Use of a receptor competition assay to explore the interaction of the T cell antigen-specific receptor with its ligands

The observation has previously been made that receptor-bearing cells in culture compete with each other for their ligand. As a result, at a fixed concentration of ligand, the fractional occupancy of the receptor will tend to fall as the number of cells is increased. We have demonstrated that T cells in culture also compete for their ligand, the combination of foreign antigen and the Ia molecule (antigen-Ia), and that this manifests itself as shifts in the antigen dose-response curves as the number of responding T cells is increased. Because of the complexity of T cell activation, modifications to the antigen that affected its stimulatory capacity (i.e., its potency) could come about by altering its interaction with either the T cell receptor or the Ia molecule. We could distinguish between these two possibilities by studying the extent to which the antigen dose-response curves shifted as the T cell number was increased. Amino acid substitutions in the antigen that affected the interaction with the T cell receptor caused changes in the dose-response curve shifts, whereas substitutions that decreased potency by other means did not cause such changes. Finally, two allelic forms of the Ia molecule that differed only slightly in their amino-terminal domain were used to present a single antigen to a T cell clone. Despite a difference in antigenic potency in the presence of these two Ia molecules, no difference was demonstrated in the avidity of the T cell receptor for either antigen-Ia combination. These results suggest that the antigen and the Ia molecule make physical contact during the process of antigen recognition, and that the potency of an antigen can vary as a result of its interaction with either the T cell receptor or the Ia molecule.     

Functionally distinct agretopic and epitopic sites. Analysis of the dominant T cell determinant of moth and pigeon cytochromes c with the use of synthetic peptide antigens

The dominant T cell determinant on moth and pigeon cytochromes c in B10.A (E beta k:E alpha k) mice is located in the C-terminal portion of the protein, contained within residues 93-103 or 93-104. Thirty-seven antigen analogs, containing single amino acid substitutions at positions 98, 99, 101, 102, 103, and 104, were synthesized. The effects of the substitutions on in vitro antigenicity and in vivo immunogenicity were determined. Functional assays with T cell clones identified residues 99, 101, 102, and 103 as critical, based on their effect on antigenic potency. Peptides containing substitutions at residues 99, 101, and 102 were capable of eliciting unique clones upon immunization of B10.A mice. This was consistent with the identification of these residues as part of the epitope, the site on the antigen that interacts with the T cell receptor. Immunization with peptides substituted at residue 103, however, failed to elicit clones with unique specificity for the immunogen. When these peptides were tested for their ability to stimulate the T cell clones with antigen-presenting cells from B10.A(5R) mice expressing the E beta b:E alpha k Ia molecule, a consistent change in the relative antigenic potency was observed with 50% of the peptides. The effect of the Ia molecule on the antigenic potency ruled out the possibility that residue 103 nonspecifically affected antigen uptake or processing and identified residue 103 as part of the agretope, the site that interacts with the Ia molecule. The locations of the agretope and the epitope on this antigenic determinant appear to be fixed, even in the presence of large numbers of amino acid substitutions. However, some substitutions were found to affect both the agretope and the epitope, placing limits on the functional independence of the two sites. The results are discussed in terms of the trimolecular complex model of T cell activation and the implications of these data for antigen-Ia molecule interactions.     

The T lymphocyte response to cytochrome c. V. Determination of the minimal peptide size required for stimulation of T cell clones and assessment of the contribution of each residue beyond this size to antigenic potency

