Abstract

Voltage-gated ion channels shape electrical signals in excitable cells. There are now high-resolution structures of eukaryotic sodium, potassium and calcium channels, thus providing structural footprint to guide functional hypotheses. In the previous funding period we discovered a dynamic region the pore region of Shaker potassium channels which suggest that state-dependent hydrogen bonding controls the conduction conformation of the channel. These observations have recently been structurally and computationally validated. Further, computational studies indicate that the status of this H-bond network, and thus the conductive state of the channel, are coupled to channel opening at the inner bundle crossing though side-chain to main-chain bonding network along the pore-lining S6 segment. Additionally, voltage gated channels remain high-value pharmacological targets, and the sodium channel Nav1.7 isoform underlies pain sensation. Genetic loss of Nav1.7 abrogates pain sensing in humans, as do adult Nav.17 conditional knock-out animal models. Aryl- and acylsulfonamide compounds target the domain IV (DIV) voltage-sensing domain (VSD) of peripherally expressed sodium channels, such as Nav1.7, with low nanomolar affinity and attenuate inflammatory and neuropathic pain. A structure of the human Nav1.7 DIV VSD in complex with GX-936, a potent arylsulfonamide, suggests that these compounds utilize a unique binding mode whereby the drug simultaneously binds within an aromatic pocket and engages a basic residue (R4) of the activated voltage- sensor. These compounds are useful research tools to advance the understanding of NaV inactivation given the role of the DIV VSD in this process. Further, advancing the chemical details of this drug-bound pose will enable the design of compounds specific activity towards other voltage-sensors. Voltage-gated calcium channels are established drug targets of dihydropyridines (DHP), and recently the binding site was captured in a structure of a bacterial chimeric ?CaVAb? ? an engineered channel construct with nanomolar DHP binding affinity. However, it is not known if this bacterial chimera faithfully replicated the binding chemistry of the eukaryotic CaV. Not having predictive information on the basis for CaV antagonism severely limits the potential to develop of more critical methods for preclinical screens of therapeutics. The successful execution of these aims will advance the molecular understanding of channel gating and will reveal the binding modes of clinical drugs with high therapeutic value. Further, research tools generated here in will be similarly available to the ion channel research community.

Public Health Relevance

The goal of this competitive renewal project is to describe hydrogen bond networks in potassium channels and to advance the chemical basis for understanding neuronal sodium channel inhibition by acyl- and arylsulfonamide compounds. We will similarly delve into the unique chemistry of calcium DHP agonist and antagonist drugs.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
5R01GM106569-07
Application #
9969188
Study Section
Special Emphasis Panel (ZRG1)
Program Officer
Nie, Zhongzhen
Project Start
2013-09-15
Project End
2023-04-30
Budget Start
2020-05-01
Budget End
2021-04-30
Support Year
7
Fiscal Year
2020
Total Cost
Indirect Cost

  Institution

Name
University of Iowa
Department
Physiology
Type
Schools of Medicine
DUNS #
062761671
City
Iowa City
State
IA
Country
United States
Zip Code
52242

  Publications

Infield, Daniel T; Matulef, Kimberly; Galpin, Jason D et al. (2018) Main-chain mutagenesis reveals intrahelical coupling in an ion channel voltage-sensor. Nat Commun 9:5055
Thompson, Ammon; Infield, Daniel T; Smith, Adam R et al. (2018) Rapid evolution of a voltage-gated sodium channel gene in a lineage of electric fish leads to a persistent sodium current. PLoS Biol 16:e2004892
Infield, Daniel T; Lee, Elizabeth E L; Galpin, Jason D et al. (2018) Replacing voltage sensor arginines with citrulline provides mechanistic insight into charge versus shape. J Gen Physiol 150:1017-1024
Infield, Daniel T; Lueck, John D; Galpin, Jason D et al. (2018) Orthogonality of Pyrrolysine tRNA in the Xenopus oocyte. Sci Rep 8:5166
Steinberg, Ximena; Kasimova, Marina A; Cabezas-Bratesco, Deny et al. (2017) Conformational dynamics in TRPV1 channels reported by an encoded coumarin amino acid. Elife 6:
Leisle, Lilia; Chadda, Rahul; Lueck, John D et al. (2016) Cellular encoding of Cy dyes for single-molecule imaging. Elife 5:
Tian, Yutao; Aursnes, Marius; Hansen, Trond Vidar et al. (2016) Atomic determinants of BK channel activation by polyunsaturated fatty acids. Proc Natl Acad Sci U S A 113:13905-13910
Ahern, Christopher A; Payandeh, Jian; Bosmans, Frank et al. (2016) The hitchhiker's guide to the voltage-gated sodium channel galaxy. J Gen Physiol 147:1-24
Lueck, John D; Mackey, Adam L; Infield, Daniel T et al. (2016) Atomic mutagenesis in ion channels with engineered stoichiometry. Elife 5:
Pless, Stephan A; Kim, Robin Y; Ahern, Christopher A et al. (2015) Atom-by-atom engineering of voltage-gated ion channels: magnified insights into function and pharmacology. J Physiol 593:2627-34

Showing the most recent 10 out of 18 publications