The B cell is the initiating antigen-presenting cell in peripheral lymph nodes

We have examined the role of B cells in antigen presentation in lymph nodes in several ways. We found that mice depleted of B lymphocytes via chronic injection of anti-mu-chain antibody do not mount peripheral lymph node T cell proliferative responses to normally immunogenic doses of antigen. Depletion of B cells by passage of immune lymph node cells over anti-immunoglobulin columns early after immunization depletes antigen-presenting function from draining lymph nodes, and this function can be restored by using B cells or splenic adherent cells to allow the remaining T cells to proliferate. Lymph node B cells present antigen very effectively to lines of antigen-specific T cells. However, unfractionated lymph node cells from anti-mu-treated mice present very poorly, if at all, whereas unfractionated spleen cells from the same mice do present antigen. This is in keeping with our previous finding that helper T cell function in the spleen is normal in B cell-deprived mice. Finally, when mice homozygous for the lymphoproliferative gene lpr are treated chronically with anti-mu-chain antibody, lymphadenopathy is greatly retarded, suggesting a role for B cells in the massive proliferation of T cells in this syndrome. From this analysis, it would appear that the initiating antigen-presenting cell in the lymph node is a B lymphocyte, and that B lymphocytes in lymph nodes may be distinct from those in the spleen. It is of interest that these results also suggest that the lymph node lacks an antigen-presenting cell that is found in the spleen, perhaps the dendritic cell.     

In vivo treatment with monoclonal anti-I-A antibodies: disappearance of splenic antigen-presenting cell function concomitant with modulation of splenic cell surface I-A and I-E antigens

A single injection of anti-I-Ak antibody (AB) into H-2k mice resulted in abrogation of splenic antigen-presenting cell (APC) function for protein antigen-primed T cells or alloantigen-specific T cells. Spleen cells from anti-I-A-treated mice are not inhibitory in cell mixing experiments when using cloned antigen-specific T cells as indicator cells, thus excluding a role for suppressor cells in the observed defect. Also, nonspecific toxic effects and carry-over of blocking Ab were excluded as causes for the defect. Experiments with anti-I-Ak Ab in (H-2b X H-2k)F1 mice showed abrogation of APC function for T cells specific for both parental I-A haplotypes. In homozygous H-2k mice, anti-I-Ak treatment not only abrogated APC function for I-Ak-restricted cloned T cells but also for I-AekE alpha k-restricted cloned T cells. FACS analysis of spleen cells from anti-I-Ak-treated (H-2b X H-2k)F1 mice revealed the disappearance of all Ia antigens (both I-A and I-E determined), whereas the number of IgM-bearing cells was unaffected. The reappearance of APC function with time after injection was correlated with the reappearance of I-A and I-E antigen expression. In vitro incubation of spleen cells from anti-I-A-treated mice led to the reappearance of Ia antigen expression and APC function within 8 hr. Thus, it appears that B cells (as determined by FACS analysis) and APC (as determined by functional analysis) behave similarly in response to in vivo anti-I-A Ab treatment. We interpret these findings as suggesting that in vivo anti-I-A treatment temporarily reduces the expression of Ia molecules through co-modulation on all Ia-bearing spleen cells, thereby rendering them incompetent as APC. Such modulation of Ia molecules does not occur when spleen cells are incubated in vitro with anti-I-A antibodies. These results imply that a primary defect purely at the level of APC in anti-I-A-treated mice may be responsible for the observed T cell nonresponsiveness when such mice are subsequently primed with antigen.     

T and B cell recovery in arthritis adoptively transferred to SCID mice: antigen-specific activation is required for restoration of autopathogenic CD4+ Th1 cells in a syngeneic system

