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Akt regulates L-type Ca²⁺ channel activity by modulating Ca_v1 protein stability

¹ Division of Cardiology, Department of Medicine and ² Department of Pharmacology, University of California, San Diego, La Jolla, CA 92093
³ Istituto di Ricovero e Cura a Carattere Scientifico Multimedica, Milan 20138, Italy
⁴ Department of Pharmacology, School of Medicine and ⁵ Genome and Biomedical Sciences Facility, University of California, Davis, Davis, CA 95616
⁶ Physiopathologie Cardiovasculaire, Institut National de la Santé et de la Recherche Médicale Unité 637, Université Montpellier 1, Montpellier 34295, France
⁷ Département de Physiologie, Institut de Génomique Fonctionnelle, Centre National de la Recherche Scientifique Unité Mixte de Recherche 5203, Institut National de la Santé et de la Recherche Médicale Unité 661, Université Montpellier 2, Montpellier 34295, France
⁸ Dipartimento di Ematologia, Oncologia e Medicina Molecolare, Istituto Superiore Sanità, Rome 00161, Italy

Correspondence to Daniele Catalucci: daniele.catalucci{at}itb.cnr.it; or Gianluigi Condorelli: gcondorelli{at}ucsd.edu

The insulin IGF-1–PI3K–Akt signaling pathway has been suggested to improve cardiac inotropism and increase Ca²⁺ handling through the effects of the protein kinase Akt. However, the underlying molecular mechanisms remain largely unknown. In this study, we provide evidence for an unanticipated regulatory function of Akt controlling L-type Ca²⁺ channel (LTCC) protein density. The pore-forming channel subunit Ca_v1 contains highly conserved PEST sequences (signals for rapid protein degradation), and in-frame deletion of these PEST sequences results in increased Ca_v1 protein levels. Our findings show that Akt-dependent phosphorylation of Ca_vβ2, the LTCC chaperone for Ca_v1, antagonizes Ca_v1 protein degradation by preventing Ca_v1 PEST sequence recognition, leading to increased LTCC density and the consequent modulation of Ca²⁺ channel function. This novel mechanism by which Akt modulates LTCC stability could profoundly influence cardiac myocyte Ca²⁺ entry, Ca²⁺ handling, and contractility.

Abbreviations used in this paper: AID, 1-interacting domain; ANOVA, analysis of variance; DN, dominant-negative; GAPDH, glyceraldehyde-3-phosphate dehydrogenase; KO, knockout; LTCC, L-type Ca²⁺ channel; PLN, phospholamban; Ryr, ryanodine receptor; siAkt, small interfering Akt; SR, sarcoplasmic reticulum; TEA, tetraethylammonium; Tg, transgenic; WT, wild type.

© 2009 Catalucci et al.
This article is distributed under the terms of an Attribution–Noncommercial–Share Alike–No Mirror Sites license for the first six months after the publication date (see http://www.jcb.org/misc/terms.shtml). After six months it is available under a Creative Commons License (Attribution–Noncommercial–Share Alike 3.0 Unported license, as described at http://creativecommons.org/licenses/by-nc-sa/3.0/).

	Introduction

Top Abstract Introduction Results Discussion Materials and methods References

 
The IGF-1 (insulin growth factor 1)–PI3K (phosphatidylinositol 3-kinase)–Akt pathway plays a crucial role in a broad range of biological processes involved in the modulation of local responses as well as processes implicated in metabolism, cell proliferation, transcription, translation, apoptosis, and growth. In the heart, the IGF-1–PI3K–Akt pathway is involved in the regulation of contractile function, and impairment of this signaling pathway is considered an important determinant of cardiac function (Condorelli et al., 2002; McMullen et al., 2003; Ceci et al., 2004; McMullen et al., 2004; Catalucci and Condorelli, 2006; Sun et al., 2006).

The Akt (also called PKB) family of Ser/Thr kinases consists of three isoforms (Akt-1, -2, and -3) that are activated by IGF-1 and insulin through PI3K, which is a member of the lipid kinase family involved in the phosphorylation of membrane phosphoinositides (Ceci et al., 2004). The product of PI3K binds to the pleckstrin domain of Akt and induces its translocation from the cytosol to the plasma membrane, where Akt becomes accessible for phosphorylation by PDK1 (phosphoinositide-dependent kinase 1), resulting in its activation (Ceci et al., 2004; Bayascas et al., 2008). The Ca²⁺ current (I_Ca,L) in both cardiomyocytes and neuronal cells has been shown to be increased by Akt activation (Blair et al., 1999; Viard et al., 2004; Catalucci and Condorelli, 2006; Sun et al., 2006) and decreased by Akt inhibition (Viard et al., 2004; Catalucci and Condorelli, 2006; Sun et al., 2006), suggesting a pivotal role of Akt in regulating L-type Ca²⁺ channel (LTCC) complex function.

In cardiomyocytes, the LTCC is composed of different subunits: the pore-forming subunit Ca_v1 and the accessory β and 2 subunits (Catterall, 2000; Bourinet et al., 2004). The opening of the LTCC is primarily regulated by the membrane potential and by other factors, including a variety of hormones, protein kinases, phosphatases, and accessory proteins (Bodi et al., 2005). In healthy cardiomyocytes, electrical excitation starting during the upstroke of the action potential leads to cytosolic Ca²⁺ influx through opening of the LTCC (Bers and Perez-Reyes, 1999; Richard et al., 2006). This triggers the CICR (Ca-induced Ca release) of intracellular Ca²⁺ from the sarcoplasmic reticulum (SR) through activation of the ryanodine receptor (Ryr), eventually leading to cardiomyocyte contraction (Bers, 2002).

The importance and ubiquity of Ca²⁺ as an intracellular signaling molecule suggests that altered channel function could give rise to widespread cellular and organ defects. Indeed, a variety of cardiovascular diseases, including atrial fibrillation, heart failure, ischemic heart disease, Timothy syndrome, and diabetic cardiomyopathy, have been related to alterations in the density or function of the LTCC (Mukherjee and Spinale, 1998; Quignard et al., 2001; Bodi et al., 2005; Pereira et al., 2006). However, the molecular basis for dysregulation of LTCC function and the possible involvement of Akt in I_Ca,L regulation remain unresolved.

Recently, a seminal study in neuronal cells revealed the importance of Akt-dependent phosphorylation of the Ca_vβ2 subunit in promoting the chaperoning of the Ca_v2.2 pore-forming unit to the plasma membrane (Viard et al., 2004). In this study, we identify a novel posttranslational mechanism by which Akt modulates LTCC function under physiological conditions, highlighting the pivotal role of this kinase in cardiac function. Interestingly, our results show that the pore-forming channel subunit Ca_v1 contains highly conserved PEST sequences that direct rapid protein degradation and demonstrate that Akt-mediated phosphorylation of the Ca_vβ2 LTCC chaperone subunit prevents PEST site recognition, thereby slowing or preventing Ca_v1 degradation. This mechanism of action might be an essential process for Ca²⁺ channel functional regulation, thus contributing to normal or better cardiomyocyte contractile function.

