CD4-CD8+ T lymphocytes mediate AKR/gross murine leukemia virus nonresponsiveness in moderately aged AKR.H-2b:Fv-1b mice.

Previously we reported that as AKR.H-2b:Fv-1b mice become older than 9 wk of age they begin to specifically lose the ability to generate anti-AKR/Gross murine leukemia virus (MuLV) CTL responses after immunization and in vitro restimulation with cells expressing AKR/Gross MuLV-encoded Ag. Interestingly, the frequency of virus-specific precursor cytotoxic T lymphocytes (CTL) observed in moderately-aged AKR.H-2b:Fv-1b mice was not substantially decreased from that found in their young responder counterparts. To further investigate the mechanism(s) responsible for the inability of moderately-aged AKR.H-2b:Fv-1b mice to mount AKR/Gross MuLV-specific CTL responses, adoptive transfer experiments were performed in the present study. Transferring splenocytes from moderately-aged AKR.H-2b:Fv-1b donors into young AKR.H-2b:Fv-1b recipients resulted in inhibition of AKR/Gross MuLV-specific CTL responsiveness. Anti-Thy-1.1 plus complement depletion of T cells from the donor cell population before adoptive transfer resulted in a near complete restoration of AKR/Gross MuLV responsiveness of young recipient AKR.H-2b:Fv-1b mice suggesting that the inhibition observed in moderately aged mice was mediated by T lymphocytes. Additional experiments using depletion of T subsets before cell transfer demonstrated that inhibition of AKR/Gross MuLV-specific CTL responsiveness was mediated by a CD4-CD8+ T lymphocyte.     

Mechanism of nonresponsiveness to AKR/Gross leukemia virus in AKR.H-2b:Fv-1b mice. An analysis of precursor cytotoxic T lymphocyte frequencies in young versus moderately aged mice

As young adult AKR.H-2b:Fv-1b mice reach about 9 wk of age, they begin to develop a nonresponsiveness to AKR/Gross leukemia virus. Unlike young mice that are responders, moderately aged AKR.H-2b:Fv-1b mice, after immunization and secondary in vitro restimulation in bulk culture with AKR/Gross virus induced tumors, can not generate anti-AKR/Gross virus-specific CTL. The mechanism of conversion to nonresponsiveness in moderately aged AKR.H-2b:Fv-1b mice is not understood, but it is correlated with increased expression of endogenous ecotropic viral antigens. Our present investigation focuses on determining the frequency of anti-AKR/Gross virus precursor CTL in AKR.H-2b:Fv-1b mice as a function of age. This was achieved by performing limiting dilution cultures of immune spleen cells obtained from young and moderately aged AKR.H-2b:Fv-1b mice. Although spleen cells obtained from immune moderately aged mice can not differentiate in bulk cultures into anti-AKR/Gross virus-specific CTL, there was no evidence of substantially decreased frequencies of virus-specific precursor CTL, relative to precursor CTL frequencies observed in young responder AKR.H-2b:Fv-1b mice.     

Genetic control of the induction of cytolytic T lymphocyte responses to AKR/Gross viral leukemias. II. Negative control by the Fv-1 locus in AKR mice of responder H-2b haplotype

To assess whether the presence of a responder H-2b haplotype would be sufficient to allow mice of nonresponder "high leukemic" phenotype to generate syngeneic anti-AKR/Gross virus cytolytic T lymphocytes (CTL), the AKR.H-2b strain was examined. Although capable of mounting vigorous apparent anti-minor histocompatibility-specific CTL responses, AKR.H-2b mice failed to produce anti-viral CTL after a variety of stimulation protocols. In contrast, the "doubly congenic" AKR.H-2b:Fv-1b strain was able to respond with substantial levels of H-2-restricted anti-AKR/Gross virus CTL activity. These results indicated that Fv-1n alleles could exert negative epistatic control over responder H-2b-encoded gene(s). Because the B6.Fv-1n congenic was also able to generate anti-viral CTL indistinguishable from the prototype B6 strain, however, it was apparent that other genes of AKR background were required for the Fv-1n-mediated inhibition in AKR.H-2b mice. The mechanism by which Fv-1 intereacted with other genes to override positive H-2b control appeared to be related to the expression of the CTL-defined, virus-associated antigens by normal AKR.H-2b cells. Thus, AKR.H-2b spleen cells but not thymus cells were able to stimulate the production of B6 anti-AKR/Gross virus CTL and were recognized as target cells by such anti-viral CTL. In contrast, both spleen cells and thymocytes from AKR.H-2b:Fv-1b mice were negative when tested as stimulator or target cells in these assays. In addition, AKR.H-2b but not AKR.H-2b:Fv-1b spleen cells were shown to display serologically defined gp70 determinants and the Gross cell surface antigen. Taking these data together, it appeared that the inhibition of anti-viral CTL responsiveness might be due to tolerance induced by the cell surface expression of virus-associated antigens by normal AKR.H-2b cells. Widespread display of viral antigens, in turn, may have been due to the permissive effects of Fv-1n on the spread of the early arising N-ecotropic, endogenous AKR leukemia virus controlled by other background genes. In this context, the implications of the multi-gene control of anti-AKR/Gross virus CTL production are discussed with respect to the induction of spontaneous leukemia in the high incidence AKR strain.     

