Your search keyword '"Frömmel, Cornelius"' showing total 3 results

1. Hydrogen-bonding and packing features of membrane proteins: functional implications.

Author

Hildebrand PW, Günther S, Goede A, Forrest L, Frömmel C, and Preissner R

Subjects

Adenosine Triphosphate chemistry, Amino Acid Motifs, Animals, Entropy, Hydrogen chemistry, Molecular Conformation, Oxygen chemistry, Protein Conformation, Rabbits, Thermodynamics, Biophysics methods, Hydrogen Bonding, Membrane Proteins chemistry

Abstract

The recent structural elucidation of about one dozen channels (in which we include transporters) has provided further evidence that these membrane proteins typically undergo large movements during their function. However, it is still not well understood how these proteins achieve the necessary trade-off between stability and mobility. To identify specific structural properties of channels, we compared the helix-packing and hydrogen-bonding patterns of channels with those of membrane coils; the latter is a class of membrane proteins whose structures are expected to be more rigid. We describe in detail how in channels, helix pairs are usually arranged in packing motifs with large crossing angles (|tau| approximately 40 degrees ), where the (small) side chains point away from the packing core and the backbones of the two helices are in close contact. We found that this contributes to a significant enrichment of Calpha-H...O bonds and to a packing geometry where right-handed parallel (tau = -40 degrees +/- 10 degrees ) and antiparallel (tau = +140 degrees +/- 25 degrees ) arrangements are equally preferred. By sharp contrast, the interdigitation and hydrogen bonding of side chains in helix pairs of membrane coils results in narrowly distributed left-handed antiparallel arrangements with crossing angles tau = -160 degrees +/- 10 degrees (|tau| approximately 20 degrees ). In addition, we show that these different helix-packing modes of the two types of membrane proteins correspond to specific hydrogen-bonding patterns. In particular, in channels, three times as many of the hydrogen-bonded helix pairs are found in parallel right-handed motifs than are non-hydrogen-bonded helix pairs. Finally, we discuss how the presence of weak hydrogen bonds, water-containing cavities, and right-handed crossing angles may facilitate the required conformational flexibility between helix pairs of channels while maintaining sufficient structural stability.

Published

2008

2. Molecular packing and packing defects in helical membrane proteins.

Author

Hildebrand PW, Rother K, Goede A, Preissner R, and Frömmel C

Subjects

Computer Simulation, Ion Channels chemistry, Membrane Transport Proteins chemistry, Permeability, Porosity, Protein Conformation, Protein Structure, Secondary, Lipid Bilayers chemistry, Membrane Fluidity, Membrane Proteins chemistry, Models, Chemical, Models, Molecular, Multiprotein Complexes chemistry

Abstract

The packing of helices spanning lipid bilayers is crucial for the stability and function of alpha-helical membrane proteins. Using a modified Voronoi procedure, we calculated packing densities for helix-helix contacts in membrane spanning domains. Our results show that the transmembrane helices of protein channels and transporters are significantly more loosely packed compared with helices in globular proteins. The observed packing deficiencies of these membrane proteins are also reflected by a higher amount of cavities at functionally important sites. The cavities positioned along the gated pores of membrane channels and transporters are noticeably lined by polar amino acids that should be exposed to the aqueous medium when the protein is in the open state. In contrast, nonpolar amino acids surround the cavities in those protein regions where large rearrangements are supposed to take place, as near the hinge regions of transporters or at restriction sites of protein channels. We presume that the observed deficiencies of helix-helix packing are essential for the helical mobility that sustains the function of many membrane protein channels and transporters.

Published

2005

3. Structural features of transmembrane helices.

Author

Hildebrand PW, Preissner R, and Frömmel C

Subjects

Amino Acid Sequence, Hydrogen Bonding, Hydrophobic and Hydrophilic Interactions, Models, Molecular, Protein Structure, Secondary, X-Ray Diffraction, Membrane Proteins chemistry

Abstract

A total of 160 transmembrane helices of 15 non-homologous high-resolution X-ray protein structures have been analyzed in respect of their structural features. The dihedral angles and hydrogen bonds of the helical sections that span the hydrophobic interior of the lipid bilayer have been investigated. The Ramachandran plot of protein channels and solute transporters exhibit a significant shift Delta (phi- and psi-angles) of Delta mean (+4.5 degrees and -5.4 degrees ), compared to a reference group of 151 alpha-helices of the same average length derived from water-soluble globular proteins. At the C-termini of transmembrane helices structural motifs equivalent to the Gly-caps of helices in globular proteins have been found, with two third of the transmembrane Gly-caps taking up a primary structure that is typically not found at helix termini exposed to a polar solvent. The structural particularities reported here are relevant for the three-dimensional modelling of membrane protein structures.

Published

2004