Antigen recognition by H-2-restricted T cells. I. Cell-free antigen processing

Differential recognition of tumor-derived and in vitro Epstein-Barr virus-transformed B-cell lines by fetal calf serum-specific T4-positive cytotoxic T-lymphocyte clones

Two interleukin-2 (IL-2)-dependent cytotoxic T-cell clones were obtained by limiting dilution from a lymphocyte culture stimulated in vitro with the autologous Epstein-Barr virus-transformed lymphoblastoid cell line (LCL) in the presence of fetal calf serum (FCS). Both clones uniformly had a T3+, T4+, Dr+ phenotype and lysed autologous B blasts, the autologous LCL, and allogeneic B cell lines sharing major histocompatibility complex (MHC) class II antigens. The cytotoxic function was triggered by FCS-derived components. There was no killing if the sensitive targets were cultured in serum-free medium or in medium supplemented with human serum. Sensitivity to lysis could be restored by exposing the targets to FCS for at least 6 hr at 37 degrees C. Monoclonal antibodies directed to T-cell-specific surface antigens and MHC class II antigens inhibited lysis with different efficiencies depending on the target cell origin. Killing of Burkitt's lymphoma (BL)-derived cell lines was blocked more easily than killing of LCLs. LCLs but not BL lines induced proliferation of the T-cell clones in the absence of exogenous IL-2. The differences were not related to quantitative variations in the expression of MHC class II antigens, indicating that BL lines differ from LCLs in other cell membrane properties that may influence antigen presentation. The results suggest that the affinity of effector/target binding, which is probably influenced by the concentration of antigenic determinants expressed on the target cell membrane, determines whether proliferative responses or cytotoxicity are induced in the antigen-recognizing T cells.

Production and characterization of cloned T-cell hybridomas that are responsive to Rickettsia conorii antigens

T-cell hybridomas produced by the fusion of Rickettsia conorii immune T cells to the AKR thymoma BW 5147 produced interleukin-2 when stimulated with the antigens of three different R. conorii strains. One cloned hybridoma responded only to R. conorii antigens, whereas a second and third cloned hybridoma also responded to the antigens of Rickettsia rickettsii Sheila Smith and Rickettsia sibirica 246, respectively. Antigen responses required antigen-presenting cells, and this interaction was major histocompatibility complex restricted. Fluorescence-activated cell-sorter analysis demonstrated that all three hybridomas were of the Thy-1.2+, Lyt-2- phenotype and that two of the three were L3T4+. These data demonstrated the presence of an antigenic epitope that is R. conorii species specific and other epitopes that are common to various members of the spotted fever group which can stimulate interleukin-2 production by T-cell hybridomas.

Antigen presentation is a function of all B cell subpopulations separated on the basis of size

Purified splenic B cells from nonimmune mice were separated by counterflow centrifugal elutriation into 6 subpopulations containing cells of discrete sizes ranging from 119 to 200 micron3. B cells of each subpopulation were competent to process and present a native globular protein antigen, cytochrome c, to a cytochrome c-specific T cell hybrid. In all cases, the B cells' antigen-presenting function was radiation sensitive and did not require T cells or T cell products, since B cells fixed with paraformaldehyde effectively presented a carboxyl-terminal peptide fragment of cytochrome c containing the T cell determinant. Furthermore, the antigen-presenting function of B cells of each subpopulation was augmented by treatment with submitogenic doses of the F(ab')2 fragment of rabbit anti-mouse Ig antibodies, in that 10-30-fold fewer B cells were required and higher maximal T cell responses were achieved, indicating that B cells of all sizes are capable of being regulated in their antigen presentation function through their surface Ig. In addition, B cells of each subpopulation responded to soluble factors present in the supernatants of activated T cells as evidenced by an increase in volume and by the uptake of [3H]thymidine. These results indicate that B cells, regardless of size, are able to participate in at least two essential phases of T cell-dependent antibody responses, initiating the interaction by processing and presenting antigen to helper T cells and responding to soluble helper factors secreted by activated T cells.

Differences in antigen presentation to MHC class I-and class II-restricted influenza virus-specific cytolytic T lymphocyte clones

We have examined requirements for antigen presentation to a panel of MHC class I-and class II-restricted, influenza virus-specific CTL clones by controlling the form of virus presented on the target cell surface. Both H-2K/D- and I region-restricted CTL recognize target cells exposed to infectious virus, but only the I region-restricted clones efficiently lysed histocompatible target cells pulsed with inactivated virus preparations. The isolated influenza hemagglutinin (HA) polypeptide also could sensitize target cells for recognition by class II-restricted, HA-specific CTL, but not by class I-restricted, HA-specific CTL. Inhibition of nascent viral protein synthesis abrogated the ability of target cells to present viral antigen relevant for class I-restricted CTL recognition. Significantly, presentation for class II-restricted recognition was unaffected in target cells exposed to preparations of either inactivated or infectious virus. This differential sensitivity suggested that these H-2I region-restricted CTL recognized viral polypeptides derived from the exogenously introduced virions, rather than viral polypeptides newly synthesized in the infected cell. In support of this contention, treatment of the target cells with the lysosomotropic agent chloroquine abolished recognition of infected target cells by class II-restricted CTL without diminishing class I-restricted recognition of infected target cells. Furthermore, when the influenza HA gene was introduced into target cells without exogenous HA polypeptide, the target cells that expressed the newly synthesized protein product of the HA gene were recognized only by H-2K/D-restricted CTL. These observations suggest that important differences may exist in requirements for antigen presentation between H-2K/D and H-2I region-restricted CTL. These differences may reflect the nature of the antigenic epitopes recognized by these two CTL subsets.

T-cell-mediated association of peptide antigen and major histocompatibility complex protein detected by energy transfer in an evanescent wave-field

Helper T cells recognize foreign antigen displayed on antigenpresenting cells which also express self-molecules of the major histocompatibility complex (MHC). A single T-cell receptor mediates recognition of both MHC and foreign antigen. A proposed ternary complex between T-cell receptor, foreign antigen and MHC antigen has not yet been demonstrated (see ref. 1 for review). Here, we show that a fluorescein-labelled synthetic peptide, together with Texas red-labelled class II MHC antigen, I-Ad, stimulates the production of interleukin-2 by a peptide-specific I-Ad-restricted T-cell hybridoma when reconstituted in a lipid membrane on a glass substrate. Under the same conditions, resonance-energy transfer from donor peptide to acceptor I-A can be stimulated in an evanescent wave-field only in the presence of the specific T-hybrid. Our results show that the T cell stabilizes an association between peptide antigen and class II MHC protein to within a distance of about 40 A.

