Diphytanoylphosphatidylcholine
(DPhPC) is a synthetic phospholipid
in which two methyl-branched acyl chains are introduced into the glycerol
moiety, mimicking phospholipids of eukaryotic and eubacterial origins.
The lipid bilayers of DPhPC reproduce the outstanding physical properties
of methyl-branched lipids that occur in archaeal membranes. DPhPC
is commonly used as the base lipid in biophysical experiments, particularly
for recording ion-channel currents. However, the dynamics of lipid
molecules that induces their useful physical properties is still unclear.
In this study, we examined the conformation and orientation of the
methyl-branched acyl chain of DPhPC in a membrane using 2H nuclear magnetic resonance (NMR) measurements of the synthetic
lipid with a high stereochemical purity and molecular dynamics (MD)
simulations. Deuterium-labeled 3′,3′-CD3,D-DPhPC
(2) and 7′,7′-CD3,D-DPhPC (3) showed the characteristic quadrupole splitting width in
the 2H NMR spectra, which corresponded to the bent orientation
reported for the archaeal lipid PGP-Me [Yamagami, M., et al. (2019) Biochemistry58, 3869–3879]. However,
MD simulations, which reproduced the 2H NMR results well,
unveiled the unknown features of DPhPC in the membrane; DPhPC has
a chain-specific average orientation, where two bent orientations
with upward and downward methyl groups occur at positions C3 and C7
of the sn-1 and sn-2 chains of DPhPC,
respectively. These MD and NMR results reveal that these two bent
orientations define the average orientation of DPhPC for the shallow
part of the acyl chains, which is considered to be an important factor
in the stability of DPhPC membranes.