Analysis of the interaction of membrane-active peptides with membranes: The case of melittin in surfactant assemblies

Some of the factors that govern the interaction between membrane-active peptides and membranes were analyzed using melittin as an example. The structural properties of melittin were studied in a variety of micellar and reverse micellar assemblies of varying sizes, shapes, and net charges. The roles of the polarity, packing, and the charge carried by the host assembly on the structural features of the incorporated melittin are delineated. Such an analysis is expected to be of relevance to other membrane-active peptides as well.     

Photophysics of norharmane in micellar environments: a fluorometric study

Steady state photophysics of norharmane (NHM) has been studied in different aqueous micellar environments. In aqueous solution at pH 7, excitation of the neutral species promotes a rapid transfer of proton giving rise to the corresponding cationic emission. Aqueous micelles differing in their surface charge characteristics interact with the fluorophore differently. The dependence of the fluorescence of the probe molecule on different micelles has been exploited to determine the critical micellar concentrations (CMCs) of the surfactants. The binding constant (K) and free energy change (deltaG) for the interaction of norharmane with the micelles have been evaluated from the fluorescence data. The probable location of the probe in the micelles has also been suggested. Polarity of the microenvironment around the probe has been determined for CTAB and TX-100 micellar systems from a comparison of the variation of fluorescence properties of the two prototropic species in water-dioxane mixture with varying composition.     

Spectral properties and inclusion of a hetero-chalcone analogue in organized media of micellar solutions and beta-cyclodextrin

The absorption and fluorescence emission spectral properties of 3-(4'-dimethylaminophenyl)-1-(2-thienyl)prop-2-en-1-one, abbreviated as DMATP, have been investigated in organized media of aqueous micellar and beta-cyclodextrin (CD) solutions. While the absorption spectra are less sensitive to the nature of the added surfactant or CD, the characteristics of the intramolecular charge transfer (ICT) fluorescence are highly sensitive to the properties of the medium. The ICT maximum is strongly blue-shifted with a great enhancement in the fluorescence quantum yield on adding micellar or CD solutions. This indicates the solubilization of DMATP in the micellar core and formation of an inclusion complex with beta-CD. The critical micelle concentration (CMC) as well as the polarity of the micellar core of SDS, CTAB and TX-100 have been determined. The CMC values are in good agreement with the reported values while the polarity is lower indicating that DMATP molecules are incorporated in the micellar core not at the micellar interface. The inclusion constants of binding of DMATP in micellar or CD have been also determined. The thermodynamic parameters of formation of DMATP:CD inclusion complex have been calculated from the temperature dependence of the fluorescence spectra of the formed complex. The negative enthalpy and free energy of formation indicate that the inclusion process is energetically favorable. The highly negative value of formation entropy (DeltaS = -162.3 J mol(-1) K(-1)) reflects the high restrictions imposed on the movement of both the host and included guest molecules which is consistent with the increase of the fluorescence yield and blue shift of the fluorescence maximum.     

Optimization of DNA immobilization on gold electrodes for label-free detection by electrochemical impedance spectroscopy

The ability to immobilize DNA probes onto gold substrates at an optimum surface density is key in the development of a wide range of DNA biosensors. We present a method to accurately control probe DNA surface density by the simultaneous co-immobilization of thiol modified probes and mercaptohexanol. Probe surface density is controlled by the thiol molar ratio in solution, with a linear relationship between thiol molar ratio and probe density spanning (1-9) x10(12)/cm2. The probe surface density per microscopic surface area was determined using chronocoulometry, and a detailed analysis of the method presented. Using this sample preparation method, the effect of probe density and hybridization on the charge transfer resistance with the negatively charged ferri/ferrocyanide redox couple was determined. Above a threshold probe surface density of 2.5 x 10(12)/cm2, electrostatic repulsion from the negatively charged DNA modulates the charge transfer resistance, allowing hybridization to be detected. Below the threshold density no change in charge transfer resistance with probe density or with hybridization occurs. The probe surface density was optimized to obtain the maximum percentage change in charge transfer resistance with hybridization.     