	Results

Top Abstract Introduction Results Discussion Materials and methods References

 
To gain insight into the mechanism of action by which Akt regulates I_Ca,L and Ca²⁺ handling in the heart, we studied a mouse line with tamoxifen-inducible (Sohal et al., 2001) and cardiac-specific deletion of PDK1, the upstream activator of all three Akt isoforms. Mice in which exons 3 and 4 of the pdk1 gene were flanked by loxP excision sequences (Lawlor et al., 2002) were crossed with transgenic (Tg) mice expressing an inducible and cardiac-specific MerCreMer -MHC promoter driving the cre recombinase gene (Sohal et al., 2001), resulting in MerCreMer -MHC PDK1 mice (knockout [KO]). As opposed to the previously described muscle creatine kinase–Cre PDK1 mouse model (Mora et al., 2003) in which PDK1 is embryonically deleted in all striated muscles, this model allows for specific deletion of PDK1 in the adult heart. A further advantage of this model is the inducible cardiac-specific deletion that was necessary to circumvent the embryonic lethality we observed in a mouse model with constitutive -MHC–Cre cardiac deletion of PDK1 (unpublished data). Similar to the muscle creatine kinase–Cre PDK1 mouse model (Lawlor et al., 2002), PDK1 gene deletion in the adult mouse heart (KO; Fig. S1, A and B) resulted in a lethal phenotype with a mortality that reached 100% at 10 d after tamoxifen injection (Fig. S1 C). Age-matched littermate control mice without cre (wild type [WT]) were unaffected by tamoxifen treatment. Consistent with findings from the previously reported analysis of the PDK1 KO mouse model (Lawlor et al., 2002), cardiac function evaluated by echocardiography at 7 d after tamoxifen injection revealed dramatically impaired systolic function with severe dilated cardiomyopathy and an abrupt drop in fractional shortening in KO but not in WT mice (Fig. S1 D, Table S1, and not depicted). Histological examination substantiated the echocardiographic findings, revealing dilatation of both ventricles and atria (Fig. S1 E) with apparently no evidence of significant apoptosis or interstitial fibrosis (Fig. S1, F and G). These observations indicate that PDK1/Akt activity plays a major role in maintaining adult heart function.

Deficiency in Akt activity leads to a reduction in the Ca_v1 protein level
Using the cardiac-specific PDK1 KO mouse model, we investigated whether deficiency in Akt activity affects the expression or activation of signaling molecules that are implicated in Ca²⁺ handling and cardiac function. A time course analysis of extracts from WT and KO mouse ventricles revealed striking changes in protein expression upon induction of the PDK1 KO (Fig. 1, A and B). Notably, KO mice had decreased protein levels of the pore-forming Ca²⁺ channel subunit, Ca_v1, which progressed as PDK1 protein expression gradually declined. No change in the protein level of the regulatory Ca_vβ2 subunit was observed. As PDK1 expression decayed, levels of Akt activation also dramatically decreased (assessed by phosphorylation of Akt at the PDK1 phosphorylation site Thr308) despite unaltered expression of total Akt protein (Fig. 1, A and B). Furthermore, Akt activity (assessed using GSK-3β as a substrate) was virtually absent in KO hearts (Fig. 1 C). Based on this evidence, we decided to perform further experiments at day 6 after the beginning of treatment.

View larger version (40K): [in this window] [in a new window] [Download PPT slide]   Figure 1. Alteration of Ca2+ handling proteins in PDK1 KO cardiomyocytes. (A and B) Western blot (A) and densitometric (B) analyses of ventricular homogenates along a time course of tamoxifen inductions (day 1–6 treatment is indicated by the line in A) using various antibodies. A representative experiment is shown (n = 3). Error bars show SD. (C) Total Akt activity in WT and KO cardiomyocyte lysates assayed using a GSK-3β/ Akt-specific substrate. IP, immunoprecipitation.

Deficiency in Akt activity affects I_Ca,L
Ca²⁺ handling and inotropism were examined in adult cardiomyocytes freshly isolated from WT and KO mice. Using the whole cell voltage-clamp technique, we recorded and analyzed LTCC I_Ca,L properties. No difference in cell size was observed between WT and KO cells as deduced from membrane capacitance measurements. Membrane capacitance was 116 ± 6 pF in WT cells (n = 18) and 115 ± 6 pF in KO cells (n = 18). However, the density of I_Ca,L (picoampere/picofarad) was decreased in KO versus WT (Fig. 2 B). At 0 mV, the density of I_Ca,L was –9.08 ± 0.96 pA/pF in KO cells (n = 12) versus –16.26 ± 0.96 pA/pF in WT cells (n = 12; P < 0.001). In addition, there was no significant difference in either steady-state activation or inactivation curves (unpublished data). Indeed, mean half-activation occurred at –12.97 ± 0.53 mV in WT cells versus –15.07 ± 0.66 mV in KO cells, and mean half-inactivation occurred at –31.11 ± 0.48 mV in WT cells versus –30.77 ± 0.42 mV in KO cells. The absence of a shift in the voltage dependence of these properties (Fig. 2 B) was consistent with the absence of modification in gating properties of the LTCC, suggesting that a reduction in the number of functional LTCCs can account for the observed decrease in I_Ca,L in KO mice. Of note, the decay kinetics of I_Ca,L were slower in KO cells compared with WT cells with a decrease in the early fast inactivating component (Fig. 2 A). Consistent with previous observations by us and others regarding the role of Akt in cardiac function (Blair et al., 1999; Condorelli et al., 2002; Kim et al., 2003; Sun et al., 2006), both contraction (Fig. 2 C) and systolic Ca²⁺ amplitudes (Ca²⁺ transients; Fig. 2 D and Fig. S3 A) were significantly depressed (by 35% and 30%, respectively; P < 0.05) in KO cardiomyocytes compared with WT littermates.

View larger version (21K): [in this window] [in a new window] [Download PPT slide]   Figure 2. Impaired intracellular Ca2+ handling and contractility in PDK1 KO cardiomyocytes. (A and B) Smaller Ca2+ current in KO cardiomyocytes. (A) Whole cell representative ICa,L currents normalized for difference in cell size. (B) ICa,L I-V current/voltage relationships (n = 12; *, P < 0.05; **, P < 0.01). (C and D) Cardiomyocyte contraction and Ca2+ transients at different stimulation frequencies. (C) Cardiomyocyte shortening is decreased in KO compared with WT cardiomyocytes (*, P < 0.05; ANOVA). (D) Ca2+ frequency relationship indicates smaller peak systolic but not diastolic Ca2+ in KO compared with WT cells (*, P < 0.05; ANOVA). Error bars show SEM.

