The phenotype of H-2M-deficient mice is dependent on the MHC class II molecules expressed

For a broader view of the role of H-2M as an accessory molecule in antigen presentation, we investigated the degree to which different MHC class II isotypes and alleles depend on H-2M to function in vivo. We generated H-2M-deficient animals expressing E^{k / b} or A^k molecules in addition to the A^b molecules already present in the mutant strain, and compared the ability of the different MHC class II molecules to present antigen at the cell surface for recognition by T cells, and contribute to positive selection of CD4⁺ T cells in the thymus. Biochemical analyses were performed to assess MHC class II maturation, and to determine the peptide content of the molecules. In the absence of H-2M, E^{k / b} molecules containd a more heterogeneous set of class II-associated invariant chain peptides (CLIP) than A^b did, which, unlike A^b -CLIP complexes, were not SDS-stable. Unlike A^b molecules, both E^{k / b} and A^k efficiently presented exogenously added peptides to T cells in the absence of H-2M. In addition, epitopes from some proteins, especially those known to be invariant chain independent, were presented by A^k molecules in the mutant animals. To our surprise, expression of E^{k / b} overcame the positive selection defect observed in H-2M-deficient mice expressing A^b alone. In contrast, A^k expression did not augment positive selection of CD4⁺ T cells in the mutant animals. Some of these findings in vivo contrast significantly with findings from in vitro studies on murine MHC class II molecules in human DM-deficient cell lines.     

Cross-reactivity among evolutionarily distant major histocompatibility complex class I molecules (HLA-B27 and H-2Kk) revealed by xenoreactive T lymphocytes

A set of mouse HLA-B27-reactive cytotoxic T lymphocyte clones were found to recognize the HLA-B27 molecule in an H-2-unrestricted manner, i.e. independently of any mouse major histocompatibility complex (MHC) molecule. The reactivity patterns of these clones on HLA-B27 variants (positive only on HLA-B*2702 and HLA-B*2701) allowed the identification of residues N77 and A81 of the HLA-B27 molecule as important for their reactivity. The location of these residues in the peptide-binding groove (specificity pocket F) suggested that the reactivity of the clones is dependent on HLA-B27-bound peptide(s). However, several other class I molecules sharing these residues (N77 and A81) were not recognized, indicating that other residues might also be involved. One of the clones was found to display an interesting cross-reactivity with allogeneic H-2K^k molecules, sharing N77 and A81 with HLA-B*2702. Sequence comparison suggested the involvement of residue H9, located in specificity pocket B of the peptide-binding groove, and revealed some similarity of pockets B in HLA-B27 and H-2K^k. The structural basis of such T cell-mediated MHC cross-reactions across species barriers is discussed.     

The T/B cell interaction involved in induction of the mouse IgG2ah suppression is restricted by major histocompatibility complex class I,but not class II molecules

To determine the major histocompatibility complex (MHC) restriction of the T/B cell interaction involved in a negative regulation of Ig production, we used mouse model of T cell-induced IgG2a^b suppression in vivo. Normal or specifically triggered T splenocytes from mice of the Igh^a haplotype, when neonatally transferred into histocompatible Igh^a/b heterozygotes, are able to induce a specific and total suppression of the IgG2a^b allotype. Nevertheless, only transfer of IgG2a^b-primed Igh^a T splenocytes induces this suppression in Igh^b/b homozygous congenic mice in which the whole IgG2a isotype production is inhibited. This suppression is chronically maintained by CD8⁺ T cells, but can be experimentally reversed. We have established that the suppression induction required a CD4⁺CD8⁺ T cell cooperation and operated via the recognition by the involved TCR of Cγ2a^b-derived peptides presented by the target B cells in an MHC haplotype-restricted manner. Here, by using Igh^b mice genetically deficient for MHC class I (β2-microglobulin^%, or β2m^%) or class II (I-Aβ^%) molecules, we demonstrate functionally that the suppression induction implicates an MHC class I-, but not class II-restricted interaction. Indeed, the anti-IgG2a^b T cells transferred into Igh^b H-2^b I-Aβ^% mice carry out the suppression process normally, while in Igh^b H-2^b β2m^% recipients, their suppression induction capacity is significantly inhibited. Moreover, the Cγ2a^b 103–118 peptide, identified as the sole Cγ2a^b-derived peptide able to amplify the anti-IgG2a^b T cell reactivity in Igh^a H-2^b mice, is also able to stabilize the H-2D^b, but not the H-2K^b class I molecules at the surface of RMA-S (TAP2^?, H-2^b) cells. These results indicate that, despite the CD4⁺/CD8⁺ T cell cooperation during the induction phase of suppression only MHC class I molecule expression is required at the surface of IgG2a^b+ B cells for suppression establishment.     

