Direct evidence for a functional role of HLA-DRB1 and -DRB3 gene products in the recognition of Dermatophagoides spp. (house dust mite) by helper T lymphocytes

The contribution of the HLA-DRB1, -B3, and -B5 gene products in the recognition of Dermatophagoides spp. (house dust mite) by helper T cells isolated from an atopic individual (HLA-DRw12, DR7; DRw52b) with perennial rhinitis was investigated. Using a panel of histocompatible and histoincompatible accessory cells, the restriction specificity obtained for a long term T cell suggested that a component of the dust mite reactive repertoire recognized antigen in association with DRB3 gene products. Oligonucleotide DNA typing of the presenting cell panel demonstrated a correlation between the DRw52b allele and T cell responsiveness. Murine fibroblasts expressing DRw52b, but not DRw52a or -c molecules, presented antigen to both the T cell line and cloned T cells (DE26) derived from the line, indicating that the supertypic specificity DRw52b was able to restrict recognition of dust mite antigens. Additional T cell clones (DE9 and DE41) also isolated from the line were restricted by the products of the B1 gene locus (DRw12B1) as determined by murine fibroblasts transfected with the appropriate HLA-DR genes. Clone DE9 was degenerate in its restriction specificity, also recognizing dust mite presented by accessory cells expressing the DR2 subtypes. Presentation by fibroblasts transfected with DRw12B1, DR2Dw2B5 genes and EBV-transformed B cell lines expressing DR2DW21B1 and -B5 indicated that the functional site restricting recognition may be associated with residues 70 and 71 of the DR beta chain helical wall of the antigen combining site. Furthermore, we have recently demonstrated that both T cell clones DE9 and DE26 induce allergen dependent IgE synthesis in vitro.(ABSTRACT TRUNCATED AT 250 WORDS)     

Specificity of HLA restricting elements for human nickel reactive T cell clones

In order to study the fine specificity of HLA class II restriction, we have established nickel specific T cell clones from a nickel allergic patient. Cells were cloned by limiting dilution after primary stimulation and selection of nickel specific blasts. Several clones were established which were all shown to carry the CD4 marker. All clones were shown to be completely blocked by monoclonal antibodies directed against DR antigens, but unaffected by antibodies against DQ or DP, thus demonstrating their DR specificity. For the study of HLA class II restriction, a panel of cell donors was carefully HLA typed by including the use of DRB and DQB cDNA probes. Specificity analysis, using allogeneic antigen presenting cells, revealed that the clones were either restricted to DR3- or DR4-like molecules, which is consistent with the fact that the donor was DR3, DR4 positive. However, the studies also revealed that the fine specificity of the DR3 and DR4 restriction could not be completely assessed by serological and genomic typing of panel cells. This indicates that cellularly defined HLA restriction elements recognized by T cells cannot be defined properly with available class II typing methods, and the results of these experiments documented the additional polymorphism of class II restriction elements. The clonal specificity analysis has shed further light on the biologically relevant level of DR polymorphism.     

Identification of cross-reactive T cell restriction epitopes located on the DR7 beta 1 and DR beta 4 molecules.

L cell fibroblasts transfected with HLA class II cDNA clones isolated from a cDNA library produced from a DR7 homozygous cell line were used as antigen-presenting cells (APC) for three HLA DR-restricted, diphtheria toxoid-specific T-cell clones in order to assess the antigen-presenting ability of the transfectants and to define the class II restriction of each clone. Class II-expressing transfectants are capable of presenting antigen to antigen-specific T-cell clones, although the transfectants are less efficient at antigen presentation than conventional APC. Paraformaldehyde fixation of transfectants prior to antigen pulsing abrogated antigen presentation, demonstrating that the transfectants require antigen processing. Antigen presentation by transfectants is completely inhibited by CD4-specific monoclonal antibodies (mAb) and one of four DR-specific mAb, whereas antigen presentation by conventional APC is only partially inhibited. Both the DR alpha:DR7 beta 1 and DR alpha:DR beta 4 (DR omega 53) molecules of the DR7 allotype serve as restriction elements for the diphtheria toxoid-specific T-cell clones. One clone is restricted by the DR7 beta 1 molecule, another clone by the DR beta 4(DR omega 53) molecule, and a third clone by a cross-reactive T cell epitope on DR7 beta 1 and DR beta 4(DR omega 53) molecules. The two DR beta 4(DR omega 53)-restricted clones react, however, differently with a panel of HLA-DR DR omega 53-positive human peripheral blood lymphocytes used as APC. Therefore the data presented here clearly document that the DR beta 4 (DR omega 53) chain may serve as restriction elements for DT-specific T-cell clones. They also provide the first evidence for functional cross-reactivity of the products of two different DR beta loci and in addition emphasize the high complexity of the supertypic HLA-DR omega 53 specificity.     

