Insulin-specific human T cells. Epitope specificity, major histocompatibility complex restriction, and alloreactivity to a diabetes-associated haplotype

T cells from an insulin-treated diabetic (ML, HLA DR1, w6) were stimulated in vitro with insulin, cloned at limiting dilution, and examined for their fine specificity and genetic restriction. T cell lines (TCL) derived from beef insulin stimulation were highly specific for epitopes on beef insulin, whereas pork insulin stimulation generated T cells that recognized determinants shared with beef insulin. Included among TCL reactive with pork insulin is one line (P2/9) that is autoreactive with human insulin. Antigen-presenting cells of known HLA type and monoclonal antibodies directed at class II major histocompatibility complex antigens were used to confirm the role of HLA-DR in restricting the response of insulin immune T cells. No preference or determinant selection within the donor's haplotypes was identified because either DR1 or DRw6 antigen-presenting cells could present the A loop of beef insulin. A TCL that recognized the A loop of beef insulin in association with DR1 was also alloreactive to HLA DR3, or a molecule closely linked to it, in the absence of insulin. A second T cell clone with insulin specificity and alloreactivity was also derived by allo stimulation of the donor's cells with DR3+ cells. When tested with a series of DR3+ stimulator cells, the alloreactivity was directed at diabetes-associated haplotypes. These data show that the T cell repertoire for insulin of a single diabetic donor encompasses that of multiple inbred animal strains and includes fine specificity for one to two amino acids, recognition of autologous insulin, and cross-reactivity with an allogeneic major histocompatibility complex antigen.     

Antigen presentation by human antigen-presenting cells to antigen-specific xenogeneic murine T cells

Successful antigen presentation by xenogeneic human antigen-presenting cells (APC) to stimulate the proliferation of antigen-specific, keyhole limpet hemocyanin (KLH)-specific, ovalbumin (OVA)-specific, and purified protein derivative of Mycobacterium tuberculosis (PPD)-specific murine T cells was observed. Evidence indicating a direct cell interaction between antigen-specific murine T cells and xenogeneic human APC was given by experiments using antigen-specific murine T cell clones. The OVA-specific B10.S(9R) T cell line (9-0-A1) and PPD-specific B10.A(4R) T cell line (4-P-1) were stimulated by both xenogeneic human APC and murine APC from syngeneic or I-A compatible strains, while the PPD-specific human T cell line (Y-P-5) was stimulated by autologous human APC but not by murine APC. Anti-HLA-DR monoclonal antibodies (MoAb) blocked the xenogeneic human APC-antigen-specific murine T cell clone interaction. Thus, human xenogeneic APC can stimulate antigen-specific murine T cells through HLA-DR molecules in the same manner as syngeneic murine APC do through Ia molecules coded for by the I region of the H-2 complex, while murine APC failed to present antigen to stimulate human antigen-specific T cells.     

Induction of IgG and IgE synthesis in normal B cells by autoreactive T cell clones

During the course of generating tetanus toxoid (TT)-specific T cell clones frm an HLA-DR2,7 donor, four clones were obtained which proliferated in the presence of autologous monocytes alone without the addition of TT antigen. This proliferation was specifically inhibited by anti-HLA-DR framework mouse monoclonal antibody, and appeared to be HLA-DR-restricted. Two of the clones proliferated in response to HLA-DR2-bearing monocytes, and the other two clones proliferated in response to HLA-DR7-bearing monocytes. The capacity of these four autoreactive human T cell helper clones to induce IgE synthesis in B cells was studied. All four clones stimulated autologous peripheral blood B cells to synthesize IgE and IgG antibody. Induction of IgE synthesis in B cells by the autoreactive T cell clones followed the same pattern of HLA-DR restriction which governed the proliferative response of these clones. These results suggest that the interaction of autoreactive helper T cells with B cell HLA-DR antigens may be important in the activation of IgE immune responses in humans.     

