Distinct functions of tapasin revealed by polymorphism in MHC class I peptide loading

Peptide assembly with class I molecules is orchestrated by multiple chaperones including tapasin, which bridges class I molecules with the TAP and is critical for efficient Ag presentation. In this paper, we show that, although constitutive levels of endogenous murine tapasin apparently are sufficient to form stable and long-lived complexes between the human HLA-B*4402 (B*4402) and mouse TAP proteins, this does not result in normal peptide loading and surface expression of B*4402 molecules on mouse APC. However, increased expression of murine tapasin, but not of the human TAP proteins, does restore normal cell surface expression of B*4402 and efficient presentation of viral Ags to CTL. High levels of soluble murine tapasin, which do not bridge TAP and class I molecules, still restore normal surface expression of B*4402 in the tapasin-deficient human cell line 721.220. These findings indicate distinct roles for tapasin in class I peptide loading. First, tapasin-mediated bridging of TAP-class I complexes, which despite being conserved across the human-mouse species barrier, is not necessarily sufficient for peptide loading. Second, tapasin mediates a function which probably involves stabilization of empty class I molecules and which is sensitive to structural compatibility of components within the loading complex. These discrete functions of tapasin predict limitations to the study of HLA molecules across some polymorphic and species barriers.     

Identification of domain boundaries within the N-termini of TAP1 and TAP2 and their importance in tapasin binding and tapasin-mediated increase in peptide loading of MHC class I

Before exit from the endoplasmic reticulum (ER), MHC class I molecules transiently associate with the transporter associated with antigen processing (TAP1/TAP2) in an interaction that is bridged by tapasin. TAP1 and TAP2 belong to the ATP-binding cassette (ABC) transporter family, and are necessary and sufficient for peptide translocation across the ER membrane during loading of MHC class I molecules. Most ABC transporters comprise a transmembrane region with six membrane-spanning helices. TAP1 and TAP2, however, contain additional N-terminal sequences whose functions may be linked to interactions with tapasin and MHC class I molecules. Upon expression and purification of human TAP1/TAP2 complexes from insect cells, proteolytic fragments were identified that result from cleavage at residues 131 and 88 of TAP1 and TAP2, respectively. N-Terminally truncated TAP variants lacking these segments retained the ability to bind peptide and nucleotide substrates at a level comparable to that of wild-type TAP. The truncated constructs were also capable of peptide translocation in vitro, although with reduced efficiency. In an insect cell-based assay that reconstituted the class I loading pathway, the truncated TAP variants promoted HLA-B*2705 processing to similar levels as wild-type TAP. However, correlating with the observed reduction in tapasin binding, the tapasin-mediated increase in processing of HLA-B*2705 and HLA-B*4402 was lower for the truncated TAP constructs relative to the wild type. Together, these studies indicate that N-terminal domains of TAP1 and TAP2 are important for tapasin binding and for optimal peptide loading onto MHC class I molecules.     

Nucleotide binding by TAP mediates association with peptide and release of assembled MHC class I molecules

Background: Newly synthesised peptide-receptive major histocompatibility complex (MHC) class I molecules form a transient loading complex in the endoplasmic reticulum with the transporter associated with antigen processing (TAP) and a set of accessory proteins. Binding of peptide to the MHC class I molecule is necessary for dissociation of the MHC class I molecule from the complex with TAP, but other components of the complex might also be involved. To investigate the role of TAP in this process, mutations that block nucleotide binding were introduced into the ATP-binding site of TAP.Results: Mutant TAP formed apparently normal loading complexes with MHC class I molecules and accessory components, but had no nucleotide-binding or peptide-transport activity. Nevertheless, whereas wild-type loading complexes in detergent lysates could be dissociated by addition of peptides that bind MHC class I molecules, mutant complexes could not be dissociated in this way. Depletion of nucleotide diphosphates or triphosphates from wild-type lysates blocked peptide-mediated dissociation of MHC class I molecules, which could be reversed by readdition of nucleotide diphosphates or triphosphates. Complexes between mutant TAP and MHC class I molecules remained associated in vivo until they were degraded. Disruption of nucleotide binding also eliminated TAP's peptide-binding activity.Conclusions: Peptide-mediated dissociation of the MHC class I molecule from the loading complex depends on conformational signals arising from TAP. Integrity of the nucleotide-binding site is required not only for transmission of this conformational signal to the loading complex, but also for binding of peptide to TAP. Thus, the dynamic activity of the loading complex is synchronised with the nucleotide-mediated peptide-binding and transport cycle of TAP.     

