Modeling the scavenging activity of ellagic acid and its methyl derivatives towards hydroxyl, methoxy, and nitrogen dioxide radicals

The reaction mechanisms involved in the scavenging of hydroxyl (OH^·), methoxy (OCH₃ ^·), and nitrogen dioxide (NO₂ ^·) radicals by ellagic acid and its monomethyl and dimethyl derivatives were investigated using the transition state theory and density functional theory. The calculated Gibbs barrier energies associated with the abstraction of hydrogen from the hydroxyl groups of ellagic acid and its monomethyl and dimethyl derivatives by an OH· radical in aqueous media were all found to be negative. When NO₂ ^· was the radical involved in hydrogen abstraction, the Gibbs barrier energies were much larger than those calculated when the OH^· radical was involved. When OCH₃ ^· was the hydrogen-abstracting radical, the Gibbs barrier energies lay between those obtained with OH^· and NO₂ ^· radicals. Therefore, the scavenging efficiencies of ellagic acid and its monomethyl and dimethyl derivatives towards the three radicals decrease in the order OH^· >> OCH₃ ^· > NO₂ ^·. Our calculated rate constants are broadly in agreement with those obtained experimentally for hydrogen abstraction reactions of ellagic acid with OH· and NO₂· radicals.

Tocopheramines and tocotrienamines as antioxidants: ESR spectroscopy,rapid kinetics and DFT calculations

Tocopheramines (TNH₂) and tocotrienamines (T₃NH₂) are analogues of tocopherols (TOH) and tocotrienols in which phenolic OH is replaced by NH₂. It was shown in previous studies that TNH₂ and T₃NH₂ act as potent antioxidants. In this study we compared the one-electron oxidation of TNH₂/T₃NH₂ by diphenyl picryl hydrazyl (DPPH) and galvinoxyl (GOX) radicals with the one of α-TOH as a reference compound using ESR spectroscopy, stopped flow spectrophotometry and density functional theory (DFT) calculations. ESR spectroscopy revealed the presence of tocopheramine radicals during electrochemical oxidation of α-TNH₂. Kinetic measurements demonstrated that in apolar n-hexane TNH₂/T₃NH₂ derivatives reacted two to three orders of magnitude slower than α-TOH with the model radicals. DFT calculations indicated that this correlates well with the higher bond dissociation energy (BDE) for N–H in TNH₂ than for O–H in α-TOH in pure H-atom transfer (HAT). In the more polar medium ethanol TNH₂/T₃NH₂ derivatives partially reacted faster than α-TOH depending on the reaction partner. DFT calculations suggest that this is due to reaction mechanisms alternative to HAT. According to thermochemistry data sequential proton loss and electron transfer (SPLET) is more favored for α-TOH in ethanol than for TNH₂. Therefore, for TNH₂ a contribution of the alternative mechanism of sequential electron transfer–proton transfer (SET–PT) could be a possible explanation. These data show that the antioxidant reactivity strongly depends on the structure, reaction partners and environment. According to these findings TNH₂/T₃NH₂ should be superior as antioxidants over α-TOH in polar head group regions of membranes but not in the apolar core of lipid bilayers.     

Structure-Thermodynamics-Antioxidant Activity Relationships of Selected Natural Phenolic Acids and Derivatives: An Experimental and Theoretical Evaluation

Phenolic acids and derivatives have potential biological functions, however, little is known about the structure-activity relationships and the underlying action mechanisms of these phenolic acids to date. Herein we investigate the structure-thermodynamics-antioxidant relationships of 20 natural phenolic acids and derivatives using DPPH^• scavenging assay, density functional theory calculations at the B3LYP/6-311++G(d,p) levels of theory, and quantitative structure-activity relationship (QSAR) modeling. Three main working mechanisms (HAT, SETPT and SPLET) are explored in four micro-environments (gas-phase, benzene, water and ethanol). Computed thermodynamics parameters (BDE, IP, PDE, PA and ETE) are compared with the experimental radical scavenging activities against DPPH^•. Available theoretical and experimental investigations have demonstrated that the extended delocalization and intra-molecular hydrogen bonds are the two main contributions to the stability of the radicals. The C = O or C = C in COOH, COOR, C = CCOOH and C = CCOOR groups, and orthodiphenolic functionalities are shown to favorably stabilize the specific radical species to enhance the radical scavenging activities, while the presence of the single OH in the ortho position of the COOH group disfavors the activities. HAT is the thermodynamically preferred mechanism in the gas phase and benzene, whereas SPLET in water and ethanol. Furthermore, our QSAR models robustly represent the structure-activity relationships of these explored compounds in polar media.     

