[Streptokinase and Staphylokinase: Differences in the Kinetics and Mechanism of Their Interaction with Plasminogen, Inhibitors and Fibrin].

Comparative in vitro study of the kinetics of various reactions involved in the process of thrombolysis initiated by streptokinase (SK) and staphylokinase (STA) was carried out. It was shown that at the interaction of an equimolar ratio of plasminogen (Pg) with SK or STA the rate of formation and the specific esterase activity of the complex plasmin (Pm) · SK are higher than those of the complex Pm · STA. The catalytic efficiency (kcat/Km) of hydrolysis of the chromogenic plasmin substrates by Pm · SK complex was 2 times higher than by Pm · STA complex. In the absence of fibrin catalytic efficiency (kPg/K(Pg)) of activation of Glu-plasminogen and Lys-plasminogen glycoform II by Pm · SK complex was higher than by Pm · STA complex, but the pres- ence of fibrin increased kPg/K(Pg)) activation of both plasminogens by Pm · STA complex significantly stronger than by Pm · SK complex due to the decrease in K(Pg)). In contrast to STA (15.5 kDa), SK molecule (47 kDa) creates significant steric hindrances for the interaction of plasmin in Pm · SK complex with protein inhibi- tors. In addition, SK caused greater fibrinogen degradation than STA. It is shown that Pm · SK and Pm · STA complexes lyse fibrin clots in buffer with similar rates, while the rate of lysis of plasma clots, immersed in plas- ma, by Pm · STA complex are significantly higher than those by Pm · SK complex. It was revealed that the species specificity of STA and S K is determined mainly by the rate of formation and the efficiency of Pm · SK and Pm · STA complexes in the activation of autologous plasminogen. The lysis efficiency of plasma clots of mammals fell in the series: human > dog > rabbit for SK and the dog > human > rabbit for STA. The results show that in the purified system SK is a more effective activator of plasminogen than STA. In the system con- taining fibrin and α2-AP, the activator and fibrinolytic activities of STA are higher than those of SK, due to the increased stability in plasma and fibrin specificity of STA, the fast reaction of the complex Pm · STA with α2AP and the ability of the STA to recyclization in the presence of α2AP.

Inhibitory effect of angiostatins on activity of the plasminogen/plasminogen activator system.

Angiostatins, kringle-containing fragments of plasminogen, are potent inhibitors of angiogenesis. Effects of three angiostatin forms, K1-3, K1-4, and K1-4.5 (0-2 microM), on the rate of native Glu-plasminogen activation by its physiological activators in the absence or presence of soluble fibrin were investigated in vitro. Angiostatins did not affect the intrinsic amidolytic activities of plasmin and plasminogen activators of tissue type (tPA) and urokinase type (single-chain scuPA and two-chain tcuPA), but inhibited conversion of plasminogen to plasmin in a dose-dependent manner. All three angiostatins suppressed Glu-plasminogen activation by tcuPA independently of the presence of fibrin, and the inhibitory effect increased in the order: K1-3 < K1-4 < K1-4.5. The inhibitory effects of angiostatins on the scuPA activator activity were lower and further decreased in the presence of fibrin. Angiostatin K1-3 (up to 2 microM) had no effect, while 2 microM angiostatins K1-4 and K1-4.5 inhibited the fibrin-stimulated Glu-plasminogen activation by tPA by 50 and 100%, respectively. The difference in effects of the three angiostatins on the Glu-plasminogen activation by scuPA, tcuPA, and tPA in the absence or presence of fibrin is due to the differences in angiostatin structures, mechanisms of action, and fibrin-specificity of plasminogen activators, as well as due to the influence of fibrin on the Glu-plasminogen conformation. Angiostatins in vivo, which mimic plasminogen-binding activity, can inhibit plasminogen activation stimulated by various proteins (including fibrin) of extracellular matrix, thereby blocking cell migration and angiogenesis. The data of this work indicate that the inhibition of Glu-plasminogen activation under the action of physiological plasminogen activators by angiostatins can be implicated in the complex mechanism of their antiangiogenic and antitumor action.

