graft rejection. In this study, we examined immunological reactions in brains that had received isogeneic (rat to rat) and xenogeneic (mouse to rat) neural transplants. In the immunohistochemical analysis, antibodies against T cell receptor αβ (R73), macrophage and microglia (0X42), MHC class II antigens (0X6), CD4 (W3/25), CD8 (0X8), NK cell (3.2.3), B cell (RLN-9D3), T cell receptor (TCR) Vβ8.2 (R78), TCR Vβ8.5 (B73) and TCR Vβl0 (G101) were used. At the early stage of both isogeneic and xenogeneic transplantation, a nonspecific inflammatory reaction characterized by macrophage infiltration was observed along the needle track which was produced by the grafting procedure. From the day 7 stage onwards, the non-specific inflammatory reaction was replaced by the specific immune reactions of T cell infiltration, neovascularization and necrosis of xenogeneic grafts. Marked T cell infiltration was detected in the lesions, whereas NK and B cells were not. Quantitative analysis of T cell subsets revealed that both CD4+ and CD8+ T cells were found in the xenogeneic transplants. Microglia became activated and strongly expressed MHC class II antigens at the time of graft rejection. Isogeneic transplants, in contrast, showed no histological characteristics of rejection, and numerous dopaminergic neurons with several neurites were observed in the grafts. Based on these findings, we concluded that T cells are the principal effectors in the rejection of xenogeneic neural grafts, and that activated microglia may have some role in presenting antigens to the infiltrating T cells during the rejection process.     

Effect of local sympathectomy on 24-h changes in mitogenic responses and lymphocyte subset populations in rat submaxillary lymph nodes during the preclinical phase of Freund's adjuvant arthritis

Wistar male rats received a bilateral superior cervical ganglionectomy or sham-operation and 10 days later were injected with Freund's complete adjuvant or its vehicle. Two days later, rats were killed at six different time intervals throughout a 24-h cycle. The mitogenic effect of lipopolysaccharide (LPS) and concanavalin A (Con A) and the relative size of lymphocyte subset populations were measured in submaxillary lymph nodes. Cells from sympathectomized lymph nodes showed a lower response to Con A. Freund's adjuvant injection decreased amplitude of daily rhythm in Con A response, an effect prevented by denervation. Generally, ganglionectomy increased Con A response at the early phase of arthritis. Acrophases for Con A and LPS effect occurred at early afternoon and did not change after ganglionectomy. Administration of Freund's adjuvant caused a 10-h advance in acrophase of LPS mitogenic activity, an effect prevented by ganglionectomy. Significant 24-h rhythms were observed in relative size of lymph node B and T cells. Denervation augmented amplitude of rhythm in B cells in adjuvant's vehicle-injected rats. As far as T lymphocyte subsets, acrophases occurred at the afternoon (CD4(+) and CD4(+)-CD8(+) cell types) or at night (CD8(+) cell types). Immunization augmented amplitude of 24-h rhythms in CD4(+)-CD8(+) cells regardless of innervation whereas denervation counteracted the suppression of daily rhythm in CD8(+) cells seen in arthritis. The results indicate that some of the changes seen in 24-h organization of immune responses in lymph nodes at an early phase of arthritis are modified by severing the local sympathetic nerves.     

Self-tolerance in the immune privileged CNS: lessons from the entorhinal cortex lesion model

