Fine specificity of HLA-B27 cellular allorecognition. HLA-B27f is a functional variant distinguishable by cytolytic T cell clones

Three HLA-B27 allospecific cytolytic T lymphocyte (CTL) clones were isolated by limiting dilution of HLA-B27-negative responder cells stimulated with HLA-B27.1-positive lymphoblastoid cells. These clones displayed three distinct reaction patterns when tested for their lytic ability against target cells expressing various structurally defined HLA-B27 subtypes. One of the clones was specific for HLA-B27.1; a second CTL clone reacted only with B27.1 and, less efficiently, with B27.2; the third clone recognized both B27.1 and B27f targets but not cells expressing any other B27 subtype. These results indicate that HLA-B27f is a functional variant amenable to differential recognition by alloreactive CTL. A correlation of the structure of the HLA-B27 subtypes with the reactivity of these clones revealed that multiple B27-specific alloreactive CTL are activated against epitopes of the HLA-B27.1 molecule sharing common structural features. This illustrates the complexity and fine specificity of the allogeneic CTL response against class I HLA antigens and suggests that their immunodominant regions are those which are capable of eliciting a diverse polyclonal response against each of these regions, rather than inducing the selective expansion of a single T cell clone.     

Molecular analysis of a functional subtype of HLA-B27. A possible evolutionary pathway for HLA-B27 polymorphism

The structure of a new HLA-B27 subtype antigen B27.4(B27D), distinguishable from the HLA-B27.1, B27.2, and B27.3 subtypes by cytolytic T lymphocytes and isoelectric focusing, has been established by comparative peptide mapping and sequence analysis. HLA-B27.4 differs from the main B27.1 subtype in the same two changes of aspartate-77 to serine-77 and valine-152 to glutamate-152, which distinguish the B27.1 and B27.3 subtypes. In addition, there are two other amino acid changes of histidine-114 to aspartate-114 and of aspartate-116 to tyrosine-116, which are unique to B27.4. The close structural relationship between B27.3 and B27.4 explains the similarity of these two subtypes in terms of T cell recognition. The presence of the two single amino acid differences between B27.3 and B27.4 within a span of three residues in the linear sequence provides a new example, suggesting that gene conversion-like mechanisms play a major role in the diversification of HLA-B27. A comparison of the structure of HLA-B27.4 with those of B27.1, B27.2, and B27.3 in the context of their ethnic distribution suggests that the diversification of the HLA-B27 antigens is an ongoing process that has continued after the separation of the major ethnic groups. A tentative evolutionary model for HLA-B27 polymorphism is proposed.     

Avidity dictates the lytic capacity of human cytolytic T lymphocyte clones with similar fine specificity against murine cells expressing HLA-B27 antigen

The role of the avidity of human CTL in the recognition and lysis of murine P815 cells expressing HLA-B27.1 Ag has been examined. Seven B27-specific alloreactive CTL clones were tested for their ability to lyse a B27.1+-P815 transfectant clone 1-7E, obtained after cotransfection of P815-HTR cells with HLA-B27.1 and human beta 2-microglobulin genes. The expression level of HLA-B27.1 on 1-7E cells was comparable to that on a human lymphoblastoid cell line, as determined by flow cytometry. Of the seven CTL clones used, CTL 1, 26, and 29 displayed the same fine specificity as established with a panel of target cells expressing six structurally different HLA-B27 variants. However, CTL 1 and 29 were of higher avidity than CTL 26, in that the lysis of human target cells by only this latter clone was inhibited by an anti-CD8 mAb. Based on the same criteria, CTL 2, 15, and 48 possessed the same or very similar fine specificity, but CTL 48 was of higher avidity than CTL 2 or 15. The seventh clone, CTL 40, was of a different fine specificity and its lysis of human target cells was also inhibited by the same anti-CD8 mAb. Only those clones whose lysis of human targets could not be inhibited by anti-CD8 antibody were able to lyse the 1-7E murine transfectants. These results indicate that, for human CTL clones with identical or very similar fine specificity, only those of higher avidity are able to lyse P815 murine cells expressing the HLA-B27 antigen. The lysis of HLA-B27.1+-murine transfectants by relevant clones was inhibited by anti-CD8 antibody. This result strongly suggests that the relative contribution of CD8 in stabilizing the interaction between human CTL and HLA-B27+-murine target cells is more significant than with human target cells.     

