The requirements for antigen multivalency in class I antigen recognition and triggering of primed precursor cytolytic T lymphocytes

In vitro generation of a secondary cytolytic T lymphocyte (CTL) response to Class I alloantigen requires two signals: recognition of the Class I antigen by precursor CTL (Signal 1), and subsequent interaction with lymphokine(s) (Signal 2). Previous work using subcellular antigen stimulation has demonstrated that the required lymphokine(s) is produced as a result of adherent cell uptake, processing, and Ia-restricted presentation of alloantigen to helper T cells. This pathway could be bypassed by addition to the cultures of supernatant from Con A-stimulated rat spleen cells. When an optimal level of lymphokine(s) is provided by addition of Con A supernatant, the magnitude of the CTL response obtained is dependent on the effectiveness of alloantigen recognition and triggering of the primed precursor CTL (pCTL). By using this approach, we examined the cellular and molecular requirements for generation of Signal 1. Previous results had indicated that pCTL were able to directly recognize subcellular antigen, and that cellular presentation of the antigen to pCTL was not required. Further evidence for this was provided by the finding that pulsing of the responder population for short times with liposomes containing purified H-2Kk resulted in effective stimulation of the response. Exposure of cells to antigen for 1 to 2 hr at 4 degrees C generated responses of comparable magnitude to those obtained when antigen was continuously present in the cultures. Experiments were also done to directly examine the ability of alloantigen-pulsed splenic adherent cells (SAC) to deliver Signal 1. Although the antigen-pulsed SAC were very effective in presenting to helper T cells to result in factor production, they were found to be very ineffective in providing Signal 1 to the pCTL. Having obtained strong evidence for triggering of pCTL occurring via direct recognition of the subcellular alloantigen, we then examined the role of antigen multivalency in recognition and triggering. Purified H-2Kk was prepared in a variety of forms of differing multivalency, ranging from monovalent papain cleavage product to large, highly multivalent liposomes and plasma membranes. The magnitude of the CTL responses obtained was found to be critically dependent on the multivalency of the antigen preparation. Examination of the antigen dose-response curves and maximal responses obtained suggests that valency of the antigen may be important both in determining the avidity of interaction between the pCTL and the antigen-bearing structure, and in determining the extent to which localized receptor cross-linking occurs on the cell surface to result in triggering.     

The mechanism of antigen presentation by dendritic cells and splenic adherent cells in the induction of an allogeneic cytotoxic T-lymphocyte response to H-2Kk liposomes

Induction of an allogeneic cytotoxic T-lymphocyte (CTL) response to purified alloantigen is partially dependent on uptake and processing of the class I alloantigen by antigen-presenting cells (APC) followed by recognition of the alloantigen and self Ia by helper T cells (TH). The activated TH provides the helper signal(s) to the alloantigen-specific CTL for proliferation and differentiation into an active effector CTL. The role of antigen processing and presentation of major histocompatibility complex alloantigens was examined and the ability of different types of APC to present purified H-2Kk liposomes was investigated. Splenic adherent cells (SAC), splenic dendritic cells (DC), and B-cell lymphoblastoid lines were all shown to be effective in the presentation of H-2Kk liposomes. The relative ability of these cells to serve as APC was determined to be DC greater than B-cell tumors greater than SAC. The role of processing of H-2Kk liposomes by SAC and DC was examined by investigating the effect of weak bases on pulsing of the APC. These experiments suggest that presentation of alloantigen by both SAC and DC involves a step which is sensitive to inhibition by weak bases. We examined whether the TH were activated by similar mechanisms when stimulated by the various APC. The functional involvement of the T-cell surface marker L3T4 was demonstrated in the induction of TH. In contrast, L3T4 was not involved in the subsequent generation of CTL since monoclonal antibody (MAb) specific for L3T4 was not effective in blocking CTL function in the presence of nonspecific T helper factor (THF). Similarly, Ia on the APC was shown to be involved in the stimulation of the TH pathway but not directly in the differentiation of the CTL. Thus, DC and B cells in addition to SAC can present H-2Kk to TH. The presentation of alloantigen by both cell types may involve an intracellular route as demonstrated by the blocking of the TH response by weak bases. Both Ia and L3T4 are required on the APC for induction of the TH response. The minimal requirements for activation of the CTL were H-2Kk liposomes and a source of THF.     

