Your search keyword '"Boyd, Lisa A."' showing total 11 results

1. An allosteric site in the T-cell receptor Cβ domain plays a critical signalling role.

Author

Natarajan, Kannan, McShan, Andrew C, Jiang, Jiansheng, Kumirov, Vlad K, Wang, Rui, Zhao, Huaying, Schuck, Peter, Tilahun, Mulualem E, Boyd, Lisa F, Ying, Jinfa, Bax, Ad, Margulies, David H, and Sgourakis, Nikolaos G

Subjects

T-Lymphocytes, Animals, Mice, Peptides, Complementarity Determining Regions, Receptors, Antigen, T-Cell, alpha-beta, Crystallography, X-Ray, Signal Transduction, Major Histocompatibility Complex, Mutagenesis, Allosteric Site, Protein Binding, Molecular Dynamics Simulation, Protein Domains, Receptors, Antigen, T-Cell, alpha-beta, Crystallography, X-Ray, 2.1 Biological and endogenous factors, 1.1 Normal biological development and functioning, Generic Health Relevance, MD Multidisciplinary

Abstract

The molecular mechanism through which the interaction of a clonotypic αβ T-cell receptor (TCR) with a peptide-loaded major histocompatibility complex (p/MHC) leads to T-cell activation is not yet fully understood. Here we exploit a high-affinity TCR (B4.2.3) to examine the structural changes that accompany binding to its p/MHC ligand (P18-I10/H2-Dd). In addition to conformational changes in complementarity-determining regions (CDRs) of the TCR seen in comparison of unliganded and bound X-ray structures, NMR characterization of the TCR β-chain dynamics reveals significant chemical shift effects in sites removed from the MHC-binding site. Remodelling of electrostatic interactions near the Cβ H3 helix at the membrane-proximal face of the TCR, a region implicated in interactions with the CD3 co-receptor, suggests a possible role for an allosteric mechanism in TCR signalling. The contribution of these TCR residues to signal transduction is supported by mutagenesis and T-cell functional assays.

Published

2017

2. Chaperone function in antigen presentation by MHC class I molecules--tapasin in the PLC and TAPBPR beyond.

Author

Margulies, David H., Jiansheng Jiang, Ahmad, Javeed, Boyd, Lisa F., and Natarajan, Kannan

Subjects

T cell receptors, ANTIGEN presentation, PEPTIDES, MOLECULAR dynamics, ALPHAVIRUSES, X-ray crystallography, MOLECULES

Abstract

Peptide loading of MHC-I molecules plays a critical role in the T cell response to infections and tumors as well as to interactions with inhibitory receptors on natural killer (NK) cells. To facilitate and optimize peptide acquisition, vertebrates have evolved specialized chaperones to stabilize MHC-I molecules during their biosynthesis and to catalyze peptide exchange favoring high affinity or optimal peptides to permit transport to the cell surface where stable peptide/MHC-I (pMHC-I) complexes are displayed and are available for interaction with T cell receptors and any of a host of inhibitory and activating receptors. Although components of the endoplasmic reticulum (ER) resident peptide loading complex (PLC) were identified some 30 years ago, the detailed biophysical parameters that govern peptide selection, binding, and surface display have recently been understood better with advances in structural methods including X-ray crystallography, cryogenic electron microscopy (cryo-EM), and computational modeling. These approaches have provided refined mechanistic illustration of the molecular events involved in the folding of the MHC-I heavy chain, its coordinate glycosylation, assembly with its light chain, b2-microglobulin (b2m), its association with the PLC, and its binding of peptides. Our current view of this important cellular process as it relates to antigen presentation to CD8+ T cells is based on many different approaches: biochemical, genetic, structural, computational, cell biological, and immunological. In this review, taking advantage of recent X-ray and cryo-EM structural evidence and molecular dynamics simulations, examined in the context of past experiments, we attempt a dispassionate evaluation of the details of peptide loading in the MHC-I pathway. By critical evaluation of several decades of investigation, we outline aspects of the peptide loading process that are well-understood and indicate those that demand further detailed investigation. Further studies should contribute not only to basic understanding, but also to applications for immunization and therapy of tumors and infections. [ABSTRACT FROM AUTHOR]

Published

2023

3. Structural mechanism of tapasin-mediated MHC-I peptide loading in antigen presentation.

Author

Jiang, Jiansheng, Taylor, Daniel K., Kim, Ellen J., Boyd, Lisa F., Ahmad, Javeed, Mage, Michael G., Truong, Hau V., Woodward, Claire H., Sgourakis, Nikolaos G., Cresswell, Peter, Margulies, David H., and Natarajan, Kannan

Subjects

PEPTIDES, ANTIGEN presentation, T cell receptors, IMMUNE recognition, CRYSTAL structure

