Studies of twoH-2D b mutants: B6.C-H-2 bm13 and B6.C-H-2 bm14

Two new C57BL/6H-2 mutants,B6.C-H- 2^bm13 and B6.C-H- 2^bm14 are described. They arose independently in C57BL/6 as spontaneous mutations of the gain and loss type. Complementation studies map the mutations in both bm13 and bm14 to theH-2D ^b gene. How ever, these two mutant strains are not identical, but occurred as independent mutations at the same locus, as shown by reciprocal graft rejection and by the inability of the (bm13 × bm114)F₁ hybrid to accept C57BL/6 grafts. Serological studies by direct testing (cytotoxicity and hemagglutination) and by quantitative absorption demonstrated a decrease in the H-2D^b private specificity H-2.2 in both bm13 and bm14 when compared to C57BL/6. This was confirmed by SDS-PAGE analysis using antisera detecting the H-2.2 specificity. Attempts to produce antibodies to either the gained or lost specificities of the two mutant strains failed.     

Reactivity of the B6.C-H-2bm−1 mutant to the wild-type tumor EL4: Characterization of the serological response

Hyperimmunization of B6.C-H-2^bm?1 (H-2^bm?1), a congenic mutant of C57Bl/6J (B6), with the C57Bl lymphoma EL4 resulted in the induction of antibodies with apparent EL4 specificity. EL4 reactivity was demonstrable in H-2^bm?1 anti-EL4 sera by complement-mediated cytotoxicity, absorption, and enzyme-linked immunosorbent assay. By these same serological tests, H-2^bm?1 anti-EL4 serum was found to be nonreactive with B6 normal lymphoid cells, embryonic fibroblasts, and two fibrosarcomas previously induced in B6 mice by methylcholanthrene. These data suggest that the serological response of H-2^bm?1 to EL4 is directed against tumor-associated antigens on EL4. These findings indicate that congenic mutants which differ from the wild-type strain at MHC Class I subloci, but which do not evoke serological responses to MHC components, may provide convenient sources for preparing serological reagents directed against tumor-specific antigens.     

Recognition of H-2Kb mutant target cells by Moloney virus-specific cytotoxic T lymphocytes from bm13 (H-2Db mutant) mice. I. Full recognition of Kbm11 by Kb-restricted CTL

In C57BL/6 (B6, H-2b) mice, the secondary in vitro CTL response against Moloney leukemia virus is restricted and regulated by the H-2Db locus. B6.C-H- 2bm13 ( bm13 ) mice, however, carrying a mutation at the Db locus, show an increased H-2Kb-restricted CTL response without a demonstrable CTL component restricted by the mutant Dbm13 molecule (D----K shift). These purely Kb-restricted bm13 virus-specific CTL were incubated with a series of Kb mutant virus-infected target cells to study the effect of the mutations at the target cell level. Of six Kb-mutant virus-infected target cells tested, bm1 cells were not recognized and bm8 cells were recognized only marginally by bm13 virus-specific CTL, whereas bm3 , bm5 , bm6 , and bm11 cells were fully recognized. Thus, the bm3 , bm5 , bm6 , and bm11 Kb mutants fully share the relevant H-2K restriction specificities with H-2Kb, whereas the bm1 mutant totally and the bm8 mutant almost completely lack these specificities. This result differs markedly from the restriction site relationships among B6 and these Kb mutants in other antigenic systems. The most striking example concerns the bm11 mutant, which is fully recognized by Moloney-specific CTL, but not at all by Sendai, minor H (H-3.1, H-4.2), and sulfhydryl hapten-specific CTL. Monoclonal anti-H-2Kb antibody B8-3-24 inhibited virus-specific lysis by bm13 CTL of all Kb virus-infected mutant target cells to which this antibody binds. Lysis of bm5 and bm11 but not of bm3 target cells was inhibited, in line with the fact that B8-3-24 antibody does not bind bm3 . On the other hand, not only bm5 and bm11 but also bm3 virus-infected target cells blocked virus-specific lysis to the same extent as syngeneic bm13 target cells. Therefore, bm13 virus-specific CTL populations do not recognize the discrete cluster alteration in the Kbm3 molecule, as identified by antibody B8-3-24. The bm1 and the bm8 mutations, which have structural alterations in completely different sites of the Kb molecule, show complete or almost complete loss, respectively, of Kb-Moloney restriction sites. This finding supports the notion that these virus-specific CTL recognize conformational determinants rather than linear amino acid sequences.     

