Clonal anergy induced in a CD8+ hapten-specific cytotoxic T-cell clone by an altered hapten-peptide ligand.

Clonal T-cell anergy has been proposed as a mechanism to ensure peripheral tolerance in vivo. Anergy has been reported to result from T cell activation with inappropriate antigen-presenting cells (APC) or, in the case of CD4+ T cells, also by altered peptide ligands. This study reveals that altered hapten ligands can also induce anergy in CD8+ T cells. The Kb-restricted, trinitrophenyl (TNP) specific cytotoxic T lymphocyte (CTL) clone E6 was found to lyse target cells presenting the TNP-modified peptides M4L-TNP (derived from mouse serum albumin) or O4TNP (derived from chicken ovalbumin), but not the corresponding dinitrophenol (DNP)-modified peptides. However, whereas M4L-DNP was found totally unreactive, O4DNP antagonistically inhibited M4L-TNP-mediated kill if expressed on the same target cell. Moreover, when presented alone on APC, O4DNP, but not M4L-DNP, induced anergy in clone E6 by preventing its subsequent proliferative response to M4L-TNP. The anergic state did not affect agonist-specific cytolysis or T-cell receptor (TCR) down-modulation by the anergized CTL, and proliferative responses were regained upon addition of interleukin (IL)-2 or IL-12 plus IL-18. These findings substantiate the similarity between hapten-and peptide-recognition by T cells. The induction as well as the reversal of anergy in CD8+ CTL may thus be of relevance not only in autoimmunity or tumour rejection, but also in contact hypersensitivity reactions to haptens.

Antigen contacts by Ni-reactive TCR: typical alphass chain cooperation versus alpha chain-dominated specificity.

VB17(+) TCR dominate in Ni-driven T cell cultures from highly Ni-sensitized patients. Using transfection of TCR from three CD4(+), VB17(+), Ni-specific human T cell clones, we studied their Ni-MHC contacts by site-directed TCR mutation and combination of alpha and ss chains between different TCR. All three TCR exhibited N-nucleotide-determined Arg-Asp motifs in their CDR3-ss sequences. Two of them were specifically restricted to HLA-DR13, while the third one accepted a variety of HLA-DR alleles. The highly similar alpha or ss chains of the DR13-restricted TCR were interchangable without loss of specificity, but alpha or ss chains of other TCR were not tolerated. Mutations of their Arg-Asp motif revealed loss of reactivity upon exchanging Asp for Glu or Ala and of Arg for Ala but not of Arg for Lys or the Ni binding His. Reactivity was also destroyed by mutation of alpha chain position 51, proposed as a general contact site for MHC. Hence, in these two TCR the Arg-Asp motif is clearly involved in contacting Ni-MHC complexes, and close cooperation between alpha and ss chain is required. In contrast, the third TCR retained Ni reactivity upon mutation of alpha chain position 51 or of its ss chain Arg-Asp motif, which rather affected the pattern of DR cross-restriction. Moreover, its alpha chain paired with various ss chains from other, even mouse TCR, irrespective of their specificity, retaining Ni reactivity as well as promiscuous HLA-DR restriction. This preponderance of an alpha chain in defining specificity indicates fundamental differences in Ni interactions of individual TCR and implies that ss chain similarities may not necessarily result from antigen selection.

Kinetics of CXCR4 and CCR5 up-regulation and human immunodeficiency virus expansion after antigenic stimulation of primary CD4(+) T lymphocytes.

The chemokine receptors CCR5 and CXCR4 are coreceptors for the human immunodeficiency virus (HIV) and determine the cell tropism of different HIV strains. Previous studies on their regulation were performed under conditions of unspecific T-lymphocyte stimulation and provided conflicting results. To mimic physiologic conditions, highly purified primary Staphylococcus enterotoxin B (SEB)-reactive CD4 T lymphocytes were stimulated in the presence of autologous antigen-presenting cells and the kinetics of CCR5 and CXCR4 surface expression and HIV replication were studied. Both chemokine receptors were transiently up-regulated with maximal expression at day 3 after stimulation. The stimulated T cells were equally susceptible to productive infection with R5-and X4-tropic virus strains. Thus, antigenic stimulation of T cells promotes efficient replication of both, T cell-tropic and macrophage-tropic HIV. (Blood. 2000;96:1853-1856)

Peptide immunization indicates that CD8+ T cells are the dominant effector cells in trinitrophenyl-specific contact hypersensitivity.

