Preferential response patterns of cytotoxic T lymphocytes specific for fluorescein isothiocyanate-[FITC] modified autologous cells

Murine cytotoxic responses to TNP-modified syngeneic cells (TNP-self) have been shown to exhibit preferential recognition of K or D end self products encoded by the H-2 complex. In the present study, a number of B10 congenic and recombinant mouse strains were investigated to determine the H-2K and H-2D-restricted FTC-self CTL response patterns, and these were compared with the CTL response patterns obtained for TNP-self. The results indicate that for strains possessing the H-2k,d,h2,h4 haplotypes, respectively, preferential CTL responses were observed against FTC recognized in association with Kk over Dk, Dd over Kd, and Kk over Db. These patterns of preferential CTL responses were the same as those reported for TNP-self as well as several anti-viral CTL responses. In contrast to the results obtained in the B10.A strain, in which Kk preference was observed over Dd for TNP-self CTL, no preferential CTL response was observed when FTC was recognized in association with Kk and with Dd. In this context, it was observed that the CTL response to FTC recognized in association with Dd was particularly strong. This strong D end-associated response was shown to involve D locus products, and no evidence was obtained indicating that L locus self products were involved. These studies are discussed with respect to the possibility that different haptens can be recognized by CTL in association with different self determinants encoded by the same H-2 gene products.     

Generation of the alloreactive T cell repertoire: K region homology between H-2b T cell precursors and T cell maturation environment is required for the generation of the Kbm6-specific cytotoxic T cell repertoire

The influence of T cell genotype and T cell maturation environment on the generation of the T cell alloreactive repertoire was evaluated in the H-2b cytotoxic T lymphocyte response to Kb mutant determinants expressed by the strain B6-H-2bm6. Specifically, by constructing radiation bone marrow chimeras with B6 or B10 (H-2b) donor cells and B10.BR, B10.A(4R), B10.MBR, and B6.C-H-2bm1 irradiated mice as recipients, it was possible to investigate the major histocompatibility complex (MHC)-encoded gene products of the host environment required for the generation of a bm6-specific H-2b CTL response. The results of such experiments confirmed the previous finding that the alloreactive T cell repertoire is influenced both by T cell MHC genotype and by the MHC gene products of the T cell maturation environment. In addition, the results of the present study further demonstrated that in the chimeric donor and host genetic combinations used, it was both necessary and sufficient that there be a homology of K region-encoded determinants for the generation of a bm6-specific CTL response. Experiments utilizing a mixed responder population of unresponsive B6----B10.D2 spleen cells and responsive Lyt-2 congenic B6.Lyt-2.1 spleen cell suggested that the cellular defect(s) underlying the unresponsiveness of the chimeric cells to bm6-encoded determinants was at the level of the CTL precursor. Together, these findings indicate that an interaction of the K region-encoded gene products of the T cell and its maturation environment play a critical role in the generation of the CTL repertoire specific for bm6 mutant determinants. We discuss here the possibility that this interaction may reflect a requirement that T cells recognize such mutant allodeterminants in association with self restriction elements present on the same mutant K region-encoded molecule.     

Suppression of anti-hapten antibody responses by hapten-specific cytolytic T lymphocytes: role of I-A-associated antigen on target B lymphocytes

Cytolytic T lymphocytes (CTL) specific for 2,4,6-trinitrophenyl (TNP) determinants suppress the effector phase of a secondary anti-TNP antibody responses of murine syngeneic spleen cells in vitro. The cells mediating this suppression are hapten-specific, H-2-restricted, and possess properties typical of CTL. Moreover, the targets of the suppression appear to be antigen-primed B lymphocytes that are recognized by CTL via soluble antigen bound noncovalently to their Ig receptors. The effect of the CTL can be blocked by the addition of monoclonal antibodies directed against I-A molecules but not I-E or H-EK-encoded molecules on the target B cells, even in strain combinations in which the CTL-B cell interaction is restricted only by the H-2K and I regions of the MHC. This result suggests that B lymphocyte-bound antigen tends to associate preferentially with I-A rather than H-2K/D-encoded determinants, and that the suppressive effect of the CTL population is attributable to the minor subset that recognizes hapten-modified Ia antigens. These findings are also discussed in terms of the possible immunoregulatory function of Ia-restricted CTL.     

