Different patterns of channel activity have been detected by patch clamping excised membrane patches from reconstituted giant liposomes containing purified KcsA, a potassium channel from prokaryotes. The more frequent pattern has a characteristic low channel opening probability and exhibits many other features reported for KcsA reconstituted into planar lipid bilayers, including a moderate voltage dependence, blockade by Na ؉ , and a strict dependence on acidic pH for channel opening. The predominant gating event in this low channel opening probability pattern corresponds to the positive coupling of two KcsA channels. However, other activity patterns have been detected as well, which are characterized by a high channel opening probability (HOP patterns), positive coupling of mostly five concerted channels, and profound changes in other KcsA features, including a different voltage dependence, channel opening at neutral pH, and lack of Na During the last decades, the use of high resolution electrophysiological techniques to study ion channels has provided a large amount of information on functional aspects of these important membrane proteins. Such a detailed information on channel function, however, has not been accompanied by structural knowledge until recently, when several structurally simpler homologues of mammalian ion channels found in extremophyle bacteria or Archaea and remarkably resistant to harsh experimental conditions, have been purified, crystallized and their structure solved at high resolution by x-ray diffraction methods (1-4). A K ϩ channel from the soil bacteria Streptomyces lividans named KcsA 4 (1), a homotetramer made up of identical 160-amino acid subunits, was the first of such structures to be solved (5, 6), and, although the x-ray structure corresponds to a closed channel conformation, it has contributed much to our current understanding of ion selectivity and permeation. Ironically, there was little or no functional information on KcsA by the time its structure was solved, and then several groups undertook the task of characterizing its single channel properties, which has been surrounded by controversy. For instance, Schrempf's group, discoverers of KcsA in S. lividans, reported a strong dependence of channel opening on acidic pH, multiple conductance states with opening probabilities near 0.5, and unusual permeabilities to Na ϩ , Li ϩ , Ca 2ϩ , or Mg 2ϩ , along with K ϩ (7-9). In contrast, Miller's group (10, 11) using purified KcsA reconstituted into planar lipid bilayers found a single conductance state with a much lower opening probability, as well as orthodox ion selectivity and other properties to validate KcsA as a bona fide K ϩ channel and as a faithful structural model for these molecules. The above discrepancies were never fully explained but, still, it became generally accepted that KcsA behaves as a moderately voltage-dependent, K ϩ -selective channel with a characteristic low opening probability and the peculiar property of opening only in response to very acidic pH condit...
Abstract-Recent studies have shown that the epithelial sodium channel (ENaC) is expressed in vascular tissue. However, the role that ENaC may play in the responses to vasoconstrictors and NO production has yet to be addressed. In this study, the contractile responses of perfused pressurized small-diameter rat mesenteric arteries to phenylephrine and serotonin were reduced by ENaC blockade with amiloride (75.1Ϯ3.2% and 16.9Ϯ2.3% of control values, respectively; PϽ0.01) that was dose dependent (EC 50 ϭ88.9Ϯ1.6 nmol/L). Incubation with benzamil, another ENaC blocker, had similar effects. ␣, , and ␥ ENaC were identified in small-diameter rat mesenteric arteries using RT-PCR and Western blot with specific antibodies. In situ hybridization and immunohistochemistry localized ENaC expression to the tunica media and endothelium of small-diameter rat mesenteric arteries. Patch-clamp experiments demonstrated that primary cultures of mesenteric artery endothelial cells expressed amiloride-sensitive sodium currents. Mechanical ablation of the endothelium or inhibition of eNOS with N -nitro-L-arginine inhibited the reduction in contractility caused by ENaC blockers. ENaC inhibitors increased eNOS phosphorylation (Ser 1177) and Akt phosphorylation (Ser 473). The presence of the phosphoinositide 3-kinase inhibitor LY294002 blunted Akt phosphorylation and eNOS phosphorylation and the decrease in the response to phenylephrine caused by blockers of ENaC, indicating that the phosphoinositide 3-kinase/Akt pathway was activated after ENaC inhibition. Finally, we observed that the effects of blockers of ENaC were flow dependent and that the vasodilatory response to shear stress was enhanced by ENaC blockade. Our results identify a previously unappreciated role for ENaC as a negative modulator of eNOS and NO production in resistance arteries.
KcsA is a prokaryotic potassium channel formed by the assembly of four identical subunits around a central aqueous pore. Although the high-resolution X-ray structure of the transmembrane portion of KcsA is known [Doyle, D. A., Morais, C.
Fiber cells of the lens are electrically and diffusionally interconnected through extensive gap junctions. These junctions allow fluxes of small solutes to move between inner cells and peripheral cells, where the majority of transmembrane transport takes place. We describe here a method utilizing two intracellular microelectrodes to measure the cell to cell resistance between fiber cells at any given distance into the intact lens. We also use ion-sensitive microelectrodes to record intracellular pH at various depths in the intact lens. We find that gap junctions connecting inner fiber cells differ in pH sensitivity as well as normal coupling resistance from those connecting peripheral cells. The transition occurs in a zone between 500 and 650 microns into the lens. Fiber cells peripheral to this zone have a specific coupling resistance of 1.1 omega cm2, whereas those inside have a specific coupling resistance of 2.7 omega cm2. However, when the cytoplasm of fiber cells is acidified by bubbling with CO2, peripheral cells uncouple and the cell to cell resistance goes up more than 40-fold, whereas junctions inside this zone are essentially unaffected by changes in intracellular pH. In a normal frog lens, the intracellular pH in fiber cells near the lens surface is 7.02, a value significantly alkaline to electrochemical equilibrium. Our data suggest that Na/H exchange and perhaps other Na gradient-dependent mechanisms in the peripheral cells maintain this transmembrane gradient. Deep in the lens, the fiber cell cytoplasm is significantly more acidic (pHi 6.81) due to influx of hydrogen across the inner fiber cell membranes and production of H+ by the inner fiber cells. Because of the normally acid cytoplasm of interior fiber cells, their loss of gap junctional sensitivity to pH may be essential to lens survival.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.