Zachary Zuzek scite author profile

The epithelial Na ؉ channel (ENaC) mediates Na ؉ transport across high resistance epithelia. This channel is assembled from three homologous subunits with the majority of the protein's mass found in the extracellular domains. Acid-sensing ion channel 1 (ASIC1) is homologous to ENaC, but a key functional domain is highly divergent. Here we present molecular models of the extracellular region of ␣ ENaC based on a large data set of mutations that attenuate inhibitory peptide binding in combination with comparative modeling based on the resolved structure of ASIC1. The models successfully rationalized the data from the peptide binding screen. We engineered new mutants that had not been tested based on the models and successfully predict sites where mutations affected peptide binding. Thus, we were able to confirm the overall general fold of our structural models. Further analysis suggested that the ␣ subunit-derived inhibitory peptide affects channel gating by constraining motions within two major domains in the extracellular region, the thumb and finger domains.Epithelial Na ϩ channels (ENaCs) 3 are members of the ENaC/degenerin family of ion channels, of which the high resolution structure of acid-sensing ion channel 1 (ASIC1) has been reported. These channels are probably trimers (1, 2) with each subunit having two transmembrane helices, large extracellular regions, and short cytosolic amino and carboxyl termini (3). The resolved structure of the extracellular region of ASIC1 is composed of core ␤-sheet domains (termed palm and ␤-ball) surrounded by peripheral ␣-helical domains (termed finger, thumb, and knuckle) (1). Channels in the ENaC/degenerin family are Na ϩ -permeable and are gated by a diverse set of stimuli, including external ligands and mechanical forces (4). As such, ENaC/degenerin family members play diverse roles in biology. For ENaC, these include the regulation of extracellular volume and blood pressure by mediating Na ϩ transport in the distal nephron of the kidney, regulation of airway surface liquid volume and mucociliary clearance by facilitating Na ϩ transport in airways, and facilitation of salt taste by transporting Na ϩ in lingual epithelium (4). ENaC is assembled from homologous ␣, ␤, and ␥ subunits and is allosterically inhibited by extracellular Na ϩ by a phenomenon referred to as Na ϩ self-inhibition (5-7). Within the ENaC/degenerin family, sequence conservation is conspicuously lacking within the finger domains of the extracellular regions of these channels (1). This fact may partly account for the diversity in the regulation of channel gating observed among gene family members and is an obstacle in building comparative models of ENaC subunits based on the resolved ASIC1 structure.Among the panoply of ENaC properties is its activation by proteolytic cleavage, which is unusual for ion channels (8). Proteolytic activation of ENaC occurs through the cleavage of both the ␣ and ␥ subunits at multiple sites within their finger domains, leading to the release of inhibitory tracts (9 -12). Pe...

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Na+ Inhibits the Epithelial Na+ Channel by Binding to a Site in an Extracellular Acidic Cleft

Kashlan

Blobner

Zuzek

et al. 2015

Journal of Biological Chemistry

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Inhibitory Tract Traps the Epithelial Na+ Channel in a Low Activity Conformation

Kashlan

Blobner

Zuzek

et al. 2012

Journal of Biological Chemistry

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Background: Proteases activate ENaC by releasing inhibitory tracts. Results: Inhibitory peptides cross-link to the finger and thumb domains of ENaC. Simply cross-linking these domains inhibits channel activity. Conclusion: Inhibitory peptides bind at a finger-thumb interface, inhibiting the channel by maintaining the interface in a tight conformation. Significance: These observations provide insights regarding the mechanisms of channel activation by proteases.

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Role of a PH Sensitive Site in Enac Na+ Self-Inhibition

Kashlan

Blobner

Zuzek

et al. 2014

Biophysical Journal

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The epithelial Na þ channel (ENaC) is key to the regulation of extracellular fluid volume and blood pressure through its action in the aldosterone-sensitive nephron. Inhibition of ENaC by extracellular Na þ , referred to as Na þ self-inhibition, likely occurs through an allosteric mechanism of Na þ binding to low affinity sites in the large extracellular regions of ENaC subunits. The effector binding sites and transduction pathways remain unidentified. A recent comparative model of the ENaC a subunit revealed an acidic cleft, analogous to the acidic region observed in the resolved structure of acid sensing ion channel 1 (ASIC1). We hypothesized that this cleft and analogous clefts in the and subunits host Na þ effector sites. Mutations of acidic residues in the subunit acidic cleft led us to identify an aspartate on the loop connecting the central palm and b-ball domains that reaches towards the finger domain. We also identified nearby sites on the loop and other structures that affected Na þ self-inhibition. To determine whether these sites were involved in effector coordination, we measured the ability of mutants to change the effector specificity of Na þ self-inhibition, which is Na þ > Li þ >> K þ for wild type mouse ENaC. Mutation of the palm/-ball loop aspartate and several nearby sites weakened Na þ inhibition relative to Li þ and K þ inhibition. We hypothesized that protonating any carboxylate groups involved in Na þ coordination would weaken Na þ binding. Consistent with this, lowering the pH to 4.7 increased ENaC currents and reduced Na þ self-inhibition. Mutation of the palm/b-ball loop aspartate reversed pH activation of ENaC. Our results suggest that an aspartate in the acidic cleft of the subunit may coordinate Na þ for Na þ self-inhibition. 3803-Pos Board B531 VDAC-Kinase Electrogenic Complexes as Direct Generators of Mitochondrial Membrane PotentialsVictor V. Lemeshko. Escuela de Fisica, Universidad Nacional de Colombia, Medellin, Colombia. The voltage dependent anion channel (VDAC) is a main metabolic pathway between mitochondria and the cytosol. Although VDAC's electrical characteristics are well known, VDAC is still considered as a constantly open pore in physiological conditions, or as regulated with ''molecular corks'' of various types. On the other hand, one of the unresolved problems, according to Colombini and Mannella (BBA, vol. 1818, 2012), remains the role of VDAC's highly conserved voltage gating properties. Earlier, we have proposed several possible mechanisms of generation of the mitochondrial outer membrane potential (OMP). According to one of them, the OMP might result from the application in part of the inner membrane potential (IMP) to the outer membrane through the intermembrane contact sites ANT (adenine nucleotide translocator)-VDAC, or AND-VDAC-HK (hexokinase). Even VDAC-HK electrogenic complex has been considered to function as a direct generator of the OMP, using the Gibbs free energy of the HK reaction. Here, we further developed this concept showing with a simple computat...

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Conformational trapping of the closed state of ENaC using sites at the finger –thumb domain interface of the alpha subunit

et al. 2011

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Zachary Zuzek

Constraint-based, Homology Model of the Extracellular Domain of the Epithelial Na+ Channel α Subunit Reveals a Mechanism of Channel Activation by Proteases

Na+ Inhibits the Epithelial Na+ Channel by Binding to a Site in an Extracellular Acidic Cleft

Inhibitory Tract Traps the Epithelial Na+ Channel in a Low Activity Conformation

Role of a PH Sensitive Site in Enac Na+ Self-Inhibition

Conformational trapping of the closed state of ENaC using sites at the finger –thumb domain interface of the alpha subunit

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