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Chemically modified cardiac Na+ channels and their sensitivity to antiarrhythmics: Is there a hidden drug receptor? (1994)

Benz, I. ; Kohlhardt, M.

Springer

The journal of membrane biology 139 (1994), S. 191-201

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ISSN: 1432-1424

Keywords: Single noninactivating Na+ channels ; Iodate ; Trypsin ; (−)-DPI 201-106 ; Drug-sensitive open state ; Channel-associated binding sites

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Chemistry and Pharmacology

Notes: Abstract Elementary Na+ currents were recorded at 19°C in inside-out patches from cultured neonatal rat cardiocytes. In analyzing the sensitivity of chemically modified Na+ channels to several class 1 antiarrhythmic drugs, the hypothesis was tested that removal of Na+ inactivation may be accompanied by a distinct responsiveness to these drugs, open channel blockade. Iodate-modified and trypsin-modified cardiac Na+ channels are noninactivating but strikingly differ from each other by their open state kinetics, a O1–O2 reaction (τopen(1) 1.4±0.3 msec; τopen(2) 5.4±1.1 msec; at −40 mV) in the former and a single open state (τopen 3.0±0.5 msec; at −40 mV) in the latter. Lidocaine (150 μmol/liter) like propafenone (10 μmol/liter), diprafenone (10 μmol/liter) and quinidine (20 μmol/liter) in cytoplasmic concentrations effective to depress NP o significantly can interact with both types of noninactivating Na+ channels to reduce the dwell time in the conducting configuration. lodate-modified Na+ channels became drug sensitive during the O2 state. At −40 mV, for example, lidocaine reduced τopen(2) to 62±5% of the control without detectable changes in τopen(1). No evidence could be obtained that these inhibitory molecules would flicker-block the open Na+ pore. Drug-induced shortening of the open state, thus, is indicative for a distinct mode of drug action, namely interference with the gating process. Lidocaine proved less effective to reduce τopen(2) when compared with the action of diprafenone. Both drugs apparently interacted with individual association rate constants, alidocaine was 0.64×106 mol−1 sec−1 and adiprafenone 13.6×106 mol−1 sec−1. Trypsin-modified Na+ channels also appear capable of discriminating among these antiarrhythmics, the ratio adiprafenone/alidocaine even exceeded the value in iodate-modified Na+ channels. Obviously, this antiarrhythmic drug interaction with chemically modified Na+ channels is receptor mediated: drug occupation of such a hypothetical hidden receptor that is not available in normal Na+ channels may facilitate the exit from the open state.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00232623

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Responsiveness of cardiac Na+ channels to antiarrhythmic drugs: The role of inactivation (1991)

Benz, I. ; Kohlhardt, M.

Springer

The journal of membrane biology 122 (1991), S. 267-278

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ISSN: 1432-1424

Keywords: single cardiac Na+ channels ; open-state kinetics ; drug-induced blockade ; (-)-DPI

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Chemistry and Pharmacology

Notes: Summary Elementary Na+ currents were recorded at 9°C in inside-out patches from cultured neonatal rat heart myocytes. In characterizing the sensitivity of cooled, slowly inactivating cardiac Na+ channels to several antiarrhythmic drugs including propafenone, lidocaine and quinidine, the study aimed to define the role of Na+ inactivation for open channel blockade. In concentrations (1–10 μmol/liter) effective to depressNP o significantly, propafenone completely failed to influence the open state of slowly inactivating Na+ channels. With 1 μmol/liter, τopen changed insignificantly to 96±7% of the control. Even a small number of ultralong openings of 6 msec or longer exceeding τopen of the whole ensemble several-fold and attaining τopen (at −45 mV) in cooled, (-)-DPI-modified, noninactivating Na+ channels proved to be drug resistant and could not be flicker-blocked by 10 μmol/liter propafenone. The same drug concentration induced in(-)-DPI-modified Na+ channels a discrete block with association and dissociation rate constants of 16.1 ± 5.3 × 106 mol−1 sec−1 and 675 ± 25 sec−1, respectively. Quinidine, known to have a considerable affinity for activated Na+ channels, in lower concentrations (5 μmol/liter) left τopen unchanged or reduced, in higher concentrations (10 μmol/liter) τopen only slightly to 81% of the predrug value whereasNP o declined to 30%, but repetitive blocking events during the conducting state could never be observed. Basically the same drug resistance of the open state was seen in cardiac Na+ channels whose open-state kinetics had been modulated by the cytoplasmic presence of F− ions. But in this case, propafenone reduced reopening and selectively abolished a long-lasting open state. This drug action is unlikely related to the inhibitory effect onNP o since hyperpolarization and the accompanying block attenuation did not restore the channel kinetics. It is concluded that cardiac Na+ channels cannot be flicker-blocked by antiarrhythmic drugs unless Na+ inactivation is removed.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01871427

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