Phenotypic Alteration of a Human BK (hSlo) Channel byhSloβSubunit Coexpression: Changes in Blocker Sensitivity, Activation/Relaxation and Inactivation Kinetics, and Protein Kinase A Modulation

Dworetzky, Steven I.; Boissard, Christopher G.; Lum-Ragan, J T; McKay, M. Craig; Post-Munson, Debra J.; Trojnacki, Joanne T.; Chang, Chia-Ping; Gribkoff, Valentin K.

doi:10.1523/jneurosci.16-15-04543.1996

Cited by 197 publications

(172 citation statements)

References 30 publications

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“…The ␤3 subunit shifts gating of Slo subunits A major functional role of the previously described ␤1 and ␤2 subunits is to produce a shift in activation by Ca 2ϩ to more negative membrane potentials (McManus et al, 1995;Dworetzky et al, 1996;Wallner et al, 1996;Saito et al, 1997;Ramanathan et al, 1999). Thus, smooth muscle BK channels or other BK channels containing a ␤1 subunit can be activated by elevations of submembrane Ca 2ϩ even at membrane potentials near rest.…”

Section: Inactivation Properties Of Slo␤3 Channels Share Key Similarimentioning

confidence: 99%

Molecular Basis for the Inactivation of Ca²⁺- and Voltage-Dependent BK Channels in Adrenal Chromaffin Cells and Rat Insulinoma Tumor Cells

Xia¹,

Ding²,

1999

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Large-conductance Ca 2ϩ -and voltage-dependent potassium (BK) channels exhibit functional diversity not explained by known splice variants of the single Slo ␣-subunit. Here we describe an accessory subunit (␤3) with homology to other ␤-subunits of BK channels that confers inactivation when it is coexpressed with Slo. Message encoding the ␤3 subunit is found in rat insulinoma tumor (RINm5f) cells and adrenal chromaffin cells, both of which express inactivating BK channels. Channels resulting from coexpression of Slo ␣ and ␤3 subunits exhibit properties characteristic of native inactivating BK channels. Inactivation involves multiple cytosolic, trypsin-sensitive domains. The time constant of inactivation reaches a limiting value ϳ25-30 msec at Ca 2ϩ of 10 M and positive activation potentials. Unlike Shaker N-terminal inactivation, but like native inactivating BK channels, a cytosolic channel blocker does not compete with the native inactivation process. Finally, the ␤3 subunit confers a reduced sensitivity to charybdotoxin, as seen with native inactivating BK channels. Inactivation arises from the N terminal of the ␤3 subunit. Removal of the ␤3 N terminal (33 amino acids) abolishes inactivation, whereas the addition of the ␤3 N terminal onto the ␤1 subunit confers inactivation. The ␤3 subunit shares with the ␤1 subunit an ability to shift the range of voltages over which channels are activated at a given Ca 2ϩ . Thus, the ␤-subunit family of BK channels regulates a number of critical aspects of BK channel phenotype, including inactivation and apparent Ca 2ϩ sensitivity.

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Section: Inactivation Properties Of Slo␤3 Channels Share Key Similarimentioning

confidence: 99%

Molecular Basis for the Inactivation of Ca²⁺- and Voltage-Dependent BK Channels in Adrenal Chromaffin Cells and Rat Insulinoma Tumor Cells

Xia¹,

Ding²,

1999

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“…3, a and b). Importantly, the inhibitory effect of cAMP on STREX-S869A channels is dependent upon endogenous PKA activity as cAMP had no effect on the activity of STREX-S869A channels in the absence of ATP (n ϭ 5, not shown) or in the presence of PKI [5][6][7][8][9][10][11][12][13][14][15][16][17][18][19][20][21][22][23][24] (n ϭ 6, Fig. 3b).…”

