Lucio Zennaro

Preparation, morphological characterization, and activity of thin films of horseradish peroxidase

Active uniform films of horseradish peroxidase (HRP) have been prepared by covalent binding on Si/SiO2 or glass supports previously activated by silanization and succinylation. Labeling by fluorescent or by Electron Spin Resonance (ESR) probes was used to quantify the surface density of active groups and of horseradish peroxidase. Atomic Force Microscopy (AFM) imaging was used to characterize the surface morphology. We observed that a non‐uniform protein adsorption due to physical interactions was present when the supports were not activated for covalent binding and was, in large part, removed by washing. The enzyme deposited by covalent binding formed homogeneous layers with a height in the range 60–90 Å. By using a fluorescent label, we calculated a protein density of 3.6 × 1012 molecules cm−2 on Si/SiO2, corresponding to an estimated area per molecule of 2800 Å2 which is in agreement with the value expected on the basis of the crystallographic data considering the formation of a monomolecular layer. The protein density of the layer immobilized on glass was similar (1.9 ×1012 molecules cm−2). The enzyme immobilized on both supports showed a kcat/KM being of the order of 3–5×105 M−1s−1 that is 1/20th of free HRP. The half‐life time of the activity of the enzyme immobilized by covalent binding was longer than 40 days at 6°C.

Isolation of amine oxidase from bovine plasma by a two-step procedure

A novel method for isolation of amine oxidase from bovine plasma is reported; it involves a two-step procedure, namely ammonium sulfate fractionation and affinity chromatography with elution by aniline, which is a competitive inhibitor of the enzyme. A homogeneous enzyme, characterized by a specific activity of 0.44 U/mg, was obtained with a yield higher than 50%.

Determination of glucose oxidase immobilised as monolayer onto a flat surface.

An assay to estimate the amount of glucose oxidase immobilised as a monolayer onto a flat surface is reported. This method is based on the electrochemical detection of the flavin adenine dinucleotide (FAD) cofactor released by the immobilised enzyme in acid solutions. FAD concentration in the acid solution was measured by amperometry, using a flow injection analysis (FIA) system equipped with a wall-jet electrode, and with a sensitivity of (9.2+/-2.0)x10(-2) nA/nM. By this method, the amount of glucose oxidase molecules present in a monolayer deposited on a silanised glass slide was easily detected, in which the detection limit is more than one order of magnitude lower than the maximum loading of the surface with an ordered monolayer of glucose oxidase.

Fast and simple method for the simultaneous evaluation of the capacity and efficiency of food antioxidants in trapping peroxyl radicals in an intestinal model system

A simple oxygraphic method, for which the theoretical and experimental bases have been recently revised, has been successfully applied to evaluate the peroxyl radical chain-breaking characteristics of some typical food antioxidants in micelle systems, among which is a system that reproduces conditions present in the upper part of the digestive tract, where the absorption and digestion of lipids occur. This method permits one to obtain from a single experimental run the peroxyl radical trapping capacity (PRTC, that is, the number of moles of peroxyl radicals trapped by a given amount of food), the peroxyl radical trapping efficiency (PRTE, that is, the reciprocal of the amount of food that reduces to half the steady-state concentration of peroxyl radicals), and the half-life of the antioxidant ( t(1/2)) when only a small fraction of peroxyl radicals reacts with the antioxidants present in foods. Examples of application of the method to various types of foodstuffs have been reported, assessing the general validity of the method in the simple and fast evaluation of the above-reported fundamental antioxidant characteristics of foods.

Glutathione peroxidase 4-catalyzed reduction of lipid hydroperoxides in membranes: The polar head of membrane phospholipids binds the enzyme and addresses the fatty acid hydroperoxide group toward the redox center

GPx4 is a monomeric glutathione peroxidase, unique in reducing the hydroperoxide group (-OOH) of fatty acids esterified in membrane phospholipids. This reaction inhibits lipid peroxidation and accounts for enzymes vital role. Here we investigated the interaction of GPx4 with membrane phospholipids. A cationic surface near the GPx4 catalytic center interacts with phospholipid polar heads. Accordingly, SPR analysis indicates cardiolipin as the phospholipid with maximal affinity to GPx4. Consistent with the electrostatic nature of the interaction, KCl increases the KD. Molecular dynamic (MD) simulation shows that a -OOH posed in the core of the membrane as 13 - or 9 -OOH of tetra-linoleoyl cardiolipin or 15 -OOH stearoyl-arachidonoyl-phosphaphatidylcholine moves to the lipid-water interface. Thereby, the -OOH groups are addressed toward the GPx4 redox center. In this pose, however, the catalytic site facing the membrane would be inaccessible to GSH, but the consecutive redox processes facilitate access of GSH, which further primes undocking of the enzyme, because GSH competes for the binding residues implicated in docking. During the final phase of the catalytic cycle, while GSSG is produced, GPx4 is disconnected from the membrane. The observation that GSH depletion in cells induces GPx4 translocation to the membrane, is in agreement with this concept.

