Reactivity patterns with HLA-A2 variants indicate lack of identity between determinants defined by monoclonal antibodies and cytotoxic-T-cell clones

The anti-HLA-A2 monoclonal antibodies (MoAb) CR11-351 and 4B inhibit the binding of each other to HLA-A2 lymphoid cells and block the cytotoxicity of the anti-HLA-A2 cytotoxic-T-cell clone R32. The blocking does not reflect reactivity of the MoAb CR11-351 and 4B and of the cytotoxic-T-cell clone R32 with the same determinant, since they display differential reactivity with four HLA-A2 variants which carry amino acid substitutions at different positions. These results show for the first time in the human system that Class I HLA variants represent useful reagents to compare the fine specificities of monoclonal antibodies and T-cell clones. Furthermore our data suggest that T-cell recognition depends upon the tertiary structure of the antigen.     

Syngeneic anti-idiotypic antisera to murine monoclonal antibodies to monomorphic and polymorphic determinants of HLA class I antigens

BALB/c mice were immunized with syngeneic anti-HLA class I monoclonal antibodies. The latter included the anti-HLA-A2, A28 monoclonal antibody (MoAb) CR11-351, the MoAb Q6/64 to a determinant restricted to HLA-B antigens and the MoAb CR10-215 and CR11-115 to the same (or spatially close) monomorphic determinant. Anti-idiotypic antibodies could be detected in bleedings obtained 3 days after the first booster, increased in titer in bleedings obtained after the second booster, and persisted at high levels in subsequent bleedings. The four anti-HLA class I MoAb did not differ in their ability to elicit syngeneic anti-idiotypic antibodies. Cross-blocking studies with a panel of anti-HLA class I, anti-HLA class II, and anti-human melanoma-associated antigen (MAA) MoAb showed that the anti-MoAb CR10-215 and anti-MoAb CR11-115 antisera contain only antibodies to private idiotopes, whereas the anti-HLA MoAb CR11-351 and anti-MoAb Q6/64 antisera also contain antibodies to public idiotopes. The latter are expressed by the anti-HLA class I MoAb CR11-351, Q1/28, Q6/64, and 6/31, and by the anti-HLA class II MoAb Q5/6, Q5/13, 127, and 441. Public idiotopes were not detected on the nine anti-MAA MoAb tested. Public idiotopes do not interfere with the binding of anti-HLA MoAb with the corresponding antigenic determinants. On the other hand private idiotopes are located within the antigen-combining site, because anti-idiotypic antisera specifically inhibit the binding of the corresponding immunizing anti-HLA class I MoAb to cultured human lymphoid cells in a dose-dependent manner. Analysis by isoelectric focusing of the anti-HLA class I MoAb antisera showed that the spectrotype of the anti-MoAb CR11-351 antiserum comprises four components that focus in the pH 6.9 to 6.2 range, the spectrotype of anti-MoAb Q6/64 antiserum comprises three components that focus in the pH 6.5 to 6.1 range, the spectrotype of the anti-MoAb CR10-215 antiserum comprises three components that focus in the pH 6.4 to 6.1 range, and the spectrotype of the anti-MoAb CR11-115 antiserum comprises three components that focus in the pH 6.6 to 6.4 range.     

Lack of a role of monocytes in the inhibition by monoclonal antibodies to monomorphic and polymorphic determinants of HLA class I antigens of PHA-P-induced peripheral blood mononuclear cell proliferation

This study aimed at characterizing the mechanism(s) underlying the regulatory role of distinct determinants of HLA Class I antigens in PHA-P-induced T cell proliferation and the involvement of monocytes in this phenomenon. The anti-HLA-A2,A28 monoclonal antibodies (MoAb) CR11-351, the MoAb Q6/64 to a determinant restricted to the gene products of the I antigens HLA-B locus, and the MoAb CR10-215 and W6/32 to distinct monomorphic determinants of HLA Class I antigens were found to inhibit PHA-P-induced peripheral blood mononuclear cell (PBMC) proliferation in a dose-dependent fashion. The inhibition is specific and reflects neither inhibition of PHA-P binding to cells nor a toxic effect of the anti-HLA Class I MoAb. The latter differed in the concentration required to induce inhibition, in the influence of the concentration of PHA-P used as mitogen, in the differential effect on the donors used as a source of PBMC, and/or in the requirement of the Fc portion to induce inhibition. At variance with the information in the literature, the inhibitory effect of anti-HLA Class I MoAb on PHA-P-induced PBMC proliferation neither reflected their interaction with accessory cells nor was mediated by suppressor factors released by monocytes stimulated with PHA-P in the presence of anti-HLA Class I MoAb. Therefore, the regulatory role of HLA Class I antigens in T cell proliferation is not likely to be mediated by monocytes and/or factors released from them, but may reflect an involvement of these molecules in T cell activation pathways.     

