Mechanosensitive ion channels are force-transducing enzymes that couple mechanical stimuli to ion flux. Understanding the gating mechanism of mechanosensitive channels is challenging because the stimulus seen by the channel reflects forces shared between the membrane, cytoskeleton and extracellular matrix. Here we examine whether the mechanosensitive channel PIEZO1 is activated by force-transmission through the bilayer. To achieve this, we generate HEK293 cell membrane blebs largely free of cytoskeleton. Using the bacterial channel MscL, we calibrate the bilayer tension demonstrating that activation of MscL in blebs is identical to that in reconstituted bilayers. Utilizing a novel PIEZO1–GFP fusion, we then show PIEZO1 is activated by bilayer tension in bleb membranes, gating at lower pressures indicative of removal of the cortical cytoskeleton and the mechanoprotection it provides. Thus, PIEZO1 channels must sense force directly transmitted through the bilayer.
Cells can respond to mechanical stress by gating mechanosensitive ion channels (MSCs). The cloning of Piezo1, a eukaryotic cation-selective MSC, defines a new system to study mechanical transduction at the cellular level. Since Piezo1 has electrophysiological properties similar to endogenous cationic MSCs that are selectively inhibited by the peptide GsMTx4, we tested and found that the peptide targets Piezo1 activity. Extracellular GsMTx4 at μM concentrations reversibly inhibited ~80% of the mechanically induced current of outside-out patches from transfected HEK293 cells. The inhibition was voltage insensitive and, as seen with endogenous MSCs, the mirror image D enantiomer inhibited similarly to the L. The rate constants for binding and unbinding based on Piezo1 current kinetics provided association and dissociation rates of 7.0 × 105 M-1s-1 and 0.11s-1 respectively and a KD of ~ 155nM, similar to values previously reported for endogenous MSCs. Consistent with predicted gating modifier behavior, GsMTx4 produced a ~30mmHg rightward shift in the pressure-gating curve and was active on closed channels. In contrast, streptomycin, a nonspecific inhibitor of cationic MSCs, showed the use-dependent inhibition characteristic of open channel block. The peptide did not block currents of the mechanical channel TREK-1 on outside out patches. Whole cell Piezo1 currents were also reversibly inhibited by GsMTx4, and although the off-rate was nearly identical to outside out patches, differences were observed for the on-rate. The ability of GsMTx4 to target the mechanosensitivity of Piezo1 supports the use of this channel in a high throughput screens for pharmacological agents and diagnostic assays.
Xerocytosis is caused by mutations that alter the kinetics of the mechanosensitive channel PIEZO1
Familial xerocytosis (HX) in humans is an autosomal disease that causes dehydration of red blood cells resulting in hemolytic anemia which has been traced to two individual mutations in the mechanosensitive ion channel, PIEZO1. Each mutation alters channel kinetics in ways that can explain the clinical presentation. Both mutations slowed inactivation and introduced a pronounced latency for activation. A conservative substitution of lysine for arginine (R2456K) eliminated inactivation and also slowed deactivation, indicating that this mutant's loss of charge is not responsible for HX. Fitting the current vs. pressure data to Boltzmann distributions showed that the half-activation pressure, P 1/2 , for M2225R was similar to that of WT, whereas mutations at position 2456 were left shifted. The absolute stress sensitivity was calibrated by cotransfection and comparison with MscL, a well-characterized mechanosensitive channel from bacteria that is driven by bilayer tension. The slope sensitivity of WT and mutant human PIEZO1 (hPIEZO1) was similar to that of MscL implying that the in-plane area increased markedly, by ∼6-20 nm 2 during opening. In addition to the behavior of individual channels, groups of hPIEZO1 channels could undergo simultaneous changes in kinetics including a loss of inactivation and a long (∼200 ms), silent latency for activation. These observations suggest that hPIEZO1 exists in spatial domains whose global properties can modify channel gating. The mutations that create HX affect cation fluxes in two ways: slow inactivation increases the cation flux, and the latency decreases it. These data provide a direct link between pathology and mechanosensitive channel