Class-II HLA Restriction of Antigen-Specific Human T-Lymphocyte Clones

Blast-enriched suspensions of T cells primed for Chlamydia trachomatis antigen were cloned by a limiting dilution technique. The class-II HLA restriction of T-lymphocyte clones (TLC) was studied by using allogeneic antigen-presenting cells (APC) carrying foreign class-II HLA antigens. Most of the TLC were restricted by one or the other of the D/DR determinants of the T-cell donor; that is, they did not respond when antigen was presented by APC expressing foreign D/DR determinants. Furthermore, heterogeneity of the DR4-expressing molecule could be demonstrated by T-cell clones from one person; APC from family members expressing DR4 gave high proliferative responses, whereas no proliferation was observed with most APC from unrelated persons expressing DR4. This heterogeneity of DR4 was confirmed by mixed lymphocyte culture (MLC) experiments, indicating a close relationship between restriction epitopes and those that activate allogeneic T cells. Other clones seemed to be restricted by other class-II HLA determinants, most probably MT determinants of the T-cell donor. The restriction specificities were confirmed by subcloning experiments.     

Human T-cell responses to ragweed allergens: Amb V homologues.

Specific IgE and IgG responses to highly purified Ambrosia (ragweed) allergens, Amb a V, Amb t V and Amb p V from the artemisiifolia (short), trifida (giant) and psilostachya (western) species are strongly associated with HLA-DR2 and Dw2 (DR2.2) in allergic Caucasoid individuals. To investigate the molecular basis of these HLA associations, we examined the human T-cell responses to these Amb V homologues using three Amb a V-specific, DR alpha beta I 2.2-restricted T-cell clones from an atopic patient. We first examined the cross-reactivity of Amb a V-specific T-cell clones upon challenge with the Amb a V homologues, Amb t V and Amb p V, in the presence of autologous antigen-presenting cells (APC). Neither Amb t V nor Amb p V was able to stimulate the T-cell clones directly. However, both Amb t V and Amb p V specifically blocked, in a dose-dependent fashion, the ability of APC to present Amb a V to all three T-cell clones. Taken together, these results suggest that Amb t V and Amb p V possess distinct T-cell epitopes, but that all Amb V homologues share similar or identical regions (agretopes) interacting with the DR alpha beta I 2.2 (DR alpha beta I 1501) heterodimer. The agretope was potentially localized to a 14-residue C-terminal Amb a V peptide (with Ala-Cys substitutions), which was able to block presentation of native Amb a V by the APC to the T-cell clones.     

Major histocompatibility complex restriction of tetanus toxoid-specific human T lymphocyte clones

Peripheral blood mononuclear cells (PBMC) from an HLA DRw6/7 individual were stimulated with tetanus toxoid (TT). T cell blasts were cloned by the limiting dilution technique in the presence of TT and irradiated autologous PBMC (iPBMC). Twelve were propagated under interleukin 2 and restimulated weekly with TT and iPBMC. All proliferated specifically in response to TT or either the alpha or beta chain of the toxin molecule. HLA restriction of specific proliferative responses was analyzed using a panel of HLA-typed unrelated donors and selected families, and blocking experiments with anti-HLA class I and class II monoclonal antibodies (mAb). Three types of restriction were observed: (a) autologous restriction; the inhibition observed using anti-HLA DR mAb as well as family studies performed previously with a similarly restricted clone obtained from the same donor suggest an HLA DRw6-linked restriction; (b) an HLA DR7 restriction was found for 2 clones, specific for alpha or beta chain; the identical pattern of inhibition obtained with two different mAb belonging to the same cluster suggests that these clones may be restricted by the same (or a very close) epitope of the HLA DR7 molecule; (c) an unusual restriction pattern was found for one clone; PBMC from more than 80% of donors could present TT whatever their degree of HLA compatibility with the autologous donor. Family studies were unable to disclose any restriction with known class II (or class I) antigens. While no inhibition was observed with anti-DR or -DC reagents, a mAb that recognizes class I antigen when associated with beta 2-microglobulin did inhibit the proliferation of this clone.     