Internalization and processing of antibodies to surface antigens on human B cells. Monoclonal anti-IgM antibodies are processed differently than monoclonal antibodies towards non-Ig surface receptors

The internalization and intracellular processing of monoclonal antibody to immunoglobulin mu heavy chain (Mamu) have been investigated in two human Burkitt lymphoma cell lines (Ramos and Raji), in a human B cell lymphoma and in normal human peripheral blood B cells. In addition to the degradation of 125I-labeled Mamu to trichloroacetic acid (TCA) soluble material, a distinct pattern of larger 125I-Mamu fragments was detected in all sources of B cells tested. The particular fragmentation pattern, as revealed by sodium dodecyl sulfate-polyacrylamide gel electrophoretic analysis, involved the cleavage of both peptide bonds and disulfide bridges. This type of antibody fragmentation appeared to be a selective mechanism associated with sIgM, as no other degradation than that leading to TCA-soluble material could be detected after the internalization and degradation of radiolabeled monoclonal antibodies towards a variety of non-Ig B cell surface receptors. Three fragments of 125I-Mamu degradation were also detected in the supernatant of Ramos cells, implying that the recycling and exocytosis of certain 125I-Mamu fragments also took place.

I-A-restricted T cell antigen recognition. Analysis of the roles of A alpha and A beta using DNA-mediated gene transfer

The contributions of A alpha and A beta chains, and of subregions of A beta, to Ia-restricted recognition of antigen by Th lymphocytes were analyzed using a panel of L cells transfected with various pairs of A alpha b,d, or k genes and recombinant or wild-type A beta b,d, or k genes. The A beta genes included all possible exchanges of the whole NH2-terminal (beta 1) domain or halves of the beta 1 domain among these three allelic A beta genes. The Ia+ L cells derived from such transfections were used as antigen-presenting cells with a 21 member panel of responding Ia-restricted T hybridoma cells of differing nominal antigen specificity and Ia-restriction. Special care was taken to account for quantitative variation in levels of Ia expression throughout the experiments. The results of this analysis reveal that (a) only 2 of the 21 Th cells recognized Ia molecules involving either a nonparental A alpha or a nonparental A beta chain, and in both cases the degeneracy extended to only one of the two other alleles tested. This suggests that allele specific contributions from both A alpha and A beta chains are important in restricted recognition for most, if not all I-A-restricted Th cells. (b) In no case did substitution of the A beta 2 domain from either of the alternative haplotypes lead to any functionally detectable effects, demonstrating that polymorphisms in the A beta 1 domain can entirely account for the restriction imposed on Th cell responses by the entire A beta chain. (c) For 90% of the cells tested, replacement of the NH2-terminal portion of the beta 1 domain with an allogeneic segment led to Ia molecules unable to elicit Th responses. Furthermore, of all the cells permissive of the substitution of one or other half of the beta 1 domain, only two permitted the substitution of sequence from both alternative haplotypes. Taken together, these data strongly suggest that antigen recognition by most, if not all, I-A-restricted Th cells involves contributions from both halves of the A beta 1 domain. These data suggest that the role of I-A molecules in restricted Th cell recognition of antigen depends on conformational determinants unique to a particular combination of polymorphic alpha and beta chains, and that multiple such sites exist on a single Ia molecule.(ABSTRACT TRUNCATED AT 400 WORDS)

Adsorption on B cell hybridomas removes suppressor cells from spleen cells of neonatally tolerized mice

Spleen cells from CBA mice neonatally tolerized to Dd MHC (major histocompatibility complex) determinants were adsorbed on monolayers of Dd-specific B cell hybridomas. Adsorption on 4 different Dd-specific hybridomas but not on a Kd-specific hybridoma removed suppressor cells and resulted in generation of cytotoxic T lymphocyte (CTL) effector cells against the tolerogen. Responses of normal CBA CTL against Dd as well as anti-third party responses were not influenced by adsorption. Successful adsorption was also achieved on monolayers of fixed hybridoma cells. Monolayers of Dd-specific hybridomas specifically removed suppressor cells from CBA mice tolerant to Dd; they failed to adsorb suppressor cells from AKR mice tolerant to H-2b. Immunofluorescence analysis with antibodies specific for determinants on tolerizing cells showed the presence of donor-derived F1 cells on the monolayer. Under the experimental circumstances described suppressor cells are most likely removed by recognition of their MHC determinants by the monolayer population. These data suggest that neonatal tolerance is actively maintained by donor-derived suppressor cells.

Large, but not small, antigens require time- and temperature-dependent processing in accessory cells before they can be recognized by T cells

We have studied if antigens of different size and structure all require processing in antigen-presenting cells of guinea-pigs before they can be recognized by T cells. The method of mild paraformaldehyde fixation was used to stop antigen-processing in the antigen-presenting cells. As a measure of antigen presentation we used the proliferative response of appropriately primed T cells during a co-culture with the paraformaldehyde-fixed and antigen-exposed presenting cells. We demonstrate that the large synthetic polypeptide antigen, dinitrophenyl-poly-L-lysine, requires processing. After an initial time-lag of 30 min this antigen is fully processed within 2 to 4 of culture at 37 degrees C. In contrast, the immunogenic heptapeptide, angiotensin III, can be presented by pre-fixed accessory cells, viz. without any prior processing. Antigen processing was found to be temperature-dependent and consequently energy-requiring. Processing is strongly inhibited by the lysosomotrophic drug, chloroquine, suggesting a lysosomal involvement in antigen processing. The existence of a minor, non-lysosomal pathway is suggested, since small amounts of antigen were processed even at 10 degrees C, at which temperature no transport to and from the lysosomes can occur.

An induced fit hypothesis for antigen recognition by T lymphocytes: a role for specific antigen retention structures on antigen-presenting cells

The nature of T lymphocyte recognition of foreign antigens is not known, despite recent advances in elucidating the cellular structures that may be involved in the specific interactions. The central difficulty in this process is that T cells respond to foreign antigen only in the context of major histocompatibility complex (MHC) antigens expressed by another antigen-presenting cell. In addition, T cells that interact with class II MHC antigens do not bind foreign protein antigens in their native form, but seem to recognize only proteolytic peptide fragments as the relevant antigen. The simplest explanation for these observations is that the class II MHC antigens themselves bind antigenic peptides to form the appropriate determinant that interacts with the antigen-specific T cell receptor. However, to date no such antigenic complex has been found with MHC antigens despite rigorous attempts at their demonstration. One alternative explanation described here is that there is no preexisting foreign antigen-MHC antigen complex prior to interaction with T cells, and it is the T cells that cause the two moieties to become associated for recognition by a single antigen-specific T cell receptor. Central to this mechanism is that foreign antigenic peptides must be associated with specific antigen retention structures (SARS) expressed by antigen-presenting cells which retain and protect the peptide on the cell surface. These SARS, upon interaction with T cell membrane moieties, would subsequently associate with MHC antigens. A hypothesis to describe this mechanism is developed to account for published observations of antigen processing by antigen-presenting cells and T cell antigen recognition, and makes several predictions that are experimentally testable. This mechanism is also generally applicable to other cellular interactions in which soluble peptide mediators may become associated with surface components of one cell type, and this newly formed complex is in turn recognized by a receptor on a second cell type to deliver functional signals.

