Induction of antigen-specific regulatory T cells following overexpression of a Notch ligand by human B lymphocytes

In mice, activation of the Notch pathway in T cells by antigen-presenting cells overexpressing Notch ligands favors differentiation of regulatory T lymphocytes responsible for antigen-specific tolerance. To determine whether this mechanism operates in human T cells, we used Epstein-Barr virus-positive lymphoblastoid cell lines (EBV-LCL) as our (viral) antigen-presenting cells and overexpressed the Notch ligand Jagged-1 (EBV-LCL J1) by adenoviral transduction. The EBV-LCL J1s were cocultured with autologous T cells, and the proliferative and cytotoxic responses to EBV antigens were measured. Transduction had no effect on EBV-LCL expression of major histocompatibility complex (MHC) antigens or of costimulatory molecules CD80, CD86, and CD40. However, we observed a 35% inhibition of proliferation and a >65% reduction in cytotoxic-T-cell activity, and interleukin 10 production was increased ninefold. These EBV-LCL J1-stimulated T lymphocytes act as antigen-specific regulatory cells, since their addition to fresh autologous T cells cultured with autologous nontransduced EBV-LCL cells significantly inhibited both proliferation and cytotoxic effector function. Within the inhibitory population, CD4(+)CD25(+) and CD8(+)CD25(-) T cells had the greatest activity. This inhibition appears to be antigen-specific, since responses to Candida and cytomegalovirus antigens were unaffected. Hence, transgenic expression of Jagged-1 by antigen-presenting cells can induce antigen-specific regulatory T cells in humans and modify immune responses to viral antigens.     

CD4+ proliferative T-cell clones reactive to autologous Epstein-Barr virus-transformed B cells (EBV-LCL) can be restricted by HLA class I molecules

In this study, we show that an HLA-loss variant, EBV-LCL .180, which lacks HLA-DR, DP, DQ and B determinants but expresses HLA-A and C molecules, can activate autologous proliferative T cells which recognize EBV-LCL antigens (or LYDMA). T-cell clones isolated from bulk culture (A.180) of T cell primed with autologous variant .180 when tested for their proliferative reactivity to .180 and three autologous class I-loss variants, each lacking specific class I determinants, showed requirement for class I HLA molecules. Clones A.180.Cl and A.180.F3D respond to the A2+, B-null, C+ mutant .53, but not to the A-null, B5+, C+ mutant .144, or the A-null, B-null, C+ mutant .184, indicating that these clones are restricted by an HLA-A2 determinant. These proliferative T-cell clones express the CD4 marker and are noncytotoxic, even in the presence of concanavalin A (Con A) lectin. In coculture experiments, A.180.Cl was further shown to provide lymphokine "help" for EBV-LCL-specific, autologous cytotoxic T-cell clones. These results suggest the repertoire of HLA determinants employed by EBV-LCL-specific proliferative T cells, in addition to the previously shown HLA-DR, DP, and DQ determinants, also includes class I molecules.     

Activation requirements of cloned inducer T cells. II. The failure of some clones to respond to antigen presented by activated B cells

Inducer/helper T cells recognize nominal antigen in association with Ia on the surface of the antigen-presenting cell (APC). Recent studies have shown that B cells can effectively function as APC. In the present study we have assessed the ability of cloned inducer T cells to discriminate between activated B cells or splenic macrophages as APC. We found that most of the clones tested demonstrated an equivalent response to antigen presented by activated B cells or splenic adherent cells. Some clones were very efficiently stimulated by antigen presented by activated B cells, whereas other clones failed to respond or responded very poorly when activated B cells were used to present antigen. We attempted to determine the mechanism responsible for the inability of certain clones to proliferate in response to antigen presented by activated B cells.     