Functional and molecular analysis of three distinct HLA-DR4 beta-chains responsible for the MLR between HLA-Dw4, Dw15, and DKT2

Differences in structure and function of HLA-class II molecules between HLA-DR4-related HLA-D specificities HLA-Dw4, Dw15, and DKT2 were investigated. Anti-HLA-DR framework monoclonal antibody HU-4 completely inhibited the one-way mixed lymphocyte reaction (MLR) between these specificities. HU-4 precipitated a monomorphic alpha-chain and a polymorphic beta-chain of human class II molecules from each B lymphoblastoid cell line (BLCL) homozygous for these three HLA-D specificities. We established IL 2-dependent T cell lines specific for streptococcal cell wall (SCW) antigen from peripheral blood lymphocytes (PBL) from four DR4-positive donors: an HLA-Dw4/DKT2 heterozygote, an HLA-Dw4/Dw12 heterozygote, an HLA-DKT2/D-blank heterozygote, and an HLA-Dw15/D-blank heterozygote. These T cell lines showed a proliferative response to SCW antigen in the presence of autologous or allogeneic antigen-presenting cells (APC) when T cell donors and APC donors shared at least one of the HLA-D specificities. This cooperation between the T cell line and APC was completely blocked by HU-4. We conclude from these data that the T cells could distinguish three distinct DR4 molecules expressed on APC of HLA-Dw4, Dw15, and DKT2 as restriction molecules at the presentation of SCW antigen.     

Immune response to Toxoplasma gondii--analysis of suppressor T cells in a patient with symptomatic acute toxoplasmosis

Unresponsiveness of antigen-dependent (Toxoplasma-specific and purified protein derivative of tuberculin [PPD]-specific) T-cell proliferative responses of peripheral blood leukocytes (PBL) was observed in a patient with symptomatic acute toxoplasmosis. The immunosuppression of T-cell responses was mediated by Leu 1+, Leu 2a+, and Leu 3a- suppressor T cells that were induced by Toxoplasma gondii antigen and suppressed both Toxoplasma-specific and PPD-specific PBL T-cell responses from a patient with chronic toxoplasmosis when PBL of these patients were mixed and cocultured in vitro. Participation of class II molecules of HLA in Toxoplasma-specific proliferative T-cell responses and activation of suppressor T cells was examined by using monoclonal antibodies specific for HLA-DR and HLA-DQ molecules. Anti-HLA-DQ monoclonal antibody released the suppressive activity, while anti-HLA-DR monoclonal antibody inhibited Toxoplasma-specific T-cell responses. Thus, the suppressive effect of PBL from a patient with acute toxoplasmosis on antigen-dependent PBL T-cell responses from a patient with chronic toxoplasmosis was mediated by HLA-DQ molecules. By contrast, Toxoplasma-specific T-cell responses were activated by HLA-DR molecules (presumably present on antigen-presenting cells).     

Measles-specific T cell clones derived from a twin with multiple sclerosis: genetic restriction studies

The association between multiple sclerosis (MS) and HLA-DR2 suggests that the disease may be associated with an aberrant immune response, likely directed against an antigen of either viral or host origin. We have used measles virus-specific T cell clones derived from a patient with MS to study genetic restriction patterns of antigen presentation by macrophage-enriched (E-) populations. Twenty-two clones proliferated in response to measles-infected Vero cells but not to mumps-infected or uninfected Veros. E- cells from both the autologous subject and her healthy, measles nonresponder identical twin were capable of presenting antigen to all clones. Studies with E- cells obtained from a panel of cell donors demonstrated clones which recognized antigen in association with D2/DR2, DR4, subgroups of DR4, and SB3. Three clones recognized antigen only in association with the autologous or twin's cells, but not with other sets of HLA-matched E-cells obtained from healthy donors or from other patients with MS. These studies indicate that the differing responses to measles virus demonstrated by these two identical twins are not explained by alterations in the interactions between antigen-presenting cells and T cells. Furthermore, at the clonal level, no preferential role is seen for HLA-DR2 as the restricting element for presentation of measles virus to these clones.     