HLA-B27 antigenicity: antibodies against the chemically synthesized 63-84 peptide from HLA-B27.1 display alloantigenic specificity and discriminate among HLA-B27 subtypes

A chemically synthesized peptide with an amino acid sequence identical to that of the segment spanning residue 63-84 of the major HLA-B27.1 subtype antigen has been obtained. Specific antibodies were raised in rabbits against this peptide, coupled to keyhole limpet hemocyanin carrier. These antibodies lysed lymphoblastoid cell lines expressing HLA-B27.1 in a complement-mediated cytotoxicity assay. They lysed neither B27-negative target cells, nor B27-positive cells expressing other B27 subtype antigens. Complement-mediated lysis of B27.1-positive targets was inhibited by free peptide and by peptide coupled to an unrelated carrier. In addition, the lytic action of the rabbit antiserum was blocked by a monoclonal antibody with no complement-activating capacity that under the conditions of the assay, was specific for HLA-B27. These results indicate that rabbit antibodies against the 63-84 peptide recognize the native HLA-B27.1 antigen; this antiserum is allospecific in character; and it discriminates among B27 subtypes. Thus the data provide direct evidence on the contribution of the hypervariable region spanning residues 63-84 to the alloantigenic specificity of HLA-B27.     

Structural analysis of an HLA-B27 functional variant, B27d, detected in American blacks

The structure of a new functional variant B27d has been established by comparative peptide mapping and radiochemical sequencing. This analysis completes the structural characterization of the six known histocompatibility leukocyte antigen (HLA)-B27 subtypes. The only detected amino acid change between the main HLA-B27.1 subtype and B27d is that of Tyr59 to His59. Position 59 has not been previously found to vary among class I HLA or H-2 antigens. Such substitution accounts for the reported isoelectric focusing pattern of this variant. HLA-B27d is the only B27 variant found to differ from other subtypes by a single amino acid replacement. The nature of the change is compatible with its origin by a point mutation from HLA-B27.1. Because B27d was found only in American blacks and in no other ethnic groups, it is suggested that this variant originated as a result of a mutation of the B27.1 gene that occurred within the black population.     

Structural analysis of an HLA-B27 population variant, B27f. Multiple patterns of amino acid changes within a single polypeptide segment generate polymorphism in HLA-B27

The structure of a new HLA-B27 variant, B27f, distinguishable from other HLA-B27 subtypes by isoelectric focusing and serologic criteria, has been established by comparative peptide mapping and radiochemical sequence analysis. HLA-B27f differs from the major B27.1 subtype in three clustered amino acid replacements: Asp74, Asp77, and Leu81 in B27.1 are changed to Tyr74, Asn77, and Ala81, respectively in B27f. This pattern of differences is analogous to that of HLA-B27.2 in that this subtype also differs from B27.1 in multiple clustered substitutions within the same segment. Thus, polymorphism within the HLA-B27 system is being achieved by introducing different sets of amino acid changes within a particular short segment of the alpha 1 domain. The most likely mechanism for the introduction of multiple changes within this segment is a nonreciprocal recombination event, such as gene conversion. The structural analogies and ethnic distribution of B27f and B27.2 as compared with those of B27.3, and B27.4 support a dynamic model of HLA-B27 evolution in which polymorphism has been created after the separation of the major ethnic groups. In this model, a Caucasian branch would be characterized by subtypes differing from B27.1 in a few changes within the alpha 1 domain, which were probably generated by single genetic steps. An Oriental branch would include those subtypes which differ from B27.1 by changes in both alpha 1 and alpha 2, involving multiple genetic steps for their generation.     