Serological and biological cross-reactivity of class II antigens between mice and humans in antigen-specific T-cell proliferative responses

Many studies have already been reported with regard to the serological cross-reactivities between the polymorphic determinants of murine Ia antigens and human HLA-DR antigens. In this paper, we examined the biological cross-reactivity of the polymorphism of Class II antigens in the xenogeneic antigen-presenting cell (APC)-T-cell interaction. The data indicate that purified protein derivative (PPD)-specific human T cells were not stimulated by PPD-pulsed murine APC from B10.S(9R) which possess I-As and I-Ek molecules serologically cross-reacting with human Class II antigens. On the contrary, B10.S(9R) T cells primed to PPD were stimulated by PPD-pulsed human APC. The failure of the murine APC-human T-cell interaction was not caused by the suppressive effect in culture with ongoing xenogeneic mixed lymphocyte reactions (MLR) or other cell culture conditions. Thus, a hierarchy of antigen-presenting ability in the xenogeneic APC-T-cell interaction was shown to exist.     

Oxidative stress impairs intracellular events involved in antigen processing and presentation to T cells

For T cells to recognize foreign antigens, the latter must be processed into peptides and associated to major histocompatibility complex (MHC) class II molecules by antigen-presenting cells (APC). APCs frequently operate under stress conditions induced by tissue damage, antigens, or inflammatory reactions. We analyze the effects of oxidative stress on intracellular processing using APC B cell lines. Before being tested for APC function, B cells (IIA1.6) were exposed for 2 hours to hydrogen peroxide (H2O2), a treatment that impairs their capacity to stimulate specific T cell clones. Because paraformaldehyde-fixed H2O2-treated B cells can still present extracellular peptides to T cell clones, the intracellular events of processing were investigated. Purified lysosomes from H2O2-treated B cells show increased proteolytic activity and increased generation of antigenic peptides. In addition, H2O2 treatment targets antigens to compartments that express low levels of MHC II and proteins (H-2M, H-2O) required for peptide loading onto this molecule. Finally, we suggest that impairment of antigen processing by oxidative stress reduces the induction of a T cell's response because H2O2 decreases the activation of naive T lymphocytes by dendritic cells. Together, these data indicate that oxidative stress inhibits the capacity of APCs to process antigens and to initiate a primary T cell response. The role of such modifications on the outcome of the specific immune response is discussed.     

Can resting B cells present antigen to T cells?

Antigen stimulation of T lymphocytes can occur only in the presence of an antigen-presenting cell (APC). An ever-increasing number of cell types have been found to act as APCs; these include macrophages, splenic and lymph node dendritic cells, and Langerhans' cells of the skin. Although activated B lymphocytes and B cell lymphomas are known to serve as APCs, it has been generally believed that resting B cells cannot perform this function. However, in recent studies we have found that resting B cells can indeed present soluble antigen to T cell clones as well as to antigen-primed T cells. The previous difficulty in demonstrating this activity can be explained by the finding that, in contrast to macrophages and dendritic cells, the antigen-presenting ability of resting B cells is very radiosensitive. Macrophages are usually irradiated with 2000-3300 rads to prevent them from incorporating [3H]thymidine in the T cell proliferation assay. Resting B cells, however, begin to lose presenting function at 1500 rads and have completely lost this activity at 3300 rads. It was also possible to distinguish two distinct T cell clonal phenotypes when resting B cells were used as APCs on the basis of two different assays (T cell proliferation, and B cell proliferation resulting from T cell activation). The majority of T cell clones tested were capable of both proliferating themselves and inducing the proliferation of B cells. Some T cells clones, however, could not proliferate in the presence of antigen and B cell APCs, although they were very good at inducing the proliferation of B cells. This suggests that there are two distinct pathways of T cell activation, one leading to T cell proliferation and the other leading only to the release of lymphokines (as measured by the polyclonal activation of B cells).     

Human T cell receptor-gamma delta-expressing T-cell lines recognize MHC-controlled elements on autologous EBV-LCL that are not HLA-A, -B, -C, -DR, -DQ, or -DP.

