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Helical Membrane Proteins (helical + membrane_protein)

Distribution by Scientific Domains

Chemistry	100%

Selected Abstracts

Dissecting membrane protein architecture: An annotation of structural complexity

BIOPOLYMERS, Issue 10 2009
Jaime Arce
Abstract ,-Helical membrane proteins exist in an anisotropic environment which strongly influences their folding, stability, and architecture, which is far more complex than a simple bundle of transmembrane helices, notably due to helix deformations, prosthetic groups and extramembrane structures. However, the role and the distribution of such heterogeneity in the supra molecular organization of membrane proteins remains poorly investigated. Using a nonredundant subset of ,-helical membrane proteins, we have annotated and analyze the statistics of several types of new elements such as incomplete helices, intramembrane loops, helical extensions of helical transmembrane domains, extracellular loops, and helices lying parallel to the membrane surface. The relevance of the annotation scheme was studied using residue composition, statistics, physical chemistry, and symmetry of their distribution in relation to the immediate membrane environment. Calculation of hydrophobicity using different scales show that different structural elements appear to have affinities coherent with their position in the membrane. Examination of the annotation scheme suggests that there is considerable information content in the amino acid compositions of the different elements suggesting that it might be useful for structural prediction. More importantly, the proposed annotation will help to decipher the complex hierarchy of interactions involved in membrane protein architecture. © 2009 Wiley Periodicals, Inc. Biopolymers 91: 815,829, 2009. This article was originally published online as an accepted preprint. The "Published Online" date corresponds to the preprint version. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com [source]

Tailoring 13C labeling for triple-resonance solid-state NMR experiments on aligned samples of proteins

MAGNETIC RESONANCE IN CHEMISTRY, Issue S1 2007
Neeraj Sinha
Abstract In order to develop triple-resonance solid-state NMR spectroscopy of membrane proteins, we have implemented several different 13C labeling schemes with the purpose of overcoming the interfering effects of 13C13C dipole,dipole couplings in stationary samples. The membrane-bound form of the major coat protein of the filamentous bacteriophage Pf1 was used as an example of a well-characterized helical membrane protein. Aligned protein samples randomly enriched to 35% 13C in all sites and metabolically labeled from bacterial growth on media containing [2- 13C]-glycerol or [1,3- 13C]-glycerol enables direct 13C detection in solid-state NMR experiments without the need for homonuclear 13C13C dipole,dipole decoupling. The 13C-detected NMR spectra of Pf1 coat protein show a substantial increase in sensitivity compared to the equivalent 15N-detected spectra. The isotopic labeling pattern was analyzed for [2- 13C]-glycerol and [1,3- 13C]-glycerol as metabolic precursors by solution-state NMR of micelle samples. Polarization inversion spin exchange at the magic angle (PISEMA) and other solid-state NMR experiments work well on 35% random fractionally and metabolically tailored 13C-labeled samples, in contrast to their failure with conventional 100% uniformly 13C-labeled samples. Copyright © 2007 John Wiley & Sons, Ltd. [source]

Asymmetric amino acid compositions of transmembrane ,-strands

PROTEIN SCIENCE, Issue 8 2004
Aaron K. Chamberlain
Abstract In contrast to water-soluble proteins, membrane proteins reside in a heterogeneous environment, and their surfaces must interact with both polar and apolar membrane regions. As a consequence, the composition of membrane proteins' residues varies substantially between the membrane core and the interfacial regions. The amino acid compositions of helical membrane proteins are also known to be different on the cytoplasmic and extracellular sides of the membrane. Here we report that in the 16 transmembrane ,-barrel structures, the amino acid compositions of lipid-facing residues are different near the N and C termini of the individual strands. Polar amino acids are more prevalent near the C termini than near the N termini, and hydrophobic amino acids show the opposite trend. We suggest that this difference arises because it is easier for polar atoms to escape from the apolar regions of the bilayer at the C terminus of a ,-strand. This new characteristic of ,-barrel membrane proteins enhances our understanding of how a sequence encodes a membrane protein structure and should prove useful in identifying and predicting the structures of trans-membrane ,-barrels. [source]

How do helix,helix interactions help determine the folds of membrane proteins?

PROTEIN SCIENCE, Issue 4 2003
Perspectives from the study of homo-oligomeric helical bundles
FRET, fluorescence resonance energy transfer; NBD, 7-nitrobenz-2-oxa-1,3-diazole; C-14 betaine, N -tetradecyl- N,N -dimethyl-3-ammonio-1-propanesulfonate; MF, mole fraction Abstract The final, structure-determining step in the folding of membrane proteins involves the coalescence of preformed transmembrane helices to form the native tertiary structure. Here, we review recent studies on small peptide and protein systems that are providing quantitative data on the interactions that drive this process. Gel electrophoresis, analytical ultracentrifugation, and fluorescence resonance energy transfer (FRET) are useful methods for examining the assembly of homo-oligomeric transmembrane helical proteins. These methods have been used to study the assembly of the M2 proton channel from influenza A virus, glycophorin, phospholamban, and several designed membrane proteins,all of which have a single transmembrane helix that is sufficient for association into a transmembrane helical bundle. These systems are being studied to determine the relative thermodynamic contributions of van der Waals interactions, conformational entropy, and polar interactions in the stabilization of membrane proteins. Although the database of thermodynamic information is not yet large, a few generalities are beginning to emerge concerning the energetic differences between membrane and water-soluble proteins: the packing of apolar side chains in the interior of helical membrane proteins plays a smaller, but nevertheless significant, role in stabilizing their structure. Polar, hydrogen-bonded interactions occur less frequently, but, nevertheless, they often provide a strong driving force for folding helix,helix pairs in membrane proteins. These studies are laying the groundwork for the design of sequence motifs that dictate the association of membrane helices. [source]