Cj. Russell et al., The membrane affinities of the aliphatic amino acid side chains in an alpha-helical context are independent of membrane immersion depth, BIOCHEM, 38(1), 1999, pp. 337-346
Understanding, predicting, and designing the binding of peptides and protei
ns to bilayers require quantifying the intrinsic propensities of individual
amino acid residues to bind membranes as a function of structural context
and bilayer depth. A host-guest study was performed using the peptide host
named helix5 in order to determine the membrane affinities of the aliphatic
side chains both in an alpha-helical context and as a function of bilayer
depth. Use of the alpha-helical host with a constrained geometry allowed th
e placement of guest sites at three different depths in bilayers and minimi
zed secondary structural changes due to guest substitutions. Circular dichr
oism and electron paramagnetic resonance (EPR) were used to characterize th
e aqueous and bilayer-bound structures of the peptide variants. EPR was als
o used to measure the bilayer-water partition constants of the peptide vari
ants, and the Delta Delta G(tr) values (relative to Gly) of the aliphatic a
mino acid side chains were subsequently calculated. Surprisingly, the Delta
Delta G(tr) values did not significantly vary as a function of the guest s
ite depth in bilayers. In addition, the Delta Delta G(tr) values determined
in an alpha-helical context are reduced to approximately two-thirds of Del
ta Delta G(tr) values determined in other studies for the bilayer-water and
octanol-water partitioning of amino acid side chains in extended and unstr
uctured hosts. Both the relative reduction in Delta Delta G(tr) values in t
he context of an alpha-helical host and the invariance of Delta Delta G(tr)
values with respect to bilayer depth are consistent with the membrane affi
nities of the aliphatic residues being largely determined by the classical
hydrophobic effect.