Akt regulates the Ca_v1 protein level at the plasma membrane
The properties of the Ca_v1 subunit are known to be markedly affected by LTCC accessory subunits (Catterall, 2000; Bourinet et al., 2004). Among the LTCC accessory subunits expressed in the heart, Ca_vβ2 is known to act as a chaperone for the Ca_v1 subunit, both as a positive modulator of channel opening probability and for its trafficking from the ER to the plasma membrane (Yamaguchi et al., 1998; Viard et al., 2004). Therefore, supported by previous results (Viard et al., 2004) as well as corroborated by unchanged Ca_v1 mRNA levels in KO compared with WT hearts (Fig. 3 A), we hypothesized that in the heart, an Akt-mediated phosphorylation of the LTCC accessory subunit would mainly affect trafficking of Ca_v1 protein to the plasma membrane. However, because the amount of Ca_v1 was reduced in both microsomal and membrane fractions from KO extracts compared with WT (Fig. 3 B), we hypothesized that the reduced Ca_v1 level observed in KO mice was caused by enhanced protein degradation in addition to impaired protein translocation to the plasma membrane. To assess the pathway involved in the Akt-dependent Ca_v1 protein degradation, three sets of specific cell degradation system inhibitors were examined for their ability to prevent the decrease in Ca_v1 protein elicited by Akt inhibition. Treatment of Ca_v1- and Ca_vβ2-cotransfected cells with bafilomycin-A1, an inhibitor of the lysosomal degradation system responsible for the degradation of many membrane proteins (Dice, 1987), prevented the decrease in Ca_v1 protein induced by Akt inhibition (Fig. 3 C, top). Conversely, a ubiquitin/proteasome inhibitor, MG132, failed to protect Ca_v1 from protein degradation. Similar results were obtained by inhibiting calpain, the intracellular Ca²⁺-dependent Cys protease known to be involved in membrane protein degradation (Belles et al., 1988; Romanin et al., 1991). Intriguingly, the bafilomycin-A1–dependent protection effect was abolished in the absence of Ca_vβ2 cotransfection, a condition under which Ca_v1 is retained in the ER (Fig. 3 C, bottom). All together, these results confirm that Akt activity is regulating Ca_v1 protein density and reveal that in the absence of Akt function, Ca_v1 is susceptible to lysosome-mediated membrane protein degradation.

View larger version (40K): [in this window] [in a new window] [Download PPT slide]   Figure 3. Akt mediates regulation of Cav1 protein density at the plasma membrane. (A) RT-PCR analysis of Cav1 mRNA expression from WT and KO ventricular extracts. GAPDH served as a loading control. (B) Western blot analysis of whole lysate, membrane, and microsomal fractions from WT and KO ventricular extracts. CSQ, calsequestrin. (C) YFP-Cav1–transfected COS-7 cells alone or in combination with Cavβ2 expression vector were serum starved and treated with Akt inhibitor (Akt inh.) and 1 µM bafilomycin-A1, 25 µM MG132, or 25 µM calpeptin. 6 h after drug administration, cell lysates were prepared and subjected to Western blot analysis for YFP. GAPDH served as a loading control. (D and E) Cav1 protein levels in KO cardiomyocytes infected with empty (mock) or active E40K-Akt (AdAkt)–expressing adenoviral vector (D) and in whole lysates of WT and E40K-Akt (Tg Akt) hearts (E). Representative experiments are shown (n = 4).

Akt is a determinant for Ca_v1 protein level regulation by direct phosphorylation of the Ca_vβ2 chaperone subunit
To assess whether Akt is directly involved in modulation of Ca_vβ2 chaperone activity in the heart, we first confirmed the interaction between Akt and Ca_vβ2. Ventricular homogenates derived from either WT or Tg Akt mice were immunoprecipitated with anti-HA antibody and assayed for Ca_vβ2, which revealed association of the Ca_vβ2 subunit with active Akt (Fig. 4 A). Similarly, Ca_vβ2 was found to coimmunoprecipitate with insulin-stimulated endogenous Akts (Fig. S4 A).

View larger version (48K): [in this window] [in a new window] [Download PPT slide]   Figure 4. Akt interacts with and phosphorylates Cavβ2. (A) Coimmunoprecipitation assay of Akt and Cavβ2. Ventricular homogenates from WT and HA–E40K-Akt Tg mice (Tg Akt) immunoprecipitated with antibodies against HA and immunoblotted for Cavβ2 as well as HA as a control. (B) Examination of Cavβ2 phosphorylation by Akt. In vitro kinase assays were performed with immunoprecipitated Cavβ2 incubated with recombinant active Akt and 32P-labeled ATP (left) or immunoprecipitated Cavβ2 from WT and KO cardiac extracts from mice treated or not treated with 1 mU/g insulin using phospho-Akt substrate (PAS) antibody (right). (C) Back phosphorylation assay of Cavβ2 from WT and KO hearts. Immunoprecipitated Cavβ2 from solubilized membranes was in vitro back phosphorylated using recombinant active Akt and [32]ATP. Precipitate amounts were assayed for [32P]Cavβ2 and total Cavβ2. Representative experiments are shown (n = 4). IP, immunoprecipitation.

To directly assess whether Akt phosphorylation of Ca_vβ2 protects Ca_v1 from protein degradation, we constructed a mutant of Ca_vβ2 in which Ser625, which is contained in the putative Akt consensus site (R-X-X-R-S/T), was replaced by glutamate (Ca_vβ2-SE) to mimic phosphorylation. Cotransfection of 293T cells with Ca_v1 and Ca_vβ2-SE resulted in Ca_v1 protein levels that were increased compared with those found when cotransfected with Ca_vβ2-WT (Fig. 5 A). Similarly, Ca_v1 expression was increased in insulin-treated Ca_vβ2-WT–cotransfected cells (Fig. 5 A). Notably, the active phosphomimic Ca_vβ2-SE also counteracted the down-regulation of Ca_v1 induced by an Akt inhibitor (Fig. 5 B). Opposite results were obtained with a dominant-negative (DN) Ca_vβ2 mutant in which Ser was replaced by Ala (Ca_vβ2-SA) to prevent Akt phosphorylation. Indeed, Ca_v1 protein levels were reduced when coexpressed with Ca_vβ2-SA (Fig. 5 C). In addition, insulin stimulation failed to increase Ca_v1 in the presence of the DN Ca_vβ2-SA mutant (Fig. 5 C). Consistent with the hypothesis that Ca_v1 protein down-regulation relies on Akt kinase activity, overexpression of a DN form of Akt (AdAktDN) resulted in a significant reduction in Ca_v1 protein levels, whereas forced expression of AdAkt was sufficient to counteract Ca_v1 reduction in a serum-free condition, in which Akt is not phosphorylated (Fig. S4 B). Furthermore, suppression of Akt expression in 293T cells by siRNA (small interfering Akt [siAkt]) resulted in reduction of the Ca_v1 protein level (Fig. 5 D).

View larger version (61K): [in this window] [in a new window] [Download PPT slide]   Figure 5. Akt phosphorylation of Cavβ2 protects Cav1 from protein degradation. (A–C) YFP-Cav1–cotransfected 293T cells with the indicated mutant variant of Cavβ2. Cells were serum starved overnight and treated with 100 µM insulin (A and C) or 5 µM Akt inhibitor (Akt inh; B) as indicated. The expression of YFP-Cav1 in lysates was monitored by Western blot analysis with anti-YFP antibody and normalized based on transfection efficiency (Cavβ2) and protein amount (tubulin; n = 3). (D) Cav1- and Cavβ2-cotransfected 293T cells were treated with siAkt-expressing vector as indicated. 3 d after transfection, cell lysate was tested by Western blot analysis. Protein loading was normalized to GAPDH levels. Representative experiments are shown (n = 3).