Human myelin basic protein-specific cytolytic T lymphocyte clones are functionally restricted by HLA class II gene products

Cellular immune reactions against the autoantigen myelin basic protein (MBP) are strongly implicated in the occurrence of postinfectious and postvaccination encephalomyelitis. Clinical autoimmune encephalomyelitis in experimental animals can be transferred with cloned MBP-specific cytolytic major histocompatibility complex Class II-restricted T lymphocytes. The HLA restriction pattern of specific proliferative and cytolytic functions of two human MBP-specific cytotoxic T lymphocyte clones, derived from two different multiple sclerosis patients, was analyzed in detail. Using monoclonal antibodies against various HLA gene products and allogeneic Epstein-Barr virus-transformed B cells as antigen-presenting cells and as targets for cytolysis, it was found that MBP-specific functions of the T cell clones was restricted by HLA class II antigens, and, more specifically, by molecules encoded for by DR locus genes.     

An antiviral T-Cell clone defines a functional supertypic specificity shared by different HLA-DR molecules from DR2-short,DRw11, and DRwl3 Haplotypes

An influenza virus-specific HLA class IIrestricted human T4⁺ clone (Ij) allows us to define a new functional supertypic HLA class II specificity shared by three different haplotypes. Influenza A virus-infected antigen-presenting cells of these three haplotypes, HLA-DR2 short, DRw11, and DRw13, are able to stimulate Ij cells. The same precise viral specificity is seen in all three cases. Proliferation inhibition experiments using HLA-specific monoclonal antibodies demonstrate that HLA-DR products are involved in all cases. However, according to the DR specificity of the antigen-presenting cell, differential blockings by a series of DR-specific monoclonal antibodies suggest that the functional epitope is shared by different HLA DR molecules. This is confirmed by two-dimensional gel analysis of the HLA DR chains expressed in the three haplotypes.Abbreviations used in this paper APC antigen-presenting cell - EBV Epstein-Barr virus - HA hemagglutinin - HLA human leukocyte antigens - IL-2 interleukin-2 - MHC major histocompatibility complex - MLR mixed lymphocyte reaction - mAb monoclonal antibody - PAGE polyacrylamide gel electrophoresis - PBM peripheral blood mononuclear cells - % RR relative response percent     

Antigen presentation by Hodgkin's disease cells

The L428 tumor cell line is a long-term tissue culture of Reed-Sternberg cells which was derived from the pleural effusion of a patient with Hodgkin's disease. The L428 cells express all known cell surface antigens, cytochemical staining, and cytologic features of freshly explanted Reed-Sternberg cells. In addition to the previously described HLA-DR cell surface antigens, the L428 cells are now demonstrated to express both DS and SB alloantigens. Thus, the L428 cells express all of the known subclasses of the human immune response genes that are located in the major histocompatibility complex. Furthermore, the L428 cells are capable of presenting soluble antigen to T cells in a genetically restricted fashion. T cell lines were established from normal donors previously immunized with tetanus toxoid. The T cells utilized were incapable of tetanus toxoid-induced proliferation unless antigen-presenting cells were added to the cultures. However, T cells from the two normal donors, which like the L428 cells expressed HLA-DR 5, demonstrated significant proliferative responses when cultured with tetanus toxoid and L428 cells. No proliferative response was observed when the L428 cells were used as antigen-presenting cells for a DR (4,-), DR (2,-) or DR (1,7) T cell line. The tetanus toxoid dose-response curve was similar regardless of whether autologous mononuclear leukocytes or L428 cells were used as antigen-presenting cells. The T cell proliferation induced by soluble antigen was also blocked by anti-HLA-DR antibody. Thus, functionally, Hodgkin's disease may be classified as a tumor of antigen-presenting cells.     

