Identification of distinct predominant epitopes recognized by myoglobin-specific T cells under the control of different Ir genes and characterization of representative T cell clones

We characterized the fine specificity of antigen recognition of myoglobin-immune T cells from B10.D2, B10.GD, and B10.A(5R) mice. Polyclonal H-2d T cells show a predominant response to an epitope centering on Glu 109 and His 116. These residues localize a dominant epitope to one segment of the myoglobin surface, but probably are not the only amino acid residues involved. This response pattern maps genetically to I-Ad (or Kd) based on the B10.GD recombinant strain. A different epitope specificity was detected in B10.A(5R) T cells mapping to I-E beta b E alpha k or I-Cd, but no difference was detected between strains differing at the Igh locus. Thus, epitope specificity varied with Ia haplotype but not Igh allotype. Myoglobin-specific B10.D2 T cell lines were established, and five clones specific for the Glu 109, His 116 epitope were isolated; these were all restricted to I-Ad antigen-presenting cells. These clones represent the dominant specificity in the polyclonal T cell response to myoglobin and will be useful in characterizing the structure and function of T cell receptors for antigen and Ia. The differences in number and nature of T cell epitopes compared to B cell epitopes of myoglobin are discussed.     

Proliferating and helper T lymphocytes display distinct fine specificities in response to human fibrinopeptide B

The fine specificity of T cell responses involved in the generation of help for antibody production and proliferation was examined by using the 14 amino acid peptide human fibrinopeptide B (hFPB, B beta 1-14) and its synthetic peptide homologues B beta 1-14(Lys14), B beta 1-13, and B beta 3-14. Peritoneal exudate or lymph node T cells from C57BL/10 and B10.BR mice immunized with hFPB or its synthetic homologues were used to measure in vitro proliferative responses. T cells from hFPB-immunized B10.BR mice showed specific proliferation to hFPB, but were unresponsive to B beta 1-14(Lys14), B beta 1-13, and B beta 3-14. B10.BR mice immunized with B beta 1-14(Lys14), B beta 1-13, or B beta 3-14 were unresponsive to all peptides tested. T cells from C57BL/10 mice showed no specific proliferation after immunization and challenge with any of the peptide antigens. In contrast to the patterns of T cell proliferation, immunization of both B10.BR and C57BL/10 mice with hFPB, B beta 1-14(Lys14), B beta 1-13, or B beta 3-14 primed for significant helper T cell activity, as assessed by the augmentation of a primary in vitro B cell IgM anti-FITC plaque-forming cell response after culture with B beta 1-1(Lys14)-FITC. Significant peptide-specific helper activity was observed when the FITC moiety was conjugated to the carboxyl terminal lysine (B beta 1-14(Lys14)-FITC) as well as FITC substitution at the amino terminus (FITC-B beta 3-13 or FITC-B beta 3-14). These results suggest that the fine specificity of T cell responses to peptide antigens are different for helper and proliferating T cells and that responsiveness by one T cell subpopulation does not predict the response pattern of other functional subpopulations.     

In vivo-induced suppression of T cell proliferation: the relationship between the specificity of induction and control

We have previously shown that sc immunization of C57BL/10 (H-2b) mice with the tobacco mosaic virus protein (TMVP) or with its tryptic peptide number 8, representing residues 93-112 of TMVP, induces T cells which proliferate in vitro in response to TMVP and to peptide 8. In contrast, immunization of B10.BR (H-2k) mice either with TMVP or with peptide 8 induces T cells which respond in vitro to the homologous but not the heterologous Ag. In the present article , we report that in the B10.BR (H-2k) strain, ip prepriming with (TMVP) 7 days prior to sc immunization with peptide 8 causes a drastic reduction in the in vitro proliferative response of peptide 8-specific T cells while no such effect is seen in the congenic C57BL/10 (H-2b) strain. This suppression of T cell responsiveness can be transferred with TMVP-primed spleen cells. Moreover, deleting T cells from the transferred spleen cells abrogates the suppressive effect. In both H-2 haplotypes, ip prepriming with peptide 8 causes suppression of the proliferative T cell response induced by subsequent immunization with peptide 8. This prepriming has no effect on the response to TMVP immunization of B10.BR mice but does effect the response of C57BL/10 mice. Using various synthetic peptides to analyze the specificity of the suppression, we have determined that (1) T cells involved in the suppression of the proliferative T cell response to a single peptide determinant do not suppress the proliferative T cell response to other determinants on the protein antigen and (2) these T cells with suppressor function, and proliferating T cells which are ultimately regulated, can exhibit specificity for the same epitope. These studies suggest that there may exist fundamental differences as to how T cells which participate in suppression an proliferating T cells (which include mainly T helper cells) recognize protein antigens.     