Identification of an HLA-DQ6-derived peptide recognized by mouse MHC class I H-2Db-restricted CD8+ T cells in HLA-DQ6 transgenic mice

Summary CD8⁺ T cells from C57BL/6(B6) mice show cytotoxicity to B cell blasts prepared from syngeneic transgenic mice expressing HLA-DQ6 molecules in a mouse MHC class I H-2D^b restricted manner. Although these results suggest that CD8⁺ T cells recognize peptides derived from DQ6 molecule bound to H-2D^b on target cells, no direct evidence so far has been obtained. To clarify this, we synthesized 23 peptides corresponding to DQ6α orβ chain and carrying the motifs of D^b-binding peptides, and examined their capacity to induce cytotoxicity in the CD8⁺ T cell line. We show here that DQA1-2, one of these peptides, induced cytotoxicity of the CD8⁺ T cells when this peptide was pulsed to H-2D^b expressing target cells, as efficiently as HLA-DQ6 expressing target cells did. Thus, our results suggest that DQA1-2 can be naturally processed from DQ6 molecules and recognized by the CD8⁺ T cells in the context of H-2D^b molecules. These results suggest that allogeneic HLA class II molecules are involved in the rejection not only as the ligand for T cell receptor of alloreactive CD4⁺ T cells but also as self-peptides bound to HLA class I molecules recognized by CD8⁺ T cells.     

The structural basis of MHC control of collagen-induced arthritis; binding of the immunodominant type II collagen 256 – 270 glycopeptide to H-2Aq and H-2Ap molecules

The A^q major histocompatibility complex (MHC) class II molecule is associated with susceptibility to murine collagen-induced arthritis (CIA), whereas the closely related H-2A^p molecule is not. To understand the molecular basis for this difference, we have analyzed the ability of H-2A^q and H-2A^p molecules (referred to as A^q and A^p) to bind and present collagen type II (CII)-derived glycosylated and non-glycosylated peptides. T cell clones specific for the immunodominant CII 256 – 270 peptide and restricted to both A^q and A^p molecules were identified. When these clones were incubated with CII protein and either A^q- or A^p-expressing antigen-presenting cells (APC), only A^q-expressing APC were able to induce stimulation. With the use of A_β transgenic mice this could be shown to be solely dependent on the MHC class II molecule itself and to be independent of other MHC- or non-MHC genes. Peptide binding studies were performed using affinity-purified MHC class II molecules. The CII 256 – 270 peptide bound with lower affinity to the A^p molecule than to the A^q molecule. Using a set of alanine-substituted CII 256 – 270 peptides, MHC class II and T cell receptor (TCR) contacts were identified. Mainly the side chains of isoleucine 260 and phenylalanine 263 were used for binding both the A^q and A^p molecule, i. e. the peptide was orientated similarly in the binding clefts. The major TCR contact amino acids were lysine 264, which can be posttranslotionally modified, and glutamic acid 266, which is the only amino acid in the heterologous peptide which differs from the mouse sequence. Glycosylation at positions 264 and 270 of the CII 256 – 270 peptide did not change the anchor positions used for binding to the A^q or A^p molecules. The autologous form of the peptide (with aspartic acid at position 266) bound with lower affinity to the A^q molecule as compared with the heterologous peptide. The variable affinity displayed by the immunodominant CII 256 – 270 peptide for different MHC class II molecules, the identification of MHC and TCR contacts and the significance of glycosylation of these have important implications for the understanding of the molecular basis for inherited MHC class II-associated susceptibility to CIA and in turn, for development of novel treatment strategies in this disease.     

