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Biophys J, October 2002, p. 2084-2095, Vol. 83, No. 4
-Helices
*National High Magnetic Field Laboratory (NHMFL), Institute
of Molecular Biophysics; and Department of Chemistry and
Biochemistry, Florida State University, Tallahassee, Florida 32310 USA
Protein environments substantially influence the balance
of molecular interactions that generate structural stability.
Transmembrane helices exist in the relatively uniform low dielectric
interstices of the lipid bilayer, largely devoid of water and with a
very hydrophobic distribution of amino acid residues. Here, through an
analysis of bacteriorhodopsin crystal structures and the transmembrane helix structure from M2 protein of influenza A, some helices are shown
to be exceptionally uniform in hydrogen bond geometry, peptide plane
tilt angle, and backbone torsion angles. Evidence from both the x-ray
crystal structures and solid-state NMR structure suggests that the
intramolecular backbone hydrogen bonds are shorter than their
counterparts in water-soluble proteins. Moreover, the geometry is
consistent with a dominance of electrostatic versus covalent contributions to these bonds. A comparison of structure as a function of resolution shows that as the structures become better characterized the helices become much more uniform, suggesting that there is a
possibility that many more uniform helices will be observed, even among
the moderate resolution membrane protein structures that are currently
in the Protein Data Bank that do not show such features.
Biophys J, October 2002, p. 2084-2095, Vol. 83, No. 4
© 2002 by the Biophysical Society 0006-3495/02/10/2084/12 $2.00
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