The identity of the effector T cell population involved in contact hypersensitivity is still questionable with evidence promoting both CD4+ or CD8+ T cells. Previous experimental studies have relied on the in vivo depletion of T cell subsets using antibody, or the use of knock-out mice with deficiencies in either CD4+ or CD8+ T cell-mediated immunity. To address the role of the class I- and class II-mediated pathways of T cell activation in contact hypersensitivity responses in mice with an intact immune system, we utilized various trinitrophenyl-derivatized peptides, which bind specifically with H-2Kb (major histocompatibility complex class I) or H-2I-Ab (major histocompatibility complex class II). The subcutaneous injection of major histocompatibility complex class II-specific, but not of class I-binding, hapten-derivatized peptides in incomplete Freund's adjuvant induced specific, albeit low, contact hypersensitivity responsiveness to trinitrochlorobenzene. When bone-marrow-derived dendritic cells, however, were pulsed with the same peptides and administered intradermally, the opposite result was observed, namely that the class I binding peptides induced contact hypersensitivity responses similar to that observed after epicutaneous trinitrochlorobenzene application. In contrast, dendritic cells pulsed with major histocompatibility complex class II binding peptides did not reproducibly sensitize for contact hypersensitivity responses. Surprisingly, both immunization protocols efficiently induced CD8+ effector T cells. These results support the notion that CD8+ T cells are the dominant effector population mediating contact hypersensitivity responsiveness and that the CD4+ T cell subset only contributes little if at all.

Functional expression and analysis of a human HLA-DQ restricted, nickel-reactive T cell receptor in mouse hybridoma cells.

Nickel-induced contact dermatitis represents a T cell mediated delayed type hyperreactivity. The elucidation of the molecular basis of T cell activation by Ni2+ ions may serve as a model for the understanding of other metal allergies. We describe here the expression of hybrid T cell antigen receptor (TCR) alpha- and beta-genes, containing rearranged human Ni-reactive variable and mouse constant regions, together with human CD4 in a mouse T cell hybridoma. The resulting hybridoma specifically responds to IL-2 secretion to Ni, but not to other metal ions in the presence of HLA-matched antigen-presenting cells. Loss of CD4 decreases, but does not completely abrogate this reactivity. The restricting HLA-DQ element is identified as consisting of DQA1*0101 and DQB1*0501; however, only some of the B cell lines homozygous for these molecules effectively present Ni to the hybridoma. We interpret these data to show that (i) Ni-reactivity is definitely mediated by alpha beta TCR variable regions; (ii) as for peptide-specific TCR, the CD4 co-receptor enhances Ni-reactivity, but is not absolutely essential; (iii) Ni2+ ions like nominal peptide antigens require HLA (here class II) molecules of the APC for presentation; (iv) the restricting molecule may require a special conformation or the association with a particular type of peptide or an as yet unidentified other surface structure on the antigen-presenting cell for effective Ni-presentation.

TCR reactivity in human nickel allergy indicates contacts with complementarity-determining region 3 but excludes superantigen-like recognition.