The B10.A T cell proliferative response to pigeon cytochrome c is mainly directed against a single antigenic determinant located at the carboxy-terminal end of the molecule. In the present experiments, we used synthetic peptide analogs of the carboxy-terminal sequence of moth cytochrome c to explore the structural requirements for antigenic potency. The minimum-sized peptide capable of stimulating a full response varied with the T cell clone, but within the limits of the biological systems studied, was shown to be moth fragment 97-103. Addition of more amino acids at the amino terminal end increased the antigenic potency in uneven increments, with a large contribution being made at residue 95. Analysis of amino acid substitutions at this position provided no evidence that it contained a residue that directly contacted the T cell receptor. Instead, good agreement with an analysis that made use of helix-coil transition theory suggested that this residue, as well as others, increased antigenic potency by contributing to the stabilization of the secondary structure of the molecule in an alpha-helical configuration. The maximum effect of chain length on antigenic potency appeared to stop at residue 93, in agreement with the theoretical analysis. However, addition of several more amino-terminal residues to residue 93 showed one additional significant increment of increased potency. This was almost entirely accounted for by a single lysine located four amino acids beyond the glutamic acid at residue 93 (approximately one turn of an alpha-helix away). To experimentally test whether alpha-helix-forming tendencies could account for the increased potency of the larger analogs, the degree of helix formation in trifluoroethanol was assessed by circular dichroism measurements. A good correlation was found between antigenic potency and percentage of alpha-helix for peptides of increasing chain length from moth 95-103 up to moth 86-90; 94-103. These results suggest that secondary structure may play an important role in determining the potency of antigenic determinants involved in the activation of T lymphocytes.     

The molecular basis of the requirement for antigen processing of pigeon cytochrome c prior to T cell activation

Antigen-induced activation of T lymphocytes that co-recognize Ia molecules has been shown to require an antigen-processing step by the presenting cell before T cell stimulation can occur. In this report, we demonstrate that antigen presentation of pigeon cytochrome c to an E kappa beta:E kappa alpha-restricted T cell hybridoma, 2C2, is inhibited by pretreatment of the antigen-presenting cells (APC) either with chloroquine or with fixation by paraformaldehyde. The chloroquine effect was partially reversible after 22 hr; the paraformaldehyde effect was not. In contrast, these treatments had little or no effect on the presentation of the carboxy-terminal cyanogen bromide cleavage fragment of pigeon cytochrome c, residues 81 to 104. There was at least a 50-fold greater potency of the fragment, as compared to that of the intact molecule, when paraformaldehyde-fixed APC were used. In addition, the fixed cells did not present synthetic fragments of the cytochrome c that were nonstimulatory when presented by unfixed cells. This observation showed that the loss of potency, demonstrated previously for analogs of pigeon cytochrome c with single amino acid substitutions at positions such as 99, was not a consequence of an alteration in the rate of antigen-processing. This result is consistent with our earlier hypothesis that these residues are contact amino acids with the antigen-specific T cell receptor or the Ia molecule. The major goal of these experiments was to define the molecular transition that occurred as a result of antigen processing. To achieve this end, we tested a variety of pigeon cytochrome c molecules and fragments for their ability to be presented by paraformaldehyde-fixed APC. Apocytochrome c, the denatured form of the molecule with the heme removed, could not be presented by the fixed cells, nor could the fragment 60-104, derived by acid cleavage of the tryptophan at position 59. Both molecules stimulated an IL 2 response from the T cell hybridoma when unfixed APC were utilized, demonstrating that the conditions used to prepare these two molecules did not destroy their antigenic determinant. In contrast, carboxy-terminal fragments, both native and synthetic, ranging in size from 16 to 39 amino acids, were capable of stimulating in the presence of paraformaldehyde-fixed APC. In particular, the partial-digest cyanogen bromide fragment, residues 66 to 104, was only twofold less potent than the pigeon fragment 81-104.(ABSTRACT TRUNCATED AT 400 WORDS)     

The relationship between immune interferon production and proliferation in antigen-specific, MHC-restricted T cell lines and clones

