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1

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Opposite effects of angiotensin II and the protein kinase C activator OAG on cardiac Na+ channels (1992)

Benz, I. ; Herzig, J. W. ; Kohlhardt, M.

Springer

The journal of membrane biology 130 (1992), S. 183-190

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ISSN: 1432-1424

Keywords: Na+ channel properties ; protein kinase C ; angiotensin II ; OAG ; phosphorylation

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Chemistry and Pharmacology

Notes: Summary Elementary Na+ currents were recorded at 19°C in cell-attached and inside-out patch-clamp experiments to study the influence of the vasoactive peptide angiotensin II (A II) and of the diacylglycerol analogue OAG (1-oleoyl-2-acetyl-snglycerol) on open probability and gating properties of single cardiac Na+ channels from cultured neonatal rat cardiocytes. Treating the cardiocytes with A II caused Na+ channel activation: reconstructed peak INa increased to 137 ± 17.5% of control at 3 μmol/liters and to 176 ± 42% at 30 μmol/liter. This NPo increase developed without major changes in open state and burst activity, even at 30 μmol/liter. OAG (6 μmol/liter) did not mimic this A II action. By contrast, OAG treatment of the cardiocytes had the opposite effect on NPo and diminished reconstructed peak INa to 67 ± 4.9% of the control. The putative protein kinase C inhibitor staurosporine (0.2 μmol/liter) abolished this INa depression and led to a normalization of NPo. OAG had the same effect on isolated Na+ channels. Exposure of the cytoplasmic surface of inside-out patches to 1 μmol/liter OAG reversibly depressed, in the simultaneous presence of 50 μmol/liter Mg-ATP, the reconstructed peak INa to 40 ± 9.7% of the control but left i unit, τ open and burst activity unaffected. No NPo depression was obtained in the absence of Mg-ATP indicating that Mg-ATP may serve as phosphate donor. Obviously, after phosphorylation by protein kinase C, cardiac Na+ channels attain a reduced open probability but appear to preserve their kinetic properties. It is also concluded that activation of protein kinase C is not the mechanism underlying the A II induced channel activation.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00231895

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2

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Properties and the Cytoskeletal Control of Ca++-independent Large Conductance K+ Channels in Neonatal Rat Hippocampal Neurons (1998)

Benz, I. ; Meyer, D.K. ; Kohlhardt, M.

Springer

The journal of membrane biology 161 (1998), S. 275-286

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ISSN: 1432-1424

Keywords: Key words: Maxi K+ channels — Colchicine — cytochalasin B — Cytoskeleton

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Chemistry and Pharmacology

Notes: Abstract. A member of the family of Ca++-independent large conductance K+ channels (termed BK channels) was identified in patch clamp experiments with cultured neonatal rat hippocampal neurons. Permeation was characterized (at 5 mmol/l external, 140 mmol/l internal K+; 135 mmol/l external Na+) by a conductance of 107 pS, a ratio PNa/PK∼ 0.01, and outward rectification near the reversal potential. Channel activity was not voltage-dependent, could not be reduced by internal TEA or by a shift of internal pH from 7.4 to 6.8, i.e., discriminating features within the Ca++-independent BK channel family. Cytosolic proteolysis abolished the functional state of hippocampal Ca++-independent BK channels, in contrast to the pronase resistance of hippocampal Ca++-activated BK channels which suggests structural dissimilarities between these related channels. Cytoskeletal alterations had an activating influence on Ca++-independent BK channels and caused a 3–4-fold rise in P o , but patch excision and channel isolation from the natural environment provoked the strongest increase in P o , from 0.07 ± 0.03 to 0.73 ± 0.04. This activation process operated slowly, on a minute time scale and can be most easily explained with the loss of a membrane-associated inhibitory particle. Once activated, Ca++-independent BK channels reacted sensitively to a Mg-ATP supplemented brain tissue extract with a P o decline, from 0.60 ± 0.06 to 0.10 ± 0.05. Heated extracts failed to induce significant channel inhibition, providing evidence for a heat-unstable molecule with reassociates with the internal channel surface to reestablish channel inhibition. A dualistic channel control, by this membrane-associated molecule and by the cytoskeleton seems possible.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/s002329900334

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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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4

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Thermodynamically specific gating kinetics of cardiac mammalian K (ATP) + channels in a physiological environment near 37°C (1995)

Haverkampf, K. ; Benz, I. ; Kohlhardt, M.

