H-Y antigen: No evidence for alleles in wild strains of mice

H-Y antigen(s) coded or controlled by the Y chromosome in a variety of wild mouse strains have been compared with those of the inbred laboratory strains C57BL/6 (B6) and C57BL/10 (B10). H-Y antigen(s) were detected by H-2-restricted cytotoxic T cells from B6 and B10 female mice primed in vivo and boosted in vitro with syngeneic male spleen cells: There was no difference in the degree of H-Y specific lysis of male cells from the C57BL strains and of F₁ hybrids or B6 congenic mice carrying the Y chromosome from the wild mouse strains examined. This result indicated that at the level of target cell specificity the H-Y antigen(s) from wild and laboratory strains were indistinguishable. H-Y antigen(s) were also found to be indistinguishable at the level of the in vitro induction of the anti H-Y cytotoxic response: F₁ female mice, primed in vivo and boosted in vitro with homologous F₁ male cells, all made H-Y-specific responses and where it could be examined, the target cell specificity of the anti-H-Y cytotoxic cells showed that B10 male cells as well as the homologous F₁ male cells (where the Y chromosome was derived from the wild strain) were good targets. Finally, possible differences in H-Y transplantation antigens between the wild strains and the B10 laboratory strain were examined by grafting F₁ male mice, the progeny of B10 females, and wild strain males with B10 male skin. These grafts were not rejected during an observation period of more than 9 months. Taken together, neither the cytotoxic data nor the skin graft data provide any evidence for allelism of H-Y even though the mouse strains examined were collected from widely disparate geographical locations.     

Helper effects required during in vivo priming for a cytolytic response to the H-Y antigen in nonresponder mice

Induction of H-Y-specific cytotoxic T lymphocyte (CTL) responses in nonresponder female mice was attempted by i.v. injection of allogeneic male cells, followed by in vitro restimulation of recipient spleen cells with syngeneic male cells. Responses were obtained only in two strain combinations in which the recipients, although phenotypically nonresponders, carried responder alleles at class I major histocompatibility complex (MHC) loci, and the immunizing cells differed from the recipients at class II MHC loci. The two positive strain combinations were B10.A(2R) anti-B10.A(4R), and B10.GD anti-B10.D2(R101). In the first combination, both recipient and donor are nonresponders to H-Y, and the CTL are induced via a bystander effect of another CTL response to a previously undetected minor histocompatibility (H) antigen. This "carrier" antigen can only induce CTL against H-Y and itself when the immunizing cells express class II MHC molecules. Furthermore, the presence of H-Y and the carrier antigen on the same cell is a prerequisite for the generation of H-Y-specific CTL. In the second combination, the recipient is a nonresponder, whereas the donor is a responder. The two strains differ at only E alpha and E beta class II MHC loci. For the induction of CTL, H-Y and the foreign E molecule must be expressed on the same cells. Thus, the B10.D2(R101) cells that express E molecules on their surface probably provide the E-nonexpressor B10.GD recipients with a stimulus for the generation of H-Y-specific T helper cells. The data are consistent with the notion that antigen-specific class II MHC-restricted T helper cells are involved in the initiation of CTL responses to minor H antigens.     

Frequency and cross-reactivity od cytolytic T lymphocyte precursors reacting against male alloantigens

It is well established that cytotoxic T lymphocytes (CTL) specific for the male minor histocompatibility antigen (H-Y) are generated by restimulation in vitro of in vivo primed spleen cells from C57BL/6 (H-2b) female mice with syngeneic male spleen cells. When tested on target cells from H-2 different strains, the male-specific C57BL/6 CTL populations exhibited significant lysis of DBA/2 (H-2d), A (H-2a), but not C3H (H-2k), male and female target cells. In an attempt to document this cross-reactivity further at the clonal level, a sensitive technique of limiting dilution analysis was used to determine the specificity of C57BL/6 individual CTL precursors (CTL-P) reactive against the male antigen. The mean frequency of anti-H-Y CTL-P in spleens of primed female mice was about 1/3500. Between one-third to one-tenth of these CTL-P produced a progeny that cross-reacted with H-2d (allogeneic) female target cells. These findings were confirmed by the analysis of the reactivity pattern exhibited by male-specific CTL clones derived by limiting dilution. Of 99 clones tested, 13 were found to cross-react with female DBA/2 target cells. These results thus indicate that a relatively large proportion (greater than 10%) of H-2b CTL-P directed against the H-Y antigen cross-react with target cells expressing H-2d alloantigens in the absence of H-Y antigen.     

