Abstract
Modulation of the L-type Ca2+ channel (LTCC) by sorcin was investigated by measuring the L-type Ca2+ current (I Ca,L) in isolated rabbit ventricular myocytes using ruptured patch, single electrode voltage clamp in the absence of extracellular Na+. Fifty millimolars EGTA (170 nM Ca2+) in the pipette solution buffered bulk cytoplasmic [Ca2+], but retained rapid Ca2+-dependant inactivation of I Ca,L,. Recombinant sorcin (3 μM) in the pipette significantly slowed time-dependant inactivation (τ fast: 8.8 ± 0.9 vs. 15.1 ± 1.7 ms). Sorcin had no significant effect on I Ca,L, after inhibition of the sarcoplasmic reticulum (SR). Using 10 mM 1,2-bis(o-N,N,N′,N′-tetraacetic acid (170 nM Ca2+), I Ca,L inactivation was then determined by a Ca2+ -independent, voltage-dependant process. Under these conditions, 3 μM sorcin speeded up inactivation. A similar effect was observed by substitution of Ca2+ with Ba2+. Down-regulation of endogenous sorcin to 27 ± 7% using an RNAi adenoviral vector slowed inactivation of I Ca,L by ∼42%. The effects of sorcin on voltage-dependant inactivation were mimicked by a truncated form of the protein containing only the Ca2+-binding domain. This data is consistent with two independent actions of sorcin on the LTCC: (1) slowing Ca2+-dependant inactivation and (2) stimulating voltage-dependant inactivation. The net effect of sorcin on the time-dependent inactivation of I Ca,L was a balance between these two effects. Under normal conditions, sorcin slows I Ca,L inactivation because the effects of Ca2+-dependant inactivation out-weigh the effects on voltage-dependant inactivation.
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Introduction
Sorcin is a 21.6-KDa intracellular Ca2+-binding protein that is expressed in a variety of mammalian tissues including the heart [1–3], where it appears close to the transverse-tubular membrane system [3]. Sorcin has been shown to bind to two intracellular targets involved in excitation–contraction (E-C) coupling; the ryanodine receptor (RyR2) and the α1C-subunit of the L-type Ca channel (LTCC) [3, 4]. Functionally, sorcin has been shown to reduce the activity of RyR2 [5, 6] and enhance inactivation of I Ca,L [7]. Effects on the activity of the Na/Ca exchanger (NCX) [6, 8] and the sarcoplasmic reticulum Ca2+-ATPase (SERCA) [9] have also been reported. However, the effect of sorcin on the LTCC in myocardium is uncertain, since two studies have failed to demonstrate an effect [5, 6]. One complicating factor in studies on intact heart cells is that sorcin affects the activity of two proteins, the LTCC and RyR2, which are in close proximity at the interface between the T-tubule and SR membranes. This area, known as the junctional cleft is a microdomain (10–20 nm wide [10, 11]) in which the diffusion of Ca2+ is restricted [12]. Ca2+ fluxes via LTCC and RyR2 influence the [Ca2+] in the cleft, which in return regulates the activity of these proteins. In the case of the LTCC [Ca2+], the cleft regulates the decay of I Ca,L via a Ca2+-dependent inactivation (CDI) process [13–15]. An additional complication in distinguishing sorcin’s action on the LTCC comes from the recent evidence that the activity of NCX can affect CDI by influencing the [Ca2+] within the cleft [16]. Therefore, sorcin’s apparently variable action on the LTCC may arise from parallel effects on NCX and the SR of cardiac muscle. To test this hypothesis, the present study used Na+- and K+-free solutions in combination with high intracellular concentrations of Ca2+ buffers. The data revealed for the first time two independent and functionally opposing effects on CDI and voltage-dependent/Ca2+ independent inactivation (CII/VDI).