View larger version (25K): [in this window] [in a new window] [Download PPT slide]   Figure 6. Akt phosphorylation of Cavβ2 preserves Cav1 currents. Ca2+ currents recorded in cotransfected tsA-201 cells with YFP-Cav1 and Cavβ2-WT, Cavβ2-SE, or Cavβ2-SA mutant cultivated for 36 h in the presence or absence of 10% fetal bovine serum. Currents were recorded 1–2 min after the whole cell configuration was achieved (i.e., after stabilization of the current) and were elicited by a 0-mV depolarization of 200-ms duration applied from a holding potential of –80 mV. Currents are normalized to cell capacitance (current density, picoampere/picofarad). Representative current traces are shown. n > 35 at each condition (*, P < 0.05 compared with YFP-Cav1; ANOVA). Error bars show SEM.

Akt regulates Ca_v1 protein stability

View larger version (42K): [in this window] [in a new window] [Download PPT slide]   Figure 7. Rapid protein degradation PEST sequences determine Cav1 protein instability. (A) Schematic representation of Cav1 mapping the AID and PEST sequences in the I–II and II–III cytosolic loops. Deleted PEST sequences (P and H) are highlighted in red. (B) Western blot and immunofluorescence analyses showing relative levels of WT and PEST-deleted mutants of YFP-Cav1 (n = 3). The asterisk indicates a YFP-Cav1 degradation fragment. (C) Half-lives of WT Cav1 subunit (alone or cotransfected with Cavβ2-SE) and its in-frame PEST mutants (Cav1-P and Cav1-H) were determined in COS-7 cells. After overnight starvation, transfected cells were pulse chased and analyzed along a time course (*, P < 0.001 compared with Cav1; ANOVA; n = 3). Error bars show SD. (D) Western blot and immunofluorescence analyses showing relative levels of WT GFP and N-terminal fusion PEST mutants (n = 3). (E) The Cav1 C terminus interacts with the Akt-phosphorylated GST-Cavβ2 coiled-coil region. Bacterially expressed GST or GST-C-Cavβ2 (Cavβ2, amino acids 480–655) fusion protein and glutathione–Sepharose beads were incubated with equal amounts of in vitro–translated [35S]Met-labeled C-Cav1 (Cav1, amino acids 1,477–2,169). Binding occurred only with Akt-phosphorylated GST-C-Cavβ2. Bound proteins were resolved by SDS-PAGE (4–12%). 10% of the input protein in each binding reaction is shown. Coomassie staining of SDS-PAGE is shown in the bottom panel. (F) Ca2+ currents recorded in tsA-201 cells cotransfected with Cavβ2-WT and either Cav1-WT or Cav1-H and cultivated for 36 h in the presence or absence of 10% fetal bovine serum. Current densities (picoampere/picofarad) are normalized to the control condition. n > 35 at each condition (*, P < 0.05 compared with Cav1; ANOVA). Error bars show SEM. Bars: (B) 5 µm; (D) 20 µm.

View this table: [in this window] [in a new window]   Table I. PEST sequences are highly conserved in Cav1

Collectively, our results suggest that Akt-mediated phosphorylation of Ca_vβ2 regulates Ca_v1 density through protection of Ca_v1 PEST motifs from the cell protein degradation machinery. Impairment of this mechanism is expected to result in dysregulation of cardiomyocyte contractile function.

	Discussion

Top Abstract Introduction Results Discussion Materials and methods References

 
This study reveals a mechanism through which the insulin IGF-1–PI3K–PDK1–Akt pathway can sustain or modulate Ca²⁺ entry in cardiac cells via the voltage-gated LTCC and eventually affect cardiac contractility. Using a mouse model with an inducible and cardiomyocyte-specific deletion of the upstream activator PDK1, we showed that Akt is of key importance for the structural organization and functionality of the LTCC complex at the plasma membrane. This regulation of LTCC activity is directly related to the Akt-mediated phosphorylation of the accessory subunit Ca_vβ2, which in turn results in increased protein density of the pore-forming Ca_v1 subunit through protection of PEST sequences from the proteolytic degradation system. In the absence of phosphorylated Akt, the Ca²⁺ current is reduced, resulting in a decreased Ca²⁺ transient and contractility. Therefore, it is tempting to speculate that the Akt-mediated phosphorylation of Ca_vβ2 and the consequent direct association of the Ca_vβ2 C-terminal tail with the Ca_v1 C-terminal coiled-coil region (Fig. 7 E) may induce conformational changes that prevent PEST sequences from being recognized by the cell degradation system (Fig. 8). In addition, one cannot exclude the possibility that phosphorylated Ca_vβ2 might also act indirectly through other, as of yet unknown, LTCC protein partners.

View larger version (41K): [in this window] [in a new window] [Download PPT slide]   Figure 8. Proposed mechanism. Akt, followed by PDK1 activation, phosphorylates Cavβ2 at the C-terminal coiled-coil domain. The phosphorylation allows association of the C-terminal portion of Cavβ2 with the Cav1 C-terminal domain. In turn, a conformation shift prevents PEST sequence recognition, stabilizing Cav1 protein levels. The blue and red ribbons in Cav1 represent AID and PEST sequences, respectively.

Several findings have shown the importance of the insulin IGF-1–PI3K–Akt pathway in heart function. Our group has previously demonstrated that overexpression of an active form of Akt-1 results in improved cardiac inotropism both in vivo (Condorelli et al., 2002) and in vitro (Kim et al., 2003), augmenting I_Ca,L. Similar results were recently obtained in a mouse model with cardiac-specific Akt-1 nuclear overexpression (Rota et al., 2005) and in mice deficient for PTEN (phosphatase and tensin homologue deleted on chromosome 10), an antagonizer of PI3K activity (Sun et al., 2006). In addition, short-term administration of IGF-1 in animal experiments has also been reported to increase cardiac contractility (Duerr et al., 1995). However, the mechanism through which the insulin IGF-1–PI3K–Akt pathway affects Ca²⁺ current has remained elusive. In an elegant in vitro study, Viard et al. (2004) demonstrated that a region of the Ca_vβ2a subunit is involved in the PI3K-induced chaperoning of Ca_v2.2 in neurons. This PI3K-induced regulation was shown to be mediated by Akt phosphorylation of the Ca_vβ2a subunit, which in turn regulates Ca_v2.2 trafficking from the ER to the plasma membrane. Notably, the C-terminal region containing the putative Akt phosphorylation consensus site is conserved in all variants of the Ca_vβ2 subunit both in neurons and the heart (Viard et al., 2004), thus illustrating the importance of this site. Interestingly, two very short human cardiac splice isoforms, Ca_vβ2f and Ca_vβ2g, with preserved Akt sites have been shown to be essential for modulating Ca²⁺ channel function and Ca_v1 channel density (De Waard et al., 1994; Kobrinsky et al., 2005). Strikingly, the same two Ca_vβ2 variants do not contain the PKA phosphorylation site (Kamp and Hell, 2000), which is consistent with our data suggesting no PKA involvement in the modulation of LTCC density (Fig. S2 B). As a corollary, the presence of this conserved C-terminal region in all Ca_vβ2 splice isoforms corroborates the relevance of identifying new functional motifs that may give important insights into LTCC modulation. Consistent with an important functional role of the conserved Ca_vβ2 C-terminal region, Lao et al. (2008) recently showed that, in the absence of the main Ca_vβ2 protein domain, the selected C-terminal essential determinant is sufficient for I_Ca,L stimulation. All together, this evidence supports the notion that this region is a potential pharmacological target.