Modulation of Ia and photoreactive antigen on antigen-presenting cells: fun with a photoprobe

To identify the antigen-specific recognition complex containing elements from T cells and antigen-presenting cells (APC), a photoactivatable antigen system was developed which could potentially crosslink the complex during the specific cellular responses. In this paper we describe the development of this system using murine T-cell hybridomas responding to stimulator cells chemically conjugated with N-hydroxysuccinimidyl 4-azidobenzoate (HSAB) and genetically restricted by I-Ad. In initial experiments it was found that several I-Ad-positive B-cell lines were nonstimulatory when coupled with HSAB, but that I-Ad-positive P388D1 macrophage-like cells were efficient stimulators of HSAB-specific T-cell responses. These results suggested that the relevant HSAB coupled surface structure was not likely I-Ad. To substantiate this point, Ia-positive or Ia-negative P388D1 cells were initially coupled with HSAB and the expression of Ia was modulated by the addition and withdrawal of Con A-stimulated spleen cell supernatant fluid through several days of culture. Under these conditions, efficient stimulation was only observed when Ia was expressed, although the HSAB antigen was continuously present. In other experiments it was found that exposure of HSAB-coupled APC to light selectively eliminated their stimulatory capacity for HSAB-specific T hybridomas, suggesting that the light-induced crosslinking by HSAB directly eliminates the antigenic determinant. This antigen system allows a unique opportunity to manipulate the antigen during specific cellular interactions, and to introduce covalent crosslinking of the specific antigen recognition complex that may allow its isolation and characterization.

Cellular requirements for antigen processing by antigen-presenting cells: evidence for different pathways in forming the same antigenic determinants

In this report we examined the antigen-presenting cell (APC) requirements for activation of T-cell hybridomas specific for the protein antigen PPD (purified protein derivative of tuberculin). During the course of these studies we observed that glutaraldehyde fixation of Ia-positive A20.2JAD (A20) and P388D1 stimulator cells had different effects on T-cell activation. A20 cells fixed with glutaraldehyde stimulated the T cells in the presence of PPD as efficiently as nonfixed A20 cells. By contrast, glutaraldehyde treatment of Ia-positive P388D1 cells dramatically inhibited their ability to process and/or present PPD to T cells. This was not due to nonspecific effects on the P388D1 cells since cells prepulsed with PPD prior to glutaraldehyde treatment stimulated T cells as efficiently as non-glutaraldehyde-treated P388D1 cells. In addition, there was no apparent difference in "fixing" of the two cell types as determined by the uptake of radiolabeled thymidine. These observations suggested that P388D1, but not A20, cells required PPD internalization to form the relevant antigenic determinants. This was substantiated by showing that treatment of P388D1 cells with chloroquine prior to PPD pulsing eliminated their stimulatory capacity, but had no effect on P388D1 cells previously pulsed with PPD. Chloroquine treatment had no effect on stimulation by A20 cells. Since PPD internalization appeared not to be required for presentation by A20 cells, we next determined if isolated A20 plasma membranes would substitute for the intact cell. We observed that the isolated plasma membranes from PPD-pulsed A20 cells stimulated the T hybridoma cells, and that this stimulation was antigen-specific and was inhibited by anti-Ia monoclonal antibodies. Taken together, the results presented here suggest that for the PPD-specific T-cell responses examined here, different APC utilize distinct pathways to present the same antigenic determinant for T-cell recognition.

Recognition of human insulin in vitro by T cells from subjects treated with animal insulins

Structurally defined proteins and peptides have provided considerable information about the specificity and regulation of immune responses in inbred animals. Many diabetics require therapy with insulin; therefore, we used this defined protein as a model antigen to investigate immune responses in the outbred human population. In this report, we examine human T cell recognition of antigenic determinants on various insulins. A group of 25 subjects was selected from over 200 diabetics because of the magnitude of their in vitro responses. 13 of the 25 had significant T cell responses to human insulin despite treatment with only beef/pork insulin mixtures. This autoimmunity may be attributed to crossreactivity of lymphocytes highly reactive to "foreign" epitopes on therapeutic insulins. Alternatively, identical determinants shared by human and animal insulins may be recognized. By employing additional insulins not used therapeutically and isolated A and B chains, several potential mechanisms for lymphocyte autoreactivity to human insulin were demonstrated. Some epitopes are conformational and require recognition of an intact molecule, whereas other epitopes may arise from antigen processing at the cellular level. Studies using zinc-free insulins suggest that zinc-induced alterations of the molecular surface may result in some shared reactivities between animal and human insulin. Furthermore, T cell reactivity against "foreign" epitopes is more complex than anticipated from differences in amino acid sequence. The response patterns of many subjects indicate that the A-chain loop associates with the N-terminal B chain to form a complex determinant. This determinant is recognized more often than individual amino acids. We conclude that insulin therapy generates polyclonal T cell responses directed at multiple epitopes on the molecule. Many of these epitopes are not identified by amino acid exchanges and their presence on human insulin leads to apparent autoimmunity.

Role of membrane immunoglobulin (Ig) crosslinking in membrane Ig-mediated, major histocompatibility-restricted T cell-B cell cooperation

Resting murine B lymphocytes can present rabbit anti-Ig to T cell lines specific for normal rabbit globulin. The T cell-B cell interaction is major histocompatibility complex (MHC)-restricted, and leads to activation, proliferation, and differentiation of the resting B cell into an antibody-secreting cell. Efficient antigen presentation and B cell activation depends upon binding of rabbit globulin to (membrane) mIg. To investigate the role of mIg in this polyclonal model for a T cell-dependent primary antibody response, we determined whether crosslinking of mIg is required either for efficient antigen presentation, as measured by helper T cell activation, or for the B cell response to T cell help, since all the direct effects of anti-Ig on B cells require crosslinking of mIg. We found that monovalent Fab' fragments of anti-IgM or anti-IgD work as efficiently as their divalent counterparts. Therefore, a signal transduced through the antigen receptor seems not to be required when T cell help is provided by an MHC-restricted T helper cell recognizing antigen on the B cell surface. Moreover, rabbit globulin bound to class I MHC molecules in the form of anti-H-2K also results in efficient antigen presentation and T cell-dependent B cell activation. However, mIg still appears to be specialized for antigen presentation, since anti-Ig is presented about three- to fivefold more efficiently than anti-H-2K.