The male antigen. II. Regulation of the primary and secondary responses to H-Y by H-2 associated genes

The primary response of females of ten inbred mouse strains to the male antigen (H-Y) was investigated by transfer of peritoneal exudate cells (PEC). Three distinct classes of reactivity were seen. Early primary response to H-Y was associated with H-2 haplotypes b and s; intermediate response with H-2 haplotypes, k, d, i, and h; and late or absent response with H-2 haplotypes a and f. The failure of A.CA (H-2^f) females to mount a detectable primary response against syngeneic male cells was not due to the lack of the antigen from A.CA male cells. The ability of (A.CA × B10)F₁ hybrid females to respond to the male antigen demonstrated the dominant nature of the B10 (H-2^b) response and excluded the possibility that A.CA females possess a dominant self-antigen cross-reactive with H-Y. The secondary response of eight inbred strains was investigated; at least three distinct levels of reactivity were apparent. The speed of the secondary response was associated with the various H-2 haplotypes in the same way as the primary response. The implications of differential strain reactivity, background effect, and the association of Ir-1 with response to H-Y are discussed.     

Delayed-type hypersensitivity responses to H-Y: Characterization and mapping ofIr genes

This paper examines the delayed-type hypersensitivity (DTH) response to male (H-Y) antigen(s). Female mice of theH?2 ^b haplotype developed delayed footpad reaction to syngeneic or allogenic male thymus and spleen cells after priming with syngeneic male thymus and spleen cells. The reaction peaks at 24 h, has classical DTH histology and is specific to H-Y antigen as it is not elicited with female cells. Cell transfer studies show that donor/recipient matching at theI?B ^b subregion is necessary for sucessful transfer of DTH and that the effective primed population is Thy-1⁺, Lyt-1⁺, 2^?. DTH response to H-Y antigen appears to be confined to mice of theH?2 ^b haplotype. There appears to be a lack of associative recognition between H-Y antigen and MHC-coded determinants in the effector phase of DTH, and macrophage processing of H-Y seems likely, since nonresponder haplotypes can elicit the DTH response. Studies withH?2 ^b recombinant mouse strains indicate that the dominantIr gene is located in theI?B region. Female F₁ hybrid mice derived from matings of strains not involvingH?2 ^b haplotype failed to develop DTH to H-Y. In summary, these data imply that a complete correlation exists between DTH to H-Y and the ability to reject male skin graft, suggesting that the effector mechanisms of skin-graft rejection may closely involve DTH cells.     

Unsuitability of the assay for cell-mediated lympholysis in inbred mice for H-Y antigen determination of human cells

Summary This study examined the H-Y-specific in vitro restimulation of splenocytes from in vivo intraperitoneally (i.p.) primed C57B1/6 (B6) female mice. In vivo priming was carried out with human male or female fibroblasts or peripheral blood lymphocytes, respectively. It was attempted to measure the in vitro H-Y-specific activity by cell-mediated lympholysis and by cell proliferation. ³[H]Thymidine incorporation was determined in mixed lymphocyte cultures (MLCs) of xenogenetic primed female splenocytes (responder cells) and of syngeneic lethally irradiated male splenocytes (stimulator cells). The xenogenic H-Y presentation by in vivo sensitization did not induce in the in vitro restimulation system an H-Y-specific cell proliferation or in the effector phase the generation of H-Y-specific killer cells. The assay for celimediated lympholysis and lymphocyte proliferation after xenogeneic priming and syngeneic in vitro restimulation is, thus, not suitable for H-Y testing of human cells.     

Interaction of monoclonal antibodies with MHC class I antigens on mouse spleen cells. II. Levels of expression of H-2K, H-2D, and H-2L in different mouse strains