In conclusion, we show that the insulin IGF-1–PI3K–PDK1–Akt pathway regulates Ca_vβ2 chaperone activity through phosphorylation by Akt and suggest that, in turn, this controls Ca_v1 channel density by protection of Ca_v1 from PEST-dependent protein degradation (Fig. 8). This paradigm highlights an unanticipated regulatory function for Akt in modulating LTCC function and provides evidence for an essential role of Akt in the control of cardiomyocyte Ca²⁺ handling and contractility. Interestingly, the high level of conservation of PEST sequences in the Ca_v1 subunit throughout evolution (Table I) indicates that our proposed mechanism may play a universal role in regulating cell Ca²⁺ handling and survival. Because pathophysiological states are often accompanied by alterations in LTCC function (Mukherjee and Spinale, 1998), the elucidation of this novel regulatory pathway may open new therapeutic perspectives.

	Materials and methods

Top Abstract Introduction Results Discussion Materials and methods References

 
Generation of genetically modified mice
Cardiac-specific PDK1-inducible KO mice (MerCreMer -MHC PDK1) were generated by breeding PDK1^{floxed/floxed} Tg mice (provided by D.R. Alessi, Medical Research Council Protein Phosphorylation Unit, University of Dundee, Dundee, Scotland, UK; Williams et al., 2000) with mice expressing the cardiac-specific MerCreMer -MHC promoter-driven cre recombinase gene (provided by J.D. Molkentin, University of Cincinnati, Cincinnati, OH; Sohal et al., 2001). The resulting background strain of the MerCreMer mice was C57BL/6-SV129 and was unchanged throughout all experiments. Control animals used in this study were PDK1^{floxed/floxed} littermates not expressing the cre recombinase gene and were treated with the same tamoxifen regiment. Tamoxifen dissolved in maize oil was injected intraperitoneally once a day at a dose of 75 mg/kg body weight. Male animals 7–8-wk old were used. All animal procedures were performed in accordance with the Guide for the Care and Use of Laboratory Animals and approved by the Institutional Animal Care and Use Committee.

Culture and treatment of mouse cardiomyocyte cells
Isolation of ventricular myocytes was performed as previously described (Care et al., 2007). Cells were infected with an adenovector expressing either no transgene (mock), HA–E40K-Akt (AdAkt), or Akt-K179M (AdAktDN) at MOI 100 and harvested 48 h after infection. The viral vector was amplified and purified in 3% sucrose/PBS by ViraQuest, Inc.

Cell culture and cDNA mutagenesis
Cell transfection was performed in serum-starved medium using Lipofectamine 2000 (Invitrogen) according to the manufacturer's instructions. 5 µM Akt-XI inhibitor (EMD), insulin (Sigma-Aldrich), 1 µM bafilomycin-A1 (Sigma-Aldrich), 25 µM MG132 (EMD), and 25 µM calpeptin (EMD) were used as described in Results. Cacnb2 cDNA (complete coding sequence, cDNA clone MGC:129335, IMAGE:40047531; American Type Culture Collection) was cloned in the pcDNA3 vector. Site-directed mutagenesis was performed using the QuikChange Site-Directed Mutagenesis kit (Agilent Technologies). Ca_v1 PEST deletion mutants and GFP fusion proteins were generated by PCR. YFP-Ca_v1 expression plasmids were provided by N. Soldatov (National Institute on Aging, National Institutes of Health, Baltimore, MD). A lentivirus vector was generated and used as an expression vector for siRNA-mediated silencing of the akt gene (siAkt). The sequence used (5'-TGCCCTTCTACAACCAGGATT-3') was chosen in a conserved region between rat, mouse, and human and has been validated for targeting Akt-1 and -2 (Katome et al., 2003). All constructs were confirmed by DNA sequencing.

Ca²⁺ current measurement
Macroscopic I_Ca,L was recorded at room temperature (22°C) using the whole cell patch-clamp technique in native cells as previously described (Maier et al., 2003; Aimond et al., 2005). External recording solution contained 136 mM tetraethylammonium (TEA)-Cl, 2 mM CaCl₂, 1.8 mM MgCl₂, 10 mM Hepes, 5 mM 4-aminopyridine, and 10 mM glucose, pH 7.4, with TEA-OH. Pipette solution contained 125 mM CsCl, 20 mM TEA-Cl, 10 mM EGTA, 10 mM Hepes, 5 mM phosphocreatine, 5 mM Mg₂-ATP, and 0.3 GTP, pH 7.2, with CsOH. Myocytes were held at –80 mV, and 10-mV depolarizing steps from –50 to 50 mV for 300 ms were applied. Analysis was performed using a microscope (Diaphot 200; Nikon) equipped with 10x NA 20 objective lenses (CFWN; Nikon). pCLAMP 9 (MDS Analytical Technologies) was used as acquisition software. For electrophysiological recordings of recombinant Ca_v1 currents, tsA-201 cells were transfected in OptiMEM (Invitrogen) with a DNA mix containing plasmids encoding YFP-Ca_v1, Ca_vβ2 subunit (either Ca_vβ2-WT, Ca_vβ2-SE, or Ca_vβ2-SA), Ca_v21 subunit, and CD8 (in a ratio of 1:2:0.5:0.1). After 24 h, cells were cultured in DME with or without serum for 36 h, and electrophysiological recordings were performed on cells expressing both YFP-Ca_v1 and CD8, which is identified using anti-CD8–coated beads (Dynabeads; Invitrogen). The 330-mosM extracellular solution contained 135 mM NaCl, 20 mM TEA-Cl, 5 mM CaCl₂, 1 MgCl₂, and 10 mM Hepes (pH adjusted to 7.4 with KOH). Borosilicate glass pipettes have a typical resistance of 1.5–3 MW when filled with an 315-mosM internal solution containing 140 mM CsCl, 10 mM EGTA, 10 mM Hepes, 3 mM Mg-ATP, 0.6 mM GTP-Na, and 2 mM CaCl₂ (pH adjusted to 7.2 with KOH). Analysis was performed using a microscope (x71; Olympus). Data acquisition was performed with pCLAMP 9 software.

Fluorescent measurement of [Ca²⁺]_i
Isolated myocytes were loaded with 5 µM Fura-PE3 acetoxymethyl (TefLabs) and analyzed as previously described (Bassani et al., 1994; DeSantiago et al., 2002). Analysis was performed using a Diaphot 200 microscope. Data acquisition and analysis were performed using pCLAMP software (Clampex and Clampfit version 8.2; MDS Analytical Technologies).

Akt and PKC kinase assay
Myocardial tissue lysates were tested using the Akt Kinase Assay kit (Cell Signaling Technology) and PKC (Millipore) according to the manufacturer's instructions.