Upon peripheral immunization with myelin epitopes, susceptible rats and mice develop T cell-mediated demyelination similar to that observed in the human autoimmune disease multiple sclerosis (MS). In the same animals, brain injury does not induce autoimmune encephalomyelitis despite massive release of myelin antigens and early expansion of myelin specific T cells in local lymph nodes, indicating that the self-specific T cell clones are kept under control. Using entorhinal cortex lesion (ECL) to induce axonal degeneration in the hippocampus, we identified possible mechanisms of immune tolerance after brain trauma. Following ECL, astrocytes upregulate the death ligand CD95L, allowing apoptotic elimination of infiltrating activated T cells. Myelin-phagocytosing microglia express MHC-II and the costimulatory molecule CD86, but lack CD80, which is found only on activated antigen presenting cells (APCs). Restimulation of invading T cells by such immature APCs (e.g. CD80 negative microglia) may lead to T cell anergy and/or differentiation of regulatory/Th3-like cells due to insufficient costimulation and presence of high levels of TGF-beta and IL-10 in the CNS. Thus, T cell -apoptosis, -anergy, and -suppression apparently maintain immune tolerance after initial expansion of myelin-specific T lymphocytes following brain injury. This view is supported by a previous metastatistical analysis which rejected the hypothesis that brain trauma is causative of MS (Goddin et al., 1999). However, concomitant trauma-independent proinflammatory signals, e.g., those evoked by clinically quiescent infections, may trigger maturation of APCs, thus shifting a delicate balance from immune tolerance and protective immune responses to destructive autoimmunity.     

Memory T cells persisting in the brain following MCMV infection induce long-term microglial activation via interferon-γ

Murine cytomegalovirus (MCMV) brain infection stimulates microglial cell-driven proinflammatory chemokine production which precedes the presence of brain-infiltrating systemic immune cells. Here, we show that in response to MCMV brain infection, antigen-specific CD8(+) T cells migrated into the brain and persisted as long-lived memory cells. The role of these persistent T cells in the brain is unclear because most of our understanding of antimicrobial T cell responses comes from analyses of lymphoid tissue. Strikingly, memory T cells isolated from the brain exhibited an effector phenotype and produced IFN-γ upon restimulation with viral peptide. Furthermore, we observed time-dependent and long-term activation of resident microglia, indicated by chronic MHC class II up-regulation and TNF-α production. The immune response in this immunologically restricted site persisted in the absence of active viral replication. Lymphocyte infiltrates were detected until 30 days post-infection (p.i.), with CD8(+) and CD4(+) T cells present at a 3:1 ratio, respectively. We then investigated the role of IFN-γ in chronic microglial activation by using IFN-γ-knockout (GKO) mice. At 30 days p.i., GKO mice demonstrated a similar phenotypic brain infiltrate when compared to wild-type mice (Wt), however, MHC class II expression on microglia isolated from these GKO mice was significantly lower compared to Wt animals. When IFN-γ producing CD8(+) T cells were reconstituted in GKO mice, MHC class II up-regulation on microglial cells was restored. Taken together, these results suggest that MCMV brain infection results in long-term persistence of antigen-specific CD8(+) T cells which produce IFN-γ and drive chronic microglial cell activation. This response was found to be dependent on IFN-γ production by viral Ag-specific T cells during the chronic phase of disease.     

Quantitation of antigen-specific T-cell-induced demyelination in vitro

To test the hypothesis that T lymphocytes sensitized to central nervous system (CNS) antigens may quantitatively induce more demyelination in neural tissue than T cells sensitized to non-CNS antigens, we established T cell lines specific for myelin basic protein (MBP) or the purified protein derivative (PPD) of M. tuberculosis. The potential of T cells to cause myelin pathology was determined by measuring the activity of the myelin-associated enzyme 2'-3'-cyclic nucleotide 3'-phosphodiesterase (CNPase) in organotypic cultures of syngeneic spinal cord after incubation with the T cell lines. The activity of CNPase in neural tissue has been shown to correlate positively with the amount and integrity of CNS myelin. Although both MBP- and PPD-specific T cells caused decreases in CNPase activity, the MBP line caused significantly greater and consistent changes. This finding indicates that T cell-mediated CNS demyelination may be comprised of CNS antigen-specific and CNS non-specific components, the former causing more pathology.     

