Class II MHC-bearing keratinocytes induce antigen-specific unresponsiveness in hapten-specific Th1 clones

Previous studies of Ia+ keratinocytes (KC) indicated that they functioned poorly or not at all when utilized as accessory cells for T cell activation. When Ia+ KC were modified with trinitrobenzene sulfonic acid, these cells did not induce a proliferative response in the TNP-specific, 1-Ek-restricted Th1 clone SE-4 (less than 5% of control). Analysis of supernatants generated from SE-4 cells incubated with these non-stimulatory accessory cells revealed low levels of IL-3 and IFN-gamma, but an absence of IL-2, when compared with supernatants generated from SE-4 cells stimulated with TNP-modified cultured Langerhans' cells that contain high levels of all of these lymphokines. Incubation of SE-4 cells with TNP-modified Ia+, but not Ia- KC or FITC-modified Ia+ KC, resulted in unresponsiveness to subsequent stimulation with TNP-modified functional accessory cells. Blocking studies with anti-class II MHC mAb revealed that the induction of unresponsiveness by hapten-modified Ia+ KC was restricted to the I-Ek molecule. Thus, the Ag and MHC specificities of unresponsiveness induced by TNP-modified Ia+ KC were identical to those observed for the proliferation of this clone in response to TNP-modified functional accessory cells. These data indicate the existence of a naturally occurring population of Ia+ cells that, after hapten-modification, induce an unresponsive state instead of proliferation of T cells.     

Characterization of the effector mechanism of help for antigen-presenting and bystander resting B cell growth mediated by Ia-restricted Th2 helper T cell lines

The mechanism of help for resting B cell growth in MHC-restricted T-B collaboration was investigated using an in vitro polyclonal model for these T cell-B cell interactions. In the presence of rabbit anti-mouse Ig, small, size-selected B cells elicit help from syngeneic Ia-restricted Th2 cell lines specific for F(ab')2 rabbit globulin. Both Ag-presenting and bystander B cells receive signals from stimulated Th cells that lead to B cell proliferation. The results suggest that the direct activation of resting Ag-presenting and bystander B cells by Th2 cells is mediated by a similar effector mechanism. Although proliferative responses by Ag-presenting B cells are of greater magnitude, help for both Ag-presenting and bystander B cell populations is characterized by the lack of a requirement for membrane Ig cross-linking, by identical kinetics, and by the necessity for direct cell contact or close proximity with Th cells. B cell proliferation is not induced by exposure to the sequence of diffusable mediators released from a synchronized Ag-specific T-B interaction. The T cell-dependent proliferation by both B cell populations can be inhibited by excess mitomycin C-treated syngeneic "cold target" B cells, demonstrating a requirement for a short-range T cell-B cell interaction. mAb inhibition experiments fail to identify a role for class II, LFA-1, or CD4 membrane molecules in the delivery of help to bystander B cells. Antibody against H2d bystander class II molecules has no effect on bystander B cell proliferation at concentrations that completely block Ag presentation by H2d B cells to an H2d-restricted Th cell line. Antibodies against the cell adhesion molecule LFA-1 or the Th cell molecule CD4 do inhibit bystander B cell proliferation, but only to the extent that they block T cell activation and the induction of help. The inductive stimulus leading to resting B cell growth results from an early, short-range interaction with Th cells. B cell proliferation is supported by T cell soluble mediators as a consequence of this interaction, which is required for at least 8 hr after T cell recognition of Ag/Ia on the surface of Ag-presenting B cells.     

Sodium periodate-induced T cell mitogenesis: an analysis of the requirement for Ia and IL 1

