| HOME | HELP | FEEDBACK | SUBSCRIPTIONS | ARCHIVE | SEARCH | TABLE OF CONTENTS |
|
|
|
|||||||
|
|||||||||
Journal of Physiology (2001), 535.3, pp. 679-687
© Copyright 2001 The Physiological Society
 |
ABSTRACT |
|---|
 TopAbstract IntroductionMethodsResultsDiscussionReferences |
|---|
|
INTRODUCTION |
|---|
|
TopAbstractIntroductionMethodsResultsDiscussionReferences |
|---|
Intracellular Ca2+ ([Ca2+]i) dynamically regulates Ca2+ entry through L-type Ca2+ channels (LTCCs) in myocardium. Increased [Ca2+]i results in dual and conflicting signals to LTCCs; increased [Ca2+]i enhances L-type Ca2+ current (ICa) through a process termed facilitation (Marban & Tsien, 1982), but also hastens inactivation (Hadley & Lederer, 1991) leading to a reduction of ICa. Recent findings have highlighted the importance of the ubiquitous Ca2+-binding protein calmodulin (CaM) in determining Ca2+-dependent ICa facilitation and inactivation (Zuhlke et al. 1999, 2000; Peterson et al. 1999; Qin et al. 1999). CaM can facilitate ICa by activation of Ca2+-CaM-dependent protein kinase II (CaMK) to induce a modal gating shift that favours prolonged LTCC openings (Dzhura et al. 2000). CaM can also interact with two distinct CaM-binding domains on the C-terminus of the LTCC. The first CaM-binding region identified was an 'IQ-like' domain (IQ) (Rhoads & Friedberg, 1997; Zuhlke & Reuter, 1998; Peterson et al. 1999; Zuhlke et al. 1999), while a more recently identified CaM-binding domain is located 12 amino acid residues N-terminal to IQ (Pate et al. 2000). IQ is implicated in [Ca2+]i-dependent modulation of ICa, because point mutations within IQ result in marked and distinct effects on Ca2+-CaM-dependent facilitation (Zuhlke et al. 1999, 2000) and inactivation (Zuhlke et al. 1999, 2000) of heterologously expressed LTCCs. However, the mechanism of IQ action and the relationship between IQ and CaMK in the modulation of ICa is unknown.
The present study was designed to test the hypothesis that IQ is important for determining ICa facilitation and inactivation in native cardiomyocytes under conditions in which CaMK activity is specifically controlled. An LTCC IQ-mimetic peptide (IQmp) and an inactive control peptide (IQmp-con) were synthesized to probe the potential regulatory role of IQ on ICa and LTCCs in rabbit ventricular myocytes, while a specific CaMK inhibitory peptide and an engineered Ca2+-independent form of CaMK were used to separately control CaMK activity.
|
METHODS |
|---|
|
TopAbstractIntroductionMethodsResultsDiscussionReferences |
|---|
Electrophysiology
New Zealand White rabbits were killed by pentobarbital (50 mg kg-1 I.V.) overdose and the heart excised. Ventricular myocytes were isolated as described previously (Anderson et al. 1994), except that the duration of exposure to collagenase-containing perfusate was determined by serial microscopic examination of apical cell isolates, and the collagenase infusion was stopped when the approximate percentage of viable myocytes reached a plateau. All experiments were approved by the Vanderbilt University Animal Care Committee.
For most whole-cell experiments, cells were stimulated (0.5 Hz) by stepping from -80 mV to +10 mV for 300 ms (T = 23-25 °C). Addition of nifedipine (10 µM) or Cd2+ (100 µM) eliminated residual current, confirming that the active current was ICa (data not shown). The pipette (intracellular) solution comprised (mM): CsCl, 120.0; EGTA, 10.0; Hepes, 10.0; tetraethylammonium chloride (TEA), 10.0; phosphocreatine, 5.0; CaCl2, 3.0; MgATP, 1.0; and NaGTP, 1.0; the pH was adjusted to 7.2 with 1.0 N CsOH. The bath (extracellular) solution comprised (mM): choline chloride or NMDG, 137.0; CsCl, 25.0; Hepes, 10.0; glucose, 10.0; CaCl2, 1.8; and MgCl2, 0.5; the pH was adjusted to 7.4 with 1.0 N CsOH or HCl. The calculated resting free [Ca2+]i for the pipette solution was ~100 nM (Bers et al. 1994). Ryanodine (10 µM) or thapsigargin (1 µM; Calbiochem) was included in the bath solution for 
10 min prior to some experiments to prevent sarcoplasmic reticulum (SR) Ca2+ release. Some experiments were also performed with pipette solutions lacking Ca2+ and EGTA, or with voltage command steps to -5 mV, the calculated Cl- reversal potential, or in the presence of niflumic acid (10 µM), to minimize the Ca2+-activated Cl- current (Zygmunt & Gibbons, 1991; Wu & Anderson, 2000). Time constants of ICa inactivation were derived as follows:
1) + A2 exp(-t/2) + c,
using pCLAMP 6 (Axon Instruments), where I is the current at time t , A1 and A2, respectively, are the amplitudes of fast and slow components, 1 and 2, respectively, are the fast and slow inactivation time constants, and c is an offset constant.
