Functional differentiation in the genetic control of murine T lymphocyte responses to human fibrinopeptide B

The ability to generate proliferative and helper T lymphocyte responses in mice was compared by using the 14 amino acid peptide, human fibrinopeptide B (hFPB). Lymph node or peritoneal exudate T cells from mice immunized with hFPB were assessed for in vitro proliferation to soluble hFPB as determined by the uptake of 3H-thymidine. The T cell proliferative response to hFPB was found to be under MHC-linked Ir gene control; mice possessing the H-2a,k haplotypes were responders, whereas H-2b,d,q,s mice were nonresponders. The influence of non-H-2 genes on these responses was not investigated, so exclusive regulation by H-2 is provisional. The absence of a detectable lymph node and peritoneal exudate T cell proliferative response persisted in H-2b,d,q,s mice after immunization and boosting with several doses of hFPB. In addition, the capacity to produce a T cell proliferative response was inherited in an autosomal dominant manner and gene(s) controlling responsiveness to hFPB mapped to the I-A subregion of the H-2 complex. To measure peptide-specific helper T cell activity, an in vitro microculture assay in which hFPB-primed lymph node T cells and normal spleen B cells and macrophages were used was developed measuring anti-fluorescein isothiocyanate (FITC) IgM and IgG plaque-forming cell (PFC) responses after culture with FITC-conjugated peptide. Immunization of B10.BR, C57BL/10, B10.D2, and B6AF mice with hFPB primed for significant helper T cell activity as assessed by the ability to augment a primary in vitro IgM response to FITC. The normal B cell IgM responses were completely dependent on hFPB-primed T cells and required that hapten (FITC) and carrier (peptide) be linked. In addition, immunization with FITC-conjugated peptide elicited positive in vivo PFC responses to FITC in B10.BR and C57BL/10 mice, indicating similar genetic control of helper activity in both the intact animals and the in vitro microcultures. Thus, B10.BR mice show both T help and T proliferative responses to hFPB, whereas C57BL/10 mice show only T help and no T proliferative responses. In contrast to B10.BR mice, C3H and CBA mice immunized with hFPB were completely unresponsive when assayed for helper T cell activity in vitro despite their ability to generate positive lymph node T cell proliferative responses. These results indicate responsiveness to hFPB by T helper and proliferating cells is different and is under separate genetic control.     

Nonrandom catabolism of proteins in the formation of antigenic peptide fragments

To examine the role of protein catabolism in the formation of antigenic peptide fragments, human fibrinopeptide-immune guinea pig T cells were stimulated with the large native molecule, human fibrinogen. Two different systems were tested. In the first, we determined responses by human fibrinopeptide B (hFPB)-immune T cells, to which strain (St.) 2 guinea pigs are responders and St. 13 are nonresponders, and by human fibrinopeptide A (hFPA)-immune T cells to which St. 13 are responders and St. 2 are nonresponders. Of interest in this comparison is that both hFPA and hFPB are amino terminal peptides on the A and B chain of fibrinogen, respectively, and are readily cleaved by thrombin during fibrin formation and by other trypsin-like enzymes, leaving a carboxyl terminal Arg. Thus, if fibrinogen catabolism occurred, both antigenic peptides should be equally represented for availability in T cell responses. It was found that hFPB-immune St. 2 T cells responded to fibrinogen, but no response was observed with hPFA-immune St. 13 T cells cultured with fibrinogen. To rule out that there was a general catabolic defect in St. 13 antigen-presenting cells, fibrinogen was presented by (2 X 13)F1 macrophages to fibrinopeptide-immune parental T cells. Again it was found that F1 macrophages could present fibrinogen to hFPB-immune T cells but failed to present hFPA. In another comparison, responses with fibrinogen were also determined with des-ARg-hFPB, which lacks the carboxyl terminal Arg of hFPB, to which St. 13 are responders and St. 2 are nonresponders. The advantage of this comparison is that both antigenic determinants are contained within the same small peptide. St. 13 des-Arg-hFPB-immune T cells failed to respond in vitro by culture with human fibrinogen, suggesting that these antigenic determinants are not produced from larger peptides or proteins containing those determinants. To rule out the possibility that this was only an in vitro phenomenon, guinea pigs were immunized with the larger protein, the B chain of fibrinogen, and the immune T cells were examined for responses to fibrinopeptides derived from the B chain. Immune St. 2 T cells responded to hFPB but not to des-Arg-hFPB, whereas St. 13 T cells remained unresponsive with both peptides. These results indicate that proteolysis of larger proteins to form small antigenic peptides is not a random event and that not all potential antigenic determinants contained in a protein are produced during antigen processing.     

