Functional significance of tapasin membrane association and disulfide linkage to ERp57 in MHC class I presentation

Tapasin is disulfide linked to ERp57 within the peptide loading complex. In cell‐free assays, a soluble variant of the tapasin/ERp57 dimer recruits MHC class I molecules and promotes peptide binding to them, whereas soluble tapasin alone does not. Here we show that within cells, tapasin conjugation with ERp57 is as critical as its integration into the membrane for efficient MHC class I assembly, surface expression, and Ag presentation to CD8⁺ T cells. Elimination of both of these properties severely compromises tapasin function, in keeping with predictions from in vitro studies.     

Disulfide bond isomerization and the assembly of MHC class I-peptide complexes

The presence of a disulfide bond inside the peptide binding groove of MHC class I molecules and of the thiol oxidoreductase ERp57 in the class I loading complex suggests that disulfide bond isomerization may play a role in peptide loading. Here we show that ERp57 and tapasin are disulfide linked inside the loading complex. Mutagenesis of cysteine 95 in tapasin not only abolishes formation of the ERp57-tapasin bond but also prevents complete oxidation of the class I heavy chain in the loading complex. The resulting MHC class I-beta2m heterodimers are poorly loaded with high-affinity peptides in the ER but nevertheless escape to the cell surface where they are unstable. These findings suggest a role for disulfide bond isomerization in tapasin-mediated peptide loading.     

Redox regulation of peptide receptivity of major histocompatibility complex class I molecules by ERp57 and tapasin

The function of the oxidoreductase ERp57 in the major histocompatibility complex (MHC) class I peptide-loading complex has remained elusive. Here we show that in the absence of tapasin, the alpha2 disulfide bond in the MHC class I peptide-binding groove was rapidly reduced. Covalent sequestration of ERp57 by tapasin was needed to protect the alpha2 disulfide bond against reduction and thus to maintain the binding groove in a peptide-receptive state. Allelic variations in MHC class I tapasin dependency reflected their susceptibility to reduction of the alpha2 disulfide bond. In the absence of sequestration, ERp57 acted directly on the alpha2 disulfide bond. Our work provides insight into how the immune system customizes 'quality control' in the endoplasmic reticulum to fit the needs of antigen presentation.     

What is the role of alternate splicing in antigen presentation by major histocompatibility complex class I molecules?

The expression of major histocompatibility complex (MHC) class I molecules on the cell surface is critical for recognition by cytotoxic T lymphocytes (CTL). This recognition event leads to destruction of cells displaying MHC class I—viral peptide complexes or cells displaying MHC class I—mutant peptide complexes. Before they can be transported to the cell surface, MHC class I molecules must associate with their peptide ligand in the endoplasmic reticulum (ER) of the cell. Within the ER, numerous proteins assist in the appropriate assembly and folding of MHC class I molecules. These include the heterodimeric transporter associated with antigen processing (TAP1 and TAP2), the heterodimeric chaperone-oxidoreductase complex of tapasin and ERp57 and the general ER chaperones calreticulin and calnexin. Each of these accessory proteins has a well-defined role in antigen presentation by MHC class I molecules. However, alternate splice forms of MHC class I heavy chains, TAP and tapasin, have been reported suggesting additional complexity to the picture of antigen presentation. Here, we review the importance of these different accessory proteins and the progress in our understanding of alternate splicing in antigen presentation.     

The optimization of peptide cargo bound to MHC class I molecules by the peptide-loading complex