The release of immune or gamma interferon (IFN-gamma) by major histocompatibility complex (MHC)-restricted pigeon cytochrome c-specific Lyt 1+2-, interleukin 2 (IL 2)-producing proliferative T cell clones when cultured with antigen and antigen-presenting cells (APC) is a sensitive measure of the state of activation of the cell. In general, the fine specificity of T cell activation was similar when activation was measured either by IFN-gamma production or by proliferation. In response to antigen and the correct Ia molecule, the T cell clones produced both high titered IFN-gamma and a strong proliferative response. However, IFN-gamma production and the degree of proliferation of the T cell clones differed at high antigen concentrations. As antigen concentration increased, the magnitude of proliferation became submaximal whereas the IFN-gamma response became maximal suggesting that IFN-gamma produced by the cells might act as an autoregulatory molecule inhibiting the proliferative response. Stimulating the T cell to divide via its IL 2 receptor by adding exogenous IL 2 produced high levels of proliferation but only low titers of IFN-gamma activity. In addition, irradiation of the clone eliminated the IFN-gamma release induced by IL 2 but did not affect the IFN-gamma release induced by antigen and Ia. Thus proliferation is not essential for IFN-gamma production and unlike antigen and Ia, IL 2 functions predominantly as a proliferative signal and not as a signal for factor release. Two T cell clones showed a dissociation of IFN-gamma production and proliferation. In one case, a clone that proliferated in response to both allogeneic and antigenic stimuli released IFN-gamma in response to antigen but failed to produce IFN-gamma in response to the allogeneic stimulus. A second clone that showed a strong proliferative response to pigeon cytochrome c but no proliferative response to a species variant of cytochrome c, tobacco hornworm moth (THWM) cytochrome c, produced IFN-gamma when stimulated with either of these antigens. Thus, the sensitivity of detecting activation of T cell clones as measured by the release of an individual lymphokine varies from one clone to another.     

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.     

Site-directed mutations in the VDJ junctional region of a T cell receptor beta chain cause changes in antigenic peptide recognition

In order to assess the importance of a conserved amino acid in the VDJ junctional region of the beta chain of T cell receptors (TCRs) specific for pigeon cytochrome c, we generated T cell transfectant clones that express either a TCR identical to that of the cytochrome c-specific clone D6 or a mutated form of the D6 TCR, in which the conserved residue was replaced by one of two other amino acids. We have found that one substitution alters antigen fine specificity, while the other substitution abolishes all detectable cytochrome c response. On the basis of these findings, we propose that this conserved amino acid is a key residue in determining the antigen specificity of the D6 TCR.     

Functional analysis of the antigenic structure of a minor T cell determinant from pigeon cytochrome C. Evidence against an alpha-helical conformation

A minor T cell determinant from pigeon cytochrome c, composed of residues 43 to 58 (p43-58), was synthesized along with a series of 48 analogs containing amino or carboxyl-terminal deletions or single amino acid substitutions. These peptides were analyzed functionally for their ability to elicit unique T cell populations on immunization of C57BL/10 mice and to stimulate a degenerate T cell clone capable of recognizing p43-58 in association with two different Ia molecules, A beta b:A alpha b and A beta d:A alpha d. These experiments allowed us to identify the residues in the determinant that are critical for T cell activation. Residues 50 and 52 had the dominant influence on T cell specificity, and residues 47, 48, 49, 51, and 53 had weak effects. Residues 46 and 54 were hardly recognized by the TCR at all, but appeared to influence the potency of the determinant by interacting with the Ia molecule. Finally, substitutions at positions 55 to 58 had no effect, but removal of these residues reduced the potency of the peptide, suggesting a contribution from the peptide backbone of this part of the molecule during T cell activation. An analysis of the spatial relationship of these dominant epitopic and agretopic residues suggests that this determinant does not assume a pure alpha-helical secondary structure when bound to the Ia molecule.     

Three classes of signalling molecules on B-cell membranes

The question of whether surface immunoglobulin and Ia molecules have a signalling function in helper T cell-dependent activation of B cells has been evaluated. Two sources of B cells have been used, one a purified population of hapten-binding B cells, the other a B-cell lymphoma, CH12, with known antigen specificity. Evidence is presented that both immunoglobulin and Ia molecules are receptors actively involved in the initial activation of resting B cells. Nevertheless, the requirements for ligand binding to either receptor can be bypassed under appropriate conditions, and the implications of this result for the function of these molecules is discussed. With respect to B-cell Ia, the authors present data that demonstrate two distinct functions of this molecule, one as a restricting element for T-cell activation, the second as a signalling receptor for B-cell excitation. On the CH12 surface, the I-A molecule fulfills the former function, but T-cell interactions with I-A fail to result in B-cell stimulation, suggesting that B-cell Ia may limit helper T cell-B cell interactions. We suggest that the binding of antigen surface immunoglobulin and binding of helper T-cell receptors to the appropriate Ia molecule(s) results in the activation of genes that encode for a third class of membrane B-cell receptors, those that bind B-cell stimulating factors.     