Section: Splicing Switches Potassium Channel Sensitivity To Pka 7718mentioning

confidence: 99%

“…Importantly, alternative splicing of the ␣-subunit is dynamically regulated in adults, for example during stress or pregnancy (15,16). Thus the diversity and plasticity of responses to PKA-dependent protein phosphorylation observed between BK channels in native tissues may result either from differential modulation of alternatively spliced BK channel ␣-subunits (12)(13)(14)(15) or through their interaction with different signaling complexes and ␤-subunits (17)(18)(19).…”

mentioning

confidence: 99%

Alternative Splicing Switches Potassium Channel Sensitivity to Protein Phosphorylation

Tian

Duncan

Hammond

et al. 2001

Journal of Biological Chemistry

196

248

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Alternative exon splicing and reversible protein phosphorylation of large conductance calcium-activated potassium (BK) channels represent fundamental control mechanisms for the regulation of cellular excitability. BK channels are encoded by a single gene that undergoes extensive, hormonally regulated exon splicing. In native tissues BK channels display considerable diversity and plasticity in their regulation by cAMP-dependent protein kinase (PKA). Differential regulation of alternatively spliced BK channels by PKA may provide a molecular basis for the diversity and plasticity of BK channel sensitivities to PKA. Here we demonstrate that PKA activates BK channels lacking splice inserts (ZERO) but inhibits channels expressing a 59-amino acid exon at splice site 2 (STREX-1). Channel activation is dependent upon a conserved C-terminal PKA consensus motif (S869), whereas inhibition is mediated via a STREX-1 exon-specific PKA consensus site. Thus, alternative splicing acts as a molecular switch to determine the sensitivity of potassium channels to protein phosphorylation.Large conductance calcium-and voltage-activated potassium (BK) 1 channels link intracellular chemical signaling events with the electrical properties of excitable cells in the endocrine, nervous, and vascular systems (1-3). BK channels are further potently modulated by reversible protein phosphorylation (4 -7). In native tissues BK channels display considerable diversity and plasticity in their regulation by reversible protein phosphorylation. For example, cAMP-dependent protein kinase (PKA) phosphorylation activates BK channels in smooth muscle cells and many neurones but inhibits channel activity in endocrine cells of the anterior pituitary (5, 7-11). Furthermore, the direction of channel regulation by PKA can be modified during challenges to homeostasis (9 -11).The pore-forming ␣-subunits of BK channels are derived from a single gene (Slo) that undergoes extensive alternative splicing to produce channels with distinct phenotypes (12-15). Importantly, alternative splicing of the ␣-subunit is dynamically regulated in adults, for example during stress or pregnancy (15, 16). Thus the diversity and plasticity of responses to PKA-dependent protein phosphorylation observed between BK channels in native tissues may result either from differential modulation of alternatively spliced BK channel ␣-subunits (12-15) or through their interaction with different signaling complexes and ␤-subunits (17-19).To address whether BK channel alternative splice variants are differentially regulated by PKA-mediated protein phosphorylation, we have examined the regulation of three mouse (mslo) BK channel variants (20 -22) expressed in HEK293 cells. BK channels are regulated by multiple protein kinase signaling pathways (5,19,23,24). We have thus assayed the functional regulation of BK channel splice variants by directly activating PKA that remains closely associated with the channels in excised inside-out patches. EXPERIMENTAL PROCEDURESMolecular and Cell Biology-cDNAs encod...

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“…This difference may be due to the level of expression of the modulatory ␤-subunit (25,42) or of splice variants of Hslo in native cells. The regulatory ␤-subunit is known to modify the biophysical, pharmacological, and modulatory properties of Hslo (31,41,(43)(44)(45). Future studies are necessary to address the question of whether the ␤-subunit affects the PKG-induced activation of the ␣-subunit (Hslo) of maxi-K channels.…”

Section: Purified Pkg-i␣ Induces An Increase In the Open Probability mentioning

confidence: 99%

The Large Conductance, Voltage-dependent, and Calcium-sensitive K+ Channel, Hslo, Is a Target of cGMP-dependent Protein Kinase Phosphorylation in Vivo