Sharing of an HLA-B27-restricted H-Y antigen between rat and mouse

The purpose of this work was twofold: 1 to learn whether rats transgenic for HLA-B27 and the human ₂-microglobulin gene HB2M can mount B27-restricted cytolytic T lymphocyte (CTL) responses to the male H-Y antigen, and 2 to learn whether such CTLs would recognize both rat and mouse H-Y in the context of HLA-B27. Female rats of the B27/HB2M transgenic line 21-4L were primed in vivo with cells from males of the same line. CTL effectors were generated from lymph node cells of these females following culture with irradiated antigen-presenting cells from either male 21-4L rats or male mice of the B27/HB2M transgenic 56-3 line. The CTLs showed male-specific, B27-specific lysis of both rat and mouse targets. Lysis of B27 targets was inhibitable by monoclonal antibodies specific for B27 or rat CD8. Specific lysis of male B27 rat and mouse targets was inhibitable equally by either rat or mouse male B27 cold targets, but not significantly by female or nontransgenic cold targets. The B27-restricted CTLs neither recognized nor were inhibited by B27⁺ or B27^- male or female human targets. These results demonstrate that CD8⁺, B27-restricted, anti-H-Y CTLs recognize and evolutionarily conserved H-Y peptide antigen in both rats and mice. In addition, they establish the transgenic rat as a model system for examining the T-cell response to antigen presented by class I HLA molecules. Correspondence to: J. D. Taurog.     

Cloned Listeria monocytogenes specific non-MHC-restricted Lyt-2+ T cells with cytolytic and protective activity

Mice were infected with Listeria monocytogenes and Lyt-2+ T cell clones capable of lysing Ag-primed bone marrow macrophages were established. In accordance with earlier findings obtained at the population level, some T cell clones were identified which lysed bone marrow macrophages of different MHC type provided the relevant Ag was present. This unusual target cell recognition was further analyzed using a T3+, L3T4-, Lyt-2+, F23+, KJ16+ T cell clone, designated L-28. Target cell lysis by this clone was Ag specific, apparently non-MHC restricted. In contrast, YAC cells and P815 cells were not lysed by clone L-28. However, lysis of irrelevant targets could be induced by anti-T3, F23, or KJ16 mAb. Furthermore, Ag-specific lysis was blocked by anti-Lyt-2 mAb and by F(ab)2 fragments of F23 mAb. In addition to its cytolytic activity, clone L-28 produced IFN-gamma after co-stimulation with accessory cells, Ag, and rIL-2 and conferred significant protection on recipient mice when given together with rIL-2. These data suggest that non-MHC-restricted Lyt-2+ killer cells generated during listeriosis are cytolytic T lymphocytes that interact with their target Ag via the T cell receptor/T3 complex and the Lyt-2 molecule and, furthermore, that these cells play a role in anti-listerial resistance. The possible relevance of IFN-gamma secretion and target cell lysis for antibacterial protection is discussed.     

Preferential HLA usage in the influenza virus-specific CTL response

To study whether individual HLA class I alleles are used preferentially or equally in human virus-specific CTL responses, the contribution of individual HLA-A and -B alleles to the human influenza virus-specific CTL response was investigated. To this end, PBMC were obtained from three groups of HLA-A and -B identical blood donors and stimulated with influenza virus. In the virus-specific CD8(+) T cell population, the proportion of IFN-gamma- and TNF-alpha-producing cells, restricted by individual HLA-A and -B alleles, was determined using virus-infected C1R cells expressing a single HLA-A or -B allele for restimulation of these cells. In HLA-B*2705- and HLA-B*3501-positive individuals, these alleles were preferentially used in the influenza A virus-specific CTL response, while the contribution of HLA-B*0801 and HLA-A*0101 was minor in these donors. The magnitude of the HLA-B*0801-restricted response was even lower in the presence of HLA-B*2705. C1R cells expressing HLA-B*2705, HLA-A*0101, or HLA-A*0201 were preferentially lysed by virus-specific CD8(+) T cells. In contrast, the CTL response to influenza B virus was mainly directed toward HLA-B*0801-restricted epitopes. Thus, the preferential use of HLA alleles depended on the virus studied.     

