Genetic control of the immune response to the H-2Dk private specificity, H-2.32. II. Genetic linkage analysis of a backcross generation.

B10.AKM mice (H-2M) when immunized with H-2k cells showed very low cytotoxic antibody responses to the H-2Dk private specificity H-2.32, whereas AKR.M and (AKR.M X B10.AKM)F1 mice that possess the same H-2m haplotype mounted reasonable anti-H-2.32 antibody responses. The genetic nature of the non-H-2 linked gene(s) controlling the anti-H-2.32 response was analyzed on the backcross progeny raised between (AKR.M X B10.AKM)F1 and B10.AKM mice. The anti-H-2.32 antibody response was found to be predominantly controlled by a single locus. This locus segregated independently of the Ig heavy chain locus, the Ly2 locus, and the Mls locus. Despite the observed difference in antibody production, no significant differences between AKR.M and B10.AKM mice were detected in induction of H-2Dk-specific killer T cells. Thus, the defect in the response of B10.AKM mice to H-2.32 can be detected at the level of B cell function and is controlled by a single non-H-2-linked genetic locus, but is not attributable to genes linked to the major immunoglobulin structural genes nor to the Mls locus.     

Regulation of idiotope expression. III. H-2 influences the magnitude and the idiotypy of a T-independent antibody response in mice of certain genetic backgrounds

Antibody response to the phosphocholine (PC) epitope on Streptococcus pneumoniae R36a (Pn), a T-independent Ag type 2, was studied in H-2 congenic mouse strains. The PC-specific antibody plaque-forming cells (PFC) were enumerated in the spleen at various intervals after the primary Pn injection, and the proportion of PFC that produced antibody expressing the AB1-2 idiotope (Id) was determined by using the corresponding monoclonal anti-Id. AB1-2 is a cross-reactive Id, detectable on germline-encoded PC antibody of the T15 family, and on most, but not all, somatic variants of that antibody. The specific PFC responses in BALB/c (H-2d) and BALB.B (H-2b) strains were of comparable magnitude and most, if not all, PFC were ABl-1 Id-positive (AB1-2+). This was not the case in the responses of the B10D2 (H-2d) vs C57BL/10 (H-2b) strains and the D1.C (H-2d) vs D1.LP (H-2b) strains (on DBA/1 background). In each of these pairs, the H-2d mice were high responders, and the response was dominated by AB1-2 Id (greater than or equal to 80% AB1-2+ PFC at the peak, on day 5). The H-2b mice were low responders, and only a minor proportion of PFC (less than or equal to 30%) were AB1-2+; an increase of AB1-2+ was seen later in the response (d.10). The results of PFC assays were confirmed by measuring the PC-binding antibody and AB1-2 Id in the sera of D1.C and D1.LP mice immunized repeatedly with Pn. Moreover, D1.LP mice that had very low levels of AB1-2 Id had higher serum levels of antibody expressing two other T15 Id, B36-82, and B24-44. The B36-82 and B24-44 Id have been previously found on somatic variants of PC antibody expressed independently of the Ab1-2 Id. The concentrations of these two Id in D1.LP mice after repeated immunization approached those in D1.C. These results indicate that 1) the H-2 allelism may have a significant effect on TID antibody response in mice of a certain genetic background, but not in the BALB/c; and 2) the idiotypic repertoire of the response may be influenced by H-2 at the level of clonal variants of PC-reactive cells.     

Modulation of F1 cytotoxic potentials by graft-vs-host reaction. Cooperative non-H-2- and H-2D region-gene control of F1 natural resistance to graft-vs-host reaction-associated immunosuppression

