Hydrogen bond integrity between MHC class II molecules and bound peptide determines the intracellular fate of MHC class II molecules.

MHC class II molecules associate with peptides through pocket interactions and the formation of hydrogen bonds. The current paradigm suggests that the interaction of side chains of the peptide with pockets in the class II molecule is responsible for the formation of stable class II-peptide complexes. However, recent evidence has shown that the formation of hydrogen bonds between genetically conserved residues of the class II molecule and the main chain of the peptide contributes profoundly to peptide stability. In this study, we have used I-A(k), a class II molecule known to form strong pocket interactions with bound peptides, to probe the general importance of hydrogen bond integrity in peptide acquisition. Our studies have revealed that abolishing hydrogen bonds contributed by positions 81 or 82 in the beta-chain of I-A(k) results in class II molecules that are internally degraded when trafficked through proteolytic endosomal compartments. The presence of high-affinity peptides derived from either endogenous or exogenous sources protects the hydrogen bond-deficient variant from intracellular degradation. Together, these data indicate that disruption of the potential to form a complete hydrogen bond network between MHC class II molecules and bound peptides greatly diminishes the ability of class II molecules to bind peptides. The subsequent failure to stably acquire peptides leads to protease sensitivity of empty class II molecules, and thus to proteolytic degradation before export to the surface of APCs.

Energetic asymmetry among hydrogen bonds in MHC class II*peptide complexes.

Comparison of crystallized MHC class II*peptide complexes has revealed that, in addition to pocket interactions involving the peptide side chains, peptide binding to MHC class II molecules is characterized by a series of hydrogen bonds between genetically conserved amino acid residues in the class II molecule and the main chain of the peptide. Many class II*peptide structures have two sets of symmetrical hydrogen bonds at the opposite ends of the class II antigen-binding groove (beta-His-81, beta-Asn-82 vs. alpha-His-68, alpha-Asn-69). In this study, we alter these peripheral hydrogen bonds and measure the apparent contribution of each to the kinetic stability of peptide* II complexes. Single conservative amino substitutions were made in the I-A(d) protein to eliminate participation as a hydrogen bonding residue, and the kinetic stability of a diverse set of peptides bound to the substituted I-A(d) proteins was measured. Although each hydrogen bond does contribute to peptide binding, our results point to the striking conclusion that those hydrogen bonds localized to the amino terminus of the peptide contribute profoundly and disproportionately to the stability of peptide interactions with I-A(d). We suggest that the peripheral hydrogen bonds at the amino terminus of the bound peptide that are conserved in all class II*peptide crystal structures solved thus far form a cooperative network that critically regulates peptide dissociation from the class II molecule.

DM determines the cryptic and immunodominant fate of T cell epitopes.

The ability of the immune system to focus T cell responses against a select number of potential epitopes of a complex antigen is termed immunodominance. Epitopes that trigger potent T cell activation, after in vivo priming, are classified as immunodominant. By contrast, determinants that fail to elicit any response are called cryptic. DM, a major histocompatibility complex (MHC) heterodimer, plays a pivotal role in the presentation of MHC class II-restricted epitopes by catalyzing the exchange of class II-associated invariant chain peptide with the antigen-derived peptides within the MHC class II binding groove. Using L cells transfected with genes for MHC class II, invariant chain, and DM, we have studied the contribution of DM in the presentation of two cryptic (peptide 11-25 and peptide 20-35) and one dominant (peptide 106-116) epitope of hen egg white lysozyme (HEL). Cells lacking DM heterodimers efficiently display the determinants HEL 11-25 and HEL 20-35 to T cells. Strikingly, however, cells expressing DM are severely compromised in their ability to present the cryptic HEL 11-25/A(d) and 20-35/A(d) epitopes. DM-mediated antagonism of HEL 11-25/A(d) and 20-35/A(d) presentation could thus be central to 11-25/A(d) and 20-35/A(d) being cryptic epitopes in the HEL system. Interestingly, the display of the immunodominant epitope of HEL, 106-116/E(d), and of a dominant epitope of sperm whale myoglobin (SWM), 102-118/A(d), is entirely dependent on the expression of DM. Thus, cells lacking DM molecules are unable to efficiently express HEL 106-116/E(d) and SWM 102-118/A(d) determinants. We conclude that the DM heterodimers direct the immunodominant and cryptic fate of antigenic epitopes in vivo.

