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.     

Mutations in the third, but not the first or second, hypervariable regions of DR(beta 1*0101) eliminate DR1-restricted recognition of a pertussis toxin peptide.

We have examined the role of 12 polymorphic residues of the beta-chain of the HLA-DR1 class II molecule in T cell recognition of an epitope of pertussis toxin. Murine L cell transfectants expressing wild-type or mutant DR1 molecules (containing single amino acid substitutions in DR(beta 1*0101)) were used as APC in proliferation assays involving nine DR1-restricted T cell clones specific for peptide 30-42 of pertussis toxin. Four different patterns of recognition of the mutants were found among the pertussis-specific clones. Residues in the third hypervariable region (HVR) of DR(beta 1*0101) are critically important for all the T cell clones; amino acid substitutions at positions 70 and 74 abrogated recognition by all of the T cell clones, and substitutions at positions 67 and 71 eliminated recognition by most of the clones. In contrast, most single amino acid substitutions in the first and second HVR, predicted to be located in the floor of the peptide binding groove, had little or no effect on the proliferative responses of these clones. However, the involvement of beta-chain first and second HVR residues was demonstrated by the inability of transfectants expressing wild-type DR(beta 1*0404) (DR4Dw14) or DR(beta 1*1402) (DR6Dw16) to present peptide to these clones. These beta-chains have completely different first and second HVR compared with DR(alpha,beta 1*0101) although the third HVR are identical. These results illustrate the functional importance of third HVR residues of DR(beta 1*0101) and allow definition of the molecular interactions of the DR1 molecule with the 30-42 peptide.     

Fine specificity of murine class II-restricted T cell clones for synthetic peptides of influenza virus hemagglutinin. Heterogeneity of antigen interaction with the T cell and the Ia molecule

We have previously demonstrated diversity in the specificity of murine, H-2k class II-restricted, T cell clones for the hemagglutinin (HA) molecule of H3N2 influenza viruses and have mapped two T cell determinants, defined by synthetic peptides, to residues 48-68 and 118-138 of HA1. In this study we examine the nature of the determinant recognized by six distinct P48-68-specific T cell clones by using a panel of truncated synthetic peptides and substituted peptide analogs. From the peptides tested, the shortest recognized were the decapeptides, P53-62 and P54-63, which suggests that the determinant was formed from the 9 amino acids within the sequence 54-62. Asn54 was critical for recognition since P49-68 (54S) was not recognized by the T cell clones. Furthermore this peptide analog was capable of competing with P48-68 for Ag presentation, thereby suggesting that residue 54 is not involved in Ia interaction and may therefore be important for TCR interaction. Residue substitutions at position 63 also affected T cell recognition, but in a more heterogeneous fashion. Peptide analogs or mutant viruses with a single amino acid substitution at position 63 (Asp to Asn or Tyr) reduced the responses of the T cell clones to variable extents, suggesting that Asp63 may form part of overlapping T cell determinants. However since the truncated peptide P53-62 was weakly recognized, then Asp63 may not form part of the TCR or Ia interaction site, but may affect recognition through a steric or charge effect when substituted by Asn or Tyr. Ag competition experiments with the two unrelated HA peptides, P48-68 and P118-138, recognized by distinct T cell clones in the context of the same restriction element (I-Ak), showed that the peptides did not compete for Ag presentation to the relevant T cell clones, whereas a structural analog of P48-68 was a potent inhibitor. This finding is discussed in relation to the nature of the binding site for peptide Ag on the class II molecule.     