Anti-idiotypic regulation of an insulin-reactive T cell clone

A series of MHC-restricted, bovine-insulin-(BI) reactive T cell clones were generated. The specificity of one group was shown to be for an insulin A-chain loop determinant; the other group apparently demonstrated specificity of a B-chain determinant and/or amino acid residue A4. Guinea pig anti-idiotypic antisera were prepared against two idiotypically related BI monoclonal antibodies of similar A-chain loop specificity. These reagents were able to modulate the antigen-specific proliferation of an insulin-reactive, A-chain loop-specific T cell clone. Because the monoclonal antibodies and the T cell clone recognize a similar molecular domain of the insulin molecule, these data suggest that the anti-idiotypic sera mimic an insulin-like determinant, perhaps by bearing an "internal image" of the antigen and thereby interfering with T cell antigen recognition. Further, these results suggest that such reagents may be useful in characterization of T cell antigen receptor specificity and lend further credence to the concept of idiotypic-anti-idiotypic regulation of the immune response.     

Different antigen-presenting cells differ in their capacity to induce lymphokine production and proliferation of an apo-cytochrome c-specific T cell clone

The activation of an apo-cytochrome c-specific T cell clone was found to differ, depending on the antigen-presenting cell population. Whereas total syngeneic spleen cells and bone marrow macrophages could be shown to trigger proliferation, IL 2, and MAF production by the T cell clone, a B cell lymphoma only induced MAF secretion. Further studies demonstrated that this effect was not due to a different antigen processing by the B lymphoma or to limiting amounts of Ia and antigen molecules on the B lymphoma cell surface. The dissociation of induction of MAF production from IL-2 production/proliferation found with the different antigen-presenting cells indicates strongly that molecules other than Ia and antigen may be required for the complete functional activation of antigen-specific T cell clones.     

The fine specificity of antigen and Ia determinant recognition by T cell hybridoma clones specific for pigeon cytochrome c

The activation of proliferative T lymphocytes normally involves the simultaneous recognition of a particular foreign antigen and a particular Ia molecule on the surface of antigen-presenting cells, the phenomenon of major histocompatibility complex (MHC) restriction. An analysis of T cell clones specific for pigeon cytochrome c, from B10.A and B10.S(9R) strains of mice, revealed the unusual finding that several of the clones could respond to antigen in association with Ia molecules from either strain. Using these cross-reactive clones, we performed experiments which demonstrated that both the Ia molecule and the T cell receptor contribute to the specificity of antigen recognition; however, MHC-linked low responsiveness to tuna cytochrome c (an immune response gene defect) could not be attributed solely to the efficacy with which the Ia molecules associated with the antigen. These results imply that antigen and Ia molecules are not recognized independently, but must interact at least during the process of T cell activation.     

Differential effects of monoclonal antibodies anti-L3T4 and anti-LFA1 on the antigen-induced proliferation of T-helper-cell clones: correlation between their susceptibility to inhibition and their affinity for antigen

Recognition by specific T helper (TH) cells of antigen presented by antigen-presenting cells (APC) involves, in addition to the antigen-specific receptor, non-antigen-specific molecules such as L3T4 and LFA1. In the present study, we analyzed the relationship between the avidity for antigen presented by APC of three TH cell lines and the participation of L3T4 and LFA1 cell surface antigens. We found a correlation between the avidity of TH cells for the complex GAT/Ia on APC measured by two independent assays and the participation of the cell-adhesion molecules L3T4 as measured by the ability of corresponding monoclonal antibody (MAb) to block the antigen-induced proliferation of TH cells. In contrast to the situation found with cytolytic T-lymphocyte (CTL) clones, we also found a differential inhibiting effect of anti-LFA1 MAb on the GAT-specific proliferation of the three TH clones. The results indicate a direct correlation between the inhibitory effects of anti-LFA1 and anti-L3T4 MAb and the affinity of TH cells for the complex formed by antigen and Ia.     