The MHC class II molecule I-Ag7 exists in alternate conformations that are peptide dependent.

Insulin-dependent diabetes mellitus is an autoimmune disease that is genetically linked to the HLA class II molecule DQ in humans and to MHC I-Ag7 in nonobese diabetic mice. The I-Ag7 beta-chain is unique and contains multiple polymorphisms, at least one of which is shared with DQ alleles linked to insulin-dependent diabetes mellitus. This polymorphism occurs at position 57 in the beta-chain, in which aspartic acid is mutated to a serine, a change that results in the loss of an interchain salt bridge between alphaArg76 and betaAsp57 at the periphery of the peptide binding groove. Using mAbs we have identified alternative conformations of I-Ag7 class II molecules. By using an invariant chain construct with various peptides engineered into the class II-associated invariant chain peptide (CLIP) region we have found that formation of these conformations is dependent on the peptide occupying the binding groove. Blocking studies with these Abs indicate that these conformations are present at the cell surface and are capable of interactions with TCRs that result in T cell activation.

Ovalbumin(323-339) peptide binds to the major histocompatibility complex class II I-A(d) protein using two functionally distinct registers.

Proteins of the class II major histocompatibility complex (MHC) bind antigenic peptides that are subsequently presented to T cells. Previous studies have shown that most of the residues required for binding of the chicken ovalbumin (Ova) 323-339 peptide to the I-A(d) MHC class II protein are contained within the shorter 325-336 peptide. This observation is somewhat inconsistent with the X-ray structure of the Ova peptide covalently attached to I-A(d) ( structure) in which residues 323 and 324 form binding interactions with the protein. A second register for the Ova(325-336) peptide is proposed where residues 326 and 327 occupy positions similar to residues 323 and 324 in the structure. Two Ova peptides that minimally encompass the and alternate registers, Ova(323-335) and Ova(325-336), respectively, were found to dissociate from I-A(d) with distinct kinetics. The dissociation rates for both peptides were enhanced when the His81 residue of the MHC beta-chain was replaced with an asparagine. In the structure the betaH81 residue forms a hydrogen bond to the backbone carbonyl of I323. If the Ova(325-336) peptide were also bound in the register, there would be no comparable hydrogen-bond acceptor for the betaH81 side chain that could explain this peptide's sensitivity to the betaH81 replacement. The Ova(323-335) peptide that binds in the register does not stimulate a T-cell hybridoma that is stimulated by Ova(325-336) bound in the alternate register. These results demonstrate that a single peptide can bind to an MHC peptide in alternate registers producing distinct T-cell responses.

Deviant trafficking of I-Ad mutant molecules is reflected in their peptide binding properties.

I-Ad molecules harboring single amino acid changes in the conserved 80-82 region of the beta-chain show altered trafficking in invariant chain (Ii)-negative cell lines. Since residues beta81 and beta82 form hydrogen bonds with the backbone of bound peptide, alterations in this region may result in distinct MHC class II conformers that are targeted aberrantly. We examined the assembly and peptide binding properties of the mutant I-Ad molecules generated by in vitro translation. Indeed, loss of a single hydrogen bond at beta81, or of two hydrogen bonds at beta82, is sufficient to render I-Ad incapable of stable interaction with CLIP and other antigenic peptides, despite normal assembly with intact invariant chain. These results suggest that stable interaction of MHC class II molecules with peptide requires the integrity of the H-bond network between residues in the MHC class II alpha-helices and bound peptide, and that conformational features revealed by stable peptide binding are critical for MHC class II intracellular transport.

Cutting edge: a single, essential hydrogen bond controls the stability of peptide-MHC class II complexes.

The binding of peptides to MHC class II molecules is mediated in part by a conserved array of intermolecular hydrogen bonds. We have evaluated the consequences of disrupting the hydrogen bond between beta-His-81 of the class II molecule and bound peptide. These studies revealed that peptide dissociation rates were accelerated by factors ranging to 200-fold. The sensitivity of a peptide to loss of the hydrogen bond is inversely correlated with the inherent kinetic stability of the peptide-MHC complex. The same relationship has been observed between inherent kinetic stability and the susceptibility to DM. Given that the rate enhancement observed for MHC class II I-Ad protein mutated at position 81 in the beta-chain is comparable with DM-catalyzed rates for other class II molecules, we suggest that DM could function by stabilizing a peptide-MHC intermediate in which one or more hydrogen bonds between the peptide and MHC, such as that contributed by the beta-His-81 hydrogen bond, are disrupted.

