Binding affinity of pyrano[3, 2-f]quinoline and DNA: spectroscopic and docking approach

The interaction between pyrano[3, 2-f]quinoline (PQ) and calf thymus DNA (CTDNA) using spectroscopic and molecular modeling approach has been presented here. Apparent association constant (1.05×10⁵ L/mol) calculated from UV-vis specta, indicates a moderate complex formation between CTDNA and PQ. The quenching phenomena as obtained from emission spectra of ethidium bromide (EB)–CTDNA by PQ was found to be a dynamic one and the binding constants found to be 8.64, 9.25, 11.17, 12.03 × 10⁴ L/mol at 293, 300, 308, and 315 K. Thermodynamic parameter enthalpy change (ΔH) and entropy change (ΔS), indicates weak force like van der Walls force and hydrogen bonds having the key role in this binding process. The results of circular dichroism (CD) demonstrate that PQ has not induced characteristic changed in CTDNA. Results achieved from UV absorption and fluorescence spectroscopy indicating the binding mode of PQ with DNA seems to be a nonintercalative binding. The theoretical results as originating from molecular modeling showed that PQ possibly will bind into the hydrophobic region of DNA having docking binding energy = ?10.03 kcal/mol and the obtained results are in consonance with the inferences obtained from experimental data. This result is important for the better understanding of pharmaceutical aspects of binding affinity of PQ and CTDNA.     

Reaction of human hemoglobin with peroxynitrite. Isomerization to nitrate and secondary formation of protein radicals

Peroxynitrite, a strong oxidant formed intravascularly in vivo, can diffuse onto erythrocytes and be largely consumed via a fast reaction (2 x 10(4) m(-1) s(-1)) with oxyhemoglobin. The reaction mechanism of peroxynitrite with oxyhemoglobin that results in the formation of methemoglobin remains to be elucidated. In this work, we studied the reaction under biologically relevant conditions using millimolar oxyhemoglobin concentrations and a stoichiometric excess of oxyhemoglobin over peroxynitrite. The results support a reaction mechanism that involves the net one-electron oxidation of the ferrous heme, isomerization of peroxynitrite to nitrate, and production of superoxide radical and hydrogen peroxide. Homolytic cleavage of peroxynitrite within the heme iron allows the formation of ferrylhemoglobin in approximately 10% yields, which can decay to methemoglobin at the expense of reducing equivalents of the globin moiety. Indeed, spin-trapping studies using 2-methyl-2-nitroso propane and 5,5 dimethyl-1-pyrroline-N-oxide (DMPO) demonstrated the formation of tyrosyl- and cysteinyl-derived radicals. DMPO also inhibited covalently linked dimerization products and led to the formation of DMPO-hemoglobin adducts. Hemoglobin nitration was not observed unless an excess of peroxynitrite over oxyhemoglobin was used, in agreement with a marginal formation of nitrogen dioxide. The results obtained support a role of oxyhemoglobin as a relevant intravascular sink of peroxynitrite.     

PpsR, a regulator of heme and bacteriochlorophyll biosynthesis, is a heme-sensing protein

Heme-mediated regulation, presented in many biological processes, is achieved in part with proteins containing heme regulatory motif. In this study, we demonstrate that FLAG-tagged PpsR isolated from Rhodobacter sphaeroides cells contains bound heme. In vitro heme binding studies with tagless apo-PpsR show that PpsR binds heme at a near one-to-one ratio with a micromolar binding constant. Mutational and spectral assays suggest that both the second Per-Arnt-Sim (PAS) and DNA binding domains of PpsR are involved in the heme binding. Furthermore, we show that heme changes the DNA binding patterns of PpsR and induces different responses of photosystem genes expression. Thus, PpsR functions as both a redox and heme sensor to coordinate the amount of heme, bacteriochlorophyll, and photosystem apoprotein synthesis thereby providing fine tune control to avoid excess free tetrapyrrole accumulation.     