Antigen-specific T cell clones restricted by DR, DRw53 (MT), or DP (SB) class II HLA molecules. Inhibition studies with monoclonal HLA-specific antibodies

T lymphocyte clones (TLCs) specific for Chlamydia trachomatis were obtained after limiting dilution of activated T cells from a single donor, BS (HLA-A3; B7,15; DR1,4; DRw53; DPw4). Most of the proliferative TLCs obtained apparently used restriction elements on DR1 or DR4 molecules, expressed in the antigen-presenting cells (APC). The restriction pattern of two TLCs, however, closely followed the DRw53 specificity, while one TLC seemed to be restricted by elements on DPw4 molecules. A panel of murine monoclonal antibodies (Mabs) was employed to further dissect the restriction specificities. The proliferative capacity of some of the TLCs was studied with and without Mabs directed against different HLA molecules, using non-T cells, monocytes, and peripheral blood dendritic cells as APC. Two Mabs, 7.2 and D-54, which seem to detect monomorphic determinants on HLA-DR, inhibited both DR- and DRw53-restricted TLCs. One Mab, 109d6 which reacts with DRw53 determinants, selectively inhibited the DRw53-restricted TLCs. The DP-restricted TLC was not inhibited significantly by any tested Mabs, including two Mabs with putative specificity for monomorphic determinants on the DP molecule.     

In vitro T cell responses to a candidate Epstein-Barr virus vaccine: human CD4+ T cell clones specific for the major envelope glycoprotein gp340

Specific T cell proliferation was observed in short-term blood mononuclear cell cultures set up from Epstein-Barr virus (EBV)-immune individuals and challenged either with UV-irradiated EB virions or with a candidate subunit vaccine preparation, the purified envelope glycoprotein gp340 incorporated into immune stimulating complexes (gp340 iscoms). Limiting dilution culture of the activated T lymphoblasts in interleukin 2-containing medium generated stable CD3+CD4+CD8- T cell clones. Particular clones showing virus-specific proliferation in preliminary screening assays were selected for more detailed study. Three gp340 iscoms-induced clones from EBV-immune donor CG responded specifically to restimulation either with UV-EBV or with purified gp340 iscoms in the presence of autologous antigen-presenting cells (APC). Both T cell-depleted blood mononuclear cells and the EBV-transformed B cell line (treated with Acyclovir to block endogenous gp340 production) could be used for presentation, the latter being the more efficient when gp340 iscoms was the source of antigen. Blocking studies with monoclonal antibodies to HLA class II antigens and experiments using HLA-typed allogeneic APC indicated that all three gp340-specific CG clones were restricted through the HLA-DR2 antigen. One gp340 iscoms-induced clone from another EBV-immune donor, MR, likewise showed gp340-specific proliferation, in this case restricted through a HLA-DR4 antigen. Using HLA-DR-homozygous B cell lines representing the five known DR4 subtypes, efficient presentation of gp340 to this T cell clone was observed with both DR4 Dw4 and DR4 Dw14 antigens. Parallel experiments on one UV-EBV-induced T cell clone from donor MR gave a different pattern of results; these cells appeared to be specific for a virus structural component other than gp340 and to be restricted through an HLA-DP determinant.     

Phenotypic and functional characterization of human suppressor T-cell clones: II. Activation by Mycobacterium leprae presented by HLA-DR molecules to alpha beta T-cell receptors.