Generation of anti-AKR/gross murine leukemia virus cytotoxic T lymphocytes (CTL). An analysis of precursor CTL frequencies in the AKR.H-2b and C57BL/6 mouse strains.

C57BL/6 mice, after immunization and secondary in vitro restimulation with AKR/Gross murine leukemia virus (MuLV)-induced tumors, generate AKR/Gross MuLV-specific CTL. After similar immunization protocols, AKR-H-2b mice fail to generate CTL specific for AKR/Gross MuLV. The basis for nonresponsiveness in AKR.H-2b mice is unknown, however, unlike C57BL/6 mice, AKR.H-2b mice carry endogenous proviruses and express N-ecotropic viral Ag. Thus, clonal deletion of pCTL populations due to the expression of AKR/Gross MuLV-like Ag is a likely mechanism for the nonresponsiveness. To determine if nonresponsiveness is due to clonal deletion, limiting dilution cultures were performed to assess the presence of pCTL specific for AKR/Gross MuLV. Our study demonstrates that the frequencies of pCTL specific for AKR/Gross MuLV are similar in both the responder C57BL/6 and nonresponder AKR.H-2b strains. The observation that normal levels of AKR/Gross MuLV-specific pCTL exist in AKR.H-2b mice, suggests that clonal deletion of pCTL is not responsible for the inability of AKR.H-2b mice to generate anti-AKR/Gross virus-specific CTL.     

Clonal heterogeneity of anti-AKR/gross leukemia virus cytotoxic T lymphocytes. Evidence for two distinct antigen systems

AKR/Gross leukemia virus-induced tumor reactive cytotoxic T lymphocyte (CTL) clones were derived from C57BL/6 spleen cells. Analysis of their specificity pattern was performed by using a panel of target cells such as E male G2 and AKR.H-2bSL1 (susceptible tumors to polyclonal anti-AKR/Gross virus CTL), and cl. 18-5 and cl. 18-12 (insusceptible variant sublines derived from AKR.H-2bSL1). Several of these CTL clones were selected for further study. Lysis of Gross cell surface antigen-positive tumor cells by these clones was restricted by the H-2Kb molecule. The cell surface phenotype of these clones was Thy-1.2+, Lyt-2.2+, L3T4-, a phenotype consistent with that of polyclonal anti-AKR/Gross CTL, suggesting that they were of conventional CTL origin. According to their fine specificity pattern, the CTL clones were divided into two major groups (A and B) which were further subdivided into five and three subgroups, respectively. The specificity of group A clones was essentially the same as that of the standard polyclonal CTL population except for a variable level of natural killer-like activity by some of the CTL clones. That is, group A clones did not efficiently lyse the insusceptible variant tumors nor any of Friend-Moloney-Rauscher-positive tumors tested, but they showed strong lytic activity to susceptible tumors and iododeoxyuridine-treated insusceptible variants. Thus, their CTL activity appeared to be strictly directed to Gross cell surface antigen-positive tumors that are susceptible to polyclonal anti-AKR/Gross virus CTL. In contrast, group B clones could lyse both susceptible and insusceptible variant tumors and also a Friend virus-induced tumor (FBL3). Therefore, as defined by these CTL clones, at least two distinct antigenic systems (A and B), each with several antigenic determinants, appeared to be present. Because recent findings suggested that most of the polyclonal anti-AKR/Gross virus CTL activity appeared to be directed to N-ecotropic proviral determinants, we further investigated the nature of these two antigenic systems by use of additional target cells including lipopolysaccharide (LPS)-stimulated spleen cell blasts from AKXL recombinant inbred strains and retrovirus-infected fibroblasts. Group A clones could lyse all LPS blasts derived from AKXL recombinant inbred strains containing the AKV-1 proviral genome, but lysed only very insufficiently or did not lyse AKV-1-negative blasts containing the AKV-3 and/or AKV-4 provirus.(ABSTRACT TRUNCATED AT 400 WORDS)     

Mechanism of escape of endogenous murine leukemia virus emv-14 from recognition by anti-AKR/Gross virus cytolytic T lymphocytes.