The Development and Study of Recombinant Immunoglobulin A to Hemagglutinins of the Influenza Virus.

We obtained recombinant variants of human antibody FI6 broadly specific to hemagglutinins of the influenza A virus. On the basis of a bi-promoter (CMV, hEF1-HTLV) vector, we developed genetic constructs for the expression of the heavy and light chains of the immunoglobulins of IgA1-, IgA2m1-, and IgG-isotypes. Following transfection and selection, stable Chinese hamster ovary (CHO) cell lines were produced. The antibodies of IgA1-, IgA2m1-, and IgG-isotypes were purified from culture media. We performed an immunochemical characterization and studied their interactions with influenza A strains of the H1N1- and H3N2-subtypes. It was shown that recombinant FI6 variants of the IgA-isotype retain the properties of the parental IgG antibody to demonstrate specificity to all the strains tested. The strongest binding was observed for the H1N1 subtype, which belongs to hemagglutinins of phylogenetic group I.

Denaturation and partial renaturation of a tightly tetramerized DsRed protein under mildly acidic conditions.

The red fluorescent protein, DsRed, recently cloned from coral Discosoma sp. has one of the longest fluorescence waves and one of the most complex absorbance spectra among the family of fluorescent proteins. In this work we found that with time DsRed fluorescence decreases under mildly acidic conditions (pH 4.0-4.8) in a pH-dependent manner, and this fluorescence inactivation could be partially recovered by subsequent re-alkalization. The DsRed absorbance and circular dichroism spectra under these conditions revealed that the fluorescence changes were caused by denaturation followed by partial renaturation of the protein. Further, analytical ultracentrifugation determined that native DsRed formed a tight tetramer under various native conditions. Quantitative analysis of the data showed that several distinct states of protein exist during the fluorescence inactivation and recovery, and the inactivation of fluorescence can be caused by protonation of a single ionogenic group in each monomer of DsRed tetramer.

Prostaglandin E2 biphasic control of lymphocyte proliferation: inhibition by picomolar concentrations.

Prostaglandins (PGs) have an important physiological role in the modulation of various cell immune functions. The main sources of PGs during immune responses are monocyte cells. We report here the ability of non-stimulated macrophages to synthesize prostanoids and show that peritoneal mouse macrophages synthesize PGE2, PGF2a and thromboxane B2, spleen macrophages produce PGE2 and PGF2a, and in a fresh medium this synthesis reaches a constant basal level in a few hours. We studied the kinetics of Con A-induced proliferation of murine splenocytes under the influence of a wide range of PGE2 concentrations (10(-14)-10(-7) M). The suppressive effect of PGE2 decreased when its concentration was lowered and disappeared at 10(-9) M PGE2 (this concentration corresponded to the basal level of non-stimulated macrophage synthesis of PGE2). Further lowering of the concentration became essential for the proliferation process once again, and at picomolar concentrations PGE2 caused a suppressive effect comparable with that for 10(-8) M PGE2. We also found that PGE2 significantly inhibited cell proliferation when it was added 1 h before the addition of mitogen, as compared with simultaneous mitogen addition. The effect was obtained for both low (10(-12) M) and high (10(-8) M) PGE2 concentrations. This phenomenon of PGE2 biphasic control of lymphocyte proliferation may play an important role in cellular homeostasis, in particular in immune cell function regulation.

Deoxyribonuclease treatment improves the homogeneity of single-stranded DNA preparations.

The isolation of single-stranded (ss) phagemid DNA using standard protocols often results in impure preparations, which contain undesirable quantities of chromosomal and/or double-stranded (ds) phagemid DNA. Here we report a simple and efficient method for elimination of virtually all dsDNA by incubation of phagemid viral particles with deoxyribonuclease I. In addition to analyzing the ratio of linear-to-circular topological forms of ssDNA after deoxyribonuclease I treatment, we verified that no decrease in transformation efficiency occurred and demonstrated that ssDNA molecules covered by capsid proteins remained intact following such treatment.