T cell homeostasis is a physiological function of the immune system that maintains a balance in the numbers and ratios of T cells at the periphery. A self-MHC/self-peptide ligand can induce weak (covert) signals via the TCR, thus providing an extended lifespan for naive T cells. A similar mechanism is responsible for the restoration of immune homeostasis in severe lymphopenic conditions such as those following irradiation or chemotherapy, or upon transfer of lymphocytes to nu/nu or SCID mice. To date, the genetic backgrounds of donor and recipient SCID mice were unmatched in all autoimmune arthritis transfer experiments, and the recovery of lymphoid cells in the host has not been followed. In this study, we present the adoptive transfer of proteoglycan (PG)-induced arthritis using unseparated and T or B cell-depleted lymphocytes from arthritic BALB/c donors to genetically matched syngeneic SCID recipient mice. We demonstrate that selectively recovered lymphoid subsets determine the clinical and immunological status of the recipient. We found that when T cells were depleted (>98% depleted), B cells did not produce PG-specific anti-mouse (auto) Abs unless SCID mice received a second Ag (PG) injection, which promoted the recovery of Ag-specific CD4(+) Th1 cells. Reciprocally, as a result of B cell recovery, high levels of serum anti-PG Abs were found in SCID mice that received B cell-depleted (>99% depleted) T lymphocytes. Our results indicate a selective and highly effective cooperation between CD4(+) T cells and B lymphocytes that is required for the restoration of pathological homeostasis and development of autoimmune arthritis in SCID mice.     

Antigen presentation by human antigen-presenting cells to antigen-specific xenogeneic murine T cells

Successful antigen presentation by xenogeneic human antigen-presenting cells (APC) to stimulate the proliferation of antigen-specific, keyhole limpet hemocyanin (KLH)-specific, ovalbumin (OVA)-specific, and purified protein derivative of Mycobacterium tuberculosis (PPD)-specific murine T cells was observed. Evidence indicating a direct cell interaction between antigen-specific murine T cells and xenogeneic human APC was given by experiments using antigen-specific murine T cell clones. The OVA-specific B10.S(9R) T cell line (9-0-A1) and PPD-specific B10.A(4R) T cell line (4-P-1) were stimulated by both xenogeneic human APC and murine APC from syngeneic or I-A compatible strains, while the PPD-specific human T cell line (Y-P-5) was stimulated by autologous human APC but not by murine APC. Anti-HLA-DR monoclonal antibodies (MoAb) blocked the xenogeneic human APC-antigen-specific murine T cell clone interaction. Thus, human xenogeneic APC can stimulate antigen-specific murine T cells through HLA-DR molecules in the same manner as syngeneic murine APC do through Ia molecules coded for by the I region of the H-2 complex, while murine APC failed to present antigen to stimulate human antigen-specific T cells.     

LPS and specific T cell responses: interleukin 1 (IL 1)-independent amplification of antigen-specific T helper (TH) cell proliferation

Lipopolysaccharide (LPS) fraction of endotoxin induces a significant potentiation of the antigen-specific proliferative response of T helper (TH) cell lines. This effect was obtained with LPS from different bacterial sources and reproduced with the lipid A moiety of endotoxin. Purified adherent spleen cells used as antigen-presenting cells (APC) support this LPS-enhanced TH cell proliferation. In addition, the effect of endotoxin on specific TH cell responses was found to be absolutely dependent on the interaction between TH lymphocytes and APC through antigen-specific recognition. Thus, it was not observed in the absence of specific antigen or when monoclonal antibodies against class II MHC products or against L3T4 antigens were used to inhibit the T cell-APC interaction. Similarly, it was found that APC from the B6.CH-2bm12 mutant do not support the LPS-mediated enhancing effect. Furthermore, interleukin 1 (IL 1) appears not to be involved in LPS-mediated enhancement, and this effect is not reproduced by muramyl dipeptide (MDP)-mediated activation of APC.     

CD4+ T lymphocytes expressing CD40 ligand help the IgM antibody response to soluble pneumococcal polysaccharides via an intermediate cell type

