Conformational dimorphism and transmembrane orientation of prion protein residues 110-136 in bicelles.

A fragment corresponding to the putative membrane-associating domain of the prion protein (residues 110-136) was analyzed in phospholipid bicelles. Prion(110-136) associated with bicelles and exhibited a lipid- and pH-dependent conformational dimorphism between unstructured (pH 4.5) and alpha-helical (pH 7.5). Mutational analysis indicated that the charge state of a single histidine residue was largely responsible for the dimorphism. Amide-lipid NOEs and amide-water chemical exchange measurements revealed that the helical conformation of prion(110-136) spanned the bilayer, and were corroborated by solid-state deuterium NMR experiments indicating that the helical axis rested at a 16 degrees angle with respect to the bilayer normal.

Structural evaluation of phospholipid bicelles for solution-state studies of membrane-associated biomolecules.

Several complementary physical techniques have been used to characterize the aggregate structures formed in solutions containing dimyristoylphosphatidylcholine (DMPC)/dihexanoylphosphatidylcholine (DHPC) at ratios of < or =0.5 and to establish their morphology and lipid organization as that of bicelles. (31)P NMR studies showed that the DMPC and DHPC components were highly segregated over a wide range of DMPC/DHPC ratios (q = 0.05-0.5) and temperatures (15 degrees C and 37 degrees C). Only at phospholipid concentrations below 130 mM did the bicelles appear to undergo a change in morphology. These results were corroborated by fluorescence data, which demonstrated the inverse dependence of bicelle size on phospholipid concentration as well as a distinctive change in phospholipid arrangement at low concentrations. In addition, dynamic light scattering and electron microscopy studies supported the hypothesis that the bicellar phospholipid aggregates are disk-shaped. The radius of the planar domain of the disk was found to be directly proportional to the ratio of DMPC/DHPC and inversely proportional to the total phospholipid concentration when the DMPC/DHPC ratio was held constant at 0.5. Taken together, these results suggest that bicelles with low q retain the morphology and bilayer organization typical of their liquid-crystalline counterparts, making them useful membrane mimetics.

Orientation and effects of mastoparan X on phospholipid bicelles.

Mastoparan X (MPX: INWKGIAAMAKKLL-NH2) belongs to a family of ionophoric peptides found in wasp venom. Upon binding to the membrane, MPX increases the cell's permeability to cations leading to a disruption in the electrolyte balance and cell lysis. This process is thought to occur either through a membrane-thinning mechanism, where the peptide resides on the membrane surface thereby disrupting lipid packing, or through formation of an oligomeric pore. To address this issue, we have used both high-resolution and solid-state 2H NMR techniques to study the structure and orientation of MPX when associated with bicelles. NOESY and chemical shift analysis showed that in bicelles, MPX formed a well-structured amphipathic alpha-helix. In zwitterionic bicelles, the helical axis was found to rest generally perpendicular to the membrane normal, which could be consistent with the "carpet" mechanism for lytic activity. In anionic bicelles, on the other hand, the helical axis was generally parallel to the membrane normal, which is more consistent with the pore model for lytic activity. In addition, MPX caused significant disruption in lipid packing of the negatively charged phospholipids. Taken together, these results show that MPX associates differently with zwitterionic membranes, where it rests parallel to the surface, compared with negatively charged membranes, where it penetrates longitudinally.

Acidic phospholipid bicelles: a versatile model membrane system.

With the aim of establishing acidic bicellar solutions as a useful membrane model system, we have used deuterium NMR spectroscopy to investigate the properties of dimyristoyl/dihexanoylphosphatidylcholine (DMPC/DHPC) bicelles containing 25% (w/w in H(2)O) of either dimyristoylphosphatidylserine (DMPS) or dimyristoylphosphatidylglycerol (DMPG). The addition of the acidic lipid component to this lyotropic liquid crystalline system reduces its range of stability because of poor miscibility of the two dimyristoylated phospholipids. Compared to the neutral bicelles, which are stable at pH 4 to pH 7, acidic bicelles are stable only from pH 5.5 to pH 7. Solid-state deuterium NMR analysis of d(54)-DMPC showed similar ordering in neutral and acidic bicelles. Fully deuterated DMPS or DMPG is ordered in a way similar to that of DMPC. Study of the binding of the myristoylated N-terminal 14-residue peptide mu-GSSKSKPKDPSQRR from pp60(nu-src) to both neutral and acidic bicelles shows the utility of these novel membrane mimetics.

Deciphering the fluorescence signature of daunomycin and doxorubicin.

The fluorescence characteristics of daunomycin (DNM), doxorubicin (DXR), and other anthracycline drugs are often used to monitor localization of the drug within lipid bilayers and liposomal delivery systems and to assess interaction of the drug with DNA and other macromolecules. However, the binding of DNM and DXR to proteins and membrane systems has been observed to exhibit variable effects on the anthracycline's fluorescence. We have delineated the spectroscopic response of DXR and DNM to their surroundings in several systems, including solvents of differing dielectric constant, aqueous solutions of varying pH or fluorophore concentration, and the reverse micellar system of AOT/heptane/water with a range of doxorubicin concentrations. We have observed that the ratio of fluorescence intestinal at the two principal lambda max values shows a parabolic dependence on solvent dielectric constant, i.e. inverted solvatochromism. This behavior has been overlooked by previous investigators and, together with the appearance of a long-wavelength band near 630 nm in solvents of low dielectric strength (also previously not reported), is key to understanding the partitioning of anthracyclines in membrane systems as well as resolving the conflicting interpretation of data in the literature.