Nickel is the most common inducer of contact sensitivity in humans. We previously found that overrepresentation of the TCRBV17 element in Ni-induced CD4+ T cell lines of Ni-allergic patients relates to the severity of the disease. Amino acid sequences of these beta-chains suggested hypothetical contact points for Ni2+ ions in complementarity-determining region (CDR) 1 and CDR3. To specifically address the molecular requirements for Ni recognition by TCR, human TCR alpha- and beta-chains of VB17+ Ni-reactive T cell clones were functionally expressed together with the human CD4 coreceptor in a mouse T cell hybridoma. Loss of CD4 revealed complete CD4 independence for one of the TCR studied. Putative TCR/Ni contact points were tested by pairing of TCR chains from different clones, also with different specificity. TCRBV17 chains with different J regions, but similar CDR3 regions, could be functionally exchanged. Larger differences in the CDR3 region were not tolerated. Specific combinations of alpha- and beta-chains were required, excluding a superantigen-like activation by Ni. Mutation of amino acids in CDR1 of TCRBV17 did not affect Ag recognition, superantigen activation, or HLA restriction. In contrast, mutation of Arg95 or Asp96, conserved in many CDR3B sequences of Ni-specific, VB17+ TCR, abrogated Ni recognition. These results define specific amino acids in the CDR3B region of a VB17+ TCR to be crucial for human nickel recognition. CD4 independence implies a high affinity of such receptor types for the Ni/MHC complex. This may point to a dominant role of T cells bearing such receptors in the pathology of contact dermatitis.

Antigen-dependent and -independent IFN-gamma modulation by penicillins.

The activation of CD4+ T lymphocytes upon Ag stimulation plays a critical role in adverse immune responses including drug-specific hypersensitivity reactions. We examined the modulation of T cell phenotype induced by hapten-specific stimulation using the model of beta-lactam antibiotics such as penicillin G (Pen G), Pen V, and ampicillin (Amp). When PBMC of donors suffering from hypersensitivity reactions against beta-lactams were stimulated in vitro with different doses of Pen G, a preferential expansion of IL-4-producing TCR alphabeta+ cells was detected. A panel of T cell clones was then prepared from Pen G-specific lines after two cycles of restimulation with the hapten. For the majority of these clones, we found that high doses of Pen G induced optimal IL-4 secretion, whereas the amount of IFN-gamma secreted was inversely correlated with the dose of Pen G, thus leading to a hapten-inducible shift of the functional phenotypes for some of the clones. Finally, Pen V and Amp were used to modulate different Ag-induced immune responses. We found that Amp had no influence on the cytokine pattern induced by specific Ag or mitogens. In contrast, Pen V inhibited the secretion of IFN-gamma, but not IL-4, most likely by Ag-independent mechanisms. This last finding may open new applications for immune intervention in those diseases in which polarized Th1 responses are involved in the development of the pathology.

Partial agonism and independent modulation of T cell receptor and CD8 in hapten-specific cytotoxic T cells.

We recently demonstrated antagonism for hapten-reactive T cells by altered hapten ligands. Here we investigated partial peptide- or hapten-agonism and effects of antigen stimulation on the expression of TCR and the CD8 coreceptor using a set of DNP- or TNP-peptide-induced, H-2Kb-restricted mouse CTL clones. Various Kb-binding TNP- and DNP-peptides acted as partial agonists, cross-reactively stimulating individual clones for cytotoxicity and IFN-gamma secretion, but failing to induce proliferation or TNF-alpha production. Full agonism, i.e. activation of all possible functions, was usually restricted to those hapten-peptide combinations used for the induction of the respective clones. Our data imply distinctive kinetic optima for TCR antigen contacts in the induction of the various T cell effector functions. Down-regulation of TCR was efficiently induced by full, but with one exception not by partial, agonists, indicating the independence of cytotoxicity or IFN-gamma secretion from TCR modulation. On the other hand, a reduction of TCR expression induced by full agonists was usually not accompanied by synchronous down-modulation of CD8 as reported by others for human T cells. In fact, three of four full agonists and all partial agonists markedly enhanced rather than reduced the expression of CD8. Increased CD8 surface levels enhanced cytolytic potential and increased cross-reactivity patterns of individual clones. Brefeldin A blocked this CD8 induction by partial agonists, and in the case of full agonists resulted in a parallel reduction of both, TCR and CD8. Thus, antigenic stimulation of mouse T cells initially down-modulates CD8 together with TCR, but the loss of coreceptor is over-compensated by a signal for increased CD8 export.

MHC-dependent and -independent activation of human nickel-specific CD8+ cytotoxic T cells from allergic donors.