It was previously shown that spleen cells from endogenous ecotropic murine leukemia virus emv-14+ AKXL-5 mice fail to stimulate an anti-AKR/Gross virus cytolytic T-lymphocyte (CTL) response in a mixed lymphocyte culture with primed C57BL/6 responder spleen cells, whereas spleen cells from AKXL strains carrying the very similar emv-11 provirus do stimulate a response (Green and Graziano, Immunogenetics 23:106-110, 1986). We wished to determine whether the lack of response with AKXL-5 spleen cells was at the level of recognition between effector cell and target cell and whether the relevant mutation was within the emv-14 provirus. It is shown here that EMV-negative SC-1 fibroblast cells transfected with the major histocompatibility complex class I Kb gene and infected with virus isolated from the AKXL-5 strain (SC.Kb/5 cells) were not lysed by H-2b-restricted anti-AKR/Gross virus CTL. SC.Kb cells infected with virus isolated from emv-11+ strains, however, were efficiently lysed by anti-AKR/Gross virus CTL, indicating that there is nothing intrinsic to EMV-infected SC.Kb cells that would prevent them from being recognized and lysed efficiently by anti-AKR/Gross virus CTL. Analysis of virus expression for the infected SC.Kb cells by XC plaque assay and by flow cytometry indicated that emv-14 virus expression for SC.Kb/5 cells was not significantly different from that for emv-11-containing SC.Kb/9 or SC.Kb/21 cells. These data show that the mutation responsible for the lack of CTL recognition and lysis is at the level of recognition between target cell and effector cell. Furthermore, these data strongly suggest that the mutation is within the emv-14 genome. Flow cytometry experiments with monoclonal antibodies against a number of viral determinants indicated that there was no gross mutation detectable in the viral determinants analyzed. The data suggest that the relevant mutation may be a point mutation or a small insertion or deletion within a coding sequence that is critical for CTL recognition.     

Linkage of the Fv-2 gene to a newly reinserted ecotropic retrovirus in Fv-2 congenic mice

Restriction enzyme and Southern gel analyses were used to determine the number and location of endogenous ecotropic retroviruses in the germ line of several mouse strains congenic at the Fv-2 gene locus. A new endogenous ecotropic provirus was observed in the germ line of B6.S (Fv-2ss) mice, in addition to the resident provirus found in its congenic partner C57BL/6 (Fv-2rr). This new provirus was similar in structure to the C57BL provirus. The SIM strain of mice, the donors of the Fv-2s allele in B6.S mice, does not contain ecotropic proviruses, suggesting that the new provirus in the B6.S mouse strain arose by germ-line reintegration during the construction of this strain. Mendelian segregation analysis indicated that this new provirus was linked to the Fv-2 gene locus on chromosome 9. In three other Fv-2s congenic mouse strains--B10.C (47N), B6.C (H-7b), and C57BL/6J Trfa, Bgsd--no additional ecotropic endogenous viruses were detected, suggesting that the reinsertion event that occurred during the construction of B6.S is not essential for the acquisition of the Fv-2s phenotype in the C57BL genetic background. Although numerous reports of germ-line reinsertions of ecotropic virus in high-virus mouse strains have been received, the present results provide definitive evidence that similar germ-line amplifications of endogenous ecotropic virus can occur in a low-virus mouse strain.     

