Antigen-specific helper T cells recognize determinants encoded in the H-2D region of the H-2 gene complex

Observations have frequently been interpreted as showing that the helper T cells which collaborate with alloantigen-specific cytotoxic T-cell precursors can only recognize antigens encoded in the I region of the H-2 gene complex. An experimental system is described here that allows analysis of the recognition repertoire of these helper cells. CBA helper T-cell precursors can be primed in vitro to antigens encoded in the H-2 ^b gene complex. These helpers can then be tested for the existence of a subset of helper cells which recognize antigens encoded in the D region of H-2 ^b haplotype. CBA thymocytes were used as a source of cytotoxic T-cell precursors that respond poorly in the absence of exogeneous helper activity. The source of alloantigen was varied by using irradiated spleen cells from various (BALB/c × recombinant)F₁ hybrid mice as stimulator cells. When the stimulator cell bears BALB/c determinants recognized by the cytotoxic T-cell precursor and also bears only the D region antigens of the H-2 ^b haplotype, an anti-BALB/c cytotoxic response is generated only if the anti-H-2^b helper population contains cells able to recognize H-2D^b. A positive cytotoxic response was obtained, indicating that helper cells are not limited to recognition of I region antigens and can efficiently recognize antigens encoded in the D region of the H-2 gene complex. This was confirmed by the demonstration of helpers specific for H-2D^d. We were unable to detect any evidence for Ia-restricted recognition of the H-2D alloantigens, suggesting that, as for cytotoxic T lymphocytes (CTL), helper cell recognition of class I alloantigens is an unrestricted event.     

Frequency of allogeneic helper T cells responding to whole H-2 differences and to an H-2K difference alone.

Limiting dilution analysis was used to determine the frequency of splenic T cells that are stimulated by alloantigen to give help in a primary antibody response to SRBC. Several haplotype combinations were tested. A semilogarithmic plot of the fraction of nonresponding culture as a function of the number of T cells added to excess B cells gave a straight line intercepting with the origin. Thus a single cell-type was limiting, which was required to help B cells respond to SRBC. The frequency of syngeneic precursors of T helper cells specific for SRBC ranged from 1/10,000 to 1/55,000 with a mean of about 1/20,000. Allohelpers generated by whole H-2 differences gave precursor frequencies that ranged from 1/1000 to 1/7000 with a mean of about 1/2500. Thus allohelpers to whole H-2 differences were approximately 8-fold more frequent than SRBC-specific helpers. When the stimulation was limited to the H-2K difference between the mutant B6.C-H-2ba and wild-type B6, frequencies of from 1/2600 to 1/7900 allohelpers were found with a mean of about 1/5000, approximately half the frequency of allohelpers to whole H-2 differences. Thus some, but probably not all, of the magnitude of allogeneic halp can be attributed to the high frequency of helper T cells that respond to a given alloantigen.     

The cellular mechanism of maintenance of neonatally induced tolerance to H-2 class I antigens

We used limiting dilution analysis protocols to investigate the mechanism by which in vitro cytotoxic T lymphocyte (CTL) hyporeactivity is maintained in adult mice that had been neonatally tolerized to major histocompatibility complex-encoded antigens. Class I molecules, presented on donor cells having an H-2 K or D region haplotype difference from recipients, readily induce tolerogen-specific CTL hyporeactivity. All attempts to identify any in vitro effects of active suppressive cells operative in the maintenance of this hyporeactivity have been unsuccessful. We conclude that this cytotoxic deficiency is the consequence of in vivo mediated clonal inactivation of the precursors of tolerogen-specific CTL. A presentation and evaluation of the assumptions inherent in this conclusion are made. In contrast to class I molecules, class II molecules, presented on donor cells having an H-2 I region haplotype difference from recipients, are unable to induce tolerogen-specific CTL hyporeactivity, even when injected neonatally at high doses. This inability of class II molecules to induce CTL tolerance parallels the considerable difficulty of inducing helper T lymphocyte tolerance to class II molecules.     

