Lipid-Protein Nanodiscs Offer New Perspectives for Structural and Functional Studies of Water-Soluble Membrane-Active Peptides

Шенкарев, Захар О.; Lyukmanova, Ekaterina N.; Paramonov, Alexander S.; Panteleev, Pavel V.; Balandin, Sergey V.; Shulepko, Mikhail A.; Mineev, K.S.; Ovchinnikova, T. M.; Кирпичников, М. П.; Arseniev, A.S.

doi:10.32607/20758251-2014-6-2-84-94

Cited by 23 publications

(27 citation statements)

References 34 publications

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“…This presents a nice prospect for the use of LPNs as a membrane mimetic for structural studies of multidomain membrane proteins, especially since LPNs have been shown to be a perfect medium for the refolding of membrane proteins (32). Nanodiscs were first proposed as a reference medium for detergent screening (28) or as a possible environment in which to study the topology of small peptides in the membrane (33)(34)(35)(36); however, recent advances, such as the development of new MSPs that form smaller discoid particles (up to~50 kDa) (31), isotope labeling strategies, and NMR experimental techniques have also made them applicable for structural studies of membrane proteins (37). In this work, we show that a transmembrane protein with a relatively large water-soluble domain (p75-DECD) can be incorporated into LPNs of various sizes and studied by the conventional means of solution NMR spectroscopy to obtain biologically relevant structural data.…”

Section: Nanodiscs As a Versatile Medium For Structural And Functionamentioning

confidence: 98%

NMR Dynamics of Transmembrane and Intracellular Domains of p75NTR in Lipid-Protein Nanodiscs

Mineev

Goncharuk

Kuzmichev

et al. 2015

Biophysical Journal

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P75NTR is a type I integral membrane protein that plays a key role in neurotrophin signaling. However, structural data for the receptor in various functional states are sparse and controversial. In this work, we studied the spatial structure and mobility of the transmembrane and intracellular parts of p75NTR, incorporated into lipid-protein nanodiscs of various sizes and compositions, by solution NMR spectroscopy. Our data reveal a high level of flexibility and disorder in the juxtamembrane chopper domain of p75NTR, which results in the motions of the receptor death domain being uncoupled from the motions of the transmembrane helix. Moreover, none of the intracellular domains of p75NTR demonstrated a propensity to interact with the membrane or to self-associate under the experimental conditions. The obtained data are discussed in the context of the receptor activation mechanism.

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Section: Nanodiscs As a Versatile Medium For Structural And Functionamentioning

confidence: 98%

NMR Dynamics of Transmembrane and Intracellular Domains of p75NTR in Lipid-Protein Nanodiscs

Mineev

Goncharuk

Kuzmichev

et al. 2015

Biophysical Journal

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“…However, this assembled structure is only stable when a secondary amphiphile is added that can bind to the high curvature edges. In this case, helical lipoproteins called membrane scaffolding proteins (MSPs) have been shown to efficiently bind to the sides of lamellar sheets to generate nanodisc structures that are alone highly stable [196]. This combination of phospholipids and MSPs efficiently coat all sides of a nanoplatelet, with different adsorbates localizing to different regions depending on curvature (Fig.…”

Section: Surface Engineering For Biomedical Applicationsmentioning

confidence: 99%

Quantum dot surface engineering: Toward inert fluorophores with compact size and bright, stable emission

Lim

Schleife

et al. 2016

Coordination Chemistry Reviews

109

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The surfaces of colloidal nanocrystals are complex interfaces between solid crystals, coordinating ligands, and liquid solutions. For fluorescent quantum dots, the properties of the surface vastly influence the efficiency of light emission, stability, and physical interactions, and thus determine their sensitivity and specificity when they are used to detect and image biological molecules. But after more than 30 years of study, the surfaces of quantum dots remain poorly understood and continue to be an important subject of both experimental and theoretical research. In this article, we review the physics and chemistry of quantum dot surfaces and describe approaches to engineer optimal fluorescent probes for applications in biomolecular imaging and sensing. We describe the structure and electronic properties of crystalline facets, the chemistry of ligand coordination, and the impact of ligands on optical properties. We further describe recent advances in compact coatings that have significantly improved their properties by providing small hydrodynamic size, high stability and fluorescence efficiency, and minimal nonspecific interactions with cells and biological molecules. While major progress has been made in both basic and applied research, many questions remain in the chemistry and physics of quantum dot surfaces that have hindered key breakthroughs to fully optimize their properties.

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“…Nanodiscs with different lipid composition have been used to study membrane‐bound active peptides . In a recent work, the authors showed that arenicin‐2, a pore‐forming antimicrobial peptide, disintegrates nanodiscs containing both zwitterionic phosphatidylcholine (PC) and anionic phosphatidylglycerol (PG).…”

Section: Biophysical Studies Of Membrane Proteins In Nanodiscsmentioning

confidence: 99%

“…This is due to the propensity of membrane proteins to aggregate outside a membrane environment during their isolation from membranes using detergents. Therefore, in recent years, several lipid membrane mimics were developed in order to facilitate interrogation of membrane proteins by rigorous biophysical and analytical techniques. In 2002, Sligar and coworkers at the University of Illinois at Urbana‐Champaign developed a new technology termed as nanodiscs based on previous experimentation with ApoA1 and synthetic phospholipids .…”

Section: Introduction To Nanodisc Technologymentioning

confidence: 99%

Recent advances in nanodisc technology for membrane protein studies (2012–2017)

et al. 2017

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Historically, progress in membrane protein research has been hindered due to solubility issues. The introduction of biomembrane mimetics has since stimulated the field’s momentum. One mimetic, the nanodisc, has proved to be an exceptional system for solubilizing membrane proteins. Herein, we critically evaluate the advantages and imperfections from employing nanodiscs in biophysical and biochemical studies. Specifically, we examine the techniques that have been modified to study membrane proteins in nanodiscs. Techniques discussed include fluorescence microscopy, solution state/solid state NMR, electron microscopy, SAXS, and several mass spectroscopy methods. Newer techniques such as SPR, charge sensitive optical detection, and scintillation proximity assays are also reviewed. Lastly, we cover nanodiscs advancing nanotechnology through nanoplasmonic biosensing, lipoprotein-nanoplatelets, and sortase-mediated labeling of nanodiscs.

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Lipid-Protein Nanodiscs Offer New Perspectives for Structural and Functional Studies of Water-Soluble Membrane-Active Peptides

Cited by 23 publications

References 34 publications

NMR Dynamics of Transmembrane and Intracellular Domains of p75NTR in Lipid-Protein Nanodiscs

NMR Dynamics of Transmembrane and Intracellular Domains of p75NTR in Lipid-Protein Nanodiscs

Quantum dot surface engineering: Toward inert fluorophores with compact size and bright, stable emission

Recent advances in nanodisc technology for membrane protein studies (2012–2017)

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