Influence of glycosylphosphatidylinositol-linked H-2Dd molecules on target cell protection and natural killer cell specificity in transgenic mice

The expression of certain major histocompatibility complex (MHC) class I ligands on target cells is one important determinate of their susceptibility to lysis by natural killer (NK) cells. NK cells express receptor molecules that bind to MHC class I. Upon binding to their MHC class I ligand, the NK cell is presumed to receive a signal through its receptor that inhibits lysis. It is unclear what role the MHC class I molecules of the effector and target cells play in signaling to the NK cell. We have investigated the role of the cytoplasmic and transmembrane domains of MHC class I molecules by producing a glycosylphosphatidylinositol (GPI)-linked H-2D^d molecule. The GPI-linked H-2D^d molecule is recognized by H-2D^d-specific antibodies and cytotoxic T lymphocytes. Expression of the GPI-linked H-2D^d molecule on H-2^b tumor cells resulted in protection of the tumor cells after transplantation into D8 mice (H-2^b, H-2D^d) from rejection by NK cells. In addition, NK cells from mice expressing the GPI-linked H-2D^d molecule as a transgene were able to kill nontransgenic H-2^b lymphoblast target cells. The GPI-linked MHC class I molecule was able to alter NK cell specificity at the target and effector cell levels. Thus, the expression of the cytoplasmic and transmembrane domains of MHC class I molecules are not necessary for protection and alteration of NK cell specificity.     

Differential reactivity of residual CD8+ T lymphocytes in TAP1 and β2-microglobulin mutant mice

TAP1 -/- and β2-microglobulin (β2m) -/- mice (H-2^b background) express very low levels of major histocompatibility complex (MHC) class I molecules on the cell surface. Consequently these mice have low numbers of mature CD8⁺ T lymphocytes. However, TAP1 -/- mice have significantly higher numbers of CD8⁺ T cells than β2m -/- mice. Alloreactive CD8⁺ cytotoxic T lymphocyte (CTL) responses were also stronger in TAP1 -/- mice than in β2m -/- mice. Alloreactive CTL generated in TAP1 -/- and β2m -/- mice cross-react with H-2^b-expressing cells. Surprisingly, such cross-reactivity was stronger with alloreactive CTL from β2m -/- mice than with similar cells from TAP1 -/- mice. The β2m -/- mice also responded more strongly when primed with and tested against cells expressing normal levels of H-2^b MHC class I molecules. Such H-2^b-reactive CD8⁺ CTL from β2m -/- mice but not from TAP1 -/- mice also reacted with TAP1 -/- and TAP2-deficient RMA-S cells. In contrast, H-2^b-reactive CD8⁺ CTL from neither β2m -/- mice nor TAP1 -/- mice killed β2m -/- cells. In line with these results, β2m -/- mice also responded when primed and tested against TAP1 -/- cells. We conclude that the reactivity of residual CD8⁺ T cells differs between TAP1 -/- and β2m -/- mice. The MHC class I-deficient phenotype of TAP1 -/- and β2m -/- mice is not equivalent: class I expression differs between the two mouse lines with regard to quality as well as quantity. We propose that the differences observed in numbers of CD8⁺ T cells, their ability to react with alloantigens and their cross-reactivity with normal H-2^b class I are caused by differences in the expression of MHC class I ligands on selecting cells in the thymus.     