H-2K/H-2D and Mls and I region-associated antigens stimulate helper factor(s) involved in the generation of cytotoxic T lymphocytes

This study examines the antigen that stimulate production or release of a soluble helper factor(s) involved in development of cytotoxic T lymphocytes (CTL). Antigens associated with the Mls locus, I and K/D regions of the MHC were all capable of stimulating responder cells in MLC to produce helper factor. These supernatant fluids were all capable of providing "help" for the generation of cytotoxic T lymphocytes in MLC in which spleen cells are stimulated by allogeneic heat-treated thymocytes or splenocytes. Previous reports from our laboratory as well as others have shown that heat-treated cells do not stimulate a cytotoxic response. Heat-treatment of Mls, I, and H-2K/H-2D region incompatible stimulatory cells in MLC eliminated their ability to induce responder cells to produce helper factor, suggesting this is the mechanism whereby heat-treatment reduces the ability of cells to stimulate cell-mediated lympholysis (CML). The inability of supernatant fluids, from MLCs in which heat-treated cells were the stimulators, to assist in the generation of cytotoxic T cells did not appear to be the result of any suppressive factor induced by such treatment. Further, the antigens that stimulate pre-killer cells appear functionally distinct from those heat labile antigens (Mls, I, H-2K/H-2D associated) that stimulate helper factor production since heat-treated allogeneic cells served as stimulators of cytotoxicity provided helper activity was added to the MLC.     

Presence of T cell-associated surface antigens on murine NK cells.

The expression of T cell-associated surface antigens on natural killer (NK) spleen cells of C57BL/6 mice was evaluated by cytotoxic depletion experiments with alloantisera prepared against the Thy 1, Ly 1, Ly 2, Ly 5, Ly 6, and NK 1 antigens. The NK activity of these nonimmunized spleen cells for YAC-1 leukemia cells was dramatically reduced by antisera to the Ly 5 and NK 1 antigens. Variable results were obtained with anti-Ly 6 sera--certain pools of this antiserum decreased the NK activity, whereas other pools showed only negligible effects. The NK activity of the same cell suspensions was not affected by antisera to the Thy 1, Ly 1, and Ly 2 antigens. In parallel tests the T cell-associated cell surface antigens of alloimmune T killer cells were similarly evaluated by cytotoxic depletion experiments. In this case, the activity of these cells was consistently diminished by antisera to the Thy 1, Ly 2, Ly 5, and Ly 6 antigens, but not by antisera to the Ly 1 and NK 1 antigens. On this basis it was concluded that the NK cells expressed a restricted subset of T cell-associated alloantigens and therefore may have been derived from the T cell lineage of lymphocytes.     

Synergistic interactions between lymph node and thymus cells in response to antigenic differences limited to selected regions of the H-2 complex.

Thymus and lymph nodes from the A.TL recombinant line were utilized as sources of responding cells in MLR (mixed lymphocyte response) assays to MHC-determined (major histocompatibility complex) antigenic differences. Cells from both sources were stimulated to proliferate by antigenic determinants controlled by the H-2K region alone, H-2D region and the H-2I-H-2S regions. Nylon-fiber-adherent splenic cells from each of the stimulating cell strains stimulated T-cell-dependent responses. Synergistic interactions between A.TL thymus and lymph node cells were initiated by antigenic products limited to single H-2 regions. Antigenic differences determined within the H-2I region were not required for synergistic responses to H-2K-controlled products or for the generation of cytotoxic killer cells to H-2D-associated antigens. The H-2I-region-associated products also were very effective in stimulating T-cell synergy. These data demonstrate that the two responsive T-cell subpopulations can both be stimulated by alloantigens coded within a single known H-2 region.     

Antigen-binding T cells: dose response and kinetic studies on the development of different subsets.

We have described a number of the parameters involved in the in vitro induction of specific SRBC-binding T cells (T rosette-forming cells, T-RFC). Although T-RFC precursors pass through nylon, most of the induced cells do not; nor do detectable numbers of Ly 1+2, 3- cells bind antigen with sufficient stability to form rosettes. The ratio of Ly 2,3:Ly 1,2,3 T-RFC varies with time after immunization and with the dose of antigen used for stimulation. Relatively high or low doses of antigen selectively induce Ly 1,2,3 T-RFC. Ly 2,3 T-RFC, when they appear, follow Ly 1,2,3 T-RFC. Pretreatment of T cells with anti-Ly sera before RFC induction prevents formation by Ly2+ T-RFC. Since anti-Ly 1 treatment blocks RFC formation and since Ly 1,2,3, T-RFC always precede the appearance of Ly 2,3, T-RFC, our results suggest that some Ly 1+ cells (Ly 123 at least, but perhaps also Ly 1) may act as inducers, precursors, and/or amplifiers for Ly 2,3 RFC as they appear to do for Ly 2,3 suppressor and killer cells. Thus, our results confirm and extend the observed similarities between T-RFC and other Ly 2+ cells such as killer and suppressor cells as well as their differences from Ly 1+ helper cells.     