Cloned human cytotoxic T lymphocyte (CTL) lines reactive with autologous melanoma cells. I. In vitro generation, isolation, and analysis to phenotype and specificity

Activation of peripheral blood lymphocytes (PBL) from a melanoma patient either in secondary MLC in which EBV-transformed B cells from the cell line JY were used as stimulator cells, or by co-cultivation with the autologous melanoma cells in a mixed leukocyte tumor cell culture (MLTC) resulted in the generation of cytotoxic activity against the autologous melanoma (O-mel) cells. From these activated bulk cultures four cloned cytotoxic T lymphocyte (CTL) lines were isolated. The CTL clone O-1 (T3+, T4+, T8-, OKM-1-, HNK-, and HLA-DR+), and O-36 (T3+, T4-, T8+, OKM-, HNK-, and HLA-DR+) were obtained from MLC, whereas the CTLC clones O-C7 (T3+, T4+, T8-, OKM-1-, HNK-, and HLA-DR+) and O-D5 (T3+, T4-, T8+, OKM-1-, HNK, and HLA-DR+) were isolated from autologous MLTC. All four CTL clones were strongly cytotoxic for O-mel cells but failed to lyse autologous fibroblasts and autologous T lymphoblasts. Moreover, the CTL clones lacked NK activity as measured against K562 and Daudi cells. Panel studies indicated that the CTL clones also killed approximately 50% of the allogeneic melanoma cells preferentially, whereas the corresponding T lymphoblasts were not lysed. Monoclonal antibodies against class I (W6/32) and class II (279) MHC antigens failed to block the reactivity of the CTL clones against O-mel and allogeneic melanoma cells, indicating that a proportion of human melanoma cells share determinants that are different from HLA antigens and that are recognized by CTL clones. In contrast to the CTL clones isolated from MLTC, the clones obtained from MLC also lysed JY cells, which initially were used as stimulator cells. The reactivity of O-36 against JY could be inhibited with W6/32, demonstrating that this reactivity was directed against class I MHC antigens. These results suggest that the lysis of O-mel and JY cells by O-36 has to be attributed to two independent specificities of this CTL clone. The specificity of the other cross-reactive CTL clone (O-1) could not be determined. The notion that individual CTL clones can have two specificities was supported by the following observations. The cytotoxic reactivity of both O-1 (T4+) and O-36 (T8+) against JY was blocked by monoclonal antibodies directed against T3 and human LFA-1, and against T3, T8, and human LFA-1, respectively.(ABSTRACT TRUNCATED AT 400 WORDS)     

Biochemical and functional evidence that an MT3 supertypic determinant defined by a monoclonal antibody is carried on the DR molecule on HLA-DR7 cell lines

A cytotoxic monoclonal antibody, PL3, was produced by immunizing mice with a cell line homozygous for the HLA class II antigenic specificity DR7. The serologic specificity of PL3 was completely concordant with the MT3 supertypic specificity, which is tightly associated with HLA-DR4, -DR7, and -DRw9. This was confirmed by the finding that F(ab')2 fragments of PL3 blocked the cytotoxicity of anti-MT3 alloantisera. Although PL3 bound to each of the MT3-positive cell lines, it showed significantly weaker binding to HLA-DR4 and -DRw9 cells relative to -DR7 cells, both in titration and in quantitative absorption assays. This differential pattern of binding was not found for the polyclonal MT3 alloantisera, suggesting that the PL3 determinant may be one of several closely related determinants that comprise the MT3 allospecificity. To identify which of the subpopulations of class II molecules carry the PL3 determinant, several approaches have been used. F(ab')2 fragments of PL3 which block the anti-MT3 alloantisera were also tested with anti-MB2 and anti-DR7 sera. Binding of the PL3 F(ab')2 fragments to DR7 homozygous target cells had no effect on the anti-MB2 sera, but significantly enhanced the cytotoxic reactivity of some anti-DR7 sera. This finding suggested that the PL3 determinant is distinct from the DR7 determinant, but is carried on the same molecule. PL3 was also used in blocking studies with allocytotoxic T cell clones which only recognize DR7-positive cell lines. Binding of PL3 to the DR7-positive target cells was found to completely inhibit these T cell clones. Complete blocking was also found with a monoclonal antibody, PL8, which recognizes a monomorphic determinant found on the DR subpopulation of class II molecules. This finding suggested that the PL3 determinant is carried on the same molecule that carries these T cell-defined DR7 allodeterminants. In biochemical studies with DR7-positive cell lines, PL3 and PL8 were found to immunoprecipitate the same subpopulation of class II molecules recognized by other DR-specific antibodies, SG157 and TAL-1B5. Two-dimensional gel analysis demonstrated that the pattern of alpha- and beta-chains immunoprecipitated by PL3, PL8, and TAL-1B5 were identical. In sequential immunoprecipitation studies, both PL3 and TAL-1B5 were capable of removing the same DR subpopulation of molecules recognized by PL3, PL8, TAL-1B5, or SG157 while leaving the additional class II molecules (DS) recognized by SG171 on DR7 cells.(ABSTRACT TRUNCATED AT 400 WORDS)     

