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1 Laboratoire de Physiopathologie et de Pharmacologie Cellulaires et Moléculaires, Hôpital Hôtel-Dieu, Institut National de la Santé et de la Recherche Médicale, 44093 Nantes Cedex, France; and 2 Howard Hughes Medical Institute, Vollum Institute, Portland, Oregon 97201
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ABSTRACT |
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 TOP
 ABSTRACT
 INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
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In cardiac myocytes, the slow component of the delayed rectifier K+ current (IKs) is regulated by cAMP. Elevated cAMP increases IKs amplitude, slows its deactivation kinetics, and shifts its activation curve. At the molecular level, IKs channels are composed of KvLQT1/IsK complexes. In a variety of mammalian heterologous expression systems maintained at physiological temperature, we explored cAMP regulation of recombinant KvLQT1/IsK complexes. In these systems, KvLQT1/IsK complexes were totally insensitive to cAMP regulation. cAMP regulation was not restored by coexpression with the dominant negative isoform of KvLQT1 or with the cystic fibrosis transmembrane regulator. In contrast, coexpression of the neuronal A kinase anchoring protein (AKAP)79, a fragment of a cardiac AKAP (mAKAP), or cardiac AKAP15/18 restored cAMP regulation of KvLQT1/IsK complexes inasmuch as cAMP stimulation increased the IKs amplitude, increased its deactivation time constant, and negatively shifted its activation curve. However, in cells expressing an AKAP, the effects of cAMP stimulation on the IKs amplitude remained modest compared with those previously reported in cardiac myocytes. The effects of cAMP stimulation were fully prevented by including the Ht31 peptide (a global disruptor of protein kinase A anchoring) in the intracellular medium. We concluded that cAMP regulation of IKs requires protein kinase A anchoring by AKAPs, which therefore participate with the channel protein complex underlying IKs.
A kinase anchoring protein; KCNQ1; KCNE1; slow delayed rectifier potassium current
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INTRODUCTION |
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TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
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HORMONAL STIMULATION OF
THE HEART involves the control of Ca2+ and
K+ currents. These events are triggered by a multistep
pathway comprising receptor-mediated activation of adenylyl cyclase and
the generation of the diffusable second messenger cAMP, resulting in
the activation of protein kinase A (PKA) (25). In
guinea pig ventricular myocytes, PKA stimulation produces an increase
in the amplitude of the delayed rectifier K+ current
(27, 28, 32). PKA activation also promotes a negative shift in its activation curve and an alteration of its deactivation kinetics (27, 28). It was previously shown that the slow
component of the delayed rectifier K+ current
(IKs) constitutes the K+ current
component sensitive to 
-adrenergic stimulations (27). In the heart muscle, IKs is related to the
activity of the KvLQT1 K+ channel protein in tandem with
its regulator, termed IsK (or minK) (2, 22). KvLQT1
channel proteins but not IsK possess a putative consensus
phosphorylation site by PKA between residues 24 and 27. Expression of
the human KvLQT1 proteins alone in Xenopus oocytes underlies
a voltage-dependent K+ current that is sensitive to PKA
stimulation (31), whereas expression of IsK alone
activates an endogenous KvLQT1-like protein that generates a
cAMP-sensitive voltage-dependent K+ current similar to
IKs (13, 21, 26, 31).
In the present study, we investigated the regulation of the human recombinant KvLQT1/IsK complex in mammalian cell lines maintained at physiological temperature. Surprisingly, these expression systems lacked key element(s) to permit cAMP activation of the IKs. cAMP regulation of IKs was restored by coexpression of KvLQT1/IsK together with A kinase anchoring proteins (AKAPs). AKAPs comprise a group of proteins with a proposed role in mediating the attachment of type II PKA to subcellular structures (20). We concluded that AKAPs are a key element for regulation of IKs by cAMP and may be additional protein components of the IKs channel functional complex.