H-41, a new minor histocompatibility locus. I. Histogenetic analysis

The B10.STA12 mouse congenic line inherited from the wild mouse parent not only the H-2w13 haplotype but also an allele at a minor H locus, which we designate H-41. This allele (H-41a) differentiates the B10.STA12 line from B10.STA10 and B10.LIB55, which carry identical H-2w13 haplotypes but a different H-41 allele (the H-41b, also present in the background strain C57BL/10Sn). The B10.STA12 and B10.STA10 lines reject each other's skin grafts and generate cytolytic T lymphocytes (CTL) after in vivo immunization and in vitro restimulation with cells of the partner strain. The B10.STA12 anti-B10.STA10 CTL react with B10.STA10, B10.LIB55, and B10.STA39 target cells and with cells of F1 hybrids between the responder strain B10.STA12 and strains C57BL/6, C57BL/10, C57L, BALB/c, A, AKR, WB, DBA/1, and DBA/2 but fail to react with (C3H x B10.STA12) F1 and (CBA x B10.STA12) F1 cells. The B10.STA10 anti-B10.STA12 CTL react with B10.STA12, B10.P, and C3H.NB cells but fail to react to (B6 x B10.STA10) F1 target cells. The CTL reactivity in both combinations is Dp restricted. The B10.STA10 anti-B10.STA12 CTL exhibit, in addition, a cross-reactivity with B10.SAA48 cells that may be directed at one of the alloantigens controlled by the H-2 haplotype of this strain.     

CTL and serologically defined antigens of B2m,H-3 region

The antigens of the B2m,H-3 region of 13 chromosome 2 congenic strains and seven inbred strains have been studied by using CML and serologic techniques. Nine patterns of cross-reactivity have been defined by CML assays. These results are in agreement with an extend previously described cross-reactivity studies. The reactivities of three monoclonal antibodies previously thought to be reacting with B2M-B are shown to differ: Ly-m11 and J-5 react with cells of strain B10-pa,at and clone 23 does not. Two H-3 region loci are hypothesized on the basis of CML and serologic activity: B2m and H-3. The CTL responses to the B2M antigens are H-2K restricted; the CTL responses to H-3 antigens are H-2D restricted. The restriction of the response to the H-3 antigen requires effector-target identity of the H-2D molecule but not the B2M molecule of the class I antigen. These loci have been separated by recombination from H-42 in the production of the congenic strain B10.FS-a. A gene order of B2m, H-3, H-42 is suggested.     

Regulatory mechanisms in cytotoxic T lymphocyte development. III. Induction, specificity, and genetic restriction of an in vitro suppressor T cell

We addressed questions pertaining to the immunogenetics of an in vitro alloinduced suppressor T cell (Ts) previously shown to inhibit cytotoxic T-lymphocyte (CTL) development by suppressing CTL precursor proliferation. Using intra-MHC recombinant strains of B10 congenic mice, the requirements for H-2 differences to induce Ts activity, the antigen specificity of the Ts, and the genetic restriction of Ts function were studied. It was found that differences at the K, D, or I regions alone can induce strong suppressor activity. Suppression of CTL development does not appear to be genetically restricted since the Ts inhibit CTL from responder cells disparate at K, K and D, I, or K and I. The alloinduced Ts is specific for the antigen stimulating its induction, but also inhibits CTL responses against immunologically unrelated determinants, even between class I and class II antigens, provided those determinants are carried on cells expressing the original inducing antigen. Ts can be triggered by antigens present on the responder cells but absent on the stimulator cells, indicating that the suppressive signal may be exerted directly on the responder population without specific interaction with stimulator cells.     