For single Ca2+ channel measurements, the bath (intracellular) solution comprised (mM): KCl, 150; EGTA, 10; Hepes, 10; CaCl2, 7.5 or 11; glucose, 5.5; EDTA, 1; and ATP, 0.01; the pH was adjusted to 7.4 with 10 N KOH. Experiments were performed at two different free intracellular Ca2+ concentrations: ~1 µM and ~100 nM (Bers et al. 1994). The pipette (extracellular) solution comprised (mM): BaCl2, 110; Hepes, 5; and TTX, 0.03; the pH was adjusted to 7.4 with Trizma base. Currents were recorded from excised cell membrane patches using the inside-out configuration (Hamill et al. 1981), in response to depolarizing steps to 0 mV (200 ms) from a holding potential of -70 mV (0.5 Hz), sampled at 20 kHz, and low-pass filtered at 2 kHz (4 pole Bessel). While most (~80 %) Ca2+ channels exhibited run-down that prevented their inclusion in the experimental results, ~20 % of channels remained sufficiently active (open probability (Po) of 4.4 ± 2.2 % (n = 6) at a [Ca2+] of ~100 nM and 5.0 ± 1.1 % (n = 6) at a [Ca2+] of ~1 µM) for experimental measurements. Blank sweeps were averaged and subtracted from all other sweeps to eliminate uncompensated capacitative transients. Subtracted records were then idealized and analysed using TRANSIT software (VanDongen, 1996). Only cell membrane patches containing a single Ca2+ channel were analysed. Analysis of modal gating was performed as described previously (Yue et al. 1990).
Inhibitory peptides
IQmp (FLIQEYFRKFKKRKEQ) was modelled after amino acids 1652-1667 in the C-terminus of the rabbit cardiac LTCC 
-subunit (1c) (Mikami et al. 1989). A control peptide (FLIQEYFRKSHKRKEG) was designed by substituting S for F (position 10) and H for K (position 11) to disrupt CaM binding (Fig. 2A). IQmp and IQmp-con were synthesized and isolated to > 95 % purity by reverse-phase high-performance liquid chromatography (Marcomolecular Resources, Fort Collins, CO, USA). The CaM-binding peptide 290-309 (LKKFNARRKLKGAILTTMLA; IC50, 52 nM) (Payne et al. 1988) is numbered to correspond to amino acids on the -isoform of CaMK (Calbiochem, La Jolla, CA, USA). The CaMK inhibitory peptide AC3-I (KKALHRQEAVDCL; IC50, ~3 µM) (Braun & Schulman, 1995) (Macromolecular Resources) is a modified CaMK substrate, and the amino acid sequence HRQEAVDCL corresponds to the autophosphorylation site (T286/287) on CaMK, except that T was modified to A to prevent phosphorylation. Peptides were dialysed for > 5 min before whole-cell experiments, where they were included in the pipette solution at a concentration of 100 µM, except for AC3-I, which was included at a concentration of 20 µM. All peptides were used at a final bath concentration of 10 µM for experiments with excised cell membrane patches.
CaM-binding assay
CaM (15 µM) was incubated with a fivefold molar excess of peptide for 1 h at 4 °C in 50 mM Tris-HCl, pH 7.5, containing either 5 µM added CaCl2 or 1 mM EGTA (10 µl, total volume). After addition of 5 µl 50 % glycerol and 0.03 % bromophenol blue, samples were analysed by non-denaturing polyacrylamide gel electrophoresis in the presence of 5 µM CaCl2 (10 % acrylamide) or 1 mM EGTA (15 % acrylamide), respectively, followed by Coomassie blue staining.
Constitutively active CaMK
Use of constitutively active CaMK allowed for independent control of [Ca2+]i and CaMK activity while using Ba2+ as the charge carrier in experiments with excised LTCCs, because Ba2+ cannot bind CaM or activate endogenous CaMK (Chao et al. 1984). Constitutively active monomeric CaMK (amino acid residues 1-380 of mouse type II, -isoform) was expressed in baculovirus and purified with a CaM affinity column as described previously (Wu et al. 1999). The purified CaMK was made Ca2+-CaM independent by thiophosphorylation of Thr 286 in the presence of Ca2+, CaM, Mg2+ and adenosine 5'-O-(3-thiotriphosphate); Ca2+-CaM-independent activity was verified with a phosphorylation assay using a synthetic CaMK substrate, autocamtide. Constitutively active CaMK was used at a final concentration of 0.9 µM, to approximate physiological activity (Gupta & Kranias, 1989). Ca2+-CaM-independent CaMK activity was 35-50 % of total activity and this activity level persisted at > 75 % of initial levels during the course of these experiments.