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MATERIALS AND METHODS |
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TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
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Intranuclear injection of plasmids. COS-7 cells [American Type Culture Collection (ATTC); Manassas, VA] were cultured in Dulbecco's medium supplemented with 10% fetal calf serum and antibiotics (100 IU/ml penicillin and 100 µg/ml streptomycin; all from GIBCO-BRL; Paisley, Scotland) at 37°C in a humidified incubator. Swiss 3T3 fibroblasts and HEK293 cells were also obtained from the ATTC. Cultured cells were microinjected into the nucleus with plasmids at day 1 after plating. The protocol to microinject cultured cells using the Eppendorf ECET microinjector 5246 system has been previously reported (17). Briefly, plasmids were diluted in a buffer made of (in mmol/l) 40 NaCl, 50 HEPES, and 50 NaOH; pH 7.4 supplemented with 0.5% fluorescein isothiocyanate-dextran (150 kDa). Human cardiac KvLQT1 isoform 1, KvLQT1 isoform 2, and the cystic fibrosis transmembrane conductance regulator (CFTR) were subcloned into the mammalian expression vector pCI (Promega; Madison, VI) under the control of a cytomegalovirus enhancer/promoter. AKAP79, a fragment of cardiac AKAP (mAKAP), and AKAP15/18 were subcloned into the mammalian expression vector pCDNA3. Human IsK cDNA was subcloned into a pRC vector under the control of a cytomegalovirus promoter. CFTR cDNA was subcloned into a pCDNA3 plasmid. A green fluorescence protein pCI plasmid (a gift from Dr. Rainer Waldmann; Sophia-Antipolis, France) was used as an inert coplasmid to ensure that cells were always injected with a constant 15 µg/ml plasmid concentration.
Patch-clamp recordings.
Whole cell currents were recorded as previously described
(17). Cells were placed on the stage of an inverted
microscope and continuously superfused with the standard extracellular
solution. Patch pipettes with a tip resistance of 2.5-5 M
were
electrically connected to a patch-clamp amplifier (Axopatch 200A, Axon
Instruments; Foster City, CA). Stimulation, data recording, and
analysis were performed through an analog-to-digital converter (Tecmar
TM100 Labmaster, Scientific Solutions; Solon, OH) and Acquis1 software (Bio-Logic; Claix, France). A microperfusion system allowed local application and rapid change of the different experimental solutions warmed at 35°C. Current measurements were normalized using the cell
capacitance. Patch-clamp measurements are presented as the means ± SE. Statistical significance of the observed effects was assessed by
means of the paired t-test or two-way ANOVA when needed. A
value of P < 0.05 was considered significant.
Solutions and drugs. The standard extracellular medium contained (in mmol/l) 145 NaCl, 4 KCl, 1 MgCl2, 1 CaCl2, 5 HEPES, and 5 glucose; pH was adjusted to 7.4 with NaOH. The intracellular medium contained (in mmol/l) 145 potassium gluconate, 5 HEPES, 2 EGTA, 2 hemimagnesium gluconate (free Mg2+: 0.1), and 2 K2ATP; pH 7.2 with KOH, whereas the extracellular medium used to record K+ currents contained (in mmol/l) 145 sodium gluconate, 4 potassium gluconate, 7 hemicalcium gluconate (free Ca2+: 1), 4 hemimagnesium gluconate (free Mg2+: 1), 5 HEPES, and 5 glucose; pH 7.4 with NaOH. Free activities were calculated using a software designed by G. L. Smith (University of Glasgow, Glasglow, UK). Intracellular cAMP was increased with a mixture made of 10 µmol/l forskolin plus 400 µmol/l 8-(4-chlorophenylthio)-cAMP (cpt-cAMP) (both from Sigma; St. Louis, MO). The anchoring inhibitor peptide derived from Ht31 was used at concentration of 1 µmol/l in the intracellular solution (3, 19).
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RESULTS |
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TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
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Effects of cAMP on KvLQT1/IsK complex expressed in mammalian cells.
With the objective of investigating the PKA-mediated regulation of
recombinant IKs in a mammalian expression
system, human KvLQT1 and IsK plasmids were injected into COS-7 cells.
