Structure of the KvAP voltage-dependent K
            <sup>+</sup>
            channel and its dependence on the lipid membrane

Lee, Seok‐Yong; Lee, Alice; Chen, Jiayun; MacKinnon, Roderick

doi:10.1073/pnas.0507651102

Cited by 293 publications

(329 citation statements)

References 22 publications

(28 reference statements)

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“…Forcing conditions also result in weak cross-links in two new regions: the S2-S3 turn, which is also known as the membrane interface anchor (positions 164 and 173) (7), and the tip of the voltage sensor paddle (positions 187 and 194) (Fig. 3 c and d) (6).…”

Section: Resultsmentioning

confidence: 99%

Dimeric subunit stoichiometry of the human voltage-dependent proton channel Hv1

Lee

Letts

MacKinnon

2008

Proc. Natl. Acad. Sci. U.S.A.

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174

269

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In voltage-gated Na ؉ , K ؉ , and Ca 2؉ channels, four voltage-sensor domains operate on a central pore domain in response to membrane voltage. In contrast, the voltage-gated proton channel (Hv) contains only a voltage-sensor domain, lacking a separate pore domain. The subunit stoichiometry and organization of Hv has been unknown. Here, we show that human Hv1 forms a dimer in the membrane and define regions that are close to the dimer interface by using cysteine cross-linking. Two dimeric interfaces appear to exist in Hv1, one mediated by S1 and the adjacent extracellular loop, and the other mediated by a putative intracellular coiled-coil domain. It may be significant that Hv1 uses for its dimer interface a surface that corresponds to the interface between the voltage sensor and pore in Kv channels.membrane protein ͉ voltage-dependent ion channel ͉ voltage sensor V oltage-gated six-transmembrane cation channels (Na ϩ , K ϩ , and Ca 2ϩ ) contain voltage-sensor and pore domains (1). In this class of ion channels voltage-sensor and pore domains carry out voltage sensing and cation conduction, respectively. Four voltage-sensor domains surround a single, centrally located ion conduction pathway. Each voltage sensor is attached to the pore in a specific manner so that conformational changes within the voltage sensors are transmitted to the pore's gate (2). It was originally thought that voltage-sensor domains existed only in the context of voltage-gated cation channels. However, the cloning of voltage-gated proton (Hv) channels and voltagesensor phosphatase enzymes revealed that voltage-sensor domains also exist in other contexts, apparently as independent (of a cation pore) membrane proteins (3-5), corroborating the studies of MacKinnon and coworkers (2, 6, 7) and Lu and coworkers (8) that supported the idea that voltage sensors, even in the context of voltage-dependent cation channels, are rather loosely attached to the central pore.The long-sought molecular identity of Hv1 (9) showed that it contains only a voltage-sensor domain without a separate pore domain in the membrane (3, 4). This observation suggested that in contrast to canonical voltage-dependent cation channels, the voltage-sensor domain of Hv1 is responsible for both H ϩ conduction and voltage sensing. In this study we evaluate the subunit stoichiometry of the Hv1 channel in cell membranes. ResultsHv1 Is a Dimer in the Membrane. To probe the oligomeric state of Hv1, cell membranes isolated from tsA201 cells (HEK293 derivatives) transfected with human Hv1 cDNAs were subjected to the amino-group specific bifunctional cross-linker disuccinimidyl suberate (DSS) and visualized by Western blot analysis using antibodies directed against the Hv1 channel. Amino groupspecific cross-linkers have been successful in defining the oligomeric status of several membrane proteins (10-12). Recombinant Hv1 makes functional channels in HEK293 cells (3, 4). In Fig. 1a, human Hv1 migrates at Ϸ35 kDa in SDS/PAGE under reducing conditions, which is consistent with the molecula...

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Section: Resultsmentioning

confidence: 99%

Dimeric subunit stoichiometry of the human voltage-dependent proton channel Hv1

Lee

Letts

MacKinnon

2008

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

174

269

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“…HaTx does not interact tightly with either KvAP or Kv1.2, the two Kv channels for which X-ray structures are available, and the sequence similarity between these channels and Kv2.1 is quite low, precluding assignment of crucial residues within the existing structures. The interaction of VSTx1 with chimeras containing the entire paddle of KvAP (Fig 2), however, offers an opportunity to explore the structure of a tarantula toxin receptor because there are three X-ray structures of KvAP 1,8 , and the structure of the paddle motif in these is very similar (whether or not an antibody is bound). To define critical residues within the paddle motif that may interact with VSTx1, we Ala scanned the paddle region of the C*[S3-S4]AP chimera between KvAP and Shaker.…”