HLA-loss variants of an EBV-transformed B lymphoblastoid cell line (EBV-LCL) 721 were used to investigate whether human MHC molecules other than known class I or class II were involved in autologous T cell responses. Bulk lymphocyte cultures of purified T cells primed to an autologous variant EBV-LCL that fails to express HLA-class II and has reduced cell surface HLA-class I expression, and oligoclonal TCR-gamma delta-bearing lines derived from them, could lyse both this EBV-LCL and an independently derived, class II expressing autologous variant EBV-LCL that bears no HLA-A, -B, or -C, suggesting the presence of additional HLA-like restriction elements. Cold target inhibition of cytolysis mediated by these lines indicated that a shared or cross-reactive MHC controlled restriction element other than the known MHC determinants was retained by the EBV-LCL variants. Single-cell derived clones from these T cell lines which expressed only the TCR-gamma delta showed this same target cell specificity pattern, proving recognition of MHC-controlled determinants by autologous gamma delta T cells. Anti-gamma delta antibody could inhibit cytolysis by the gamma delta-expressing lines, suggesting that the TCR-gamma delta was involved in recognition of the EBV-LCL targets. Flow cytometric analysis with separate HLA-reactive antibodies indicated that the restriction element for these cytolytic responses is a molecule serologically cross-reactive with HLA-B and -C Ag, yet is a determinant that cannot be HLA-A, -B, -C, -DR, -DQ or -DP.     

Hepatitis B virus (HBV)-specific cytotoxic T-cell (CTL) response in humans: characterization of HLA class II-restricted CTLs that recognize endogenously synthesized HBV envelope antigens.

In this study, we show that CD4+, hepatitis B virus (HBV) envelope-specific T-cell clones produced by stimulation with a particulate antigen preparation are able to recognize and kill not only autologous antigen-presenting cells incubated with exogenous HBV envelope antigens but also autologous HLA class II-positive cells expressing endogenously synthesized HBV envelope antigens following infection with recombinant vaccinia viruses or transfection with recombinant Epstein-Barr virus expression vectors. Experiments with lysosomotropic agents and brefeldin A suggest that the endosomal compartment is likely involved in the processing of endogenously synthesized viral proteins for recognition by CD4+ T cells. Our study indicates that HBV envelope-specific, HLA class II-restricted CD4+ cytotoxic T lymphocytes can potentially participate in the immune clearance of HBV-infected cells and the pathogenesis of hepatocellular injury in hepatitis B.     

Human myelin basic protein-specific cytolytic T lymphocyte clones are functionally restricted by HLA class II gene products

Cellular immune reactions against the autoantigen myelin basic protein (MBP) are strongly implicated in the occurrence of postinfectious and postvaccination encephalomyelitis. Clinical autoimmune encephalomyelitis in experimental animals can be transferred with cloned MBP-specific cytolytic major histocompatibility complex Class II-restricted T lymphocytes. The HLA restriction pattern of specific proliferative and cytolytic functions of two human MBP-specific cytotoxic T lymphocyte clones, derived from two different multiple sclerosis patients, was analyzed in detail. Using monoclonal antibodies against various HLA gene products and allogeneic Epstein-Barr virus-transformed B cells as antigen-presenting cells and as targets for cytolysis, it was found that MBP-specific functions of the T cell clones was restricted by HLA class II antigens, and, more specifically, by molecules encoded for by DR locus genes.     

Theileria parva: bovine helper T cell clones specific for both infected lymphocytes and schizont membrane antigens

Two Theileria parva-specific bovine helper T cell clones were used to identify T. parva-derived antigens expressed on the surface of schizont infected lymphoblastoid cells. Although the clones proliferated in response to both the immunizing (Muguga) and heterologous stocks of T. parva, the patterns of the responses differed, showing that the two clones recognized different antigenic epitopes. Both clones were stimulated by autologous infected cells, without an additional source of antigen-presenting cells, as well as by purified schizonts and by a subcellular membrane fraction prepared from infected lymphoblastoid cells, when antigen-presenting cells were present. The membrane fraction was shown to be enriched for schizont membranes as indicated by the presence of a schizont surface antigen detected by immunoblotting using a schizont-specific monoclonal antibody. Elimination of schizonts with the anti-theilerial drug, parvaquone, resulted in reduced antigenicity of the membrane fraction as detected by both the T cell clones and the schizont-specific monoclonal antibody. We conclude that the T. parva-infected cell surface antigens recognized by the T cell clones are of schizont membrane origin. Although the antigens have not yet been characterized biochemically, the monoclonal antibody-specific epitope appears to be distinguishable from the T cell epitopes.     

