C. Reyes Mateo

The relationship between the antioxidant and the antibacterial properties of galloylated catechins and the structure of phospholipid model membranes

The effects of four catechins, (+)-catechin (C), (-)-epicatechin (EC), (-)-epicatechin gallate (ECG), and (-)-epigallocatechin gallate (EGCG), on the physical properties of phospholipid model membranes and the correlation to their antioxidant and antibacterial capacities have been studied by using differential scanning calorimetry (DSC), fluorescence spectroscopy, infrared spectroscopy (IR), AAPH-induced oxidation, and leakage experiments. DSC data revealed that galloylated catechins, especially ECG, affected the physical properties of both the phosphatidylcholine (PC) and phosphatidylethanolamine (PE) bilayers dramatically. Galloylated catechins showed higher phospholipid/water partition coefficients than their homologues and were immersed in the phospholipid palisade intercalating within the hydrocarbon chains, ECG being at the deepest position. In contrast, nongalloylated catechins presented a shallow location close to the phospholipid/water interface. ECG also exhibited the highest antioxidant capacity against lipid peroxidation, which correlated with its strong effect on DPH fluorescence anisotropy (as observed by the increase of the lipid order of fluid PC bilayers) and with the presence of highly cooperative transitions as seen by DSC. We propose that the high antioxidant capacity of some galloylated catechins such as ECG could be partially due to the formation of membrane structures showing resistance to detergent solubilization and in which the phospholipids have tightly packed acyl chains and highly hydrated phosphate groups. Significantly, PE was found to be essential to the promotion of carboxyfluorescein leakage from bacterial model membranes by galloylated catechins, indicating that their bactericidal activity, at least at the membrane level, could be due to the specific effect of these catechins on PE.

Freeze-Drying of Aqueous Solutions of Deep Eutectic Solvents: A Suitable Approach to Deep Eutectic Suspensions of Self-Assembled Structures

This work describes how the preparation of deep eutectic solvents (DES) in its pure state can be accomplished through a simple approach based on the freeze-drying of aqueous solutions of the individual counterparts of DES. DES in its pure state obtained via freeze-drying are studied by (1)H NMR, which reveals the formation of halide ion-hydrogen-bond-donor supramolecular complexes (characteristic of DES), and by cryo-etch-SEM, which provides insight about the capability of aqueous solutions of DES to be segregated in DES and ice upon freezing. The paper also explores the suitability of the freeze-drying approach to incorporate organic self-assemblies (in particular, liposomes of ca. 200 nm) in DES with full preservation of their self-assembled structure. This is not a trivial issue given that amphiphilic molecules tend to be readily dissolved (hence, disassembled) in DES. The strategy proposed in this work is based on the freeze-drying of aqueous solutions containing the individual counterparts of DES and the preformed liposomes (also known as large unilamellar vesicles or LUV). The simplicity of the method should also make it suitable for the incorporation of different self-assembled structures (such other types of vesicles and micelles) in DES in its pure state.

Effects of (+)-totarol, a diterpenoid antibacterial agent, on phospholipid model membranes.

(+)-Totarol, a highly hydrophobic diterpenoid isolated from Podocarpus spp., is inhibitory towards the growth of diverse bacterial species. (+)-Totarol decreased the onset temperature of the gel to liquid-crystalline phase transition of DMPC and DMPG membranes and was immiscible with these lipids in the fluid phase at concentrations greater than 5 mol%. Different (+)-totarol/phospholipid mixtures having different stoichiometries appear to coexist with the pure phospholipid in the fluid phase. At concentrations greater than 15 mol% (+)-totarol completely suppressed the gel to liquid-crystalline phase transition in both DMPC and DMPG vesicles. Incorporation of increasing amounts of (+)-totarol into DEPE vesicles induced the appearance of the H(II) hexagonal phase at low temperatures in accordance with NMR data. At (+)-totarol concentrations between 5 and 35 mol% complex thermograms were observed, with new immiscible phases appearing at temperatures below the main transition of DEPE. Steady-state fluorescence anisotropy measurements showed that (+)-totarol decreased and increased the structural order of the phospholipid bilayer below and above the main gel to liquid-crystalline phase transition of DMPC respectively. The changes that (+)-totarol promotes in the physical properties of model membranes, compromising the functional integrity of the cell membrane, could explain its antibacterial effects.

A fluorescence study of the interaction and location of (+)-totarol, a diterpenoid bioactive molecule, in model membranes.

(+)-Totarol, a diterpene extracted from Podocarpus totara, has been reported as a potent antioxidant and antibacterial agent. Although the molecular mechanism of action of this hydrophobic molecule remains unknown, recent work made in our laboratory strongly suggests that it could be lipid-mediated. Since (+)-totarol contains a phenolic ring, we have studied the intrinsic fluorescent properties of this molecule, i.e., quantum yield, lifetime, steady-state anisotropy and emission spectra, both in aqueous and in phospholipid phases, in order to obtain information on the interaction and location of (+)-totarol in biomembrane model systems. The phospholipid/water partition coefficient of (+)-totarol was found to be very high (K(p)=1.8x10(4)), suggesting that it incorporates very efficiently into membranes. In order to estimate the transverse location (degree of penetration) of the molecule in the fluid phase of DMPC model membranes, the spin labelled fatty acids 5-NS and 16-NS were used in differential quenching experiments. The results obtained show that (+)-totarol is located in the inner region of the membrane, far away from the phospholipid/water interface. Since (+)-totarol protects against oxidative stress, its interaction with an unsaturated fatty acid, trans-parinaric acid, was studied using fluorescence resonance energy transfer. No significant interactions were observed, molecules of trans-parinaric acid distributing themselves randomly amongst those of (+)-totarol in the phospholipid membrane.