Regulatory role of a monomorphic determinant of HLA Class I antigens in T cell proliferation

The role of HLA Class I antigens in T cell proliferation was investigated by using the anti-HLA Class I monoclonal antibodies (MoAb) CR10-215, CR10-325, and CR11-115. MoAb CR10-215 and CR11-115 recognize the same (or spatially close) monomorphic determinant, which is distinct and spatially distant from that reacting with MoAb CR10-325. Addition of MoAb CR10-215 and CR11-115 to cultures of peripheral blood mononuclear cells stimulated with MoAb OKT3, MoAb Pan T2, PHA, or PPD inhibited cell proliferation. The blocking is specific in that the anti-HLA Class I MoAb CR10-325 and the Pan T MoAb Pan T1 had no effect on the proliferation. The inhibitory activity of MoAb CR10-215 and CR11-115 does not reflect i) toxic effects, ii) induction of suppressor cells and factors, iii) blocking of the binding of mitogens to lymphocytes, iv) inhibition of the production of interleukin 1 (IL 1) and interleukin 2 (IL 2), or v) function of IL 2 receptor. Anti-HLA Class I MoAb were able to inhibit the proliferation of purified, Tac-, T cells. The inhibited cells did not express Tac antigen, as assayed by direct immunofluorescence, with MoAb anti-Tac, but released a normal amount of IL 2 in culture medium. These results indicate that monomorphic determinants of the HLA Class I complex are involved in the regulation of T cell proliferation. The effect appears to occur at the level of IL 2 receptor expression.     

Differential regulatory role of monomorphic and polymorphic determinants of histocompatibility leukocyte antigen class I antigens in monoclonal antibody OKT3-induced T cell proliferation

Monoclonal antibodies (mAb) to monomorphic and polymorphic determinants on the heavy chain of histocompatibility leukocyte antigen (HLA) class I antigens inhibit mAb OKT3-induced T cell proliferation, whereas the anti-beta 2-microglobulin mAb NAMB-1 does not affect it. The inhibitory effect of anti-HLA class I mAb is specific, is not an Fc-mediated phenomenon, does not require accessory cells, and does not involve early stages of T cell activation. Distinct determinants of HLA class I antigens regulate T cell proliferation by different mechanisms, because the anti-HLA-A2, A28 mAb CR11-351, and the mAb W6/32 to a framework determinant of HLA class I antigens block interleukin 2 (IL-2) secretion and IL-2 receptor expression, whereas the mAb CR10-215 to a monomorphic determinant blocks only IL-2 receptor expression. The mAb CR10-215 and W6/32 induced a 50% of maximal inhibition of T cell proliferation, when added after 27 and 12 hr, respectively, of incubation of peripheral blood mononuclear cells with mAb OKT3. On the other hand, the mAb CR11-351 inhibited T cell proliferation even when added after 38 hr of incubation of peripheral blood mononuclear cells with mAb OKT3 and was the only one to inhibit proliferation of cycling T lymphocytes. It is suggested that HLA class I antigens regulate T cell proliferation by interacting with cell-surface molecules involved in T cell activation. The differential inhibitory activity of the anti-HLA class I monoclonal antibodies tested may reflect the different ability of the corresponding determinants to interact with activation molecules.     