Epstein-Barr virus-transformed lymphoblastoid cell lines as antigen-presenting cells and "augmenting" cells for human CMV-specific Th clones

The ability of Epstein-Barr virus-transformed lymphoblastoid cell lines (LCL) to present human cytomegalovirus (HCMV) antigen to a panel of HCMV-specific T helper (Th) clones was evaluated. Among the seven Th clones studied, only one clone (SP-CN/T3-16) proliferated well to HCMV presented by both autologous mononuclear cells (MNC) and LCL, and one clone (SP-CN/T3-9) proliferated significantly better to HCMV presented by autologous LCL than by autologous MNC. The majority of the HCMV-specific Th clones tested (five out of seven) responded much better to HCMV presented by MNC than to HCMV presented by LCL. The mechanism(s) responsible for the inefficiency of LCL to present HCMV to certain clones was studied. Our results suggested that the defect of LCL is not due to insufficient interleukin 1 production, insufficient MHC class II molecule expression, nor an inhibitory mechanism or factor. In this report, we also demonstrate that by adding a minimum amount of LCL along with MNC as antigen-presenting cells (APC), one can restimulate and expand Th clones much more efficiently than by using MNC alone as APC.     

Receptor-mediated B cell antigen processing. Increased antigenicity of a globular protein covalently coupled to antibodies specific for B cell surface structures

Helper T cell recognition of globular protein antigens requires the intracellular processing of the native molecule by an antigen-presenting cell and subsequent presentation of a peptide fragment, containing the antigenic determinant, on the cell surface where it is recognized by the specific T cell in conjunction with Ia. B lymphocytes can function as antigen-presenting cells and, when antigen is bound by their surface Ig, are greatly enhanced in this capacity. In this report it is demonstrated that pigeon cytochrome c covalently coupled to antibodies directed toward either B cell surface immunoglobulin, class I or class II are effectively processed and presented by B cells to cytochrome c-specific T cells, requiring up to 1000-fold less cytochrome c as compared with cytochrome c alone or cytochrome c coupled to nonspecific immunoglobulin. The potent activity of the cytochrome c-antibody conjugates appears to be due to the ability of B cells to concentrate the antigen when the process becomes receptor mediated rather than to a signal provided to the B cell by the conjugate binding, because cytochrome c was not more effectively presented in the presence of unconjugated antibodies as compared with cytochrome c alone. Furthermore, the binding of the native antigen to B cell surfaces is not alone sufficient for T cell activation, in that the cytochrome c-antibody conjugates require processing and are major histocompatibility complex restricted. The results presented here indicate that surface immunoglobulin is not unique in its ability to facilitate antigen processing and/or presentation and that Ig, class I and class II are capable of transporting the cytochrome c to a cytoplasmic vesicle where proteolysis occurs yielding the required peptide, minimally of 10 amino acids. Cytochrome c coupled to monovalent fragments of anti-Ig-antibodies was nearly as effectively presented as cytochrome c coupled to bivalent antibodies, indicating that phenomena mediated by bivalent binding, such as patching and capping of the surface Ig, were not required for effective antigen presentation. The cytochrome c-antibody conjugates, which allow antigen processing to be initiated by receptor-mediated endocytosis, may provide the necessary tools to unravel the intracellular processes by which protein antigens are processed and presented by B lymphocytes.     

