Valdecir Farias Ximenes scite author profile

Apocynin is the most employed inhibitor of NADPH oxidase (NOX), a multienzymatic complex capable of catalyzing the one-electron reduction of molecular oxygen to the superoxide anion. Despite controversies about its selectivity, apocynin has been used as one of the most promising drugs in experimental models of inflammatory and neurodegenerative diseases. Here, we aimed to study the chemical and biophysical properties of apocynin. The oxidation potential was determined by cyclic voltammetry (Epa = 0.76V), the hydrophobicity index was calculated (logP = 0.83) and the molar absorption coefficient was determined ( 275nm = 1.1 × 10). Apocynin was a weak free radical scavenger (as measured using the DPPH, peroxyl radical and nitric oxide assays) when compared to protocatechuic acid, used here as a reference antioxidant. On the other hand, apocynin was more effective than protocatechuic acid as scavenger of the non-radical species hypochlorous acid. Apocynin reacted promptly with the non-radical reactive species H 2 O 2 only in the presence of peroxidase. This finding is relevant, since it represents a new pathway for depleting H 2 O 2 in cellular experimental models, besides the direct inhibition of NADPH oxidase. This could be relevant for its application as an inhibitor of NOX4, since this isoform produces H 2 O 2 and not superoxide anion. The binding parameters calculated by fluorescence quenching showed that apocynin binds to human . The association did not alter the secondary and tertiary structure of HSA, as verified by synchronous fluorescence and circular dichroism. The displacement of fluorescent probes suggested that apocynin binds to site I and site II of HSA. Considering the current biomedical applications of this phytochemical, the dissemination of these chemical and biophysical properties can be very helpful for scientists and physicians interested in the use of apocynin.

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Oxidation of melatonin and its catabolites, N¹‐acetyl‐N ²‐formyl‐5‐methoxykynuramine and N¹‐acetyl‐5‐methoxykynuramine, by activated leukocytes

Silva

Rodrigues

Carvalho

et al. 2004

Journal of Pineal Research

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N(1)-acetyl-N(2)-formyl-5-methoxykynuramine (AFMK) and N(1)-acetyl-5-methoxykynuramine (AMK), two melatonin catabolites, have been described as potent antioxidants. We aimed to follow the kinetics of AFMK and AMK formation when melatonin is oxidized by phorbol myristate acetate (PMA) and lipopolysaccharide (LPS)-activated leukocytes. An HPLC-based method was used for AFMK and AMK determination in neutrophil and peripheral blood mononuclear cell cultures supernatants. Samples were separated isocratically on a C18 reverse-phase column using acetonitrile/H(2)O (25:75) as the mobile phase. AFMK was detected by fluorescence (excitation 340 nm and emission 460 nm) and AMK by UV-VIS absorbance (254 nm). Activation of neutrophils and mononuclear cells with PMA produces larger amounts of AFMK than activation with LPS, probably due to the lower levels of reactive oxygen species formation and myeloperoxidase (MPO) degranulation that occurs when cells are stimulated with LPS. The concentration of AMK found in the supernatant was about 5-10% (from 18-hr cultures) compared with AFMK. This result may reflect its reactivity. Indeed AMK, but not AFMK, is easily oxidized by activated neutrophils in a MPO and hydrogen peroxide-dependent reaction. In conclusion, we defined a simple procedure for the determination of AFMK and AMK in biological samples and demonstrated the capacity of leukocytes to oxidize melatonin and AMK.

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Synthetic nanoparticles of bovine serum albumin with entrapped salicylic acid