Chemical reagents
All chemicals used were reagent grade and were purchased from Sigma unless otherwise indicated.
Statistical analysis
The null hypothesis was rejected for P < 0.05 using ANOVA. Data are expressed as means ± S.E.M. Student's t test with the Bonferroni correction was used for repeated measures after ANOVA.
|
RESULTS |
|---|
|
TopAbstractIntroductionMethodsResultsDiscussionReferences |
|---|
IQmp increases ICa facilitation and slows inactivation
IQmp significantly increased ICa facilitation, compared with cells treated with IQmp-con (Fig. 1A and B), under conditions in which activation of endogenous CaMK is thought to determine ICa facilitation (Anderson et al. 1994; Yuan & Bers, 1994; Xiao et al. 1994; Dzhura et al. 2000). ICa facilitation was nearly abolished by the specific CaMK inhibitory peptide AC3-I (Fig. 1C) in the absence of IQmp. IQmp 'rescued' ICa facilitation when co-administered with AC3-I (Fig. 1D). Quantitatively similar results were obtained in separate experiments with voltage command steps to the calculated Cl- reversal potential, or when Ca2+ and EGTA were omitted from the pipette solution, or when niflumic acid was added to the bath solution, indicating that the interpretation of the IQmp effects was not confounded by the Ca2+-activated Cl- current (n = 5, data not shown) (Zygmunt & Gibbons, 1991). These findings suggest that IQmp may circumvent the physiological chain of signalling events whereby CaMK activity determines ICa facilitation.
 |
View larger version [in this window] [in a new window] |
|
|
Figure 1. CaMK is required for ICa facilitation, but IQmp is able to facilitate L-type Ca2+ current even after CaMK inhibition A-D show representative ICa recorded using whole-cell mode voltage clamp. A, a ventricular myocyte dialysed with IQmp-con developed increased ICa and slowed inactivation during successive stimulation pulses (i.e. 'facilitation'). The first (B1) and fifth (B5) 'beats' are superimposed for comparison. B, addition of IQmp enhanced ICa facilitation compared with cells treated with IQmp-con. C, ICa facilitation was nearly eliminated by addition of the specific CaMK inhibitory peptide AC3-I. D, IQmp restored ICa facilitation when co-administered with AC3-I. The holding current was 0 pA. E, summary data for peak ICa, expressed as the ratio of the n th (Bn) to the first (B1) stimulated beat (0.5 Hz) plotted against the beat number for cells treated with IQmp-con ( | ||
Enhanced ICa facilitation by IQmp is not due to CaM sequestration
Because CaM is required for Ca2+-dependent inactivation of ICa (Peterson et al. 1999; Qin et al. 1999; Zuhlke et al. 1999), IQmp might bind and sequester CaM to reduce ICa inactivation and 'unmask' apparent ICa facilitation. To test this potential mechanism for IQmp enhancement of ICa facilitation, we measured the relative Ca2+-CaM-binding avidity of IQmp and a CaM-binding peptide modelled on CaMK (290-309). IQmp bound CaM in the presence of Ca2+ (Fig. 2A), but not after addition of the Ca2+ buffer EGTA (not shown), as reported previously for IQ (Peterson et al. 1999; Zuhlke et al. 1999). In contrast, IQmp-con did not bind CaM in the presence (Fig. 2A) or absence (not shown) of Ca2+. Thus, IQmp bound CaM in a manner similar to IQ and so could replicate and enhance IQ actions and/or act as a CaM buffer when dialysed into cardiac myocytes. IQmp bound to CaM far less effectively than the CaMK-derived 290-309 peptide, because IQmp failed to disrupt CaM:290-309 binding, even when present in eightfold excess. In contrast, addition of the 290-309 peptide disrupted bound IQmp:CaM when present at a quarter of the concentration of IQmp (Fig. 2B). These data show that IQmp is a poor CaM sink relative to 290-309 and therefore suggest that CaMK activation would occur at a lower [Ca2+]i than CaM binding to IQ.