Theoretical insight into the conversion of xylose to furfural in the gas phase and water

The antioxidant properties of some phenolic Schiff bases in the presence of different reactive particles such as ^•OH, ^•OOH, (CH₂=CH−O−O^•), and ^-•O₂ were investigated. The thermodynamic values, ΔH _BDE, ΔH _IP, and ΔH _PA, were used for this purpose. Three possible mechanisms for transfer of hydrogen atom, concerted proton−electron transfer (CPET), single electron transfer followed by proton transfer (SET-PT), and sequential proton loss electron transfer (SPLET) were considered. These mechanisms were tested in solvents of different polarity. On the basis of the obtained results it was shown that SET-PT antioxidant mechanism can be the dominant mechanism when Schiff bases react with radical cation, while SPLET and CPET are competitive mechanisms for radical scavenging of hydroxy radical in all solvents under investigation. Examined Schiff bases react with the peroxy radicals via SPLET mechanism in polar and nonpolar solvents. The superoxide radical anion reacts with these Schiff bases very slowly.

     

Effects of Nitrogen Source and Bacterial Elicitor on Isoflavone Accumulation in Root Cultures of Albizzia kalkora （Roxb.） Prain

Changes in cellular isoflavone （daidzein and genistein） contents were monitored in root cultures of Albizzia kalkora （Roxb.） Prain after feeding different ratios of NH4^＋/NO3^- and treatment with a biotic elicitor （three strains of Rhizobium sp.）. The NH4^＋/NO3^- ratio appears to be positively correlated with daidzein content in the roots and shows a negative correlation with genistein. Among the three different strains of Rhizobium used, the strain ATCC 15834 caused a 35% increase in daidzein production by infection. In the case of genistein, maximum production （94%） was obtained when cultures were treated on Day 6 by the strains ATCC 15834 and KCTC 1541. The biosynthetic pathway of the two isoflavones apparently reacts differently to the same culture conditions and the same strains of Rhizobium. Therefore, the present data suggest that the production of daidzein and genistein could be modulated by changing the NH4^＋/NO3^- ratio and the application of Rhizobium.     

Studies on the antioxidant properties of some phytoestrogens

Isoflavones genistein and daidzein are nonsteroidal phytoestrogens occurring mainly in soybean foods. These phytoestrogens possess estrogenic properties and show a variety of health benefits as anti‐inflammatory agents. However, the mechanism of their action has not been identified in detail. The aim of this study is to characterize the antioxidant powers of genistein, daidzein and daidzein metabolite–equol through their activities to scavenge superoxide anion radical (O^?₂^?), hydroxyl radical (HO^?), 2,2–diphenyl–1‐picrylhydrazyl radical (DPPH^?) and hydrogen peroxide (H₂O₂) using chemiluminescence and spectrophotometry techniques. Potassium superoxide in dimethyl sulphoxide (DMSO) and 18‐crown‐6 ether were used as a source of O^?₂^?. Hydroxyl radicals were produced using the Fenton reaction. In free radical assays, genistein had the IC₅₀ values (an amount of antioxidant concentration required to decrease the initial radical concentration by 50%) 0.391 ± 0.012 mM for O^?₂^?, 0.621 ± 0.028 mM for HO^? and 1.89 ± 0.16 mM for DPPH^?. The IC₅₀ values for daidzein for these free radicals were 1.924 ± 0.011 mM, 0.702 ± 0.012 mM and 2.81 ± 0.03 mM, respectively. Equol was the most active the free radical scavenger with IC₅₀ = 0.451 ± 0.018 mM for HO^? and IC₅₀ = 1.36 ± 0.11 mM for DPPH^?. All tested compounds exerted a significant effect on the H₂O₂: IC₅₀ = 18.1 ± 1.1 μM for genistein, IC₅₀ = 2.1 ± 0.5 μM for daidzein, and IC₅₀ = 1.06 ± 0.2 μM for equol. These findings show that genistein, daidzein and equol are effective free radical scavengers and possess high antioxidant power in vitro. Copyright © 2016 John Wiley & Sons, Ltd.     