Bronze‐Uhle¹,

Costa²,

Ximenes³

et al. 2016

NSA

124

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Bovine serum albumin (BSA) is highly water soluble and binds drugs or inorganic substances noncovalently for their effective delivery to various affected areas of the body. Due to the well-defined structure of the protein, containing charged amino acids, albumin nanoparticles (NPs) may allow electrostatic adsorption of negatively or positively charged molecules, such that substantial amounts of drug can be incorporated within the particle, due to different albumin-binding sites. During the synthesis procedure, pH changes significantly. This variation modifies the net charge on the surface of the protein, varying the size and behavior of NPs as the drug delivery system. In this study, the synthesis of BSA NPs, by a desolvation process, was studied with salicylic acid (SA) as the active agent. SA and salicylates are components of various plants and have been used for medication with anti-inflammatory, antibacterial, and antifungal properties. However, when administered orally to adults (usual dose provided by the manufacturer), there is 50% decomposition of salicylates. Thus, there has been a search for some time to develop new systems to improve the bioavailability of SA and salicylates in the human body. Taking this into account, during synthesis, the pH was varied (5.4, 7.4, and 9) to evaluate its influence on the size and release of SA of the formed NPs. The samples were analyzed using field-emission scanning electron microscopy, transmission electron microscopy, Fourier transform infrared, zeta potential, and dynamic light scattering. Through fluorescence, it was possible to analyze the release of SA in vitro in phosphate-buffered saline solution. The results of chemical morphology characterization and in vitro release studies indicated the potential use of these NPs as drug carriers in biological systems requiring a fast release of SA.

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Superoxide-dependent Oxidation of Melatonin by Myeloperoxidase

Ximenes

Silva

Rodrigues

et al. 2005

Journal of Biological Chemistry

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Myeloperoxidase uses hydrogen peroxide to oxidize numerous substrates to hypohalous acids or reactive free radicals. Here we show that neutrophils oxidize melatonin to N 1 -acetyl-N 2 -formyl-5-methoxykynuramine (AFMK) in a reaction that is catalyzed by myeloperoxidase. Production of AFMK was highly dependent on superoxide but not hydrogen peroxide. It did not require hypochlorous acid, singlet oxygen, or hydroxyl radical. Purified myeloperoxidase and a superoxide-generating system oxidized melatonin to AFMK and a dimer. The dimer would result from coupling of melatonin radicals. Oxidation of melatonin was partially inhibited by catalase or superoxide dismutase. Formation of AFMK was almost completely eliminated by superoxide dismutase but weakly inhibited by catalase. In contrast, production of melatonin dimer was enhanced by superoxide dismutase and blocked by catalase. We propose that myeloperoxidase uses superoxide to oxidize melatonin by two distinct pathways. One pathway involves the classical peroxidation mechanism in which hydrogen peroxide is used to oxidize melatonin to radicals. Superoxide adds to these radicals to form an unstable peroxide that decays to AFMK. In the other pathway, myeloperoxidase uses superoxide to insert dioxygen into melatonin to form AFMK. This novel activity expands the types of oxidative reactions myeloperoxidase can catalyze. It should be relevant to the way neutrophils use superoxide to kill bacteria and how they metabolize xenobiotics.Catalysis of hypochlorous acid production is the accepted physiological function of myeloperoxidase (MPO) 2 (1, 2). This heme enzyme is the major protein in neutrophils and is also present in monocytes, macrophages, microglia (3), and neurons (4, 5). It reacts with hydrogen peroxide to form the redox intermediate compound I, which oxidizes chloride to hypochlorous acid with coincident regeneration of the native enzyme (Reactions 1 and 2). HOCl indicates hypochlorous acid.Myeloperoxidase also promotes the oxidation of numerous substrates (RH) to free radical intermediates via the classical peroxidase cycle involving compound I and compound II (Reactions 3 and 4).Klebanoff (6) was the first to show that myeloperoxidase has potent antimicrobial activity because of its ability to generate hypochlorous acid. He proposed that myeloperoxidase produces hypochlorous acid inside phagosomes where it reacts with and kills ingested bacteria. However, during microbial killing myeloperoxidase functions in the presence of a high flux of superoxide (7). Superoxide reacts rapidly with native enzyme to produce oxymyeloperoxidase or compound III (Reaction 5; k 5 ϭ 2 ϫ 10 6 M Ϫ1 s Ϫ1 (8)), which is the dominant form of myeloperoxidase in stimulated neutrophils (9). Reactions of superoxide with myeloperoxidase are likely to be important in host defense because it has been demonstrated that superoxide enhances myeloperoxidasedependent killing of Staphylococcus aureus by isolated human neutrophils (10). The nature of this interaction has yet to be revealed.Compound II...

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