Lipid‐mediated presentation of MHC class II molecules guides thymocytes to the CD4 lineage

Previous studies on the MHC class‐specific differentiation of CD4⁺CD8⁺ thymocytes into CD4⁺ and CD8⁺ T cells have focused on the role of coreceptor molecules. However, CD4 and CD8 T cells develop according to their MHC class specificities even in these mice lacking coreceptors. This study investigated the possibility that lineage is determined not only by coreceptors, but is also guided by the way how MHC molecules are presented. MHC class II molecules possess a highly conserved Cys in their transmembrane domain, which is palmitoylated and thereby associates with lipid rafts, whereas neither palmitoylation nor raft association was observed with MHC class I molecules. The generation of CD4 T cells was impaired and that of CD8 T cells was augmented when the rafts on the thymic epithelial cells were disrupted. This was due to the conversion of MHC class II‐specific thymocytes from the CD4 lineage to CD8. The ability of I‐A^d molecule to associate with rafts was lost when its transmembrane Cys was replaced. The development of DO11.10 thymocytes recognizing this mutant I‐A^dm was converted from CD4 to CD8. These results suggest that the CD4 lineage commitment is directed by the raft‐associated presentation of MHC class II molecules.     

MUC1 peptide epitopes associated with five different H-2 class I molecules

We have previously described the induction of murine CD8⁺ major histocompatibility complex (MHC) class I-restricted cytotoxic T cells (CTL) recognizing the 20-amino acid repeat region of the human mucin 1 (MUC1) variable number of tandem repeats region (VNTR), a mucin greatly increased in expression in breast cancer and proposed as a target for immunotherapy. In that study, CTL could detect MUC1 peptides associated with the MHC of all nine strains examined, and we now report the different epitopes presented by five different MHC class I molecules. The epitopes were defined in CTL assays using peptide-pulsed phytohemagglutinin blasts or MHC class I-transfected L cells as targets; in addition, peptide binding assays and T cell proliferation studies were performed. Within the 20-amino acid VNTR, nine potential epitopes could be defined. The epitopes for the four MHC class I molecules [K^b (three epitopes), D^d, L^d and K^k] were closely related, all containing the amino acids PDTRPAP. For D^b, three epitopes were identified, all containing APGSTAP. Most of the epitopes did not contain a consensus motif for the particular MHC class I allele, and bound with low ‘affinity’, compared with known high-affinity peptides. CD8⁺ T cell proliferation also occurred to the same MHC class I-presented epitopes. Finally, when conventional anchor residues were introduced into the peptides, peptide binding increased, whereas CTL recognition was either retained (K^b) or lost (D^b) depending on the epitope.     

Antigen processing mutant T2 cells present viral antigen restricted through H-2K

Cytotoxic T lymphocytes (CTL) recognize foreign antigens as short peptides presented by class I molecules of the major histocompatibility complex (MHC). T2 cells are profoundly defective in the presentation of endogenously synthesized antigens to CTL due to a deletion of MHC class II-encoded genes for transporters associated with antigen presentation (TAP1/TAP2). Surprisingly, we here demonstrate that T2 cells, after infection with Sendai virus, are readily killed by H-2K^b restricted CD8⁺ T cells. In contrast to classical class I-mediated antigen presentation, the presentation of Sendai virus antigen inT2K^b cells is brefeldin A (BFA) insensitive. The present findings may suggest the presence of an alternative pathway for MHC class I-mediated antigen presentation in T2 cells.     

Generation of hen egg lysozyme-specific and major histocompatibility complex class I-restricted cytolytic T lymphocytes: recognition of cytosolic and secreted antigen expressed by transfected cells

Syngeneic cells exogenously supplied with hen egg lysozyme (HEL) or endogenously synthesizing HEL were used as antigen-presenting cells to induce major histocompatibility complex class I-restricted cytotoxic T lymphocytes (CTL). Immunization of C57BL/6 mice followed by repeated stimulation of their splenocytes in vitro with trypsinized HEL peptides led to the generation of CTL lines specific for trypsinized HEL peptides and restricted by H-2K^b. Immunization of C3H mice with a mixture of soluble native HEL and irradiated syngeneic spleen cells followed by in vitro stimulation of immune spleen cells with soluble HEL could in a few cases result in HEL-specific CTL able to kill syngeneic transfectant L cells secreting HEL (HELs) or expressing cytosol-targeted HEL (HELc). The use of HELs or HELc transfectant L cells as in vivo and in vitro immunogens was a potent way for eliciting HEL-specific polyclonal CTL. These CTL and two CD8⁺ clones were found to be H-2K^k restricted and specific for the 1-17 N-terminal HEL peptide. In addition, the anti-HEL CTL could also exhibit a significant cross-reactivity against unsensitized and HEL-untransfected targets expressing the K restriction element. This cross-reactivity was likely due to recognition of unidentified HEL mimicking peptides (self-derived ?) presented by the MHC class I (H-2K^b or H-2K^k) molecule used as the restriction element for the specific recognition of HEL. The CTL raised after immunization with HELs or HELc transfectant cells were found to recognize both the HELs and HELc transfectant cells even though HEL was not detected in the latter after a 2- or 5-min radiolabeling pulse. Recognition of both HELs and HELc transfectant cells by a given CTL clone suggests that HEL subjected to two separate processing pathways, each depending on the initial subcellular localization, can ensure the generation of similar MHC class I peptide complexes.     

