Truncation of Kir6.2 produces ATP-sensitive K+ channels in the absence of the sulphonylurea receptor

Tucker, Stephen J.; Gribble, Fiona M.; Zhao, Chao; Trapp, Stefan; Ashcroft, Frances M.

doi:10.1038/387179a0

Cited by 717 publications

(966 citation statements)

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“…Assembly of Kir6.2 with SUR enhances ATP-induced inhibition of the channel pore [25], and defines the tissue-specific burst kinetics of K ATP channel behavior [5,34,35]. Furthermore, fundamental K ATP channel properties, including stimulation by MgADP and potassium channel openers as well as inhibition by sulfonylurea drugs that are absent in truncated Kir6.2 channels, are rescued by co-expression of Kir6.2 with SUR [25,36].…”

Section: Kir62 Pore-forming Subunit: Site Of K Atp Channel Atp Inhibmentioning

confidence: 98%

“…The poreforming Kir6.2 subunits cannot readily traffic to the plasma membrane alone, without the regulatory SUR module, due to a C-terminal RKR endoplasmic reticulum retention signal [23,24]. When engineered to be expressed independently of SUR through truncation of the Cterminal amino acids, the Kir6.2 subunit was identified as critical for K ATP channel inhibition by intracellular ATP [25,26]. Although a conventional nucleotide binding motif has not been identified within the Kir6.2 sequence, photoaffinity labeling and scanning with sulfhydryl group reagents accomplished by mutagenesis identified that both N-and C-termini may contribute to recognition of ATP [27,28,29].…”

Section: Kir62 Pore-forming Subunit: Site Of K Atp Channel Atp Inhibmentioning

confidence: 99%

“…Furthermore, fundamental K ATP channel properties, including stimulation by MgADP and potassium channel openers as well as inhibition by sulfonylurea drugs that are absent in truncated Kir6.2 channels, are rescued by co-expression of Kir6.2 with SUR [25,36].…”

Section: Kir62 Pore-forming Subunit: Site Of K Atp Channel Atp Inhibmentioning

confidence: 99%

“…Indeed, the classical allosteric model was successfully applied to nucleotidedependent K ATP channel gating [15] which presumed that four identical binding sites for ATP and ADP co-exist within the octameric stoichiometry of the K ATP channel complex [22]; binding of ATP to the pore-forming Kir6.2 subunit inhibits channel opening [25,26], whereas binding of ADP to the corresponding regulatory SUR subunit antagonizes ATP-binding to Kir6.2 [43,81]. Although this classic allosteric model of channel regulation was in agreement with experimentally defined nucleotide-dependent gating (i.e.…”

Section: Allosteric Regulation Of the K Atp Channel Complexmentioning

confidence: 99%

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ATP-sensitive K channel channel/enzyme multimer: Metabolic gating in the heart

Alekseev

Hodgson

Karger

et al. 2005

Journal of Molecular and Cellular Cardiology

108

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Cardiac ATP-sensitive K + (K ATP ) channels, gated by cellular metabolism, are formed by association of the inwardly rectifying potassium channel Kir6.2, the potassium conducting subunit, and SUR2A, the ATP-binding cassette protein that serves as the regulatory subunit. Kir6.2 is the principal site of ATP-induced channel inhibition, while SUR2A regulates K + flux through adenine nucleotide binding and catalysis. The ATPase-driven conformations within the regulatory SUR2A subunit of the K ATP channel complex have determinate linkage with the states of the channel's pore. The probability and life-time of ATPase-induced SUR2A intermediates, rather than competitive nucleotide binding alone, defines nucleotide-dependent K ATP channel gating. Cooperative interaction, instead of independent contribution of individual nucleotide binding domains within the SUR2A subunit, serves a decisive role in defining K ATP channel behavior. Integration of K ATP channels with the cellular energetic network renders these channel/enzyme heteromultimers high-fidelity metabolic sensors. This vital function is facilitated through phosphotransfer enzyme-mediated transmission of controllable energetic signals. By virtue of coupling with cellular energetic networks and the ability to decode metabolic signals, K ATP channels set membrane excitability to match demand for homeostatic maintenance. This new paradigm in the operation of an ion channel multimer is essential in providing the basis for K ATP channel function in the cardiac cell, and for understanding genetic defects associated with life-threatening diseases that result from the inability of the channel complex to optimally fulfill its physiological role.

