Site recognition by protein-primed T cells shows a non-specific peptide size requirement beyond the essential residues of the site. Demonstration by defining an immunodominant T site in myoglobin.

In previous studies, six T sites within myoglobin (Mb) were localized. To define precisely the boundaries of the T sites, a new approach is introduced and applied here to the T site residing within residues 107-120 of Mb. Two sets of peptides were synthesized. One set represents a stepwise elongation by one-residue increments of the Mb sequence. The other set represents an identical stepwise addition of one-residue increments of the Mb sequence, but which were extended by additional unrelated (nonsense) residues to a uniform size of 14 residues. The longer peptides (nonsense-extended) usually gave higher proliferative responses than did their shorter counterparts having the same Mb region. Thus a minimum peptide size is required for optimal T-cell stimulation. The T site subtends, in three high-responder mouse strains, residues 109-119 or 110-120, depending on strain, and, in three low-responder strains, maps to residues 108-120. Thus, in this case, the T site coincides with the site of B-cell recognition and resides in a small discrete surface region of the protein chain.     

T-cell recognition and antigen presentation of myoglobin. Protein recognition by site-specific T-cell clones is influenced by amino acid substitutions outside the site.

Six T-cell clones from SJL mice were prepared from T-cell lines that were obtained by passage with synthetic myoglobin (Mb) peptide 107-120. In addition, a T-cell clone, specific to this region of Mb, was isolated from a Mb-passaged T-cell culture. The proliferative responses of these clones to Mb variants from 14 different species were studied. It was found, as expected, that amino acid replacements within the site affected its recognition by the T-cell clones. In addition to these effects, the T-cell recognition site, like the sites recognized by antibodies, was also influenced by substitutions of residues that are close to site residues in three-dimensional structure but are otherwise distant in sequence. This is noteworthy in view of the fact that six of the clones were selected with a free peptide, and thus the environmental residues are clearly not part of the 'contact' residues of the site. These findings are discussed in relation to the presentation of the antigen and are interpreted as indicating that Mb is presented in its intact form to the T-cells in vitro.     

Class II-restricted T-cell clones to a synthetic peptide of influenza virus hemagglutinin differ in their fine specificities and in the ability to respond to virus.

Fifteen T-cell clones were derived from BALB/c or DBA/2 mice immunized with a synthetic peptide corresponding to the C-terminal 24 residues (residues 305 to 328) of the HA1 chain of H3 subtype influenza virus hemagglutinin. All of the clones proliferated when the peptide was presented in association with I-Ed. By using shorter homologs, it was shown that the T-cell response was focused predominantly on the region at the N-terminal end of the peptide encompassed by residues 306 to 319. Individual clones recognizing this region differed in their absolute requirements for residues at the extremities of the site and also in their patterns of efficiency of recognition of shorter homologs. One particular clone defined another site of T-cell recognition within residues 314 to 328. The response of the clones to peptide analogs identified certain residues within the sites that were critical for recognition, with the substitution Gln-311----Ser having a differential effect on clones responding to the N-terminal site. Only one of the clones responded well to influenza virus itself. This clone also required relatively low concentrations of the parent peptide for optimum stimulation and was suppressed by higher concentrations. The data demonstrate striking heterogeneity in the T-cell response even to a short synthetic peptide, with different T-cell clones recognizing slightly different but overlapping areas of the molecule.     

Comparative analysis of core amino acid residues of H-2D(b)-restricted cytotoxic T-lymphocyte recognition epitopes in simian virus 40 T antigen.

Simian virus 40 (SV40) tumor (T) antigen expressed in H-2b SV40-transformed cells induces the generation of Lyt-2+ (CD8+) cytotoxic T lymphocytes (CTL), which are involved in tumor rejection, in syngeneic mice. Five CTL recognition sites on T antigen have been described by using mutant T antigens. Four of the sites (I, II, III, and V) are H-2Db restricted and have been broadly mapped with synthetic peptides of 15 amino acids in length overlapping by 5 residues at the amino and carboxy termini. The goal of this study was to define the minimal and optimal amino acid sequences of T antigen which would serve as recognition elements for the H-2Db-restricted CTL clones Y-1, Y-2, Y-3, and Y-5, which recognizes sites I, II, III, and V, respectively. The minimal and optimal residues of T antigen recognized by the four CTL clones were determined by using synthetic peptides truncated at the amino or carboxy terminus and an H-2Db peptide-binding motif. The minimal site recognized by CTL clone Y-1 was defined as amino acids 207 to 215 of SV40 T antigen. However, the optimal sequence recognized by CTL clone Y-1 spanned T-antigen amino acids 205 to 215. The T-antigen peptide sequence LT223-231 was the optimal and minimal sequence recognized by both CTL clones Y-2 and Y-3. Site V was determined to be contained within amino acids 489 to 497 of T antigen. The lytic activities of CTL clones Y-2 and Y-3, which recognize a single nonamer peptide, LT223-231, were affected differently by anti-Lyt-2 antibody, suggesting that the T-cell receptors of these two CTL clones differ in their avidities. As the minimal and optimal H-2Db-restricted CTL recognition sites have been defined by nonamer synthetic peptides, it is now possible to search for naturally processed H-2Db-restricted epitopes of T antigen and identify critical residues involved in processing, presentation, and recognition by SV40-specific CTL.     

