Orientation of <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis> KAT1 Channel in the Plasma Membrane

The Arabidopsis thaliana KAT1, an inward-rectifying potassium channel, shares molecular features with the Shaker family of outward rectifier K⁺ channels. The KAT1 amino-acid sequence reveals the presence of a positively charged S4 and a segment containing the TXGYGD signature sequence in the pore (P) region. To test whether the inward-rectifying properties of KAT1 are due to reverse orientation in the membrane, such that the voltage sensor is oriented in the opposite direction of the electric field compared with the Shaker K⁺ channel, we have inserted a flag epitope in the NH₂ terminus or the S3–S4 loop. The KAT1 and tagged constructs expressed functional channels in whole cells, Xenopus oocytes and COS-7. The electrophysiological properties of both tagged constructs were similar to those of the wild type. Immunofluorescence with an antibody against the flag epitope and an anti-C terminal KAT1 determined the membrane localization of these epitopes and the orientation of the KAT1 channel in the membrane. Our data confirm that KAT1 in eukaryotic cells has an orientation similar to the Shaker K⁺ channel.     

Towards an understanding of the molecular basis of plants K+ transport: Characterization of cloned K+ transport cDNAs

Recently, two K⁺-transport cDNAs, KAT1 and AKT1, were cloned in Arabidopsis thaliana. These cDNAs had structural similarities to K⁺ channel genes in animals, and also conferred the ability for growth on micromolar levels of K⁺ when expressed in K⁺ transport-defective yeast mutants. In this study, we examined the possibility that KAT1 encodes the high-affinity K⁺ transport system that has been previously characterized in plant roots, by studying the concentration-dependent kinetics of K⁺ transport for KAT1 expressed in Xenopus oocytes and Saccharomyces cerevisiae. In both organisms, the K⁺ transport system encoded by KAT1 yielded Michaelis-Menten kinetics with a high K_m for K⁺ (35 mM in oocytes, 0.6 mM in yeast cells). Furthermore, Northern analysis indicated that KAT1 is expressed primarily in the Arabidopsis shoot. These results strongly suggest that the system encoded by KAT1 is not a root high-affinity K⁺ transporter.     

Diversity of Channels Generated by Different Combinations of Epithelial Sodium Channel Subunits

The epithelial sodium channel is a multimeric protein formed by three homologous subunits: α, β, and γ; each subunit contains only two transmembrane domains. The level of expression of each of the subunits is markedly different in various Na⁺ absorbing epithelia raising the possibility that channels with different subunit composition can function in vivo. We have examined the functional properties of channels formed by the association of α with β and of α with γ in the Xenopus oocyte expression system using two-microelectrode voltage clamp and patch-clamp techniques. We found that αβ channels differ from αγ channels in the following functional properties: (a) αβ channels expressed larger Na⁺ than Li⁺ currents (I_Na+/I_Li+ 1.2) whereas αγ channels expressed smaller Na⁺ than Li⁺ currents (I_Na+/I_Li+ 0.55); (b) the Michaelis Menten constants (K _m) of activation of current by increasing concentrations of external Na⁺ and Li⁺ of αβ channels were larger (K _m > 180 mM) than those of αγ channels (K _m of 35 and 50 mM, respectively); (c) single channel conductances of αβ channels (5.1 pS for Na⁺ and 4.2 pS for Li⁺) were smaller than those of αγ channels (6.5 pS for Na⁺ and 10.8 pS for Li⁺); (d) the half-inhibition constant (K _i) of amiloride was 20-fold larger for αβ channels than for αγ channels whereas the K _i of guanidinium was equal for both αβ and αγ. To identify the domains in the channel subunits involved in amiloride binding, we constructed several chimeras that contained the amino terminus of the γ subunit and the carboxy terminus of the β subunit. A stretch of 15 amino acids, immediately before the second transmembrane domain of the β subunit, was identified as the domain conferring lower amiloride affinity to the αβ channels. We provide evidence for the existence of two distinct binding sites for the amiloride molecule: one for the guanidium moiety and another for the pyrazine ring. At least two subunits α with β or γ contribute to these binding sites. Finally, we show that the most likely stoichiometry of αβ and αγ channels is 1α:1β and 1α:1γ, respectively.     

