Peptide length variants p2Ca and QL9 present distinct conformations to L(d)-specific T cells

Potentiation of T Cell Stimulatory Activity by Chemical Fixation of a Weak Peptide-MHC Complex

The stability of peptide-MHC complex (pMHC) is an important factor to shape the fate of peptide-specific T cell immune response, but how it influences on T cell activation process is poorly understood. To better understand that, we investigated various T cell activation events driven by Ld MHCI loaded with graded concentrations of P2Ca and QL9 peptides, respectively, with 2C TCR Tg T cells; the binding strength of P2Ca for Ld is measurably weaker than that of QL9, but either peptides in the context of Ld interact with 2C TCR with a similar strength. When their concentrations required for early T cell activation events, which occur within several minutes to an hour, were concerned, EC50s of QL9 were about 100 folds lower than those of P2Ca, which was expected from their association constants for Ld. When EC50s for late activation events, which takes over several hours to occur, were concerned, the differences grew even larger (> 300 folds), suggesting that, due to weak binding, Ld/P2Ca dissociate from each other more easily to lose its antigenicity in a short time. Accordingly, fixation of Ld/P2Ca with paraformaldehyde resulted in a significant improvement in its immunogenicity. These results imply that binding strength of a peptide for a MHC is a critical factor to determine the duration of pMHC-mediated T cell activation and thus the attainment of productive T cell activation. It is also suggested that paraformaldehyde fixation should be an effective tool to ameliorate the immunogenicity of pMHC with a poor stability.

Embryonic stem cell-derived haematopoietic progenitor cells down-regulate the CD3 ξ chain on T cells, abrogating alloreactive T cells

Murine embryonic stem (ES) cell-derived haematopoietic progenitor cells (HPCs) engraft and populate lymphoid organs. In vivo, HPCs engraft across MHC barriers protecting donor-type allografts from rejection. However, the underlying phenomenon remains elusive. Here, we sought to determine the mechanism by which ES cell-derived HPCs regulate alloreactive T cells. We used the 2C mouse, which expresses a transgenic T-cell receptor against H2-L(d) to determine whether HPCs are deleted by cytotoxic T lymphocytes (CTLs). Previously, we reported that HPCs express MHC class I antigens poorly and do not express class II antigens. In vitro stimulated 2C CTLs failed to lyse H2-L(d) HPCs in a standard 4-hr (51) chromium release assay. Similarly, when the HPCs were tested in an ELISPOT assay measuring the release of interferon-γ by CTLs, HPCs failed to induce CTL degranulation. In addition, mice that were injected with HPCs showed a marked decrease in T-cell responses to alloantigen and CD3 stimulation, but showed a normal response to PMA/ionomycin, suggesting that HPCs impaired T-cell signalling through the T-cell receptor/CD3 complex. Here, we show that HPCs secrete arginase, an enzyme that scavenges l-arginine, leading to metabolites that down-regulate CD3 ζ chain. Indeed an arginase inhibitor partially restored expression of the CD3 ζ chain, implicating arginase 1 in the down-regulation of T cells. This previously unrecognized property of ES cell-derived HPCs could positively enhance the engraftment of ES cell-derived HPCs across MHC barriers by preventing rejection.

Cross-reactivity analysis of T cell receptors specific for overlapping HIV-1 Nef epitopes of different lengths

Overlapping peptides of different lengths from a certain immunodominant region can be presented by the same HLA class I molecule and elicit different T cell responses. However, how peptide-length specificity of antigen-specific CD8(+) T lymphocytes influence cross-reactivity profiles of these cells remains elusive. This question is particularly important in the face of highly variable pathogens such as HIV-1. Here, we examined this problem by using HLA-B*35:01-restricted CD8(+) T lymphocytes specific for Nef epitopes, i.e., RY11 (RPQVPLRPMTY), VY8 (VPLRPMTY), and RM9 (RPQVPLRPM), in which VY8 and RM9 were contained entirely within RY11, in combination with a T cell receptor (TCR) reconstruction system as well as HLA-B35 tetramers and a set of a single-variant peptide library. The TCR reactivity toward the peptide-length variants was classified into three types: mutually exclusive specificity toward (1) RY11 or (2) VY8 and (3) cross-recognition toward RM9 and RY11. TCR cross-reactivity toward variant peptides was similar within the same peptide-length reactivity type but was markedly different between the types. Thus, TCRs showing similar peptide-length reactivity have shared peptide recognition footprints and thereby similar weakness to antigenic variations, providing us with further insight into the antiviral vaccine design.