Enhancing effect of anti-HLA class I monoclonal antibodies on T cell proliferation induced via CD2 molecule

The mAb 131 to a determinant preferentially expressed on the gene products of the HLA-A locus, the mAb Q6/64 and 4E to determinants preferentially expressed on the gene products of the HLA-B locus, the anti-HLA-A2,A28 mAb CR11-351, HO-2, HO-3, HO-4, and KS1, and the anti-HLA-B7 cross-reacting group mAb KS4 enhanced proliferation of T cells in most, if not all, the PBMC preparations stimulated with the anti-CD2 mAb 9-1 + 9.6. The mAb CR10-215, W6/32, and 6/31 to distinct monomorphic determinants of HLA class I antigens enhanced CD2-induced T cell proliferation in at most 30% of the PBMC preparations tested. The anti human beta 2-microglobulin (beta 2-mu) mAb NAMB-1 displayed no detectable effect on the proliferation of T cells stimulated with the mAb 9-1 + 9.6. The enhancing effect of anti-HLA class I mAb is specific, is dose dependent, is not abrogated by the addition of exogenous IL-1 and IL-2 to the cultures, and reflects the interaction of anti-HLA class I mAb with T cells. Enhancement of CD2 mediated proliferation of T cells is not a unique property of anti-HLA class I mAb, since the anti-HLA class II mAb Q5/6 and Q5/13 also had a similar effect. Analysis of the kinetics of the enhancing effect of anti-HLA class I mAb suggests that they modulate an early event of T cell activation and may affect the interaction of T cells with mAb 9-1. Phenotyping of T lymphocytes activated by mAb 9-1 + 9.6 in the presence of anti-HLA class I mAb suggests that the enhancing effect of anti-HLA class I mAb may reflect the recruitment of a higher percentage of T cells. The present study has shown for the first time that certain, but not all, the determinants of the HLA class I molecular complex are involved in the proliferation of T cells stimulated with the anti-CD2 mAb 9-1 + 9.6. Furthermore, the inhibitory effect of mAb CR11-351, KS1, Q6/64, and W6/32 on the proliferation of T cells stimulated with mAb OKT3 or with mAb BMA 031 indicates that the same determinants of HLA class I antigens play a differential regulatory role in T cell proliferation induced via the CD2 and CD3 pathway.     

Serological expression after sequential double transfection with purified HLA-11 gene of mouse fibroblasts carrying human beta-2 microglobulin

A genomic cosmid library constructed from DNA from a genotyped individual (JF = HLA-A11, Cw–, B38/A26, Cw7, B51) was screened for clones containing class I histocompatibility genes. Among these clones, one was found to carry a 4.8 kb Hind III fragment which is highly correlated with HLA-A11. This clone was used to transfect LMTK⁺ cultured mouse fibroblast transformants expressing human beta-2 microglobulin. The human beta-2 microglobulin heavy chain-associated determinant was positively detected by the M18 monoclonal antibody. HLA-A11 expression on these doubly transformed cells was specifically demonstrated by complement-dependent cytotoxicity with HLA-A11 + A3-specific but not with HLA-A3-specific monoclonal antibodies. Absorption studies with human alloantisera confirmed the presence on these cells of HLA-A11 determinants and of cross-reacting determinants which absorbed anti-HLA-A1 and –A3 alloantisera. The JF5-J27 transfected cell expressed both heavy and light chains of human class I histocompatibility genes.Abbreviations used in this paper ₂m beta-2 microglobulin - CTL cytolytic T lymphocytes - FCS fetal calf serum - HAT hypoxanthine-azaguanine-thymidine - kb kilobase pair - MHC major histocompatibility complex - MoAb monoclonal antibodies - PBL peripheral blood lymphocytes - PEG polyethylene glycol - r correlation coefficient This study is dedicated to the memory of Jean-Jacques Metzger.     

Antibody-induced association between discrete regions of HLA class I and II antigens

The anti-HLA-DR + DP monoclonal antibody (MoAb) CR11-462 was unexpectedly found to cross-inhibit the binding to B lymphoid cells of the anti-HLA Class I MoAb CR10-215 and CR11-115. The latter two antibodies recognized the same or spatially close antigenic determinant. The cross-blocking of anti-HLA Class I MoAb CR10-215 and CR11-115 by MoAb CR11-462 reflects neither its contamination by anti-HLA Class I antibodies nor its cross-reactivity with HLA Class I antigens. On the other hand, the cross-blocking appears to reflect redistribution of HLA Class II antigens by the MoAb CR11-462, since the MoAb CR10-215 and CR11-115 are not susceptible to blocking when lymphoid cells are treated with 0.025% glutaraldehyde or are coated with Fab' fragments of the MoAb CR11-462. Furthermore, immunoprecipitates from B lymphoid cells preincubated with the MoAb CR11-462 before solubilization contain HLA Class I antigens. Therefore, these results have shown for the first time an antibody-induced association between discrete regions of HLA Class I and Class II antigens on the membrane of B lymphoid cells.     

