T cell recognition of Tn-glycosylated peptide antigens

The mouse hemoglobin-derived decapeptide Hb (67–76), VITAFNEGLK, which binds well to E^k and is non-immunogenic in CBA/J mice, was O-glycosylated with the tumor-associated carbohydrate Tn (α-D -N-acetylgalactosamine, or α-D -GalNAc). Each of the ten positions in the peptide was substituted with serine or threonine having the Tn antigen attached. The complete set of Tn-glycosylated peptides were then studied for binding to E^k and for immunogenicity in CBA/J mice. All of those glycopeptides which had the Tn attached to serine or threonine at a position in the peptide where, according to the crystal structure determinations, the amino acid side chain was oriented downwards into the binding site of the major histocompatibility complex (MHC) molecule, completely lost their capacity for binding to E^k. This was the case for the glycopeptides with Tn attacted at position 68 and 76, which are the major anchor residues and for those with Tn attached at position 71 and 73, which function as secondary anchor residues. Those glycopeptides which had Tn attached to serine or threonine at positions where the side chain pointed away from the binding site maintained their capacity for binding to E^k, except for those with Tn attached at position 70 and 74. Furthermore, some of the MHC-binding glycopeptides were immunogenic. In particular, this was the case for the glycopeptide with Tn attached to the central position 72 in the decapeptide. From previous studies, this is known to be the dominant T cell receptor contact residue of Hb (67–76). The results suggest that T cells may be capable of recognizing epitopes which are partially defined by a small glycan group.     

Endogenous and exogenous forms of the same antigen are processed from different pools to bind MHC class II molecules in endocytic compartments

The current studies were carried out to examine the basis for the differences in the antigenic peptides generated from exogenous and endogenous forms of hen egg white lysozyme (HEL). The role of different intracellular compartments in the generation and binding of HEL peptides derived from two endogenous forms of HEL, either secreted (sHEL) or retained in the endoplasmic reticulum (ER, KDEL HEL), presented by MHC class II molecules was examined and compared to exogenous HEL. Initially it was found that antigen-presenting cells bearing both intracellular forms of HEL generated and presented a number of IA^k-restricted HEL epitopes to T cell hybridomas, although s HEL was processed more efficiently than KDEL HEL. There were differences, however, for some determinants between endogeneous and exogenous HEL. At equivalent antigen-presenting efficiencies, endogenous HEL-bearing cells displayed a lower surface density of IA^k-bound HEL-52-61-related peptides than cells pulsed with exogenous HEL, as detected by a specific monoclonal antibody. Neither endogenous HEL degradation nor peptide binding to MHC class II molecules occurred in the ER. Processing of sHEL and KDEL HEL appears to take place either in a post-trans-Golgi network acidic compartment or in the cytosol, whereas peptide binding to MHC class II molecules occurs in endocytic compartments . Furthermore, the peptides generated were derived from an endogenous source rather than from secreted and re-endocytosed HEL. Thus, processing of endogenous HEL is from a different pool than exogenous HEL and occurs in different compartments.     

Peptide anchor residue glycosylation: effect on class I major histocompatibility complex binding and cytotoxic T lymphocyte recognition

This study extends our previous observation that glycopeptides bind to class I major histocompatibility complex (MHC) molecules and elicit carbohydrate-specific CTL responses. The Sendai virus nucleoprotein wild-type (WT) peptide (FAPGNYPAL) binds H-2D^b using the P5-Asn as an anchor. The peptide K2 carrying a P5 serine substitution did not bind D^b. Surprisingly, glycosylation of the serine (K2-O-GlcNAc) with N-acetylglucosamine (GlcNAc), a novel cytosolic O-linked glycosylation, partially restored peptide binding to D^b. We argue that the N-acetyl group of GlcNAc may fulfil the hydrogen bonding requirements of the D^b pocket which normally accomodates P5-Asn. Glycosylation of the P5-Asn residue itself abrogated binding similar to K2, probably for steric reasons. The peptide K2-O-GlcNAc readily elicited D^b-restricted cytotoxic T lymphocytes (CTL), which did not cross-react with K2 or WT. However, all D^b-restricted CTL raised against K2-O-GlcNAc cross-reacted strongly with another glycopeptide, K3-O-GlcNAc, where the GlcNAc substitution is on a neighboring P4-Ser. Furthermore, D^b-restricted CTL clones raised against K2-O-GlcNAc or K3-O-GlcNAc displayed a striking TCR conservation. Our interpretation is that the carbohydrate of K2-O-GlcNAc not only mediates binding to D^b, but also interacts with the TCR in such a way as to mimic K3-O-GlcNAc. This unusual example of molecular mimicry extends the known effects of peptide glycosylation from what we and others have previously reported: glycosylation may create a T cell neo-epitope, or, conversely, abrogate recognition. Alternatively, glycosylation may block peptide binding to MHC class I and finally, as reported here, restore binding, presumably through direct interaction of the carbohydrate with the MHC molecule.     