Ginseng Gintonin Activates the Human Cardiac Delayed Rectifier K+ Channel: Involvement of Ca2+/Calmodulin Binding Sites

Gintonin, a novel, ginseng-derived G protein-coupled lysophosphatidic acid (LPA) receptor ligand, elicits [Ca²⁺]_i transients in neuronal and non-neuronal cells via pertussis toxin-sensitive and pertussis toxin-insensitive G proteins. The slowly activating delayed rectifier K⁺ (I_Ks) channel is a cardiac K⁺ channel composed of KCNQ1 and KCNE1 subunits. The C terminus of the KCNQ1 channel protein has two calmodulin-binding sites that are involved in regulating I_Ks channels. In this study, we investigated the molecular mechanisms of gintonin-mediated activation of human I_Ks channel activity by expressing human I_Ks channels in Xenopus oocytes. We found that gintonin enhances I_Ks channel currents in concentration- and voltage-dependent manners. The EC₅₀ for the I_Ks channel was 0.05 ± 0.01 μg/ml. Gintonin-mediated activation of the I_Ks channels was blocked by an LPA1/3 receptor antagonist, an active phospholipase C inhibitor, an IP₃ receptor antagonist, and the calcium chelator BAPTA. Gintonin-mediated activation of both the I_Ks channel was also blocked by the calmodulin (CaM) blocker calmidazolium. Mutations in the KCNQ1 [Ca²⁺]_i/CaM-binding IQ motif sites (S373P, W392R, or R539W)blocked the action of gintonin on I_Ks channel. However, gintonin had no effect on hERG K⁺ channel activity. These results show that gintonin-mediated enhancement of I_Ks channel currents is achieved through binding of the [Ca²⁺]_i/CaM complex to the C terminus of KCNQ1 subunit.     

Increased Resistance to Extracellular Cation Block by Mutation of the Pore Domain of the Arabidopsis Inward-rectifying K+ Channel KAT1

Inward-rectifying potassium channels in plant cells provide important mechanisms for low-affinity K⁺ uptake and membrane potential control in specific cell types, including guard cells, pulvinus cells, aleurone cells and root hair cells. K⁺ channel blockers are potent tools for studying the physiological functions and structural properties of K⁺ channels. In the present study the structural and biophysical mechanisms of Cs⁺ and TEA⁺ block of a cloned Arabidopsis inward-rectifying K⁺ channel (KAT1) were analyzed. Effects of the channel blockers Cs⁺ and TEA⁺ were characterized both extracellularly and intracellularly. Both external Cs⁺ and TEA⁺ block KAT1 currents. A mutant of KAT1 (``m2KAT1'; H267T, E269V) was produced by site-directed mutagenesis of two amino acid residues in the C-terminal portion of the putative pore (P) domain. This mutant channel was blocked less by external Cs⁺ and TEA⁺ than the wild-type K⁺ channel. Internal TEA⁺ and Cs⁺ did not significantly block either m2KAT1 or KAT1 channels. Other properties, such as cation selectivity, voltage-dependence and proton activation did not show large changes between m2KAT1 and KAT1, demonstrating the specificity of the introduced mutations. These data suggest that the amino acid positions mutated in the inward-rectifying K⁺ channel, KAT1, are accessible to external blockers and may be located on the external side of the membrane, as has been suggested for outward-rectifying K⁺ channels. Received: 31 July 1995/Revised: 5 January 1996     

The Role of the C-Terminus for Functional Heteromerization of the Plant Channel KDC1

Voltage-gated potassium channels are formed by the assembly of four identical (homotetramer) or different (heterotetramer) subunits. Tetramerization of plant potassium channels involves the C-terminus of the protein. We investigated the role of the C-terminus of KDC1, a Shaker-like inward-rectifying K⁺ channel that does not form functional homomeric channels, but participates in the formation of heteromeric complexes with other potassium α-subunits when expressed in Xenopus oocytes. The interaction of KDC1 with KAT1 was investigated using the yeast two-hybrid system, fluorescence and electrophysiological studies. We found that the KDC1-EGFP fusion protein is not targeted to the plasma membrane of Xenopus oocytes unless it is coexpressed with KAT1. Deletion mutants revealed that the KDC1 C-terminus is involved in heteromerization. Two domains of the C-terminus, the region downstream the putative cyclic nucleotide binding domain and the distal part of the C-terminus called K_HA domain, contributed to a different extent to channel assembly. Whereas the first interacting region of the C-terminus was necessary for channel heteromerization, the removal of the distal K_HA domain decreased but did not abolish the formation of heteromeric complexes. Similar results were obtained when coexpressing KDC1 with the KAT1-homolog KDC2 from carrots, thus indicating the physiological significance of the KAT1/KDC1 characterization. Electrophysiological experiments showed furthermore that the heteromerization capacity of KDC1 was negatively influenced by the presence of the enhanced green fluorescence protein fusion.     