The Killing of Tumour Cell Targets Coupled to Tuberculin (PPD) by Human and Murine PPD-Reactive T Helper Clones

This paper takes up the major histocompatibility complex (MHC) restriction of killing by a murine and a human tuberculin (PPD)-specific T helper clone of PPD-Con A bound targets. In the previous paper we demonstrated that the specificity of killing of such targets was directed against PPD and not the lectin. This paper provides further evidence to suggest that the PPD-specific clones recognize PPD on PPD-Con A-bound cells though the T cell antigen receptor complex, since the killing was restricted by MHC class II products. Using a range of syngeneic, allogeneic, and semi-syngeneic targets we have shown the fine specificity of the restricting element to be one of the two alleles of the DR region (DR 2) for the human clone, and to be the I-A subregion for the murine clone. Binding studies with radiolabelled class II antibodies were performed to see whether killing efficiency was dependent on the number of class II products expressed. The findings showed that the human B-EBV targets express 2-3 x 10(6) molecules per cell, while the susceptible murine tumours, the Abelson line and the 6A tumour, only expressed 600-800 binding sites per cell. Target cell susceptibility appeared to be linked to the number of class II molecules expressed; thus the syngeneic murine MBL-2 tumour expressing 200-300 binding sites per cell was not killed and the lysis of the 6A and Abelson tumours could be enhanced by doubling the number of class II binding sites by incubating cells with Con A-conditioned medium. However, maximum lysis did not exceed 30-40%, suggesting that class II expression alone did not govern killing.     

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.     

Class II major histocompatibility complex restriction of human T cell responses to short ragweed allergen, Amb a V

Although T cells are known to play a crucial role in the induction of IgE synthesis, the class II major histocompatibility complex (MHC) restriction of aeroallergen-induced T cell responses in humans is incompletely defined. We have previously shown that, in allergic Caucasoid individuals, HLA-DR2 and Dw2 (DR2.2) is strongly associated with specific IgE and IgG antibody responses to highly purified Ambrosia (ragweed) allergen, Amb a V, from the artemisiifolia (short) species. For example, 95% of IgE antibody responders to Amb a V were typed as DR2.2. In a novel study of the genetic control of T cell responses to the Amb a V allergen, we have investigated the MHC class II restriction specificity of three CD4, Amb a V-specific T cell clones derived from a DR2.2+ atopic patient, and a polyclonal Amb a V-reactive T cell line from another DR2.2+ patient. We observed proliferative responses of all three clones to Amb a V only when either HLA-DR2.2 or DR2, Dw12 (DR2.12; found on Mongoloid populations) was present on the antigen-presenting cells, regardless of the HLA-DQ phenotype of the cells. Moreover, the responses of T cell line and clones were abolished by anti-DR but not by anti-DQ nor by anti-DP monoclonal antibodies, and, significantly, anti-DR alpha/beta I2 (anti-DR alpha /beta Iw15/w16; anti-"DR2b") monoclonal antibody blocked, in a dose-dependent manner, the cloned T cell responses to Amb a V. These findings demonstrate that DR alpha/beta I2.2 (DR alpha/beta I1501) and DR alpha/beta I2.12 (DR alpha/beta I1502) are functional in the restriction of the T cell recognition of Amb a V. These findings also illustrate the power of the allergy model for definitive investigation of the molecular basis of the human immune response.     

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.     