Summary: Major histocompatibility complex (MHC) class I complexes present peptides from both self and foreign intracellular proteins on the surface of most nucleated cells. The assembled heterotrimeric complexes consist of a polymorphic glycosylated heavy chain, non‐polymorphic β₂ microglobulin, and a peptide of typically nine amino acids in length. Assembly of the class I complexes occurs in the endoplasmic reticulum and is assisted by a number of chaperone molecules. A multimolecular unit termed the peptide‐loading complex (PLC) is integral to this process. The PLC contains a peptide transporter (transporter associated with antigen processing), a thiooxido‐reductase (ERp57), a glycoprotein chaperone (calreticulin), and tapasin, a class I‐specific chaperone. We suggest that class I assembly involves a process of optimization where the peptide cargo of the complex is edited by the PLC. Furthermore, this selective peptide loading is biased toward peptides that have a longer off‐rate from the assembled complex. We suggest that tapasin is the key chaperone that directs this action of the PLC with secondary contributions from calreticulin and possibly ERp57. We provide a framework model for how this may operate at the molecular level and draw parallels with the proposed mechanism of action of human leukocyte antigen‐DM for MHC class II complex optimization.     

Assembly of MHC class I molecules within the endoplasmic reticulum

MHC class I molecules bind cytosolically derived peptides within the endoplasmic reticulum (ER) and present them at the cell surface to cytotoxic T cells. A major focus of our laboratory has been to understand the functions of the diverse proteins involved in the intracellular assembly of MHC class I molecules. These include the molecular chaperones calnexin and calreticulin, which enhance the proper folding and subunit assembly of class I molecules and also retain assembly intermediates within the ER; ERp57, a thiol oxidoreductase that promotes heavy chain disulfide formation and proper assembly of the peptide loading complex; tapasin, which recruits class I molecules to the TAP peptide transporter and enhances the loading of high affinity peptide ligands; and Bap31, which is involved in clustering assembled class I molecules at ER exit sites for export along the secretory pathway. This review describes our contributions to elucidating the functions of these proteins; the combined effort of many dedicated students and postdoctoral fellows.     

The murine gamma-herpesvirus-68 MK3 protein causes TAP degradation independent of MHC class I heavy chain degradation

The murine gamma-herpesvirus-68 MK3 protein has an intricate interaction with the peptide loading complex that involves MK3 stabilization, a rapid degradation of MHC class I heavy chains, and a slower degradation of TAP. Here we have used tapasin chimeras to distinguish functionally the different immune evasion mechanisms of MK3. Tapasin was cloned in two alternatively spliced forms that differed by a single transmembrane valine residue. Each restored antigen presentation and MK3 function in tapasin-deficient cells. The transmembrane/cytoplasmic portion of tapasin, linked to the extracellular domain of CD8, also restored TAP stability and MK3 stability in tapasin-deficient cells. MK3 did not associate with or degrade MHC class I in these cells, which lacked the endoplasmic reticulum domain of tapasin, but degraded TAP at least as efficiently as when full-length tapasin was present. The un-degraded MHC class I consequently showed impaired maturation. The fact that MK3 required intact tapasin to degrade MHC class I but only the transmembrane/cytoplasmic portion of tapasin to degrade TAP indicated that these two immune evasion functions operate independently.     

Disulfide bridge disruption in the alpha2 domain of the HLA class I molecule leads to low expression of the corresponding antigen

Using sequence-based typing, we have identified a novel human leukocyte antigen (HLA)-A*30 allele, HLA-A*3014L, with a low expression pattern. The sequence of HLA-A*3014L is identical to that of HLA-A*3001 except for a G to C substitution in exon 3 at nucleotide position 563, resulting in an amino acid difference at position 164 (Cys to Ser). Due to the cysteine substitution, a disulfide bridge in the alpha2 domain of the HLA class I heavy chain cannot be formed. By using the standard microlymphocytotoxicity test, the HLA-A30 antigen cannot be detected. By flow cytometric analysis of the cell-surface expression at either 37 degrees C or 30 degrees C, a temperature-sensitive expression pattern of the HLA-A*3014L antigen was observed. Only by incubating the cells at 30 degrees C, which increases the stability of HLA class I heavy chains, was a weak but clearly detectable HLA-A*3014L expression found. The mRNA expression level of the HLA-A*3014L allele was not affected by the nucleotide substitution. The intrachain disulfide bond formation in the alpha2 domain is essential for the normal expression of the HLA molecules. Reduced protein expression is probably caused by incorrect HLA class I heavy chain folding and HLA class I complex assembly.     