Cross-priming of T cells to intracranial tumor antigens elicits an immune response that fails in the effector phase but can be augmented with local immunotherapy

Central nervous system (CNS) tumors are thought to be poorly immunogenic. However, whether defective anti-tumor immunity is a consequence of a relative failure of T cell priming versus a deficient effector phase of the anti-tumor immune response is not clear. We utilized a well-defined model system of B16 melanoma expressing the model antigen SIY-GFP to evaluate tumor antigen cross-priming and tumor rejection from the CNS versus subcutaneous compartments. We observed that B16-SIY cells implanted in the CNS were capable of inducing T cell priming as measured by IFN-gamma ELISPOT in the spleen. Cross-priming occurred in the absence of detectable systemic dissemination of the tumor. Despite the induction of a T cell response, CNS tumors grew progressively and were fatal, whereas the same tumor implanted in the flank was rejected. To study the effector phase of the immune response in more detail, in vitro primed 2C/RAG2-/- TCR transgenic CD8+ cells, which recognize the SIY peptide, were adoptively transferred. In addition, the CNS microenvironment was modulated by intracranial delivery of IL-2. While mice that received primed 2C cells alone showed an increase in survival, co-administration of intracranial IL-2 led to a marked prolongation of survival, with 20% of mice surviving at least 120 days. Our results demonstrate that CD8+ T cell cross-priming does indeed occur in response to a CNS tumor, but that manipulation of the brain tumor microenvironment may be necessary to support the effector phase of the anti-tumor immune response.     

Central nervous system: A modified immune surveillance circuit?

Immune surveillance in the central nervous system (CNS) was considered impossible because: (i) the brain parenchyma is separated from the blood circulation by the blood-brain barrier (BBB); (ii) the brain lacks lymphatic drainage and (iii) the brain displays low major histocompatibility complex class II (MHCII) expression. In this context, the BBB prevents entry of immune molecules and effector cells to the CNS. The absence of lymphatic vessels avoids CNS antigens from reaching the lymph nodes for lymphocyte presentation and activation. Finally, the low MHCII expression hinders effective antigen presentation and re-activation of T cells for a competent immune response. All these factors limit the effectiveness of the afferent and efferent arms necessary to carry out immune surveillance. Nevertheless, recent evidence supports that CNS is monitored by the immune system through a modified surveillance circuit; this work reviews these findings.     

Presentation by myoblasts of an epitope from endogenous acetylcholine receptor indicates a potential role in the spreading of the immune response

It is generally considered that myoblasts are unable to prime naive T cell responses without help from professional antigen-presenting cells (APC). However, their ability to present endogenous antigens to previously primed T lymphocytes in the secondary phase of a T cell response has not been well studied. We show here that primary human myoblasts, when stimulated with IFNgamma to express class II MHC, can present an endogenous epitope, probably an acetylcholine receptor (AChR) peptide, to a CD4(+) AChR-specific T helper lymphocyte clone. Presentation leads to secretion of IFNgamma by the T cell clone and, in addition, killing of the myoblast. Our results suggest that, during the effector phase of the immune response, myoblasts could enhance the inflammatory response by presenting endogenous antigen, and thereby become targets for CD4(+) T lymphocyte-induced cytotoxicity; subsequent release of myoblast antigens could then lead to inter- and intra-molecular determinant spreading.     

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     

Brain-immune connection: immuno-regulatory properties of CNS-resident cells

Even though the immune privileged status of the central nervous system (CNS) limits access of systemic immune cells through the blood brain barrier (BBB), an immune response can occur in this compartment with or without major breach of the BBB. In this review, we consider properties of resident cells of the CNS, that participate in regulating the neural antigen (Ag)-directed immune responses implicated in autoimmune diseases such as multiple sclerosis (MS). Under such conditions, the CNS is usually viewed as the target or victim of the immune assault, because such immune responses are thought to be initiated and regulated within the systemic immune compartment. The CNS-endogenous cells may themselves, however, initiate, regulate and sustain an immune response. We consider the immune regulatory functions within the CNS in terms of events occurring within the CNS parenchyma (microglia, astroglia) and at the vascular interface. These regulatory functions involve antigen presentation to T cells and polarization of the cytokine response of these cells. Such responses may contribute not only to the overall tissue injury in primary immune disorders but also in a wide range of traumatic, ischemic and degenerative processes.     

Adult human glial cells can present target antigens to HLA-restricted cytotoxic T-cells.