Effects of Free Radicals on Partial Reactions of the Na,K-ATPase

The function of the Na,K-ATPase is known to be considerably impaired in the presence of free radicals such as OH^•. While previous experiments were largely based on the loss of enzymatic activity of the protein, this is the first communication dealing with partial reactions of the pump cycle in the presence of free radicals produced by water radiolysis. Three different system states, which are directly involved in ion transfer catalyzed by the enzyme, showed similar sensitivity to free radical action. This is indicated by largely identical D₃₇-doses of the decay of the reaction amplitudes investigated. The decrease in the efficiency of the enzyme functions was largely due to a lethal damage of pump molecules. A kinetic analysis of the ATP-induced conformational transition E₁→ E₂ revealed, however, that a minor component of the inactivation is due to a reduction of the transition rate constant. The decrease of the enzymatic activity could be simulated by the decay of the rate-limiting conformational transition. This finding indicates the conservation of a close coupling between ATP-hydrolysis and sodium translocation process throughout free-radical induced inactivation. As a result of the tight coupling, enzyme modification at different system states leads to similar functional consequences for the protein. Received: 19 July 1996/Revised: 21 October 1996     

Theoretical study on the antioxidant properties of 2′-hydroxychalcones: H-atom vs. electron transfer mechanism

The free radical scavenging activity of six 2′-hydroxychalcones has been studied in gas phase and solvents using the density functional theory (DFT) method. The three main working mechanisms, hydrogen atom transfer (HAT), stepwise electron-transfer-proton-transfer (ET-PT) and sequential-proton-loss-electron-transfer (SPLET) have been considered. The O-H bond dissociation enthalpy (BDE), ionization potential (IP), proton affinity (PA) and electron transfer energy (ETE) parameters have been computed in gas phase and solvents. The theoretical results confirmed the important role of the B ring in the antioxidant properties of hydroxychalcones. In addition, the calculated results matched well with experimental values. The results suggested that HAT would be the most favorable mechanism for explaining the radical-scavenging activity of hydroxychalcone in gas phase, whereas SPLET mechanism is thermodynamically preferred pathway in aqueous solution.     

Nitric oxide and peroxynitrite. The ugly,the uglier and the not so good

Nitric oxide, a gaseous free radical, is poorly reactive with most biomolecules but highly reactive with other free radicals. Its ability to scavenge peroxyl and other damaging radicals may make it an important antioxidant in vivo, particular in the cardiovascular system, although this ability has been somewhat eclipsed in the literature by a focus on the toxicity of peroxynitrite, generated by reaction of O^·-₂ with NO^· (or of NO^- with O₂). On balance, experimental and theoretical data support the view that ONOO^- can lead to hydroxyl radical (OH^·) generation at pH 7.4, but it seems unlikely that OH^· contributes much to the cytotoxicity of ONOO^-. The cytotoxicity of ONOO^- may have been over-emphasized: its formation and rapid reaction with antioxidants may provide a mechanism of using NO^· to dispose of excess O^·-₂, or even of using O^·-₂ to dispose of excess NO^·, in order to maintain the correct balance between these radicals in vivo. Injection or instillation of “bolus” ONOO^- into animals has produced tissue injury, however, although more experiments generating ONOO^- at steady rates in vivo are required. The presence of 3-nitrotyrosine in tissues is still frequently taken as evidence of ONOO^- generation in vivo, but abundant evidence now exists to support the view that it is a biomarker of several “reactive nitrogen species”. Another under-addressed problem is the reliability of assays used to detect and measure 3-nitrotyrosine in tissues and body fluids: immunostaining results vary between laboratories and simple HPLC methods are susceptible to artefacts. Exposure of biological material to low pH (e.g. during acidic hydrolysis to liberate nitrotyrosine from proteins) or to H₂O₂ might cause artefactual generation of nitrotyrosine from NO^-₂ in the samples. This may be the origin of some of the very large values for tissue nitrotyrosine levels quoted in the literature. Nitrous acid causes not only tyrosine nitration but also DNA base deamination at low pH: these events are relevant to the human stomach since saliva and many foods are rich in nitrite. Several plant phenolics inhibit nitration and deamination in vitro, an effect that could conceivably contribute to their protective effects against gastric cancer development.     

