I-region linked complementing loci in resistance to viral leukemogenesis in the mouse

A-RadLV, a variant of the radiation leukemia virus, inoculated intrathymically into adult mice, causes a high frequency of leukemia in haplotypesb, f, k, d, p andj on the B10 background, whereas H-2^S mice are resistant. Resistance is dominant and segregates withH-2 ^S in the offspring of (b×s)b and (b×t ₂)b backcrosses. Analysis of recombinant strains revealed that resistance is associated withI-A andI-B. B10.A(5R), a recombinant of two sensitive haplotypes, was found to be resistant, suggesting intra-H-2-gene complementation. The resistance of such complementing loci was demonstrated also in thetrans position by testing F₁ mice bred from sensitive parents. These data are taken to suggest thatI-region linked complementing loci, similar to classicalIr genes, may be involved in resistance to murine leukemia.     

H-2-associated and background genes influence the development of a murine retrovirus-induced immunodeficiency syndrome

Host genetic determinants of resistance or susceptibility to a retrovirus-induced immunodeficiency syndrome, termed MAIDS, were evaluated in Fv-1b mice infected with the mixture of ecotropic, MCF, and defective murine leukemia viruses designated LP-BM5 murine leukemia viruses. Genes of the MHC were shown to exert a major influence on the development of disease and the extent of virus spread in mice infected as adults. Strains bearing the b, f, k, q, r, and s haplotypes were moderately to highly susceptible to MAIDS whereas mice of the d haplotype were the most resistant. Resistance to disease was strongly associated with inhibition of mink cell focus-inducing virus spread and, to a lesser extent, with inhibition of ecotropic virus expression. Mapping studies localizing resistance associated with the d haplotype to H-2Dd were confirmed by the demonstration that B6 mice carrying this gene as a transgene or by recombination were resistant to disease. Penetrance of resistance to disease associated with expression of H-2Dd was markedly influenced by MHC genes mapping to the left of H-2D and by non-MHC loci such that some strains bearing this gene were highly susceptible to MAIDS. The combined effects of MHC and background genes among 40 strains examined yielded a remarkably wide spectrum of disease phenotypes with the onset of advanced disease ranging from 10 wk to 72 wk postinfection. Resistance to disease in moderately to highly resistant strains was shown to develop with age. Unexpectedly, the disease resistant phenotype was found to be a recessive trait.     

Genetic regulation of early survival and cyst number after peroral Toxoplasma gondii infection of A x B/B x A recombinant inbred and B10 congenic mice

Genetics of two traits, survival and brain cyst number after peroral Toxoplasma gondii infection, were studied by using recombinant inbred strains of mice derived from resistant A/J (A) and susceptible C57BL/6J (B) progenitors, F1 progeny of crosses between A/J and C57BL/6J mice, and congenic mice (B10 background). Analysis of strain distribution pattern of survival of A x B/B x A recombinant mice indicated that survival is regulated by a minimum of five genes. One of these genes appears to be linked to the H-2 complex and another is related to an as yet unmapped gene controlling resistance to Ectromelia virus. Associations of defined traits with resistance or susceptibility to Toxoplasma cyst formation were also analyzed. Cyst number is regulated by a locus on chromosome 17 within 0 to 4 centimorgans of the H-2 complex (p = 0.001). Mice with the H-2a haplotype are resistant and those with the H-2b haplotype are susceptible. This analysis also indicated that the Bcg locus on chromosome 1 may effect cyst number (map distance = 12 centimorgans, p = 0.05). Resistance to cyst formation is a dominant trait. To analyze relative roles of H-2 and Bcg loci on cyst numbers, C57BL10 (B10)-derived congenic strains of mice with known H-2 and Bcg type were studied. These studies indicated that the H-2 complex locus has the primary effect on cyst number.     