T lymphocytes are critical effectors in the pathogenesis of contact hypersensitivity. Nickel is the most common contact sensitizer in humans and nickel-specific CD4+ T helper cells have been extensively characterized. Because recent observations have suggested the activation of CD8+ T cells in murine models of contact hypersensitivity, we investigated the existence of CD8+ hapten-specific T lymphocytes in patients with allergy to nickel. Nickel-specific T cell lines were generated from the peripheral blood of three allergic donors. The T cell lines were composed of a majority of CD4+ T cells, but CD8+ T cells were also present and their percentage increased with repeated in vitro stimulations. In addition to nickel-reactive helper T cell-0-type or helper T cell-2-type CD4+ T cell clones, CD8+ T cell clones could be derived from these cell lines and a total of 15 clones were further studied. Cytokine production was evaluated for 11 CD8+ T cell clones that were either cytotoxic T cell-0- or cytotoxic T cell-1-type clones. Additional effector functions were investigated on the complete panel of T cell clones. These CD8+ T cells did not only display hapten-specific proliferation, but also specific cytotoxic activities towards autologous EBV-B cells in the presence of nickel. Two different types of CD8+ T cells were characterized. Most of the clones lysed only autologous targets in the constant presence of nickel; however, one clone was able to lyse numerous targets in the presence of NiSO4, irrespective of the expression of either major histocompatibility complex class I or class II molecules. The characterization of nickel-specific cytotoxic CD8+ T cells with different requirements for nickel-specific target lysis, may have important implications in the development or in the control of human contact hypersensitivity reactions to nickel in vivo.

Further characterization of UVB radiation effects on Langerhans cells: altered expression of the costimulatory molecules B7-1 and B7-2.

We have reported previously that low-dose UVB radiation (UVBR, 50-200 J/m2) perturbs the antigen-presenting cell (APC) function of murine Langerhans cells (LC) by interfering with yet undefined costimulatory signals. In this study, we investigated (1) the effects of UVBR on the expression of the costimulatory molecules B7-1 and B7-2 on murine LC, (2) the functional consequences of defective B7-1 and B7-2 signalling on primary and secondary T-cell responses induced by LC and (3) the mechanism by which UVBR interferes with B7-1 and B7-2 expression. Ultraviolet-B radiation dose-dependently inhibited the culture-induced upregulation of B7-1 and B7-2 on LC from both UVB-susceptible (UVBs, C57BL/6) and UVB-resistant (UVBR, Balb/c) mice and abrogated their capacity to stimulate proliferation of naive alloreactive T cells and of the KLH (keyhole limpet hemocyanin)-specific T helper (Th)1 clone HDK-1. The UVBR-induced suppression of B7-1 and B7-2 on LC and their perturbed APC function were related, because exogenous triggering of the B7/CD28 pathway with a stimulatory monoclonal antibody (mAb) for CD28 to UVB-irradiated LC partially restored T-cell proliferation. Such reconstitution was not observed when the mAb was added to killed LC, indicating that the UVBR-induced suppression of APC function was not due to lethal effects on LC. Conditioned supernatants from UVB-irradiated epidermal cells did not inhibit the functional upregulation of B7-1 and B7-2, suggesting that UVBR inhibits B7-1 and B7-2 upregulation by acting directly on LC and not by altering LC costimulatory function via release of soluble immunosuppressive factors. In conclusion, UVBR distorts the functional expression of B7-1 and B7-2 on LC from both UVBS and UVBR mice, thereby contributing to the failure of UVB-irradiated LC to stimulate resting alloreactive T cells or KLH-specific Th1 cells.

Molecular features of penicillin allergy.

Haptens, such as drugs and other low molecular weight chemicals, become immunogenic only upon binding to proteins. Among antibiotics, penicillins are most commonly used for the treatment of bacterial infections and constitute a typical example of allergy inducing drugs in humans. Previous work on their immunologic properties focused mainly on the examination of IgE-mediated hypersensitivity reactions; however, drug-specific T cell reactions are also involved in causing a serious allergic inflammatory response. This review will focus on the interaction between antibiotic molecules and penicillin-specific T lymphocytes in humans. Experimental data accumulated so far on the reactivity of T cells with penicillin G point to penicilloyl-modified, major histocompatibility complex-associated peptides as T cell epitopes. The recognition specificity of the respective T cell receptors appears to be directed at both the backbone and the specific side chain of penicillin. In contrast, the sequence of the carrier peptides appears to contribute little to the antigenic specificity, mainly as a holder for the haptenic determinant. Finally, recent results demonstrating the capacity of penicillins to modulate, in vitro, the Th0/Th2 phenotype of established T cell clones will be presented and discussed in relation to possible therapeutic applications.