T lymphocytes oxidized with the mitogen sodium periodate undergo a proliferative response when cultured in the presence of Ia+ accessory cells. However, the exact role(s) the accessory cells play in such a response has not been clearly defined. We have evaluated the role of Ia and the requirement for interleukin 1 (IL 1) in periodate mitogenicity by using the Ia+ cloned tumor cell lines P388AD (Ia+, IL 1 inducible) and P388NA (Ia+, IL 1 noninducible) as accessory cells. P388AD but not P388NA was able to supply accessory cell function to periodate-treated T cells, suggesting that Ia expression alone was not sufficient to reconstitute a response. Monoclonal anti-I-Ad and anti-I-Ed antibody blocked the accessory cell function of P388AD. In addition, monoclonal antibody GK 1.5, directed against the T cell determinant L3T4a, blocked the P388AD/periodate-treated T cell interaction, confirming that this interaction was restricted by class II molecules. Although Ia expression was required, the response was not major histocompatibility complex (MHC) restricted, because allogeneic as well as syngeneic macrophages were capable of supplying accessory cell function to periodate-treated T cells. Exogenous IL 1 alone was able to trigger periodate-treated T cells, suggesting that Ia was required for the induction of IL 1 synthesis by the accessory cells. Furthermore, purified IL 2, devoid of IL 1 activity, was able to fully reconstitute the proliferative response of accessory cell-depleted oxidized T cells to a level equal to that of whole spleen accessory cells or P388AD. These data suggest that periodate-treated T cells can proliferate with IL 1 alone and that Ia+ accessory cells in periodate-mediated T cell mitogenicity may function in the release of IL 1 and the induction of IL 2 synthesis by the T cells.     

Qualitative and quantitative studies of antigen-presenting cell function by using I-A-expressing L cells

I-A-expressing transfected murine L cells were analyzed as model antigen-presenting cells. Four features of accessory cell function were explored: antigen processing, interaction with accessory molecules (LFA-1, L3T4), influence of Ia density, and ability to stimulate resting, unprimed T lymphocytes. I-A+ L cells could present complex protein antigens to a variety of T cell hybridomas and clones. Paraformaldehyde fixation before but not subsequent to antigen exposure rendered I-A+ L cells unable to present intact antigen. These results are consistent with earlier studies that made use of these methods to inhibit "processing" by conventional antigen-presenting cells. The ability of anti-L3T4 antibody to inhibit T cell activation was the same for either B lymphoma or L cell antigen-presenting cells. In striking contrast, anti-LFA-1 antibody, which totally blocked B lymphoma-induced responses, had no effect on L cell antigen presentation, measured as interleukin 2 (IL 2) release by T hybridomas, proliferation, IL 2 release, or IL 2 receptor upregulation by a T cell clone. I-A+ L cell transfectants were found to have a stable level of membrane I-A and I-A mRNA, even after exposure to interferon-gamma-containing T cell supernatants. In agreement with earlier reports, a proportional relationship between the (Ia) X (Ag) product and T cell response was found for medium or bright I-A+ cells. However, dull I-A+ cells had a disproportionately low stimulatory capacity, suggesting that there may be a threshold density of Ia per antigen-presenting cell necessary for effective T cell stimulation. Finally, I-A-bearing L cells were shown to trigger low, but reproducible primary allogeneic mixed lymphocyte responses with the use of purified responder T cells, indicating that they are capable of triggering even resting T cells. These studies confirm the importance of antigen processing and I-A density in antigen-presenting cell function, but raise questions about the postulated role of the LFA-1 accessory molecule in T cell-antigen-presenting cell interaction. They also illustrate the utility of the L cell transfection model for analysis and dissection of antigen-presenting cell function.     

Regulation of an idiotype+ B cell lymphoma. Effects of antigen and anti-idiotopic antibodies on proliferation and Ig secretion

The B cell surface Ig molecule plays an important regulatory role in delivering inductive/tolerogenic signals to the cell. In this paper, the effect of Ag and anti-idiotopic antibodies on the in vitro proliferation and Ig secretion of a B cell tumor was studied. The tumor (BCL1), which had been transfected with the TEPC-15 VH and VL Ig genes, expresses surface Ig and secretes antibody that binds the hapten phosphorylcholine. We found that Ag (C polysaccharide and phosphorylcholine carrier Ag) and two different anti-idiotopic antibodies, in the absence of T cells, all inhibited the proliferation of the T15+ transfectant cell line. The anti-idiotopic antibodies, but not Ag, also inhibited the secretion of T15 Ig by this cell line, suggesting different functional roles for Ag vs anti-Id in the regulation of B cell inactivation. The inhibition of secretion and proliferation appears to be cell cycle phase related. In addition, mouse rIL-4 could override the inhibition of proliferation induced in these studies. These phenomena, demonstrating that binding of surface Ig can result in the transduction of negative growth signals to a B cell tumor, can be viewed as a manifestation of immunologic tolerance. These findings collectively demonstrate that Ag and anti-Id mediate different signals to B cells via interaction with the surface Ig. Because of the monoclonal nature of the T15 transfectant and the anti-idiotypic antibodies, this system can be used to investigate the underlying molecular reactions involved in the B cell response and induction of tolerance.     