The role of T8 in the cytotoxic activity of cloned cytotoxic T lymphocyte lines specific for class II and class I major histocompatibility complex antigens

It is reported here that most cytotoxic T lymphocytes (CTL), which recognize class I major histocompatibility complex (MHC) loci, express the T cell differentiation antigen T8. However, a minority of T8+ CTL clones was found to recognize class II MHC antigens. To test the hypothesis that T8 is involved only in T cell recognition of class I MHC antigens, we studied the role of T8 in the cytotoxic activity of class II MHC-specific CTL. Monoclonal antibodies specific for T8 blocked the activity of most class I MHC-specific CTL clones but did not affect the activity of class II MHC-specific CTL clones. Moreover, a mild trypsin treatment of the clones, which removed and T8 determinant, affected the activity of class I MHC but not that of class II MHC-specific CTL clones. These findings indicate that the class II-specific MHC CTL clones described here did not require T8 for their cytolytic activity. The activity of one T8+ class I MHC-specific (HLA-B27) CTL clone (HG-61) against the B cell line JY, which was used to raise this CTL clone, was not blocked by trypsin treatment of this clone. However, the activity of CTL clone HG-61 against target cells different from JY but carrying the appropriate HLA specificity was blocked by anti-T8 antibodies and trypsin treatment. The implications of these findings for the hypothesis that T8 is involved only in the activity of CTL with a relatively low avidity for class I MHC antigens are discussed.     

Activation of human cytolytic cells through CD2/T11. Comparison of the requirements for the induction and direction of lysis of tumor targets by T cells and NK cells

We studied the mechanisms whereby human T cells and NK cells are activated and directed to lyse tumor targets through the CD2 (T11/E-rosette) Ag. Using two cloned NK lines, we showed that these cells, as had previously been shown for T cells, could be directed to lyse an "NK-resistant" tumor target in the presence of antibody heterodimers. These heterodimers consisted of a (mAb) to CD2 (anti-T11(2) or anti-T11(3] linked to a mAb recognizing the tumor cell (J5, anti-CALLA). However, distinct differences between NK cells and T cells were observed with regard to the requirements for such directed lysis: first, only one epitope of CD2 on NK cells (either T11(2) or T11(3] needed to be recognized by the antibody heterodimer in order for directed lysis to occur, whereas for T cells both T11(2) and T11(3) epitopes had to be recognized. Second, in confirmation of previous data with monomeric anti-T11(2) or anti-T11(3) antibody, heterodimers constructed with these reagents enhanced conjugate formation between NK cells and tumor targets, whereas no such enhancement was seen with T cells. All types of heterodimer directed lysis were dependent on the adhesion molecule LFA-1, as an anti-LFA-1 antibody-blocked lysis. Third, whereas in T cells lysis mediated through CD2 appeared to be regulated by CD3 but not vice versa, all types of lysis by NK cells appeared to be regulated through CD2. Finally we showed that F(ab')2 fragments of the anti-T11(2) and anti-T11(3) antibodies could activate NK cells, but were unable to activate T cells either as cloned cytolytic lines, or in populations of PBL. The implications of our findings with regard to the role of CD2 in the activation of cytolytic cells is discussed.     

Lack of correlation between levels of MHC class I antigen and susceptibility to lysis of small cellular lung carcinoma (SCLC) by natural killer cells

Small cellular lung carcinoma (SCLC) cell lines are susceptible to lysis by NK cells. SCLC, normally negative for MHC class I Ag, were rendered positive for HLA-A and -B Ag by two methods: treatment with IFN-gamma or transfection with HLA class I genes. Exposure to IFN-gamma induced high levels of class I Ag and reduced susceptibility to NK-mediated lysis. However, transfection with either HLA-A2, HLA-B27, or HLA-B27 with beta 2m did not result in reduced susceptibility to NK cells. These transfectants expressed amounts of HLA class I Ag comparable to those in IFN-gamma-treated, untransfected cells. Transfection with the beta 2m gene or plasmid alone neither influenced levels of surface class I Ag nor resulted in reduced susceptibility to lysis by NK cells. Thus, the effects of IFN-gamma on NK susceptibility can be dissociated from the induction of class I Ag.     