Dominance of the BV17 element in nickel-specific human T cell receptors relates to severity of contact sensitivity.

Hypersensitivity to nickel (Ni) represents the most common manifestation of contact allergy in humans. The role of metal-specific T cells in this disease is well established, but the molecular interactions involved in their activation are poorly understood. We examined the T cell receptor (TCR) repertoire in T cells activated with either NiSO4 or NiSO4-treated human serum albumin from six allergic patients. For the three most hyperreactive donors, we found a strong over-representation of the TCR BV17 element. TCR sequencing for one of these donors revealed an additional skewing for AV1 as well as a selection for an N region encoded argine at position 95 of the BV17 complementarity determining region (CDR)3. Since Arg is not known to participate in Ni complexing, we suppose that this selection is driven by contacts with peptide rather than nickel. However, the CDR1 of BV17 contains a unique combination of amino acids (HDA) that bears similarities to known motifs in Ni-binding proteins or peptides. We therefore propose that the severe hypersensitivity reactions found in BV17 over-expressors may be the result of Ni2+ ions bridging the germ-line-encoded BV17 CDR1 loop to corresponding sites in the major histocompatibility complex/peptide complex and thereby creating a superantigen-like enhancement of weak TCR-peptide contacts.

Penicilloyl peptides are recognized as T cell antigenic determinants in penicillin allergy.

Although hapten immune responses have been intensively studied in the mouse, very little is known about hapten determinants involved in human allergic reactions. Penicillins, as chemically reactive compounds of low molecular weight, constitute typical examples of hapten allergens for humans. Penicillins become immunogenic only after covalent binding to carrier proteins and in this form frequently induced IgE-mediated allergic reactions in patients subjected to antibiotic treatment. However, our previous data strongly indicated that penicillins also form part of the epitopes contacting the antigen receptors of beta lactam-specific T cells in allergic individuals. We have therefore investigated the molecular constraints involved in the T cell immune response to penicillin G (Pen G). Designer peptides containing a DRB1*0401-binding motif and covalently modified with Pen G via a lysine epsilon-amino group were found to induce proliferation of Pen G-specific T cell clones. A precise positioning of the hapten molecule on the peptide backbone was required for optimal T cell recognition. Furthermore, we extended these observations from our designer peptides to show that a peptide sequence derived from a natural DRB1*1101-binding peptide modified in vitro with Pen G, also acquired antigenic properties. Our data for the first time provide insight into the manner in which allergenic haptens are recognized by human T cells involved in allergic reactions to drugs and suggest possible mechanisms leading to the onset of these adverse immune responses.

Altered hapten ligands antagonize trinitrophenyl-specific cytotoxic T cells and block internalization of hapten-specific receptors.

Low molecular chemicals (haptens) frequently cause T cell-mediated adverse immune reactions. Our previous work provided evidence that hapten-specific T cells, in analogy to those specific for nominal peptide antigens, direct their TCR towards hapten-modified, MHC-associated peptides. We now demonstrate that trinitrophenyl (TNP)-specific, class I MHC-restricted CTL from mice may exhibit exquisite specificity for subtle structural details of these hapten determinants, surpassing even the specificity of immunoglobulins. More importantly, these CTL could be antagonized by ligands altered either in their peptide sequence or in their hapten structure. The system was employed to examine the molecular basis of T cell antagonism. Whereas agonists resulted in a dose-dependent downregulation of TCR in different mouse T cell clones, antagonistic peptides totally failed to do so despite engaging the specific TCR. Moreover, simultaneous presentation of antagonist and agonist on the same antigen presenting cell prevented TCR internalization. No signs of anergy or functional receptor inactivation were observed in CTL treated with antagonist-loaded target cells. Based on a serial triggering model of T cell activation, our data favor a model in which antagonists block T cell functions by competitively engaging the specific TCR in unproductive interactions.