Kinetic study of the slow cyanide binding to Glycera dibranchiata monomer hemoglobin components III and IV

Compared to other monomeric heme proteins and the heme peroxidases, the Glycera dibranchiata monomer hemoglobin components III and IV exhibit very slow cyanide binding kinetics. This is agreement with the previously reported behavior of component II. Similar to component II, components III and IV have been studied under pseudo-first-order conditions at pH 6.0, 7.0, 8.0, and 9.0 by using a 100-250-fold excess of potassium cyanide at each pH. At 20 degrees C with micromolar protein concentrations, kobs for component III varies between 7.08 x 10(-5) s-1 at pH 6.0 and 100-fold cyanide excess and 1.06 x 10(-2) s-1 at pH 9.0 and 250-fold cyanide excess. For component IV, the values are 2.03 x 10(-4) s-1 for 100-fold cyanide excess at pH 6.0 and 4.13 x 10(-2) s-1 for 250-fold cyanide excess at pH 9.0. In comparison to other heme proteins, our analysis shows that the bimolecular rate constant (klapp) is small. For example, at pH 7.0, it is 3.02 x 10(-1) M-1 s-1 for component III and 1.82 M-1 s-1 for component IV, compared to 400 M-1 s-1 for sperm whale metmyoglobin, 692 M-1 s-1 for soybean metleghemoglobin a, 111 M-1 s-1 for guinea pig methemoglobin, and 1.1 x 10(5) M-1 s-1 for cytochrome c peroxidase. Our results also show that the dissociation rates (k-lapp) are extremely slow and no larger than 10(-6) s-1.(ABSTRACT TRUNCATED AT 250 WORDS)     

Heme degradation during autoxidation of oxyhemoglobin

Two fluorescent heme degradation compounds are detected during autoxidation of oxyhemoglobin. These fluorescent compounds are similar to fluorescent compounds formed when hydrogen peroxide reacts with hemoglobin [E. Nagababu and J. M. Rifkind, Biochem. Biophys. Res. Commun. 247, 592-596 (1998)]. Low levels of heme degradation in the presence of superoxide and catalase are attributed to a reaction involving the superoxide produced during autoxidation. The inhibition of most of the degradation by catalase suggests that the hydrogen peroxide generated during autoxidation of oxyhemoglobin produces heme degradation by the same mechanism as the direct addition of hydrogen peroxide to hemoglobin. The formation of the fluorescent degradation products was inhibited by the peroxidase substrate, ABTS, which reduces ferrylhemoglobin to methemoglobin, indicating that ferrylhemoglobin is produced during the autoxidation of hemoglobin. It is the transient formation of this highly reactive Fe(IV) hemoglobin, which is responsible for most of the heme degradation during autoxidation.     

Deciphering the intercalative binding modes of benzoyl peroxide with calf thymus DNA

The binding of benzoyl peroxide (BPO), a flour brightener, with calf thymus DNA (ctDNA) was predicted by molecular simulation, and this were confirmed using multi‐spectroscopic techniques and a chemometrics algorithm. The molecular docking result showed that BPO could insert into the base pairs of ctDNA, and the adenine bases were the preferential binding sites which were validated by the analysis of Fourier transform infrared spectra. The mode of binding of BPO with ctDNA was an intercalation as supported by the results from ctDNA melting and viscosity measurements, iodide quenching effects and competitive binding investigations. The circular dichroism and DNA cleavage assays indicated that BPO induced a conformational change from B‐like DNA structure towards to A‐like form, but did not lead to significant damage in the DNA. The complexation was driven mainly by hydrogen bonds and hydrophobic interactions. Moreover, the ultraviolet–visible (UV–vis) spectroscopic data matrix was resolved by a multivariate curve resolution–alternating least–squares algorithm. The equilibrium concentration profiles for the components (BPO, ctDNA and BPO–ctDNA complex) were extracted from the highly overlapping composite response to quantitatively monitor the BPO–ctDNA interaction. This study has provided insights into the mechanism of the interaction of BPO with ctDNA and potential hazards of the food additive.     