Studies on the product of antigenic recognition. I. Formation of the product in recognition of alloantigens.

A product of antigenic recognition (PAR) was produced whenever receptors for alloantigens from T lymphocytes or a principle present in T-cell dependent alloantisera interacted with alloantigen. With two forms of the PAR assay (direct and indirect) the mechanisms underlying these interactions have been analyzed. For the interaction of T-lymphocyte receptors with alloantigen measured with direct PAR assays, the following conclusion emerged: upon confrontation with alloantigen, receptors (if not already present in secreted form) had first to be released from T-cell membranes. Shed T-cell receptors interacted with alloantigens by solubilizing them. Both processes could be prevented by fixing cells with formaldehyde. Release of T-cell receptors was temperature-dependent, solubilization of alloantigens was not. Because in mixed cell cultures receptors had first to be shed, this process was considerably slower and, in concordance with temperature dependence of receptor release, took place only at 37 degrees C. Titration of T lymphocytes with 'bound' receptors by the direct PAR test revealed that in the presence of excess alloantigen 10(2) T cells sufficed to give measurable responses. Supernates of parental strain lymphocytes containing numerous T-cell receptor specificities could be depleted of one of them. Alloantisera raised in presence of T helper cells ('T alloantisera') contained a principle capable of recognizing alloantigens, alloantisera incited in the absence of T helpers ('B alloantisera') did not. The recognizing principle appeared to be IgG. Like T-cell receptors, it was capable of solubilizing alloantigens form target cell membranes. B alloantisera lacked this capacity and their alloantigen-recognizing moiety was found to be monomeric IgM. The mode of interaction of this IgM with alloantigen most likely consisted in fixation to and shielding of antigen.     

Absolute requirement for adherent cells in the production of human interleukin 2 (IL2)

Activated T lymphocytes appear to require a growth factor, interleukin 2 (IL2), for continued proliferation. It has been hypothesized that T lymphocytes serving an amplifier function produce IL2 in response to an activating signal such as antigen or mitogen; in addition, the producer lymphocytes receive a second signal from macrophages. The present experiments demonstrated that human IL2 production in culture is totally depleted by exhaustive removal of adherent cells and can be completely restored by replacement of the adherent cells.     

Studies on the role of lymphocyte-activating factor (Interleukin 1) in antigen-induced lymph node lymphocyte proliferation

The in vitro proliferation of primed lymph node lymphocytes (LNL) in response to the soluble antigen ovalbumin (OVA) was dependent upon the presence of adherent cells. Restoration of OVA-induced LNL proliferation could be achieved by addition of highly purified lymphocyte-activating factor (LAF; Interleukin 1, IL 1): LAF (IL 1) did not stimulate LNL proliferation in the absence of the priming antigen or T lymphocytes. Furthermore, treatment of the LNL with antimacrophage serum completely blocked the ability of the LNL to respond to OVA and LAF (IL 1), suggesting that the residual macrophages in the LNL population were necessary to provide an additional function or signal, possibly antigen presentation, in conjunction with LAF (IL 1). These data therefore support the two signal hypothesis of macrophage-mediated lymphocyte activation and demonstrate the ability of LAF (IL 1) to provide one of these signals.     

OKT3 monoclonal antibody induces production of colony-stimulating factor(s) for granulocytes and macrophages in cultures of human T lymphocytes and adherent cells