Carrier-independent hapten recognition and promiscuous MHC restriction by CD4 T cells induced by trinitrophenylated peptides.

The elucidation of mechanisms underlying the recognition of haptens by class II MHC-restricted T cells is instrumental for the understanding of chemical- and drug-induced allergies. We have previously demonstrated that trinitrophenyl (TNP) peptides represent dominant antigenic epitopes for CD8+ and CD4+ mouse T cells triggered by chemically TNP-modified APC. Here, we report the characterization of TNP-specific, CD4+ mouse T cell lines and hybridomas that were induced in vivo and in vitro by defined hapten-conjugated peptides. These peptides, which we had previously shown to induce contact sensitivity to picryl chloride in vivo regardless of sequence homologies to mouse proteins, were found to activate carrier-independent TNP-specific T cells in vitro. We interpret these findings to support our view that carrier-independent T cells, reactive to particularly repetitive hapten epitopes, may play a crucial role in allergies to chemicals and drugs. In addition to carrier independence, one of our hybridomas (IT-H6/A11) exhibited a striking promiscuity of MHC restriction. Although absolutely dependent in its TNP reactivity on the presence of MHC class II molecules, the IT H6/A11 hybridoma completely ignored class II polymorphism and even reacted to TNP peptides presented on human DR molecules. Regarding hapten allergies in humans with a heterozygous situation for three types of class II molecules (DR, DP, and DQ), such promiscuous MHC restriction should lead to the presentation of even higher epitope densities to the respective T cell clones. Hybridoma IT-H6/A11, reacting to TNP independent of carrier peptide and of MHC haplotype, also allowed for an unusually systematic study of the minimal requirements for TNP recognition. Despite an almost complete ignorance of amino acid side chains on the carrier peptide, our data indicate a clearly position-specific interaction of hapten and TCR.

Selective activation of CD8 T cell effector functions by epitope variants of lymphocytic choriomeningitis virus glycoprotein.

We provide evidence for selective activation of different effector functions of CD8+ T lymphocytes by altered peptide ligands. A T cell epitope from the glycoprotein of lymphocytic choriomeningitis virus (p33-41) and single amino acid variants thereof were used for primary in vitro induction of CTL clones. When the CTL were analyzed for cytotoxicity, proliferation, IFN-gamma production, and Ca2+ mobilization, we found that some of the clones showed activation of only their cytotoxic effector function when stimulated with variants of their inducing peptides. For one clone, cytotoxic reactivity was readily detected to the inducing peptide and three of four variants, but only the former was also able to trigger proliferation, IFN-gamma production, and Ca2+ mobilization. Another clone also revealed this dichotomy, but in this case some of the altered peptide ligands in addition to the inducing peptide were able to stimulate the full spectrum of effector functions, whereas others only stimulated cytotoxicity. A third clone revealed inefficient triggering of some effector functions by the peptide variants. Our data suggest that, as described for CD4 T cells, altered peptide ligands may lead to partial activation of effector functions of CD8 T cells. In addition, ligands with glycine substitutions in potential TCR contact positions induced CTL, which were able to recognize peptides with a variety of amino acids in the former glycine position.

Cross-reactivity of T cell lines and clones to beta-lactam antibiotics.

To clarify on a molecular level the specific T cell response to haptens like penicillin G, we generated T cell lines and clones from penicillin-allergic patients. Two types of beta-lactam reactivity of T cells could be delineated: one group of patients showed a rather restricted specificity, as the penicillin-elicited T cell lines generated from such donors proliferated only to the stimulating penicillin, but not to other beta-lactam antibiotics nor to cephalosporines, even if the side chain was identical. This indicates that the penicilloyl structure together with the side chain was recognized by these T cells. The second group comprised patients with more broadly reactive T cells, as they were restimulated by penicillin G as well as by related penicillins like amoxicillin or ampicillin, but not cephalosporines. This indicates that the penicilloyl structure, a common motif of penicillins, was important for T cell recognition. Clones generated from a broadly reactive patient confirmed this heterogeneity, as either monospecific or broadly specific T cell clones could be identified. This broad or very restricted pattern of T cell reactivity was reflected in the use of TCR Vbeta-chains: while the broadly reactive T cell lines showed a heterogenous TCR usage, the highly restricted T cell lines showed an up-regulation of one TCR Vbeta-chain. Thus, our data suggest that the outgrowth of T cells bearing a certain TCR Vbeta may be a sign of a limited cross-reactivity.