Our previous study revealed that in F1 mice raised by crossing C3H/He or AKR/J mice with various H-2-congenic B10-series strains, parental H-2k spleen cells (SC) could not induce the graft-vs-host reaction (GvHR)-associated immunosuppression (GAIS). We also elucidated that a limited number of non-H-2 genes of parental C3H/He or AKR/J mice that had been incorporated into the F1 hybrids determined the F1 resistance to the GAIS, and the present study was done to explore the mechanism implicated in this type of F1 resistance to GAIS. SC from B10.AL mice carrying an rH-2 (K:k I:k S:k D:d) haplotype but not SC from H-2K B10.BR (k k k k) mice induced GAIS of in vitro CTL responses to third-party alloantigens in H-2k/d (C3H/He x B10.D2)F1 recipients mice. Further, SC from H-2k/a (C3H/He x B10.A)F1 mice carrying heterozygous C3H/B10 non-H-2 background but not SC from the same H-2k/a (B10.BR x B10.A)F1 mice but carrying homozygous B10/B10 background induced GAIS in H-2k/d (C3H/He x B10.D2)F1 recipients. Although C3H/He-, B10.BR-, and C3H.OH (d d d k)-SC were incapable of inducing GAIS in (C3H/He x B10.D2)F1 (k/d k/d k/d k/d) recipients, they were all good inducers of GAIS in (C3H.OH x B10.BR)F1 (d/k d/k d/k k/k) recipients. Exactly the same pattern of co-operative non-H-2 AKR and H-2D region-gene control of GAIS was observed on GvHR induced in H-2k/d (AKR/J x B10.D2)F1 recipients. These results suggest that the non-H-2 genes of C3H/He or AKR/J strain inhibit the functional expression of certain antigenic determinant(s) when it is encoded by heterozygous but not homozygous gene(s) linked tightly to H-2D region of k haplotype. Thus, the F1 resistance to GAIS is mediated by immune response of F1 recipients who miss the antigenic determinant(s) against that expressed on cell surface of GvHR-inducing T lymphocytes.     

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.     

The antibody repertoire to proteins of Mycobacterium leprae. Genetic influences at the antigen and epitope level.

The effects of both H-2 and non-H-2 genes on the antibody response to the proteins of Mycobacterium leprae were investigated. Using a B10 series of congenic mice we found that the repertoire of antibody responses was under H-2 gene control, and that non-H2 genes were also involved. By Western blotting, differences in the number and m.w. of proteins recognised by mice of different genetic background were apparent. Such differences were also reflected in the total antibody response to a soluble extract of M. leprae (M. leprae sonicate), as measured by ELISA. Concentrating on one particular Ag, the 65-kDa heat shock protein, we found that all strains of mice developed antibodies following immunization with the purified recombinant protein, although there was a continuous distribution in the titer of antibodies obtained, with differences between individual strains indicating both H-2 and non-H-2 effects. Using a library of overlapping peptides based on the amino acid sequence of this protein, we have mapped the B cell epitopes in the different strains of mice. H-2 genes had no effect on the structure and number of epitopes recognized, although this was influenced by non-H-2 genes. There was a high level of concordance between actual epitopes recognized and those predicted by calculations of antigenic index, and B cell epitopes were located in similar positions to previously determined T cell epitopes.     

Functional differentiation in the genetic control of murine T lymphocyte responses to human fibrinopeptide B

The ability to generate proliferative and helper T lymphocyte responses in mice was compared by using the 14 amino acid peptide, human fibrinopeptide B (hFPB). Lymph node or peritoneal exudate T cells from mice immunized with hFPB were assessed for in vitro proliferation to soluble hFPB as determined by the uptake of 3H-thymidine. The T cell proliferative response to hFPB was found to be under MHC-linked Ir gene control; mice possessing the H-2a,k haplotypes were responders, whereas H-2b,d,q,s mice were nonresponders. The influence of non-H-2 genes on these responses was not investigated, so exclusive regulation by H-2 is provisional. The absence of a detectable lymph node and peritoneal exudate T cell proliferative response persisted in H-2b,d,q,s mice after immunization and boosting with several doses of hFPB. In addition, the capacity to produce a T cell proliferative response was inherited in an autosomal dominant manner and gene(s) controlling responsiveness to hFPB mapped to the I-A subregion of the H-2 complex. To measure peptide-specific helper T cell activity, an in vitro microculture assay in which hFPB-primed lymph node T cells and normal spleen B cells and macrophages were used was developed measuring anti-fluorescein isothiocyanate (FITC) IgM and IgG plaque-forming cell (PFC) responses after culture with FITC-conjugated peptide. Immunization of B10.BR, C57BL/10, B10.D2, and B6AF mice with hFPB primed for significant helper T cell activity as assessed by the ability to augment a primary in vitro IgM response to FITC. The normal B cell IgM responses were completely dependent on hFPB-primed T cells and required that hapten (FITC) and carrier (peptide) be linked. In addition, immunization with FITC-conjugated peptide elicited positive in vivo PFC responses to FITC in B10.BR and C57BL/10 mice, indicating similar genetic control of helper activity in both the intact animals and the in vitro microcultures. Thus, B10.BR mice show both T help and T proliferative responses to hFPB, whereas C57BL/10 mice show only T help and no T proliferative responses. In contrast to B10.BR mice, C3H and CBA mice immunized with hFPB were completely unresponsive when assayed for helper T cell activity in vitro despite their ability to generate positive lymph node T cell proliferative responses. These results indicate responsiveness to hFPB by T helper and proliferating cells is different and is under separate genetic control.     

