Ling B N, Kemendy A E, Kokko K E, Hinton C F, Marunaka Y, Eaton D C
Department of Medicine, Emory University School of Medicine, Atlanta, Georgia.
Mol Cell Biochem. 1990 Dec 20;99(2):141-50. doi: 10.1007/BF00230344.
The first step in net active transepithelial transport of sodium in tight epithelia is mediated by the amiloride-blockable sodium channel in the apical membrane. This sodium channel is the primary site for discretionary control of total body sodium and, therefore, investigating its regulatory mechanisms is important to our understanding of the physiology of fluid and electrolyte balance. Because essentially all of the regulatory sites on the channel are on the intracellular surface, patch clamp methods have proven extremely useful in the electrophysiological characterization of the sodium channel by isolating it from other channel proteins in the epithelial membrane and by allowing access to the intracellular surface of the protein. We have examined three different regulatory mechanisms. (1) Inhibition of channel activity by activation of protein kinase C; (2) activation of the channel by agents which activate G-proteins; and (3) modulation of channel kinetics and channel number by mineralocorticoids. Activation of protein kinase C by phorbol esters or synthetic diacylglycerols reduces the open probability of sodium channels. Protein kinase C can be activated in a physiological context by enhancing apical sodium entry. Actions which reduce sodium entry (low luminal sodium concentrations or the apical application of amiloride) increase channel open probability. The link between sodium entry and activation of protein kinase C appears to be mediated by intracellular calcium activity linked to sodium via a sodium/calcium exchange system. Thus, the intracellular sodium concentration is coupled to sodium entry in a negative feedback loop which promotes constant total entry of sodium. Activation of G-proteins by pertussis toxin greatly increases the open probability of sodium channels. Since channels can also be activated by pertussis toxin or GTP gamma S in excised patches, the G-protein appears to be closely linked in the apical membrane to the sodium channel protein itself. The mechanism for activation of this apical G-protein, when most hormonal and transmitter receptors are physically located on the basolateral membrane, is unclear. Mineralocorticoids such as aldosterone have at least two distinct effects. First, as expected, increasing levels of aldosterone increase the density of functional channels detectable in the apical membrane. Second, contrary to expectations, application of aldosterone increases the open probability of sodium channels. Thus aldosterone promotes the functional appearance of new sodium channels and promotes increased sodium entry through both new and pre-existant channels.
在紧密上皮细胞中,钠的净主动跨上皮转运的第一步是由顶端膜中可被氨氯地平阻断的钠通道介导的。这种钠通道是全身钠自主控制的主要部位,因此,研究其调节机制对于我们理解液体和电解质平衡的生理学很重要。由于该通道上基本上所有的调节位点都在细胞内表面,膜片钳方法已被证明在钠通道的电生理特性研究中极其有用,它可以将钠通道与上皮细胞膜中的其他通道蛋白分离,并能接触到该蛋白的细胞内表面。我们研究了三种不同的调节机制。(1)通过蛋白激酶C的激活来抑制通道活性;(2)通过激活G蛋白的试剂来激活通道;(3)盐皮质激素对通道动力学和通道数量的调节。佛波酯或合成二酰甘油激活蛋白激酶C会降低钠通道的开放概率。在生理环境中,通过增强顶端钠内流可激活蛋白激酶C。减少钠内流的行为(低管腔钠浓度或顶端应用氨氯地平)会增加通道开放概率。钠内流与蛋白激酶C激活之间的联系似乎是由通过钠/钙交换系统与钠相关联的细胞内钙活性介导的。因此,细胞内钠浓度与钠内流在一个负反馈回路中耦合,该回路促进钠的恒定总内流。百日咳毒素激活G蛋白会大大增加钠通道的开放概率。由于在切除的膜片中通道也可被百日咳毒素或GTPγS激活,G蛋白似乎在顶端膜中与钠通道蛋白本身紧密相连。当大多数激素和递质受体实际位于基底外侧膜时,这种顶端G蛋白的激活机制尚不清楚。醛固酮等盐皮质激素至少有两种不同的作用。首先,正如预期的那样,醛固酮水平的升高会增加在顶端膜中可检测到的功能性通道的密度。其次,与预期相反,应用醛固酮会增加钠通道的开放概率。因此,醛固酮促进新钠通道的功能性出现,并促进通过新通道和预先存在的通道增加钠内流。