Green hemoprotein of erythrocytes: methemoglobin superoxide transferase

Influences of base (pH 10), heat (50 degrees C), microwave radiation (2450 MHz, 103 +/- 4 W/kg), and hydrogen peroxide (5.6 mM) generated by glucose oxidase on oxidation of human oxyhemoglobin to methemoglobin were examined. Conversion of oxyhemoglobin to methemoglobin was followed by the difference in absorbancy of 540 or 542 nm and 576 nm wavelength light versus time. Fresh basic hemolysates auto-oxidized on heating with a zero order rate constant, implying that hemoglobin or another protein saturated with oxyhemoglobin catalyzed the oxidation. Simultaneous microwave irradiation inhibited thermally induced auto-oxidation on the average by 28.6%. However, there was great variability among samples and a decrease in auto-oxidation with aging of individual samples. The auto-oxidation rate was independent of initial oxyhemoglobin concentration. Oxidation of partially purified oxyhemoglobin by hydrogen peroxide was not influenced by microwave irradiation. Adding green hemoprotein isolated from human erythrocytes to the oxyhemoglobin/glucose oxidase reaction mixture yielded absorption spectra (500-600 nm) that were a combination of oxyhemoglobin, deoxyhemoglobin, and methemoglobin spectra. Green hemoprotein was labile in hemolysates but stable in a partially purified ferric form. These results imply that thermally unstable reduced green hemoprotein can reverse oxidation of oxyhemoglobin by hydrogen peroxide and could mediate the thermally induced and microwave inhibited auto-oxidation of oxyhemoglobin.     

Ferrous ion-induced strand breaks in the DNA plasmid pBR322 are not mediated by hydrogen peroxide

Ferrous ion-induced generation of single and multiple strand breaks in the DNA plasmid pBR322 induces the formation of two new plasmid forms with altered electrophoretic mobility. The yield of these plasmid forms, the circular relaxed and the linear forms, depended on the applied Fe²⁺ concentration. This property was independent of the presence of hydrogen peroxide in the incubation mixture indicating the lack of Fenton chemistry to explain the DNA degradation. The removal of dioxygen or the presence of superoxide dismutase diminished partially the yield of ferrous ion-induced DNA plasmid degradation, while catalase was without any effect. Autoxidation of divalent iron as followed by the formation of a coloured iron-phenanthroline complex was enhanced in a concentration-dependent manner by phosphate and bicarbonate and very efficiently using a mixture of 0.15 M NaCl, 1.2 mM phosphate, 23.8 mM bicarbonate, pH 7.4, that concentrations correspond closely to the intracellular values of buffer components. Thus, the formation of a yet unknown reactive species from Fe²⁺, and dioxygen, that is complexed to buffer components especially phosphate and its contribution in DNA plasmid degradation is more likely than the often cited formation of hydroxyl radicals in result of the Fenton reaction from Fe²⁺ and hydrogen peroxide. Dedicated to Prof. K. Arnold on the occasion of his 65th birthday.     

Capecitabine as a minor groove binder of DNA: molecular docking,molecular dynamics,and multi-spectroscopic studies

The interaction mechanism and binding mode of capecitabine with ctDNA was extensively investigated using docking and molecular dynamics simulations, fluorescence and circular dichroism (CD) spectroscopy, DNA thermal denaturation studies, and viscosity measurements. The possible binding mode and acting forces on the combination between capecitabine and DNA had been predicted through molecular simulation. Results indicated that capecitabine could relatively locate stably in the G-C base-pairs-rich DNA minor groove by hydrogen bond and several weaker nonbonding forces. Fluorescence spectroscopy and fluorescence lifetime measurements confirmed that the quenching was static caused by ground state complex formation. This phenomenon indicated the formation of a complex between capecitabine and ctDNA. Fluorescence data showed that the binding constants of the complex were approximately 2 × 10⁴ M^?1. Calculated thermodynamic parameters suggested that hydrogen bond was the main force during binding, which were consistent with theoretical results. Moreover, CD spectroscopy, DNA melting studies, and viscosity measurements corroborated a groove binding mode of capecitabine with ctDNA. This binding had no effect on B-DNA conformation.     

