Contributions of the N-terminal flanking residues of an antigenic peptide from the Japanese cedar pollen allergen Cry j 1 to the T-cell activation by HLA-DP5.

Cry j 1 is a major allergen present in Japanese cedar (Cryptomeria japonica) pollens. Peptides with the core sequence of KVTVAFNQF from Cry j 1 ('pCj1') bind to HLA-DP5 and activate Th2 cells. In this study, we noticed that Ser and Lys at positions -2 and -3, respectively, in the N-terminal flanking (NF) region to pCj1 are conserved well in HLA-DP5-binding allergen peptides. A competitive binding assay showed that the double mutation of Ser(-2) and Lys(-3) to Glu [S(P-2)E/K(P-3)E] in a 13-residue Cry j 1 peptide (NF-pCj1) decreased its affinity for HLA-DP5 by about 2-fold. Similarly, this double mutation reduced, by about 2-fold, the amount of NF-pCj1 presented on the surface of mouse antigen-presenting dendritic cell line 1 (mDC1) cells stably expressing HLA-DP5. We established NF-pCj1-specific and HLA-DP5-restricted CD4+ T-cell clones from HLA-DP5 positive cedar pollinosis (CP) patients, and analyzed their IL-2 production due to the activation of mouse TG40 cells expressing the cloned T-cell receptor by the NF-pCj1-presenting mDC1 cells. The T-cell activation was actually decreased by the S(P-2)E/K(P-3)E mutation, corresponding to the reduction in the peptide presentation by this mutation. In contrast, the affinity of NF-pCj1·HLA-DP5 for the T-cell receptor was not affected by the S(P-2)E/K(P-3)E mutation, as analyzed by surface plasmon resonance. Considering the positional and side-chain differences of these NF residues from previously reported T-cell activating sequences, the mechanisms of enhanced T-cell activation by Ser(-2) and Lys(-3) of NF-pCj1 may be novel.

Rapid cloning of antigen-specific T-cell receptors by leveraging the cis activation of T cells.

It is commonly understood that T cells are activated via trans interactions between antigen-specific T-cell receptors (TCRs) and antigenic peptides presented on major histocompatibility complex (MHC) molecules on antigen-presenting cells. By analysing a large number of T cells at the single-cell level on a microwell array, we show that T-cell activation can occur via cis interactions (where TCRs on the T cell interact with the antigenic peptides presented on MHC class-I molecules on the same cell), and that such cis activation can be used to detect antigen-specific T cells and clone their TCR within 4 d. We used the detection-and-cloning system to clone a tumour-antigen-specific TCR from peripheral blood mononuclear cells of healthy donors. TCR cloning by leveraging the cis activation of T cells may facilitate the development of TCR-engineered T cells for cancer therapy.

Direct homophilic interaction of LAMP2A with the two-domain architecture revealed by site-directed photo-crosslinks and steric hindrances in mammalian cells.

LAMP1 (lysosomal-associated membrane protein 1) and LAMP2 are the most abundant protein components of lysosome membranes. Both LAMPs have common structures consisting of a large lumenal domain composed of two domains (N-domain and C-domain, which are membrane-distal and -proximal, respectively), both with the ß-prism fold, a transmembrane domain, and a short cytoplasmic tail. LAMP2 is involved in various aspects of autophagy, and reportedly forms high-molecular weight complexes at the lysosomal membrane. We previously showed that LAMP2 molecules coimmunoprecipitated with each other, but whether the homophilic interaction is direct or indirect has remained to be elucidated. In the present study, we demonstrated the direct homophilic interaction of mouse LAMP2A molecules, using expanded genetic code technologies that generate photo-crosslinking and/or steric hindrance at specified interfaces. Specifically, the results suggested that LAMP2A molecules assemble by facing each other with one side of the ß-prism (defined as side A) of the C-domains. The N-domain truncation, which increased the coimmunoprecipitation of LAMP2A molecules in our previous study, permitted the nonspecific involvement of both sides of the ß-prism (side A and side B). Thus, the presence of the N-domain restricts the LAMP2A interactions to side A-specific. The truncation of LAMP2A impaired the recruitment of GAPDH (a CMA-substrate) fused to the HaloTag protein to the surface of late endosomes/lysosomes (LE/Lys) and affected a process that generates LE/Lys. The present study revealed that the homophilic interaction of LAMP2A is direct, and the side A-specific, homophilic interaction of LAMP2A is required for the functional aspects of LAMP2A.Abbreviations: Aloc-Lys: Nε-allyloxycarbonyl-l-lysine; CMA: chaperone-mediated autophagy; FFE: free-flow electrophoresis; GAPDH-HT: glyceraldehyde-3-phosphate dehydrogenase fused to HaloTag protein; LAMP1: lysosomal-associated membrane protein 1; LAMP2A: lysosomal-associated membrane protein 2A; LBPA: lysobisphosphatidic acid; LE/Lys: late endosome/lysosomes; MEFs: mouse embryonic fibroblasts; pBpa: p-benzoyl- l-phenylalanine.