 |
View larger version [in this window] [in a new window] |
|
|
Figure 2. Effects of IQmp on L-type ICa facilitation are not due to CaM sequestration A and B show gel shift assays for determining Ca2+-dependent CaM binding to peptide probes (see Methods). A, the (vertical) lanes are labelled to indicate the presence of CaM and added peptide in a ratio of 1:5. IQmp-con was modified from the original sequence to eliminate CaM binding (see Methods). 290-309 is a peptide that contains a 'conventional' CaM-binding domain numbered according to the sequence from CaMK, from which it is derived (Payne et al. 1988). The arrows show that IQmp and 290-309 bound CaM in the presence of Ca2+ (5 µM) and slowed CaM migration through the gel, while IQmp-con did not 'shift' CaM migration compared with CaM alone (lane 4). B, the (vertical) lanes are labelled to show the molar proportion of added peptide (IQmp in lanes 2-5 and 290-309 in lanes 6-9) to preformed complexes of CaM:290-309 in equimolar proportions (lanes 2-5) and CaM:IQmp in twofold excess of IQmp over CaM (lanes 6-9). CaM alone was run for comparison (lanes 1 and 10). C and D show summary data for ICa facilitation and inactivation. C, peak ICa, normalized to B1 (as in Fig. 1E), for ventricular myocytes dialysed with IQmp-con ( | ||
IQmp significantly increased ICa facilitation in comparison with cells dialysed with the more potent CaM-binding peptide 290-309 (Fig. 2C). Unlike peptide 290-309, IQmp slowed the fast component of ICa inactivation (Fig. 2D). These specific IQmp effects on ICa facilitation and inactivation were not due to CaM sequestration and are therefore consistent with the hypothesis that IQmp can interact with a specific site or process that determines ICa facilitation.
Ca2+ from intracellular stores is important for signalling ICa facilitation and inactivation
SR Ca2+ is important for Ca2+-dependent ICa inactivation (Adachi-Akahane et al. 1996; Sun et al. 1997) and for activation of CaMK (Wu et al. 1999). SR Ca2+ release was disrupted to test the role of SR Ca2+ in ICa facilitation. ICa facilitation was eliminated in cells pretreated with the SR Ca2+ release channel-blocking agent ryanodine (10 µM) (Fig. 3A and C), or by thapsigargin (1 µM, n = 4) or caffeine (10 mM, n = 3) (data not shown). Similar findings were observed in response to ryanodine in cells dialysed with solution lacking Ca2+ and EGTA (n = 15, data not shown). Addition of IQmp did not restore ICa facilitation in ryanodine-treated cells (Fig. 3B), in contrast with the observed response in AC3-I-treated cells (Fig. 1D). Under control conditions, ICa inactivation was described by fast (Fig. 2D) and slow time constants, but the fast component of inactivation was eliminated by ryanodine pretreatment (Fig. 3D). The failure of IQmp to restore ICa facilitation in the absence of SR Ca2+ release suggests that, under these experimental conditions, SR Ca2+ is critical for activation of a signalling element that could not be circumvented by IQmp.
 |
View larger version [in this window] [in a new window] |
|
|
Figure 3. SR Ca2+ is required for ICa facilitation A, ryanodine pretreatment slowed ICa inactivation and eliminated ICa facilitation in the presence of IQmp-con. B, failure of IQmp to restore ICa facilitation in a myocyte treated with ryanodine. In A and B, the holding current was 0 pA. C, summary data (represented as in Fig. 1E) for ICa in myocytes pretreated with ryanodine and then dialysed with IQmp-con ( | ||
IQmp increases LTCC Po
The results described above are consistent with the hypothesis that IQmp interacts with a specific site on or near the LTCC. However, interpretation of the whole-cell findings might be complicated by actions of IQmp on other processes, such as SR Ca2+ homeostasis. Thus, further experiments were performed to measure the action of IQmp on LTCCs in excised cell membrane patches. Previous work showed that a Ca2+-independent form of CaMK potently activated LTCCs when applied to the cytoplasmic 'face' of murine LTCCs in excised cell membrane patches (Dzhura et al. 2000). Endogenous CaMK is anticipated to be inactive under these conditions because Ba2+, used as the charge carrier, does not bind CaM (Chao et al. 1984), and because addition of the CaM-binding peptide 290-309 did not reduce the LTCC response to engineered, Ca2+-independent CaMK (Dzhura et al. 2000). CaMK potently activated rabbit LTCCs (Fig. 4E) and this effect was occluded by co-administration of the inhibitory peptide AC3-I (Fig. 4F). Direct application of IQmp also increased LTCC opening (Fig. 4B), while the inactive IQmp-con (Fig. 4A) or CaM-bound IQmp (Fig. 4D) had no effect. In contrast to CaMK, AC3-I did not prevent increased LTCC opening in response to IQmp (Fig. 4C). Overall, IQmp and CaMK resulted in similar increases in LTCC Po at low (100 nM) and high (1 µM; data not shown) free [Ca2+]i (Fig. 4G). LTCC Po was not additively increased when CaMK and IQmp were applied together (Fig. 4G), suggesting that these signalling elements may operate through a common mechanism.
