Anti-major histocompatibility complex immunity detected prior to intentional alloimmunization. II. Monoclonal H-2-specific antibodies obtained from an unimmunized C57BL/KaLwRij (H-2b) mouse

A monoclonal 'natural' anti-H-2 IgM antibody produced by a hybridoma cell line OL-3.17 (H-2 m. 209) is described. The OL-3.17 monoclonal antibody was obtained by hybridization of spleen B cells from an unimmunized C57BL/Ka (H-2b) mouse in the serum of which simultaneously an IgM kappa paraprotein of high concentration and a natural H-2-specific antibody of high titer was detected. The monoclonal antibody OL-3.17 reacted strongly with H-2d and H-2s and weakly with H-2k,q,r lymphocytes, thereby detecting a hitherto unknown H-2 public determinant. The target molecules for OL-3.17 cocapped with class-I H-2 antigens, but immunoprecipitation of H-2 antigens was not achieved. This is the first monoclonal H-2-specific antibody obtained from a mouse without intentional immunization and, with high probability, was derived from a B-cell clone which produced natural H-2-specific antibodies detectable in the serum of the original mouse.     

Clonal analysis of H-2Kb + TNP recognition by T cells with the use of H-2Kbm mutants and H-2Kb-specific monoclonal antibodies

Eleven long-term cytotoxic T lymphocyte (CTL) clones derived from C57BL/10 T cells sensitized in vivo and in vitro with trinitrobenzene sulfonate- (TNBS) treated syngeneic cells were all restricted to the K end of H-2b. The fine specificity of these CTL clones was analyzed by using H-2Kbm mutant target cells and H-2Kb-specific monoclonal antibodies (mAb). Seven distinct patterns of reactivity of the T cell clones could be observed with the use of six H-2Kbm mutant target cells. Further heterogeneity could be detected in terms of the ability of anti-Lyt-2 mAb to inhibit CTL activity. Cross-reactivity between H-2Kb + TNP and H-2Kbm + TNP was observed for all clones tested for bm5 and bm6, but less frequently for bm3 (8/11), bm8 (7/10), bm4 (4/11), and bm1 (3/11). It was further observed that amino acid substitutions located in the first domain only (one clone), or in the second domain only (six clones), or in either the first or the second domain (three clones) of the H-2Kb molecule could affect target cell recognition by a given T cell clone. the latter type of reactivity suggested that some clones recognized "conformational" determinants of the H-2 molecule, or that amino acid substitutions in one domain might influence the structure of the next domain. One H-2Kb + TNP-reactive clone exhibited a heteroclitic behavior with decreasing avidities for target cells expressing H-2Kbm8 + TNP, H-2Kb + TNP, and H-2Kbm8, which further extends the various patterns of T cell cross-reactions observed within a given class of MHC products. The use of H-2Kb-specific mAb in blocking studies as an attempt to define further the H-2Kb epitopes recognized by CTL clones indicated that: a) TNBS treatment may affect the antigenicity of the H-2Kb molecule as assessed by some mAb; and b) that the T cell clone-target cell interaction may or may not be inhibited by a given mAb, depending on structural variations of the H-2Kb molecule (use of H-2Kbm mutants) that do not affect the interaction itself. These results indicate that this type of analysis does not permit correlation of serologic- and T cell-defined epitopes.     

Serological analysis of H-2 and Ia molecules with monoclonal antibodies

Five H-2 and seven Ia monoclonal antibodies were tested against a panel of 43 independentH-2 haplotypes (11 of laboratory-mouse and 32 of wild-mouse origin), 33 recombinantH-2 haplotypes, and up to 74 wild mice. All the antibodies gave negative reactions in the PVP hemagglutination tests; all, however, gave positive reaction with some members of the panel in the dye-exclusion cytotoxic test. Four of the antibodies (H-2.m2,Ia.m2, Ia.m5 and Ia.m7) reacted identically to conventional antibodies detecting determinants H-2.2., and Ia-1.2, Ia-1.15, and Ia-5.7, respectively (this statement does not apply to wild mice in which minor differences in reactivity patterns of the corresponding antibodies were found: the reproducibility of these differences, however, could not be checked by absorption). Five other antibodies (H-2.m5, H-2.m3, H-2.m4, Ia.ml, and Ia.m6) had very similar though not identical reactivity patterns to conventional antibodies detecting determinants H-2.5, H-2.11, H-2.25, Ia-1.2, and Ia-1.19, respectively. The last three monoclonal antibodies (H-2.ml, Ia.m3, and Ia.m4) had a reactivity pattern that did not match those of any known conventional antibodies. The near identity or great similarity of many monoclonal and conventional antibodies indicates that the cleanest of the conventional antisera are truly monospecific, and gives credence to the H-2 serology as defined by conventional antibodies. The serological analysis of monoclonal antibodies supports the true existence of private and public determinants, and reveals that the H-2 and Ia determinants are complex, even when the antibody is simple.     