The free and the β2-microglobulin-associated heavy chains of HLA-A,B alloantigens share the antigenic determinant recognized by the monoclonal antibody Q1/28

Serological and immunochemical assays have shown that the monoclonal antibody Q1/28 recognizes an antigenic determinant which is expressed on the heavy chain of subsets of HLA-A, B antigens and is distinct from those defining the serological polymorphism of this system. Association of the HLA-A, B heavy chain with ₂-microglobulin is not required for expression of the antigenic determinant recognized by the monoclonal antibody Q1/28, since this antibody can immunoprecipitate a 45 000 m. w. component from radiolabeled lymphoid-cell glycoproteins immunodepleted with either an anti-human ₂-microglobulin xenoantiserum or the MoAb W6/32 to framework determinants of HLA-A, B, C antigens. Furthermore, the MoAb Q1/28 can immunoprecipitate a 45 000 m. w. component from an NP40lysate of radiolabeled Daudi cells, which lack the genetic information for ₂-microglobulin. The determinant recognized by the MoAb Q1/28 is relatively resistant to denaturing treatments and does not appear to be carbohydrate in nature. The MoAb Q1/28 is the first example of an antibody which recognizes an antigenic determinant expressed on both the ₂-microglobulin-associated and free HLA-A, B heavy chains.     

Clonal T lymphocyte recognition of the fine structure of the HLA-A2 molecule

A human alloimmune cytotoxic T lymphocyte (CTL) clone (4E4) was generated against the HLA-A2 molecule. Lysis of 51Cr-labeled HLA-A2 target cells was blocked by monoclonal antibodies (mAb), including mAb PA2.1 (anti-HLA-A2), mAb BB7.2 (anti-HLA-A2), mAb 4B (anti-HLA-A2-plus-A28), mAb MA2.1 (anti-HLA-A2-plus-B17), and mAb W6/32 (anti-HLA-A,B,C), which are directed against different serologic epitopes on the HLA-A2 molecule. However, HLA-A2 mutant lines lacking the serologic epitope recognized by mAb BB7.2 (anti-HLA-A2) were efficiently lysed by CTL 4E4. Thus, although mAb may block cytolysis, the HLA-A2 epitope recognized the 4E4 CTL clone is distinct from the HLA-A2-specific epitope recognized by serologic reagents. Moreover, analysis of HLA-A2 population variants revealed that only the predominant HLA-A2.1 subtype molecule was recognized by CTL 4E4. No cross-reactivity on other, biochemically related HLA-A2 population subtypes was observed, including HLA-A2.2 cells (Hill, CVE, ZYL, M7), HLA-A2.3 cells (TENJ, DK1), or HLA-A2.4 cells (CLA, KNE). This CTL clone appears to recognize a single epitope and, like monoclonal antibody counterparts, can be used to discriminate among immunogenic cellular and serologic epitopes on closely related HLA-A2 molecules. On the basis of the known sequence changes in mutant and subtype HLA-A2 molecules, it appears that the sequence spanning residues 147 to 157 may be critical for cellular recognition of this Class I MHC molecule.     

HLA-DR antigens and mitogenic factors released by PWM-stimulated T lymphocytes share the framework determinant recognized by the monoclonal antibody Q5/13

Human T lymphocytes release factors which enhance the mitogenic response of B lymphocytes to PWM. These mitogenic factors share with HLA-DR antigens the framework determinant recognized by the monoclonal antibody Q5/13 (MoAb Q5/13) since adsorption of T-cell medium with an excess of insolubilized MoAb Q5/13 significantly reduces the enhancing activity of the T-cell supernatant on the proliferative response of B cells to PWM. On the other hand, incubation of the T-cell supernatant with an excess of insolubilized anti-HLA-A,B MoAb Q1/28 did not effect the activity of the T-cell supernatant in the proliferative assay.     