Polymorphism of minor histocompatibility genes in wild mice

H-2^b-restricted cytolytic T lymphocytes (CTL) were generated against H-1, H-3, and H-4 antigens and tested against target cells of F₁ hybrids between wild mice and inbred H-2 ^b mice. The congenic strain combinations for the CTL production were such that they tested one allele each at the H-1 and H-4 loci and four alleles at the H-3 locus. Most of the wild mice tested came from Southern Germany, but a few mice came from other European countries and Egypt and Israel. Virtually all wild mice typed as positive with CTL directed against H-3^b and H-4^b antigens; 32% of the F₁ hybrids tested reacted with anti-H-1^cCTL and 9% reacted with anti-H-3^d CTL. The positive results were not caused by cross-reaction with allogeneic H-2 antigens controlled by the major histocompatibility complex (Mhc) genes of the wild mice. At least some of the H-3 and H-4 antigens detected by the CTL in the F₁ hybrid were not identical with antigens of the immunizing strains. These results suggest a relatively low degree of polymorphism of the tested minor H loci in wild mice and further support the notion that minor H loci are unrelated to the Mhc.     

Specificity of the mouse cytotoxic T lymphocyte response to adenovirus 5. E1A is immunodominant in H-2b, but not in H-2d or H-2k mice

The Ag specificity and MHC restriction of the CTL response to adenovirus 5 (Ad5) in three strains of mice, C57BL/10 (H-2b), BALB/c (H-2d), and C3H/HeJ (H-2k), were tested. Polyclonal Ad5-specific CTL were prepared by priming mice in vivo with live Ad5 virus followed by secondary in vitro stimulation of the spleen cells with virus-infected syngeneic cells. The Ad5-specific CTL were Db restricted in C57BL/10 and Kk restricted in C3H/HeJ. In BALB/c mice both Kd- and Dd/Ld-restricted CTL were detected. The polyclonal Ad5-specific CTL response in C57BL/10 mice is directed exclusively against the products of the E1A region, which comprises only 5% of the Ad5 genome. In BALB/c mice E1A is at best a very minor target Ag and in C3H/HeJ mice E1A is not recognized at all. Using the H-2 congenic mouse strains B10.BR (H-2k) and C3H.SW (H-2b) it was shown that the immunodominance of E1A is H-2 dependent. The 19-kDa glycoprotein encoded in the E3 region of Ad5, which binds to class I MHC in the endoplasmic reticulum and prevents its translocation to the cell surface, does not affect the specificity of the CTL response in C57BL/10 mice toward E1A. However, it affects the MHC restriction of the Ad5-specific response in BALB/c mice, selectively inhibiting generation of Kd-restricted CTL.     

Pretreatment with minor histocompatibility antigens prevents the development of functional CTL helper cell activity

We have been studying the regulation of allogeneic cytotoxic cells (CTL) in vivo. CBA/J (H-2k, mls d) responder mice are unable to develop CTL after an allogeneic footpad immunization if they are pretreated i.p. with spleen cells from either C3H/HeN (H-2k, mls c) or B10.BR (H-2k, mls b) mice. These mouse strain combinations are H-2 compatible but differ at the Mls and other minor histocompatibility loci. We reported that this state of CTL unresponsiveness is specific and that the allogeneic cells used for footpad immunization and the pretreatment strain must share both minor antigens and part of the MHC. In this paper, we describe some of the characteristic features of this CTL unresponsiveness. The CBA host plays an active role and appears to down-regulate its subsequent response against minor antigens after the initial pretreatment. This statement is based on the following: 1) The inhibition of in vivo CTL generation can be achieved by injecting F1 or irradiated C3H cells, i.e., under conditions where GVHD was not a factor; and 2) the state of unresponsiveness is abolished by host treatment with cyclophosphamide. In addition, we demonstrate that the lack of CTL development in pretreated responder animals is the result of impaired helper cell activity. Draining LNC from unresponsive mice can become functionally cytolytic if cultured in a Con A-activated spleen cell supernatant. However, normal CTL responses were not restored after adult thymectomy or splenectomy. Thus, the state of CTL inhibition that is induced by the minor antigen pretreatment is the result of a host-mediated regulatory circuit.     

