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Electrochemical potential enables dormant spores to integrate environmental signals

Kaito Kikuchi, Leticia Galera-Laporta, Colleen Weatherwax, Jamie Y. Lam, Eun Chae Moon, Emmanuel A. Theodorakis, Jordi García‐Ojalvo, Gürol M. Süel

2022Science100 citationsDOIOpen Access PDF

Abstract

The dormant state of bacterial spores is generally thought to be devoid of biological activity. We show that despite continued dormancy, spores can integrate environmental signals over time through a preexisting electrochemical potential. Specifically, we studied thousands of individual Bacillus subtilis spores that remain dormant when exposed to transient nutrient pulses. Guided by a mathematical model of bacterial electrophysiology, we modulated the decision to exit dormancy by genetically and chemically targeting potassium ion flux. We confirmed that short nutrient pulses result in step-like changes in the electrochemical potential of persistent spores. During dormancy, spores thus gradually release their stored electrochemical potential to integrate extracellular information over time. These findings reveal a decision-making mechanism that operates in physiologically inactive cells.

Topics & Concepts

SporeDormancyBacillus subtilisEndosporeExtracellularBiologyBiophysicsBacteriaChemistryGerminationBotanyBiochemistryGeneticsPlant and Biological Electrophysiology StudiesBiofield Effects and BiophysicsOrigins and Evolution of Life
Electrochemical potential enables dormant spores to integrate environmental signals | Litcius