The numbers of MHC class I molecules expressed by spleen cells from various mouse strains were determined by using MHC-specific monoclonal antibodies and a radioactive binding assay. Although small differences were found to exist in some cases, our general conclusion is that different mice of the same strain, congenic mice of different haplotypes, and syngeneic mice of varying background all express similar numbers of class I antigens. B10.A mice (8 to 10 wk old), for example, express 5.3 X 10(4) Kk molecules/cell, 5.4 X 10(4) Dd molecules/cell, and 2.2 X 10(4) Ld molecules/cell. Some of the differences observed in class I antigen expression included: 1) the level of Kk expression increased to a small but significant extent with age in B10.A mice; 2) female B10.A mice expressed slightly higher amounts of Kk than male mice; and 3) B10.A(2R) and B10.A(4R) recombinant strains expressed elevated levels of K-end antigens and slightly decreased levels of D-end antigens when compared with the unrecombinant B10.A strain. In several strains, F1 mice express approximately 50% as many copies of each parental antigen as do the homozygous parents. B10 mice, which are negative for the L antigen, nevertheless express the same total number of D-end molecules as do B10.A mice. The data suggest that the levels of expression of MHC class I molecules are controlled by at least two factors: gene dosage and another factor(s) that gives rise to the small variations in class I antigen expression seen with age, sex, and strain, and to the low expression of Ld relative to Dd and Kk.     

Anti-receptor antibody-induced H-Y-specific delayed-type hypersensitivity responses in nonresponder mice

The present study examines an antiserum prepared against antigen-reactive T cells that induces murine H-Y-specific delayed-type hypersensitivity (DTH) responses. This anti-H-Y receptor antibody (ARA) was raised in C57BL/6 male mice against splenic T lymphocytes from H-Y immune syngeneic females. Subcutaneous administration of ARA to cyclophosphamide-pretreated C57BL/6 females is able to induce H-Y-specific delayed-type footpad swelling responses. The DTH inducing capacity in ARA was selectively retained on rabbit anti-mouse immunoglobulin columns and was absorbed completely by H-Y immune lymphoid cells from C57BL/6 females. The induction of H-Y DTH reactivity was due at least in part to the activation of H-Y antigen-specific T lymphocytes that could adoptively transfer DTH-like responses to naive female mice. ARA induces DTH responses in strains with the same lgh regions, including selected strains of H-Y nonresponders. Therefore, MHC-linked lr genes do not appear to be as critical when responses are triggered by ARA instead of by antigen. Possible mechanisms for the induction of immune responses by ARA are discussed.     

The pigeon cytochrome c-specific T cell response of low responder mice. I. Identification of antigenic determinants on fragment 1 to 65

An examination of the proliferative response to pigeon cytochrome c fragments 1 to 65 and 1 to 80 by T cells from mice that are low responders to the native molecule revealed that some of the strains could respond to antigenic determinants on these fragments. T cell clones derived from B10.A(3R) and B10.A(4R) mice were used to characterize the antigenic determinants on fragment 1 to 65. All of the clones recognized syngeneic A beta:A alpha Ia molecules as their restriction element. Three B10.A(3R) clones and six B10.A(4R) clones recognized fragment 39 to 65. Another four B10.A(4R) clones responded to fragment 1 to 38. By stimulating with a series of cytochrome c fragments from different species, as well as a synthetic peptide, it was possible to localize the antigenic determinant(s) recognized by the B10.A(3R) clones to residues 45 to 58. Each clone showed a unique pattern of responsiveness to the various fragments, suggesting a diversity of T cell receptors specific for the same peptide. One B10.A(3R) clone could be stimulated by many of the 1 to 65 fragments in association with allogeneic B10.SM presenting cells and by tuna fragment 1 to 65 in association with B10.M presenting cells, although the rank order of potency for several of the fragments was different than that observed with syngeneic antigen-presenting cells. In addition, the clone was poorly reactive to a synthetic peptide containing a conservative substitution, serine for threonine, at position 49. The implications of these results for subsite dissection (agretope and epitope) of the antigenic determinant recognized by this clone are discussed.     

Graft-vs-host reactions (GVHR) across minor murine histocompatibility barriers. II. Development of natural suppressor cell activity