Clustering of antigenic determinants on H-2 molecules

The spatial relationship of individual antigenic determinants on H-2Kk and H-2Db molecules was investigated with seven different monoclonal anti-H-2Kk and seven anti-H-2Db antibodies. In these studies the binding of radiolabeled monoclonal anti-H-2 to target cells was competed by addition of various cold anti-H-2 antibodies. The results indicate that on both H-2Kk and H-2Db molecules the antigenic determinants are arranged in two spatially separated clusters. Thus, antibodies to determinants within a cluster show mutual inhibition of binding but do not block the binding of antibodies to the other cluster, and vice versa. Furthermore, in the case of H-2Db antigens it was observed that binding of antibodies to one cluster would considerably enhance the binding of antibodies to the other cluster. A preliminary Scatchard analysis indicated that the enhancing antibody did not alter the affinity of the radiolabeled antibody, but led to an increase of available binding sites on the cell membrane. In addition, binding inhibition studies revealed that the conventional private specificity H-2.2 of H-2Db consists of at least two independent sites on the molecule.     

Role of the major histocompatibility complex in T cell activation of B cell subpopulations: antigen-specific and H-2-restricted monoclonal TH cells activate Lyb-5+ B cells through an antigen-nonspecific and H-2-unrestricted effector pathway

Monoclonal T helper (TH) cell populations were employed to study the mechanism of activation of the Lyb-5+ B cell subpopulation in T cell-dependent antibody responses in vitro. It was demonstrated that monoclonal T cell populations were sufficient to help rigorously T-depleted unprimed (B + accessory) cells for direct plaque-forming cell responses to trinitrophenyl- (TNP) conjugated keyhole limpet hemocyanin (KLH). The activation of several lines of cloned (H-2b X H-2k)F1 TH cells was antigen (KLH) specific and H-2 restricted. Individual clones were restricted to H -2b, H-2k, or unique (H-2b X H-2k)F1 encoded determinants. Under the experimental conditions employed, responses mediated by cloned TH cells were found to result in the activation of the Lyb-5+ B cell subpopulation. The activation of Lyb-5+ B cells by cloned TH cells did not require covalent linkage of carrier and hapten, and responses could be stimulated in the presence of free KLH plus TNP conjugated to an irrelevant carrier. The H-2 restriction of TH cell function was shown to reflect a requirement for T cell recognition of determinants expressed by accessory cells, whereas no requirement existed for restricted T cell recognition of B cells. These findings suggest that the help provided by monoclonal TH cells, once activated, was both antigen nonspecific and H-2 unrestricted. Consistent with this interpretation, it was found that the supernatant of antigen-stimulated TH cells provided antigen-nonspecific help to T-depleted spleen cells. Thus, these results demonstrate that the activation of Lyb-5+ B cells by antigen-specific and H-2-restricted monoclonal TH cell populations is itself antigen nonspecific and H-2 unrestricted.     

T-cell and antibody typing of a mouse population segregating for Sxr and H-2 haplotype

During investigation of the frequency of recombination of the testis determining gene, Tdy, and the minor histocompatibility antigen gene Hya on the Sxr segment in an outbred mouse stock, we identified two fertile males, one XY and the other XYSxr, which typed H-2k positive using the H-2b anti-H-2k monoclonal antibody HB50, but whose cells failed either to stimulate H-Y specific H-2k restricted T-cell clones, or to be killed by anti-H-2k or anti-H-2k restricted H-Y specific cytotoxic T cells. We investigated these two mice and their existing relatives, using H-2 and H-Y typing methods. The progeny of their test matings with H-2b homozygous C57BL/6 females were also investigated. The results indicate that the transmission of the Hya gene on the Y chromosomes from both mice, and the additional Hya gene on the Sxr segment of the carrier male, allowed for the expression of the H-Y antigen and its detection in the presence of an H-2 haplotype for which we had H-2 restricted H-Y specific typing cells (H-2b and H-2k). Furthermore, we identified the haplotype of the two original males as expressed in the H-2 homozygous and heterozygous F2 progeny as H-2q and discovered an unexpected cross reactivity of the monoclonal anti KkDk antibody HB13 with half the cells of H-2q homozygotes, but not qb heterozygotes.     