Ig alpha and Ig beta are required for efficient trafficking to late endosomes and to enhance antigen presentation.

The B cell Ag receptor (BCR) is a multimeric complex, containing Ig alpha and Ig beta, capable of internalizing and delivering specific Ags to specialized late endosomes, where they are processed into peptides for loading onto MHC class II molecules. By this mechanism, the presentation of receptor-selected epitopes to T cells is enhanced by several orders of magnitude. Previously, it has been reported that, under some circumstances, either Ig alpha or Ig beta can facilitate the presentation of Ags. However, we now demonstrate that if these Ags are at low concentrations and temporally restricted, both Ig alpha and Ig beta are required. When compared with the BCR, chimeric complexes containing either chain alone were internalized but failed to access the MHC class II-enriched compartment (MIIC) or induce the aggregation and fusion of its constituent vesicles. Furthermore, Ig alpha/Ig beta complexes in which the immunoreceptor tyrosine-based activation motif tyrosines of Ig alpha were mutated were also incapable of accessing the MIIC or of facilitating the presentation of Ag. These data indicate that both Ig alpha and Ig beta contribute signaling, and possibly other functions, to the BCR that are necessary and sufficient to reconstitute the trafficking and Ag-processing enhancing capacities of the intact receptor complex.

Individual hydrogen bonds play a critical role in MHC class II: peptide interactions: implications for the dynamic aspects of class II trafficking and DM-mediated peptide exchange.

Determination of the crystal structure of class II: peptide complexes has shown that in addition to pocket interactions involving the side chains of the peptide, peptide binding to MHC class II molecules is characterized by a series of hydrogen bonds which are contributed by genetically conserved amino acid residues in the class II molecule to the main chain of the peptide. Our experiments have revealed an unexpectedly large contribution of hydrogen bonds at the periphery of the MHC peptide binding pocket to MHC class II function. Kinetic studies have shown that peptide dissociation rates are profoundly accelerated by loss of a single hydrogen bonding residue. The magnitude of the effects seen with the loss in potential for a single hydrogen bond support a co-operative model in which individual bonds between class II and peptide are dependent on the integrity of neighboring interactions. Collectively our studies have revealed that MHC class II structure, peptide binding and intracellular trafficking events are critically dependent on the integrity of the hydrogen bonding network between class II molecules and its bound peptide.

Alteration of a single hydrogen bond between class II molecules and peptide results in rapid degradation of class II molecules after invariant chain removal.

To characterize the importance of a highly conserved region of the class II beta chain, we introduced an amino acid substitution that is predicted to eliminate a hydrogen bond formed between the class II molecule and peptide. We expressed the mutated beta chain with a wild-type alpha chain in a murine L cell by gene transfection. The mutant class II molecule (81betaH-) assembles normally in the endoplasmic reticulum and transits the Golgi complex. When invariant chain (Ii) is coexpressed with 81betaH-, the class II-Ii complex is degraded in the endosomes. Expression of 81betaH- in the absence of Ii results in a cell surface expressed molecule that is susceptible to proteolysis, a condition reversed by incubation with a peptide known to associate with 81betaH-. We propose that 81betaH- is protease sensitive because it is unable to productively associate with most peptides, including classII-associated invariant chain peptides. This model is supported by our data demonstrating protease sensitivity of peptide-free wild-type I-Ad molecules. Collectively, our results suggest both that the hydrogen bonds formed between the class II molecule and peptide are important for the integrity and stability of the complex, and that empty class II molecules are protease sensitive and degraded in endosomes. One function of DM may be to insure continuous groove occupancy of the class II molecule.

The inability of the nonobese diabetic class II molecule to form stable peptide complexes does not reflect a failure to interact productively with DM.