Epstein-Barr virus-transformed B cell lines present M. leprae antigens to T cells

We have investigated whether or not Epstein-Barr virus-transformed lymphoblastoid B cell lines (EBV-BLCL) are able to present Mycobacterium leprae (M. leprae) to antigen-reactive T cell lines and clones. Such EBV-BLCL would provide us with a homogeneous and unlimited source of antigen-presenting cells. Antigen-triggered proliferation of T cells has been studied with co-cultures either with autologous or allogeneic irradiated EBV-BLCL. Our results show that EBV-BLCL are able to present M. leprae as efficiently as peripheral blood mononuclear cells, and that they also function in an HLA-DR-restricted fashion. Apart from their possible in vivo relevance, these results have important practical implications, in particular for the generation and study of M. leprae-reactive T-cell clones.

Analysis of antigen presentation by metabolically inactive accessory cells and their isolated membranes

Several amino acid copolymers are potent immunogens under the control of major histocompatibility complex (MHC)-encoded Ir genes. We have further characterized their accessory-cell-dependent, MHC-restricted presentation to T lymphocytes. We initially characterized their processing requirements by investigating the ability of paraformaldehyde-fixed antigen-presenting cells (APC) to present these copolymers. Fixed APC can present poly(Glu56Lys35Phe9) and poly(Glu60Ala30Tyr10) provided that they have been incubated with antigen prior to fixation. The inability of these same fixed preparations to present soluble antigen indicates a fixation-sensitive antigen-processing step. In contrast, the antigens poly(Glu55Lys35Leu10) and poly(Glu55Lys35Tyr10) can be presented by APC fixed before antigen exposure. This differential requirement for antigen processing was exploited to analyze the events of antigen presentation in two related systems. First, the ability of isolated APC membranes to process and present antigen was assessed. APC membranes can present the antigens poly(GluLysLeu) and poly(GluLysTyr) in a specific and MHC-restricted manner. However, the isolated membranes fail to present either poly(GluLysPhe) or poly(GluAlaTyr), suggesting that such preparations can present but not process antigen. Second, the distinct properties of the various copolymers were used with fixed APC to test the effects of antigen processing on the phenomenon of antigen competition. APC that had processed poly(GluLysPhe) or poly(GluAlaTyr) were subsequently fixed and used to present antigen in the presence or absence of various antagonists. Under these conditions, poly(GluLysLeu) and poly(Glu50Tyr50) could effect specific inhibition, clearly indicating that antigen competition occurs distal to and does not require antigen processing. In contrast, native antigen with an absolute processing requirement is not capable of competing with preprocessed antigen on fixed APC. Taken together, these results suggest that processing is important for the molecular interactions between the copolymer antigens and the APC cell surface that are relevant to both antigen presentation and competitive inhibition.

The ability of Ia and H-2Kk-bearing membranes to replace the antigen-presenting cell in an H-2Kk allogeneic cytotoxic T cell response

Induction of an allogeneic cytotoxic T lymphocyte (CTL) response is dependent, in part, on uptake and processing of the class I alloantigen by antigen-presenting cells and subsequent Ia-restricted recognition of the alloantigen by helper T cells, resulting in lymphokine production. The nature of the antigen-processing event has been investigated using reconstituted membranes to replace the antigen-presenting cells in the generation of a secondary allogeneic CTL response. Membranes were isolated from an Iad-positive antigen presenting B cell lymphoma (D2N), detergent solubilized and then reconstituted together with affinity-purified H-2Kk antigen in the presence of protease inhibitors. These reconstituted vesicles, containing both syngeneic Ia and alloantigen, were able to induce the helper T cell arm of the CTL response in cultures depleted of antigen-presenting cells. A variety of control experiments provided strong evidence that the helper T cells recognized the H-2Kk, probably in its native form, in an Ia-restricted manner on the vesicles, while the pre-CTL can directly recognize H-2Kk. Recognition was only effective if both the Ia and alloantigen were inserted into the same membrane bilayer. The results strongly suggest that the obligatory antigen processing event required for helper T cell recognition of alloantigen is simply the insertion of the alloantigen into the same membrane bilayer as the syngeneic Ia restricting element.

Activated human T cells can present alloantigens but cannot present soluble antigens

Human T cells, when activated by antigen or mitogen, express Ia antigens. We have examined the capacity of activated T cells to stimulate autologous and allogeneic T cells and their ability to present soluble antigen. Interleukin 2-dependent T-cell lines (TCL), free of accessory cells, were used for antigen-presenting cells. These activated T cells were potent stimulators in an autologous mixed lymphocyte reaction (AMLR), more so than autologous irradiated non-T mononuclear cells. Activated T cells were also able to stimulate proliferation of allogeneic T cells in the absence of any other accessory cells, and this stimulation was blocked by anti-Ia antibodies. Resting unstimulated T cells were unable to stimulate autologous or allogeneic responses. Thus, activated T cells were able to present self antigens and alloantigens. However, activated T cells could not present soluble antigens to autologous T cells or to antigen-specific TCL even if exogenous interleukin 1 was added to cultures. The ability of activated T cells to stimulate an AMLR in vitro may reflect an important immunologic amplification mechanism in vivo. The ability of activated T cells to present alloantigens but not soluble antigens suggests an inability to process antigen, and this may provide further insights into the complexities of antigen presentation.

Activation of an interleukin-1-responsive T-cell lymphoma by fixed P388D1 macrophages and an antibody against the Ag:MHC T-cell receptor

We have characterized the activation of the interleukin 1 (IL-1)-responsive T-cell lymphoma LBRM33-1A5-47 to interleukin 2 (IL-2) production by phytohemagglutinin (PHA) and IL-1. The signal provided by soluble IL-1 could be replaced by fixed P388D1 cells and the signal provided by PHA by a monoclonal antibody directed against an allotypic determinant of the Ag/MHC T-cell receptor (KJ16-133). The signal provided by fixed P388D1 does not appear to be due to alloreactivity. Instead, it appears to be due to a membrane-bound IL-1. The implications of these observations are discussed.