Biochemical studies of H-2K antigens from a group of related mutants. II. Identification of a shared mutation in B6-H-2 bm6 , B6.C-H-2 bm7 , and B6.C-H-2 bm9

In an earlier paper, we presented evidence that two independent mutants of the bg series, B6-H-2 ^bm5 (bm5) and B6-H-2 ^bm16 (bm16) carry identical mutations such that tyrosine at residue number 116 of the H-2K^b molecule from the parent strain C57BL/6Kh is replaced by a phenylalanine in each of the two mutant molecules. In this paper, we demonstrate, using similar techniques, that the independent bg series mutants B6-H-2 ^bm6 (bm6), B6.C-H-2 ^bm7 (bm7), and B6.C-H-2 ^bm9 (bm9), which share biological properties with bm5 and bm16, can be grouped together because they share two identical mutations, one of which is common to bm5 and bm16, a Tyr to Phe interchange at residue number 116. In addition, a second mutation is at residue number 121, where a Cys in the H-2K molecule from 136 is substituted with an Arg in the mutant. Since all of the bg series mutants arose independently and share biological and biochemical characteristics, it is anticipated that study of these mutants could lead to some understanding of the high mutation rate in the K^b molecule.     

The definition of a new IA antigenic specificity using the B6.C-H-2 bm12 I-region mutant strain

A new Ia specificity has been defined using theIA-subregion mutant B6.C-H-2 ^bm12. The immunization to produce the antiserum wasbm12 anti-A.BY, as all other immunizations, such asbm12 anti-C57BL/6, failed to produce antibody. By selecting strains of C57BL origin for testing, it was shown that, (a) the serum was only weakly cytotoxic but gave substantial reactions using a rosetting assay; (b) the antibody reacted with B cells and not T cells; (c) strains of theb, d, p andq H–2 haplotypes were positive, whereasf, k, r ands were negative; (d) absorption studies demonstrated only a single specificity to be present and by testing recombinant strains, the reaction mapped to theIA subregion; (e) SDS-PAGE demonstrated that the antiserum reacted with a molecule of MW 33 000. Preliminary studies indicate this new specificity, present on C57BL/6 and lost frombm12, is present on the same molecule as other I-A specificities.This work was supported by funds obtained from the N. H. and M. R. C. (Australia) and the National Institutes of Health, Grant No. CA-21224.     

Haplotype-specific suppression of antibody responses in vitro. III. Haplotype-specific suppressor factor (TsF-H) binds to but fails to suppress responses by the I-A mutant strain B6.C-H-2bm12

Spleen cells from C57BL/6 and B6.C-H-2bm12 mice, both responder strains to GAT, differ in their ability to be suppressed by the monoclonal I-A-restricted, nonantigen-specific, but haplotype-specific suppressor factor, TsF-H, from the hybridoma 266A4.5. Whereas GAT-specific responses by C57BL/6 spleen cells are susceptible to TsF-H-mediated suppression, responses by bm12 spleen cells are nonsuppressible under the same conditions. Responses of both C57BL/6 and bm12 spleen cells are suppressed by monoclonal GAT-specific suppressor factors. The inability of TsF-H to suppress responses by the bm12 spleen cells presumably reflects the effects of the mutation in the beta-chain of the I-A antigen in this strain on the required I-A restriction between TsF-H and target cell for manifestation of suppressive activity. The data are discussed in terms of involvement of I-A or recognition of I-A in mediating suppression.     