We have been studying human T-cell clones that suppress anti-mycobacterial T-cell responses but not T-cell responses to an unrelated antigen or mitogen. In the present paper we report our studies on the activation requirements of these suppressor-T-cell clones. The suppressor-T-cell clones could proliferate and produce interferon-gamma upon stimulation with Mycobacterium leprae and other mycobacteria but not with unrelated antigens or autologous T cells. Both suppressor and nonsuppressor clones react to a 36-kDa antigen of M. leprae. Thus far, we have not been able to demonstrate whether they see the same or different epitopes. The antigen-driven proliferation of suppressor-T-cell clones was, however, significantly lower than that observed for T-cell clones that did not mediate suppression. The proliferation of suppressor-T-cell clones to M. leprae antigens could be blocked by monoclonal antibodies to HLA-DR, alpha beta T-cell receptor, interleukin-2 receptor, and, in the case of CD4-positive suppressor-T-cell clones, anti-CD4 monoclonal antibodies. DR restriction of the antigen presentation to these suppressor-T-cell clones was shown in mixing experiments using antigen-presenting cells as mononuclear cells from family members and unrelated individuals. These experiments also indicated that apart from regular DR-restriction a hitherto unknown factor may be required for presentation to or activation of suppressor-T-cell clones that is present in the family members and unrelated individuals with the same ethnic and geographic background but absent in DR/Dw-matched healthy Dutch individuals.     

Functional polymorphism of the HLA-DR beta III chain

Several clusters of class II HLA genes contribute to variation in human antigen-presenting capacity. In the HLA-DR cluster, most of the variation is due to the highly polymorphic DR beta I gene. Recent work by others has shown some nucleotide and implied amino acid sequence variation in DR beta III chains, but this variation is not known to be functionally significant. We show here that two proliferating human T-cell clones define three allelic variants of DR beta III (assignment to DR beta III based on blocking of proliferation by selected monoclonal antibodies). Thus, the DR beta III locus encodes at least three alleles that are distinguishable by human T cells and most probably contribute to the human antigen-presenting repertoire. The three DR beta III alleles subdivide the "supertypic" HLA antigen DRw52 into subtypes provisionally called DRw52.1-52.3. The DR3 haplotypes studied to date have been either DRw52.1 or 52.2; DR5 haplotypes have all (23 of 23) been 52.2; DRw6 haplotypes have included all three DRw52 subtypes, nearly half being 52.3. Our data, combined with other published data, imply that DRw8 must either have a fourth DRw52 subtype or be DR beta III null.     

T-cell hybridomas from HLA-transgenic mice as tools for analysis of human antigen processing

The study of antigen processing and presentation by human antigen presenting cells (APC) has been limited by difficulties of producing and maintaining human T-cell clones. Murine T-cell hybridomas have advantages for detecting specific peptide-MHC complexes on APC. Human antigen-specific immortalized T-cell lines have not been successfully produced. We report and validate the use of transgenic mice with human MHC genes for HLA-A2, DR1 and DR4 to produce murine T-cell hybridomas that are restricted to human HLA alleles and respond to human macrophages, dendritic cells (DC), and B-cell lines. Hybridomas restricted by human MHC-I and -II specific for influenza matrix protein, tetanus toxoid, diphtheria antigen CRM(197), and various M. tuberculosis antigens were produced. Epitope specificity was determined for several hybridomas. T hybridomas recognized peptide-MHC complexes on fixed APC for analysis of kinetics or susceptibility to inhibitors of antigen processing. T hybridomas restricted by human MHC represent convenient and powerful tools for the study of antigen processing by human APC.     

Functional evidence for the recognition of endogenous peptides by autoreactive T cell clones