Leishmania donovani infection in heterozygous and recombinant H-2 haplotype mice

On a B10 (Lshs) genetic background the development of acquired T-cell-mediated immunity to Leishmania donovani infection in mice is under H-2-linked genetic control. Three phenotypic patterns of recovery were previously observed: "early cure" (H-2s, H-2r), "cure" (H-2b) and "noncure" (H-2d, H-2q, H-2f), with cure behaving as a recessive trait in H-2b/H-2d mice. In this study the long-term response to L. donovani is followed over 130 days of infection in eight recombinant haplotype strains and in six further heterozygous haplotype combinations. Noncure in B10.HTG mice, which carry d alleles for loci at the K end and b alleles for loci at the D end of H-2, confirms that H-2-linked genetic control of the acquired response to L. donovani infection is located in the K end. The complex pattern of dominance relationships observed in the additional heterozygous haplotypes studied, the variable phenotypic response of H-2k mice and of recombinant haplotype strains carrying IEk in common, and the differential early curing activity observed in heterozygotes involving the s but not the r early cure haplotype and in recombinant haplotype mice carrying s alleles to the left of IE suggest, however, that more than one subregion (IE and presumably IA) are involved. Results are interpreted in the light of immunoregulatory T-cell populations previously demonstrated in noncure, cure, and early cure strains.     

Major histocompatibility complex-conferred resistance to Theiler's virus-induced demyelinating disease is inherited as a dominant trait in B10 congenic mice.

Intracerebral inoculation of Theiler's murine encephalomyelitis virus into susceptible strains of mice produces chronic demyelinating disease in the central nervous system characterized by persistent viral infection. Immunogenetic data suggest that genes from both major histocompatibility complex (MHC) and non-MHC loci are important in determining susceptibility or resistance to demyelination. The role of the MHC in determining resistance or susceptibility to disease can be interpreted either as the presence of antigen-presenting molecules that confer resistance to viral infection or as the ability of MHC products to contribute to pathogenesis by acting as viral receptors or by mediating immune attack against virally infected cells. These alternatives can be distinguished by determining whether the contribution of the MHC to resistance is inherited as a recessive or dominant trait. Congenic mice with different MHC haplotypes on identical B10 backgrounds were crossed and quantitatively analyzed for demyelination, infectious virus, and local virus antigen production. F1 hybrid progeny derived from resistant B10 (H-2b), B10.D2 (H-2d), or B10.K (H-2k) and susceptible B10.R111 (H-2r), B10.M (H-2f), or B10.BR (H-2k) parental mice exhibited no or minimal demyelination, indicating that on a B10 background, resistance is inherited as a dominant trait. Although infectious virus, as measured by viral plaque assay, was cleared inefficiently from the central nervous systems of resistant F1 hybrid progeny mice, we found a direct correlation between local viral antigen production and demyelination. These data are consistent with our hypothesis that the immunological basis for resistance is determined by efficient presentation of the viral antigen to the immune system, resulting in local virus clearance and absence of subsequent demyelination.     

Effects of non-MHC loci on resistance to retrovirus-induced immunodeficiency in mice

Mice of certain strains are highly sensitive to development of a severe immunodeficiency disease following inoculation as adults with LP-BM5 murine leukemia viruses (MuLV) whereas others are extremely resistant. These strain-dependent differences in response to infection have been shown to be genetically determined with resistance to disease being, in general, associated with homozygosity for Fv-1 ⁿand H-2 haplotypes a and d and sensitivity with homozygosity for Fv-1 ^band other H-2 haplotypes including b, s, and q. The Fv-1 ^b, H-2 ^rstrain RIIIS/J (RIIIS) was found to be highly resistant to disease even though B10.RIII(71NS)/J (B10.RIII), also H-2 ^r, was very sensitive, thus excluding a role for H-2 in the resistance of RIIIS. The characteristics of RIIIS resistance were evaluated in studies of infected (B10.RIII×RIIIS) F₁, F₂ and reciprocal backcross mice. Resistance to disease was shown to be semidominant and determined by more than one gene, although a preponderant influence of a single gene was suggested. Studies of segregating populations showed that resistance was not associated with or linked to polymorphisms of the V _\complex or genes in proximity to the Emv-2 locus on chromosome 8. However, there was almost complete concordance between absence of disease in infected mice and inhibition of ecotropic virus spread. These results demonstrate that genes other than Fv-1 or H-2 can profoundly influence the development of retrovirus-induced immunodeficiency and replication of ecotropic viruses.Abbreviations MuLV murine leukemia virus - MCF mink cell focus-inducing MuLV - B6 C57BL/6 - BM5d the defective virus in LP-BM5 MuLV - MAIDS murine acquired immunodeficiency syndrome - RIIIS RIIIS/J - B10.RIII B10.RIII (71NS)/J - MLR mixed lymphocyte reaction - FACS fluorescence activated cell sorter     

Genetic control of immune response to sperm whale myoglobin in mice. I. T lymphocyte proliferative response under H-2-linked Ir gene control.