Amino acid sequences around 1, 2-epoxy-3-(p-nitrophenoxy)propane-reactive residues in rhizopus chinensis acid protease: homology with pepsin and rennin.

Two different peptides containing an aspartyl residue reactive with 1, 2-epoxy-3-(p-nitrophenoxy)propane (EPNP) in the acid protease from Rhizopus chinensis were isolated from a peptic digest of the EPNP-modified enzyme. One of the peptides was sequenced as Asp-Thr-Gly-Ser-Asp. The amino acid sequence had very high homology with those around the EPNP-reactive aspartyl residues in rennin (chymosin) [EC 3.4.23.4] and pepsin [EC 3.4.23.1]. The other peptide contained no methionine residue and gave the sequence: Asp-Thr-Gly-Thr-Thr-Leu. The N-terminal aspartyl residue of each peptide was deduced to be the EPNP-reactive site.     

Dissection of H-2Db-restricted cytotoxic T-lymphocyte epitopes on simian virus 40 T antigen by the use of synthetic peptides and H-2Dbm mutants.

Five distinct cytotoxic T-lymphocyte (CTL) recognition sites were identified in the simian virus 40 (SV40) T antigen by using H-2b cells that express the truncated T antigen or antigens carrying internal deletions of various sizes. Four of the CTL recognition determinants, designated sites I, II, III, and V, are H-2Db restricted, while site IV is H-2Kb restricted. The boundaries of CTL recognition sites I, II, and III, clustered in the amino-terminal half of the T antigen, were further defined by use of overlapping synthetic peptides containing amino acid sequences previously determined to be required for recognition by T-antigen site-specific CTL clones by using SV40 deletion mutants. CTL clone Y-1, which recognizes epitope I and whose reactivity is affected by deletion of residues 193 to 211 of the T antigen, responded positively to B6/PY cells preincubated with a synthetic peptide corresponding to T-antigen amino acids 205 to 219. CTL clones Y-2 and Y-3 lysed B6/PY cells preincubated with large-T peptide LT220-233. To distinguish further between epitopes II and III, Y-2 and Y-3 CTL clones were reacted with SV40-transformed cells bearing mutations in the major histocompatibility complex class I antigen. Y-2 CTL clones lysed SV40-transformed H-2Dbm13 cells (bm13SV) which carry several amino acid substitutions in the putative antigen-binding site in the alpha 2 domain of the H-2Db antigen but not bm14SV cells, which contain a single amino acid substitution in the alpha 1 domain. Y-3 CTL clones lysed both mutant transformants. Y-1 and Y-5 CTL clones failed to lyse bm13SV and bm14SV cells; however, these cells could present synthetic peptide LT205-219 to CTL clone Y-1 and peptide SV26(489-503) to CTL clone Y-5, suggesting that the endogenously processed T antigen yields fragments of sizes or sequences different from those of synthetic peptides LT205-219 and SV26(489-503).     

Antigenic structure of human hemoglobin: Delineation of the antigenic site (site 2) within region 41–65 of the alpha chain by immunochemistry of synthetic peptides