Specific Schistosoma mansoni rat T cell clones. I. Generation and functional analysis in vitro and in vivo

In an attempt to determine the role of schistosome-specific T cells in the immune mechanisms developed during schistosomiasis, Schistosoma mansoni-specific T cells and clones were generated in vitro and some of their functions analyzed in vitro and in vivo in the fischer rat model. The data presented here can be summarized as follows: a) Lymph node cells (LNC) from rats primed with the excretory/secretory antigens-incubation products (IPSm) of adult worms proliferate in vitro only in response to the homologous schistosome antigens and not to unrelated antigens (Ag) such as ovalbumin (OVA) or Dipetalonema viteae and Fasciola hepatica parasite extracts. b) After in vitro restimulation of the primed LNC population with IPSm in the presence of antigen-presenting cells (APC) and maintenance in IL 2-containing medium, the frequency of IPSm-specific T cells is increased and the T cells can be restimulated only in the presence of APC possessing the same major histocompatibility complex (MHC) antigens. c) Following appropriate limiting dilution assays (LDA) (1 cell/well), 10 IPSm-specific T cell clones were obtained, and two of four maintained in culture were tested for their helper activity because they expressed only the W3/13+ W3/25+ surface phenotypes. d) The two highly proliferating IPSm-specific T cell clones (G5 and E23) exhibit an IPSm-dependent helper activity, as shown by the increase in IgG production by IPSm-primed B cells. e) IPSm-T cell clone (G5) as well as IPSm-T cell lines when injected in S. mansoni-infested rats can exert an in vivo helper activity, which is characterized by an accelerated production of IgG antibodies specific for the previously identified 30 to 40 kilodaltons (kd) schistosomula surface antigens (Ag). As recent studies have demonstrated that rat monoclonal antibodies recognize some incubation products of adult S. mansoni as well as one of the 30 to 40 kd schistosomula surface antigens, and taking into account the fact that the T cell clones here studied were restimulated either with IPSm or with schistosomulum Ag, it appears that such IPSm-specific T cell clones could be involved in the concomitant immunity mechanisms.     

Antigen-presenting B cells: efficient uptake and presentation by activated B cells for induction of cytotoxic T lymphocytes against vesicular stomatitis virus

We have evaluated the efficacy of mitogen (LPS/DxSO4)-activated B cells (B lymphoblasts) to function as antigen-presenting cells (APC) for vesicular stomatitis virus (VSV). Our studies revealed that B lymphoblasts induced potent cytotoxic thymus (T)-derived lymphocyte (CTL) activity in VSV-immune splenic T cells depleted of adherent accessory cells. Dose-response curves indicated that B lymphoblasts were approximately 15-20 times more efficient APC than spleen cells for CTL induction against VSV. There was little evidence of reprocessing of viral antigens by the responder population because only CTL activity restricted to the parental haplotype of the B lymphoblast was generated following stimulation of VSV-immune F1 T cells. B lymphoblasts activated VSV-specific memory CTL which expressed the Lyt-1-23+, AsGM1+ phenotype without activating natural killer and/or lymphokine-activated killer cells. The ability of B lymphoblasts to function as efficient APC was not related to enhanced viral replication in these cells because potent VSV-specific proliferative and class I-restricted CTL responses were induced by B lymphoblasts infected with VSV rendered noninfectious by exposure to ultraviolet (uv) light. This indicates that activated B cells can efficiently process and present input virion protein. Purified splenic B cells that were not activated by mitogen stimulation did not function as APC for VSV even at high multiplicities of infection. The failure of B cells to function as APC for VSV was related to inefficient uptake of VSV and their inability to provide accessory cell signals required for T-cell proliferation; both these functions developed following mitogen stimulation. These data suggest that activated B cells may function as a potent APC population for virus independent of the specificity of their immunoglobulin antigen receptor.     