Morphine effect on proliferation of normal and tumor cells of immune origin.

The influence of morphine on proliferation of human tumor K562 and lymphoid cells was studied and compared with that on the mitogen-induced proliferation of human peripheral blood mononuclear cells (PBMC). Morphine was shown to act as a suppressor of both cellular DNA synthesis (50% and more as compared to control) and the cellular population growth of mitogen-induced PBMC, B-lymphoma Namalva cells and EBV-transformed lymphocytes. Morphine activated proliferation of myeloid K562 and T-lymphoma Yurkat cells 1.5-fold. It is supposed that the opposite effects of morphine on proliferation of cell lines of immune origin reveal the difference in modulation of diverse immune cell types by morphine.

The development of a new biosensor based on recombinant E. coli for the direct detection of organophosphorus neurotoxins.

A new biosensor for the direct detection of organophosphorus (OP) neurotoxins has been developed utilizing cryoimmobilized, recombinant E. coli cells capable of hydrolyzing a wide spectrum of OP pesticides and chemical warfare agents. The biological transducer was provided by the enzymatic hydrolysis of OP neurotoxins by organophosphate hydrolase which generates two protons through a reaction in which P-O, P-F, P-S or P-CN bonds are cleaved, and the proton release corresponded with the quantity of organophosphate hydrolyzed. This stoichiometric relationship permitted the creation of a potentiometric biosensor for detection of OP neurotoxins and a pH-based assay was developed as a direct function of the concentration of OP neurotoxins and the immobilized biomass. In these studies utilizing paraoxon as the substrate, neurotoxin concentration was determined with two different types of measuring units containing immobilized cells: (1) a stirred batch reactor; and (2) a flow-through column minireactor. A pH glass electrode was used as the physical transducer. The linear detection range for paraoxon spanned a concentration range of 0.25-250 ppm (0.001-1.0 mM). The response times were 10 min for the batch reactors and 20 min for the flow-through systems. It was possible to use the same biocatalyst repetitively for 25 analyses with a 10 min intermediate washing of the biocatalyst required for reestablishing the starting conditions. The cryoimmobilized E. coli cells exhibited stable hydrolytic activity for over 2 months under storage in 50 mM potassiumphosphate buffer at +4 degrees C and provide the potential for the development of a stable biotransducer for detecting various OP neurotoxins.

Bioelectrocatalysis: the electrochemical kinetics of hydrogenase action.

A hydrogen electrode based on a hydrogenase immobilized on a carbon material has been developed. The equilibrium hydrogen potential was reached in an atmosphere of H2 on the enzyme electrode according to the mechanism of direct exchange of electrons between the electrode and the enzyme active center. The electrochemical kinetics of the hydrogen enzyme electrode action is presented.

Kinetics of merthiolate-induced aggregation of human platelets.

Incubation of human platelet-rich plasma (PRP) or washed platelets with merthiolate (MT; sodium ethylmercurithiosalicylate; an inhibitor of lysophosphatide: arachidonoyl transferase) leads to irreversible platelet aggregation which is parallelled by an increase in thromboxane A2 synthesis. MT-induced aggregation is preceded by a pronounced lag-period (0.5-10 min). Duration of the latter is inversely related to the concentration of MT ([MT]). Platelet responses to MT are similar to those triggered by arachidonate (AA) in that the relationships of the aggregation rates both to [MT] and [AA] are threshold and exhibit characteristic super-high values of the apparent Hill coefficients (h > 30). A typical MT-induced response can be subdivided in two sequential phases: i) cyclooxygenase-independent slow aggregation, and ii) indomethacin-abrogated rapid aggregation. MT-induced responses are blocked by PGE1 or ajoene (which inhibits binding of fibrinogen to its cell surface receptor, GPIIb/IIIa). The obtained data are interpreted both quantitatively and qualitatively in terms of a model assuming the existence of: i) a relationship between the rate of MT-inhibitable AA incorporation into phospholipids and the concentration of intracellular free AA, [AA]i; ii) a certain threshold value of [AA]i essential for triggering the second phase of the aggregation.