Measurement of lipid hydroperoxides in human plasma and lipoproteins by kinetic analysis of photon emission

Publisher Summary The measurement of plasma or lipoprotein lipid hydroperoxides requires a very sensitive, specific and accurate analytic procedure. This chapter discusses the most updated kinetic procedure for analyzing lipid hydroperoxides by chemiluminescence, where mathematical fitting of the integrated equation describing the whole kinetics of photon emission is used for calculating the hydroperoxide concentration in the sample. This approach provides (1) a better understanding and a continuous monitoring of the reaction chemistry underlying the photon emission; (2) a better analytical precision, since the effect of noise and background is minimized; and, (3) an indirect evaluation of the effect of antioxidants possibly present in the sample. This kinetic approach ensures that no side reactions are taking place and reduces the influence of signal noise and background. It is worth noting, on the other hand, that kinetic analysis is the most appropriate way for measuring a product—the excited form of aminophthalate—which is transient and does not accumulate like usual reaction products.

Stable aqueous solutions of naked titanate nanotubes.

Aqueous solutions of naked nanotubes with Ti concentration up to 10 mM are obtained by hydrothermal synthesis followed by extensive ultrasound treatment. The morphology, surface characteristics, and solution behavior of the solubilized nanotubes are investigated. The time course of the solubilization process driven by ultrasound follows a first-order kinetic law and is mediated by the competition between Na(+) and H(+) for surface sites. The dynamics of interaction with small cations (i.e. the sodium ion) is studied by nuclear magnetic resonance spectroscopy and is demonstrated to be a multifaced process, since Na(+) is in part free to exchange between the binding sites on nanotubes and the bulk and in part is confined to slowly exchanging nanotube sites. The aqueous titanate nanotube solutions are stable for months, thus opening new perspectives for the use of this material in drug delivery and in homogeneous photocatalysis.

Metabonomics by proton nuclear magnetic resonance in human pleural effusions: A route to discriminate between benign and malignant pleural effusions and to target small molecules as potential cancer biomarkers

Cytopathology is a noninvasive and cost‐effective method for detecting cancer cells in pleural effusions (PEs), although in many cases, the diagnostic performance is hindered by the paucity of significant cells or the lack of clear morphological criteria. This study presents the results of an omics approach to improving the diagnostic performance of PE cytology.

Surface characterisation of bags for total parenteral nutrition by tensiometry and atomic force microscopy

Bags made of poly-ethylene and poly-vinylchloride and of the copolymer ethylene-vinylacetate were used as containers of perfusion solutions for total parenteral nutrition. The bags were characterised by tensiometry (free energy and its polar and dispersed components) and atomic force microscopy (AFM) before and after various periods of storage of solutions for total parenteral nutrition containing L-aminoacids, electrolytes or glucose. In most of the cases, after storage of these solutions, tensiometric characterisation and atomic force microscopy analysis of the internal surface of bags showed deep modifications which highlight the adsorption of the solutes. The changes of surface characteristics were found to depend on the time of contact, the wettability of the polymer and the compounds present into the solutions, while their concentration has a negligible effect. Generally, the aminoacid solutions produced a higher increase in the polar component even after short storage times. Poly-ethylene and the copolymer ethylene-vinylacetate showed a greater inertia if compared with the poly-vinylchloride bags.

Reaction rates of α-tocopheroxyl radicals confined in micelles and in human plasma lipoproteins

α-Tocopherol, the main component of vitamin E, traps highly reactive radicals which otherwise might react with lipids present in plasmatic lipoproteins or in cell membranes. The α-tocopheroxyl radicals generated by this process have also a pro-oxidant action which is contrasted by their reaction with ascorbate or by bimolecular self-reaction (dismutation). The kinetics of this bimolecular self-reaction were explored in solution such as ethanol, and in heterogeneous systems such as deoxycholic acid micelles and in human plasma. According to ESR measurements, the kinetic rate constant (2k(d)) of the bimolecular self-reaction of α-tocopheroxyl radicals in micelles and in human plasma was calculated to be of the order of 10(5) M(-1) s(-1) at 37 °C. This value was obtained considering that the reactive radicals are confined into the micellar pseudophase and is one to two orders of magnitude higher than the value we found in homogeneous phase. The physiological significance of this high value is discussed considering the competition between bimolecular self-reaction and the α-tocopheroxyl radical recycling by ascorbate.