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)     

I-Ak polymorphisms define a functionally dominant region for the presentation of hen egg lysozyme peptides

The class II molecules of the MHC not only bind processed antigenic peptides but also interact with the TCR. This latter interaction is thought to be the basis for allele specific "restriction" of Ag presentation to T cells. The specificity of this interaction is likely due to amino acid differences in a small number of polymorphic or "hypervariable" regions located in the amino terminal domains of the alpha- and beta-chains. We have explored the functional significance of these polymorphic regions in an I-Ak-restricted, hen egg lysozyme specific Ag presentation system in which the measurement of IL-2 production by T cell hybridomas was used as the indicator of TCR recognition of the I-A/Ag complex. Chimeric I-A molecules, in which b allelic residues were substituted in one or more of the polymorphic regions of the A alpha k chain or in which d allelic residues were substituted in one or more of the polymorphic regions of the A beta k chain, were used to examine the contribution of each polymorphic region of the molecule to its function. The results obtained demonstrate that the regions between residues 69 to 76 of the A alpha k chain and the regions between residues 63 to 67 and 75 to 78 of the A beta k-chain exert a dominant effect on the presentation of lysozyme peptides by I-Ak to the T cell hybridomas in our panel. These observations were confirmed and extended by the analysis of Ag presentation by seven serologically selected mutants, all of which have amino acid interchanges in or around the dominant polymorphic regions. The results suggest that the serologically selected mutants fail to present Ag not because they fail to bind the peptide Ag but because the amino acid substitutions destabilize the interaction between the Ia/peptide complex and the TCR. Use of the recently published hypothetical model for class II structure to interpret the Ag presentation results suggests that the dominant polymorphic regions lie across from one another near one end of the alpha-helices that form the two walls of the proposed Ag-binding cleft located on the top surface of the class II molecule. Furthermore, the majority of the amino acids which have been changed in the serologically selected mutants have side chains which are postulated to point up toward the exterior of the molecule and would, therefore, be potential contact residues for the TCR.     

Functional sites on the A alpha-chain. Polymorphic residues involved in antigen presentation to insulin-specific, Ab alpha:Ak beta-restricted T cells

The interaction between the clonally selected TCR, the processed Ag peptide and the Ia molecule is not fully understood in molecular terms. Our study intended to delineate the residues of Ab alpha molecules that function as contact sites for Ag and for the TCR of a panel of T cells specific for the A chain of insulin in combination with mixed haplotype Ab alpha:Ak beta molecules. Multiple L cell transfectants expressing alpha,beta-heterodimers composed of wild-type A beta- and chimeric or mutant A alpha-chains served as antigen presenting cells. The recombinant A alpha-chains had been generated by an exchange of allelically hypervariable regions (ahv) or amino acids. The results point out a broad spectrum of b sequence requirements for the bovine insulin-specific activation of the various T cell populations. Activation of some T cells seemed quite permissive, requiring b-haplotype amino acids in any one of the three ahv, while others had strict requirements, demanding b-haplotype sequence in all three ahv. Our data stress the role of ahvII and especially ahvIII in T cell activation. Interestingly, single amino-acid substitutions in ahvII or ahvIII of Ak alpha were sufficient to bring up full stimulation potential for two T cell hybridomas. We also found that some ahv permutations influenced the Ag preference (beef insulin versus pig insulin) of some T cells. These data suggest a critical role for the three-dimensional structure of the complex formed by Ia and the processed Ag peptide. The stability of the trimolecular complex essential for T cell activation is envisioned as being the sum of the interactions between Ag/I-A, TCR/Ag, and TCR/I-A, each variable in strength and compensated for by the others.     

A large degree of functional diversity exists among helper T cells specific for the same antigenic site of influenza hemagglutinin.

The site-1 determinant of the hemagglutinin molecule of influenza virus (A/PR/8/34) is one of several immunodominant sites in the BALB/c Th cell response to Ha. A synthetic peptide comprising this T cell site (HA110-120), a panel of analogs containing single substitutions in this determinant, and homologs truncated at the amino- or carboxyl-terminal were used to examine the fine specificities of 15 T cells specific for site-1 in the context of I-Ed. The results indicate that every residue within the minimal determinant plays a role in the T cell recognition process, as single substitutions at any of these positions affected the ability of the peptide to stimulate at least some site 1-specific T cells. For the majority of the residues examined, substitutions had dissimilar effects on distinct T cells, indicating that the substituted residues were affecting recognition in a receptor-specific manner. Each of the 15 T cells examined had a distinct fine specificity pattern, suggesting that the BALB/c T cell repertoire for this site is likely to exceed 100 distinct clonotypes.     

