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.     

Cross-reactivity patterns of influenza-specific cytotoxic T lymphocytes from H-2Kb mutant mice

Limit dilution cultures were used to test for influenza immune T cell populations from bm1 and bm3 mutant mice that were not lytic for virus-infected targets expressing the Kb and Db major histocompatibility complex glycoproteins. Both Kbm3- and Kbm1-restricted cytotoxic T cells were detected. Such effectors showed minimal cross-recognition of influenza on other mutant targets, except for the case of bm1 and bm10 targets. This is dissimilar to previous findings concerning vaccinia presentation in which bm3+bm11, bm1+bm9, and bm3+bm9 pairs each showed high cross-reactivity. These differences illustrate the role of the H-2K glycoprotein in immune responsiveness. Not only are multiple determinants on each H-2K glycoprotein involved in antigen presentation, they appear to play differential roles in the presentation of different viral antigens.     

Structural basis of Kbm8 alloreactivity. Amino acid substitutions on the beta-pleated floor of the antigen recognition site

We have analyzed the functional significance of the four amino acid differences between the parental H-2Kb and mutant H-2Kbm8 glycoproteins. Six bm8 variants including single substitutions at residues 22, 23, 24, and 30 as well as paired substitutions at residues 23, 30 and 22, 24 were generated and transfected into L cells. Surface expression of these H-2Kb variants was analyzed using monoclonal antibodies which bind to well-defined H-2Kb epitopes. No alterations introduced into the conformational structure of H-2Kb by the amino acid substitutions were detected. The effect of these substitutions on CTL recognition was initially analyzed using the following bulk CTL: either H-2Kb anti-H-2Kbm8, H-2Kbm8 anti-H-2Kb, or third party anti-H-2Kb. The alloreactivity between H-2Kb and H-2Kbm8 is dominated by the amino acid substitution at residue 24 (Glu----Ser). The complete bm8 phenotype, however, also requires the additional substitution at residue 22 (Tyr----Phe). The H-2Kbm8 anti-Kb bulk CTL reacted with both variant H-2Kbm8 molecules containing single substitutions at amino acid positions 22 or 24 but not the variant molecule containing both substitutions. Further analysis using three individual H-2Kbm8 anti-Kb CTL clones indicated the complexity of the self Kbm8 phenotype. Clone 8B1.20 did not react to changes in residues 22 or 24. The 8B1.32 clone reacted with the change at residue 22 but not with the change at residue 24, although the 8B1.54 clone reacted with the change at residue 24 but not with the change at residue 22. The changes in residues 23 (Met----Ile) and/or 30 (Asp----Asn) did not impact significantly on the alloantigenic properties of Kbm8 as determined by both the bulk and cloned CTL populations. According to the three-dimensional class I structure the substitution at amino acid 24 is inaccessible to the TCR. The location of this substitution within the Ag recognition site implies that altered peptide binding, and not a disruption of MHC residues that interact with the TCR, is responsible for the alloreactivity between H-2Kb and H-2Kbm8.     

Characterization of the spontaneous mutant H-2Kbm29 indicates that gene conversion in H-2 occurs at a higher frequency than detected by skin grafting.

A spontaneous mutation of H-2Kb, Kbm29, was discovered among the progeny of F1 hybrid parents. Unlike other characterized spontaneous class I variants, this mutant was detected with the use of antibody, rather than tissue grafting. Although Kbm29 is serologically indistinguishable from the previously described mutant molecule Kbm3, it is identical to the parental Kb by skin grafting and CTL assays. A full length cDNA of Kbm29 was amplified by polymerase chain reaction with locus-specific primers, cloned, and sequenced. Two nucleotides were found to be mutated, resulting in a single amino acid change (Lys----Ala) at amino acid 89 of the mature glycoprotein. This is consistent with the observed serologic changes, as the same amino acid substitution is responsible for the serologic profile of Kbm3. The occurrence of a mutation which is not detectable by the methods normally used to screen for H-2 mutants provides evidence that the high spontaneous rate of structural mutation described for the Kb molecule is underestimated.     