The fine specificity of two human T cell clones responding to autologous HLA-DR1 expressing antigen-presenting cells (APC) in the absence of nominal antigen has been investigated using Epstein-Barr virus-transformed B cells (BCL) of known DR beta 1 domain sequence. It was found that responsiveness was markedly affected by changes in a limited number of residues in this domain. Substitution of the DR1 beta sequence at one residue, position 74, even conservatively, was found to be particularly significant. Located on the beta 1 domain alpha-helix, this residue is predicted to point into the antigen-binding groove and is therefore unlikely to make contact with the T cell receptor. This finding suggests that these T cells are specific for a bound endogenous peptide within the autologous major histocompatibility (MHC) binding groove. The autospecific T cell clones also responded to murine L cell transfectants expressing DR alpha DR1 beta as well as to transfectants expressing the mouse/human hybrid MHC molecule I-E alpha DR1 beta but not to the reciprocal combination DR alpha I-E beta, thus confirming the importance of the beta 1 domain to T cell recognition. In contrast to the autocytotoxicity observed with BCL, cytolysis of the murine L cells expressing the HLA-DR1 molecule was slight and only found at high effector-target ratios. In addition, although fixation enhanced the recognition of BCL, capacity of the murine L cells bearing the HLA-DR1 molecule to stimulate T cell clone proliferation was markedly reduced by aldehyde fixation. When taken together, these results suggest that the endogenous peptides recognized by these autoreactive T cells are of human origin.     

HLA class II restriction repertoire of antigen-specific T cells. I. The main restriction determinants for antigen presentation are associated with HLA-D/DR and not with DP and DQ

In order to study the HLA class II restriction repertoire in antigen presentation to T cells, T lymphoblasts (T-LB) of ten different HLA class II donors were generated by a simple and rapid technique; peripheral blood lymphocytes (PBL) were restimulated in vitro with purified protein derivative (PPD) or tetanus toxoid (TET), and then propagated in interleukin-2 containing conditioned medium (IL2-CM). These T-LB appeared to be antigen specific and devoid of alloreactivity. Antigen was presented to these T-LB by allogeneic irradiated PBL as antigen-presenting cells (APC) in 179 combinations. T-LB proliferative responses were restricted mainly by determinants associated with HLA-DR and not with -DP or -DQ; in 102 fully DR mismatched T-LB/APC combinations matching for DP or DQ determinants had no significant influence on T-LB responses. For PPD, preferential DR1 restriction was observed, and the results suggest a preferential DRw11 vs. DRw12 restriction for TET. Moreover, DRw13 may be associated with low anti-PPD T-LB responsiveness.     

Restriction molecules involved in the interaction of human T cell clones with antigen-presenting cells

Two of three distinct human Ia molecules detected by murine monoclonal antibodies (MoAb) have been suggested to be involved in antigen presentation for T cell responses to purified protein derivatives (PPD) and herpes simplex virus (HSV). This observation was first suggested from studies on the inhibition of proliferative responses of whole T cell populations with MoAb against human Ia molecules. To determine whether a single T cell recognizes the antigen in the context of both Ia molecules or in the context of each one of two Ia molecules, we isolated and propagated PPD-reactive T cell clones from an HLA-DR heterozygous individual. They showed four different restriction patterns: type I and type II clones each appeared to be restricted to one of two HLA-DR antigens, type III clone gave anomalous patterns of response and seemed to be restricted to non-DR antigens, and type IV clone recognized antigen when both DR antigens were presented on the same antigen-presenting cells (APC) surface. Blocking study with monoclonal anti-Ia antibodies suggested that type I, II and IV clones are restricted to DR molecules and type III clones are restricted to 1B4 molecules distinct from DR or MB1 molecules. These data imply that human T cell clones recognizing PPD in the context of each one of two Ia molecules are clonally distributed.     

DR beta peptides block the antigen-specific response but not the alloresponse of a dual-reactive T-cell clone.

It is generally assumed that alloreactivity and the response to foreign antigens are equivalent T-cell recognition events. We have addressed this issue by examining the antigen presentation of beef insulin by two DR1-restricted human T-clones. One of the clones was dual-reactive and exhibited alloreactivity. By employing 20 synthetic consecutive overlapping peptides representing the entire extracellular (residues 1-198) and intracellular (residues 222-273) parts of the DR2 beta molecule, the effects of each of these peptides on antigen presentation and alloreactivity were examined. The DR1-restricted response to beef insulin by both clones was inhibited by peptides from DR2 beta region 1-25. Other DR2 beta (residues 21-198 en 222-237) or control peptides had no effect. The DR3-associated alloresponse of the dual-reactive clone was not inhibited by any peptide. These observations suggest that recognition of antigen is fundamentally different from allorecognition.     