Genetic control of sensitivity to Moloney leukemia virus in mice V. Role of H-2-linked genes in the control of anti-FMR cytolytic T lymphocytes

Three H-2-linked genes, Rmv1, Rmv2, and Rmv3 control the resistance of mice against Moloney virus (MLV)-induced leukemias. It has been shown previously that they function as immune response (Ir) genes regulating the level of antivirus antibodies. In the present experiments, the cell-mediated anti-tumor response has been studied in a series of inbred strains selected for their resistance or sensitivity to the MLV-induced disease. We failed to detect any relationship between resistance and sensitivity and the ability to produce cytolytic T lymphocytes (CTL) directed against the virus-induced FMR cell surface antigen. Furthermore, the role of each Rmv gene has been studied separately using congenic pairs of mice differing at only one of these loci: we failed to evidence any influence of these genes in the cell-mediated antitumor reactions as measured by the ability to lyse syngeneic FMR(+) target cells. Nevertheless a gene mapping in the D region of the MHC but probably different from Rmv3 controls the response of a subset of anti-FMR CTL restricted by the H-2K^k antigens, with higher response in H-2D^d than in H-2D^b animals. This observation confirms the existence of H-2D region associated Ir genes regulating the CTL-mediated antitumor immune responses by choosing the subset of responder CTL, and suggests that a fourth H-2-linked gene plays some role in the genetic control of the anti-FMR immune response.     

H-2-linked control of resistance to Ectromelia virus infection in 1310 congenic mice

Several B 10 strains of mice, recombinant at theH-2 locus, have been shown to differ in their resistance to infection with ectromelia virus, a natural mouse pathogen. Of 10 strains, 1310, B 10.A(2R), B10.A(4R) and B10.D2 were the most resistant, while B10.G and B 10.A(5R) were the most susceptible. Other strains were intermediate between these extremes. Several genes conferring resistance have been mapped toD ^b in B10.A(2R),K ^k I-A ^k I-B ^k in B10.A,I-J ^b in B10.A(2R) and toD ^d in B 10.T(6R). In general, death among susceptible strains was not a consequence of acute liver necrosis as in other non-B10 strains, and occurred randomly from 8–14 days after infection. The exact cause of death is unknown but is characterized by persisting high titers of virus in the spleen and sometimes the liver, despite an ongoing immune response indicated by strong cytotoxic T-cell activity detectable in the spleens of all mice. The most resistant B10 and B10.A(2R) strains cleared virus from the spleen and liver by 8 days after infection. Analysis of infection in chimeric mice indicates thatH-2 genes, which determine susceptibility to virus persistence in the spleen, operate via radiosensitive cells of the lymphomyeloid system. This evidence, together with several examples ofH-2-linked differences in cytotoxic T-cell responsiveness between resistant and susceptible strains, is consistent with the hypothesis that the mechanism by whichH-2 genes control resistance to ectromelia virus in B10 strain mice is by their influence on the effectiveness of a cell-mediated immune response.     

Inability of mice to generate cytotoxic T lymphocytes to vesicular stomatitis virus restricted to H-2Kk or H-2Dk

H-2k mice are unable to generate cytotoxic T lymphocytes (CTL) to vesicular stomatitis virus (VSV). This apparent unresponsiveness is found for both major serotypes of VSV, VSV-Indiana and VSV-New Jersey. CTL unresponsiveness occurs despite the ability of H-2k mice to generate a humoral immune response against VSV that is comparable to that found in responder (H-2b and H-2a) strains. All H-2k mice regardless of background genes, including various Ig allotypes, were found to be nonresponders. H-2k-linked unresponsiveness mapped to both H-2Kk and H-2Dk and occurred despite the presence of responder alleles in (responder x nonresponder)F1 mice. The unresponsiveness cannot be attributed to an inability of VSV-infected H-2k target cells to express viral surface antigens of H-2 molecules. Further, unresponsiveness cannot be overcome by using secondary stimulation in vivo or in vitro. H-2k-linked unresponsiveness does not appear to be due to suppression, and no complementation has been found in various (nonresponder x nonresponder)F1 mice. Thus unresponsiveness to VSV in association with H-2Kk or H-2Dk appears to represent an extensive defect of immune responsiveness that probably occurs because VSV is not a natural mouse pathogen.     

AKR.H-2b lymphocytes inhibit the secondary in vitro cytotoxic T-lymphocyte response of primed responder cells to AKR/Gross murine leukemia virus-induced tumor cell stimulation.