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.     

Multispecific CD4+ T cell response to a single 12-mer epitope of the immunodominant heat-shock protein 60 of Yersinia enterocolitica in Yersinia-triggered reactive arthritis: overlap with the B27-restricted CD8 epitope, functional properties, and epitope presentation by multiple DR alleles

Yersinia heat-shock protein 60 (Ye-hsp60) has recently been found to be a dominant CD4 and CD8 T cell Ag in Yersinia-triggered reactive arthritis. The nature of this response with respect to the epitopes recognized and functional characteristics of the T cells is largely unknown. CD4+ T cell clones specific for Ye-hsp60 were raised from synovial fluid mononuclear cells from a patient with Yersinia-triggered reactive arthritis. and their specificity was determined using three recombinant Ye-hsp60 fragments, overlapping 18-mer synthetic peptides as well as truncated peptides. Functional characteristics were assessed by cytokine secretion analysis in culture supernatants after specific antigenic stimulation. Amino acid positions relevant for T cell activation were detected by single alanine substitutions within the epitopes. Fragment II comprising amino acid sequence 182-371 was recognized by the majority of clones. All these clones were specific for peptide 319-342. Th1 clones and IL-10-secreting clones occurred in parallel, sometimes with the same fine specificity. The 12-mer core epitope 322-333 is a degenerate MHC binder and is presented to some T cell clones in a "promiscuous" manner. This epitope is almost identical with a B27-restricted CTL epitope of Ye-hsp60. Cross-reactivity of Ye-hsp60-specific T cell clones with self-hsp60 was not observed. In conclusion, an interesting Ye-hsp60 T cell epitope has been identified and characterized. It remains to be determined whether this epitope is also relevant in other reactive arthritis patients.     

T cell specificity for class II (I-A) and the encephalitogenic N-terminal epitope of the autoantigen myelin basic protein

The role of class II restriction in T cell recognition of an epitope of the autoantigen myelin basic protein (MBP) has been investigated. Encephalitogenic PL/J(H-2u) and (PL/J X SJL/J(H-2s))F1 ((PLSJ)F1) clones, isolated after immunization with intact MBP, recognize the N-terminal 11 amino acid residues of MBP in association with I-Au class II molecules. The synthetic peptide MBP 1-11 has been tested in vivo for induction of EAE. Clinical and histological EAE occurs in PL/J and (PLSJ)F1 mice but not SJL/J. The class II restriction of T cells primed with MBP 1-11 has been examined in primary cultures in vitro. Similar to encephalitogenic T cell clones, isolated after continuous selection in vitro, the population of MBP 1-11-specific proliferative PL/J and (PLSJ)F1 T cells, recognize this epitope in association with I-Au class II molecules. Not all MBP-specific T cell clones which are restricted to I-Au class II molecules cause autoimmune encephalomyelitis. The specificity of these non-encephalitogenic clones has been examined in this report. These clones also recognize MBP 1-11. Thus recognition of an encephalitogenic T cell epitope is not sufficient for induction of EAE.     

Limited T cell receptor beta-chain usage in the sperm whale myoglobin 110-121/E alpha dA beta d response by H-2d congenic mouse strains.