Biochemical studies of H-2K antigens from a group of related mutants. I. Identification of a shared mutation in B6-H-2 bm5 and B6-H-2 bm16

Structural studies of the H-2 gene products from a group of five closely related but independent C57BL/6 H-2 mutant mice were undertaken. Each of the mutants exhibits reciprocal graft rejection with the parent. The group is remarkable, however, because each member of this group can accept skin grafts from any other member. The results of biochemical analysis of the H-2 glycoproteins from two of these related mutants, bm5 and bm16, are presented in this report. Evidence is given that the H-2K molecules from these two mutants are identical to each other based on comparative tryptic peptide mapping profiles with the parent. From partial amino acid sequence analysis, K products of both mutants have at least one common difference from the parental type located at residue number 116. Definitive studies established that in both bm5 and bm16 a tryosine found in the parent molecule is substituted with a phenylalanine in the mutant. These results show that a biochemical difference between the K products of the two mutants and of the parent can be detected, that the mutants appear to be identical with one another even though they arose independently, and that they differ from the other H-2K ^b mutants analyzed.Abbreviations used in this paper B6 C57BL/6Kh - bm5 B6-H-2^bm5 - bm6 B6-H-2 ^bm6 - bm7 B6.C-H-2 ^bm7 - bm9 B6.C-H-2 ^bm9 - bm16 B6-H-2 ^bm16 - D H-2D - K H-2K - MHC major histocompatibility complex     

Restriction in adoptive transfer of resistance to Listeria monocytogenes. II. Use of congenic and mutant mice show transfer to be H-2K restricted

Adoptive transfer of cell-mediated immunity to the facultative intracellular bacterium Listeria monocytogenes is restricted by the H-2 complex of mice. Using C57BL/10 and C57BL/6 congenic strains of mice it was shown that compatibility of the H-2K locus, not the I region, was essential and sufficient for adoptive transfer and that H-2D compatibility was not relevant. Mutation at the H-2K locus prevented adoptive transfer, while mutation at the Ia-1 locus, as in the B6.C-H-2bm12 mutant of C57BL/6, did not affect adoptive transfer. The contrast between these findings and the previously accepted I region restriction of adoptive transfer of Listeria immunity is discussed.     

Studies ofH-2K b mutant mice

Three newH-2 ^b mutant strains, B6.C-H-2 ^bm9 , B6.C-H-2 ^bm10 and B6.C-H–2 ^bm11 , are described. The three mutant strains are of the gain and loss type as they reject skin grafts reciprocally with the parental C57BL/6Kh. The mutations, which arose independently, are all allelic at the same locus as 11 other mutant strains already described. By complementation and other studies the mutated gene has been shown to beH-2K ^b . The strains were typed directly and by absorption with antisera specific for H-2K^b and H-2D^b private and public specificities and for Ia^b specificities. Each strain typed differently with these sera. The strain B6.C-H-2 ^bm9 was found to be serologically identical with C57BL/6. The strains B6.C-H-2 ^bm10 and B6.C-H-2 ^bm11 were found to have alterations in the private H-2K^b specificity, H-2.33, and in the public specificity, H-2.5, but to a different extent. B6.C-H- 2^bm10 had a marked decrease in the amount of H-2.33 expressed on the splenic cell surface as compared to C57BL/6 and also has a marked decrease in the expression of H-2.5 on both spleen and red blood cells. In comparison, B6.C-H-2 ^bm11 has a decrease in the expression of H-2.33 but an increase in the expression of H-2.5 on both splenic and red blood cells. The other H-2^b specificities appeared to be unaltered as compared with C57BL/6.     

T cell responses to select Ia determinants using the I-A mutant mouse strain B6.C-H-2bm12

