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.     

H-2 effects on cell-cell interactions in the response to single non-H2 alloantigens. IV. Variations in the proliferative response to H-Y and H-3

Individual mice were tested for their proliferation T-cell response to H-Y- and H-3-incompatible stimulator cells in secondary mixed lymphocyte culture. Responders expressing the H-2b haplotype were restricted in their response to stimulators presenting H-Y and H-3 in the context of H-2b. Lymphocytes from individual B10 females proliferated in response to H-Y presented with I-Ab and Db. The ratio of I-Ab/Db-restricted responses varied between individual responders, indicating significant qualitative variation between genetically identical responders. The majority of the proliferative response in all tested mice was restricted to the entire H-2b haplotype suggesting complementation of I-Ab- and Db-region genes in presenting the H-Y antigen. Similar observations were made in the response of individual B10.LP mice to the H-3 antigen. H-3-specific, proliferating T cells were restricted to H-3 antigen presented with KbAb and Db with significant variation between individuals in proliferative response to H-3 plus KbAb and Db. In contrast to the response to H-Y, the proliferative response to H-3 plus H-2b could be accounted for by the summation of the proliferative responses to H-3 plus KbAb and Db. These observations demonstrate that the proliferative response to non-H-2H antigens in the context of I-region determinants is not a sine qua non for the T-cell response to these antigens. Further, the individual qualitative and quantitative variation observed with individual genetically identical mice has strong implications for our knowledge of intrastrain variation in immune responsiveness and the characterization of inbred strains for immune responsiveness.     

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.     

T-cell and antibody typing of a mouse population segregating for Sxr and H-2 haplotype

During investigation of the frequency of recombination of the testis determining gene, Tdy, and the minor histocompatibility antigen gene Hya on the Sxr segment in an outbred mouse stock, we identified two fertile males, one XY and the other XYSxr, which typed H-2k positive using the H-2b anti-H-2k monoclonal antibody HB50, but whose cells failed either to stimulate H-Y specific H-2k restricted T-cell clones, or to be killed by anti-H-2k or anti-H-2k restricted H-Y specific cytotoxic T cells. We investigated these two mice and their existing relatives, using H-2 and H-Y typing methods. The progeny of their test matings with H-2b homozygous C57BL/6 females were also investigated. The results indicate that the transmission of the Hya gene on the Y chromosomes from both mice, and the additional Hya gene on the Sxr segment of the carrier male, allowed for the expression of the H-Y antigen and its detection in the presence of an H-2 haplotype for which we had H-2 restricted H-Y specific typing cells (H-2b and H-2k). Furthermore, we identified the haplotype of the two original males as expressed in the H-2 homozygous and heterozygous F2 progeny as H-2q and discovered an unexpected cross reactivity of the monoclonal anti KkDk antibody HB13 with half the cells of H-2q homozygotes, but not qb heterozygotes.     

Studies on H-Y antigen in different cell fractions of the testis during pubescence

Summary Various cell types of the rat testis during pubescence, including germ, Sertoli, and Leydig cells, were partially enriched. The fractions were tested for the presence, binding, and secretion of H-Y antigen. The main results are: Immature germ cells are H-Y antigen-negative until the late diploid stages, and late primary spermatocytes or spermatids become positive; the somatic cells of the gonad are positive at all ages examined (18 days old to adulthood). Secretion of H-Y antigen is restricted to the Sertoli cell fraction. Binding of externally supplied antigen takes place on Leydig cells; the Sertoli cell surface will be saturated because of active secretion; there is no binding to germ cells. Thus, immature germ cells seem to be the only H-Y antigen-negative cells of the male organism, and the Sertoli cells seem to be the only ones to secrete H-Y antigen.     

