Stephan L. Grage scite author profile

Mechanosensitive channels allow bacteria to respond to osmotic stress by opening a nanometer-sized pore in the cellular membrane. Although the underlying mechanism has been thoroughly studied on the basis of individual channels, the behavior of channel ensembles has yet to be elucidated. This work reveals that mechanosensitive channels of large conductance (MscL) exhibit a tendency to spatially cluster, and demonstrates the functional relevance of clustering. We evaluated the spatial distribution of channels in a lipid bilayer using patch-clamp electrophysiology, fluorescence and atomic force microscopy, and neutron scattering and reflection techniques, coupled with mathematical modeling of the mechanics of a membrane crowded with proteins. The results indicate that MscL forms clusters under a wide range of conditions. MscL is closely packed within each cluster but is still active and mechanosensitive. However, the channel activity is modulated by the presence of neighboring proteins, indicating membrane-mediated protein-protein interactions. Collectively, these results suggest that MscL self-assembly into channel clusters plays an osmoregulatory functional role in the membrane.

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Asymmetric Molecular Friction in Supported Phospholipid Bilayers Revealed by NMR Measurements of Lipid Diffusion

Hetzer

et al. 1998

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The bilayer−substrate coupling in fluid bilayers of dipalmitoyl phosphatidylcholine (DPPC) on a solid support of spherical silica beads was examined by measuring the lateral diffusion of the lipids in both monolayers using a deuterium NMR relaxation technique. The results obtained at 55 °C show that the lipid diffusion constant in the monolayer facing the silica surface, D = 7.5 × 10-12 m2/s, is slower by a factor of 2 than that in the monolayer exposed to the bulk water (D = 14 × 10-12 m2/s). This indicates that the monolayer−monolayer coupling in fluid bilayers must be rather weak compared to the monolayer−substrate coupling across an ultrathin water film between the bilayer and the silica surface.

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Solid state 19F NMR parameters of fluorine-labeled amino acids. Part I: Aromatic substituents

Dürr

Grage²,

Witter³

et al. 2008

Journal of Magnetic Resonance

111

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Structural parameters of peptides and proteins in biomembranes can be directly measured by solid state NMR of selectively labeled amino acids. The 19F nucleus is a promising label to overcome the low sensitivity of 2H, 13C or 15N, and to serve as a background-free reporter group in biological compounds. To make the advantages of solid state 19F NMR fully available for structural studies of polypeptides, we have systematically measured the chemical shift anisotropies and relaxation properties of the most relevant aromatic and aliphatic 19F-labeled amino acids. In this first part of two consecutive contributions, six different 19F-substituents on representative aromatic side chains were characterized as polycrystalline powders by static and MAS experiments. The data are also compared with results on the same amino acids incorporated in synthetic peptides. The spectra show a wide variety of lineshapes, from which the principal values of the CSA tensors were extracted. In addition, temperature-dependent T(1) and T(2) relaxation times were determined by 19F NMR in the solid state, and isotropic chemical shifts and scalar couplings were obtained in solution.

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Fluorinated amino acids in amyloid formation: a symphony of size, hydrophobicity and α-helix propensity

et al. 2014

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Fluorinated amino acids can have dramatic effects on protein stability and protein-protein interactions due to the unique stereoelectronic properties of fluorine. Previous approaches to assessing their properties have mainly focused on helical systems, even though fluoro-amino acids are known to exhibit lower intrinsic helix propensities than their hydrocarbon analogues. Fluorination of specific b-sheet positions within globular proteins has been shown to have a stabilizing effect, suggesting that fluorinated amino acids may generally be well suitable for modulating non-helical structures. Still, fluorinated amino acids have rarely been studied in amyloid forming peptides, which take on a characteristically high cross-b-sheet content. Here, we examine the substitution of natural amino acids within an amyloid forming model peptide by amino acids that contain different stoichiometries of fluorine in their side chains. This approach enables a systematic evaluation of the impact of fluorine on amyloid formation. We have investigated the impact of size, hydrophobicity and secondary structure propensities of the fluorinated amino acids on the amyloid formation process. The structure of the model peptide is based on an engineered coiled coil folding motif that was designed to provide an a-helical starting structure that can fold into b-sheet rich amyloids under controlled conditions. Substitution with fluorinated amino acids was accomplished for two neighboring valine residues that play a key role in the structural transition. The resulting peptides show an unexpected folding behavior as a consequence of the interplay of stereoelectronic effects, helix propensity, hydrophobicity and position of the particular substitution within the amyloid forming system.

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Untitled

Salgado¹,

Grage²,

Kondejewski

et al. 2001

118

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The antimicrobial properties of the cyclic beta-sheet peptide gramicidin S are attributed to its destabilizing effect on lipid membranes. Here we present the membrane-bound structure and alignment of a derivative of this peptide, based on angular and distance constraints. Solid-state 19F-NMR was used to study a 19F-labelled gramicidin S analogue in dimyristoylphosphatidylcholine bilayers at a lipid:peptide ratio of 80:1 and above. Two equivalent leucine side chains were replaced by the non-natural amino acid 4F-phenylglycine, which serves as a highly sensitive reporter on the structure and dynamics of the peptide backbone. Using a modified CPMG multipulse sequence, the distance between the two 19F-labels was measured from their homonuclear dipolar coupling as 6 A. in good agreement with the known backbone structure of natural gramicidin S in solution. By analyzing the anisotropic chemical shift of the 19F-labels in macroscopically oriented membrane samples, we determined the alignment of the peptide in the bilayer and described its temperature-dependent mobility. In the gel phase, the 19F-labelled gramicidin S is aligned symmetrically with respect to the membrane normal, i.e., with its cyclic beta-sheet backbone lying flat in the plane of the bilayer, which is fully consistent with its amphiphilic character. Upon raising the temperature to the liquid crystalline state, a considerable narrowing of the 19F-NMR chemical shift dispersion is observed, which is attributed the onset of global rotation of the peptide and further wobbling motions. This study demonstrates the potential of the 19F nucleus to describe suitably labelled polypeptides in membranes, requiring only little material and short NMR acquisition times.

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Stephan L. Grage

Bilayer-Mediated Clustering and Functional Interaction of MscL Channels

Asymmetric Molecular Friction in Supported Phospholipid Bilayers Revealed by NMR Measurements of Lipid Diffusion

Solid state 19F NMR parameters of fluorine-labeled amino acids. Part I: Aromatic substituents

Fluorinated amino acids in amyloid formation: a symphony of size, hydrophobicity and α-helix propensity

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