I-Region genetic restrictions imposed upon the recognition of KLH by murine T-cell clones

Data presented in this paper show that the recognition of keyhole limpet hemocyanin by murine T-cell clones is restricted by products of the I region. These data have been obtained by genetic mapping studies as well as by the use of monoclonal la-specific antibodies which inhibit the ability of antigen-presenting cells to effectively present antigen to such T-cell clones. Use of heterozygous antigen-presenting cells derived from crosses between B6.C-H-2 ^bm12 and B10.A(4R) mice have allowed us to show that both trans-complementing I-A products are used for restriction of recognition of KLH. These data were confirmed using monoclonal Ia antibodies to inhibition recognition of KLH by the same T-cell clones. Thus, we have shown that there exist hybrid molecules formed by free combinatorial association of products encoded within the I-A subregion which restrict the recognition of soluble antigen. Additionally, we have shown that the molecule formed by complementation between the alpha chain encoded within the I-E region and a beta chain encoded within the A region (A_e) can function effectively in presenting KLH to certain murine T-cell clones. These results support the hypothesis that the recognition of individual antigenic epitopes within large multideterminant antigens is under the control of Ir genes.     

Epstein-Barr virus-transformed B cells process and present Mycobacterium tuberculosis particulate antigens to T-cell clones

We have analyzed the presentation of mycobacterial antigens by Epstein-Barr virus-transformed human B (EBV-B) cells to mycobacteria-specific T-cell clones and lines, and to purified resting T cells. EBV-B cells were able to process and present not only soluble forms of antigen, such as PPD and the expressate preparation of M. tuberculosis strain H37Rv, but also particulate forms of antigen, such as whole mycobacterial H37Rv or M. bovis organisms. Electron microscopy studies demonstrated the capacity of EBV-B cells to phagocytose mycobacterial cells in 18 hr and pulsing experiments confirmed that an 18-hr of incubation is required for an efficient processing and presentation of mycobacterial determinants to T cells. The processing of whole-H37Rv particulate antigen by EBV-B cells was inhibited by the lysosomotrophic compound chloroquine and by high doses of irradiation. Finally, the analysis of the presentation of soluble and particulate mycobacterial antigens by PPD-positive and PPD-negative EBV-B cell clones has shown a preferential presentation of both forms of antigen by PPD-positive EBV-B clones.     

Identification of two T-cell epitopes on the candidate Epstein-Barr virus vaccine glycoprotein gp340 recognized by CD4+ T-cell clones.

Current efforts to develop an Epstein-Barr virus subunit vaccine are based on the major envelope glycoprotein gp340. Given the central role of CD4+ T cells in regulating immune responses to subunit vaccine antigens, the present study has begun the work of identifying linear epitopes which are recognized by human CD4+ T cells within the 907-amino-acid sequence of gp340. A panel of gp340-specific CD4+ T-cell clones from an Epstein-Barr virus-immune donor were first assayed for their proliferative responses to a series of truncated gp340 molecules expressed from recombinant DNA vectors in rat GH3 cells, by using an autologous B lymphoblastoid cell line as a source of antigen-presenting cells. The first four T-cell clones analyzed all responded to a truncated form of gp340 which contained only the first 260 N-terminal amino acids. These clones were subsequently screened for responses to each of a panel of overlapping synthetic peptides (15-mers) corresponding to the primary amino acid sequence of the first 260 N-terminal amino acids of gp340. One clone (CG2.7) responded specifically to peptides from the region spanning amino acids 61 to 81, while three other clones (CG5.15, CG5.24, and CG5.36) responded specifically to peptides from the region spanning amino acids 163 to 183. Work with individual peptides from these regions allowed finer mapping of the T-cell epitopes and also revealed the highly dose-dependent nature of peptide-induced responses, with inhibitory effects apparent when the most antigenic peptides were present at supraoptimal concentrations. Experiments using homozygous typing B lymphoblastoid cell lines as antigen-presenting cells showed that the T-cell clones with different epitope specificities were restricted through different HLA class II antigens; clone CG2.7 recognized epitope 61-81 in the context of HLA DRw15, whereas clones CG5.15, CG5.24, and CG5.36 recognized epitope 163-183 in the context of HLA DRw11. The present protocol therefore makes a systematic analysis of CD4+ T-cell epitopes within gp340 possible; it will be necessary to screen gp340-specific T-cell clones from a variety of donors to assess the wider influence of HLA class II polymorphism upon epitope choice.     