dysfunction in nonsensory cells.mechanical channels | PIEZO1 mutations | channel domains H ereditary xerocytosis (HX) is an autosomal dominant disease characterized by dehydrated red blood cells (RBCs) and mild-to-moderate hemolytic anemia. Two familial HX mutations were identified recently in the gene encoding hPIEZO1, a mechanosensitive ion channel (MSC) (1).Mouse PIEZO1 (mPIEZO1) cloned from Neuro2A cells contains ∼2,500 amino acids predicted to have 24-36 transmembrane domains. Using crosslinking and photobleaching techniques, PIEZO1 was shown to assemble as a homotetramer (2, 3) with no other cofactors. Currently it is not known whether the pore is central to the tetramer (intermolecular) or whether each subunit conducts (intramolecular). mPIEZO1 is a cation-selective channel with a reversal potential near 0 mV. The conductance is ∼70 pS and is reduced to 35 pS by increasing extracellular Mg +2 (3, 4). mPIEZO1, like other cationic MSCs, is inhibited by the peptide GsMTx4 (5) and nonspecifically by ruthenium red (2). Heterologous expression in HEK293 cells is efficient, and mechanical currents can be evoked in whole-cell mode or patches. In cell-attached patches at hyperpolarized potentials, mPIEZO1 activates with ∼30 mmHg of pipette suction and inactivates within ∼30 ms, a rate that slows with depolarization (2-4).To explore the biophysi...
PIEZO1 is an inactivating eukaryotic cation-selective mechanosensitive ion channel. Two sites have been located in the channel that when individually mutated lead to xerocytotic anemia by slowing inactivation. By introducing mutations at two sites, one associated with xerocytosis and the other artificial, we were able to remove inactivation. The double mutant (DhPIEZO1) has a substitution of arginine for methionine (M2225R) and lysine for arginine (R2456K). The loss of inactivation was accompanied by ∼30-mmHg shift of the activation curve to lower pressures and slower rates of deactivation. The slope sensitivity of gating was the same for wild-type and mutants, indicating that the dimensional changes between the closed and open state are unaffected by the mutations. The unitary channel conductance was unchanged by mutations, so these sites are not associated with pore. DhPIEZO1 was reversibly inhibited by the peptide GsMTx4 that acted as a gating modifier. The channel kinetics were solved using complex stimulus waveforms and the data fit to a three-state loop in detailed balance. The reaction had two pressure-dependent rates, closed to open and inactivated to closed. Pressure sensitivity of the opening rate with no sensitivity of the closing rate means that the energy barrier between them is located near the open state. Mutant cycle analysis of inactivation showed that the two sites interacted strongly, even though they are postulated to be on opposite sides of the membrane.
Piezo1 is a eukaryotic cation-selective mechanosensitive ion channel. To understand channel function in vivo, we first need to analyze and compare the response in the whole cell and the patch. In patches, Piezo1 inactivates and the current is fit well by a 3-state model with a single pressure-dependent rate. However, repeated stimulation led to an irreversible loss of inactivation. Remarkably, the loss of inactivation did not occur on a channel-by-channel basis but on all channels at the same time. Thus, the channels are in common mechanical domain. Divalent ions decreased the unitary conductance from ~68 pS to ~37 pS, irrespective of the cation species. Mg and Ca did not affect inactivation rates, but Zn caused a 3-fold slowing. CytochalasinD (cytoD) does not alter inactivation rates or the transition to the non-inactivating mode but does reduce the steady-state response. Whole-cell currents were similar to patch currents but also had significant differences. In contrast to the patch, cytoD inhibited the current suggesting that the activating forces were transmitted through the actin cytoskeleton. Hypotonic swelling that prestressed the cytoskeleton and the bilayer greatly increased the sensitivity of both control and cytoD cells so there are two pathways to transmit force to the channels. In contrast to patch, removing divalent ions decreased the whole-cell current. The difference between whole cell and patch properties provide new insights into our understanding of the Piezo1 gating mechanisms and cautions against generalization to in situ behavior.
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