Membrane protein structure from rotational diffusion

Das, Bidisa; Park, Sang Ho; Opella, Stanley J.

doi:10.1016/j.bbamem.2014.04.002

Cited by 28 publications

(28 citation statements)

References 139 publications

(207 reference statements)

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“…For the DQ complexes: CDR2 contacts range is 2-helix a.a. E69 to a.a. D76; CDR2: Q57 to H68 (Table 1D). Thus, we hypothesized that if these helical a.a. are indeed swept/scanned by CDR2 of the V-domain, that we should be able to model such with integration from spherical coordinates in each structure [25][26][27][28]. To normalize the equation across structures and use the geometry, the central cysteine (C22/23) was chosen as a point rotating from the fixed across-the-groove a.a. position that defines twist, tilt, and sway (Figs.…”

Section: Triple Integralsmentioning

confidence: 99%

CDR3 binding chemistry controls TCR V-domain rotational probability and germline CDR2 scanning of polymorphic MHC

Js¹

2019

Preprint

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The mechanism which 'adapts' the T-cell antigen receptor (TCR) repertoire within a given major histocompatibility complex (MHC; HLA, in humans) genotype is essential for protection against rapidly dividing pathogens. Historically attributed to relative affinity, genetically vast TCRs are surprisingly "focused" towards a micromolar affinity for their respective pHLA ligands. Thus, the somatic diversity of the TCR with respect to MHC restriction, and (ultimately) to pathogens, remains enigmatic. Here, we derive a triple integral equation (from fixed geometry) for any given V-domain in TCR bound to pMHC. We examined solved complexes involving HLA-DR and HLA-DQ, where all the available structures are still reasonably analysed. Certain V-beta domains displayed "rare" geometry within this panelspecifying a very low ("highly-restricted") rotational probability/volumetric density (dV). Remarkably, hydrogen (H)-bond charge-relays spanning CDR3-beta, the peptide, and polymorphic MHC distinguished these structures from the others; suggesting that CDR3 binding chemistry dictates CDR2 'scanning' on the respective MHC-II alpha-helix. Taken together, this analysis (n = 38 V-domains) supports a novel geometric theory for MHC restriction-one not constrained by a thymus "optimized" TCR-affinity.

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Section: Triple Integralsmentioning

confidence: 99%

CDR3 binding chemistry controls TCR V-domain rotational probability and germline CDR2 scanning of polymorphic MHC

Js¹

2019

Preprint

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“…Solid-state NMR spectroscopy enables studies of the structure and dynamics of membrane proteins in near-native phospholipid bilayer environments (37)(38)(39)(40). There are several examples where solid-state NMR methods have been used to characterize the structures of ligands bound to GPCRs (41)(42)(43)(44) as well as GPCRs themselves.…”

Section: Introductionmentioning

confidence: 99%

Interaction of Monomeric Interleukin-8 with CXCR1 Mapped by Proton-Detected Fast MAS Solid-State NMR

Park

Berkamp

Radoicic

et al. 2017

Biophysical Journal

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The human chemokine interleukin-8 (IL-8; CXCL8) is a key mediator of innate immune and inflammatory responses. This small, soluble protein triggers a host of biological effects upon binding and activating CXCR1, a G proteincoupled receptor, located in the cell membrane of neutrophils. Here, we describe 1 H-detected magic angle spinning solid-state NMR studies of monomeric IL-8 (1-66) bound to full-length and truncated constructs of CXCR1 in phospholipid bilayers under physiological conditions. Cross-polarization experiments demonstrate that most backbone amide sites of IL-8 (1-66) are immobilized and that their chemical shifts are perturbed upon binding to CXCR1, demonstrating that the dynamics and environments of chemokine residues are affected by interactions with the chemokine receptor. Comparisons of spectra of IL-8 (1-66) bound to full-length CXCR1 (1-350) and to N-terminal truncated construct NT-CXCR1 (39-350) identify specific chemokine residues involved in interactions with binding sites associated with N-terminal residues (binding site-I) and extracellular loop and helical residues (binding site-II) of the receptor. Intermolecular paramagnetic relaxation enhancement broadening of IL-8 (1-66) signals results from interactions of the chemokine with CXCR1 (1-350) containing Mn 2þ chelated to an unnatural amino acid assists in the characterization of the receptor-bound form of the chemokine.

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“…Better structural knowledge of membrane protein systems is also crucial to our understanding of the basic mechanisms of disease pathways and benefit novel clinical therapy development (Rask-Andersen, Almén, & Schioth, 2011; Shukla, Vaitiekunas, & Cotter, 2012). Despite the abundance and importance of membrane proteins, there is very limited knowledge about structure, function, and dynamics of these complicated biological systems (Das, Park, & Opella, 2015; Kang, Lee, & Drew, 2013). …”

Section: Introductionmentioning

confidence: 99%

Determining the Secondary Structure of Membrane Proteins and Peptides Via Electron Spin Echo Envelope Modulation (ESEEM) Spectroscopy

Liu

Mayo

Sahu

et al. 2015

Methods in Enzymology

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Revealing detailed structural and dynamic information of membrane embedded or associated proteins is challenging due to their hydrophobic nature which makes NMR and X-ray crystallographic studies challenging or impossible. Electron paramagnetic resonance (EPR) has emerged as a powerful technique to provide essential structural and dynamic information for membrane proteins with no size limitations in membrane systems which mimic their natural lipid bilayer environment. Therefore, tremendous efforts have been devoted toward the development and application of EPR spectroscopic techniques to study the structure of biological systems such as membrane proteins and peptides. This chapter introduces a novel approach established and developed in the Lorigan lab to investigate membrane protein and peptide local secondary structures utilizing the pulsed EPR technique electron spin echo envelope modulation (ESEEM) spectroscopy. Detailed sample preparation strategies in model membrane protein systems and the experimental setup are described. Also, the ability of this approach to identify local secondary structure of membrane proteins and peptides with unprecedented efficiency is demonstrated in model systems. Finally, applications and further developments of this ESEEM approach for probing larger size membrane proteins produced by over-expression systems are discussed.

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Membrane protein structure from rotational diffusion

Cited by 28 publications

References 139 publications

CDR3 binding chemistry controls TCR V-domain rotational probability and germline CDR2 scanning of polymorphic MHC

CDR3 binding chemistry controls TCR V-domain rotational probability and germline CDR2 scanning of polymorphic MHC

Interaction of Monomeric Interleukin-8 with CXCR1 Mapped by Proton-Detected Fast MAS Solid-State NMR

Determining the Secondary Structure of Membrane Proteins and Peptides Via Electron Spin Echo Envelope Modulation (ESEEM) Spectroscopy

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