Abstract

Loading of MHC-I molecules with peptide by the catalytic chaperone tapasin in the peptide loading complex plays a critical role in antigen presentation and immune recognition. Mechanistic insight has been hampered by the lack of detailed structural information concerning tapasin–MHC-I. We present here crystal structures of human tapasin complexed with the MHC-I molecule HLA-B*44:05, and with each of two anti-tapasin antibodies. The tapasin-stabilized peptide-receptive state of HLA-B*44:05 is characterized by distortion of the peptide binding groove and destabilization of the β2-microglobulin interaction, leading to release of peptide. Movements of the membrane proximal Ig-like domains of tapasin, HLA-B*44:05, and β2-microglobulin accompany the transition to a peptide-receptive state. Together this ensemble of crystal structures provides insights into a distinct mechanism of tapasin-mediated peptide exchange. The catalytic chaperone tapasin assists peptide loading onto MHC-I molecules for antigen presentation and immune recognition. Here, the authors present crystal structures that provide insights into the molecular mechanism of tapasin-mediated peptide exchange. [ABSTRACT FROM AUTHOR]

Published

2022

4. Chaperones and Catalysts: How Antigen Presentation Pathways Cope With Biological Necessity.

Author

Margulies, David H., Taylor, Daniel K., Jiang, Jiansheng, Boyd, Lisa F., Ahmad, Javeed, Mage, Michael G., and Natarajan, Kannan

Subjects

ANTIGEN presentation, T cell receptors, CARRIER proteins, PEPTIDES, IMMUNE recognition, T cells

Abstract

Immune recognition by T lymphocytes and natural killer (NK) cells is in large part dependent on the identification of cell surface MHC molecules bearing peptides generated from either endogenous (MHC I) or exogenous (MHC II) dependent pathways. This review focuses on MHC I molecules that coordinately fold to bind self or foreign peptides for such surface display. Peptide loading occurs in an antigen presentation pathway that includes either the multimolecular peptide loading complex (PLC) or a single chain chaperone/catalyst, TAP binding protein, related, TAPBPR, that mimics a key component of the PLC, tapasin. Recent structural and dynamic studies of TAPBPR reveal details of its function and reflect on mechanisms common to tapasin. Regions of structural conservation among species suggest that TAPBPR and tapasin have evolved to satisfy functional complexities demanded by the enormous polymorphism of MHC I molecules. Recent studies suggest that these two chaperone/catalysts exploit structural flexibility and dynamics to stabilize MHC molecules and facilitate peptide loading. [ABSTRACT FROM AUTHOR]

Published

2022

5. Alterations in the HLA-B*57:01 Immunopeptidome by Flucloxacillin and Immunogenicity of Drug-Haptenated Peptides.

Author

Puig, Montserrat, Ananthula, Suryatheja, Venna, Ramesh, Kumar Polumuri, Swamy, Mattson, Elliot, Walker, Lacey M., Cardone, Marco, Takahashi, Mayumi, Su, Shan, Boyd, Lisa F., Natarajan, Kannan, Abdoulaeva, Galina, Wu, Wells W., Roderiquez, Gregory, Hildebrand, William H., Beaucage, Serge L., Li, Zhihua, Margulies, David H., and Norcross, Michael A.

Subjects

GRAM-positive bacterial infections, PEPTIDES, HLA histocompatibility antigens, LIVER cells, KILLER cells, ANTIBIOTICS, T cells

Abstract

Neoantigen formation due to the interaction of drug molecules with human leukocyte antigen (HLA)-peptide complexes can lead to severe hypersensitivity reactions. Flucloxacillin (FLX), a β-lactam antibiotic for narrow-spectrum gram-positive bacterial infections, has been associated with severe immune-mediated drug-induced liver injury caused by an influx of T-lymphocytes targeting liver cells potentially recognizing drug-haptenated peptides in the context of HLA-B*57:01. To identify immunopeptidome changes that could lead to drug-driven immunogenicity, we used mass spectrometry to characterize the proteome and immunopeptidome of B-lymphoblastoid cells solely expressing HLA-B*57:01 as MHC-I molecules. Selected drug-conjugated peptides identified in these cells were synthesized and tested for their immunogenicity in HLA-B*57:01-transgenic mice. T cell responses were evaluated in vitro by immune assays. The immunopeptidome of FLX-treated cells was more diverse than that of untreated cells, enriched with peptides containing carboxy-terminal tryptophan and FLX-haptenated lysine residues on peptides. Selected FLX-modified peptides with drug on P4 and P6 induced drug-specific CD8+ T cells in vivo. FLX was also found directly linked to the HLA K146 that could interfere with KIR-3DL or peptide interactions. These studies identify a novel effect of antibiotics to alter anchor residue frequencies in HLA-presented peptides which may impact drug-induced inflammation. Covalent FLX-modified lysines on peptides mapped drug-specific immunogenicity primarily at P4 and P6 suggesting these peptide sites as drivers of off-target adverse reactions mediated by FLX. FLX modifications on HLA-B*57:01-exposed lysines may also impact interactions with KIR or TCR and subsequent NK and T cell function. [ABSTRACT FROM AUTHOR]

Published

2021

6. An allosteric mechanism controls antigen presentation by the H-2Kb complex.

Author

Gakamsky, Dmitry M. and Boyd, Lisa F.