The specificity and TCR gene usage of a panel of sperm whale myoglobin (SpWMb)-reactive T cell clones from DBA/2 mice have previously been characterized, to study structure-function relationships between components of the ternary complex consisting of Ag, TCR, and MHC class II molecules, whose interaction leads to Th cell activation. These DBA/2 clones were specific for epitopes within the residue 110 to 121 region of SpWMb, in the context of the mixed isotype molecule E alpha dA beta d, and expressed the TCR V beta 8.2 gene element. SpWMb-specific T cell hybridomas from the H-2d-congenic B10.D2 mouse strain, which differs from the DBA/2 strain only in the non-MHC background, were generated and compared with the T cell hybridomas from DBA/2 mice, in order to investigate the influence of non-MHC genes on the specificity of the T cell response to the 110-121 epitope. V beta usage by these hybridomas was very homogeneous; three of three DBA/2 and eight of nine B10.D2 hybridomas specific for the 110-121 epitope, in the context of the mixed isotype molecule E alpha dA beta d, expressed the V beta 8.2 gene product. Nucleotide and amino acid sequences of D beta, J beta, and N regions were also similar. One 110-121/E alpha dA beta d-specific B10.D2 hybridoma used V beta 7, a V beta that is clonally deleted in DBA/2 mice. These experiments suggest that a similar set of TCR beta genes are used to respond to a given epitope, regardless of non-MHC background, and they support the hypothesis that, despite great variability between individuals in their non-MHC background genes, human HLA-associated diseases might result from the formation of a particular ternary complex consisting of a shared MHC molecule, a common "disease-associated" epitope, and a shared TCR.     

Measles virus-specific murine T cell clones: characterization of fine specificity and function

Measles virus (MV)-specific murine helper T cell clones (Thy-1.2+, CD4+, CD8-) were generated from mice immunized with MV-infected mouse brain homogenate by limiting dilution and in vitro stimulation of spleen cells with UV-inactivated MV Ag. The protein specificity of 7 out of 37 stable T cell clones, which displayed MHC-restricted MV Ag recognition, could be assessed by using purified MV proteins. Two fusion (F) protein-specific, two hemagglutinin-specific, and three nucleoprotein- or matrix protein-specific clones were shown to be established. The F protein-specific T cell clones together with a panel of previously generated F protein-specific T cell clones were characterized for their fine specificity by using beta-galactosidase fusion products, which contained different parts of the F protein. It was shown that at least two epitopes on the major part of the F protein (amino acid 2-513) can be recognized by mouse T cells. Functional characterization of three T cell clones showed that they were able to assist MV-specific B cells and bystander B cells for antibody production. Furthermore, they were shown to produce the lymphokines IL-2 and IFN-gamma. It was also shown that these T cell clones induced a MV-specific delayed type hypersensitivity response. These observations suggest that all of the T cell clones characterized belong to the TH1 helper subset.     

Molecular mapping of a histocompatibility-restricted immunodominant T cell epitope with synthetic and natural peptides: implications for T cell antigenic structure

We have prepared synthetic and natural peptides that have allowed delineation of a major antigenic site of myoglobin recognized by histocompatibility (I-Ed)-restricted T cell clones. The smallest peptide capable of stimulating T cell proliferation consisted of residues 136-146. Residues Glu 136, Lys 140, and Lys 145 were essential for antigenicity, whereas Lys 133 and Tyr 146 added potency but were not required for antigenicity. The periodicity of these residues suggests that folding the peptide into its native alpha-helical structure may be essential for antigenicity either by forming a hydrophilic binding site for the T cell receptor or by participating in antigen presentation. The same folding could also produce a hydrophobic site on the opposite side of the alpha-helix that could participate in hydrophobic interactions. The extrapolation of these findings to other known peptide antigens suggests that this tendency to form an amphipathic alpha-helix may be a general property of antigenic sites recognized by T cells, perhaps due to a different functional role of each type of site in eliciting T cell responses.     

Adsorption of the protein antigen myoglobin affects the binding of conformation-specific monoclonal antibodies.