Streptococcus pneumoniae causes serious infections in children, the elderly, and immunocompromised patients. Protection against infections with S. pneumoniae is mediated through Abs against the capsular polysaccharides (caps-PS). We previously showed that the murine Ab response to caps-PS is dependent on CD40-CD40L interaction. In the present paper, we addressed the question of whether the CD40-CD40L-mediated modulation of the anti-caps-PS immune reaction is the result of a direct interaction between B lymphocytes and T lymphocytes or of an indirect interaction. SCID/SCID mice reconstituted with B lymphocytes from wild-type mice did not mount anti-caps-PS Abs. SCID/SCID mice reconstituted with B lymphocytes from wild-type mice and CD4+ T lymphocytes from wild-type mice but not CD4+ T lymphocytes from CD40L knockout mice stimulated the anti-caps-PS Ab response. This indicated that CD4+ T lymphocytes stimulated the anti-caps-PS Ab response in a CD40L-dependent manner. SCID/SCID mice reconstituted with B lymphocytes from CD40 knockout mice and CD4+ T lymphocytes from wild-type mice generated an anti-caps-PS Ab response that could be inhibited by MR1, a blocking anti-CD40L Ab. These data indicated that CD4+ T lymphocytes stimulated the anti-caps-PS Ab response in an indirect way. Finally, lethally irradiated CD40 knockout mice reconstituted with bone marrow from wild-type mice mounted an anti-caps-PS Ab response that was comparable to the Ab response in wild-type mice, revealing that the required CD40 was on hemopoietic cells. In conclusion, we provide evidence that CD4+ T lymphocytes expressing CD40L stimulate the Ab response to soluble caps-PS by interacting with CD40-expressing non-B cells.     

Lymphoid bone marrow cultures can reconstitute heterogeneous B and T cell-dependent responses in severe combined immunodeficient mice

Long-term lymphoid bone marrow cultures (LBMC) produce B lymphocytes and their precursors for several months in vitro. To assess their differentiative potential and determine their capacity to function as immune effectors, cells from the cultures were transplanted into mice with severe combined immune deficiency disease (SCID). SCID mice are deficient in T and B lymphocytes and are serum immunoglobulin (Ig) negative, but grafts of normal lymphoid precursors can expand and differentiate in them, thereby restoring immunocompetence. The results of these studies indicate that cells from LBMC are able to reconstitute splenic B lymphocytes in the SCID mice. Upon in vivo transfer, LBMC cells secreted Ig that displayed isotype distribution and a pattern of heterogeneity comparable with normal BALB/c mice, as determined by two-dimensional gel electrophoresis. The transplanted LBMC cells were functional, because reconstituted mice could respond to immunization with the T-independent antigen TNP-Ficoll. The results also indicate that cultured cells could reconstitute T cell activity in SCID mice. Splenocytes from approximately one-third of the recipients could generate a cytotoxic response to alloantigens after 5 days of sensitization in a mixed lymphocyte culture, and all reconstituted SCID mice could respond to immunization with the T cell-dependent antigen TNP-BSA. These results demonstrate that B cells, as well as T cell activity, are present in LBMC-reconstituted SCID mice, and show that LBMC cells have the capacity to mediate an immune response.     

Synergistic and differential modulation of immune responses by Hsp60 and lipopolysaccharide

Activation of professional antigen-presenting cells (APC) is a crucial step in the initiation of an efficient immune response. In this study we show that Hsp60 mediates immune stimulation by different mechanisms, dependent and independent of lipopolysaccharide (LPS). We have demonstrated earlier that both, Hsp60 and LPS, increase antigen-specific interferon (IFN) gamma release in T cells. Here we show that in contrast to LPS Hsp60 induces IFNalpha production in professional APC. Neutralization of IFNalpha as well as the absence of functional IFNalphabeta receptor on APC and T cells interfered with Hsp60-mediated IFNgamma secretion in antigen-dependent T cell activation, strongly suggesting that IFNalpha represents one factor contributing to Hsp60-specific immune stimulation. On the other hand, we show that Hsp60 bound to the cell surface of APC colocalizes with the LPS co-receptor CD14 and LPS binding sites. Hsp60 specifically binds bacterial LPS and both molecules synergistically enhanced IL-12p40 production in APC and IFNgamma release in antigen-dependent T cell activation. This effect was Hsp60-specific and dependent on LPS-binding by Hsp60. Furthermore, we show that Hsp60 exclusively binds to macrophages and DC but not to T or B lymphocytes and that both, T cell stimulation by Hsp60 as well as Hsp60/LPS complexes, strictly depends on the presence of professional APC and is not mediated by B cells. Taken together, our data support an extension of the concept of Hsp60 as an endogenous danger signal: besides its function as a classical danger signal indicating unplanned tissue destruction to the innate immune system, in the incident of bacterial infection extracellular Hsp60 may bind LPS and facilitate microbe recognition by lowering the threshold of pathogen-associated molecular pattern (PAMP) detection and enhancing Toll-like receptor (TLR) signaling.     

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.     

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.     