Merged mechanisms for hydride transfer from 1,4-dihydronicotinamides

Recent work on the reduction of heteroaromatic cations by 1,4-dihydronicotinamides and related reducing agents is reviewed. Extensive correlations are presented between the second-order rate constants (k₂) for these reactions and the second-order rate constants (k_OH) and equilibrium constants (pK_R⁺) for hydroxide ion attack on these cations. Close correlations of log k₂ with the electron affinities and one-electron reduction potentials of these cations are also presented. These relationships are considered in the context of a direct hydride transfer from donor to acceptor and also in terms of SET mechanisms which are also commonly discussed for such reactions. It is shown that the interpretation of these formal hydride transfer reactions in terms of an imbalanced development of electronic charge and C---H bond fission within the transition state species leads to a rational merging of the single-step hydride transfer mechanism and the SET mechanisms. The structures of the transition state species are expected to be highly variable and quite dependent upon the nature of the hydride donor and acceptor species, with considerable contribution from charge-transfer interactions. Such imbalanced transition state species are analyzed in terms of two different types of reaction coordinate diagrams and also in terms of the valence bond configuration mixing theory.     

Inhibitory effect of genistein on agonist-induced modulation of vascular contractility

The present study was undertaken to determine whether treatment with genistein, the plant-derived estrogen-like compound influences agonist-induced vascular smooth muscle contraction and, if so, to investigate related mechanisms. The measurement of isometric contractions using a computerized data acquisition system was combined with molecular experiments. Genistein completely inhibited KCl-, phorbol ester-, phenylephrine-, fluoride- and thromboxane A₂-induced contractions. An inactive analogue, daidzein, completely inhibited only fluoride-induced contraction regardless of endothelial function, suggesting some difference between the mechanisms of RhoA/Rho-kinase activators such as fluoride and thromboxane A₂. Furthermore, genistein and daidzein each significantly decreased phosphorylation of MYPT1 at Thr855 had been induced by a thromboxane A₂ mimetic. Interestingly, iberiotoxin, a blocker of large-conductance calcium-activated potassium channels, did not inhibit the relaxation response to genistein or daidzein in denuded aortic rings precontracted with fluoride. In conclusion, genistein or daidzein elicit similar relaxing responses in fluoride-induced contractions, regardless of tyrosine kinase inhibition or endothelial function, and the relaxation caused by genistein or daidzein was not antagonized by large conductance K_Ca-channel inhibitors in the denuded muscle. This suggests that the RhoA/Rho-kinase pathway rather than K⁺-channels are involved in the genistein-induced vasodilation. In addition, based on molecular and physiological results, only one vasoconstrictor fluoride seems to be a full RhoA/Rho-kinase activator; the others are partial activators.     

A novel chemiluminescence system for the determination of daidzein and its hydroxyl radical-scavenging capacity

A novel chemiluminescence (CL) system was established for the determinations of daidzein in pharmaceutical preparations and to assess its ability to scavenge hydroxyl radicals. It was shown that a strong CL signal generated when eosin Y was mixed with Fenton reagent was decreased significantly when daidzein was added to the reaction system due to partial scavenging of the hydroxyl radicals in the solution. The extent of decrease in the CL intensity had a good stoichiometric relationship with the daidzein concentration. Based on this, we developed a new method for the determination of daidzein, using a flow‐injection chemiluminescence (FI–CL) technique. Under the optimal conditions, the linear range of daidzein concentration was 8.0 × 10^–8–3.0 × 10^–6 mol/L (R = 0.9982), with a detection limit of 9.0 × 10^–9 mol/L (S:N = 3), and the RSD was 5.8% for 1.0 × 10^–6 mol/L daidzein (n = 11). This method was successfully used in the determination of daidzein in tablets and for evaluation of the hydroxyl radical‐scavenging capacity of daidzein. The possible reaction mechanism of the CL system is discussed. Copyright © 2011 John Wiley & Sons, Ltd.     

