ACCELERATED PUBLICATION
Alternative Splicing Switches Potassium Channel Sensitivity to Protein Phosphorylation*

Lijun TianDagger , Rory R. DuncanDagger , Martin S. L. HammondDagger , Lorraine S. CoghillDagger §, Hua Wen, Radda Rusinova||, Alan G. ClarkDagger **, Irwin B. Levitan, and Michael J. ShipstonDagger DaggerDagger

From the Dagger  Membrane Biology Group & Medical Research Council Membrane and Adapter Protein Co-operative Group, University of Edinburgh Medical School, Teviot Place, Edinburgh EH8 9AG, United Kingdom and the  Department of Neuroscience, University of Pennsylvania School of Medicine, Philadelphia, Pennsylvania 19104-6074

Received for publication, October 19, 2000, and in revised form, December 22, 2000



    ABSTRACT
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES

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.



    INTRODUCTION
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES

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 alpha -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 alpha -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 alpha -subunits (12-15) or through their interaction with different signaling complexes and beta -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 PROCEDURES
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES

Molecular and Cell Biology-- cDNAs encoding mouse BK channel variants were subcloned into the mammalian expression vector pcDNA3 or pcDNA3.1+ (Invitrogen BV, Leek, The Netherlands) and transfected into HEK293 cells using lipofectAMINE as previously described (22). The cloning and subcloning of the three splice variants have been described previously (ZERO and STREX-1 (22); and ZERO1/4Delta C, also referred to as mB2 (21, 25)). ZERO lacks inserts at mammalian splice sites 1-5 and STREX-1 channels are identical except for a 59-amino acid cysteine-rich insert at mammalian splice site 2. ZERO1/4Delta C contains inserts at splice sites 1 and 4 and has modified N and C termini compared with ZERO constructs. Site-directed mutagenesis was performed using QuikChange (Stratagene) and verified by DNA sequencing. Site-directed mutants displayed no significant change in single channel kinetics or conductance, although S869A channels displayed a significant shift in V0.5 (10-12 mV in the absence of intracellular ATP) compared with wild type ZERO channels. GST fusion proteins of the STREX-1 splice insert were constructed in pGEX-5x-1 by polymerase chain reaction and recombinant protein purified and assayed in a PKA phosphorylation reaction under standard conditions. Coimmunoprecipitation of channel variants with the catalytic subunit of PKA (PKAc) was performed essentially as described previously (24).

Electrophysiology-- All experiments were performed in the inside-out configuration of the patch clamp technique at room temperature (20-24 °C) using physiological potassium gradients essentially as described previously (22). The pipette solution (extracellular) contained (in mM): 140 NaCl, 5 KCl, 0.1 CaCl2, 2 MgCl2, 20 glucose, 10 HEPES, pH 7.4. The bath solution (intracellular) contained (in mM): 140 KCl, 5 NaCl, 2 MgCl2, 1 or 5 BAPTA, 30 glucose, 10 HEPES, 1 mM ATP, pH 7.3, with free calcium [Ca2+]i buffered to 0.2 µM, unless indicated otherwise. Data acquisition and voltage protocols were controlled by an Axopatch 200 A or B amplifier and pCLAMP6 software (Axon Instruments Inc., Foster City, CA). All recordings were sampled at 10 kHz and filtered at 2 kHz. Following patch excision channel activity was allowed to stabilize for at least 10 min (typically 10-15 min after excision) before application of cAMP or other reagents to the intracellular face of patches by gravity-driven perfusion or direct application to the bath. In all experiments 1 mM cAMP was used to activate endogenous PKA, similar results were also observed using 0.1 mM cAMP (not shown). Patches were held at 0 mV, and channel activity was determined during voltage steps to +40 mV. To determine mean percent change in channel activity after a treatment, in patches with low to moderate levels of channel expression, mean NPo (number of functional channels × open probability of channel) was averaged from 60 s of recording at +40 mV immediately before and 10 min after the respective drug treatment. Mean change in activity was expressed as a percentage of the pretreatment control ± S.E. with analysis undertaken using pCLAMP6 and IGOR Pro3.1 (Wavemetrics). In the respective figure legends and text a positive percentage change in activity reflects activation, whereas a negative percentage change reflects channel inhibition. Statistical significance was defined at p < 0.05 using nonparametric Kruskal-Wallis or Mann-Whiney U test as appropriate.