An IL 2-secreting T cell hybridoma that responds to a self class I histocompatibility antigen in the H-2D region

A self-reactive T cell hybridoma that secretes IL-2 in response to H-2d haplotype cells resulted from a fusion of BALB/cBy lymph node cells with the AKR thymoma BW5147. The lymph node cells used had been enriched for cells reactive to (TG)-A--L, but neither this antigen nor fetal calf serum were required for stimulation of the hybridoma designated 3DT52.5. The gene product responsible for stimulation mapped to the H-2D region. Allogeneic cells of the b, f, k, q, and s haplotypes failed to stimulate. Not all H-2d haplotype cells were effective stimulators of 3DT52.5. Peritoneal cells and splenic B cells were much more stimulatory than splenic T cells. Most tumor cell lines of H-2d derivation and of B cell or macrophage/monocyte lineage were stimulatory, whereas H-2d T cell lines were not. The capacity to stimulate 3DT52.5 did not correlate with the ability to stimulate I region-restricted hybridomas, or with the ability to be induced to stimulate such hybridomas. Stimulatory cell lines did not apparently produce a soluble factor required for stimulation, and negative cell lines were not inhibitory. The monoclonal antibody 27-11-13, which reacts with H-2D of the b, d, and q haplotypes, inhibited stimulation of 3DT52.5 but did not inhibit stimulation of the sibling hybridoma 3DT18.11, which responds to (TG)-A--L plus I-Ad. Conversely, the monoclonal anti-I-Ad antibody MK-D6 inhibited stimulation of 3DT18.11 but not 3DT52.5. Although it is clear that 3DT52.5 recognizes a class I antigen coded for in the H-2D region, the precise molecular nature of the antigen is unknown. The structure of the antigen receptor on this hybridoma may prove to be of interest when it can be compared with receptors found on T cell hybridomas restricted by class II histocompatibility antigens.     

Somatic cell variants of H-2k: b: A point mutation in the first extracellular domain results in altered immune recognition

A cell-surface-associated variant H-2K product was expressed by an Abelson virus-induced pre-B-cell line after chemical mutagenesis with ethyl methane sulfonate. The variant cell line (R8.313) was previously demonstrated to have altered allodeterminants in K^b as demonstrated by both K^b-specific monoclonal antibody binding and alloreactive cytotoxic T lymphocyte (CTL) cytolysis. The mutant H-2K ^b gene from R8.313 was cloned and characterized in detail. DNA sequence analysis of the region of the gene corresponding to the three extracellular domains identified a single point mutation resulting in a leucine-to-phenylalanine substitution at amino acid residue 82. The site of mutation within the 1 domain was confirmed by oligonucleotide hybridization analysis. Mouse L-cell fibroblasts transfected with the mutant gene were recognized with the same monoclonal antibody binding and CTL lytic pattern as the R8.313 cell line, confirming that the altered phenotype of the mutant cell line was due to a point mutation in the H-2K ^b gene. These data further extend the hypothesis that the region of amino acid residues 70–90 in the 1 domain is important in the formation of both antibody and CTL-defined recognition structures on major histocompatibility complex class I molecules.     

Synthesis of H-2 antigens by preimplantation mouse embryos

An enzyme-linked immunosorbent assay (ELISA), which utilized anti-H-2 monoclonal antibody, was used to detect H-2 antigens on preimplantation mouse embryos. All embryonic stages studied, including unfertilized eggs and 1-cell, 2-cell, 8-cell, and blastocyst-stage embryos, showed the presence of H-2 antigens. To prove that the H-2 antigens were not cytophilically adsorbed to the embryos, blastocysts were treated with papain to strip off the H-2 antigens, and then the embryos were further incubated to allow the H-2 antigens to regenerate. After a 3-h incubation time, 60% of the H-2 antigens on the embryos had reappeared, proving that the H-2 antigens were synthesized by the embryos themselves.     