The pigeon cytochrome c-specific T cell response of low responder mice. I. Identification of antigenic determinants on fragment 1 to 65

An examination of the proliferative response to pigeon cytochrome c fragments 1 to 65 and 1 to 80 by T cells from mice that are low responders to the native molecule revealed that some of the strains could respond to antigenic determinants on these fragments. T cell clones derived from B10.A(3R) and B10.A(4R) mice were used to characterize the antigenic determinants on fragment 1 to 65. All of the clones recognized syngeneic A beta:A alpha Ia molecules as their restriction element. Three B10.A(3R) clones and six B10.A(4R) clones recognized fragment 39 to 65. Another four B10.A(4R) clones responded to fragment 1 to 38. By stimulating with a series of cytochrome c fragments from different species, as well as a synthetic peptide, it was possible to localize the antigenic determinant(s) recognized by the B10.A(3R) clones to residues 45 to 58. Each clone showed a unique pattern of responsiveness to the various fragments, suggesting a diversity of T cell receptors specific for the same peptide. One B10.A(3R) clone could be stimulated by many of the 1 to 65 fragments in association with allogeneic B10.SM presenting cells and by tuna fragment 1 to 65 in association with B10.M presenting cells, although the rank order of potency for several of the fragments was different than that observed with syngeneic antigen-presenting cells. In addition, the clone was poorly reactive to a synthetic peptide containing a conservative substitution, serine for threonine, at position 49. The implications of these results for subsite dissection (agretope and epitope) of the antigenic determinant recognized by this clone are discussed.     

Alteration of a non-polymorphic residue in a class II E beta gene eliminates an antibody-defined epitope without affecting T cell recognition

The interaction between the clonally selected T cell receptor, antigen, and Ia molecule is poorly understood at the molecular level. A cell line bearing an altered E beta k molecule has been examined to provide more information about the relationship between Ia structure and function. The cell line, 2B1, was derived from the TA3 B cell hybridoma through a series of negative and positive immunoselection steps. The 2B1 mutant lacked the binding site recognized by the 17.3.3 monoclonal antibody (mAb) but presented antigen normally to all I-Ek-restricted T cell hybridomas and clones examined. Sequence analysis of the mutant E beta k gene showed a single base transition (G----A) that resulted in an arginine to a histidine substitution at amino acid 49 of the beta 1 domain. This mutation demonstrates that residue 49 is not involved in antigen presentation to T cells but can be involved in B cell recognition (mAb binding).     

The T lymphocyte response to cytochrome c. IV. Distinguishable sites on a peptide antigen which affect antigenic strength and memory