OKT3 monoclonal antibody (mab) recognizes a membrane antigen associated with the T cell antigen recognition receptor, and is known to be mitogenic and to induce lymphokine production. Our studies demonstrate the ability of OKT3 mab to induce from cultures of human T lymphocytes supplemented with adherent cells the production of colony-stimulating factor(s) for granulocytes and macrophages (GM-CSF) and interferon-gamma (IFN-gamma), an inhibitor of clonal growth of hematopoietic progenitor cells. As has been shown for the mitogenic and IFN-gamma-inducing activity of OKT3 mab, the induction of GM-CSF release in cultures of T cells is strictly dependent on the presence of adherent cells. However, the concentrations of OKT3 mab required for optimal GM-CSF production (50 ng/ml) were found to be 80-fold higher than those sufficient for maximal IFN-gamma production, proliferation, and interleukin 2 production. IFN-gamma activity induced by OKT3 mab partially inhibited colony and cluster formation from progenitor cells of granulocytes and macrophages in vitro. Therefore, neutralization of the IFN-gamma by monoclonal anti-human-IFN-gamma antibody before assay of conditioned medium in bone marrow cultures significantly enhanced the detection of GM-CSF. Kinetic studies demonstrated maximal cumulative GM-CSF production in response to optimal OKT3 mab concentrations on days 4 through 6 in cultures of T cells supplemented with 15% adherent cells. Highly enriched OKT4+ and OKT8+ T cell subsets co-cultured with adherent cells in the presence of OKT3 mab both produced GM-CSF and IFN-gamma and showed similar dose-response curves to OKT3 mab. The requirement for the presence of adherent cells could not be overcome by the addition of purified interleukin 1 or macrophage supernatants. Studies using irreversible inhibitors of DNA (mitomycin C) or protein biosynthesis (emetine-HCl) revealed the necessity of intact DNA synthesis and translation in mononuclear cells to produce GM-CSF in response to OKT3 mab. Loss of GM-CSF production was observed when either adherent cells or T lymphocytes were treated with emetine before co-culture with untreated cells of the other population in the presence of OKT3 mab. In contrast, mitomycin C reduced GM-CSF production significantly when T cells, but not adherent cells, were pretreated. These results suggest that T lymphocytes and adherent cells closely cooperate in the production of GM-CSF induced by OKT3 mab.     

Cell-sized, supported artificial membranes (pseudocytes): response of precursor cytotoxic T lymphocytes to class I MHC proteins

Novel cell-sized, supported artificial membranes bearing class I antigens have been prepared by a simple dialysis procedure and then used to study the requirements for antigen recognition by precursor cytotoxic T lymphocytes (CTL). The membranes were made by mixing lipid, H-2 antigen, and C18 alkylated 5 microns silica beads in deoxycholate, and dialyzing to remove the detergent. The H-2 antigen-bearing, cell-sized beads, termed pseudocytes (artificial cells), were able to simulate generation of secondary CTL responses with the same specificity as alloantigen-bearing spleen cells. Comparative analyses demonstrated that the size of an antigen-bearing structure, and thus its potential for multivalent interaction, was a critical determinant of effectiveness of antigen recognition, and showed that H-2 antigen was recognized as effectively on cell-sized beads as on allogeneic spleen cells. Generation of a response to antigen on the cell-sized beads was completely dependent on addition of lymphokines to the cultures. Thus, unlike liposomes, H-2 antigen on beads was not available to accessory cells for stimulation of Ia-dependent production of lymphokines by T helper cells. These results, as well as direct observations by microscopy, strongly indicate that antigen is recognized on the surface of the beads. Despite effective stimulation of secondary CTL responses, antigen on beads was completely inactive in stimulating a primary CTL response by naive spleen cells. The results of mixing experiments by using beads and alloantigen-bearing cells or plasma membrane vesicles indicate that the lack of a primary response may result from a requirement for a soluble factor(s) that is not needed for generation of secondary responses. The unique advantages of cell-size supported membranes for studying antigen recognition by T cells are discussed. The beads can be handled and used like antigen-bearing cells in functional assays, while possessing well-defined, readily varied, and easily quantitated composition.     

Liposome-Mediated Cytoplasmic Delivery of Proteins: An Effective Means of Accessing the MHC Class I-Restricted Antigen Presentation Pathway

Different types of liposomes have been employed to deliver soluble antigen for processing and presentation in the major histocompatibility complex class I-restricted pathway. Anionic pH-sensitive liposomes as well as cationic liposomes efficiently sensitize antigen-presenting cells for recognition by the class I-restricted cytotoxic T lymphocytes (CTL). Cytoplasmic delivery of liposome-entrapped antigen from an endocytic compartment allows the exogenous antigen to gain access to the class I presentation pathway. Cytoplasmic delivery, however, is probably not the only mechanism by which liposomes induce the class I-restricted CTL priming in vivo. Macrophages play a central role in the processing of the liposome-encapsulated antigens. The processed antigen fragments are probably released by the macrophages and taken up by the nearby dendritic cells for antigen presentation. Collaboration between the two types of immune cells with the help of the appropriate costimulatory factors is the central theme for this hypothesis. In this case, the host immune system utilizes the similar mechanism for other membranous, particulate antigens to process and present the liposomal antigens.     

