Voltage clamp analyses, combined with pharmacological tools demonstrate the independence of reactive Na and K channels in electrically excitable membrane of eel electroplaques. Spike electrogenesis is due to Na activation and is eliminated by tetrodotoxin or mussel poison, or by substituting choline, K, Cs, or Rb for Na in the medium. The K channels remain reactive, but K activation is always absent, the electroplaques responding only with K inactivation. This is indicated by an increased resistance when the membrane is depolarized by more than about 30 mv. The resting resistance (1 to 5 ohm cm2) is dependent upon the ionic conditions, but when K inactivation occurs the resistance becomes about 10 ohm cm2 in all conditions. K inactivation does not change the EMF significantly. The transition from low to high resistance may give rise to a negative-slope voltage current characteristic, and to regenerative inactivation responses under current clamp. The further demonstration that pharmacological K inactivation (by Cs or Rb) leaves Na activation and spike electrogenesis unaffected emphasizes the independence of the reactive processes and suggests different chemical compositions for the membrane structures through which they operate.
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机译:电压钳分析与药理学工具相结合,证明了鳗鱼斑块电激发膜中反应性Na和K通道的独立性。尖峰的电发生是由于Na的激活,并通过河豚毒素或贻贝中毒或通过用胆碱,K,Cs或Rb代替培养基中的Na消除。 K通道保持反应性,但始终不存在K活化,电斑仅以K失活响应。当膜去极化超过约30 mv时,电阻增加表明了这一点。静息电阻(1至5 ohm cm 2 )取决于离子条件,但是当K失活时,电阻在所有条件下都变为约10 ohm cm 2 。 K失活不会显着改变EMF。从低电阻到高电阻的过渡可能会引起负斜率电压电流特性,并导致电流钳制下的再生失活响应。药理性K失活(通过Cs或Rb)使Na活化和刺突生电不受影响的进一步证明强调了反应过程的独立性,并暗示了它们通过其运作的膜结构的不同化学组成。
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