    RESULTS AND DISCUSSION
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES

Five major alternative splice sites and a conserved weak PKA consensus motif (RQPS869) have been identified in the C-terminal region of mammalian BK channels (14, 20-22, 26, 27) (Fig. 1a).



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Fig. 1.   Activation of endogenous PKA differentially regulates BK channel splice variants. a, diagrammatic representation (not to scale) of BK channel alpha -subunit domain structure. Numbered triangles indicate the five alternative mammalian splice sites in the C-terminal tail of BK channels downstream of the transmembrane domains (black boxes), including the pore region and voltage sensor common to other voltage gated potassium channels. ZERO represents channels lacking inserts at any splice site, STREX-1 represents channels identical to ZERO except for an additional 59-amino acid exon at splice site 2 (stippled box). Serine residue 869 (S869) is conserved in all mammalian BK channel splice variants. The indicated serine residue in the STREX-1 exon (S4STREX) is conserved in all mammalian STREX-1 splice variants. b, representative single channel recordings and diary plots of mean single channel open probability (Po) of STREX-1 and ZERO channels in inside-out patches from HEK293 cells before (Control) and 10 min after application of 1 mM cAMP to the intracellular face of the patch. All currents were recorded in physiological potassium gradients at +40 mV in the presence of 0.2 µM intracellular free calcium and 2 mM MgCl2. c, summary of the mean percent change in activity for each splice variant ± S.E. (shown on the left) after activation of endogenous PKA with 1 mM cAMP. cAMP was applied in the presence (+cAMP) and absence (-ATP) of 1 mM ATP or after pretreatment with 0.45 µM concentration of the specific PKA inhibitor PKI5-24 in the presence of ATP. A positive percent change in activity indicates activation, a negative percent change indicates inhibition.

Application of cAMP to the intracellular face of excised inside-out patches containing channels that lack inserts at any splice site (ZERO construct channels (Fig. 1a) (20, 22)) resulted in significant (p < 0.01) activation of mean channel activity in 10 out of 16 patches (Fig. 1, b and c). The mean percentage activation in response to cAMP was 128.6 ± 45.2%. cAMP-mediated inhibition of channel activity was never observed in patches containing ZERO channels. This activation was dependent upon closely associated cAMP-dependent protein kinase activity as cAMP had no effect in any patch in the absence of ATP (mean percent change in activity was: 2.9 ± 15.6%, n = 4) or in the presence of the specific PKA inhibitor peptide PKI5-24 (-9.3 ± 8.2%, n = 6).

In contrast, under identical recording conditions, application of cAMP to the intracellular face of patches containing channels expressing the 59-amino acid cysteine-rich exon at splice site 2 (STREX-1, Fig. 1a (22, 26)) resulted in significant inhibition of channel activity in eight out of nine patches (Fig. 1, b and c; mean percent change in activity: -56.5 ± 6.8%). cAMP had no significant effect in the absence of ATP (18.6 ± 11.9%, n = 4) or in the presence of PKI5-24 (7.6 ± 11.8%, n = 6). The STREX-1 exon is widely expressed in neuroendocrine tissues and confers enhanced apparent calcium sensitivity on native BK channels compared with the ZERO variant that is highly expressed in brain (22, 26). The inhibitory effect of cAMP was not a result of the enhanced single channel Po observed in STREX-1 compared with ZERO channels under identical recording conditions as cAMP also inhibited STREX-1 channels when recording conditions were adjusted to give a Po similar to that of ZERO (not shown).

The data suggest that an endogenous cAMP-dependent protein kinase A activity (PKA) remains closely associated with STREX-1 or ZERO channels in excised patches from HEK293 cells. Indeed, the catalytic subunit of PKA (PKAc) binds directly to the C-terminal tail of dSlo (24) and coimmunoprecipitates with both mouse ZERO and STREX-1 channel splice variants expressed in HEK293 cells (Fig. 2a). This interaction is specific as PKAc did not coimmunoprecipitate with KCNQ3 potassium channel subunits under the same conditions.2 It is interesting that, in the case of one splice variant of dSlo, PKA regulatory subunit competes with the channel for PKAc binding, and hence the holoenzyme does not bind to the channel.3



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Fig. 2.   Catalytic subunit of protein kinase A (PKAc) coimmunoprecipitates with mSlo splice variants and phosphorylates the STREX exon. a, PKAc and the respective splice variant were transiently expressed in HEK293 cells, and cell lysates were analyzed by Western blotting using an anti-mSlo antibody that recognizes all three variants (top panel) to normalize for channel expression. Lysates were subjected to immunoprecipitation using anti-mSlo and immunoprecipitates subjected to Western blotting with anti-PKAc antibodies (lower panel). b, autoradiograph of 32P-phosphoproteins analyzed by SDS-polyacrylamide gel electrophoresis from in vitro PKA phosphorylation assays of the STREX-1 insert (as a GST fusion protein, GST-STREX-1) and the corresponding site-directed mutant GST-S4STREXA.