Cytotoxic T lymphocyte response to minor H-43a alloantigen in H-43b mice. Privileged H-2Kb restriction to the response is not due to immunodominance or epistatic effect but due to Ir gene function of H-2Kb itself

Previous study demonstrated that anti-H-43a cytotoxic T lymphocyte (CTL) response of H-43b CWB (H-2b) stain carrying non-major histocompatability complex (MHC) genes of C3H and F1 strains raised by crossing CWB with various H-43b strains was restricted exclusively by self H-2Kb (Kb). In the present study, newly produced C3W strain (H-2k, H-43b), which is H-43-congenic to C3H/HeN (H-2k, H-43a), was used as H-43b mice, and possibility of immunodominance of Kb was examined. No anti-H-43a CTL response could be induced in C3W strain and F1 strains raised by crossing C3W with other H-43b strains not carrying Kb. Thus, the possibility of immunodominance of Kb over the other MHC class I alleles could not be supported. We also examined possibility of epistatic effect of I region genes and non-MHC genes on the Kb restriction. (C3W x C57BL/6)F1(I-Ak/b) and (C3W x B6.CH-2bm12)F1(I-Ak/bm12)mice showed equally anti-H-43a CTL response restricted exclusively by self Kb, and (C3W x B10.MBR)F1(Ik/k) mice also showed anti-H-43a CTL response restricted solely by self Kb. Cold target competition experiments demonstrated that H-43b C57BL/10 or A.BY mice, which do not have non-MHC genes of C3H mounted anti-H-43a CTL response restricted solely by self Kb. Thus, no relation of I region genes or non-MHC genes to the Kb restriction was shown. All the results indicate that H-43b mouse strains, including F1, can not achieve anti-H-43a CTL response unless they carry Kb allele. Notably, (C3W x C57BL/6)F1 mice mounted self Kb-restricted anti-H-43a CTL response, whereas (C3W x B6.CH-2bm1)F1 mice carrying mutated Kb could not mount anti-H-43a CTL response at all. These findings indicate strongly that Kb itself is classical Ir gene of anti-H-43a CTL response and directs self Kb restriction of the response.     

Virus specificity of cytotoxic T lymphocytes generated during acute lymphocytic choriomeningitis virus infection: role of the H-2 region in determining cross-reactivity for different lymphocytic choriomeningitis virus strains

We have compared the relatedness of five different strains of lymphocytic choriomeningitis virus (LCMV) as assessed by LCMV-specific cytotoxic T lymphocytes (CTL). Several different mouse strains were injected with each of the five LCMV strains, and the cross-reactivity of virus-specific CTL generated during the acute infection was tested by killing on a panel of target cells infected with the various LCMV strains. We found that the cross-reactivity pattern of LCMV-specific CTL generated in mice of H-2d haplotype (BALB/c WEHI and DBA/2) was strikingly different from that in mice of H-2b haplotype (C57BL/6 and C3H.Sw/Sn), suggesting that the fine specificity of LCMV-specific CTL is a function of the H-2 region. The characteristic cross-reactivity patterns were also observed in (C57BL/6 X DBA/2)F1 mice, demonstrating that the repertoire of the H-2b- and H-2d-restricted LCMV-specific CTL is not changed as a result of complementation by gene products of the other major histocompatibility haplotype. Studies with congenic BALB.B10 and (BALB.B10 X BALB/c)F1 mice firmly established that the characteristic cross-reactivity patterns of LCMV-specific CTL map to the H-2 region and are not influenced by background genes outside the major histocompatibility locus. These results suggest that LCMV determinants seen in the context of H-2d-restricting elements are different from those seen in the context of H-2b-restricting elements. Moreover, our studies show that CTL can be used as probes for dissecting differences among various LCMV strains, but the degree of relatedness between the different LCMV strains is not absolute when measured by CTL recognition. Since the H-2 region regulates the fine specificity of CTL generated during LCMV infection in its natural host, the degree of cross-protective immunity developed during a viral infection apparently depends on the major histocompatibility haplotype. The importance of these findings lies in understanding susceptibility or resistance of various host populations to viral infections and in designing vaccination programs to provide immunity.     

