[Antioxidant activity of oxygen-containing aromatic compounds].

Inhibition efficiency (antioxidant activity) of 26 oxygen-containing aromatic compounds was studied in methemalbumin-H202-o-phenylenediamine (PDA) or tetramethylbenzidine (TMB) pseudoperoxidase system at 20 degrees C in buffered physiological solution (pH 7.4) containing 6% DM F and 0.25% DMSO. The inhibitor's efficiency was quantitatively characterized by the inhibition constants (Ki, microM) or the inhibition degree (%). Ki values varied in the range of4 to 500 microM and were influenced by a substrate, the structure of an inhibitor, hydroxyl groups, electron-donating substituents in aromatic ring, and steric hindrances. The type of inhibition at cooxidation of eight pairs was noncompetitive, and that of five pairs was mixed and determined by the substrate nature and the inhibitor structure. Lignin phenolic compounds ofguaiacyl and syringal series exhibited high antioxidant activity (Ki in the range of 10-300 microM), and their efficiency decreased in the following order: caffeic acid > synapaldehyde > syringic acid > coniferyl aldehyde > para-hydroxycou maric acid.

Purification and viral inactivation of hemoglobin from human placenta blood.

A new procedure was developed to obtain high-quality polymerized human hemoglobin by modifying purified hemoglobin with PLP and polymerized with GDA. Comparing polymerized hemoglobin products obtained from different methods, the product from the new procedure has similar physical, chemical, and biological properties in the molecular distribution, methemoglobin concentration, oxygen carrier capacity, P(50) and spectral analysis. Furthermore, the new procedure of modification after polymerization can save PLP greatly, and significantly reduce the cost. So the procedure of modification after polymerization is a better way in research and production.

[Substituted aminophenols and flavonoids as potential components for test-systems of total antioxidant activity].

A comparative kinetic study of ortho-phenylenediamine (PDA) oxidation in the "pseudoperoxidase" system Methemalbumin-H2O2 in the presence of 2-amino-4-tret-butylphenol (ATBP), 2-amino-4,6-di-tret-butylphenol (ADTBP) and its four N-acyl derivates, as well as flavonoids (quercetin, morin, silibin, hesperidin and naringin) has been carried out under standart conditions at 20 degrees C in phosphate buffered saline, pH 7.4, containing 5.25% ethanol and DMFA. ATBP, ADTBP and two its N-acyl-derivatives as well as all five flavonoids inhibited with different efficiency the PDA oxidation characterized in terms of the inhibition constants, K(i), M, or the percent of inhibition degree at the maximal taking concentrations of these inhibitors. Most effective antioxidants were quercetin (K(i) = 7.7x10(-5) M) and ATBP (K(i) = 1.26x10(-4) M). Using these characteristics and other necessary criteria, the pairs PDA-quercetin and PDA-ATBP were proposed for a practical application in the test-systems for total antioxidant activity of biological objects.

Effect of prototypic drugs ibuprofen and warfarin on global chaotropic unfolding of human serum heme-albumin: a fast-field-cycling 1H-NMR relaxometric study.

Human serum albumin (HSA) is the most prominent protein in plasma, but it is also found in tissues and secretions throughout the body. The three-domain design of HSA provides a variety of binding sites for many ligands, including heme and drugs. HSA has been used as a model multidomain protein to investigate how interdomain interactions affect the global folding/unfolding process. Here, we report on the reversible chemical denaturation of heme-HSA involving three different conformational states (F, N, and B, occurring at pH 4.0, 7.0, and 9.0, respectively) and on the effect of prototypic drugs ibuprofen and warfarin on thermodynamics of the reversible unfolding process. Chaotropic unfolding of heme-HSA in the F, N, and B conformations is governed by different thermodynamic regimes, with the B form showing an entropic stabilization of the structure that compensates an enthalpic destabilization, and the F form easily unfolding under entropic control. Warfarin and ibuprofen binding stabilizes heme-HSA in both N and B states.

Binding of heme to human serum albumin: steady-state fluorescence, circular dichroism and optical difference spectroscopic studies.

The binding of monomeric heme to human serum albumin (HSA) was investigated using steady-state fluorescence, circular dichroism (CD) and optical difference spectroscopic (ODS) techniques. The existence of one strong binding site for heme on HSA was confirmed by titrating heme with HSA and following the quenching of tryptophan (Trp214) fluorescence emission intensity that occurred due to energy transfer. Up to around 1:1 stoichiometric ratio of HSA/heme, the quenching was observed to be very strong, however at higher ratios the quenching progressed very weakly. Similarly, the negative CD band centered at -397 nm, which appeared on adding heme to HSA, increased in intensity on sequential addition of heme up to [heme]/[HSA] = 1. Titration of HSA with heme was followed by ODS and the dissociation constant K(D) = (4.0 +/- 1.0) x 10(-5) M was deduced. Results have been explained on the basis of Michaelis-Menton type of mechanism for the heme binding, in which heme first binds reversibly to His146 at the surface of the protein to form an intermediate complex, followed by irreversible binding to Tyr161 in the interior of the protein.

[Methemalbuminnemia after massive hemolysis during blackwater fever]. / Methémmalbuminémie après hémolyse massive au cours d'une fièvre bilieuse hémoglobinurique.

