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

For many but not for all: how the conformational flexibility of the peptide/MHCII complex shapes epitope selection

The adaptive immune response starts when CD4+ T cells recognize peptide antigens presented by class II molecules of the Major Histocompatibility Complex (MHCII). Two outstanding features of MHCII molecules are their polymorphism and the ability of each allele to bind a large panoply of peptides. The ability of each MHCII molecule to interact with a limited, though broad, range of amino acid sequences, or "permissive specificity" of binding, is the result of structural flexibility. This flexibility has been identified through biochemical and biophysical studies, and molecular dynamic simulations have modeled the conformational rearrangements that the peptide and the MHCII undergo during interaction. Moreover, there is evidence that the structural flexibility of the peptide/MHCII complex correlates with the activity of the "peptide-editing" molecule DM. In light of the impact that these recent findings have on our ability to predict MHCII epitopes, a review of the structural and thermodynamic determinants of peptide binding to MHCII is proposed.

Characterization of structural features controlling the receptiveness of empty class II MHC molecules

MHC class II molecules (MHC II) play a pivotal role in the cell-surface presentation of antigens for surveillance by T cells. Antigen loading takes place inside the cell in endosomal compartments and loss of the peptide ligand rapidly leads to the formation of a non-receptive state of the MHC molecule. Non-receptiveness hinders the efficient loading of new antigens onto the empty MHC II. However, the mechanisms driving the formation of the peptide inaccessible state are not well understood. Here, a combined approach of experimental site-directed mutagenesis and computational modeling is used to reveal structural features underlying “non-receptiveness.” Molecular dynamics simulations of the human MHC II HLA-DR1 suggest a straightening of the α-helix of the β1 domain during the transition from the open to the non-receptive state. The movement is mostly confined to a hinge region conserved in all known MHC molecules. This shift causes a narrowing of the two helices flanking the binding site and results in a closure, which is further stabilized by the formation of a critical hydrogen bond between residues αQ9 and βN82. Mutagenesis experiments confirmed that replacement of either one of the two residues by alanine renders the protein highly susceptible. Notably, loading enhancement was also observed when the mutated MHC II molecules were expressed on the surface of fibroblast cells. Altogether, structural features underlying the non-receptive state of empty HLA-DR1 identified by theoretical means and experiments revealed highly conserved residues critically involved in the receptiveness of MHC II. The atomic details of rearrangements of the peptide-binding groove upon peptide loss provide insight into structure and dynamics of empty MHC II molecules and may foster rational approaches to interfere with non-receptiveness. Manipulation of peptide loading efficiency for improved peptide vaccination strategies could be one of the applications profiting from the structural knowledge provided by this study.

The relative energetic contributions of dominant P1 pocket versus hydrogen bonding interactions to peptide:class II stability: implications for the mechanism of DM function

Peptides are bound to MHC class II molecules by an array of hydrogen bonds between conserved MHC class II protein side-chains and the peptide backbone and through interactions between MHC protein pockets and peptide side-chain anchors. The crystal structure of murine I-A(k) protein with peptide shows a network of electrostatic interactions with the P1 aspartic acid anchor and an arginine in the P1 pocket that are thought to constitute the major stabilizing interaction between peptide and MHC. In this paper, have explored the relative energetic contribution of this dominant P1 pocket interaction with that made by a genetically conserved hydrogen bond which is formed by the beta 81 histidine residue and the main chain of the bound peptide. We have performed peptide dissociation experiments using antigenic peptides or variants that have altered side-chain interactions with the I-A(k) P1 pocket using either native I-A(k) or I-A(k) proteins mutated to disrupt the N-terminal hydrogen bond. The results demonstrate that the N-terminal hydrogen bonds in I-A(k) complexes make highly significant energetic contributions to the kinetic stabilities comparable to or greater than the energetic contribution of highly favorable P1 pocket interactions. Hence, we conclude that the kinetic stability of MHC class II:peptide complexes critically depends on two quite distinct molecular interactions between peptide and MHC located at the peptide's amino terminus. We discuss these results in light of the proposed mechanism for DM function.

