We study fully hydrated bilayers of two di-monounsaturated phospholipids diC18:1PC (DOPC) and
diC22:1PC with varying amounts of alamethicin (Alm). We combine the use of X-ray diffuse scattering
and molecular dynamics simulations to determine the orientation of alamethicin in model lipids.
Comparison of the experimental and simulated form factors shows that Alm helices are inserted
transmembrane at high humidity and high concentrations, in agreement with earlier results. The X-ray
scattering data and the MD simulations agree that membrane thickness changes very little up to 1/10 Alm/
DOPC. In contrast, the X-ray data indicate that the thicker diC22:1PC membrane thins with added Alm, a total
decrease in thickness of 4 Å at 1/10 Alm/diC22:1PC. The different effect of Alm on the thickness changes of
the two bilayers is consistent with Alm having a hydrophobic thickness close to the hydrophobic thickness of
27 Å for DOPC; Alm is then mismatched with the 7 Å thicker diC22:1PC bilayer. The X-ray data indicate that
Alm decreases the bending modulus (KC) by a factor of ∼2 in DOPC and a factor of ∼10 in diC22:1PC
membranes (P/L ∼1/10). The van der Waals and fluctuational interactions between bilayers are also
evaluated through determination of the anisotropic B compressibility modulus.