The specificity of alloreactive T cells is determined by MHC polymorphisms which contact the T cell receptor and which influence peptide binding

The separate contributions to allorecognition of peptide-binding and T cell receptor-contacting residues of an allogeneic HLA-DR molecule were investigated by site-directed mutagenesis. Alloreactive T cell clones were generated from a combination of responder (DR1Dw1,DR4Dw14) and stimulator (DR1Dw1, DR4Dw10) whose DR products differed at only three amino acid positions, two of which are predicted to interact with the T cell receptor (67 and 70), and one with bound peptide (71). Transfected murine DAP.3 cells expressing the wild type and mutated forms of DR4Dw10 in which the codons for residues 70 and/or 71 had been altered towards DR4Dw14 were used to stimulate a panel of anti-DR4Dw10 T cell clones. Substitutions at either position 70 or 71, or the combination of the two, led to loss of recognition by the alloreactive T cell clones. This implies that residues involved in peptide binding and residues involved in interaction with the T cell receptor are important for this panel of alloreactive T cell clones. The specificity of these alloreactive T cells for exposed polymorphic residues on the allogeneic MHC molecule was further demonstrated by the inhibitory effects of synthetic peptides, derived from the alpha-helix of the beta 1 domain of the DR4Dw10 molecule.     

Homozygous typing cell-defined HLA-Dw specificities correlate better than serologically defined HLA-DR specificities with restriction elements for influenza virus-specific proliferative human T lymphocyte clones

Human T lymphocyte clones with specific proliferative response to influenza A virus were derived by limiting dilution from peripheral blood lymphocytes (PBL) after in vitro stimulation with autologous irradiated, virus-infected PBL. Four OKT3+4+8- T lymphocyte clones (TLC) that showed HLA-restricted antigen-specific proliferative responses were used for a detailed analysis of the restriction elements for antigen presentation. None of the clones showed alloreactivity and all required the presence on the antigen-presenting cell of HLA class II antigens of one or other haplotype of the donor. Restriction elements for two clones were correlated with Dw1 rather than DR1, and for two others with Dw6 rather than DRw6. These latter clones showed differential recognition of HLA-Dw6 subtypes as defined tentatively by homozygous typing cells, without relationship to putative serological "splits" of DRw6. One of the Dw6-restricted clones was specific for a Dw6.1 (now Dw18) "subtype," confirmed by family segregation analysis, the other for a broad Dw6 (Dw18 and Dw19) specificity. Studies with a panel of monoclonal antibodies against monomorphic determinants of HLA class II antigens revealed heterogeneous patterns of blocking activity, distinguishing between clones of different restriction specificity. Inhibition patterns were partly as predictable from the known activity of the monoclonal antibody in alloantigeneic PLT systems. These results provide evidence that certain structures that function as restriction elements for antigen presentation also carry alloantigeneic determinants.     

MHC class II restriction specificity of cloned human T lymphocytes reactive with Dermatophagoides farinae (house dust mite)

In this report the antigen and restriction specificity of human T-cell clones induced with Dermatophagoides farinae (D. farinae) and isolated from an atopic individual with perennial rhinitis has been investigated. Of the six clones analysed, four were species specific and two showed cross-reactivity for the closely related Dermatophagoides pteronyssinus (D. pteronyssinus). Inhibition of antigen-dependent proliferation by murine monoclonal antibodies directed against HLA-D-region gene products revealed that all the clones were restricted by HLA-DR molecules. The restriction specificity was investigated further using a panel of histocompatible and allogeneic-presenting cells. Of the clones tested, one appeared to be DR5 restricted while the remainder showed complex patterns suggesting that DRw52 and DRw53 supertypic specificities may be the restriction elements presenting antigen.     

Structural analysis of human anti-mouse H-2E xenorecognition: T cell receptor bias and impaired CD4 interaction contribute to weak xenoresponses.