 |
View larger version [in this window] [in a new window] |
|
|
Figure 4. LTCC Po is non-additively increased by CaMK and IQmp in excised cell membrane patches A, under control conditions, LTCCs opened infrequently. B, LTCC Po was markedly increased by IQmp under conditions adverse to endogenous CaMK activation (see Methods). C, addition of the CaMK inhibitory peptide AC3-I did not prevent increased Po in response to IQmp, confirming that the effects of IQmp were independent of ongoing CaMK activity. D, CaM-bound IQmp failed to increase LTCC activity. E, addition of an engineered Ca2+-independent form of CaMK (0.9 µM) increased LTCC Po. F, the effect of CaMK was prevented by the CaMK inhibitory peptide AC3-I, as previously reported (Dzhura et al. 2000). A-F all show representative single-channel sweeps (top), with an ensemble-averaged current (255 to 446 traces, middle), and an all-sweep probability diary (bottom) where the bar height represents the percentage of time the channel was open during the 200 ms depolarization, for each experimental condition. Calibration bars apply to all panels. G, mean LTCC Po was not different for 100 nM or 1 µM (not shown) free bath (intracellular) Ca2+ concentrations. IQmp and CaMK both significantly (P < 0.001) increased LTCC Po compared with control (IQmp-con), but these effects were not additive. LTCC Po was not different between IQmp, CaMK and IQmp + CaMK. The number of cell membrane patches studied is indicated for each group. | ||
CaMK and IQmp both facilitate LTCCs via induction of a modal gating shift
CaMK determines ICa facilitation by inducing a modal gating shift that favours prolonged LTCC openings (Dzhura et al. 2000). To further test whether IQmp enhanced ICa facilitation through a common mechanism, we quantified LTCC open times and performed an analysis of gating modes (Yue et al. 1990; Dzhura et al. 2000). Both IQmp and CaMK increased the percentage of prolonged LTCC openings without changing the time constant for long LTCC openings, in comparison with LTCCs treated with IQmp-con (Fig. 5A-E). Both IQmp and CaMK induced LTCCs to repartition into a gating mode (mode 2) that favoured prolonged openings (Fig. 5F-I). These findings further suggest that IQmp and CaMK may activate LTCCs through a shared biophysical mechanism.
 |
View larger version [in this window] [in a new window] |
|
|
Figure 5. Quantification of LTCC open times and analysis of modal gating A-C, histograms with logarithmically binned open time durations (abscissa) plotted against the number of events (ordinate) (Sigworth & Sine, 1987). LTCC open times were best fitted by the sum of two exponentials; the long ( | ||
|
DISCUSSION |
|---|
|
TopAbstractIntroductionMethodsResultsDiscussionReferences |
|---|
IQmp modulates ICa facilitation and inactivation in rabbit ventricular myocytes
Addition of IQmp significantly enhanced ICa facilitation (Fig. 1B and E), and slowed the fast component of ICa inactivation (Fig. 2D). In excised cell membrane patches, IQmp directly activated LTCC opening (Fig. 4B and G) by inducing a modal gating shift favouring long openings (Fig. 5I). These findings in cardiomyocytes are both consistent with the hypothesized role of IQ in regulating ICa facilitation and inactivation when expressed in heterologous systems (Peterson et al. 1999; Zuhlke et al. 1999). The effect of IQmp on ICa facilitation and LTCC modal gating was nearly identical to that of CaMK, which also increases ICa facilitation by inducing LTCCs to partition into a gating mode favouring long openings (Dzhura et al. 2000).
The role of CaM 'buffering'
Previous work (Anderson et al. 1994) showed that lower (10-20 µM) concentrations of the peptide 290-309 prevented ICa facilitation by inhibiting CaMK. Surprisingly, the higher peptide concentration used in the present study (100 µM) modestly but significantly enhanced ICa facilitation, although this enhancement was significantly less than that with IQmp (Fig. 2C) and occurred without the marked slowing of the fast component of inactivation seen with IQmp (Fig. 2D). Thus, the effects of IQmp on ICa were independent of CaM buffering. In contrast, Yuan & Bers (1994) reported a near complete loss of ICa facilitation with 100 µM peptide 290-309, but their experiments were carried out at a lower [Ca2+]i (i.e. no added Ca2+ and 10 mM EGTA) than that used in the present experiments (100 nM calculated, see Methods). A possible explanation for these findings is that robust bulk CaM binding with the 290-309 peptide can compete effectively for CaM bound to IQ and thus reduce Ca2+-CaM-dependent ICa inactivation to 'reveal' a pattern of facilitation. This hypothesis is supported by our findings that peptide 290-309 bound CaM more avidly than IQmp (Fig. 2B), and that CaM binding eliminated LTCC activation by IQmp (Fig. 4D and G).