Five monoclonal antibodies against sperm whale myoglobin have been used to investigate the physical state of the antigen adsorbed onto a polydimethylsiloxane surface. The binding of each antibody is sensitive to the antigen's conformation in solution while the locations of the antigenic sites on the myoglobin molecule for three of the antibodies have been determined (Berzofsky, J.A., G.K. Buckenmeyer, G. Hicks, F.R.N. Gurd, R.J. Feldmann, and J. Minna. 1982. J. Biol. Chem. 257:3189-3198). The binding of the fluorescein isothiocyanate-labeled IgG and Fab antibodies to previously adsorbed myoglobin has been observed using total internal reflection fluorescence. Three of the antibodies bind specifically to surface-adsorbed myoglobin with affinities at least 50% relative to myoglobin in solution whereas two of the antibodies show affinities for the surface-adsorbed myoglobin diminished by at least two orders of magnitude relative to myoglobin in solution. The specific loss of certain antigenic determinants on the adsorbed myoglobin, coupled with the retention of others, indicates a nonrandom adsorption of the myoglobin molecules.     

Peptide-MHC class I tetrameric complexes display exquisite ligand specificity

The production of synthetic MHC-peptide tetramers has revolutionized cellular immunology by revealing enormous CD8(+) T cell expansions specific for peptides from various pathogens. A feature of these reagents, essential for their staining function, is that they bind T cells with relatively high avidity. This could, theoretically, promote cross-reactivity with irrelevant T cells leading to overestimates of epitope-specific T cell numbers. Therefore, we have investigated the fine specificity of CTL staining with these reagents for comparison with functional data. Using a panel of CTL clones with distinct fine specificity patterns for analogs of an HLA-B8-binding EBV epitope, together with B8 tetramers incorporating these peptides, we show a very good correlation between tetramer staining and peptide activity in cytotoxicity assays. Significant staining only occurred with tetramers that incorporate strong stimulatory agonist peptides and not weak agonists that are unlikely to induce full T cell activation at physiological levels of presentation. In almost every case where a peptide analog had >10-fold less activity than the optimal EBV peptide in cytotoxicity assays, the corresponding tetramer stained with >10-fold less intensity than the EBV epitope tetramer. Furthermore, by examining an EBV-specific clonotypic T cell expansion in EBV-exposed individuals, we show similar fine specificity in tetramer staining of fresh peripheral T cells. Collectively, our data demonstrate the exquisite specificity of class I MHC-peptide tetramers, underlining their accuracy in quantifying only those T cells capable of recognizing the low levels of cell surface peptide presented after endogenous Ag processing.     

Human CD4+ T cells induced by synthetic peptide malaria vaccine are comparable to cells elicited by attenuated Plasmodium falciparum sporozoites

Peptide vaccines containing minimal epitopes of protective Ags provide the advantages of low cost, safety, and stability while focusing host responses on relevant targets of protective immunity. However, the limited complexity of malaria peptide vaccines raises questions regarding their equivalence to immune responses elicited by the irradiated sporozoite vaccine, the "gold standard" for protective immunity. A panel of CD4+ T cell clones was derived from volunteers immunized with a peptide vaccine containing minimal T and B cell epitopes of the Plasmodium falciparum circumsporozoite protein to compare these with previously defined CD4+ T cell clones from volunteers immunized with irradiated P. falciparum sporozoites. As found following sporozoite immunization, the majority of clones from the peptide-immunized volunteers recognized the T* epitope, a predicted universal T cell epitope, in the context of multiple HLA DR and DQ molecules. Peptide-induced T cell clones were of the Th0 subset, secreting high levels of IFN-gamma as well as variable levels of Th2-type cytokines (IL-4, IL-6). The T* epitope overlaps a polymorphic region of the circumsporozoite protein and strain cross-reactivity of the peptide-induced clones correlated with recognition of core epitopes overlapping the conserved regions of the T* epitope. Importantly, as found following sporozoite immunization, long-lived CD4+ memory cells specific for the T* epitope were detectable 10 mo after peptide immunization. These studies demonstrate that malaria peptides containing minimal epitopes can elicit human CD4+ T cells with fine specificity and potential effector function comparable to those elicited by attenuated P. falciparum sporozoites.     