Functional difference between HLA-DR and HLA-DQ molecules in mixed lymphocyte reaction

In order to analyze the functional differences between HLA-DR and HLA-DQ molecules, we have established transfectants expressing HLA class II molecules. We investigated the contribution of these molecules in mixed lymphocyte reaction (MLR) using these transfectants. 1) The genomic clones encoding for DR alpha, DR beta, DQ alpha, and DQ beta from HLA-Dw 15 haplotype were isolated. These genes were introduced into murine L cells and two kinds of stable transfectants expressing either of HLA-DR4 and HLA-DQw4 were established. Expression of HLA class II molecules on transfectants was confirmed by FACS analysis using monoclonal antibodies specific for HLA class II molecules. 2) Primary MLR against class II transfectants and blocking experiments showed that DR molecules function as dominant stimulator molecules in allo MLR, whereas DQ molecules as well as DR molecules stimulate equally auto MLR. 3) We also determined the clone size of MLR reactive CD4+ T cells by the limiting dilution analysis. Frequencies of allo DR, auto DQ, and allo DQ reactive CD4+ T cells was estimated to be almost equal, but frequency of auto DR reactive CD4+ T cells was estimated to be far low. These results suggest the relatively high occurrence of auto DQ reactive clones which contribute significantly to auto MLR. These auto DQ reactive clones may not be eliminated as efficiently as DR reactive clones, because of lower expression of DQ molecules than DR molecules on bone marrow derived cells.     

Diverse locations of amino acids in HLA-DR beta chains involved in polymorphic antibody binding epitopes on DR(alpha, beta 1*0101), DR(alpha, beta 1*1101), and DR(alpha,beta 3*0202) molecules.

In a previous study, we used transfectants expressing hybrid HLA-DR(beta 1*0403)/DR(beta 1*0701) chains to map sequences involved in polymorphic antibody binding epitopes on DR(alpha, beta 1*0403) or DR(alpha, beta 1*0701) molecules. Amino acids 1-40 of the beta 1 domain were found to make the major contributions to most of the antibody binding epitopes studied. To begin to localize sequences that contribute to polymorphic antibody epitopes on DR(alpha,beta 1*0101), DR(alpha,beta 1*1101) and DR(alpha,beta 3*0202) molecules, we used indirect immunofluorescence and flow cytometry to assess the binding of mAb to transfectants expressing hybrid DR(beta 1*0101)/DR(beta 1*1101) or DR(beta 1*1101)/DR(beta 3*0202) chains that divide the DR beta chain into three segments: amino acids 1-40, 41-97, and the beta 2 domain. The results indicate that amino acids 41-97 of the beta 1 domain on DR(beta 1*0101), DR(beta 1*1101), or DR(beta 3*0202) are critical in most of the epitopes, including those recognized by human antibodies MP4 and MP12, and mouse mAb GS88.2, I-LR1, 21r5, and 7.3.19.1, whereas amino acids 1-40 of DR(beta 1*1101) are critical in the epitope recognized by the MCS-7 mAb, and both segments 1-40 and 41-97 of DR(beta 1*1101) are important in the epitopes recognized by the I-LR2 and UL-52 mAbs. Based on these data and comparison of DR beta allelic protein sequences, the residues that may play critical roles in these antibody binding epitopes are predicted.     