Modulation of natural cytotoxicity by alloantibodies: III. Augmentation of natural killer activity by alloantisera directed against K,D, and I regions of the murine H-2 complex

Natural killer activity of mouse spleen cells toward a human myeloid leukemia cell line, K562, can be enhanced by alloantisera directed against individual antigens in the H-2 region. By using a panel of 13 antisera (8 directed against antigens in the K and D regions and 5 directed against antigens in the I region) and four strains of mice (C57BL/6J, CBA, DBA/2, and A/J) it was found that certain antisera would stimulate target cell lysis by spleen cells only if the antisera had specificity for antigens which were a part of the haplotype represented on the spleen NK effector cells. Anti Ia antisera could stimulate the anti K562 NK activity of nude mouse spleen cells which lack mature T cells. Depletion of B cells and macrophages from nude spleen cells, by passing through a nylon-wool column also did not abolish the effect of anti-Ia antiserum. It appears likely therefore that the anti-Ia antibodies exert this effect directly on NK cells and that Ia antigens may be expressed on NK cells. Since the antisera directed against different antigens in H-2 complex irrespective of subregion specificity (K, D, or I) stimulated the NK activity of mouse spleen cells, the phenomenon offered an interesting method for testing the presence of a given alloantigen on mouse spleen cells. Log-dose response curves for the augmentation of lysis induced by appropriate alloantisera were linear over a dilution range of 1:320 to 1:5120. By using the dose-response curves, potency ratios of two preparations of antisera (directed against antigen 33 of the K region) could be successfully determined. Besides the K562 cell line, many human lymphoblastoid cell lines could also be used as target cells in this assay system.     

T lymphocyte responses to non-H-2 histocompatibility antigens. I. Role of Ly-1+2+ T cells as cytotoxic effectors and requirement for Ly-1+2+ T cells for optimal generation of cytotoxic effectors

Cytotoxic effector T cells specific for non-H-2 histocompatibility (H) antigens were examined for phenotypic expression of lymphocyte differentiation (Ly) antigens. Virtually all H-Y-specific cytotoxic effectors generated in mixed lymphocyte culture were Ly-1+2+ T cells. H-3-specific effectors comprised both Ly-1+2+ and Ly-1-2+ T cells. However, cytotoxic effectors specific for multiple non-H-2 H antigens were predominantly Ly-1-2+ T cells. The optimal generation of H-Y- and H-3-specific effectors required Ly-1+2+ T cells; optimal generation of multiple non-H-2 H antigen-specific effectors required an interaction between Ly-1+2- and Ly-1-2+ T cells. These observations suggest that the identity of the target H antigen in part determines the Ly type of responsive T cells. Our observations suggest that 2 alternative pathways of T cell response exist for non-H-2 H antigens. The first pathway involves an interaction between Ly-1+2- helper T cells and Ly-1-2+ cytotoxic effector precursors. The 2nd pathway simply involves the response of Ly-1+2+ T cells proliferating and generating H antigen-specific cytotoxic effectors.     

Surface markers on the T cells that regulate cytotoxic T-cell responses I. The Ly phenotype of suppressor T cells changes as a function of time, and is distinct from that of helper or cytotoxic T cells

Regulatory T cells can be obtained from primary mixed lymphocyte cultures of CBA spleen cells responding to BALB/c stimulators. At day 3 of culture, T cells are generated which can either help or suppress the generation of cytotoxic T cells in a second primary MLC culture. The regulatory activity observed depends on the conditions employed in the assay system allowing independent assay of different functional cell types which coexist in the cultures. Both the helper activity and the suppressor activity are mediated by differentiated antigen-specific T cells whose function is radioresistant. The Ly phenotype of these regulatory cells was tested. At day 3 of the first-step culture, the phenotype of the helper cells is Ly 1.1+ Ly 2.1-, whereas the inhibitory cells are Ly 1.1 Ly 2.1+. At day 5 of M LC culture, suppressor activity and helper activity are also observed. However, at this point, a suppressor cell which is Ly 1.1-Ly 2.1+ represents the major inhibitory activity. It is not clear whether this change in suppressor cell phenotype as a function of time in culture represents one differentiation pathway or cells derived from two different precursor cells. The Ly phenotype of helper or cytotoxic T cells did not change as a function of time in culture. In day 5 first-step cells, the cytotoxic cells were typed as Ly 1.1+ 2.1+, whereas the inhibitory cells present in aliquots of the same treated cell population expressed the Ly 1.1- Ly 2.1 phenotype. Taken together, these observations show that the antigen-specific suppressor cells and helper cells which regulate the generation of cytotoxicity, and the cytotoxic cells themselves represent physically distinct subclasses of T cells.     