Interactions Of Vitamin E With Free Radicals And Membranes

-Tocopherol performs an antioxidant role in biological membranes by acting as a one-electron reductant. In micellar solutions it has been observed by pulse radiolysis that the micellar charge has a pronounced effect on the rate constant for repair of organic free radicals by -tocopherol. The interactions between -tocopherol and model bilayer lipid membranes have been studied by fluorescence spectroscopy. Quencing of -tocopherol fluorescence by acrylamide and some n-doxyl stearates shows the transverse distribution of -tocopherol in membranes to be affected by the physical state of the membrane lipids and by the salt concentration in the aqueous phase. Time-resolved fluorescence depolarization measurements, with a diphenylhexatriene-phospholipid conjugate as probe. demonstrate an increase in the bilayer order parameter on incorporation of -tocopherol into a membrane     

Interactions Of Vitamin E With Free Radicals And Membranes

α-Tocopherol performs an antioxidant role in biological membranes by acting as a one-electron reductant. In micellar solutions it has been observed by pulse radiolysis that the micellar charge has a pronounced effect on the rate constant for repair of organic free radicals by α-tocopherol. The interactions between α-tocopherol and model bilayer lipid membranes have been studied by fluorescence spectroscopy. Quencing of α-tocopherol fluorescence by acrylamide and some n-doxyl stearates shows the transverse distribution of α-tocopherol in membranes to be affected by the physical state of the membrane lipids and by the salt concentration in the aqueous phase. Time-resolved fluorescence depolarization measurements, with a diphenylhexatriene-phospholipid conjugate as probe. demonstrate an increase in the bilayer order parameter on incorporation of α-tocopherol into a membrane     

Time-resolved fluorescence and circular dichroism of porphyrin cytochrome c and Zn-porphyrin cytochrome c incorporated in reversed micelles

Interactions between fluorescent horse heart cytochrome c derivatives (e. g. porphyrin cytochrome c and Zn-porphyrin cytochrome c) with surfactant interfaces in reversed micellar solutions have been studied, using different spectroscopic techniques. Anionic [sodium bis(2-ethylhexyl)sulfosuccinate, AOT] and cationic (cetyltrime-thylammonium bromide, CTAB) surfactant solutions have been used in order to investigate the effects of charge interactions between proteins and interfaces. Circular dichroism reveals that much of the protein secondary structure is lost in AOT-reversed micelles, especially when the molar water/surfactant ratio, wo, is high (wo = 40), whereas in CTAB-reversed micelles secondary structure seems to be preserved. Time-resolved fluorescence measurements of the porphyrin in the cytochrome c molecule yields information about the changes in structure and the dynamics of the protein upon interaction with surfactant assemblies both in aqueous and in hydrocarbon solutions. With AOT as surfactant a strong interaction between protein and interface can be observed. The effects found in aqueous AOT solution are of the same kind as in hydrocarbon solution. In the CTAB systems the interactions between protein and surfactant are much less pronounced. The measured effects on the fluorescence properties of the proteins are different in aqueous and hydrocarbon solutions. In general, the observations can be explained by an electrostatic attraction between the overall positively charged protein molecules and the anionic AOT interface. Electrostatic attraction can also occur between the cytochrome c derivatives and CTAB because there is a negatively charged zone on the surface of the proteins. From the fluorescence anisotropy decays it can be concluded that in the CTAB-reversed micellar system these interactions are not important, whereas in an aqueous CTAB solution the proteins interact with surfactant molecules.     