Subjects

*MAJOR histocompatibility complex, *ALLOSTERIC regulation, *PEPTIDES

Abstract

Examines the mechanism of assembly/dissociation of a recombinant water-soluble class I major histocompatibility complex H-2Kb molecule. Allosteric mechanism control of interactions among the heavy chains and antigenic peptides; Effects of peptide interactions; Comparison of peptide dissociation rate.

Published

1999

7. Crystal structure of a TAPBPR–MHC I complex reveals the mechanism of peptide editing in antigen presentation.

Author

Jiansheng Jiang, Natarajan, Kannan, Boyd, Lisa F., Morozov, Giora I., Mage, Michael G., and Margulies, David H.

Subjects

*CRYSTAL structure, *HISTOCOMPATIBILITY, *CARRIER proteins, *PEPTIDES, *MAJOR histocompatibility complex, *TAPASIN

Abstract

Central to CD8+ T cell–mediated immunity is the recognition of peptide–major histocompatibility complex class I (p–MHC I) proteins displayed by antigen-presenting cells. Chaperone-mediated loading of high-affinity peptides onto MHC I is a key step in the MHC I antigen presentation pathway. However, the structure of MHC I with a chaperone that facilitates peptide loading has not been determined. We report the crystal structure of MHC I in complex with the peptide editor TAPBPR (TAP-binding protein–related), a tapasin homolog. TAPBPR remodels the peptide-binding groove of MHC I, resulting in the release of low-affinity peptide. Changes include groove relaxation, modifications of key binding pockets, and domain adjustments. This structure captures a peptide-receptive state of MHC I and provides insights into the mechanism of peptide editing by TAPBPR and, by analogy, tapasin. [ABSTRACT FROM AUTHOR]

Published

2017

8. Effects of Cross-Presentation, Antigen Processing, and Peptide Binding in HIV Evasion of T Cell Immunity.

Author

Frey, Blake F., Yongjun Sui, Billeskov, Rolf, Solaymani-Mohammadi, Shahram, Berzofsky, Jay A., Jiansheng Jiang, Boyd, Lisa F., Margulies, David H., Bin Yu, Gwen Tatsuno, and Berman, Phillip W.

Subjects

*ANTIGENS, *T cells, *PEPTIDES, *HIV prevention, *CATHEPSINS

Abstract

Unlike cytosolic processing and presentation of viral Ags by virus-infected cells, Ags first expressed in infected nonprofessional APCs, such as CD4+ T cells in the case of HIV are taken up by dendritic cells and cross-presented. This generally requires entry through the endocytic pathway, where endosomal proteases have first access for processing. Thus, understanding virus escape during cross-presentation requires an understanding of resistance to endosomal proteases, such as cathepsin S (CatS). We have modified HIV-1MN gp120 by mutating a key CatS cleavage site (Thr322Thr323) in the V3 loop of the immunodominant epitope IGPGRAFYTT to IGPGRAFYVV to prevent digestion. We found this mutation to facilitate cross-presentation and provide evidence from MHC binding and X-ray crystallographic structural studies that this results from preservation of the epitope rather than an increased epitope affinity for the MHC class I molecule. In contrast, when the protein is expressed by a vaccinia virus in the cytosol, the wild-type protein is immunogenic without this mutation. These proof-of-concept results show that a virus like HIV, infecting predominantly nonprofessional presenting cells, can escape T cell recognition by incorporating a CatS cleavage site that leads to destruction of an immunodominant epitope when the Ag undergoes endosomal cross-presentation. [ABSTRACT FROM AUTHOR]

Published

2018

9. Enzymatic processing and MHC loading 3Molecular mechanisms of chaperone-mediated MHC-I peptide loading.

Author

Margulies, David, Jiang, Jiansheng, Natarajan, Kannan, Boyd, Lisa, Mage, Michael, Kim, Ellen, Ingram, Jessica, McShan, Andrew, and Sgourakis, Nikolaos

Subjects

*T cell receptors, *PEPTIDES, *HISTOCOMPATIBILITY class I antigens, *CARRIER proteins, *NUCLEAR magnetic resonance, *PROTEIN folding