Veto cell H-2 antigens: veto cell activity is restricted by determinants encoded by K, D, and I MHC regions

Responder cells from primary syngeneic and allogeneic one-way mixed-lymphocyte cultures (MLC) specifically inhibit the development of cytotoxic T lymphocytes (CTL) directed against the major histocompatibility complex (MHC) antigens of the MLC responder cells. This special kind of suppressor activity is known as veto suppression. Ia+ cells with veto activity obtained from H-2 recombinant mouse strains were shown to downregulate alloantigen (class II)-specific helper activity for class I-specific CTL development in a primary MLC provided that the veto cells expressed the same I-E alpha subregion as the MLC stimulator cells. The veto-induced suppression of allo-help was prevented by the addition of supernatant from concanavalin A-stimulated spleen cells (Con A-SN) and was inhibited considerably by very high amounts of recombinant interleukin-2 (IL-2). In the presence of Con A-SN, CTL precursors recognizing either the K end or the D end of the veto cell MHC were found to be inactivated. Thus, our results indicate that MLC responder cells include active veto cells expressing Ia region-encoded restriction elements for allospecific T helper cells, as well as K- or D-encoded restriction elements for allospecific T cytotoxic cells.     

Properties of H-2L locus products in allogeneic and H-2 restricted, trinitrophenyl-specific cytotoxic responses.

The role of the recently defined L antigen (a second D region product) in allogeneic and TNP-specific syngeneic primary CML responses has been investigated. The lysis by anti-L specific cytotoxic effector cells was not inhibited when the target cells were pretreated with an antiserum directed against K and D, whereas an antiserum against L completely abrogated this response. Therefore, H-2L products are recognized on the target cell independently of H-2K and H-2D locus products. Both A.SW cells as well as B10 cells were found to respond to Ld alloantigens, in addition to Dd alloantigens when stimulated by cells differing only in the D region. The results of cold target blocking and antiserum inhibition experiments failed to detect cytotoxic cells with specificity of L antigens in association with TNP, under conditions in which TNP-specific effectors to K and D antigens were demonstrable. These findings suggest that there is a more limited involvement of H-2L locus products than the H-2K or H-2D locus products in the induction and specificity of these responses.     

A comparison of the neonatal tolerance-inducing capacities of H-2 class I and class II antigens

We have investigated the abilities of murine major histocompatibility complex-encoded antigens to induce in vitro hyporeactivity of T lymphocytes when these antigens are injected neonatally. Class I molecules, presented on F1 donor cells having an H-2 K or D region difference from recipients, can readily induce tolerogen-specific cytotoxic T cell hyporeactivity; as few as 1 X 10(6) neonatally injected donor cells suffice. In contrast, class II molecules, presented on F1 donor cells having an H-2 I region difference from recipients, can induce tolerogen-specific helper T cell hyporeactivity only when at least 1 X 10(7) neonatally injected donor cells are used, and then only in some of these recipients. Results from another in vitro assay system, taken in conjunction with these data, indicate that the molecular class of the tolerizing disparity, rather than the effector function of the responding cell type assayed, may be the most important factor in controlling the ease with which neonatally induced alloantigen tolerance can be achieved. In each type of tolerance described here, the hyporeactivity seen is antigen specific, in its induction and its expression; the implications of this fact for considerations of possible mechanisms of tolerance maintenance are discussed.     

Alloreactive T-cell clones. Ly phenotypes predict both function and specificity for major histocompatibility complex products

We have studied the association of Ly phenotype with function and specificity for major histocompatibility complex (MHC) products by examining the properties of 21 T-cell clones derived from B10 anti-B 10.D2 and B10.A anti-B10.D2 mixed lymphocyte cultures (MLC). T cells were selected after MLC solely on the basis of Ly phenotype, cloned by limiting dilution, and tested for stability of Ly phenotype, function and specificity for class I or class II MHC products. Sixteen Ly-1⁺2^– and five Ly-1^–2⁺ T-cell clones were tested. The clones selected for the Ly-1 ⁺2^– phenotype maintained this phenotype, expressed helper but not lytic function, and recognized class II MHC products (I-A^d or I-Ed). All Ly-1^–2^– clones maintained this phenotype, possessed cytolytic but not helper activity, and recognized class I MHC products (D^d and L^d). Our data therefore confirm at the clonal level the original observations of a remarkably consistent correlation between Ly markers, MHC specificity, and. function. They suggest that the expression of Ly antigens on T-cell clones forms part of a genetic program for each of these specialized cells that also determines their function and MHC specificity.Abbreviations used in this paper MHC major histocompatibility complex - MLC mixed lymphocyte culture - TCGF T cell growth factor (Interleukin-2) - Con A Concanavalin A - DME Dulbecco's modified Eagle's medium - PHA phytohaemagglutinin - LPS lipopolysaccharide - TRF-C T cell replacing factor required for induction of cytolytic cells from thymocytes - PBS phosphate-buffered saline (pH 7.4)     