T-lymphocyte recognition of antigen either on antigen-presenting cells (APC) necessary for the generation of an immune response or on target cells during the effector phase of a cellular immune response requires expression of HLA molecules. Although immune mechanisms operate in many disease processes of the central nervous system (CNS), cells of the CNS generally express low levels of HLA molecules. In this study, the potential for upregulation of HLA molecules on adult human glial cells was examined. Moreover, the functional implication of this upregulation was assessed by the capacity of glial cells to process and present target antigens to HLA class I-restricted influenza-specific and class II-restricted myelin basic protein (MBP)-specific CTL lines. Glial cells cultured from adult human surgical brain specimens or cells from established glioblastoma multiforme cell lines were studied. Lysis by antigen-specific CTLs was dependent on treatment of the target cell with interferon-gamma. The lysis was HLA restricted and antigen specific. The results indicate that adult human glial cells can process and present antigen to HLA-restricted CTLs but require the upregulation of HLA molecules. These findings have implications for infectious and autoimmune diseases of the CNS.     

Neural precursors attenuate autoimmune encephalomyelitis by peripheral immunosuppression

OBJECTIVE: Intracerebroventricular or intravenous (IV) injection of neural precursor cells (NPCs) attenuates experimental autoimmune encephalomyelitis (EAE), the animal model of multiple sclerosis. Although stem cell therapy was introduced initially for cell replacement, we examine here whether NPCs possess immunomodulatory effects. METHODS: We examined the effects of systemic administration of NPCs on central nervous system (CNS) inflammation in EAE and the interactions between NPCs and T cells in vitro and in vivo. RESULTS: IV NPC therapy decreased significantly CNS inflammation and tissue injury and attenuated the clinical severity of EAE. IV-injected NPCs could not be found in the CNS but were detected in lymphoid organs. Coculture experiments showed that NPCs inhibited the activation and proliferation of lymph node-derived T cells in response to CNS-derived antigens and to nonspecific polyclonal stimuli. The relevance of NPC/lymph node cell interactions in vivo was further demonstrated when lymph node cells obtained from IV NPC-treated mice exhibited poor encephalitogenicity on transfer to naive mice and caused a markedly milder EAE compared with those obtained from nontreated mice. INTERPRETATION: IV administration of neural precursors inhibits EAE by a peripheral immunosuppressive effect. Our findings suggest a profound bystander inhibitory effect of NPCs on T-cell activation and proliferation in the lymph nodes, leading to amelioration of EAE.     

Role of the blood-brain barrier in the establishment of the immmune response against polyoma virus-induced cerebral tumours in hamsters

The existence of an immunological blood-brain barrier (BBB) is well established but its role in cerebral tumour immunology is less well defined. Attempting to clarify this problem we tested the graft rejection of polyoma virus-induced central nervous (CNS) tumours in hamsters after systemic or intracerebral immunization with polyoma virus. Animals were immunized by intracerebral or subcutaneous inoculations of polyoma virus before tumours were induced by intracerebral or intramuscular graft of polyoma-transformed hamster neuroglial cells. The growth of cerebral and muscular tumours was significantly inhibited in animals immunized subcutaneously. In animals immunized intracerebrally the inhibition of growth was highly significant for cerebral tumours and only very slight for intramuscular tumours. These results suggest that the blood-brain barrier allowed immunocompetent effector cells to penetrate inside the CNS but prevented the locally elicited cell-mediated immune response from diffusing outside the CNS. The ability of the brain to develop a local immune response and the partial lack of circulation of immunocompetent cells to cross the BBB could be mainly responsible for the special immune status of the CNS and may greatly interfere with the establishment of an efficient immune response toward brain tumours.     

CNS中抗原递呈细胞调节T细胞对CNS抗原的应答

在中枢神经系统 (CNS)炎症或损伤时 ,T细胞对CNS抗原的应答启动于外周免疫系统 ,而作用于CNS。CNS中小胶质细胞、星形胶质细胞和血管周围巨噬细胞可作为抗原递呈细胞 ,通过对Th1和Th2细胞的再刺激 ,分泌可溶性因子调节Th1和Th2细胞应答 ,以及与T细胞间相互作用 ,调控Th1细胞和Th2细胞间的平衡 ,从而促进或抑制T细胞应答 ,影响CNS炎症损伤的结局