The products of transferred H-2 genes express determinants that restrict hapten-specific cytotoxic T cells

Cell lines into which cloned H-2 genes had been introduced (i.e., transformants) were used to correlate the genes and their products that are capable of functioning as H-2 restriction elements for hapten-self-(AED and TNP) specific cytotoxic T cells (CTL). These transformants provided a unique system in which major histocompatibility restricted (MHC) T cell recognition could be examined by using cells that express only H-2Ld or only H-2Dd gene products. BALB/c (H-2d) anti AED-self CTL lysed both the H-2Ld and Dd transformants, but not parental, i.e., untransformed, cells. The AED-self lysis of the Ld and Dd transformants was shown to be specifically inhibited by anti-H-2Ld and anti H-2Dd monoclonal antibody, respectively. In contrast to these results, BALB/c anti TNP-self CTL were found to lyse readily the Dd but not Ld transformed lines, supporting reports indicating that H-2Ld-restricted TNP-self CTL could not be detected. The results of this study thus demonstrate that the cell surface products encoded by these transferred MHC class I genes contain self determinants recognized by CTL.     

Target-cell recognition by cloned lines of influenza virus-specific cytotoxic T lymphocytes. Selective inhibition by a monoclonal H-2-specific antibody

A monoclonal H-2^d-specific antibody markedly inhibits target-cell lysis mediated by two influenza virus A/JAP/57-specific, H-2K ^d -restricted cloned CTL lines. Three other A/JAP/57-specific, H-2 ^d -restricted CTL clones (two of which are also restricted to H-2K ^d in target-cell recognition) are only minimally inhibited by this monoclonal antibody. The inhibitory effect of the antibody is not due to selective binding to certain cloned CTL lines but rather is due to blocking of a determinant on the target cell. The monoclonal antibody produces partial inhibition of lysis mediated by a heterogeneous population of A/JAP/57-specific, H-2 ^d -restricted CTL. Likewise the profound, selective inhibition of cytolysis produced by the H-2^d-specific monoclonal antibody could not be reproduced with a conventional H-2^d alloantiserum. These observations suggest that more than one site on a particular H-2K or H-2D molecule can serve as a determinant for H-2-restricted CTL recognition. They furthermore imply that there is more than one recognition structure (receptor) for self MHC products clonally distributed among a population of H-2-restricted CTL directed to a particular antigen.     

Flow microfluorometric analysis of H-2L expression

The cell surface expression of H-2L, a major transplantation antigen, was compared by flow microfluorometry to the expression of products of H-2K and H-2D loci, using monoclonal antibodies. By this methodology, the ontogeny and tissue distribution of Ld antigens were found to be indistinguishable from those of the K and D antigens. In a reciprocal blocking assay, using fluorescein-labeled test reagents, it was shown that monoclonals anti-H-2.65 and anti-H-2.64 did not inhibit the binding of each other. These results suggest that the alloantigenic determinants H-2.64 and H-2.65 are located at distinct sites on Ld molecules. Quantitative comparisons using the fluorescein-labeled monoclonal reagents indicated that Ld molecules are expressed at 2- to 3-fold lower levels on the cell surface compared with K and D molecules. These findings give new credence to a "3-locus" model for the major histocompatibility complex of man and mouse, where H-2L and HLA-C share several homologies that are unique and distinguish them from the other histocompatibility loci.     

A single monoclonal anti-Ia antibody inhibits antigen-specific T cell proliferation controlled by distinct Ir genes mapping in different H-2 I subregions

A xenogeneic rat anti-mouse Ia monoclonal antibody, M5/114 (gamma 2b, kappa), was studied for its effects in vitro on T cell proliferative responses. Strain distribution studies revealed that M5/114 could inhibit I-A subregion-restricted T cell responses of the H-2b,d,q,u but not the H-2f,k,s haplotypes, indicating that this xenoantibody recognizes a polymorphic determinant on mouse Ia molecules. This same monoclonal antibody was found to inhibit BALB/c (H-2d) T cell proliferation to both G60A30T10 and G58L38 phi 4. The Ir genes regulating responses to these antigens map to either the I-A subregion (GAT), or the I-A and I-E subregions (GL phi), raising the possibility that M5/114 recognizes both I-A and I-E subregion-encoded Ia glycoproteins. It could be shown, using appropriate F1 responding cells, that M5/114 does in fact affect GAT and GL phi responses by interaction with both the I-A and the I-E subregion products, and not by any nonspecific effect resulting from binding to the I-A subregion product alone. These results are consistent with genetic and biochemical studies directly demonstrating that M5/114 recognizes A alpha A beta and E alpha E beta molecular complexes. The existence of a shared epitope on I-A and I-E subregion products suggests the possibility that these molecules arose by gene duplication. Finally, the precise correlation between the Ia molecules recognized by M5/114 and the ability of this antibody to block T cell responses under Ir gene control strengthens the hypothesis that Ia antigens are Ir gene products.     