Fine specificity of T cell recognition of the same peptide in association with different I-A molecules

The fine specificity of the response of T cell clones derived from B10.BR and B10.S congenic mouse strains restricted by I-Ak and I-As molecules, respectively, and which recognize the same 17 amino acid sequence (102-118) of myoglobin, has been investigated and compared with that of T cell clones specific for the same peptide with I-A.d The critical amino acid residues within the 102-118 region of myoglobin required for stimulation of I-Ak-and I-As-restricted T cell clones specific for this determinant were compared using a panel of synthetic peptide analogs. Residues 109, 113, and 116 were critical for stimulation of clones from both haplotypes, although the precise fine specificity varied, even among clones using the same restriction molecule. Residues 109 and 116 are also critical for stimulation of myoglobin-specific I-Ad-restricted clones (Berkower, I., L. A. Matis, G.K. Buckenmeyer, F.R. N. Gurd, D. L. Longo, and J. A. Berzofsky. J. Immunol. 132:1370, 1984). There was also considerable overlap in the size of the minimal determinant necessary for full activity: 106-118 for B10.BR and B10.D2 (Cease, K. B., I. Berkower, J. York-Jolley, and J. A. Berzofsky. J. Exp. Med. 164:1779, 1986) clones and 102-117 for B10.S clones. Despite this similarity in fine specificity, T cell clones were genetically restricted and could not be stimulated with the 102-118 peptide presented by Ia molecules of other haplotypes that could also present this epitope to syngeneic clones. These results suggest that binding of an immunogenic peptide to class II molecules is not sufficient to ensure recognition by a given T cell antigen receptor specific for the peptide, but do not indicate whether the major histocompatibility complex molecules interact directly with the T cell antigen receptor or induce a different recognizable conformation of the peptide.     

Analysis of peptide residues interacting with MHC molecule or T cell receptor. Can a peptide bind in more than one way to the same MHC molecule?

It has generally been assumed implicitly that one can define amino acid residues of a T cell antigenic determinant peptide that interact with the MHC molecule, i.e., residues that form the "agretope." However, if the same peptide can be seen in different conformations or orientations in the same MHC molecule by different T cells, then we would predict that some residues would appear to interact with the TCR of one T cell clone but with the MHC molecule as the peptide is seen by another T cell clone. To test this hypothesis, we synthesized 36 analogue peptides of an immunogenic fragment (P133-146) of sperm whale myoglobin with three different substitutions for each of 12 amino-acid residues and analyzed the role of each residue for I-Ed-binding and for activation of two Th clones, 14.1 and 14.5, specific for the peptide. The two T cell clones showed slightly different fine specificity from each other in that the truncated peptide P136-144 could stimulate 14.5 but not 14.1. The binding activity of nonstimulatory analogues to the I-Ed molecule was measured by functional inhibition analyses using truncated wild-type peptides as stimulators and nonstimulatory analogues as inhibitors. Paradoxical results were obtained that could not be explained by the peptide binding in a single way to the same I-Ed molecule. Some residues appeared to reciprocally reverse their roles for binding to I-Ed vs binding to the TCR when assessed using T-cell clone 14.5 compared to clone 14.1. These results fit the prediction of the above hypothesis and indicate the possibility that the same peptide, P133-146, can bind in more than one way to the same Ia molecule. The T cell clones, 14.1 and 14.5, appear to recognize different P133-146-I-Ed complexes in which the peptide is bound differently. Moreover, a given residue may not have a unique function of always interacting with the MHC molecule or TCR, but may change from one role to the other as it is presented to different T cells.     