Sequence variability in MHC class II molecules plays a major role in genetically determined susceptibility to insulin-dependent diabetes mellitus (IDDM). It is not yet clear whether MHC class II polymorphism allows selective binding of diabetogenic peptides or regulates some key intracellular events associated with class II-restricted Ag presentation. In this study, we have employed gene transfer techniques to analyze the intracellular events that control peptide acquisition by the unique class II molecule expressed by nonobese diabetic mice (I-Ag7). This structurally unique class II molecule fails to demonstrate stable binding to antigenic peptides and fails to undergo the conformational change associated with stable peptide binding to class II molecules. The experiments reported here demonstrate that I-Ag7 can productively associate with two protein cofactors important in class II-restricted Ag presentation, invariant chain (Ii) and DM. DM participates in the removal of the Ii-derived class II-associated Ii chain peptide and the p12 degradation product from the I-Ag7 molecule. In addition, I-Ag7 undergoes a conformational change when DM is expressed within the APC. Finally, DM can mediate accumulation of peptide/class II complexes on the surface of APCs. Collectively, our experiments indicate that the failure of the I-Ag7 molecule to stably bind peptide cannot be attributed to a failure to interact with the DM or Ii glycoproteins.

Late events in the intracellular sorting of major histocompatibility complex class II molecules are regulated by the 80-82 segment of the class II beta chain.

The molecular mechanisms that regulate sorting of major histocompatibility complex (MHC) class II molecules into the endocytic pathway are poorly understood. For many proteins, access to endosomal compartments is regulated by cytosolically expressed sequences. We present evidence that a sequence in the lumenal domain of the MHC class II molecule regulates a very late event in class II biogenesis. Class II molecules containing single amino acid changes in the highly conserved 80-82 region of the beta chain were introduced into invariant chain (Ii)-negative fibroblasts with wild-type alpha chain, and the derived transfectants were analyzed biochemically. Using an endosomal isolation technique, we have quantified the level of class II molecules expressed in endocytic compartments and found that in the absence of Ii, approximately 15% of total cellular class II molecules can be isolated from endosomal compartments. Mutation at position 80 enhances this localization, while changes at positions 81 and 82 ablate class II expression in endosomal compartments. In addition, we have evaluated whether the induced changes in intracellular distribution of class II molecules were due to alterations in early biosynthetic events, indicative of misfolding of the molecules, or to modulation of later trafficking events more likely to be a consequence of the modulation of a specific transport event. Despite the dramatic effects on endosomal localization induced by the mutations, early biosynthetic events and maturation of class II were unaffected by the mutations. Collectively, our data argue that late trafficking events that control the ability of the class II molecule to access antigens is regulated by the 80-82 segment of the MHC class II beta chains.

DM-mediated release of a naturally occurring invariant chain degradation intermediate from MHC class II molecules.

The nonpolymorphic, nonclassical class II molecule DM has been shown to be important in the processing and presentation of antigenic epitopes by MHC class II molecules. The dependence of class II molecules on the coexpression of DM varies with the particular allele or epitope studied. In an effort to resolve disparities that exist for some alleles of class II in their requirements for DM, we have constructed a species-matched murine transfection model with which we can test both the functional and biochemical consequences of DM expression for different alleles of murine class II. When we evaluated the ability of class II molecules to form SDS-stable dimer and release CLIP, we find that while I-A(d) requires DM for the formation of SDS-stable dimers and the release of CLIP, I-A(k) is capable of both SDS-stable dimer formation and CLIP release in the absence of DM. Despite the apparent differences in the biochemical consequences of DM expression for I-A(d) and I-A(k), we find that Ag presentation by both alleles can be enhanced by the expression of DM. Interestingly, we find that DM can facilitate the removal of a natural intermediate in Ii processing (p12). The ability of DM to catalyze the dissociation of p12 and possibly larger Ii fragments from class II in vivo offers a possible mechanism to account for the observed DM enhancement of Ag presentation for alleles that have a low affinity for CLIP. Our findings indicate that DM may function in multiple compartments and on multiple class II/Ii substrates.

Invariant chain and DM edit self-peptide presentation by major histocompatibility complex (MHC) class II molecules.

We have studied the consequences of invariant chain (Ii) and DM expression on major histocompatibility complex (MHC) class II function. Ii has a number of discrete functions in the biology of class II, including competitive blocking of peptide binding in the endoplasmic reticulum and enhancing localization in the endocytic compartments. DM is thought to act primarily in endosomes to promote dissociation of the Ii-derived (CLIP) peptide from the class II antigen-binding pocket and subsequent peptide loading. In this study, we have evaluated the functional role of Ii and DM by examining their impact on surface expression of epitopes recognized by a large panel of alloreactive T cells. We find most epitopes studied are influenced by both Ii and DM. Most strikingly, we find that surface expression of a significant fraction of peptide-class II complexes is extinguished, rather than enhanced, by DM expression within the APC. The epitopes antagonized by DM do not appear to be specific for CLIP. Finally, we found that DM was also able to extinguish recognition of a defined peptide derived from the internally synthesized H-2Ld protein. Thus, rather than primarily serving in the removal of CLIP, DM may have a more generalized function of editing the array of peptides that are presented by class II. This editing can be either positive or negative, suggesting that DM plays a specifying role in the display of peptides presented to CD4 T cells.