Characterization of cell surface molecules involved in the recognition of antigen-presenting cells by cloned helper T-cell lines

The recognition of antigen-presenting cells (APCs) by T helper (TH) cells occurs in an antigen (Ag)-specific, MHC-restricted manner. Recent evidence, however, suggests that other interaction molecules may also be involved in TH:APC interaction in addition to the T-cell receptor (Ti) and class II or la antigens. We chose, therefore, to examine the role of various interaction molecules (Ia, Ti, L3T4, and LFA-1) in Ag presentation using several TH clones with distinct recognition patterns (self-Ia, self-Ia/Ag, and allogenic Ia). We describe here the use of a rapid clustering assay to study the initial binding events that occur between TH cells and APCs of various types. In all combinations of TH cells and APCs, conjugate formation was both Ag-specific and MHC-restricted. Moreover, with one exception cell clustering was prevented by the addition of monoclonal antibodies (mAb) against either the T-cell receptor or class II MHC molecules. In contrast, mAb to L3T4 and LFA-1 generally failed to inhibit cluster formation even though T-cell proliferation was profoundly inhibited. The relative importance of these interaction molecules in conjugate formation appeared to depend on the APC type as well as on the T-cell clone used. The implications of these findings for the mechanisms of Ag presentation and T-cell activation are discussed.     

Characterization of the signaling function of MHC class II molecules during antigen presentation by B cells.

In addition to their role as peptide binding proteins, MHC class II proteins can also function as signal transducing molecules. Recent work using B cells expressing genetically engineered truncated MHC class II molecules has suggested that signaling through the cytoplasmic domains of these proteins plays an important role in the generation of signals required for the activation of some T cell hybrids. Treatment of truncated Ia-expressing B cells with cAMP-elevating agents corrects the deficiency in Ag presentation by these cells. We report that the MHC class II-mediated signal appears to act by a mechanism that increases the efficiency of Ag presentation by B cells thereby lowering the amount of specific Ag required for T cell activation. We further show that the induction of the cAMP-induced signal in B cells is inhibited by cycloheximide and cytochalasin A, implicating protein synthesis as well as cytoskeletal rearrangements in Ag presentation to accessory signal- dependent hybrids. In contrast, these agents do not block Ag presentation to a T cell hybrid previously shown not to require the cAMP-induced signal for activation. The signal-dependent T hybrid is additionally dependent on LFA-1-ICAM-1 interaction for activation, whereas the signal-independent hybrid is not. These observations suggest the existence of two types of T cell hybrid with respect to their requirements for activation: those that require only the recognition of MHC class II-peptide complexes without accessory signals, as shown by their ability to respond to purified Ia on planar membranes, and those that, in addition to recognition of MHC II/Ag, require LFA-1-ICAM-1 interaction and the delivery of additional signal(s) induced in the B cell via signal transduction through MHC class II molecules.     

Stimulation of B lymphocytes through surface Ig receptors induces LFA-1 and ICAM-1-dependent adhesion.

Engagement of the surface Ig receptor with anti-IgM antibodies stimulates murine B lymphocytes to markedly increase their expression of the cell adhesion molecules ICAM-1 and LFA-1. Stimulated B cells display increased homotypic adhesiveness and form spontaneous heterotypic conjugates with T lymphocytes. This latter T-B cell interaction is further enhanced if T cells have been previously activated with phorbol esters. In all cases, the formation of cell-cell conjugates is dependent on LFA-1-ICAM-1-mediated interactions as assessed in mAb blocking experiments. B lymphocytes stimulated with anti-IgM display a marked increase in binding to ICAM-1-transfected L cells. This cell-cell interaction is inhibited by anti-LFA-1 mAb binding to the B lymphocyte. Together, these results demonstrate that there is an induction of both ICAM-1 and LFA-1 on stimulated B cells and a corresponding increase in the adhesiveness of these cells. These findings suggest that Ag binding to the surface Ig receptor could prepare a B lymphocyte for subsequent interaction with a T lymphocyte. This provides insight into how efficient T-B collaboration may occur between very infrequent Ag-specific lymphocytes.     