The functional significance of two amino acid polymorphisms in the antigen-presenting domain of class I MHC molecules. Molecular dissection of Kbm3

The functional properties of two amino acid substitutions, characteristic of the bm3 mutation, in the Kb class I glycoprotein were analyzed in light of the HLA-A2 crystal model. The model predicts that amino acid residues extending into the proposed ligand-binding site or projecting up from the alpha-helices are functional with respect to peptide Ag presentation; whereas those residues pointing away from the site are silent. L cell clones expressing Kb, Kbm3, and derivatives of Kbm3, Kbm3-77 (Asp----Ser "ligand-binding") and Kbm3-89 (Lys----Ala "silent"), were generated for the analysis. Serologic characterization of this panel of cells by using the mAb B8-24-3, EH-144, 20-8-4, K9-136, and Y-25 (Kb but not Kbm3 specific) revealed the loss of the epitopes recognized by these mAb in the Kbm3-89 clone and the retention of these epitopes in the Kbm3-77 clone. Analysis of the L cell clones by using B6 anti-bm3 CTL demonstrated that L cell clones expressing Kbm3 or Kbm3-77 were lysed by these CTL, whereas clones expressing Kb, Kbm3-89, and Ld were not lysed. In reciprocal experiments, bm3 anti-B6 CTL lysed L cell clones expressing Kb or Kbm3-89 but were unable to lyse clones expressing Kbm3, Kbm3-77, and Ld. The results indicate that the substitution at amino acid 89 determines the Kbm3 serologic phenotype, whereas the Kbm3 alloreactive phenotype is primarily determined by the substitution at amino acid 77. These findings are in good agreement with the predictions derived from the x-ray crystal model of the HLA-A2 molecule.     

Differential helper and effector responses of Lyt-2+ T cells to H-2Kb mutant (Kbm) determinants and the appearance of thymic influence on anti-Kbm CTL responsiveness

The goal of this study was to assess and compare the allorecognition requirements for eliciting Lyt-2+ helper and effector functions from primary T cell populations. By using interleukin 2 (IL 2) secretion as a measure of T helper (Th) function, and cytolytic T lymphocyte (CTL) generation as a measure of effector function, this study compared the responses of Lyt-2+ T cells from wild-type B6 mice against a series of H-2Kb mutant determinants. Although all Kbm determinants stimulated B6 Lyt-2+ T cells to become cytolytic effector cells, the various Kbm determinants differed dramatically in their ability to stimulate Lyt-2+ T cells to function as IL 2-secreting helper cells. For example, in contrast to Kbm1 determinants that stimulated both helper and effector functions, Kbm6 determinants only stimulated B6 Lyt-2+ T cells to become cytolytic and failed to stimulate them to secrete IL 2. The distinct functional responses of Lyt-2+ T cells to Kbm6 determinants was documented by precursor frequency determinations, and was not due to an inability of the Kbm6 molecule to stimulate Lyt-2+ Th cells to secrete IL 2. Rather, it was the specific recognition and response of Lyt-2+ T cells to novel mutant epitopes on the Kbm6 molecule that was defective, such that anti-Kbm6 Lyt-2+ T cells only functioned as CTL effectors and did not function as IL 2-secreting Th cells. The failure of Lyt-2+ anti-Kbm6 T cells to function as IL 2-secreting Th cells was a characteristic of all Lyt-2+ T cell populations examined in which the response to novel mutant epitopes could be distinguished from the response to other epitopes expressed on the Kbm6 molecule. The absence of significant numbers of anti-Kbm6 Th cells in Lyt-2+ T cell populations was examined for its functional consequences on anti-Kbm6 CTL responsiveness. It was found that primary anti-Kbm6 CTL responses could be readily generated in vitro, but unlike responses to most class I alloantigens that can be mediated by Lyt-2+ Th cells, anti-Kbm6 CTL responses were strictly dependent upon self-Ia-restricted L3T4+ Th cells. Because the restriction specificity of L3T4+ Th cells is determined by the thymus, in which their precursors had differentiated, anti-Kbm6 CTL responsiveness, unlike responsiveness to most class I alloantigens, was significantly influenced by the Ia phenotype of the thymus in which the responder cells had differentiated.(ABSTRACT TRUNCATED AT 400 WORDS)     