Antigen presentation of myoglobin: profiles of T cell proliferative responses following priming with synthetic overlapping peptides encompassing the entire molecule

Recently, the regions of myoglobin, which are recognized by T cells (T sites), were localized by a comprehensive synthetic strategy in which uniform synthetic overlapping peptides encompassing the entire protein chain were examined for stimulation of T cell proliferative activity. In this study, we report about the proliferative response to these peptides, as well as to the native protein, of lymph node cells from mice primed with the overlapping peptides either individually or in a mixture. Some, but not all, of the T site-containing peptides were effective in priming for an anti-myoglobin T cell response. Further, several peptides, which were highly immunogenic as free synthetic peptides, were not associated with any of the known T sites in this protein. Thus, the pattern of T cell recognition following priming with the overlapping peptides differs from the pattern observed when the native protein is the priming antigen. If antigen processing proceeds via fragmentation, then only those regions containing T sites would be expected to be effective in priming for a T cell response to the intact protein and, conversely, highly immunogenic peptides would correspond to T sites of the protein. Therefore, these findings indicate that the current concept of antigen fragmentation as a prerequisite for its presentation must be reappraised. We suggest that, in the presentation of a protein antigen, the protein is recognized predominantly intact and that the crucial aspects of presentation are determined by interaction with the cell membrane which trigger cellular activating events.

Antigen presentation of lysozyme: T-cell recognition of peptide and intact protein after priming with synthetic overlapping peptides comprising the entire protein chain

Recently, using synthetic overlapping peptides which encompass the entire protein chain of hen egg lysozyme, the full submolecular profile of continuous regions on the protein recognized by T cells (T sites) was localized. In the present report, we have examined in two mouse strains the proliferative response to peptides and to native protein of lymph node cells from mice primed with synthetic overlapping peptides, either individually or as a mixture. It was found that the pattern of T-cell recognition observed after priming with peptides differs from that obtained when the native protein is used as the immunogen. Some, but not all, of the T-site containing peptides were effective in priming for an anti-lysozyme T-cell response. Several peptides which were highly immunogenic as free synthetic peptides were not associated with any of the known protein T sites. Further, some peptides were effective in priming for T cells that respond in vitro to the priming peptide, but not to the whole protein. If antigen processing proceeds via fragmentation, then only those regions containing T sites would be expected to be effective in priming for a T-cell response to the intact protein. Since this was not found to be the case, it is unlikely that fragmentation of lysozyme is a prerequisite for antigen presentation. Rather, we suggest that the critical aspects in the presentation of a protein antigen predominantly involve recognition of an intact protein, the interaction of which with the cell membrane triggers cellular activating events.

Regulation of the human immune response to HBsAg: effects of antibodies and antigen conformation in the stimulation of helper T cells by HBsAg

The role of accessory cells (antigen-presenting cells) in binding HBsAg in the response of human T cells to this antigen was studied. Antibodies to HBsAg of IgG class increased significantly the amount of HBsAg that was captured and internalized by accessory cells in vitro. On the other hand, antibodies to HBsAg of IgM class or the F(ab')2 and Fab fragments of antibodies to HBsAg of IgG class did not modify the amount of HBsAg associated to these cells. HBsAg that was subjected to various denaturing treatments (acid, organic solvents, urea and heat) was compared for its capacity to react with antibody to HBsAg and stimulate the response of helper T lymphocytes. Results presented here indicate that HBsAg denatured by treatment with formic acid was captured by accessory cells and presented to the T cells much more efficiently than the native HBsAg. These results suggest that the response of helper T lymphocytes to some antigens such as HBsAg can be affected greatly by the presence of antibodies or the antigens' conformation.

Ia-transfected L-cell fibroblasts present a lysozyme peptide but not the native protein to lysozyme-specific T cells

We studied the antigen-presenting capacity of mouse L fibroblasts transfected with genes encoding Ia polypeptides of the major histocompatibility complex (MHC). These cells function as efficient antigen-presenting cells (APC) in stimulating peptide antigen-specific MHC-restricted proliferation of long-term T-cell lines, thus establishing the capacity of Ia-expressing L-cell transfectants to present antigens to apparently normal T cells. However, in contrast to splenic APC, L-cell transfectants fail to present native hen egg-white lysozyme to the same T cells. Since this result is similar to that obtained with physiologic APC pretreated to prevent antigen degradation, it suggests that L-cell transfectants, without such pretreatments, may be compromised in their ability to process native lysozyme. However, since such transfectant cells have been shown to present other complex polypeptides such as keyhole limpet hemocyanin, a random copolymer of glutamic acid, alanine, and tyrosine, and influenza virus neuraminidase, this observation suggests that protein antigens differ in the stringency of processing requirements.

Anti-immunoglobulin augments the B-cell antigen-presentation function independently of internalization of receptor-antigen complex

All mouse splenic B cells, including small resting B cells, process and present the native globular protein antigens, pigeon and tobacco hornworm moth cytochromes c, to a cytochrome c-specific T-cell hybrid in a major histocompatibility complex-restricted fashion, in the micromolar to nanomolar antigen-concentration range. As is the case for macrophages, treatment with paraformaldehyde or the lysosomotropic agents chloroquine and ammonium chloride blocked processing of the native pigeon protein but did not affect the presentation of a carboxyl-terminal peptide fragment of pigeon cytochrome c (residues 81-104) which contained the T-cell antigenic determinant. However, in contrast to macrophages, whose antigen-processing and -presentation functions are insensitive to radiation, radiation blocked the processing of the native protein but not the presentation of the peptide fragment. The processing and presentation function of the B cells was augmented by F(ab')2 of rabbit anti-mouse Ig antibodies, in that 1/10th to 1/30th as many cells and 1/10th as much antigen were required to maximally activate the T-cell hybrid. This augmentation did not appear to be due to either crosslinking of the Ig receptors or to B-cell activation, as monovalent Fab fragments were nearly as effective as the bivalent reagent, and the concentrations of F(ab')2 anti-Ig used did not induce measurable proliferative responses. Furthermore, enhancement can occur in the absence of cytochrome c binding and internalization, since B cells that were fixed with paraformaldehyde after treatment with F(ab')2 anti-Ig were more effective in presenting the carboxyl-terminal peptide than were untreated fixed cells. The same phenomenon followed the binding of an irrelevant antigen (carboxydinitrophenylated bovine serum albumin) by antigen-binding B cells, resulting in enhanced processing and/or presentation of native pigeon cytochrome c. Thus, nonspecific enhancement of antigen processing and presentation can be obtained by either antigen or anti-Ig binding to the B-cell antigen receptor, both treatments presumably delivering the same signal without requiring internalization of the specifically bound antigen for subsequent processing.

