Discovery of a unique strain-specific idiotypic antigenic determinant of mouse T-lymphocyte antigen-recognizing receptors

The cellular radioimmunoassay using rabbit anti-CBA-anti-C57BL/6 antiidiotypic serum was performed to detect a private strain-specific antigenic idiotypic determinant (s) on activated CBA-anti-C57BL/6 T cells. This private idiotype was not expressed on other activated T cells under study: CBA-anti-BALB/C; C3H-anti-C57BL/6; AKR-anti-C57BL/6; A/Sn-anti-C57BL/6; BALB/C-anti-C57BL/6; DBA/2-anti-C57BL/6. It is suggested that gene (s) coding the private strain-specific idiotypic antigenic determinant of the antigen-recognition receptor of T cells is not localized on the H-2 complex of mice.     

Evidence for more than one Ia antigenic specificity on molecules determined by the I-A subregion of the mouse major histocompatibility complex.

Ia antigenic specificities determined by the I-A subregion of the mouse major histocompatibility complex have been examined in strain B10.D2 (H-2d), C57BL/10 (H-2b), and in a (C57BL/6xDBA/2) hybrid (BDF1; H-2b/d). Detergent solubilized, 3H-leucine-labeled antigen preparations were mixed with appropriate alloantisera and precipitation was induced either by addition of goat anti-mouse gamma-globulin or by addition of protein A-bearing Staphylococci. Sequential precipitation analysis showed that in strain B10.D2, Ia specificities 8 and 11 were co-precipitable, and that in strain C57BL/10, Ia specificities 8 and 9 were co-precipitable. In contrast, precipitation of specificities 9 and 11 from a BDF1 antigen preparation showed that these two Ia specificities were on separate molecules. The genetic implications of these data are discussed.     

Study of H-2 mutations in mice. IV. A comparison of the mutants M505 and Hz1 by skin grafting and serological techniques

The line B6.M505 is congenic with C57BL/6JY and carries a mutant form of theH-2 ^b haplotype designatedH-2 ^bd . The mutant site 505 was located by the F₁ tests in theK end of theH-2 gene complex. The M505 mice are histoincompatible with the B6.C(Hz1) line (haplotypeH-2 ^ba ) carrying another mutation in theK end ofH-2 ^b . Inability of M505 to complement Hz1 in tests with B6 skin grafting is considered as an evidence that the same gene was altered by both mutations. The gained H antigens of two mutants can cross-react in vivo as revealed by accelerated rejection of Hz1 skin grafts by B6 recipients presensitized with M505 spleen cells. The lost antigenic determinants are not identical as shown by accelerated rejection of B6 skin grafts by Hz1 hosts preimmunized with M505 spleen cells. Absorptions of the antiserum ASY-015, (d×a) anti-i, anti-H-2.33 with M505 spleen cells did not clear forH-2 ⁱ ,H-2 ^b andH-2 ^ba , and absorptions with Hz1 did not clear forH-2 ⁱ ,H-2 ^b , andH-2 ^bd . These results show that changes of histocompatibility determinants may be accompanied by loss of some haptenic determinants in the Hz1 and M505 mutations.     

Major histocompatibility complex-dependent cytotoxic T lymphocyte repertoire and functional avidity contribute to strain-specific disease susceptibility after murine respiratory syncytial virus infection

Susceptibility to respiratory syncytial virus (RSV) infection in mice is genetically determined. While RSV causes little pathology in C57BL/6 mice, pulmonary inflammation and weight loss occur in BALB/c mice. Using major histocompatibility complex (MHC)-congenic mice, we observed that the H-2(d) allele can partially transfer disease susceptibility to C57BL/6 mice. This was not explained by altered viral elimination or differences in the magnitude of the overall virus-specific cytotoxic T lymphocyte (CTL) response. However, H-2(d) mice showed a more focused response, with 70% of virus-specific CTL representing Vβ8.2(+) CTL directed against the immunodominant epitope M2-1 82, while in H-2(b) mice only 20% of antiviral CTL were Vβ9(+) CTL specific for the immunodominant epitope M187. The immunodominant H-2(d)-restricted CTL lysed target cells less efficiently than the immunodominant H-2(b) CTL, probably contributing to prolonged CTL stimulation and cytokine-mediated immunopathology. Accordingly, reduction of dominance of the M2-1 82-specific CTL population by introduction of an M187 response in the F1 generation of a C57BL/6N × C57BL/6-H-2(d) mating (C57BL/6-H-2(dxb) mice) attenuated disease. Moreover, disease in H-2(d) mice was less pronounced after infection with an RSV mutant failing to activate M2-1 82-specific CTL or after depletion of Vβ8.2(+) cells. These data illustrate how the MHC-determined diversity and functional avidity of CTL responses contribute to disease susceptibility after viral infection.     