A comprehensive synthetic approach consisting of a series of consecutive, uniform overlapping peptides encompassing the entire protein chain was recently used to determine the full antigenic profile of the α-chain of human hemoglobin (Hb). The peptides synthesized enabled the localization of five major “continuous” antigenic regions within the α chain. The present findings describe the delineation of an antigenic site (site 2) residing within the region 41–65. Ten peptides representing the α-chain regions 41–55, 51–65, 45–54, 45–56, 45–58, 45–60, 48–56, 49–56, 50–56, and 51–56 were synthesized and purified. Quantitative radioimmunoadsorbent titrations were used to determine binding to peptide adsorbents of radioiodinated anti-Hb antibodies that were raised in rabbit, goat, and outbred mouse. In one set of peptides, the N-terminal was fixed while the C-terminal end was increased by increments of two residues from Gln-54 to Lys-60 (i.e., peptides 45–54, 45–45, 45–58, and 45–60). Binding studies revealed that maximum antibody activity resided in peptide 45–45, indicating that Lys-56 marks the C-terminal boundary of the site. In the second set of peptides, the C-terminal was fixed at Lys-56 while the peptides were elongated at their N-terminal by one-residue increments from Gly-51 to Leu-48. Antibody-binding studies with these peptides indicated that Ser-49 defines the N-terminal boundary of the site. Therefore, the antigenic site within region 41–65 of the α chain comprises residues 49–56. The relevance of these findings to the immune recognition of Hb and other proteins is discussed.     

Primary structure of hemocyanin subunit c from Panulirus interruptus.

The amino acid sequence of the hemocyanin subunit c from the spiny lobster, Panulirus interruptus, has been determined. The elucidation was mainly based on three digests, with CNBr, trypsin and endoproteinase Glu-C, respectively. Additional evidence was obtained by sequencing of peptides from an endoproteinase Lys-C digest. Subunit c is a polypeptide with 661 amino acid residues and with a carbohydrate group attached to residue 476 in the third domain. No heterogeneity was observed. The degree of identity with subunit a is 59%. Some differences with subunit a are an N-terminal extension of six residues, a one-residue C-terminal extension, and a three-residue deletion. Furthermore, carbohydrate attachment is in a different position, as are most half-cystine residues. Limited trypsinolysis resulted in cleavage at the same site as in subunits a and b.     

Expressed protein ligation. Method and applications.

The introduction of noncanonical amino acids and biophysical probes into peptides and proteins, and total or segmental isotopic labelling has the potential to greatly aid the determination of protein structure, function and protein-protein interactions. To obtain a peptide as large as possible by solid-phase peptide synthesis, native chemical ligation was introduced to enable synthesis of proteins of up to 120 amino acids in length. After the discovery of inteins, with their self-splicing properties and their application in protein synthesis, the semisynthetic methodology, expressed protein ligation, was developed to circumvent size limitation problems. Today, diverse expression vectors are available that allow the production of N- and C-terminal fragments that are needed for ligation to produce large amounts and high purity protein(s) (protein alpha-thioesters and peptides or proteins with N-terminal Cys). Unfortunately, expressed protein ligation is still limited mainly by the requirement of a Cys residue. Of course, additional Cys residues can be introduced into the sequence by site directed mutagenesis or synthesis, however, those mutations may disturb protein structure and function. Recently, alternative ligation approaches have been developed that do not require Cys residues. Accordingly, it is theoretically possible to obtain each modified protein using ligation strategies.     

Effect of point mutations in the native simian virus 40 tumor antigen, and in synthetic peptides corresponding to the H-2Db-restricted epitopes, on antigen presentation and recognition by cytotoxic T lymphocyte clones.

The effects on CTL recognition of individual amino acid substitutions within epitopes I, II, and III of SV40 tumor Ag (T Ag) were examined. Epitope I spans amino acids 207 to 215, and epitope II/III is within residues 223 to 231 of SV40 T Ag. An amino acid substitution at position 207 (Ala----Val) or 214 (Lys----Glu) of SV40 T Ag expressed in transformed cells resulted in loss of epitope I, recognized by CTL clone Y-1. The amino acid substitution at residue 214 in the corresponding synthetic peptide, LT207-215(214-Lys----Glu), also led to loss of recognition by CTL clone Y-1. The recognition, by CTL clone Y-1, of peptides LT207-215 and LT207-217 with an Ala----Val substitution at position 207 was severely affected. Peptides LT205-215 and LT205-219 with the Ala----Val substitution at residue 207 were, however, recognized by CTL clone Y-1, suggesting that residues 205 and 206 may be involved in presentation of site I. Alteration of residue 224 (Lys----Glu) in the native T Ag resulted in loss of recognition by both CTL clones Y-2 and Y-3. However, a peptide corresponding to epitope II/III with an identical amino acid substitution at residue 224 provided a target for CTL clone Y-3 but not clone Y-2. A change of Lys----Gln at residue 224 in both the native protein and a synthetic peptide caused loss of recognition by CTL clone Y-2 but not CTL clone Y-3. Further, an amino acid substitution of Lys----Arg at position 224 of the native T Ag decreased recognition of epitope II/III by CTL clones Y-2 and Y-3 but had no effect on recognition of a synthetic peptide bearing the same substitution. These results indicate that the mutagenesis approach, resulting in identical amino acid substitutions in the native protein and in the synthetic peptides, may provide insight into the role of individual residues in the processing, presentation, and recognition of CTL recognition epitopes.     

