46 research outputs found

    The RCK2 domain of the human BKCa channel is a calcium sensor

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    Large conductance voltage and Ca2+-dependent K+ channels (BKCa) are activated by both membrane depolarization and intracellular Ca2+. Recent studies on bacterial channels have proposed that a Ca2+-induced conformational change within specialized regulators of K+ conductance (RCK) domains is responsible for channel gating. Each pore-forming α subunit of the homotetrameric BKCa channel is expected to contain two intracellular RCK domains. The first RCK domain in BKCa channels (RCK1) has been shown to contain residues critical for Ca2+ sensitivity, possibly participating in the formation of a Ca2+-binding site. The location and structure of the second RCK domain in the BKCa channel (RCK2) is still being examined, and the presence of a high-affinity Ca2+-binding site within this region is not yet established. Here, we present a structure-based alignment of the C terminus of BKCa and prokaryotic RCK domains that reveal the location of a second RCK domain in human BKCa channels (hSloRCK2). hSloRCK2 includes a high-affinity Ca2+-binding site (Ca bowl) and contains similar secondary structural elements as the bacterial RCK domains. Using CD spectroscopy, we provide evidence that hSloRCK2 undergoes a Ca2+-induced change in conformation, associated with an α-to-β structural transition. We also show that the Ca bowl is an essential element for the Ca2+-induced rearrangement of hSloRCK2. We speculate that the molecular rearrangements of RCK2 likely underlie the Ca2+-dependent gating mechanism of BKCa channels. A structural model of the heterodimeric complex of hSloRCK1 and hSloRCK2 domains is discussed

    A Common Ca2+-Driven Interdomain Module Governs Eukaryotic NCX Regulation

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    Na+/Ca2+ exchanger (NCX) proteins mediate Ca2+-fluxes across the cell membrane to maintain Ca2+ homeostasis in many cell types. Eukaryotic NCX contains Ca2+-binding regulatory domains, CBD1 and CBD2. Ca2+ binding to a primary sensor (Ca3-Ca4 sites) on CBD1 activates mammalian NCXs, whereas CALX, a Drosophila NCX ortholog, displays an inhibitory response to regulatory Ca2+. To further elucidate the underlying regulatory mechanisms, we determined the 2.7 Å crystal structure of mammalian CBD12-E454K, a two-domain construct that retains wild-type properties. In conjunction with stopped-flow kinetics and SAXS (small-angle X-ray scattering) analyses of CBD12 mutants, we show that Ca2+ binding to Ca3-Ca4 sites tethers the domains via a network of interdomain salt-bridges. This Ca2+-driven interdomain switch controls slow dissociation of “occluded” Ca2+ from the primary sensor and thus dictates Ca2+ sensing dynamics. In the Ca2+-bound conformation, the interdomain angle of CBD12 is very similar in NCX and CALX, meaning that the interdomain distances cannot account for regulatory diversity in NCX and CALX. Since the two-domain interface is nearly identical among eukaryotic NCXs, including CALX, we suggest that the Ca2+-driven interdomain switch described here represents a general mechanism for initial conduction of regulatory signals in NCX variants

    Potentiation of large conductance KCa channels by niflumic, flufenamic, and mefenamic acids.

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    Large conductance calcium-activated K+ (KCa) channels are rapidly activated by niflumic acid dose-dependently and reversibly. External niflumic acid was about 5 times more potent than internal niflumic acid, and its action was characterized by an increase in the channel affinity for [Ca2+], a parallel left shift of the voltage-activation curve, and a decrease of the channel long-closed states. Niflumic acid applied from the external side did not interfere with channel block by charybdotoxin, suggesting that its site of action is not at or near the charybdotoxin receptor. Accordingly, partial tetraethylammonium blockade did not interfere with channel activation by niflumic acid. Flufenamic acid and mefenamic acid also stimulated KCa channel activity and, as niflumic acid, they were more potent from the external than from the internal side. Fenamates applied from the external side displayed the following potency sequence: flufenamic acid approximately niflumic acid >> mefenamic acid. These results indicate that KCa channels possess at least one fenamatereceptor whose occupancy leads to channel opening

    Voltage-controlled gating in a large conductance Ca(2+)-sensitive K(+)channel (hslo)