Surface markers of T cells causing lethal graft-vs-host disease to class I vs class II H-2 differences

Information was sought on the phenotype of lymphoid cells causing lethal graft-vs-host disease (GVHD) in irradiated mice expressing whole or partial H-2 differences. In all strain combinations tested, pretreating donor lymph node (LN) cells with anti-Thy-1 monoclonal antibodies (MAb) plus complement (C) abolished mortality. With GVHD directed to class I H-2 differences, pretreating LN cells with anti-Lyt-2 MAb prevented mortality, whereas MAb specific for Ly-1 or L3T4 cell surface determinants caused severe mortality. These data imply that lethal GVHD directed to class I H-2 differences is mediated by L3T4-, Lyt-2+ cells; this subset of T cells was shown previously to control GVHD directed to multiple minor histocompatibility antigens, i.e., antigens seen in the context of self-class I molecules. With whole H-2 differences, GVHD appeared to be controlled largely but not exclusively by L3T4+, Lyt-2-T cells. This T cell subset was also the predominant cause of GVHD directed to class II differences. With class II incompatibilities, depleting donor cells of L3T4+ T cells, either by pretreatment with anti-L3T4 MAb + C or by fluorescence activated cell sorter selection, greatly reduced but did not completely abolish GVHD. These data might imply that L3T4-, Lyt-2+ cells have some capacity to elicit anti-class II GVHD. A more likely possibility, however, is that the residual GVHD to class II differences observed with Lyt-2+-enriched cells reflected minor contamination with L3T4+ cells.     

F1 hybrid anti-parental H-2k cell-mediated lympholysis. I. Stimulator and target determinants controlled by the H-2K region.

H-2k-heterozygous F1 hybrid mouse spleen cells cultured with irradiated H-2k-homozygous stimulator cells generated specific anti-parent cytolytic effectors. The parental antigenic determinants recognized by responder cells during induction (afferent arm) and by effector cells during cytolysis (efferent arm) were coded for, or regulated by, the H-2K-Hh3 region of the MHC, according to recombinant analysis. There were no detectable influences by other linked or unlinked genes on the phenotypic expression of parental antigens; however, the anti-parent responsiveness was modulated by background genes of responder cells. These experiments establish that the K end of H-2 controls determinants of F1 anti-parental H-2k CML, like the D end controls those of F1 anti-parental H-2b CML, thus confirming the basic symmetry of the H-2 complex. The relationship of this primary in vitro cell-mediated response with natural in vivo resistance to parental and allogeneic bone marrow grafts is discussed.     

Modulation of Thy-1 alloantibody responses: donor cell-associated H-2 inhibition and augmentation without recipient Ir gene control

In this study we have found that in vivo PFC responses to Thy-1 are strongly modulated by H-2 gene products in at least 2 ways. First, a profound inhibition of primary PFC responses occurs when foreign H-2 antigens are expressed on Thy-1 incompatible donor cells. This interference effect does not reflect a requirement for H-2-restricted antigen presentation by donor cells, since it is also seen using semi-syngeneic antigenic cells that share a full H-2 haplotype with the recipient. Interference acts more profoundly on slower primary responses than on more rapid secondary responses and requires associative recognition of the H-2 and Thy-1 antigens. By contrast, strong augmentation of the anti-Thy-1 response was obtained when foreign H-2 antigens were expressed in the recipient, as shown by a poor response of an H-2k/k recipient to Thy-1.1 on AKR cells (H-2k) compared with high responses of H-2k/b recipients. A gene controlling this phenotype was mapped to the H-2IA or H-2K regions. However, subsequent experiments revealed that donor recognition of recipient H-2 antigens was required for these high responses; thus, an Ir-gene effect was excluded and an 'intimate form' of an allogeneic effect was postulated. Thus, the immune response to Thy-1 is regulated by at least 3 factors acting at the level of the donor cell, including non-H-2 helper alloantigens, H-2 interference, and H-2-associated allogeneic effects.     