Acute rejection in the absence of cognate recognition of allograft by T cells

We studied the effects of the indirect pathway of allograft recognition using T cells from TCR transgenic Marilyn mice, which recognize the male Ag H-Y in an I-A(b)-restricted fashion. The T cells are not alloreactive to the H-2(k) haplotype, because they are not activated when adoptively transferred into recombinase-activating gene-2(-/-) common gamma-chain(-/-) double-mutant H-2(k) male or female mice. However, skin from H-2(k) males, but not from H-2(k) females, is acutely rejected by recombinase-activating gene-2(-/-) transgenic female recipients. In vitro, Marylin spleen cells primed by H-2(k) skin grafting proliferated and secreted both IL-4 and IFN-gamma in response to H-2(k) male stimulators. However, the removal of H-2(b) APC from the responding population abolished the response. Taken together, these results show that the indirect recognition that triggers rejection in this model is due to the recognition of H-Y Ag shed from H-2(k) male allograft and presented by the recipient's own I-A(b) APC to transgenic T cells. This study demonstrates unequivocally the capacity of naive CD4(+) T cells to promote the rejection of allografts through mechanisms that involve indirect destruction of grafted tissues.     

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.     

H-2 effects on cell-cell interactions in the response to single non-H-2 alloantigens

Individual mice were tested for their proliferative T-cell response to H-Y- and H-3-incompatible stimulator cells in secondary mixed lymphocyte culture. Responders expressing the H-2 ^bhaplotype were restricted in their response to stimulators presenting H-Y and H-3 in the context of H-2 ^b. Lymphocytes from individual B10 females proliferated in response to H-Y presented with I-A ^band D ^b. The ratio of I-A ^b/D ^b-restricted responses varied between individual responders, indicating significant qualitative variation between genetically identical responders. The majority of the proliferative response in all tested mice was restricted to the entire H-2 ^bhaplotype suggesting complementation of I-A ^b- and D ^b-region genes in presenting the H-Y antigen. Similar observations were made in the response of individual B10.LP mice to the H-3 antigen. H-3-specific, proliferating T cells were restricted to H-3 antigen presented with K ^bA^band D ^bwith significant variation between individuals in their preference for H-3 plus K ^bA^band D ^b. In contrast to the response to H-Y, the proliferative response to H-3 plus H-2 ^bcould be accounted for by the summation of the proliferative responses to H-3. plus K ^bA^band D ^b. These observations demonstrate that the proliferative response to non-H-2 H antigens in the context of I-region determinants is not a sine qua non for the T-cell response to these antigens. Further, the individual qualitative and quantitative variation observed with individual genetically identical mice has strong implications for our knowledge of intrastrain variation in immune responsiveness and the characterization of inbred strains for immune responsiveness.     

Variable spread of X inactivation affecting the expression of different epitopes of the Hya gene product in mouse B-cell clones

Cloned B-cell lines from a female T16H/XSxr mouse in which Tdy expression was suppressed due to X inactivation and from a male X/XSxr mouse, both of the (kxb)F₁ haplotype, were examined for H-Y expression. This was determined both by their ability to act as targets for H-2^k and H-2^b-restricted H-Y-specific cytotoxic T cells and by their ability to stimulate the proliferation of H-2K^k, H-2D^b (class I) and A^b (class II)-restricted T-cell clones. In B-cell clones from the T16H/XSxr mouse, expression of H-Y/D^b exhibited partial X inactivation and only a proportion ( 30%) of the cells were targets for or stimulated H-2D^b-restricted H-Y-specific T cells. In contrast, H-Y eiptopes restricted by H-2^k (H-Y/K^k, H-Y/D^k) and A^b (H-Y/A^b) exhibited no X inactivation. Furthermore, no inactivation of H-Y/D^b, H-Y/A^b, or H-Y^k was observed in the male X/XSxr mouse. These results indicate that the T16H/XSxr female is a mosaic, as a result of the variable spread of X inactivation into the Sxr region. They further suggest that the H-Y antigen recognized in association with H-2^k and H-2D^b class I molecules and A^b class II molecules may be the product of more than one gene.     