Characterization of accessory cell function during acute infection of BALB/cByJ mice with mouse hepatitis virus (MHV), strain JHM.

Earlier studies revealed defective concanavalin A-stimulated proliferation and cytokine production by spleen cells derived from BALB/cByJ mice acutely infected with mouse hepatitis virus (MHV), strain JHM. Based on those observations, assays of in vitro antigen-presenting cell (APC) function were undertaken. APC function of unfractionated spleen cells from individual MHV-infected mice was highly variable. Experiments using pooled spleen cells derived from MHV-infected mice revealed that adherent spleen cell APC function was impaired to a much greater degree than B cell APC function. Adherent cells derived from peritoneal exudates of infected mice exhibited an APC defect that was similar in magnitude to that observed for splenic adherent cells. Splenic B cells derived from acutely infected BALB/cByJ mice harbored infectious MHV. In contrast, lysates of adherent spleen cells from acutely infected mice did not kill intracerebrally inoculated neonatal mice, but did induce seroconversion among all survivors. Despite impairment of APC function of cells derived from MHV-infected donors, neither indomethacin nor accessory cells from uninfected control mice restored concanavalin A-induced proliferative responses of spleen cells collected from acutely infected mice. These results and those of earlier studies suggest that, although APC function is impaired, in vitro T cell dysfunction exhibited by spleen cells from MHV-JHM-infected donors is probably related to an inherent proliferative defect subsequent to T cell activation. Defective concanavalin A-stimulated proliferation does not appear to be secondary to accessory cell function suppression or to inhibitory factors secreted by accessory cells.     

Genetically transferred central and peripheral immune tolerance via retroviral-mediated expression of immunogenic epitopes in hematopoietic progenitors or peripheral B lymphocytes.

BACKGROUND: Based on the hypothesis that IgGs are potent tolerogens and that immature lymphohematopoietic antigen-presenting cells (APC), and even mature peripheral B cells, may be effective APC for tolerance induction, we designed an immunoglobulin fusion protein retroviral expression vector to test the role of B cells in a novel gene therapy strategy for the transfer of immune tolerance. METHODS: An immunodominant epitope (residues 12-26 of the lambda repressor cI protein) was fused in frame to an IgG heavy chain in a retroviral vector, which was used to infect either bone marrow cells or activated peripheral B lymphocytes. These cells were transferred into syngeneic recipients, who were subsequently challenged with the 12-26 peptide in adjuvant. RESULTS: Bone marrow (BM) chimeras generated with retrovirally transduced bone marrow were shown to be profoundly unresponsive to the 12-26 peptide at both the humoral and cellular levels, but were competent to respond to an unrelated protein (lysozyme or PPD). Importantly, we also show that immunocompetent adult recipients infused with transduced mature, activated B lymphocytes, are rendered unresponsive by this treatment. Surprisingly, lymphoid-deficient BM progenitors from syngeneic SCID donors could also be transduced to produce tolerogenic APC. CONCLUSIONS: Our data suggest that activated B cells are sufficient to be effective tolerogenic APC in immunocompetent adult mice, but that nonlymphoid cells may also induce tolerance in reconstituted hosts. This approach for gene-transferred tolerogenesis has the potential to be maintained indefinitely, and it requires only knowledge of cDNA sequences of target antigens.     

Accelerated recovery of antigen-presenting cell activity by the administration of interleukin 1 alpha in 5-fluorouracil-treated mice

In this study, we investigated the effect of human recombinant interleukin-1 alpha (IL-1 alpha) on antigen-presenting cell (APC) activity of spleen cells in mice treated with 5-fluorouracil (5-FU). APC activity was determined by the antigen-specific proliferation of T cell clone D10.G4.1 cells. When mice were injected with 5-FU, APC activity of spleen cells was suppressed. The administration of IL-1 alpha accelerated the recovery from this suppression. The most accelerated recovery was observed when these mice were administered with IL-1 alpha both before and after the 5-FU treatment. The recovery was also accelerated when the mice were injected with IL-1 alpha after the 5-FU treatment, but not when injected before the 5-FU treatment. The injection of 5-FU also decreased the cell numbers of whole spleen cells, B cells, and non-T non-B cells (Ig- and Thy-1- cells). The administration of IL-1 alpha accelerated the recovery of the decreased cell numbers. Both B cells and non-T non-B cells possessed APC activity, but most APC activity of unseparated spleen cells was carried by non-T non-B cells. B cells possessed only 1/20 of the APC activity of non-T non-B cells. The injection of 5-FU decreased APC activity of both B cells and non-T non-B cells, but the administration of IL-1 alpha accelerated its recovery. Thus, the accelerated recovery of APC activity by IL-1 alpha was suggested to be due to the recovery in the numbers of APC activity-bearing cell subpopulations and also due to the recovery of the APC activity of each subpopulation. Possible mechanisms for the recovery were discussed.     

