Evaluation of the thermal coefficient of the resistance to fluorophore rotation in model membranes

Regulation of the lateral association of phospholipase Cbeta2 and G protein subunits by lipid rafts

One function of membrane domains of liquid-ordered lipids or "rafts" may be to stabilize complexes of signaling proteins, thereby playing a role in the transduction of cellular signals. Here, we have used fluorescence methods to directly test this idea by assessing the ability of phospholipase Cbeta2 (PLCbeta2) to associate with G protein subunits on model membranes in the fluid phase and on membranes that contain domains of lipids in the liquid-ordered phase (rafts). We find that the apparent dissociation constant for the equilibrium between PLCbeta2 and Galpha(q)(GTPgammaS) was identical on both types of membrane surfaces. However, the degree of association between PLCbeta2 and Gbetagamma subunits was significantly reduced on the surfaces containing rafts. Time studies indicate that this phenomenon is a dynamic process. Incorporating the lipid substrate of PLCbeta2 into membranes that forms rafts, we find that its basal activity is unaffected. However, its activation by Gbetagamma subunits is inhibited, supporting a reduced degree of interaction between these two proteins when rafts are present. Since lipid rafts affected PLCbeta2-Gbetagamma association and not PLCbeta2-Galpha(q)(GTPgammaS) association, we explored the possibility that the membrane interaction of Gbetagamma differed when rafts are present. We find that although the membrane partition coefficient of Gbetagamma is not significantly changed in the presence of rafts, proteolysis of Gbetagamma by trypsin increases and the ability of Gbetagamma Tyr/Trp fluorescence to be quenched by iodide ions decreases when rafts are present. These results suggest a model in which lipid rafts occlude the PLCbeta2 interaction site on Gbetagamma subunits by localizing these subunits at the domain interface.

Effects of cholesterol on membrane surfaces as studied by high-pressure fluorescence spectroscopy

We have studied the effects of cholesterol on membrane surfaces using fluorescence spectroscopy at high pressure. At atmospheric pressure, the dissociation state of a pH-sensitive fluorophore (6-decanylnaphthol or DECNA) incorporated into several types of membranes showed an apparent increase in dissociation with cholesterol content coming somewhat closer to its dissociation state in solution. Previous studies have shown that when DECNA is free in solution, pressure induces proton dissociation due to the volume decrease that occurs when water electrostricts around the ions. But in phosphatidylcholine (PC) bilayers, proton dissociation is inhibited, either due to the inability of the surface to expand and allow for increased hydration, or other changes in lipid structure. The pressure behavior of DECNA in dioleoyl-PC, dioleoylphosphatidic acid and dioleylphosphatidylglycerol bilayers shows that incorporation of 5-10% cholesterol causes DECNA to behave like it is in a more unrestricted environment. This trend is reversed at higher cholesterol concentrations. These data, together with compressibility measurements, support the model of Sankaram and Thompson [M. Sankaram, T.E. Thompson, Biochemistry 29 (1990) 10676.] whereby in the disordered phase, cholesterol can span the two leaflets causing an increase in the area between the head groups; whereas in the ordered phase, no expansion occurs. Thus, the effect of cholesterol on membrane surfaces depends on its phase diagram.

Compression of lipid membranes as observed at varying membrane positions

We have measured the microscopic isothermal compressibility of dioleoyl- and dimyristyl-phosphatidylcholine multilayers and bilayers as a function of membrane depth by the pressure dependence of the polarization of a series of anthroyloxy fatty acids. In both systems, within experimental error, the compressibility did not change with membrane depth. The magnitudes of the compressibilities matched those of organic solids and those reported for dipalmitoylphosphatidylcholine multilayers from neutron diffraction measurements (Braganza, L. F., and D. L. Worcester. 1986. Biochemistry, 25:7484-7488). The bilayer compressibility decreased with temperature and this decrease was similar with membrane depth consistent with the isotropic thermal expansion of membranes previously observed (Scarlata, S. 1989. Biophys. J. 55:1215-1223). The vertical compressibility in the z direction is much lower than the horizontal (xy planes) for probes that lie parallel to the hydrocarbon chains which is consistent with an increase in bilayer thickness. The compressibility for probes that lie perpendicular to the hydrocarbon chains is more isotropic due to their limited spatial access to the z plane.

