How lipid headgroups sense the membrane environment: an application of ¹4N NMR.

The orientation of lipid headgroups may serve as a powerful sensor of electrostatic interactions in membranes. As shown previously by (2)H NMR measurements, the headgroup of phosphatidylcholine (PC) behaves like an electrometer and varies its orientation according to the membrane surface charge. Here, we explored the use of solid-state (14)N NMR as a relatively simple and label-free method to study the orientation of the PC headgroup in model membrane systems of varying composition. We found that (14)N NMR is sufficiently sensitive to detect small changes in headgroup orientation upon introduction of positively and negatively charged lipids and we developed an approach to directly convert the (14)N quadrupolar splittings into an average orientation of the PC polar headgroup. Our results show that inclusion of cholesterol or mixing of lipids with different length acyl chains does not significantly affect the orientation of the PC headgroup. In contrast, measurements with cationic (KALP), neutral (Ac-KALP), and pH-sensitive (HALP) transmembrane peptides show very systematic changes in headgroup orientation, depending on the amount of charge in the peptide side chains and on their precise localization at the interface, as modulated by varying the extent of hydrophobic peptide/lipid mismatch. Finally, our measurements suggest an unexpectedly strong preferential enrichment of the anionic lipid phosphatidylglycerol around the cationic KALP peptide in ternary mixtures with PC. We believe that these results are important for understanding protein/lipid interactions and that they may help parametrization of membrane properties in computational studies.

Low pH acts as inhibitor of membrane damage induced by human islet amyloid polypeptide.

Human islet amyloid polypeptide (IAPP) is the major component of the amyloid deposits found in the pancreatic islets of patients with type 2 diabetes mellitus. After synthesis, IAPP is stored in the ß-cell granules of the pancreas at a pH of approximately 5.5 and released into the extracellular compartment at a pH of 7.4. To gain insight into the possible consequences of pH differences for properties and membrane interaction of IAPP, we here compared the aggregational and conformational behavior of IAPP as well as IAPP-membrane interactions at pH 5.5 and pH 7.4. Our data reveal that a low pH decreases the rate of fibril formation both in solution and in the presence of membranes. We observed by CD spectroscopy that these differences in kinetics are directly linked to changes in the conformational behavior of the peptide. Mechanistically, the processes that occur at pH 5.5 and pH 7.4 appear to be similar. At both pH values, we found that the kinetic profile of IAPP fibril growth matches the kinetic profile of IAPP-induced membrane damage, and that both are characterized by a lag phase and a sigmoidal transition. Furthermore, monolayer studies as well as solid-state NMR experiments indicate that the differences in kinetics and conformational behavior as function of pH are not due to a different mode of membrane insertion. Our study suggests that a low pH prevents aggregation and membrane damage of IAPP in the secretory granules, most likely by affecting the ionization properties of the peptide.

Sterols have higher affinity for sphingomyelin than for phosphatidylcholine bilayers even at equal acyl-chain order.

The interaction between cholesterol and phospholipids in bilayer membranes is important for the formation and maintenance of membrane structure and function. However, cholesterol does not interact favorably with all types of phospholipids and, for example, prefers more ordered sphingomyelins (SMs) over phosphatidylcholines (PCs). The reason for this preference is not clear. Here we have studied whether acyl-chain order could be responsible for the preferred sterol interaction with SMs. Acyl-chain order was deduced from diphenylhexatriene anisotropy and from the deuterium order parameter obtained by (2)H-NMR on bilayers made from either 14:0/14:0((d27))-PC, or 14:0((d27))-SM. Sterol/phospholipid interaction was determined from sterol bilayer partitioning. Cholestatrienol (CTL) was used as a fluorescence probe for cholesterol, because its relative membrane partitioning is similar to cholesterol. When CTL was allowed to reach equilibrium partitioning between cyclodextrins and unilamellar vesicles made from either 14:0/14:0-PC or 14:0-SM, the molar-fraction partitioning coefficient (K(x)) was approximately twofold higher for SM bilayers than for PC bilayers. This was even the case when the temperature in the SM samples was raised to achieve equal acyl-chain order, as determined from 1,6-diphenyl-1,3,5-hexatriene (DPH) anisotropy and the deuterium order parameter. Although the K(x) did increase with acyl-chain order, the higher K(x) for SM bilayers was always evident. At equal acyl-chain order parameter (DPH anisotropy), the K(x) was also higher for 14:0-SM bilayers than for bilayers made from either 14:0/15:0-PC or 15:0-/14:0-PC, suggesting that minor differences in chain length or molecular asymmetry are not responsible for the difference in K(x). We conclude that acyl-chain order affects the bilayer affinity of CTL (and thus cholesterol), but that it is not the cause for the preferred affinity of sterols for SMs over matched PCs. Instead, it is likely that the interfacial properties of SMs influence and stabilize interactions with sterols in bilayer membranes.

Mechanism and kinetics of peptide partitioning into membranes from all-atom simulations of thermostable peptides.

Partitioning properties of transmembrane (TM) polypeptide segments directly determine membrane protein folding, stability, and function, and their understanding is vital for rational design of membrane active peptides. However, direct determination of water-to-bilayer transfer of TM peptides has proved difficult. Experimentally, sufficiently hydrophobic peptides tend to aggregate, while atomistic computer simulations at physiological temperatures cannot yet reach the long time scales required to capture partitioning. Elevating temperatures to accelerate the dynamics has been avoided, as this was thought to lead to rapid denaturing. However, we show here that model TM peptides (WALP) are exceptionally thermostable. Circular dichroism experiments reveal that the peptides remain inserted into the lipid bilayer and are fully helical, even at 90 degrees C. At these temperatures, sampling is approximately 50-500 times faster, sufficient to directly simulate spontaneous partitioning at atomic resolution. A folded insertion pathway is observed, consistent with three-stage partitioning theory. Elevated temperature simulation ensembles further allow the direct calculation of the insertion kinetics, which is found to be first-order for all systems. Insertion barriers are DeltaH(in)(double dagger) = 15 kcal/mol for a general hydrophobic peptide and approximately 23 kcal/mol for the tryptophan-flanked WALP peptides. The corresponding insertion times at room temperature range from 8.5 mus to 163 ms. High-temperature simulations of experimentally validated thermostable systems suggest a new avenue for systematic exploration of peptide partitioning properties.

Peptide Partitioning and Folding into Lipid Bilayers.

The folding and partitioning of WALP peptides into lipid bilayers is characterized using atomic detail molecular dynamics simulations on microsecond time scales. Elevated temperatures are used to increase sampling, and their suitability is validated via circular dichroism experiments. A new united atom parametrization of lipids is employed, adjusted for consistency with the OPLS all-atom force field. In all simulations secondary structure forms rapidly, culminating in the formation of the native trans-membrane helix, which is demonstrated to have the lowest free energy. Partitioning simulations show that peptide insertion into the bilayer is preceded by interfacial folding. These results are in excellent agreement with partitioning theory. In contrast, previous simulations observed unfolded insertion pathways and incorrectly report stable extended configurations inside the membrane. This highlights the importance of accurately tuning and experimentally verifying force field parameters against microsecond time scale phenomena.