Syngeneic anti-idiotypic antisera to murine anti-HLA class II monoclonal antibodies

BALB/c mice have been immunized with six anti-HLA Class II monoclonal antibodies (MoAb); the latter included MoAb CR11-462, Q5/6, and Q5/13 to monomorphic determinants, the anti-HLA-DR1,4,w6,w8,w9 MoAb AC1.59, the anti-HLA-DRw9 MoAb AB7ae9, and the anti-HLA-DQw3 MoAb AC6G. The six monoclonal antibodies markedly differ in their ability to induce anti-idiotypic antibodies, because the latter were not detected in the sera from the mice immunized with the MoAb AB7ae9 and with the MoAb AC6G. The MoAb AC1.59 and CR11-462 elicited antibodies to private idiotypes, and the MoAb Q5/6 and Q5/13 elicited antibodies to private and public idiotypes. The titer of the latter in the anti-MoAb Q5/6 antiserum appears to be markedly lower than that of the former ones; no marked difference was detected in the titer of the two types of antibodies in the anti-MoAb Q5/13 antiserum. Blocking experiments with a panel of monoclonal antibodies showed that the MoAb Q5/13 shares idiotypes with the anti-HLA Class I MoAb Q5/6, 127, and 441 and with the anti-HLA Class I MoAb CR11-351, Q1/28, Q6/64, and 6/31, but does not share idiotypes with any of the nine anti-human melanoma-associated antigen MoAb tested. The spectrotypes of the anti-MoAb CR11-462 and anti-MoAb Q5/13 antisera comprise two major components in the pH 6.2 to 6.7 range, that of the anti-MoAb Q5/6 antiserum comprises two major components in the pH 6.5 to 6.8 range, and that of the anti-MoAb AC1.59 antiserum comprises a number of components in the pH 5.6 to 7.2 range.     

Comparison of one-dimensional IEF patterns for serologically detectable HLA-A and B allotypes

A new mouse monoclonal antibody (MoAb) 4E, which detects an epitope shared by HLA-B locus antigens, together with the MoAb W6/32, detecting a common HLA, B, C, determinant, and the MoAb 4B, detecting HLA-A2 and A28, were used to isolate HLA-A and -B antigens in sequential immunoprecipitation. The HLA antigens obtained from metabolically labeled cell extracts of B-lymphoblastoid cell lines or from phytohemagglutinin (PHA) activated peripheral blood lymphocytes were compared by one-dimensional isoelectric focusing (1D-IEF). The IEF banding patterns obtained with native HLA antigens segregated in a family with HLA. Neuraminidase treatment of isolated antigens reduced the number of bands to one or two, simplifying the analysis of characteristic patterns. Thus, we have cataloged IEF banding patterns for the majority of the serologically recognized HLA-A and -B allotypes obtained from 57 unrelated American Caucasians. While no HLA-A locus or HLA-B locus specific banding patterns were observed, the HLA-A antigens had, in general, slightly higher pl values than the HLA-B antigens. HLA-C antigens could not be detected in this assay system. The polymorphism detected by IEF banding patterns was as extensive as the serologically detected polymorphism identified by classical HLA serology. Moreover, variants for some HLA allotypes could be detected by this method. In addition to previously recognized A2 variants, new variants were identified for HLA-A1, A26, and Bw44. Each A1 and Bw44 variant was associated with particular haplotypes. The HLA-A2 antigens occurred on 43 HLA haplotypes in the unrelated Caucasian population. Only one of each A2 variants was identified in this population.     

Identification by site-directed mutagenesis of amino acid residues contributing to serologic and CTL-defined epitope differences between HLA-A2.1 and HLA-A2.3

