Identification of an Amiloride Binding Domain within the α-Subunit of the Epithelial Na+ Channel

Ismailov, Iskander I.; Kieber‐Emmons, Thomas; Lin, Chaomei; Berdiev, Bakhrom K.; Shlyonsky, Vadim; Patton, Holly K.; Fuller, Catherine M.; Worrell, Roger T.; Zuckerman, Jonathan B.; Sun, Weijing; Eaton, Douglas C.; Benos, Dale J.; Kleyman, Thomas R.

doi:10.1074/jbc.272.34.21075

Cited by 67 publications

(57 citation statements)

References 40 publications

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“…5C). However, it has been reported that mutation of residues at a site in the extracellular domain also disrupted block by amiloride, raising the possibility that amiloride might block the channel indirectly through an allosteric mechanism (35). If this is the case, then the site between Gly 533 and Gly 536 might not be a binding site for amiloride, but rather the site of a conformational change that occludes the pore in response to the binding of amiloride to a distant site.…”

Section: Discussionmentioning

confidence: 92%

A Pore Segment in DEG/ENaC Na+ Channels

Snyder

Olson

Bucher

1999

Journal of Biological Chemistry

138

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DEG/ENaC Na؉ channels have diverse functions, including Na ؉ absorption, neurotransmission, and sensory transduction. The ability of these channels to discriminate between different ions is critical for their normal function. Several findings suggest that DEG/ ENaC channels have a pore structure similar to K ؉ channels. To test this hypothesis, we examined the accessibility of native and introduced cysteines in the putative P loop of ENaC. We identified residues that span a barrier that excludes amiloride as well as anionic and large methanethiosulfonate reagents from the pore. This segment contains a structural element ((S/G)CS) involved in selectivity of ENaC. The results are not consistent with predictions from the K ؉ channel pore, suggesting that DEG/ENaC Na ؉ channels have a novel pore structure.

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Section: Discussionmentioning

confidence: 92%

A Pore Segment in DEG/ENaC Na+ Channels

Snyder

Olson

Bucher

1999

Journal of Biological Chemistry

138

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“…However, previous studies have identified a region in the extracellular loop of rat ␣-ENaC between amino acids 278 and 283, with the sequence WYRFHY, that interacts with amiloride (12). When this stretch of amino acids, located just COOH terminal to the first transmembrane-spanning domain within a cysteinerich domain, is deleted or mutated, amiloride binding of these channels expressed in a bilayer system is dramatically reduced.…”

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confidence: 99%

“…open probability; extracellular loop; channel pore; sodium channel; single-channel recording EPITHELIAL SODIUM CHANNELS (ENaC) play a critical role in the control of blood pressure and regulation of total body sodium balance. Although the original work in which the channel components were cloned suggested that functional channels consist of three subunits, ␣, ␤, and ␥ (5), under appropriate circumstances, ␣-subunits alone can form sodium-permeable channels (12,13,17). It has been proposed that some of the diversity in conductance, gating, and selectivity of functional ENaC may be due to different subunit combinations.…”