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

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

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.     

Human T cell recognition of influenza A nucleoprotein. Specificity and genetic restriction of immunodominant T helper cell epitopes.

The characterization of human T cell antigenic sites on influenza A nucleoprotein (NP) is important for subunit vaccine development for either antibody boosting during infection or to stimulate T cell-mediated immunity. To identify such sites, 31 synthetic peptides that cover more than 95% of the amino acid sequence from NP of influenza A/NT/60/68 virus were tested for their ability to stimulate PBL from 42 adult donors. The most frequently recognized region was covered by a peptide corresponding to residues 206-229 of NP, with 20/42 (48%) of responders. In many individuals this was also one of the peptides that stimulated the strongest T cell responses. Other regions that were also frequently recognized were 341-362 by 13/42 (30%), 297-318 by 10/42 (23%), and 182-205 by 9/42 (21%) of individuals. These peptides covered highly conserved regions in NP of influenza A viruses, suggesting that they could be useful in boosting cross-reactive immunity against the known type A virus strains. In order to define the class II restriction molecules used to present particular T cell epitopes, 22 persons from the donor panel were HLA-typed. The majority of persons who expressed DR2, and proliferated to NP also responded to the major immunodominant region 206-229. In addition, this peptide was also immunodominant in the one person expressing DRw13. The observation that recognition of this peptide is associated with DR2 was confirmed by using short term T cell lines and APC from a panel of typed donors. Further results with virus-specific T cell lines and clones and transfected L cells expressing DR molecules showed that DR1 could also present this peptide. Therefore the results suggest that recognition of 206-229 is associated with at least three different DR haplotypes and this may explain the high frequency with which this peptide is recognized in the population. The fine specificity of the response to peptide 206-229 was distinct when presented by DR1- or DR2-expressing APC. The DR1 response was dependent on the N terminus, and the DR2 response was directed to the C terminus of the peptide.     

Structural aspects of a protein epitope and their role in the major histocompatibility complex control of T cell responsiveness.

We have previously shown that immunization of C57BL/10 (H-2b) mice with the tobacco mosaic virus protein (TMVP) or with its tryptic peptide number 8, representing residues 93-112 of TMVP, induces T cells which proliferate in vitro in response to TMVP and peptide 8. In contrast, immunization of congenic B10.BR (H-2k) mice with either TMVP or with peptide 8 induces T cells which respond in vitro to the homologous but not the heterologous antigen. The capacity to exhibit cross-reactivity between TMVP and peptide 8 on the T cell level has been shown to be under major histocompatibility complex (MHC)-linked genetic control. The lack of cross-reactivity has been attributed to the inability of the H-2k APC to present the appropriate epitope to T cells. In the present paper, we report results of a comparative analysis of the role of structural aspects of the epitope on the proliferative T cell responses from TMVP and peptide 8-immune C57BL/10 (H-2b) and B10.BR (H-2k) mice. Utilizing a panel of synthetic peptides representing portions of peptide 8 and a panel of peptide-protein conjugates, we have determined that peptide 8-immune T cells of the H-2k strain appear to recognize a single epitope within peptide 8, located at its N-terminus. In contrast, in the H-2b strain, both TMVP and peptide 8-immune T cells appear to recognize two overlapping epitopes within peptide 8; one located in the middle region and the other toward the N-terminus. Experiments with H-2b T cells revealed that random amino acids added to the carboxyl or amino-terminus of nonstimulatory peptides can confer activity to these peptides, demonstrating limited specificity of interaction between antigen and Iab. Results of experiments dealing with fixation of antigen-presenting cells suggest that TMVP requires processing in order to be recognized by peptide 8-immune H-2b proliferative T cells whereas peptide 8 does not. Taken together the results suggest that the T cell responsiveness to TMVP and peptide 8 exhibited by these two congenic strains H-2b and H-2k is not only controlled by the strains MHC but is also influenced by antigen processing. Antigen processing may eliminate a potential epitope for the primary induction and the secondary stimulation of B10.BR T cells.     