Suppression of Inward-Rectifying K+ Channels KAT1 and AKT2 by Dominant Negative Point Mutations in the KAT1 α-Subunit

The Arabidopsis thaliana cDNA, KAT1 encodes a hyperpolarization-activated K⁺ (K⁺ _in ) channel. In the present study, we identify and characterize dominant negative point mutations that suppress K⁺ _in channel function. Effects of two mutations located in the H5 region of KAT1, at positions 256 (T256R) and 262 (G262K), were studied. The co-expression of either T256R or G262K mutants with KAT1 produced an inhibition of K⁺ currents upon membrane hyperpolarization. The magnitude of this inhibition was dependent upon the molar ratio of cRNA for wild-type to mutant channel subunits injected. Inhibition of KAT1 currents by the co-expression of T256R or G262K did not greatly affect the ion selectivity of residual currents for Rb⁺, Na⁺, Li⁺, or Cs⁺. When T256R or G262K were co-expressed with a different K⁺ channel, AKT2, an inhibition of the channel currents was also observed. Voltage-dependent Cs⁺ block experiments with co-expressed wild type, KAT1 and AKT2, channels further indicated that KAT1 and AKT2 formed heteromultimers. These data show that AKT2 and KAT1 are able to co-assemble and suggest that suppression of channel function can be pursued in vivo by the expression of the dominant negative K ⁺ _in channel mutants described here. Received: 2 July 1998/Revised: 23 October 1998     

Arabidopsis thaliana vacuolar TPK channels form functional K+ uptake pathways in Escherichia coli

Very few vacuolar two pore potassium channels (TPKs) have been functionally characterized. In this paper we have used complementation of K⁺ uptake deficient Escherichia coli mutant LB2003 to analyze the functional properties of Arabidopsis thaliana TPK family members. The four isoforms of AtTPKs were cloned and expressed in LB2003 E. coli background.The expression of channels in bacteria was analyzed by RT-PCR. Our results show that AtTPK1, AtTPK2 and AtTPK5 are restoring the LB2003 growth on low K⁺ media. The analysis of potassium uptake exhibited elevated level of K⁺ uptake in the same three types of AtTPKs transformants.     

Evaluation of functional interaction between K(+) channel alpha- and beta-subunits and putative inactivation gating by Co-expression in Xenopus laevis oocytes

Animal K⁺ channel α- (pore-forming) subunits form native proteins by association with β-subunits, which are thought to affect channel function by modifying electrophysiological parameters of currents (often by inducing fast inactivation) or by stabilizing the protein complex. We evaluated the functional association of KAT1, a plant K⁺ channel α-subunit, and KAB1 (a putative homolog of animal K⁺ channel β-subunits) by co-expression in Xenopus laevis oocytes. Oocytes expressing KAT1 displayed inward-rectifying, non-inactivating K⁺ currents that were similar in magnitude to those reported in prior studies. K⁺ currents recorded from oocytes expressing both KAT1 and KAB1 had similar gating kinetics. However, co-expression resulted in greater total current, consistent with the possibility that KAB1 is a β-subunit that stabilizes and therefore enhances surface expression of K⁺ channel protein complexes formed by α-subunits such as KAT1. K⁺ channel protein complexes formed by α-subunits such as KAT1 that undergo (voltage-dependent) inactivation do so by means of a “ball and chain” mechanism; the ball portion of the protein complex (which can be formed by the N terminus of either an α- or β-subunit) occludes the channel pore. KAT1 was co-expressed in oocytes with an animal K⁺ channel α-subunit (hKv1.4) known to contain the N-terminal ball and chain. Inward currents through heteromeric hKv1.4:KAT1 channels did undergo typical voltage-dependent inactivation. These results suggest that inward currents through K⁺ channel proteins formed at least in part by KAT1 polypeptides are capable of inactivation, but the structural component facilitating inactivation is not present when channel complexes are formed by either KAT1 or KAB1 in the absence of additional subunits.     