Studies on the genetic control of immune response to sperm whale myoglobin were initiated. As demonstrated in this paper, the T lymphocyte proliferative response to whale myoglobin is under H-2-linked Ir gene control. Mice of H-2d, H-2f, and H-2s haplotypes were high responders to the myoglobin, whereas haplotypes H-2b, H-2k, H-2p, H-2q, and H-2r were low responders. The Ir gene(s) was localized between H-2K and H2D regions, since the recombinant strain A.TL (KsIkSkDd) was a low responder and A.TH (KsIsSsDd) was a high responder. Further studies with recombinant strains revealed that the expression of the high-responder I-Ad or Ias alleles was sufficient to give a good response, since strains D2.GD (d d b b b b b b) and B10.HTT (s s s s k k k d) were high responders. The expression of the I-Cd allele in strains B10.A (k k k k k d d d) and B10.A(5R) (b b b k k d d d) also gave high response, and thus suggested a second Ir gene, derived from the H-2d haplotype. The finding that expression of the I-Cs allele in B10.S(8R) (k k ? ? s s s s) did not result in high response suggests the lack of the second Ir gene in the high-responder H-2s haplotype.     

H-2I-linked control of immunological resistance to viral leukemogenesis as a response to preleukemic cells

The mechanism of resistance to leukemogenesis by two radiation leukemia virus variants, A-RadLV and D-RadLV, was investigated. Resistance to these viruses is linked toH-2I in both B10.S and C57BL/10 mice. The resistance of virus-infected mice to transplantation of syngeneic, A- or D-RadLV-induced lymphoma cells was similar to their resistance to leukemogenesis by the same viruses. This resistance could be transferred by lymphoid cells from immune donors to normal recipients, and it was specific for RadLV lymphomas. Virus-primed (responder x sensitive)F₁ hybrids rejected only resistant-type parental lymphoma cells. Hence, it appears thatH-2I-linked resistance to RadLV leukemogenesis is regulated byIr genes. Resistant mice immunized by A- or D-RadLV rejected syngeneic lymphoma cells, irrespective of whether they were sensitive or resistant to the RadLV variant used for the induction of the lymphoma cells. It follows that resistant and sensitive type lymphomas are antigenically similar for the effector mechanism, and that theIr genes may be expressed in the sensitization phase of the reaction. In virus-infected mice which are resistant to A- or D-RadLV we were able to demonstrate the presence of preleukemic lymphocytes. Normal mice could be immunized by these preleukemic cells against lymphoma challenge. These data are interpreted to suggest that mice havingH-2I-linked resistance to RadLV infection may be sensitized by their preleukemic cells, and that these preleukemic cells are then arrested in their development as a result of the immune response.     

Recombinants in the H-2S/H-2D interval of mouse chromosome 17 define the map position of a gene for cleft palate susceptibility

The H-2 region of mouse chromosome 17 is known to include one or more genes that affect susceptibility to cortisone-induced cleft palate. We have now studied congenic strains that possess crossovers in the interval between H-2S and H-2D and have observed significant differences in susceptibility among recombinants that had been believed to possess the same H-2 haplotypes. Pregnant mice were injected on days 11 through 14 of gestation with 100 mg of cortisone per kg of body weight. The frequency of cleft palate in B10.A(2R) was significantly greater than in B10.A(1R), despite the fact that both have H-2a/H-2b crossovers in the interval between the S and D loci and have the same alleles at all loci that have been previously characterized. Both B10.BAR5 and B10.BAR12 were significantly more susceptible than B10.A(18R), although these strains also share the same alleles at all loci that have been previously characterized. All three of these strains have H-2b/H-2a recombinant chromosomes, with crossovers in the S/D interval. Genetic linkage between H-2 and the high-susceptibility gene of B10.BAR5 was confirmed by testing H-2 homozygotes derived by intercrossing backcross animals. These data therefore suggest that a gene coding for susceptibility, which we designate Cps-1, maps in the 350-kb interval between H-2S and H-2D, and the congenic strains that we have found to be different have different crossover points within this interval. Alleles at the Cps-1 locus have embryonic effects, but no demonstrable effects on the maternal environment.     