Inhibition of an allospecific T cell hybridoma by soluble class I proteins and peptides: estimation of the affinity of a T cell receptor for MHC

To investigate the molecular basis of the interaction between the T cell receptor and the MHC class I antigen in an allogeneic response, a soluble counterpart of the murine class I molecule, H-2Kb, was genetically engineered. Cells secreting this soluble molecule, H-2Kb/Q10b, inhibited stimulation of an H-2Kb-reactive T cell hybridoma by cells transfected with H-2Kbm10, a weak stimulus, but not by H-2Kb- or H-2Kbm6-transfected cells. Soluble purified H-2Kb/Q10b protein also blocked T cell stimulation. In addition, a peptide from the wild-type H-2Kb molecule spanning the region of the bm10 mutation specifically inhibited activation of the T cell hybridoma by H-2Kbm10 cells, thus suggesting that amino acid residues 163-174 of H-2Kb define a region important for T cell receptor binding. An estimate for the Kd of the T cell receptor for soluble H-2Kb/Q10b was 10(-7) M, while the Kd for soluble peptide 163-174 was 10(-4) M.     

Peptide interactions with the Kb antigen recognition site

The ability of OVA-specific H-2Kb-restricted CTL to recognize the defined OVA258-276 peptide in the context of the Kbm mutants and variants of these mutants was examined to determine how specific variations in the Ag recognition site-influenced peptide presentation to these CTL. L cells expressing Kb or Kbm10 were equally capable of presenting the OVA peptide to Kb-restricted, OVA-specific bulk CTL, whereas L cell clones expressing Kbm8 or Kbm1 showed little to no capacity to present this peptide. L cell transfectants expressing Kbm3 and Kbm23 consistently demonstrated an intermediate to low level of presentation to bulk OVA-specific CTL. Dissection of the Kbm8 mutant revealed that cells expressing Kbm8-22 (Tyr----Phe) and/or Kbm8-24 (Glu----Ser) presented the OVA peptide significantly less well than the Kb-presenting molecule. Presentation of OVA by cells expressing Kbm8-23,30 (Met----Ile) (Asp----Asn), Kbm8-23 (Met----Ile), and Kbm8-30 (Asp----Asn) was equivalent to Kb presentation. Another mutation designated as Kbm5, that has a substitution at position 116 (Tyr----Phe), demonstrated an intermediate to high ability to present OVA258-276 to an OVA-specific CTL line. The Kbm3, Kbm11, and Kbm23 mutants were unable to present the OVA peptide to this same CTL line. Dissection of these mutants showed that the substitution at position 77 (Asp----Ser), which is shared by all three mutants, was responsible for their inability to present the peptide. A second Kb-restricted CTL line was able to recognize OVA in the context of the Asp----Ser substitution at position 77. The results of this analysis suggest that the OVA258-276 peptide interacts with multiple regions within the Ag recognition site of the Kb class I protein.     

Adoptive transfer of delayed-type hypersensitivity to Sendai virus. III. Effect of H-2 mutations on recognition by K, D-region restricted T effector lymphocytes

The H-2 restriction pattern of cytolytic T lymphocytes (Tc) and T lymphocytes which mediate a delayed-type hypersensitivity response (Td) directed against infectious Sendai virus was investigated using H-2 mutant mice. Td and Tc lymphocytes exhibit the same fine specificity for self-recognition, for example, B6.C-H-2bm1 effector T cells were unable to recognize viral antigens in association with wild-type Kb and vice versa, B6.H-2bm6 effector cells did not mediate a reaction against virus plus wild-type Kb but, on the other hand, T cells of wild-type Kb recognized virus plus Kbm6 BALB/c-H-2dm2 T cells lacked reactivity against virus in association with wild-type Dd, but again wild-type Dd effector cells recognized virus plus Ddm2.     

