Project description:Chaperones Tapasin and TAP-binding protein related (TAPBPR) perform the important functions of stabilizing nascent MHC-I molecules (chaperoning) and selecting high-affinity peptides in the MHC-I groove (editing). While X-ray and cryo-EM snapshots of MHC-I in complex with TAPBPR and Tapasin, respectively, have provided important insights into the peptide-deficient MHC-I groove structure, the molecular mechanism through which these chaperones influence the selection of specific amino acid sequences remains incompletely characterized. Based on structural and functional data, a loop sequence of variable lengths has been proposed to stabilize empty MHC-I molecules through direct interactions with the floor of the groove. Using deep mutagenesis on two complementary expression systems, we find that important residues for the Tapasin/TAPBPR chaperoning activity are located on a large scaffolding surface, excluding the loop. Conversely, loop mutations influence TAPBPR interactions with properly conformed MHC-I molecules, relevant for peptide editing. Detailed biophysical characterization by solution NMR, ITC and FP-based assays shows that the loop hovers above the MHC-I groove to promote the capture of incoming peptides. Our results suggest that the longer loop of TAPBPR lowers the affinity requirements for peptide selection to facilitate peptide loading under conditions and subcellular compartments of reduced ligand concentration, and to prevent disassembly of high-affinity peptide-MHC-I complexes that are transiently interrogated by TAPBPR during editing.

Project description:Peptide loading of major histocompatibility complex class I (MHC-I) molecules is central to antigen presentation, self-tolerance, and CD8(+) T-cell activation. TAP binding protein, related (TAPBPR), a widely expressed tapasin homolog, is not part of the classical MHC-I peptide-loading complex (PLC). Using recombinant MHC-I molecules, we show that TAPBPR binds HLA-A*02:01 and several other MHC-I molecules that are either peptide-free or loaded with low-affinity peptides. Fluorescence polarization experiments establish that TAPBPR augments peptide binding by MHC-I. The TAPBPR/MHC-I interaction is reversed by specific peptides, related to their affinity. Mutational and small-angle X-ray scattering (SAXS) studies confirm the structural similarities of TAPBPR with tapasin. These results support a role of TAPBPR in stabilizing peptide-receptive conformation(s) of MHC-I, permitting peptide editing.

Project description:MHC class I molecules bind only those peptides with high affinity that conform to stringent length and sequence requirements. We have now investigated which peptides can aid the in vitro folding of class I molecules, and we find that the dipeptide glycyl-leucine efficiently supports the folding of HLA-A*02:01 and H-2K(b) into a peptide-receptive conformation that rapidly binds high-affinity peptides. Treatment of cells with glycyl-leucine induces accumulation of peptide-receptive H-2K(b) and HLA-A*02:01 at the surface of cells. Other dipeptides with a hydrophobic second amino acid show similar enhancement effects. Our data suggest that the dipeptides bind into the F pocket like the C-terminal amino acids of a high-affinity peptide.

Project description:Dendritic cell (DC)-based cytotoxic T lymphocyte (CTL) epitope vaccines are effective to induce CTL responses but require complex ex vivo DC preparation and epitope-loading. To take advantage of DC-based epitope vaccines without involving the ex vivo procedures, we aimed to develop carriers to directly load CTL epitopes onto DCs in vivo. Here, we first engineered a carrier consisting of a hydrophilic polypeptide, immune-tolerant elastin-like polypeptide (iTEP) and a substrate peptide of matrix metalloproteinases-9 (sMMP). The iTEP was able to solubilize CTL epitopes. CTL epitopes were connected to the carrier, iTEP-sMMP, through sMMP so that the epitopes can be cleaved from the carrier by MMP-9. iTEP-sMMP was found to release its epitope payloads in the DC culture media, which contained MMP-9 released from DCs. iTEP-sMMP allowed for the direct loading of CTL epitopes onto the surface MHC class I complexes of DCs. Importantly, iTEP-sMMP resulted in greater epitope presentation by DCs both in vitro and in vivo than a control carrier that cannot directly load epitopes. iTEP-sMMP also induced 2-fold stronger immune responses than the control carrier. To further enhance the direct epitope-loading strategy, we furnished iTEP-sMMP with an albumin-binding domain (ABD) and found the new carrier, ABD-iTEP-sMMP, had greater lymph node (LN) accumulation than iTEP-sMMP. ABD-iTEP-sMMP also resulted in greater immune responses than iTEP-sMMP by 1.5-fold. Importantly, ABD-iTEP-sMMP-delivered CTL epitope vaccine induced stronger immune responses than free CTL epitope vaccine. Taken together, these carriers utilized two physiological features of DCs to realize direct epitope-loading in vivo: the accumulation of DCs in LNs and MMP-9 released from DCs. These carriers are a potential substitute for DC-based CTL epitope vaccines.

Project description:Glycosylation plays a crucial role in the folding, structure, quality control and trafficking of glycoproteins. Here, we explored whether the glycosylation status of MHC class I (MHC-I) molecules impacts their affinity for the peptide editor, TAPBPR. We demonstrate that the interaction between TAPBPR and MHC-I is stronger when MHC-I lacks a glycan. Subsequently, TAPBPR can dissociate peptides, even those of high affinity, more easily from non-glycosylated MHC-I compared to their glycosylated counterparts. In addition, TAPBPR is more resistant to peptide-mediated allosteric release from non-glycosylated MHC-I compared to species with a glycan attached. Consequently, we find the glycosylation status of HLA-A*68:02, -A*02:01 and -B*27:05 influences their ability to undergo TAPBPR-mediated peptide exchange. The discovery that the glycan attached to MHC-I significantly influences the affinity of their interactions with TAPBPR has important implications, on both an experimental level and in a biological context.