H-21-linked control of immunological resistance to viral leukemogenesis as a response to preleukemic cells

The mechanism of resistance to leukemogenesis by two radiation leukemia virus variants, A-RadLV and D-RadLV, was investigated. Resistance to these viruses is linked to H-21 in both B10.S and C57BL/10 mice. The resistance of virus-infected mice to transplantation of syngeneic. A- or D-RadLV-induced lymphoma cells was similar to their resistance to leukemogenesis by the same viruses. This resistance could be transferred by lymphoid cells from immune donors to normal recipients, and it was specific for RadLV lymphomas. Virus-primed (responder x sensitive)F1 hybrids rejected only resistant-type parental lymphoma cells. Hence, it appears that H-21-linked resistance to RadLV leukemogenesis is regulated by Ir genes. Resistant mice immunized by A- or D-RadLV rejected syngeneic lymphoma cells, irrespective of whether they were sensitive or resistant to the RadLV variant used for the induction of the lymphoma cells. It follows that resistant and sensitive type lymphomas are antigenically similar for the effector mechanism, and that the Ir genes may be expressed in the sensitization phase of the reaction. In virus-infected mice which are resistant to A- or D-RadLV we were able to demonstrate the presence of preleukemic lymphocytes. Normal mice could be immunized by these preleukemic cells against lymphoma challenge. These data are interpreted to suggest that mice having H-21-linked resistance to RadLV infection may be sensitized by their preleukemic cells, and that these preleukemic cells are then arrested in their development as a result of the immune response.     

Two new recombinant H-2 haplotypes, one of which juxtaposes Kb and Ik alleles.

Two new recombinant H-2 haplotypes have been detected and established as congenic resistant lines on the C57BL/10 background. On the basis of serologic testing and immunoprecipitation analyses, the sublocus composition of the first recombinant haplotype, H-2bq1 (B10.MBR) has been shown to be KbIkDq, and that of the second recombinant, H-2sq3 (B10.SQR) to be KsIsSsDq. The occurrence of the Kb I-Ak juxtaposition after a recombination between H-2b and H-2m contrasts with the almost uniform failure to observe H-2b/H-2k recombinants in previous studies. This finding and the occurrence of a second recombination event involving the same chromosome soon after the first in our studies may imply that recombination within H-2 is not generally a random event. The B10.MBR line has proved useful in the production of specific anti-H-2Kb and anti-I-Ab antisera previously quite difficult to obtain contamination by anti-Ia or anti-H-2K antibodies, respectively.     

Major histocompatibility complex class II-regulated immunity to murine leukemia virus protects against early T- but not late B-cell lymphomas

We studied the relative importance of class I and class II major histocompatibility complex (MHC) immunoregulation in the control of T- and B-cell lymphomas induced by murine leukemia virus. Previously, we have described a mink cell focus-inducing (MCF) murine leukemia virus, MCF 1233, which induces not only lymphoblastic T-cell lymphomas but also follicle center cell or lymphoblastic B-cell lymphomas. We now report that the outcome of neonatal infection with MCF 1233 in H-2-congenic C57BL/10 and C57BL/6 mice is decisively influenced by the H-2 I-A locus. A total of 64% of H-2 I-Ak, d mice [B10.BR, B10.D2, B10.A(2R), B10.A(4R), and B10.MBR] developed T-cell lymphomas after MCF 1233 infection (mean latency, 37 weeks). In contrast, H-2 I-Ab [B10, B10.A(5R), B6], H-2 I-Ab/k [(B10.A x B10)F1 and (B10 x B10.A)F1], and H-2 I-Abm12 (bm12) mice were resistant against T-cell lymphomagenesis, but 65% of these H-2 I-Ab, b/k, bm12 animals developed B-cell lymphomas (mean latency, 71 weeks). Animals of T-cell lymphoma-susceptible strains that escaped from T-cell lymphomagenesis developed B-cell lymphomas with similar frequency as animals of T-cell lymphoma-resistant strains, but with a shorter latency. H-2 class II-determined regulation of antiviral immunity was reflected in the presence of high titers of antiviral envelope antibodies in T-cell lymphoma-resistant B-cell lymphoma-susceptible H-2 I-Ab, b/k, bm12 mice, whereas in T-cell lymphoma-susceptible H-2 I-Ak,d mice no antiviral antibodies were found. At week 4 after neonatal MCF 1233 infection, a high percentage of thymocytes were virally infected in both T-cell lymphoma-susceptible and -resistant mice. However, T-cell lymphoma-resistant animals cleared the thymic infection between weeks 4 and 10 of age, coinciding with a sharp rise in serum levels of antiviral antibodies. We conclude that the pleiotropic effects of MCF 1233 infection in H-2-congenic mice result from MHC class II I-A-determined T-cell response differences.     