Generation of hen egg lysozyme-specific and major histocompatibility complex class I-restricted cytolytic T lymphocytes: recognition of cytosolic and secreted antigen expressed by transfected cells

Syngeneic cells exogenously supplied with hen egg lysozyme (HEL) or endogenously synthesizing HEL were used as antigen-presenting cells to induce major histocompatibility complex class I-restricted cytotoxic T lymphocytes (CTL). Immunization of C57BL/6 mice followed by repeated stimulation of their splenocytes in vitro with trypsinized HEL peptides led to the generation of CTL lines specific for trypsinized HEL peptides and restricted by H-2K^b. Immunization of C3H mice with a mixture of soluble native HEL and irradiated syngeneic spleen cells followed by in vitro stimulation of immune spleen cells with soluble HEL could in a few cases result in HEL-specific CTL able to kill syngeneic transfectant L cells secreting HEL (HELs) or expressing cytosol-targeted HEL (HELc). The use of HELs or HELc transfectant L cells as in vivo and in vitro immunogens was a potent way for eliciting HEL-specific polyclonal CTL. These CTL and two CD8⁺ clones were found to be H-2K^k restricted and specific for the 1-17 N-terminal HEL peptide. In addition, the anti-HEL CTL could also exhibit a significant cross-reactivity against unsensitized and HEL-untransfected targets expressing the K restriction element. This cross-reactivity was likely due to recognition of unidentified HEL mimicking peptides (self-derived ?) presented by the MHC class I (H-2K^b or H-2K^k) molecule used as the restriction element for the specific recognition of HEL. The CTL raised after immunization with HELs or HELc transfectant cells were found to recognize both the HELs and HELc transfectant cells even though HEL was not detected in the latter after a 2- or 5-min radiolabeling pulse. Recognition of both HELs and HELc transfectant cells by a given CTL clone suggests that HEL subjected to two separate processing pathways, each depending on the initial subcellular localization, can ensure the generation of similar MHC class I peptide complexes.     

Immunization with glycosylated Kb-binding peptides generates carbohydrate-specific,unrestricted cytotoxic T cells

Cytotoxic T cells (CTL) recognize target proteins as short peptides presented by major histocompatibility complex (MHC) class I restriction elements. However, there is also evidence for peptide-independent T cell receptor (TCR) recognition of target proteins and non-protein structures. How such T cell responses are generated is presently unclear. We generated carbohydrate (CHO)-specific, MHC-unrestricted CTL responses by coupling di- and trisaccharides to K^b- or D^b-binding peptides for direct immunization in mice. Four peptides and three CHO have been analyzed with the CHO either in terminal or central positions on the carrier peptide. With two of these glycopeptides, with galabiose (Galα1-4Gal; Gal₂) bound to a homocysteine (via an ethylene spacer arm) in position 4 or 6 in a vesicular stomatitis virus nucleoprotein-derived peptide (RGYVYQGL binding to K^b), CTL were generated which preferentially killed target cells treated with glycopeptide compared to those treated with the core peptide. Polyclonal CTL were also found to kill target cells expressing the same Gal₂ epitope in a glycolipid. By fractionation of CTL, preliminary data indicate that glycopeptide-specific K^b-restricted CTL and unrestricted CHO-specific CTL belong to different T cell populations with regard to TCR expression. The results demonstrate that hapten-specific unrestricted CTL responses can be generated with MHC class I-binding carrier peptides. Different models that might explain the generation of such responses are discussed.     