Membrane-reconstituted, purified H-2Kb specifically inhibits T-cell-target cell conjugate formation

We report the use of a sensitive microassay to detect purified H-2Kb antigens which have been functionally reconstituted into membrane vesicles of defined composition. The histocompatibility antigens have been purified by monoclonal antibody affinity chromatography. The assay utilizes inhibition of specific conjugate formation between allogeneically primed (H-2d anti- H-2b) cytotoxic T cells and H-2b target cells by the membrane-reconstituted H-2Kb antigens. Cytoskeletal proteins were added to the H-2Kb (and control H-2k) antigens. Sucrose density fractionation of reconstituted vesicles and Pronase E cleavage studies suggested that the cytoskeletal proteins aided in the incorporation and vectorial orientation of the antigens into large, cholesterol-containing membrane vesicles. As little as 6 ng purified H-2Kb plus 28 ng cytoskeletal proteins in vesicles of defined lipid composition (0.28, 0.25, 0.47 mol fraction cholesterol, dimyristoylphosphatidylcholine, and dipalmitoylphosphatidylcholine, respectively) inhibited specific conjugate formation to 50% of the maximum inhibition observed. This inhibition was shown to be specific in two ways: (i) the same H-2Kb-containing vesicles did not inhibit nonspecific conjugate formation, and (ii) control vesicles containing the same amounts of lipid, cytoskeletal proteins, and purified H-2k proteins inhibited conjugate formation but only at significantly higher H-2k concentrations, indicating the specificity of the response with the vesicles containing H-2Kb.     

Demonstration of H-2 antigens on preimplantation mouse embryos using conventional antisera and monoclonal antibody

Mouse embryos at the 2-cell, 8-cell, and blastocyst stages of development were examined for the presence of H-2 antigens by immunoperoxidase labeling and transmission electron microscopy. Conventional antisera made in congenic mouse strains were used to study embryos of four different haplotypes: b, a, k, and d. Blastocysts showed uniform heavy labeling of all cells of the trophectoderm, 8-cell embryos showed lighter labeling of only some of the cells, and 2-cell embryos showed no labeling. Similar results were found for all four haplotypes studied. In addition, monoclonal antibody 11-4.1 (anti-Kk) was reacted with homologous (H-2k) and heterologous (H-2b) blastocysts. Positive results with the monoclonal antibody corroborates the concept that H-2 antigens are expressed on early mouse embryos.     

Selective destruction by formaldehyde fixation of an H-2Kb serological determinant involving lysine 89 without loss of T-cell reactivity

In preparation for functional analyses, a study of the binding of H-2K^b-specific monoclonal antibodies (mAb) to formaldehyde (FOR)-fixed H-2^b spleen or tumor cells revealed that three of nine mAb tested had lost reactivity with the FOR-fixed cells, whereas the reactivity of the other mAb generally did not diminish. Comparison of the reactivity of these mAb on untreated H-2K ^bm mutant cells and on FOR-treated H-2K^b cells suggests that for three mAb the total loss of reactivity on the latter could be a consequence of the alteration by FOR of lysine 89, which is substituted by alanine in mutant bm3. H-2KP^b-specific alloreactive polyclonal or monoclonal CTL, all of which had retained reactivity with bm3 target cells, had also retained reactivity with FOR-fixed H-2^b cells as indicated by cold target inhibition studies. The H-2K^b-specific CTL were probably reactive with conformational determinants of H-2K^b, which are dependent on the integrity of both the 1 and the 2 domains of the H-2K^b molecule. Results are compatible with FOR treatment selectively affecting a serological determinant in the 1 domain without affecting conformational-type CTL determinants.Abbreviations used in this paper CTL cytotoxic T lymphocyte - FOR formaldehyde - PBS phosphatebuffered saline - FCS fetal calf serum - mAb monoclonal antibody - TNBS trinitrobenzene sulfonate     

Inhibition of cytolytic T lymphocyte clones reactive with Moloney leukemia virus-associated antigens by monoclonal antibodies: a direct approach to the study of H-2 restriction