Stoichiometric tapasin interactions in the catalysis of major histocompatibility complex class I molecule assembly

The assembly of major histocompatibility complex (MHC) class I molecules with their peptide ligands in the endoplasmic reticulum (ER) requires the assistance of many proteins that form a multimolecular assemblage termed the 'peptide-loading complex'. Tapasin is the central stabilizer of this complex, which also includes the transporter associated with antigen processing (TAP), MHC class I molecules, the ER chaperone, calreticulin, and the thiol-oxidoreductase ERp57. In the present report, we investigated the requirements of these interactions for tapasin protein stability and MHC class I dissociation from the peptide-loading complex. We established that tapasin is stable in the absence of either TAP or MHC class I interaction. In the absence of TAP, tapasin interaction with MHC class I molecules is long-lived and results in the sequestration of existing tapasin molecules. In contrast, in TAP-sufficient cells, tapasin is re-utilized to interact with and facilitate the assembly of many MHC class I molecules sequentially. Furthermore, chemical cross-linking has been utilized to characterize the interactions within this complex. We demonstrate that tapasin and MHC class I molecules exist in a 1 : 1 complex without evidence of higher-order tapasin multimers. Together these studies shed light on the tapasin protein life cycle and how it functions in MHC class I assembly with peptide for presentation to CD8(+) T cells.     

Differential contribution of TAP and tapasin to HLA class I antigen expression

Expression of class I human leucocyte antigens (HLA) on the surface of malignant cells is critical for their recognition and destruction by cytotoxic T lymphocytes. Surface expression requires assembly and folding of HLA class I molecules in the endoplasmic reticulum with the assistance of proteins such as Transporter associated with Antigen Processing (TAP) and tapasin. Interferon-gamma induces both TAP and tapasin so dissection of which protein contributes more to HLA class I expression has not been possible previously. In this study, we take advantage of a human melanoma cell line in which TAP can be induced, but tapasin cannot. Interferon-gamma increases TAP protein levels dramatically but HLA class I expression at the cell surface does not increase substantially, indicating that a large increase in peptide supply is not sufficient to increase HLA class I expression. On the other hand, transfection of either allelic form of tapasin (R240 or T240) enhances HLA-B*5001 and HLA-B*5701 antigen expression considerably with only a modest increase in TAP. Together, these data indicate that in the presence of minimal TAP activity, tapasin can promote substantial HLA class I expression at the cell surface.     

Thiol oxidation and reduction in MHC-restricted antigen processing and presentation

Major histocompatibility complex (MHC) class I molecules are assembled in the endoplasmic reticulum (ER) as a trimer of the class I heavy chain, Β² microglobulin (Β²m), and a short peptide. Assembly occurs in a complex with additional noncovalently associated proteins, which include the thiol oxidoreductase, ERp57. This molecule facilitates the formation of the correct disulfide bonds in glycoproteins as they fold in the ER and may play a key role in assembling a stable MHC class I-peptide complex. In the endocytic pathway, reduction of protein disulfide bonds is important for the generation of MHC class II-peptide complexes. This process is catalyzed by a γ-interferon-inducible thiol reductase (GILT). The possible requirement for catalysis of disulfide bond formation in MHC class I-restricted antigen processing and the known requirement for disulfide bond reduction in MHC class II-restricted antigen processing present interesting examples of the adaptation of cellular “housekeeping” functions to facilitate immune responses.     

The nature of the MHC class I peptide loading complex

Summary: Peptide binding to major histocompatibility complex (MHC) dass I molecules occurs in the endoplasmic reticulum (ER). Efficient peptide binding requires a number of components in addition co the MHC class I-β₂ microglobulin dimer (β₂m). These include the two subunits of the transporter associated with antigen presentation (TAP1 and TAP2), which are essential for introducing peptides into the ER from the cytosol, and tapasin, an MHC-encoded membrane protein. Prior to peptide binding, MHC class I-β₂m dimers form part of a large multisubnnit ER complex which includes TAP and tapasin. In addition to these specialized components two soluble 'house-keeping' proteins, the chaperone calreticulin and the thiol oxidoreductase ERp57, are also components of this complex. Our current understanding of the nature and function of the MHC class I peptide loading complex is the topic of this review.     

