Molecular principles of assembly, activation, and inhibition in epithelial sodium channel.

The molecular bases of heteromeric assembly and link between Na+ self-inhibition and protease-sensitivity in epithelial sodium channels (ENaCs) are not fully understood. Previously, we demonstrated that ENaC subunits - α, ß, and γ - assemble in a counterclockwise configuration when viewed from outside the cell with the protease-sensitive GRIP domains in the periphery (Noreng et al., 2018). Here we describe the structure of ENaC resolved by cryo-electron microscopy at 3 Å. We find that a combination of precise domain arrangement and complementary hydrogen bonding network defines the subunit arrangement. Furthermore, we determined that the α subunit has a primary functional module consisting of the finger and GRIP domains. The module is bifurcated by the α2 helix dividing two distinct regulatory sites: Na+ and the inhibitory peptide. Removal of the inhibitory peptide perturbs the Na+ site via the α2 helix highlighting the critical role of the α2 helix in regulating ENaC function.

Structure of the human epithelial sodium channel by cryo-electron microscopy.

The epithelial sodium channel (ENaC), a member of the ENaC/DEG superfamily, regulates Na+ and water homeostasis. ENaCs assemble as heterotrimeric channels that harbor protease-sensitive domains critical for gating the channel. Here, we present the structure of human ENaC in the uncleaved state determined by single-particle cryo-electron microscopy. The ion channel is composed of a large extracellular domain and a narrow transmembrane domain. The structure reveals that ENaC assembles with a 1:1:1 stoichiometry of α:ß:γ subunits arranged in a counter-clockwise manner. The shape of each subunit is reminiscent of a hand with key gating domains of a 'finger' and a 'thumb.' Wedged between these domains is the elusive protease-sensitive inhibitory domain poised to regulate conformational changes of the 'finger' and 'thumb'; thus, the structure provides the first view of the architecture of inhibition of ENaC.

Aldosterone Modulates the Association between NCC and ENaC.

Distal sodium transport is a final step in the regulation of blood pressure. As such, understanding how the two main sodium transport proteins, the thiazide-sensitive sodium chloride cotransporter (NCC) and the epithelial sodium channel (ENaC), are regulated is paramount. Both are expressed in the late distal nephron; however, no evidence has suggested that these two sodium transport proteins interact. Recently, we established that these two sodium transport proteins functionally interact in the second part of the distal nephron (DCT2). Given their co-localization within the DCT2, we hypothesized that NCC and ENaC interactions might be modulated by aldosterone (Aldo). Aldo treatment increased NCC and αENaC colocalization (electron microscopy) and interaction (coimmunoprecipitation). Finally, with co-expression of the Aldo-induced protein serum- and glucocorticoid-inducible kinase 1 (SGK1), NCC and αENaC interactions were increased. These data demonstrate that Aldo promotes increased interaction of NCC and ENaC, within the DCT2 revealing a novel method of regulation for distal sodium reabsorption.

Larval bullfrog skin lacks amiloride-blockable epithelial transport because α-ENaC is located within intracellular vesicles in epidermal apical cells and not in the apical plasma membrane.

The epithelial Na channel (ENaC) plays an essential role in sodium transport across epithelia such as adult frog skin. Transport across the skin, measured as short-circuit current (SCC), is blocked by amiloride. Bullfrog alpha-ENaC (α-fENaC) is expressed in adult bullfrog skin, and the SCC across this skin is blocked by amiloride. In contrast, an amiloride-blockable SCC is not detected in larval bullfrog skin, even though it expresses α-fENaC. We examined the subcellular localization of α-ENaC in such larval and adult skins. Immunofluorescent and immunoelectron microscopy of apical cells in the larval epidermis revealed α-fENaC localization within intracellular vesicles, but not in the plasma membrane. In contrast, in adult skin α-fENaC was localized to the apical-side membrane and to intracellular vesicles in Stratum granulosum cells. This may support the view that amiloride-blockable SCC is absent from larval skin, but is present in adult skin.

Thermal and chemical unfolding and refolding of a eukaryotic sodium channel.