Synergy among rat T cells in the proliferative response to alloantigen.

A synergistic interaction in the proliferative response to alloantigen is described for mixtures of rat thymus and lymph node cells. The optimal conditions for synergy are quantitatively defined. Regression analysis of the slope of the dose-response curve has been utilized to estimate the degree of interaction in thymus-lymph node cell mixtures. The slope of the response of cell mixtures was noted to be significantly greater than the slope for the response of lymph node cells alone. Irradiation was shown to have a differential effect on the response of thymus and lymph node cells in mixtures. Irradiated thymus cells retained the capacity for synergy in mixtures, whereas irradiated lymph node cells did not. Additional studies have demonstrated that both de novo protein synthesis and specific antigen recognition by both responding cell populations in mixtures was required for maximal synergy. These studies demonstrate that synergy cannot be explained as an artifact of altered cell density in vitro. They establish that thymus cells and lymph node cells represent distinct subsets which manifest qualitatively different functions in the proliferative response to alloantigen. Thymus cells can respond directly to alloantigen by proliferation but also have the capacity to amplify the proliferative response of lymph node cells—a capacity which is resistant to X irradiation but requires recognition of alloantigen and de novo protein synthesis. Lymph node cells may similarly respond by proliferation to alloantigen but lack the amplifier activity of thymus cells. Synergy for rat lymphoid cells, like mouse lymphoid cells, has been shown to involve an interaction of thymus-derived lymphocytes.     

Participation of lymphocyte activating factor (Interleukin 1) in the induction of cytotoxic T cell responses

The initiation of murine alloantigen-specific cytotoxic T cell responses is macrophage dependent. The requirement for macrophages can be replaced in macrophage-depleted cytotoxic T lymphocyte assay by a soluble factor released from phorbol myristic acetate-stimulated mouse peritoneal adherent cells or P388D1 macrophage tumor cells. On the basis of the cell of origin, m.w. (15,000), and elution profiles on DEAE cellulose and polyacrylamide gels, this macrophage-replacing factor for T cell-mediated cytotoxicity was identical to lymphocyte activating factor (LAF). The stimulatory effect of LAF was totally dependent on the presence of the priming alloantigen. The results presented in this report support the hypothesis that macrophage-mediated antigen-induced T cell activation is dependent on two signals, antigen and LAF.     

Adherent cell function in murine T lymphocyte antigen recognition. II. Definition of genetically restricted and nonrestricted macrophage functions in T cell proliferation.

The mechanisms by which adherent cells, presumably of mononuclear phagocytic lineage, influence in vitro antigen-specific activation of murine T lymphocytes was examined. Two distinct functions for macrophages could be discerned. One macrophage function is dependent on a soluble factor produced by cultured adherent cells and is most easily studied with complex multideterminant antigens. This factor is neither antigen-specific nor MHC-restricted in its action in that PEC, regardless of haplotype, produce factor in the absence of antigen. A second function, antigen-specific T cell activation, is seen when antigens of more restricted heterogeneity are used, such as those under the control of Ir genes. This latter activity demands identity or partial identity between the antigen-presenting cell and the primed T cell, thus suggesting an additional specific, genetically restricted function for macrophages in in vitro antigen recognition. Whether these adherent cell functions are mediated by all or distinct subsets of cells was not established.     

The effect of age on the antigen-presenting mechanism in limiting dilution precursor cell frequency analysis

We have utilized limiting dilution analysis (LDA)2 to compare the intrinsic precursor cytotoxic T lymphocyte (pCTL) frequency for influenza-plus-self in young and old C57BL/6 mice. Under conditions of excess interleukin 2 (IL-2) and antigen presenting cells (APC) derived from spleens of mice matched in age to those being tested, we found more than a twofold difference in pCTL frequency between young and old animals. However, there was no difference in pCTL frequency between the two age groups if antigen was presented to the old responder cells on spleen cells derived from young mice. The apparent decrease in pCTL frequency in old mice by standard LDA may in fact be due to a defect in the antigen processing and/or presentation mechanism of old spleen cells. We conclude that the age-associated defective CTL activity previously reported by us and by others may be due at least in part to a defect in the antigen presentation mechanism of aging mice.     

