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Article Addendum
New insights into the therapeutic inhibition of voltage-gated sodium channels
Christopher Ahern, Amy Eastwood, Dennis Dougherty and Richard Horn
volume 2 | issue 1
January/February 2008Subscribe to this journal for $79/year
Antiarrhythmics, anticonvulsants and local anesthetics inhibit voltage gated sodium channels and reduce membrane excitability in neurons and muscle, making them useful in the management of cardiac arrhythmias, epilepsy and pain. These compounds, which are often termed singly in the literature as ‘local anesthetics’, have at least two inhibitory states: a resting inhibition that develops with intermittent stimulation and a higher affinity inhibition that arises upon repeated depolarization and likely involves the inactivated state of the channel. Although elucidating their mechanism of inhibition has been an active area of research for decades, many questions remain unanswered. Do these two inhibitory states share a common, but guarded or modulated receptor? Or do they represent different protonated states of the drugs, many of which have pKa’s close to physiological pH, thereby yielding a significant population of both charged and uncharged compound inside cells. Some mechanistic clues can be found by mutating conserved phenylalanine and tyrosine residues of the ‘local anesthetic receptor’ in the channel’s inner vestibule. Mutations of these aromatic residues universally disrupt the mechanism of drug inhibition in numerous channel isoforms. For instance, non aromatic substitutions of Phe1579 (NaV1.4 numbering) in the pore lining S6 segment of domain four (DIVS6) can abolish inactivated state inhibition.1,2 The strict conservation of Phe1579 and other DIVS6 aromatic residues in all nine sodium channel isoforms led us to further dissect the role of this and other aromatic residues on local anesthetic inhibition. We recently employed subtly modified phenylalanine derivatives to better understand the role of these aromatics in the binding of local anesthetics and found a significant electrostatic interaction at one site, Phe1579, contributes to channel inhibition.3 What follows is a self guided tour of our motivation and experimental findings.
Authors
Christopher Ahern
University of British Columbia
Amy Eastwood
California Institute of Technology
Dennis Dougherty
California Institute of Technology
Richard Horn
Jefferson Medical College