TAP association influences the conformation of nascent MHC class I molecules

The influence of TAP-MHC class I interactions on peptide binding to the class I heavy chain is assessed during TAP-dependent assembly using Kb-specific Abs that recognize conformational changes induced by assembly with beta2-microglobulin (beta2m) and by peptide binding. A significant portion (45%) of Kb molecules in TAP+, RMA-derived microsomes are associated with the TAP complex as measured by coimmunoisolation of Kb using anti-TAP1 Abs, while only 20% of the Kb heavy chain molecules are isolated as Kbbeta2m complexes with the alpha-Kb-specific Abs, Y-3 or K-10-56. The amount of Kb isolated with Y-3 and K-10-56 increases in proportion to transport and binding of peptide to the Kb molecules within the RMA microsomes. In contrast, less than 5% of the Kb within TAP2-RMA-S microsomes associated with the remaining TAP1 subunit. However, greater than 60% of Kb heavy chain is isolated as K-10-56- and Y-3-reactive Kbbeta2m complexes. We propose that a TAP-MHC class I interaction serves to stabilize the MHC class I:beta2m complex in an immature conformation (Y-3 and K-10-56 nonreactive) prior to high affinity peptide binding, preventing the export of class I molecules complexed with low affinity peptide ligands from the ER.     

Identifying MHC class I epitopes by predicting the TAP transport efficiency of epitope precursors

We are able to make reliable predictions of the efficiency with which peptides of arbitrary lengths will be transported by TAP. The pressure exerted by TAP on Ag presentation thus can be assessed by checking to what extent MHC class I (MHC-I)-presented epitopes can be discriminated from random peptides on the basis of predicted TAP transport efficiencies alone. Best discriminations were obtained when N-terminally prolonged epitope precursor peptides were included and the contribution of the N-terminal residues to the score were down-weighted in comparison with the contribution of the C terminus. We provide evidence that two factors may account for this N-terminal down-weighting: 1) the uncertainty as to which precursors are used in vivo and 2) the coevolution in the C-terminal sequence specificities of TAP and other agents in the pathway, which may vary among the various MHC-I alleles. Combining predictions of MHC-I binding affinities with predictions of TAP transport efficiency led to an improved identification of epitopes, which was not the case when predictions of MHC-I binding affinities were combined with predictions of C-terminal cleavages made by the proteasome.     

The role of MHC class I heterodimer expression in mouse ankylosing enthesopathy

 Ankylosing enthesopathy (ANKENT) is a spontaneous mouse joint disease with strikingly similar pathology to human HLA-B27-associated enthesopathies such as ankylosing spondylitis. In C57Bl/10 mice, transgenic HLA-B^*2702 as well as H2 genes have been shown to be relative risk factors for ANKENT. To investigate the role of major histocompatibility complex (MHC) class I expression in disease pathogenesis, ANKENT occurrence was compared among β₂-microglobulin (β₂m) knockout littermates with or without transgenes for HLA-B^*2702 and human β₂m. In the knockout phenotype lacking β₂m, ANKENT occurrence is significantly reduced (P = 0.016). In the absence of β₂m, B^*2702 is not detected on the cell membrane, nor does it increase the risk for ANKENT. This means that the previous finding that HLA-B^*2702 increases susceptibility to ANKENT in C57Bl/10 mice cannot be ascribed to a transgene insertion effect. Rather, in order to increase disease susceptibility, B^*2702 must be coexpressed with mouse β₂m (mo-β₂m). In contrast, when HLA-B^*2702 is expressed with β₂m of human origin, disease susceptibility is not affected. Thus, both H2^b-derived class I heterodimers and HLA-B^*2702/mo-β₂m heterodimers contribute to ANKENT susceptibility.     

Influence of the tapasin C terminus on the assembly of MHC class I allotypes

Several endoplasmic reticulum proteins, including tapasin, play an important role in major histocompatibility complex (MHC) class I assembly. In this study, we assessed the influence of the tapasin cytoplasmic tail on three mouse MHC class I allotypes (H2-K^b, -K^d, and -L^d) and demonstrated that the expression of truncated mouse tapasin in mouse cells resulted in very low K^b, K^d, and L^d surface expression. The surface expression of K^d also could not be rescued by human soluble tapasin, suggesting that the surface expression phenotype of the mouse MHC class I molecules in the presence of soluble tapasin was not due to mouse/human differences in tapasin. Notably, soluble mouse tapasin was able to partially rescue HLA-B8 surface expression on human 721.220 cells. Thus, the cytoplasmic tail of tapasin (either mouse or human) has a stronger impact on the surface expression of murine MHC class I molecules on mouse cells than on the expression of HLA-B8 on human cells. A K408W mutation in the mouse tapasin transmembrane/cytoplasmic domain disrupted K^d folding and release from tapasin, but not interaction with transporter associated with antigen processing (TAP), indicating that the mechanism whereby the tapasin transmembrane/cytoplasmic domain facilitates MHC class I assembly is not limited to TAP stabilization. Our findings indicate that the C terminus of mouse tapasin plays a vital role in enabling murine MHC class I molecules to be expressed at the surface of mouse cells.     

