A role of methionines in the functioning of oxidatively modified fibrinogen.

Posttranslational modifications in fibrinogen resulting from induced oxidation or oxidative stress in the organism can have deleterious influence on optimal functioning of fibrinogen, causing a disturbance in assembly and properties of fibrin. The protective mechanism supporting the ability of fibrinogen to function in ROS-generating environment remains completely unexplored. The effects of very low and moderately low HOCl/-OCl concentrations on fibrinogen oxidative modifications, the fibrin network structure as well as the kinetics of both fibrinogen-to-fibrin conversion and fibrin hydrolysis have been explored in the current study. As opposed to 25 Μm, HOCl/-OCl, 10 µM HOCl/-OCl did not affect the functional activity of fibrinogen. It is shown for the first time that a number of Met residues, AαMet476, AαMet517, AαMet584, BßMet367, γMet264, and γMet94, identified in 10 µM HOCl/-OCl fibrinogen by the HPLC-MS/MS method, operate as ROS scavengers, performing an important antioxidant function. In turn, this indicates that the fibrinogen structure is adapted to the detrimental action of ROS. The results obtained in our study provide evidence for a protective mechanism responsible for maintaining the structure and functioning of fibrinogen molecules in the bloodstream under conditions of mild and moderate oxidative stress.

Peroxide-Induced Damage to Plasminogen Molecules.

Plasminogen is a zymogenic form of plasmin, an enzyme that plays a fundamental role in the dissolution of fibrin clots as well as in many other physiological processes. For the first time, by the method of gas chromatography-mass spectrometry, post-translational modifications in the primary structure of plasminogen treated with physiologically relevant amounts of hydrogen peroxide were identified. It was found that methionine and tryptophan residues located in different structural regions of plasminogen served as targets of the oxidant. Plasminogen oxidation caused a dose-dependent effect in decreasing the fibrinogenolytic activity of plasmin evidenced by the formation of fibrinogen degradation products. The possible antioxidant role of methionines in the oxidative modification of plasminogen is discussed.

Effect of Hypochlorite- and Peroxide-Induced Oxidation of Fibrinogen on the Fibrin Structure.

Using the methods of dynamic and elastic light scattering and confocal laser scanning microscopy, the damage in the spatial fibrin structure during peroxide- and hypochlorite-induced oxidation of fibrinogen was studied. Peroxide had a weak effect on the structural organization of fibrin, whereas hypochlorite caused the formation of abnormal fibrin with reduced individual fiber diameter and decreased porosity. Measurements of the size distributions of the native and oxidized fibrinogen revealed a decrease in the hydrodynamic size of the oxidized fibrinogen molecule with an increase in the concentration of oxidizers. These results indicate that the hydrophobicity of fibrinogen surface increased and its colloidal stability decreased. The possible role of oxidative sites in the assembly of structurally abnormal fibrin is analyzed.

The Nature of Resistance of the Coagulation Factor XIII Structure to Hypochlorite-Induced Oxidation.

The damage to blood coagulation factor XIII (FXIII) at different stages of its enzymatic activation under the action of various physiological amounts of hypochlorite ion was studied. The results obtained by HPLC-MS/MS, SDS-PAGE, and colorimetry showed that, during the conversion of FXIII to FXIIIa, the vulnerability of FXIII to hypochlorite-induced oxidation increased. FXIII oxidized with 150 µM hypochlorite completely retained its enzymatic activity inherent to the intact protein, whereas FXIIIa treated with 50 µM hypochlorite showed sharply reduced enzymatic activity. It was shown that a number of methionine and cysteine residues on the catalytic subunit can perform antioxidant function; additionally, the regulatory subunits of FXIII-B contribute to the antioxidant protection of the catalytic center of the FXIII-A subunit, which, together with the tight packing of the tetrameric structure of the FXIII proenzyme, are the three factors that provide high protein resistance to the oxidizing agent.

The Structural-Functional Damage of Fibrinogen Oxidized by Hydrogen Peroxide.

The effect of peroxide-induced oxidation of fibrinogen on modification of its primary structure and functional properties was investigated. The oxidation sites were shown to be Met, Trp, and His residues. Using the DLS method, it was found that the oxidative modification of fibrinogen results in the change of microrheological characteristics of fibrin network. The fibrinogen oxidation diminishes its tolerance to plasmin hydrolysis and deteriorates the factor XIIIa ability to stabilize the fibrin gel.