Expression and function of I region products on immunocompetent cells. II. I region products in T-B interaction.

The anti-Lac B precursor cells from BALB/c (H-2)d mice which survive cytotoxic treatment with anti-Iak and complement will respond to Lac-KLH in culture but require more KLH helper T cells than unselected B cell populations or B cells surviving anti-Ig killing. These findings are not explainable by the classical Poisson assumption of a constant target of T-B ionteraction. We propose a T-B interaction theory with variable Ia target on the B cell surface. The theory quantitatively predicts the observed dose response relationships, and implies that Ia molecules on B cells are cell interaction structures.     

Human resting B lymphocytes can serve as accessory cells for anti-CD2-induced T cell activation.

Although resting B cells are poor accessory cells for signals transmitted through the TCR/CD3 complex, we report that these B cells can support T cell proliferation when T cell activating signals are delivered through CD2. This was first suggested when leucine methyl ester treatment of PBMC abolished proliferation induced by anti-CD3, but not by the accessory cell-dependent anti-CD2 mAb combination, GT2 and OKT11. Then we demonstrated that unstimulated, resting B cells could support the proliferation of both CD4+ and CD8+ T cells. Aggregated IgG inhibited proliferation, suggesting that anti-CD2 mAb bound to T cells were cross-linked by attachment to B cell FcR. Two lines of evidence suggested that lymphocyte function-associated Ag-1/intercellular adhesion molecule-1 interaction was crucial for anti-CD2-induced proliferation. First, proliferation was blocked by mAb against these adhesion molecules. Second, intercellular adhesion molecule-1 expression rapidly increased on resting B cells after the addition of anti-CD2, but not anti-CD3. This was of interest because fixed monocytes, but not fixed B cells, were able to support the proliferative response. In contrast to lymphocyte function-associated Ag-1/intercellular adhesion molecule-1, CD28/B7 interaction was not required for anti-CD2-induced proliferation, although ligation of these molecules provided important costimulatory signals for stimulation by anti-CD3. Finally, neutralizing antibodies against IL-1 alpha, IL-1 beta, and IL-6 showed only modest inhibitory effects on T cell proliferation. The addition of IL-1 and/or IL-6 to T cells failed to substitute for accessory cells and were only partially effective with fixed B cells. Further evidence of a linkage between CD2 and CD45 isoforms was obtained. Anti-CD45RA, but not anti-CD45RO, potentiated anti-CD2-induced T cell proliferation. These studies have revealed a novel role for resting B cells as accessory cells and have documented costimulatory signals that are important for this effect. Because Ag-presentation by resting B cells to T cells generally leads to T cell nonresponsiveness, it is possible that this tolerogenic signal may be converted to an activation signal if there is concurrent perturbation of CD2 on T cells.     

Polyclonal B cell activation by B cell differentiation factor B151-TRF2. I. Involvement of self-Ia recognition process mediated by B cells

The present study examined the functional role of Ia antigens on B cells in polyclonal B cell activation induced by a B cell differentiation factor, B151-TRF2. The polyclonal IgM PFC responses by B151-TRF2 were inhibited by monoclonal antibodies specific for class II MHC antigens (Ia antigens) but not class I MHC antigens. Such inhibition by anti-Ia antibodies was haplotype-specific and was observed in the absence of both T cells and accessory cells. Moreover, the anti-Ia antibody-induced inhibition of the B151-TRF2 responses was not due to the blocking of binding of B151-TRF2 to the corresponding B cell receptor. A series of kinetic studies revealed that some Ia-mediated cellular activation process occurs before the resting B cells become responsive to B151-TRF2. Thus, the B151-TRF2-mediated B cell responses consist of at least two distinct phases. The early phase is an Ia-dependent but B151-TRF2-independent process, whereas the late phase is an Ia-independent but B151-TRF2-dependent process. To further characterize the functional role of Ia antigens on B cells, an additional experiment was carried out by using F1 B cells which co-dominantly express both parental Ia antigens on the surface. Interestingly, it was observed that the degree of inhibition of the B151-TRF2-mediated responses of F1 B cells by anti-parental Ia antibody was, at best, one-half that of the parental B cells, suggesting that F1 B cells may be separated into two subpopulations with the restriction specificity for the respective parental Ia antigens. To examine this possibility, (B10 X B10.BR)F1 B cells were separated into adherent and nonadherent cell populations by their ability to bind to either one of the parental B cell monolayers, and the specificity of inhibition of their responses to B151-TRF2 by anti-Ia antibodies was assessed. It was found that the responses of (B10 X B10.BR)F1 B cells adherent to the B10 B cell monolayer or the B10.BR B cell monolayer were almost completely inhibited by anti-I-Ab and anti-I-Ak antibodies, whereas those of nonadherent cells were now selectively inhibited by anti-I-Ak and anti-I-Ab antibodies, respectively. These findings are interpreted as indicating that the B151-TRF2-responsive F1 B cells consist of at least two subpopulations with the restriction specificity for either one of the parental Ia antigens.(ABSTRACT TRUNCATED AT 400 WORDS)     