Heterogeneity in the response of T cells to antigens presented by B lymphoma cells

Proliferation of antigen-specific T-cell populations was induced in cultures stimulated with antigen and a suitable source of antigen-presenting cells. Soluble (keyhole limpet hemocyanin) and particulate (horse red blood cells) antigens were presented by irradiated spleen cells and by a variety of B-lymphoma-cell lines, providing support for antigen-specific H-2-restricted T-cell responses. A marked heterogeneity was demonstrated, however, in the capacity of T-cell lines to proliferate in response to antigen presented by the B-lymphoma cells. T-cell populations were prepared from the lymph nodes of antigen-primed mice and restimulated in vitro in the presence of antigen and irradiated spleen cells. During the first six in vitro restimulations, these T-cell populations maintained the capacity to respond to antigen presented either by irradiated spleen cells or by B-lymphoma cells. Continued growth of these T-cell populations, again in the presence of antigen and irradiated spleen cells, resulted in the generation of T-cell lines which had lost the ability to respond to antigen presented by B-lymphoma cells. These lines however, fully retained the capacity to proliferate in the presence of antigen and irradiated spleen cells. T-cell clones derived from one of these lines were also unable to respond to antigen presented by B-lymphoma cells but again proliferated in the presence of antigen and irradiated spleen cells. Supernatants containing high levels of IL-1, IL-2, or IL-3 activity failed to reconstituted the antigen-specific response of T-cell lines which had lost the capacity to respond to antigen presented by B-lymphoma cells. Furthermore, titrated numbers of irradiated spleen cells, while having the capacity to support T-cell proliferation themselves, failed to synergize with B-lymphoma cells in the support of antigen-specific T-cell proliferation. Thus we have defined populations of antigen-specific, H-2-restricted T cells which do not recognize antigen presented by B-lymphoma cells and can therefore discriminate between different antigen-presenting cell types.     

MHC class I allele dosage alters CD8 expression by intestinal intraepithelial lymphocytes

The development of TCR alphabeta(+), CD8alphabeta(+) intestinal intraepithelial lymphocytes (IEL) is dependent on MHC class I molecules expressed in the thymus, while some CD8alphaalpha(+) IEL may arise independently of MHC class I. We examined the influence of MHC I allele dosage on the development CD8(+) T cells in RAG 2(-/-) mice expressing the H-2D(b)-restricted transgenic TCR specific for the male, Smcy-derived H-Y Ag (H-Y TCR). IEL in male mice heterozygous for the restricting (H-2D(b)) and nonrestricting (H-2D(d)) MHC class I alleles (MHC F(1)) were composed of a mixture of CD8alphabeta(+) and CD8alphaalpha(+) T cells, while T cells in the spleen were mostly CD8alphabeta(+). This was unlike IEL in male mice homozygous for H-2D(b), which had predominantly CD8alphaalpha(+) IEL and few mostly CD8(-) T cells in the spleen. Our results demonstrate that deletion of CD8alphabeta(+) cells in H-Y TCR male mice is dependent on two copies of H-2D(b), whereas the generation of CD8alphaalpha(+) IEL requires only one copy. The existence of CD8alphabeta(+) and CD8alphaalpha(+) IEL in MHC F(1) mice suggests that their generation is not mutually exclusive in cells with identical TCR. Furthermore, our data imply that the level of the restricting MHC class I allele determines a threshold for conventional CD8alphabeta(+) T cell selection in the thymus of H-Y TCR-transgenic mice, whereas the development of CD8alphaalpha(+) IEL is dependent on, but less sensitive to, this MHC class I allele.     