Genetic control of immune responses to the 18-kDa protein of Mycobacterium leprae. Different TH1 subsets may be involved in proliferative and delayed-type hypersensitivity responses.

In vitro and in vivo responses to the 18-kDa protein of Mycobacterium leprae have been analysed in different strains of mice. Lymphocytes from BALB/cJ (H-2d), BALB.B (H-2b), B10.BR (H-2k), and B10.M (H-2f) mice primed with 18-kDa protein yielded high T cell proliferative responses, while those from C57BL/10J (H-2b) mice yielded lower responses. Both H-2 and non-H-2 genes contributed to the magnitude of responsiveness. F1 mice from high and low responder strains showed high responsiveness to the 18-kDa protein. Supernatants from lymph node cell cultures prepared from 18-kDa protein-immunised BALB/cJ, B10.BR, and C57BL/10J mice contained IL-2 but no IL-4, indicating that activated T cells from both high and low responder mice were of a TH1 phenotype. Cell cultures from low responder C57BL/10J mice produced less IL-2 than those from high responders. The low responsiveness to the 18-kDa protein in proliferative assays might be due to a low frequency of antigen-specific T cells in the C57BL/10J mouse strain. BALB/cJ, C57BL/10J, and F1 (BALB/cJ x B10.BR) mouse strains were tested for in vivo DTH reactions to the 18-kDa protein. All strains, including C57BL/10J, were high DTH responders. Although DTH effector cells and 18-kDa protein-specific proliferative T cells belong to the TH1 subset, our data comparing high and low responder status indicate that distinct TH1 subpopulations are stimulated in response to the 18-kDa protein of M. leprae.     

Trypanosoma brucei: influence of host strain and parasite antigenic type on infections in mice

Inbred mice were infected with cloned populations of Trypanosoma brucei brucei Lister S42 under carefully controlled conditions. The course of infection was found to depend both on host strain and the antigenic type of the infecting organisms. The two antigenic types used, “NIM2” and “NIM6” had differing virulence for (CBA/H × C57BL/6)F₁ mice, and when mice were infected with parasites of one clone, trypanosomes of the other type frequently appeared after the initial population had been eliminated. Different mouse strains had varying susceptibility to clone NIM6. In most cases there was an inverse relation between the survival time and the parasite load during the first peak of parasitemia. The differences in resistance to T. brucei were unrelated to H-2 haplotype: C57BL/6 and (CBA/H × C57BL/6)F₁ were most resistant, CBA/H, BALB/c and DBA/2 less so, and C3H/He most susceptible.     

Antigen-dependent proliferation of cloned continuous lines of H-2-restricted influenza virus-specific cytotoxic T lymphocytes

The antigenic requirements for in vitro proliferation of several cloned continuous lines of H-2-restricted influenza virus-specific cytotoxic T lymphocytes (CTL) has been examined. The cloned CTL lines were established from individual splenic CTL precursors obtained from A/JAPAN/305/57 (H2N2)-immune F1 (C57BL/6 X BALB/c) donors. The lines were isolated (by limiting dilution in liquid culture) and expanded in the presence of A/JAPAN/305/57-infected irradiated syngeneic (F1) spleen cells and T cell growth factor (TCGF) of rat spleen origin. Optimal proliferation (and long-term in vitro cultivation) of these H-2-restricted CTL lines required both specific antigenic stimulation in the form of virus-infected syngeneic spleen cells and an exogenous source of TCGF. In addition, the antigenic requirements for proliferation of these lines directly reflected the pattern of H-2-restricted influenza virus-specific recognition at the level of target cell recognition and lysis.     

Strain variation in BCG-induced chronic pulmonary inflammation in mice. I. Basic model and possible genetic control by non-H-2 genes.