Cross-linking surface Ig delays CD40 ligand- and IL-4-induced B cell Ig class switching and reveals evidence for independent regulation of B cell proliferation and differentiation

T cells stimulate B cells to divide and differentiate by providing activating signals in the form of inducible membrane-bound molecules and secreted cytokines. Provision of these signals in vitro reproduces many of the consequences of T-B collaboration in the absence of any form of Ag stimulation. Although clearly not obligatory, Ag signals appear to play an important regulatory role in numerous aspects of the B cell response. To examine directly the effect of an Ag signal, naive B cells were stimulated in the presence of rCD40 ligand, with or without IL-4 in the presence or absence of different anti-Ig mAbs. Anti-Ig mAbs exerted variable effects on the B cell division rate, from enhancement to no effect to inhibition. In contrast, all anti-Ig mAbs tested inhibited division-linked isotype switching to IgG1 and IgE. Thus, B cell Ag receptor ligands could modify the rates of B cell expansion and class switching independently. The ability of anti-Ig reagents to modify class switching suggests the B cell Ag receptor may play an important role in the selection of Ig isotypes during T cell-dependent humoral immune responses to Ags of different physical structure.     

Activation of Lyt-2+ (CD8+) and L3T4+ (CD4+) T cell subsets by anti-receptor antibody

The mAb F23.1, specific for V beta 8-related determinants on the TCR, was used to study the requirements for TCR cross-linking and for accessory cells (AC) in the induction of proliferation or IL-2 responsiveness in L3T4+ (CD4+) and Lyt-2+ (CD8+) T cells. T cells were exposed in vitro to soluble native F23.1 antibody, to heteroconjugates composed of the Fab fragments of F23.1 linked to Fab fragments of antibodies specific for Ia determinants on AC, or to F23.1 immobilized on an insoluble matrix. Soluble F23.1 antibody-induced proliferation in naive T cells only in the presence of both AC and exogenous IL-2, and these responses were confined to Lyt-2+ T cells. In contrast, heteroconjugates capable of crosslinking F23.1+ TCR to AC surface Ia determinants were capable of inducing proliferation in both L3T4+ and Lyt-2+ T cells in the absence of added lymphokine. Moreover, binding to and presumably multi-valent crosslinking of the TCR by immobilized F23.1 was sufficient to induce proliferation in both Lyt-2+ and L3T4+ T cells in the absence of AC or exogenous IL-2. Further, it was found that the conditions necessary for T cell growth factor secretion paralleled closely those required for induction of T cell proliferation in the absence of added lymphokine, suggesting that production of endogenous lymphokine might be the limiting process for triggering of T cell proliferation. Taken together, these findings suggest that under optimal conditions of TCR cross-linking, TCR occupancy and cross-linking is sufficient to deliver all of the signals necessary to initiate proliferation in naive populations of both L3T4+ and Lyt-2+ T cells. However, when conditions for TCR signaling are suboptimal, as may be the case for normal Ag-mediated stimulation, a role for second signals delivered by AC or exogenous lymphokines can become critical for T cell activation.     

