Tryptophan orientations in membrane-bound gramicidin and melittin-a comparative linear dichroism study on transmembrane and surface-bound peptides.

In the search for methods to study structure and function of membrane-associated proteins and peptides flow linear dichroism, LD, spectroscopy has emerged as a promising technique. Using shear-aligned lipid vesicles, conformations and binding geometries of membrane-bound bio-macromolecules can be assessed. Here we investigate anchoring properties and specific orientations of tryptophan relative to the peptide backbone and to the membrane normal for the model peptides gramicidin and melittin. We have monitored the conformational change associated with the refolding of non-channel gramicidin into its channel form, and quantitatively determined the average orientations of its tryptophan transition moments, suggesting that these residues adopt a well-defined orientation at the membrane interface. An important conclusion regards the structural variation of gramicidin between these two distinct transmembrane forms. Whilst circular dichroism (CD) spectra, as has been reported before, vary strongly between the two forms suggesting their structures might be quite different, the LD results clearly evidence both the peptide backbone orientation and tryptophan side-chain positioning to be very similar. The latter are oriented in accord with what is expected from their role to anchor peptide termini to the membrane surface. The variations in CD could be due to, the in LD observed, minor shifts in mutual orientation and distance between neighbouring tryptophans sensitively determining their exciton interactions. Our data dispute that the non-channel form of membrane-bound gramicidin would be any of the intertwined forms often observed in crystal as the positioning of tryptophans along the peptide axis would not be compatible with the strong interfacial positioning observed here. The general role of tryptophans as interfacial anchors is further assessed for melittin whose conformation shows considerable angular spread, consistent with a carpet model of its mechanism for induced membrane leakage, and a predominantly surface-aligned membrane orientation governed by amphipathic interactions.

Effects of chirality on the intracellular localization of binuclear ruthenium(II) polypyridyl complexes.

Interest in binuclear ruthenium(II) polypyridyl complexes as luminescent cellular imaging agents and for biomedical applications is increasing rapidly. We have investigated the cellular localization, uptake, and biomolecular interactions of the pure enantiomers of two structural isomers of [µ-bipb(phen)(4)Ru(2)](4+) (bipb is bis(imidazo[4,5-f]-1,10-phenanthrolin-2-yl)benzene and phen is 1,10-phenanthroline) using confocal laser scanning microscopy, emission spectroscopy, and linear dichroism. Both complexes display distinct enantiomeric differences in the staining pattern of fixed cells, which are concluded to arise from chiral discrimination in the binding to intracellular components. Uptake of complexes in live cells is efficient and nontoxic at 5 µM, and occurs through an energy-dependent mechanism. No differences in uptake are observed between the structural isomers or the enantiomers, suggesting that the interactions triggering uptake are rather insensitive to structural variations. Altogether, these findings show that the complexes investigated are promising for future applications as cellular imaging probes. In addition, linear dichroism shows that the complexes exhibit DNA-condensing properties, making them interesting as potential gene delivery vectors.

Luminescent dipyridophenazine-ruthenium probes for liposome membranes.

Ruthenium complexes with dipyridophenazine (dppz) type ligands have several characteristics that make them good candidates for use as luminescence probes for hydrophobic environments. Most studies have concerned DNA intercalation, but also lipid membrane fluidity and liposome orientation have been assessed. We report here dipyridophenazine derivatives ([Ru(phen)2dppz]2+) substituted with one or two alkyl ether chains of different lengths aimed at finding the optimum substitution for a high quantum yield when bound to a phospholipid membrane bilayer. The orientation of membrane bound molecules is studied using flow linear dichroism (LD) with phospholipid vesicles as membrane models. LD, excitation anisotropy, steady state luminescence and excited-state lifetime measurements are used to quantitatively investigate the insertion and orientation of the complexes in the vesicles. All complexes are inserted with their long axis of the dppz moiety mainly parallel to the lipid chains, and the degree of orientation is comparable to that of the orientation probe retinoic acid. The ruthenium "head group" with its positive charge functions as a buoy at the water-membrane interface while the hydrophobic chain part embeds the complex down into the bilayer. The complex with two hexyl ether substituents (named D6) has the optimal chain length regarding membrane insertion and orientation, and together with the highest quantum yield, is the best luminescence membrane probe in the two series.