The Magnitude and Specificity of Influenza A Virus-Specific Cytotoxic T-Lymphocyte Responses in Humans Is Related to HLA-A and -B Phenotype

The repertoire of human cytotoxic T-lymphocytes (CTL) in response to influenza A viruses has been shown to be directed towards multiple epitopes, with a dominant response to the HLA-A2-restricted M1(58-66) epitope. These studies, however, were performed with peripheral blood mononuclear cells (PBMC) of individuals selected randomly with respect to HLA phenotype or selected for the expression of one HLA allele without considering an influence of other HLA molecules. In addition, little information is available on the influence of HLA makeup on the overall CTL response against influenza viruses. Here, the influenza A virus-specific CTL response was investigated in groups of HLA-A and -B identical individuals. Between groups the individuals shared two or three of the four HLA-A and -B alleles. After in vitro stimulation of PBMC with influenza virus, the highest CTL activity was found in HLA-A2(+) donors. A similar pattern was observed for the precursor frequency of virus-specific CTL (CTLp) ex vivo, with a higher CTLp frequency in HLA-A2-positive donors than in HLA-A2-negative donors, which were unable to recognize the immunodominant M1(58-66) epitope. In addition, CTL activity and frequency of CTLp for the individual influenza virus epitopes were determined. The frequency of CTLp specific for the HLA-B8-restricted epitope NP(380-388) was threefold lower in HLA-B27-positive donors than in HLA-B27-negative donors. In addition, the frequency of CTLp specific for the HLA-A1-restricted epitope NP(44-52) was threefold higher in HLA-A1-, -A2-, -B8-, and -B35-positive donors than in other donors, which was confirmed by measuring the CTL activity in vitro. These findings indicate that the epitope specificity of the CTL response is related to the phenotype of the other HLA molecules. Furthermore, the magnitude of the influenza virus-specific CTL response seems dependent on the HLA-A and -B phenotypes.     

Multiple epitopes on human and murine cells expressing HLA-B7 as defined by specific murine cytotoxic T cell clones

Eleven cytotoxic T lymphocyte (CTL) clones were derived from C57BL/6 spleen cells immunized with HLA-B7 expressing human lymphoblastoid cell lines. Reactivity against HLA-B7 was initially established because the clones lysed 2 target cells that shared only HLA-B7 with the immunizing cell line and they did not lyse five other cell lines that were HLA-B7 negative but expressed other class I or class II antigens found on the immunizing cell. Six of the clones were subsequently shown to lyse all tested HLA-B7-positive B and T lymphoid cell lines, peripheral blood lymphocytes, and a murine L cell that expressed HLA-B7 as a consequence of DNA-mediated gene transfer. On the basis of the inability of the clones to lyse a panel of HLA-B7-negative cell lines, up to 18 other class I antigens could be eliminated as being cross-reactively recognized. However, two of the clones recognized a single HLA-B7-negative cell line. It is suggested that in these cases the clones were cross-reactively recognizing the HLA-B27 or HLA-B40 antigens that were present on these target cells. The remaining five CTL clones failed to lyse one out of seven tested HLA-B7-positive lymphoid lines (either RPMI-1788 or DR1B) and failed to lyse peripheral blood lymphocytes from one out of three tested HLA-B7-positive individuals. These five clones also did not recognize the HLA-B7-positive murine L cell. However, based on analysis with a large target cell panel, the reactivity pattern of these five clones could only be correlated with recognition of HLA-B7. This conclusion is further supported by antibody-blocking studies to be reported elsewhere. As before, lysis of single HLA-B7-negative target cells by two of the clones could be ascribed to recognition of HLA-B27 or HLA-B40. The results show that murine clones raised against HLA-B7 exhibit a high degree of specificity for determinants that are unique or largely confined to the HLA-B7 alloantigen. In addition, these clones define different antigenic determinants on the molecule. Thus, such clones appear to be excellent candidates for use as human tissue typing reagent. The results further show that there is a strong correlation between recognition of particular HLA-B7-positive human cell lines and recognition of the HLA-B7 expressing murine L cell. Possible reasons for such a correlation and their relationship to the general phenomenon of CTL recognition are discussed.     

Reaction of anti-HLA-B monoclonal antibodies with envelope proteins of Shigella species. Evidence for molecular mimicry in the spondyloarthropathies