The whole cell configuration of the patch-clamp technique was used to
assess the formation of functional channel complexes. Results obtained in cells injected with 2.5 µg/ml pCI-KvLQT1 and 2.5 µg/ml pRC-IsK are summarized in Fig. 1. As shown in
Fig. 1, A and B, the IKs current elicited by a depolarizing step to +40 mV was totally insensitive to cAMP stimulation produced by adding 10 µmol/l
forskolin plus 400 µmol/l cpt-cAMP to the extracellular medium. On
average, the voltage-activated K+
current measured during the depolarizing step to +40 mV was
27.5 ± 7.2 pA/pF in control versus 28.9 ± 7.6 pA/pF under
cAMP stimulation [n = 8; P = not
significant (NS)]. In the same expression system, we have previously
shown that intracellular cAMP increases at least 10-fold in response to
10 µmol/l forskolin, thereby allowing PKA-mediated activation of CFTR
channels (12). Therefore, the absence of response to
forskolin plus cpt-cAMP of KvLQT1/IsK complexes was unlikely to be
caused by low intracellular cAMP. Deactivating tail currents at 
40 mV
were fitted by a single-exponential decay, which was extrapolated to
time 0 so as to reliably measure tail current amplitude. As
illustrated in Fig. 1, A and C, no difference was
observed in either the tail current amplitude (9.6 ± 2.4 pA/pF in
control vs. 9.5 ± 2.4 pA/pF with cAMP, respectively;
n = 8) or deactivation kinetics [deactivation time
constant (
deact) was 95.4 ± 7.1 ms in control vs.
101.7 ± 10.6 ms with cAMP, n = 6; Fig.
1C] in the absence or presence of cAMP stimulation. The
voltage-dependence of the IKs was also
investigated. Neither the current-voltage relation for
IKs (Fig. 1B) nor its activation (Fig. 1D) were affected by increased cAMP: the
half-activation potential (V0.5) was 9.4 ± 3.4 mV in control conditions versus 6.2 ± 5.8 mV under cAMP
stimulation (n = 5). Additional experiments were also
carried out in other cell lines including HEK293 and 3T3 fibroblast
cells. These experiments produced similar negative data as obtained in
COS-7 cells (data not shown). Thus this first set of experiments
demonstrated that KvLQT1/IsK channel complexes expressed in mammalian
cells are insensitive to cAMP-mediated PKA activation. We next tested
whether a regulating protein, absent in host mammalian cells, was
involved in the sensitivity of KvLQT1/IsK complex to cAMP stimulation.
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Effects of cAMP on IKs in the presence of regulating
proteins.
KvLQT1 isoform 2 is a KCNQ1 gene alternative splice variant
constitutively expressed in the adult human heart, which participates in the IKS channel complex
(4). Isoform 2 has an NH2-terminal sequence 131 amino acids shorter than the cardiac KvLQT1 full-length isoform (isoform 1) (4) and thus lacks the consensus
protein kinase phosphorylation site localized at amino acids 24-27
of isoform 1. In a previous work (4), we have shown that
COS-7 cells expressing both KvLQT1 isoform 1 and isoform 2 in the
presence of IsK exhibited a K+ current with a reduced
amplitude compared with cells expressing KvLQT1 isoform 1 plus IsK. We
decided to test whether coexpression of isoform 2 as in cardiac
myocytes interferes with protein kinase phosphorylation of isoform 1. As shown in Fig. 2A, cells
injected with KvLQT1 isoform 1, KvLQT1 isoform 2, and IsK plasmids
exhibited an IKs that was also insensitive to
cAMP stimulation (n = 7). Varying the concentration of
IsK or KvLQT1 isoform 2 plasmids in the injection medium did not affect
cAMP regulation of IKs.
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Effect of cAMP on IKs in the presence of AKAPs.
COS-7 cells were coinjected with KvLQT1, IsK, and AKAP79 plasmids. In
the absence of cAMP stimulation, the characteristics of
IKs generated by the KvLQT1/IsK complex in the
presence of AKAP79 were undistinguishable from those recorded in its
absence. In cells expressing KvLQT1 plus IsK, the K+
current amplitude at +40 mV was 25.9 ± 5.1 pA/pF
(n = 12), i.e., not different from the value obtained
in cells coexpressing AKAP79 (26.9 ± 5.8 pA/pF; n = 10). Other parameters of IKs were not altered by AKAP79 expression including activation and deactivation kinetics and
voltage dependence. In contrast, in cells expressing AKAP79, the
amplitude of the K+ current related to
KvLQT1/IsK expression was consistently enhanced by 10 µmol/l
forskolin plus 400 µmol/l cpt-cAMP (Fig.
3, A and B). The
tail current amplitude increased from 7.8 ± 2.6 to 8.6 ± 2.5 pA/pF (+15%, n = 6, P < 0.01)
under cAMP stimulation. In addition, deact also
increased from 104.5 ± 16 to 122.9 ± 17 ms
(n = 6, P < 0.001; Fig.
