In nature, biofilms are the most common form of bacterial growth. In biofilms, bacteria display coordinated behaviour to performspecific functions. Here,we investigated electrical signalling as a possible driver in biofilm sociobiology. Using a multi-electrode array system that enables high spatio-temporal resolution, we studied the electrical activity in two biofilm-forming strains and one non-biofilm-forming strain. The action potential rates monitored during biofilm- forming bacterial growth exhibited a one-peak maximum with a long tail, corresponding to the highest biofilm development. This peak was not observed for the non-biofilm-forming strain, demonstrating that the intensity of the electrical activity was not linearly related to the bacterial density, but was instead correlated with biofilm formation. Results obtained indicate that the analysis of the spatio-temporal electrical activity of bacteria during biofilm formation can open a new frontier in the study of the emergence of collective microbial behaviour.
Bacterial electrical spiking in biofilm sociobiology / Masi E.; Ciszak M.; Santopolo L.; Giovannetti L.; Viti C.; Mancuso S.. - ELETTRONICO. - (2013), pp. 1-1. (Intervento presentato al convegno IOP Physics and Emergent Behavior: From single cells to groups of individuals tenutosi a Brighton (UK) nel 24-26 June 2013).
Bacterial electrical spiking in biofilm sociobiology
MASI, ELISA;SANTOPOLO, LUISA;GIOVANNETTI, LUCIANA;VITI, CARLO;MANCUSO, STEFANO
2013
Abstract
In nature, biofilms are the most common form of bacterial growth. In biofilms, bacteria display coordinated behaviour to performspecific functions. Here,we investigated electrical signalling as a possible driver in biofilm sociobiology. Using a multi-electrode array system that enables high spatio-temporal resolution, we studied the electrical activity in two biofilm-forming strains and one non-biofilm-forming strain. The action potential rates monitored during biofilm- forming bacterial growth exhibited a one-peak maximum with a long tail, corresponding to the highest biofilm development. This peak was not observed for the non-biofilm-forming strain, demonstrating that the intensity of the electrical activity was not linearly related to the bacterial density, but was instead correlated with biofilm formation. Results obtained indicate that the analysis of the spatio-temporal electrical activity of bacteria during biofilm formation can open a new frontier in the study of the emergence of collective microbial behaviour.
I documenti in FLORE sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
