State-Dependent Verapamil Block of the Cloned Human Ca<sub>v</sub>3.1 T-Type Ca<sup>2+</sup> Channel

Freeze, Benjamin; McNulty, Megan M.; Hanck, Dorothy A.

doi:10.1124/mol.106.023473

Cited by 35 publications

(38 citation statements)

References 38 publications

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“…Verapamil produces tonic block (i.e., block at the resting potential), measured with infrequent depolarizations, in both T-type and L-type channels. In heterologous expression systems, the affinity of verapamil is similar, with an ED 50 for L-type channels of ϳ10 M, versus an ED 50 of ϳ20 M for T-type channels (Johnson et al, 1996;Freeze et al, 2006). D888 is a much higher-affinity ligand for L-type channels than verapamil, with an ED 50 for closed channel block of ϳ50 nM (Johnson et al, 1996).…”

Section: Resultsmentioning

confidence: 99%

“…In particular, D888 has 5-fold higher affinity for depolarized than for resting L-type channels (Johnson et al, 1996). In T-type channels, block by verapamil is modestly use-dependent (Freeze et al, 2006). We tested the use-dependence of D888 using a train of 25-ms depolarizing pulses to Ϫ10 mV with an interpulse interval of 100 ms.…”

Section: Resultsmentioning

confidence: 99%

“…In L-type channels, the affinity of verapamil for depolarized channels is on the order of 10-fold higher than for closed channels (Johnson et al, 1996). In T-type channels, the state-dependence is less dramatic, with less than 2-fold more block of depolarized channels than closed channels in the presence of 10 M verapamil (Freeze et al, 2006). D888, also known as devapamil or desmethoxyverapamil, is a related PAA lacking one methoxy group.…”

Section: Introductionmentioning

confidence: 99%

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Verapamil Block of T-Type Calcium Channels

Bergson¹,

Lipkind²,

Lee³

et al. 2010

Mol Pharmacol

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Verapamil is a prototypical phenylalkylamine (PAA), and it was the first calcium channel blocker to be used clinically. It tonically blocks L-type channels in the inner pore with micromolar affinity, and its affinity increases at depolarized membrane potentials. In T-type calcium channels, verapamil blocks with micromolar affinity and has modestly increased affinity at depolarized potentials. We found that a related PAA, 4-desmethoxyverapamil (D888), is comparable with verapamil both in affinity and in state-dependence. Permanently charged verapamil was more effective intracellularly than neutral verapamil. Charged PAAs were able to access their binding site from both inside and outside the cell. Furthermore, membrane-impermeant [2-(trimethylammonium)ethyl]methanethiosulfonate was able to access the inner pore from outside of the cell. We examined a homology model of the T-type calcium channel to look for possible routes of drug entry. Mutation of L1825W produced a channel that was blocked significantly more slowly by charged verapamil from the outside, with an increase in apparent affinity when the drug was applied from the inside. Data suggest that T-type channels have a back pathway through which charged drugs can access the inner pore of the channel without passing through the plasma membrane.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Verapamil Block of T-Type Calcium Channels

Bergson¹,

Lipkind²,

Lee³

et al. 2010

Mol Pharmacol

Self Cite

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“…In contrast, stably expressed human Ca v 3.1 T-type channels in human embryonic kidney (HEK) cells were blocked by verapamil in a use-and voltagedependent manner with an IC 50 of 21.4 µM and the drug significantly slowed the recovery from inactivation. It was suggested that verapamil achieves its inhibitory effect via occlusion of the channel pore associated with an open/inactivated conformation of the channel [54]. 10 µM diltiazem (which reduced I Ca,L by 18 %) had no action on T-type calcium channels in guinea-pig ventricular myocytes [47] but in rat aorta SMCs it reduced I Ca,T with an IC 50 of 30 µM, ten times less potently than I Ca,L .…”

Section: Actions On the L-type Calcium Channelsmentioning

confidence: 99%

“…4. Prolongation of the recovery from inactivation of calcium channels was described with verapamil [54], bepridil [35], semotiadil and also with diltiazem [39]. This alteration of channel behavior can also contribute to the antiarrhythmic action of CCAs by increasing the refractory period (RP) of nodal tissues.…”

Section: Potential Mechanisms Behind the Antiarrhythmic Actions Of Ccasmentioning

confidence: 99%

Class IV Antiarrhythmic Agents: New Compounds Using an Old Strategy

Szentandrássy

Nagy²,

Hegyi³

et al. 2014

CPD

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Cardiac arrhythmias are a major cause of morbidity and mortality in the industrialized world. Among their treatment regimens one can find the calcium channel antagonists (CCAs), the class IV agents. In the cardiovascular system Land T-type calcium channels are found on vascular smooth muscle cells and cardiac myocytes with well defined physiological roles. Inhibition of calcium channels by CCAs has widely been used in clinical practice for several decades. Cardiovascular disorders are one of the many fields of medicine in which CCAs are used for various reasons and conditions. The three main indications of them are hypertension, angina and various cardiac arrhythmias. The most important classes of CCAs are dihydropyridines, phenylalkylamines and benzothiazepines but some newer compounds do not fall into any of these major classes. Dihydropyridines are not used in the antiarrhythmic therapy but are good vasodilators and antianginal agents. In contrast, phenylalkylamines and benzothiazepines exert cardiac actions in vivo and therefore these are one choice of antiarrhythmic drugs. This review focuses on phenylalkylamines, benzothiazepines and on new drugs with potential antiarrhythmic action in the heart as well as the mechanisms how calcium channels antagonism can lead to an antiarrhythmic action.

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Multitargeting in cardioprotection: An example of biaromatic compounds

Mokrov

2023

Archiv der Pharmazie

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A multitarget drug design approach is actively developing in modern medicinal chemistry and pharmacology, especially with regard to multifactorial diseases such as cardiovascular diseases, cancer, and neurodegenerative diseases. A detailed study of many well‐known drugs developed within the single‐target approach also often reveals additional mechanisms of their real pharmacological action. One of the multitarget drug design approaches can be the identification of the basic pharmacophore models corresponding to a wide range of the required target ligands. Among such models in the group of cardioprotectors is the linked biaromatic system. This review develops the concept of a “basic pharmacophore” using the biaromatic pharmacophore of cardioprotectors as an example. It presents an analysis of possible biological targets for compounds corresponding to the biaromatic pharmacophore and an analysis of the spectrum of biological targets for the five most known and most studied cardioprotective drugs corresponding to this model, and their involvement in the biological effects of these drugs.

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State-Dependent Verapamil Block of the Cloned Human Ca_v3.1 T-Type Ca²⁺ Channel

Cited by 35 publications

References 38 publications

Verapamil Block of T-Type Calcium Channels

Verapamil Block of T-Type Calcium Channels

Class IV Antiarrhythmic Agents: New Compounds Using an Old Strategy

Multitargeting in cardioprotection: An example of biaromatic compounds

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State-Dependent Verapamil Block of the Cloned Human Cav3.1 T-Type Ca2+ Channel

Cited by 35 publications

References 38 publications

Verapamil Block of T-Type Calcium Channels

Verapamil Block of T-Type Calcium Channels

Class IV Antiarrhythmic Agents: New Compounds Using an Old Strategy

Multitargeting in cardioprotection: An example of biaromatic compounds

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Product

Resources

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State-Dependent Verapamil Block of the Cloned Human Ca_v3.1 T-Type Ca²⁺ Channel