Project description:Tapasin and TAPBPR are known to perform peptide editing on major histocompatibility complex class I (MHC I) molecules; however, the precise molecular mechanism(s) involved in this process remain largely enigmatic. Here, using immunopeptidomics in combination with novel cell-based assays that assess TAPBPR-mediated peptide exchange, we reveal a critical role for the K22-D35 loop of TAPBPR in mediating peptide exchange on MHC I. We identify a specific leucine within this loop that enables TAPBPR to facilitate peptide dissociation from MHC I. Moreover, we delineate the molecular features of the MHC I F pocket required for TAPBPR to promote peptide dissociation in a loop-dependent manner. These data reveal that chaperone-mediated peptide editing on MHC I can occur by different mechanisms dependent on the C-terminal residue that the MHC I accommodates in its F pocket and provide novel insights that may inform the therapeutic potential of TAPBPR manipulation to increase tumour immunogenicity.

Project description:Cytotoxic T lymphocyte (CTL)-mediated immune responses are the primary defense mechanism against cancer and infection. CTL epitope peptides have been used as vaccines to boost CTL responses; however, the efficacy of these peptides is suboptimal. Under current vaccine formulation and delivery strategies, these vaccines are delivered into and processed inside antigen-presenting cells such as dendritic cells (DCs). However, the intracellular process is not efficient, which at least partially contributes to the suboptimal efficacy of the vaccines. Thus, we hypothesized that directly loading epitopes onto MHC class I complexes (MHC-Is) on the DC surface would significantly improve the efficacy of the epitopes because the direct loading bypasses inefficient intra-DC vaccine processing. To test the hypothesis, we designed an immune-tolerant elastin-like polypeptide (iTEP)-delivered CTL vaccine containing a metalloproteinase-9 (MMP-9)-sensitive peptide and an CTL epitope peptide. We found that the epitope was released from this MMP-sensitive vaccine through cleavage by DC-secreted MMP-9 outside of the DCs. The released epitopes were directly loaded onto MHC-Is on the DC surface. Ultimately, the MMP-sensitive vaccine strikingly increased epitope presentation by DCs by 7-fold and enhanced the epitope-specific CD8+ T-cell response by as high as 9.6-fold compared to the vaccine that was uncleavable by MMP. In summary, this novel direct-loading strategy drastically boosted vaccine efficacy. This study offered a new avenue to enhance CTL vaccines.

Project description:Major histocompatibility complex (MHC) class I molecules present antigenic peptides to cytotoxic T cells. During an adaptive immune response, MHC molecules are regulated by several mechanisms including lipopolysaccharide (LPS) and interferon gamma (IFN-g). However, it is unclear whether the serine protease cathepsin G (CatG), which is generally secreted by neutrophils at the site of inflammation, might regulate MHC I molecules. We identified CatG, and to a higher extend CatG and lactoferrin (LF), as an exogenous regulator of cell surface MHC I expression of immune cells and glioblastoma stem cells. In addition, levels of MHC I molecules are reduced on dendritic cells from CatG deficient mice compared to their wild type counterparts. Furthermore, cell surface CatG on immune cells, including T cells, B cells, and NK cells triggers MHC I on THP-1 monocytes suggesting a novel mechanism for CatG to facilitate intercellular communication between infiltrating cells and the respective target cell. Subsequently, our findings highlight the pivotal role of CatG as a checkpoint protease which might force target cells to display their intracellular MHC I:antigen repertoire.

Project description:Calreticulin is a lectin chaperone of the endoplasmic reticulum (ER). In calreticulin-deficient cells, major histocompatibility complex (MHC) class I molecules travel to the cell surface in association with a sub-optimal peptide load. Here, we show that calreticulin exits the ER to accumulate in the ER-Golgi intermediate compartment (ERGIC) and the cis-Golgi, together with sub-optimally loaded class I molecules. Calreticulin that lacks its C-terminal KDEL retrieval sequence assembles with the peptide-loading complex but neither retrieves sub-optimally loaded class I molecules from the cis-Golgi to the ER, nor supports optimal peptide loading. Our study, to the best of our knowledge, demonstrates for the first time a functional role of intracellular transport in the optimal loading of MHC class I molecules with antigenic peptide.

Project description:Chaperones TAPBPR and tapasin associate with class I major histocompatibility complexes (MHC-I) to promote optimization (editing) of peptide cargo. Here, we use solution NMR to investigate the mechanism of peptide exchange. We identify TAPBPR-induced conformational changes on conserved MHC-I molecular surfaces, consistent with our independently determined X-ray structure of the complex. Dynamics present in the empty MHC-I are stabilized by TAPBPR and become progressively dampened with increasing peptide occupancy. Incoming peptides are recognized according to the global stability of the final pMHC-I product and anneal in a native-like conformation to be edited by TAPBPR. Our results demonstrate an inverse relationship between MHC-I peptide occupancy and TAPBPR binding affinity, wherein the lifetime and structural features of transiently bound peptides control the regulation of a conformational switch located near the TAPBPR binding site, which triggers TAPBPR release. These results suggest a similar mechanism for the function of tapasin in the peptide-loading complex.