Functional differentiation in the genetic control of murine T lymphocyte responses to human fibrinopeptide B

The ability to generate proliferative and helper T lymphocyte responses in mice was compared by using the 14 amino acid peptide, human fibrinopeptide B (hFPB). Lymph node or peritoneal exudate T cells from mice immunized with hFPB were assessed for in vitro proliferation to soluble hFPB as determined by the uptake of 3H-thymidine. The T cell proliferative response to hFPB was found to be under MHC-linked Ir gene control; mice possessing the H-2a,k haplotypes were responders, whereas H-2b,d,q,s mice were nonresponders. The influence of non-H-2 genes on these responses was not investigated, so exclusive regulation by H-2 is provisional. The absence of a detectable lymph node and peritoneal exudate T cell proliferative response persisted in H-2b,d,q,s mice after immunization and boosting with several doses of hFPB. In addition, the capacity to produce a T cell proliferative response was inherited in an autosomal dominant manner and gene(s) controlling responsiveness to hFPB mapped to the I-A subregion of the H-2 complex. To measure peptide-specific helper T cell activity, an in vitro microculture assay in which hFPB-primed lymph node T cells and normal spleen B cells and macrophages were used was developed measuring anti-fluorescein isothiocyanate (FITC) IgM and IgG plaque-forming cell (PFC) responses after culture with FITC-conjugated peptide. Immunization of B10.BR, C57BL/10, B10.D2, and B6AF mice with hFPB primed for significant helper T cell activity as assessed by the ability to augment a primary in vitro IgM response to FITC. The normal B cell IgM responses were completely dependent on hFPB-primed T cells and required that hapten (FITC) and carrier (peptide) be linked. In addition, immunization with FITC-conjugated peptide elicited positive in vivo PFC responses to FITC in B10.BR and C57BL/10 mice, indicating similar genetic control of helper activity in both the intact animals and the in vitro microcultures. Thus, B10.BR mice show both T help and T proliferative responses to hFPB, whereas C57BL/10 mice show only T help and no T proliferative responses. In contrast to B10.BR mice, C3H and CBA mice immunized with hFPB were completely unresponsive when assayed for helper T cell activity in vitro despite their ability to generate positive lymph node T cell proliferative responses. These results indicate responsiveness to hFPB by T helper and proliferating cells is different and is under separate genetic control.     

Comparative analysis of collagen type II-specific immune responses during development of collagen-induced arthritis in two B10 mouse strains

Introduction

Immune responses against collagen type II (CII) are crucial for the development of collagen-induced arthritis (CIA). The aim of the present study was to evaluate and compare the CII-directed T cell and antibody specificity at different time points in the course of CIA using two mouse strains on the B10 genetic background - B10.Q, expressing A^q MHC class II molecules, and B10.DR4.Ncf1^*/*, expressing human rheumatoid arthritis-associated MHC II DR4 molecules (DRA*0101/DRB*0401).

Methods

B10.Q and B10.DR4.Ncf1^*/* mice were immunized with CII emulsified in adjuvant and development of CIA was assessed. T cells from draining lymph nodes were restimulated in vitro with CII peptides and interferon-gamma (IFN-γ) levels in culture supernatants were evaluated by ELISA. CII-specific antibody levels in serum samples were measured by ELISA.

Results

At four different CIA time points we analyzed T cell specificity to the immunodominant CII epitope 259-273 (CII259-273) and several posttranslationally modified forms of CII259-273 as well as antibody responses to three B cell immunodominant epitopes on CII (C1, U1, J1). Our data show that CII-specific T and B cell responses increase dramatically after disease onset in both strains and are sustained during the disease course. Concerning anti-CII antibody fine specificity, during all investigated stages of CIA the B10.Q mice responded predominantly to the C1 epitope, whereas the B10.DR4.Ncf1^*/* mice also recognized the U1 epitope. In the established disease phase, T cell reactivity toward the galactosylated CII259-273 peptide was similar between the DR4- and the A^q-expressing strains whereas the response to the non-modified CII peptide was dramatically enhanced in the DR4 mice compared with the B10.Q. In addition, we show that the difference in the transgenic DR4-restricted T cell specificity to CII259-273 is not dependent on the degree of glycosylation of the collagen used for immunization.