Nature of T lymphocyte recognition of macrophage-associated antigens. III. Definition of the antigenic regions of human fibrinopeptide B involved in guinea pig T-cell responses

The clonal diversity of guinea pig T-lymphocyte responses to the 14-amino-acid peptide antigen human fibrinopeptide B (hFPB, Bβ1–14) and sequential hFPB³ homologs (Bβ5–14 and 7–14) was examined using bromodeoxyuridine (BUdR) and light elimination of T cell responses. PPD and hFPB-immune strain 2 guinea pig T cells and macrophages were stimulated in a first culture with PPD, Bβ1–14, 5–14, or 7–14; BUdR was added on the second day and the cultures exposed to light on the third day. The BUdR and light-treated T cells recovered from the first culture were restimulated in a second culture containing fresh stimulator macrophages and PPD, Bβ1–14, 5–14, and 7–14. BUdR and light-treated T cells initially stimulated with Bβ1–14 in the first culture showed no responsiveness to Bβ1–14, 5–14, or 7–14 in the second culture. BUdR and light-treatment of T cells initially stimulated with Bβ5–14 eliminated 70 to 80% of the subsequent response to Bβ1–14 and all of the responsiveness to Bβ7–14. Similar treatment of T cells stimulated with Bβ7–14 reduced responsiveness to Bβ1–14 by 50 to 60% and to Bβ5–14 by 60 to 70%. These observations indicate that T-cell responses are directed against three antigenic regions in the hFPB molecule; the major region defined by the carboxy-terminal sequence including residues 7 to 14, a second minor antigenic region including residues 5 and 6, and a third minor region including the amino terminal residues 1 to 4. Results are discussed with respect to the regions of the hFPB molecules that are recognized by antigen-binding T-cell receptors and the regions which interact with stimulator macrophages.     

CD4+ T cells cross-compete for MHC class II-restricted peptide antigen complexes on the surface of antigen presenting cells

CD4(+) T cells are activated upon recognition of peptide antigen in the context of MHC class II molecules, expressed by specialized APC. In this study, we show that CD4(+) T cells cross-compete for antigenic complexes on the surface of APC, inhibiting activation of other potentially reactive T cells of the same and differing specificities. T cells with either a higher affinity receptor for antigen or which have undergone prior activation compete more efficiently than low affinity or resting T cells. This implies that T-cell avidity for the APC is primarily responsible for the competitive advantage. We also provide evidence that the mechanism for competition is steric hindrance of the surface of the APC, rather than T-cell-mediated sequestration or internalization of antigenic complexes. This is because removal of competing T cells restores the antigenic potential of the APC, and APC fixation does not abrogate competition. Demonstration that competition for access to APC can also occur in vivo suggests that this process may represent a physiologically important mechanism for influencing the quality and quantity of CD4(+) T-cell responses.     

