ATP concentration regulates enzyme kinetics

TL;DR

This paper investigates how ATP concentration influences enzyme kinetics and cellular signaling, revealing that ATP levels affect response duration, amplification, and ultrasensitivity in the MAP kinase cascade, especially under stress conditions.

Contribution

It introduces a model considering ATP as a secondary substrate, highlighting its regulatory role in enzyme reactions and cellular signaling pathways.

Findings

ATP concentration affects response duration in signaling

Signal amplification depends on ATP levels

Ultrasensitivity to stimuli is modulated by ATP concentration

Abstract

Adenosine 5'-triphosphate (ATP) is the nearly ubiquitous "energy currency" of living organisms, and thus is a crucial participant in the majority of enzymatic reactions. The standard models in enzyme kinetics generally ignore the temporal dynamics of ATP because it is assumed to be present in large excess. However, this assumption may not hold in many situations of cellular stress where ATP concentrations may be comparable to substrate levels. Here, we demonstrate the importance of ATP concentration on the dynamics of multi-enzyme reactions by explicit consideration of ATP as a secondary substrate for an enzyme. We apply our model to the mitogen-activated protein (MAP) kinase cascade, which is involved in the regulation of a vast range of cellular activities. We show that three fundamental features of this signaling network --- (i) duration of response, (ii) signal amplification, and (iii) ultrasensitivity to stimulus concentration --- are all dependent on ATP concentration. Our results indicate that the concentration of ATP regulates the response of the MAP kinase activation network, and potentially suggests another possible mechanism for disruption of the cascade in pathogenic states.