The effect of mutations on the alloreactive T cell receptor/peptide-MHC interface structure: a molecular dynamics study

T cells orchestrate adaptive, pathogen-specific immune responses. T cells have a surface receptor (called TCR) whose ligands are complexes (pMHCs) of peptides (derived from pathogens or host proteins) and major histocompatibility complex proteins (MHCs). MHC proteins vary between hosts. During organ transplants, host TCRs interact with peptides present in complex with genetically different MHCs. This usually causes a vigorous immune response: alloreactivity. Studies of alloreactive protein interactions have yielded results that present a puzzle. Some crystallographic studies concluded that the alloreactive TCR/MHC interface is essentially unaffected by changing the TCR peptide-binding region, suggesting that the peptide does not influence the interface. Another biochemical study concluded from mutation data that different peptides can alter the binding interface with the same TCR. To explore the origin of this puzzle, we used molecular dynamics simulations to study the dependence of the TCR/pMHC interface on changes in both the peptide and the TCR. Our simulations show that the footprint of the TCR on the pMHC is insensitive to mutations of the TCR peptide-binding loops, but peptide mutations can make multiple local changes to TCR/pMHC contacts. Therefore, our results demonstrate that the structural and mutation data do not conflict and reveal how subtle, but important, characteristics of the alloreactive TCR/pMHC interface are influenced by the TCR and the peptide.

Different strategies adopted by K(b) and L(d) to generate T cell specificity directed against their respective bound peptides

Mouse T cell clone 2C recognizes two different major histocompatibility (MHC) ligands, the self MHC K(b) and the allogeneic MHC L(d). Two distinct peptides, SIY (SIYRYYGL) and QL9 (QLSPFPFDL), act as strong and specific agonists when bound to K(b) and L(d), respectively. To explore further the mechanisms involved in peptide potency and specificity, here we examined a collection of single amino acid peptide variants of SIY and QL9 for 1) T cell activity, 2) binding to their respective MHC, and 3) binding to the 2C T cell receptor (TCR) and high affinity TCR mutants. Characterization of SIY binding to MHC K(b) revealed significant effects of three SIY residues that were clearly embedded within the K(b) molecule. In contrast, QL9 binding to MHC L(d) was influenced by the majority of peptide side chains, distributed across the entire length of the peptide. Binding of the SIY-K(b) complex to the TCR involved three SIY residues that were pointed toward the TCR, whereas again the majority of QL9 residues influenced binding of TCRs, and thus the QL9 residues had impacts on both L(d) and TCR binding. In general, the magnitude of T cell activity mediated by a peptide variant was influenced more by peptide binding to MHC than by binding the TCR, especially for higher affinity TCRs. Findings with both systems, but QL9-L(d) in particular, suggest that many single-residue substitutions, introduced into peptides to improve their binding to MHC and thus their vaccine potential, could impair T cell reactivity due to their dual impact on TCR binding.

Molecular analysis of thymopentin binding to HLA-DR molecules

Thymopentin (TP5) triggers an immune response by contacting with T cells; however the molecular basis of how TP5 achieves this process remains incompletely understood. According to the main idea of immunomodulation, we suppose that it would be necessary for TP5 to form complex with human class II major histocompatibility complex DR molecules (HLA-DR) before TP5 interacts with T cells. The uptake of TP5 by EBV-transformed B cells expressing HLA-DR molecules and the histogram of fluorescence intensities were observed by using fluorescent- labeled TP5, testifying the direct binding of TP5 to HLA-DR. The binding specificity was confirmed by the inhibition with unlabeled TP5, suggesting the recognition of TP5 by HLA-DR. To confirm the interaction between TP5 and HLA-DR, the complex formation was predicted by using various modeling strategies including six groups of trials with different parameters, alanine substitutions of TP5, and the mutants of HLA-DR. The results demonstrated that TP5 and its alanine substitutions assumed distinct conformations when they bound to HLA-DR. The observation further showed that there was flexibility in how the peptide bound within the binding cleft. Also, the molecular analysis supplemented a newly important discovery to the effect of Val anchor on TP5 binding HLA-DR, and revealed the important effects of Glu11 and Asn62 on the recognition of TP5. These results demonstrated the capability of TP5 to associate with HLA-DR in living antigen presenting cells (APC), thereby providing a new and promising strategy to understand the immunomodulation mechanism induced by TP5 and to design potential immunoregulatory polypeptides.

Cellular uptake followed by class I MHC presentation of some exogenous peptides contributes to T cell stimulatory capacity

The T cell stimulatory activity of peptides is known to be associated with the cell surface stability and lifetime of the peptide-MHC (pepMHC) complex. In this report, soluble high-affinity T cell receptors (TCRs) that are specific for pepMHC complexes recognized by the mouse CD8+ clone 2C were used to monitor the cell surface lifetimes of synthetic agonist peptides. In the 2C system, L(d)-binding peptide p2Ca (LSPFPFDL) has up to 10,000-fold lower activity than peptide QL9 (QLSPFPFDL) even though the 2C TCR binds to p2Ca-L(d) and QL9-L(d) complexes with similar affinities. Unexpectedly, p2Ca-L(d) complexes were found to have a longer cell surface lifetime than QL9-L(d) complexes. However, the strong agonist activity of QL9 correlated with its ability to participate in efficient intracellular delivery followed by cell surface expression of the peptide, resulting in high and persistent surface levels of QL9-L(d). The ability of target cells to take up and present QL9 was observed with TAP-deficient cells and TAP-positive cells, including dendritic cells. The process was brefeldin A-sensitive, indicating a requirement for transport of the pepMHC through the ER and/or golgi. Thus, strong T cell stimulatory activity of some pepMHC complexes can be accomplished not only through long cell surface lifetimes of the ligand, but through a mechanism that leads to delayed presentation of the exogenous antigen after intracellular uptake.