The role of antigen-presenting B cells in T cell priming in vivo. Studies of B cell-deficient mice

Mice rendered B cell deficient by treatment with rabbit anti-mouse IgM (anti-mu) antibodies from birth fail to respond when primed with soluble protein antigens in CFA, as measured by T cell proliferation when challenged with antigen in vitro. The role of B cells in T cell priming in vivo was examined by adoptively transferring hapten-specific B cells into anti-mu mice, followed by immunization with haptenated Ag in CFA. The T cell proliferative response to OVA of anti-mu BALB/c mice was partially restored by the administration of TNP or FITC-specific B cells and immunization with TNP-OVA or FITC-OVA, respectively. This reconstitution was Ag-specific, inasmuch as hapten-binding B cells restored the T cell responses to OVA in mice immunized with the same hapten coupled to OVA. The mechanism of B cell reconstitution of T cell priming in anti-mu mice was addressed using parental to F1 B cell transfers. The Ia restriction pattern of the activated T cells from these mice indicated that both direct presentation of Ag by transferred B cells and antibody-mediated enhancement of Ag presentation by non-B, host Ag-presenting cells occurred. Thus, Ag-specific B lymphocytes play a critical role in priming of T cells in vivo.     

T cell surface molecules regulating noncognate B lymphocyte activation. Role of CD2 and LFA-1.

A central event in humoral responses is the Ag-mediated interaction of Th cells and B cells. This interaction leads to the activation of both cell types and results in cytokine secretion by the T cells and proliferation and secretion of Ig by the B cells. The proliferative and differentiative responses of B cells are dependent on contact-mediated signals and cytokines provided by the activated Th cells. Although the role of cytokines in B cell activation and differentiation is understood, the nature of the signals delivered by the activated Th cells and the molecules involved in this process are not known. In this study we have examined Ag-mediated "cognate" T-B cell interactions as well as B cell activation induced by contact with preactivated and fixed Th lymphocytes. Our results indicate that both the T cell surface molecules lymphocyte function associated Ag-1 and CD2 are important in the activation of T cells by Ag presented by B lymphocytes. This indicates that B cells have similar characteristics as other APC. However, once the T cells are activated, contact-mediated stimulation of resting B lymphocytes (the noncognate phase) is dependent on CD2 but not lymphocyte function associated Ag-1. Two lines of evidence indicate this; first, it is inhibited by blocking of CD2 on the T cells and, second, such stimulation is not efficiently mediated by a CD2- Th cell line. Thus, CD2 plays an obligatory role at several discrete stages of T cell-mediated activation of resting B lymphocytes.     

Influenza viruses as lymphocyte mitogens. II. Role of I-E molecules in B cell mitogenesis by influenza A viruses of the H2 and H6 subtypes

Influenza A viruses of the H2 and H6 subtypes behave as T cell-independent B cell mitogens for lymphocytes from strains of mice that express the class II MHC glycoprotein I-E (Ia.7+ haplotypes). We have examined the role of I-E molecules in mitogenesis by these viruses. Lymphocytes from (Ia.7+ X Ia.7-)F1 hybrid strains that express lower levels of I-E antigen than homozygous Ia.7+ strains showed a level of response to H2 and H6 influenza viruses that was intermediate between the high response of the Ia.7+ parent and the low response of the Ia.7- parent. The mitogenic response of H-2k lymphocytes to these viruses was completely inhibited by low concentrations of anti-I-Ek monoclonal antibody that had no effect on B cell proliferation induced by LPS or by influenza A virus of the H3 subtype. Furthermore, incubation of H-2k spleen cells with high concentrations of H2 (but not H3) influenza viruses substantially inhibited the binding of radio-labeled anti-I-Ek, but not anti-I-Ak, monoclonal antibody. Cell mixing experiments indicated that expression of I-E by the B cells was critical to the mitogenic response, whereas I-E expression by accessory cells may not be necessary. The data support a model in which B cell mitogenesis by these viruses results from direct binding of the viruses to I-E molecules on B lymphocytes.     

Antigen presentation by resting B cells. Effectiveness at inducing T cell proliferation is determined by costimulatory signals, not T cell receptor occupancy

Resting B cells stimulated the proliferation of two T cell clones much less efficiently than T cell-depleted low-density APC. In contrast, low-density cells and resting B cells stimulated the clones to produce similar levels of inositol phosphates, a rapid biochemical event dependent only on occupancy of the TCR. The inefficient stimulation of T cell proliferation by resting B cell APC was dramatically improved by the addition of allogeneic low-density accessory cells incapable of being recognized by the TCR on the responding T cells. The results are most consistent with a model where low-density and resting B cell APC display similar amounts of Ag/Ia molecule complexes capable of being recognized by the TCR on the responding T cells but differ in the provision of costimulatory signals that, together with TCR occupancy, are required for IL-2 production.     