Characterization of two distinct major histocompatibility complex class I Kk-restricted T-cell epitopes within the influenza A/PR/8/34 virus hemagglutinin.

Cytotoxic T-lymphocyte (CTL) clones specific for the influenza A/PR/8/34 virus hemagglutinin (HA) were isolated by priming CBA mice with a recombinant vaccinia virus expressing the HA molecule. The epitopes recognized by two of these clones, which were CD8+, Kk restricted, and HA subtype specific, were defined by using a combination of recombinant vaccinia viruses expressing HA fragments and synthetic peptides. One epitope is in the HA1 subunit at residues 259 to 266 (numbering from the initiator methionine), amino acid sequence FEANGNLI, and the other epitope is in the HA2 subunit at residues 10 to 18 (numbering from the amino terminus of the HA2 subunit), sequence IEGGWTGMI. These two peptides are good candidates for naturally processed HA epitopes presented during influenza infection, as they are the same length (eight and nine residues) as other naturally processed viral peptides presented to CTL. A comparison of the sequences of these two new epitopes with those of the three previously published Kk-restricted T-cell epitopes showed some homology among all of the epitopes, suggesting a binding motif. In particular, an isoleucine residue at the carboxy-terminal end is present in all of the epitopes. On the basis of this homology, we predicted that the Kk-restricted epitope in influenza virus nucleoprotein, previously defined as residues 50 to 63, was contained within residues 50 to 57, sequence SDYEGRLI. This shorter peptide was found to sensitize target cells at a 200-fold lower concentration than did nucleoprotein residues 50 to 63 when tested with a CTL clone, confirming the alignment of Kk-restricted epitopes.     

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.     

Evidence for cellular but not serologic cross-reactivity between keyhole limpet hemocyanin and sperm-whale myoglobin.

The addition of keyhole limpet hemocyanin (KLH) to cultures of rabbit lymph node cells (LNC) primed with KLH and sperm-whale myoglobin (Mb) induced the synthesis of antibody to Mb as well as to KLH. Several mechanisms for this heterologous induction were considered. It was established that KLH does not nonspecifically activate rabbit T or B lymphocytes. It was also shown that KLH and Mb do not cross-react serologically by several sensitive and specific criteria. Therefore, it was surmised that heterologous induction of Mb antibody synthesis by KLH was due to cellular cross-reactivity between these proteins. Rabbits were primed by the injection of Mb-complete Freund's adjuvant (CFA), alum-Mb, or alum-KLH, and their LNC challenged with KLH, Mb, and synthetic antigenic sites of Mb. These experiments yielded much and diverse evidence for cellular cross-reactivity between KLH and Mb, and especially between KLH and the Mb peptides: KLH plus Mb-primed LNC evoked enhanced anti-KLH and anti-Mb syntheses. KLH plus KLH-sensitized LNC resulted in a lowered anti-Mb antibody response. Mb added to Mb-educated LNC either enhanced or inhibited the anti-KLH antibody response, depending on whether the priming adjuvant was CFA or alum. The addition of Mb to KLH-primed cells enhanced or inhibited the ensuing anti-Mb antibody synthesis; KLH did not affect or inhibit anti-KLH antibody synthesis. Addition of synthetic Mb antigenic sites to Mb-sensitized LNC elevated or suppressed anti-KLH antibody production, depending on the length of time between priming and in vitro challenge. A mixture of KLH and Mb peptide lowered the anti-Mb antibody response of Mb-educated LNC compared to KLH alone. A combination of KLH and Mb peptide also reduced the anti-KLH antibody synthesis of KLH-primed cells compared to KLH per se. The addition of KLH to Mb-sensitized LNC enhanced their uptake of tritiated thymidine, and their transport of tritiated cyclic AMP and protein synthesis. Added Mb induced the synthesis of protein and nonspecific IgG by KLH-primed LNC; Mb peptides evoked protein synthesis by these cells. It is postulated that cross-reactivity at the T-cell level is responsible for the induction of Mb antibody synthesis by adding KLH to either Mb-primed or KLH/Mb-primed LNC. The implications of these findings with respect to cellular and humoral immunity are discussed.     