Possible involvement of transglutaminase in endocytosis and antigen presentation

Experiments were carried out to determine as to whether or not internalization of antigen is necessary for subsequent antigen presentation by accessory cells using monoamines which are known as transglutaminase (TGase) inhibitors. It was found that endocytosis for immune complexes via Fc receptors such as sheep erythrocytes coated with IgG class antibody (EA) was different from receptor-independent endocytosis for soluble protein such as horse radish peroxidase (HRP) in the sensitivity to monoamines; methylamine inhibited the receptor-dependent endocytosis of immune complexes at a concentration of over 20 mM and the receptor-independent endocytosis of HRP at 2 mM, while dansylcadaverine (DC) inhibited both at a concentration of 100 microM. It was noteworthy that antigen-specific T cell proliferation to splenic adherent cells pulsed with DNP9.6-ovalbumin (DNP9.6-OVA) was blocked strongly by DC as well, but weakly by methylamine. These results suggest the possibility that antigen presentation requires internalization of antigen by a mechanism such as receptor-dependent endocytosis for the subsequent reexpression of antigen on membranes. Furthermore, it was confirmed that TGase activity is high in peritoneal exudate and spleen adherent cells, both of which have accessory cell activities for lymphocytes, suggesting the possibility that TGase might be involved intimately in receptor-dependent endocytosis and subsequent antigen presentation.

T-cell activation by peptide antigen: effect of peptide sequence and method of antigen presentation

A series of synthetic peptide analogues of a determinant recognized by the ovalbumin-specific, I-Ad-restricted, T-cell hybridoma 3DO-54.8 were synthesized. The resulting peptides were tested for activation of 3DO-54.8 cells by using glutaraldehyde-fixed cells as well as reconstituted membranes as antigen-presenting surfaces. The results show that the minimum epitope for activation of this T cell is between 7 and 11 amino acids in length. This region includes two important histidine residues. The order of preference of the various peptide analogues was the same regardless of the method of antigen presentation. However, the amount of peptide required for T-cell activation was considerably higher when reconstituted membranes, rather than fixed cells, were used as antigen-presenting surfaces.

Genetic complexity and expression of human class II histocompatibility antigens

The genes encoding nearly all of the serologically defined class II antigens of the major histocompatibility complex have been isolated. Three class II loci have been studied in great detail. The DR region contains a single alpha gene and 3 beta chain genes, 1 of which is a pseudogene. The DR alpha chain gene has been linked to a DR beta gene which encodes a beta protein which contains the serological determinant MT3. A second cosmid cluster contains 2 beta genes, 1 of which encodes the DR4 allospecificity. The identification of these genes has been made by the comparison of amino terminal sequences of DR molecules obtained from a DR4 cell line and the deduced protein sequences of the beta 1 exons from cosmid and phage clones. A conserved element including the promoter and signal sequence is found at the 5' end of each of the 3 DR beta genes. Additionally, this element occurs three more times in the DR region, raising the question of whether additional beta chain genes might be found. The DQ region contains 2 pairs of genes, 1 of which encodes the DQ antigen. The 2nd pair of genes, called DX alpha and beta, appears to be capable of expressing a DQ-related product, although, to date, there is no evidence for its expression. The DP region also contains 2 pairs of genes. One pair encodes the DP antigen while the 2nd alpha-beta pair is shown to be composed of pseudogenes. The location of polymorphic regions in these genes and aspects of their relationship to the serology, evolution, and function of the class II MHC are discussed. The control of expression of class II genes by gamma-interferon has been examined. The promoters of class II genes are characterized by two conserved sequences common to all alpha and beta chain genes as well as by conserved sequences specific for either alpha or beta chain genes. In addition to studies of expression by DNA-mediated gene transformation, a system for the gene transfer of MHC antigens utilizing transmissible retrovirus vectors is described. Retrovirus vectors have been used to transmit DR alpha, DR beta, and the invariant chain (gamma) sequences to recipient cells with resultant expression of these proteins.

The role of Langerhans cells in antigen presentation

Epidermal Langerhans cells are dendritic bone marrow-derived cells which synthesize and express Ia antigens. During the past decade, in vitro studies have demonstrated that they play a critical role in the induction of many types of T-cell responses. Specifically, Langerhans cells are effective antigen-presenting cells in allogeneic and antigen specific proliferative and cytotoxic T-cell responses. This paper reviews these functions and suggests areas of future investigations into the mechanisms involved in T-cell activation by Langerhans cells.

Induction of regulatory T-lymphocyte responses by liposomes carrying major histocompatibility complex molecules and foreign antigen

Regulatory (helper and suppressor) T lymphocytes become activated only when foreign antigen is presented to them on the surface of antigen-presenting cells (APC), together with class II major histocompatibility complex (MHC) molecules (heterodimers of polypeptides of 28,000 and 35,000 relative molecular mass). Once activated by a certain foreign antigen--MHC combination, T cells react to the same antigen only in combination with the same MHC molecule, a phenomenon termed MHC restriction of T-cell recognition (reviewed in refs 1,5). Studies of the mechanisms involved in antigen presentation and MHC restriction have been hampered mainly by the virtual impossibility of inducing T-cell responses in the absence of APC. We describe here the production of synthetic lipid vesicles with inserted class II MHC molecules and a protein antigen coupled covalently to the lipid. These liposomes are shown to stimulate cloned helper T cells and T-cell hybridomas in an antigen-specific, MHC-restricted manner in the absence of APC. Thus, the recognition of foreign antigen together with class II MHC molecules seems to be the only signal required for the activation of antigen-primed regulatory T cells. Furthermore, 'processing' of antigen by APC is not essential for its recognition by T cells.

A unidirectional carrier effect

A surprising unidirectional carrier effect has been observed in the antibody response to myoglobin-ferritin conjugate. This conjugate serves as a hapten-carrier complex for myoglobin-specific T cells to help ferritin-specific B cells make anti-ferritin antibodies, but it does not function for ferritin-specific T cells to help myoglobin-specific B cells to make anti-myoglobin. Therefore, myoglobin-ferritin does not bypass the Ir gene defect of low responders to myoglobin. In contrast, myoglobin-fowl gamma-globulin does induce anti-myoglobin antibodies in low responder mice and thus bypasses the Ir gene defect. Both complexes are covalently coupled. Since the myoglobin-ferritin conjugate serves for myoglobin-specific T cells to help myoglobin-specific B cells, the myoglobin in the conjugate is not altered in a way that would prevent recognition by myoglobin-specific B cells. Similarly, the conjugate serves for ferritin-specific helper T cells to help ferritin-specific B cells, so it can be recognized functionally by ferritin-specific T helper cells. Explanations such as unidirectional induction of or sensitivity to bystander help, or T-cell suppression, have been excluded. While the explanation for this unexpected observation is not yet certain, several possibilities are discussed to explain this novel phenomenon, which is believed to be the first example of such a unidirectional carrier effect between two proteins.