Invriant chain peptides enhancing or inhibiting the presentation of antigenic peptides by major histocompatibility complex class II molecules

Two soluble invariant chain (Ii) peptides with overlapping sequences had contrasting effects on the presentation of antigenic peptides by murine A^d, A^k, E^d, and E^k major histocompatibility complex (MHC) class II molecules. Naturally produced class II-associated invariant chain peptides human (h)Ii81–104/murine (m)Ii80–103 inhibited antigen presentation on these MHC class II alleles in a manner consistent with competitive inhibition. The Ii-4 peptides hIi77–92/mIi76–91 enhanced presentation of antigenic peptides on I-E class II alleles by promoting the exchange of peptides at the cell surface. Treatment of antigenpresenting cells (APC) with Ii-4 before the addition of antigenic peptide greatly enhanced subsequent T cell responses, while treatment of APC with Ii–4 after antigenic peptide binding decreased subsequent T cell responses. The hIi81–104 and mIi80–103 peptides inhibited T cell responses in both types of assays. The binding of biotinylated antigenic peptide to MHC class II-transfected L cells, as measured by flow cytometry, was inhibited by mIi80-103 and enhanced by mIi-4. Segments of Ii fragments remaining associated with MHC class II, or released Ii peptides, appear to regulate the formation of stable antigenic peptide/MHC class II complexes either positively or negatively through interactions at or near the antigenic peptide binding site. These findings open a pathway for the design of novel therapeutics based on the structure and function of natural and rationally designed fragments of Ii.     

Carbohydrate-dependent,HLA class II-restricted,human T cell response to the bee venom allergen phospholipase A2 in allergic patients

The T cell-independent antibody response to polysaccharide antigen (Ag) is believed to result from their inability to bind major histocompatibility complex (MHC) restriction elements. However, recent studies using glycosylated analogues of known immunogenic peptides revealed that glycopeptides can interact with MHC molecules and are able to elicit specific T cell responses in experimental animals. This raises questions about the possible role which carbohydrates can play in T cell responses following natural exposure to glycoprotein antigens. Analyzing the fine specificity of the human T cell response against the major bee venom allergen phospholipase A2 (PLA), a 16–20-kDa protein glycosylated at a single site (Asn¹³), we have identified several T cell clones which proliferate in response to the glycoprotein but not to its non-glycosylated variants. Neither the carbohydrate moiety alone nor the combination of carbohydrate and nonglycosylated protein could substitute for the intact glycoprotein. Antibody directed against the carbohydrate moiety inhibited Ag-induced proliferation of these clones whereas control clones with known peptide specificity were not affected, providing additional evidence for the involvement of carbohydrates in T cell recognition. Moreover, peripheral blood mononuclear cells of two individuals from whom glycosylation-dependent T cell clones have been isolated showed significantly higher proliferation in response to glycosylated compared to non-glycosylated Ag, suggesting that glycosylation can contribute in some cases extensively to the immunogenicity of a glycoprotein Ag. Thus, this report shows that glycosylation-dependent Ag recognition by T cells can also occur following natural exposure to a glycoprotein.     

Dose-dependent T cell tolerance to an immunodominant self peptide

We have previously described a model of tolerance to self peptides in a mouse transgenic (Tg) line producing secreted hen egg-white lysozyme (HEL). The HEL cDNA was placed under the control of a ubiquitous promoter expressed early in embryogenesis, so that HEL should be present in Tg mice throughout the development of the immune system. Since individual HEL Tg mice express different amounts of serum HEL, we were previously able to show that H-2^d mice with HEL blood level > 10 ng/ml are tolerant to HEL and to the immunodominant (ID) peptide 108–116. However, autoreactive T lymphocytes recognizing the HEL subdominant (SD) peptides 74–96 and 1–18 still persist and the SD-specific responses disappear at higher blood HEL concentrations. In the present work, we have studied HEL Tg H-2^d mice with HEL serum levels < 10 ng/ml (HEL-low Tg animals). We find that 50% of Tg animals with HEL blood concentration < 2 ng/ml are responsive to HEL in T cell proliferation assays, although these responses are lower than those seen in non-Tg control mice. The HEL-specific T lymphocytes react only with 15-mer overlapping peptides encompassing the single H-2^d ID region of HEL (residues 102–122); whereas the 9-mer minimal ID peptide 108–116, which strongly triggers non-Tg T cells, is unable to stimulate auto-reactive T cells in vitro from HEL-low Tg mice. Altogether, our results suggest that T lymphocytes specific for the minimal ID peptide are deleted or inactivated, while T cell clones of lower affinity and reacting with epitopes on longer peptides persist. Thus, the high affinity ID peptide-specific T cell clones can be negatively selected even in the presence of low amounts of HEL.     