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Section: Kir62 Pore-forming Subunit: Site Of K Atp Channel Atp Inhibmentioning

confidence: 98%

Section: Kir62 Pore-forming Subunit: Site Of K Atp Channel Atp Inhibmentioning

confidence: 99%

Section: Kir62 Pore-forming Subunit: Site Of K Atp Channel Atp Inhibmentioning

confidence: 99%

Section: Allosteric Regulation Of the K Atp Channel Complexmentioning

confidence: 99%

See 2 more Smart Citations

ATP-sensitive K channel channel/enzyme multimer: Metabolic gating in the heart

Alekseev

Hodgson

Karger

et al. 2005

Journal of Molecular and Cellular Cardiology

108

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“…1) [13][14][15]. ATP maintains K ATP channel closure by binding to Kir6.2 [16,17], whereas ATP/ADP interactions with SUR secure the metabolic sensor function of the channel complex (Fig. 1A) [18][19][20].…”

mentioning

confidence: 99%

Nucleotide-gated K_ATPchannels integrated with creatine and adenylate kinases: Amplification, tuning and sensing of energetic signals in the compartmentalized cellular environment

et al. 2004

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Transmission of energetic signals to membrane sensors, such as the ATP-sensitive K + (K ATP ) channel, is vital for cellular adaptation to stress. Yet, cell compartmentation implies diffusional hindrances that hamper direct reception of cytosolic energetic signals. With high intracellular ATP levels, K ATP channels may sense not bulk cytosolic, but rather local submembrane nucleotide concentrations set by membrane ATPases and phosphotransfer enzymes. Here, we analyzed the role of adenylate kinase and creatine kinase phosphotransfer reactions in energetic signal transmission over the strong diffusional barrier in the submembrane compartment, and translation of such signals into a nucleotide response detectable by K ATP channels. Facilitated diffusion provided by creatine kinase and adenylate kinase phosphotransfer dissipated nucleotide gradients imposed by membrane ATPases, and shunted diffusional restrictions. Energetic signals, simulated as deviation of bulk ATP from its basal level, were amplified into an augmented nucleotide response in the submembrane space due to failure under stress of creatine kinase to facilitate nucleotide diffusion. Tuning of creatine kinase-dependent amplification of the nucleotide response was provided by adenylate kinase capable of adjusting the ATP/ADP ratio in the submembrane compartment securing adequate K ATP channel response in accord with cellular metabolic demand. Thus, complementation between creatine kinase and adenylate kinase systems, here predicted by modeling and further supported experimentally, provides a mechanistic basis for metabolic sensor function governed by alterations in intracellular phosphotransfer fluxes. KeywordsATP-sensitive K + channel; nucleotide diffusion; metabolic sensor; intracellular compartment; heart Metabolic sensing by K ATP channelsMaintenance of homeostasis requires efficient transmission of energetic signals from sites of ATP generation to ATP sensors governing cellular response [1][2][3][4][5][6]. In the compartmentalized cell environment, energetic signaling must integrate detection, amplification and delivery of metabolic signals arising from deviations in adenine nucleotide levels [1][2][3][4][5][6][7][8][9]. While the identity of energy-responsive elements is being increasingly resolved, the molecular mechanisms that synchronize metabolic sensor function with cell metabolism remain largely unknown. © 2004 Kluwer Academic PublishersAddress for offprints: A.E. Alekseev, Division of Cardiovascular Diseases, Departments of Medicine, Molecular Pharmacology and Experimental Therapeutics, Mayo Clinic, Guggenheim 7, Rochester, MN 55905, USA (E-mail: alekseev.alexey@mayo.edu). (Fig. 1A) [18][19][20]. The sensor role of cardiac K ATP channels stems from the nonequivalent properties of nucleotide binding domains (NBD1 and NBD2) in the SUR2A subunit (Fig. 1A). NBD1 binds nucleotides whereas NBD2 hydrolyzes ATP, with NBDs working in tandem to gate K ATP channels [21][22][23]. The ATP hydrolysis cycle at SUR2A drives conformational transitio...

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Congenital hyperinsulinism: Molecular basis of a heterogeneous disease

1999

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Truncation of Kir6.2 produces ATP-sensitive K+ channels in the absence of the sulphonylurea receptor

Cited by 717 publications

References 19 publications

ATP-sensitive K channel channel/enzyme multimer: Metabolic gating in the heart

ATP-sensitive K channel channel/enzyme multimer: Metabolic gating in the heart

Nucleotide-gated K_ATPchannels integrated with creatine and adenylate kinases: Amplification, tuning and sensing of energetic signals in the compartmentalized cellular environment

Congenital hyperinsulinism: Molecular basis of a heterogeneous disease

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Truncation of Kir6.2 produces ATP-sensitive K+ channels in the absence of the sulphonylurea receptor

Cited by 717 publications

References 19 publications

ATP-sensitive K channel channel/enzyme multimer: Metabolic gating in the heart

ATP-sensitive K channel channel/enzyme multimer: Metabolic gating in the heart

Nucleotide-gated KATPchannels integrated with creatine and adenylate kinases: Amplification, tuning and sensing of energetic signals in the compartmentalized cellular environment

Congenital hyperinsulinism: Molecular basis of a heterogeneous disease

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Nucleotide-gated K_ATPchannels integrated with creatine and adenylate kinases: Amplification, tuning and sensing of energetic signals in the compartmentalized cellular environment