Cell response kinetics: the phenomenon of supercooperativity in aggregation of human platelets.

Concentration-response relationships of human platelet aggregation rates were analyzed for a variety of agonists and inhibitors. Their approximation by the Hill equation showed that the values of the Hill coefficient (h) were agonist-dependent and increased as follows: hADP = hL-EPINEPHRINE = hPAF = hPGH2 = hU46619 less than hPMA less than hA23187 less than hMERTHIOLATE = hARACHIDONATE. The results were interpreted in terms of a model assuming varying degrees of cooperativity for each step of signal transduction involved in platelet aggregation. Super-high values of h (greater than 30) obtained with arachidonate and merthiolate, as well as in the case of inhibition of an arachidonate-induced response by indomethacin and PTA2, suggested that at least one region of signal transduction pathway leading to aggregation exhibited supercooperative properties.

Low concentrations of nonsteroidal anti-inflammatory drugs affect cell functions.

The effect of 10(-14)-10(-4)M ibuprofen and aspirin both on arachidonic acid metabolism in peritoneal murine macrophages and on the concanavalin A-induced proliferation of murine splenocytes were investigated. It was shown that 10(-7)-10(-4)M ibuprofen inhibits the arachidonic acid metabolism. On the other hand, 10(-12)-10(-11)M ibuprofen causes pronounced activation of arachidonic acid metabolism. The low concentration (10(-14)-10(-10)M) effects also take place when non-steroidal anti-inflammatory drugs influence other functions of the immune system: that is, they activate the splenocyte mitogen-induced proliferative response. These results are in accord with our suggestion that the low concentration effects of these drugs do not depend upon cell types and may have an important physiological significance.

Direct and electrically wired bioelectrocatalysis by hydrogenase from Thiocapsa roseopersicina.

Hydrogen enzyme electrodes based on direct and mediated bioelectrocatalysis were developed. Direct bioelectrocatalysis of hydrogen oxidation/evolution was observed for hydrogenase adsorbed on carbon filament material. The equilibrium hydrogen potential was achieved on mediatorless hydrogen enzyme electrodes in hydrogen atmosphere. The electrocatalytic activity of hydrogenase in direct bioelectrocatalysis of hydrogen oxidation was two orders of magnitude higher compared to platinum. The reported electrode remained 50% activity after 6 months of storage with periodical testing. Wired bioelectrocatalysis was achieved by adsorption of hydrogenase onto electropolymerized redox mediator N-methyl-N'-(12-pyrrol-1-yl-dodecyl)-4,4'-bipyridinium ditetrafluoroborate.

Enzyme activity regulation by an outer physical signal.

The main principles and methods of creating artificial systems with the directional regulation of enzyme activity by an outer physical signal are discussed. We are presenting some experimental results for the systems working in the necessary regime and responding to light and temperature.

Kinetics of the dual-action mechanism of narcotic substances: conditions for conservative functioning of enzyme-receptor systems.

We have studied the kinetics of the conservative behavior of systems which are subject to the dual action of an external effector or a negative feedback. Conditions have been found under which the dual-action mechanism produces conservative behavior. Negative feedback alone was shown not to produce the conservative behavior of an enzyme-receptor system.

Kinetic behavior of a receptor-enzyme system: a model for drug addiction.

A theoretical kinetic model describing the behavior of a receptor-enzyme system during formation of drug addiction is considered in this article. The model assumes concomitant action of narcotic on at least two targets with opposite effects. Theoretical kinetic principles that the system must satisfy for the development of drug addiction are formulated. These kinetic principles are the slow inactivation of receptor-enzyme system and the divergence of characteristic times of dynamic concentration of product and enzyme.

Enzyme self-inactivation is a main limitation of the preparation of eicosanoids. Enzymatic synthesis of thromboxane and 12(S)-hydroxytetraenoic acid.