Expression of CTL-defined, AKR/Gross retrovirus-associated tumor antigens by normal spleen cells: control by Fv-1, H-2, and proviral genes and effect on antiviral CTL generation

In previous studies we have characterized H-2-restricted cytolytic T lymphocytes (CTL) type specific for Gross cell surface antigen-positive tumor cells induced by AKR/Gross leukemia viruses. The generation of such CTL was shown to be controlled by at least three genetic loci including H-2 and Fv-1. The Fv-1n phenotype was able to negate positive immune response gene effects of the H-2b haplotype. Fv-1n-mediated inhibition appeared to operated by allowing the early expression by normal cells of N-ecotropic leukemia virus-related antigens recognized by the antiviral CTL, perhaps via tolerance induction. In the present study, the expression of CTL-defined viral antigens by normal cells is further considered. Possible gene dosage effects by H-2 as well as Fv-1 and the other virus-related (V) genes, including proviral structural loci, were examined by comparison of a panel of congenic and F1 mice. These experiments indicated that the quantitative level of expression of CTL-defined viral antigens was primarily controlled by the Fv-1 genotype. Gene dosage effects were also observed for the V genes and, in some situations, for H-2. The importance of the early display of viral antigens by normal cells was underscored by the inability of those mice to generate specific antiviral CTL responses. Even strains expressing low levels of viral antigens, such as responder X nonresponder (AKR.H-2b:Fv-1b X AKR.H-2b)F1 mice, failed to respond. These results are discussed with respect to the inability of mice of the AKR background to respond with specific antiviral CTL generation and in light of their high incidence of spontaneous leukemia.     

Cytolytic T cells activated by H-2-controlled E molecules cross-react with A molecules

Cell-mediated lymphocytotoxicity was generated in four strain combinations differing only by the cell-surface expression of the class II E molecule controlled by the H-2 complex. The four combinations were: B10.D2(R107) anti-B10.A(3R), B10.A(4R) anti-B10.A(2R), B10.GD anti-B10.D2(R101), and B10.S(7R) anti-B10.S(9R). In all four of these combinations, the stimulator expresses E molecules on the cell surface, while the responder does not. The cytolytic T lymphocytes generated in the B10.D2(R107) anti-B10.A(3R) and B10.A(4R) anti-B10.A(2R) combinations reacted not only with the stimulator but also with strains that do not express cell-surface E molecules, in particular, strains carrying the H-2 ^f and H-2 ^q haplotypes. The cross-reactivity with E-negative strains could be blocked by monoclonal antibodies specific for the A^f or A^q molecules but not by antibodies recognizing determinants on E or class I (K) molecules. The anti-H-2^f cross-reactivity could be inhibited by H-2 ^q cold targets and, reciprocally, the anti-H-2^q reactivity could be blocked by H-2 ^f cold targets. These findings are interpreted as indicating that the cytolytic T lymphocytes stimulated by E molecules can recognize and lyse cells lacking E molecules but expressing A molecules. The observed E-A cross-reactivity supports the notion of structural and functional relatedness between the A and E molecules and suggests a common evolutionary origin of the A- and E-encoding loci.     

An early event in murine cytomegalovirus replication inhibits presentation of cellular antigens to cytotoxic T lymphocytes.

Cytomegalovirus (CMV) infection of simian virus 40 (SV40)-immune mice inhibits priming of SV40-specific helper and cytotoxic T lymphocytes (CTL) in vivo (A. E. Campbell, J. S. Slater, and W. S. Futch, Virology 173:268-275, 1989; J. S. Slater, W. S. Futch, V. J. Cavanaugh and A. E. Campbell, Virology 185:132-139, 1991). We now demonstrate that murine CMV (MCMV) infection of SV40-transformed macrophages and fibroblasts prevents presentation of SV40 T antigen to SV40-specific CTL. MCMV-infected macrophages failed to stimulate SV40-immune CTL precursors in vitro. In addition, MCMV-infected, SV40-transformed macrophage and fibroblast target cells lost their susceptibility to lysis by major histocompatibility complex class I-restricted, SV40-specific CTL clones. MCMV infection did not alter the synthesis of SV40 T antigen in the target cells. MCMV early gene expression was required for inhibition of SV40 T-antigen presentation; immediate-early gene expression was insufficient for this effect. Early viral gene expression also resulted in significant reduction of H-2K and H-2D molecules on the surface of MCMV-infected fibroblasts. However, this reduction occurred independently from suppression of antigen presentation to CTL. The same target cells which were resistant to lysis by SV40 CTL were susceptible to lysis by MCMV-specific CTL. MCMV early gene products therefore interfere with the processing and/or presentation of SV40 T-antigen determinants to CTL independent of alterations in the major histocompatibility complex.     