Tapasin-the keystone of the loading complex optimizing peptide binding by MHC class I molecules in the endoplasmic reticulum

MHC class I molecules are loaded with peptides that mostly originate from the degradation of cytosolic protein antigens and that are translocated across the endoplasmic reticulum (ER) membrane by the transporter associated with antigen processing (TAP). The ER-resident molecule tapasin (Tpn) is uniquely dedicated to tether class I molecules jointly with the chaperone calreticulin (Crt) and the oxidoreductase ERp57 to TAP. As learned from the study of a Tpn-deficient cell line and from mice harboring a disrupted Tpn gene, the transient association of class I molecules with Tpn and TAP is critically important for the stabilization of class I molecules and the optimization of the peptide cargo presented to cytotoxic T cells. The different functions of molecular domains of Tpn and the highly coordinated formation of the TAP-associated peptide loading complex will also be discussed in this review.     

Interleukin-18 Inhibition of Oral Carcinoma Cell Proliferation

Rationale:  Major histocompatibility complex class I (MHC I) molecules monitor the protein content of the cell by binding small derived peptides and presenting them to cytotoxic CD8⁺ T cells. The goal of the human MHC project is to predict the binding strength of any given peptide/MHC complex. This prediction allows the design of peptide-based vaccines. The prediction requires representative binding data from MHC alleles from all the nine HLA supertypes. Here, we describe the genetic construction, protein production and purification as well as the establishment-binding assays for two recombinant MHC supertype alleles, HLA-B*1501 and HLA-B*5801.
Methods:  Using the Quikchange Multisite Directed Mutagenesis Kit (Stratagene), codon-optimized genes encoding HLA-B*1501 and HLA-B*5801 are created. The two MHC I molecules are fermented and purified by ion exchange chromatography, hydrophobic interaction chromatography and size exclusion chromatography. The binding (KD) of natural T-cell epitopes, as well as predicted peptide ligands, is described by radioactive immunoassays (RIAs) and enzyme-linked immunosorbent assays (ELISAs). The MHC molecules are biotinylated during expression.
Results:  The expression of MHC I resulted in multiple disulfide bond isomers, which are separated by hydrophobic interaction chromatography and used in subsequent binding studies resulting in the determination of KD for various peptide ligands ranging from strong binders (KD < 50 nM) to low binders (KD > 5 µM). Tetramerization is visualized by SDS-PAGE.
Conclusion:  An effective method for the production of highly pure MHC I molecules has been applied to HLA-B*1501 and HLA-B*5801, and RIA and ELISA binding assays for those alleles have been established, showing the binding of various peptide ligands to the MHC I molecules.     

MHC class I assembly: out and about

The assembly of major histocompatibility complex (MHC) class I molecules with peptides is orchestrated by several assembly factors including the transporter associated with antigen processing (TAP) and tapasin, the endoplasmic reticulum (ER) oxido-reductases ERp57 and protein disulfide isomerase (PDI), the lectin chaperones calnexin and calreticulin, and the ER aminopeptidase (ERAAP). Typically, MHC class I molecules present endogenous antigens to cytotoxic T lymphocytes (CTLs). However, the initiation of CD8(+) T-cell responses against many pathogens and tumors also requires the presentation of exogenous antigens by MHC class I molecules. We discuss recent developments relating to interactions and mechanisms of function of the various assembly factors and pathways by which exogenous antigens access MHC class I molecules.     