Luminescence study of G-quadruplex formation in the presence of Tb3+ ion

The interactions of Tb3+ with the quadruplex-forming oligonucleotide bearing human telomeric repeat sequence d(G(3)T(2)AG(3)T(2)AG(3)T(2)AG(3)), (htel21), have been studied using luminescence spectroscopy and circular dichroism (CD). Enhanced luminescence of Tb3+, resulting from energy transfer from guanines, indicated encapsulation of Tb3+ ion in the central cavity of quadruplex core. The ability of lanthanide ions (Eu3+ and Tb3+) to mediate formation of quadruplex structure has been further evidenced by the fluorescence energy transfer measurements with the use of oligonucleotide probe labeled with fluorescein and rhodamine FRET partners, FAM-htel21-TAMRA. The CD spectra revealed that Tb3+/htel21 quadruplex possesses antiparallel strand orientation, similarly as sodium quadruplex. Tb3+ binding equilibria have been investigated in the absence and the presence of competing metal cations. At low Tb3+ concentration (8 microM) Tb3+/htel21 quadruplex stability is very high (5 x 10(6) M(-1)) and stoichiometry of 5-7 Tb3+ ions per one quadruplex molecule is observed. Luminescence and CD titration experiments suggested that the cavity of quadruplex accommodates two Tb3+ ions and the remaining Tb3+ ions bind probably to TTA loops of quadruplex. Higher concentration of Tb3+ (above 10 microM) results in the excessive binding of Tb3+ ions that finally destabilizes quadruplex, which undergoes transformation into differently organized assemblies. Such assemblies (probably possessing multiple positive charge) exhibit kinetic stability, which is manifested by a very slow kinetics of displacement of Tb3+ ion by competing cations (Li+, Na+, K+).     

Surface potential and energy-coupling in bioenergy-conserving membrane systems

In order to understand the localization of dyes and the nature of their responses in membranes and particularly in those involved in energy-conservation processes, the influence of micelles of neutral and ionic surfactants on the pK _a of solubilized fluorophoric (umbelliferone) and chromophoric (bromthymol blue and methyl red) indicator dyes is studied. It is shown that the pK _a of the indicator adsorbed onto micelles shifted towards the acid extreme with cationic micelles, to the alkaline side with anionic micelles while it was not significantly modified by the neutral ones. Maximal displacements were observed with Methyl Red where the difference in pK _a between anionic and cationic micelles was as large as 3 pH units. Phospholipid liquid crystals (Liposomes) of phosphatidylcholine with and without adsorbed long-chain ions introduced in order to confer to it a net surface charge induced displacements of the pK _a of UBF analogous to those detected in the presence of detergent micelles. It was demonstrated that UBF can monitor reversal of charge phenomena such as that obtained by the interaction of phosphatidylcholine + dicetyl phosphate liposomes (anionic colloid) with poly-L-lysine (cationic colloid). The partition of the indicator dyes between micellar and aqueous phases was determined by gel filtration revealing thequasi exclusive presence of the dyes in the micellar phase. Fluorescence polarization measurement of solubilized UBF in either ionic micelles or submitochondrial particles indicate that the dye tumbling rate is as rapid as in pure water suggesting that the dye is mobile in an interfacial environment where it can experience modifications due to changes in surface potential. The use of UBF as a probe of respiration-dependent energy-linked reactions in submitochondrial particles is presented. The available data on the use of indicator dyes in mitochondrial, chloroplast and bacterial chromatophore membranes is reevaluated, on the basis of the evidence of the extreme sensitivity of these probes to surface charge. The implications of these results and considerations are discussed in terms of the importance of the surface potential in the primary event of the energy-coupling process in oxidative and photosynthetic phosphorylation.A preliminary account of this research has been presented elsewhere (IV International Biophysics Congress of the International Union of Pure and Applied Biophysics, Moscow, August 1972).     

Development of the myoglobin sensor based on the surface plasmon resonance

Bioaffinic sensor based on the surface plasmon resonance (SPR) with golden layer as a transducer was developed. This sensor was applied for control of antigen-antibodies (Ag-Ab) interactions. For modification of transducer surface the spontaneously organized molecular assemblies of two types of mercaptan were formed. It was shown that the created bioaffinic sensor allowed to detect minimal concentration of antibodies, about 1 ng/ml, to the human heart myoglobin, which preliminary was immobilized on the sensitive surface. The particularities of the dynamics of protein interaction were observed. Duration of incubation with the biospecific component was no more than 5 minutes. After rupturing of specific binding it was possible to obtain initial signal again during 7-9 cycles.     