Abstract

Peptide loading of MHC-I molecules occurs as a result of dynamic protein folding and assembly processes involving not only the MHC-I heavy chain, the light chain, beta 2-m, and antigenic peptide, but also the components of the peptide loading complex (PLC), including tapasin, as well as the PLC-independent chaperone, TAP binding protein, related (TAPBPR). Structural studies of tapasin and TAPBPR reveal that these, like many other proteins, contain both well-ordered domains as well as regions of disorder. To examine the contributions of disordered regions of both MHC-I molecules and of TAPBPR, we have examined X-ray structures of MHC-I molecules assembled with disulfide linked truncated peptides, of TAPBPR/MHC-I complexes containing truncated peptides, and of nanobody/TAPBPR complexes. Different disordered regions of TAPBPR rigidify on interaction with MHC-I or with specific nanobodies. Conversely, the peptide binding groove of MHC-I structurally rearranges on interaction with TAPBPR. These observations are consistent with solution nuclear magnetic resonance (NMR) spectroscopy data examining the interaction of TAPBPR with isotope-labeled peptide-MHC-I complexes. The dynamic NMR data reveal a transient pMHC-I/TAPBPR intermediate that controls the selection of high-affinity peptides. We propose a model of negative allosteric coupling that involves the entire peptide binding groove. Such a model, based primarily on observations of TAPBPR should be applicable to tapasin in the PLC as well. [ABSTRACT FROM AUTHOR]

Published

2022

10. The Peptide-Receptive Transition State of MHC Class I Molecules: Insight from Structure and Molecular Dynamics.

Author

Mage, Michael G., Dolan, Michael A., Rui Wang, Boyd, Lisa F., Revilleza, Maria Jamela, Robinson, Howard, Natarajan, Kannan, Myers, Nancy B., Hansen, Ted H., and Margulies, David H.

Subjects

*MAJOR histocompatibility complex, *MOLECULAR dynamics, *MOLECULAR structure, *IMMUNE system, *CONFORMATIONAL analysis, *PEPTIDES, *ENDOPLASMIC reticulum

Abstract

MHC class I (MHC-I) proteins of the adaptive immune system require antigenic peptides for maintenance of mature conformation and immune function via specific recognition by MHC-I-restricted CD8+ T lymphocytes. New MHC-I molecules in the endoplasmic reticulum are held by chaperones in a peptide-receptive (PR) transition state pending release by tightly binding peptides. In this study, we show, by crystallographic, docking, and molecular dynamics methods, dramatic movement of a hinged unit containing a conserved 310 helix that flips from an exposed "open" position in the PR transition state to a "closed" position with buried hydrophobic side chains in the peptide-loaded mature molecule. Crystallography of hinged unit residues 46-53 of murine H-2Ld MHC-I H chain, complexed with mAb 64-3-7, demonstrates solvent exposure of these residues in the PR conformation. Docking and molecular dynamics predict how this segment moves to help form the A and B pockets crucial for the tight peptide binding needed for stability of the mature peptide-loaded conformation, chaperone dissociation, and Ag presentation. The Journal of Immunology, 2012, 189: 1391-1399. [ABSTRACT FROM AUTHOR]

Published

2012

11. A structural and molecular dynamics approach to understanding the peptide-receptive transition state of MHC-I molecules

Author

Mage, Michael G., Dolan, Michael A., Wang, Rui, Boyd, Lisa F., Revilleza, Maria Jamela, Robinson, Howard, Natarajan, Kannan, Myers, Nancy B., Hansen, Ted H., and Margulies, David H.

Subjects

*MOLECULAR dynamics, *PEPTIDES, *MAJOR histocompatibility complex, *CELL surface antigens, *CD8 antigen, *MOLECULAR chaperones, *T cells

Abstract

Abstract: The mature conformation of major histocompatibility complex class I (MHC-I) proteins depends on the presence of bound peptides, permitting recognition at the cell surface by CD8+ T lymphocytes. Newly synthesized MHC-I molecules in the endoplasmic reticulum are maintained in a peptide-receptive (PR) transition state by several chaperones until they are released concomitant with the loading of peptides. By determining the crystallographic structure of a region of an MHC-I molecule that is recognized by a unique monoclonal antibody and comparing this with docking and molecular dynamics simulations with the whole molecule, we demonstrate the movement of a hinged unit supporting the part of the binding groove that interacts with the amino terminal residues of the bound peptide. This unit contains a conserved 310 helix that flips from an exposed “open” position in the PR form to a “closed” position in the peptide-loaded (PL) mature molecule. These analyses indicate how this segment of the MHC-I molecule moves to help establish the A and B pockets critical for tight peptide binding and the stable structure required for antigen presentation and T cell recognition at the cell surface. [Copyright &y& Elsevier]

Published

2013