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    Large conductance calcium- and voltage-sensitive K(+) (MaxiK) channels share properties of voltage- and ligand-gated ion channels. In voltage-gated channels, membrane depolarization promotes the displacement of charged residues contained in the voltage sensor (S4 region) inducing gating currents and pore opening. In MaxiK channels, both voltage and micromolar internal Ca(2+) favor pore opening. We demonstrate the presence of voltage sensor rearrangements with voltage (gating currents) whose movement and associated pore opening is triggered by voltage and facilitated by micromolar internal Ca(2+) concentration. In contrast to other voltage-gated channels, in MaxiK channels there is charge movement at potentials where the pore is open and the total charge per channel is 4–5 elementary charges

    Interaction of S100A1 with the Ca2+ release channel (ryanodine receptor) of skeletal muscle

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    n the present report we studied the interaction between the skeletal muscle ryanodine receptor and the ubiquitous S100A1 Ca2+ binding protein. S100A1 did not affect equilibrium [3H]ryanodine binding to purified rabbit skeletal muscle terminal cisternae at 100 microM free [Ca2+]. At nanomolar free [Ca2+], however, S100A1 activated by 40 +/- 6.7% (mean +/- SE, n = 5) the [3H]ryanodine binding activity; the half-maximal concentration for stimulation of [3H]ryanodine binding was approximately 70 nM, a value well below the estimated S100A1 concentration in skeletal muscle fibers. Scatchard analysis of [3H]ryanodine binding performed in the presence of 100 microM EGTA indicates that S100A1 increases the apparent affinity of the receptor for ryanodine (Kd = 191 vs 383 nM in the presence and in the absence of 100 nM S100A1, respectively). The effect of S100A1 was also tested on the single-channel gating properties of the purified ryanodine receptor after reconstitution into a lipid planar bilayer. Currents carried by purified ryanodine receptor channels were modulated by both cis Ca2+ and ruthenium red. In the presence of nanomolar [Ca2+], S100A1 activated the channel by increasing (6.0 +/- 2.8)-fold (mean +/- SE, n = 3) the normalized open probability. The interaction between S100A1 and the purified RYR was verified using the optical biosensor BIAcore: we show that the two proteins interact directly both at millimolar and at nanomolar calcium concentrations. We next mapped the regions of the skeletal muscle RYR involved in the interaction with S100A1 by performing ligand overlays on a panel RYR of fusion proteins in the presence of 100 nM S100A1. Our results indicate that the skeletal muscle RYR contains three potential S100A1 binding domains. Binding of S100A1 to the RYR fusion proteins occurred at both nanomolar and millimolar free [Ca2+]. S100A1 binding domain 1 binds the ligand in the presence of 1 mM free [Ca2+] or 1 mM EGTA. Maximal binding to S100A1#2 was achieved in the presence of 1 mM free [Ca2+]. The S100A1#3 domain, which overlaps with calcium-dependent calmodulin binding domain 3 (CaM 3), exhibits weak and strong S100A1 binding activity in the presence of either millimolar or nanomolar Ca2+, respectively. The interaction between S100A1 and the purified RYR complex was also investigated by affinity chromatography: in the presence of nanomolar Ca2+, we observed binding of native RYR complex to S100A1-conjugated Sepharose. This interaction could be inhibited by the presence of RYR polypeptides encompassing S100A1 binding sites S100A1#1, S100A1#2, and S100A1#3

    The second Ca2+-binding domain of the Na+–Ca2+ exchanger is essential for regulation: Crystal structures and mutational analysis

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    The Na+–Ca2+ exchanger plays a central role in cardiac contractility by maintaining Ca2+ homeostasis. Two Ca2+-binding domains, CBD1 and CBD2, located in a large intracellular loop, regulate activity of the exchanger. Ca2+ binding to these regulatory domains activates the transport of Ca2+ across the plasma membrane. Previously, we solved the structure of CBD1, revealing four Ca2+ ions arranged in a tight planar cluster. Here, we present structures of CBD2 in the Ca2+-bound (1.7-Å resolution) and -free (1.4-Å resolution) conformations. Like CBD1, CBD2 has a classical Ig fold but coordinates only two Ca2+ ions in primary and secondary Ca2+ sites. In the absence of Ca2+, Lys585 stabilizes the structure by coordinating two acidic residues (Asp552 and Glu648), one from each of the Ca2+-binding sites, and prevents a substantial protein unfolding. We have mutated all of the acidic residues that coordinate the Ca2+ ions and have examined the effects of these mutations on regulation of exchange activity. Three mutations (E516L, D578V, and E648L) at the primary Ca2+ site completely remove Ca2+ regulation, placing the exchanger into a constitutively active state. These are the first data defining the role of CBD2 as a regulatory domain in the Na+–Ca2+ exchanger
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