We explored the immunoincompetence of mice undergoing a chronic graft-vs-host reaction (GVHR) across minor histocompatibility barriers. BALB/c and B10.D2 mice are H-2d and mls b, and differ only with regard to minor histocompatibility antigens (MiHA). A large number of BALB/c mice were unirradiated or were irradiated with 300, 600, or 900 R. They then were injected with 5 X 10(7) spleen cells from either allogeneic B10.D2 or syngeneic BALB/c mice. The spleen cells from these recipient mice were assayed at various times post-irradiation/injection for their proliferative response to Con A and LPS, their ability to suppress the mitogen responses of normal spleen cells, and for the genetic specificity of this suppression. Spleen cells from BALB/c mice that had received 600 or 900 R (but not 0 or 300 R), and allogeneic B10.D2 lymphocytes, became very hyporesponsive to mitogens and became suppressive in vitro by days 7 to 10 post-irradiation/injection. These phenomena persisted for the entire 49 days of the experiment. After an initial period of splenomegaly, the spleens of these mice gradually became depleted of viable lymphocytes. Initial characterization of suppressor cells found in the spleens of GVH mice showed that they were not removed by treatment with anti-Thy-1.2 plus complement. GVH suppressors also were not adherent to plates coated with antiserum directed towards murine Ig. In addition, these cells did not adhere to plastic plates. Thus, we believe that the suppressor cells found in mice undergoing GVHD across MiHA are not mature T cells, B cells, or macrophages, but belong to a class of suppressor cells termed natural suppressor (NS). Genetic analysis of NS cell activity showed that as early as 10 days post-irradiation/injection, NS cells inhibited mitogen responses of all mouse strains tested, the exception being the relative difficulty in suppressing the LPS response of B10.D2 (syngeneic with donor cells). By day 42, this had developed into an almost complete inability to suppress a B10.D2 LPS response, although at this time NS cells were still capable of inhibiting all the other mitogen responses of all strains tested, including the Con A response of B10.D2 spleen cells. Moderate amounts of mitogen unresponsiveness and suppressor activity were seen in the syngeneic groups (BALB/c----BALB/c) but only if recipients received 600 or 900 R. This was a transient phenomenon that was maximal at day 14, and which we believe to be a similar but less severe degree of immunoincompetence when compared with that seen with allogeneic stimulation in the B10.D2----BALB/c GVH model.(ABSTRACT TRUNCATED AT 400 WORDS)     

Skin graft rejection and delayed-type hypersensitivity responses to H-Y in an I-A b mutant

Based on graft rejection in C57BL/6 and B10.A(4R), but not in B10.A mice, skin graft rejection and delayed-type hypersensitivity (DTH) responses to the male HY antigen were considered to be under the control of the IBb gene in the mouse H-2 complex. These two phenomena were re-examined in the B6.C-H-2 ^bm12 mutant strain [mutation in the A gene in IA leading to an alteration in Ia ^b serologically detected specificities and the inability to generate cytotoxic T (Tc) cells to H-Y]. In this study the bm12 mutant was shown to produce weak DTH responses to H-Y. By contrast, bm12 female mice were unable to reject male skin grafts unless they had received prior footpad priming of male spleen cells, when graft rejection occurred, albeit slowly. In C57BL/6 mice the response to the HY antigen therefore appears to be solely under the control of the IA ^b gene. In other strains, response/nonresponse is presumably dictated by the ability of IA/IE interactions to produce T-helper responses.     

Major histocompatibility complex-linked control of the murine immune response to myelin basic protein

Recent experiments have shown that different regions of myelin basic protein (MBP) are encephalitogenic for different inbred strains of mice. It was therefore of interest to determine whether the immune response to MBP was MHC associated, and if so, what subregion controlled this response. Because PL/J and A/J mice were good responders to mouse MBP and C57Bl/10SN were not, B10.PL(73NS) and B10.A mice were immunized with mouse MBP under conditions designed to induce EAE. These strains were found to be highly susceptible. Intra-H-2 recombinant mice were then assessed for susceptibility. B10.A(4R) and B10.MBR were susceptible, whereas B10.A(5R) were resistant. Thus, EAE induced by purified MBP is under the control of the MHC, and the response maps to the I-A subregion. Production of IL 2 in vitro by T cells from MBP-primed mice in the presence of antigen and adherent cells was blocked by monoclonal antibody to the I-A, but not the I-E, subregion. When the specificity of the encephalitogenic response was tested, peptide 1-37 was active in B10.PL(73NS) and B10.A mice, whereas peptide 89-169 was active in A.SW, SWR, and B10.T(6R) strains. Serum from mice immunized with MBP peptides was assayed for antibody content. PL, B10.PL, and B10.A mice made a good antibody response to peptides 1-37 and 43-88 but were nonresponsive to peptide 89-169. SJL, A.SW, SWR, and B10.T(6R) mice responded well to peptide 89-169 but were poorly responsive to peptides 1-37 and 43-88.     