Role of the major histocompatibility complex class II transmembrane region in antigen presentation and intracellular trafficking

While a sorting signal in the cytoplasmic tail of the major histocompatibility complex (MHC) class II molecules is known to influence their endocytic transport, potential effects of the transmembrane (TM) domain of the MHC class II molecules on endocytic transport remain unclear. We have examined the role of the TM domain by comparing antigen-presenting functions of the wildtype (WT) I-Ab and mutant (MT) I-Ab molecule substituted in the beta-chain TM with alpha chain TM. A20 cells transfected with WT I-Ab were able to present antigen (hen egg lysozyme) better to some hybridomas, while those transfected with MT I-Ab consistently outperformed WT for other hybridomas recognizing different epitopes. This difference in antigen processing and presentation is not caused by the differences in H-2M (DM) requirement or association with Ii. The time required for processing of specific epitopes appears to be different, suggesting sequential involvement of various endocytic compartments in the antigen processing. Although both WT and MT molecules were found in the early endocytic (transferrin receptor-rich) compartments, MT molecules accumulated in these compartments in higher quantities for longer time periods. Similarly, the MT molecule is retained for a longer time period than WT in late endocytic (LAMP-1 associated) compartments. Together, our data indicate an important role of the TM domain of the MHC class II molecules in the intracellular trafficking and, consequently, antigen processing and presentation.

The transcytosis of divalent metal transporter 1 and apo-transferrin during iron uptake in intestinal epithelium

Caco-2 cells grown in bicameral chambers are a model system to study intestinal iron absorption. Caco-2 cells exhibit constitutive transport of iron from the apical (luminal) chamber to the basal (serosal) chamber that is enhanced by apo-transferrin in the basal chamber, with the apo-transferrin undergoing endocytosis to the apical portion of the cell. With the addition of iron to the apical surface, divalent metal transporter 1 (DMT1) on the brush-border membrane (BBM) undergoes endocytosis. These findings suggest that in Caco-2 cells DMT1 and apo-transferrin may cooperate in iron transport through transcytosis. To prove this hypothesis, we determined by confocal microscopy that, after addition of iron to the apical chamber, DMT1 from the BBM and Texas red apo-transferrin from the basal chamber colocalized in a perinuclear compartment. Colocalization was also observed by isolating endosomes from Caco-2 cells after ingestion of ultra-small paramagnetic particles from either the basal or apical chamber. The isolated endosomes contained both transferrin and DMT1 independent of the chamber from which the paramagnetic particles were endocytosed. These findings suggest that iron transport across intestinal epithelia may be mediated by transcytosis.

Binding interactions between peptides and proteins of the class II major histocompatibility complex

The activation of helper T cells by peptides bound to proteins of the class II Major Histocompatibility Complex (MHC II) is pivotal to the initiation of an immune response. The primary functional requirement imposed on MHC II proteins is the ability to efficiently bind thousands of different peptides. Structurally, this is reflected in a unique architecture of binding interactions. The peptide is bound in an extended conformation within a groove on the membrane distal surface of the protein that is lined with several pockets that can accommodate peptide side-chains. Conserved MHC II protein residues also form hydrogen bonds along the length of the peptide main-chain. Here we review recent advances in the study of peptide-MHC II protein reactions that have led to an enhanced understanding of binding energetics. These results demonstrate that peptide-MHC II protein complexes achieve high affinity binding from the array of hydrogen bonds that are energetically segregated from the pocket interactions, which can then add to an intrinsic hydrogen bond-mediated affinity. Thus, MHC II proteins are unlike antibodies, which utilize cooperativity among binding interactions to achieve high affinity and specificity. The significance of these observations is discussed within the context of possible mechanisms for the HLA-DM protein that regulates peptide presentation in vivo and the design of non-peptide molecules that can bind MHC II proteins and act as vaccines or immune modulators.

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.

Proteolysis in MHC class II antigen presentation: who's in charge?

Antigen-presenting cells (APC) degrade proteins intracellularly to generate peptides, which are then bound by products of the major histocompatibility complex (MHC) and exposed on the surface of the APC for recognition by T cells. The supply of antigenic peptides and their association with MHC molecules requires the concerted action of a cohort of accessory molecules that includes chaperones, transporters of peptides, and the proteases that degrade the antigens.

Determinants of the peptide-induced conformational change in the human class II major histocompatibility complex protein HLA-DR1

The human class II major histocompatibility complex protein HLA-DR1 has been shown previously to undergo a distinct conformational change from an open to a compact form upon binding peptide. To investigate the role of peptide in triggering the conformational change, the minimal requirements for inducing the compact conformation were determined. Peptides as short as two and four residues, which occupy only a small fraction of the peptide-binding cleft, were able to induce the conformational change. A mutant HLA-DR1 protein with a substitution in the beta subunit designed to fill the P1 pocket from within the protein (Gly(86) to Tyr) adopted to a large extent the compact, peptide-bound conformation. Interactions important in stabilizing the compact conformation are shown to be distinct from those responsible for high affinity binding or for stabilization of the complex against thermal denaturation. The results suggest that occupancy of the P1 pocket is responsible for partial conversion to the compact form but that both side chain and main chain interactions contribute to the full conformational change. The implications of the conformational change to intracellular antigen loading and presentation are discussed.

