Theiler's murine encephalomyelitis virus (TMEV)-induced demyelinating disease in mice is influenced by the H-2D region: correlation with TEMV-specific delayed-type hypersensitivity

Intracranial inoculation of Theiler's murine encephalomyelitis virus (TMEV) leads to the development of a chronic demyelinating disorder in certain mouse strains. Development of this disease is controlled by at least two unlinked genes, one of which is within or linked to the H-2 complex. In the present study, we attempted to map the relevant H-2 loci involved in susceptibility to TMEV-induced demyelination using crosses between SJL and several congenic H-2 recombinant mouse strains bearing different combinations of MHC genes from the susceptible H-2s and resistant H-2b haplotypes all on the C57BL/10 strain background. The data suggest that the D region of the H-2 complex strongly influences development of the demyelinating disease because increased susceptibility correlates well with homozygosity for H-2s alleles in the D region, but not in K or I-A. In addition, we also attempted to correlate certain immune and nonimmune pathophysiologic parameters with the development of clinical disease. Specifically, central nervous system TMEV titers and TMEV-specific humoral and cellular [delayed-type hypersensitivity (DTH) and T cell proliferative (Tprlf)] responses were examined. The data show that TMEV-induced demyelinating disease did not correlate with either CNS TMEV titers or TMEV-specific humoral or Tprlf responses but did correlate closely with the presence of high levels of TMEV-specific DTH. Collectively, our findings demonstrating a strong correlation between disease incidence, the presence of particular H-2D region genotypes, and high levels of TMEV-specific DTH in susceptible strains (as well as previous findings showing predominant mononuclear cell infiltrates in CNS demyelinating lesions) support the hypothesis that the disease is immune mediated rather than a result of direct cytolytic effects of virus infection.     

Genes of the H-2 complex regulate the antibody response to murine leukemia virus

The influence of the major histocompatibility complex of the mouse (H-2 complex) on the antibody response against murine leukemia virus (MuLV) was investigated after 3 different ways of virus presentation (milk transmission of virus, spontaneous virus activation, and immunization with inactivated virus). The antibody response against MuLV was measured in the sera of H-2 congenic C57BL V+ sublines (V+ denotes positive for milk-transmitted MuLV), (B10.AV+ X C57BL)F1 mice, (C57BL X AKR)F1 mice and of C57BL animals after immunization with inactivated AKR virus. The pattern of immune responsiveness of the different C57BL strains to MuLV was independent of virus replication and was similar for the 3 ways of virus presentation. Serum antibody levels were controlled by 2 genes within the H-2 complex. The first gene (Ir-MuLV-1) was located in the I-A region and was complemented by a second gene (Ir-MuLV-2), which was situated in the regions to the right of the I-B region. Presence of 2 responder alleles (Ir-MuLV-1+,2+) led to an optimal antibody response (H-2b haplotype). Animals that only expressed a responder allele in the I-A region (Ir-MuLV-1+,2-) were intermediate responders. Animals lacking a responder allele in the I-A region (Ir-MuLV-1-,2+ or Ir-MuLV-1-,2-) were low responders.     

Functional analysis of cloned macrophage hybridomas. VI. Differential ability to induce immunity or suppression

