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

Abstract: 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 … Show more

“…Indeed, the rate of ATP hydrolysis at NBD2 can be doubled by creatine kinase, reversing MgADP-induced K ATP channel opening highlighting a critical role for phosphotransfer reactions in setting the balance between the lifetime/probability of MgADP versus MgATP-bound conformational intermediates in the SUR ATPase cycle [9,14]. As a consequence of metabolic stress, a drop of creatine kinase flux compromises ADP removal from ATPase sites and suspends the ATPase cycle in a MgADP-bound state producing channel opening [12,15,16].…”

“…Indeed, during a normally operating ATPase, NBD2 during each single cycle unavoidably adopts the ADPbound conformation that potentially could activate K ATP channels. Paradoxically, ATPregenerating systems that facilitate ATPase cycling and therefore promote transit through the MgADP-bound intermediate state, do not activate K ATP channels [9,15,16,45]. It is only through arrest of the SUR ATPase in a pre-or post-hydrolytic conformation that specific channel outcome, pore closure or antagonism of ATP-induced pore inhibition, can be achieved [9].…”

“…Theoretical and experimental analysis of cooperative interaction between the two prototypic phosphotransfer enzymes, creatine kinase (CK) and adenylate kinase (AK) systems, in a compartmentalized cellular environment reveals unique properties of these enzymes in transmission of energetic signals to sarcolemmal K ATP channels [8,15,16]. Specifically, signal transmission from the cytosol to the submembrane compartment is limited due to restricted diffusion of nucleotides, creatine (Cr) and creatine phosphate (CrP).…”

“…Under cardiomyocyte stress, phosphotransfer flux through CK is significantly damped [92][93][94] such that with only a moderate drop in bulk cytosolic ATP, CK could no longer effectively dissipate nucleotide gradients precipitating a significant fall in submembrane CrP, and generation of an amplified nucleotide response at the K ATP channel site (Fig. 2) [16]. According to the CK reaction equilibrium, substitution by creatine of 9.95 out of the total 10.25 mM of creatine phosphate, a 50 μM drop of bulk ATP (from 0.3 to 0.25 mM) and concomitant increase of bulk ADP can be expected.…”

“…The basic gating of the K ATP channel that underlies the channel's metabolic response occurs in reaction to the balance at the channel site of inhibitory and stimulatory nucleotides, ATP and ADP, respectively [1,14]. The way in which the cellular metabolic state is "read" incorporates generation and delivery of nucleotide signals to the K ATP channel subunits, and nucleotide interactions with specialized channel domains that ultimately secure signal processing and translation into pore gating [15,16].…”

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

“…Indeed, the rate of ATP hydrolysis at NBD2 can be doubled by creatine kinase, reversing MgADP-induced K ATP channel opening highlighting a critical role for phosphotransfer reactions in setting the balance between the lifetime/probability of MgADP versus MgATP-bound conformational intermediates in the SUR ATPase cycle [9,14]. As a consequence of metabolic stress, a drop of creatine kinase flux compromises ADP removal from ATPase sites and suspends the ATPase cycle in a MgADP-bound state producing channel opening [12,15,16].…”

“…Indeed, during a normally operating ATPase, NBD2 during each single cycle unavoidably adopts the ADPbound conformation that potentially could activate K ATP channels. Paradoxically, ATPregenerating systems that facilitate ATPase cycling and therefore promote transit through the MgADP-bound intermediate state, do not activate K ATP channels [9,15,16,45]. It is only through arrest of the SUR ATPase in a pre-or post-hydrolytic conformation that specific channel outcome, pore closure or antagonism of ATP-induced pore inhibition, can be achieved [9].…”

“…Theoretical and experimental analysis of cooperative interaction between the two prototypic phosphotransfer enzymes, creatine kinase (CK) and adenylate kinase (AK) systems, in a compartmentalized cellular environment reveals unique properties of these enzymes in transmission of energetic signals to sarcolemmal K ATP channels [8,15,16]. Specifically, signal transmission from the cytosol to the submembrane compartment is limited due to restricted diffusion of nucleotides, creatine (Cr) and creatine phosphate (CrP).…”

“…Under cardiomyocyte stress, phosphotransfer flux through CK is significantly damped [92][93][94] such that with only a moderate drop in bulk cytosolic ATP, CK could no longer effectively dissipate nucleotide gradients precipitating a significant fall in submembrane CrP, and generation of an amplified nucleotide response at the K ATP channel site (Fig. 2) [16]. According to the CK reaction equilibrium, substitution by creatine of 9.95 out of the total 10.25 mM of creatine phosphate, a 50 μM drop of bulk ATP (from 0.3 to 0.25 mM) and concomitant increase of bulk ADP can be expected.…”

“…The basic gating of the K ATP channel that underlies the channel's metabolic response occurs in reaction to the balance at the channel site of inhibitory and stimulatory nucleotides, ATP and ADP, respectively [1,14]. The way in which the cellular metabolic state is "read" incorporates generation and delivery of nucleotide signals to the K ATP channel subunits, and nucleotide interactions with specialized channel domains that ultimately secure signal processing and translation into pore gating [15,16].…”

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

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