The reactions of plant hormones with reactive oxygen species: chemical insights at a molecular level

The reactions of two plant hormones, namely jasmonic acid (JA) and methyl jasmonate (MJ), with different reactive oxygen species (ROS) were investigated using the density functional theory. Different reaction sites and mechanisms were explored, as well as solvents of different polarity, and pH in aqueous solution. The thermochemical viability and kinetics of the investigated reaction pathways were found to be strongly influenced by the reacting ROS. All the investigated pathways were found to be exergonic, both in aqueous and lipid solution and for both JA and MJ, when the reactions involve ^?OH and ^?OCH₃. On the contrary, for the reactions with peroxy radicals (^?OOH and ^?OOCH₂CHCH₂) only a few hydrogen transfer pathways were found to be thermochemically viable. The reactions involving ^?OH were found to be diffusion-controlled, with both JA and MJ, regardless of the polarity of the solvent. This led to the hypothesis that the direct ^?OH scavenging activity of JA and MJ might play a role in the beneficial effects of the jasmonate family regarding the antioxidant defense of plants against metal-induced oxidative stress. The deprotonated fraction of JA is, to some extent, more reactive than the neutral fraction toward ROS. This, together with the acid-base equilibria inherent to some ROS, make the pH an influential environmental factor on the overall reactivity of JA toward ROS.     

Genistein and daidzein induce neurotoxicity at high concentrations in primary rat neuronal cultures

Summary It is known that estrogen can protect neurons from excitotoxicity. Since isoflavones possess estrogen-like activity, it is of interest to determine whether isoflavones can also protect neurons from glutamate-induced neuronal injury. Morphological observation and lactate dehydrogenase (LDH) release assay were used to estimate the cellular damage. It is surprising that, contrary to estrogen, isoflavones, specifically genistein and daidzein, are toxic to primary neuronal culture at high concentration. Treatment of neurons with 50 μM genistein and daidzein for 24 h increased LDH release by 90% and 67%, respectively, indicating a significant cellular damage. Under the same conditions, estrogen such as 17β-estradiol did not show any effect on primary culture of brain cells. At 100 μM, both genistein and daidzein increased LDH release by 2.6- and 3-fold, respectively with a 30-min incubation. Furthermore, both genistein and daidzein at 50 μM increased the intracellular calcium level, [Ca²⁺]_i, significantly. To determine their mode of action, genistein and daidzein were tested on glutamate and GABA_A receptor binding. Both genistein and daidzein were found to have little effect on glutamate receptor binding, while the binding of [³H]muscimol to GABA_A receptors was markedly inhibited. However, 17β-estradiol did not affect GABA_A receptor binding suggesting that the toxic effect of genistein and daidzein could be due to their inhibition of the GABA_A receptor resulting in further enhancement of excitation by glutamate and leading to cellular damage. Ying Jin, Heng Wu contributed equally to this article.     

Physiological,biochemical, antioxidant and growth characterizations of gibberellin and paclobutrazol-treated sweet leaf (<Emphasis Type="Italic">Stevia rebaudiana</Emphasis> B.) herb

A greenhouse experiment was designed to study the responses of Stevia rebaudiana herb to paclobutrazol (PBZ) and gibberellin (GA) treatments. GA and PBZ treatments caused no significant impact on photosynthesis pigments while they increased carbohydrates, amino acids and protein metabolites. Stevia showed a potent antioxidant activity through scavenging DPPH, NO^·; O ₂ ^·? and OH^· radicals which was highlighted in GA and PBZ treatments. The enzymatic and non-enzymatic antioxidant system of Stevia plant showed a significant increase in response to PBZ and GA treatments. PBZ treatment decreased plant growth while GA treatment had no significant effect on it. Collectively, both GA and PBZ treatments effectively increased metabolites and antioxidant property of Stevia herb.     

