A Standardized Test for the Identification and Characterization of Melanins Using Electron Paramagnetic Resonance (EPR) Spectroscopy

Melanins are complex, incompletely understood polymeric pigments that historically have been difficult to investigate with common chemical, histochemical, and physicochemical techniques. Because these pigments uniquely contain a stable population of organic free radicals, electron paramagnetic resonance (EPR) spectroscopy is a particularly effective method for studying them, and a set of qualitative EPR criteria has been established for their identification. However, a number of practical problems have arisen in applying these criteria to identify and characterize unknown pigments in relatively scarce pathological specimens, indicating that a standardized approach is needed. As reported here, a standardized EPR test for melanin based on the EPR criteria has been developed, guided by the requirements that it be sensitive, accurate, simple, and easy to interpret. It has been evaluated using the well-characterized synthetic melanin prepared by alkaline autooxidation of 5,6-dihydroxyphenylalanine (Dopa) and initially applied to the identification and characterization of an unknown pigment purified from an unusual malignant lung tumor.     

Purified Human Neuromelanin, Synthetic Dopamine Melanin as a Potential Model Pigment, and the Normal Human Substantia Nigra: Characterization by Electron Paramagnetic Resonance Spectroscopy

Abstract: Neuromelanin is a poorly understood pigment that accumulates in catecholaminergic neurons during normal aging. Electron paramagnetic resonance spectroscopy, an especially effective technique for investigating melanins, is used in the present study to show unambiguously that neuromelanin is a melanin; however, it is not well modeled by synthetic dopamine melanin and thus is an atypical melanin. Some of the unusual features of neuromelanin can be explained by postulating two distinct sources for its free radicals, the dominant one possibly derived from a precursor containing sulfur. Examination of human substantia nigra by electron paramagnetic resonance spectroscopy during the purification of neuromelanin also demonstrates, contrary to some other studies, that a portion of the paramagnetic metal ions in this tissue are bound to the pigment in situ. Combined with previous histochemical data, these observations have implications for the mechanism through which neuromelanin accumulates in vivo and are consistent with its having a cytoprotective function under normal conditions, but a cytotoxic role at advanced ages and in patients with Parkinson's disease. Other results of this study show that homogenizing tissues during the purification of any natural pigment may cause contamination of the pigment by extraneous metal ions and that subsequent incubation in hot acid, though most effective in removing metal ions and hydrolyzing proteins, leads to degradation of melanin. A purification procedure using incubation in acid at room temperature, however, is well suited for identifying and characterizing unknown natural pigments by electron paramagnetic resonance spectroscopy.     

果蔬采后病害的生物防治(综述)

采用生物防治措施控制采后病害是当前果蔬采后保鲜的重要研究方向。概述了生物防治果蔬采后病害的方法,包括利用拮抗菌、诱导抗病性、天然植物产物以及抗病基因工程技术在果蔬病害防治上的研究与应用。     

Reducing Ability of the Striatum and Cerebral Cortex in Rats following Acute Administration of Risperidone or Haloperidol: An Estimation by in Vivo Electron Paramagnetic Resonance Imaging

In vivo temporal electron paramagnetic resonance (EPR) imaging of the blood-brain barrier-permeable nitroxide radical, 3-methoxycarbonyl-2,2,5,5-tetramethylpyrrolidin-1-yloxy (PCAM), in the brain of rats was conducted following acute administration of risperidone (RSP) or haloperidol (HPD). The half-life of the signal intensity of PCAM was obtained from a selected area in the temporal EPR images. The half-lives in the striatum and cerebral cortex for the RSP- or HPD-treated rats were significantly longer than for the control rats (p < 0.01). This finding indicates that the reducing abilities of the striatum and cerebral cortex decreased in the rats to which either RSP or HPD had been acutely administrated because the half-life of PCAM in the selected region of the brain reflects its reducing ability.     

高氧对果蔬采后生理影响研究进展

高氧（21%-100%O2）贮藏是近几年发展起来的果蔬采后处理技术之一.概述了高氧对果蔬采后生理如呼吸作用、乙烯合成、组织褐变、活性氧代谢及抗氧化能力、风味等方面的影响,还介绍了高氧对病原微生物生长和采后果蔬腐烂控制的作用.     