Presentation of a horse cytochrome c peptide by multiple H-2b class I major histocompatibility complex (MHC) molecules to C57BL/6- and bm1-derived cytotoxic T lymphocytes: Presence of a single MHC anchor residue may confer efficient peptide-specific CTL recognition

In this study the immunogenic tryptic fragment from a horse cytochrome c (cyt c) digest recognized by cytotoxic T lymphocytes (CTL), induced by in vitro peptide stimulation from C57BL/6 (B6) and mutant B6.C-H-2^bm1 (bm1) mice is identified. An identical sequence, p40—53, is recognized by CTL from both B6 and bm1 mice. In addition, both B6 and bm1 cloned CTL lines display unusual major histocompatibility complex (MHC) class I-restricted recognition of this peptide in that they respond to it in the context of H-2K^b, H-2D^b, and H-2K^bm1 class I molecules, although the sequence lacks the usual structural K^b and D^b peptide-binding motifs. Truncated analogues which resemble the lengths of naturally processed MHC class I-presented peptides, confer reactivity for B6 and bm1 CTL against EL4 (H-2^b) targets as well as the L cell transfectants, L + K^b, L + D^b, and L + K^bm1. The antigenic peptide with the greatest potency is p41—49, which appears to be generated by angiotensin converting enzyme cleavage of the full-length p40—53 tryptic peptide. The minimum antigenic peptide recognized by both B6 and bm1 CTL, and which targets lysis on each of the transfectants, is the hexamer p43—48 peptide from horse cyt c. Residues Pro⁴⁴ and Thr⁴⁷, which occupy polymorphic positions with respect to other species-variant cyt c molecules, influence recognition of these peptides differently for the B6 and bm1 CTL. The ability of H-2K^b, H-2D^b, and mutant H-2K^bm1 class I molecules to present the same peptide to a single cloned CTL is discussed in the context of current knowledge of peptide anchor residues and side chain-specific binding pockets in the MHC class I peptide-binding site.     

Efficient presentation of endogenous superantigen by H-2Aq

Endogenous superantigens encoded by mouse mammary tumor viruses associate with MHC class II and interact with T cells bearing particular Vβ gene segments. H-2E is more efficient at presentation than H-2A, indeed A^q has not been shown to be capable of presenting endogenous superantigens. Atypically, the superantigen vSAG-3 encoded by Mtv-3 is presented efficiently in non-obese diabetic (H-2^g7) mice by H-2A; we have examined the independent contributions of vSAG-3 and A^g7 to this process. A^g7 was not found to have a more general ability to efficiently present endogenous superantigens other than Mtv-3. Examination of Mtv-3-mediated thymic deletion of Vβ 3⁺ thymocytes in the presence of H-2^q additionally demonstrated the efficient presentation of vSAG-3 by A^q. Interaction of vSAG-3 with A^q and A^g7 is likely to reflect the unique sequence of Mtv-3 within the second polymorphic region previously implicated in MHC class II binding. The demonstration that mouse endogenous superantigens can be presented by a wider range of MHC haplotypes than previously thought is further evidence for their immunological impact on the mouse population.     