H-2-linked genetic control of the plaque-forming cell response to sheep red blood cells

The role of genes linked to the H-2 locus in effecting an immune response to SRBC was examined using strains of mice which differ in the classes of antibodies produced following multiple injections with SRBC. While H-2-linked gene action appeared to be at the level of regulating the number of plaque-forming cells (PFC) present in the spleens of different strains following two injections with SRBC, non-H-2-linked immune response genes seemed to determine whether an IgM-IgG switch occurred as well as how much of each antibody class was produced by the number of PFC available as a result of H-2-linked gene intervention. Mapping studies showed that the H-2-linked genetic effects were due to either the requirement for two genes or the presence of genes located between I-B and H-2D.     

Influence of immunizing dose and presence or absence of adult worms on the development of resistance to Nematospiroides dubius challenge infections of mice

H-2 congenic strains expressing resistant (H-2q, H-2f) or susceptible (H-2k) haplotypes were compared for their ability to resist challenge infection with N. dubius following a 6- or 14-day ivermectin-abbreviated immunizing infection. B10.BR mice (H-2k) were considerably more resistant to infection when the priming interval was shortened from 14 to 6 days. B10.Q (H-2q) and B10.M (H-2f) mice resisted challenge regardless of which immunization regimen was used. The influence of parasite numbers on the response to challenge was studied by comparing infections in resistant DBA/1 (H-2q) and susceptible CBA/J (H-2k) mice that differ at both H-2 and non-H-2 genes. DBA/1 mice, immunized with 50 or 150 L3 of N. dubius for 14 days, resisted challenge, whereas mice receiving 300 worms did not. In contrast, CBA/J mice failed to resist challenge at all priming doses tested. When the immunizing infection was shortened from 14 to 6 days, DBA/1 mice resisted challenge regardless of priming dose and CBA/J mice resisted challenge only when the highest dose of 300 worms was used for priming. The data suggest that susceptible strains of mice may be preferentially immunosuppressed, particularly at low infective doses, and that suppression is associated with adult worms present in the lumen of the small intestine.     

Insertion of the B2 sequence into intron 13 is the only defect of the H-2k C4 gene which causes low C4 production.

The serum level of the fourth component of complement (C4) in mice bearing H-2k haplotype is only 1/10 of that of non-H-2k mice. H-2k bearing mice, but not non-H-2k bearing mice, have an insertion of the B2 sequence into intron 13 of the C4 gene, and aberrant C4 mRNA in liver apparently generated by abnormal RNA splicing caused by the insertion of the B2 sequence. To test the possible causal relationship between the B2 insertion and low C4 production in H-2k mice directly, we constructed the H-2k C4 gene without the B2 insertion and the H-2w7 (non-H-2k) C4 gene with the B2 insertion by exchanging a part of intron 13 between these two genes. Transfection of the intact H-2w7 C4 gene or the chimeric H-2k gene without the B2 insertion into HepG2 cells resulted in the production of only normal C4 mRNA at the normal level. On the other hand, the intact H-2k C4 gene or the chimeric H-2w7 C4 gene with the B2 insertion directed production of both aberrant and a decreased amount of normal C4 mRNA. These results demonstrated that the insertion of B2 sequence into intron 13 of the C4 gene is the only determinant of low C4 production by H-2k mice through aberrant RNA processing.     