Models for Proton-Coupled Electron Transfer in Photosystem II

The coupling of proton and electron transfers is a key part of the chemistry of photosynthesis. The oxidative side of photosystem II (PS II) in particular seems to involve a number of proton-coupled electron transfer (PCET) steps in the S-state transitions. This mini-review presents an overview of recent studies of PCET model systems in the authors’ laboratory. PCET is defined as a chemical reaction involving concerted transfer of one electron and one proton. These are thus distinguished from stepwise pathways involving initial electron transfer (ET) or initial proton transfer (PT). Hydrogen atom transfer (HAT) reactions are one class of PCET, in which H⁺ and e ⁻ are transferred from one reagent to another: AH+B→A+BH, roughly along the same path. Rate constants for many HAT reactions are found to be well predicted by the thermochemistry of hydrogen transfer and by Marcus Theory. This includes organic HAT reactions and reactions of iron-tris(α-diimine) and manganese-(μ-oxo) complexes. In PS II, HAT has been proposed as the mechanism by which the tyrosine Z radical (Y_Z) oxidizes the manganese cluster (the oxygen evolving complex, OEC). Another class of PCET reactions involves transfer of H⁺ and e ⁻ in different directions, for instance when the proton and electron acceptors are different reagents, as in AH–B+C⁺→A–HB⁺+C. The oxidation of Y_Z by the chlorophyll P680 + has been suggested to occur by this mechanism. Models for this process – the oxidation of phenols with a pendent base – are described. The oxidation of the OEC by Y_Z could also occur by this second class of PCET reactions, involving an Mn–O–H fragment of the OEC. Initial attempts to model such a process using ruthenium-aquo complexes are described. An erratum to this article can be found at     

Synthesis and luminescence properties of novel 8‐hydroxyquinoline derivatives and their Eu(III) complexes

Six novel 8‐hydroxyquinoline derivatives were synthesized using 2‐methyl‐8‐hydroxyquinoline and para‐substituted phenol as the main starting materials, and were characterized by ¹H nuclear magnetic resonance (NMR), mass spectrometry (MS), ultraviolet (UV) light analysis and infra‐red (IR) light analysis. Their complexes with Eu(III) were also prepared and characterized by elemental analysis, molar conductivity, UV light analysis, IR light analysis, and thermogravimetric–differential thermal analysis (TG–DTA). The results showed that the ligand coordinated well with Eu(III) ions and had excellent thermal stability. The structure of the target complex was EuY^1–6(NO₃)₃.2H₂O. The luminescence properties of the target complexes were investigated, the results indicated that all target complexes had favorable luminescence properties and that the introduction of an electron‐donating group could enhance the luminescence intensity of the corresponding complexes, but the addition of an electron‐withdrawing group had the opposite effect. Among all the target complexes, the methoxy‐substituted complex (–OCH₃) had the highest fluorescence intensity and the nitro‐substituted complex (–NO₂) had the weakest fluorescence intensity. The results showed that 8‐hydroxyquinoline derivatives had good energy transfer efficiency for the Eu(III) ion. All the target complexes had a relatively high fluorescence quantum yield. The fluorescence quantum yield of the complex EuY³(NO₃)₃.2H₂O was highest among all target complexes and was up to 0.628. Because of excellent luminescence properties and thermal stabilities of the Eu(III) complexes, they could be used as promising candidate luminescent materials.     