We previously screened a series of macrophage hybridomas derived from fusion of P388D1 (H-2d) tumor cells with CKB (H-2k) splenic adherent cells for their ability to induce I-J restricted Ts cell responses. One Ia+ macrophage clone (63) consistently induced Ag-specific, I-J-restricted Ts. To evaluate whether macrophage hybridoma 63 also induced delayed-type hypersensitivity (DTH) immunity, mice were immunized with hapten-coupled macrophage hybridoma cells. Hapten-coupled splenic adherent cells and control macrophage hybridomas induced significant primary DTH responses, whereas hapten-coupled macrophage 63 induced little or no immunity when injected into H-2 compatible hosts. However, macrophage hybridoma 63 specifically activated I-Ak, I-Ad, or I-Ed restricted T cell hybridomas/clones, in vitro in the presence of appropriate Ag. Three different strategies designed to eliminate suppressor cell activity were successfully used to demonstrate that hapten-coupled macrophage 63 could also induce in vivo immunity. First, after immunization with hapten-coupled macrophages, mice were treated with cyclophosphamide. Second, macrophage 63 was treated with anti-IJ idiotype antibody before 4-hydroxy-3-nitrophenyl acetyl hapten (NP) coupling. Finally, haptenated macrophages were injected into I-A compatible but I-J incompatible recipients. These protocols are known to inhibit the induction of Ts activity, thus these results indirectly suggest that there is stimultaneous generation of Ts activity in vivo. The latter hypothesis was tested in adoptive transfer experiments. Transfer of lymph node cells from NP-63 primed B10.BR (H-2k) mice induced immunity in naive 4R animals, whereas the same number of immune cells suppressed NP-induced DTH responses in 5R mice. The combined results indicate that a cloned macrophage line can activate both Th and Ts cells. Macrophages which induce Ts activity may be responsible for maintaining the balance of immunity vs suppression. The data support the hypothesis that IJ interacting molecules (IJ-IM) expressed on macrophages are critical for induction of suppressor cell activity.     

Genetic restrictions of transfer of delayed-type hypersensitivity to sheep erythrocytes: local versus systemic transfer.

Regulation of the transfer of delayed-type hypersensitivity (DTH) reactions to SRBC was studied using two assays. In the systemic transfer, SRBC immune cells were transferred intravenously and the recipient challenged by injecting antigen into the footpad. In the local transfer assay, SRBC immune cells were mixed with antigen before transfer into the footpad of the recipient. These studies utilized B10.D2 and B10.BR mice which are congenic strains differing only at H-2 region. DTH reactions can be transferred across H-2 barriers using a local transfer assay. When the immune cells were transferred intravenously or depleted of adherent cells prior to local transfer, DTH reactions cannot be transferred to an H-2 congenic recipient. Spleen cells from naive mice syngeneic to the intravenously transferred cells supply the necessary accessory cell when mixed with the antigen prior to injection into the footpad. This accessory cell may be a macrophage.     

Genetic restriction of delayed-type hypersensitivity to tuberculin in mice

An adoptive local transfer method has been used to study the immunological features and genetic restriction of cell interaction during the development of the delayed-type hypersensitivity (DTH) to tuberculin in mice. Peritoneal cells from the BCG-infected mice transfer the DTH to intact animals (into hind footpad) in both syngeneic and allogeneic donor-recipient combinations. Nonadherent cells (macrophage-deleted) transfer the reaction in syngeneic but not allogeneic combination. The use of H-2 recombinant mouse strains demonstrated that successful transfer of the DTH requires I-A subregion compatibility. Treatment of CBA cells with anti-Thy-1.2 antiserum abrogates the reaction transfer. These results indicate that antigen presentation to immune T-cells proliferating during DTH to tuberculin is mediated through the molecular products of the I-A subregion.     

Intra-H-2 recombination in the mouse. III. I-Region characterization of haplotypes H-2at2, H-2at3 and H-2a2

Serological characterization of three K-S interval recombinant strains, TBR2 (H-2at2), TBR3 (H-2at3) and AIR 1 (H-2a2) was performed using anti-H-2, Ia, Ss and Slp antisera. The data presented here reveal that the crossover events in both TBR2 and TBR3 occurred between the I-A and I-E subregions. In both cases, the H-2K and I-A subregions were derived fron the H-2t1 of chromosome, while the I-E, S and H-2D regions were derived from the H-2b chromosome (KsAkEbSbDb). The H-2a2 chromosome resulted from a crossover event between the H-2a1 and H-2i9 chromosomes. Ia and Ss typing of AIR 1 suggested that the K to I-E regions originated from H-2a1 and the S and D regions originated from H-2i9 (KkAkEkSbDd).     