Polymorphic HLA-DR7 beta 1 chain residues that are involved in T cell allorecognition

The contributions to allorecognition of polymorphic amino acids in the HLA-DR7 beta 1 chain were analyzed by using mutant DR7 beta 1 chains with single amino acid substitutions at position 4, 11, 13, 25, 30, 37, 57, 60, 67, 70, 71, 74, or 78. Transfectants expressing mutant DR7 molecules were used as stimulators for six DR7-alloreactive T cell clones. The majority of the substitutions had profound effects on the ability of the DR7 molecule to stimulate one or more T cell clones. Nine of the 13 substitutions completely abrogated recognition by at least one clone. The finding that each of the substitutions in the beta-strands in the floor of the peptide binding groove affected T cell allorecognition supports the model of allorecognition in which the complex of a self-peptide bound to a class II molecule is recognized by the TCR. Interestingly, the substitution at position 4, which is predicted to be located outside the peptide binding groove, decreased the ability of the DR7 molecule to stimulate some clones. Each of the DR7-alloreactive T cell clones had a unique reactivity pattern in response to the different mutant molecules, indicating that the TCR of each clone recognized the DR7 molecule differently. Surprisingly, many of the mutant DR7 molecules induced proliferation by one or more clones that was greater than 125% of the proliferation induced by the wild-type DR7 molecule. These data indicate that multiple polymorphic residues, predicted in the class II model to be located in both the beta-strands and alpha-helix of the DR7 beta 1 chain, contribute to allorecognition of the DR7 molecule.     

Identification of residues necessary for clonally specific recognition of a cytotoxic T cell determinant.

The residues in an influenza nucleoprotein (NP) cytotoxic T cell determinant necessary for cytotoxic T cell (CTL) recognition, were identified by assaying the ability of hybrid peptides to sensitize a target cell to lysis. The hybrid peptides were formed by substituting amino acids from one determinant (influenza NP 147-158) for the corresponding residues of a second peptide (HLA CW3 171-182) capable of binding to a common class I protein (H-2Kd). Six amino acids resulted in partial recognition; however, the presence of a seventh improved the potency of the peptide. Five of the six amino acids were shown to be required for recognition. The spacing of the six amino acids was consistent with the peptide adopting a helical conformation when bound. The importance of each amino acid in CTL recognition and binding to the restriction element was investigated further by assaying the ability of peptides containing point substitutions either to sensitize target cells or to compete with the natural NP sequence for recognition by CTL. The T cell response was much more sensitive to substitution than the ability of the peptide to bind the restriction element. Collectively the separate strategies identified an approximate conformation and orientation of the peptide when part of the complex and permitted a potential location in the MHC binding site to be identified. The model provides a rationalization for analogues which have previously been shown to exhibit greater affinity for the class I molecule and suggests that the binding site in major histocompatibility complex (MHC) class I molecules might have greater steric constraints that the corresponding area of class II proteins.     

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.     

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.     

Antigen-specific T cells with monogamous or promiscuous restriction patterns are sensitive to different HLA-DR beta chain substitutions

The contributions of the amino acids at 13 polymorphic positions in the HLA-DR7 beta 1 chain to T cell recognition of two antigenic peptides of tetanus toxin (p2 and p30) were assessed using transfectants expressing mutant DR7 beta 1 chains as APC for six toxin-specific T cell clones with two different restriction patterns: monogamous (restricted by DR7 only) or promiscuous (restricted by DR7; DR1; DR2, Dw21; and DR4, Dw4). Each of the 13 substitutions significantly decreased or eliminated the ability of the DR7 molecule to present a peptide to one or more of the T cell clones, but none of the substitutions abolished recognition by all clones. Interestingly, substitutions at positions 4 and 25, which are predicted in the class II model to be located outside the peptide binding groove, decreased the ability of the DR7 molecule to present Ag to some clones but not to others. Each of the four clones specific for the p2 peptide and the two clones specific for peptide p30 had a different reactivity pattern to the panel of DR7 beta 1 mutants, indicating that the TCR of each clone has a different view of the p2/DR7 or p30/DR7 complex. These data emphasize the complexity of the interactions of multiple residues in DR7 beta 1 chains in Ag-specific T cell recognition.     