Genetic control of acquired resistance to visceral leishmaniasis in mice

A series of H-2 and non-H-2 congenic resistant (CR) strains on a C57BL/10Sn background were infected with 10(7) amastigotes of Leishmania donovani. Non-H-2 congenic strains B10.LP-H-3b and B10.CE(30NX) and (B10.LP-H-3b x B10)F1 hybrids showed a very rapid decrease in liver-parasite burdens beyond day 21. Parasite counts for these strains at day 35 were significantly lower than for all other strains tested. The rapid decrease in parasite numbers, massive lymphocellular infiltration into the liver and strong delayed hypersensitivity reactions to parasite antigens in strains congenic for a portion of chromosome 2 indicated that acquired immunity to L. donovani was controlled by a dominant gene at or near the Ir-2 locus. In addition, B10.129(10M) mice, which differ from C57BL/10Sn at the H-11 locus, showed highly significant increases in parasite numbers at day 35. Other observations supporting the absence of acquired immunity in B10.129(10M) included negative delayed hypersensitivity tests to parasite antigens and the absence of lymphocellular infiltrate into the liver. Although the differences were not as pronounced, H-2 CR strains with H-2b, H-2a, and H-2k haplotypes also showed significantly greater decreases in parasite numbers by day 35 as compared to other H-2 CR strains.     

Preferential induction of protective T cell responses to Theiler's virus in resistant (C57BL/6 x SJL)F1 mice

Infection of the central nervous system (CNS) with Theiler's murine encephalomyelitis virus (TMEV) induces an immune-mediated demyelinating disease in susceptible mouse strains such as SJL/J (H-2(s)) but not in strains such as C57BL/6 (H-2(b)). In addition, it has been shown that (C57BL/6 × SJL/J)F1 mice (F1 mice), which carry both resistant and susceptible MHC haplotypes (H-2(b/s)), are resistant to both viral persistence and TMEV-induced demyelinating disease. In this study, we further analyzed the immune responses underlying the resistance of F1 mice. Our study shows that the resistance of F1 mice is associated with a higher level of the initial virus-specific H-2(b)-restricted CD8(+) T cell responses than of the H-2(s)-restricted CD8(+) T cell responses. In contrast, pathogenic Th17 responses to viral epitopes are lower in F1 mice than in susceptible SJL/J mice. Dominant effects of resistant genes expressed in antigen-presenting cells of F1 mice on regulation of viral replication and induction of protective T cell responses appear to play a crucial role in disease resistance. Although the F1 mice are resistant to disease, the level of viral RNA in the CNS was intermediate between those of SJL/J and C57BL/6 mice, indicating the presence of a threshold of viral expression for pathogenesis.     

Chromosomal locations and gonadal dependence of genes that mediate resistance to ectromelia (mousepox) virus-induced mortality.