Characterization of cryopreserved human Langerhans cells

Epidermal Langerhans cells are potent antigen-presenting cells in the epidermis. The establishment of a cryopreservation method for human Langerhans cells would greatly contribute to our ability to successfully conduct various experiments dealing with Langerhans cells. Since Langerhans cells are known to be sensitive to cold injury, there have been no reports concerning the cryopreservation of Langerhans cells. We have investigated the effect of cryopreservation on the function and phenotype of human Langerhans cells. Langerhans cells from human foreskins were isolated with the immunomagnetic microbead method using monoclonal antibodies for CD1a. Langerhans cells were cryopreserved in the presence of dimethylsulfoxide (DMSO) 10% and fetal calf serum 90%. Cryopreserved Langerhans cells were phenotypically assessed by flowcytometry using monoclonal antibodies to HLA-DR and CD1a. The ultrastructures of the Langerhans cells were compared using electron microscopy. An autologous T cell stimulation test was performed to compare the functions of cryopreserved Langerhans cells and fresh Langerhans cells. The viability of the cryopreserved Langerhans cells was able to be maintained at more than 90%. Cryopreserved Langerhans cells expressed high levels of HLA-DR and CD1a antigens and stimulated autologous T cells to an extent almost identical to that obtained from fresh Langerhans cells. These findings indicate that the cryopreservation of human Langerhans cells could lead to a breakthrough in various experiments dealing with human Langerhans cells.     

Complexity of the supertypic HLA-DRw53 specificity: two distinct epitopes differentially expressed on one or all of the DR beta-chains depending on the HLA-DR allotype

The supertypic HLA-DRw53 specificity is associated with three allelic class II specificities defined by alloantisera: HLA-DR4, -DR7, and DRw9. The present study demonstrates the complexity of this supertypic DR specificity by comparing two DRw53-related determinants defined by the monoclonal antibodies PL3 and 109d6. For every HLA-DR4 cell line tested, both monoclonal antibodies were found to bind to the same subpopulation of DR molecules. This PL3+, 109d6+ DR subpopulation is also found on most, but not all, DR7+ cell lines with a beta-chain pattern that is identical to the beta-chain pattern of the PL3+, 109d6+ subpopulation on DR4 cell lines. However, some DR7+ cells which carry the HLA haplotype Bw57, DR7, DRw53, DQw3 were also found which completely lack the expression of the 109d6 determinant, but continue to express the PL3 determinant and some of the DRw53 determinants recognized by alloantisera. This results from the fact that the PL3 determinant is expressed on all of the DR molecules found on DR7 cells, including the distinct subpopulation of molecules that carry the HLA-DR7 determinant recognized by the monoclonal antibody SFR16-DR7. This PL3+, SFR16-DR7+ subpopulation does not carry the 109d6 determinant, demonstrating that the PL3 and 109d6 DRw53-related determinants are distinct and can be expressed on a different number of DR molecules, depending on the allotype of the cells. Blocking studies were also performed by using these monoclonal antibodies with alloreactive HLA-DR7-specific cytotoxic T cell clones. In these studies, the T cell-defined HLA-DR7 determinants were found to be carried by the same subpopulation of DR molecules recognized by the HLA-DR7-specific monoclonal antibody and not carried by the DR molecules recognized by 109d6. The DR7+ cell lines which do not express the 109d6 determinant also fail to express another supertypic determinant recognized by the monoclonal antibody IIIE3 carried on this molecule. Furthermore, no additional allelic forms of this unique DR beta-chain were found associated with the nonpolymorphic DR alpha-chain on these cells, suggesting that this DR beta-chain gene is not expressed. These cells also behave as homozygous typing cells for the Dw11 subtype of DR7 in HLA-D typing in the mixed lymphocyte culture assay. This suggests that the lack of expression of a specific class II gene may contribute additional genetic polymorphism within the known HLA-DR allotypes.     