Direct Detection of Ascorbyl Radical in Experimental Brain Injury: Microdialysis and an Electron Spin Resonance Spectroscopic Study

Abstract: To examine the role played by free radicals in brain injury, we performed experiments to detect radicals in the frontal cortex of rats, using electron spin resonance (ESR) and microdialysis. A dialysis probe was inserted into the frontal cortex, and spin adducts in perfusates were immediately detected by ESR. We obtained a relatively stable doublet signal, with parameters of g = 2.0057 and aH = 0.17 mT. This signal corresponded with that of the ascorbyl radical. Ascorbyl radical in the perfusate collected from the frontal cortex was augmented by microinjection of H₂O₂ and FeCl₂ adjacent to the dialysis probe. When the rats were challenged with cold-induced brain injury, ascorbyl radical and lactate dehydrogenase (LDH) level in the perfusate increased significantly. Pretreatment with superoxide dismutase and catalase attenuated the increase in ascorbyl radical and LDH level induced by the cold injury. Infusion of FeCl₂ dissolved in perfusate caused a pronounced increase in ascorbyl radical and LDH level after the cold injury. We conclude that the direct detection of free radical formation further supports the hypothesis that free radicals play an important role in traumatic brain injury. Our findings also indicate that combined microdialysis with ESR spectroscopy is a useful in vivo method for monitoring free radical production in the brain.     

Antioxidant activities of 5-hydroxyoxindole and its 3-hydroxy-3-phenacyl derivatives: The suppression of lipid peroxidation and intracellular oxidative stress

The antioxidant activities of 5-hydroxyoxindole (1) and newly synthesized 3,5-dihydroxy-3-phenacyl-2-oxindole derivatives against rat liver microsome/tert-butylhydroperoxide system-induced lipid peroxidation and hydrogen peroxide-induced intracellular oxidative stress were investigated. Compound 1 and its derivatives showed significant suppression of lipid peroxidation and an intracellular oxidative stress. The effects of the more lipophilic derivatives tended to be greater than that of the original compound 1. The cytotoxicity of all of the oxindole derivatives on human promyelocytic leukemia HL60 cells was lower than that of 2,6-di(tert-butyl)-4-hydroxytoluene (BHT), a widely used phenolic antioxidant. These results show that compound 1 and its 3-substituted derivatives could be good lead candidates for future novel antioxidant therapeutics.     

Electron paramagnetic resonance spectroscopy as a probe of coordination structure in green heme systems: iron chlorins and iron formylporphyrins reconstituted into myoglobin

A series of ferric low-spin derivatives of myoglobin containing its natural prosthetic group, iron protoporphyrin IX, and reconstituted with iron heme s (a formyl-substituted porphyrin) and iron methylchlorin have been examined using low-temperature electron paramagnetic resonance (EPR) spectroscopy. Good agreement is observed between the EPR properties of parallel derivatives of natural myoglobin and heme s-myoglobin. Likewise, the EPR properties of parallel adducts of three types of iron chlorins, methylchlorin-myoglobin, sulfyomyoglobin (a myoglobin derivative known to contain a chlorin macrocycle) and synthetic chlorin models are similar to each other. The ferric chlorin systems are shown to exhibit increased tetragonality and decreased rhombicity values relative to protoporphyrin/formylporphyrin systems. Thus, EPR spectroscopy is a very useful technique with which to probe the coordination structure of naturally occurring iron chlorin proteins and the method can be used to distinguish between proteins containing iron formylporphyrins and iron chlorin prosthetic groups.     

Studies on the Circular Dichroism (CD) and Electron Paramaguetic Resonance(EPR) Spe-ctroscopy of the Partially Oxidized FeMo Protein from Azotobacter vinelandii Nitrogenase

After nitrogenase FeMo protein from A. vinelandii was incubated with a large excess (5–6 equivalents) of indigo carmine for 30–60 min., all of P-clusters in the partially oxidized FeMo protein were oxidized, but all of FeMoCo in the protein were still in the reductive state. The oxidized P-clusters in the protein were able to be completely reduced by Na2S2O4(DT) and the reduction was accelerated by methyl viologen (MV). And all of FeMoCo in the protein were firstly oxidized by some oxidants such as methylene blue. The numbers of the redox equivalent of P-cluster and FeMoCo have been obtained by the CD reductive titration of and EPR/ ABS time course on the oxidation of the partially oxidizeA FeMo protein, respectivelly.     