Proliferating and helper T lymphocytes display distinct fine specificities in response to human fibrinopeptide B

The fine specificity of T cell responses involved in the generation of help for antibody production and proliferation was examined by using the 14 amino acid peptide human fibrinopeptide B (hFPB, B beta 1-14) and its synthetic peptide homologues B beta 1-14(Lys14), B beta 1-13, and B beta 3-14. Peritoneal exudate or lymph node T cells from C57BL/10 and B10.BR mice immunized with hFPB or its synthetic homologues were used to measure in vitro proliferative responses. T cells from hFPB-immunized B10.BR mice showed specific proliferation to hFPB, but were unresponsive to B beta 1-14(Lys14), B beta 1-13, and B beta 3-14. B10.BR mice immunized with B beta 1-14(Lys14), B beta 1-13, or B beta 3-14 were unresponsive to all peptides tested. T cells from C57BL/10 mice showed no specific proliferation after immunization and challenge with any of the peptide antigens. In contrast to the patterns of T cell proliferation, immunization of both B10.BR and C57BL/10 mice with hFPB, B beta 1-14(Lys14), B beta 1-13, or B beta 3-14 primed for significant helper T cell activity, as assessed by the augmentation of a primary in vitro B cell IgM anti-FITC plaque-forming cell response after culture with B beta 1-1(Lys14)-FITC. Significant peptide-specific helper activity was observed when the FITC moiety was conjugated to the carboxyl terminal lysine (B beta 1-14(Lys14)-FITC) as well as FITC substitution at the amino terminus (FITC-B beta 3-13 or FITC-B beta 3-14). These results suggest that the fine specificity of T cell responses to peptide antigens are different for helper and proliferating T cells and that responsiveness by one T cell subpopulation does not predict the response pattern of other functional subpopulations.     

Molecular requirements for T cell activation by the staphylococcal toxic shock syndrome toxin-1

The activation of Ag-specific, Ia molecule-restricted, TCR V beta 3+ T cell clones by staphylococcal toxic shock syndrome toxin-1 (TSST-1), was investigated. The results show that although Ag- and TSST-1-induced activation of T cell clones both require TCR expression and similar biologic activation signals, the Ia molecule requirement for TSST-1 recognition was much less stringent than that observed for antigenic peptide recognition. In addition, T cell clones recognized TSST-1 without processing by APC. These results suggest that the ability of TSST-1 to polyclonally activate T cells is dependent on TCR recognition of the intact toxin molecule bound to a nonpolymorphic region(s) of the Ia molecule resulting in the same activation events induced by Ag recognition.     

IA mutant functional antigen-presenting cell lines

We describe a protocol for the selection of mutant cells with an altered pattern of Ia antigenic determinants and antigen-presenting properties from a homogeneous population of functional antigen-presenting cells (APC). The APC line used in this work was obtained by fusing lipopolysaccharide-stimulated B cells from (BALB/c x A/J)F1 donors with cells from the M12.4.1 BALB/c B lymphoma cell line. The resulting hybridomas, including TA3, retained the potent antigen-presenting activity of the parental B lymphoma line and expressed Ia antigens and immune response gene-determined antigen-presenting properties of the A/J type. Mutants of TA3 were obtained by subjecting the cells to negative immunoselection with one monoclonal anti-(alpha) 1-Ak antibody and complement followed by positive immunoselection via electronic cell sorting with a second monoclonal alpha I-Ak or alpha I-Ek antibody. Two types of mutants were obtained. One, A8, appeared to have undergone a fairly limited alteration, since it lost only some of the I-Ak antigenic determinants; the second type appeared to have lost the entire I-Ak molecule but to have retained the I-E molecule. Functional studies with the A8 mutant demonstrated that the loss of a limited number of I-Ak determinants correlated with the loss of a specific I-Ak-encoded restriction element, since A8 failed to present a specific antigen, hen egg lysozyme (HEL), to a HEL-specific I-Ak-restricted T cell hybridoma but retained some capacity to present a second antigen, poly(Glu60Ala30Tyr10) (GAT), to a GAT-specific I-Ak-restricted T cell hybridoma. These results indicate that Ia antigens are the products of immune response gene loci. The availability of such mutants should allow an examination of the relationship between the structure of an Ia molecule and the antigens with which it is co-recognized by T cells.     