Cationic porphyrins bearing diazolium rings: synthesis and their interaction with calf thymus DNA

Two novel cationic porphyrins bearing five-membered rings at the meso-positions, meso-tetrakis(1,3-dimethylimidazolium-2-yl)porphyrin (H2TDMImP) and meso-tetrakis(1,2-dimethylpyrazolium-4-yl)porphyrin (H2TDMPzP), have been synthesized. These two compounds interact with calf thymus DNA (CTDNA) in different binding modes from that of mesotetrakis(N-methylpyridinium-4-yl)porphyrin (H2TMPyP). H2TDMImP outside binds to the minor groove of CTDNA while H2TDMPzP intercalates into CTDNA. These two novel cationic porphyrins strongly bind to CTDNA even at high ionic strength and the binding constant of H2TDMPzP to CTDNA is comparable to that of H2TMPyP. The binding of H2TDMImP to CTDNA is enthalpically driven. The favorable free energy changes in binding of H2TDMPzP to CTDNA come from the large negative enthalpy changes accompanied by small positive entropy changes.     

Molecular interaction studies of zinc sulphide nanoparticles with DNA and its consequence: a multitechnique approach

Molecular interaction studies between nanoparticles (NPs) and biomolecules are of great importance in the field of nanomedicine as they affect many physiological processes. Therefore, the interaction of zinc sulphide nanoparticles (ZnS NPs) with calf thymus deoxyribonucleic acid (CT DNA) and its significance was analyzed using ultraviolet (UV)–visible light, fluorescence, circular dichroism (CD), zeta potential, viscometry, electrochemical, and polymerase chain reaction methods. Fluorescence quenching analysis revealed that the fluorescence of ZnS NPs was quenched using CT DNA through a static quenching mechanism. The negative values of thermodynamic parameters (ΔG, ΔH, and ΔS) showed that the binding process was spontaneous, exothermic, and van der Waals or hydrogen bonding plays an important role in the interaction of ZnS NPs with CT DNA. Thermal melting (T_m) studies indicated a decrease in the T_m of CT DNA, suggesting the destabilization of CT DNA upon interaction with ZnS NPs. In addition, the results obtained from competitive binding, zeta potential, CD, and viscometry measurements showed that the interaction of ZnS NPs with CT DNA is through groove binding. Electrochemical analysis further confirmed the observed results from various spectroscopic and other related studies, in which decrease in the redox peak current along with changes in peak potential (CV) and increase in the electrical resistance (EIS) indicated the interaction between ZnS NPs and CT DNA. Furthermore, PCR analysis using DNA polymerase revealed the potential of ZnS NPs to inhibit DNA replication in vitro. ZnS NP–CT DNA interaction studies can be explored to define new horizons in biomedical applications of ZnS NPs.     

The oxidative stress response in Bacillus subtilis

Abstract Bacillus subtilis undergoes a typical bacterial stress response when exposed to low concentrations (0.1 mM) of hydrogen peroxide. Protection is thereby induced against otherwise lethal, challenge concentrations (10 mM) of this oxidant and a number of proteins are induced including the scavenging enzymes, catalase and alkyl hydroperoxide reductase, and a putative DNA binding and protecting protein. Induced protection against higher concentrations (10–30 mM) of hydrogen peroxide is eliminated in a catalase-deficient mutant. Both RecA and Spo0A influence the basal but not the induced resistance to hydrogen peroxide. A regulatory mutation has been characterized that affects the inducible phenotype and is constitutively resistant to high concentrations of hydrogen peroxide. This mutant constitutively overexpresses the proteins induced by hydrogen peroxide in the wild-type. The resistance of spores to hydrogen peroxide is partly attributable to binding of small acid soluble proteins by the spore DNA and partly to a second step which coincides with the depletion of the NADH pool, which may inhibit the generation of hydroxyl radicals from hydrogen peroxide.     