Peptide-loaded dendritic cells prime and activate MHC-class I-restricted T cells more efficiently than protein-loaded cross-presenting DC

Undifferentiated and differentiated dendritic cells (uDC and dDC, respectively), derived from the bone marrow, were studied in vitro and in vivo. Ovalbumin (OVA) and two OVA-derived peptides binding to H-2K(b) and I-A(b), respectively, were used. Two IL-2 secreting T cell hybridomas specific for the OVA-derived epitopes were used in the in vitro read-out. The ability to cross-present the H-2K(b) binding OVA(257-264)-peptide (SIINFEKL) was restricted to dDC, which express CD11c(+), CD86(+), and MHC-II(+). In vitro, the antigenicity of SIINFEKL-loaded DC declined at a slower rate than that of OVA-pulsed DC. Moreover, SIINFEKL-loaded DC were up to 50 times more efficient than DC-pulsed with OVA-protein for generation of an H-2K(b)-restricted response. Immunization of mice with SIINFEKL-loaded DC resulted in a much stronger H-2K(b)-restricted response than immunization with OVA-pulsed DC. These data might have important implications for the choice of antigen source in the design of DC-based vaccines.     

The absence of specific interactions of Sertoli-cell-secreted proteins with antibodies directed against H-Y antigen

Radiolabeled proteins secreted into the medium by rat Sertoli cells in primary culture have been examined for specific interactions with polyclonal and monoclonal antibodies directed against serologically detectable H-Y antigen(s). None of the proteins secreted by Sertoli cells reacted specifically with H-Y antibodies, as determined with immunoprecipitation procedures and immunoabsorbent affinity chromatography, followed by SDS gel electrophoresis. Radioactivity profiles of proteins obtained after reaction with H-Y antibodies were similar to those observed after treatment with nonimmune sera or with irrelevant antibodies. We obtained comparable findings with proteins secreted by the mouse cell line TM4, which is of presumptive Sertoli cell origin, and with proteins present in ram rete testis fluid. These and other findings presented do not support the contention that Sertoli cells secrete a protein having the properties of serologically detectable H-Y antigen as previously described.     

Priming for a cytotoxic response to minor histocompatibility antigens: antigen specificity and failure to demonstrate a carrier effect.

Spleen cells from normal mice do not give a detectable in vitro cytotoxic T cell (CTL) response to minor H antigens. Spleen cells from animals primed in vivo with minor H antigens give a strong CTL response when boosted in culture with the appropriate stimulating cells. Here I have studied the requirements for priming a CTL response to minor H antigens. It is shown that priming is just as antigen specific as is cytolytic effector function. That is, priming cells have to carry the same minor antigens as the challenge cells. Inducing a graft-vs-host reaction in vivo does not nonspecifically allow spleen cells to respond to minor H antigens in vitro. Using minor H congenic mice (congenic for H-Y and/or H-7) I have also tried, and failed, to demonstrate a carrier effect in priming. Female mice primed to H-Y were challenged in culture with cells bearing H-Y and H-7 antigens in the hope that a helper response to H-Y would augment a CTL response to H-7. This did not happen, however. Such primed and boosted cells gave a strong secondary CTL response to H-Y but none to H-7. It is concluded that in order to prime for a detectable in vitro response to minor antigens it is necessary to expose the CTL precursors to antigen in vivo. This either expands the size of the pool of precursors by cell division or changes them in some qualitative way.     

In vitro studies of gonadal organogenesis in the presence and absence of H-Y antigen.

In a very strict sense, the primary (gonadal) sex of mammals is determined not so much by the presence or absence of the Y but the expression or nonexpression of the evolutionary extremely conserved plasma membrane H-Y antigen. The central somatic blastema of embryonic indifferent gonads contains one cell lineage characterized by the possession of S-F differentiation antigen that differentiates into testicular Sertoli cells in the presence of H-Y and into ovarian follicular (granulosa) cells in its absence. This cell lineage appears to play the most critical role in gonadal differentiation. Whether or not testicular Leydig cells and ovarian theca cells are similarly derived from the common cell lineage has not been determined. Nevertheless, if given H-Y antigen, presumptive theca-cell precursors of the fetal ovary acquire hCG (LH?)-receptors-the characteristic of fetal Leydig cells.     