Trypanosoma cruzi: Responses by cells from infected mice to alloantigens

In unidirectional mixed lymphocyte cultures containing (as responders, stimulators, or regulators) spleen cells from mice infected with Trypanosoma cruzi, alloantigen responses were less than in cultures containing normal spleen cells only. Depletion of plastic adherent cells from infected spleen cells (stimulators or regulators) reversed their inhibitory effect on normal spleen cells (responders); removal of adherent responder cells and/or B lymphocytes did not alter the low alloantigen responses of normal spleen cells (stimulated by infected spleen cells) or infected spleen cells (stimulated by normal spleen cells). Infected spleen cells were effective in regulating mixed lymphocyte cultures only when added at the initiation of the culture. Serum from infected mice suppressed mixed lymphocyte cultures containing responder spleen cells syngeneic to the serum donor if added up to 24 hr after initiation of cultures, whereas the “suppressor serum” had to be present at the initiation of cultures when responder cells were allogeneic to the serum donor. Cultures of infected spleen cells (whole or macrophage enriched) produced a factor which was suppressive when added to mixed lymphocyte cultures containing syngeneic responder cells at initiation. It is proposed that the serum suppressor substance regulates cell-mediated immune responses directly by suppressing the response-potential of cells and indirectly by triggering the release of a factor from adherent splenic cells which induces a hyporesponsive state in T lymphocytes.     

Alloantigen bound to agarose beads and syngeneic carrier cells are capable of stimulating mouse cytolytic T lymphocytes in vitro.

Bead-bound antigen was prepared by coupling alloantigen covalently to agarose beads. Alloantigen-bearing syngeneic carrier cells were prepared by dilution of detergent solubilized alloantigen in the presence of syngeneic spleen cells. Both types of antigen were compared to spleen cells and reconstituted membrane fragments for the ability to stimulate cytolytic thymus-dependent lymphocytes in vitro. All these types of antigen could stimulate immune but not nonimmune spleen cells to form cytolytic T lymphocytes. The amount of lytic activity obtained with the bead-bound antigen was found to be only dependent upon the amount of H-2 antigen present in the culture and independent of the number of beads.     

T helper cell-dependent B cell activation.

Small, resting B lymphocytes are driven into the cell cycle as a consequence of receiving multiple signals from elements found within their local environment. The first of these signals results from the binding of specific antigen to membrane immunoglobulin (mIg) receptors on the B cells. Pursuant to antigen binding, signals are transduced and the B cell commences to endocytose and degrade the antigen. Fragments of the antigen are expressed on the B cell surface in noncovalent association with class II major histocompatibility complex (MHC) molecules. The antigen-class II MHC complex serves as a recognition complex for CD4+ helper T cells (Th). As a consequence of recognition, Th form stable physical conjugates with the B cells. Over an extended period of time the Th and B cells bilaterally signal one another. This interchange of signals results in the growth and differentiation of both cells. This review will discuss the sequence of events that culminate in the growth and differentiation of B lymphocytes to antibody-producing cells.     

Functional activation of immune lymphocytes by antigenic stimulation in cell-mediated immunity. IV. Role of macrophage and its soluble factor in antigen-induced MIF production of immune T lymphocytes.

Histocompatibility-linked restriction of macrophage-T lymphocyte interaction in antigen-induced MIF production by sensitized lymphocytes was examined, by using combinations of inbred strain 2, strain 13, and JY-1 guinea pigs. The effective interaction of the antigen-bearing macrophages with the immune T lymphocytes was observed when the donor of the antigen-bearing macrophages and that of the immune lymphocytes shared Ia antigens of the major histocompatibility complex. Identities of B antigens and S antigens were not important for this cooperation. It was further demonstrated that the previously reported soluble factor derived from LPS-stimulated peritoneal adherent cells (macrophages) could help antigenic activation of the immune lymphocytes across the strain barrier provided a small number of macrophages (0.01%) from syngeneic strain were present. These results show that the presence of macrophages is absolutely required to present antigen to immune T lymphocytes in a genetically restricted manner and the soluble factor from macrophages appears to give a nonspecific effect on the lymphocyte activation in addition to or in collaboration with antigenic stimulation.     

Generation of human plaque-forming cells in culture: tissue distribution, antigenic and cellular requirements.