Functional characterization of a wheat plasma membrane Na+/H+ antiporter in yeast

The functional analysis of the sodium exchanger SOS1 from wheat, TaSOS1, was undertaken using Saccharomyces cerevisiae as a heterologous expression system. The TaSOS1 protein, with significant sequence homology to SOS1 sodium exchangers from Arabidopsis and rice, is abundant in roots and leaves, and is induced by salt treatment. TaSOS1 suppressed the salt sensitivity of a yeast strain lacking the major Na⁺ efflux systems by decreasing the cellular Na⁺ content while increasing K⁺ content. Na⁺/H⁺ exchange activity of purified plasma membrane from yeast cells expressing TaSOS1 was higher than controls transformed with empty vector. These results demonstrate that TaSOS1 contributes to plasma membrane Na⁺/H⁺ exchange.     

Inward rectifier potassium channels in plants differ from their animal counterparts in response to voltage and channel modulators

We have investigated the electrophysiological basis of potassium inward rectification of the KAT1 gene product from Arabidopsis thaliana expressed in Xenopus oocytes and of functionally related K⁺ channels in the plasma membrane of guard and root cells from Vicia faba and Zea mays. The whole-cell currents passed by these channels activate, following steps to membrane potentials more negative than –100 mV, with half activation times of tens of milliseconds. This voltage dependence was unaffected by the removal of cytoplasmic magnesium. Consequently, unlike inward rectifier channels of animals, inward rectification of plant potassium channels is an intrinsic property of the channel protein itself. We also found that the activation kinetics of KAT1 were modulated by external pH. Decreasing the pH in the range 8.5 to 4.5 hastened activation and shifted the steady state activation curve by 19 mV per pH unit. This indicates that the activity of these K⁺ channels and the activity of the plasma membrane H⁺-ATPase may not only be coordinated by membrane potential but also by pH. The instantaneous current-voltage relationship, on the other hand, did not depend on pH, indicating that H⁺ do not block the channel. In addition to sensitivity towards protons, the channels showed a high affinity voltage dependent block in the presence of cesium, but were less sensitive to barium. Recordings from membrane patches of KAT1 injected oocytes in symmetric, Mg²⁺-free, 100 mM-K⁺, solutions allowed measurements of the current-voltage relation of single open KAT1 channels with a unitary conductance of 5 pS. We conclude that the inward rectification of the currents mediated by the KAT1 gene product, or the related endogenous channels of plant cells, results from voltage-modulated structural changes within the channel proteins. The voltage-sensing or the gating-structures appear to interact with a titratable acidic residue exposed to the extracellular medium. Correspondence to: R. Hedrich     

Ion Conduction through C-Type Inactivated Shaker Channels

C-type inactivation of Shaker potassium channels involves entry into a state (or states) in which the inactivated channels appear nonconducting in physiological solutions. However, when Shaker channels, from which fast N-type inactivation has been removed by NH₂-terminal deletions, are expressed in Xenopus oocytes and evaluated in inside-out patches, complete removal of K⁺ ions from the internal solution exposes conduction of Na⁺ and Li⁺ in C-type inactivated conformational states. The present paper uses this observation to investigate the properties of ion conduction through C-type inactivated channel states, and demonstrates that both activation and deactivation can occur in C-type states, although with slower than normal kinetics. Channels in the C-type states appear “inactivated” (i.e., nonconducting) in physiological solutions due to the summation of two separate effects: first, internal K⁺ ions prevent Na⁺ ions from permeating through the channel; second, C-type inactivation greatly reduces the permeability of K⁺ relative to the permeability of Na⁺, thus altering the ion selectivity of the channel.     