Site-directed mutagenesis of HLA-A2.1 has been used to identify the amino acid substitutions in HLA-A2.3 that are responsible for the lack of recognition of the latter molecule by the HLA-A2/A28 specific antibody, CR11-351, and by HLA-A2.1 specific CTL. Three genes were constructed that encoded HLA-A2 derivatives containing one of the amino acids known to occur in HLA-A2.3: Thr for Ala149, Glu for Val152, and Trp for Leu156. Three additional genes were constructed that encoded the different possible combinations of two amino acid substitutions at these residues. Finally, a gene encoding all three substitutions and equivalent to HLA-A2.3 was constructed. These genes were transfected into the class I negative, human cell line Hmy2.C1R. Analysis of this panel of cells revealed that recognition by the antibody CR11-351 was completely lost when Thr was substituted for Ala149, whereas substitutions at amino acids 152 and 156, either singly or in combination, had no effect on the binding of this antibody. The epitopes recognized by the allogeneic and xenogeneic HLA-A2.1 specific CTL clones used in this study were all affected by either one or two amino acid substitutions. Of those epitopes sensitive to single amino acid changes, none were affected by the substitution of Thr for Ala149, whereas all of them were affected by at least one of the substitutions of Glu for Val 152 or Trp for Leu156. Overall, amino acid residue 152 exerted a stronger effect on the epitopes recognized by HLA-A2.1 specific CTL than did residue 156. Of those epitopes affected only by multiple amino acid substitutions, double substitutions at residues 149 and 152 or at 152 and 156 resulted in a loss of recognition, whereas a mutant with substitutions at residues 149 and 156 was recognized normally. This reemphasizes the importance of residue 152 and indicates that residue 149 can affect epitope formation in conjunction with another amino acid substitution. These results are discussed in the context of current models for the recognition of alloantigens and in light of the recently published three-dimensional structure of the HLA-A2.1 molecule.     

Role of HLA class I and class II antigens in activation and differentiation of B cells

The monoclonal antibodies (MoAb) CR10-214, CR11-115, and Q1/28 to distinct monomorphic determinants of HLA class I antigens, the MoAb CL413 and PTF29.12 recognizing monomorphic determinants of HLA-DR antigens, the anti-HLA-DQw1 MoAb KS11, the anti-HLA-DPw1 MoAb B7/21, and the anti-HLA-DR,DP MoAb CR11-462 were tested for their ability to modulate human B-lymphocyte proliferation and maturation to IgM-forming cells. Purified tonsillar B cells were stimulated with Staphylococcus aureus bacteria of the Cowan first strain (SAC) or anti-human mu-chain xenoantibodies, as well as in growth factor- or T-cell-dependent activation cultures. The B-cell proliferative responses induced by SAC or by mitogenic concentrations of anti-mu-chain xenoantibodies were inhibited by some of the anti-HLA class I and anti-HLA class II monoclonal antibodies tested. The same antibodies were effective inhibitors of the proliferation of B cells stimulated with interferon-gamma (IFN-gamma) or interleukin-2 (IL-2) and with submitogenic concentrations of anti-mu-chain xenoantibodies. The proliferation induced by IL-2 of SAC-preactivated B cells was inhibited by some of the anti-HLA class II monoclonal antibodies, but not by the anti-HLA class I monoclonal antibodies tested. This inhibition appeared to reflect at least in part a direct effect on later events of the B-cell activation cascade, since some anti-HLA class II monoclonal antibodies still exerted considerable inhibitory activity when added together with IL-2 to SAC-preactivated B cells after the third day of culture. Anti HLA-DR, DQ, and DP monoclonal antibodies consistently inhibited the IgM production induced in B cells by T cells alone, T cells plus pokeweed mitogen (PWM), SAC plus IL-2, or IL-2 alone. In contrast, two of the three anti-HLA class I monoclonal antibodies tested inhibited the IgM production in cultures stimulated with SAC plus IL-2 and one the IgM production induced by IL-2 alone, but none of them had inhibitory effects on T-cell dependent IgM production. The results reported herein indicate that HLA class II molecules directly participate in different phases of the B-cell activation cascade. In addition, our data also suggest that HLA class I molecules can be involved in the events leading to B-cell proliferation and differentiation into immunoglobulin-secreting cells.     

Structural and functional analysis of monomorphic determinants recognized by monoclonal antibodies reacting with the HLA class I alpha 3 domain.

