Membrane Dipole Potential as Measured by Ratiometric 3-Hydroxyflavone Fluorescence Probes: Accounting for Hydration Effects

We previously applied the electrochromic modulation of excited-state intramolecular proton-transfer (ESIPT) reaction for the design of novel 3-hydroxyflavone (3-HF) derivatives as fluorescent probes for measuring the dipole potential, Ψ_D, in lipid bilayers (Klymchenko et al., Proc. Natl. Acad. Sci. USA, 2003, 100, 11219). In the present work, this method was revisited to take into account the influence of the bilayer hydration on the emission ratiometric response of 3-HF probes. For this reason, it was necessary to deconvolute the whole fluorescence spectra into three bands corresponding to the non H-bonded forms, normal N^* and tautomer T^* forms, both participating to the ESIPT reaction, and to the H-bonded H–N^* form, excluded from this reaction. This allowed us to determine the pure N^*/T^* intensity ratio, without any contribution from the H–N^* form emission depending essentially on the bilayer hydration. This new approach allowed us to confirm the correlation we obtained between the response of 3-HF probes on dipole potential modifications and the corresponding response of the reference fluorescent probe di-8-ANEPPS, thus further confirming the potency of 3-HF probes as excellent emission ratiometric probes to measure dipole potential in lipid membranes.     

Electro‐optical interferometric microscopy of periodic and aperiodic ferroelectric structures

The ferroelectric domain structures of periodically poled KTiOPO₄ and two‐dimensional short range ordered poled LiNbO₃ crystals are determined non‐invasively by interferometric measurements of the electro‐optically induced phase retardation. Owing to the sign reversal of the electro‐optical coefficients upon domain inversion, a π phase shift is observed for the inverted domains. The microscopic setup provides diffraction‐limited spatial resolution allowing us to reveal the nonlinear and electro‐optical modulation patterns in ferroelectric crystals in a non‐destructive manner and to determine the poling period, duty cycle and short‐range order as well as detect local defects in the domain structure. Conversely, knowing the ferroelectric domain structure, one can use electro‐optical microscopy so as to infer the distribution of the electric field therein.

     

Fluorescent biomembrane probe for ratiometric detection of apoptosis

Herein, we developed the first ratiometric fluorescent probe for apoptosis detection. This probe incorporates selectively into the outer leaflet of the cell plasma membrane and senses the loss of the plasma membrane asymmetry occurring during the early steps of apoptosis. The high specificity to the plasma membranes was achieved by introduction into the probe of a membrane anchor, composed of a zwitterionic group and a long (dodecyl) hydrophobic tail. The fluorescence reporter of this probe is 4'-(diethylamino)-3-hydroxyflavone, which exhibits excited-state intramolecular proton transfer (ESIPT), resulting in two-band emission highly sensitive to the lipid composition of the biomembranes. Fluorescence spectroscopy, flow cytometry, and microscopy measurements show that the ratio of the two emission bands of the probe changes dramatically in response to apoptosis. This response reflects the changes in the lipid composition of the outer leaflet of the cell plasma membrane because of the exposure of the anionic phospholipids from the inner leaflet at the early steps of apoptosis. Being ratiometric, the response of the new probe can be easily quantified on an absolute scale. This allows monitoring by laser scanning confocal microscopy the degree and spatial distribution of the apoptotic changes at the cell plasma membranes, a feature that can be hardly achieved with the commonly used fluorescently labeled annexin V assay.