Springer

The journal of membrane biology 146 (1995), S. 85-90

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ISSN: 1432-1424

Keywords: K+ permeation ; Open state kinetics ; Q10 ; Arrhenius anomalies ; Temperature dependence ; cAMP-dependent phosphorylation

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Chemistry and Pharmacology

Notes: Abstract Elementary K+ currents through isolated ATP-sensitive K+ channels from neonatal rat cardiocytes were recorded to study their temperature dependence between 9°C and 39°C. Elementary current size and, thus, K+ permeation through the open pore varied monotonically with temperature with a Q10 of 1.25 corresponding to a low activation energy of 3.9 kcal/mol. Open-state kinetics showed a complicated temperature dependence with Q10 values of up to 2.94. Arrhenius anomalies of τopen(1) and τopen(2) indicate the occurrence of thermallyinduced perturbations with a dominating influence on channel portions that are involved in gating but are obviously ineffective in altering pore-forming segments. At 39°C, open-state exit reactions were associated with the highest activation energy (O2 exit reaction: 12.1 kcal/ mol) and the largest amount of entropy. A transition from 19°C to 9°C elucidated a paradoxical kinetic response, shortening of both O-states, irrespective of the absence or presence of cAMP-dependent phosphorylation. Another member of the K+ channel family and also a constituent of neonatal rat cardiocyte membranes, 66 pS outwardly-rectifying channels, was found to react predictably since τopen increased on cooling. Obviously, cardiac K (ATP) + channels do not share this exceptional kinetic responsiveness to a temperature transition from 19°C to 9°C with other K+ channels and have a unique sensitivity to thermally-induced perturbations.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00232682

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5

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Characterization of the Driving Force as a Modulator of Gating in Cardiac ATP-sensitive K+ Channels — Evidence for Specific Elementary Properties (1998)

Benz, I. ; Haverkampf, K. ; Kohlhardt, M.

Springer

The journal of membrane biology 165 (1998), S. 45-52

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ISSN: 1432-1424

Keywords: Key words: Cardiac inward rectifier K+ channels — Kinetics — Permeation — Electrochemical K+ gradient — pH — Rubidium

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Chemistry and Pharmacology

Notes: Abstract. Single cardiac ATP-sensitive K+ channels and, comparatively, two other members of the inwardly rectifying K+ channel family, cardiac K+ (ir) and K+ (ACh) channels, were studied in the inside-out recording mode in order to analyze influence and significance of the electrochemical K+ gradient for open-state kinetics of these K+ channels. The conductive state of K+ (ATP) channels was defined as a function of the electrochemical K+ gradient in that increased driving force correlates with shortened open-channel lifetime. Flux coupling of gating can be largely excluded as the underlying mechanism for two reasons: (i) τopen proved identical in 23 pS, 56 pS and 80 pS channels; (ii) K+ (ATP) channel protonation by an external pH shift from 9.5 to 5.5 reduced conductance without a concomitant detectable change of τopen. Since gating continued to operate at E K , i.e., in the absence of K+ permeation through the pore, K+ driving force cannot be causally involved in gating. Rather the driving force acts to modulate the gating process similar to Rb+ whose interference with an externally located binding site stabilizes the open state. In K+ (ir) and K+ (ACh) channels, the open state is essentially independent on driving force meaning that their gating apparatus does not sense the electrochemical K+ gradient. Thus, K+ (ATP) channels differ in an important functional aspect which may be tentatively explained by a structural peculiarity of their gating apparatus.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/s002329900419

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6

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Distinct modes of blockade in cardiac ATP-sensitive K+ channels suggest multiple targets for inhibitory drug molecules (1994)

Benz, I. ; Kohlhardt, M.

Springer

The journal of membrane biology 142 (1994), S. 309-322

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ISSN: 1432-1424

Keywords: Single cardiac KATP channels ; Sulfonylureas ; Verapamil ; Sulfonamide derivatives ; Elementary properties ; Channel-associated drug targets

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Chemistry and Pharmacology

Notes: Abstract Elementary K+ currents were recorded at 19°C in inside-out patches from cultured neonatal rat cardiocytes to elucidate the block phenomenology in cardiac ATP-sensitive K+ channels when inhibitory drug molecules, such as the sulfonylurea glibenclamide, the phenylalkylamine verapamil or sulfonamide derivatives (HE 93 and sotalol), are interacting in an attempt to stress the hypothesis of multiple channel-associated drug targets. Similar to their adult relatives, neonatal cardiac K(ATP) channels are characterized by very individual open state kinetics, even in cytoplasmically well-controlled, cell-free conditions; at −7 mV, τopen(1) ranged from 0.7 to 4.9 msec in more than 200 patches and τopen(2) from 10 to 64 msec—an argument for a heterogeneous channel population. Nevertheless, a common response to drugs was observed. Glibenclamide and the other inhibitory molecules caused long-lasting interruptions of channel activity, after cytoplasmic application, as if drug occupancy trapped cardiac K(ATP) channels in a very stable, nonconducting configuration. The resultant NP 0 depression was strongest with glibenclamide (apparent IC50 13 nmol/liter) and much weaker with verapamil (apparent IC50 9 μmol/liter), HE 93 (apparent IC50 29 μmol/liter) and sotalol (apparent IC50 43 μmol/ liter) and may have resulted from the occupancy of a single site with drug-specific affinity or of two sites, the high affinity glibenclamide target and a distinct nonglibenclamide, low affinity target. Changes in open state kinetics, particularly in the transition between the O1 state and the O2 state, are other manifestations of drug occupancy of the channel. Any inhibitory drug molecule reduced the likelihood of attaining the O2 state, consistent with a critical reduction of the forward rate constant governing the O1-O1 transition. But only HE 93 (10 μmol/liter) associated (with an apparent association rate constant of 2.3 × 106 mol−1 sec−1) to shorten significantly τopen(2) to 60.6 ± 6% of the predrug value, not the expected result when the entrance in and the exit from the O2 state would be drug-unspecifically nfluenced. Sotalol found yet another and definitely distinctly located binding site to interfere with K+ permeation; both enantiomers associated with a rate close to 5×105 mol−1 sec−1 with the open pore thereby flicker-blocking cardiac K(ATP) channels. Clearly, these channels accommodate more than one drug-binding domain.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00233438