Synthesis of prostanoids is accompanied by various processes reducing the product yield. These processes are also known to affect syntheses of thromboxane (TX) and 12(S)-hydroxy-5(Z),8(Z),10(E),14(Z)-eicosatetraenoic acid (12-HETE). Partially purified preparations of TX synthase and prostaglandin (PG) synthase were used to optimize TX synthesis with respect to concentrations of the enzymes and eicosapolyenoic acid (EPA). Conditions for the maximum product yield and the minimum consumption of enzymes were determined. Consumption of the TX synthase was large owing to its inactivation during the reaction and the nonenzymatic destruction of the intermediate product PG-endoperoxide. Separate addition of PG and TX synthases increased the product yield by preventing EPA sorption on ballast proteins. Microsomal 12-lipoxygenase (12-LO) was also shown to be inactivated during the reaction, and this process was the major limitation of 12-HETE synthesis. Lipoxygenase reaction in the presence of some reducing agents led to a considerable increase of the 12-HETE yield, supposedly by preventing further oxidation of the 12-LO reaction product 12-hydroperoxy derivative of eicosatetraenoic acid. The possibility of using human blood platelet microsomes for preparation of some derivatives of EPAs is discussed.

Purification and properties of Clostridium thermocellum endoglucanase 5 produced in Escherichia coli.

Endoglucanase 5 (EG5) has been isolated from the strain of E. coli TG1 harboring recombinant plasmid pCU108, which contains the cel5 gene of C. thermocellum. The enzyme has been produced with 98-fold purification and a final yield of 27% by using subsequent twofold high performance ion-exchange chromatography on Mono Q and high performance chromatofocusing on Mono P. The protein has a mol mass of 35 kDa and includes 3 multiple forms with pI 4.4-4.8 as evidenced by analytical gel isoelectrofocusing. EG5 cleaves CMC (Km = 0.097 g/L, Vmax = 8.2 mg/min.mg of protein), amorphous cellulose, xylan, lichenan as a substrate with an optimum temperature of 80 degrees C and pH 6.0 and Avicel (Km = 18.2 g/L, Vmax = 0.035 mg/min.mg of protein) with an optimum temperature of 60 degrees C and pH 6.0. Cellobiose in concentrations up to 200 micrograms/mL do not inhibit the hydrolysis of CMC by EG5, but 10-30 micrograms/mL of glucose significantly decrease the activity of this enzyme. The stimulating role of calcium chloride and concentration of protein in the system has been demonstrated for Avicel hydrolysis by EG5.

Kinetic investigation and mathematical modeling of methanogenesis of glucose.

The kinetic regularities of anaerobic conversion of glucose, and intermediates of its decomposition (ethanol, butyrate, and acetate) by a microbial methanogenic association from anaerobic digester were investigated. Kinetic scheme for conversion of glucose is suggested, and the mathematical model based on the scheme is evolved. The model includes growth and metabolism of three kinds of microorganisms--acid producents, and acetate- and hydrogen-utilizing methane producents; of cell lysis with consequent fermentation of "died biomass" to acetate, hydrogen, and carbon dioxide; of induction and repression of the enzyme responsible for decomposition of butyrate, and for a number of regulations depending on the concentrations of intermediates in glucose metabolism. The values of parameters of the model have been calculated, sufficiently describing the experimental regularities. The numerical experiments have enabled us to reveal and describe the principal regulating factors of glucose methanogenesis.

Kinetics of growth and metabolism of Clostridium thermosaccharolyticum culture. Isolation and characteristics of its plasmids.

The kinetics of growth and metabolism of Clostridium thermosaccharolyticum DSM 571 has been studied at varying initial pH and glucose concentration. A weak inhibitory effect of excess glucose on the specific growth rate has been shown. The effect of antibiotics of various classes on culture growth and hydrogen evolution has been studied. Streptomycin and kanamycin resistance of this culture has been revealed as well as the phenomenon of increased hydrogen production in the presence of the above antibiotics. New plasmids, pNB1 (4.9 kb) and pNB2 (2.0 kb), were isolated from C. thermosaccharolyticum DSM 571. The restriction analysis of pNB1 and pNB2 has been performed.