Workshop H: Antigen Processing and Presentation, Abstract H1 bis H20

H. 1 Subcellular distribution of proteases in the endocytic compartment of human dendritic cellsH. 2 Potential nickel coordination sites in a MHC-Ni²⁺-TCR complexH. 3 Multiple functions of tapasin in the loading complex: Loading of class I molecules with optimal peptides and stabilization of the transporter associated with antigen presentationH. 4 Differences in specificity of thymus-selected T cells and corresponding hybridomas: Evidences for a multivalent αβT cell receptorH. 5 Neosynthesis is required for the presentation of a T cell epitope from a long-lived viral proteinH. 6 Residue V38 of MHC class II α-chains: Negative effects of the substitution V38M on surface expression and antigen presentation can be rescued by enforced peptide bindingH. 7 Long-term procainamide treatment in the drinking water of A/J mice produces a positive T cell reaction to an unidentified neo-antigen in the lymphocyte transformation testH. 8 The role of ER60/ERp57 in MHC class I assemblyH. 9 Characterization of domains in the human peptide transporter subunit TAP2 required for TAP functionH. 10 Proteasome-dependent processing of autoantigens of systemic rheumatic diseasesH. 11 Human dendritic cells counter-regulate HLA-DM and HLA-DR in the course of maturationH. 12 Expression of the proteasome activator PA28 rescues the presentation of a cytotoxic T lymphocyte epitope on human melanoma cellsH. 13 Interferon-γ influences the in vivo antigen presentation of dendritic cellsH. 14 Antigen presentation by human B cells demonstrates colocalisation of B and T cell epitopes and dominant HLA-DR presentation of part of the B cell epitopeH. 15 MHC class II/peptide complexes become enriched in tetraspan microdomains depending on the type of peptide boundH. 16 Dendritic cells pulsed with the viral pseudocapsid HBsAg efficiently cross-present different epitopes to murine MHC class I-restricted cytotoxic T cellsH. 17 Recruitment of MHC class I molecules by tapasin into the TAP-associated complex is essential for optimal peptide loadingH. 18 Incorrect folding of MHC class I molecules in hemodialysis patients: A reason for impaired immune function?H. 19 Structural analysis of HLA-B27 subtypes differently associated with arthritisH. 20 Ligands binding to the MHC class II allele DQA1*0401-DQB1*0402 identified by screening synthetic combinatorial peptide libraries     

Impaired assembly of the major histocompatibility complex class I peptide-loading complex in mice deficient in the oxidoreductase ERp57

The thiol-oxidoreductase ERp57 is an integral component of the peptide-loading complex of the major histocompatibility complex (MHC) class I pathway, but its function is unknown. To investigate its function in antigen presentation, we generated ERp57-deficient mice. Death in utero caused by ubiquitous ERp57 deletion was prevented by specific deletion in the B cell compartment. We demonstrate that ERp57 was central for recruitment of MHC class I molecules into the loading complex. In ERp57-deficient cells, we found short-lived interaction of MHC class I molecules with the loading complex. Thus, in the steady state, very few MHC class I molecules were present in the loading complex. Surface H-2K(b)-peptide expression and stability were reduced, and presentation of a model antigen was decreased. Our results indicate that ERp57 does not influence the redox state of MHC class I molecules but is an essential structural component required for stable assembly of the peptide-loading complex.     

HLA-DM, HLA-DO and tapasin: functional similarities and differences.

In both the MHC class II and class I pathways of antigen presentation, accessory molecules influence formation of MHC-peptide complexes. In the MHC class II pathway, DM functions in the loading and editing of peptides; recent work demonstrated that it is acting not only in late endosomal compartments but also in recycling compartments and on the surface of B cells and immature dendritic cells. DM activity is modulated by another accessory molecule, DO, but this modulation is mainly operative in B cells, where it may lead to preferential activation of B cells producing high-affinity antibodies. In the MHC class I pathway of antigen presentation, recent in vivo experiments with knockout mice confirmed the role of tapasin in antigen presentation and indicate that it acts as a peptide editor and as a chaperone for TAP and the MHC class I heavy chain. In the class I loading complex, calreticulin and the thiol-dependent oxidoreductase ER60/ERp57 appear to support the function of tapasin in an as-yet-unknown fashion. The picture emerges that DM and tapasin have analogous functions in shaping the peptide repertoire presented by the respective MHC class II and class I molecules.