Role of APC in the selection of immunodominant T cell epitopes

Following antigenic challenge, MHC-restricted T cell responses are directed against a few dominant antigenic epitopes. Here, evidence is provided demonstrating the importance of APC in modulating the hierarchy of MHC class II-restricted T cell responses. Biochemical analysis of class II:peptide complexes in B cells revealed the presentation of a hierarchy of peptides derived from the Ig self Ag. Functional studies of kappa peptide:class II complexes from these cells indicated that nearly 20-fold more of an immunodominant epitope derived from kappa L chains was bound to class II DR4 compared with a subdominant epitope from this same Ag. In vivo, T cell responses were preferentially directed against the dominant kappa epitope as shown using Ig-primed DR4 transgenic mice. The bias in kappa epitope presentation was not linked to differences in class II:kappa peptide-binding affinity or epitope editing by HLA-DM. Rather, changes in native Ag structure were found to disrupt presentation of the immunodominant but not the subdominant kappa epitope; Ag refolding restored kappa epitope presentation. Thus, Ag tertiary conformation along with processing reactions within APC contribute to the selective presentation of a hierarchy of epitopes by MHC class II molecules.     

The role of CTLA-4 in the regulation of T cell immune responses

Over the past few years a great deal of research has examined how T cell-dependent immune responses are initiated and subsequently regulated. Ligation of the TCR with an antigenic peptide bound to an MHC protein on a professional APC provides the crucial antigen-specific stimulus required for T cell activation. Interaction of CD28 with CD80 or CD86 molecules on APC initiates a costimulatory or second signal within the T cell which augments and sustains T cell activation initiated through the TCR. However, recently it has become clear that T cell immune responses are a result of a balance between stimulatory and inhibitory signals. Cytotoxic T lymphocyte-associated molecule-4 (CTLA-4) is a cell surface molecule that is expressed nearly exclusively on CD4+ and CD8+ T cells. Investigation into the role of CTLA-4 in the regulation of T cell immune responses has revealed that CTLA-4 is a very important molecule involved in the maintenance of T cell homeostasis. In the present review, evidence for the proposed inhibitory role of CTLA-4 is examined and a model suggesting a role for CTLA-4 in both early and late stages of T cell activation is presented.     

Role of L3T4 and Ia in the heteroclitic response of T cells to cytochrome c

The activation of helper T lymphocytes has been proposed to result from the sum of low-affinity interactions between the specific immune receptor, as well as nonpolymorphic receptors such as L3T4 on the T cell surface, and nominal antigen and Ia displayed in a multivalent array on the antigen-presenting cell surface. The present work takes advantage of a T cell hybridoma specific for pigeon cytochrome c in the context of I-Ek, which responds to tobacco hornworm moth cytochrome c at one hundredth the concentration of the homologous antigen, to determine if the T cell's requirement for L3T4 and Ia is directly related to its functional affinity for antigen. The results demonstrate that the T cell's activation by pigeon cytochrome c was blocked by antibodies directed to L3T4 and to I-Ek, even at antigen concentrations twofold to fourfold above those required for maximal responses. In contrast, the response to tobacco hornworm moth cytochrome c was not as affected by these antibodies under equivalent superoptimal conditions. The same phenomenon was observed for the T cell's activation by the carboxyl-terminal peptide fragments of the two cytochromes c, which do not require processing, indicating that the differences were not due to the relative efficiency of processing and/or presentation of the antigens. Although both I-Ek- and L3T4-specific antibodies blocked the T cell response to pigeon cytochrome, antibodies to I-Ak had no effect, even though I-Ak had been considered to be a ligand for L3T4. Thus, either Ia does not bind L3T4 or, if it does, I-Ek must be a sufficient ligand for L3T4 for T cells that recognize their antigen in the context of I-Ek. These studies provide more definitive evidence that the T cell's requirement for the functions of Ia and of L3T4 is dependent on the T cell's functional affinity for its antigenic determinant. This data is consistent with a model of T cell activation in which, given a high enough affinity of the T cell receptor for the processed antigen, the requirement for other components of a stimulatory complex, such as Ia and L3T4, may diminish to undetectable levels.     