Cytolytic activity of antigen-specific T cells with helper phenotype

We have investigated an unusual cytolytic activity displayed in vitro by cloned T cells which have the cell surface phenotype of helper T cells. When the cloned T cells are cultured with the appropriate antigen and antigen-presenting cells (APC), the T cells become activated in that they produce lymphokines and proliferate in an antigen-specific and major histocompatibility complex-restricted manner. At the same time, these T cells cause lysis of the APC. In addition, innocent non-histocompatible bystander cells present in the cultures can also be killed. The cytolytic activity may be involved in a mechanism of immune regulation.     

Development of antigenic heterogeneity in the splenic meshwork of severe combined immunodeficient (SCID) mice after reconstitution with T and B lymphocytes

Recently, we produced monoclonal antibodies reacting specifically with the reticular meshwork (RM) of lymphoid tissues, and demonstrated that, in the splenic white pulp of normal mouse, the antigenic heterogeneity of RM was associated with the segregation of the T and B lymphocytes. In the present study, we attempted to visualize further the interaction between splenic RM and T and B lymphocytes transferred into severe combined immunodeficient (SCID) mice. The splenic white pulp of naive SCID mice, containing a few T and B cells, showed little tendency for T-B segregation and antigenic diversity of RM. Transfer of spleen or bone marrow cells from normal mice resulted in complete recovery of lymphocyte populations, showing not only a clear segregation of T and B lymphocytes but also a remarkable antigenic diversity of RM. The same results were obtained following the transfer of spleen or bone marrow cells from the nude mouse. Next, we transferred purified T lymphocytes to one group of SCID mice and B cells to another. In mice given T cells, a few B cells were observed in the white puop; T lymphocytes lodged not only in the inner periarterial lymphatic sheath (PALS) but also in the outer PALS and follicles. In the animals to which B cells were transferred, T cells were few and the homing of B cells occurred only into their proper compartments, such as the outer PALS, follicles and marginal zone, but not in the inner PALS. Thus, B cells can home into their proper compartments of the splenic white pulp independently of T lymphocytes.     

Antigen presentation by liver sinusoidal lining cells after antigen exposure in vivo

The ability of liver sinusoidal lining cells (LSLC), a mixture of Kupffer cells and endothelial cells, to function as antigen-presenting cells (APC) was examined. Guinea pig LSLC were found to present antigen in vitro, albeit somewhat less effectively than a reference population of peritoneal exudate macrophages. The difference in APC function could not be explained by a deficiency of interleukin 1 (IL 1), as LSLC secreted IL 1 and expressed membrane-bound thymocyte stimulatory activity. The ability of LSLC to take up antigen from the portal blood in vivo and present it to primed T lymphocytes in vitro was also investigated. Trinitrophenyl-ovalbumin was injected intraportally into either strain 13 or strain 2 guinea pigs. The LSLC were subsequently isolated by collagenase digestion and density separation and assessed for the ability to induce proliferation of antigen-primed accessory cell-depleted syngeneic peritoneal exudate T lymphocytes in vitro. The in vivo antigen-pulsed LSLC were found to present antigen in vitro to primed T cells in an antigen-specific and genetically restricted manner. T cell DNA synthesis induced by antigen-bearing LSLC could be augmented by coculture with additional accessory cells, but not IL 1-containing macrophage supernatants. Enhancement of responsiveness was not genetically restricted. The demonstration that LSLC can take up, process, and retain antigen in vivo and present it to primed T cells in vitro suggests that LSLC are capable of contributing to the immune response to antigens appearing in portal blood.     