The murine T cell proliferative response to the carboxyl terminal cyanogen bromide cleavage fragment 81-104 of pigeon cytochrome c (cyt) has been studied. Two interesting properties of this response have been previously described. First, T cells from B10.A mice primed with pigeon cyt 81-104 show more vigorous proliferation when restimulated with moth cyt 81-103 than when stimulated with pigeon cyt 81-104; that is, the B10.A T cell response to pigeon shows heteroclitic restimulation by moth. Second, T cells primed with the acetimidyl derivative (Am) of pigeon cyt 81-104 did not cross-react with the unmodified cyt fragments, but Am-moth cyt 81-103 still stimulated Am-pigeon cyt 81-104 primed T cells better than the Am-pigeon cyt 81-104 fragment. These results raised the issue of whether the antigenic sites on the fragments responsible for the specificity of T cell priming in vivo differed from the residues that contributed to the heteroclitic response of pigeon (or Am pigeon)-primed T cells to moth cyt c fragments. In this paper, synthetic peptide antigens were tested in order to identify which residues caused the heterocliticity of the moth fragment and which residues were involved in the antigenic differentiation of native and derivatized fragments. The heterocliticity of the T cell response to moth fragment 81-103 was found to be due to the deletion of the penultimate residue (Ala103) from the pigeon fragment. However, the ability to cause heterocliticity was not uniquely a property of this deletion. T cells from animals primed with peptides containing substitutions at positions 100 or 102 were also heteroclitically stimulated by the moth-like antigen. The observation that T cells could not be primed for recognition of the changes in peptide sequence that caused heteroclitic stimulation suggests that T cells do not directly recognize determinants in this region. The antigenically significant site of derivatization for T cell priming was found to be Lys99. Furthermore, substitution of a Gln at position 99 also resulted in elicitation of yet a third set of T cell clones specific for the presence of that residue. That is, the specificity of the primed T cell population was found to be altered by changes at residue-99, but no such alterations in specificity were demonstrable when T cells primed with peptides altered at residue-103, residue-102, or residue-100 were compared. Overall, the results demonstrate that the antigen can be divided into two functionally distinct sites that are in close physical proximity.     

The interaction of nominal antigen with T cell antigen receptors. I. Specific binding of multivalent nominal antigen to cytolytic T cell clones

In this report, we describe an experimental strategy for analyzing the interaction of nominal antigen with antigen-specific T cell clones. Our approach was based on the notion that low affinity interactions between nominal antigen and T cell antigen receptors might be detected by using a highly multivalent form of the antigen in which a large number of identical, appropriately spaced epitopes are attached to a polymer backbone. Antigens of this kind should be capable of multivalent binding to receptors on the T cell, resulting in a marked enhancement of the overall avidity of the interaction. To examine this possibility, we established a series of murine cytolytic T cell (Tc) clones specific for the readily detectable hapten fluorescein isothiocyanate (FL). These clones lysed FL-conjugated target cells in an antigen-specific fashion and also showed specificity for target cell MHC gene products. The interaction of these clones with the nominal antigen FL was assessed by flow cytometry, using a series of water-soluble FL-conjugated polymers varying in polymer backbone and FL isomer. High m.w. (600 to 2000 Kd) polymers of acrylamide, dextran, or Ficoll conjugated with 300 to 800 FL groups/molecule bound specifically to anti-FL Tc clones. There was little binding to syngeneic spleen cells, thymocytes, noncytolytic T cell clones, or T cell clones specific for other haptens such as NIP. Polymer concentrations in the 1 to 10 micrograms/ml range produced readily detectable binding within minutes at 20 degrees C, and the binding approached plateau levels at polymer concentrations of between 100 and 300 micrograms/ml. Studies with closely related FL isomers showed that the same antigen fine specificity was operative in both lysis of FL-conjugated target cells and in binding of FL-conjugated polymers. The functional significance of the observed binding was assessed by measuring the effect of FL-conjugated polymers on lymphokine secretion by the clones. High m.w. FL-conjugated polymers caused a dose-dependent increase in the production of macrophage activation factor (MAF) by anti-FL Tc clones, but did not increase MAF production by an NIP-specific clone. In contrast, concanavalin A induced MAF production by both FL-specific and NIP-specific clones. Thus, the observed binding is both specific and functionally significant. These results suggest that soluble nominal antigen, in an appropriately multivalent form, can bind specifically to antigen receptors on Tc clones.     