Effect of salt and membrane fluidity on fluorophore motions of a gramicidin C derivative

We have used fluorescence spectroscopy to investigate the effect of salt and membrane fluidity on the rotational motion of a 5-(dimethylamino)naphthalene-1-sulfonyl (dansyl) derivative of gramicidin C (dansyl-gC) in dimyristoylphosphatidylcholine bilayers, under conditions where the peptide is a formyl-NH to formyl-NH terminal dimer, and in octyl glucoside micelles, where the peptide is an intertwined helical dimer. Energy-transfer experiments showed no changes in either conformation or dimer aggregation under the conditions explored here (15-40 degrees C, 1-350 bar, 0-0.33 M Mg2+, and 0-1 M Na+). The addition of permeable (Na+) or nonpermeable (Mg2+) ions did not affect the temperature or pressure behavior of dansyl rotation. However, fluorescence lifetime measurements indicated an increase in solvent accessibility in the presence of sodium. In bilayers, the temperature dependence of the fluorescence polarization and lifetime shows strong interactions between the dansyl residue and the peptide, and at no time did the dansyl motions become solvent controlled as has been observed for aqueous solvent peptides [Scarlata, S. F., Rholam, M., & Weber, G. (1984) Biochemistry 23, 6789]. In micelles, the change in rotational motion with temperature followed solvent expansion, showing that in this case the dansyl residue does not associate extensively with the peptide. Our results indicate that because of the extensive coupling between the dansyl residue and the rest of the peptide, membrane fluidity does not play a major role in controlling side-chain motions.

Compression of lipid membranes as observed at varying membrane positions

We have measured the microscopic isothermal compressibility of dioleoyl- and dimyristyl-phosphatidylcholine multilayers and bilayers as a function of membrane depth by the pressure dependence of the polarization of a series of anthroyloxy fatty acids. In both systems, within experimental error, the compressibility did not change with membrane depth. The magnitudes of the compressibilities matched those of organic solids and those reported for dipalmitoylphosphatidylcholine multilayers from neutron diffraction measurements (Braganza, L. F., and D. L. Worcester. 1986. Biochemistry, 25:7484-7488). The bilayer compressibility decreased with temperature and this decrease was similar with membrane depth consistent with the isotropic thermal expansion of membranes previously observed (Scarlata, S. 1989. Biophys. J. 55:1215-1223). The vertical compressibility in the z direction is much lower than the horizontal (xy planes) for probes that lie parallel to the hydrocarbon chains which is consistent with an increase in bilayer thickness. The compressibility for probes that lie perpendicular to the hydrocarbon chains is more isotropic due to their limited spatial access to the z plane.

Dynamic motions of 1,6-diphenyl-1,3,5-hexatriene in interdigitated C(18):C(10)phosphatidylcholine bilayers

This study investigates the dynamic behavior of 1,6-diphenyl-1,3,5-hexatriene (DPH) in C(18):C(10)phosphatidylcholine [C(18):C(10)PC] bilayers. C(18):C(10)PC is an asymmetric mixed-chain phosphatidylcholine known to form mixed-interdigitated structures below the transition temperature and form partially interdigitated bilayers above the transition temperature. The rotation of DPH in C(18):C(10)PC has been described in terms of the thermal coefficient of rotation using the modified Y-plot method which takes into account the limiting anisotropy value. During the phase transition of C(18):C(10)PC, DPH exhibits a thermal coefficient b2M = 0.41 - 0.51 degrees C-1 which is similar to the b2M values obtained with noninterdigitated phosphatidylcholine bilayers. Differential polarized phase-modulation fluorometry has also been employed to study the dynamic behavior of DPH in C(18):C(10)PC in real time. The data show that DPH contains considerable motion in the highly ordered mixed interdigitated bilayers. The DPH motion steadily increases with an increase in temperature as shown by the rotational correlation time, and the wobbling diffusion constant. However, the limiting anisotropy, the order parameter, and the width of the lifetime distribution undergo an abrupt decrease, and a corresponding abrupt increase in the cone angle, at approximately 16 degrees C. This temperature range is near the onset temperature of the phase transition as determined by differential scanning calorimetry. The rotational parameters show strong hysteresis on heating and cooling. All the rotational parameters derived from DPH fluorescence in mixed interdigitated C(18):C(10)PC exhibit magnitudes similar to those obtained from non interdigitated gel phases of symmetric diacylphosphatidylcholines. These results, combined with those obtained with dehydroergosterol (Kao, Y. L., P. L.-G. Chong, and C. Huang. 1990. Biochemistry. 29:1315-1322), suggest that considerable rotational mobility of small molecules can be sustained in an intramolecularly highly ordered interdigitated lipid matrix, implying that the membrane maintains a fluid environment around membrane perturbants even when the lipid matrix is extensively interdigitated.