2 research outputs found
Fate of Liposomes in the Presence of Phospholipase C and D: From Atomic to Supramolecular Lipid Arrangement
Understanding the
origins of lipid membrane bilayer rearrangement
in response to external stimuli is an essential component of cell
biology and the bottom-up design of liposomes for biomedical applications.
The enzymes phospholipase C and D (PLC and PLD) both cleave the phosphorus–oxygen
bonds of phosphate esters in phosphatidylcholine (PC) lipids. The
atomic position of this hydrolysis reaction has huge implications
for the stability of PC-containing self-assembled structures, such
as the cell wall and lipid-based vesicle drug delivery vectors. While
PLC converts PC to diacylglycerol (DAG), the interaction of PC with
PLD produces phosphatidic acid (PA). Here we present a combination
of small-angle scattering data and all-atom molecular dynamics simulations,
providing insights into the effects of atomic-scale reorganization
on the supramolecular assembly of PC membrane bilayers upon enzyme-mediated
incorporation of DAG or PA. We observed that PC liposomes completely
disintegrate in the presence of PLC, as conversion of PC to DAG progresses.
At lower concentrations, DAG molecules within fluid PC bilayers form
hydrogen bonds with backbone carbonyl oxygens in neighboring PC molecules
and burrow into the hydrophobic region. This leads initially to membrane
thinning followed by a swelling of the lamellar phase with increased
DAG. At higher DAG concentrations, localized membrane tension causes
a change in lipid phase from lamellar to the hexagonal and micellar
cubic phases. Molecular dynamics simulations show that this destabilization
is also caused in part by the decreased ability of DAG-containing
PC membranes to coordinate sodium ions. Conversely, PLD-treated PC
liposomes remain stable up to extremely high conversions to PA. Here,
the negatively charged PA headgroup attracts significant amounts of
sodium ions from the bulk solution to the membrane surface, leading
to a swelling of the coordinated water layer. These findings are a
vital step toward a fundamental understanding of the degradation behavior
of PC lipid membranes in the presence of these clinically relevant
enzymes, and toward the rational design of diagnostic and drug delivery
technologies for phospholipase-dysregulation-based diseases
Fate of Liposomes in the Presence of Phospholipase C and D: From Atomic to Supramolecular Lipid Arrangement
Understanding the
origins of lipid membrane bilayer rearrangement
in response to external stimuli is an essential component of cell
biology and the bottom-up design of liposomes for biomedical applications.
The enzymes phospholipase C and D (PLC and PLD) both cleave the phosphorus–oxygen
bonds of phosphate esters in phosphatidylcholine (PC) lipids. The
atomic position of this hydrolysis reaction has huge implications
for the stability of PC-containing self-assembled structures, such
as the cell wall and lipid-based vesicle drug delivery vectors. While
PLC converts PC to diacylglycerol (DAG), the interaction of PC with
PLD produces phosphatidic acid (PA). Here we present a combination
of small-angle scattering data and all-atom molecular dynamics simulations,
providing insights into the effects of atomic-scale reorganization
on the supramolecular assembly of PC membrane bilayers upon enzyme-mediated
incorporation of DAG or PA. We observed that PC liposomes completely
disintegrate in the presence of PLC, as conversion of PC to DAG progresses.
At lower concentrations, DAG molecules within fluid PC bilayers form
hydrogen bonds with backbone carbonyl oxygens in neighboring PC molecules
and burrow into the hydrophobic region. This leads initially to membrane
thinning followed by a swelling of the lamellar phase with increased
DAG. At higher DAG concentrations, localized membrane tension causes
a change in lipid phase from lamellar to the hexagonal and micellar
cubic phases. Molecular dynamics simulations show that this destabilization
is also caused in part by the decreased ability of DAG-containing
PC membranes to coordinate sodium ions. Conversely, PLD-treated PC
liposomes remain stable up to extremely high conversions to PA. Here,
the negatively charged PA headgroup attracts significant amounts of
sodium ions from the bulk solution to the membrane surface, leading
to a swelling of the coordinated water layer. These findings are a
vital step toward a fundamental understanding of the degradation behavior
of PC lipid membranes in the presence of these clinically relevant
enzymes, and toward the rational design of diagnostic and drug delivery
technologies for phospholipase-dysregulation-based diseases