Analgesic ω-Conotoxins CVIE and CVIF Selectively and Voltage-Dependently Block Recombinant and Native N-Type Calcium Channels

Berecki, Géza; Motin, Leonid; Haythornthwaite, Alison R.; Vink, Simone; Bansal, Paramjit S.; Drinkwater, R. D.; Wang, Ching I; Moretta, Melissa; Lewis, Richard J.; Alewood, Paul F.; Christie, MacDonald J.; Adams, David J.

doi:10.1124/mol.109.058834

Cited by 55 publications

(105 citation statements)

References 41 publications

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“…The high-affinity block of Ca v 2.2 by CVID was found to be reversible in heterologous systems expressing only the pore-forming ␣-subunit, but irreversible in DRG neurons, an effect that is mimicked in expression systems where the ␣-subunit is coexpressed with auxiliary ␤3 and ␣2␦1 subunits (Lewis et al, 2000;Mould et al, 2004;Motin et al, 2007). Likewise, inhibition of Ca v 2.2 by CVIE and CVIF was found to be virtually irreversible in the presence of ␤3 subunits but reversible in systems coexpressing the ␤2 subunit (Berecki et al, 2010). Intriguingly, these effects parallel modification of channel characteristics by auxiliary subunits, suggesting that altered block characteristics of -conotoxins in the presence of auxiliary subunits reflect altered channel kinetics.…”

mentioning

confidence: 82%

“…However, reversibility can be induced by hyperpolarizations to potentials more negative than the minimum of the steady-state inactivation curve; i.e., -conotoxins bind with higher affinity to the inactivated state of the N-channel than the resting state (Stocker et al, 1997). Such voltage-dependent recovery from block varies for different -conotoxins and is strongly influenced for some by the ␣2␦-and ␤-subunits, in particular ␣2␦1, ␤2a, and ␤3, coexpressed with the ␣-subunit (Mould et al, 2004;Berecki et al, 2010). Reversibility of GVIA and MVIIA is only weakly influenced by ␣2␦1-and ␤2a-or ␤3-subunit coexpression, and both appear to have a narrower therapeutic index than for CVID, which is strongly influenced by the presence of these subunits (Mould et al, 2004;Berecki et al, 2010).…”

Section: Calcium Channel Inhibition By Conotoxins In Pain Managementmentioning

confidence: 99%

“…Such voltage-dependent recovery from block varies for different -conotoxins and is strongly influenced for some by the ␣2␦-and ␤-subunits, in particular ␣2␦1, ␤2a, and ␤3, coexpressed with the ␣-subunit (Mould et al, 2004;Berecki et al, 2010). Reversibility of GVIA and MVIIA is only weakly influenced by ␣2␦1-and ␤2a-or ␤3-subunit coexpression, and both appear to have a narrower therapeutic index than for CVID, which is strongly influenced by the presence of these subunits (Mould et al, 2004;Berecki et al, 2010). Two more recently identified -conotoxins from Conus catus, CVIE and CVIF, show greater voltage-dependent reversal in the presence of ␣2␦1-and ␤-subunits than CVID (Berecki et al, 2010).…”

Section: Calcium Channel Inhibition By Conotoxins In Pain Managementmentioning

confidence: 99%

“…Intriguingly, these effects parallel modification of channel characteristics by auxiliary subunits, suggesting that altered block characteristics of -conotoxins in the presence of auxiliary subunits reflect altered channel kinetics. In addition to altered binding kinetics, many -conotoxins also have lower affinity for Ca v 2.2 in the presence of auxiliary subunits, especially Ca v ␣2␦1 (Lewis et al, 2000;Berecki et al, 2010). However, the precise mechanisms contributing to these intriguing characteristics of -conotoxins, as well as the effect of these pharmacological differences on the therapeutic potential of these peptides, remain to be elucidated.…”

mentioning

confidence: 99%

“…It is now appreciated that -conotoxins represent some of the most selective known inhibitors for the neuronal Ca v isoforms 2.2 and 2.1. Specifically, -conotoxins CVID, CVIE, CVIF, GVIA, and MVIIA are particularly selective for Ca v 2.2, whereas MVIIC and MVIID show a preference for Ca v 2.1 underlying P/Q-type calcium currents (Monje et al, 1993;Woppmann et al, 1994;Nadasdi et al, 1995;Nielsen et al, 1996;Flinn et al, 1999;Lewis et al, 2000;Berecki et al, 2010). The binding site of -conotoxins to the Ca v subtypes has been mapped primarily to the external vestibule of the channel in the domain III S5-S6 region (Ellinor et al, 1994), consistent with preliminary results obtained from docking of -MVIIA to a homology model of Ca v 2.2 ( Fig.…”

mentioning

confidence: 99%

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Section: Calcium Channel Inhibition By Conotoxins In Pain Managementmentioning

confidence: 99%

Section: Calcium Channel Inhibition By Conotoxins In Pain Managementmentioning

confidence: 99%

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Conotoxins and Other Conopeptides

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2014

Outstanding Marine Molecules

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Conopeptides are a large family of peptide toxins produced by marine cone snails. They act with high potency and exquisite specificity on a range of ion channels and transporters of the nervous system, making them valuable drug leads and important molecular probes in neurophysiological studies. Most conopeptides are small, ranging from 10 to 30 amino acid residues, but some contain up to about 90 amino acids. They display a large chemical diversity because they have very diverse sequences and a large number of post-translational modifications. Disulfide-rich conopeptides are commonly referred to as conotoxins, and have particularly diverse structures and a broad range of molecular targets. One conotoxin, MVIIA (also named Prialt 1 or ziconotide), is an N-type calcium channel blocker that is used clinically as an analgesic to treat neuropathic pain. Other conopeptides have also attracted considerable interest for their potential pharmaceutical applications. In this chapter, the marine cone snails and their venoms are introduced and the chemical diversity of conopeptides is described, along with the techniques used to unravel this diversity. The three-dimensional structures of conopeptides are discussed and linked to their pharmacological activities.

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Cyclisation of Disulfide‐Rich Conotoxins in Drug Design Applications

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Conotoxins are disulfide‐rich peptides found in the venoms of marine snails of the genus Conus. They have attracted great attention from the pharmaceutical industry because of their potential uses as drug leads, but like most peptides, conotoxins are susceptible to proteolysis and typically are not orally bioavailable. Here we discuss approaches that have been used to stabilise conotoxins to improve their potential pharmaceutical use. Specifically, we focus on the use of backbone cyclisation to improve their stability in biological fluids. The Microreview provides an introduction to the various classes of conotoxins, including their frameworks (cysteine patterns) and a background on the receptors that they interact with, as well as an analysis of the binding interactions between conotoxins and their receptors.

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Analgesic ω-Conotoxins CVIE and CVIF Selectively and Voltage-Dependently Block Recombinant and Native N-Type Calcium Channels

Cited by 55 publications

References 41 publications

Conus Venom Peptide Pharmacology

Conus Venom Peptide Pharmacology

Conotoxins and Other Conopeptides

Cyclisation of Disulfide‐Rich Conotoxins in Drug Design Applications

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