MUC1-derived glycopeptide libraries with improved MHC anchors are strong antigens and prime mouse T cells for proliferative responses to lysates of human breast cancer tissue

Multi-component glycopeptide libraries and single glycopeptides were used for immunization of mice with the aim of inducing strong T helper cell responses to the repetitive sequence of MUC1 expressed by human tumor cells. The glycopeptides and glycopeptide libraries were modeled upon the native human MUC1 amino acid variable number of tandem repeats sequence by introduction of modifications in the MHC anchor positions to optimally fulfil the binding requirements of the A(d) MHC class II molecule in the BALB/c mouse. The immunogenicity of the MUC1 glycopeptides in BALB/c mice was determined by immunization in complete Freund's adjuvant and assaying lymph node T cells for a proliferative response to the glycopeptide used. Strong proliferative responses with stimulation indices over 50 were obtained with anchor-improved glycopeptide libraries as well as with single glycopeptides. Immunization with one of the glycopeptide libraries primed T cells for a proliferative cross-response to the native MUC1 glycopeptide, which by itself was nonimmunogenic. In addition, immunization with the same glycopeptide library primed T cells for a strong response to lysate of a MUC1-expressing human breast cancer, and immunization with the tumor lysate primed T cells for a response to the glycopeptide library. The T cells responding in the assay for proliferation were restricted to the A(d) MHC class II molecule. The results indicate that immunization with MHC anchor-improved MUC1 glycopeptide libraries can effectively prime T helper cells and may induce long-term memory. The approach may be useful in the design of preventive cancer vaccines for use in humans.     

Qa-1 interaction and T cell recognition of the Qa-1 determinant modifier peptide

The peptide-binding properties of the nonclassical major histocompatibility complex (MHC) class 1b molecule Qa-1 were investigated using a transfected hybrid molecule composed of the α1 and α2 domains of Qa-1^b and the α3 domain of H-2D^b. This allowed the use of a monoclonal antibody directed against H-2D^b whilst retaining the peptide-binding groove of Qa-1^b. By comparison with classical MHC class I molecules, intracellular maturation of the chimeric molecule was inefficient with weak intracellular association with β2-microglobulin. However, at the cell surface the hybrid molecules were stably associated with β2-microglobulin and were recognized by cytotoxic T lymphocyte (CTL) clones specific for the Qa-1^b -presented peptide Qdm (AMAPRTLLL). A whole-cell binding assay was used to determine which residues of Qdm were important for binding to Qa-1^b and CTL clones served to identify residues important for T cell recognition. Substitutions at position 1 and 5 did not reduce the efficiency of binding and had little effect on CTL recognition. In contrast, substitutions at position 9 resulted in loss of MHC class I binding. Mass spectrometric analysis of peptides eluted from immunopurified Qa-1^b/D^b molecules indicated that Qdm was the dominant peptide. The closely related peptide, AMVPRTLLL, which is derived from the signal sequence of H-2D^k, was also present, although it was considerably less abundant. The mass profile suggested the presence of additional peptides the majority of which consisted of eight to ten amino acid residues. Finally, the finding that a peptide derived from Klebsiella pneumoniae can bind raises the possibility that this non-classical MHC class I molecule may play a role in the presentation of peptides of microorganisms.     

Peptide length preferences for rat and mouse MHC class I molecules using random peptide libraries

MHC class I molecules bind short peptides for presentation to CD8⁺ T cells. The determination of the three-dimensional structure of various MHC class I complexes has revealed that both ends of the peptide binding site are composed of polar residues conserved among all human and murine MHC class I sequences, which act to lock the ends of the peptide into the groove. In the rat, however, differences in these important residues occur, suggesting the possibility that certain rat MHC class I molecules may be able to bind and present longer peptides. Here we have studied the peptide length preferences of two rat MHC class I a molecules expressed in the TAP2-deficient mouse cell line RMA-S: RT1-A1^c, which carries unusual key residues at both ends of the groove, and RT1.A^a which carries the canonical residues. Temperature-dependent peptide stabilization assays were performed using synthetic random peptide libraries of different lengths (7 – 15 amino acids) and successful stabilization was determined by FACS analysis. Results for two naturally expressed mouse MHC class I molecules revealed different length preferences (H2-K^b, 8 – 13-mer and H2-D^b, 9 – 15-mer peptides). The rat MHC class Ia molecule, RT1-A^a, revealed a preference for 9 – 15-mer peptides, whereas RT1-A1^c showed a more stringent preference for 9 – 12-mer peptides, thereby ruling out the hypothesis that unusual residues in rat MHC molecules allow binding of longer peptides.     