Induction of class I MHC-restricted, peptide-specific cytolytic T lymphocytes by peptide priming in vivo

The present study investigated the possibility that protein Ag fragments in the form of peptides could serve as the priming Ag in the generation of a MHC class I-restricted immune response. Trypsin-digested chicken ovalbumin (OVA-TD) fragments were used as the model Ag. The results demonstrate the peptides within OVA-TD, when injected into C57BL/6 mice, could prime T cells which lysed H-2b Ia-EL4 target cells in an OVA-TD-specific manner. In contrast to priming with OVA-TD, immunization of mice with intact OVA did not lead to generation of CTL against OVA-TD or OVA. Furthermore, target cells sensitized with intact OVA failed to be recognized by OVA-peptide-specific CTL indicating that the target cells serving as APC were unable to generate the relevant peptide determinants recognized by the T cells. These results support the idea that the processing pathway within APC for class I-restricted T cells may differ from that used for class II-restricted T cells. Using OVA-TD-specific CTL clones (phenotypically Thy 1+, CD8+, CD4-, Pgp-1+) isolated from primed animals to screen OVA-TD fractions separated by HPLC, two T cell peptide determinants were identified corresponding to OVA sequences 111-122 and 370-381. Both determinants were recognized by CTL clones in the context of the H-2Db molecule.     

The target minor H antigen for F1 cytotoxic T lymphocytes induced by Igh-congenic parental spleen cells is coded for by gene linked to H-2

Graft-vs-host reaction (GvHR) induced in (B10.BR X CWB)F1 (BWF1; H-2k/b, Ighb/b) by i.v. injection with CWB (H-2b, Ighb) spleen cells resulted in complete suppression of cytotoxic T lymphocyte (CTL) responsiveness of the F1 host spleen cells (GvHR-associated immunosuppression). In contrast, GvHR induced in BWF1 mice with CSW (H-2b, Ighj; Igh-congenic to CWB) spleen cells did not affect CTL responsiveness of the F1 host spleen cells at all. The BWF1 hosts undergoing the CSW-induced GvHR generated anti-CSW CTL in their spleens, and the subsequent culture of such BWF1 spleen cells with CSW stimulator cells, augmented the CTL activity. The BWF1 anti-CSW CTL lysed both Con A- and LPS-induced splenic blasts from mouse strains carrying the Ighj allele in the context of self H-2Kb. However, determination of the Igh haplotype in the serum IgG and of the susceptibility of the splenic lymphocytes to the BWF1 anti-CSW CTL on backcross mice, which carry either Ighb/j or Ighb/b in the context of H-2b/b or H-2b/k, showed clearly that Ighj and the gene coding for the target antigen for the BWF1 anti-CSW CTL segregated at ratios close to 1:1. The study in which linkage between the gene(s) coding for the target antigen for the BWF1 anti-CSW CTL and H-2 was examined on CWB X (C3H X CWB)F1 backcross mice and (B10.BR X CSW)F1 X B10 mice demonstrated that the gene, most likely a single gene, coding for the target antigen for the BWF1 anti-CSW CTL is located at 8.5 +/- 4.3 cross-over units to the right or left of the H-2 complex. We designated the minor H antigen to be recognized by the BWF1 anti-CSW CTL as H-X+, and we discuss the distinction between the H-X+ locus and the other minor H loci on chromosome 17.     