Western blot analysis and antibodies
Protein expression was evaluated in total lysates or cell fractions by Western blot analysis according to standard procedures. Antibodies against the following proteins were used: Ca_v1 (Novus Biologicals); Ca_v1 and Ca_vβ2 (provided by H. Haase, Max Delbrück Center for Molecular Medicine, Berlin, Germany); Ryr and Ryr2-P2809 (provided by A. Marks, Columbia University, New York, NY); PDK1 (EMD); Akt-1, -2, and -3, Akt, Akt-P308, and anti–phospho-Ser/Thr-Akt substrate (Cell Signaling Technology); PLN and PLN-P16 (Novus Biologicals); calsequestrin (BD); caspase 3 (Cell Signaling Technology); HA (Roche); GFP/YFP (GeneTex, Inc.); tubulin (Novus Biologicals); GSK-3β (Cell Signaling Technology); and glyceraldehyde-3-phosphate dehydrogenase (GAPDH; Cell Signaling Technology). ImageJ software (National Institutes of Health) was used to perform densitometry analyses.

Tissue preparation, immunoprecipitation, and in vitro phosphorylation
When described, overnight-fasted mice were injected intraperitoneally with 1 mU/g insulin or saline solution. 20 min after injection, the hearts were rapidly extracted, freeze clamped in liquid nitrogen, and homogenized to a powder in liquid nitrogen. In vitro phosphorylation assays on immunoprecipitates were performed as described previously (Haase et al., 1999).

Cell fractionation
Pulverized hearts were homogenized in ice-cold solution 1 (300 mM sucrose, 10 mM Tris-HCl, pH 7.5, 1 mM EDTA, 1 mM EGTA, 50 mM NaF, 1 mM Na₃VO₄, and protease inhibitors) at 1.5 ml/ventricle by three bursts of 10 s in a homogenizer (PT 3000; Polytron). Homogenates were then incubated for 15 min on ice (whole homogenates). Samples were spun at 1,000 g for 10 min at 4°C. Pellets were washed in solution 1 and spun at 1,000 g for 10 min at 4°C, and supernatants were filtered through four layers of cheese cloth and centrifuged at 10,000 g for 30 min at 4°C. Supernatants were then centrifuged at 143,000 g for 30 min at 4°C, and pellets were resuspended in solution 2 (600 mM KCl, 30 mM Tris-HCl, pH 7.5, 300 mM sucrose, 1 mM EDTA, 1 mM EGTA, 50 mM NaF, 1 mM Na₃VO₄, and protease inhibitors). Supernatants were saved as cytosolic fractions. Resuspended pellets from a further centrifugation at 143,000 g for 45 min at 4°C were resuspended in solution 3 (100 mM KCl, 20 mM Tris-HCl, pH 7.5, 300 mM sucrose, 1 mM EDTA, 1 mM EGTA, 50 mM NaF, 1 mM Na₃VO₄, and protease inhibitors) and saved as ER fractions. All aliquots were stored at –80°C.

Histology and confocal microscopy
Fixation, staining, and confocal analysis were performed as previously described (Care et al., 2007). Confocal microscopy was performed using a confocal microscope (Radiance 2000; Bio-Rad Laboratories) with a 60x Plan-Apochromat NA 1.4 objective (Carl Zeiss, Inc.). Individual images (1,024 x 1,024 pixels) were converted to tiff format and merged as pseudocolor RGB images using Imaris (Bitplane AG).

Pulse-chase and immunoprecipitation experiments
36 h after transfection, 293T cells were starved for 30 min in Met- and Cys-free DME (Sigma-Aldrich) and were then labeled for 30 min by adding 500 µCi ³⁵S-labeled L-Met and 2 mM L-Cys. Radioactive media was eventually washed out with PBS (time 0 pulse) and replaced with normal DME. Time points were at 4, 10, and 25 h after pulse. Anti-GFP polyclonal IgG (GTX20290) was used for immunoprecipitation. Radioactivity was quantitated with ImageQuant 5.2 software (GE Healthcare).

GST pull-down assay
Affinity-purified GST fusion proteins were generated using a pGEX system (GE Healthcare) and phosphorylated as described below. GST fusion protein bound to glutathione–Sepharose 4B beads (GE Healthcare) was incubated with 25 µl of ³⁵S-labeled Met protein with moderate shaking at 25°C for 2 h in 200 µl of binding buffer containing 20 mM Hepes, pH 7.9, 1 mM EDTA, 10% glycerol, 0.15 M KCl, 0.05% Nonidet P-40, and 1 mM DTT. ³⁵S-labeled probes were generated from the C-terminal region of Ca_v1 cDNA fragments under control of the T7 promoter using the TnT Quick Coupled Reticulocyte Lysate System (L1170; Promega), washed three times with washing buffer (20 mM Hepes, pH 7.9, 1 mM EDTA, 10% glycerol, 250 mM KCl, and 0.1% Nonidet P-40), and centrifuged. Bound proteins were eluted in SDS sample buffer, subjected to SDS-PAGE, and detected by autoradiography. Recombinant GST-Ca_vβ2 beads or GST beads were phosphorylated by incubation with recombinant Akt (Millipore). In brief, 5 µg GST-Ca_vβ2 or GST beads were incubated at 30°C for 45 min in a 50-µl solution containing 2 µg activated Akt kinase, 10 mM Hepes-KOH, pH 7.5, 50 mM -glycerophosphate, 50 mM NaCl, 1 mM dithiothreitol, 10 mM MnCl₂, and 1 mM ATP.

Statistical analysis
Statistical comparison was performed within at least three independent experiments by paired or unpaired Student's t test, whereas comparison between groups was analyzed by one-way repeated-measures analysis of variance (ANOVA) combined with a Newman-Keuls post-test to compare different values using Prism 4.0 software (GraphPad Software, Inc.). Differences with P < 0.05 were considered statistically significant.

Online supplemental material
Fig. S1 shows additional biochemical, histological, and echocardiographic analyses of mice lacking PDK1 expression. Fig. S2 shows SERCA2 level and phosphorylation of specific PKA regulatory sites in two SR Ca²⁺ regulatory proteins, Ryr (Ryr2-P2809) and PLN (PLN-P16). Fig. S3 shows representative Ca²⁺ traces and twitch Ca²⁺ transient amplitude in KO compared with WT cardiomyocytes. Fig. S4 shows coimmunoprecipitation of Ca_vβ2 with insulin-activated Akt isoforms and the effects of dominant-active and -negative Akt as well as siAkt on the Ca_v1 protein level. Fig. S5 shows current-voltage analysis (I-V curves) of cells transfected with Ca_v1-WT or Ca_v1-H in normal or serum-free conditions. Table S1 shows echocardiography analysis values of WT and KO mice. Online supplemental material is available at http://www.jcb.org/cgi/content/full/jcb.200805063/DC1.

	Acknowledgments

 
We thank Dr. Dario R. Alessi for PDK1^{floxed/floxed} Tg mice, Dr. Jeffrey D. Molkentin for MerCreMer -MHC mice, Dr. Hannelore Haase for Ca_v1 and Ca_vβ2 antibodies, Dr. Nikolai Soldatov for YFP-Ca_v1, and Dr. Marie-Louise Bang for critical comments on the manuscript.