Minute quantities of a single immunodominant foreign epitope are presented as large nested sets by major histocompatibility complex class II molecules

The processing and presentation of immunogenetic peptides is an obligate event in the generation of an immune response. However, the degree of complexity with which an immunogenic foreign epitope is presented is still unclear. This question was addressed by analyzing the naturally processed peptides generated from exogenously-derived hen egg white lysozyme (HEL) bound to the murine major histocompatibility complex (MHC) class II molecule, H-2A^k. Using reversed-phase chromatography (RPC), T cell hybridomas and mass spectrometry, 16 peptides were identified that contain the minimal MHC binding epitope 52–61. These peptides exhibited substantial N- and C-terminal extensions and ranged from 13–28 amino acids in length. In contrast, MHC class I molecules present peptides of 8–11 residues and each foreign epitope appears to be represented by only a single peptide. The data here also show that only ～ 0.8% of the total bound peptide was derived from this single HEL epitope. These findings provide direct evidence that relatively small amounts of processed peptide are required to stimulate an effective T cell response.     

Both positive and negative effects on immune responses by expression of a second class II MHC molecule

It is perplexing why vertebrates express a limited number of major histocompatibility complex (MHC) molecules when theoretically, having a greater repertoire of MHC molecules would increase the number of epitopes presented, thereby enhancing thymic selection and T cell response to pathogens. It is possible that any positive effects would either be neutralized or outweighed by negative selection restricting the T cell repertoire. We hypothesize that the limit on MHC number is due to negative consequences arising from expressing additional MHC. We compared T cell responses between B6 mice (I-A⁺) and B6.E⁺ mice (I-A⁺, I-E⁺), the latter expressing a second class II MHC molecule, I-E^b, due to a monomorphic Eα^k transgene that pairs with the endogenous I-Eβ^b chain. First, the naive T cell Vβ repertoire was altered in B6.E⁺ thymi and spleens, potentially mediating different outcomes in T cell reactivity. Although the B6 and B6.E⁺ responses to hen egg-white lysozyme (HEL) protein immunization remained similar, other immune models yielded differences. For viral infection, the quality of the T cell response was subtly altered, with diminished production of certain cytokines by B6.E⁺ CD4⁺ T cells. In alloreactivity, the B6.E⁺ T cell response was significantly dampened. Finally, we observed markedly enhanced susceptibility to experimental autoimmune encephalomyelitis (EAE) in B6.E⁺ mice. This correlated with decreased percentages of nTreg cells, supporting the concept of Tregs exhibiting differential susceptibility to negative selection. Altogether, our data suggest that expressing an additional class II MHC can produce diverse effects, with more severe autoimmunity providing a compelling explanation for limiting the expression of MHC molecules.     

O-glycosylated versus non-glycosylated MUC1-derived peptides as potential targets for cytotoxic immunotherapy of carcinoma

Due to the fact that many cellular proteins are extensively glycosylated, processing and presentation mechanisms are expected to produce a pool of major histocompatibility complex (MHC) class I-bound protein-derived peptides, part of which retain sugar moieties. The immunogenic properties of the presented glycosylated peptides in comparison to their non-glycosylated counterparts have not been determined clearly. We assessed the cellular immunogenicity of MUC1 (mucin)-derived peptides O-glycosylated with a Tn epitope (GalNAc) using HLA-A*0201 single chain (HHD)-transfected cell lines and transgenic mice. For part of the compounds Tn moiety did not interfere with the HLA-A*0201 binding. Moreover, part of the glycopeptides elicited effective cytotoxic responses, indicating recognition of the glycopeptide-HLA-A*0201 complex by the T cell receptor (TCR) and subsequent cytotoxic T lymphocyte (CTL) activation. The CTLs exhibited a substantial degree of cross-reactivity against target cells loaded with glycosylated and non-glycosylated forms of the same peptide. The studied (glyco)peptides showed cellular immunogenicity in both MUC1-HHD and HHD mice and induced effective lysis of (glyco)peptide-loaded target cells in CTL assays. However, the elicited CTLs did not induce selective lysis of human MUC1-expressing murine cell lines. Moreover, immunization with (glyco)peptide-loaded dendritic cells (DCs) did not induce significant immunotherapeutic effects. We conclude that Tn glycosylated MUC1-derived peptides can be presented by MHC class I molecules, and may be recognized by specific TCR molecules resulting in cytotoxic immune responses. However, the studied glycopeptides did not offer significant benefit as targets for cytotoxic immune response due apparently to (a) cross-reactivity of the elicited CTLs against the glycosylated and non-glycosylated forms of the same peptide and (b) low abundance of glycopeptides on tumour target cells.     