HLA-DR antigens induce proliferation and cytotoxicity of T cells against haptenated (TNP and FITC) self structures

Antisera directed against the heavy, the light, or reactive against the complex of both chains of HLA-DR antigens strongly inhibited proliferation of T cells induced by TNP- or FITC-labeled autologous cells when added at initiation of the cultures, but not 72 h later. T cells from cultures treated with the anti-DR sera were unresponsive to interleukin-2 (IL-2). Nonetheless, the anti-DR sera did not inhibit proliferation of T cells that had already acquired sensitivity to IL-2. The DR antibodies abrogated the synthesis of IL-2 induced by both TNP- and FITC-conjugated autologous cells. Treatment of TNP- and FITC-labeled autologous cell cultures with the four different types of anti-DR sera significantly inhibited the induction of cytotoxic T cells. However, DR antibodies added at the effector phase of cytotoxicity assays did not inhibit the cytotoxic activity. Effector T cells from cultures treated with the anti-DR sera were unresponsive to IL-2 and addition of IL-2 to these cultures did not restore the cytotoxic activity. In contrast, effector T cells from cultures performed in the absence of the anti-DR sera proliferated to IL-2 stimulation and addition of IL-2 to these cultures significantly increased the generation of killer cells specific for hapten-labeled self structures. From these results we concluded the following: (1) Both the heavy and the light chains of DR antigens participate actively in the activation of T cells by rendering resting T cells sensitive to IL-2 and by inducing production of the growth factor in TNP- and FITC-conjugated autologous cell cultures. (2) The heavy and light chains of the DR antigens play an essential role in the induction of cytotoxic T cells specific for hapten-labeled self structures, most likely by enabling cytotoxic T cells to respond to IL-2 and by inducing the IL-2 producer T cells to synthesize the growth factor.     

DR antigen expression on ovarian carcinoma cells does not correlate with their capacity to elicit an autologous proliferative response

Summary Expression of HLA-DR antigens by purified preparations of human ovarian carcinoma cells freshly isolated from surgical specimens was examined in parallel with the capacity of tumor cells to elicit a blastogenic response from autologous lymphocytes in mixed lymphocyte-tumor culture (MLTC) assay. Of 21 tumor preparations, 11 (52%) reacted with monoclonal antibodies 279 and/or 949 specific for a monomorphic determinant of HLA-DR antigens, with heterogeneous positivity, ranging between 30% and 95%. In this series of patients positive MLTC occurred in 8/21 individual experiments. The HLA-DR expression was proportionally similar in tumors giving positive MLTC (4/8=50%) and negative MLTC (7/13=53%). The lack of correlation between DR expression on tumor cells and stimulatory activity in autologous MLTC and the fact that DR-negative tumors could induce lymphocyte stimulation, support the hypothesis that blastogenesis occurs upon recognition of tumor-associated antigens, different from DR molecules, possibly tumor-specific antigens.     

Establishment and functional characterization of human herpesvirus 6-specific CD4+ human T-cell clones.