Major histocompatibility complex-restricted augmenting T cells induced by in vitro cultivation of antigen-primed T cells. A new parallelism between suppressor and augmenting circuits

In vitro cultivation of primed T cells with antigen resulted in the induction of a regulatory T cell that nonspecifically augmented the in vitro antibody responses of H-2-compatible T and B cells. This T cell, designated as the augmenting T cell (Ta), was unable to help B cells by itself but enhanced the antibody response of B cells to several multitudes only when conventional helper T (Th) cells or cloned Th cells from the same H-2 haplotype coexisted. Ta was radioresistant and belonged to Lyt-1+, 2-, L3T4+, I-J- T cell lineage. Ta exhibited interesting H-2-restricted activities: when primed T cells from (A X B) F1 were cultured with the antigen in the presence of parent A type antigen-presenting cells, the induced Ta was able to augment the antibody response of (A x B) F1 B cells in the presence of Th cells from F1----A but not from F1----B radiation bone marrow chimeras. This indicates that the induction of Ta in an F1 T cell population is dependent on the H-2 haplotype of antigen-presenting cells during in vitro cultivation. The restriction specificity of the established Ta is, however, not directed to the class II antigen itself but to the restriction specificity of Th cells that recognize class II antigen. In support of this is the fact that the elimination of A-restricted Th cells during cultivation by treatment with anti-I-J mAb, which is known to react with H-2-restricted Th cells, resulted in failure of induction of Ta cells having the augmenting activity for the A-restricted response.     

H-2-specific antibodies induced by injection of syngeneic leukemia cells

AKR/J mice immunized with several syngeneic leukemia cells contained antibodies in their sera which reacted with certain AKR leukemia cell lines, depending on their H-2 expression, and precipitated H-2K antigens from lysates of leukemia cells. Precipitation of H-2K was not due to virus-specific antibodies: it could not be blocked by prior absorption with H-2-negative leukemias, but was blocked by certain allogeneic lymphocytes. Tumor-specific H-2K antibodies did not react with H-2K from normal AKR lymphocytes either on the cell surface or after detergent solubilization; however, they did react with H-2K from mitogen-activated AKR and BALB.K lymphoblasts. Since both these latter cells were also lysed by AKR-Gross/MuLV-specific and H-2K^k-restricted cytotoxic T lymphocytes, we consider the possibility that antibodies detecting conformational alterations induced in H-2K^k molecules by viral association may be present in syngeneic AKR antileukemia sera.Abbreviations used in this paper GCSA Gross-virus-induced cell-surface antigen - MCF mink cell focus-forming virus - MuLV murine leukemia virus - Th T helper     

Expression of the H-Y Antigen on thymus cells and skin: Differential genetic control linked toK end ofH-2

The strength of the H-Y antigen on thymus cells and on skin was compared in differentH-2-congenic mouse strains using a host-versus-graft reaction popliteal lymph node assay, and skin grafts from males of parental strains grafted to F₁ hybrid females. The results revealed considerable differences in the strength of the H-Y antigen among different congenic strains; these differences demonstrate the effect of theH-2-linked gene on the expression of the H-Y antigen. The linkage withH-2 was also confirmed in tests with segregating F₂ generations. In the strains bearing recombinantH-2 haplotypes, the strength of the H-Y antigen is similar to that of parental strain from which the recombinant received itsK end, and the responsible gene (or genes) map to the left ofI-C. The effect of theH-2-linked gene(s) on thymus cells and skin is different. The gene linked to theK end ofH- 2^b determines a strong H-Y antigen on thymus cells, but a relatively weak H-Y antigen on skin. The gene linked to theK end ofH- 2^k determines a weak H-Y antigen on thymus cells, but a strong H-Y antigen on skin. The gene linked to theK end ofH- 2^d determines a weak H-Y antigen on both thymus cells and skin. Our observations raise the possibility that the structural gene for the H-Y antigen is linked toH-2. Alternative (but not exclusive) explanations invoke regulatory effects ofH-2 on the expression of the H-Y antigen, possibly by means of the control of the cellular andogen receptors.     