Alteration of enzymatic properties of cell-surface antigen CD38 by agonistic anti-CD38 antibodies that prolong B cell survival and induce activation.

Leukocyte cell-surface antigen CD38 is a single-transmembrane protein. CD38 ligation by anti-CD38 antibodies triggers the growth or apoptosis of immune cells. Although the extracellular domain of CD38 has multifunctional catalytic activities including NAD(+) glycohydrolase and cyclase, the CD38-mediated cell survival or death appears to be independent of its catalytic activity. It is proposed that a conformational change of CD38 triggers the signalling. The conformational change of CD38 could influence its catalytic activity. However, the agonistic anti-CD38 antibody that alters the catalytic activity of CD38 has not been reported so far. In the present study, we demonstrated that two agonistic anti-mouse CD38 mAbs (CS/2 and clone 90) change the catalytic activities of CD38. CS/2 was clearly more potent than clone 90 in prolonging B cell survival and activation. CS/2 inhibited the NAD(+) glycohydrolase activity of both the isolated extracellular domain of CD38 (FLAG-CD38) and cell-surface CD38. Kinetic analysis suggested a non-competitive inhibition. On the other hand, clone 90 stimulated the NAD(+) glycohydrolase activity of FLAG-CD38 and had little effect on the NAD(+) glycohydrolase activity of cell-surface CD38. CS/2 and clone 90 had no effect on the cyclase activity of FLAG-CD38 and inhibited the cyclase activity of cell-surface CD38. Accordingly, these agonistic antibodies probably induce the conformational changes of CD38 that are evident in the distinct alterations of the catalytic site. The antibodies will be useful tools to analyze the conformational change of CD38 in the process of triggering B cell survival and the activation signal.

Structural basis for the specific recognition of the major antigenic peptide from the Japanese cedar pollen allergen Cry j 1 by HLA-DP5.

The major allergen, Cry j 1, was isolated from Japanese cedar Cryptomeria japonica (Cry j) pollen and was shown to react with immunoglobulin E antibodies in the sera from pollinosis patients. We previously reported that the frequency of HLA-DP5 was significantly higher in pollinosis patients and the immunodominant peptides from Cry j 1 bound to HLA-DP5 to activate Th2 cells. In the present study, we determined the crystal structure of the HLA-DP5 heterodimer in complex with a Cry j 1-derived nine-residue peptide, at 2.4Å resolution. The peptide-binding groove recognizes the minimal peptide with 10 hydrogen bonds, including those between the negatively charged P1 pocket and the Lys side chain at the first position in the peptide sequence. We confirmed that HLA-DP5 exhibits the same Cry j 1-binding mode in solution, through pull-down experiments using structure-based mutations of Cry j 1. We also identified the characteristic residues of HLA-DP5 that are responsible for the distinct properties of the groove, by comparing the structure of HLA-DP5 and the previously reported structures of HLA-DP2 in complexes with pDRA of the self-antigen. The comparison revealed that the HLA-DP5·pCry j 1 complex forms several hydrogen bond/salt bridge networks between the receptor and the antigen that were not observed in the HLA-DP2·pDRA complex. Evolutionary considerations have led us to conclude that HLA-DP5 and HLA-DP2 represent two major groups of the HLA-DP family, in which the properties of the P1 and P4 pockets have evolved and acquired the present ranges of epitope peptide-binding specificities.

Ectodomain structures of the CGRP and AM receptors.