Hypochlorite-Induced Damage of Plasminogen Molecules: Structural-Functional Disturbance.

Plasminogen, the precursor of plasmin, is a serine protease that plays a fundamental role in the intravascular thrombolysis. For the first time, by using high-resolution mass spectrometry, data on the oxidative modifications of the plasminogen molecule under induced oxidation were obtained. The FTIR data show that, under oxidation on the protein, its secondary structure also undergoes the rearrangements. The high tolerance of plasminogen to oxidation can be due to both the closed conformation and the ability of some Met residues to serve as ROS trap.

Peroxide-Induced Oxidative Modification of Hemoglobin.

The oxidative modification of human hemoglobin (Hb) treated with hydrogen peroxide was investigated. Using the mass spectrometry method, the oxidized amino acid residues of the hemoglobin molecule were detected: αTrp14, αTyr24, αArg31, αMet32, αTyr42, αHis45, αHis72, αMet76, αPro77, αLys90, αCys104, αTyr140, ßHis2, ßTrp15, ßTrp37, ßMet55, ßCys93, ßCys112, ßTyr130, ßLys144, and ßHis146. The antioxidant potential of the Hb molecule in the intracellular space and in the blood plasma is discussed.

Hypochlorite-Induced Oxidative Modification of Fibrinogen.

Oxidation of fibrinogen with hypochlorite inhibited the fibrin network self-assembly even at the lowest concentration of the oxidant. The analysis of the results of protein electrophoresis at this hypochlorite concentration showed the absence of fragmentation of the protein and covalent cross-linking of its chains. The study of the areas responsible for the conversion of fibrinogen into fibrin by mass spectrometry showed that they are not subject to oxidative damage. However, we identified oxidized amino acid residues, which could affect the protofibril aggregation.

Study of Human Fibrinogen Oxidative Modification using Differential Scanning Calorimetry.

For the first time, with the aid of differential scanning calorimetry, the thermal denaturation of fibrinogen under induced oxidation was studied. All fibrinogen structural elements detected by DSC (D region, αC-domain, and E region) are subjected to oxidation. Structural changes in fibrinogen molecule were characterized by the denaturation temperature, denaturation enthalpy, and van't Hoff enthalpy.

Oxidation-induced modification of the fibrinogen polypeptide chains.

By using the mass-spectrometry method, the oxidative modifications of the fibrinogen Aα, Bß, and γ polypeptide chains induced by its oxidation have been studied. The αC-region has been proven to be the most vulnerable target for the oxidizer (ozone) as compared with the other structural elements of the Aα chain. The Bß chain mapping shows that the oxidative sites are localized within all the structural elements of the chain in which the ß-nodule exhibits high susceptibility to oxidation. The γ chains are the least vulnerable to the oxidizer action. The results obtained demonstrate convincingly that the self-assembly centers dealing with interactions of knob "A": hole "a" are not involved in oxidative modification. It is concluded that the numerous oxidative sites revealed are mainly responsible for inhibiting lateral aggregation of protofibrils. The part of amino acid residues subjected to oxidation is supposed to carry out the antioxidant function.

Modification of human serum albumin under induced oxidation.

For the first time, by using the complex of physicochemical methods (mass-spectrometry, differential scanning calorimetry, spectrofluorimetry, method of spectral and fluorescent probes, dynamic light scattering, and UV spectrophotometry), the oxidation-mediated modification of chemical and spatial structure of albumin has been studied. All albumin structural regions are subjected to oxidation, methionine and aromatic amino acids primarily involved in oxidation. The albumin melting shows a decrease in thermal stabilization of the structure and changing of aggregation upon oxidation. The change in physical and chemical properties of albumin under different quantity of the oxidizer has been analyzed.

Modification of the catalytic subunit of plasma fibrin-stabilizing factor under induced oxidation.