Dissection of the functions of antigen-presenting cells in the induction of T cell activation

The functions of antigen-presenting cells (APC) in the initiation of T cell activation was examined by culturing antigen-bearing guinea pig macrophages (M phi) with T cells obtained from antigen-primed animals. Although such antigen-bearing M phi stimulated primed syngeneic T cell DNA synthesis, as assessed by tritiated thymidine incorporation, paraformaldehyde fixation (0.15% for 1 min at 37 degrees C) abolished this capacity. Analysis with acridine orange staining indicated that fixed antigen-bearing M phi could not trigger primed syngeneic T cells to progress from the G0 to the G1 phase of the cell cycle. The addition of control non-antigen-bearing syngeneic or allogeneic M phi but not interleukin 1 or 2 to cultures of T cells and fixed APC permitted a proliferative response. Although the interaction between fixed antigen-bearing M phi and responding T cells was genetically restricted, there was no similar restriction for the supplemental control M phi. In fact, completely Ia-negative endothelial cells (EC) and fibroblasts (FB) could restore antigen responsiveness to cultures of fixed antigen-bearing M phi and syngeneic responding T cells, although they could not directly present antigen. Moreover, metabolically intact accessory cells, including Ia-negative EC and FB, could take up and process antigen to an immunogenic moiety, which fixed Ia-positive M phi could present to primed T cells. These data indicate that recognition of the antigen-Ia complex on an APC is necessary but not sufficient to trigger proliferation of freshly obtained primed T cells. The results additionally support the conclusion that APC carry out at least two separate functions necessary for the initiation of antigen-induced T cell activation. Not only must the APC display the antigen-Ia complex, but it must also convey another required effect. This influence, which apparently involved the establishment of cell to cell contact, was neither Ia nor antigen dependent and could only be provided by a metabolically intact cell. By contrast, genetically restricted antigen presentation could be accomplished by a fixed Ia-positive cell. Only when both the antigen-Ia complex and the influence of an intact accessory cell were provided by the same or different accessory cell were T cells triggered to enter the cell cycle.     

Antigen presentation of a modified tumor-derived peptide by tumor infiltrating lymphocytes

CD8+ T-lymphocytes recognize peptides in the context of major histocompatibility complex (MHC) class I antigens. Upon activation, these cells differentiate into effector cytotoxic T lymphocytes (CTL) and no longer require formal antigen presentation by professional antigen presenting cells (APC). Subsequently, any cell expressing MHC class I/cognate peptide can stimulate CTL. Using TIL specific for a melanoma antigen-derived peptide, IMDQVPFSV (g209 2M), we sought to determine whether these CTL could present peptide to each other. Our findings demonstrate that peptide presentation of the g209 2M peptide epitope by TIL is comparable to conventional methods of using T2 cells as APC. We report here that CTL are capable of self-presentation of antigenic peptide to neighboring CTL resulting in IFN-gamma secretion, proliferation, and lysis of peptide-loaded CTL. These results demonstrate that human TIL possess both APC functions as well as cytotoxic functions and that this phenomenon could influence CTL activity elicited by immunotherapy.     