T cell immune responses to haptens. Structural models for allergic and autoimmune reactions.

Protein-reactive chemicals, metal salts and drugs, commonly classified as immunological haptens, are major environmental noxes targeted at the immune system of vertebrates. They may not only interfere with this defense system by toxicity alone, but more often by evoking hapten-specific immune responses resulting in allergic and eventually autoimmune responses. Here, we review recent developments in the analysis of the structural basis of hapten recognition, particularly by T lymphocytes, which represent central elements in cell-mediated, as well as in IgE dependent, allergies. A break-through in this field was the finding that T cells detect haptens as structural entities, attached covalently or by complexation to self-peptides anchored in binding grooves of major histocompatibility antigens (MHC-proteins). Synthetic hapten-peptide conjugates were shown to induce hapten-specific contact sensitivity in mice, opening new routes for studying hapten-induced immune disorders.

Analysis of major histocompatibility complex class I-restricted hapten recognition by mutation of the V-J joining of T cell receptor alpha chains.

Hapten-specific T cell responses are responsible for chemically induced immune disorders. However, the molecular details of hapten interactions with T cell receptors (TCR) are poorly understood. Recent studies of trinitrophenyl (TNP)-specific responses revealed major histocompatibility complex-associated TNP-peptides as dominant epitopes for CD8+ and CD4+ T cells. The present study is based on the observation that two H-2Kb/TNP-specific CTL clones (II/7 and III/1), differing exclusively in two amino acids of their TCR alpha chains, also differed in their carrier specificities for various TNP-peptides. The genes of the two alpha chains and the common beta chain were cloned into expression vectors. Transfection of the TCR alpha chain of clone III/1 into a hybridoma of clone II/7 also transferred the fine specificity of clone III/1, indicating that the small alpha chain variations were indeed responsible for the different carrier specificities. Point mutations bridging the difference between the alpha chains of clones II/7 and III/1 and functional studies of the respective TCR alpha beta transfectants into a TCR-negative hybridoma revealed an unexpected result: the two receptors did not represent examples of structural complementarity for different sets of hapten-peptide conjugates; rather, they resembled two structures of principally similar specificity but of significantly different overall affinity. This was demonstrated more directly by comparing the fine specificities of III/1 transfectants expressing or not expressing the co-receptor CD8: the CD8-negative III/1 transfectant assumed a specificity pattern indistinguishable from that of a CD8-expressing, II/7-derived transfectant. Hence, comparable alterations of antigen recognition may be induced either by subtle TCR alterations or by removal of CD8, i.e. by the presence or absence of a non-polymorphic adhesion molecule.

T cell recognition of penicillin G: structural features determining antigenic specificity.

Penicillin G (Pen G) and other beta-lactam antibiotics frequently induce allergic reactions constituting typical examples of human immune responses to haptens. In fact, penicillins represent a unique set of haptens with outstanding structural variability on the basis of an identical protein-reactive beta-lactam containing backbone. Although both cellular and humoral responses are involved in drug-induced allergies, little is known about the T cell reactivity to penicillins. To understand which structural features determine antigenic specificity, we isolated a panel of MHC-restricted, Pen G-reactive T cell clones from different penicillin-allergic patients and tested them for their capacity to proliferate in the presence of other penicillin derivatives. We found that the antigenic epitope consists of both the amide-linked side chain, which is different in every member of the penicillin family, as well as the thiazolidine ring common to all penicillin derivatives. We also demonstrated the presence of two different types of penicillin-specific T cells, one dependent, and the other independent of antigen processing by autologous antigen-presenting cells. Our data strongly suggest that penicillins form part of the epitopes contacting the antigen receptors of T cells.