Alioua¹,

Tanaka²,

Wallner³

et al. 1998

Journal of Biological Chemistry

164

129

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Native large conductance, voltage-dependent, and Ca 2؉ -sensitive K ؉ channels are activated by cGMP-dependent protein kinase. Two possible mechanisms of kinase action have been proposed: 1) direct phosphorylation of the channel and 2) indirect via PKG-dependent activation of a phosphatase. To scrutinize the first possibility, at the molecular level, we used the human poreforming ␣-subunit of the Ca 2؉ -sensitive K ؉ channel, Hslo, and the ␣-isoform of cGMP-dependent protein kinase I. In cell-attached patches of oocytes co-expressing the Hslo channel and the kinase, 8-Br-cGMP significantly increased the macroscopic currents. This increase in current was due to an increase in the channel voltage sensitivity by ϳ20 mV and was reversed by alkaline phosphatase treatment after patch excision. In inside-out patches, however, the effect of purified kinase was negative in 12 of 13 patches. In contrast, and consistent with the intact cell experiments, purified kinase applied to the cytoplasmic side of reconstituted channels increased their open probability. This stimulatory effect was absent when heat-denatured kinase was used. Biochemical experiments show that the purified kinase incorporates ␥-33 P into the immunopurified Hslo band of ϳ125 kDa. Furthermore, in vivo phosphorylation largely attenuates this labeling in back-phosphorylation experiments. These results demonstrate that the ␣-subunit of large conductance Ca 2؉ -sensitive K ؉ channels is substrate for G-I␣ kinase in vivo and support direct phosphorylation as a mechanism for PKG-I␣-induced activation of maxi-K channels.

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Phenotypic Alteration of a Human BK (hSlo) Channel byhSloβSubunit Coexpression: Changes in Blocker Sensitivity, Activation/Relaxation and Inactivation Kinetics, and Protein Kinase A Modulation

Cited by 197 publications

References 30 publications

Molecular Basis for the Inactivation of Ca²⁺- and Voltage-Dependent BK Channels in Adrenal Chromaffin Cells and Rat Insulinoma Tumor Cells

Molecular Basis for the Inactivation of Ca²⁺- and Voltage-Dependent BK Channels in Adrenal Chromaffin Cells and Rat Insulinoma Tumor Cells

Alternative Splicing Switches Potassium Channel Sensitivity to Protein Phosphorylation

The Large Conductance, Voltage-dependent, and Calcium-sensitive K+ Channel, Hslo, Is a Target of cGMP-dependent Protein Kinase Phosphorylation in Vivo

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Phenotypic Alteration of a Human BK (hSlo) Channel byhSloβSubunit Coexpression: Changes in Blocker Sensitivity, Activation/Relaxation and Inactivation Kinetics, and Protein Kinase A Modulation

Cited by 197 publications

References 30 publications

Molecular Basis for the Inactivation of Ca2+- and Voltage-Dependent BK Channels in Adrenal Chromaffin Cells and Rat Insulinoma Tumor Cells

Molecular Basis for the Inactivation of Ca2+- and Voltage-Dependent BK Channels in Adrenal Chromaffin Cells and Rat Insulinoma Tumor Cells

Alternative Splicing Switches Potassium Channel Sensitivity to Protein Phosphorylation

The Large Conductance, Voltage-dependent, and Calcium-sensitive K+ Channel, Hslo, Is a Target of cGMP-dependent Protein Kinase Phosphorylation in Vivo

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Molecular Basis for the Inactivation of Ca²⁺- and Voltage-Dependent BK Channels in Adrenal Chromaffin Cells and Rat Insulinoma Tumor Cells

Molecular Basis for the Inactivation of Ca²⁺- and Voltage-Dependent BK Channels in Adrenal Chromaffin Cells and Rat Insulinoma Tumor Cells