Conjugation of the Bowman-Birk soybean proteinase inhibitor with hydroxyethylstarch.

The classical Bowman-Birk soybean proteinase inhibitor was modified by hydroxyethylstarch. The modified inhibitor retained the capacity for simultaneous binding of trypsin and human leukocyte elastase. The inhibition constants, Ki, of bovine trypsin, alpha-chymotrypsin and human leukocyte elastase (HLE) increased not more than 10-, 1.5-, and 20-fold, respectively, on modification of the inhibitor. The less effective inhibition is presumably due to the steric hindrance brought about by the conjugation with polysaccharide molecules. The results obtained indicate the pronounced structure differences of the binding regions for trypsin and chymotrypsin/leukocyte elastase in the modified preparation.

[Aldose reductase: physiological role, properties and prospects for regulating activity]. / Al'dozoreduktaza: fiziologicheskaia rol', svoistva i vozmozhnosti reguliatsii aktivnosti.

Some properties of aldose reductase isolated from various sources and possible ways of regulation of the enzyme catalytic activity are reviewed. Mammalian aldose reductases are monomeric enzymes with M(r) of 30-40 kDa and a broad substrate specificity towards aldoses. The physiological role of this enzyme consists, apparently, in providing an additional pathway for utilization of glucose and removing toxic compounds carrying an aldehyde group from the cell. Aldose reductase is thought to play a key role in various hyperglycemic states, including diabetic cataract. The kinetics of the aldose reductase reaction is hyperbolic with NADPH and nonhyperbolic with glucose. The rate of the enzyme-catalyzed reaction is determined by the effector binding in the active of inhibitory center of the enzyme. Incubation with substrates leads to the activation of the enzyme which is accompanied by a decrease of the effector binding in the enzyme inhibitory center with a sharp decrease in the sensitivity of the activated enzyme to NADPH concentration changes in the presence of glucose excess. A mechanism underlying the catalytic effect of both native and activated forms of the enzyme is proposed.

[Regulation of aldose reductase activity. Mechanism of action of an activated form of the enzyme]. / Reguliatsiia aktivnosti al'dozoreductazy. Mekhanizm deistviia aktivirovannoi formy fermenta.

Activation of bovine eye lens aldose reductase during its incubation with NADPH and glucose was studied. The activated form of the enzyme was isolated, and the rate of glucose reduction measured within a broad range of substrate concentrations. Spectrophotometric titration and equilibrium gel-filtration were used to study the interaction of the enzyme active center with substrates. It was found that the reaction kinetics obeys the mechanism of a quasi-equilibrium binding of substrates with isomerization of the enzyme complexes with nicotinamide dinucleotide phosphates. This activation is accompanied by a transition from non-ordered to highly ordered binding of the substrates. The effect of ligands in the catalytic and inhibitory centers of the activated enzyme on the catalytic reaction was examined. It was found that the activated form of aldose reductase is characterized by a lower affinity of the inhibitory center for the flavonoid, morin. Morin binding not only inhibits the reaction but also prevents the activation of the enzyme.

[Regulation of aldose reductase activity. The influence of effectors on reverse isomerization of the enzyme]. / Reguliatsiia aktivnosti al'dozoreduktaz. Vliianie éffektorov na obratimuiu izomerizatsiiu fermenta.

The effects of ligands of active and inhibitory centers of homogeneous aldose reductase from cattle eye lens on glucose reduction were studied. Using spectrophotometric titration and equilibrium gel filtration, the interaction of the enzyme active center with substrates was investigated. It was shown that the reaction kinetics obeys a mechanism with a quasi-equilibrium non-ordered attachment of substrates and isomerization of enzyme complexes with nicotinamide dinucleotide phosphates in the course of the catalytic act. It was found that the NADPH in equilibrium NADP equilibrium in the enzyme active center is shifted to the right; however, NADP dissociation may occur only as a result of the aldehyde reduction. The mechanisms of regulation of the enzyme activity by NADP, ADP and alpha-glycerol phosphate were proposed. It was shown that the binding of catalin and morine to the enzyme results in the inhibition of the enzymatic reaction and in the isomerization blocking. It was found that the inhibitory site of the isomeric form of aldose reductase displays a lower affinity for morine.

[Regulation of crystalline lens aldose reductase activity. Nonhyperbolic oxidation kinetics of NADPH by glucose]. / Reguliatsiia aktivnosti al'dozoreduktazy khrustalika glaza. Negiperbolicheskaia kinetika okisleniia NADPH gliukozoi.

A homogeneous aldose reductase was isolated from bovine eye lens tissue by using affinity chromatography on blue agarose. A kinetic analysis of the initial rates of NADPH oxidation at 0.5-100 mM glucose and at 1.2-10 microM NADPH was carried out. The Line-weaver-Burk plots for glucose concentration were nonlinear at fixed concentrations of NADPH and linear at fixed concentrations of glucose. It was shown that the experimental plots reflect the mechanisms, in which substrate regulation of enzyme activity is effectuated by glucose binding to the regulatory site or is due to the shift of the equilibrium between the isomeric forms of aldose reductase.