NMR derived model of GTPase effector domain (GED) self association: relevance to dynamin assembly

Self-association of dynamin to form spiral structures around lipidic vesicles during endocytosis is largely mediated by its 'coiled coil' GTPase Effector Domain (GED), which, in vitro, self-associates into huge helical assemblies. Residue-level structural characterizations of these assemblies and understanding the process of association have remained a challenge. It is also impossible to get folded monomers in the solution phase. In this context, we have developed here a strategy to probe the self-association of GED by first dissociating the assembly using Dimethyl Sulfoxide (DMSO) and then systematically monitoring the refolding into helix and concomitant re-association using NMR spectroscopy, as DMSO concentration is progressively reduced. The short segment, Arg109 - Met116, acts as the nucleation site for helix formation and self-association. Hydrophobic and complementary charge interactions on the surfaces drive self-association, as the helices elongate in both the directions resulting in an antiparallel stack. A small N-terminal segment remains floppy in the assembly. Following these and other published results on inter-domain interactions, we have proposed a plausible mode of dynamin self assembly.     

Brownian dynamics simulation of probe diffusion in DNA: effects of probe size, charge and DNA concentration

We have used Brownian dynamics simulation to study probe diffusion in solutions of short chain DNA using our previously developed simulation algorithm. We have examined the effect of probe size, charge, and DNA concentration on the probe diffusion coefficient, with the aim of gaining insight into the diffusion of proteins in a concentrated DNA environment. In these simulations, DNA was modeled as a worm-like chain of hydrodynamically equivalent spherical frictional elements while probe particles were modeled as spheres of given charge and hydrodynamic radius. The simulations allowed for both short range Lennard-Jones interactions and long ranged electrostatic interactions between charged particles. For uncharged systems, we find that the effects of probe size and DNA concentration on the probe diffusion coefficient are consistent with excluded volume models and we interpret our results in terms of both empirical scaling laws and the predictions of scaled particle theory. For charged systems, we observe that the effects of probe size and charge are most pronounced for the smallest probes and interpret the results in terms of the probe charge density. For an ionic strength of 0.1 M we find that, below a critical probe surface charge density, the probe diffusion coefficient is largely independent of probe charge and only weakly dependent on the DNA charge. These effects are discussed in terms of the interactions between the probe and the DNA matrix and are interpreted in terms of both the underlying physics of transport in concentrated solutions and the assumptions of the simulation model.     

Electron spin resonance studies on the dynamics of phosphatidylcholine — sulfatide model membranes

The effects of sulfatide on the fluidity and surface dynamics of bilayered and micellar model membranes of egg phosphatidylcholine containing sulfatide were studied by electron spin resonance (ESR). 5-Nitroxystearic acid and 15-nitroxystearic acid were employed as spin-label probes for the region close to the surface and that close to the hydrophobic core of lipid structures. In the vesicular structures, the signals generated by 5-nitroxystearic acid showed that the presence of sulfatide reduced the mobility of the hydrocarbon chains around the probe. The effect increased with increasing glycolipid concentration. The decrease in membrane fluidity was also monitored with the 15-nitroxystearic acid probe, although to a lesser extent. We think that sulfatide causes strong side-to-side head-group interactions on the bilayer surface, causing the lipid chains to assemble in a more rigid fashion, though this effect may be balanced in part by the disordered mechanical coupling of glycolipid acyl chains in theapposite faces of the hydrophobic core of the bilayer. Reduction of this mechanical coupling between apposite lipids when there was transition from a bilayered to a micellar structure resulted in a further increase in the order of the system.     