In vivo priming of mouse CTL precursors directed to product of a newly defined minor H-42 locus is under a novel control of class II MHC gene

In a previous study, we discovered a new mouse minor histocompatibility antigen encoded by a locus at 8.5 cM apart from the H-2 complex, and we have since named the locus H-42. One allele of H-42, which is named H-42a, had been elucidated, but the other alleles, which we tentatively named H-42b, have not been elucidated. In the present study, we explored MHC control on the anti-H-42a cytotoxic T lymphocyte (CTL) responsiveness in H-42b mice. In vivo immunization (i.v. injection) of H-42b mice with 5 to 30 X 10(6) spleen cells (SC) bearing allogeneic H-42a antigen but carrying H-2 complex (mouse MHC) matched with the H-42b mice failed to prime anti-H-42a CTL but induced stable and specific anti-H-42a CTL unresponsiveness, i.e., tolerance, in the H-42b recipient mice. In contrast, H-2 heterozygous H-42b F1 mice injected with SC bearing H-42a alloantigen on either of the parental H-2 haplotypes were effectively primed to generate anti-H-42a CTL. Exploration of the region or subregion in the H-2 complex of H-42a donor SC that should be compatible with H-42b recipient mice for the induction of their anti-H-42a CTL tolerance demonstrated that the compatibility at I region, most probably I-A subregion, but not at K, S, or D region, determined the induction of the tolerance. MHC class II compatible H-42a skin graft (SG) to H-42b mice, however, consistently primed the anti-H-42a CTL in the H-42b recipients. These results were discussed in several aspects, including uniqueness of MHC class II control on the CTL response to minor H-42a antigen, possibility of inactivation of responding anti-H-42a precursor CTL or helper T cells in H-42b mice by encountering the veto cells present in MHC class II-matched H-42a SC population, and significance of the present observations as a mechanism of CTL tolerance to self-components.     

Delayed hypersensitivity in mice infected with reovirus. I. Identification of host and viral gene products responsible for the immune response

Delayed-type hypersensitivity (DTH) can be demonstrated in mice infected with reovirus by challenging primed animals in the footpad with virus. Maximal responses occur 7 days after immunization with as little as 10(5) viral particles. DTH to reovirus is transferable by lymph node cells and is mediated by T cells as the transfer of reactivity can be abrogated by treatment of cells with anti-Thy 1.2 plus complement. DTH to reovirus is serotype specific, animals infected with reovirus type 1 or 3 only develop DTH responses when challenged with the same serotype with which they were infected. Using recombinant viral clones containing genes from both parental serotypes, we have demonstrated that the S1 gene, the gene encoding the viral hemagglutinin, determines serotype specificity. Furthermore, in adoptive transfer experiments between mice of varying histocompatibility backgrounds, it was found that D or K, IA-IB region identity was required for the transfer of reactivity. These studies demonstrate that specific host and viral genes determine the in vivo cellular immune response to reovirus and should allow a more precise definition of the host cellular immune response to viral antigens.     

H-2 homology requirements for secondary cell-mediated lympholysis and miced lymphocyte reactions to TNP-modified syngeneic lymphocytes.

Secondary cell-mediated lympholysis (CML) and mixed lymphocyte reactions (MLR) were generated in a tissue culture system against trinitrophenyl (TNP)-modified murine syngeneic spleen cells. H-2 homology between primary and secondary TNP-modified stimulating cells was required in order to restimulate in the secondary CML. Strong proliferative responses (MLR) were detected only in the secondary cultures, for which H-2 homology was also required between TNP-modified primary and secondary immunogens. Intra-H-2 mapping for the secondary MLR indicated that the relevant regions of homology were I, D, and K and/or I-A. Homology throughout the entire major histocompatibility complex or at K plus I-A gave stronger MLR than did cultures in which there was homology between the primary and secondary phases at I or D only.     