Evidence for a Multi-ion Pore Behavior in the Plant Potassium Channel KAT1

KAT1 is a cloned voltage-gated K⁺ channel from the plant Arabidopsis thaliana L., which displays an inward rectification reminiscent of `anomalous' rectification of the i <sub>f</sub> pacemaker current recorded in animal cells. Macroscopic conductance of KAT1 expressed in Xenopus oocytes was 5-fold less in pure Rb<sup>+</sup> solution than in pure K<sup>+</sup> solution, and negligible in pure Na<sup>+</sup> solution. Experiments in different K<sup>+</sup>/Na<sup>+</sup> or K<sup>+</sup>/Rb<sup>+</sup> mixtures revealed deviations from the principle of independence and notably two anomalous effects of the K<sup>+</sup>/Rb<sup>+</sup> mole fraction (i.e., the ratio [K<sup>+</sup>]/([K<sup>+</sup>]+[Rb<sup>+</sup>])). First, the KAT1 deactivation time constant was both voltage- and mole fraction-dependent (a so-called `foot in the door' effect was thus observed in KAT1 channel). Second, when plotted against the K⁺/Rb⁺ mole fraction, KAT1 conductance values passed through a minimum. This minimum is more important for two pore mutants of KAT1 (T259S and T260S) that displayed an increase in P_Rb/P_K. These results are consistent with the idea that KAT1 conduction requires several ions to be present simultaneously within the pore. Therefore, this atypical `green' member of the Shaker superfamily of K⁺ channels further shows itself to be an interesting model as well for permeation as for gating mechanism studies. Received: 9 February 1998/Revised: 28 July 1998     

Complex interactions among residues within pore region determine the K+ dependence of a KAT1‐type potassium channel AmKAT1

KAT1‐type channels mediate K⁺ influx into guard cells that enables stomatal opening. In this study, a KAT1‐type channel AmKAT1 was cloned from the xerophyte Ammopiptanthus mongolicus. In contrast to most KAT1‐type channels, its activation is strongly dependent on external K⁺ concentration, so it can be used as a model to explore the mechanism for the K⁺‐dependent gating of KAT1‐type channels. Domain swapping between AmKAT1 and KAT1 reveals that the S5–pore–S6 region controls the K⁺ dependence of AmKAT1, and residue substitutions show that multiple residues within the S5–Pore linker and Pore are involved in its K⁺‐dependent gating. Importantly, complex interactions occur among these residues, and it is these interactions that determine its K⁺ dependence. Finally, we analyzed the potential mechanism for the K⁺ dependence of AmKAT1, which could originate from the requirement of K⁺ occupancy in the selectivity filter to maintain its conductive conformation. These results provide new insights into the molecular basis of the K⁺‐dependent gating of KAT1‐type channels.     

Voltage-dependent Gating of Single Wild-Type and S4 Mutant KAT1 Inward Rectifier Potassium Channels

The voltage-dependent gating mechanism of KAT1 inward rectifier potassium channels was studied using single channel current recordings from Xenopus oocytes injected with KAT1 mRNA. The inward rectification properties of KAT1 result from an intrinsic gating mechanism in the KAT1 channel protein, not from pore block by an extrinsic cation species. KAT1 channels activate with hyperpolarizing potentials from −110 through −190 mV with a slow voltage-dependent time course. Transitions before first opening are voltage dependent and account for much of the voltage dependence of activation, while transitions after first opening are only slightly voltage dependent. Using burst analysis, transitions near the open state were analyzed in detail. A kinetic model with multiple closed states before first opening, a single open state, a single closed state after first opening, and a closed-state inactivation pathway accurately describes the single channel and macroscopic data. Two mutations neutralizing charged residues in the S4 region (R177Q and R176L) were introduced, and their effects on single channel gating properties were examined. Both mutations resulted in depolarizing shifts in the steady state conductance–voltage relationship, shortened first latencies to opening, decreased probability of terminating bursts, and increased burst durations. These effects on gating were well described by changes in the rate constants in the kinetic model describing KAT1 channel gating. All transitions before the open state were affected by the mutations, while the transitions after the open state were unaffected, implying that the S4 region contributes to the early steps in gating for KAT1 channels.     

Clustering of the K+ channel GORK of Arabidopsis parallels its gating by extracellular K+

GORK is the only outward‐rectifying Kv‐like K⁺ channel expressed in guard cells. Its activity is tightly regulated to facilitate K⁺ efflux for stomatal closure and is elevated in ABA in parallel with suppression of the activity of the inward‐rectifying K⁺ channel KAT1. Whereas the population of KAT1 is subject to regulated traffic to and from the plasma membrane, nothing is known about GORK, its distribution and traffic in vivo. We have used transformations with fluorescently‐tagged GORK to explore its characteristics in tobacco epidermis and Arabidopsis guard cells. These studies showed that GORK assembles in puncta that reversibly dissociated as a function of the external K⁺ concentration. Puncta dissociation parallelled the gating dependence of GORK, the speed of response consistent with the rapidity of channel gating response to changes in the external ionic conditions. Dissociation was also suppressed by the K⁺ channel blocker Ba²⁺. By contrast, confocal and protein biochemical analysis failed to uncover substantial exo‐ and endocytotic traffic of the channel. Gating of GORK is displaced to more positive voltages with external K⁺, a characteristic that ensures the channel facilitates only K⁺ efflux regardless of the external cation concentration. GORK conductance is also enhanced by external K⁺ above 1 mm . We suggest that GORK clustering in puncta is related to its gating and conductance, and reflects associated conformational changes and (de)stabilisation of the channel protein, possibly as a platform for transmission and coordination of channel gating in response to external K⁺.     