Stimulatory effect of genistein and daidzein on protein synthesis in osteoblastic MC3T3-E1 cells: Activation of aminoacyl-tRNA synthetase

The effect of genistein and daidzein on protein synthesis in osteoblastic MC3T3-E1 cells in vitro was investigated to determine a cellular mechanism by which the isoflavones stimulate bone formation. Cells were cultured for 48 h in -minimal essential medium containing either vehicle, genistein (10^–7–10^–5 M) or daidzein (10^–7–10^–5 M). The 5,500 g supernatant of cell homogenate was used for assay of protein synthesis with [³H]leucine incorporation in vitro. The culture with genistein or daidzein caused a significant elevation of protein synthesis in the cell homogenate. The effect of genistein (10^–5 M) or daidzein (10^–5 M) in elevating protein synthesis was significantly prevented, when cells were cultured for 48 h in a medium containing either actinomycin D (10^–7 M) or cycloheximide (10^–6 M) in the absence or presence of isoflavones. Moreover, when genistein (10^–7–10^–5 M) or daidzein (10^–6 and 10^–5 M) was added to the reaction mixture containing the cell homogenate obtained from osteoblastic cells cultured without isoflavone, protein synthesis was significantly raised. This increase was markedly blocked by the addition of cycloheximide (10^–7 M). In addition, [³H]leucyl-tRNA synthetase activity in the cytosol of osteoblastic cells was significantly increased by the addition of genistein (10^–6 and 10^–5 M) or daidzein (10^–5 M) into the enzyme reaction mixture. The present study demonstrates that genistein or daidzein can stimulate protein synthesis in osteoblastic MC3T3-E1 cells. The isoflavones may have a stimulatory effect on osteoblastic bone formation due to increasing protein synthesis.     

Isoflavones stimulate estrogen receptor-mediated core histone acetylation

The isoflavones genistein and daidzein and the daidzein metabolite equol have been reported to interact with estrogen receptors (ERs). Some studies indicate that they behave clinically like estrogen in some estrogen-deficiency diseases. However, the detailed molecular mechanism used by these compounds to create beneficial effects in patients with estrogen-related diseases has not been clarified. Using histone acetyltransferase (HAT) assay, we found that equol, genistein, and AglyMax had significant effects on ERalpha-mediated histone acetylation. Although 17beta-estradiol (E2)-dependent HAT activity of steroid receptor coactivators 2 (SRC2) and p300 mediated by ERbeta could be detected, it was weaker than that mediated by ERalpha. Equol, genistein, AglyMax, and daidzein all markedly stimulated ERbeta-mediated histone acetylation. On the other hand, anti-estrogenic compounds ICI 182,780 (ICI) and tamoxifen (TA) did not have an effect on HAT activity mediated by either ERalpha or ERbeta. Our data indicate that estrogenic ligands exert their effects by elevating histone acetylation and coactivator activity of ER, and suggest that the risk of estrogen-related diseases might be reduced by a sufficient amount of genistein or AglyMax supplements.     

Radical scavenging and electron-transfer reactions in Polyporus Versicolor laccase: A pulse radiolysis study

The interaction of the radicals OH^?, t-BuO^?, e_aq^?, CO₂^XXX and O₂^XXX with the copper oxidase. laccase. from Polyporus, has been studied by the pulse-radiolysis technique. Each of these radicals formed transient adducts with a broad absorption maximum around 310 nm. Analysis of the optical properties and of the very fast rates of formation of these compounds shows that each radical interacts with a limited number of sites on the polypeplide part of the protein amongst R-S-S-R. histidine and aromatic residues. Interaction with the carbonyl group of some of the peptide bonds is also possible. The few target sites are probably hit simultaneously and electron transfer between these sites may also occur. In all cases, in a subsequent step, intramolecular electron transfer from the polypeptide radical adducts leads to a partial reduction of the blue type-1 Cu²⁺ with rates varying between 10³ and 10⁴ s^?1. Further reduction of the type-1 Cu²⁺ occurs through a slow intermolecular reaction between two laccase radical transient adducts. In the case of CO^XXX₂ and O^XXX₂, this slow reduction could alternatively be due to an intermolecular reaction between laccase and CO^XXX₂ or O^XXX₂. The oxidant radicals OH^?. Br^XXX₂ and (SCN)^XXX₂, which formed radical adducts with fully ascorbate-reduced laccase, did not induce any type-1 copper reoxidation.