In order to clarify the protective immune responses against a newly identified herpesvirus, human herpesvirus 6 (HHV-6), we established HHV-6-specific human T-cell clones and examined their functional properties. Five CD3+CD4+CD8- T-cell clones, which proliferated in response to stimulation with two different strains of HHV-6 in the presence of autologous antigen-presenting cells but not with herpes simplex virus type 1 or human cytomegalovirus, were established from peripheral blood lymphocytes of a healthy individual. The proliferative response of all T-cell clones to HHV-6 antigen was inhibited by addition of anti-HLA-DR monoclonal antibody, indicating that these clones were human leukocyte antigen (HLA) class II DR restricted. Of the five clones, two lysed HHV-6-infected autologous lymphoblasts, but not HHV-6-infected allogeneic cells or natural killer-sensitive K562 cells (group 1); one showed cytotoxicity against HHV-6-infected autologous lymphoblasts as well as HHV-6-infected allogeneic cells and K562 cells (group 2); and the remaining two showed no cytotoxic activity (group 3). The cytotoxic activity of group 1 was inhibited by addition of anti-HLA-DR monoclonal antibody to the culture, whereas this monoclonal antibody had no effect on the cytotoxicity of group 2 and did not induce the cytotoxicity of group 3. Perforin, which is one of the mediators of cytotoxicity, was abundantly expressed in group 1 and 2 clones. Moreover, all groups of clones produced gamma interferon after culture with antigen-presenting cells followed by HHV-6 antigen stimulation. These results suggest that HHV-6-specific CD4+ T cells have heterogeneous functions.     

Tumour-specific MHC-class-II-restricted responses after in vitro sensitization to synthetic peptides corresponding to gp100 and Annexin II eluted from melanoma cells

In a search for potentially tumour-specific MHC-class-II-restricted antigens, the immunogenicity of endogenous peptides that had been eluted from HLA-DR molecules of the human melanoma cell line FM3 (HLA-DRB1*02x, DRB1*0401) was tested in vitro. Two 16-mers representing gp100 positions 44–59, and annexin II positions 208–223 bound well to isolated DRB1*0401 molecules and are discussed here. HLA-DR-matched normal donors' T cells were cultured with peptide-pulsed artificial antigen-presenting cells (CHO cells cotransfected with genes for HLA-DRB1*0401 and CD80 and coexpressing high levels of both human molecules). Specific sensitization was achieved against both peptides, as measured in assays of autocrine proliferation and interleukin-2 secretion. Moreover, responses to native autologous melanoma cells but not to autologous B cells were also observed. In view of the expression of fas by the activated T cells and of fas ligand by the melanoma cells, blockade of potential fas/fas-ligand interactions was undertaken using monoclonal antibodies (mAb). The antagonistic fas-specific mAb M3, but not the fas agonist M33, caused a markedly enhanced T cell response to FM3 cells. These results demonstrate that synthetic peptide antigens are able to sensitize T cells in vitro for effective MHC-class-II-restricted recognition of melanoma cells. Received: 12 April 1998 / Accepted: 23 April 1998     

HLA-DR restriction in suppression of hematopoiesis by T cells from allogeneic bone marrow transplants

Three allogeneic bone marrow transplantation patients who exhibited a suppressive subset of T cells for in vitro hematopoiesis have been investigated to determine whether this T cell suppressive effect was genetically restricted. In the three cases, T cells separated by sheep red cell rosetting inhibited blood colony-forming units granulocyte-monocyte (CFU-GM) and burst-forming unit erythroid (BFU-E) growth from the patients and from the bone marrow donors who were HLA identical, but not from randomly chosen unrelated subjects. In one case, cocultures were performed between the patient T cells and the T-depleted cells from eight siblings and from the mother. A marked inhibition (30 to 60%) of CFU-GM and BFU-E growth was found in the relatives who shared a haplo-identical HLA-DR 5. The same degree of suppression was found with respect to whether the siblings were homozygous or heterozygous for the HLA-DR 5 antigen, and whether or not they shared common class I antigens. This inhibition was totally abolished when a monoclonal antibody against HLA-DR was added, whereas a monoclonal antibody against class I histocompatibility antigen had no effect. To additionally demonstrate that this inhibition was mediated by a single HLA-DR haplotype, T cells from the patient were co-cultured with cells from three normal unrelated individuals, one with a phenotypically identical DR and two with only one haploidentical DR. Inhibition was similarly found in the subject exhibiting complete DR identity, and the subject with only the DR 5 haploidentical phenotype. These results demonstrate that a unique subset of T cells present in allogeneic bone marrow transplants specifically suppress differentiation of hemopoietic progenitors that bear one phenotypically haplo-identical HLA-DR antigen.     

