Enzyme chemistry of dithiohemiacetals: synthesis and characterization of S-D-dithiomandeloylglutathione as an alternate substrate for glyoxalase I.

Both the D- and L-forms of S-dithiomandeloylglutathione (1) have been synthesized by a dithioester-interchange reaction between GSH and S-carboxy-methyl(D,L)-dithiomandelate. Kinetic and product analysis studies indicate that yeast glyoxalase I efficiently catalyzes the stereoselective conversion of D-1 to GSH-phenylglyoxal dithiohemiacetal (2), isolated as a disulfide adduct between 2 and a second molecule of GSH. This observation suggests that dithioester substrate analogues should be generally useful as mechanistic probes of enzyme catalyzed reactions involving thiohemiacetal intermediates.

Diffusion-dependent rates for the hydrolysis reaction catalyzed by glyoxalase II from rat erythrocytes.

Glyoxalase II from rat erythrocytes is a near optimal catalyst for the hydrolysis of S-D-lactoylglutathione in the sense that the magnitude of kcat/Km is limited, in large part, by the rate constant for diffusion-controlled encounter between substrate and active site. The experimental basis for this conclusion is derived from the dependencies of the kinetic properties of the enzyme on solution viscosity (pH 7, Ic = 0.1 M, 25 degrees C). When sucrose is used as a viscogenic agent, kcat/Km for S-D-lactoylglutathione (8.8 x 10(5) M-1 s-1) decreases markedly with increasing solution viscosity. This effect appears not to be due to a sucrose-induced change in the intrinsic kinetic properties of the enzyme, since kcat/Km for the slow substrate S-acetylglutathione (3.7 x 10(4) M-1 s-1) is nearly independent of solution viscosity. Quantitative treatment of the data using Stoke's law indicates that the rate of hydrolysis of S-D-lactoylglutathione will be approximately 50% diffusion limited when [substrate] much less than Km; the encounter complex between enzyme and substrate partitions nearly equally between product formation and dissociation to form free enzyme and substrate. The same conclusion is reached when glycerol is used as a viscogenic agent, once the apparent activation effect of glycerol on the intrinsic activity of the enzyme is taken into account. Finally, the rate of formation of the encounter complex between substrate and active site may be governed to a significant extent by charge-charge interactions.(ABSTRACT TRUNCATED AT 250 WORDS)

Optimization of efficiency in the glyoxalase pathway.

A quantitative kinetic model for the glutathione-dependent conversion of methylglyoxal to D-lactate in mammalian erythrocytes has been formulated, on the basis of the measured or calculated rate and equilibrium constants associated with (a) the hydration of methylglyoxal, (b) the specific base catalyzed formation of glutathione-(R,S)-methylglyoxal thiohemiacetals, (c) the glyoxalase I catalyzed conversion of the diastereotopic thiohemiacetals to (S)-D-lactoylglutathione, and (d) the glyoxalase II catalyzed hydrolysis of (S)-D-lactoylglutathione to form D-lactate and glutathione. The model exhibits the following properties under conditions where substrate concentrations are small in comparison to the Km values for the glyoxalase enzymes: The overall rate of conversion of methylglyoxal to D-lactate is primarily limited by the rate of formation of the diastereotopic thiohemiacetals. The hydration of methylglyoxal is kinetically unimportant, since the apparent rate constant for hydration is (approximately 500-10(3))-fold smaller than that for formation of the thiohemiacetals. The rate of conversion of methylglyoxal to (S)-D-lactoylglutathione is near optimal, on the basis that the apparent rate constant for the glyoxalase I reaction (kcatEt/Km congruent to 4-20 s-1 for pig, rat, and human erythrocytes) is roughly equal to the apparent rate constant for decomposition of the thiohemiacetals to form glutathione and methylglyoxal [k(obsd) = 11 s-1, pH 7]. The capacity of glyoxalase I to use both diastereotopic thiohemiacetals, versus only one of the diastereomers, as substrates represents a 3- to 6-fold advantage in the steady-state rate of conversion of the diastereomers to (S)-D-lactoylglutathione.(ABSTRACT TRUNCATED AT 250 WORDS)

Purification and characterization of an acidic trypsin/subtilisin inhibitor from tortoise egg white.

Egg whites of three species of tortoise and turtle have been compared by gel chromatography for inhibitory activity against proteases. The egg white of Geomyda trijuga trijuga Schariggar contains trypsin/subtilisin inhibitor while the egg white of Caretta caretta Linn. contains both trypsin and chymotrypsin inhibitors. No protease inhibitory activity has been detected in the egg white of Trionyx gangeticus Cuvier. An acidic trypsin/subtilisin inhibitor has been purified to homogeneity from the egg white of tortoise (G. trijuga trijuga). It is a single polypeptide chain of 100 amino acid residues, having a molecular weight of 11,700. It contains six disulphide bonds and is devoid of methionine and carbohydrate moiety. Its isoelectric point is at pH 5.95 and is stable at 100 degrees C for 4 hr at neutral pH. The inhibitor inhibits both trypsin and subtilisin by forming enzyme-inhibitor complexes at a molar ratio close to unity. Their dissociation constants are 7.2 x 10(-9) M for bovine trypsin and 5.5 x 10(-7) M for subtilisin. Chemical modification of amino groups with trinitrobenzene sulfonate has reduced its inhibitory activities against both trypsin and subtilisin, but the loss of its trypsin inhibitory activity is faster than that of its subtilisin inhibitory activity. It has independent binding sites for inhibition of trypsin and subtilisin.