Voltage-gated sodium channels are dynamic membrane proteins essential for signaling in nervous and muscular systems. They undergo substantial conformational changes associated with the closed, open and inactivated states. However, little information is available regarding their conformational stability. In this study circular dichroism spectroscopy was used to investigate the changes in secondary structure accompanying chemical and thermal denaturation of detergent-solubilised sodium channels isolated from Electrophorus electricus electroplax. The proteins appear to be remarkably resistant to either type of treatment, with "denatured" channels, retaining significant helical secondary structure even at 77 degrees C or in 10% SDS. Further retention of helical secondary structure at high temperature was observed in the presence of the channel-blocking tetrodotoxin. It was possible to refold the thermally-denatured (but not chemically-denatured) channels in vitro. The correctly refolded channels were capable of undergoing the toxin-induced conformational change indicative of ligand binding. In addition, flux measurements in liposomes showed that the thermally-denatured (but not chemically-denatured) proteins were able to re-adopt native, active conformations. These studies suggest that whilst sodium channels must be sufficiently flexible to undergo major conformational changes during their functional cycle, the proteins are highly resistant to unfolding, a feature that is important for maintaining structural integrity during dynamic processes.

Presence and regulation of epithelial sodium channels in the marginal cells of stria vascularis.

CONCLUSION: This study indicates that epithelial Na(+)-selective channels (ENaC) recycle Na(+) via clathrin-mediated endocytosis in the marginal cells of the stria vascularis and that clathrin-independent endocytosis appeared to be modulated by the amount of Na(+) transported. These results suggest the presence of ENaC in the luminal membrane of marginal cells and that ENaC are an efficient pathway for the uptake of Na(+) from the endolymph. OBJECTIVE: The ENaC found in many transporting epithelia play a key role in the regulation of salts and water homeostasis, cellular pH, cell volume, and cell function. Both biochemical and physiological approaches have been used to identify, characterize, and quantify this important channel, but its location in the marginal cells of the stria vascularis has not been fully clarified. The aim of this study was to determine the localization and regulation of ENaC. MATERIALS AND METHODS: Forty healthy female guinea pigs were used: 20 for the control experiment, 10 for the amiloride experiment, and 10 for the aldosterone experiment. We perfused cationized ferritin (CF) and microperoxidase (MPO) as tracers for clathrin-mediated and clathrin-independent endocytosis, respectively, into the cochlear duct. After 30 min of endolymphatic perfusion, the tissues were fixed and CF- and MPO-loaded endosomes within the marginal cell were observed by transmission electron microscopy. The numbers of CF- and MPO-loaded endosomes were compared between the three groups. RESULTS: In the amiloride group, the numbers of CF- and MPO-loaded endosomes decreased in comparison with the control. In the aldosterone group, the numbers of CF- and MPO-loaded endosomes decreased and increased, respectively. Recently, it has been reported that ENaC are endocytosed via clathrin-mediated endosomes and aldosterone decreases the rate of endocytosis of ENaC. In this study, the results of the aldosterone experiment were consistent with those of recent studies.

Nanoscale organization of the MEC-4 DEG/ENaC sensory mechanotransduction channel in Caenorhabditis elegans touch receptor neurons.

Hearing, touch and proprioception are thought to involve direct activation of mechano-electrical transduction (MeT) channels. In Caenorhabditis elegans touch receptor neurons (TRNs), such channels contain two pore-forming subunits (MEC-4 and MEC-10) and two auxiliary subunits (MEC-2 and MEC-6). MEC-4 and MEC-10 belong to a large superfamily of ion channel proteins (DEG/ENaCs) that form nonvoltage-gated, amiloride-sensitive Na+ channels. In TRNs, unique 15-protofilament microtubules and an electron-dense extracellular matrix have been proposed to serve as gating tethers critical for MeT channel activation. We combined high-pressure freezing and serial-section immunoelectron microscopy to determine the position of MeT channels relative to putative gating tethers. MeT channels were visualized using antibodies against MEC-4 and MEC-2. This nanometer-resolution view of a sensory MeT channel establishes structural constraints on the mechanics of channel gating. We show here that MEC-2 and MEC-5 collagen, a putative extracellular tether, occupy overlapping but distinct domains in TRN neurites. Although channels decorate all sides of TRN neurites; they are not associated with the distal endpoints of 15-protofilament microtubules hypothesized to be gating tethers. These specialized microtubules, which are unique to TRNs, assemble into a cross-linked bundle connected by a network of kinked filaments to the neurite membrane. We speculate that the microtubule bundle converts external point loads into membrane stretch which, in turn, facilitates MeT channel activation.