Genetic restrictions in the development of antibody responses to L-glutamic acid60-L-alanine30-L-tyrosine10 by nude mice implanted with semiallogeneic thymus glands

Athymic nude mice implanted with F1 thymus glands were used to investigate genetic restrictions regulating T cell-macrophage (M phi) interactions in the development of antibody responses to GAT. Spleen cells from conventional mice developed comparable primary plaque-forming cell (PFC) responses when stimulated by syngeneic and allogeneic GAT-M phi. However, spleen cells from strain A nude mice implanted with (A X B)F1 thymus glands were tolerant of strain B alloantigens and developed GAT-specific PFC responses to strain A GAT-M phi and allogeneic strain C GAT-M phi, but failed to respond to strain B GAT-M phi. The lack of primary GAT-specific PFC responses by spleen cells from (A X B)thy----A nude mice stimulated by strain B GAT-M phi was not due to detectable suppressor mechanisms. However, an allogeneic effect stimulated by H-2- or non-H-2-disparate GAT-pulsed or unpulsed M phi was able to overcome the inability of spleen cells from (A X B)F1 thy----A nude mice to respond to strain B GAT-M phi. Furthermore, the inability to respond to strain B GAT-M phi was overcome by the addition of supernatant fluids from independent cultures of H-2-disparate cells. These results 1) demonstrate that T cells from A nude mice implanted with (A X B)F1 thymus glands did not recognize nominal antigen in the context of B MHC antigens, and 2) suggested that the T cell repertoire was altered in strain A nude mice implanted with (A X B)F1 thymus glands, such that T cells that could recognize GAT in association with strain B MHC antigens were functionally deleted.     

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.     

AKR/J gene(s) unlinked to H-2 determines dominant inheritance of lymphocyte hyporesponsiveness to acetylcholine receptor

Mice with the H-2b major histocompatibility complex haplotype are high immune responders to nicotinic acetylcholine receptors (AChR), whereas mice with the H-2k haplotype are generally low responders. F1 progeny of C57BL/6 (H-2b) mice crossed with mice of most H-2k strains are high responders to AChR in standard conditions of testing helper T cell proliferation in vitro (4 X 10(5) lymph node cells/microwell, 1 wk after primary challenge in vivo). In contrast, the F1 progeny of AKR/J (H-2k) crossed with high responder (H-2b) strains (B6, A.BY, or C3H.SW) were all hyporesponsive to AChR when lymphocytes were tested at 4 X 10(5) cells/well. However, at a density of 1 X 10(6) or greater/well, a high level of antigen-specific responsiveness was demonstrable in the F1 hybrid lymphocytes. A shift from low to high responsiveness to AChR at high cell densities was observed also in the H-2b strain AKR.B6. Other strains previously demonstrated to be low responders to AChR did not become responsive to AChR when lymphocyte numbers were increased to 1.4 X 10(6)/well. The N2 generation yielded by backcrossing (AKR X B6)F1 mice to AKR/J were all low responders, whereas N2 progeny derived by backcrossing F1 to B6 were high or low responders in a ratio of approximately 1:1 (independent of their H-2 phenotype). Results consistent with this observation were obtained in (AKR X B6) F2 mice. These data suggest that at least one AKR/J gene outside of the H-2 complex exerts a hyporesponsive influence on the I-A-dependent helper T cell response to AChR in H-2b mice.     

Primary in vitro cytotoxic response of F1 T lymphocytes against parental antigens.

Spleen cells from adult female (AKR/J x BALB/(c)F1 mice can respond to mitomycin C-treated spleen from AKR/J mice and can generate effector CTL in a 5-day primary in vitro culture. The response is comparable in magnitude to the response to allogeneic H-2K or H-2D antigens. The response is T cell mediated and is directed to antigen(s) present only on the parental cells. The target cell must be homozygous at H-2Kk to be lysed and H-2Dk antigens do not serve as a target in this response. Spleen cells from (B10.BR x B10.D2) hybrids that have been stimulated with AKR/J lyse B10.Br as well as AKR/J target cells. Similar H-2k/d hybrid F1 anti-H-2k parent responses are seen in certain other strain combinations. A number of possible interpretations of these responses are discussed.     