Four genetic loci were tested for linkage with loci that control genetic resistance to lethal ectromelia virus infection in mice. Three of the loci were selected because of concordance with genotypes assigned to recombinant inbred (RI) strains of mice derived from resistant C57BL/6 and susceptible DBA/2 (BXD) mice on the basis of their responses to challenge infection. Thirty-six of 167 male (C57BL/6 x DBA/2)F1 x DBA/2 backcross (BC) mice died (22%), of which 27 (75%) were homozygous for DBA/2 alleles at Hc and H-2D. Twenty-eight percent of sham-castrated and 6% of sham-ovariectomized BC mice were susceptible to lethal mousepox, whereas 50% of gonadectomized mice were susceptible. There was no linkage evident between Hc or H-2D and loci that controlled resistance to lethal ectromelia virus infection in 44 castrated BC mice. Mortality among female mice of BXD RI strains with susceptible or intermediate male phenotypes was strongly correlated (r = 0.834) with male mortality. Gonadectomized C57BL/6 mice were as resistant as intact mice to lethal ectromelia virus infection. These results indicate that two gonad-dependent genes on chromosomes 2 and 17 and one gonad-independent gene control resistance to mousepox virus infection, that males and females share gonad-dependent genes, and that the gonad-independent gene is fully protective.     

Expression of hemopoietic histocompatibility antigens on H-2-loss variants of F1 hybrid lymphoma cells: evidence consistent with trans gene regulation

H-2 heterozygous marrow stem cells, lymphoid progenitor cells, and leukemia/lymphoma cells do not express hemopoietic or hybrid histocompatibility (Hh) antigens, which are important transplantation antigens recognized during the rejection of normal or neoplastic hemopoietic cells. The Hh-1b determinant of the H-2b haplotype maps to the D region of H-2. We have tested the hypothesis that gene(s) at or near H-2D of the H-2d haplotype down-regulate the expression of Hh-1b in the trans configuration. We used Abelson leukemia virus-transformed pre-B lymphoma cells (ACCb) of BALB/c X BALB.B (H-2d X H-2b) origin, as well as variant lines of ACCb, which were selected for resistance to monoclonal anti-H-2 antibodies plus complement. B6D2F1 (H-2b X H-2d), C3B6F1 (H-2k X H-2b), or B6 (H-2b) mice were infused with inocula of 5 X 10(6) B6 bone marrow cells (BMC). Proliferation of donor-derived marrow cells was judged in terms of DNA synthesis by measuring the splenic incorporation of 5-iodo(125I)-2'-deoxyuridine (IUdR) 5 days after cell transfer. B6 BMC grew much better in B6 than in F1 hybrid host mice, an expression of "hybrid resistance". As observed previously, the injection of EL-4 (H-2b, Hh-1b) tumor cells prior to infusion of B6 (H-2b, Hh-1b) BMC enhanced the growth of B6 BMC in F1 hybrid mice. Therefore, this in vivo "cold target cell competition" type of assay can be used to detect the expression of Hh-1b antigens. Unlike EL-4 (H-2b) cells, hybrid resistance was not affected by prior infusion of (H-2b X H-2d) heterozygous ACCb cells. In contrast, three ACCb variant cell lines, H-2d-, Ld-Dd-, and Dd-, enhanced the growth of B6 BMC in F1 hosts. The ACCb H-2b- cell line did not affect hybrid resistance to B6 BMC. The loss of gene expression on the H-2d chromosome at or very near the H-2Dd locus is correlated with the appearance Hh-1b, as determined by the in vivo cold target competition assay. These results support the hypothesis that heterozygous cells possess trans-acting, dominant, down-regulatory genes mapping near H-2D that control the Hh-1 phenotype of lymphoid tumor cells.     

Class I MHC genes and CD8+ T cells determine cyst number in Toxoplasma gondii infection

To determine roles of MHC class I and II genes in protection against Toxoplasma gondii, H-2 congenic and mutant mice were infected perorally with bradyzoites of T. gondii and brain cysts were enumerated 30 days later. As B10 mice (H-2b) are cyst susceptible and B10.A mice (H-2a) are cyst resistant, B10 congenic mice having the same alleles but different H-2 haplotypes were used to locate the controlling gene. Genes located at H-2L (i.e., class I genes) were found to regulate the number of brain cysts which form following peroral infection with T. gondii (p less than 0.001) with Ld being resistant and Lb being susceptible. The regulatory function of the H-2L gene product was confirmed through the study of D mutant (dm) mice. B10.D2-H-2dm1 (dm1) mice have a gain-loss mutation in Dd and Ld (i.e., recombination of Ld and Dd) and BALB/c-H-2dm2 (dm2) mice have a deletion of the Ld gene. Both these dm strains were cyst susceptible (p less than 0.001). These results provide the first direct evidence that class I genes regulate numbers of T. gondii cysts that form. In vivo ablation of CD8+ T cells with mAb YTS 169.4 converted cyst resistant B10.BAR12 mice to cyst susceptible. This result is consistent with a role for MHC restricted CD8+ cytotoxic (or suppressor) T cell regulation of cyst formation. A mutation in Ia in B6.C-H-2bm12 (bm12) mice amplified cyst numbers in susceptible mice, which is consistent with the importance of helper/inducer T cells in the induction of cytotoxic T cells. These findings are relevant to understanding the complex immunologic mechanisms that protect against T. gondii infection, development of protective preparations, and provide a conceptual basis for determining whether similar immunogenetic regulation of susceptibility is also operative in humans.     