In vitro T-cell immunogenicity of oligopeptides derived from the region 92-110 of the 16-kDa protein of Mycobacterium tuberculosis

The 16-kDa protein of Mycobacterium tuberculosis provokes specific immune responses; it is thus a target for the development of peptide-based diagnostic reagents and subunit vaccines. Previous studies have demonstrated the presence of several regions containing murine and human T-cell epitopes. Within the 91-110 immunodominant domain, we found that peptides comprising the sequence of 91SEFAYGSFVRTVSL104 elicit specific T-cell responses in both human T-cell clones and human peripheral blood mononuclear cells (PBMC) from PPD+ (purified protein derivative) individuals. Elongation of this peptide towards the C-terminal end did not provide more effective peptides, but the removal of residue 91Ser resulted in an almost complete loss of functionality. However, the introduction of an acetyl group at the N-terminal of residue 92Glu produced a shorter peptide (Ac-92EFAYGSFVRTVSL104) exhibiting properties required for efficient T-cell responses. CD measurements indicated that peptide 91SEFAYGSFVRTVSLPVGADE110 adopts a helical conformation in trifluoroethanol. We found that the N-terminal part of this sequence plays a major role in the induction of proliferative T-cell responses and is responsible for the highly ordered, helical secondary structure. The "lead" structure described here could also be considered in the development of synthetic peptides or multicomponent peptide mixtures for the early detection, monitoring, or preventing Mycobacterium tuberculosis infection with optimized T-cell response-provoking capacity.     

Beta-amino acid scan of a class I major histocompatibility complex-restricted alloreactive T-cell epitope

An HLA-B27-restricted self-octapeptide known to react with an alloreactive T-cell receptor has been modified by systematic substitution of a beta-amino acid for the natural alpha-amino acid residue, over the whole length of the parent epitope. All modified peptides were shown to bind to recombinant HLA-B*2705 and induce stable major histocompatibility complex-peptide complexes, but with some variation depending on the position of the beta-amino acid on the peptide sequence. Alteration of the natural peptide sequence at the two N-terminal positions (positions 1 and 2) decreases binding affinity and thermodynamic stability of the refolded complex, but all other positions (from position 3 to the C-terminal residue) were insensitive to the beta-amino acid substitution. All modified peptides were recognized by an alloreactive T-cell clone specific for the parent epitope with decreased efficiency, to an extent dependent of the position that was modified. Furthermore, the introduction of a single beta-amino acid at the first two positions of the modified peptide was shown to be sufficient to protect them against enzymatic cleavage. Thus, beta-amino acids represent new interesting templates for alteration of T-cell epitopes to design either synthetic vaccines of T-cell receptor antagonists.     

Antigenic sequences of poliovirus recognized by T cells: serotype-specific epitopes on VP1 and VP3 and cross-reactive epitopes on VP4 defined by using CD4+ T-cell clones.

A panel of poliovirus-specific murine CD4+ T-cell clones has been established from both BALB/c (H-2d) and CBA (H-2k) mice immunized with Sabin vaccine strains of poliovirus serotype 1, 2, or 3. T-cell clones were found to be either serotype specific or cross-reactive between two or all three serotypes. Specificity analysis against purified poliovirus proteins demonstrated that T-cell clones recognized determinants on the surface capsid proteins VP1, VP2, and VP3 and the internal capsid protein VP4. Panels of overlapping synthetic peptides were used to identify eight distinct T-cell epitopes. One type 3-specific T-cell clone recognized an epitope within amino acids 257 and 264 of VP1. Three T-cell epitopes corresponding to residues 14 to 28, 189 to 203, and 196 to 210 were identified on VP3 of poliovirus type 2. The remaining four T-cell epitopes were mapped to an immunodominant region of VP4, encompassed within residues 6 and 35 and recognized by both H-2d and H-2k mice. The epitopes on VP4 were conserved between serotypes, and this may account for the predominantly cross-reactive poliovirus-specific T-cell response observed with polyclonal T-cell populations. In contrast, T-cell clones that recognize epitopes on VP1 or VP3 were largely serotype specific; single or multiple amino acid substitutions were found to be critical for T-cell recognition.     

Studies on the biotin-binding site of streptavidin. Tryptophan residues involved in the active site.

