Bright fluorogenic squaraines with tuned cell entry for selective imaging of plasma membrane vs. endoplasmic reticulum.

A rational design of squaraine dyes with lipophilic and zwitterionic groups tunes cell entry, allowing for selective far-red/near-infrared imaging of plasma membrane vs. endoplasmic reticulum. They exhibit up to 110-fold fluorescence enhancement in biomembranes and enable cellular imaging at 1 nM concentration, which make them the brightest membrane probes to date.

Solvatochromic Nile Red probes with FRET quencher reveal lipid order heterogeneity in living and apoptotic cells.

Detecting and imaging lipid microdomains (rafts) in cell membranes remain a challenge despite intensive research in the field. Two types of fluorescent probes are used for this purpose: one specifically labels a given phase (liquid ordered, Lo, or liquid disordered, Ld), while the other, being environment-sensitive (solvatochromic), stains the two phases in different emission colors. Here, we combined the two approaches by designing a phase-sensitive probe of the Ld phase and a quencher of the Ld phase. The former is an analogue of the recently developed Nile Red-based probe NR12S, bearing a bulky hydrophobic chain (bNR10S), while the latter is based on Black Hole Quencher-2 designed as bNR10S (bQ10S). Fluorescence spectroscopy of large unilamellar vesicles and microscopy of giant vesicles showed that the bNR10S probe can partition specifically into the Ld phase, while bQ10S can specifically quench the NR12S probe in the Ld phase so that only its fraction in the Lo phase remains fluorescent. Thus, the toolkit of two probes with quencher can specifically target Ld and Lo phases and identify their lipid order from the emission color. Application of this toolkit in living cells (HeLa, CHO, and 293T cell lines) revealed heterogeneity in the cell plasma membranes, observed as distinct probe environments close to the Lo and Ld phases of model membranes. In HeLa cells undergoing apoptosis, our toolkit showed the formation of separate domains of the Ld-like phase in the form of blebs. The developed tools open new possibilities in lipid raft research.

Red fluorescent turn-on ligands for imaging and quantifying G protein-coupled receptors in living cells.

Classical fluorescence-based approaches to monitor ligand-protein interactions are generally hampered by the background signal of unbound ligand, which must be removed by tedious washing steps. To overcome this major limitation, we report here the first red fluorescent turn-on probes for a G protein-coupled receptor (oxytocin receptor) at the surface of living cells. The peptide ligand carbetocin was conjugated to one of the best solvatochromic (fluorogenic) dyes, Nile Red, which turns on emission when reaching the hydrophobic environment of the receptor. We showed that the incorporation of hydrophilic octa(ethylene glycol) linker between the pharmacophore and the dye minimized nonspecific interaction of the probe with serum proteins and lipid membranes, thus ensuring receptor-specific turn-on response. The new ligand was successfully applied for background-free imaging and quantification of oxytocin receptors in living cells.

Fluorescent probes for lipid rafts: from model membranes to living cells.

Membrane microdomains (rafts) remain one of the controversial issues in biophysics. Fluorescent molecular probes, which make these lipid nanostructures visible through optical techniques, are one of the tools currently used to study lipid rafts. The most common are lipophilic fluorescent probes that partition specifically into liquid ordered or liquid disordered phase. Their partition depends on the lipid composition of a given phase, which complicates their use in cellular membranes. A second class of probes is based on environment-sensitive dyes, which partition into both phases, but stain them by different fluorescence color, intensity, or lifetime. These probes can directly address the properties of each separate phase, but their cellular applications are still limited. The present review focuses on summarizing the current state in the field of developing and applying fluorescent molecular probes to study lipid rafts. We highlight an urgent need to develop new probes, specifically adapted for cell plasma membranes and compatible with modern fluorescence microscopy techniques to push the understanding of membrane microdomains forward.

Rational design of fluorescent membrane probes for apoptosis based on 3-hydroxyflavone.

Environment-sensitive probes constitute powerful tools for monitoring changes in the physico-chemical properties of cell plasma membranes. Among these probes, 3-hydroxyflavone probes are of great interest due to their dual emission and ratiometric response. Here, three probes derived from the parent F2N12S were designed, characterized and applied to monitor the membrane changes occurring during apoptosis. These three probes were designed to orient the dye vertically in the membrane. They differ by the length of their alkyl chains (from 4 to 8 carbons), which were included to optimize their affinity to the lipid membranes. Among these three probes, the one with medium chain length (hexyl) showed the best affinity to model and cell membranes, while the one with the longest alkyl chains (octyl) did not efficiently stain the membranes, probably due to aggregation. The new probes were found to be more sensitive than F2N12S to both the lipid phase and surface charge in lipid vesicles and to loss of lipid order in cell plasma membranes after cholesterol extraction. The one with the shortest (butyl) chains was found to be the most sensitive to apoptosis, while the one with medium-length (hexyl) chains was the brightest. Interestingly, apoptosis induced by different agents led to similar spectroscopic effects to those produced by the loss of lipid order and change in the surface charge, confirming that apoptosis decreases the lipid order and increases the negative surface charge in the outer leaflet of cell membranes. In conclusion, these studies report the relationship between the probe structures and their sensitivity to lipid order, surface charge and apoptosis and propose new probes for membrane research.