Karsten Mörs scite author profile

NMR structural studies of membrane proteins (MP) are hampered by complications in MP expression, technical difficulties associated with the slow process of NMR spectral peak assignment, and limited distance information obtainable for transmembrane (TM) helices. To overcome the inherent challenges in the determination of MP structures, we have developed a rapid and cost-efficient strategy that combines cell-free (CF) protein synthesis, optimized combinatorial dual-isotope labeling for nearly instant resonance assignment, and fast acquisition of long-distance information using paramagnetic probes. Here we report three backbone structures for the TM domains of the three classes of Escherichia coli histidine kinase receptors (HKRs). The ArcB and QseC TM domains are both two-helical motifs, whereas the KdpD TM domain comprises a four-helical bundle with shorter second and third helices. The interhelical distances (up to 12 Å) reveal weak interactions within the TM domains of all three receptors. Determined consecutively within 8 months, these structures offer insight into the abundant and underrepresented in the Protein Data Bank class of 2-4 TM crossers and demonstrate the efficiency of our CF combinatorial dual-labeling strategy, which can be applied to solve MP structures in high numbers and at a high speed. Our results greatly expand the current knowledge of HKR structure, opening the doors to studies on their widespread and pharmaceutically important bacterial signaling mechanism.backbone NMR structure | cell-free synthesis | combinatorial selective labeling

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Modified lipid and protein dynamics in nanodiscs

Mörs

Roos

Scholz

et al. 2013

Biochimica et Biophysica Acta (BBA) - Biomembranes

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For membrane protein studies, nanodiscs have been shown to hold great potential in terms of preparing soluble samples while maintaining a lipid environment. Here, we describe the differences in lipid order and protein dynamics in MSP1 nanodiscs compared to lamellar preparations by solid-state NMR. For DMPC, an increase of the dipolar C-H lipid acyl chain order parameters in nanodiscs is observed in both gel- and liquid crystalline phases. Incorporating proteorhodopsin in these nanodiscs resulted in a significantly longer rotating frame spin-lattice relaxation time for (13)C leerzeichen and better cross polarisation efficiency due to restricted protein dynamics. A comparison of (13)C-(13)C correlation spectra revealed no structural differences. The incorporation of proteorhodopsin into nanodiscs has been optimised with respect to detergent and to protein/scaffold protein/lipid stoichiometries. Its functional state was probed by time-resolved optical spectroscopy revealing only minor differences between lamellar and nanodisc preparations. Our observations show remarkable dynamic effects between membrane proteins, lipids and scaffold protein. The potential use of nanodiscs for solid-state NMR applications is discussed.

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How to Investigate Interactions Between Membrane Proteins and Ligands by Solid-State NMR

Lakatos

Mörs

Glaubitz

2012

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Solid-state NMR is an established method for biophysical studies of membrane proteins within the lipid bilayers and an emerging technique for structural biology in general. In particular magic angle sample spinning has been found to be very useful for the investigation of large membrane proteins and their interaction with small molecules within the lipid bilayer. Using a number of examples, we illustrate and discuss in this chapter, which information can be gained and which experimental parameters need to be considered when planning such experiments. We focus especially on the interaction of diffusive ligands with membrane proteins.

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A lipid-dependent link between activity and oligomerization state of the M. tuberculosis SMR protein TBsmr

Mörs

Hellmich

Basting

et al. 2013

Biochimica et Biophysica Acta (BBA) - Biomembranes

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TBsmr is a secondary active multidrug transporter from Mycobacterium tuberculosis that transports a plethora of compounds including antibiotics and fluorescent dyes. It belongs to the small multidrug resistance (SMR) superfamily and is structurally and functionally related to E. coli EmrE. Of particular importance is the link between protein function, oligomeric state and lipid composition. By freeze fracture EM, we found three different size distributions in three different lipid environments for TBsmr indicating different oligomeric states. The link of these states with protein activity has been probed by fluorescence spectroscopy revealing significant differences. The drug binding site has been probed further by (19)F-MAS NMR through chemical labeling of native cysteine residues showing a water accessible environment in agreement with the alternating access model.

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Morphological Differences between β₂‐Microglobulin in Fibrils and Inclusion Bodies

et al. 2011

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Over expression of proteins in E. coli frequently results in the production of inclusion bodies. Although β2‐microglobulin frequently forms fibrillar structures, our studies reveal significant differences between the protein in fibrils and inclusion bodies. This suggests that the formation of fibrils in inclusion bodies is dependent on the propensity of the protein to form fibrillar structures.

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Karsten Mörs

Membrane domain structures of three classes of histidine kinase receptors by cell-free expression and rapid NMR analysis

Modified lipid and protein dynamics in nanodiscs

How to Investigate Interactions Between Membrane Proteins and Ligands by Solid-State NMR

A lipid-dependent link between activity and oligomerization state of the M. tuberculosis SMR protein TBsmr

Morphological Differences between β₂‐Microglobulin in Fibrils and Inclusion Bodies

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Karsten Mörs

Membrane domain structures of three classes of histidine kinase receptors by cell-free expression and rapid NMR analysis

Modified lipid and protein dynamics in nanodiscs

How to Investigate Interactions Between Membrane Proteins and Ligands by Solid-State NMR

A lipid-dependent link between activity and oligomerization state of the M. tuberculosis SMR protein TBsmr

Morphological Differences between β2‐Microglobulin in Fibrils and Inclusion Bodies

Contact Info

Product

Resources

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Morphological Differences between β₂‐Microglobulin in Fibrils and Inclusion Bodies