Field-Dependent Effect of Crown Ether (18-Crown-6) on Ionic Conductance of α-Hemolysin Channels

Closing linear poly(ethylene glycol) (PEG) into a circular “crown” dramatically changes its dynamics in the α-hemolysin channel. In the electrically neutral crown ether (C 2H 4O) 6, six ethylene oxide monomers are linked into a circle that gives the molecule ion-complexing capacity and increases its...

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Bibliographic Details
Published in:Biophysical journal 2004-11, Vol.87 (5), p.3162-3171
Main Authors: Bezrukov, Sergey M., Krasilnikov, Oleg V., Yuldasheva, Liliya N., Berezhkovskii, Alexander M., Rodrigues, Claudio G.
Format: Article
Language:English
Subjects:
Channels, Receptors, and Electrical Signaling
Computer Simulation
Crown Ethers - chemistry
Dose-Response Relationship, Drug
Electric Conductivity
Electromagnetic Fields
Escherichia coli Proteins - chemistry
Escherichia coli Proteins - drug effects
Escherichia coli Proteins - radiation effects
Hemolysin Proteins - chemistry
Hemolysin Proteins - drug effects
Hemolysin Proteins - radiation effects
Ion Channel Gating - drug effects
Ion Channel Gating - radiation effects
Ions
Kinetics
Lipid Bilayers - chemistry
Lipid Bilayers - radiation effects
Membrane Potentials - drug effects
Membrane Potentials - radiation effects
Membranes, Artificial
Models, Chemical
Models, Molecular
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Summary:Closing linear poly(ethylene glycol) (PEG) into a circular “crown” dramatically changes its dynamics in the α-hemolysin channel. In the electrically neutral crown ether (C 2H 4O) 6, six ethylene oxide monomers are linked into a circle that gives the molecule ion-complexing capacity and increases its rigidity. As with linear PEG, addition of the crown to the membrane-bathing solution decreases the ionic conductance of the channel and generates additional conductance noise. However, in contrast to linear PEG, both the conductance reduction (reporting on crown partitioning into the channel pore) and the noise (reporting on crown dynamics in the pore) now depend on voltage strongly and nonmonotonically. Within the whole frequency range accessible in channel reconstitution experiments, the noise power spectrum is “white”, showing that crown exchange between the channel and the bulk solution is fast. Analyzing these data in the framework of a Markovian two-state model, we are able to characterize the process quantitatively. We show that the lifetime of the crown in the channel reaches its maximum (a few microseconds) at about the same voltage (∼100 mV, negative from the side of protein addition) where the crown's reduction of the channel conductance is most pronounced. Our interpretation is that, because of its rigidity, the crown feels an effective steric barrier in the narrowest part of the channel pore. This barrier together with crown-ion complexing and resultant interaction with the applied field leads to behavior usually associated with voltage-dependent binding in the channel pore.
ISSN:0006-3495
1542-0086
DOI:10.1529/biophysj.104.044453