Analysis of the interaction of peptide hen egg white lysozyme (34-45) with the I-Ak molecule

We examined the structural characteristics of a peptide Ag that determine its ability to interact with class II-MHC molecules and TCR. The studies reported here focused on recognition of the hen egg white lysozyme (HEL) tryptic fragment HEL(34-45) by two I-Ak-restricted T cell hybridomas. HEL(34-45) bound to I-Ak created more than one antigenic specificity. Experiments with truncated peptides and alanine-substituted peptides indicated that two T cell hybrids either recognized distinct regions of the HEL(34-45) peptide, or different determinants generated by interaction of the peptide with I-Ak. Although we identified residues of HEL(34-45) that were critical to T cell recognition, no positions in the peptide were identified as I-Ak contact sites using single alanine substitutions. This suggests that more than one site or region of the peptide contributes to the binding to I-Ak. Finally, the murine lysozyme equivalent of 34-45 did not bind to I-Ak. Substitution of the corresponding murine lysozyme (self) residue at position 41 of HEL(34-45) abrogated I-Ak binding of the peptide.     

The role of B7 costimulation in T-cell immunity.

CD4+ T cells are considered to be the major controlling element of the adaptive immune response. They recognize foreign peptides by interaction of the T cell receptor (TCR) with peptide complexed to major histocompatibility complex (MHC) class II molecules on the surface of antigen presenting cells (APC). Once activated, CD4+ T cells orchestrate the various phases of the immune response. They are responsible for the production of numerous cytokines, which activate specific immune effector cell populations including B cells, eosinophils, mast cells and macrophages. Not surprisingly, the activation of CD4+ T cells needs to be tightly regulated and is subject to finely tuned control mechanisms. The requirement for a second or 'costimulatory' signal, in addition to the antigenic signal, provides a key element for the exquisite control of T cell activation. One of the major signalling pathways responsible for delivery of this costimulatory signal is induced by interaction of CD28 on T cells with B7 molecules found only on APC. The present review outlines our current understanding of the physiological role of B7 costimulatory signals in regulating CD4+ T cell responses.     

Functional and biochemical parameters of peptide antigen presentation

To understand the mechanism by which peptide antigens are processed and presented to T cells, we examined the T-cell response to the 13-amino-acid peptide alpha-melanocyte-stimulating hormone (alpha-MSH). To determine the fine specificity of T-cell recognition, T cells specific for alpha-MSH, and genetically restricted by I-Ab/d, were challenged with different alpha-MSH analogs and homologs. It was found that intact alpha-MSH, including the blocked amino and carboxy termini of the native molecule, was required for T-cell responsiveness. Antigen-presenting cells (APC) could be briefly pulsed with alpha-MSH and then present the alpha-MSH antigenic determinant to T cells, indicating that the relevant antigen was retained by the APC. APC stimulatory capacity was dramatically reduced by aldehyde treatment of the APC, or by pulsing the APC with alpha-MSH at low temperature. Efficient alpha-MSH pulsing was also impaired by treatment of the APC with the carboxylic ionophore, monensin, but not by the lysosomotropic agents chloroquine and methylamine. In addition, isolated APC plasma membranes added to the T cells in the presence of soluble alpha-MSH were not stimulatory. However, plasma membranes isolated from APC that had been previously pulsed with alpha-MSH retained stimulatory activity for T-cell responses. The only detectable alpha-MSH contained in these pulsed APC membranes was in an acid-stable complex of higher molecular weight than native peptide. The amount of alpha-MSH detected in the cellular membrane fraction isolated by density gradient sedimentation was also reduced by treatments that reduced the APC stimulatory capacity, such as pulsing at low temperature or in the presence of monensin. Taken together, these results suggest that processing of alpha-MSH is unlike that heretofore described for other peptide antigens and seems to involve APC handling to form the stimulatory moiety presented on the APC surface.     