Immunologic cross-reactivity between enteric bacteria and the HLA-B27 protein may play a role in the etiology of Reiter's syndrome and reactive arthritis. The reactivity of two anti-B27 mAb (B27M1 and B27M2) with envelope proteins of Shigella flexneri isolated from Reiter's syndrome patients was studied by Western blot analysis. Proteins with an apparent Mr of approximately 36 and 23 kDa reacted with both mAb in ascites. mAb against related HLA class I Ag B7 and B40 did not react with the 23 kDa protein. Relatively high concentrations of antibody were required for reactivity, suggesting a low affinity interaction. Additional evidence for cross-reactive epitopes was obtained by ELISA against whole envelope and by using unsolubilized envelope to inhibit binding of M1 and M2 to B27-positive cell lines, as measured by quantitative flow microfluorimetry. The presence of cross-reactive proteins was not related to the presence of the intact virulence-associated plasmid or the invasive phenotype. Two Shigella sonnei isolates not implicated as causative agents of Reiter's syndrome or reactive arthritis showed a similar pattern of cross-reactivity. These results indicate that cross-reactive epitopes may be present on "arthritogenic" bacteria, but their presence is not a unique feature of such strains and is not the sole factor in induction of arthritis in B27-positive individuals.     

Human T cells can be directed to lyse tumor targets through the alternative activation/T11-E rosette receptor pathway

We investigated the ability of human T cells to be directed to lyse murine and human tumor targets by antibodies (Ab) to the T11-E rosette (CD2) receptor. We found that the human cytotoxic T lymphocyte clone TBI-6, which is specific for the Epstein-Barr virus-transformed cell line, CM-EBV, could be directed to lyse the Fc receptor-positive murine tumor P388D1, by the combination of anti-T11(2) plus anti-T11(3) Ab. This activation and lysis was demonstrable only with an Fc receptor expressing tumor target and only with those Ab or with anti-T3 (CD3) Ab but not with other anti-T11 Ab or other Ab directed against surface structures on the clone. We therefore constructed heterodimeric Ab consisting of anti-T11(2) or anti-T11(3) Ab and the J5 anti-common acute lymphoblastic leukemic antigen (anti-CALLA) Ab. The purity and retained functional properties of the dimers were demonstrated by sodium dodecyl sulfate-polyacrylamide gels, fluorescence-activated cell sorter analysis on relevant cells, and by the ability of these conjugates to activate human peripheral blood lymphocytes to proliferate. These heterodimeric Ab conjugates were shown to be able to direct the lysis of CALLA+ targets by TBI-6. The specificity of this lysis was demonstrated by the inability of these heterodimers to direct the lysis of CALLA- targets by the cytotoxic T lymphocyte clone, and by the ability of excess free J5, but not an irrelevant Ab of the same isotype, to block this type of lysis. The potential clinical significance of these reagents is discussed.     

Susceptibility of cytotoxic T lymphocyte (CTL) clones to inhibition by anti-T3 and anti-T4 (but not anti-LFA-1) monoclonal antibodies varies with the "avidity" of CTL-target interaction

To explore the role of the T3, T4, and LFA-1 molecules in high and low "avidity" interactions between SB2-specific cytotoxic T lymphocyte (CTL) clones and their targets, monoclonal antibody-mediated inhibition of cytotoxicity has been studied in experiments that vary the "avidity" of interaction in three different ways. 1) Previous results have been extended with respect to different CTL clones assayed on the same SB2-positive target cells. Differences between clones in susceptibility to anti-T3 inhibition paralleled variations in anti-T4 inhibition, and both correlated inversely with the "avidity" of the effector-target interaction (inferred previously from studies of conjugate dissociation). 2) A high "avidity" clone, 8.4, was identified that lysed not only SB2-positive cells but also cross-reacted on a few SB2-negative cells. Cold target inhibition studies confirmed the cross-reaction, and together with conjugate dissociation studies, indicated that cross-reaction to be of lower "avidity" than the specific recognition of SB2. Cross-reactive lysis was much more susceptible to inhibition by anti-T3 and anti-T4 than was specific lysis. 3) Anti-T3 and anti-T4 blocking was analyzed in the presence of anti-Ia antibody to reduce the amount of Ia antigen available on the target. Anti-T3 and anti-T4 antibody blocking was more efficient after the addition of anti-Ia antibody concentrations that (by themselves) produced minimal inhibition of lysis. As a control, anti-LFA-1 antibody blocking was analyzed in each of these three experimental systems that compare interactions of different "avidity"; minimal variation was observed in the efficiency of inhibition by anti-LFA-1. Thus, anti-T3 and anti-T4 inhibition correlates inversely with the "avidity" of that CTL-target interaction, but anti-LFA-1 inhibition does not.     