In contrast to the robust regulation of ZERO or STREX-1 channels, cAMP had no significant effect on channels containing inserts at splice sites 1 and 4 with different N and C termini (Fig. 1c; ZERO1/4Delta C variant (21), mean percent change in activity was 7.8 ± 5.2%, n = 8). As PKAc also coimmunoprecipitates with the ZERO1/4Delta C variant, the lack of regulation by cAMP is unlikely to be a result of the inability of PKAc to interact with this variant. Thus, the functional effect of PKA-mediated phosphorylation on BK channel activity is determined by alternative exon splicing of the BK channel pore-forming subunit.

The differential regulation of the ZERO and STREX-1 splice variants may result from (i) the STREX-1 exon modifying the functional effect of PKA protein phosphorylation at conserved sites within the alpha -subunit or, alternatively, (ii) the STREX-1 exon itself introducing additional PKA consensus motifs. To address these issues we undertook site-directed mutagenesis of putative conserved C-terminal and STREX-1 insert-specific PKA consensus motifs (Fig. 1a). Although mammalian BK channel alpha -subunits do not contain strong PKA consensus sites, sequence analysis reveals more than 10 putative weaker PKA sites in the C terminus (20, 27). The conserved mammalian C-terminal serine residue at position 869 (Ser869) has been reported as the target for PKA-mediated activation of the hSlo ZERO variant expressed in Xenopus oocytes (27). Furthermore, the equivalent site in dSlo (Ser942) is phosphorylated by PKA (24).

Mutation of serine 869 to alanine (S869A) completely abolished cAMP-mediated activation of the ZERO variant (S869A construct, mean percent change activity was 3.2 ± 1.5%, n = 8) but had no significant effect on cAMP-mediated inhibition of the site-directed STREX-1 variant (STREX-S869A, mean percent change was -58.1 ± 12.1%, n = 11) in excised patches (Fig. 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 = 5, not shown) or in the presence of PKI5-24 (n = 6, Fig. 3b). Thus the effect of cAMP in the STREX-S869A variant is specific to activation of endogenous cAMP-dependent protein kinase and not a result of nonspecific actions or activation of protein kinase G under the recording conditions used. These data suggest that Ser869 is essential for PKA-mediated activation of the ZERO variant but is not required for PKA-mediated inhibition of STREX-1. This implies that the presence of the STREX-1 exon per se does not modify the functional effect of PKA-mediated phosphorylation of Ser869. The presence of the STREX-1 exon may expose or introduce additional protein kinase A consensus sites within the alpha -subunit.



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Fig. 3.   Ser869 and S4STREX are required for cAMP-mediated activation and inhibition of ZERO and STREX-1 respectively. a, representative single channel recordings and diary plots of mean single channel open probability (Po) of S4STREXA and S869A channels in inside-out patches from HEK293 cells before (Control) and 10 min after application of 1 mM cAMP to the intracellular face of the patch as in Fig. 1. b, summary of the effect of site-directed mutation of Ser869 and S4STREX on cAMP-mediated regulation of ZERO and STREX-1 variants. Data are expressed as the mean percent change in channel activity ± S.E. after activation of endogenous PKA with 1 mM cAMP for each construct shown on the left. cAMP was applied in the presence (+cAMP) of ATP or after pretreatment with 0.45 µM of the specific PKA inhibitor PKI5-24 in the presence of ATP. A positive percent change in activity indicates activation, a negative percent change indicates inhibition.