We have previously shown that AKR.H-2b congenic mice, though carrying the responder H-2b major histocompatibility complex haplotype, are unable to generate secondary cytolytic T-lymphocyte (CTL) responses specific for AKR/Gross murine leukemia virus (MuLV). Our published work has shown that this nonresponsive state is specific and not due to clonal deletion or irreversible functional inactivation of antiviral CTL precursors. In the present study, an alternative mechanism based on the presence of inhibitory AKR.H-2b cells was examined. Irradiated or mitomycin C-treated AKR.H-2b spleen cells function as in vitro stimulator cells in the generation of C57BL/6 (B6) anti-AKR/Gross virus CTL, consistent with their expression of viral antigens. In contrast, untreated viable AKR.H-2b spleen cells functioned very poorly as stimulators in vitro. Viable AKR.H-2b spleen cells were also able to cause dramatic (up to > or = 25-fold) inhibition of antiviral CTL responses stimulated in vitro by standard AKR/Gross MuLV-induced tumor cells. This inhibition was specific: AKR.H-2b modulator spleen cells did not inhibit allogeneic major histocompatibility complex-specific CTL production, even when a concurrent antiviral CTL response in the same culture well was inhibited by the modulator cells. These results and those of experiments in which either semipermeable membranes were used to separate AKR.H-2b modulator spleen cells from AKR/Gross MuLV-primed responder cells or the direct transfer of supernatants from wells where inhibition was demonstrated to wells where there was antiviral CTL responsiveness argued against a role for soluble factors as the cause of the inhibition. Rather, the inhibition was dependent on direct contact of AKR.H-2b cells in a dose-dependent manner with the responder cell population. Inhibition was shown not to be due to the ability of AKR.H-2b cells to function as unlabeled competitive target cells. Exogenous interleukin-2 added at the onset of the in vitro CTL-generating cultures partially restored the antiviral response that was decreased by AKR.H-2b spleen cells. Positive and negative cell selection studies and the development of inhibitory cell lines indicated that B lymphocytes and both CD4- CD8+ and CD4+ CD8- T lymphocytes from AKR.H-2b mice could inhibit the generation of AKR/Gross virus-specific CTL in vitro. AKR.H-2b macrophages were shown not to be required to demonstrate AKR/Gross MuLV-specific inhibition, however, confirming that the inhibition by T-cell (or B-cell)-depleted spleen populations was dependent on the enriched B-cell (T-cell) population per se.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of H-2 on neural tube defects in congenic mice.

Pregnant mice congenic with C57BL/10 (B10.A, B10.BR, B10.D2, B10.A[2R], B10.A[5R], B10.A[15Rd, B10.A[1R], B10.A[18R], and B10.0L) were fed Purina Mouse Chow or the same diet plus 200 IU of vitamin A daily. The pregnant dams were sacrificed on the eighteenth day of gestation, and the fetuses were sexed and examined for defects in neural tube development. The frequency of neural tube defects was low (mean frequency of all strains, 0.36%) and was not affected by the addition of vitamin A (200 IU/day) to the diet. Twenty-seven of the 29 defects observed occurred in the anterior tube (exencephaly); fourteen were identified in female fetuses, but the sex could not be determined in the other 15 cases because of fetal death and early autolysis. Variations in frequency among the strains suggest that a locus between E beta and H-2D has a moderate influence on the occurrence of neural tube defects. Strains that had H-2d alleles in this segment of the H-2 complex had relatively high frequencies, and those with H-2b or H-2k alleles had significantly lower frequencies.     

Generation of cytolytic T lymphocytes in vitro. VIII. failure of anti-RS antisera to inhibit the generation of cytolytic T lymphocytes or cytolytic T lymphocyte activity.

Antibody reactive with "recognition structures" (RS) of mouse lymphoid cells for alloantigens (anti-RS) was prepared by immunization of F1 hybrid mice with parentalstrain lymphoid cells or with antibody produced in one parental strain against alloantigens of the other parental strain. Such antisera prevented generation of the "product of antigenic recognition" (PAR) that is produced within a few hours in cultures prepared with a mixture of lymphoid cells from genetically disparate mice. However, treatment of responding lymphoid cells with anti-RS sera and complement did not inhibit generation of cytolytic T lymphocytes (CTL) in mixed lymphocyte cultures (MLC). Treatment of cells obtained from MLC with anti-RS sera and complement failed to inhibit cytolytic activity of such cells for specific alloantigens.     