CLIP-region mediated interaction of Invariant chain with MHC class I molecules

An association between the MHC class II chaperone molecule Invariant chain (Ii) and MHC class I molecules is known to occur, but the basis of the interaction is undetermined. Evidence is presented here that the CLIP region of Ii is involved in this interaction. A peptide encoding residues 91-99 of CLIP (MRMATPLLM) stabilised multiple MHC class I alleles, with the methionine residue at position 99 having a crucial role in binding to H2-K(b), whereas methionine at position 91 also appeared important in binding to RT1-A(a). Ii can also be detected in the class I MHC peptide loading complex. These data provide an explanation for the association of Ii and MHC class I molecules.     

Retention of empty MHC class I molecules by tapasin is essential to reconstitute antigen presentation in invertebrate cells.

Presentation of antigen-derived peptides by major histocompatibility complex (MHC) class I molecules is dependent on an endoplasmic reticulum (ER) resident glycoprotein, tapasin, which mediates their interaction with the transporter associated with antigen processing (TAP). Independently of TAP, tapasin was required for the presentation of peptides targeted to the ER by signal sequences in MHC class I-transfected insect cells. Tapasin increased MHC class I peptide loading by retaining empty but not peptide-containing MHC class I molecules in the ER. Upon co-expression of TAP, this retention/release function of tapasin was sufficient to reconstitute MHC class I antigen presentation in insect cells, thus defining the minimal non-housekeeping functions required for MHC class I antigen presentation.     

Distinct functions for the glycans of tapasin and heavy chains in the assembly of MHC class I molecules

Complexes of specific assembly factors and generic endoplasmic reticulum (ER) chaperones, collectively called the MHC class I peptide-loading complex (PLC), function in the folding and assembly of MHC class I molecules. The glycan-binding chaperone calreticulin (CRT) and partner oxidoreductase ERp57 are important in MHC class I assembly, but the sequence of assembly events and specific interactions involved remain incompletely understood. We show that the recruitments of CRT and ERp57 to the PLC are codependent and also dependent upon the ERp57 binding site and the glycan of the assembly factor tapasin. Furthermore, the ERp57 binding site and the glycan of tapasin enhance β(2)m and MHC class I heavy (H) chain recruitment to the PLC, with the ERp57 binding site having the dominant effect. In contrast, the conserved MHC class I H chain glycan played a minor role in CRT recruitment into the PLC, but impacted the recruitment of H chains into the PLC, and glycan-deficient H chains were impaired for tapasin-independent and tapasin-assisted assembly. The conserved MHC class I glycan and tapasin facilitated an early step in the assembly of H chain-β(2)m heterodimers, for which tapasin-ERp57 or tapasin-CRT complexes were not required. Together, these studies provide insights into how PLCs are constructed, demonstrate two distinct mechanisms by which PLCs can be stabilized, and suggest the presence of intermediate H chain-deficient PLCs.     

Association of ERp57 with mouse MHC class I molecules is tapasin dependent and mimics that of calreticulin and not calnexin

Before peptide binding in the endoplasmic reticulum, the class I heavy (H) chain-beta(2)-microglobulin complexes are detected in association with TAP and two chaperones, TPN and CRT. Recent studies have shown that the thiol-dependent reductase, ERp57, is also present in this peptide-loading complex. However, it remains controversial whether the association of ERp57 with MHC class I molecules precedes their combined association with the peptide-loading complex or whether ERp57 only associates with class I molecules in the presence of TPN. Resolution of this controversy could help determine the role of ERp57 in class I folding and/or assembly. To define the mouse class I H chain structures involved in interaction with ERp57, we tested chaperone association of L(d) mutations at residues 134 and 227/229 (previously implicated in TAP association), residues 86/88 (which ablate an N-linked glycan), and residue 101 (which disrupts a disulfide bond). The association of ERp57 with each of these mutant H chains showed a complete concordance with CRT, TAP, and TPN but not with calnexin. Furthermore, ERp57 failed to associate with H chain in TPN-deficient.220 cells. These combined data demonstrate that, during the assembly of the peptide-loading complex, the association of ERp57 with mouse class I is TPN dependent and parallels that of CRT and not calnexin.     