Analysis of intraepithelial lymphocytes from major histocompatibility complex (MHC)-deficient mice: No evidence for a role of MHC class II antigens in the positive selection of Vδ4+γδ T cells

Three-color flow cytometric analysis was carried out with intraepithelial lymphocytes from mice deficient in expression of major histocompatibility complex (MHC) antigens. These experiments were done to address the possible role of MHC class II molecules in the positive selection of Vδ4⁺ γδ T cells. By analyzing mice deficient MHC class II antigens alone or in combination with MHC class I antigens, no evidence was found for positive selection of Vδ4⁺ cells among CD8a⁺ or CD4^?CD8^? subpopulations of γδ T cell receptor-positive cells. Because V54⁺, CD8a⁺ cells were reported to be positively selected on I-E^k and hybrid I-E^k/b molecules, class II-deficient animals were crossed with I-E^k transgenic mice and progeny examined for Vδ4 expression. Again, no evidence for positive selection was found. Interestingly, in MHC class I-deficient animals, the total number of γδ T cells was about twofold higher than in control and MHC class II-deficient mice and the proportion of V8δ-expressing cells was correspondingly decreased. Taken together, these results cast doubt on a major role for conventional MHC antigens in shaping the γδ T cell repertoire of intraepithelial lymphocytes.     

Leishmania major infection in mice primes for specific major histocompatibility complex class I-restricted CD8+ cytotoxic T cell responses

This report shows that lymphoid tissues of mice which have resolved a primary infection with Leishmania major contain parasite-specific major histocompatibility complex (MHC) class I-restricted cytolytic CD8⁺ T cell precusors that can be expanded after specific restimulation in vitro with syngeneic antigen-presenting cells pulsed with a cyanogen bromide digest of L. major. In H-2^b mice, two distinct populations of CD8⁺ T cells were identified which both lysed target cells pulsed with L. major-derived peptides but were restricted by a different H-2^b class I gene product. Interestingly, these two populations appear to recognize different parasite-derived peptides. It is noteworthy that one K°-restricted CD8⁺ T cell line was able to specifically lyse syngeneic macrophages infected with viable L. major, indicating that some L. major-derived peptides may reach the MHC class I pathway of presentation from the phagolysosomal compartment where the parasites are confined in infected macrophages. The importance of these parasite-specific MHC class I restricted cytolytic CD8⁺ T cells for the elimination of L. major by the infected host remains to be determined.     

Mouse pancreatic beta cells express MHC class II and stimulate CD4+ T cells to proliferate

Type 1 diabetes results from destruction of pancreatic beta cells by autoreactive T cells. Both CD4⁺ and CD8⁺ T cells have been shown to mediate beta‐cell killing. While CD8⁺ T cells can directly recognize MHC class I on beta cells, the interaction between CD4⁺ T cells and beta cells remains unclear. Genetic association studies have strongly implicated HLA‐DQ alleles in human type 1 diabetes. Here we studied MHC class II expression on beta cells in nonobese diabetic mice that were induced to develop diabetes by diabetogenic CD4⁺ T cells with T‐cell receptors that recognize beta‐cell antigens. Acute infiltration of CD4⁺ T cells in islets occurred with rapid onset of diabetes. Beta cells from islets with immune infiltration expressed MHC class II mRNA and protein. Exposure of beta cells to IFN‐γ increased MHC class II gene expression, and blocking IFN‐γ signaling in beta cells inhibited MHC class II upregulation. IFN‐γ also increased HLA‐DR expression in human islets. MHC class II⁺ beta cells stimulated the proliferation of beta‐cell‐specific CD4⁺ T cells. Our study indicates that MHC class II molecules may play an important role in beta‐cell interaction with CD4⁺ T cells in the development of type 1 diabetes.     