In vitro analysis of allogeneic lymphocyte interaction. IV. Dual recognition of B cell-associated Mls locus and I-region determinants by a helper allogeneic effect factor (AEF) generated across a minor H locus disparity.

A helper allogeneic effect factor (AEF) was produced across an incompatibility at the minor histocompatibility loci. This AEF is genetically restricted in its activity since it helps B cells only of the stimulator haplotype and of haplotypes that share both an Mls and I-region identity with the stimulator haplotype. The I-region genes involved here map to the I-A and/or I-C subregions. An anti-LyM immunoadsorbent column but neither an anti-H-2 nor an anti-Ia column absorbed AEF helper activity. It is suggested that the activation of T helper cells by a positive allogeneic effect across a minor H locus difference and their genetically restricted interaction with allogeneic B cells may in part be due to the acquisition by alloactivated T cells of stimulator cell-derived LyM and/or Mls determinants. The data presented indicate that helper T cells recognize Mls locus alloantigens in the milieu of self Ia antigens.     

The use of a clonal assay for cytotoxic T lymphocytes to determine the Ly phenotypes of the cytotoxic precursor and effector cells to alloantigens and trinitrophenyl-modified self antigens

Considerable controversy has arisen regarding the Ly phenotypes of cytotoxic T lymphocytes (CTL) and their precursors (CLP) to alloantigens and modified-self antigens. Although there is general agreement that all CTL and their pregenitors express the Ly2 alloantigen, the presence of the LY1 alloantigen on either CTL or CLP is debated. Clonal assays for CLP, capable of detecting single CLP in the absence of accessory cells, have recently been developed. This assay system provides a sensitive means of determining the Ly phenotypes of CLP to alloantigens or trinitrophenyl- (TNP) modified self antigens. Lymph node cells from C57BL/6 (Ly-1.2, 2.2, 3.2) or CBA (Ly-1.1, 2.1, 3.2) mice were treated with anti-Ly serum and complement (C), and the frequencies of CLP of the treated populations to alloantigens or TNP-modified self antigens were determined. We found that the number of CLP reactive to alloantigens or TNP-modified self antigens were greatly reduced after treatment with either anti-Ly-1 or anti-Ly-2 serum and C in both C57BL/6 and CBA mice. In other words, the CLP to alloantigens or TNP-modified self antigens in these 2 strains of mice are Ly 1+2+. We also found that the CTL derived from the Ly1+2+ CLP were also Ly1+2+. The significance of this finding with respect to the cytotoxic repertoire for alloantigens and modified self antigens is discussed.     

Genetic analysis of the H-2D region using a new intra-D-region recombinant mouse strain

A rare D-region recombination event which gave rise to the B10.RQDB major histocompatibility complex haplotype has been examined to ascertain the nature of the crossover and to determine which class I genes are present in the new alignment of D-region genes. Serologic analysis have shown that the B10 . RQDB major histocompatibility complex recombinant mouse inherited the H-2Dd gene from the B10.T(6R) parental line and the H-2Db gene from the B10.A(2R) parental line, representing the first example of an intra-D-region crossover resulting from an intercross. Previous molecular genetic analyses of the d and b haplotypes revealed structural diversity in the organization of their D-region gene clusters. Hence, the D region is comprised of five class I genes in the d haplotype and only one in the b haplotype. Because allelic relationships among the various D-region genes are not defined, either a homologous or nonhomologous alignment of genes has generated the RQDB crossover. Therefore, the possibility that all three D-region antigen-presenting molecules (Dd, Ld, and Db) might be encoded by the RQDB haplotype was examined. Fluorescence-activated cell sorter and cytotoxic T lymphocyte analyses revealed no detectable levels of H-2Ld cell-surface expression, confirming earlier studies with antibody-mediated cytotoxicity and immunoprecipitation. Southern blot analysis localized the recombination point to within a 1-kb region at the centromeric end of the H-2Ld gene on the B10 . T(6R) chromosome in a region of high homology to the H-2Db gene on the B10 . A(2R) chromosome. Together, these studies define the D region of the RQDB haplotype as containing the five class I genes: Dd, D2d, D3d, D4d, and Db. In addition to providing insight into rare recombination events in the D region, the B10.RQDB mouse should be a useful tool for exploring the function of D-region genes.