A stoichiometric study of heme degradation catalyzed by the reconstituted heme oxygenase system with special consideration of the production of hydrogen peroxide during the reaction

In heme degradation catalyzed by the reconstituted heme oxygenase system, 8 to 9 mol of dioxygen and 11 to 12 mol of NADPH were consumed per mol of hemin lost, and about half the amount of dioxygen consumed could be accounted for by the production of hydrogen peroxide, which accumulated in the reaction mixture. Production of hydrogen peroxide in the heme oxygenase reaction did not appear to be due to the bimolecular dismutation of superoxide anions but rather seemed to be due to dissociation of a "peroxo" species formed on heme or intermediates of heme degradation. The hydrogen peroxide produced appeared to cause a considerable degree of non-specific degradation of heme (not leading to the formation of biliverdin) and also caused an inactivation of heme oxygenase. By taking into account the amount of dioxygen incorporated into hydrogen peroxide and some other factors, it could be deduced that 3 mol of dioxygen is consumed for the formation of 1 mol of biliverdin in the heme oxygenase reaction.     

In vivo heme scavenging by Staphylococcus aureus IsdC and IsdE proteins

We report the first characterization of the in vivo porphyrin scavenging abilities of two components of a newly discovered heme scavenging system involving iron-regulated surface determinant (Isd) proteins. These proteins are present within the cell envelope of the Gram-positive human pathogen Staphylococcus aureus. IsdC and IsdE, when expressed heterologously in Escherichia coli, efficiently scavenged intracellular heme and resulted in de novo heme synthesis in excess of 100-fold above background. Magnetic circular dichroism analyses showed that the heme-binding properties of the two proteins differ significantly from one another. IsdC bound almost exclusively free-base protoporphyrin IX, whereas the IsdE protein was associated with low spin Fe(III) and Fe(II) heme. These properties provide important insight into the possible mechanisms of iron scavenging from bound heme by Isd proteins.     

Models for the complexes formed between cytochrome b5 and the subunits of methemoglobin

Computer graphics-generated models for the electron transfer complexes formed between cytochrome b5 and the subunits of methemoglobin are proposed. For both complexes, the orientation allowing optimal hydrogen bonding involves interaction between negatively charged residues on cytochrome b5 and positively charged residues on methemoglobin. In each complex, the heme groups of the interacting species are coplanar with the edges of the heme groups separated by 7-8 A and with the iron atoms 16 A apart. For the alpha-chain X cytochrome b5 complex, alpha-chain residues 56 (Lys), 60 (Lys), and 90 (Lys) interact with cytochrome b5 residues 44 (Glu), 43 (Glu), and 60 (Asp) respectively. A fourth hydrogen bond involves alpha-61 (Lys) bridging between a heme propionate from cytochrome b5 and a heme propionate from the alpha-chain. The contacts present in the beta-chain X cytochrome b5 complex involve hydrogen-bonding between beta-chain lysyl residues 59, 61, 65, and 95, and cytochrome b5 residues 48 (Glu), 44 (Glu), 43 (Glu), and 60 (Asp) respectively. An additional hydrogen bond can be formed by bridging of the epsilon-amino group of beta-66 (Lys) between a heme propionate from cytochrome b5 and a beta-chain heme propionate. In each complex, two nonionic interactions, one on each side of the heme groups, are also suggested. These interactions appear to effectively exclude external water molecules from the center of the protein-protein interaction domain. Comparison of the proposed binding loci for cytochrome b5 on the methemoglobin subunits with those proposed on cytochrome c reveals considerable structural homology between the cytochrome b5 binding sites.     