Antigen-specific interaction between T and B cells

It is well known that B cells require T-cell help to produce specific antibody. Classic experiments suggested that antigen-specific helper T cells interact with antigen-specific B cells via an antigen 'bridge', the B cells binding to one determinant on an antigen molecule (the 'hapten'), while the T cells at the same time recognize another determinant (the 'carrier'). T-helper cells bind specifically to antigen-presenting cells (APC), which have picked up and processed the appropriate antigen, and this interaction, like the interaction of T-helper cells with specific B cells, is restricted by products encoded by the major histocompatibility complex (MHC). Whereas conventional APC such as macrophages display no binding specificity for antigen, B cells have clonally distributed antigen-specific surface immunoglobulin receptors which would be expected to enhance their capacity to present antigen to T cells. These findings are difficult to reconcile with the simple 'antigen bridge' mechanism of interaction, because it is hard to visualize how the bimolecular complex (processed antigen plus MHC molecule) on the APC surface can resemble the trimolecular complex (antigen bound to surface immunoglobulin plus MHC molecule) on the B-cell surface. To address this problem, we have cloned and immortalized human antigen-specific B cells with Epstein-Barr virus (EBV) and analysed their interaction with T-cell clones specific for the same antigen. We report here that surface immunoglobulin is indeed involved in the uptake and concentration of antigen, allowing specific B cells to present antigen to T cells with very high efficiency. However, the antigen must first be internalized and processed by specific B cells and it is then presented to T cells in an MHC-restricted manner indistinguishable from that characteristic of conventional APC.

Effect of prostaglandin E2 on the gamma-interferon induction of antigen-presenting ability in P388D1 cells and on IL-2 production by T-cell hybridomas

The effect of prostaglandin E2 on the gamma-interferon (IFN-gamma)-mediated induction of Ia expression and antigen-presenting activity in macrophage cell lines was studied. Using a lymphokine preparation obtained from the T-cell hybridoma FS7-20.6.18 (known to produce interferon) to induce the expression of Ia in P388D1 cells, the influence of PGE2 on this phenomenon was studied. Screening of the cell cultures by indirect immunofluorescence using an anti-I-Ad monoclonal antibody confirmed the inhibitory effect of PGE2 in the induction of I-Ad. However, the inhibition of the antigen-presenting ability of these cells, as measured by their capacity to stimulate interleukin 2 (IL-2) production by antigen-specific, I-region-restricted (Ag/I) T-cell hybridomas, was more difficult to demonstrate and was only evident when using low concentrations of Ia-inducing lymphokines or when using "low avidity" T-cell hybridomas. The latter were distinguished by the limited response (in the form of IL-2 production) that was observed when they were tested with P388D1 cells that had been induced with IFN-gamma. By contrast, PGE2 had profound inhibitory effects on the ability of T-cell hybridomas to secrete IL-2 in response to Ag/I or concanavalin A. These results suggest that although PGE2 inhibits the full induction of Ia on macrophages, it has little effect on the induction of Ag/I presentation by the same cells, probably because most T cells require relatively low levels of Ia on the surface of presenting cells. T-cell responses to Ag/I are inhibited, however, because of the effects of PGE2 on the T cells themselves.

The poised B cell: lymphokines induce an Ia-increase and antigen-presenting function in B cells

Individual murine B cells express a wide range of Ia densities on the plasma membrane. Here we demonstrate that a dramatic increase in B-cell Ia could be induced by overnight exposure to an uncharacterized lymphokine (LK). Membrane I-A and I-E molecules were both increased after LK treatment, whereas membrane IgM remained unchanged. Two subpopulations of B cells were identified, based on their requirements for expressing maximal Ia; one subpopulation required only LK, the other required both LK and T cells in the overnight culture. Functional changes accompanied the Ia increase. The functional capacity to present antigens to T cells was lacking in normal resting B cells, but was acquired following LK treatment. We suggest that the LK-treated B cell has achieved a new differentiation state, one of preparation for interaction with T cells. We term this state the "poised" B cell, and propose that B cells in the poised state may significantly contribute to T-cell activation as antigen-presenting cells. Moreover, poised B cells may themselves find an advantage over normal B cells in successfully acquiring T-cell help.

Antigen presentation by proliferating thymic macrophages to A (T,G)-A-L specific T cell line in an H-2 restricted manner

Long-term cultures of murine homogeneous populations of Ia-bearing thymus-derived murine macrophages were tested for their ability to present antigen to a (T,G)-A-L specific IL-2-dependent continuous T cell line. Thymus-derived macrophages, with and without pretreatment for Ia induction, triggered efficiently antigen-specific T cell proliferation in an MHC restricted way. This experimental system, consisting of two normal proliferating homogeneous populations of macrophages and antigen specific T cells, provides an ideal tool for studying the mechanism of antigen presentation to T cells and for elucidation of the role of macrophages in T-B cell collaboration for antibody production.

Major histocompatibility complex-restricted, polyclonal B cell responses resulting from helper T cell recognition of antiimmunoglobulin presented by small B lymphocytes

Anti-Ig has been widely used as a model for antigen receptor-mediated B cell activation. B cells activated with mitogenic concentrations of anti-Ig (approximately 10 micrograms/ml) become responsive to a set of T cell-derived, antigen-nonspecific helper factors that enable the B cells to proliferate, and, in some cases, mature to Ig secretion. In the present experiments, we show that anti-Ig can also be used as a model for major histocompatibility complex (MHC)-restricted, antigen-specific T-B cell collaboration. We used murine helper T cell lines and T cell hybridomas specific for a protein antigen, the F(ab')2 fragment of normal rabbit IgG. Small B cells are very efficient at presenting rabbit anti-IgM or rabbit anti-IgD to these rabbit Ig-specific T cell lines and hybridomas, and the responding (initially) small B cells, appear to be the only antigen-presenting cells required. Efficient presentation depends upon binding of rabbit antibody to mIg on the B cell surface. MHC-restricted recognition of rabbit Ig determinants on the B cell surface results in a polyclonal B cell response. This response is qualitatively different from the well-studied response to blastogenic concentrations of anti-Ig plus stable, T cell-derived helper factors, since it (a) requires 1,000-fold lower concentrations of anti-Ig, (b) involves helper T cell functions other than, or in addition to, the local production of the same stable helper factors, and (c) is largely MHC-restricted at the T-B cell level.

Epithelial cells expressing aberrant MHC class II determinants can present antigen to cloned human T cells

The first step in the induction of immune responses, whether humoral or cell mediated, requires the interaction between antigen-presenting cells and T lymphocytes restricted at the major histocompatibility complex (MHC). These cells invariably express MHC class II molecules (HLA-D region in man and Ia in mouse) which are recognized by T cells of the helper/inducer subset in association with antigen fragments. Interestingly, in certain pathological conditions, for example in autoimmune diseases such as thyroiditis and diabetic insulitis, class II molecules may be expressed on epithelial cells that normally do not express them. We speculated that these cells may be able to present their surface autoantigens to T cells, and that this process may be crucial to the induction and maintenance of autoimmunity. A critical test of this hypothesis would be to determine whether epithelial cells bearing MHC class II molecules (class II+ cells) can present antigen to T cells. We report here that class II+ thyroid follicular epithelial cells (thyrocytes) can indeed present viral peptide antigens to cloned human T cells.