Cyclic AMP-independent effects of cholera toxin on B cell activation. II. Binding of ganglioside GM1 induces B cell activation.

Although the physiologic function of gangliosides is unknown, evidence suggests they play a role in the regulation of cell growth. The binding of ganglioside GM1 by recombinant B subunit of cholera toxin (rCT-B) inhibited mitogen-stimulated B cell proliferation without elevating intracellular cAMP. CT-B paradoxically enhanced the expression of MHC class II (Ia) molecules and minor lymphocyte-stimulating determinants without altering the expression of some other immunologically relevant B cell surface Ag. Increased expression of Ia was not detected until 4 h after stimulation, kinetics similar to those seen when B cells are stimulated with anti-Ig antibody or IL-4, suggesting that the enhancement was not the result of redistribution of existing cell surface markers but rather the result of a new metabolic event. Both the inhibitory and stimulatory effects of CT-B could be blocked by incubation of CT-B with ganglioside GM1. Furthermore, enhancement of the CT-B-mediated effect was seen when additional ganglioside GM1 was incorporated into the B cell membrane. rCT-B with a mutation that interfered with its binding to ganglioside GM1 did not enhance Ia expression. Taken together, these results indicate that the observed effects of CT-B were most likely mediated through the binding of cell surface ganglioside GM1. CT-B-mediated stimulation of Ia expression provides a potential explanation for the previously described ability of CT-B to act as an immunoadjuvant. These results suggest that the binding of ganglioside GM1 has multiple B cell growth-regulating effects.     

Role of the LFA3-CD2 interaction in human specific B cell differentiation

We examined the role of the lymphocyte function-associated (LFA)3 molecule in human B cell response. A mAb to this molecule did not influence B cell proliferation induced by anti-mu antibody and IL. In contrast, the same mAb inhibited the specific T-dependent B cell response induced by a particulate Ag. In the same line, two anti-CD2 mAb (directed toward the T11-1 and T11-2 epitopes) inhibited this response, whether used alone or in association. These inhibitions took place at an early stage of the response, and anti-LFA3 and anti-CD2 mAb acted on B cells and T cells, respectively. In contrast, when T cell help was provided by exogenous IL-2, the B cell response was resistant to the inhibitory effect of anti-LFA3 mAb. Taken together, these results indicate that the LFA3-CD2 pair play a major role in the direct T-B interaction required for T cell help.     

Granulocyte-macrophage colony-stimulating factor activates macrophages derived from bone marrow cultures to synthesis of MHC class II molecules and to augmented antigen presentation function

The effects of granulocyte-macrophage (GM)-CSF on the synthesis of MHC class II molecules and on the Ag presentation capacity by bone marrow derived macrophages (BMM phi) was investigated. BMM phi obtained by in vitro culture in the presence of macrophage-CSF were negative for synthesis of I-A molecules and induced the Ag-mediated proliferation of insulin-specific T clone cells with lower efficiency than splenic accessory cells. After pulse treatment with GM-CSF for 24 to 48 h, day 12 BMM phi exhibited highly efficient Ag presentation function which was superior to that induced by IFN-gamma. Expression of membrane-bound IL-1 was augmented significantly by GM-CSF, but not by IFN-gamma. However, the T cell clone used to probe for accessory cell function of BMM phi was not dependent on IL-1 for optimal proliferation. Concomitantly, GM-CSF induced the de novo synthesis of I-A molecules, although to a lesser extent than optimal doses of IFN-gamma. Thus GM-CSF appears to elicit properties in addition to Ia molecule synthesis and membrane IL-1 expression in BMM phi being essential for efficient accessory cell function to the T clone cells. The activation of BMM phi by GM-CSF was reversible and could be repeated. These data show that GM-CSF exerts a modulatory influence on preformed BMM phi, reversibly activating cells to Ia biosynthetic potential and pronounced accessory cell capacity, thus rendering the explanation unlikely that differentiation of precursor cells into a constitutively functional state had occurred.