Immunodominance in the T cell response to multiple non-H-2 histocompatibility antigens. III. Single histocompatibility antigens dominate the male antigen

Immunization of mice with multiple non-H-2 histocompatibility antigens results in the generation of cytolytic T lymphocytes that are specific for a limited number of immunodominant antigens. The experiments presented in this communication were designed to reveal immunodominance in pairwise combinations of autosomal and sex-linked non-H-2 histocompatibility (H) antigens. Priming and boosting responders with the male antigen, H-Y, paired with the H-4.2, H-7.1, or H-3.1 antigens, resulted in the generation of cytolytic T cells specific for the autosomal H antigens but not the H-Y antigen. Furthermore, co-immunization and boosting of C57BL/6 female responder spleen cells with BALB.B male cells resulted in the generation of cytolytic T cells specific for the BALB.B immunodominant antigens but not H-Y. No dominance was observed in H-4-plus H-7-incompatible combinations. Co-immunization of three different H-3 congenic strains with H-3.1 plus H-Y demonstrated that an efficient anti-H-3.1 T cell response is required for observing H-3.1 immunodominance over H-Y. Co-expression of H-3.1 and H-Y on the same priming and boosting cells was required for immunodominance. In fact, immunization with H-3.1 and H-Y presented on different cells resulted in normal generation of H-Y-specific cytolytic T cells, but no generation of H-3.1-specific cytolytic T cells resulted unless H-Y-specific cells were stimulated in the mixed lymphocyte cultures. These observations suggest that in vitro T cell responses to paired, non-H-2 H antigens may be independent, competitive, or synergistic, depending on the identity of the antigens and the priming and boosting conditions.     

Serology of H-Y antigen

Summary Anti-H-Y antiserum is generally obtained from female inbred mice or rats that have been hyperimmunized with syngeneic male cells. The specificity of such antiserum is defined by its reactivity for male but not female cells. A number of conventional serological assays have been used to measure that reactivity. However, H-Y is a weak antigen, evidently represented sparingly on the surfaces of cells other than sperm, epidermal cells and brain cells; thus the srological assays for H-Y are technically difficult. Yet H-Y serology has enabled significant progress toward the understanding of primary sex differentiation.A recent advance in H-Y serology is the establishment of monoclonal anti-H-Y antisera which promise to facilitate analysis and clarification of the H-Y system.     

In vitro studies of the genetically determined unresponsiveness to thymus-independent antigens in CBA/N mice.

The X-chromosome-linked B lymphocyte defect of CBA/N mice has been studied in vitro by comparing the ability of (CBA/N X DBA/2)F1 (X-/X- X X+/Y) male (X-/Y) and female (X-/X+) spleen cells to respond to the thymus-independent antigen DNP (or TNP)-AECM-Ficoll. (CBA/N X DBA/2)F1 male spleen cells failed to generate significant in vitro anti-TNP antibody responses to DNP- or TNP-AECM-Ficoll, in contrast to spleen cells from F1 female (X-/X+) mice which responded normally to these T-independent antigens. Spleen cells from male F1 mice responded almost as well as F1 female cells to the thymus-dependent antigen, TNP-sheep red blood cells (TNP-SRBC) in vitro. Adding F1 male cells to F1 female cells failed to reduce the response of the latter to DNP-AECM-Ficoll, suggesting that the inability of F1 male cells to respond was not due to active suppression. The response of F1 male spleen cells to TNP-SRBC was not impaired by adding high concentrations of TNP-AECM-Ficoll indicating that the mechanism of unresponsiveness was not tolerance induction in all TNP-specific precursors. Lymphocytes from F1 male mice were capable of forming anti-TNP antibody after stimulation with lipopolysaccharide (LPS) in high concentrations; DNP-AECM-Ficoll had no effect on this polyclonal response. B lymphocytes from mice bearing only the X-chromosome of the CBA/N strain thus display a profound defect in B cell activation. This functional defect may represent either an inability of the defective B cells to be activated by thymus-independent antigens or the absence of a sub-class of B cells which respond to thymus-independent antigens.     