Modulation of ICa through an IQ domain requires SR Ca2+ in ventricular myocytes
Previous studies employing heterologously expressed cardiac LTCCs found that IQ was important for determining both ICa facilitation (Zuhlke et al. 1999) and inactivation (Peterson et al. 1999; Zuhlke et al. 1999). Because significant Ca2+ release from intracellular stores was unlikely to have contributed to [Ca2+]i-dependent regulation of ICa in heterologous systems, it is likely that ICa itself was the primary source of [Ca2+]i for regulation of LTCCs. Our results suggest that the SR is especially important for [Ca2+]i-dependent regulation of ICa in native ventricular myocytes under our experimental conditions (Fig. 3), or in the absence of added Ca2+ buffers. These findings do not exclude the possibility that CaMK may also be directly activated by ICa in ventricular myocytes under other experimental conditions (Hryshko & Bers, 1990).
The relationship between findings in excised patches and cardiac myocytes
IQmp and CaMK both facilitated LTCCs (Fig. 4) and ICa (Fig. 1). However, LTCC facilitation under our experimental conditions did not replicate the transitory nature of ICa facilitation. Regulatory elements such as SR Ca2+ release, phosphatases and dynamic Ca2+ activation of CaM are present in intact cardiac myocytes, but are probably lacking in excised cell membrane patches. All of these elements may contribute to dynamic aspects of ICa facilitation, while their absence may account for the more constant nature of LTCC facilitation by IQmp and CaMK in excised cell membrane patches.
Summary
The results of the present study indicate that CaMK activation is required for ICa facilitation, but that IQmp can rescue ICa facilitation during CaMK inhibition. Both CaMK and IQmp facilitated ICa by inducing a modal gating shift favouring prolonged LTCC openings. LTCC facilitation by CaMK and the IQmp was non-additive, suggesting that these signalling elements converge in a common pathway.
|
REFERENCES |
|---|
|
TopAbstractIntroductionMethodsResultsDiscussionReferences |
|---|
| ADACHI-AKAHANE S., CLEEMANN, L. & MORAD, M. (1996). Cross-signaling between L-type Ca2+ channels and ryanodine receptors in rat ventricular myocytes. Journal of General Physiology 108, 435-454 | [Abstract] |
| ANDERSON M. E., BRAUN, A. P., SCHULMAN, H. & PREMACK, B. A. (1994). Multifunctional Ca2+/calmodulin-dependent protein kinase mediates Ca2+-induced enhancement of the L-type Ca2+ current in rabbit ventricular myocytes. Circulation Research 75, 854-861 | [Abstract] |
| BERS D. M., PATTON, C. W. & NUCCITELLI, R. (1994). A practical guide to the preparation of Ca2+ buffers. Methods in Cell Biology 40, 3-29 | [Medline] |
| BRAUN A. P. & SCHULMAN, H. (1995). A non-selective cation current activated via the multifunctional Ca2+-calmodulin-dependent protein kinase in human epithelial cells. Journal of Physiology 488, 37-55 | [Abstract] |
| CHAO S. H., SUZUKI, Y., ZYSK, J. R. & CHEUNG, W. Y. (1984). Activation of calmodulin by various metal cations as a function of ionic radius. Molecular Pharmacology 26, 75-82 | [Abstract] |
| DZHURA I., WU, Y., COLBRAN, R. J., BALSER, J. R. & ANDERSON, M. E. (2000). Calmodulin kinase determines calcium-dependent facilitation of L-type calcium channels. Nature Cell Biology 2, 173-177 | [Medline] |
| GUPTA R. C. & KRANIAS, E. G. (1989). Purification and characterization of a calcium-calmodulin-dependent phospholamban kinase from canine myocardium. Biochemistry 28, 5909-5916 | [Medline] |
| HADLEY R. W. & LEDERER, W. J. (1991). Ca2+ and voltage inactivate Ca2+ channels in guinea-pig ventricular myocytes through independent mechanisms. Journal of Physiology 444, 257-268 | [Abstract] |
| HAMILL O. P., MARTY, A., NEHER, E., SAKMANN, B. & SIGWORTH, F. J. (1981). Improved patch-clamp techniques for high-resolution current recording from cells and cell-free membrane patches. Pflügers Archiv 391, 85-100 | [Medline] |
| HRYSHKO L. V. & BERS, D. M. (1990). Ca current facilitation during postrest recovery depends on Ca entry. American Journal of Physiology 259, H951-961 | [Medline] |