The Ig-Like Domain of Tapasin Influences Intermolecular Interactions

Presentation of antigenic peptides to T lymphocytes by MHC class I molecules is regulated by events involving multiple endoplasmic reticulum proteins, including tapasin. By studying the effects of substitutions in the tapasin Ig-like domain, we demonstrated that H-2L(d)/tapasin association can be segregated from reconstitution of folded L(d) surface expression. This finding suggests that peptide acquisition by L(d) is influenced by tapasin functions that are independent of L(d) binding. We also found that the presence of a nine-amino acid region in the Ig-like domain of mouse or human tapasin is required for association with L(d), and certain point substitutions in this sequence abrogate human, but not mouse, tapasin association with L(d). These data are consistent with a higher overall affinity between L(d) and mouse tapasin compared with human tapasin. In addition, we found that other point mutations in the same region of the tapasin Ig-like domain affect MHC class I surface expression and Ag presentation. Finally, we showed that the cysteine residues in the Ig-like domain of tapasin influence tapasin's stability, its interaction with the MHC class I H chain, and its stabilization of TAP. Mutagenesis of these cysteines decreases tapasin's electrophoretic mobility, suggesting that these residues form an intramolecular disulfide bond. Taken together, these results reveal a critical role for the tapasin Ig-like domain in tapasin function.

Enhanced immune presentation of a single-chain major histocompatibility complex class I molecule engineered to optimize linkage of a C-terminally extended peptide

Major histocompatibility complex class I molecules can be expressed as single polypeptides wherein the antigenic peptide, beta2-microglobulin, and heavy chain are attached by flexible linkers. These molecules, single-chain trimers (SCTs), are remarkably stable at the cell surface compared with native (noncovalently attached) class I molecules. In this study, we used a structure-based approach to engineer an F pocket variant SCT of the murine class I molecule Kb that presents the SIINFEKL epitope of ovalbumin. Mutation of heavy chain residue Tyr84 (Y84A) in the SCT resulted in enhanced serological and cytolytic CD8 T cell recognition of the covalently linked peptide due to better accommodation of the linker extending from the C terminus of the peptide. These SCTs exhibit significant cell-surface stability, which we hypothesize is rendered by their ability to continuously and efficiently rebind the covalently attached peptide. In addition, we demonstrate that SCT technology can be applied to tetramer construction using recombinant SCTs expressed in Escherichia coli. SCT-based tetramers could have applications for the enumeration of T and natural killer cells that recognize peptide.class I complexes prone to dissociation.

Homology between an alloantigen and a self MHC allele calibrates the avidity of the alloreactive T cell repertoire independent of TCR affinity

The self-restricted T cell repertoire exhibits a high frequency of alloreactivity. Because these alloreactive T cells are derived from the pool of cells selected on several different self MHC alleles, it is unknown how development of the alloantigenic repertoire is influenced by homology between a self MHC allele and an alloantigen. To address this, we used the 2C transgenic TCR that is selected by K(b), is alloreactive for L(d), and cross-reacts with L(q). L(q) is highly homologous to L(d) and binds several of the same peptide ligands, including p2Ca, the peptide recognized by 2C. We find that L(d)/p2Ca is a high avidity agonist ligand, whereas L(q)/p2Ca is a low avidity agonist ligand for 2C T cells. When mice transgenic for the 2C TCR are bred to L(q)-expressing mice, 2C(+) T cells develop; however, they express lower levels of either the 2C TCR or CD8 and require a higher L(d)/p2Ca ligand density to be activated than 2C(+) T cells selected by K(b). Furthermore, the 2C T cells selected in the presence of L(q) fail to detect L(q)/p2Ca complexes even at high ligand density. Thus, despite possessing the identical TCR, there is a functional avidity difference between 2C(+) T cells selected in the presence of L(q) vs K(b). These data provide evidence that homology between the selecting ligand and an alloantigen can influence the avidity of the T cell repertoire for the alloantigen, and suggest that thymic selection can fine tune T cell avidity independent of intrinsic TCR affinity.

Cutting edge: single-chain trimers of MHC class I molecules form stable structures that potently stimulate antigen-specific T cells and B cells

We report in this work the expression and characterization of class I molecules expressed as single-chain trimers consisting of an antigenic peptide-spacer-beta(2)-microglobulin-spacer H chain. Our results indicate that these single-chain constructs assemble efficiently, maintain their covalent structure, and are unusually stable at the cell surface. Consequently, these constructs are at least 1000-fold less accessible to exogenous peptide than class I molecules loaded with endogenous peptides, and they are potent simulators of peptide-specific CTL and Abs. Our combined findings suggest that single-chain trimers may have applications as DNA vaccines against virus infection or tumors.