For the first time, by using mass-spectrometry method, the oxidation-mediated modification of the catalytic FXIII-A subunit of plasma fibrin-stabilizing factor, pFXIII, has been studied. The oxidative sites were identified to belong to all structural elements of the catalytic subunit: the ß-sandwich (Tyr104, Tyr117, and Cys153), the catalytic core domain (Met160, Trp165, Met266, Cys328, Asp352, Pro387, Arg409, Cys410, Tyr442, Met475, Met476, Tyr482, and Met500), the ß-barrel 1 (Met596), and the ß-barrel 2 (Met647, Pro676, Trp692, Cys696, and Met710), which correspond to 3.9%, 1.11%, 0.7%, and 3.2%, respectively, of oxidative modifications as compared to the detectable amounts of amino acid residues in each of the structural domains. Lack of information on some parts of the molecule may be associated with the spatial unavailability of residues, complicating analysis of the molecule. The absence of oxidative sites localized within crucial areas of the structural domains may be brought about by both the spatial inaccessibility of the oxidant to amino acid residues in the zymogen and the screening effect of the regulatory FXIII-B subunit.

The oxidative modification of cellular fibrin-stabilizing factor.

For the first time, the induced oxidative modification of cellular fibrin-stabilizing factor (cFXIII) has been studied. According to the electrophoresis analysis, the conversion of oxidized cFXIII into FXIIIa resulted in producing the enzyme that significantly lost the initial enzymatic activity. At the same time, FXIIIa subjected to induced oxidation was completely devoid of enzymatic activity. The results of FTIR spectroscopy showed that the oxidation of cFXIII or FXIIIa was accompanied by profound changes both in chemical and spatial structures of the protein. The results of this study are in good agreement with our earlier assumption regarding the antioxidant role of the regulatory subunits B of plasma fibrin-stabilizing factor.

The strengthening role of D:D interactions in fibrin self-assembly under oxidation.

The effect on ozone-induced oxidation on the self-assembly of fibrin in the presence of fibrin-stabilizing factor FXIIIa of soluble cross-linked fibrin oligomers was studied in a medium containing moderate urea concentrations. It is established that fibrin oligomers were formed by the protofibrils cross-linked through γ-γ dimers and the fibrils additionally cross-linked by through α-polymers. The oxidation promoted both the accumulation of greater amounts of γ-γ dimers and the formation of protofibrils, fibrils, and their dissociation products emerging with increasing urea concentrations, which have a high molecular weight. It is concluded that the oxidation enhances the axial interactions between D-regions of fibrin molecules.

Longitudinal orientation of cross-linked polypeptide γ chains in fibrin fibrils.

The crosslinking of fibrin γ-polypeptide chains under the influence of the plasma fibrin-stabilizing factor (FXIIIa), which causes their conversion to γ-γ dimers, is the major enzyme reaction of covalent fibrin stabilization. We studied the self-assembly of soluble cross-linked fibrin oligomers. The results of analytical ultracentrifugation as well as elastic and dynamic light scattering showed that the double-stranded fibrin oligomers formed under the influence of moderate concentrations of urea are cross-linked only due to formation of γ-γ dimers, which can dissociate into single-stranded structure when the concentration of urea increases. This fact proves that γ-γ dimers are formed in the end-to-end manner.

Ozone-induced oxidative modification of fibrinogen molecules.

Ozone-induced oxidation of fibrinogen has been investigated. The conversion of oxidized fibrinogen to fibrin catalyzed either by thrombin or by a reptilase-like enzyme, ancistron, in both cases is accompanied by production of gels characterized by a higher weight/length ratio of fibrils in comparison with the native fibrin gels. IR spectra of the D and E fragments isolated from unoxidized and oxidized fibrinogen suggest a noticeable transformation of functional groups by oxidation. A decrease in content of N-H groups in the peptide backbone and in the number of C-H bonds in aromatic structures, as well as a decrease in the intensity of the C-H valence vibrations in aliphatic fragments CH2 and CH3 were found. The appearance in the differential spectra of the D fragments of rather intense peaks in the interval of 1200-800 cm(-1) clearly indicates the interaction of ozone with amino acid residues of methionine, tryptophan, histidine, and phenylalanine. Comparison of the differential spectra for the D and E fragments suggests that fibrinogen fragment D is more sensitive to the oxidant action than fragment E. Using EPR spectroscopy, differences are found in the spectra of spin labels bound with degradation products of oxidized and unoxidized fibrinogen, the D and E fragments, caused by structural and dynamical modifications of the protein molecules in the areas of localization of the spin labels. The relationship between the molecular mechanism of oxidation of fibrinogen and its three-dimensional structure is discussed.