To identify mAb reacting with the HLA class I alpha 3 domain, 14 mAb recognizing monomorphic determinants expressed on HLA-A, B, and C Ag or restricted to HLA-B Ag were screened in indirect immunofluorescence with mouse L cells expressing HLA-B7/H-2Kb chimeric Ag. mAb CR1S63, CR10-215, CR11-115, and W6/32 were found to react with the HLA class I alpha 3 domain in addition to the alpha 2 domain. mAb Q1/28 and TP25.99 were found to react only with the HLA class I alpha 3 domain. The determinants recognized by the six mAb were mapped on the HLA class I alpha 3 domain by indirect immunofluorescence staining of L cells expressing H-2Kb Ag containing different segments of the HLA-B7 alpha 3 domain chimerized with the H-2Kb alpha 3 domain. mAb TP25.99 reacts with chimeric Ag containing the HLA-B7 184 to 199 stretch, mAb CR10-215 and CR11-115 react with chimeric Ag containing the HLA-B7 184 to 246 stretch, mAb CR1S63 and Q1/28 react with chimeric Ag containing the HLA-B7 184 to 256 stretch, and mAb W6/32 reacts with chimeric Ag containing the whole HLA-B7 alpha 3 domain. Functional analysis using human CD8 alpha-bearing mouse H-2Kb-specific T cell hybridoma cells (HTB-Leu2) showed that only mAb TP25.99 inhibited IL-2 production by HTB-Leu2 cells stimulated with L cells expressing KbKbB7 Ag. This inhibition may occur because of the spatial proximity of the determinant defined by mAb TP25.99 to the CD8 alpha binding loop and/or because of change(s) in the conformation of the CD8 alpha binding loop induced by the binding of mAb TP25.99 to the HLA class I molecule. Furthermore, mAb TP25.99 inhibited the cytotoxicity of CD8-dependent and CD8-independent CTL clones. These results indicate that mAb TP25.99 has unique specificity and functional characteristics. Therefore it represents a valuable probe to characterize the role of the HLA class I alpha 3 domain in immunologic phenomena.     

A panel of unique HLA-A2 mutant molecules define epitopes recognized by HLA-A2-specific antibodies and cytotoxic T lymphocytes

HLA-A2.1 and HLA-A2.3, which differ from one another at residues 149, 152, and 156, can be distinguished by the mAb CR11-351 and many allogeneic and xenogeneic CTL. Site-directed mutagenesis was used to incorporate several different amino acid substitutions at each of these positions in HLA-A2.1 to evaluate their relative importance to serologic and CTL-defined epitopes. Recognition by mAb CR11-351 was completely lost when Thr but not Pro was substituted for Ala149. A model to explain this result based on the 3-dimensional structure of HLA-A2.1 is presented. In screening eight other mAb, only the substitutions of Pro for Val152 or Gly for Leu156 led to the loss of mAb binding. Because other non-conservative substitutions at these same positions had no effect, these results suggest that the loss of serologic epitopes is in many cases due to a more indirect effect on molecular conformation. Specificity analysis using 28 HLA-A2.1-specific alloreactive and xenoreactive CTL clones showed 19 distinct patterns of recognition. The epitopes recognized by alloreactive CTL clones demonstrated a pronounced effect by all substitutions at residue 152, including the very conservation substitution of Ala for Val. Overall, the most disruptive substitution at amino acid residue 152 was Pro, followed by Glu, Gln, and then Ala. In contrast, substitutions at 156 had little or no effect on allogeneic CTL recognition, and most clones tolerated either Gly, Ser, or Trp at this position. Similar results were seen using a panel of murine HLA-A2.1-specific CTL clones, except that substitutions at position 156 had a greater effect. The most disruptive substitution was Trp, followed by Ser and then Gly. In addition, when assessed on the entire panel of CTL, the effects of Glu and Gln substitutions at position 152 demonstrated that the introduction of a charge difference is no more disruptive than a comparable change in side chain structure that does not alter charge. Taken together, these results indicate that the effect of amino acid replacements at positions 152 and 156 on CTL-defined epitopes depends strongly on the nature of the substitution. Thus, considerable caution must be exercised in evaluating the significance of particular positions on the basis of single mutations. Nonetheless, the more extensive analysis conducted here indicates that there are differences among residues in the class I Ag "binding pocket," with residue 152 playing a relatively more important role in formation of allogeneic CTL-defined epitopes than residue 156.     

Distinct and non-cross-reactive epitopes are recognized on B16 melanoma by LAK cells and anti-B16 monoclonal antibodies.

