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A split-intein-based method for the efficient production of circularized nanodiscs for structural studies of membrane proteins.
ChemBioChem 19, 1927-1933 (2018)
Phospholipid nanodiscs are a native-like membrane mimetic that is suitable for structural studies of membrane proteins. Although nanodiscs of different sizes exist for various structural applications, their thermal and long-term stability can vary considerably. Covalently circularized nanodiscs are a perfect tool to overcome these limitations. Existing methods for the production of circularized nanodiscs can be time-consuming and technically demanding. Therefore, an easy in vivo approach, in which circularized membrane scaffold proteins (MSPs) can be directly obtained from Escherichia coli culture, is reported herein. Nostoc punctiforme DnaE split-intein fusions with MSPs of various lengths are used and consistently provide circularized nanodiscs in high yields. With this approach, a large variety of circularized nanodiscs, ranging from 7 to 26 nm in diameter, that are suitable for NMR spectroscopy and electron microscopy (EM) applications can be prepared. These nanodiscs are superior to those of the corresponding linear versions in terms of stability and size homogeneity, which affects the quality of NMR spectroscopy data and EM experiments. Due to their long-term stability and homogeneity, the presented small circular nanodiscs are suited for high-resolution NMR spectroscopy studies, as demonstrated with two membrane proteins of 17 or 32 kDa in size. The presented method will provide easy access to circularized nanodiscs for structural studies of membrane proteins and for applications in which a defined and stable nanodisc size is required.
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2.774
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Publication type
Article: Journal article
Document type
Scientific Article
Keywords
Electron Microscopy ; Membrane Proteins ; Nanostructures ; Nmr Spectroscopy ; Structural Biology; Phospholipid-bilayer Nanodiscs; Nostoc-punctiforme; Dnae Intein; Controlled Size; Nmr; Stability; Binding; Ligand
Language
Publication Year
2018
HGF-reported in Year
2018
ISSN (print) / ISBN
1439-4227
e-ISSN
1439-7633
Journal
ChemBioChem
Quellenangaben
Volume: 19,
Issue: 18,
Pages: 1927-1933
Publisher
Wiley
Publishing Place
Postfach 101161, 69451 Weinheim, Germany
Reviewing status
Peer reviewed
Institute(s)
Institute of Structural Biology (STB)
POF-Topic(s)
30505 - New Technologies for Biomedical Discoveries
Research field(s)
Enabling and Novel Technologies
PSP Element(s)
G-553600-001
WOS ID
WOS:000444798400006
Scopus ID
85051073852
PubMed ID
29947468
Erfassungsdatum
2018-09-13