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7

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Responsiveness of cardiac Na+ channels to a site-directed antiserum against the cytosolic linker between domains III and IV and their sensitivity to other modifying agents (1993)

Beck, W. ; Benz, I. ; Bessler, W. ; [et al.]

Springer

The journal of membrane biology 134 (1993), S. 231-239

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ISSN: 1432-1424

Keywords: Noninactivating cardiac Na+ channels ; Removal of inactivation ; Cardiac Na+ channel protein ; α-subunit

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Chemistry and Pharmacology

Notes: Abstract Elementary Na+ currents were recorded in inside-out patches from neonatal rat heart cardiocytes to analyze the influence of a site-directed polyclonal anti-serum against the linker region between the domains III and IV (amino acids 1489–1507 of the cardiac Na+ channel protein) on Na+ channel gating and to test whether this part of the α-subunit may be considered as a target for modifying agents such as the (−)-enantiomer of DPI 201-106. Anti-SLP 1 serum (directed against amino acids 1490–1507) evoked, usually within 10–15 min after cytosolic administration, modified Na+ channel activity. Antiserum-modified Na+ channels retain a single open state but leave, at −60 mV for example, their conducting configuration consistently with an about threefold lower rate than normal Na+ channels. Another outstanding property of noninactivating Na+ channels, enhanced burst activity, may be quite individually pronounced, a surprising result which is difficult to interpret in terms of structure function relations. Removal of inactivation led to an increase of reconstructed peak I Na (indicating a rise in NP o) and changed I Na decay to obey second-order kinetics, i.e., open probability declined slowly but progressively during membrane depolarization. The underlying deactivation process is voltage dependent and responds to a positive voltage shift with a deceleration but may operate even at the same membrane potential with different rates. Iodatemodified Na+ channels exhibit very similar properties including a conserved conductance. They are likewise controlled by an efficient, voltage-dependent deactivation process. Modification by (−)-DPI 201-106 fundamentally contrasts to the influence of anti-SLP 1 serum and the protein reagent iodate since (−)-DPI-modified Na+ channels maintain their open probability for at least 120 msec, i.e., a deactivation process seems lacking. This functional difference suggests that the linker region between the domains III and IV of the α-subunit may not be the only target for (−)-DPI 201-106 and related compounds, if at all.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00234504

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Blockade of cardiac outwardly rectifying K+ channels by TEA and class III antiarrhythmics — evidence against a single drug-sensitive channel site (1994)

Benz, I. ; Kohlhardt, M.

Springer

European biophysics journal 22 (1994), S. 437-446

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ISSN: 1432-1017

Keywords: Single cardiac K+ channels ; Gating ; Quinidine ; Verapamil ; Channel-associated binding site ; Heart muscle

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Physics

Notes: Abstract Elementary K+ currents through cardiac outwardly rectifying K+ channels were recorded in insideout patches excised from cultured neonatal rat cardiocytes at 19 °C and at 9 °C. By studying the inhibitory effects of tetraethylammonium (TEA), quinidine and verapamil, the properties of this novel type of K+ channel were further characterized. Internal TEA (50 mmol/1) evoked a reversible decline of iunit to 62.7 + 2.7% of control (at −7 mV), without significant changes of open state kinetics, indicating a blockade of the open K+ pore with kinetics too fast to be resolvable at 1 kHz. This TEA blockade was e-fold voltage-dependent, with a decrease of the apparent KD( TEA) from 102 mmol/1 at −37 mV to 65 mmol/1 at +33 mV and, furthermore, became accentuated on lowering the internal K+ concentration. Thus, TEA competes with the permeant K+ for a site located in some distance from the cytoplasmic margin, within the K+ pore. Quinidine (100 μmol/l), like verapamil (40 μmol/1) reversibly depressed iunit to about 80% of the control value (at −7 mV), but drug-induced fast flicker blockade proved voltage-insensitive between −27 mV and +23 mV These drugs gain access to a portion of the pore distinct from the TEA binding site whose occupancy by drugs likewise blocks K+ permeation. Both drugs showed a greater potency to depress Po which, with quinidine,decreased reversibly to38.6 ± 11.1% (at −7 mV) and, with verapamil to 24.9 ± 9.1%(at −7 mV), mainly by an increase of the prolonged closed state (C,). This alteration of the gating process also includes a sometimes dramatic shortening of the open state. Most probably, cardiac K(outw.-rect.) +K+ outw.-rect. channels possess a second drug-sensitive site whose occupancy by quinidine or verapamil may directly or allosterically stabilize their non-conducting configuration.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00180164