C57BL/6 mice (haplotype H-2b) responded in a dose-dependent fashion to killed BCG by marked enlargement of the spleen and lung. Neither CBA nor C3H mice (haplotype H-2k) responded to such treatment. Pulmonary inflammation in responder B6 animals was characterized by a marked chronic interstitial and alveolar granulomatous process, and was accompanied by occasional granulomata, hyperemia, and loss of architecture in the spleen. Inflammation in non-responder CBA and C3H animals was minimal in both the lung and spleen. The response does not appear to be controlled by genes within the major histocompatibility complex, but is associated with a C57 background. B10.BR mice (responder background, H-2k) were responder animals and C3H.SW mice (nonresponder background, H-2b) were nonresponders. In addition, all animals tested with a C57 background were responders even though two of these strains were not H-2b (C57BL/Ks, H-2d and C57Br/cd, H-2k). The resolution of the mechanism of genetic control of this response in mice may provide information relevant to possible genetic control of chronic pulmonary inflammation in man.     

Studies of two H-2Db mutants: B6. C-H-2bm13 and B6.C-H-2bm14

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

Interstrain differences in mice in developing migration inhibition factors to Candida albicans antigens

The authors studied the time course of MIF production by lymphocytes of CBA (H-2k), C57BL/6J (H-2b) and (CBA X C57BL/6J) F1 (H-2b/H-2k) mice sensitized to Candida albicans antigens. The interstrain differences in lymphokin production were identified, CBA mice appeared to be highly responsive, whereas C57BL/6J to be low-responsive. Partial hybridological analysis made it possible to ascertain the presence of the dominant type heredity of high MIF production in response to Candida albicans antigens.     

Immunity to leprosy. II. Genetic control of murine T cell proliferative responses to Mycobacterium leprae

T cell proliferative responses to Mycobacterium leprae were measured after immunization of mice at the base of the tail with antigen and challenging lymphocytes from draining lymph nodes in culture with M. leprae. This T cell response to M. leprae has been compared in 18 inbred strains of mice. C57BL/10J mice were identified as low responder mice. The congenic strains B10.M and B10.Q were found to be high responders, whereas B10.BR and B10.P were low responders. F1 (B10.M X C57BL/10J) and F1 (B10.Q X C57BL/10J) hybrid mice were found to be low responders, similar to the C57BL/10J parent, indicating that the low responsive trait is dominant. Whereas B10.BR mice were shown to be low responders to M. leprae, B10.AKM and B10.A(2R) were clearly high responders, indicating that the H-2D region influences the magnitude of the T cell proliferative response. Gene complementation within the H-2 region was evident. Genes outside the H-2 region were also shown to influence the response to M. leprae. C3H/HeN were shown to be high responder mice, whereas other H-2k strains, BALB.K, CBA/N, and B10.BR, were low responders. Gene loci that influence the T cell proliferation assay have been discussed and were compared to known background genes which may be important for the growth of intracellular parasites. Because mycobacteria are intracellular parasites for antigen-presenting cells, genes that affect bacterial growth in these cells will also influence subsequent immune responses of the host.     

Genetic control of murine T cell proliferative responses to Mycobacterium leprae. V. Evidence for cross-reactivity between host antigens and Mycobacterium leprae

T cell proliferative responses to Mycobacterium leprae were measured by immunization of mice at the base of the tail with Ag and challenging lymphocytes from draining lymph nodes in culture with M. leprae. C57BL/10J and B10.BR mice were identified as low responder mice and the congenic strains B10.M, B10.Q, and B10.AKM as high responders whereas F1 (high x low) hybrid mice were found to be low responders. The cellular basis of low responsiveness did not appear to result from a defect in Ag-presenting cells or the activation of suppressor T cells by M. leprae. The influence of the environment in which T cells developed on responsiveness to M. leprae was analyzed in chimeric mice prepared by irradiating F1(C57BL/10J x B10.M) mice and reconstituting with bone marrow from C57BL/10J, B10.M, or F1 donors. Six weeks later, chimeric mice were immunized with M. leprae, lymph node cells were subsequently prepared, and H-2 phenotyped and challenged in culture with M. leprae Ag. T cell proliferative responses were found to be low in all cases, similar to those observed using lymph node cells from F1 hybrid mice. These results suggested that high responder B10.M lymphocytes developing in the irradiated F1 mice became tolerized to antigenic determinants found on M. leprae. This implied cross-reactive epitopes existed between some mouse strains and M. leprae. Low responsiveness to M. leprae in low responder and F1 hybrid mice may result from tolerance to H-2-encoded Ag that show cross-reactivity with M. leprae.     