Dissociation of alloantigen recognition from self major histocompatibility complex-restricted recognition of cytolytic T lymphocytes by monoclonal antireceptor antibodies

Two monoclonal antibodies (mAb) directed to the dual reactive cytolytic T lymphocyte clone OH8 (Db + H-Y and H-2d) were established. Analysis by cell surface staining and immunoprecipitation of radiolabeled surface molecules of OH8 followed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed that both mAb recognized an identical heterodimeric, clonotypic structure on OH8 cells, i.e., T cell receptor. However, although the MR3-2 mAb inhibited the lysis of either Db + H-Y or H-2d targets by OH8, the MR3-6 mAb inhibited the lysis of H-2d target cells, but not that of Db + H-Y target cells. Modulation of T cell receptor by either MR3-2 or MR3-6 mAb rendered the OH8 cytolytic T lymphocyte incapable of killing both Db + H-Y and H-2d target cells. These findings suggest that different epitopes of OH8 T cell receptor were involved for the recognition of self + antigen and alloantigen.     

Cell surface expression of cytotoxic T lymphocyte-defined, AKR/Gross leukemia virus-associated tumor antigens by normal AKR.H-2b splenic B cells

We previously described a system in which H-2Kb-restricted C57BL/6 (B6) cytotoxic T lymphocytes (CTL) could be raised that were specific for tumors, such as the thymic lymphoma AKR.H-2b SL1, that were induced by endogenous AKR/Gross murine leukemia virus and that expressed the Gross cell surface antigen. In this study, certain normal lymphoid cells from AKR.H-2b mice were also found to express target antigens defined by such anti-AKR/Gross virus CTL. AKR.H-2b spleen, but surprisingly not thymus, cells stimulated the production of anti-AKR/Gross virus CTL when employed at either the in vivo priming phase or the in vitro restimulation phase of anti-viral CTL induction. This selective stimulation by spleen vs thymus cells was not dependent on the age of the mice over the range (3 to 28 wk) tested. Both AKR.H-2b spleen and thymus cells, however, were able to stimulate the generation of H-2-restricted B6 anti-AKR minor histocompatibility (H) antigen-specific CTL. Thus, AKR.H-2b spleen cells appeared to display the same sets (minor H and virus-associated) of cell surface antigens recognized by CTL as the AKR.H-2b SL1 tumor, whereas AKR.H-2b thymocytes were selectively missing the virus-associated target antigens, a situation analogous to that of cl. 18-5, a variant subclone of AKR.H-2b SL1 insusceptible to anti-AKR/Gross virus CTL. Like AKR.H-2b thymocytes, neither AKR spleen cells or thymocytes nor B6.GIX + thymocytes were able to stimulate the generation of anti-AKR/Gross virus CTL from primed B6 responder cell populations. In contrast, both T cell-enriched and B cell-enriched preparations derived from AKR.H-2b spleen cells were able to stimulate at the in vitro phase of induction, although B cell-enriched preparations were considerably more efficient. The discordant results obtained with AKR.H-2b spleen cells vs thymocytes were confirmed and extended in experiments in which these cells were employed as target cells to directly assess the cell surface expression of virus-associated, CTL-defined antigens. Thus, AKR.H-2b spleen cells, but not thymocytes, were recognized by anti-AKR/Gross virus CTL when fresh normal cells were tested as unlabeled competitive inhibitors, or when mitogen blasts were tested as labeled targets. Fresh or lipopolysaccharide-stimulated B cell-enriched spleen cells were as efficiently recognized as unseparated spleen cell preparations. Unexpectedly, fresh or Lens culinaris hemagglutinin-stimulated T cell-enriched spleen cell preparations, although susceptible to anti-minor H CTL, were almost as poor as targets for anti-viral CTL as were thymocytes. Together, these results demonstrate the H-2-restricted expression of CTL-defined, endogenous, AKR/Gross virus-associated target antigens by normal AKR.H-2b splenic B cells.(ABSTRACT TRUNCATED AT 400 WORDS)