Characterization of the Fas ligand/Fas-dependent apoptosis of antiretroviral, class I MHC tetramer-defined, CD8+ CTL by in vivo retrovirus-infected cells

C57BL/6 (B6; H-2(b)) mice mount strong AKR/Gross murine leukemia virus (MuLV)-specific CD8(+) CTL responses to the immunodominant K(b)-restricted epitope, KSPWFTTL, of endogenous AKR/Gross MuLV. In sharp contrast, spontaneous virus-expressing AKR.H-2(b) congenic mice are low/nonresponders for the generation of AKR/Gross MuLV-specific CTL. Furthermore, when viable AKR.H-2(b) spleen cells are cocultured with primed responder B6 antiviral precursor CTL, the AKR.H-2(b) cells function as "veto" cells that actively mediate the inhibition of antiviral CTL generation. AKR.H-2(b) veto cell inhibition is virus specific, MHC restricted, contact dependent, and mediated through veto cell Fas ligand/responder T cell Fas interactions. In this study, following specific priming and secondary in vitro restimulation, antiretroviral CD8(+) CTL were identified by a labeled K(b)/KSPWFTTL tetramer and flow cytometry, enabling direct visualization of AKR.H-2(b) veto cell-mediated depletion of these CTL. A 65-93% reduction in the number of B6 K(b)/KSPWFTTL tetramer(+) CTL correlated with a similar reduction in antiviral CTL cytotoxicity. Addition on sequential days to the antiviral CTL restimulation cultures of either 1) AKR.H-2(b) veto cells or 2) a blocking Fas-Ig fusion protein (to cultures also containing AKR.H-2(b) veto cells) to block inhibition demonstrated that AKR.H-2(b) veto cells begin to inhibit B6 precursor CTL/CTL expansion during days 2 and 3 of the 6-day culture. Shortly thereafter, a high percentage of B6 tetramer(+) CTL cocultured with AKR.H-2(b) veto cells was annexin V positive and Fas(high), indicating apoptosis as the mechanism of veto cell inhibition. Experiments using the irreversible inhibitor emetine demonstrated that AKR.H-2(b) cells had to be metabolically active and capable of protein synthesis to function as veto cells. Of the tetramer-positive CTL that survived veto cell-mediated apoptosis, there was no marked skewing from the preferential usage of Vbeta4, 8.1/8.2, and 11 TCR normally observed. These findings provide further insight into the complexity of host/virus interactions and suggest a fail-safe escape mechanism by virus-infected cells for epitopes residing in critical areas of viral proteins that cannot accommodate variations of amino acid sequence.     

Helper effects required during in vivo priming for a cytolytic response to the H-Y antigen in nonresponder mice

Induction of H-Y-specific cytotoxic T lymphocyte (CTL) responses in nonresponder female mice was attempted by i.v. injection of allogeneic male cells, followed by in vitro restimulation of recipient spleen cells with syngeneic male cells. Responses were obtained only in two strain combinations in which the recipients, although phenotypically nonresponders, carried responder alleles at class I major histocompatibility complex (MHC) loci, and the immunizing cells differed from the recipients at class II MHC loci. The two positive strain combinations were B10.A(2R) anti-B10.A(4R), and B10.GD anti-B10.D2(R101). In the first combination, both recipient and donor are nonresponders to H-Y, and the CTL are induced via a bystander effect of another CTL response to a previously undetected minor histocompatibility (H) antigen. This "carrier" antigen can only induce CTL against H-Y and itself when the immunizing cells express class II MHC molecules. Furthermore, the presence of H-Y and the carrier antigen on the same cell is a prerequisite for the generation of H-Y-specific CTL. In the second combination, the recipient is a nonresponder, whereas the donor is a responder. The two strains differ at only E alpha and E beta class II MHC loci. For the induction of CTL, H-Y and the foreign E molecule must be expressed on the same cells. Thus, the B10.D2(R101) cells that express E molecules on their surface probably provide the E-nonexpressor B10.GD recipients with a stimulus for the generation of H-Y-specific T helper cells. The data are consistent with the notion that antigen-specific class II MHC-restricted T helper cells are involved in the initiation of CTL responses to minor H antigens.