We report a case of blackwater fever with brown plasma due to the presence of methemalbumin. The discovery of plasma with this color is a rare event at the laboratory. This compound appears during intravascular hemolysis or hemorrhagic pancreatitis when the ability of haptoglobin and hemopexin to bind free hemoglobin has been exceeded. In these cases some of heme is oxidized to hematin and taken up by serum albumin to form an albumin-hematin complex called methemalbumin. The major clinical problem is to evoke the diagnosis of methemalbuminemia and not confuse with methemoglobinemia. In our case, methemalbumin was detected and quantified using a scanning spectrophotometer. Its diagnostic and clinicals consequences are discussed.

Spectroscopic studies on human serum albumin and methemalbumin: optical, steady-state, and picosecond time-resolved fluorescence studies, and kinetics of substrate oxidation by methemalbumin.

The nature of the heme environment in methemalbumin, the Fe(III) protoporphyrin IX (heme)-human serum albumin (HSA) complex, was investigated by optical spectroscopy. Comparison of the optical spectra of methemalbumin, ferro-hemalbumin in the absence and presence of 2-methylimidazole, and their carbon monoxide derivatives with horseradish peroxidase (HRP) and its corresponding derivatives indicates that histidine is not present in the first coordination sphere of heme in methemalbumin and that the protein is devoid of a well-defined heme cavity. The complex exhibits peroxidase activity by catalyzing oxidation of 2,2'-azinobis(3-ethylbenzthiazoline-6-sulfonate) by hydrogen peroxide. Its activity ( K(M)=433 microM, molar catalytic activity=0.33 s(-1)), however, is considerably lower compared to HRP, indicating differences in the heme environments. Fluorescence intensity decays of Trp214 in HSA and methemalbumin, best fitted to a three-exponential model, gave the lifetimes 7.03 ns (30%), 3.17 ns (38%), and 0.68 ns (32%) for HSA and 8.04 ns (1.7%), 2.42 ns (19.7%), and 0.64 ns (78.6%) for methemalbumin. These lifetime values were further confirmed by a model-independent maximum entropy method. Similarity in the lifetimes and variations in the amplitudes suggest that while conformational heterogeneity of HSA is unperturbed on heme binding, redistribution of the populations of the three conformations occurs and the sub-state associated with the shortest lifetime dominates the total population by approximately 80%. Decay associated spectra (DAS) indicate that the observed lifetime variation with wavelength is predominantly due to ground state heterogeneity, though solvent dipolar relaxation also contributes. Time-resolved fluorescence anisotropy measurements of the Trp214 residue yielded information on motion within the protein together with the whole protein molecule. The binding of heme did not affect the rotational correlation time of the albumin molecule (approximately 20 ns). However, the motion of tryptophan within the protein matrix increased by a factor of approximately 3 (0.46 ns to 0.15 ns). This indicates that while the overall hydrodynamic volume of the albumin molecule remained the same, tryptophan underwent a more rapid internal rotation because of the efficient energy transfer to the bound heme. Optical studies, analysis of lifetime measurements, DAS, and anisotropy measurements together suggest that heme binds to a surface residue. The rapid internal motion of Trp214 during its excited state lifetime for the approximately 80% populated conformer of methemalbumin allows the orientation factor, kappa(2), to approach the average value of 2/3. From the time-resolved fluorescence measurements and the energy transfer calculations on methemalbumin, a Trp214-heme distance of 22 A was deduced.

The atomic structure of human methemalbumin at 1.9 A.

The high resolution structure of hemalbumin was determined by single crystal X-ray diffraction to a resolution of 1.9 A. The structure revealed the protoporphyrin IX bound to a single site within a hydrophobic cavity in subdomain IB, one of the principal binding sites for long chain fatty acid. The iron is penta coordinated with the fifth ligand comprised of the hydroxyl oxygen of Tyr-161 (phenolic oxygen to heme plane distance: 2.73 A) in an otherwise completely hydrophobic pocket. The heme propionic acid residues form salt bridges with His-142 and Lys-190, which together with a series of hydrophobic interactions, enclose and secure the heme within the IB helical motif. A detailed discussion of the structure together with its implications for the development of potential blood substitutes is presented.

[Determining role of media in peroxide oxidation of aromatic type antioxidants with participation of methemalbumins]. / Opredeliaiushchaia rol' sredy v peroksidnom okislenii antioksidantov aromaticheskiogo riada s uchastiem metgemal'buminov.

Participation of the complexes of hemin and albumins (or delipidated albumins) in peroxidation of aromatic free radical scavengers and antioxidants was studied at varying hemin/albumin ratios. The radical-scavenging amines included o-phenylenediamine (OPD) and tetramethylbenzidine (TMB); the antioxidants, gallic acid (GA) and GA polydisulfide (GAPD). Peroxidation reactions were carried out in buffered physiological saline (BPS) supplemented with 2% dimethylsulfoxide(DMSO), pH 7.4 (medium A), or in 40% aqueous dimethylformamide (DMF), pH 7.4 (medium B). In all systems involving methemalbumins, kinetic constants (kcat), Michaelis constants (kM), and the ratios thereof (kcat/kM) were determined for OPD oxidation in medium A and TMB oxidation in medium B. Oxidation of OPD, GA, and GAPD in medium A was characterized by a decrease in the catalytic activity of hemin after the formation of hemin-albumin complexes. Conversely, oxidation of TMB and OPD in medium B was distinguished by pronounced activation of hemin present within methemalbumins.