Activation or suppression of bactericidal activity of macrophages during a graft-versus-host reaction against I-A and I-J-region differences, respectively

Systemic graft-versus-host reactions (GVHR) were induced in F1 heterozygous mice by injecting 10(8) parental lymphocytes. The Anti-Thy 1.2-sensitive, T-cell mediated activation of macrophages was assessed by their increased capacity to destroy a facultative intracellular bacterium Listeria monocytogenes. The difference in MHC regions causing a GVHR that induced high levels of macrophage activation mapped to I-A. In contrast, differences at K or D, in any of the other H-2 subregions or in the non-H-2 background, including Mls alone or in combination, did not induce a GVHR leading to macrophage activation, unless these differences were combined with a difference at I-A. The numbers of parental cells needed to activate macrophages via a GVHR caused by I-A vs. non-I-A differences, varied at least 30- to 100-fold. When parental cells were injected into F1 offspring of parents differing at I-J, growth of Listeria was enhanced significantly; this negative effect on macrophages was not seen when parental combinations differing at I-A alone were compared with those differing at I-A plus I-J or I-J plus other H-2 regions.     

Synergism of T lymphocyte subsets in the response to Mls-locus coded antigens during graft-versus-host reaction

After transplantation of lymphoid cells into lethally irradiated (semi)allogeneic mice specific anti-host directed effector T cells are generated. This can be demonstrated using a delayed type hypersensitivity (DTH) assay. In H-2 compatible combinations, Mls-locus antigens, but no other minor histocompatibility antigens, can induce the generation of such effector T cells. This paper shows that maximal anti-host DTH responses are obtained when the lymphoid cells transplanted constitute of a mixture of long-lived, recirculating T2 cells and short-lived, sessile T1 cells. It was demonstrated that anti-Mls locus-directed DTH effector T cells are the progeny of T2 cells, and that T1 cells amplify this response. The latter, however, are by themselves incapable of displaying anti-Mls DTH reactivity. The T1 cells were found to be of the Lyt-1+2+ phenotype, and the T2 cells of the Lyt-1+2- phenotype. The same Lyt phenotypes were found for T1 and T2 cells synergizing in the GvH reaction against H-2 alloantigens.     

Genetic control of the murine immune response to cholera toxin

This study was undertaken to determine whether previously noted differences in the immune response of inbred strains of mice to cholera toxin (CT) might be under immune response gene control. A series of inbred, congenic, and intra-H-2I region recombinant mouse strains were tested for responsiveness to CT after i.p. immunization with 0.1 micrograms CT in alum. Samples of plasma were collected at intervals before and after priming and boosting. IgG and IgA anti-CT were measured by ELISA. In three different sets of congenic strains, the level of IgG anti-CT clearly depended on the H-2 haplotype of the strain rather than on any background or Igh genes. Strains with the H-2b and H-2q haplotypes were high responders, and strains with the H-2k, H-2s and H-2d haplotypes were low responders. Within the H-2 complex, the IgG anti-CT response was mapped to the I-A subregion with the use of congenic intra-H-2I region recombinant strains. In contrast to these results with IgG anti-CT, plasma IgA anti-CT levels were uniformly low and indeterminate. We conclude that the murine IgG anti-CT response is controlled by a locus within the I-A subregion of H-2--a remarkable finding, considering the known abilities of this toxin to bind to and to directly stimulate lymphocytes.     

Regulation of antitubercular immunity in mice by genes of the H-2 complex

Development of DTH reaction and survival time after M. tuberculosis H37Rv infection have been studied in H-2 congenic and recombinant mice pretreated with high doses of BCG vaccine. In addition, in vitro proliferation of lymphocytes from infected CBA, B6 and 4R mice to PPD was studied in the presence of anti-I-A and anti-I-E mAbs. High doses of BCG vaccination (1 mg/mouse) have led to a significant inhibition of DTH and diminution of survival time in B10.M (H-2f) mice only, and to opposite effects in all other strains tested (H-2a, b, d, k, h4). In I-A+, I-E- 4R mice anti-I-Ak mAbs abrogated lymphocyte proliferation to PPD completely, while in I-A+, I-E- CBA mice only the mixture of anti-I-Ak and anti-I-Ek mAbs was effective.     