Modulation of F1 cytotoxic potentials by GvHR: role and mode of action of non-MHC genes that determine the hybrid resistance to GvHR-associated suppression of F1 cytotoxic potential

The resistance of unirradiated F1 mice against graft-vs-host reaction (GvHR) induced by lymphocytes from certain parental strains is apparently a violation of the basic law in classical transplantation immunity. To explore genetic mechanisms of this peculiar phenomenon, GvHR-associated immunosuppression was examined on various kinds of F1 mice undergoing GvHR induced by parental lymphocytes. In F1 mice raised by crossing DBA/2 mice with various H-2-congeneic B10-series strains, parental lymphocytes having non-H-2 genetic background of DBA (DBA/2 and DBA/1) invariably could not induce GvHR-associated immunosuppression, irrespective of the H-2 haplotype incompatibility involved, whereas lymphocytes of the partner parental strain induced the immunosuppression. The number of the relevant loci in the DBA non-H-2 was assessed to be three recessive loci by examination of the capability to induce the GvHR-associated immunosuppression on lymphocytes from individual (B 10.D2 X DBA/2)F1 X DBA/2 backcross mice. On the other hand, in F1 mice raised by crossing C3H/He or AKR/J mice with various H-2-congeneic B10-series strains, parental lymphocytes of H-2k haplotype, irrespective of their non-H-2 haplotype, invariably could not induce the GvHR-associated immunosuppression. Furthermore, it was revealed that non-H-2 genes of parental C3H or AKR incorporated in the F1 mice determine the resistance of the F1 mice against the H-2k-induced GvHR. The results of examination of the resistance on individual (B10 X [B10.BR X C3H/He]F1) and (B10 X [B10.BR X AKR/J]F1) mice suggested that three non-H-2 loci of C3H/He or two non-2 loci of AKR/J incorporated in F1 hybrids could determine the resistance of the respective F1 mice.     

Genetic control of the IgG2a response to sheep erythrocytes in mice: isotype- and antigen-specific T cell-mediated suppression in low responders.

The IgG2a response to sheep erythrocytes is examined in different congenic strains of mice. B10, B6, and C57BL/Ks animals produce a low level of IgG2a antibodies to SRBC during the primary response in vivo. They remain low responders after secondary challenge in vitro. Total spleen cells or nylon-purified T cells from these low responders inhibit the IgG2a response of H-2 compatible-responding mice in a mixed culture system. This suppression is mediated by Thy-1+, Ly-1-, Ly-2+, and I-J+T cells only present in the spleen of low responding animals. These suppressor T cells appear to be IgG2a- and SRBC-specific. Function of non-H-2-linked genes as regulators of suppressor T cells differentiation is discussed.     

The antibody response in mice to carrier-free synthetic polymers of Plasmodium falciparum circumsporozoite repetitive epitope is I-Ab-restricted: possible implications for malaria vaccines

The immunogenicity of a novel synthetic peptide consisting of an average of 40 (Asn-Ala-Asn-Pro) repeats of the circumsporozoite protein of Plasmodium falciparum, (NANP)40, was studied in mice without using any carrier proteins. First, high titers of anti-(NANP)40 antibodies could be obtained after immunization of C57BL/6 mice. These antibodies also reacted with an extract of mosquitoes infected with P. falciparum sporozoites. C57BL/6 nu/nu mice did not produce antibodies against (NANP)40. Secondly, when 14 strains of mice with nine different H-2 haplotypes were immunized with (NANP)40 without carrier, only H-2b mice were found to produce anti-(NANP)40 antibodies, whereas all non-H-2b mice were consistently unresponsive. This response was demonstrated to be I-A-linked by using recombinant and mutant mice. I-Ab [B10.A(5R)] mice produced anti-(NANP)40 antibodies as well as H-2b inbred mice. B6CH-2bm12 I-Ab-mutant mice showed only a very low response. Third, the antibody response against (NANP)40 could be induced in nonresponder mice by immunization with the peptide coupled to a carrier protein. In view of the existence of such an exceptional H-2b restriction in the response to sporozoite synthetic peptides in mice, the triggering of peptide-specific T cell responses in humans receiving sporozoite malaria vaccines might be difficult to achieve.     