| MARBAN E. & TSIEN, R. W. (1982). Enhancement of calcium current during digitalis inotropy in mammalian heart: positive feed-back regulation by intracellular calcium? Journal of Physiology 329, 589-614 | [Medline] |
| PATE P., MOCHCA-MORALES, J., WU, Y., ZHANG, J., RODNEY, G., SERYSHEVA, I. I., WILLIAMS, B. Y., ANDERSON, M. E. & HAMILTON, S. L. (2000). Determinants for calmodulin binding on voltage-dependent Ca2+ channels. Journal of Biological Chemistry 275, 39786-39792 | [Abstract/Full Text] |
| PAYNE M. E., FONG, Y. L., ONO, T., COLBRAN, R. J., KEMP, B. E., SODERLING, T. R. & MEANS, A. R. (1988). Calcium/calmodulin-dependent protein kinase II. Characterization of distinct calmodulin binding and inhibitory domains. Journal of Biological Chemistry 263, 7190-7195 | [Abstract] |
| PETERSON B. Z., DEMARIA, C. D., ADELMAN, J. P. & YUE, D. T. (1999). Calmodulin is the Ca2+ sensor for Ca2+-dependent inactivation of L-type calcium channels. Neuron 22, 549-558 | [Medline] |
| QIN N., OLCESE, R., BRANSBY, M., LIN, T. & BIRNBAUMER, L. (1999). Ca2+-induced inhibition of the cardiac Ca2+ channel depends on calmodulin. Proceedings of the National Academy of Sciences of the USA 96, 2435-2438 | [Abstract/Full Text] |
| RHOADS A. R. & FRIEDBERG, F. (1997). Sequence motifs for calmodulin recognition. FASEB Journal 11, 331-340 | [Abstract] |
| SIGWORTH R. J. & SINE, S. M. (1987). Data transformations for improved display and fitting of single-channel dwell time histograms. Biophysical Journal 52, 1047-1054 | [Abstract] |
| SUN H., LEBLANC, N. & NATTEL, S. (1997). Mechanisms of inactivation of L-type calcium channels in human atrial myocytes. American Journal of Physiology 272, H1625-1635 | [Medline] |
| VANDONGEN A. M. (1996). A new algorithm for idealizing single ion channel data containing multiple unknown conductance levels. Biophysical Journal 70, 1303-1315 | [Abstract] |
| WU Y. & ANDERSON, M. E. (2000). Ca2+-activated non-selective cation current in rabbit ventricular myocytes. Journal of Physiology 522, 51-57 | [Abstract/Full Text] |
| WU Y., MACMILLAN, L. B., MCNEILL, R. D., COLBRAN, R. J. & ANDERSON, M. E. (1999). CaM kinase augments cardiac L-type Ca2+ current: a cellular mechanism for long Q-T arrhythmias. American Journal of Physiology 276, H2168-2178 | [Medline] |
| XIAO R. P., CHENG, H., LEDERER, W. J., SUZUKI, T. & LAKATTA, E. G. (1994). Dual regulation of Ca2+/calmodulin-dependent kinase II activity by membrane voltage and by calcium influx. Proceedings of the National Academy of Sciences of the USA 91, 9659-9663 | [Abstract] |
| YUAN W. & BERS, D. M. (1994). Ca-dependent facilitation of cardiac Ca current is due to Ca-calmodulin-dependent protein kinase. American Journal of Physiology 267, H982-993 | [Medline] |
| YUE D. T., HERZIG, S. & MARBAN, E. (1990). Beta-adrenergic stimulation of calcium channels occurs by potentiation of high-activity gating modes. Proceedings of the National Academy of Sciences of the USA 87, 753-757 | [Abstract] |
| ZUHLKE R. D., PITT, G. S., DEISSEROTH, K., TSIEN, R. W. & REUTER, H. (1999). Calmodulin supports both inactivation and facilitation of L-type calcium channels. Nature 399, 159-162 | [Medline] |
| ZUHLKE R. D., PITT, G. S., TSIEN, R. W. & REUTER, H. (2000). Ca2+-sensitive inactivation and facilitation of L-type Ca2+ channels both depend on specific amino acid residues in a consensus calmodulin-binding motif in the (alpha)1C subunit. Journal of Biological Chemistry 275, 21121-21129 | [Abstract/Full Text] |
| ZUHLKE R. D. & REUTER, H. (1998). Ca2+-sensitive inactivation of L-type Ca2+ channels depends on multiple cytoplasmic amino acid sequences of the alpha1C subunit. Proceedings of the National Academy of Sciences of the USA 95, 3287-3294 | [Abstract/Full Text] |
| ZYGMUNT A. C. & GIBBONS, W. R. (1991). Calcium-activated chloride current in rabbit ventricular myocytes. Circulation Research 68, 424-437 | [Abstract] |
Acknowledgements
This work was supported by grants from the National Institutes of Health (NHLBI, HL03727 and HL62494, to M.E.A.) and the American Heart Association S.E. Affiliate (M.E.A. and R.J.C.). We thank Martha Bass for excellent technical assistance, and Jeffrey R. Balser and Dan M. Roden for thoughtful comments and criticisms.