Kinetics and ion specificity of Na/Ca exchange mediated by the reconstituted beef heart mitochondrial Na/Ca antiporter

The Na⁺/Ca²⁺ antiporter was purified from beef heart mitochondria and reconstituted into liposomes containing fluorescent probes selective for Na⁺ or Ca²⁺. Na⁺/Ca²⁺ exchange was strongly inhibited at alkaline pH, a property that is relevant to rapid Ca²⁺ oscillations in mitochondria. The effect of pH was mediated entirely via an effect on the K_m for Ca²⁺. When present on the same side as Ca²⁺, K⁺ activated exchange by lowering the K_m for Ca²⁺ from 2  to 0.9 μM. The K_m for Na⁺ was 8 mM. In the absence of Ca²⁺, the exchanger catalyzed high rates of Na⁺/Li⁺ and Na⁺/K⁺ exchange. Diltiazem and tetraphenylphosphonium cation inhibited both Na⁺/Ca²⁺ and Na⁺/K⁺ exchange with IC₅₀ values of 10 and 0.6 μM, respectively. The V_max for Na⁺/Ca²⁺ exchange was increased about fourfold by bovine serum albumin, an effect that may reflect unmasking of an autoregulatory domain in the carrier protein.     

Characterization of the ion transport activity of the budding yeast Na/H antiporter, Nha1p, using isolated secretory vesicles

The Saccharomyces cerevisiae Nha1p, a plasma membrane protein belonging to the monovalent cation/proton antiporter family, plays a key role in the salt tolerance and pH regulation of cells. We examined the molecular function of Nha1p by using secretory vesicles isolated from a temperature sensitive secretory mutant, sec4-2, in vitro. The isolated secretory vesicles contained newly synthesized Nha1p en route to the plasma membrane and showed antiporter activity exchanging H⁺ for monovalent alkali metal cations. An amino acid substitution in Nha1p (D266N, Asp-266 to Asn) almost completely abolished the Na⁺/H⁺ but not K⁺/H⁺ antiport activity, confirming the validity of this assay system as well as the functional importance of Asp-266, especially for selectivity of substrate cations. Nha1p catalyzes transport of Na⁺ and K⁺ with similar affinity (12.7 mM and 12.4 mM), and with lower affinity for Rb⁺ and Li⁺. Nha1p activity is associated with a net charge movement across the membrane, transporting more protons per single sodium ion (i.e., electrogenic). This feature is similar to the bacterial Na⁺/H⁺ antiporters, whereas other known eukaryotic Na⁺/H⁺ antiporters are electroneutral. The ion selectivity and the stoichiometry suggest a unique physiological role of Nha1p which is distinct from that of other known Na⁺/H⁺ antiporters.     

Functional role of the N-terminus of Na,K-ATPase α-subunit as an inactivation gate of palytoxin-induced pump channel

The N-terminus of the Na⁺,K⁺-ATPase α-subunit shows some homology to that of Shaker-B K⁺ channels; the latter has been shown to mediate the N-type channel inactivation in a ball-and-chain mechanism. When the Torpedo Na⁺,K⁺-ATPase is expressed in Xenopus oocytes and the pump is transformed into an ion channel with palytoxin (PTX), the channel exhibits a time-dependent inactivation gating at positive potentials. The inactivation gating is eliminated when the N-terminus is truncated by deleting the first 35 amino acids after the initial methionine. The inactivation gating is restored when a synthetic N-terminal peptide is applied to the truncated pumps at the intracellular surface. Truncated pumps generate no electrogenic current and exhibit an altered stoichiometry for active transport. Thus, the N-terminus of the α-subunit appears to act like an inactivation gate and performs a critical step in the Na⁺,K⁺-ATPase pumping function.