Kinetic involvement of acetaldehyde substrate inhibition on the rate equation of yeast aldehyde dehydrogenase.

In order to evaluate the effectiveness of aldehyde dehydrogenase (ALDH) from Saccharomyces cerevisiae as a catalyst for the conversion of acetaldehyde into its physiologically and biologically less toxic acetate, the kinetics over broad concentrations were studied to develop a suitable kinetic rate expression. Even with literature accounts of the binding complexations, the yeast ALDH currently lacks a quantitative kinetic rate expression accounting for simultaneous inhibition parameters under higher acetaldehyde concentrations. Both substrate acetaldehyde and product NADH were observed as individual sources of inhibition with the combined effect of a ternary complex of acetaldehyde and the coenzyme leading to experimental rates as little as an eighth of the expected activity. Furthermore, the onset and strength of inhibition from each component were directly affected by the concentration of the co-substrate NAD. While acetaldehyde inhibition of ALDH is initiated below concentrations of 0.05 mM in the presence of 0.5 mM NAD or less, the acetaldehyde inhibition onset shifts to 0.2 mM with as much as 1.6 mM NAD. The convenience of the statistical software package JMP allowed for effective determination of experimental kinetic constants and simplification to a suitable rate expression: v = Vmax(AB)/(K(ia)K(b) + K(b)A + K(a)B + AB + B(2)/K(I-Ald) + B(2)Q/K(I-Ald-NADH) + BQ/K(I-NADH)) where the last three terms represent the inhibition complex terms for acetaldehyde, acetaldehyde-NADH, and NADH, respectively. The corresponding values of K(I-Ald), K(I-Ald-NADH), and K(I-NADH) for yeast ALDH are 2.55, 0.0269, and 0.162 mM at 22 °C and pH 7.8.

Impact of high pyruvate concentration on kinetics of rabbit muscle lactate dehydrogenase.

In order to evaluate the effectiveness of L: -lactate dehydrogenase (LDH) from rabbit muscle as a regenerative catalyst of the biologically important cofactor nicotinamide adenine dinucleotide (NAD), the kinetics over broad concentrations were studied to develop a suitable kinetic rate expression. Despite robust literature describing the intricate complexations, the mammalian rabbit muscle LDH lacks a quantitative kinetic rate expression accounting for simultaneous inhibition parameters, specifically at high pyruvate concentrations. Product inhibition by L: -lactate was observed to reduce activity at concentrations greater than 25 mM, while expected substrate inhibition by pyruvate was significant above 4.3 mM concentration. The combined effect of ternary and binary complexes of pyruvate and the coenzymes led to experimental rates as little as a third of expected activity. The convenience of the statistical software package JMP allowed for effective determination of experimental kinetic constants and simplification to a suitable rate expression: [formula: see text] where the last three terms represent the inhibition complex terms for lactate, pyruvate, and pyruvate-NAD, respectively. The corresponding values of K (I-Lac), K (I-Pyr), and K (I-Pyr-NAD) for rabbit muscle LDH are 487.33 mM(-1) and 29.91 mM and 97.47 mM at 22 °C and pH 7.8.