A human autoreactive T cell line specific for minor histocompatibility antigen(s) isolated from a bone marrow-grafted patient

A human autoreactive T cell line named Bur-1 has been obtained from a woman 4 mo after an allogeneic bone marrow transplantation (BMT) from one of her HLA-identical brothers. The phenotype of the cell line is 100% T11+ and over 90% T4+, and the karyotype confirms its donor (male) origin. These donor T cells proliferate specifically in the presence of donor's peripheral blood monocytes (PBM) but not recipient's cells, and they kill specifically donor's but not recipient's Epstein-Barr virus (EBV)-induced lymphoblastoid cell lines (LCL). PBM from another HLA-identical brother and from several unrelated donors also stimulate Bur-1 cells, and EBV-induced LCL from the same donors are killed in cytotoxicity assays. All of these donors share HLA-DR5 or HLA-DRw11 (the major split of HLA-DR5) with Bur-1 cells. However, some but not all of the PBM sharing HLA-DR5 with Bur-1 cells are recognized. Therefore, in contrast with the previously described autoreactive T cells, Bur-1 cells are not directed against self-MHC antigens but rather recognize autologous minor histocompatibility (mH) antigens in the context of autologous HLA class II molecules. Because both male and female cells can be recognized, the reacting minor antigen could not be the male-specific HY antigen. It is suggested that autoreactivity against mH antigens can be observed in bone marrow-grafted patients due to the education of bone marrow donor precursors in the recipient thymus not allowing tolerance to autologous (donor) mH antigens not shared by the recipient.     

T cell recognition of allopeptides in context of syngeneic MHC.

We have analyzed the ability of T cells to recognize peptides corresponding in sequence to an allogeneic HLA-DR molecule, in context of syngeneic MHC. PBMC from a responder with the HLA-DR beta 1*1101/DR beta 1*1201 genotype were stimulated in vitro with a mixture of four synthetic peptides derived from the first domain of the DR beta 1*0101 chain (amino acid residue 1-20, 21-42, 43-62, and 66-90). An alloreactive T cell line, TCL-LS, which proliferates only in response to peptide 21-42 presented by HLA-DR beta 1*1101, was obtained. The blastogenic response of the line was inhibited by anti-HLA-DR and CD4 antibodies but was not affected by antibodies to HLA-DQ, HLA-DP, HLA-ABC, and CD8. In the presence of irradiated, autologous APC, TCL-LS displayed specific proliferative responses to stimulating cells obtained from individuals carrying the DR beta 1*0101 allele. In the absence of autologous APC, TCL-LS recognized HLA-DR1 on allogeneic cells only when expressed together with HLA-DR beta 1*1101, the restrictive element. This indicates that TCL-LS recognizes processed HLA-DR1 molecule presented as nominal Ag. Study of TCR-V beta gene repertoire expressed by TCL-LS showed that only two V beta genes were used (V beta 13.2 and V beta 12). Two T cell clones (TCC) derived from this line, TCC-A5 and B4, exhibited a similar pattern of reactivity and expressed V beta 13.2. These results indicate that T cells recognizing peptides, which are derived from the breakdown of allogeneic MHC class II proteins and are presented by self-HLA-DR molecules, participate in allorecognition.