The use of hydrophobic, alpha-helix-defined peptides in delineating the T cell determinant for pigeon cytochrome c

The B10.A T cell proliferative response to pigeon cytochrome c is largely directed to a single site in the molecule located at the carboxyl terminus within the amino acid sequence of residues 81 to 104. This study uses the pigeon cytochrome c-specific T cell clone A.E7 and synthetic peptide analogs to clarify the role of certain residues within this sequence in T cell recognition. By using the helically constrained amino acid, alpha-aminoisobutyric acid, alternated with alanine in an amino-terminal leader sequence, we generated a series of molecules of similar length and alpha-helical conformation but which contain increasing lengths of the native sequence. By comparing the stimulatory ability of this series of peptides, we have clearly identified that the isoleucyl residue at position 95 in pigeon cytochrome c is essential for T cell recognition. This series, when compared with a series containing the same native sequences but without the leader sequence, also showed that the presence of the leader sequence has a general effect on enhancement of T cell recognition. An analysis of the conformational preferences of the peptides using circular dichroism indicated that all of the peptides with leader sequences have a strong preference for the alpha-helical conformation in nonpolar solvents. However, the introduction of helix-breaking residues into these peptides, with a concomitant measured reduction in alpha-helix, did not affect their recognition by clone A.E7. This implies that factors other than conformational stabilization are responsible for the full potency of these peptides. Binding studies to phospholipid vesicles indicated that residues in the leader sequence and in the amino terminus of segment 81-104 beyond residue 95 were important in increasing the ability of the antigens to bind to membranes. These results suggest that the capacity to bind to membranes may be a significant factor in the dose response of T cells to exogenously presented peptides.     

High frequency and nonrandom distribution of alloreactivity in T cell clones selected for recognition of foreign antigen in association with self class II molecules

Previous studies have demonstrated that a single T cell clone can respond to both a foreign antigen in the context of self major histocompatibility complex (MHC)-encoded molecules (self plus X) and to an allogeneic class I or class II molecule in the absence of antigen (non-self). We have used limiting dilution of T cells obtained from the draining lymph nodes of antigen-primed B10.A mice to establish a large number of T cell clones that recognize either GAT, pigeon cytochrome c, or sheep insulin in association with syngeneic antigen-presenting cells. Sixty-two antigen-specific T cell clones were assayed for their ability to proliferate in response to a panel of nine different allogeneic haplotypes. Of these, 38 (61%) responded to at least one allogeneic haplotype, and 15 of the 38 (39%) responded to more than one allogeneic stimulator. In addition, the patterns of alloreactivity varied with the immunizing antigen. The GAT-specific T cells had at least one responder to every haplotype tested, although H-2u-responsive T cell clones were the most common. In contrast, no pigeon cytochrome c-specific T cells responded to stimulators of the H-2u haplotype, but rather predominantly responded to H-2t4/H-2s and H-2i5/H-2b. Finally, sheep insulin-reactive T cell clones preferentially responded to H-2u stimulators, although stimulation by antigen-presenting cells of the H-2p and H-2q haplotypes was also common. A chi 2 analysis of the data demonstrated that the dependence of the pattern of alloreactivity observed upon the antigen used for immunization was statistically significant (p less than 0.01). The high frequency of alloreactivity found in antigen-specific T cell clones is discussed, as well as the implications that the antigen-dependent skewing of the distribution of alloreactivity have for a one-receptor model vs a two-receptor model of T cell recognition.     

Antigen presentation by hapten-specific B lymphocytes. IV. Comparative ability of B cells to present specific antigen and anti-immunoglobulin antibody

The ability of trinitrophenyl (TNP)-binding murine B lymphocytes to present native rabbit IgG (RGG), TNP-modified RGG, and rabbit anti-mouse Ig (RAMG) to an Ia-restricted, RGG-specific helper/inducer T cell clone was compared. By three independent assays (lymphokine secretion, T cell proliferation, and B cell differentiation), TNP-RGG was presented at 10(2)- to 10(3)-fold lower concentrations than RGG, and RAMG at 10(2)- to 10(3)-fold lower concentrations than TNP-RGG. The available data suggest that the efficiency of antigen presentation is dependent primarily on the avidity of binding of a ligand to B cell surface Ig and/or the extent of subsequent endocytosis (modulation). Despite the observed quantitative differences between anti-Ig (RAMG) and specific antigen (TNP-RGG), these results demonstrate that qualitatively both are essentially similar in their ability to mediate specific T-B interactions. Thus, anti-Ig antibodies are valid models for analyzing cognate interactions between antigen-specific B and helper T lymphocytes.