T lymphocyte responses to the MHC of an evolutionarily distant species are known to be weak compared with responses against allogeneic MHC products within a species. This fact was used to examine the regions of human MHC class II molecules required for the stimulation of strong primary immune responses against MHC alloantigens. A panel of mouse DAP.3 transfectants expressing the products of wild-type and recombinant DR1/H-2Ek MHC class II genes paired to either DR alpha or H-2E alpha genes was generated, and tested as stimulator cells for purified human T cells. A strong proliferative response to DAP.3 transfectants expressing allogeneic HLA-DR molecules was seen. In contrast, weak or absent responses were recorded against DAP.3 cells expressing H-2E molecules. Substitution of the DR1 beta chain with H-2E beta k led to a dramatic loss of recognition; alpha chain substitution had a less marked effect. Furthermore, replacement of the beta 2 domain of DR1 with H-2E sequence caused 90% inhibition, whereas introduction of the beta 2 domain of DR1 into H-2Ek led to a 10-fold increase in T cell response. These results are most readily explained if the beta 2 domain contributes to the interaction site for the CD4 molecule. Substitution of either half of the beta 1 domain led to a marked loss of response. This was more impressive following substitution of the TCR-contacting alpha-helical region of the domain.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

HLA-DR-, MB- and novel DC-related determinants restrict purified protein derivative of tuberculin (PPD)-stimulated human T cell proliferation

Class II major histocompatibility complex determinants restricting recognition of tuberculin antigens (purified protein derivative; PPD) were studied by using monoclonal antibodies (mAb) to block lymphoproliferative responses. Anti-class II mAb were shown to exert inhibitory effects at the level of the antigen-presenting cells, without inducing suppressive lymphocytes or macrophages. Using panels of HLA-typed antigen-presenting cells and nonalloreactive proliferative T cell lines, derived by limiting dilution, restriction elements for PPD responses appeared to correlate with the donor's HLA-DRw6 specificity (one clone), MB1 (one clone), MB3 (one clone), or no established class II (or class I) specificity (three clones). mAb TU22, reacting with nonpolymorphic DC-like determinants, strongly inhibited stimulation of all clones except that restricted by DR antigens, suggesting the DC-like character not only of the MB1- and MB3-associated, but also of the unassigned, restriction elements of these cloned lines. In contrast, stimulation of the DR-restricted line was strongly inhibited by DR/SB-specific mAb which only weakly inhibited the stimulation of clones restricted by DC-like determinants. These results suggest that clonally distributed PPD-reactive proliferative lymphocytes from a single donor may be restricted by at least three different class II determinants (HLA-DR, MB, or a second, novel, DC-related molecule).     

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.     

Clonal analysis of HLA-DR and -DQ associated determinants: Their contribution to Dw specificities

In order to investigate the distribution of epitopes recognized by T-cell clones directed against HLA class II products, bulk primed cell populations were generated using cells matched for class I determinants but disparate for class II determinants. Cells were cloned by single cell deposition (FACS IV) or limiting dilution (1 cell/3 wells), and assayed for proliferative and cytolytic function with panels of well-characterized cells. All cytolytic clones generated from an anti-DR4/Dw4/DQw3 priming combination or an anti-DR2/Dw2/DQw1 priming combination lysed essentially all targets sharing the same Dw type as the sensitizing cell. In some cases, other targets were also lysed. For instance, some clones were lytic to targets bearing the same DR antigen but another Dw subtype including a few clones lytic to virtually all cells carrying that DR specificity. An occasional target cell expressing a different DR antigen from the sensitizing cell was also lysed by these clones, in some cases to the same extent of lysis seen on the specific target. Monoclonal antibody inhibition studies identified three groups of clones: the DQ directed clones and clones apparently directed at more than one DR product. However, the number of molecules detected for each haplotype remains to be investigated. Our data indicate that determinants detected on both DR and DQ products are associated with the Dw type of the sensitizing cell showing that there is polymorphism recognized by T cells on both DR and DQ that is subtypic to the serologically defined specificities. Thus, it appears that the bulk T-cell response is a composite of individual clones recognizing distinct determinants on these class II molecules. The implications of these findings for studies of HLA restricted recognition are discussed.     