Denaturation and Leaching Study of Horseradish Peroxidase Encapsulated in Sol-Gel Matrices

Sol-gel matrices have been shown to be relatively inert while preserving the spectroscopic properties and biological activity of the encapsulated proteins. Horseradish peroxidase (HRP) is a hemeprotein widely used in the field of biosensors because of its high specificity for hydrogen peroxide. However, partial inactivation of the protein has been reported when incorporated in aged gels. Whether that inactivation comes from the unfolding of some of the encapsulated proteins or from the leaching of the heme non-covalent active site of HRP is evaluated by absorption and fluorescence spectroscopy. This study shows that the single Trytophan (Trp) fluorescence of HRP may be used to distinguish denaturation processes from leaching of the heme group, as well as to estimate the extent of the denaturation.

Immobilization of a trienzymatic system in a sol-gel matrix : A new fluorescent biosensor for xanthine

In this work we report the development of a highly sensitive fluorescent multienzymatic biosensor for quantitative xanthine detection. This biosensor is built by the simultaneous encapsulation of three enzymes, xanthine oxidase, superoxide dismutase and peroxidase, in a single sol-gel matrix coupled to the Amplex Red probe. The sol-gel chemistry yields a porous, optically transparent matrix that retains the natural conformation and the reactivity of the three co-immobilized proteins. Xanthine determination is based on a sequence of reactions, namely catalytic oxidation of xanthine to uric acid and superoxide radical, and subsequent catalytic dismutation of the radical, resulting in the formation of hydrogen peroxide, which reacts stoichiometrically with non-fluorescent Amplex Red to produce highly fluorescent resorufin. The optimal operational conditions for the biosensor were investigated. Linearity was observed for xanthine concentrations up to 3.5 microM, with a detection limit of 20 nM, which largely improved the sensitivity of the current xanthine biosensors. The developed biosensor is reusable and remains stable for 2 weeks under adequate storage conditions.

Immobilization and characterization of giant unilamellar vesicles (GUVs) within porous silica glasses

Immobilization of cells or artificial liposomes has interesting applications in protein biology, membrane biophysics, biomedicine, biosensor technology and new materials development. In this work for the first time we have entrapped giant unilamellar vesicles (GUVs) in silica glasses prepared by the sol–gel process. Results show that GUVs are successfully confined in the porous matrix retaining their structural integrity for at least fifteen days, allowing single-vesicle studies to be performed. Using different fluorescence microscopy approaches, we have studied the effect of the encapsulation on membrane properties, such as their size and shape, hydration degree, domain coexistence and lipid lateral mobility. Results reveal that these properties are altered to a more or less degree after immobilization, but most of vesicles are affected in a similar fashion and no different populations are distinguished. Such effects are attributed to the increase in lateral packing induced by changes in the hydrostatic and/or osmotic pressure occurring during the sol–gel process, as well as to the establishment of interactions between the polar head of the phospholipids and the negatively charged silica surface of the porous matrix.

Protein-Lipid Interactions : New Approaches and Emerging Concepts

From Lipid Phases to Membrane Protein Organization: Fluorescence Methodologies in the Study of Lipid-Protein Interactions.- NMR of Membrane Proteins in Lipid Environments: the Bcl-2 Family of Apoptosis Regulators.- X-ray and Neutron Diffraction Approaches to the Structural Analysis of Protein-Lipid Interactions.- The Role of Proteins in the Formation of Domains in Membranes.- Lateral Membrane Structure and Lipid-Protein Interactions.- The Membrane as a System: How Lipid Structure Affects Membrane Protein Function.- Peptide-Lipid Interaction: Shedding Light into the Mode of Action and Cell Specificity of Antimicrobial Peptides.- Structural and Functional Modulation of Ion Channels by Specific Lipids: from Model Systems to Cell Membranes.

Biophysical and functional characterization of an ion channel peptide confined in a sol-gel matrix.

Immobilization of zwitterionic lipid membranes in sol-gel matrices induces irreversible alterations of the bilayer fluidity, which can limit the use of these systems for practical applications. Recently, we have reported that electrostatic interactions between phospholipids polar heads and the negative-charged silica surface of the porous matrix should be the cause of such behavior. In the present work, we analyze the effect of these interactions on the biophysical and functional properties of the ion-channel peptide gramicidin, entrapped in a sol-gel matrix, to get more insight on the ability of these inorganic materials to immobilize ion channels and other membrane-bound proteins. Gramicidin was reconstituted in anionic and zwitterionic liposomes and the effects of sol-gel immobilization on the biophysical properties of gramicidin were determined from changes in the photophysical properties of its tryptophan residues. In addition, the physical state of the immobilized lipid membrane containing gramicidin was analyzed by measuring the spectral shift of the fluorescent probe Laurdan. Finally, the ion-channel activity of the peptide was monitored upon sol-gel immobilization through a fluorescence quenching assay using the fluorescent dye pyrene-1,3,6,8-tetrasulfonic acid (PTSA). Results show that the channel properties of the immobilized gramicidin are preserved in both zwitterionic and anionic liposomes, even though the zwitterionic polar heads interact with the porous surface of the host matrix.

Investigation of the effect of high hydrostatic pressure on proteins and lipidic membranes by dynamic fluorescence spectroscopy

Dynamic fluorescence spectroscopy brings new insight into the functional and structural changes of biological molecules under moderate and high hydrostatic pressure. The principles of time-resolved fluorescence methods are briefly described and the resulting type of information is summarized. A first set of selected applications of the use of dynamic fluorescence on pressure effects on proteins in terms of denaturation, ternary and quaternary structure, aggregation and also interaction with DNA are presented. A second set of applications is devoted to the effect of pressure and of cholesterol on lateral heterogeneity of lipidic membranes.