Species-restricted recognition of transfected HLA-A2 and HLA-B7 by human CTL clones

Human cytolytic T lymphocytes (CTL) clones and HLA-A2- and HLA-B7-transfected human, monkey, and mouse cell lines were used to investigate the basis for species-restricted antigen recognition. Most allospecific CTL clones obtained after stimulation with the human JY cell line (source of HLA-A2 and HLA-B7 genomic clones) recognized HLA antigens expressed in human and monkey cell lines but did not recognize HLA expressed in murine cells. By initially stimulating the responder cells with HLA-transfected mouse cells, two CTL clones were obtained that recognized HLA expressed in murine cells. Functional inhibition of these CTL clones with anti-class I monoclonal antibodies (MAb) indicated that clones reactive with HLA+ murine cells were of higher avidity than clones that did not recognize HLA+ murine target cells. MAb inhibition of accessory molecule interactions demonstrated that the LFA-1 and T8 surface molecules were involved in CTL-target cell interactions in all three species. In contrast, the LFA-2/CD2 molecule, previously shown to participate in a distinct activation pathway, was involved in the cytolysis of transfected human and monkey target cells, but not in the lysis of HLA+ murine cells. Thus transfection of HLA genes into different recipient species cell lines provides us with the ability to additionally delineate the functional requirements for allospecific CTL recognition and lysis.     

Physical and functional association of the T cell receptor and the T3 molecular complex on cytotoxic T cell clones that are differentially inhibitable by anti-T3 antibodies

To examine the hypothesis that the antigen-specific T cell receptor (TcR) can function independently from the T3 complex on cytolytic T lymphocyte (CTL) clones, the physical and functional association of the T3 molecular complex and the T cell receptor has been examined on CTL clones that are differentially susceptible to inhibition by anti-T3 antibodies. From a panel of nine DPw2-specific CTL clones derived from the same donor, two clones (8.4 and 8.8) that were the most disparate in their susceptibility to inhibition by anti-T3 antibody were chosen for study. No significant differences were found between 8.4 and 8.8 for: (1) the levels of cell surface expression of the T3 complex and the TcR; (2) the ability to modulate T3 cell surface molecules; and (3) the capacity of the TcR to comodulate with the T3 complex. Modulation of the T3 complex from clone 8.4 did not significantly affect cytolytic activity, and incubation of modulated 8.4 with additional anti-T3 antibody did not inhibit cytolytic activity. Although no T3 function for clone 8.4 could be demonstrated by simply blocking cytolytic activity with anti-T3 antibody, addition of limiting quantities of anti-T11 (but not anti-T4, anti-Tac, or anti-LFA-1) antibodies plus anti-T3 produced a marked synergistic inhibition of cytolysis. These results suggest that: (1) CTL clones that are resistant to inhibition by anti-T3 antibodies actually have a physical and functional association between the T3 complex and the TcR; and (2) the ability to demonstrate a functional role for T3 by antibody blocking may, in some cases, require limiting the involvement of the T11 molecule in CTL-target interactions. The most likely explanation for the observed heterogeneity in susceptibility to blocking by anti-T3 antibodies is, therefore, thought to be that individual CTL clones possess TcR with differential avidity for specific targets.     

Recognition of HLA-B27 by mouse cytotoxic T-cell clones: a transgenic mouse

As a basis for the characterization of mouse T cells involved in the recognition of xenogeneic HLA molecules, a panel of HLA-B27-reactive cytotoxic T-cell clones was generated upon stimulation by cells from HLA-B27-transgenic mice. The HLA-B27-induced T-cell response was found to comprise two categories of clones: some recognizing HLA-B27 independent of H-2 molecules expressed by the target cells (unrestricted clones), others recognizing HLA-B27 in an H-2 restricted manner. The unrestricted clones exhibited diverse specificities, as judged from their various cross-reactivities with other xenogeneic (HLA) or allogeneic (H-2) molecules. In addition, although most of the unrestricted clones were able to react with both mouse and human HLA-B27-transgenic mice. The HLA-B27 induced T-cell which reacted only with HLA-B27-positive mouse, and not human cells. These findings illustrate that both H-2-restricted and unrestricted T cells with diverse species contribute to HLA-B27-xenorecognition.