Adoptive transfer of delayed-type hypersensitivity to Sendai virus. I. Induction of two different subsets of T lymphocytes which differ in H-2 restriction as well as in the Lyt phenotype

This paper investigates kinetics and antigenic and genetic requirements for transfer of delayed-type hypersensitivity (DTH) reactions against Sendai virus. Kinetics of sensitization of effector cells are similar to those described in other virus systems. Maximum DTH response is elicited in the footpad 7 days after sensitization; maximal increase in footpad thickness is found approximately 24 hr after injection of virus and transfer of immune lymphocytes. DTH effector cells are Ig^? and are susceptible to treatment with anti-theta antibody and complement. After transfer of immune lymphocytes a DTH reaction can be elicited by infectious virus, uv light-inactivated virus or cell-cultured Sendai virus which lacks fusion capacity. Requirements of H-2 compatibility are dependent on the biological nature of the virus preparation used for challenge: High doses of infectious or uv light-inactivated Sendai virus require K, D, or IA region compatibility; low concentrations of infectious virus require K and/or D region compatibility, while cell-cultured fusion-negative Sendai virus requires IA region homology. At the level of induction K, D region-restricted DTH-effector T lymphocytes (Td) and cytolytic T lymphocytes (Tc) are stimulated to a greater extent by infectious virus than by uv light-inactivated virus. Furthermore, stimulation of these T lymphocytes is dependent on the route chosen for immunization: intravenous (iv) injection is superior to intraperitoneal (ip) injection; subcutaneous (sc) injection causes the lowest degree of sensitization. IA region-restricted Td lymphocytes are stimulated to comparable amounts by infectious or uv light-inactivated Sendai virus independent of the route of immunization. Td lymphocytes, which require IA region compatibility and Td lymphocytes which require K or D region compatibility can be distinguished by their Lyt phenotype, e.g., IA region-restricted Td lymphocytes are characterized by Lyt-1⁺2^? antigens, while K or D region-restricted Td lymphocytes are phenotypically Lyt-1(⁺)2⁺.     

Cell surface expression of cytotoxic T lymphocyte-defined, AKR/Gross leukemia virus-associated tumor antigens by normal AKR.H-2b splenic B cells

We previously described a system in which H-2Kb-restricted C57BL/6 (B6) cytotoxic T lymphocytes (CTL) could be raised that were specific for tumors, such as the thymic lymphoma AKR.H-2b SL1, that were induced by endogenous AKR/Gross murine leukemia virus and that expressed the Gross cell surface antigen. In this study, certain normal lymphoid cells from AKR.H-2b mice were also found to express target antigens defined by such anti-AKR/Gross virus CTL. AKR.H-2b spleen, but surprisingly not thymus, cells stimulated the production of anti-AKR/Gross virus CTL when employed at either the in vivo priming phase or the in vitro restimulation phase of anti-viral CTL induction. This selective stimulation by spleen vs thymus cells was not dependent on the age of the mice over the range (3 to 28 wk) tested. Both AKR.H-2b spleen and thymus cells, however, were able to stimulate the generation of H-2-restricted B6 anti-AKR minor histocompatibility (H) antigen-specific CTL. Thus, AKR.H-2b spleen cells appeared to display the same sets (minor H and virus-associated) of cell surface antigens recognized by CTL as the AKR.H-2b SL1 tumor, whereas AKR.H-2b thymocytes were selectively missing the virus-associated target antigens, a situation analogous to that of cl. 18-5, a variant subclone of AKR.H-2b SL1 insusceptible to anti-AKR/Gross virus CTL. Like AKR.H-2b thymocytes, neither AKR spleen cells or thymocytes nor B6.GIX + thymocytes were able to stimulate the generation of anti-AKR/Gross virus CTL from primed B6 responder cell populations. In contrast, both T cell-enriched and B cell-enriched preparations derived from AKR.H-2b spleen cells were able to stimulate at the in vitro phase of induction, although B cell-enriched preparations were considerably more efficient. The discordant results obtained with AKR.H-2b spleen cells vs thymocytes were confirmed and extended in experiments in which these cells were employed as target cells to directly assess the cell surface expression of virus-associated, CTL-defined antigens. Thus, AKR.H-2b spleen cells, but not thymocytes, were recognized by anti-AKR/Gross virus CTL when fresh normal cells were tested as unlabeled competitive inhibitors, or when mitogen blasts were tested as labeled targets. Fresh or lipopolysaccharide-stimulated B cell-enriched spleen cells were as efficiently recognized as unseparated spleen cell preparations. Unexpectedly, fresh or Lens culinaris hemagglutinin-stimulated T cell-enriched spleen cell preparations, although susceptible to anti-minor H CTL, were almost as poor as targets for anti-viral CTL as were thymocytes. Together, these results demonstrate the H-2-restricted expression of CTL-defined, endogenous, AKR/Gross virus-associated target antigens by normal AKR.H-2b splenic B cells.(ABSTRACT TRUNCATED AT 400 WORDS)     

Analysis of wild-derived mice for Fv-1 and Fv-2 murine leukemia virus restriction loci: a novel wild mouse Fv-1 allele responsible for lack of host range restriction.