pH-triggered reversible "stealth" polycationic micelles

Amphiphilic polycations with a "stealth" cationic nature have been designed and synthesized by the PEGylation of polycationic amphiphile via a novel pH responsible benzoic imine linker. The linkage is stable in aqueous solution at physiological pH but cleaves in slight acidic conditions such as the extracellular environment of solid tumor and endosomes. The polymeric micelle formed from the amphiphilic "stealth" polycation contains a pH-switchable cationic surface driven by the reversible detachment/reattachment of the shielding PEG chains due to the cleavage/formation process of the imine linkage. At physiological pH, the micellar surface was shielded by the PEG corona, leading to lower cytotoxicity and less hemolysis, whereas in a mild acidic condition like in endosomes or solid tumors, the deshielding of the PEG chains exposed the positive charge on the micellar surface and retained the membrane disrupting ability. The amphiphilic "stealth" polycation is potentially useful as a drug targeting system toward tumors via endocytosis and trafficked through the endosomal pathway.     

Spectroscopic characterization of 2-amino-N-hexadecyl-benzamide (AHBA), a new fluorescence probe for membranes

We report the results of investigation on the spectroscopic properties of a new fluorescent lipophylic probe. The fluorophore o-aminobenzoic acid was covalently bound to the acyl chain hexadecylamine, producing the compound 2-amino-N-hexadecyl-benzamide. The behavior of the probe was dependent on the polarity of the medium: absorption and emission spectral position, quantum yield and lifetime decay indicate distinct behavior in water compared to ethanol and cyclohexane. The probe dissolves in the organic solvents, as indicated by the very low value of steady state fluorescence anisotropy and the short rotational correlation times obtained from fluorescence anisotropy decay measurements. On the other hand, the probe has low solubility in water, leading to the formation of aggregates in aqueous medium. The complex absorption spectrum in water was interpreted as originating from different forms of aggregation, as deduced from the wavelength dependence of anisotropy parameters. The probe interacts with surfactants in pre-micellar and micellar forms, as observed in experiments in the presence of sodium n-dodecylsulphate (SDS), n-cetyltrimethylammonium bromide (CTAB); 3-(dodecyl-dimethylammonium) propane-1-sulphonate (DPS) and 3-(hexadecyl-dimethylammonium) propane-1-sulphonate (HPS), and with vesicles of the phospholipid dimiristoyl-phosphatidylcholine (DMPC). The results demonstrate that AHBA is able to monitor properties like surface electric potential and phase transition of micelles and vesicles.     

Light scattering measurements on gangliosides: dependence of micellar properties on molecular structure and temperature

Static and dynamic laser light scattering measurements on micellar aqueous solutions of gangliosides GM2, GM1, GD1a are reported. The aggregation number, the hydrodynamic radius and the micellar shape depend on the type of ganglioside and the unsaturation degree of the hydrocarbon chains. At a temperature of 25 degrees C the molecular weights of GM2, GM1 and GD1a are 740,000, 470,000 and 418,000 DA respectively. A significant decrease of micellar size with temperature has been found for saturated GM1 in the region 25 degrees-40 degrees C. The strong sensitivity of the micellar parameters to the ganglioside structure is explained by making reference to some simple model which takes into account geometrical packing considerations. By measuring the scattered light intensity at low ionic strength of the solution (0.1-30 mE) it was possible to evaluate the ganglioside micellar charge, 100 electronic units for GM2, 48 for GM1 and 60 for GD1a.     

Structural hierarchy in molecular films of two class II hydrophobins

Hydrophobins are highly surface-active proteins that are specific to filamentous fungi. They function as coatings on various fungal structures, enable aerial growth of hyphae, and facilitate attachment to surfaces. Little is known about their structures and structure-function relationships. In this work we show highly organized surface layers of hydrophobins, representing the most detailed structural study of hydrophobin films so far. Langmuir-Blodgett films of class II hydrophobins HFBI and HFBII from Trichoderma reesei were prepared and analyzed by atomic force microscopy. The films showed highly ordered two-dimensional crystalline structures. By combining our recent results on small-angle X-ray scattering of hydrophobin solutions, we found that the unit cells in the films have dimensions similar to those of tetrameric aggregates found in solutions. Further analysis leads to a model in which the building blocks of the two-dimensional crystals are shape-persistent supramolecules consisting of four hydrophobin molecules. The results also indicate functional and structural differences between HFBI and HFBII that help to explain differences in their properties. The possibility that the highly organized surface assemblies of hydrophobins could allow a route for manufacturing functional surfaces is suggested.     