Anti-bacterial immunity to Listeria monocytogenes in allogeneic bone marrow chimera in mice

Protection and delayed-type hypersensitivity (DTH) to the facultative intracellular bacterium Listeria monocytogenes (L.m.) were studied in allogeneic and syngeneic bone marrow chimeras. Lethally irradiated AKR (H-2k) mice were successfully reconstituted with marrow cells from C57BL/10 (B10) (H-2b), B10 H-2-recombinant strains or syngeneic mice. Irradiated AKR mice reconstituted with marrow cells from H-2-compatible B10.BR mice, [BR----AKR], as well as syngeneic marrow cells, [AKR----AKR], showed a normal level of responsiveness to the challenge stimulation with the listeria antigens when DTH was evaluated by footpad reactions. These mice also showed vigorous activities in acquired resistance to the L.m. By contrast, chimeric mice that had total or partial histoincompatibility at the H-2 determinants between donor and recipient, [B10----AKR], [B10.AQR----AKR], [B10.A(4R)----AKR], or [B10.A(5R)----AKR], were almost completely unresponsive in DTH and antibacterial immunity. However, when [B10----AKR] H-2-incompatible chimeras had been immunized with killed L.m. before challenge with live L.m., these mice manifested considerable DTH and resistance to L.m. These observations suggest that compatibility at the entire MHC between donor and recipient is required for bone marrow chimeras to be able to manifest DTH and protection against L.m. after a short-term immunization schedule. However, this requirement is overcome by a preceding or more prolonged period of immunization with L.m. antigens. These antigens, together with marrow-derived antigen-presenting cells, can then stimulate and expand cell populations that are restricted to the MHC (H-2) products of the donor type.     

Two distinct high immune response phenotypes are both controlled by H-2 genes mapping K or I-A

Murine responses to immunization with 2, 4, 6-trinitrophenyl (TNP) conjugated to autogenous mouse serum albumin (MSA) in complete Freund's adjuvant (CFA) are controlled by a gene(s) in the K or I-A region of H-2 complex. High immune responses of both H-2d and H-2b mice have been mapped to this region of the major histocompatibility complex. No modifying effects were observed from genes to the right of I-A in either responder haplotype. High responsiveness controlled by Kb or I-Ab is inherited with complete or partial recessivity, depending on the route of immunization and the sex of the responder. However, high responsiveness controlled by Kd or I-Ad is inherited dominantly. This unusual pattern of inheritance of immune responsiveness to TNP-MSA is consistent with the genetic mapping to K or I-A. TNP-MSA-specific T-cell reactivity following immunization with TNP-MSA in vivo was examined utilizing a T-cell-dependent proliferation assay in vitro with cells obtained from high or low responder mice. Genetic mapping and mode of inheritance in this assay for antigen-specific T-cell reactivity corresponded with results obtained from a plaque-forming cell (PFC) assay measuring antibody production by B cells. Both the proliferative and PFC responses are probably under the same Ir gene control. Both gene dosage effects and Ir-gene-product interaction could influence the generation of specific immune responsiveness in F1 hybrids between high and low responders to TNP-MSA.     

The generation of effector T cells in influenza A-infected, cyclosporine A-treated mice

Specific effector T cells that mediate DTH to influenza virus were found to be formed in vivo in CsA-treated mice. The activity of these cells could only be measured when they were transferred into untreated naive mice. The cells mediating DTH were H-2 restricted in the I region of the MHC. When effector T cells that mediated DTH were transferred into CsA-treated recipients, no DTH activity could be detected. Influenza-specific cytotoxic T cells could not be detected in the spleens of CsA-treated mice given virus intravenously, even when drug treatment was started 3 days after virus administration. There was only a partial restoration of cytotoxic activity when spleen cells from CsA-treated infected mice were cultured in the presence of virus-infected stimulators. This seemed to indicate that Class I-restricted responses were more susceptible to CsA than the generation of Class II (or I-region-restricted) responses.     