The T cell repertoire of B6.C-H-2bm12 mice (an I-A mutant mouse strain) to wild-type Iab antigens was investigated using both secondary proliferative cultures and cloned T cell lines. Because bm12 mice have a gain-loss mutation of their gene encoding the Ia beta-chain polypeptide, bm12 anti-B6 T cell responses are specific for the select component of Iab specificities that was lost as a result of the mutation. Although stimulator cells bearing Iab antigens elicited the strongest responses, Iaq, d, and s antigens also resulted in reproducible stimulations of these bm12 anti-B6-primed T cells. Cloned T cell lines isolated from bm12 anti-b6 cultures revealed similar findings, with most clones recognizing determinants unique for Iab antigens; however, clones showing cross-reactions with Iad and/or q were also selected. Using F1 hybrid responder T cells (mutant x cross-reactive strain), we further dissected this cross-reactivity into several distinct cross-reactive determinants. Because bm12 mice lack the serologically defined Ia differentiation antigen W39, T cell recognition of this determinant was investigated by using bm12 anti-B6-primed cells. Stimulation by Ia.W39+ cells was appreciably better than by Ia.W39- (Xid-defective) cells, suggesting that bm12 T cells recognize an Xid-regulated, W39-like Ia differentiation antigen.     

Genetic analysis of anH-2 mutant,B6.C-H-2 ba,using cell-mediated lympholysis: T- and B-cell dictionaries for histocompatibility determinants are different

B6.C-H-2 ^ba [H (z1)] is a mutant derived from C57BL/6. The two strains mutually reject their skingrafts and are incompatible in the mixed leucocyte reaction (MLR) and in cell-mediated lympholysis (CML) assays. They are serologically indistinguishable. This report shows that H(z1) carries a new, privateK end CML specificity clearly distinguishable from that of B6 by a third party strain, HTG. Antisera directed against the private H-2K specificity of B6 present on H(z1) cells) can block CML between the two strains in either direction. The new CML specificities of H(z1) cross-react with (public) CML specificities controlled by bothK andD regions of other unrelated haplotypes. The results suggest that H(z1) carries a mutation in theH-2K locus itself or in a closely linked gene, the product of which is also physically associated with the H-2K molecule corresponding to the cis-configuration of the alleles in both loci. These findings indicate that T- and B-cell dictionaries for histocompatibility determinants are different.     

Molecular analysis of antigen recognition by insulin-specific T-cell hybridomas from B6 wild-type and bm12 mutant mice.

Molecular analysis of the heterodimeric T-cell antigen receptor of insulin-specific class II-restricted T-cell hybridomas (THys) derived from C57BL/6 (B6) wild-type and B6.C-H-2bm12 (bm12) mutant mice revealed that such T cells use a diverse V gene repertoire. Analysis of three THys that use related V genes, however, showed a number of novel features. Two THys that share major histocompatibility complex restriction use V alpha genes that are 98.6% homologous. Two THys sharing the same antigen fine specificity use a particular germ line V beta D beta J beta combination. A 21-base-pair deletion in the 5' segment of the J beta gene occurs in one THy, suggesting a novel mechanism for generating diversity in T-cell antigen receptor beta genes. The first amino acid encoded by N sequences at the V-D junction is conserved in a pair of T cells which recognize identical antigenic epitopes. The implications of these findings for the structural mechanisms underlying major histocompatibility complex-restricted antigen-specific T-cell recognition are discussed.     

Interaction of H-2Db with mutant histocompatibility gene H (KH-11) in the mouse

The detectable presence of H (KH-11)b, a mutant non-H-2 histocompatibility gene, was previously shown to depend upon the simultaneous presence, in the skin-graft donor, of both the mutant gene and the H-2b haplotype. The experiments reported here demonstrate that H-2Db is the essential element of H-2b for this interaction. Of two H-2Db histocompatibility mutations, H-2bm13 can replace H-2Db in this interaction, but H-2bm14 cannot.     

The congenic mutant B6.C-H-2bm-1 (H-2bm-1) serological response to the T-cell receptor on EL4