Two rat anti-B16 melanoma monoclonal antibodies (MoAb), designated IB16-6 and IB16-8, recognize an epitope expressed with high density on the surface of B16 parental cells and B16-F1, F10, F10FLR, and BL6 sublines. The purpose of this study was to define by means of cytolytic and clonogenic assays whether these MoAbs reacted with the same or distinct determinants as those recognized on B16 targets by lymphokine-activated killer (LAK) cells. Using 125I-labeled antibody and Scatchard analysis, the affinity constant (KA) of IB16-6 was determined to range from 5.6 to 9.4 x 10(8) liter/M and the number of receptor sites per B16 cell was 4.8 x 10(4) to 2.5 x 10(5). The effects of anti-B16 MoAb on LAK activity were determined by either preincubating 51Cr-labeled B16 target cells with varying concentrations of MoAb, followed by the cytolytic assay, or exposing unlabeled B16 cells to MoAb, and then carrying out a 10-day clonogenic assay. Over a wide range of antibody concentrations, IB16-6 and IB16-8 had minimal effects on LAK activity, and even at MoAb concentrations up to 1 mg there were no changes in target cell sensitivity or colony-forming ability. Enzymatic treatment of B16 melanoma cells with either trypsin or pronase completely removed the epitope recognized by MoAb IB16-6 but did not alter B16 sensitivity to LAK cells. These observations indicate that the LAK recognition unit was distinct from the epitope reactive with MoAb IB16-6 and that the B16 determinant(s) recognized by LAK cells is resistant to proteolytic enzymes. The molecular structure of each of these remains to be determined.     

The immunologic and molecular profiles of HLA antigens isolated from urine.

Human urine was shown to be a good source for the isolation of immunologically functional HLA-A9 antigens. The use of complex solubilization procedures can be avoided since the antigens are present in soluble form and are not complexes with membrane fragements. Purification in excess of 400-fold could be achieved by the application of cellulose ion exchange chromatography, isoelectric focusing, and acrylamide gel electrophoresis. The purified HLA-A9 antigen is composed of a glycoprotein of m.w. 38,000 and beta2-microglobulin, a peptide of m.w. 12,000. HLA-A9 antigens isolated from urine proved to be immunologically functional since they not only reacted specifically with anti-HLA-A9 alloantibody but also elicited anti-HLA-A9 xenoantibodies. These antibodies when covalently attached to Sepharose 4B specifically bound HLA-A9 antigens isolated from both serum and urine.     

The binding of monoclonal antibodies to cell-surface molecules. A quantitative analysis with immunoglobulin G against two alloantigenic determinants of the human transplantation antigen HLA-A2.

Monoclonal IgG1 (immunoglobulin G1) PA2.1 and MA2.1 antibodies recognize polymorphic sites of the human transplantation antigen HLA-A2. They are distinguishable because MA2.1 binds HLA-A2 and HLA-B17, whereas PA2.1 binds HLA-A2 and HLA-A28. The affinities of PA2.1-Fab for HLA-A2, three HLA-A2 variants and HLA-A28 are similar and relatively low (1.9 X 10(7) M-1). The affinities of MA2.1-Fab for HLA-A2, three HLA-A2 variants and HLA-B17 are similar and high (1.2 X 10(9) M-1). The difference in affinity is due to the rates of dissociation, which give half-times of dissociation of 290 min for MA2.1-Fab and 4 min for PA2.1-Fab. For both Fab, equilibrium measurements and kinetic determinations gave consistent estimates for affinity. When PA2.1-F(ab)2 or IgG is incubated with cells it reaches equilibrium within 3 h, with most molecules bound bivalently to the cell. Under similar conditions, MA2.1-F(ab)2 does not reach equilibrium and a significant proportion of molecules bound with one and two sites are found. For the lower-affinity antibody (PA2.1), estimates of the binding constants for one- and two-site interactions could be made. By simple Scatchard analysis the avidity of F(ab)2 or IgG is 1.3 X 10(9) M-1, giving an enhancement factor of 68 between bivalent and univalent binding. This is a measure of the equilibrium constant for the interchange between bivalent and univalent binding. Analysis of the results with more realistic models indicates that the actual value is larger (10(3)-10(4) M-1) than 68 M-1. The avidities of F(ab)2 and IgG for HLA-A2 are identical, showing the Fc does not interfere with bivalent binding to cells.