Receptor activity-modifying proteins (RAMPs) 1-3, which are classified as type I transmembrane proteins, serve as the partner proteins of several family B GPCRs for physiologically active peptides, including the calcitonin receptor- like receptor (CLR). The properties of the GPCRs are defined by the RAMP and peptide ligand combination. The CLR•RAMP1 heterodimer functions mainly as the calcitonin gene-related peptide (CGRP) receptor, while the CLR•RAMP2 and CLR•RAMP3 heterodimers primarily function as the adrenomedullin 1 and adrenomedullin 2 (AM1 and AM2) receptors, respectively. The crystal structures of the RAMP1 and RAMP2 ectodomains exhibited three-helix bundles, and those of their complexes with the N-terminal extracellular domain of CLR revealed how the two ectodomains associate to form the CGRP and AM1 receptors, respectively. On this structural framework, the various intermolecular interactions of CLR with RAMP1 and RAMP2 result in the distinct shapes of the putative ligand-binding sites, where several residues are uniquely presented. Therefore, the differences in the shapes and the presented residues of the binding sites determine the specificities of the receptors to either CGRP or AM. These structural features of the ectodomains are consistent with mutagenesis results, and are useful to further examine the binding modes of the peptide ligands to the full-length CGRP and AM1 receptors.

Structural basis for extracellular interactions between calcitonin receptor-like receptor and receptor activity-modifying protein 2 for adrenomedullin-specific binding.

The calcitonin receptor-like receptor (CRLR), a class B GPCR, forms a heterodimer with receptor activity-modifying protein 2 (RAMP2), and serves as the adrenomedullin (AM) receptor to control neovascularization, while CRLR and RAMP1 form the calcitonin gene-related peptide (CGRP) receptor. Here, we report the crystal structures of the RAMP2 extracellular domain alone and in the complex with the CRLR extracellular domain. The CRLR-RAMP2 complex exhibits several intermolecular interactions that were not observed in the previously reported CRLR-RAMP1 complex, and thus the shape of the putative ligand-binding pocket of CRLR-RAMP2 is distinct from that of CRLR-RAMP1. The CRLR-RAMP2 interactions were confirmed for the full-length proteins on the cell surface by site-specific photo-crosslinking. Mutagenesis revealed that AM binding requires RAMP2 residues that are not conserved in RAMP1. Therefore, the differences in both the shapes and the key residues of the binding pocket are essential for the ligand specificity.

Structural basis of interleukin-5 dimer recognition by its α receptor.

Interleukin-5 (IL-5), a major hematopoietin, stimulates eosinophil proliferation, migration, and activation, which have been implicated in the pathogenesis of allergic inflammatory diseases, such as asthma. The specific IL-5 receptor (IL-5R) consists of the IL-5 receptor α subunit (IL-5RA) and the common receptor ß subunit (ßc). IL-5 binding to IL-5R on target cells induces rapid tyrosine phosphorylation and activation of various cellular proteins, including JAK1/JAK2 and STAT1/STAT5. Here, we report the crystal structure of dimeric IL-5 in complex with the IL-5RA extracellular domains. The structure revealed that IL-5RA sandwiches the IL-5 homodimer by three tandem domains, arranged in a "wrench-like" architecture. This association mode was confirmed for human cells expressing IL-5 and the full-length IL-5RA by applying expanded genetic code technology: protein photo-cross-linking experiments revealed that the two proteins interact with each other in vivo in the same manner as that in the crystal structure. Furthermore, a comparison with the previously reported, partial GM-CSF•GM-CSFRA•ßc structure enabled us to propose complete structural models for the IL-5 and GM-CSF receptor complexes, and to identify the residues conferring the cytokine-specificities of IL-5RA and GM-CSFRA.

Crystal structure of the human receptor activity-modifying protein 1 extracellular domain.

Receptor activity-modifying protein (RAMP) 1 forms a heterodimer with calcitonin receptor-like receptor (CRLR) and regulates its transport to the cell surface. The CRLR.RAMP1 heterodimer functions as a specific receptor for calcitonin gene-related peptide (CGRP). Here, we report the crystal structure of the human RAMP1 extracellular domain. The RAMP1 structure is a three-helix bundle that is stabilized by three disulfide bonds. The RAMP1 residues important for cell-surface expression of the CRLR.RAMP1 heterodimer are clustered to form a hydrophobic patch on the molecular surface. The hydrophobic patch is located near the tryptophan residue essential for binding of the CGRP antagonist, BIBN4096BS. These results suggest that the hydrophobic patch participates in the interaction with CRLR and the formation of the ligand-binding pocket when it forms the CRLR.RAMP1 heterodimer.