Antisera reactive with the C57Bl lymphoma EL4 were induced by hyperimmunization of B6.C-H-2bm-1 (H-2bm-1) mice, a congenic mutant strain of C57Bl/6 (B6). Molecular weight determinations of EL4 surface structures detected with the congenic mutant antibodies were accomplished by electrophoretic analyses (one and two dimensions) on sodium dodecyl sulfate-polyacrylamide gels (SDS-PAGE). Analysis of immunoprecipitates in the first dimension under reducing conditions revealed protein bands corresponding to gp 70 and its 33-kDa cleavage fragment, and two-three bands (40-45 kDa) that overlapped with those precipitated from EL4 with AS 8177, an antiserum which detects framework determinants on the T-cell heterodimeric receptor. Further analysis by diagonal electrophoresis confirmed identity of the 40- to 45-kDa proteins precipitated from EL4 with either AS 8177 or H-2bm-1 anti-EL4 sera. Additional diagonal electrophoretic studies showed that the congenic mutant antibodies do not precipitate T-cell receptor molecules from C6VL, an in vitro line derived from the C6XL T-cell lymphoma of C57Bl/ka origin, which was previously shown by some of us to express the heterodimeric T-cell receptor. Together these results demonstrate detection of the heterodimeric T-cell receptor on EL4 with congenic mutant antibodies directed against nonconstant region determinant(s), and indicate a possible linkage between MHC haplotype and the immune response to intraspecies variable regions of the T-cell receptor.     

Failure or success in the restoration of virus-specific cytotoxic T lymphocyte response defects by dendritic cells

C57BL/6 (B6, H-2b) mice are CTL responders to both Sendai virus and Moloney leukemia virus. In the former response the H-2Kb class I MHC molecule is used as CTL restriction element, in the latter response the H-2Db molecule. B6 dendritic cells (DC) are superior in the presentation of Sendai virus Ag to CTL in comparison with B6 normal spleen cells. Con A blasts have even less capacity to present viral Ag than NSC, and LPS blasts show an intermediate capacity to present viral Ag. H-2Kb mutant bm1 mice do not generate a CTL response to Sendai virus, but respond to Moloney leukemia virus, as demonstrated by undetectable CTL precursors to Sendai virus and a normal CTL precursor frequency to Moloney virus. Compared to B6 mice, other H-2Kb mutant mice show decreased Sendai virus-specific CTL precursor frequencies in a hierarchy reflecting the response in bulk culture. The Sendai virus-specific CTL response defect of bm1 mice was not restored by highly potent Sendai virus-infected DC as APC for in vivo priming and/or in vitro restimulation. In mirror image to H-2Kb mutant bm1 mice, H-2Db mutant bm14 mice do not generate a CTL response to Moloney virus, but respond normally to Sendai virus. This specific CTL response defect was restored by syngeneic Moloney virus-infected DC for in vitro restimulation. This response was Kb restricted indicating that the Dbm14 molecule remained largely defective and that a dormant Kb repertoire was aroused after optimal Ag presentation by DC. In conclusion, DC very effectively present viral Ag to CTL. However, their capacity to restore MHC class I determined specific CTL response defects probably requires at least some ability of a particular MHC class I/virus combination to associate and thus form an immunogenic complex.     

Biology of cloned cytotoxic T lymphocytes specific for lymphocytic choriomeningitis virus. I. Generation and recognition of virus strains and H-2b mutants

Cytotoxic T lymphocytes (CTL) were induced in C57BL/6 and (C57BL/6 X DBA/2)F1 mice after immunization with the Armstrong strain of lymphocytic choriomeningitis virus (LCMV-Arm) and were cloned by limiting dilution in vitro. The cytotoxic activity of these clones was LCMV specific and H-2 restricted. All clones induced in C57BL/6 (H-2b) mice with LCMV-Arm lysed target cells infected with each of five distinct strains of LCMV (Arm, Traub , WE, Pasteur, and UBC ), suggesting recognition of common regions of viral proteins in association with H-2b molecules. In contrast, one clone obtained from (B6 X D2)F1 mice and restricted to the H-2d haplotype only lysed cells infected with one of three strains of virus (Arm, Traub , WE) but not two others (Pasteur, UBC ), suggesting recognition of variable regions of viral proteins in the context of H-2d molecules. To assess the fine specificity for H-2 molecules, we tested H-2Kb-restricted CTL clones for their ability to kill LCMV-infected target cells bearing mutations in their H-2Kb, and we tested clones presumed to be restricted to the H-2Db region for their ability to all LCMV targets cells bearing a mutation in the H-2Db region. Several different patterns of killing of the mutant targets were observed, indicating that a number of different epitopes on the H-2b molecules were used as restricting determinants for LCMV antigen recognition by CTL. Thus, cross-reactive viral determinants were recognized in the context of several different restricting determinants. Mutations in the N or C1 domains of the H-2 molecule affected recognition by a single LCMV specific CTL clone. One implication of this result is that CTL recognize a conformational determinant on the H-2 molecule formed by the association of virus antigen(s) with H-2. An alternate explanation is that one site on the H-2 molecule is involved in the interaction of viral antigens with H-2, whereas another may serve as a binding site for the CTL receptor.     