Cross-reactive recognition of mouse cells expressing the bm3 and bm11 mutations within H-2Kb by H-2Kb-restricted herpes simplex virus-specific cytotoxic T lymphocytes

Cytotoxic T lymphocytes, generated in C57BL/6 mice in response to herpes simplex virus type 1 (HSV) and known to be restricted in their recognition of HSV-encoded antigen(s) in association with the class I H-2Kb gene product, were consistently found to contain a subpopulation that recognized and lysed uninfected, SV40-transformed cells that expressed the H-2Kbm3 and H-2Kbm11 mutant class I gene products on their cell surface. The mutant cell lines, designated Lgbm3SV and Kbm11SV, share a common amino acid substitution at position 77, with the bm3 mutation having an additional amino acid substitution at position 89. Cross-reactive lysis was observed only after in vivo priming with HSV, suggesting an important role for an antigen-dependent driving step in the expansion of these cross-reactive CTL. The phenotype of the cross-reactive effector population was further confirmed as a T lymphocyte by negative-selection techniques. Limiting dilution analysis of the frequency of cross-reactive CTL precursors suggested that cross-reactivity was mediated by a subpopulation of HSV-specific CTL, and this was confirmed by clonal analysis of the reactivity patterns of short-term, HSV-specific CTL clones. However, analysis of the specificity of the cross-reactive CTL population by cold-target inhibition of bulk culture-derived CTL, or by Spearman ranking analysis of limiting dilution-derived CTL, indicated that the specificity of the cross-reactive population for HSV-infected H-2b target cells and for uninfected bm3 or bm11 target cells was quite distinct. These findings suggested that the cross-reactive CTL population played little, if any, role in the HSV-specific CTL response as measured in vitro. The findings also suggested that the HSV-specific CTL clones able to mediate cross-reactive recognition of the bm3 and bm11 targets had a higher intrinsic avidity for the foreign target than for the inducing antigen.     

T lymphocyte responses to non-H-2 histocompatibility antigens. I. Role of Ly-1+2+ T cells as cytotoxic effectors and requirement for Ly-1+2+ T cells for optimal generation of cytotoxic effectors

Cytotoxic effector T cells specific for non-H-2 histocompatibility (H) antigens were examined for phenotypic expression of lymphocyte differentiation (Ly) antigens. Virtually all H-Y-specific cytotoxic effectors generated in mixed lymphocyte culture were Ly-1+2+ T cells. H-3-specific effectors comprised both Ly-1+2+ and Ly-1-2+ T cells. However, cytotoxic effectors specific for multiple non-H-2 H antigens were predominantly Ly-1-2+ T cells. The optimal generation of H-Y- and H-3-specific effectors required Ly-1+2+ T cells; optimal generation of multiple non-H-2 H antigen-specific effectors required an interaction between Ly-1+2- and Ly-1-2+ T cells. These observations suggest that the identity of the target H antigen in part determines the Ly type of responsive T cells. Our observations suggest that 2 alternative pathways of T cell response exist for non-H-2 H antigens. The first pathway involves an interaction between Ly-1+2- helper T cells and Ly-1-2+ cytotoxic effector precursors. The 2nd pathway simply involves the response of Ly-1+2+ T cells proliferating and generating H antigen-specific cytotoxic effectors.     

Microrecombinations generate sequence diversity in the murine major histocompatibility complex: analysis of the Kbm3, Kbm4, Kbm10, and Kbm11 mutants.