Epitopic analysis by anti-I-Ak monoclonal antibodies of I-Ak-restricted presentation of lysozyme peptides

Anti-I-A mAb were used as probes of functional epitopes for both the presentation of hen egg lysozyme (HEL) peptides to I-Ak-restricted T cell hybridomas and the direct binding of the HEL (46-61) peptide. When mAb directed to polymorphic regions of I-Ak were used as inhibitors of Ag presentation, several different patterns of inhibition were observed among T cells specific for the same HEL peptide as well as among T cells specific for different fragments of HEL. Although there appears to be a conserved usage of some TCR V beta gene segments among the T cell hybrids specific for the same HEL peptide, no correlation is evident between a single V gene usage and susceptibility to blocking of Ag presentation by a particular anti-I-Ak mAb. Several of the mAb demonstrated T cell "clonotypic blocking" of Ag presentation, whereas others blocked presentation to every T cell hybrid tested, regardless of the peptide specificity. When mAb directed to nonpolymorphic regions of the I-A molecule were tested for their ability to block Ag presentation, little or no inhibition was observed. In addition, Fab' fragments of inhibitory mAb functioned identically to their intact homologous counterparts in their ability to block Ag presentation indicating that "nonspecific" steric hindrance was not playing a major role in the inhibitions observed. When the polymorphic region-directed anti-I-A mAb were tested for their ability to block the direct binding of the lysozyme peptide HEL(46-61) to I-Ak, those mAb that block HEL presentation to all T cell hybrids were found to block the binding of this peptide. However, anti-I-A mAb that demonstrate selective inhibition of T cell hybrid stimulation during Ag presentation, i.e., those directed to polymorphic serologic specificities Ia.15 and Ia.19, do not block the binding of HEL(46-61) to I-Ak. These data indicate that functionally independent epitopes exist on the I-Ak molecule for the binding of antigenic peptides and for interaction with the TCR.     

Antigen presentation and the triggering of the immune response

Immune defense is based on the interaction of nonspecific factors of natural resistance and factors of antigen-specific adaptive immune response. The key event of this interaction is antigen presentation. Its matter is a recognition of antigenic peptide complexed with MHC molecule of class II on the antigen-presenting cell (APC) surface by TCR receptor of T helper cell. The realization of the antigen presentation is connected with some problems: the number of cells in specific T cell clones is too low; the complexes of each peptide with MHC-II is a low part of the general population of APC surface peptide-MHC-II complexes; the bonds forming between these complexes and TCR molecules are too weak and some other molecules must be involved to reach T cell activation. These difficulties and mechanisms of their overcoming are considered in the review.     

Two roles for Ia in antigen-specific T lymphocyte activation

In this study we examined the mechanism by which a PPD-specific murine T cell hybridoma, 8B2, recognized PPD associated with antigen-presenting cells (APC) in a manner genetically restricted by I-Ad. It was found that PPD-pulsed APC that were glutaraldehyde-fixed and treated with anti-Ia monoclonal antibody (abbreviated as PGM) were unable to stimulate the 8B2 T cells, as expected, due to inhibition caused by antibody binding to the Ia. However, addition of non-antigen-treated, glutaraldehyde-fixed APC (abbreviated as G) to cultures containing 8B2 T cells and PGM restored T cell activation, as determined by IL 2 production. This second non-antigen-specific function provided by the additional APC, G, was attributed to Ia and could be substituted by APC plasma membranes and by soluble membrane extracts. Genetic restriction analysis in which a variety of Ia-positive and Ia-negative cell lines and B cell blasts from different mouse strains were used as PGM or as G showed that each APC provided different Ia determinants that were specifically recognized by the T cells. PGM cells had to express I-Ad in order to present the PPD determinant, whereas the non-antigen-specific function was specific for I-Ad or I-Ab. These results suggest that the anti-Ia antibody does not interfere with the PPD/I-Ad-specific determinant bound by the antigen-specific T cell receptor, but prevents a second non-antigen-specific interaction with another region of the Ia molecule, which is provided by G. These two roles for Ia (antigen-specific and non-antigen-specific) were also found for activation of normal polyclonal PPD-specific T cell responses; thus they are not unique to the 8B2 T cell, but are generally applicable. In addition, T cell interactions with PGM and with G each provide different intracellular activation signals. This was determined by substituting the PGM or the G with either the tumor promoter phorbol 12-myristate 13-acetate (PMA) or the Ca++ ionophore, ionomycin. It was found that 8B2 T cells cultured with PGM and ionomycin, but not with PGM and PMA, were activated for IL 2 production. Neither PMA nor ionomycin in conjunction with G resulted in T cell activation. Taken together, these results indicate that 8B2 T cell activation involves APC Ia antigens in two different ways: one is to contribute to the presentation of the foreign PPD antigen, and a second is a non-antigen-specific Ia-T cell interaction necessary to provide additional intracellular activation signals.(ABSTRACT TRUNCATED AT 400 WORDS)     