B cell activation potential of insulin-reactive T cells in H-2b mice

The murine T cell response to heterologous insulins provides a good model system for studying the mechanism of immune response (Ir)-gene function, since insulin is a small, chemically well-defined molecule. H-2b mice respond predominantly to A chain loop determinants of beef insulin, presented by the I-A epitope Ia. W39. However, using a library of insulin-specific T cell hybridomas (THy), we previously found that immunization of H-2b mice with beef insulin activates a much wider population of T cells than are detected in T cell proliferation assays. Using such cloned THy we were able to study Ir-gene control at the level of antigen presentation. We compared the ability of the various THy to induce differentiation in I-A-matched B cells in response to antigen. Although both A and B chain-reactive clones respond with interleukin 2 production, they differ markedly in their potential to activate B cells in that only the former are able to induce B cell differentiation in the presence of the intact beef insulin molecule. The latter, however, can serve as helper cells in the presence of isolated B chain, and can synergize with a suboptimal concentration of A chain-reactive THy to induce an optimal B cell response. These results suggest that the insulin molecule is presented by I-Ab antigen-presenting cells in a very specific configuration that allows more effective T cell recognition of the A chain loop than the B chain determinants. To explain the discrepancy between the interleukin 2 assay and the induction of polyclonal activation, it can be assumed that in the former assay antigen is presented by macrophages, while presentation by B cells is necessary for induction of polyclonal activation. Macrophages are able to process the intact beef insulin molecule and, therefore, present B chain determinants, while nonimmune B cells may be unable to process antigen and could present B chain determinants only when the isolated B chain is given as antigen.

Processing and presentation of hen egg-white lysozyme by macrophages

The processing and presentation by macrophages of the well-defined protein hen egg-white lysozyme (HEL) was analyzed using two HEL-specific T cell hybridomas. The processing studies revealed that both clones required that native HEL be processed, while neither clone required any processing of a tryptic digest of lysozyme. A differential requirement for processing was found for the intact, denatured lysozyme (CM-HEL) with one clone (2A11) requiring processing, and a second clone (3A9) did not require any processing. The determinant on the HEL molecule that both clones recognized was localized to a tryptic fragment containing residues 46 to 61. By testing the immunogenicity of fragments of the 46-61 peptide, mouse lysozyme, and human lysozyme, we were able to localize the T cell determinant to either of two residues, Gly-49 or Leu-56.

Accessory cells and T cell activation. The relationship between two components of macrophage accessory cell function: I-A and IL1

Accessory cells are required for the activation of helper T cells. We have examined two characteristics of accessory cells, their expression of I-A, and their ability to release IL1. We provide evidence that these two properties are related, and postulate that membrane I-A molecules participate in the pathway leading to IL1-release. Experimental results are described relating I-A to IL1-release as follows: 1. In vitro-educated Ly1 T cells stimulate IL1-release from M phi; this process is H-2-restricted and blocked by anti-I-A antibodies. 2. H-2-restriction between T cells and M phi is overcome in the presence of ConA, but this unrestricted interaction is also blocked by anti-I-A. 3. LPS stimulation of IL1-release is blocked by anti-I-A. These findings suggested an active role for I-A molecules on IL1-producing cells. We next describe a series of experiments designed to assess the requirements for I-A versus IL1 during T cell activation. In a number of experimental systems, T cells demonstrated a requirement for I-A-recognition, but none that could not also be satisfied by IL1: 1. Generation of helper T cells in allogeneic chimeras. 2. Proliferation of KLH-primed lymph node cells. 3. Proliferation of KLH-primed lymph node cells from chronically anti-I-A-suppressed mice. 4. Proliferation of GAT-primed lymph node cells from nonresponder mice. These findings suggest that for many kinds of T cells (not necessarily all) the apparent requirement for I-A-recognition is primarily involved in stimulating IL1-release from accessory cells.

Resting and sensitized T lymphocytes exhibit distinct stimulatory (antigen-presenting cell) requirements for growth and lymphokine release

Previous studies have shown that unprimed or resting T lymphocytes will grow and release lymphokines when stimulated by dendritic cells (DC). We now have examined the stimulatory requirements for antigen-primed or blast-transformed T cells. The latter were derived from dendritic/T cell clusters that developed during the primary mixed leukocyte reaction (MLR). The specificity of the blasts was established by a binding assay in which most T cells aggregated small B lymphocytes of the appropriate haplotype within 2 h at 4 or 37 degrees C. Since unprimed T cells did not aggregate allogeneic B cells, we suggest that DC induce T lymphocytes to express additional functioning receptors for antigen. Lyt-2-T blasts did not grow or release interleukin 2 or B cell helper factors unless rechallenged with specific alloantigen, whereupon growth (generation time of 14-18 h) and lymphokine release rapidly resumed. The blasts could be stimulated by allogeneic macrophages, B cells, and B lymphoblasts, whereas the primary MLR was initiated primarily by DC. responsiveness appeared restricted to the I region of the major histocompatibility complex, and varied directly with the level of Ia antigens on the stimulator cells. The interaction of B cells and T blasts was bidirectional. The T blasts would grow and form B cell helper factors, while the B cells grew and secreted antibody. However, the efficacy of T cell-mediated antibody formation was enhanced some 10-fold by the addition of specific antigen. Therefore, responses of resting helper T cells, then, are initiated by antigen plus DC. Once sensitized, T blasts interact independently with antigen presented by other leukocytes.

Antigen presentation by supported planar membranes containing affinity-purified I-Ad

I-Ad, purified from A20-1.11 cells by affinity chromatography, was incorporated into supported planar membranes by incubation of I-Ad-containing phospholipid vesicles with clean glass coverslips. Such planar membranes present a peptide digest of ovalbumin to the ovalbumin-specific, I-Ad-restricted T-cell hybridoma 3DO-54.8, resulting in the antigen-specific release of interleukin 2. However, when the same material was provided in the form of small unilamellar vesicles, no response was obtained. Antigen presentation by the I-Ad-containing planar membranes was inhibited by the monoclonal antibody MKD6 (anti-I-Ad) but not by the antibody 10-2.16 (anti-I-Ak). The antibody GK1.5, which recognizes the T-cell surface antigen L3T4, was also inhibitory. In contrast to the results with purified I-Ad, crude membrane preparations from A20-1.11 cells were effective in antigen presentation in both planar and vesicular forms.