H-2 restriction in cytolytic T lymphocyte (CTL)-mediated lysis of syngeneic murine Moloney leukemia virus (MoLV)-induced tumor cells was studied at the clonal level by testing the inhibitory effect of monoclonal anti-H-2 antibodies on the lytic interaction between CTL clones and target cells. Large numbers of MoLV-specific CTL clones were generated by placing limiting numbers of C57BL/6 regressor (responder) spleen cells into micro-mixed leukocyte-tumor cell cultures. The clonal CTL populations thus obtained were split into 5 aliquots and tested for lytic activity in the presence (or absence) of 1 of 3 monoclonal antibodies or of an anti-whole H-2b haplotype antiserum. Two of the monoclonal antibodies were directed against H-2Db and one against H-2Kb determinants. Specificity of these reagents had been verified by demonstrating inhibition of lysis by CTL populations directed against H-2Db and H-2Kb alloantigens. In 44 of a total of 51 clones tested, results showed selective inhibition by the anti-H-2Db (and the anti-whole haplotype) reagents, and lack of inhibition by the anti-H-2Kb antibody., Of the remaining 7 clones, none was inhibited by the anti-H-2Db antibody, and 3 were inhibited by the anti-whole haplotype antiserum. These studies show that the recognition of MoLV-associated antigens by the majority of CTL clones was restricted to the H-2Db region, and that there exists limited heterogeneity in the H-2 restriction of such clones.     

Negatively selected H-2bml and H-2b cells stimulated with vaccinia virus completely discriminate between mutant and wild-type H-2K alleles

Lymphocyte populations from B6, C-H-2bml (KbmlDb) mutant mice cannot, after both in vivo and in vitro negative selection for alloreactivity, be induced to recognize vaccinia virus presented in the context of H-2Kb. This finding may mean that the T cell receptor(s) expresses a component that is very specific for a particular "active site" on the self-H-2 molecule. Alternatively, (if recognition is directed at a virus-H-2 complex) the more similar 2 H-2 molecules are, the more likely it may be that precursor thymocytes in the mutant with the capacity to bind H-2Kb + vaccinia virus may be deleted during ontogeny as a result of cross-reaction with H-2Kbml + endogenous antigen.     

Synthetic Plasmodium falciparum circumsporozoite peptides elicit heterogenous L3T4+ T cell proliferative responses in H-2b mice

The ability of synthetic P. falciparum (NANP)n circumsporozoite peptides to elicit murine T cell proliferative responses was studied. When C57BL/6, C3H, and DBA/2 mice were injected with (NANP)40, only C57BL/6 (H-2b)-immune lymph node cells proliferated on restimulation in vitro with the same peptide. By using anti-I-A monoclonal antibodies or spleen cells from congenic H-2b mice as a source of antigen-presenting cells, the T cell proliferative response was shown to be restricted to the I-Ab region of the C57BL/6 haplotype. These results are in agreement with previous experiments which demonstrated that the anti-(NANP)40 antibody response was uniquely restricted to C57BL/6 (H-2b) mice. Several C57BL/6 long-term (NANP)n-specific T cell lines and clones were derived. All of the clones exhibited the L3T4 helper T cell phenotype. A considerable heterogeneity of T cell responses was observed when the lines and clones were stimulated with different concentrations of the various peptides studied. The results, together with the observed genetic restriction for both antibody and T cell responses, suggest that perhaps not all individuals who receive a similar repetitive tetrapeptide sporozoite malaria vaccine will develop T cell and or antibody responses.     

Somatic cell variants express altered H-2Kb allodeterminants recognized by cytolytic T cell clones

The present studies have made use of in vitro derived H-2Kb mutants to analyze the fine specificity of alloreactive cytotoxic T lymphocytes (CTL). The variants were derived by negatively selecting mutagenized tumor cells with a monoclonal anti-H-2Kb antibody and positively selecting for residual cells expressing serologically altered H-2Kb molecules. Details of this procedure are described in the companion paper. Selected populations of bulk alloreactive and cloned CTL were examined for recognition of the variants. In contrast to the serologic findings presented in the companion paper, there does not appear to be a correlation between the monoclonal antibody used to select the R8 variant and the CTL specificities recognized. In several instances, CTL clones could discriminate between variants having identical serologic profiles. Therefore, it would appear that the CTL have a large repertoire of allorecognition, even when generated across a mutant anti-Kb combination reflecting only a few amino acid differences. In addition, a diverse set of epitopes can be recognized on the Kb molecule. Finally, in some instances a change in what would appear to be a single amino acid resulted in a profound alteration of CTL recognition even though the Kb mutant molecule expressed limited serologic changes. These results support the idea that small changes in the H-2Kb molecule can have dramatic effects on CTL even though there are relatively little effects on serologic recognition of the target molecule.