Polymorphic residues on the I-A beta chain modulate the stimulation of T cell clones specific for the N-terminal peptide of the autoantigen myelin basic protein

The effect of polymorphic residues on the A alpha A beta molecule on T cell recognition of the N-terminal nonapeptide of myelin basic protein (R1-9) was determined. Ak-restricted T cell clones recognizing R1-9 were isolated. The peptide-Ia specificities of these clones were determined by testing the response to 1) a panel of peptide analogs of R1-11, 2) splenic APC from mice expressing MHC molecules from serologically distinct haplotypes, and 3) L cell transfectants expressing mutant/recombinant A beta cDNA containing combinations of polymorphic nucleotide sequences from the k and u alleles. Comparisons were made between the Ak-restricted clones and a previously characterized panel of Au-restricted clones. Certain Ak-restricted clones were able to recognize MBP peptide analogs that were not recognized by any of the Au-restricted clones. The Au-restricted T cell clones did not cross-react with R1-9 presented in the context of Ak, whereas the majority of the Ak-restricted clones responded to R1-9 presented in the context of Au. This nonreciprocal cross-reactivity was also reflected in the relative responses of the two sets of T cell clones to the interchange of u- and k-derived residues in the A beta chain. Residues in regions corresponding both the alpha-helical or beta-sheet portions of the hypothetical Ia three-dimensional structure were involved. The results suggest that overall specificity of the T cell clones is the summation of numerous distinct subspecificities for different regions of the peptide-Ia ligand. These results indicate that there can be striking differences in T cell specificity for an autoantigenic epitope, even in the context of A alpha A beta molecules from very closely related haplotypes.     

Minimum length of an idiotypic peptide and a model for its binding to a major histocompatibility complex class II molecule.

We have defined the minimum length of a synthetic peptide which can activate I-Ed-restricted BALB/c T cell clones specific for a mutated self-antigen: an idiotope on the syngeneic lambda 2315 immunoglobulin light chain. A peptide comprising residues 91-101 of the lambda 2315 sequence had full stimulatory potency. Surprisingly, a peptide analogue in which His97 was deleted was almost fully active. Truncated, deleted or substituted peptide analogues did not distinguish between seven T cell clones that use different alpha/beta T cell receptors. The 91-101 region in the lambda 2315 light chain does not form an amphipathic helix even though such a helix has been suggested to be important for T cell epitopes. Further, a motif proposed by Rothbard and Taylor as being common to T cell immunogenic peptides is not necessary for the lambda 2315 idiotypic peptide. Comparison with seven other I-Ed-restricted peptides revealed that the peptides are generally positively charged and have two basic amino acids clustered around the centre. On the basis of a model of the class II molecule peptide binding site, we suggest that these positively charged residues may interact with the negatively charged residues at positions 114(Glu) and 155(Asp) of the E beta d chain.     

Binding to Ia protects an immunogenic peptide from proteolytic degradation

A 34 amino acid hen egg-white lysozyme (HEL) peptide was designed and synthesized to investigate if an immunogenic peptide once bound to an Ia molecule becomes proteolytically inaccessible. The determinant recognized by T cells, HEL(52-61) was composed of L-amino acids whereas the 12 amino acid extension on each side of this core were composed of D-epimers. This peptide, HEL(40-73) was resistant to proteolysis, except in the core region, where any cleavage would destroy the determinant. Initially HEL(40-73) was shown to be able to stimulate the HEL specific T cell, 3A9, indicating that an I-Ak molecule can bind and present large peptides that extend beyond the theoretical binding groove. HEL(40-73) was then used to examine the proteolytic sensitivity of determinants recognized by T cells. If HEL(40-73) was treated with chymotrypsin before binding to I-Ak, the determinant was totally destroyed; however, if HEL(40-73) was allowed to first bind to I-Ak, then the determinant became resistant to chymotrypsin cleavage. Thus an Ia molecule can protect a determinant from proteolytic degradation, a finding that has important implications for proposed pathways of Ag processing.     