The function of invariant chain in class II-restricted antigen presentation.

The role of invariant chain (Ii) in antigen presentation has been studied using two independent approaches. The first was to reconstitute cell lines with class II molecules and various forms of the Ii; the second has been to generate mice that lack functional expression of the Ii gene (Ii.). Both types of studies show that Ii facilitates assembly of class II molecules in the endoplasmic reticulum (ER), chaperones or retains properly folded class II complexes through endosomal compartments, and finally, serves as a T-cell ligand. How Ii facilitates assembly of antigenic class II-peptide complexes is less clear and seems to depend on a number of factors reviewed here: the antigen and epitope studied; the route and dose by which antigen is administered; the form of Ii present; and the responding T cell used in the experiment. During assembly of the class II-peptide complex, Ii may facilitate this process in a number of ways: specifically, by increasing the amount of class II available in endosomal vesicles; changing access or retention of class II molecules in the endosomal pathway; facilitating peptide exchange during CLIP dissociation, or finally, by modulating the antigen processing environment in the cell. In summary, we propose that instead of playing just one role in assembling the class II-peptide complex, Ii may perform all of the above described activities, functioning in different capacities along the pathway of antigen presentation.

Identification of a unique costimulatory activity for murine T helper 1 T cell clones.

We have examined the ability of several class II-positive tumor cell transfectants to stimulate murine Th1 clones. Most of the transfectants failed to activate the Th1 clones and, in fact, induced Ag-specific anergy. However, we found that one tumor, a UV-induced fibrosarcoma (6130-VAR1), was capable of stimulating both cytokine production and proliferation in Th1 clones. We believe that 6130-VAR1 cells possess a unique costimulatory activity for the following reasons. First, these cells fail to express known costimulatory molecules including B7-1 and B7-2. Second, 6130-VAR1-mediated stimulation of Th1 clones was not blocked by anti-CD28 Fab or by CTLA4Ig, which suggests that members of the B7 family were not up-regulated during the course of stimulation and that activation does not occur via a CD28-dependent pathway. Third, 6130-VAR1 could provide costimulation when presented on a different surface than the class II/peptide ligand for the TCR. This last finding suggested that the activity on these cells was not simply an adhesion molecule that facilitated increased efficiency of T cell:MHC interactions. Finally, like B7-1 transfectants, stimulation by class II-positive 6130-VAR1 cells prevented the induction of anergy in the Th1 clones. Taken together, these results strongly suggest that 6130-VAR1 expresses a unique costimulatory activity (VAM-1) that, like B7-1, can promote T cell activation and prevent anergy induction.

In the absence of major histocompatibility complex class II molecules, invariant chain is translocated to late endocytic compartments by autophagy.

It has been suggested that the cytoplasmic amino-terminal tail of invariant chain (Ii) contains a sorting signal that directs trafficking of the major histocompatibility complex (MHC) class II: Ii oligomeric complex to endocytic compartments. This model is based, in part, on the observation that in the absence of MHC class II molecules, Ii is detectable in lysosomal structures, a phenotype that is dependent on an intact NH2 terminus. However, the route by which Ii gains access to endosomal compartments in the absence of class II molecules remains uncertain. Here we report a mechanism that localizes Ii in lysosomal compartments independently of class II. We show that murine Ii can be detected by immunofluorescence within late endocytic compartments of stably transfected Ltk- mouse fibroblasts. Immunochemical studies indicate that degradation of Ii in these cells is sensitive to the lysosomotropic agent ammonium chloride, yet the majority of Ii that undergoes this apparent lysosomal degradation is sensitive to the enzyme endoglycosidase H. This finding suggests that Ii may reach the lysosomal compartment by a route that bypasses the Golgi complex. Consistent with this possibility, we found that in contrast to Ii which is complexed to class II molecules, transport of free Ii to lysosomes is prevented by 3-methyladenine, an inhibitor of the autophagic pathway of protein degradation, a process which involves direct transport from the endoplasmic reticulum to lysosomes. These data suggest the route of transport that leads to endosomal localization of Ii in the absence of class II is distinct from that taken when expressed with class II. This forces a re-evaluation of the concept that the cytosolic tail of Ii contains a dominant Golgi-to-endosomal sorting signal.