Biochemical studies on the H-2K mutant B6.C-H-2 bm10

The H-2K glycoprotein from the MHC mutant bm10 was analyzed biochemically to determine where primary structural differences distinguished it from the parental standard molecule, K^b. Comparative peptide maps showed differences in two peptides known to be part of the parental CNBr fragment spanning amino acids 139 to 228. Partial sequence analyses of CNBr fragments and tryptic peptides identified two tightly clustered amino acid substitutions at amino acids 165 (Val to Met) and 173 (Lys to unknown). The substitutions in bm10 represent the most carboxy-terminal substitutions characterized in the K^b molecules of the spontaneous, histogenically active H-2 mutants.     

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.     

Ia specificities on parental and hybrid cells of an I-A mutant mouse strain

Splenic B cells and B cell blasts from the I-A mutant mouse strain B6.C-H-2bm12 were tested by serology with a series of new monoclonal anti-Iab antibodies. Four out of 5 of those monoclonal antibody-defined specificities that are determined by wild-type I-Ab antigens were undetectable on B6.C-H-2bm12 cells. Specificities both present and absent on mutant cells appear to be determinants on the same wild-type molecule, as indicated by sequential precipitation experiments with soluble H-2b antigens. The lack of expression of certain Ia specificities on mutant cells was found not to be the result of disparate control by the Xid gene, which was previously shown to control the expression of Ia.W39, another specificity absent in B6.C-H-2bm12 mice. Serologic testing of Ia specificities on cells and blasts from F1-hybrid mice suggested that the Iabm12 antigens are codominantly expressed, indicating a failure to detect trans regulation or complementation of the mutant phenotype. Another monoclonal antibody-defined Ia specificity dependent on the expression of the E beta polypeptide was normally expressed in B6.C-H-2bm12 mice. These data thus suggest that the lesion of these mutant mice occurred in the A alpha and/or A beta structural gene, resulting in the loss of several Ia specificities.     

Role of dendritic cells in the regulation of class I restricted cytotoxic T lymphocyte responses

Two class I MHC mutant mouse strains, bm14 and bm13, differ from the strain of origin B6 in one and three amino acids in the alpha 1 and alpha 2 domains of the H-2Db molecule, respectively. These alterations result in specific failure to generate a CTL (Tc) response to the male-specific Ag H-Y. Immunization and/or restimulation in vitro with syngeneic male dendritic cells (DC), expressing very high levels of class I MHC molecules, restored the H-Y-specific Tc response of bm14 but not of bm13 mice. Serologically Db determinants were lost in normal spleen cells of both mutants, because FACS analysis showed a decreased binding of Db domain-specific mAb. Although bm13 DC show a higher fluorescence than bm13 normal spleen cells it is still strongly reduced (30 to 50%) in comparison with B6 DC. Surprisingly, bm14 DC show an equally very strong binding compared with B6 DC with these mAb. The quantitative expression of class I molecules on APC thus appears to be a major determinant in the regulation of Tc responses. In addition, immunization with DC markedly influenced the target cell specificity of the ensuing Tc response. The combined data clearly demonstrate that besides the highly efficient class II-restricted presentation of Ag to Th, shown previously, DC are also superior in the presentation of Ag in the context of class I molecules to Tc. bm14 DC are capable of directly activating H-Y-specific Lyt-2+ Tc memory cells without the need for L3T4+ Th. These biologic effects of DC can at least in part be explained by their very high class I MHC expression. Moreover, these results reiterate that class I MHC Db mutants and different APC can be used to study the contribution of specific class I domains to Tc recognition and restriction specificity.