A system for the induction of specific, hemolytic plaque-forming cells from normal human lymphocytes in vitro (HcPFC) has been established and cells from various normal lymphoid tissues have been investigated. Normal values for anti-SRBC HcPFC responses in cultures of 107 Ficoll-Hypaque separated lymphocytes range from 2000 (bone marrow) to 7000 (spleen) and 15,000 (tonsillar and peripheral blood lymphocytes). HcPFC responses to ovalbumin were lower by factor of 2 to 4. Anti-SRBC as well as anti-ovalbumin responses required the cooperation of T lymphocytes and IgM-bearing B lymphocytes and the magnitude of the response was antigen dose dependent. Addition of adherent cells as well as of 2-mercaptoethanol enhanced the response. On the basis of the data obtained in experiments examining the role of B and T lymphocytes, a tentative model of cellular interaction has been postulated, suggesting a major role for antigen concentration in the modulation of the response via reactive T lymphocytes.     

Defining cytolytic T lymphocyte recognition of chemically modified self. I. Response to trinitrophenyl-H-2Kk

We used purified class I antigen incorporated into liposomes to examine the response of secondary cytolytic T lymphocytes (CTL) to chemically modified self. By generating the secondary response in the presence of T cell helper factor, the level of CTL response was limited by CTL recognition of added antigen rather than by helper cell generation of lymphokines. We found a strong secondary response against chemically modified self when spleen cells from trinitrophenyl (TNP)-primed C3H/HeJ mice were stimulated with a) TNP-modified liposomes containing H-2Kk, b) liposomes containing H-2Kk purified from TNP-modified RDM-4 (H-2k) cells, or c) liposomes containing the limited trypsin proteolysis product of H-2Kk that had been directly modified with TNP. In contrast, we were not able to generate a significant CTL response with unmodified H-2Kk incorporated into vesicles along with TNP-modified membrane components lacking H-2Kk. These results suggest that TNP-modified H-2Kk is a major antigenic site recognized by CTL from C3H/HeJ mice after priming against TNP-modified self.     

Suppression of cytotoxic lymphocyte responses in vitro by soluble products of alloantigen-activated spleen cells.

Suppression of in vitro cytotoxic lymphocyte (CL) responses was mediated by soluble factor(s) produced when in vivo alloantigen-activated suppressor cells were re-exposed to alloantigen in vitro. Elaboration of suppressor factor (SF) was T cell dependent and was optimal 7 days after alloantigen injection. Suppressor factor failed to inhibit CL generation when alloantigen-primed cells rather than normal spleen cells were used as responders. Moreover, SF added at day 3 of incubation rather than at culture initiation was also ineffective, suggesting that suppression probably occurs during antigen induction or early differentiation. Additionally, suppression was abrogated by the presence of 2-mercaptoethanol. Studies combining SF and CL responder cells from a variety of H-2 disparate mouse sdrains revealed that suppression of CL responses: 1) was not alloantigen specific; 2) did not require H-2 homology between responder and suppressor strains; and 3) could not be demonstrated with CBA/J mice. Although CBA/J CL responses were not suppressed by any SF preparation, allo-sensitized CBA/J spleen cells did elaborate SF that inhibited BALB/c CL responses.     

Astrocytes as antigen-presenting cells. I. Induction of Ia antigen expression on astrocytes by T cells via immune interferon and its effect on antigen presentation

Ia antigens seem to control immune responses on at least two levels. First, they influence the antigen recognition repertoire of the T cells. Second, their variable expression on certain antigen-presenting cells is a powerful regulatory mechanism for the local immune reaction. This is particularly important in the central nervous system (CNS) in which no Ia antigens are normally expressed. Recent experiments in this context have shown that astrocytes are able to express Ia antigens during interaction with T cells, and that they function as antigen-presenting cells. The Ia-inducing activity is produced by activated T cells, and can be replaced by immune interferon (IFN-gamma). In this study we report on the functional and kinetic relationship between Ia antigen expression on astrocytes and the immune-specific activation of T cells by astrocytes. Normal resting astrocytes were found to be negative for Ia antigens by immunofluorescence and by biochemical criteria. Moreover, they are only able to stimulate T cells after they have been induced to express Ia antigens by a signal from the T cells, which is probably mediated by IFN-gamma. In conclusion, the immune-specific interaction between astrocytes and T lymphocytes is a sensitively controlled system that might be pivotal to the development of immune responses in the brain. Malfunction of the system could be an important factor in the pathogenesis of aberrant immune reactions in the CNS, e.g., in multiple sclerosis.