钠对ENaC的刹车和气体调节

IF 3.3 3区 生物学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY
M. Awayda
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引用次数: 2

摘要

上皮性NaC通道(ENaC)限制了NaC进入许多上皮。它的活性改变了上皮内NaC的运输,进而改变了盐和水的吸收。人们早就知道,随着NaC浓度的增加,通道的电导会增加,尽管是非线性的。然而,这种通道的独特之处在于,它也可以通过提高输送离子的浓度来抑制通透性。这种效应发生在两个不同的时域,源于至少两种不同的机制。最初的急性时间过程通过钠离子与通道或通道相关蛋白的相互作用而发生,并在几秒钟内发生。延长的时间跨度从几分钟到几天。这一点很早就被认识到,并被称为反馈抑制。反馈抑制在许多天然和异种系统中普遍存在,并被报道涉及到泛素连接酶蛋白Nedd4-2和蛋白激酶c。Palmer及其同事已经证明了反馈抑制的生理意义;然而,与该频道的确切联系仍然缺失。在8(5)期的Channels中,Patel等人研究了[NaC]对ENaC的反馈抑制机制。他们将反馈抑制细分为一种1-2小时的时间过程和一种过夜(大约8小时)的时间过程。在早期阶段,抑制并不伴随着对亚基运输或质膜密度的可检测影响,而是依赖于完整通道亚基c末端的存在。通过利用截断的c端b亚基,他们证明了对增加的[NaC]i的敏感性向右移位或降低。这首次证明了反馈抑制可能会影响单个通道活性或开放概率(Po),但有趣的是,其影响方式取决于完整的细胞内Ctermini的存在。更广泛的含义是,Po不能简单地分配给单个氨基酸,而是许多额外的,膜内和跨膜结构域的集体活动。第二个暗示是[NaC]i的持续增加可能涉及下游修饰或细胞内c末端的信号传导。第二阶段的反馈抑制发生在bbb ~ 8 h。这一较长的阶段依赖于gENaC的内化,可能伴随着该亚基切割的减少,表明通过降低膜蛋白密度和减少亚基切割过程导致通道激活而降低通道活性。他们的研究结果表明了c端在这一阶段的重要性,并呈现出一系列事件,其中早期反馈抑制可能通过使膜驻留通道失活而发生,而延长的失活则通过内源性和可能的细胞内亚基切割减少以及质膜内化增强而发生。这些差异的生理意义可能存在于肾脏细胞内NaC负荷的恢复中。这些数据可以预测,管状[NaC]增加1-2小时后可以很容易地从抑制中快速恢复,这可能是由于通道Po抑制的可逆性;一种要求膜蛋白密度没有发生变化的过程。相反,从
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Brakes and gas-regulation of ENaC by sodium
The epithelial NaC Channel (ENaC) is rate limiting to NaC entry across many epithelia. Its activity modifies transepithelial NaC transport and by extension salt and water absorption. It has long been known that the channel’s conductance increases, albeit non-linearly, as the NaC concentration increases. However, this channel is unique in that it is also inhibited by elevating the concentration of the transported ion leading to inhibition of permeability. This effect occurs at 2 different time domains stemming from at least 2 distinct mechanisms. The initial acute time course occurs by interaction of the sodium ion with the channel or channel associated proteins and occurs within seconds. The prolonged time course spans minutes to days. This has been recognized early on and termed feedback inhibition. Feedback inhibition is ubiquitously observed for ENaC in many native and heterologous systems and has been reported to involve the ubiquitin ligase protein Nedd4-2, and protein kinase C. The physiological significance of feedback inhibition has been demonstrated by Palmer and colleagues; however, an exact link to the channel has remained missing. In the 8(5) issue of Channels Patel et al. examined the mechanism of feedback inhibition of ENaC by [NaC]i . They subdivide feedback inhibition into one with a 1–2 hour time course and one with an overnight (>8 h) time course. In the early phase, inhibition was not accompanied by detectable effects on subunit trafficking or plasma membrane density but was dependent on the presence of intact channel subunit C-termini. By utilizing a truncated C-terminus b subunit they demonstrated that the sensitivity to increased [NaC]i was rightward shifted or reduced. This demonstrates for the first time that feedback inhibition may affect individual channel activity or open probability (Po), but interestingly, in a manner that depends on the presence of intact intracellular Ctermini. The broader implications are that Po cannot be simply assigned to a single amino acid but is rather the collective activity of numerous extra, intra and transmembrane domains. The second implication is that prolonged increases of [NaC]i may involve downstream modification or signaling with the intracellular C-termini. The second phase of feedback inhibition was observed at periods >8 h. This longer phase was dependent on internalization of gENaC possibly accompanied by reduced cleavage of this subunit indicating reduced channel activity by reducing membrane protein density and by reducing subunit cleavagea process that leads to channel activation. Their results indicate the importance of the C-termini in this phase and present a continuum of events whereby early feedback inhibition likely occurs by inactivating membrane resident channels, while prolonged inactivation occurs by reduced endogenous and presumably intracellular cleavage of subunits accompanied by enhanced internalization from the plasma membrane. The physiological significance of these differences could reside in the recovery from an intracellular NaC load in the kidneys. These data would predict that rapid recovery from inhibition after a 1–2 h increase of tubular [NaC] is allowed with ease possibly due to the reversibility of inhibition of channel Po; a process that requires that no changes of membrane protein density have occurred. Conversely, recovery from
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来源期刊
Channels
Channels 生物-生化与分子生物学
CiteScore
5.90
自引率
0.00%
发文量
21
审稿时长
6-12 weeks
期刊介绍: Channels is an open access journal for all aspects of ion channel research. The journal publishes high quality papers that shed new light on ion channel and ion transporter/exchanger function, structure, biophysics, pharmacology, and regulation in health and disease. Channels welcomes interdisciplinary approaches that address ion channel physiology in areas such as neuroscience, cardiovascular sciences, cancer research, endocrinology, and gastroenterology. Our aim is to foster communication among the ion channel and transporter communities and facilitate the advancement of the field.
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