Sodium Flux Ratio in Na/K Pump-Channels Opened by Palytoxin

Rakowski, Robert F.; Artigas, Pablo; Palma, Francisco; Holmgren, Miguel; Weer, Paul De; Gadsby, David C.

doi:10.1085/jgp.200709770

Cited by 18 publications

(7 citation statements)

References 52 publications

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“…That ∼6-Å wide × ∼12-Å long MTSET + , MTSES - , and MTSACE pass through palytoxin-bound Na + ,K + pump-channels corroborates the findings that these channels conduct N-methyl-D-glucamine ions (diameter ≥7 Å) only ∼50 fold more slowly than Na + ions22, and that their measured27 Na + flux ratio exponent28 is ∼1.0, implying little interaction between Na + ions in a queue along the principal pathway that passes through site II. Occupancy by a second Na + ion of site I, off the main pathway but linked to it via a connection narrow enough to preclude reactivity with MTSET + , could account for suggested average pump-channel occupancy by two Na + ions23.…”

supporting

confidence: 75%

The ion pathway through the opened Na+,K+-ATPase pump

Takeuchi

Reyes

Artigas

et al. 2008

Nature

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P-type ATPases pump ions across membranes, generating steep electrochemical gradients that are essential for the function of all cells. Access to the ion-binding sites within the pumps alternates between the two sides of the membrane1 to avoid the dissipation of the gradients that would occur during simultaneous access. In Na+,K+-ATPase pumps treated with the marine agent palytoxin, this strict alternation is disrupted and binding sites are sometimes simultaneously accessible from both membrane sides, transforming the pumps into ion channels (e.g., refs 2,3). Current recordings in these channels can monitor accessibility of introduced cysteine residues to water-soluble sulphydryl-specific reagents4. We found previously5 that Na+,K+ pump-channels open to the extracellular surface through a deep and wide vestibule that emanates from a narrower pathway between transmembrane helices TM4 and TM6. Here we report that cysteine scans from TM1 through TM6 reveal a single unbroken cation pathway that traverses palytoxin-bound Na+,K+ pump-channels from one side of the membrane to the other. This pathway comprises residues from TM1, TM2, TM4, and TM6, passes through ion-binding site II, and is likely conserved in structurally and evolutionarily related P-type pumps, such as SERCA- and H+,K+-ATPases.

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supporting

confidence: 75%

The ion pathway through the opened Na+,K+-ATPase pump

Takeuchi

Reyes

Artigas

et al. 2008

Nature

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“…Specifically, a double mutation of residues flanking the central Cl − in the E. coli ClC 2Cl − /H + exchanger converts the transporter into a channel likely by stabilizing conformations where inner and outer gates are open 34 . The Na + -K + -ATPase (the ATP-dependent Na + /K + -exchanger) is converted into a cation channel when bound to palytoxin likely by uncoupling the inner and outer gates 35 . Finally, naturally occurring mutations in AE1 block its anion exchange activity and uncover a monovalent cation conductance 30 , 36 .…”

Section: Discussionmentioning

confidence: 99%

CryoEM structure of the human SLC4A4 sodium-coupled acid-base transporter NBCe1

et al. 2018

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Na+-coupled acid–base transporters play essential roles in human biology. Their dysfunction has been linked to cancer, heart, and brain disease. High-resolution structures of mammalian Na+-coupled acid–base transporters are not available. The sodium-bicarbonate cotransporter NBCe1 functions in multiple organs and its mutations cause blindness, abnormal growth and blood chemistry, migraines, and impaired cognitive function. Here, we have determined the structure of the membrane domain dimer of human NBCe1 at 3.9 Å resolution by cryo electron microscopy. Our atomic model and functional mutagenesis revealed the ion accessibility pathway and the ion coordination site, the latter containing residues involved in human disease-causing mutations. We identified a small number of residues within the ion coordination site whose modification transformed NBCe1 into an anion exchanger. Our data suggest that symporters and exchangers utilize comparable transport machinery and that subtle differences in their substrate-binding regions have very significant effects on their transport mode.

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“…These slow turnover values contrast with the much faster transport rates in ion channels (10 7 –10 8 s −1 ). Thus, none of these Na/K pump α1 mutants can be considered bona fide channels, like those induced by binding of the Na/K pump–specific marine toxin palytoxin, which opens a pump channel that transports millions of cations per second ( Artigas and Gadsby, 2004 ; Rakowski et al, 2007 ). Rather, these mutations appear to destabilize ion-occlusion reactions, an effect resembling the alterations produced by deletion or mutation of the α-subunit C-terminal end, which also induce leaky pumps under near-physiological Na + o ( Yaragatupalli et al, 2009 ; Meier et al, 2010 ; Vedovato and Gadsby, 2010 ).…”

Section: Discussionmentioning

confidence: 99%