Interaction of melanin with carbon- and oxygen-centered radicals from methanol and ethanol

The interaction of dopa-melanin (DM) and cysteinyldopa-melanin (CDM) with carbon- and oxygen-centered radicals generated by benzophenone-photosensitized hydrogen abstraction from ethanol, or by pulse radiolysis of aqueous solutions of methanol and ethanol, is reported. Photosensitized formation of carbon-centered radicals and their interaction with melanin was monitored by electron paramagnetic resonance (EPR) spin trapping using DMPO, and via the melanin free radical signal itself. In the pulse radiolysis experiments, the interaction of DM or CDM with hydroxymethyl, hydroxyethyl, and the corresponding methanol peroxyl radical was monitored by recording time-dependent changes of the melanin absorbance at selected wavelengths. The data indicate that both melanins are good scavengers of carbon-centered radicals, with corresponding rate constants in the range of 10⁷ to 10⁸ M⁻¹ s⁻¹. Significantly, compared to DM, CDM is also an exceptionally efficient scavenger of oxygen-centered radicals derived from methanol with corresponding rate constants of 2.7 × 10⁴ and 2 × 10⁶, M⁻¹ s⁻¹ for DM and CDM, respectively. The results are discussed with reference to the potential role of melanin in protecting the integrity of melanosomes by inhibiting peroxidation of lipid components of the organelle membrane.     

A spectroscopic and voltammetric study of the pH-dependent Cu(II) coordination to the peptide GGGTH: relevance to the fifth Cu(II) site in the prion protein

The GGGTH sequence has been proposed to be the minimal sequence involved in the binding of a fifth Cu(II) ion in addition to the octarepeat region of the prion protein (PrP) which binds four Cu(II) ions. Coordination of Cu(II) by the N- and C-protected Ac-GGGTH-NH(2) pentapeptide (P(5)) was investigated by using potentiometric titration, electrospray ionization mass spectrometry, UV-vis spectroscopy, electron paramagnetic resonance (EPR) spectroscopy and cyclic voltammetry experiments. Four different Cu(II) complexes were identified and characterized as a function of pH. The Cu(II) binding mode switches from NO(3) to N(4) for pH values ranging from 6.0 to 10.0. Quasi-reversible reduction of the [Cu(II)(P(5))H(-2)] complex formed at pH 6.7 occurs at E (1/2)=0.04 V versus Ag/AgCl, whereas reversible oxidation of the [Cu(II)(P(5))H(-3)](-) complex formed at pH 10.0 occurs at E (1/2)=0.66 V versus Ag/AgCl. Comparison of our EPR data with those of the rSHaPrP(90-231) (Burns et al. in Biochemistry 42:6794-6803, 2003) strongly suggests an N(3)O binding mode at physiological pH for the fifth Cu(II) site in the protein.     

The iron complex of Dp44mT is redox-active and induces hydroxyl radical formation: An EPR study

Iron chelation therapy was initially designed to alleviate the toxic effects of excess iron evident in iron-overload diseases. However, some iron chelator-metal complexes have also gained interest due to their high redox activity and toxicological properties that have potential for cancer chemotherapy. This communication addresses the conflicting results published recently on the ability of the iron chelator, Dp44mT, to induce hydroxyl radical formation upon complexation with iron (B.B. Hasinoff and D. Patel, J Inorg. Biochem.103 (2009), 1093-1101). This previous study used EPR spin-trapping to show that Dp44mT-iron complexes were not able to generate hydroxyl radicals. Here, we demonstrate the opposite by using the same technique under very similar conditions to show the Dp44mT-iron complex is indeed redox-active and induces hydroxyl radical formation. This was studied directly in an iron(II)/H₂O₂ reaction system or using a reducing iron(III)/ascorbate system implementing several different buffers at pH 7.4. The demonstration by EPR that the Dp44mT-iron complex is redox-active confirms our previous studies using cyclic voltammetry, ascorbate oxidation, benzoate hydroxylation and a plasmid DNA strand-break assay. We discuss the relevance of the redox activity to the biological effects of Dp44mT.     