Class II positive human dermal fibroblasts restimulate cloned allospecific T cells but fail to stimulate primary allogeneic lymphoproliferation

Recently, a number of laboratories have shown that gamma interferon (IFN-gamma) is a potent modulator of HLA class II antigen expression in a variety of cell types ranging from classical antigen presenting cells to those not expected to participate in physiological antigen presentation such as fibroblasts. In order to examine the role of HLA class II expressing fibroblasts in antigen presentation, we established dermal fibroblast (FIB) strains from five HLA typed donors. After optimal preculture with IFN-gamma, class II positive FIB were fully competent to restimulate proliferative responses of two DR specific T cell clones and one DP specific T cell line. However, they failed to elicit strong primary allogeneic proliferation from fully DR mismatched fresh PBMC. This failure was not due to a direct suppressive effect of FIB and could not be corrected by exogenous IL1 or by factors contained in conventional mixed leukocyte culture supernatants.     

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.     

The relationship between MHC restricted and allospecific T cell recognition

The existence in the mature T cell repertoire of a high precursor frequency of cells which recognise allogeneic MHC molecules appears to contradict the well-established dogma of positive selection for self MHC restriction. In order to explore the possibility that alloreactive cells are derived from a fraction of the repertoire that is not self-MHC-restricted, the contribution of in vivo-primed T cells to "primary" alloresponses was investigated. Peripheral blood T cells were separated into virgin and memory populations by sorting for low and high levels of LFA-3 expression, and their proliferative responses to MHC incompatible stimulator cells was quantitated. The results demonstrated that approximately half of a "primary" alloresponse is contributed by previously primed T cells that, by definition, must be self-MHC restricted. Furthermore it was possible to define the original MHC-restricted antigen specificity of two T cell clones raised against the allospecific HLA-DR1 from a DR4Dw4/DRw13DW19 responder. The emerging consensus view that anti-MHC alloreactive T cells, like antigen-specific T cells, are specific for MHC/peptide complexes, and have a parental self-MHC restriction, begs a structural explanation. Comparison of multiple DR beta 1 domain sequences reveals that DR molecules fall into groups that have extensive homology in the residues on the beta 1 domain alpha-helix that are predicted to point up towards the T cell receptor (histotopic), and thus to determine MHC restriction. Given that the DR alpha chain is invariant this creates the possibility that anti-DR allorecognition can mimic self-restricted recognition. Within these groups of histotopically similar DR products there are multiple differences in the peptide-binding residues that lie on the inner aspects of the alpha-helix or on the floor of the antigen-binding groove. As a consequence, it is predicted that a different array of endogenous peptides will be bound, due to determinant selection. Thus, allorecognition within these groups may result from the recognition of endogenous peptides that are bound by stimulator but not by responder MHC products, seen in a self-restricted manner. In combinations where histotopic similarity does not exist, allorecognition may be best explained by the chance occurrence of a receptor selected for intermediate affinity for thymically expressed MHC molecules having a higher affinity for an allogeneic histotope. Such a receptor would have been deleted in a thymus expressing the allospecificity, but would be perceived as "safe" in the absence of this MHC product.     

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.     

HLA class II restriction governing cell cooperation between antigen-specific helper T lymphocytes, B lymphocytes and monocytes for in vitro antibody production to influenza virus

To study HLA class II compatibility requirement for in vitro antibody production to influenza virus, semipurified T lymphocytes, B lymphocytes and monocytes from HLA-typed responder donors were used. The presence of the three subpopulations was required for antibody production while a mixture of only two of those was ineffective. When using fresh T lymphocytes which exert an allogeneic suppressive effect and may also exhibit allogeneic helper activity, it was not possible to conclude an HLA class II-linked restriction of T-B cell cooperation although there was a suggestion of it. However, a grown H3 hemagglutinin-specific T cell line (L2), previously shown to be restricted by HLA-DR molecule (DR1) for interaction with antigen-presenting cells and devoid of allogeneic reactivity, exerts an HLA class II-restricted helper activity. This was demonstrated by various combinations of HLA-DR semi-compatible or incompatible B lymphocytes and/or monocytes with L2 T cells. The restriction element was identified as an HLA-DR determined since HLA-DC-compatible, HLA-DR-incompatible B lymphocytes were not helped by L2 T cells. In addition, monoclonal anti-HLA-DR but not anti-HLA-DC antibodies directed to the relevant specificity did inhibit the antigen-specific helper activity. We present evidence that not only T monocyte but also T-B and/or T-B-monocyte interactions are HLA class II restricted.