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9

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Two types of modified cardiac Na+ channels after cytosolic interventions at the α-subunit capable of removing Na+ inactivation (1997)

Benz, I. ; Beck, W. ; Kraas, W. ; [et al.]

Springer

European biophysics journal 25 (1997), S. 189-200

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ISSN: 1432-1017

Keywords: Key words Single cardiac Na+ channels ; Site-directed antipeptide antibody ; Proteolysis ; Protein reagents ; Calpain ; Stochastic mode switching

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Physics

Notes: Abstract Failure of inactivation is the typical response of voltage-gated Na+ channels to the cytosolic presence of proteolytic enzymes, protein reagents such as N-bromoacetamide (NBA) or iodate, and antibodies directed against the linker between domains III and IV of the α-subunit. The present patch clamp experiments with cardiac Na+ channels aimed to test the hypothesis that these interventions may provoke the occurrence of non-inactivating Na+ channels with distinct kinetic properties. A site-directed polyclonal antibody (anti-SLP2, target sequence 1481–1496 of the cardiac Na+ channel α-subunit) eliminated fast Na+ inactivation to induce burst activity which was accompanied by the occurrence of two open states. A deactivation process terminated channel activity during membrane depolarization proceeding with time constants of close to 40 ms (at –40 mV). NBA-modified and iodate-modified Na+ channels were kinetically indistinguishable from the anti-SLP2-modified type since they likewise deactivate and, thus, attain an only moderate Po of close to 20%. This is fundamentally different from the behaviour of enzymatically-modified Na+ channels: after cytosolic proteolysis with α-chymotrypsin, trypsin or pronase, mean Po during membrane depolarization amounted to approximately 40% because deactivation operated extremely slowly and less efficiently (time constants 100–200 ms at –40 mV, as a minimum) or was virtually non-operating. In-vitro cleavage of the synthetic linker sequence 1481–1496 confirmed that this part of the α-subunit provides a substrate for these peptidases or reactants for NBA but cannot be chemically modified by iodate. This iodate resistance indicates that iodate-modified Na+ channels are based on a structural alteration of still another region which is also involved in Na+ inactivation, besides the linker between domains III and IV of the α-subunit. Endogenous peptidases such as calpain did not affect Na+ inactivation. This stresses the stochastic nature of a kinetic peculiarity of cardiac Na+ channels, mode-switching to a non-inactivating mode.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/s002490050031

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Single cardiac outwardly rectifying K+ channels modulated by protein kinase A and a G-protein (1991)

Benz, I. ; Fröbe, U. ; Kohlhardt, M.

Springer

European biophysics journal 20 (1991), S. 281-286

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ISSN: 1432-1017

Keywords: Cardiac K+ channels ; Phosphorylation ; GTP ; GDP ; Neonatal rat heart myocytes

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Physics

Notes: Abstract Elementary K+ currents were recorded at 19 °C in cell-attached and in inside-out patches excised from neonatal rat heart myocytes. An outwardly rectifying K+ channel which prevented Na+ ions from permeating could be detected in about 10% of the patches attaining (at 5 mmol/l external K+ and between − 20 mV and + 20 mV) a unitary conductance of 66 +- 3.9 pS. K (outw.-rect.) + channels have one open and at least two closed states. Open probability and τopen rose steeply on shifting the membrane potential in the positive direction, thereby tending to saturate. Open probability (at −7 mV) was as low as 3 ± 1% but increased several-fold on exposing the cytoplasmic surface to Mg-ATP (100 μmol/l) without a concomitant change of τopen. No channel activation occurred in response to ATP in the absence of cytoplasmic Mg−+. The cytoplasmic administration of the catalytic subunit of protein kinase A (120–150 μ/ml) or GTP-γ-S (100 μmol/l) caused a similar channel activation. GDP-β-S (100 μmol/l) was also tested and found to be ineffective in this respect. This suggests that cardiac K (outw.-rect.) + channels are metabolically modulated by both cAMP-dependent phosphorylation and a G-protein.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00450563

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