The mechanism that generates spontaneous mutants of the Kb histocompatibility gene was analyzed. Nucleotide sequence analysis of four mutant genes (Kbm3, Kbm4, Kbm10, and Kbm11) revealed that each mutant K gene contains clustered, multiple nucleotide substitutions. Hybridization analyses of parental B6 genomic DNA and cloned class I genes with mutant-specific oligonucleotide probes, followed by sequence analyses, have identified major histocompatibility complex class I genes in the K, D, and Tla regions (K1, Db, and T5, respectively) that contain the exact sequences as substituted into mutant Kb genes. These data provide evidence for the hypothesis that the mutant Kb genes are generated by a microrecombination (gene conversion) mechanism that results in the transfer of small DNA segments from class I genes of all four regions of the major histocompatibility complex (K, D, Qa, and Tla) to Kb. Many of the nucleotides substituted into the mutant Kb genes were identical to those found in other naturally occurring K alleles such as Kd. Thus, we propose that the accumulation of microrecombination products within the K genes of a mouse population is responsible for the high sequence diversity among H-2 alleles.     

H-2Kb mutations limit the CTL response to SV40 TASA

The cytotoxic T lymphocyte (CTL) responses directed towards SV40 tumor-associated specific antigen (TASA) in nine strains of spontaneously arising Kb mutant mice were analyzed. All nine mutants generated normal levels of H-2Db-restricted response, but the K-end-restricted CTL response varied. B6.C-H-2bm1 (bm1) did not produce K-end-restricted SV40 TASA-specific CTL upon immunization, and SV40-transformed bm1 cells were not lysed by intra-H-2 recombinant Kb [B10.A(5R)] CTL. Nonreciprocal cross-reactive lysis was seen between B6-H-2bm8 (bm8) and B10.A(5R). Strain B6-H-2bm8 mice produce highly specific Kbm8-restricted CTL that lyse SV40-transformed bm8 cells (Kbm8SV) but not B10.A(5R) target cells (K5RSV), although Kbm8SV targets can be partially lysed by B10.A(5R) CTL. The other seven Kb mutants cross-react with B10.A(5R). These experiments definitively show that genes mapping to the K and/or D region directly control the H-2-restricted CTL response to SV40 TASA.     

H-2 effects on cell-cell interactions in the response to single non-H2 alloantigens. IV. Variations in the proliferative response to H-Y and H-3

Individual mice were tested for their proliferation T-cell response to H-Y- and H-3-incompatible stimulator cells in secondary mixed lymphocyte culture. Responders expressing the H-2b haplotype were restricted in their response to stimulators presenting H-Y and H-3 in the context of H-2b. Lymphocytes from individual B10 females proliferated in response to H-Y presented with I-Ab and Db. The ratio of I-Ab/Db-restricted responses varied between individual responders, indicating significant qualitative variation between genetically identical responders. The majority of the proliferative response in all tested mice was restricted to the entire H-2b haplotype suggesting complementation of I-Ab- and Db-region genes in presenting the H-Y antigen. Similar observations were made in the response of individual B10.LP mice to the H-3 antigen. H-3-specific, proliferating T cells were restricted to H-3 antigen presented with KbAb and Db with significant variation between individuals in proliferative response to H-3 plus KbAb and Db. In contrast to the response to H-Y, the proliferative response to H-3 plus H-2b could be accounted for by the summation of the proliferative responses to H-3 plus KbAb and Db. These observations demonstrate that the proliferative response to non-H-2H antigens in the context of I-region determinants is not a sine qua non for the T-cell response to these antigens. Further, the individual qualitative and quantitative variation observed with individual genetically identical mice has strong implications for our knowledge of intrastrain variation in immune responsiveness and the characterization of inbred strains for immune responsiveness.     

Specificities of killing by T lymphocytes generated against syngeneic SV40 transformants: studies employing recombinants within the H-2 complex.

