Theory of two-photon induced fluorescence anisotropy decay in membranes

We report the first theoretical description for the time-dependent fluorescence anisotropy decay resulted from two-photon excitation (r([2])(t)) for fluorophores in macroscopically isotropic and oriented membranes. In case of two-photon excitation, the initial value of the fluorescence anisotropy r([2])(0) immediately after excitation by a flash of polarized light is a function of the components of the two-photon absorption transition tensor [unk]S and the projections of the emission transition moment to the principal axes of [unk]S. The components of [unk]S depend on the symmetries of all molecular states relevant to the two-photon absorption process. The maximal value of r([2])(0) is proven to be as large as 0.61 in contrast to 0.4 for the conventional one-photon induced fluorescence anisotropy r([1])(0). It is shown that only for some special cases the ratio of the two-photon r([2])(t) over the conventional one-photon r([1])(t) will be a constant at all times for fluorophores in macroscopically isotropic membrane systems. In oriented membrane systems, an additional order parameter <P(6)> can be determined by the use of angle-resolved fluorescence depolarization measurements resulted from two-photon excitation. The advantages of measuring time-resolved fluorescence anisotropy decays or angle-resolved fluorescence depolarization ratios by two-photon excitation for the study of orientational dynamics in isotropic or oriented membranes are discussed from the theoretical point of view

Evidence for a regular distribution of cholesterol in phospholipid bilayers from diphenylhexatriene fluorescence.

Cholesterol/dimyristoylphosphatidylcholine (DMPC) multilamellar vesicles were studied by steady-state fluorescence using diphenylhexatriene (DPH) as a probe. A series of dips were found in the plot of DPH fluorescence intensity versus cholesterol concentration at certain specific cholesterol concentrations. This observation indicates that there are dominant domains in which cholesterol molecules are regularly distributed on a hexagonal superlattice in the acyl chain matrix of DMPC at critical cholesterol concentrations. These concentrations can be predicted by an equation or a mathematical series, except the one at 33 mol %. These dips of DPH fluorescence intensity are temperature dependent. The excellent agreement between experimental data and calculated values as well as similar previous findings of dips and/or kinks in the excimer-over-monomer fluorescence in pyrenephosphatidylcholine/phospholipid mixtures confirm our conclusion about lateral organizations of cholesterol and acyl lipid chains in cholesterol/phospholipid multilamellar vesicles. The regular distribution model at critical concentration is consistent with the phase diagram of cholesterol/DMPC. Using the model of regular distribution, the physical origin of the liquid-disordered (Ld) phase, liquid-ordered phase (Lo), and coexistence of liquid-disordered phase and Lo phase (Lo + Ld) is discussed on the molecular level

The impact of heterogeneity and dark acceptor states on FRET: implications for using fluorescent protein donors and acceptors.

Förster resonance energy transfer (FRET) microscopy is widely used to study protein interactions in living cells. Typically, spectral variants of the Green Fluorescent Protein (FPs) are incorporated into proteins expressed in cells, and FRET between donor and acceptor FPs is assayed. As appreciable FRET occurs only when donors and acceptors are within 10 nm of each other, the presence of FRET can be indicative of aggregation that may denote association of interacting species. By monitoring the excited-state (fluorescence) decay of the donor in the presence and absence of acceptors, dual-component decay analysis has been used to reveal the fraction of donors that are FRET positive (i.e., in aggregates)._However, control experiments using constructs containing both a donor and an acceptor FP on the same protein repeatedly indicate that a large fraction of these donors are FRET negative, thus rendering the interpretation of dual-component analysis for aggregates between separately donor-containing and acceptor-containing proteins problematic. Using Monte-Carlo simulations and analytical expressions, two possible sources for such anomalous behavior are explored: 1) conformational heterogeneity of the proteins, such that variations in the distance separating donor and acceptor FPs and/or their relative orientations persist on time-scales long in comparison with the excited-state lifetime, and 2) FP dark states