Section: Structural Analysis Of the Tarantula Toxin-paddle Interactionmentioning

confidence: 99%

Portability of paddle motif function and pharmacology in voltage sensors

Alabi

Bahamonde

Jung

et al. 2007

Nature

204

278

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Voltage-sensing domains enable membrane proteins to sense and react to changes in membrane voltage. Although identifiable S1-S4 voltage-sensing domains are found in an array of conventional ion channels and in other membrane proteins that lack pore domains, the extent to which their voltage sensing mechanisms are conserved is unknown. Here we show that the voltage-sensor paddle, a motif composed of S3b and S4 helices, can drive channel opening with membrane depolarization when transplanted from an archaebacterial voltage-activated potassium (Kv) channel (KvAP) or voltagesensing domain proteins (Hv1 and Ci-VSP) into eukaryotic Kv channels. Tarantula toxins that partition into membranes can interact with these paddle motifs at the protein-lipid interface and similarly perturb voltage sensor activation in both ion channels and voltage-sensing domain proteins. Our results show that paddle motifs are modular, that their functions are conserved in voltage sensors, and that they move in the relatively unconstrained environment of the lipid membrane. The widespread targeting of voltage-sensor paddles by toxins demonstrates that this modular structural motif is an important pharmacological target.Ion channels that open and close in response to changes in membrane voltage have a modular architecture, with a central pore domain that determines ion selectivity, and four surrounding voltage sensing domains that move in response to changes in membrane voltage to drive opening of the pore 1-5 (Fig 1a). Although X-ray structures have now been solved for two voltage-activated potassium (Kv) channels 1, 6-9 , the structural basis of voltage sensing remains controversial 10-12 . A seminal observation in the X-ray structures of the KvAP channel, an archaebacterial Kv channel from Aeropyrum pernix, was that the S3b helix and the charge-bearing S4 helix within the voltage-sensing domain form a helix-turn-helix structure, termed the paddle motif 1, 8, 9 . Studies on KvAP 1, 9, 13-16 suggest that this voltage-sensor paddle is buried in the membrane and that it moves at the protein-lipid interface, which contrasts with models for eukaryotic Kv channels where the S4 helix is protected from membrane lipids by other regions of the protein 10-12, 17-21 . Voltage-sensing domains have also recently been described in voltage-sensing proteins that lack associated pore domains 5, 22, 23 . In Ci-VSP the voltage-sensing domain is coupled to a phosphatase domain and in Hv1 the voltage-sensing domain itself is thought to function as a proton channel. Here we explore whether the mechanisms of voltage-sensing are conserved between the distantly related eukaryotic and Chimeras between Kv channelsWe began by generating chimeras between the archaebacterial KvAP channel 24 and the eukaryotic Kv2.1 channel from rat brain 25 to define the interchangeable regions. Transfer of the KvAP pore domain into Kv2.1 results in channels that open in response to membrane depolarization (Fig 1a ; Supplementary Fig 1 and Table 1), so long as the S4-S5 linker hel...

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“…It is now recognized that the first KvAP structure was likely distorted by crystallization conditions and its structure has been corrected and shown to be consistent with later structures of other VSDs. 22,23 Following the structure of KvAP, the next VSD to be defined at atomic level and considered a native, non-perturbed structure was part of the now paradigmatic structure of the Kv1.2 mammalian potassium channel. 24 This structure showed that the VSDs interact with the pore domain of an adjacent subunit and stand at the periphery of the whole channel.…”

Section: Introductionmentioning

confidence: 99%

Functional diversity of potassium channel voltage-sensing domains

Islas¹

2016

Channels

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Voltage-gated potassium channels or Kv's are membrane proteins with fundamental physiological roles. They are composed of 2 main functional protein domains, the pore domain, which regulates ion permeation, and the voltage-sensing domain, which is in charge of sensing voltage and undergoing a conformational change that is later transduced into pore opening. The voltagesensing domain or VSD is a highly conserved structural motif found in all voltage-gated ion channels and can also exist as an independent feature, giving rise to voltage sensitive enzymes and also sustaining proton fluxes in proton-permeable channels. In spite of the structural conservation of VSDs in potassium channels, there are several differences in the details of VSD function found across variants of Kvs. These differences are mainly reflected in variations in the electrostatic energy needed to open different potassium channels. In turn, the differences in detailed VSD functioning among voltage-gated potassium channels might have physiological consequences that have not been explored and which might reflect evolutionary adaptations to the different roles played by Kv channels in cell physiology.

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Structure of the KvAP voltage-dependent K ⁺ channel and its dependence on the lipid membrane

Cited by 293 publications

References 22 publications

Dimeric subunit stoichiometry of the human voltage-dependent proton channel Hv1

Dimeric subunit stoichiometry of the human voltage-dependent proton channel Hv1

Portability of paddle motif function and pharmacology in voltage sensors

Functional diversity of potassium channel voltage-sensing domains

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Structure of the KvAP voltage-dependent K + channel and its dependence on the lipid membrane

Cited by 293 publications

References 22 publications

Dimeric subunit stoichiometry of the human voltage-dependent proton channel Hv1

Dimeric subunit stoichiometry of the human voltage-dependent proton channel Hv1

Portability of paddle motif function and pharmacology in voltage sensors

Functional diversity of potassium channel voltage-sensing domains

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Product

Resources

About

Structure of the KvAP voltage-dependent K ⁺ channel and its dependence on the lipid membrane