The requirement for DM in class II-restricted antigen presentation and SDS-stable dimer formation is allele and species dependent.

Recently several cell lines have been identified with mutations in a major histocompatibility complex (MHC)-linked protein that lead to defects in class II-restricted antigen presentation and a defect in the formation of class II SDS-stable dimers. The defect in these cells has recently been shown to result from the inability to express the MHC-encoded nonclassical class II molecule called DM. To further examine the role of DM in class II-restricted antigen presentation, we asked if this defect would equally affect different allelic and species variants of class II molecules. To investigate this, we transfected the parent cell lines T1 and 8.1.6 and their respective antigen presentation mutants T2 and 9.5.3 with the genes encoding I-Ad and examined the derived transfectants for their ability to present antigen, the conformation of I-Ad at the cell surface, association of I-Ad with invariant chain (Ii), and the ability to form I-Ad SDS-stable dimers. The lack of functional DM expression did not affect any of the anti-I-Ad monoclonal antibody (mAb) epitopes tested or the ability of I-Ad to associate and dissociate with Ii. Surprisingly, these studies also revealed that the antigen presentation defect observed for DR in the 9.5.3 cells did not compromise I-Ad-restricted antigen presentation. In addition, we found that the level of SDS-stable dimer formation did not correlate with antigen presentation capacity for I-Ad and that the amount of SDS-stable I-Ad dimer depends on the cellular context in which the class II molecule is expressed. Our results suggest that the ability to form SDS-stable dimer is not strictly correlated with class II-restricted antigen presentation. Finally, when two allelic forms of murine class II molecules were compared in the defective T2 cell line, it was found that I-Ak but not I-Ad forms SDS-stable dimers equivalent to that seen in the parental cell lines. Overall, our results suggest that DM may modulate rather than play a requisite role in I-Ad-restricted antigen presentation and SDS-stable dimer formation and that dependency on DM may be allele or species specific.

A segment of the MHC class II beta chain plays a critical role in targeting class II molecules to the endocytic pathway.

The ability of MHC class II molecules to sort into the endocytic pathway has generally been attributed to the invariant chain glycoprotein. In this paper, we present evidence suggesting that lumenal sequences in the MHC class II molecule itself control the post-Golgi entry of class II into endosomes. Single amino acid changes have been introduced into a highly conserved region of the class II beta chain (amino acids 80-83). Mutant class II beta chain genes and wild-type alpha chain genes have been transfected into cells that lack both class II and invariant chain expression. Immunofluorescent staining of transfected cells indicates that single amino acid changes in this region of beta can positively or negatively modulate expression of class II in endocytic vesicles independently of invariant chain. Mutation at residue 80 leads to prominent localization in vesicular structures typical of late endocytic compartments, while a change at position 82 leads to arrest in the Golgi. These data argue in favor of the possibility that MHC class II molecules bear a sorting signal that allows access to MHC class II molecules into the endocytic pathway of antigen presenting cells.

T cell receptor recognition of MHC class II alloantigens is highly cell type dependent.

According to some models of T cell education, tolerance, and autoimmunity, recognition of MHC molecules by T cells may depend on the nature of the APC expressing the MHC/Ag complex. To examine this, a panel of 23 I-Ad-restricted, alloreactive T cells were used to probe MHC class II molecules expressed on established lines representing different lineages. Surprisingly, we observed cell type-specific reactivity in the majority of the T cells. In all, 18 different reactivity patterns were identified. The patterns observed suggests that MHC reactivity can be organized into a hierarchical pattern for both the APC and the T cells. Experiments assessing T cells' avidities for allogeneic targets, ability to produce lymphokines, and expression of accessory molecules revealed no predictive correlation with the hierarchical reactivity pattern, nor did experiments measuring allogeneic target cells' expression of known accessory molecules and ability to stimulate Ag-specific hybridomas. These results suggest that the differential reactivity cannot be accounted for by accessory molecule discrepancies among the APC, but rather might reflect deficiencies in the ability of the various APC to engage the Ag-specific T cell receptor. Collectively, these data indicate that a significant fraction of allorecognition of MHC class II is cell-type dependent and that cell-type-specific recognition may relate to peptide-specific recognition requirements by the Ag receptor of alloreactive T cells.