Alloreactive T cell recognition of the HLA-DR beta N-terminal polymorphic region

T cell alloreactivity, originally discovered as a tissue transplantation effect, is believed to be a manifestation of the normal major histocompatibility complex (MHC) restriction of antigen presentation by accessory cells to T cells. The molecular features of the human class II-MHC proteins (HLA) which are recognized by alloreactive T cells are not at present understood, although they are clearly related to the polymorphic nature of the MHC proteins. Human CD4+ T cell clones were selected by response to the HLA-DR2 peptides beta 1-15 or beta 51-65, in an MHC-restricted manner. In addition, these clones respond to cell lines expressing the DR2 haplotype, without the requirement for accessory antigen presenting cells. DR2 beta peptide 1-15 blocks the T cell alloresponse and polymorphic residues are shown to stimulate the peptide-specific response of these clones. Thus, the polymorphic residues contained within the DR beta sequence 1-15 are demonstrated to be directly recognized by alloreactive T cells.     

New polymorphic HLA-DR epitopes recognized by three monoclonal antibodies produced against DR103 transfected L cells

Production of monoclonal antibodies directed against polymorphic epitopes of HLA class II molecules using whole human cells as immunogen has often proved ineffective, because most of the antibodies produced are directed against non-MHC human cell surface molecules. One approach to overcome this problem is the use of transfected mouse L cells expressing a single HLA class II allele as immunogen. By immunizing C3H mice with DR103-transfected L cells, we obtained 3 mAb, OHA TM901, OHA TM902, and OHA TM903, that recognize different polymorphic epitopes of the HLA-DR molecule. The molecular specificities of the 3 mAb were determined on a large panel of B-lymphoblastoid cell lines (B-LCL), peripheral blood cells and HLA class II transfectants from the XIth International Histocompatibility Workshop. Interestingly, the 3 polymorphic mAb detect new HLA-DR epitopes shared by several specificities: OHA TM901 reacts with DR1 (DR101, DR103), DR9 (DR901) and DR10 (DR1001) molecules; OHA TM902 recognizes the same molecules but also DR8 (DR801, 802, 803); OHA TM903 reacts with all DR types except DR3 (DR301, 302), DR7 (DR701, 702) and DR52. Surprisingly, OHA TM901 reacts with DR9 transfectants and B-LCL but not with DR9 peripheral blood lymphocytes. Biochemical analyses indicate that the 3 mAb immunoprecipitate HLA-DR products and react in western blots with DR alpha/beta-dimer but not with free alpha- or beta-chains. This study shows that transfected L cells are very useful tools for the production and the fine characterization of mAb recognizing polymorphic epitopes of HLA class II molecules.     

Inhibitory effects of monoclonal antibodies to a synthetic peptide of influenza haemagglutinin on the processing and presentation of viral antigens to class II-restricted T-cell clones

Monoclonal antibodies (mAb) prepared against a synthetic peptide of influenza virus haemagglutinin (HA), containing a known T-cell determinant, were used to examine the mechanism of antigen-induced activation of HA-specific class II-restricted T-cell clones. Previous studies had shown that T-cell clones, established from mice primed by infection with influenza virus, recognize variable antibody binding region of HA, including a determinant formed from residues within the sequence HA1 48-68. MAb to the synthetic peptide, p48-68, recognized purified HA and whole virus in an ELISA, and their specificity pattern for natural variant viruses was similar to that described for the T-cell clones specific for the same peptide. The anti-peptide mAb inhibited peptide or virus-induced proliferation of the peptide specific T-cell clones (but has no effect on a unrelated HA-specific clone), whereas mAb to the native HA molecule inhibited virus but not peptide-induced T-cell activation. In addition, the anti-peptide mAb showed significant inhibition of T-cell proliferation to peptide or virus pulsed antigen-presenting cell (APC). The results suggest that the anti-HA mAb affect antigen induced T-cell activation simply through blocking virus uptake by the APC, whereas the anti-peptide antibodies, which appear to recognize the same determinant on the peptide and the processed antigen, mediate their effect at the level of antigen presentation.     