The cellular basis for the Ia restriction in murine experimental autoimmune thyroiditis

Susceptibility to experimental autoimmune thyroiditis (EAT) in the mouse is linked to the I-A subregion of the major histocompatibility complex. EAT can be induced in susceptible strains of mice by immunization with mouse thyroglobulin (MTg) and adjuvant. We have described a cell transfer system wherein spleen cells from EAT-susceptible CBA/J mice primed in vivo with MTg and lipopolysaccharide (LPS) can be activated in vitro with MTg to transfer EAT to naive syngeneic recipients. This cell transfer system was used to elucidate the cellular basis for the I-A restriction in EAT. While the cell active in transferring EAT was Thy 1+ I-A-, depletion of I-A+ cells from the in vitro culture prevented the activation of EAT effector T cells. MTg-pulsed mitomycin C-treated naive syngeneic spleen cells as antigen-presenting cells (APCs) could replace the I-A+ cells in vitro. Allogeneic (Balb/c) APCs were ineffective. Using APCs from several recombinant inbred strains of mice, it was shown that C3H/HEN and B10.A(4R) APCs were effective in activating MTg/LPS-primed CBA/J spleen cells to transfer EAT while B10.A(5R) APCs were ineffective. This maps the H-2 restriction to the K or I-A subregions. Addition of polyclonal anti-Iak or monoclonal anti-I-Ak or anti-L3T4 during in vitro activation inhibited both the generation of EAT effector cells and the proliferative response to MTg. Irrelevant anti-Ia reagents, monoclonal anti-I-Ek, and monoclonal anti-I-Jk were ineffective. Thus the I-A restriction in murine EAT appears to result from an I-A restricted interaction between Ia+ APCs and Ia- EAT effector T cells.     

IgG-specific helper activity of t lymphocytes from mice lacking theIr-IgG gene

Cooperative interactions between T and B cells from the congenic inbred mouse strains B10.A(2R) and B10.A(4R) in antibody responses controlled byIr genes have been studied. Within theI region of the MHC, these strains share only theI-A subregion. TheIr gene controlling responsiveness to IgA maps in theI-A subregion, both strains being responders to IgA. T cells from 2R mice collaborate effectively with B cells from 2R or 4R mice for antihapten antibody responses to DNP-IgA. TheIr gene controlling responses to IgG maps in theI-B subregion, and 2R mice are nonresponders for this antigen. Nevertheless, 2R T cells primed with IgG can help responder (4R) B cells -but not syngeneic nonresponder (2R) B cells -in responding to DNP-IgG. These results indicate that mice lacking theIr-IgG gene nonetheless may develop helper T lymphocytes specific for myeloma proteins. In addition, they indicate that cells from congenic mice sharing only theA subregion of theI region can collaborate efficiently.     

Immune dysfunction associated with graft-vs-host reaction in mice transplanted across minor histocompatibility barriers. II. Reversible defect in T-dependent antibody responses

B cell and Th cell functions were assessed in mice undergoing a graft-vs-host reaction (GvHR) in response to minor histocompatibility Ag by using the plaque-forming cell (PFC) response to the T-independent Ag TNP-Brucella abortus and the T-dependent Ag TNP-SRBC. Bone marrow plus spleen cells from B10.D2 mice were transplanted into lethally irradiated B10.D2 (syngeneic recipient) or H-2d-compatible BALB/c (allogeneic recipient) to produce a chronic form of GvHR. BALB/c recipients of an allogeneic transplant demonstrated a marked and proportional lymphoid depletion of the spleen with normal percentages of B cells, T cells, and CD4+ and CD8+ T cell subsets. Mice with GvHR made normal numbers of PFC/10(5) spleen cells in response to the T-independent Ag, but a significantly depressed number of PFC/10(5) spleen cells to the T-dependent Ag compared with normal B10.D2 mice and with irradiated B10.D2 recipients of syngeneic B10.D2 marrow plus spleen cells. Mice undergoing the minor Ag GvHR made significantly larger numbers of PFC/10(5) spleen cells after secondary immunization with TNP-SRBC compared with controls. In vitro assays demonstrated that B cells from mice with GvHR responded to T help from normal B10.D2 mice and that T cells from mice with GvHR provided help to normal B cells after in vivo immunization. These data demonstrate that radiation chimeras with GvHR in response to minor histocompatibility Ag have relatively normal B cell function and an apparent defect in T helper cell function that is reversible by immunization with appropriate Ag.     

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.     

Analysis of the cytotoxic T cell response to H-Y in CBA/H mice

The dose response, kinetics, and target cell specificity of the H-Y immune Tc-cell response of fp-primed CBA/H mice was analyzed. Non-MHC genes were shown to influence responsiveness in fp-primed H-2k strains of mice. The possibility that dominant T-suppressor cells mask responsiveness in i.p. primed CBA/H mice was not confirmed in mixing experiments. Female spleen-adherent cells injected with male spleen cells i.p. elicited H-Y immune Tc-cell responses.