Wild-derived mice originally obtained from Asia, Africa, North America, and Europe were typed for in vitro sensitivity to ecotropic murine leukemia viruses and for susceptibility to Friend virus-induced disease. Cell cultures established from some wild mouse populations were generally less sensitive to exogenous virus than were cell cultures from laboratory mice. Wild mice also differed from inbred strains in their in vitro sensitivity to the host range subgroups defined by restriction at the Fv-1 locus. None of the wild mice showed the Fv-1n or Fv-1b restriction patterns characteristic of most inbred strains, several mice resembled the few inbred strains carrying Fv-1nr, and most differed from laboratory mice in that they did not restrict either N- or B-tropic murine leukemia viruses. Analysis of genetic crosses of Mus spretus and Mus musculus praetextus demonstrated that the nonrestrictive phenotype is controlled by a novel allele at the Fv-1 locus, designated Fv-10. The wild mice were also tested for sensitivity to Friend virus complex-induced erythroblastosis to type for Fv-2. Only M. spretus was resistant to virus-induced splenomegaly and did not restrict replication of Friend virus helper murine leukemia virus. Genetic studies confirmed that this mouse carries the resistance allele at Fv-2.     

Cytotoxic T lymphocyte response to minor H-42a alloantigen in H-42b mice: clonal inactivation of the precursor cytotoxic T lymphocytes by veto-like spleen cells that express the H-42a antigen

When (B10.BR X CWB)F1 (BWF1; H-2k/b) mice carrying the H-42b allele at the minor H-42 locus were injected with H-42a C3H.SW (CSW; H-2b) or C3H (H-2k) spleen cells (SC), self-H-2Kb restricted anti-H-42a pCTL in the BWF1 recipients were primed and differentiated to anti-H-42a CTL after in vitro stimulation with (B10.BR X CSW)F1 (BSF1; H-2k/b, H-42b/a) SC. In contrast, anti-H-42a pCTL in H-42b mice were inactivated by injection with H-42-congenic H-42a SC, and stable anti-H-42a CTL tolerance was induced. Preference of H-2Kb restriction of anti-H-42a CTL was strict, and self-H-2Kb-restricted anti-H-42a CTL did not lyse target cells carrying H-42a antigen in the context of H-2Kbm1. Involvement of suppressor cells in the anti-H-42a CTL tolerance was ruled out by the present cell transfer study and the previous cell-mixing in vitro study. Notably, treatment with anti-Thy-1.2 antibody (Ab) plus complement (C) wiped out the ability of CSW SC in the priming of anti-H-42a pCTL of BWF1 mice but left that of C3H SC unaffected, and injection of the anti-Thy-1.2 Ab plus C-treated CSW SC induced anti-H-42a CTL tolerance in the BWF1 recipients. Furthermore, H-42a/b, I-Ab/bm12 [CSW X B6.CH-2bm12 (bm12)]F1 SC could not prime anti-H-42a pCTL in H-42b, I-Ab (CWB X B6)F1 recipients, whereas H-42a/b, I-Ab (CSW X B6)F1 SC primed anti-H-42a pCTL in H-42b, I-Ab/bm12 (CWB X bm12)F1 recipients. The unresponsiveness of anti-H-42a pCTL in H-42b mice to H-42-congenic H-42a SC was sometimes corrected by immunization of H-42b female mice with H-42-congenic H-42a male SC. Taking all of the results together, we propose the following. Unresponsiveness of anti-H-42a pCTL in H-42b mice to H-42-congenic H-42a SC is caused by "veto cells" contained in the antigenic H-42a SC. Anti-H-42a pCTL in the H-42b recipients directly interacting with H-42-congenic H-42a SC, which bear H-42a antigen and H-2Kb restriction element, are inactivated or vetoed.(ABSTRACT TRUNCATED AT 400 WORDS)