Clonal distribution of human T cells recognizing PPD in the context of each of two distinct Ia molecules

Participation of two of three distinct human Ia molecules, HLA-DR and the Ia molecule detected by monoclonal antibody (MoAb) 1B4 (1B4 molecules), in antigen presentation for T cell responses to purified protein derivative (PPD) and herpes simplex virus (HSV) was first suggested from studies on the inhibition of proliferative responses of whole T cell populations with MoAb against human Ia molecules. To determine whether a single T cell recognizes the antigen in the context of both Ia molecules or in the context of each one of two Ia molecules, we isolated and propagated PPD-reactive T cell clones from an HLA-DR heterozygous individual. The clones showed four different restriction patterns: type I and type II clones appeared to be restricted to one of two HLA-DR antigens, type III clones gave anomalous patterns of response and seemed to be restricted to non-DR antigens, and type IV clone recognized antigen when both DR antigens were presented on the same APC surface. Blocking study with MoAb to Ia molecules suggested that type I and type II clones are restricted to DR molecules and type III clones are restricted to 1B4 molecules distinct from DR or MB1 molecules. Furthermore, it is most likely that type IV clone was restricted to the interaction molecule associated with DR antigens. These data imply that human T cell clones recognizing PPD in the context of each one of two Ia molecules are clonally distinct.     

Self-nonself discrimination and repertoire selection of human T cells differentiated in an HLA-semiallogeneic environment following bone marrow transplantation for severe combined immunodeficiency.

We have analyzed allorecognition, HLA restriction and T cell receptor (TcR) diversity in an HLA-heterozygous (HLA-DRw6,7) severe combined immunodeficiency (SCID) patient whose T cell system had been repopulated by HLA-homozygous (HLA-DRw6) paternal T cells following T cell-depleted bone marrow transplantation (BMT). Donor origin of T cells and host origin of antigen-presenting cells (APC) in peripheral blood and BM is shown by HLA typing of separated cell populations and two-color immunofluorescence using an anti-HLA monoclonal antibody (mAb). Peripheral blood lymphocytes (PBL) from the chimeric patient proliferate normally against PHA, anti-TcR/CD3 mAb, pooled allogeneic PBL, and also against the recall antigen (Ag) tetanus toxoid and purified protein derivative of tuberculin (PPD) following immunization, suggesting recognition by donor (DRw6) T cells of Ag presented by host (DRw6,7) APC. PPD-specific cytotoxic T lymphocytes generated in vitro from patient PBL post-BMT display specific cytotoxicity against targets expressing DRw6 and DR7, but not against DR-mismatched targets, suggesting that HLA restriction of Ag recognition may occur through determinants expressed by the host and not by the donor. Donor T cells differentiated in the HLA-semiallogeneic host show specific proliferative and cytotoxic responses against HLA-mismatched stimulators, but not against stimulators taken from the host, expressing the host-specific HLA-haplotype, or expressing the host-specific HLA-DR7 antigens. Compared to T cells directly taken from the donor, differentiation of donor T cells in the host is associated with a significant decrease of T cells expressing TcR V beta 5 and V alpha 2 determinants, while no differences in the abundance of of TcR V beta 6, V beta 8 and V beta 12 subsets were noticed. We conclude that allorecognition, major histocompatibility complex (MHC) restriction and TcR diversity generation of human T cells can be modulated through differentiation in an MHC-different environment, as had been previously shown to be the case in murine model systems.     

On the relative immunogenicity of DR alloantigens: T cell recognition of HLA-DR2a and HLA-DR2b

The HLA-DR2 haplotype encodes two highly polymorphic DR molecules, DR2a and DR2b. Because little is known regarding the relative immunogenicity of different HLA-DR molecules, we have studied the T-cell recognition of DR2a and DR2b molecules from the DRw15, Dw2 haplotype. A series of DR2-specific alloreactive T-cell clones were analyzed with murine L-cell transfectants expressing either the DR2a or the DR2b molecules as stimulator cells in proliferation assays. Somewhat surprisingly, both DR2a and DR2b were capable of stimulating DR2-specific T-cell clones with equal magnitude and similar frequency. In addition, DR2a and DR2b are functionally distinct, that is, no clone was identified which was stimulated by both DR2a and DR2b molecules.