This work was sponsored by grants from the National Institutes of Health (HL078797-01A1 to G. Condorelli, HL28143 to J.H. Brown, and HL080101 to J.H. Brown and D.M. Bers), the Marie Curie Outgoing Research Fellowship European Union Sixth Framework Program (8566 to D. Catalucci), the Perlman Fund for Cardiovascular Research and Education, and the San Diego Foundation for Cardiovascular Research and Education (grant to K.L. Peterson). S. Richard holds a permanent position as Centre National de la Recherche Scientifique Director of Research.

Submitted: 13 May 2008

Accepted: 23 February 2009

	References

Top Abstract Introduction Results Discussion Materials and methods References

 

Aimond, F., S.P. Kwak, K.J. Rhodes, and J.M. Nerbonne. 2005. Accessory Kvbeta1 subunits differentially modulate the functional expression of voltage-gated K+ channels in mouse ventricular myocytes. Circ. Res. 96:451–458.[Abstract/Free Full Text]

Bassani, J.W., R.A. Bassani, and D.M. Bers. 1994. Relaxation in rabbit and rat cardiac cells: species-dependent differences in cellular mechanisms. J. Physiol. 476:279–293.[Abstract/Free Full Text]

Bayascas, J.R., S. Wullschleger, K. Sakamoto, J.M. Garcia-Martinez, C. Clacher, D. Komander, D.M. van Aalten, K.M. Boini, F. Lang, C. Lipina, et al. 2008. Mutation of PDK1 PH domain inhibits PKB/Akt leading to small size and insulin-resistance. Mol. Cell. Biol. 28:3258–3272.[Abstract/Free Full Text]

Belles, B., J. Hescheler, W. Trautwein, K. Blomgren, and J.O. Karlsson. 1988. A possible physiological role of the Ca-dependent protease calpain and its inhibitor calpastatin on the Ca current in guinea pig myocytes. Pflugers Arch. 412:554–556.[CrossRef][Medline]

Bers, D.M. 2002. Cardiac excitation-contraction coupling. Nature. 415:198–205.[CrossRef][Medline]

Bers, D.M., and E. Perez-Reyes. 1999. Ca channels in cardiac myocytes: structure and function in Ca influx and intracellular Ca release. Cardiovasc. Res. 42:339–360.[Abstract/Free Full Text]

Blair, L.A., K.K. Bence-Hanulec, S. Mehta, T. Franke, D. Kaplan, and J. Marshall. 1999. Akt-dependent potentiation of L channels by insulin-like growth factor-1 is required for neuronal survival. J. Neurosci. 19:1940–1951.[Abstract/Free Full Text]

Bodi, I., G. Mikala, S.E. Koch, S.A. Akhter, and A. Schwartz. 2005. The L-type calcium channel in the heart: the beat goes on. J. Clin. Invest. 115:3306–3317.[CrossRef][Medline]

Bourinet, E., M.E. Mangoni, and J. Nargeot. 2004. Dissecting the functional role of different isoforms of the L-type Ca2+ channel. J. Clin. Invest. 113:1382–1384.[CrossRef][Medline]

Care, A., D. Catalucci, F. Felicetti, D. Bonci, A. Addario, P. Gallo, M.L. Bang, P. Segnalini, Y. Gu, N.D. Dalton, et al. 2007. MicroRNA-133 controls cardiac hypertrophy. Nat. Med. 13:613–618.[CrossRef][Medline]

Catalucci, D., and G. Condorelli. 2006. Effects of Akt on cardiac myocytes: location counts. Circ. Res. 99:339–341.[Free Full Text]

Catterall, W.A. 2000. Structure and regulation of voltage-gated Ca2+ channels. Annu. Rev. Cell Dev. Biol. 16:521–555.[CrossRef][Medline]

Ceci, M., J. Ross, Jr., and G. Condorelli. 2004. Molecular determinants of the physiological adaptation to stress in the cardiomyocyte: a focus on AKT. J. Mol. Cell. Cardiol. 37:905–912.[CrossRef][Medline]

Condorelli, G., A. Drusco, G. Stassi, A. Bellacosa, R. Roncarati, G. Iaccarino, M.A. Russo, Y. Gu, C. Chung, M. Latronico, et al. 2002. Akt induces enhanced myocardial contractility and cell size in vivo in transgenic mice. Proc. Natl. Acad. Sci. USA. 99:12333–12338.[Abstract/Free Full Text]

De Waard, M., D.R. Witcher, and K.P. Campbell. 1994. Functional properties of the purified N-type Ca2+ channel from rabbit brain. J. Biol. Chem. 269:6716–6724.[Abstract/Free Full Text]

DeSantiago, J., L.S. Maier, and D.M. Bers. 2002. Frequency-dependent acceleration of relaxation in the heart depends on CaMKII, but not phospholamban. J. Mol. Cell. Cardiol. 34:975–984.[CrossRef][Medline]

Dice, J.F. 1987. Molecular determinants of protein half-lives in eukaryotic cells. FASEB J. 1:349–357.[Abstract]

Duerr, R.L., S. Huang, H.R. Miraliakbar, R. Clark, K.R. Chien, and J. Ross, Jr. 1995. Insulin-like growth factor-1 enhances ventricular hypertrophy and function during the onset of experimental cardiac failure. J. Clin. Invest. 95:619–627.[Medline]

Haase, H., T. Podzuweit, G. Lutsch, A. Hohaus, S. Kostka, C. Lindschau, M. Kott, R. Kraft, and I. Morano. 1999. Signaling from beta-adrenoceptor to L-type calcium channel: identification of a novel cardiac protein kinase A target possessing similarities to AHNAK. FASEB J. 13:2161–2172.[Abstract/Free Full Text]

Kamp, T.J., and J.W. Hell. 2000. Regulation of cardiac L-type calcium channels by protein kinase A and protein kinase C. Circ. Res. 87:1095–1102.[Abstract/Free Full Text]

Katome, T., T. Obata, R. Matsushima, N. Masuyama, L.C. Cantley, Y. Gotoh, K. Kishi, H. Shiota, and Y. Ebina. 2003. Use of RNA interference-mediated gene silencing and adenoviral overexpression to elucidate the roles of AKT/protein kinase B isoforms in insulin actions. J. Biol. Chem. 278:28312–28323.[Abstract/Free Full Text]

Kim, Y.K., S.J. Kim, A. Yatani, Y. Huang, G. Castelli, D.E. Vatner, J. Liu, Q. Zhang, G. Diaz, R. Zieba, et al. 2003. Mechanism of enhanced cardiac function in mice with hypertrophy induced by overexpressed Akt. J. Biol. Chem. 278:47622–47628.[Abstract/Free Full Text]

Kobrinsky, E., S. Tiwari, V.A. Maltsev, J.B. Harry, E. Lakatta, D.R. Abernethy, and N.M. Soldatov. 2005. Differential role of the alpha1C subunit tails in regulation of the Cav1.2 channel by membrane potential, beta subunits, and Ca2+ ions. J. Biol. Chem. 280:12474–12485.[Abstract/Free Full Text]

Krappmann, D., F.G. Wulczyn, and C. Scheidereit. 1996. Different mechanisms control signal-induced degradation and basal turnover of the NF-kappaB inhibitor IkappaB alpha in vivo. EMBO J. 15:6716–6726.[Medline]

