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Modeling control and transduction of electrochemical gradients in acid-stressed bacteria

Marcus Benyamin, Matthew P. Perisin, Caleb A. Hellman, Nathan D. Schwalm, Justin P. Jahnke, Christian Sund

2023iScience11 citationsDOIOpen Access PDF

Abstract

Transmembrane electrochemical gradients drive solute uptake and constitute a substantial fraction of the cellular energy pool in bacteria. These gradients act not only as "homeostatic contributors," but also play a dynamic and keystone role in several bacterial functions, including sensing, stress response, and metabolism. At the system level, multiple gradients interact with ion transporters and bacterial behavior in a complex, rapid, and emergent manner; consequently, experiments alone cannot untangle their interdependencies. Electrochemical gradient modeling provides a general framework to understand these interactions and their underlying mechanisms. We quantify the generation, maintenance, and interactions of electrical, proton, and potassium potential gradients under lactic acid-stress and lactic acid fermentation. Further, we elucidate a gradient-mediated mechanism for intracellular pH sensing and stress response. We demonstrate that this gradient model can yield insights on the energetic limitations of membrane transport, and can predict bacterial behavior across changing environments.

Topics & Concepts

Electrochemical gradientBiophysicsLactic acidChemistryIon transporterMicrobial metabolismBacteriaAntiporterBiochemistryBiological systemBiologyMembraneGeneticsMicrobial Fuel Cells and BioremediationBacterial Genetics and BiotechnologyATP Synthase and ATPases Research
Modeling control and transduction of electrochemical gradients in acid-stressed bacteria | Litcius