Comprehensive Study of Mediterranean (Croatian) Propolis Peculiarity: Headspace,Volatiles, Anti‐Varroa‐Treatment Residue,Phenolics, and Antioxidant Properties

Eight propolis samples from Croatia were analyzed in detail, to study the headspace, volatiles, anti‐Varroa‐treatment residue, phenolics, and antioxidant properties. The samples exhibited high qualitative/quantitative variability of the chemical profiles, total phenolic content (1,589.3–14,398.3 mg GAE (gallic acid equivalent)/l EtOH extract), and antioxidant activity (11.1–133.5 mmol Fe²⁺/l extract and 6.2–65.3 mmol TEAC (Trolox^® equivalent antioxidant capacity)/l extract). The main phenolics quantified by HPLC‐DAD at 280 and 360 nm were vanillin, p‐coumaric acid, ferulic acid, chrysin, galangin, and caffeic acid phenethyl ester. The major compounds identified by headspace solid‐phase microextraction (HS‐SPME), simultaneous distillation extraction (SDE), and subsequent GC‐FID and GC/MS analyses were α‐eudesmol (up to 19.9%), β‐eudesmol (up to 12.6%), γ‐eudesmol (up to 10.5%), benzyl benzoate (up to 28.5%), and 4‐vinyl‐2‐methoxyphenol (up to 18.1%). Vanillin was determined as minor constituent by SDE/GC‐FID/MS and HPLC‐DAD. The identified acaricide residue thymol was ca. three times more abundant by HS‐SPME/GC‐FID/MS than by SDE/GC‐FID/MS and was not detected by HPLC‐DAD.     

Reaction of haem containing proteins and enzymes with hydroperoxides: The radical view

The reaction between hydroperoxides and the haem group of proteins and enzymes is important for the function of many enzymes but has also been implicated in a number of pathological conditions where oxygen binding proteins interact with hydrogen peroxide or other peroxides. The haem group in the oxidized Fe³⁺ (ferric) state reacts with hydroperoxides with a formation of the Fe⁴⁺=O (oxoferryl) haem state and a free radical primarily located on the π-system of the haem. The radical is then transferred to an amino acid residue of the protein and undergoes further transfer and transformation processes. The free radicals formed in this reaction are reviewed for a number of proteins and enzymes. Their previously published EPR spectra are analysed in a comparative way. The radicals directly detected in most systems are tyrosyl radicals and the peroxyl radicals formed on tryptophan and possibly cysteine. The locations of the radicals in the proteins have been reported as follows: Tyr133 in soybean leghaemoglobin; αTyr42, αTrp14, βTrp15, βCys93, (αTyr24−αHis20), all in the α- and β-subunits of human haemoglobin; Tyr103, Tyr151 and Trp14 in sperm whale myoglobin; Tyr103, Tyr146 and Trp14 in horse myoglobin; Trp14, Tyr103 and Cys110 in human Mb. The sequence of events leading to radical formation, transformation and transfer, both intra- and intermolecularly, is considered. The free radicals induced by peroxides in the enzymes are reviewed. Those include: lignin peroxidase, cytochrome c peroxidase, cytochrome c oxidase, turnip isoperoxidase 7, bovine catalase, two isoforms of prostaglandin H synthase, Mycobacterium tuberculosis and Synechocystis PCC6803 catalase-peroxidases.     

SOD mimics: From the tool box of the chemists to cellular studies

Superoxide dismutases (SODs) are metalloproteins that protect cells against oxidative stress by controlling the concentration of superoxide (O₂⁻) through catalysis of its dismutation. The activity of superoxide dismutases can be mimicked by low-molecular-weight complexes having potential therapeutic applications. This review presents recent strategies for designing efficient SOD mimics, from molecular metal complexes to nanomaterials. Studies of these systems in cells reveal that some SOD mimics, designed to react directly with superoxide, may also indirectly enhance the cellular antioxidant arsenal. Finally, a good understanding of the bioactivity requires information on the cell-penetration, speciation, and subcellular location of the SOD mimics: we will describe recent studies and new techniques that open opportunities for characterizing SOD mimics in biological environments.