Major histocompatibility complex and T cell receptor interaction of the P91A tum− peptide

The P91A antigen was identified following mutation of P1 mastocytoma cells. The peptide epitope is encoded by a mutant form of the S3 subunit of the PA 700 proteasome regulatory complex. P91A stimulates a strong CD8⁺ T cell response when expressed on tumor cells or normal tissue and P91A-specific T cells express a restricted range of T cell receptors. Although it is a strong L^d-binding peptide, P91A does not conform to the established motif for this major histocompatibility complex (MHC) molecule and this has hampered elucidation of the precise epitope. L^d predominantly associates with nonamer peptides; however, using a variety of complementary approaches, the P91A epitope is identified as the octamer QNHRALDL. In the absence of the L^d motif residue proline at position 2, residues 5–7 are primarily involved in MHC interaction. P91A is thus atypical in its interaction with L^d. Residues 1, 3, and 4 are found to influence T cell recognition of P91A. Definition of the P91A peptide will allow studies on P91A processing and interactions of the P91A peptide/MHC complex with T cell receptors of differing avidity to establish the basis for restricted T cell receptor usage. The basis for the failure of the P91A tum⁺ peptide (QNRRALDL) to bind to L^d is addressed by molecular modeling.     

The phenotype of H-2M-deficient mice is dependent on the MHC class II molecules expressed

For a broader view of the role of H-2M as an accessory molecule in antigen presentation, we investigated the degree to which different MHC class II isotypes and alleles depend on H-2M to function in vivo. We generated H-2M-deficient animals expressing E^{k / b} or A^k molecules in addition to the A^b molecules already present in the mutant strain, and compared the ability of the different MHC class II molecules to present antigen at the cell surface for recognition by T cells, and contribute to positive selection of CD4⁺ T cells in the thymus. Biochemical analyses were performed to assess MHC class II maturation, and to determine the peptide content of the molecules. In the absence of H-2M, E^{k / b} molecules containd a more heterogeneous set of class II-associated invariant chain peptides (CLIP) than A^b did, which, unlike A^b -CLIP complexes, were not SDS-stable. Unlike A^b molecules, both E^{k / b} and A^k efficiently presented exogenously added peptides to T cells in the absence of H-2M. In addition, epitopes from some proteins, especially those known to be invariant chain independent, were presented by A^k molecules in the mutant animals. To our surprise, expression of E^{k / b} overcame the positive selection defect observed in H-2M-deficient mice expressing A^b alone. In contrast, A^k expression did not augment positive selection of CD4⁺ T cells in the mutant animals. Some of these findings in vivo contrast significantly with findings from in vitro studies on murine MHC class II molecules in human DM-deficient cell lines.     

MUC1 peptide epitopes associated with five different H-2 class I molecules

We have previously described the induction of murine CD8⁺ major histocompatibility complex (MHC) class I-restricted cytotoxic T cells (CTL) recognizing the 20-amino acid repeat region of the human mucin 1 (MUC1) variable number of tandem repeats region (VNTR), a mucin greatly increased in expression in breast cancer and proposed as a target for immunotherapy. In that study, CTL could detect MUC1 peptides associated with the MHC of all nine strains examined, and we now report the different epitopes presented by five different MHC class I molecules. The epitopes were defined in CTL assays using peptide-pulsed phytohemagglutinin blasts or MHC class I-transfected L cells as targets; in addition, peptide binding assays and T cell proliferation studies were performed. Within the 20-amino acid VNTR, nine potential epitopes could be defined. The epitopes for the four MHC class I molecules [K^b (three epitopes), D^d, L^d and K^k] were closely related, all containing the amino acids PDTRPAP. For D^b, three epitopes were identified, all containing APGSTAP. Most of the epitopes did not contain a consensus motif for the particular MHC class I allele, and bound with low ‘affinity’, compared with known high-affinity peptides. CD8⁺ T cell proliferation also occurred to the same MHC class I-presented epitopes. Finally, when conventional anchor residues were introduced into the peptides, peptide binding increased, whereas CTL recognition was either retained (K^b) or lost (D^b) depending on the epitope.     