To address whether the STREX-1 exon is itself a target for PKA phosphorylation, we analyzed whether a STREX-1 insert GST fusion protein is a substrate for PKA-dependent phosphorylation in vitro. Sequence analysis of mammalian STREX-1 exons reveals putative weak PKA consensus sites with serine residue 4 (S4STREX, Fig. 1a) conserved in all mammalian STREX-1 inserts identified to date (22, 26). PKA phosphorylates a GST-STREX-1 fusion protein in vitro (Fig. 2b), and this phosphorylation is completely eliminated when S4STREX is mutated to alanine (GST-S4STREXA; Fig. 2b). We thus addressed whether S4STREX plays a functional role in mediating PKA inhibition of STREX-1 using the full-length site-directed S4STREXA mutant expressed in HEK293 cells. In contrast to the robust cAMP-mediated inhibition of channel activity observed with the STREX-1 or STREX-S869A channels cAMP-mediated protein phosphorylation resulted in significant stimulation (mean percent increase in activity was 45.8 ± 5.9%, n = 7) of the S4STREXA site-directed mutant (Fig. 3, a and b). This suggests that S4STREX plays a dominant inhibitory role in the regulation of BK channels expressing the STREX-1 exon as the activation of S4STREXA channels dependent upon the conserved C-terminal Ser869 site is overridden in the presence of a functional S4STREX site. cAMP-dependent protein kinase-mediated regulation was abolished when both the conserved C-terminal Ser869 and exon-specific S4STREX serine residues were mutated to alanine (double mutant, S4STREXA-S869A, percent change was 6.5 ± 6.8%, n = 8, Fig. 3b).

Several mechanisms contribute to the diversity and plasticity of the properties and regulation of potassium ion channels, including multiple gene families, heteromultimerization of subunits, association with regulatory or accessory subunits, and post-translational modifications such as reversible protein phosphorylation. As BK channels are derived from a single gene alternative, exon splicing plays a major role in determining the functional diversity of BK channels.

Our data reveal that alternative exon splicing of BK channels also provides a fundamental context-sensitive mechanism for switching BK channel sensitivity to protein phosphorylation that has significant implications for both the long and short term control of cellular excitability. As BK channel splice variant expression can be dynamically regulated, for example during stress or pregnancy (15, 16), the functional consequence of PKA-mediated regulation of BK channel activity may be switched in the long term by altering the splice variant expressed (e.g. from ZERO to STREX-1). In contrast, short term switching of BK channel sensitivity to PKA could be achieved by specific dephosphorylation of residues important for PKA regulation within a splice insert. For example, in STREX-1 containing channels that are normally inhibited by PKA, dephosphorylation of the PKA site specifically within the STREX-1 insert would allow PKA-dependent activation of the channel through conserved sites in the C terminus (as for S4STREXA construct). Further diversity and plasticity may be achieved through splice variant heteromultimerization and/or association with regulatory subunits (17-19).

In conclusion, alternative exon splicing acts as a powerful long and short term molecular switch to define the sensitivity of BK channels to protein phosphorylation and provides a fundamental mechanism for specifying the diversity, plasticity, and functional role of such modular coincidence detectors of excitable cells.


    ACKNOWLEDGEMENTS

We thank Hannah Florance and Janet Philp for expert technical assistance and other members of the Membrane Biology Group and Medical Research Council Membrane and Adapter Protein Co-operative Group for useful discussion. Mouse brain BK channel clones used to construct expression plasmids were generous gifts from L. Salkoff and L. Pallanck, respectively.


    FOOTNOTES

* This work was supported by grants from The Wellcome Trust (046787) and the Biotechnology and Biological Sciences Research Council (15/C11774) (to M. J. S.) and a grant (to I. B. L.) from the National Institutes of Health.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§ University of Edinburgh Faculty of Medicine postgraduate Crichton Scholar.

|| Current addresses: Dept. of Physiology and Biophysics, Mt. Sinai Medical Center, New York, NY 10029.

** Current addresses: Organon Laboratories Ltd., Newhouse, Lanarkshire ML1 5SH, United Kingdom.

Dagger Dagger To whom all correspondence should be addressed: Membrane Biology Group, University of Edinburgh Medical School, Teviot Place, Edinburgh EH8 9AG, United Kingdom. Tel.: 44-131-650-3253; Fax: 44-131-650-6527; E-mail: mike.shipston@ed.ac.uk.

Published, JBC Papers in Press, January 19, 2001, DOI 10.1074/jbc.C000741200

2 H. Wen and I. B. Levitan, unpublished data.

3 Y. Zhou and I. B. Levitan, unpublished data.


    ABBREVIATIONS

The abbreviations used are: BK, large conductance calcium-activated potassium; PKA, cAMP-dependent protein kinase; GST, glutathione S-transferase; BAPTA, 1,2-bis(aminophenoxy)ethane-N,N,N',N'-tetraacetic acid.


    REFERENCES
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES


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