3C). Figure 3D illustrates the time course of
IKs tail current amplitude and
deact changes as produced by cAMP enhancement. In native
cardiac cells, phosphorylating agents shift the activation curve of
IKs toward more negative potentials (28,
32). In accordance with this, in our cells, the
IKs activation curve shifted toward more
negative potentials under cAMP (Fig. 3E;
V0.5 was 12.9. ± 6.5 mV under control vs. 3.6 ± 5.7 mV with cAMP, n = 6, P < 0.01). Thus AKAP79 expression in COS-7 cells restores regulation by
cAMP of the expressed KvLQT1/IsK channel.
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-helical conformation, binding to the PKA RII site and preventing
PKA anchoring. The same experiments as conducted in cells coexpressing
KvLQT1/IsK and mAKAP were repeated in the presence of 1 µmol/l Ht31
peptide in the intracellular pipette solution dialysing the cell.
Results are summarized in Fig. 5. The
basal current recorded under such conditions was not modified by Ht31 peptide. In the presence of Ht31 peptide, however, cAMP stimulation did
not increase the K+ current amplitude (tail
current amplitude was 8.2 ± 1.7 pA/pF in control vs. 7.5 ± 1.5 pA/pF under cAMP, n = 7, P = NS)
did not modify deact (97.1 ± 5.9 vs. 108.5 ± 7.1 ms, n = 6, P = NS) and did not
shift the activation curve (V0.5 was 10.3. ± 5.4 vs. 7.5 ± 4.2 mV, n = 5, P = NS). Thus preventing PKA anchoring to AKAPs with Ht31 peptide
suppresses its activity on KvLQT1/IsK channel complexes.
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DISCUSSION |
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TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
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In this report, we show that AKAP expression is required for cAMP regulation of recombinant IKs in mammalian cell lines. Recombinant KvLQT1/IsK complexes expressed in mammalians cells (COS-7, HEK293, or 3T3 cells) are insensitive to cAMP stimulation in the absence of AKAP. This observation contrasts with the well-known stimulatory effects of PKA on recombinant IKs in Xenopus oocytes (13, 21, 26, 31). However, Xenopus oocytes have been shown to express an endogenous KvLQT1-like protein, which complements with exogenous IsK to form functional channel complexes (2, 22). In the absence of exogenous IsK, endogenous KvLQT1-like channel activity cannot be detected in oocytes. KvLQT1 channel proteins but not IsK possess a putative consensus phosphorylation site for PKA. Therefore, when oocytes are injected with IsK mRNA to record recombinant IKs, the target for PKA is the KvLQT1-like protein settled in its natural environment. To our knowledge, only one study (31) showed that exogenous human KvLQT1 expressed in oocytes is also sensitive to PKA phosphorylation. In that situation, however, the exogenous KvLQT1 profits in the same environment as the endogenous KvLQT1-like protein. Our study, which was performed in an expression system containing no endogenous KvLQT1 expression, demonstrates that exogenous KvLQT1 is not sensitive to PKA. In this connection, it was previously shown that the sensitivity to regulation by PKA of Kv1.3 channels is partially lost when recombinant channels are expressed in mammalian HEK293 host cells (15). Similarly, Zong et al. (34) reported that the L-type Ca2+ channel reconstituted in HEK293 cells does not display the same extent of sensitivity to modulation by cAMP-dependent phosphorylation as the native channel in myocytes. Likewise, Gerlach et al. (8) found that hIK1 K+ channels are activated by PKA when endogenously expressed and that this regulation is recapitulated in Xenopus oocytes but not in HEK293 cells. Interestingly, cAMP regulation of KCNQ2 and KCNQ3 gene products, which are highly homologous to KvLQT1, does not require coexpression of an AKAP in mammalian cells (24).