Unique role of thyroxine in T cell recognition of a pathogenic peptide in experimental autoimmune thyroiditis

We have previously demonstrated the importance of iodination and the requirement of the thyroxine residues in thyroglobulin (Tg) for the stimulation of two clonotypically distinct murine T cell hybridomas reactive against human and mouse Tg. We are now able to show that these T cell hybridomas only recognize an 11-residue peptide containing a thyroxine structure that has iodine at two positions on each ring. This iodination state is critical for recognition by these hybridomas as a peptide containing de-iodinated thyroxine is nonstimulatory. Furthermore we have demonstrated that a peptide lacking the thyroxine residue or containing de-iodinated thyroxine cannot block the recognition of the thyroxine-containing peptide. We suggest that in our system the thyroxine residue is involved in binding to major histocompatibility complex (MHC) class II molecules. We have also been able to show that the thyroxine residue is available for contact by the T cell receptor (TCR) as recognition of the peptide/H-2A^k complex is blockable by an antibody directed against thyroxine. Using substituted peptides, we have been able partially to define the residues within the peptide that are critical for recognition of the 11-residue peptide by our hybridomas. From our data, we suggest that the thyroxine residue may bind the MHC and TCR, while the residues identified in the peptide backbone as important for the stimulation of the hybridomas may bind only the TCR.     

A defect in bone marrow derived dendritic cell maturation in the nonobesediabetic mouse

The pathogenesis of diabetes in the nonobese diabetic (NOD) mouse is characterized by a selective destruction of the insulin-producing β-cells in the islets of Langerhans mediated by autoreactive T cells. The function of T cells is controlled by dendritic cells (DC), which are not only the most potent activators of naïve T cells, but also contribute significantly to the establishment of central and peripheral tolerance. In this study, we demonstrate that the NOD mouse (H2: K^d, A^g7, E°, D^b) shows selective phenotypic and functional abnormalities in DC derived from bone marrow progeny cells in response to GM-CSF (DC^NOD). NOD DC, in contrast to CBA DC, have very low levels of intracellular I-A molecules and cell surface expression of MHC class II, CD80, CD86 and CD40 but normal β2-microglobulin expression. Incubation with the strong inflammatory stimulus of LPS and IFN-γ does not increase class II MHC, CD80 or CD86, but upregulates the level of CD40. The genetic defect observed in the DC^NOD does not map to the MHC, because the DC from the MHC congenic NOD.H2^h4 mouse (H2: K^k, A^k, E^k, D^k) shares the cell surface phenotype of the DC^NOD. DC from these NOD.H2^h4 also fail to present HEL or the appropriate HEL-peptide to an antigen-specific T cell hybridoma. However all the DC irrespective of origin were able to produce TNF-α, IL-6, low levels of IL-12(p70) and NO in response to LPS plus IFN-γ. A gene or genes specific to the NOD strain, but outside the MHC region, therefore must regulate the differentiation of DC in response to GM-CSF. This defect may contribute to the complex genetic aetiology of the multifactorial autoimmune phenotype of the NOD strain.     

A biological function for the XP motif within the N terminus of major histocompatibility complex class II-associated peptides

A high proportion (up to 30%) of major histocompatibility complex (MHC) class II-bound peptides in the mouse and humans contains a proline residue at the N-terminal penultimate position (XP motif). We used a set of ovalbumin (OVA)-specific and hen egg lysozyme (HEL)-specific T cell hybridomas and asked whether the XP motif in MHC class II-associated peptides might influence the stimulation of T cells. We created N-terminally substituted variants of OVA323–339, an H2-A^d restricted OVA epitope and of HEL50–63, a dominant epitope in the context of H2-A^k. Our results show that the N-terminal sequence of MHC class II-bound peptides has a strong impact for the overall stimulation of specific T cells. Proline at the N terminus of antigenic peptides, in contrast to other amino acids, is tolerated or even enhances the recognition of MHC class II-bound peptides significantly.