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confidence: 99%

Characterization of an amiloride binding region in the α-subunit of ENaC

Kelly¹,

Lin²,

Mohan³

et al. 2003

American Journal of Physiology-Renal Physiology

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.-One of the defining characteristics of the epithelial sodium channel (ENaC) is its block by the diuretic amiloride. This study investigates the role of the extracellular loop of the ␣-subunit of ENaC in amiloride binding and stabilization. Mutations were generated in a region of the extracellular loop, residues 278-283. Deletion of this region, WYRFHY, resulted in a loss of amiloride binding to the channel. Channels formed from wild-type ␣-subunits or ␣-subunits containing point mutations in this region were examined and compared at the single-channel level. The open probabilities (P o) of wild-type channels were distributed into two populations: one with a high P o and one with a low P o. The mean open times of all the mutant channels were shorter than the mean open time of the wild-type (high-P o) channel. Besides mutations Y279A and H282D, which had amiloride binding affinities similar to that of wild-type ␣-ENaC, all other mutations in this region caused changes in the amiloride binding affinity of the channels compared with the wild-type channel. These data provide new insight into the relative position of the extracellular loop with respect to the pore of ENaC and its role in amiloride binding and channel gating. open probability; extracellular loop; channel pore; sodium channel; single-channel recording EPITHELIAL SODIUM CHANNELS (ENaC) play a critical role in the control of blood pressure and regulation of total body sodium balance. Although the original work in which the channel components were cloned suggested that functional channels consist of three subunits, ␣, ␤, and ␥ (5), under appropriate circumstances, ␣-subunits alone can form sodium-permeable channels (12,13,17). It has been proposed that some of the diversity in conductance, gating, and selectivity of functional ENaC may be due to different subunit combinations. The expression of ␣-subunits alone, rather than the expression of all three subunits together, depends on the environmental conditions to which renal epithelial cells (A6) (7) or alveolar type II cells (14) are exposed. However, regardless of which channel type is expressed, one of the defining characteristics of all these channels is their block by the diuretic amiloride, a substituted pyrazinoylguanidine. The tertiary structure of all the subunits is similar: each subunit is predicted to span the membrane twice, to have a large extracellular loop, and to have short intracellular NH 2 and COOH termini (2, 6). Because amiloride blocks the channel from the extracellular surface of the channel protein, it is possible that one or more of the extracellular loops could play a role in amiloride's interaction with and block of the channel by stabilizing amiloride in the channel pore.About 70% of each ENaC subunit is extracellular. Structure-function studies of the extracellular loop have focused primarily on the region immediately preceding and including the second transmembrane (M2) domain of ␣-ENaC. These data have implicated these regions in binding to amiloride and also play a role in...

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“…Recent work examining the properties of channels composed solely of ␣-subunits identified a domain within the extracellular loop of ␣-rENaC (residues 278 -283) where mutations or deletions affect amiloride block as well as the open probability of the channels (14,17). Furthermore, selected mutations within this region of ␣-ENaC or within the corresponding region of ␥-ENaC altered the channel's response to external Ni 2ϩ (27) and to changes in extracellular Na ϩ (26).…”

Section: Discussionmentioning

confidence: 99%

“…In channels composed solely of ␣-subunits, mutations in this domain affect both channel gating and channel block by amiloride (14,17). This region within the ␣-subunit includes residues 278 -283 (WYRFHY).…”

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confidence: 99%

Mutations in the extracellular loop of α-rENaC alter sensitivity to amiloride and reactive species

Chen

Fuller²,

Kleyman³

et al. 2004

American Journal of Physiology-Renal Physiology

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Matalon. Mutations in the extracellular loop of ␣-rENaC alter sensitivity to amiloride and reactive species. Am J Physiol Renal Physiol 286: F1202-F1208, 2004. First published February 17, 2004 10.1152/ajprenal. 00352.2003.-We studied the effects of two mutations of the extracellular loop of the ␣-subunit of the (ENaC) on amiloride-sensitive current in Xenopus laevis oocytes and the inhibition of this current by 3-morpholinosydnonimine (SIN-1). Injection of oocytes with wild-type (wt) ␣-,␤-,␥-rENaC cRNA (8.3 ng/subunit) resulted 48 -72 h later in inward Na ϩ currents (Ϫ5.5 Ϯ 0.8 A; means Ϯ SE at Ϫ100 mV; n ϭ 21), which were completely inhibited by amiloride. Oocytes injected with either ␣ Y279A-or ␣Y283A-and ␤-,␥-rENaC cRNAs had significantly lower Na ϩ currents. Furthermore, ␣Y279A-,␤-,␥-rENaC-injected oocytes had a higher K i for amiloride (0.54 Ϯ 0.97 vs. 0.10 Ϯ 0.04 M; P Ͻ 0.01). Exposure of oocytes to SIN-1 (1 mM) for 5 min decreased both total Na ϩ and amiloride-sensitive currents across wt and ␣Y279A-but not ␣ Y283A-,␤-,␥-rENaC. Furthermore, exposure to SIN-1 increased the Ki for amiloride across wt but not ␣Y279A-,␤-,␥-rENaC-injected oocytes. These data indicate that both tyrosines are important for proper ENaC function and their oxidative modifications contribute to altered ENaC function.

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Identification of an Amiloride Binding Domain within the α-Subunit of the Epithelial Na+ Channel

Cited by 67 publications

References 40 publications

A Pore Segment in DEG/ENaC Na+ Channels

A Pore Segment in DEG/ENaC Na+ Channels

Characterization of an amiloride binding region in the α-subunit of ENaC

Mutations in the extracellular loop of α-rENaC alter sensitivity to amiloride and reactive species

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