Bacterial Outer Membrane Porins as Electrostatic Nanosieves: Exploring Transport Rules of Small Polar Molecules

Bacterial Outer Membrane Porins as Electrostatic Nanosieves: Exploring Transport Rules of Small Polar Molecules

Transport of molecules through biological membranes is a fundamental process in biology, facilitated by selective channels and general pores. The architecture of some outer membrane pores in Gram-negative bacteria, common to other eukaryotic pores, suggests them as prototypes of electrostatically re...

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Bibliographic Details
Published in:ACS nano Vol. 11; no. 6; pp. 5465 - 5473
Main Authors: Bajaj, Harsha, Acosta Gutierrez, Silvia, Bodrenko, Igor, Malloci, Giuliano, Scorciapino, Mariano Andrea, Winterhalter, Mathias, Ceccarelli, Matteo
Format: Journal Article
Language:English
Published: United States American Chemical Society 27-06-2017
Subjects:
electric field
porins
transport
Gram-negative bacteria
antibiotics
single-molecule electrophysiology
molecular simulations
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Summary:Transport of molecules through biological membranes is a fundamental process in biology, facilitated by selective channels and general pores. The architecture of some outer membrane pores in Gram-negative bacteria, common to other eukaryotic pores, suggests them as prototypes of electrostatically regulated nanosieve devices. In this study, we sensed the internal electrostatics of the two most abundant outer membrane channels of Escherichia coli, using norfloxacin as a dipolar probe in single molecule electrophysiology. The voltage dependence of the association rate constant of norfloxacin interacting with these nanochannels follows an exponential trend, unexpected for neutral molecules. We combined electrophysiology, channel mutagenesis, and enhanced sampling molecular dynamics simulations to explain this molecular mechanism. Voltage and temperature dependent ion current measurements allowed us to quantify the transversal electric field inside the channel as well as the distance where the applied potential drops. Finally, we proposed a general model for transport of polar molecules through these electrostatic nanosieves. Our model helps to further understand the basis for permeability in Gram-negative pathogens, contributing to fill in the innovation gap that has limited the discovery of effective antibiotics in the last 20 years.
ISSN:1936-0851
1936-086X
DOI:10.1021/acsnano.6b08613