Recruitment of MHC class I molecules by tapasin into the transporter associated with antigen processing-associated complex is essential for optimal peptide loading

The ER protein tapasin (Tpn) forms a bridge between MHC class I H chain (HC)/beta(2)-microglobulin and the TAP peptide transporter. The function of this TAP-associated complex was unclear because it was reported that soluble Tpn that has lost TAP interaction would be fully competent in terms of peptide loading and Ag presentation. We found, however, that only wild-type human Tpn (hTpn), but not three soluble hTpn variants, a transmembrane domain point mutant of hTpn (L410-->F), wild-type mouse Tpn, nor a mouse-human Tpn hybrid, fully up-regulated peptide-dependent Bw4 epitopes when expressed in Tpn-deficient.220.B*4402 cells. Consistent with suboptimal peptide loading, the t(1/2) of class I molecules was considerably reduced in the presence of soluble hTpn, hTpn-L410F, and murine Tpn. Furthermore, eluted peptide spectra and the class I-mediated inhibition of NK clones showed distinct differences to the hTpn transfectant. Only wild-type hTpn efficiently recruited HC and calreticulin (Crt) into complexes with TAP and endoplasmic reticulum p57 (ERp57). The L410F mutant was defective in TAP association, but bound to class I molecules, Crt, and ERp57. Mouse Tpn associated with human TAP and ERp57 on the one hand, and with HC and Crt on the other, but failed to recruit normal amounts of HLA class I molecules into the TAP complex. We conclude that the loading with peptides conferring high stability requires the Tpn-mediated introduction of HC into the TAP complex, whereas the mere interaction with Tpn is not sufficient.     

Sequence, linkage to H2-K, and function of mouse tapasin in MHC class I assembly

 Assembly of major histocompatibility complex (MHC) class I molecules in human cells is dependent on the accessory protein tapasin, which mediates their interaction with the transporters associated with antigen processing (TAP) and thereby ensures efficient peptide binding. Analysis of a mouse tapasin complementary DNA defined a conserved polypeptide sharing sequences diagnostic of a transmembrane protein related to the immunoglobulin superfamily, and an endoplasmic reticulum retention motif. The mouse tapasin gene was mapped about 70 kilobases from H2-K at the centromeric end of the mouse MHC. Expression of mouse tapasin in a tapasin-deficient human mutant cell line restored the normal assembly and expression of class I alleles. Thus, tapasin is a structurally and functionally conserved component of the MHC class I antigen processing pathway. Its genetic linkage to the class I and TAP subunit genes in the MHC may be of significance in the coordinate expression and functional coadaptation of the diverse gene products. Received: 1 February 1998 / Revised: 23 March 1998     

A single polymorphic residue within the peptide-binding cleft of MHC class I molecules determines spectrum of tapasin dependence

Different HLA class I alleles display a distinctive dependence on tapasin for surface expression and Ag presentation. In this study, we show that the tapasin dependence of HLA class I alleles correlates to the nature of the amino acid residues present at the naturally polymorphic position 114. The tapasin dependence of HLA class I alleles bearing different residues at position 114 decreases in the order of acidity, with high tapasin dependence for acidic amino acids (aspartic acid and glutamic acid), moderate dependence for neutral amino acids (asparagine and glutamine), and low dependence for basic amino acids (histidine and arginine). A glutamic acid to histidine substitution at position 114 allows the otherwise tapasin-dependent HLA-B4402 alleles to load high-affinity peptides independently of tapasin and to have surface expression levels comparable to the levels seen in the presence of tapasin. The opposite substitution, histidine to glutamic acid at position 114, is sufficient to change the HLA-B2705 allele from the tapasin-independent to the tapasin-dependent phenotype. Furthermore, analysis of point mutants at position 114 reveals that tapasin plays a principal role in transforming the peptide-binding groove into a high-affinity, peptide-receptive conformation. The natural polymorphisms in HLA class I H chains that selectively affect tapasin-dependent peptide loading provide insights into the functional interaction of tapasin with MHC class I molecules.     

Phosphorylated peptides can be transported by TAP molecules, presented by class I MHC molecules, and recognized by phosphopeptide-specific CTL.

CTL recognize short peptide fragments presented by class I MHC molecules. In this study, we examined the effect of phosphorylation on TAP transport, binding to class I MHC molecules, and recognition by CTL of peptide fragments from known phosphorylated oncogene proteins or virus phosphoproteins. We show that phosphopeptides can be efficiently transported from the cytosol to the endoplasmic reticulum by the TAP. Furthermore, we show that phosphorylation can have a neutral, negative, or even a positive effect on peptide binding to class I MHC. Finally, we have generated phosphopeptide-specific CTL that discriminate between the phosphorylated and the nonphosphorylated versions of the peptide. We conclude that phosphopeptide-specific CTL responses are likely to constitute a subset of the class I MHC-restricted CTL repertoire in vivo.