Peptide length preferences for rat and mouse MHC class I molecules using random peptide libraries

MHC class I molecules bind short peptides for presentation to CD8⁺ T cells. The determination of the three-dimensional structure of various MHC class I complexes has revealed that both ends of the peptide binding site are composed of polar residues conserved among all human and murine MHC class I sequences, which act to lock the ends of the peptide into the groove. In the rat, however, differences in these important residues occur, suggesting the possibility that certain rat MHC class I molecules may be able to bind and present longer peptides. Here we have studied the peptide length preferences of two rat MHC class I a molecules expressed in the TAP2-deficient mouse cell line RMA-S: RT1-A1^c, which carries unusual key residues at both ends of the groove, and RT1.A^a which carries the canonical residues. Temperature-dependent peptide stabilization assays were performed using synthetic random peptide libraries of different lengths (7 – 15 amino acids) and successful stabilization was determined by FACS analysis. Results for two naturally expressed mouse MHC class I molecules revealed different length preferences (H2-K^b, 8 – 13-mer and H2-D^b, 9 – 15-mer peptides). The rat MHC class Ia molecule, RT1-A^a, revealed a preference for 9 – 15-mer peptides, whereas RT1-A1^c showed a more stringent preference for 9 – 12-mer peptides, thereby ruling out the hypothesis that unusual residues in rat MHC molecules allow binding of longer peptides.     

Major histocompatibility complex class I presentation of exogenously acquired minor alloantigens initiates skin allograft rejection

Major histocompatibility complex (MHC) class I molecules present peptides from endogenous proteins. However, in some cases class I-restricted peptides can also derive from exogenous antigens. This MHC class I exogenous presentation could be involved in minor histocompatibility antigen (mHAg)-disparate allograft rejection when donor alloantigens are not expressed in graft antigen-presenting cells (APC) that initiate the rejection mechanism. Here we addressed this question by using a skin graft experimental model where donors (H-2^b or H-2^d Tgβ-gal mice) expressed the mHAg like β-galactosidase (β-gal) in keratinocytes but not in Langerhans' cells (LC) which have an APC function. Rejection of Tgβ-gal skin by a β-gal-specific CD8 cytotoxic T lymphocyte (CTL) effector mechanism should require presentation by donor and/or recipient LC of MHC class I-restricted peptides of exogenous β-gal shed by keratinocytes. Indeed, our results showed that 1) H-2^b Tgβ-gal skin was rejected by H-2^bxs and H-2^bxd recipients; 2) rejection was mediated by β-gal-specific CD8⁺ CTL effectors; and 3) H-2^bxd mice having rejected H-2^b Tgβ-gal skin generated β-gal-specific CTL restricted by H-2^b and H-2^d class I molecules and rejected subsequently grafted H-2^d Tgβ-gal skin in an accelerated fashion, demonstrating that recipient LC have presented exogenous β-gal-derived MHC class I epitopes. These results lead to the conclusion that MHC class I exogenous presentation of donor mHAg can initiate allograft rejection.     

Structural studies on H-2Db and H-2Kd molecules indicate that murine major histocompatibility b and d haplotype alloantigens share structural features

Structural properties of the H-2D^b and H-2K^d murine major histocompatibility complex (MHC) antigens were examined by radiochemical methods. Radiolabelled preparations of the H-2D^b and H-2K^d antigens were obtained by indirect immune precipitation of NP-40 lysates of the lymphoid tumor cell lines EL-4 (H-2^b) and C14 (H-2^d), respectively. After preparation of the 37,000 molecular weight papain fragment the antigens were cleaved with CNBr. The H-2K^d antigen yielded four major CNBr fragments whereas the H-2D^b molecule provided six. These CNBr fragments were subjected to partial NH₂-terminal amino acid sequence analysis and aligned by homology to the H-2K^b glycoprotein. Comparison of the structural properties of the H-2K^d and H-2D^b molecules with previously published data on the other known major transplantation antigens of the b and d haplotypes (H-2K^b, H-2D^d and H-2L^d) reveal a marked structural similarity. First, the data show that certain methionine residues have been highly conserved and that cleavage by CNBr at these positions provides an initial strategy for the study of these molecules. Secondly, disulfide-linked peptides obtained after CNBr cleavage could be aligned and the data suggest the presence of disulfide bridges in homologous positions. Third, after CNBr cleavage both the H-2K^d and H-2D^b molecules yielded two glycopeptides which were homologous to glycopeptides from the H-2K^b molecule. Fourth, overall homology for a limited number of comparable positions is about 81% between the H-2K^b and H-2K^d gene products and 88% between the H-2K^b and H-2D^b gene products.