Conclusions

The present study provides important evaluation of CII-specific immune responses at different phases during CIA development as well as a comparative analysis between two CIA mouse models. We indicate significant differences in CII T cell and antibody specificities between the two strains and highlight a need for improved humanized B10.DR4 mouse model for rheumatoid arthritis.     

Relationship between T cell receptors and antigen-binding factors. I. Specificity of functional T cell receptors on mouse T cell hybridomas that produce antigen-binding T cell factors

Upon antigenic stimulation with OVA-pulsed syngeneic macrophages, the mouse T cell hybridoma 231F1 produced glycosylation inhibiting factor (GIF) having affinity for OVA and IgE-suppressive factors, whereas another T cell hybridoma, 12H5, cells produced OVA-binding glycosylation enhancing factor (GEF) and IgE-potentiating factor. The OVA-binding GIF from the 231F1 cells is an Ag-specific Ts cell factor, whereas OVA-binding GEF from the 12H5 cells is an Ag-specific augmenting factor. Both hybridomas express CD3 complex and functional TCR-alpha beta. Cross-linking of TCR-alpha beta or CD3 molecules on the hybridomas by anti-TCR-alpha beta mAb or anti-CD3 mAb and protein A resulted in the formation of the same factors as those obtained by the stimulation of the cells with OVA-pulsed syngeneic macrophages. It was also found that both the 231F1 cells and 12H5 cells formed IgE-binding factors upon incubation with H-2d and H-2b APC, respectively, with a synthetic peptide corresponding to residues 307-317 in the OVA molecules (P307-317). Six other synthetic peptides, including those containing the major immunogenic epitope, i.e., P323-339, failed to stimulate the hybridomas in the presence of APC. Indeed, all of the 10 T cell hybridoma clones, which could produce either OVA-binding GIF or OVA-binding GEF, responded to P307-317 and APC for the formation of IgE-binding factors. In contrast, GIF/GEF derived from six other hybridoma clones, whose TCR recognized P323-339 in the context of a MHC product, failed to bind to OVA-coupled Sepharose. The results indicate the correlation between the fine specificity of TCR and the affinity of GIF/GEF to the nominal Ag. The amino acid sequence of P307-317 suggested that TCR on the cell sources of Ag-binding factors are specific for an external structure of the Ag molecules.     

Recognition of hepatitis B virus envelope proteins by liver-infiltrating T lymphocytes in chronic HBV infection

The Ag specificity and cytotoxic function of human T cell clones, generated from lymphocytes infiltrating the liver of a chronic hepatitis B patient, were studied. Both class I- and class II-restricted T clones specifically proliferated to hepatitis B virus envelope proteins, but not to hepatitis B core Ag. The fine specificity of T cells was studied by using rAg having different composition in relation to HBV-envelope proteins or synthetic peptides of preS regions. The antigenic determinant recognized by T cell clones mapped to the preS2 region based on the response to r(preS1+preS2+S) and to r(preS2+S) and the failure to respond to S or preS1 alone. More precise epitope mapping was based on synthetic preS2 peptides 120-150 or 120-134, which stimulated both class I- and class II-restricted T clones, whereas preS2 153-171 or preS1 1-110 peptides did not; thus, the preS2 120-134 appears to contain both the residues binding to class I molecules and the residues binding to class II molecules. Moreover, strong and specific cytotoxic responses of these clones were observed only when HLA-matched EBV-lines, used as target cells, were previously sensitized with r(preS1+preS2+S) or preS2 peptides, which were shown to stimulate the clones. Thus, a preS2 epitope can represent a target Ag for liver-infiltrating T cells, which could kill the hepatocytes expressing the Ag plus the appropriate MHC molecule.