T lymphocyte effectors to syngeneic SV40-transformed cells, generated by secondary in vitro sensitization of immune spleen cells, lyse SV40 transformed targets that are syngeneic at the H-2 locus. In this study we have employed recombinants within the H-2 region to examine in detail this H-2 specificity. H-2b effectors were found to lyse SV40-transformed targets from recombinants bearing either H-2Kb or H-2Db.H-2k effectors recognized only SV40-transformed H-2Kk, and not H-2Dk target cells. By using the same protocol for sensitization, no effector cells could be detected in H-2d mice. Effectors generated in H-2 recombinant mice showed that the response capacity resides with K and D. For example, HTG, which is H-2d except at the D locus (H-2Db), produced effector cells specific for SV40-transformed H-2Db targets. Thus, the secondary in vitro response to SV40 transformants was found to depend only on the K and D alleles and not to be modified by the I region to any measurable extent.     

Cell-mediated lympholysis responses against autologous cells modified with haptenic sulfhydryl reagents. IV. Self-determinants recognized by wild-type anti-H-2Kb and H-2Db-restricted cytotoxic T cells specific for sulfhydryl and amino-reactive haptens are absent in certain H-2 mutant strains

Virus-specific H-2-restricted cytotoxic T cells (CTL) have been found to discriminate between wild-type and mutant class I molecules. The only results reported concerning a hapten-self model, however, indicate that TNP-specific CTL do not discriminate between wild-type and mutant self determinants (7). In the present study, hapten-specific CTL generated against N-iodoacetyl-N'-(5-sulfonic-1-naphthyl) ethylene diamine-modified syngeneic cells (AED-self) were used to determine whether a hapten that is known to react with different cell surface sites than TNP can induce CTL that distinguish mutant H-2K and D molecules from those of wild type. The findings of this study indicate that H-2Kb-AED-self cytotoxic effector cells can discriminate between self-determinants of H-2Kb wild-type and the H-2bm1 and H-2bm11 mutants, but not between wild-type and the H-2bm6 and H-2bm9 mutants. H-2Db-AED-self effector cells were also found to discriminate between self-determinants of H-2Db wild-type and the H-2bm13 and H-2bm14 mutants. Furthermore, cold target competition experiments indicated that the bm1 and bm11 Kb products also lack some determinants recognized by anti-wild-type Kb TNP-specific CTL. These findings provide the first demonstration that hapten-self-specific effectors can detect alterations in H-2 mutant class I molecules. The results in the present report also support the hypothesis that haptens do not have to derivatize H-2 molecules in order to form antigens recognized by H-2-restricted CTL. These findings are discussed with respect to the involvement of self-determinants on MHC and non-MHC cell surface molecules.     

Induction in vivo of specific T suppressors in mice of mutant lines H-2KbT

The differences in the generation of specific suppressor T cells (SSTC) against H-2Kb wild type were investigated in H-2Kbm1, H-2Kbm3 and H-2Kbm4 mutants. Anti-Kb SSTC were produced only by bm3 mutant and F1(BALB/c X bm3) hybrid. T-cell nature of SSTC of bm3 mutant was confirmed by anti-Thy 1.2 monoclonal antibodies described in the same study.     

Interaction between Kb and Q4 gene sequences generates the Kbm6 mutation.

Genetic interaction as a mechanism for the generation of mutations is suggested by recurrent, multiple nucleotide substitutions that are identical to nucleotide sequences elsewhere in the genome. We have sequenced the mutant K gene from the bm6 mouse, which is one of a series of eight closely related, yet independently occurring mutants known collectively as the "bg series." Two changes from the Kb gene are found, positioned 15 nucleotides apart: an A-to-T change and a T-to-C change in the codons corresponding to amino acids 116 and 121, resulting in Tyr-to-Phe and Cys-to-Arg substitutions, respectively. Hybridization analysis with an oligonucleotide specific for the altered Kbm6 sequence identifies one donor gene, Q4, located in the Qa region of the H-2 complex. The two altered nucleotides that differentiate Kbm6 and Kb are present in Q4 in a region where Kb and Q4 are otherwise identical for 95 nucleotides, delineating the maximum genetic transfer between the two genes. Because the Kbm6 mutation arose in an homozygous mouse these data indicate that the Q4 gene contains the only donor sequence and demonstrates that Q-region gene sequences can interact with the Kb gene to generate variant K molecules.     

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.