Immunogenetic analysis ofH-2 mutations

A.BY, B10.LPa, and B10.129(5M) mice were presensitized in vivo against B10.A(5R) cells and then restimulated in vitro by the same cells in the standard CML assay. The effector cells thus generated lysed not only B10.A(5R), but also C57BL/6 targets, indicating that, in addition to anti-H-2D_d response [measured on the B10.A(5R) targets], response to minor histocompatibility (H) antigens (measured on the C57BL/6 targets) also occurred. The latter response was directed against multiple minor H antigens in the case of the A.BY effectors, and against H-1 and H-3 antigens in the case of B10.129(5M) and B10.LPa effectors, respectively. The sensitization against minor H antigens occurred in the context of H-2K^b H-2D^d antigens, but by testing the response on C57BL/6 targets, only cells reacting with minor H antigens in the context of H-2K^b were assayed. The same effector cells were then tested against H-2^b mutant strains, in which theH-2K ^b allele was replaced by a mutant one. All three effector types [A.BY, B10.LPa, and B10.129(5M)] behaved in a similar way: they all reacted with theH-2 ^bg1 mutant to the same degree as withH-2 ^b, they did not react at all or reacted only weakly with theH-2 ^bd andH-2 ^bh mutants, and they reacted moderately or strongly with theH-2 ^ba mutant. The degree of crossreactivity with the mutants reflects, with one exception, the degree of relatedness of these mutants toH-2 ^b, as established by other methods. The one exception is theH-2 ^ba mutant, which is the most unrelated toH-2 ^b, and yet it crossreacted strongly. Further testing, however, suggested that in this instance the crossreactivity was probably directed against H-2 antigens: the anti-H-2D^d effectors apparently crossreacted with the H-2K^ba antigens. This finding is an example of cell-mediated crossreactivity between the products of two differentH-2 genes (H-2K andH-2D). It is also an example of anH-2 mutation generating an antigenic determinant known to be present in another strain.     

Alloreactive T cell responses and acute rejection of single class II MHC-disparate heart allografts are under strict regulation by CD4+ CD25+ T cells

Skin but not vascularized cardiac allografts from B6.H-2bm12 mice are acutely rejected by C57BL/6 recipients in response to the single class II MHC disparity. The underlying mechanisms preventing acute rejection of B6.H-2bm12 heart allografts by C57BL/6 recipients were investigated. B6.H-2bm12 heart allografts induced low levels of alloreactive effector T cell priming in C57BL/6 recipients, and this priming was accompanied by low-level cellular infiltration into the allograft that quickly resolved. Recipients with long-term-surviving heart allografts were unable to reject B6.H-2bm12 skin allografts, suggesting potential down-regulatory mechanisms induced by the cardiac allografts. Depletion of CD25+ cells from C57BL/6 recipients resulted in 15-fold increases in alloreactive T cell priming and in acute rejection of B6.H-2bm12 heart grafts. Similarly, reconstitution of B6.Rag(-/-) recipients with wild-type C57BL/6 splenocytes resulted in acute rejection of B6.H-2bm12 heart grafts only if CD25+ cells were depleted. These results indicate that acute rejection of single class II MHC-disparate B6.H-2bm12 heart allografts by C57BL/6 recipients is inhibited by the emergence of CD25+ regulatory cells that restrict the clonal expansion of alloreactive T cells.     

Limiting dilution analysis of alloantigen-reactive T lymphocytes. III. Effect of priming on precursor frequencies.

The effect of specific priming with alloantigens on the frequency of cytolytic T lymphocyte precursors (CTL-P) has been investigated. Alloimmune lymphoid cells were obtained from the spleen of C57BL/6 (H-2b) mice primed with DBA/2 (H-2d) tumor cells or from 14-day unidirectional mixed leukocyte cultures (C57BL/6 anti-DBA/2). CTL-P frequencies directed against H-2d alloantigens were estimated by limiting dilution analysis in a sensitive micro MLC system. Under these conditions, an apparent increase of 3 to 4-fold in CTL-P frequency was observed in alloimmune (as compared with normal) C57BL/6 spleen cells. Evidence was obtained suggesting that this increase was specific for the priming alloantigens. A much greater increase in CTL-P frequency (25 to 100-fold) was observed after alloimmunization of C57BL/6 spleen cells in unidirectional MLC. Under the latter conditions, 5 to 20% of the surviving splenic MLC cells could be identified operationally as CTL-P. A similar enrichment in CTL-P frequency was obtained when lymph node, peripheral blood, or thymus cells were cultured for 14 days in MLC. These studies provide direct evidence that the pool of specific CTL-P can be expanded after alloimmunization. Furthermore, the very high frequencies observed after in vitro priming indicate that this system should be particularly useful for future studies of the progeny of individual CTL-P.     