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.     

Identification and characterization of a T cell-inducing epitope of bovine ribonuclease that can be restricted by multiple class II molecules.

An immunodominant epitope of bovine RNase restricted by I-Ek molecules was identified using a T cell hybridoma recognizing RNase. This epitope was localized to the peptide RNase(90-105). Single conservative amino acid substitutions were made at each of the positions 94 through 105. It was found that only at one position, Asn-103, were conservative substitutions not allowed. This residue was shown to be the critical residue in determining T cell specificity. The ability of RNase(90-105) and the well-defined T cell epitope, HEL(46-61) to stimulate mouse strains expressing different independent H-2 haplotypes was examined using a T cell proliferation assay. The response to HEL(46-61) was completely restricted to mice expressing an I-Ak molecule. In striking contrast, 6 of 10 different mouse strains, H-2b,f,k,q,s,u, mounted vigorous T cell responses to RNase(90-105). The response was restricted to both I-A and I-E molecules, including I-Ab, I-Af, I-Ek, I-Aq, and I-As. H-2d mice were nonresponders to RNase(90-105), which was shown to be due to the failure of RNase(90-105) to bind to I-Ad molecules. A variant RNase(90-105) peptide was generated, containing an I-Ad binding motif, that could bind to I-Ad molecules. Despite its ability to bind, this variant peptide was not able to stimulate a response in H-2d mice. This result demonstrates that the ability of a peptide to bind to an Ia molecule is necessary but not always sufficient for a response to occur. Thus, in contrast to the highly restricted HEL(46-61) determinant, the RNase(90-105) determinant is permissive in its binding to Ia molecules. These results show that in the universe of T cell inducing epitopes contains both highly restricted and broadly restricted epitopes are found.     

Structure-function analysis of the Abm12 beta mutation using site-directed mutagenesis and DNA-mediated gene transfer

The B6.C-H-2bm12 (bm12) mouse possesses a naturally occurring mutation in its class II MHC A beta gene. The three amino acid substitutions at positions 67, 70, and 71 that comprise this mutation lead to changes in both Ia expression and immune recognition of the resultant A beta A alpha molecule. The experiments reported here utilize a combination of oligonucleotide-mediated site-directed mutagenesis and DNA-mediated gene transfer to explore the roles played by each of the three mutant residues in these various phenotypic changes. A beta genes comprising all permutations of the residues distinguishing Ab beta from Abm12 beta were created and were individually co-transfected with Ab beta into mouse L cells. Sublines expressing high levels of membrane Ia were selected by preparative flow cytometry and were studied for reactivity with a panel of monoclonal anti-Ia antibodies, or for their ability to act as antigen-presenting cells (APC) for the stimulation of T cell hybridomas. During the generation of these transfectant lines, it was noted that expression of a high level of Abm12 beta Ab alpha was more difficult to achieve than a similar level of Ab beta Ab alpha. Northern blot analysis of specific A beta and A alpha mRNA levels in these various lines indicated that more class II mRNA, and presumably more A beta and A alpha chains, were required to achieve expression of Abm12 beta Ab alpha equal to that of Ab beta Ab alpha, suggesting that the previously noted reduction of Ia expression on cells from bm12 mice reflects a decreased ability of Abm12 beta Ab alpha chains to pair, or to reach the membrane. Staining of the panel of transfectants with monoclonal antibodies revealed that antibodies which did not distinguish Ab beta Ab alpha from Abm12 beta Ab alpha also reacted equally well with all molecules involving in vitro mutant A beta chains. Monoclonal antibodies reactive with Ab beta Ab alpha but not Abm12 beta Ab alpha were specific for an epitope primarily determined by the presence or absence of Arg 70 in Ab beta. In striking contrast, all three mutant positions were found to play crucial roles in T cell recognition, because all substitutions led to significant or complete loss of antigen-presenting function with all but one of the T hybridomas tested.(ABSTRACT TRUNCATED AT 400 WORDS)