The degradation of cytochrome c by hydrogen peroxide

Cytochrome c is degraded by a large excess of hydrogen peroxide, leading to opening of the heme porphyrin ring and loss of the Soret absorption bands. The kinetic parameters of this reaction have been determined, and it is shown that a small concentration of oxygen is liberated at the same rate as degradation. Low-level chemiluminescence and release of a hydroxylating species also accompany heme destruction. It is proposed that heme iron activates hydrogen peroxide to a more powerful oxidant, perhaps the hydroxyl radical, which remains bound to the heme iron and initiates attack on the porphyrin ring. Chemiluminescence appears to result from a side reaction involving singlet oxygen attack on the alpha-methene bridge, yielding a dioxetane. The in vivo degradation of cytochrome c by excess hydrogen peroxide may interfere with respiration, accelerate aging, and enhance the metabolism of carcinogens.     

植物过氧化物酶超家族的分子结构

过氧化物酶广泛存在于生物中。基于序列相似性比较,可将真菌、细菌和植物来源的过氧化物酶归为一个超家族－植物过氧化物酶超家族。作者对近几年来植物过氧化物酶超家族的分子结构与功能研究进展,从过氧化物酶的辅基（血红素）微循环结构、过氧化物酶超家族的序列结构域,以及酶分子中底物结合位点和Ca^2＋结合位点的结构等方面作了简要评述。     

Interactions of heme proteins with hydrogen peroxide: protein crosslinking and covalent binding of benzo[a]pyrene and 17 beta-estradiol

This work reveals two biochemical effects of hydrogen peroxide treatment on hemoglobin, myoglobin, and cytochrome c. First, these heme proteins rapidly formed covalently crosslinked dimers and polymers detectable by detergent gel electrophoresis. Second, when treated in the presence of radioactive benzo[a]pyrene or 17 beta-estradiol, the heme proteins became covalently labeled. Nonheme proteins exhibited both cross-linking and radioactive labeling upon peroxide treatment in the presence but not the absence of heme protein or free hemin. Benzoyl peroxide or glucose and glucose oxidase effectively replaced direct addition of hydrogen peroxide. These results indicate that adventitious peroxidase activity expressed by oxygen carrying and electron transport proteins yields active oxygen species that can damage these heme proteins and nearby macromolecules, a possible biochemical mechanism for the lethal and other deleterious intracellular effects of peroxide.     

Destructive effect of anticancer oxali-palladium on heme degradation through the generation of endogenous hydrogen peroxide

The interaction between human hemoglobin (Hb) and oxali-palladium was studied using different spectroscopic methods of UV–vis, fluorescence, circular dichroism (CD), and chemiluminescence at two temperatures of 25 and 37°C. The experimental results showed that both dynamic and static quenching is occurred simultaneously when oxali-palladium quenches the fluorescence of Hb. According to the fluorescence quenching method, the binding site number, apparent binding constant, and corresponding thermodynamic parameters were measured at two temperatures. The values of ΔH°, ΔS°, and ΔG° indicate that process of the formation of oxali-palladium–Hb complex is a spontaneous interaction procedure in which electrostatic interaction plays a major role. In addition, UV–vis and CD results showed that the addition of oxali-palladium changes the conformation of Hb. To evaluate the functional changes of Hb via destruction of the heme structure, fluorescence studies were performed. The results demonstrated that two fluorescent heme degradation products are found during the interaction of oxali-palladium with Hb. Also, the amount of hydrogen peroxide produced in the solution of Hb due to the interaction of oxali-palladium with Hb using chemiluminescence method indicated heme degradation in the protein is occurred. Structural and functional changes induced in Hb via heme degradation are considered as side effects of this synthesized anticancer drug.