Recognition of noninfectious influenza virus by class I-restricted murine cytotoxic T lymphocytes

We have recently shown that murine target cells can be sensitized for lysis by class I-restricted influenza virus-specific cytotoxic T lymphocytes (CTL) using noninfectious influenza virus. Sensitization is dependent on inactivation of viral neuraminidase activity (which can be achieved by heating virus); and requires fusion of viral and cellular membranes. In the present study, we have examined recognition of antigens derived from heat-treated virus by cloned CTL lines induced by immunization with infectious virus. Target cells sensitized with heat-treated virus were recognized by all 11 CTL clones that were specific for internal virion proteins (nucleoprotein and basic polymerase 1), and by one of six clones specific for the major viral glycoprotein (the hemagglutinin). Immunization of mice with heat-treated virus primed their splenocytes for secondary in vitro CTL responses. CTL generated in this manner recognized target cells infected with recombinant vaccinia virus expressing cloned influenza virus gene products. These findings indicate that both integral membrane proteins and internal proteins that comprise virions can be processed by antigen-presenting cells for recognition by class I-restricted CTL. It also appears that not all hemagglutinin determinants recognized on virus-infected cells are presented by cells sensitized with heat-treated virus.     

Antigen presentation in acquired immunological tolerance

In acquired tolerance, previous exposure to antigen under certain conditions induces specific unresponsiveness instead of specific immunological memory. It has been studied as an approach to the mechanisms of self-tolerance that operate on immunocompetent T and B lymphocytes once they leave their sites of origin in the thymus and the bone marrow. Possible mechanisms involve induction of specific suppressor cells or inactivation of antigen-specific lymphocytes (clonal anergy) as a consequence of abortive antigen presentation, in which the antigen receptor is effectively engaged but certain poorly defined accessory signals the T lymphocytes require are lacking. We propose that small, resting B lymphocytes, which lack these accessory signals, are the inactivating antigen-presenting cells in acquired tolerance to proteins and to the class II transplantation antigens. B lymphocytes, which can use their antigen receptors to gather and process antigens that are present at very low concentrations, may play a role in self-tolerance. In addition, B lymphocytes and T lymphocytes rendered anergic by encounter with self antigens could persist as self-specific suppressor cells to block an autoimmune response of autoreactive clones that had escaped deletion or anergy.     

Human Antigen-Presenting Cells: Characterization of the Cells in the T-Lymphocyte Proliferative Response

Human antigen-presenting cells (APC) which present the antigen to T lymphocytes resulting in a T-lymphocyte proliferative response were found among peripheral mononuclear cells (MNC), by employing purified protein derivative (PPD) as soluble antigen. To assess the adherence capacity of human antigen-presenting cells, MNC were separated by plastic Petri dishes or nylon wool columns. Plastic nonadherent cells were almost equivalent to unseparated cells in antigen-presenting ability. Plastic adherent cells, however, showed better antigen-presenting ability than unseparated cells. On the other hand, cells passed over nylon wool columns showed essentially no ability to present PPD to T lymphocytes. Removal of phagocytic cells by carbonyl iron resulted in about 50–70% reduction in antigen-presenting ability. Carrageenan, which is known to be toxic to macrophages, had no effect on APC. By using both rabbit anti-human Ia-like antiserum and alloantiserum specific for HLA-DR phenotype and complement, it was shown that APC possessed Ia-like antigens, whereas they did not bear surface immunoglobulins. These results indicate that the human APC is probably a cell in the monocyte-macrophage lineage. Allogeneic MNC were used as APC in order to determine whether any genetic restriction exists between MNC as APC and responding T lymphocytes. Optimal stimulation was shown to require identity of mixed leukocyte reaction (MLR)-activating determinants between APC and T lymphocytes. It is, however, obscure whether an HLA-D region restriction exists in these combinations because PPD-pulsed allogeneic MNC lost their ability to elicit even MLR. It is possible that this failure to elicit MLR was caused by T lymphocytes among the MNC used as APC.