Nematospiroides dubius: two H-2-linked genes influence levels of resistance to infection in mice

Strains of mice sharing common H-2 haplotypes but different genetic backgrounds, and H-2 congenic strains of mice differing only at H-2 genes were studied to assess the role of H-2 and non-H-2 genes in immunity to challenge infections with the nematode parasite Nematospiroides dubius. Strains of mice sharing the H-2k haplotype were uniformly more susceptible to challenge than strains expressing H-2q alleles, regardless of genetic background. However, in some cases strains of mice sharing the k or q haplotypes differed significantly in levels of resistance. Therefore, non-H-2 genes must influence the response observed. H-2 cogenic strains of mice differed markedly in their ability to resist challenge infections. Mice sharing the C57BL/10 background but expressing k alleles were very susceptible to challenge, while the H-2q, H-2f, and H-2s, haplotypes were associated with resistance. Studies of H-2 congenic recombinant strains of mice suggested that two H-2 genes influence the antiparasite response. One of these genes maps to the left of E alpha and the other to the D-end of the H-2 complex. It is concluded also that the unique configuration of H-2 genes in F1 hybrids contributes to increased resistance to challange.     

Recombinant haplotype H-2 in mice of the congenic resistant strain B10.D1(R108)/Y

Recombinant H-2 haplotype of mouse strain B10.D1(R108)/Y (symbol R108) obtained in experiments with skin grafting in the course of developing the CR B10.D1/Y strain (strain DBA/LacY--the donor of H-2q) was studied. Strains with recombinant H-2 haplotypes a, h2, g1, i3, i5, i7, m, y1 were used. Alleles of different H-2 (K, I, D) regions were determined according to the presence or absence of genetic complementation in the F1 test with skin grafts. R108 recombinant was studied by serological methods with panel of anti-H-2 sera. Anti-H-2Kb (H-2.33) and anti-H-2Dq (H-2.30) monospecific antisera were used in microcytotoxicity test and in absorption experiments in vitro. It was concluded that crossing over between H-2b and H-2q chromosomes, which led to formation of recombinant H-2 haplotype of R108 mice, occurred at I region, between IA and IC subregions. The H-2 complex of R108 line has KbIAbIJ?IE?ICqSqDq alleles. bq1 symbol was proposed for the H-2 haplotype of B10.D1(R108)/Y strain.     

Genetic control of the immune response in mice to Leishmania mexicana surface protease

Congenic mouse strains were tested in the lymphocyte proliferation assay for their response to the purified surface protease of Leishmania mexicana (gp63). The data obtained allow us to distinguish three different patterns of response, influenced both by H-2 (class II) and non-H-2 genes. Mice of the C57BL/10 (B10) background carrying H-2 haplotypes b,q, and r were found to be high responders; those carrying H-2 haplotypes d, j, v, and z were low responders; and those with H-2a, H-2f, H-2k, H-2p, and H-2u haplotypes were intermediate responders. Studies with H-2 recombinant strains indicated that the high responsiveness on the B10 background was determined by the Ab allele and the low responsiveness influenced by the Ad allele. Other genes besides H-2 appear to have a role in the immune response as shown by the fact that some strains with BALB, DBA, or C3H background differed in their pattern of responsiveness from B10 background strains carrying the corresponding H-2 haplotypes. By using recombinant protein, the influence of the leishmanial surface lipophosphoglycan that might co-purify with gp63, on the MHC restriction of the response to gp63 was excluded. The immune response to gp63 did not correlate with susceptibility of mouse strains to cutaneous infection with L. mexicana promastigotes.