Ia Restriction Specificity of KLH-Specific T Cells from Allogeneic Bone Marrow Chimeras Is Influenced by Histocompatibility at the H-2 and Minor Histocompatibility Loci

Ia restriction specificity involved in T cell proliferative responses to keyhole limpet hemocyanin (KLH) has been analyzed using a variety of allogeneic bone marrow chimeras. The chimeric mice were prepared by reconstituting irradiated AKR, SJL, B10.BR and B10.A(4R) mice with bone marrow cells from B10 mice. When such chimeric mice had first been primed with KLH in complete Freund's adjuvant (CFA), T cells from H-2 incompatible fully allogeneic chimeras showed significantly higher responses to KLH in the presence of antigen-presenting cells (APC) of donor strain (B10) than APC of recipient strain. However, in H-2 subregion compatible chimeras, [B10→B10.A(4R)], which were matched at the H-2D locus and at minor histocompatible loci, the T cells could mount vigorous responses to KLH with antigen-presenting cells (APC) of either donor or recipient type. The same results were obtained as well with chimeras that had been thymectomized after full reconstitution of lymphoid tissues by donor-derived cells. A considerable proportion of KLH-specific T cell hybridomas established from [B10→B10.A(4R)] chimeras exhibited both I-A^b and I-A^k restriction specificities. The present findings indicate that the bias to donor Ia type of antigen specific T cells is determined by donor-derived APC present in the extrathymic environment but that cross-reactivity to the recipient Ia is influenced to some degree by histocompatibility between donor and recipient mice, even though the histocompatible H-2D locus and minor histocompatibility loci seem not to be directly involved in the I-A restricted responses studied herein.     

Induction of I region-restricted hapten-specific cytotoxic T lymphocytes.

Murine cytotoxic T lymphocytes (CTL) reactive to TNP-conjugated syngeneic target cells do lyse to a moderate but significant extent TNP-conjugated, I region compatible but H-2K or H-2D region incompatible target cells. Antibody inhibition experiments and "cold inhibition" experiments indicate that some CTL clones recognize TNP-conjugated targets in association with syngeneic I region determinants independently of H-2K or H-2D gene products. The data suggest that besides TNP-conjugated H-2K or H-2D gene products, in principle, also TNP-conjugated I region determinants do stimulate TNP-specific CTL precursor cells and act as target antigens of TNP-specific CTL.     

Ir gene control of the cytotoxic T lymphocyte response to Sendai virus: H-2k mice are low responders to Sendai

H-2k mice generate a secondary in vitro cytotoxic T lymphocyte response to Sendai virus 20- to 100-fold weaker than those of other haplotypes tested (H-2b,d,q,s). This immune response defect maps to both H-2K and H-2D. H-2k x H-2d F1 mice (responder x nonresponder) only lyse targets that have the d allele at H-2K and/or H-2D. H-2k targets are equally lysable with anti-Sendai antibody. Furthermore, H-2k mice demonstrate normal antibody and T cell proliferation responses to Sendai virus. The Ir gene defect therefore appears to be limited to the generation of the cytotoxic T lymphocytes.     

Expression of the I-E target antigen for T-cell killing requires two genes

The H-2Ik region encodes at least two different target antigens for unrestricted T-cell mediated killing. The first is controlled by the I-A region alone and the second depends on a pair of alleles, one located to the left of I-B (presumably in I-A) and the other to the right of I-J (presumably in I-E). Hence, effector cells nominally specific for a product of the I-E region do not kill target cells with the same I-E region as the stimulator unless the I-A region is also shared. Some effectors specific for H-2Ik, such as A.TH anti-A.TL and B10.A(4R) anti-B10.A(2R), cross-react with B10.A(3R) and B10.A(5R) target cells. A product of the H-2b haplotype was shown to complement products of the H-2d or H-2k haplotypes in forming this cross-reactive determinant. The results are consistent with recent biochemical data on the component chains of Ia antigens.