Intracellular traffic to compartments for MHC class II peptide loading: signals for endosomal and polarized sorting

In this review we focus on the traffic of MHC class II and endocytosed antigens to intracellular compartments where antigenic peptides are loaded. We also discuss briefly the nature of the peptide loading compartment and the sorting signals known to direct antigen receptors and MHC class II and associated molecules to this location. MHC class II molecules are expressed on a variety of polarized epithelial and endothelial cells, and polarized cells are thus potentially important for antigen presentation. Here we review some cell biological aspects of polarized sorting of MHC class II and the associated invariant chain and the signals that are involved in the sorting process to the basolateral domain. The molecules involved in sorting and loading of peptide may modulate antigen presentation, and in particular we discuss how invariant chain may change the cellular phenotype and the kinetics of the endosomal pathway.

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.

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 β-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 β-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 β-His-81 hydrogen bond, are disrupted.

Polarized Transport of MHC Class II Molecules in Madin-Darby Canine Kidney Cells Is Directed by a Leucine-Based Signal in the Cytoplasmic Tail of the β-Chain

MHC class II molecules are found on the basolateral plasma membrane domain of polarized epithelial cells, where they can present Ag to intraepithelial lymphocytes in the vascular space. We have analyzed the sorting information required for efficient intracellular localization and polarized distribution of MHC class II molecules in stably transfected Madin-Darby canine kidney cells. These cells were able to present influenza virus particles to HLA-DR1-restricted T cell clones. Wild-type MHC class II molecules were located on the basolateral plasma membrane domain, in basolateral early endosomes, and in late multivesicular endosomes, the latter also containing the MHC class II-associated invariant chain and an HLA-DM fusion protein. A phenylalanine-leucine residue within the cytoplasmic tail of the β-chain was required for basolateral distribution, efficient internalization, and localization of the MHC class II molecules to basolateral early endosomes. However, distribution to apically located, late multivesicular endosomes did not depend on signals in the class II cytoplasmic tails as both wild-type class II molecules and mutant molecules lacking the phenylalanine-leucine motif were found in these compartments. Our results demonstrate that sorting information in the tails of class II dimers is an absolute requirement for their basolateral surface distribution and intracellular localization.

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.

HLA-DM can partially replace the invariant chain for HLA-DR transport and surface expression in transfected endocrine epithelial cells

The function of HLA class II molecules as peptide presenters to CD4+ T cells depends on the expression of associated molecules such as the invariant chain (Ii) and DM responsible for the correct transport of and high-stability peptide binding to the class II dimers. In organs affected by autoimmune diseases, endocrine epithelial cells express class II molecules, which presumably are involved in the presentation of self-peptides to autoreactive T cells. We have transfected the rat insulinoma cell line RINm5F with different combinations of HLA-DR, Ii and HLA-DM cDNAs and have studied how Ii and DM affect the transport and stability of class II molecules expressed by the different transfectants. Immunofluorescence and biochemical analysis showed that cells transfected with DR and DM in the absence of Ii expressed mostly stable molecules in their surface, and showed a lower accumulation of DR molecules in the endoplasmic reticulum (ER) than cells expressing only DR. This suggests that, in the absence of invariant chain, DM molecules can not only exchange peptides other than class II-associated invariant chain peptide (CLIP) but may also be involved in the transport of class II molecules out of the ER towards the endosomal route. In addition, these data confirm that expression of DR alone or DR+Ii do not allow the formation of sodium dodecyl sulphate (SDS)-stable complexes, that cells expressing DR+Ii have most DR molecules occupied by CLIP and that Ii and DM molecules allow regular routing and peptide loading of class II molecules.

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.

MHC Class II Transport from Lysosomal Compartments to the Cell Surface Is Determined by Stable Peptide Binding, But Not by the Cytosolic Domains of the α- and β-Chains

Inside APCs, MHC class II molecules associate with antigenic peptides before reaching the cell surface. This association takes place in compartments of the endocytic pathway, more related to endosomes or lysosomes depending on the cell type. Here, we compared MHC class II transport from endosomal vs lysosomal compartments to the plasma membrane. We show that transport of MHC class II molecules to the cell surface does not depend on the cytosolic domains of the α- and β-chains. In contrast, the stability of the αβ-peptide complexes determined the efficiency of transport to the cell surface from lysosomal, but not from endosomal, compartments. In murine B lymphoma cells, SDS-unstable and -stable complexes were transported to the cell surface at almost similar rates, whereas after lysosomal relocalization or in a cell line in which MHC class II molecules normally accumulate in lysosomal compartments, stable complexes were preferentially addressed to the cell surface. Our results suggest that when peptide loading occurs in lysosomal compartments, selective retention and lysosomal degradation of unstable dimers result in the expression of highly stable MHC class II-peptide complexes at the APC surface.