Lao, Q.Z., E. Kobrinsky, J.B. Harry, A. Ravindran, and N.M. Soldatov. 2008. New determinant for the CaVbeta2 subunit modulation of the CaV1.2 calcium channel. J. Biol. Chem. 283:15577–15588.[Abstract/Free Full Text]

Lawlor, M.A., A. Mora, P.R. Ashby, M.R. Williams, V. Murray-Tait, L. Malone, A.R. Prescott, J.M. Lucocq, and D.R. Alessi. 2002. Essential role of PDK1 in regulating cell size and development in mice. EMBO J. 21:3728–3738.[CrossRef][Medline]

Maier, L.S., T. Zhang, L. Chen, J. DeSantiago, J.H. Brown, and D.M. Bers. 2003. Transgenic CaMKIIdeltaC overexpression uniquely alters cardiac myocyte Ca2+ handling: reduced SR Ca2+ load and activated SR Ca2+ release. Circ. Res. 92:904–911.[Abstract/Free Full Text]

McMullen, J.R., T. Shioi, L. Zhang, O. Tarnavski, M.C. Sherwood, P.M. Kang, and S. Izumo. 2003. Phosphoinositide 3-kinase(p110alpha) plays a critical role for the induction of physiological, but not pathological, cardiac hypertrophy. Proc. Natl. Acad. Sci. USA. 100:12355–12360.[Abstract/Free Full Text]

McMullen, J.R., T. Shioi, W.Y. Huang, L. Zhang, O. Tarnavski, E. Bisping, M. Schinke, S. Kong, M.C. Sherwood, J. Brown, et al. 2004. The insulin-like growth factor 1 receptor induces physiological heart growth via the phosphoinositide 3-kinase(p110alpha) pathway. J. Biol. Chem. 279:4782–4793.[Abstract/Free Full Text]

Mora, A., A.M. Davies, L. Bertrand, I. Sharif, G.R. Budas, S. Jovanovic, V. Mouton, C.R. Kahn, J.M. Lucocq, G.A. Gray, et al. 2003. Deficiency of PDK1 in cardiac muscle results in heart failure and increased sensitivity to hypoxia. EMBO J. 22:4666–4676.[CrossRef][Medline]

Mora, A., D. Komander, D.M. van Aalten, and D.R. Alessi. 2004. PDK1, the master regulator of AGC kinase signal transduction. Semin. Cell Dev. Biol. 15:161–170.[CrossRef][Medline]

Mukherjee, R., and F.G. Spinale. 1998. L-type calcium channel abundance and function with cardiac hypertrophy and failure: a review. J. Mol. Cell. Cardiol. 30:1899–1916.[CrossRef][Medline]

Pereira, L., J. Matthes, I. Schuster, H.H. Valdivia, S. Herzig, S. Richard, and A.M. Gomez. 2006. Mechanisms of [Ca2+]i transient decrease in cardiomyopathy of db/db type 2 diabetic mice. Diabetes. 55:608–615.[Abstract/Free Full Text]

Quignard, J.F., M.C. Harricane, C. Menard, P. Lory, J. Nargeot, L. Capron, D. Mornet, and S. Richard. 2001. Transient down-regulation of L-type Ca(2+) channel and dystrophin expression after balloon injury in rat aortic cells. Cardiovasc. Res. 49:177–188.[Abstract/Free Full Text]

Rechsteiner, M. 1990. PEST sequences are signals for rapid intracellular proteolysis. Semin. Cell Biol. 1:433–440.[Medline]

Richard, S., E. Perrier, J. Fauconnier, R. Perrier, L. Pereira, A.M. Gomez, and J.P. Benitah. 2006. ‘Ca(2+)-induced Ca(2+) entry’ or how the L-type Ca(2+) channel remodels its own signalling pathway in cardiac cells. Prog. Biophys. Mol. Biol. 90:118–135.[CrossRef][Medline]

Rogers, S., R. Wells, and M. Rechsteiner. 1986. Amino acid sequences common to rapidly degraded proteins: the PEST hypothesis. Science. 234:364–368.[Abstract/Free Full Text]

Romanin, C., P. Grosswagen, and H. Schindler. 1991. Calpastatin and nucleotides stabilize cardiac calcium channel activity in excised patches. Pflugers Arch. 418:86–92.[CrossRef][Medline]

Rota, M., A. Boni, K. Urbanek, E. Padin-Iruegas, T.J. Kajstura, G. Fiore, H. Kubo, E.H. Sonnenblick, E. Musso, S.R. Houser, et al. 2005. Nuclear targeting of Akt enhances ventricular function and myocyte contractility. Circ. Res. 97:1332–1341.[Abstract/Free Full Text]

Sandoval, A., N. Oviedo, A. Tadmouri, T. Avila, M. De Waard, and R. Felix. 2006. Two PEST-like motifs regulate Ca2+/calpain-mediated cleavage of the CaVbeta3 subunit and provide important determinants for neuronal Ca2+ channel activity. Eur. J. Neurosci. 23:2311–2320.[CrossRef][Medline]

Smith, L.K., M. Bradshaw, D.E. Croall, and C.W. Garner. 1993. The insulin receptor substrate (IRS-1) is a PEST protein that is susceptible to calpain degradation in vitro. Biochem. Biophys. Res. Commun. 196:767–772.[CrossRef][Medline]

Sohal, D.S., M. Nghiem, M.A. Crackower, S.A. Witt, T.R. Kimball, K.M. Tymitz, J.M. Penninger, and J.D. Molkentin. 2001. Temporally regulated and tissue-specific gene manipulations in the adult and embryonic heart using a tamoxifen-inducible Cre protein. Circ. Res. 89:20–25.[Abstract/Free Full Text]

Sun, H., B.G. Kerfant, D. Zhao, M.G. Trivieri, G.Y. Oudit, J.M. Penninger, and P.H. Backx. 2006. Insulin-like growth factor-1 and PTEN deletion enhance cardiac L-type Ca2+ currents via increased PI3Kalpha/PKB signaling. Circ. Res. 98:1390–1397.[Abstract/Free Full Text]

Viard, P., A.J. Butcher, G. Halet, A. Davies, B. Nurnberg, F. Heblich, and A.C. Dolphin. 2004. PI3K promotes voltage-dependent calcium channel trafficking to the plasma membrane. Nat. Neurosci. 7:939–946.[CrossRef][Medline]

Williams, M.R., J.S. Arthur, A. Balendran, J. van der Kaay, V. Poli, P. Cohen, and D.R. Alessi. 2000. The role of 3-phosphoinositide-dependent protein kinase 1 in activating AGC kinases defined in embryonic stem cells. Curr. Biol. 10:439–448.[CrossRef][Medline]

Yamaguchi, H., M. Hara, M. Strobeck, K. Fukasawa, A. Schwartz, and G. Varadi. 1998. Multiple modulation pathways of calcium channel activity by a beta subunit. Direct evidence of beta subunit participation in membrane trafficking of the alpha1C subunit. J. Biol. Chem. 273:19348–19356.[Abstract/Free Full Text]

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