Haplotype-Specific Interactions of Non-H-2-Linked Genetic Factors Controlling the Mouse C4 and Slp Protein Levels

The influence of non-H-2 linked genes on the plasma levels of the H-2 S-region encoded proteins C4, Slp, and factor B was tested in Recombinant Inbred (RI) strains. The A X B and B X A RI strains exhibit a continuous range of C4 and Slp levels from very high to very low which reach beyond the levels of their parental strains, C57BL/6J and A/J, indicating involvement of several trans-regulatory (non-H-2-linked) genes. Only limited variation in levels of factor B has been found. No linkage relationship could be established for the trans-regulatory genes, because more than one gene is involved. A complex interaction of H-2 haplotype, genetic background, sex, and possibly maternal effect in determining the C4 and Slp protein plasma levels has been observed. The H-2-dependent sex effect is evident, because males have higher C4 levels than females in RI strains with H-2b but not with H-2a haplotype. This sex effect is also background dependent, because it is present in the H-2b congenic strain on A background (A.BY) but not in C57BL/10 and C57BL/6 (both H-2b). Mice from RI strains with H-2b haplotype have in general higher C4 levels than mice with H-2a haplotype.     

Inheritance of tolerance susceptibility to human gamma-globulin in congenic mice.

The genetic control of susceptibility to tolerance induction with human gamma-globulin (HGG) was studied by using H-2 congenic mice. Strains tested that were congenic with C57BL/10Sn were completely tolerized by 1.0 mg deaggregated HGG. In contrast A/Sn mice showed full tolerance whereas A.SW mice were only intermediately tolerant. It was further shown that (B10 X SJL)F1 mice could be rendered tolerant but (B10.S X SJL)F1 mice could not. These data indicate a role for H-2 linked genes in control of tolerance susceptibility. Results obtained with the progeny of (B10.S X SJL)F1 backcrossed to B10.S indicate that two non-H-2 linked genes are involved in control of tolerance induction. Preliminary mapping studies show the H-2 gene located to the left of the IC subregion. These results confirm our previous finding that both H-2 and non-H-2 genes control susceptibility of adult mice to tolerance induction with HGG.     

Dominant low responsiveness in the IgG response of mice to the complex protein antigen type 1 fimbriae from Actinomyces viscosus T14V.

Type 1 fimbriae from Actinomyces viscosus T14V, composed of a complex protein of Mr 65,000, mediate the adherence of A. viscosus T14V to the host, whereas type 1 fimbriae-specific antibodies inhibit adherence. Genetic control of the serum IgG response to type 1 fimbriae was evaluated in a series of inbred, hybrid, recombinant inbred, and back-cross mice. Mice were given i.p. injections of 10(8) A. viscosus T14V cells in saline on days 0 and 14, and IgG anti-type 1 fimbriae in sera obtained on day 26 were measured by ELISA. Segregation analysis of the responses of (BALB/cJ x A/J)F1 x A/J backcross mice suggested polygenic control. Linkage analysis in (BALB/cJ x A/J)F1 x A/J backcross and SWXL recombinant inbred mice suggested control by genes linked with H-2 and with Ly-17 and Akp-1. In several F1 hybrid strains derived from H-2-disparate high and low responder parental strains, low responsiveness was dominant. The F1 derived from the H-2-identical high and low responder strains CBA/J and C3H/HeJ was a low responder, suggesting that dominant low responsiveness was mediated by non-H-2-linked genes. A three-gene model is proposed for regulation of the type 1 fimbriae response, including an MHC-linked gene, a gene linked with Ly-17 and Akp-1 on the telomeric portion of chromosome 1, and a background gene whose linkage is unknown.     

Genetic and nongenetic control of the immune response of mice to a synthetic glycolipid, stearylisomaltotetraose

Evidence for genetic control of antibody response to stearylisomaltotetraose (ST-IM4), a chemically defined synthetic glycolipid, was studied in various mouse strains. Anti-glycolipid antibodies were induced by repeated injections of ST-IM4 in complete Freund's adjuvant. C57BL and CBA/J mice were found to be good responders, while A/J, SJL/J, and AKR/J mice were poor responders. Responsiveness is independent of the H-2 genotype since AKR/J and CBA/J mice share the same H-2 locus. In addition, B10.A and B10.PL mice developed antibody levels similar to those of C57BL. The immunoglobulin heavy-chain locus (IgCH) was also found not to control antibody levels to ST-IM4 since C57BL and SJL/J mice share the same IgCH allotype. In C58/J mice, wide variation in response was observed among individual mice. Study of the response to ST-IM4 in 12 breeder pairs from different family lines of the C58/J colony also indicated that the regulation of the immune response to ST-IM4 is apparently more complex than can be explained by single gene control. C58 mice, unlike many other strains, had very low preimmune titers.