Cell-cell interactions in the T cell proliferative response. I. Analysis of the cell types involved and evidence for nonspecific T cell recruitment

In the antigen-induced T cell proliferative response, it has been firmly established that antigen-specific T cell activation signals are provided by a specialized antigen-presenting cell (APC). However, the number of responding T cell populations involved has not been clearly delineated. This problem can be analyzed by plotting the logarithm of the number of cultured cells against the logarithm of the response. This yields a straight line, the slope of which indicates the minimum number of interacting cell populations that are required to give the response. In the antigen-induced T cell proliferative response, this number is 3. Based on their ability to shift the slopes of the log cell number-log response line, two of the populations were identified to be T cells. The third cell, which was present in irradiated spleens, possessed certain properties of the APC. Of the two T cells, one was antigen-specific and the other could come from normal unprimed animals. The frequency of antigen-specific proliferating T cells in primed animals was estimated to be only 1 in 1.3 x 10(3), and a large proportion of the proliferation was shown to be due to unprimed cells. Furthermore, without the need to use antigen-pulsed macrophages, this slope analysis demonstrated convincingly that the successful interaction between APCs and proliferating T lymphocytes is determined by products of the I-region immune response genes.     

Essential role for CD40 ligand interactions in T lymphocyte-mediated modulation of the murine immune response to pneumococcal capsular polysaccharides

Protection against infection with pneumococci is provided by anti-capsular polysaccharide (caps-PS) Abs. We investigated whether CD40 ligand (CD40L) plays a role in T lymphocyte-mediated regulation of the immune response to caps-PS, which are considered thymus-independent Ags. Administration of MR1, an antagonist mAb against murine CD40L, in BALB/c mice immunized with Pneumovax resulted in an inhibition of the IgM and IgG Ab response for various caps-PS serotypes. Evidence for the involvement of CD4(+) T lymphocytes in the Ab response to caps-PS was obtained in SCID/SCID mice that, when reconstituted with B lymphocytes and CD4(+) T lymphocytes, mounted a higher specific IgM response compared with SCID/SCID mice reconstituted with only B lymphocytes. This helper effect of CD4(+) T lymphocytes was abrogated by MR1. Blocking CD40L in vitro decreased the IgM response to caps-PS and abolished the helper effect of CD4(+) T lymphocytes. CD8(+) T lymphocyte-depleted murine spleen cells mounted a higher in vivo immune response than total murine spleen cells, which provided evidence for a suppressive role of CD8(+) T lymphocytes on the anti-caps-PS immune response. CD4(+) T lymphocyte-depleted murine spleen cells, leaving a B and CD8(+) T lymphocyte fraction, elicited only a weak in vivo and in vitro Ab response, which was enhanced after MR1 administration. In summary, our data provide evidence that T lymphocytes contribute to the regulation of the anti-caps-PS immune response in a CD40L-dependent manner.     

The frequency of mouse spleen dendritic cells which present alloantigens or ovalbumin to primed T lymphocytes is equal

We have used limiting dilution analysis to compare the frequency of dendritic cells (DC) which present endogenous alloantigens with that which present an exogenous protein antigen to T lymphocytes. Spleen DC present alloantigens or ovalbumin to primed T lymphocytes with equal frequency, showing that DC are equipotent for presenting endogenous and exogenous antigens. Also, antigen-presenting cell (APC) frequencies among DC were compared with other APC populations. DC were enriched about 1000-fold for APC compared to unfractionated spleen cells.     

Nonmyelin-specific T cells accelerate development of central nervous system APC and increase susceptibility to experimental autoimmune encephalomyelitis

Previously we demonstrated that both myelin-specific and nonmyelin-specific rat T cells were capable of accelerating the development of transplanted rat BM-derived APC in the CNS of SCID C.B-17/scid (SCID) mice. This suggested that nonmyelin-specific T cells might be capable of increasing susceptibility to EAE by increasing the number and function of APC in the CNS before disease induction. To assess this possibility, we evaluated disease incidence, day of onset, duration, mean peak severity, cumulative disease index, and histopathology in the presence or absence of nonmyelin-specific T cells. The results demonstrate an association between T cell responses to nonmyelin Ags, accelerated development of BM-derived CNS APC before disease induction, and heightened susceptibility to CNS inflammation mediated by myelin-specific T cells. This suggests that T cell responses to nonmyelin Ags can potentiate CNS inflammation by elevating the functional presence of CNS APC.