Streptavidin, the non-glycosylated bacterial analogue of the egg-white glycoprotein avidin, was modified with the tryptophan-specific reagent 2-hydroxy-5-nitrobenzyl (Hnb) bromide. As with avidin, complete loss of biotin-binding activity was achieved upon modification of an average of one tryptophan residue per streptavidin subunit. Tryptic peptides obtained from an Hnb-modified streptavidin preparation were fractionated by reversed-phase h.p.l.c., and three major Hnb-containing peptide fractions were isolated. Amino acid and N-terminal sequence analysis revealed that tryptophan residues 92, 108 and 120 are modified and probably comprise part of the biotin-binding site of the streptavidin molecule. Unlike avidin, the modification of lysine residues in streptavidin failed to result in complete loss of biotin-binding activity. The data imply subtle differences in the fine structure of the respective biotin-binding sites of the two proteins.     

Cytochrome c from Schizosaccharomyces pombe. 2. Amino-acid sequence.

The amino acid sequence of Schizosaccharomyces pombe cytochrome c has been established by automatic degradation of the protein and by manual degradation of fragments obtained by cyanogen bromide cleavage and chymotryptic digestion. The chymotryptic peptides were aligned by homology with other known cytochrome c sequences. The protein is 108 residues long, with a four-residue amino-terminal tail. It has only one methionine residue and differs from other fungal cytochromes c in lacking the one-residue deletion at the C-terminal end. After a cyanogen bromide step, an unexpected cleavage of the peptide chain before a cysteine residue was observed. This is ascribed to formation of a dehydroalanyl residue during an incomplete S-carboxymethylation of the apoprotein, and subsequent cleavage under acidic conditions. Experimental evidence is presented in favour of the proposed mechanisms.     

Identification of T-cell epitopes on E2 protein of rubella virus, as recognized by human T-cell lines and clones.

T-cell epitopes on the E2 protein of rubella virus were studied by using 15 overlapping synthetic peptides covering the E2 protein sequence. The most frequently recognized epitopes on E2 were E2-4 (residues 54 to 74), with 5 of 10 tested T-cell lines responding to it. Two CD4+ cytotoxic T-cell cloned isolated from one T-cell line responded strongly in proliferation assays with peptide E2-4 and were cytotoxic to target cells presenting the E2-4 determinant. Truncated peptides contained within the E2-4 peptide sequence were used to define the T-cell determinants. Results indicated that amino acid residues 54 to 65 were directly involved. Human cell lines with different HLA phenotypes were tested for the capacity to present the antigenic determinants. The results suggested that recognition of peptide E2-4 by T-cell clones was associated with HLA DR7.     

Structural basis of Kbm8 alloreactivity. Amino acid substitutions on the beta-pleated floor of the antigen recognition site

We have analyzed the functional significance of the four amino acid differences between the parental H-2Kb and mutant H-2Kbm8 glycoproteins. Six bm8 variants including single substitutions at residues 22, 23, 24, and 30 as well as paired substitutions at residues 23, 30 and 22, 24 were generated and transfected into L cells. Surface expression of these H-2Kb variants was analyzed using monoclonal antibodies which bind to well-defined H-2Kb epitopes. No alterations introduced into the conformational structure of H-2Kb by the amino acid substitutions were detected. The effect of these substitutions on CTL recognition was initially analyzed using the following bulk CTL: either H-2Kb anti-H-2Kbm8, H-2Kbm8 anti-H-2Kb, or third party anti-H-2Kb. The alloreactivity between H-2Kb and H-2Kbm8 is dominated by the amino acid substitution at residue 24 (Glu----Ser). The complete bm8 phenotype, however, also requires the additional substitution at residue 22 (Tyr----Phe). The H-2Kbm8 anti-Kb bulk CTL reacted with both variant H-2Kbm8 molecules containing single substitutions at amino acid positions 22 or 24 but not the variant molecule containing both substitutions. Further analysis using three individual H-2Kbm8 anti-Kb CTL clones indicated the complexity of the self Kbm8 phenotype. Clone 8B1.20 did not react to changes in residues 22 or 24. The 8B1.32 clone reacted with the change at residue 22 but not with the change at residue 24, although the 8B1.54 clone reacted with the change at residue 24 but not with the change at residue 22. The changes in residues 23 (Met----Ile) and/or 30 (Asp----Asn) did not impact significantly on the alloantigenic properties of Kbm8 as determined by both the bulk and cloned CTL populations. According to the three-dimensional class I structure the substitution at amino acid 24 is inaccessible to the TCR. The location of this substitution within the Ag recognition site implies that altered peptide binding, and not a disruption of MHC residues that interact with the TCR, is responsible for the alloreactivity between H-2Kb and H-2Kbm8.