Corresponding author
M. E. Anderson: Departments of Internal Medicine and Pharmacology, Vanderbilt University, Nashville, TN 37232-6300, USA.
Email: mark.anderson{at}mcmail.vanderbilt.edu
This article has been cited by other articles:
|
|
 |
|
  C. Chantawansri, N. Huynh, J. Yamanaka, A. Garfinkel, S. T. Lamp, M. Inoue, J. H. B. Bridge, and J. I. Goldhaber Effect of Metabolic Inhibition on Couplon Behavior in Rabbit Ventricular Myocytes Biophys. J., March 1, 2008; 94(5): 1656 - 1666. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 A. L. Tippens and A. Lee Caldendrin, a Neuron-specific Modulator of Cav/1.2 (L-type) Ca2+ Channels J. Biol. Chem., March 16, 2007; 282(11): 8464 - 8473. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 M. E. Anderson Multiple downstream proarrhythmic targets for calmodulin kinase II: Moving beyond an ion channel-centric focus Cardiovasc Res, March 1, 2007; 73(4): 657 - 666. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 L. P. Collis, M. B. Meyers, J. Zhang, C. K. L. Phoon, E. A. Sobie, W. A. Coetzee, and G. I. Fishman Expression of a sorcin missense mutation in the heart modulates excitation-contraction coupling FASEB J, February 1, 2007; 21(2): 475 - 487. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
T.-S. Lee, R. Karl, S. Moosmang, P. Lenhardt, N. Klugbauer, F. Hofmann, T. Kleppisch, and A. Welling Calmodulin Kinase II Is Involved in Voltage-dependent Facilitation of the L-type Cav1.2 Calcium Channel: IDENTIFICATION OF THE PHOSPHORYLATION SITES J. Biol. Chem., September 1, 2006; 281(35): 25560 - 25567. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 J. Guo and H. J. Duff Calmodulin kinase II accelerates L-type Ca2+ current recovery from inactivation and compensates for the direct inhibitory effect of [Ca2+]i in rat ventricular myocytes J. Physiol., July 15, 2006; 574(2): 509 - 518. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 H. I. Akbarali Signal-Transduction Pathways that Regulate Smooth Muscle Function II. Receptor-ion channel coupling mechanisms in gastrointestinal smooth muscle Am J Physiol Gastrointest Liver Physiol, April 1, 2005; 288(4): G598 - G602. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 J.-J. Xu, L.-Y. Hao, A. Kameyama, and M. Kameyama Calmodulin reverses rundown of L-type Ca2+ channels in guinea pig ventricular myocytes Am J Physiol Cell Physiol, December 1, 2004; 287(6): C1717 - C1724. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
Y. Wu, J. T. Kimbrough, R. J. Colbran, and M. E. Anderson Calmodulin kinase is functionally targeted to the action potential plateau for regulation of L-type Ca2+ current in rabbit cardiomyocytes J. Physiol., January 1, 2004; 554(1): 145 - 155. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 K. B. Walsh and Q. Cheng Intracellular Ca2+ regulates responsiveness of cardiac L-type Ca2+ current to protein kinase A: role of calmodulin Am J Physiol Heart Circ Physiol, January 1, 2004; 286(1): H186 - H194. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 P. J. Welsby, H. Wang, J. T. Wolfe, R. J. Colbran, M. L. Johnson, and P. Q. Barrett A Mechanism for the Direct Regulation of T-Type Calcium Channels by Ca2+/Calmodulin-Dependent Kinase II J. Neurosci., November 5, 2003; 23(31): 10116 - 10121. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
S. Ohya and B. Horowitz Differential transcriptional expression of Ca2+ BP superfamilies in murine gastrointestinal smooth muscles Am J Physiol Gastrointest Liver Physiol, December 1, 2002; 283(6): G1290 - G1297. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 A. B. Belousov, N. D. Hunt, R. P. Raju, and J. V. Denisova Calcium-Dependent Regulation of Cholinergic Cell Phenotype in the Hypothalamus In Vitro J Neurophysiol, September 1, 2002; 88(3): 1352 - 1362. [Abstract] [Full Text] [PDF]
|
|
| ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| HOME | HELP | FEEDBACK | SUBSCRIPTIONS | ARCHIVE | SEARCH | TABLE OF CONTENTS |
; n = 10), IQmp (
; n = 10), AC3-I (
; n = 19) and AC3-I + IQmp (
; n = 12). ICa facilitation was significantly increased in all groups compared with AC3-I-treated cells (P < 0.001) from beat 2 onwards.
; n = 7) or solution lacking peptide (
; n = 23). The data for IQmp-con- and IQmp-treated cells are the same as in Fig. 1E. Differences in ICa facilitation were significant (P = 0.047 for beat 3 and P < 0.001 for subsequent beats) between groups. Differences in ICa facilitation were also significant (P < 0.05) between 290-309-treated cells versus IQmp-con-treated cells for beats 10-20. D, the fast time constant of ICa inactivation was significantly slowed by IQmp (P < 0.01) for beats 6-17. Symbols as in C.