The morphology of adsorbed extracellular matrix assemblies is critically dependent on solution calcium concentration.

The adsorption of proteins to surfaces may alter their biological properties. Understanding and controlling these interactions is important in ultrastructural, biochemical and cellular studies. We have previously demonstrated that both the morphology and biological function of extracellular matrix assemblies such as fibrillin and type VI collagen microfibrils are influenced by surface chemistry. In this study we have employed atomic force microscopy to determine if the morphology of extracellular matrix microfibrils is influenced by solution chemistry. Microfibrils were adsorbed to mica or poly-L-lysine modified mica (mica-PLL) in the presence of 31 microM-1000 microM Ca(2+). Although both microfibrillar species adsorbed to mica and mica-PLL at all calcium concentrations, maximal adsorption was observed on mica at 125-250 microM. On mica surfaces fibrillin microfibril morphology varied continuously with calcium concentration from laterally diffuse assemblies at high concentrations to compact assemblies at low concentrations. In contrast, distinct type VI collagen microfibril morphologies were observed at high, intermediate and low calcium concentrations. Similar calcium dependent microfibrillar morphologies were evident on mica-PLL. Therefore physiologically relevant concentrations of solution calcium, independent of surface charge, profoundly influenced both the adsorbed amount and morphology of native extracellular assemblies. These studies highlight the importance not only of surface chemistry but also of solute composition and concentration in influencing the morphology and hence biological function of adsorbed proteins.     

Hydration and protein folding in water and in reverse micelles: compressibility and volume changes

The partial specific volume and adiabatic compressibility of proteins reflect the hydration properties of the solvent-exposed protein surface, as well as changes in conformational states. Reverse micelles, or water-in-oil microemulsions, are protein-sized, optically-clear microassemblies in which hydration can be experimentally controlled. We explore, by densimetry and ultrasound velocimetry, three basic proteins: cytochrome c, lysozyme, and myelin basic protein in reverse micelles made of sodium bis (2-ethylhexyl) sulfosuccinate, water, and isooctane and in aqueous solvents. For comparison, we use beta-lactoglobulin (pI = 5.1) as a reference protein. We examine the partial specific volume and adiabatic compressibility of the proteins at increasing levels of micellar hydration. For the lowest water content compatible with complete solubilization, all proteins display their highest compressibility values, independent of their amino acid sequence and charge. These values lie within the range of empirical intrinsic protein compressibility estimates. In addition, we obtain volumetric data for the transition of myelin basic protein from its initially unfolded state in water free of denaturants, to a folded, compact conformation within the water-controlled microenvironment of reverse micelles. These results disclose yet another aspect of the protein structural properties observed in membrane-mimetic molecular assemblies.     

Improving protein extraction yield in reversed micellar systems through surface charge engineering

The mechanism of extraction of rat cytochrome b(5) from water into a sodium dioctylsulfosuccinate (AOT) micellar organic phase was studied using protein engineering of surface charged residues. The extraction behavior of native cytochrome b(5) and modified proteins with substitutions of the type glutamic acid --> lysine at positions 44 (E44K), 56 (E56K), and 92 (E92K), was studied as a function of pH. The results indicate that an important mechanism of extraction is an electrostatic interaction of this protein with the negatively charged surfactant. We demonstrate that it is possible to improve extraction by engineering the protein surface charge, increasing the driving force responsible for the protein transfer to the micellar phase. (c) 1994 John Wiley & Sons, Inc.