In mammalian cells transfected with human KvLQT1/IsK complexes, coexpression of AKAPs and biologically active fragments restored regulation of recombinant IKs by PKA. Functional analysis of AKAPs began when Rosenmund et al. (19) applied electrophysiological techniques in concert with the perfusion of Ht-31 peptide to assess the role of AKAPs in cultured hippocampal neurons. Since 1994, studies have shown that AKAPs are involved in ionic channel regulation in a variety of tissues (6). Cardiac AKAP15/18 has been shown to be required for PKA-dependent potentiation of L-type calcium channels (9, 11). In mammalian cells expressing AKAP79, mAKAP, or AKAP15/18, PKA increased the amplitude of recombinant IKs, shifted its activation curve, and slowed its deactivation kinetics. These effects recapitulate those produced by cAMP stimulation on endogenous IKs in cardiac myocytes (28, 32). However, in cardiac myocytes, cAMP stimulation with isoproterenol almost doubles the IKs tail amplitude (23, 28, 29, 32). In Xenopus oocytes expressing exogenous KvLQT1, the addition of 10 µmol/l forskolin plus 100 µmol/l IBMX increases the IKs peak current by 44% (31). In our study, 10 µmol/l forskolin plus 400 µmol/l cpt-cAMP increased the recombinant IKs tail amplitude by only 15% in COS-7 cells expressing AKAP79, by 16% in cells expressing mAKAP, and by 22% in cells expressing AKAP15/18. Although these effects were fully prevented by Ht31 peptide and although they were accompanied by significant modifications in the activation curve and deactivation kinetics, they remained modest in amplitude relatively to what is usually observed in myocytes. We interpret this difference as an indication that host mammalian cells are still missing an additional partner in the channel complex. Further investigation should be directed to identify this putative partner.
The main function of AKAPs is to contribute to PKA
compartimentalization in the vinicity of PKA targets. KvLQT1 channel
proteins are mainly expressed in cardiac and epithelial tissues but are not abundant in the central nervous system (5). Despite
this tissue distribution, cAMP regulation of recombinant
IKs was restored when either the neuronal AKAP79
or the cardiac mAKAP or AKAP15/18 were coexpressed, suggesting a low
specificity for AKAPs to permit PKA regulation of KvLQT1. Critical
RII-binding regions in several AKAPs have been identified and consist
in each case of a single amphipathic helix (18).
Interestingly, the AKAP binding of PKA in the heart may be regulated by
RII autophophorylation (33). A short peptide containing
the RII-binding amphipathic helix of the AKAP Ht31 has been shown to
bind RII with nanomolar affinity and has been termed an "anchoring
inhibitor peptide" on the basis of its ability to competitively
inhibit RII-AKAP interactions. Microinjection of Ht31 peptide displaces
the kinase from the anchoring sites and attenuates ion flow through
skeletal muscle L-type Ca2+ channels (11) and
-amino-3-hydroxy-5-methyl-isotazole propione acid-kainate glutamate
receptor ion channels (19).
Given the importance of IKs in cardiac action
potential repolarization and its role in long Q-T syndrome,
understanding the regulation of human IKs may
shed light on its physiological and pathophysiological roles. The
ability to up- or downregulate IKs is a means of
controlling the duration of action potential in the human heart.
IKs is generated by a complex protein assembly composed of KvLQT1 isoform 1 (the channel pore), KvLQT1 isoform 2 (a
dominant negative protein), and IsK (the channel regulator). The
present data provide support for the formation of signaling complexes
in which protein kinases that regulate phosphorylation status of KvLQT1
isoform 1 are maintained in proximity to their target protein. Our
results therefore suggest that, in the human heart,
IKs is generated by a protein assembly composed
of KvLQT1 isoform1, KvLQT1 isoform2, IsK, and a anchoring protein that
permits its -adrenergic regulation.
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ACKNOWLEDGEMENTS |
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We thank Béatrice Leray, Marie-Joseph Louerat, Emilie Grelet, and Chloé Bellocq for expert technical assistance with cell cultures and plasmid amplifications.
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FOOTNOTES |
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This study was supported by Institut National de la Santé et de la Recherche Médicale Grant PROGRES 4P009D (to D. Escande) and National Institute of General Medical Sciences Grant GM-48231 (to J. D. Scott).
Address for reprint requests and other correspondence: D. Escande, Laboratoire de Physiopathologie et de Pharmacologie Cellulaires et Moléculaires, INSERM U533, Bât HNB, Hôpital Hôtel-Dieu, BP 1005, 44093 Nantes Cedex, France (E-mail: denis.escande{at}inserm.nantes.fr).
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.
Received 19 June 2000; accepted in final form 6 November 2000.
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REFERENCES |
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TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
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) and under cAMP stimulation
(
; n = 8). Inset:
superimposed current traces elicited by test potentials between 