Retinoid chromophores as probes of membrane lipid order.

There is a great need for development of independent methods to study the structure and function of membrane-associated proteins and peptides. Polarized light spectroscopy (linear dichroism, LD) using shear-aligned lipid vesicles as model membranes has emerged as a promising tool for the characterization of the binding geometry of membrane-bound biomolecules. Here we explore the potential of retinoic acid, retinol, and retinal to function as probes of the macroscopic alignment of shear-deformed 100 nm liposomes. The retinoids display negative LD, proving their preferred alignment perpendicular to the membrane surface. The magnitude of the LD indicates the order retinoic acid > retinol > retinal regarding the degree of orientation in all tested lipid vesicle types. It is concluded that mainly nonspecific electrostatic interactions govern the apparent orientation of the retinoids within the bilayer. We propose a simple model for how the effective orientation may be related to the polarity of the end groups of the retinoid probes, their insertion depths, and their angular distribution of configurations around the membrane normal. Further, we provide evidence that the retinoids can sense subtle structural differences due to variations in membrane composition and we explore the pH sensitivity of retinoic acid, which manifests in variations in absorption maximum wavelength in membranes of varying surface charge. Based on LD measurements on cholesterol-containing liposomes, the influence of membrane constituents on bending rigidity and vesicle deformation is considered in relation to the macroscopic alignment, as well as to lipid chain order on the microscopic scale.

Correlation between cellular localization and binding preference to RNA, DNA, and phospholipid membrane for luminescent ruthenium(II) complexes.

Because of their unique photophysical properties, sensitively depending on environment, ruthenium dipyridophenazine (dppz) complexes are interesting as probes for cellular imaging with fluorescence microscopy. Here three complexes derivatized with alkyl ether chains of varied length, which exhibit distinctly different cellular staining patterns by confocal laser scanning microscopy, are studied regarding their binding preference for rRNA compared with calf thymus DNA (ct-DNA) and phospholipid membranes. Co-staining with commercial RNA and membrane-specific dyes shows that whereas the least lipophilic complex exclusively stains DNA inside the nucleus, the most lipophilic complex preferentially stains membrane-rich parts of the cell. Interestingly, only the intermediate lipophilic complex shows intense staining of the RNA-rich nucleoli. The intracellular localizations of the probes correlate with their binding preferences concluded from spectroscopy measurements.

Ruthenium(II) Complex Enantiomers as Cellular Probes for Diastereomeric Interactions in Confocal and Fluorescence Lifetime Imaging Microscopy.

Ruthenium dipyridophenazine (dppz) complexes are sensitive luminescent probes for hydrophobic environments. Here, we apply multiple-frequency fluorescence lifetime imaging microscopy (FLIM) to Δ and Λ enantiomers of lipophilic ruthenium dppz complexes in live and fixed cells, and their different lifetime staining patterns are related to conventional intensity-based microscopy. Excited state lifetimes of the enantiomers determined from FLIM measurements correspond well with spectroscopically measured emission decay curves in pure microenvironments of DNA, phospholipid membrane or a model protein. We show that FLIM can be applied to monitor the long-lived excited states of ruthenium complex enantiomers and, combined with confocal microscopy, give new insight into their biomolecular binding and reveal differences in the microenvironment probed by the complexes.

Lipophilic ruthenium complexes with tuned cell membrane affinity and photoactivated uptake.

Ruthenium dipyridophenazine (dppz) complexes are virtually non-emissive in aqueous solutions but show strong luminescence in hydrophobic environments, making them interesting as molecular probes in cellular imaging. We show by luminescence spectroscopy that by substituting the dppz ligand with alkyl ether chains of increasing length the complexes can be tuned from preferential intercalation into DNA to insertion in model phospholipid membranes. Confocal laser scanning microscopy (CLSM) on methanol fixed CHO-K1 cells show an analogous distribution in the cell, where the least hydrophobic complex exclusively stains the nucleus whereas the more hydrophobic ones seem to predominantly stain membrane structures in the cytoplasm. In live cells CLSM show that initially only the more hydrophobic derivatives stain the plasma membrane. However, brief further exposure to the laser light causes permeabilization of the membrane and accumulation of extracellular ruthenium complexes in internal cellular structures, similarly to the distribution found in fixed cells.