Contribution of antigen processing to the recognition of a synthetic peptide antigen by specific T cell hybridomas

Most antigens recognized by T cells require unfolding or partial degradation (processing) followed by association with Major Histocompatibility Complex (MHC) molecules. We examined the processing requirements for the presentation of antigen to two T cell hybridomas which recognize the alpha-helical synthetic polypeptide antigen Poly 18, Poly [EYK(EYA)5], in association with I-Ad. Hybridoma A.1.1 responds to EYK(EYA)4 as the minimum antigenic sequence while hybridoma B.1.1 recognizes (EYA)5 sequence. It was found that these hybridomas responded to Poly 18 and to minimum peptide sequences presented by glutaraldehyde and chloroquine treated antigen presenting cells (APC), suggesting that antigen processing is not a requirement for the activation of these cells. The reactivity pattern of hybridoma B.1.1 in the presence of glutaraldehyde fixed APC revealed that antigens containing lysine were presented with much less efficiency than antigens without lysine, suggesting an interaction of these residues with the antigen presenting cell surface. We discuss the possibility that alanine residues in the alpha-helical Poly 18 form a hydrophobic ridge which may be required for appropriate interaction between antigen, the T cell receptor, and MHC molecules.     

Heterogeneity in cellular antigen retention structures

The mechanism of presentation of foreign antigens to helper T lymphocytes and the nature of the structures involved in this process are not totally understood. It is well documented that this event is carried out by antigen-presenting cells (APC) (e.g., macrophages, dendritic cells, and B lymphocytes) that internalize the antigen, process it, reexpress it on their membrane surface, and present it to the T cell in the context of major histocompatibility complex class II (Ia) molecules. Recent evidence supports the hypothesis that peptide antigens associate directly with Ia molecules on the APC surface membrane. However, the characteristics of other APC membrane structures potentially involved in antigen presentation are not entirely clear. Previous studies in our laboratories identified a guinea pig macrophage membrane-bound, non-Ia-containing antigenic complex (peak A) formed upon incubation of APC with the octapeptide antigen angiotensin (AII). This complex was capable of stimulating AII-immune guinea pig T cells and thus appeared to contain the immunologically relevant form of the antigen. For this reason it was important to establish whether such complex formation with peptides occurs with other cell types and with other peptide antigens. In the present study we found that other types of cells are also capable of forming such a membrane complex with antigen (peak A) and that this event is not unique to AII. Two other peptides, alpha-melanocyte-stimulating hormone and human fibrinopeptide B, both of which are antigenic in mice, were found to form peak A with a number of murine cell lines. As in our earlier studies with guinea pig macrophages, there was no evidence from these experiments for a role for major histocompatibility complex Ia antigens in the peptide binding observed. Differences in both the amount of peak A formation and the pattern of peptide antigen degradation were found from cell line to cell line for a given peptide, and from peptide to peptide for a given cell line, suggesting cellular heterogeneity in peptide processing and retention. In addition, cross-inhibition studies indicated that there was peptide specificity in the formation of peak A perhaps suggestive of molecular heterogeneity in the structure of peak A. These results indicate that there may be several types of cell surface molecules that specifically bind and retain peptide antigens.(ABSTRACT TRUNCATED AT 400 WORDS)