Optimal enzyme utilization suggests concentrations and thermodynamics favor condition-specific saturations and binding mechanisms

Abstract

AbstractUnderstanding the dynamic responses of living cells upon genetic and environmental perturbations is crucial to decipher the metabolic functions of organisms. The rates of enzymatic reactions and their evolution are key to this understanding, as metabolic fluxes are limited by enzymatic activity. In this work, we investigate the optimal modes of operations for enzymes with regard that the evolutionary pressure drives enzyme kinetics toward increased catalytic efficiency. We use an efficient mixed-integer formulation to decipher the principles of optimal catalytic properties at various operating points. Our framework allows assessing the distribution of the thermodynamic forces and enzyme states, providing detailed insight into the mode of operation. Our results confirm earlier theoretical studies on the optimal kinetic design using a reversible Michaelis-Menten mechanism. The results further explored the optimal modes of operation for random-ordered multi-substrate mechanisms. We show that optimal enzyme utilization is achieved by unique or alternative modes of operations depending on the reactant’s concentrations. Our novel formulation allows investigating the optimal catalytic properties of all enzyme mechanisms with known elementary reactions. We propose that our novel framework provides the means to guide and evaluate directed evolution studies and estimate the limits of the direct evolution of enzymes.