Genetic differences in BCG-induced resistance to Schistosoma mansoni are not controlled by genes within the major histocompatibility complex of the mouse.

Induction of nonspecific resistance to Schistosoma mansoni infection after the i.v. injection of viable BCG was investigated in outbred mice and a panel of inbred and H-2 congenic strains. Significant protection was induced in CF1, A/J, C57BL/6, C57BL/10, DBA/2, C57BR, and SJL mice. BALB/c mice were not protected whereas CBA and C3H mice expressed intermediate degrees of protection. Expression of the protective phenomenon is not controlled by genes within the MHC as shown by the marked differences in response between BALB/c and DBA/2 (H-2d) as well as between C57BR and C3H (H-2k) mice. H-2 congenic strains with C57BL/10 background (B10.A and B10.D2) were high responders. BALB.B10 mice carrying the high responder (B10) MHC on the nonresponder (BALB/c) background were not protected. The degree of splenic hypertrophy did not correlate with the expression of nonspecific resistance. These results demonstrate that, in addition to controlling specific immune responses, genetic differences influence the nonspecific protective phenomena related to BCG administration as well.     

Murine responses to (Tyr-Glu-Ala-Gly)n: II. H-2 and non-H-2 gene effects

Mice of the H-2^b haplotype responded to the sequential polymer poly(Tyr-Glu-Ala-Gly) in the in vitro T-cell proliferative assay, irrespective of whether they were homozygous or heterozygous at the H-2^b locus. The antibody responses of the H-2^b congenic mice to this polymer were variable, with A.BY and BALB.B showing responses better than those of C57BL/6 and C57BL/10 strains. The antibody responses of the F₁ progeny of (responder × nonresponder) strains of mice to this polymer are generally lower than the responder parents. F₁ mice with C57BL/10 background were the poorest responders. Studies with F₂ mice and backcross progenies of selective breeding of high and low antibody responder (C57BL/6 × BALB/c) F₁ to high responder C57BL/6 mice indicated that both non-H-2 genes and H-2 gene dosage effects influenced the magnitude of the humoral antibody responses. Animals having low responder non-H-2 background and only half the dosage of the responder immune response genes has greatly diminished antibody responses.     

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

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

Suppressive effects of soluble histocompatibility antigens on the in vitro generation of cytotoxic T cells to D-end alloantigens

Murine histocompatibility antigens were solubilized from the spleens and lungs of C57BL/6 (H-2b) animals with hypertonic salt (3 M KC1). Aggregate-free soluble antigens were incubated with nonadherent lymph node cells from BALB/c (H-2d) mice for 18 hr prior to their use as responder cells in the mixed-lymphocyte reaction (MLR). It was found that the generation of cytotoxic cells was suppressed while the proliferative response was not affected. The observed suppression was not due to a shift in the kinetics of the generation of cytotoxicity as determined throughout a 10-day culture period. The suppression was specific in that the response in MLR to unrelated H-2f stimulator cells and the subsequent generation of cytotoxic cells were unchanged. Using various H-2 recombinant strains as target cells in the assay of cell-mediated lympholysis, suppression of cytotoxicity was observed when the D end, but not the K end, was shared with the C57BL/6 strain from which the antigens were derived.     

Suppressor T cells arising in mice undergoing a graft-vs-host response.

We investigated the ability of mice to generate antibody-forming cells when undergoing a graft-vs-host reaction. (C57BL/6 X DBA/2)F1 mice (BDF1) injected with C57BL/6 spleen cells generated suppressor T cells which inhibit antibody synthesis by BDF1 spleen cells in vitro. These T cells arose from the donor inoculum. They differ from helper T cells in size and they act directly on antigen reactive B cells. The suppressor T cells were specifically directed against components of the H-2 region of the reciprocal parental strain (DBA/2 = H-2d) in the hybrid F1 mouse.