Materials and methods
Isolation of rabbit ventricular myocytes
New Zealand White rabbits (2–2.5 kg) were euthanized by administration of an intravenous injection of 500 IU heparin together with an overdose of sodium pentobarbitone (100 mg kg−1). Hearts were removed in accordance with the United Kingdom Animals (Scientific Procedures) Act 1986, and the Guide for the Care and use of Laboratory Animals published by the US National Institutes of Health (NIH Publication No. 85-23, revised 1985). Ventricular cardiomyocytes were then isolated as previously described [17] and suspended in Krebs buffer of the following composition (mM): NaCl, 140; KCl, 4; MgCl2, 1; CaCl2, 1; glucose, 11.1; HEPES, 5; pH 7.4, Ca2+ 1.8 mM.
Electrophysiology
Ventricular myocytes were whole cell voltage clamped using an Axon Axoclamp 2B switch clamp amplifier in discontinuous mode (10–35 kHz); voltage and current signals were filtered at 1 kHz. Patch electrodes had a resistance of 2–10 MΩ when back filled with the internal solution described below. Following patch rupture and dialysis (5 min), I Ca,L was elicited by a 300-ms step depolarization from –40 to 0 mV, preceded by a 50-ms prepulse from –80 to –40 mV to inactivate I Na at 0.5 Hz.. Current–voltage relations were obtained by depolarizing the cell to a range of test pulses between –40 and +80 mV in 10 mV increments. Steady-state voltage-dependent activation and inactivation was assessed by a double pulse protocol where a test pulse to 0 mV was preceded by a range of conditioning pulses between –60 and +60 mV in 10 mV steps at 0.5 Hz. Experiments examining I Ca,L in adult cardiomyocytes cultured for 96 h used a depolarizing step to +20 mV.
Pipette and extracellular solutions
The pipette solution contained (in mM): Cs2EGTA, (0.01–50); CsCl, 20; TEACl, 35; MgCl2, 4.5; Na2ATP, 4; Na2CRP, 1; HEPES, 20; Ca, 25 (free Ca2+, 170 ± 5 nM, n = 10). To achieve the range of [EGTA] described in the solution above, a near identical pipette solution was made with the following composition (in mM): CsCl, 120; TEACl, 35; MgCl2, 4.5; Na2ATP, 4; Na2CRP, 1; HEPES, 20; EGTA, 0.3; pH 7.25 with CsOH. Ca2+ concentration was titrated to equal that of the 50 mM solution (calculated to be 170 nM) with CaCl2 using a spectrophotometer and Fura 2 (free acid, Molecular Probes). These two solutions could then be mixed as desired to yield intracellular solutions with identical Ca2+ activities but with varying [EGTA].
Where required, 1,2-bis(o-ethane-N,N,N′,N′-tetraacetic acid (BAPTA; 10 mM) was added to the pipette solution and free Ca2+ activity corrected by the addition of Ca2+ (from a 100-mM CaCl2 stock). Free [Ca2+] was calculated as described [18] and checked using Fura-2 fluorescence in a cuvette-based spectrophotometer system. Extracellular solutions devoid of Na+ and K+ were based on previous studies [19] (in mM): TEACl, 140; CsCl, 4; HEPES, 5; MgCl2, 1; CaCl2, 1.8; Glucose, 11.1; 4AP, 5; pH to 7.4 with CsOH. The osmolarity of both intracellular and extracellular solutions did not vary by more than 5%.
Intracellular [Ca2+]
Monitoring of intracellular Ca2+ (Ca2+ i) was performed using Fura-2 (100 μM), introduced into the cell via the patch pipette, and the fluorescence was monitored using a Cairn monochrometer (Carin, Faversham, Kent, UK).
Expression and purification of wild-type sorcin and its variants
Chinese hamster ovary recombinant sorcin was expressed in E. coli BL21 (DE3) cells and purified as previously described [20]. The same purification procedure was used for the truncated protein. Protein concentration was determined spectrophotometrically at 280 nm. Full-length sorcin and the truncated peptide consisting of the C-terminus only [sorcin–calcium-binding domain—(SCBD)] was added to the intracellular pipette solution for dialysis into the cell at a concentration of 3 μM using a protocol similar to previous work [5]. Allowing sorcin to dialyze into the cell for up to 10 min had no additional effects (data not shown). Preliminary experiments using 1 μM sorcin had no significant effect on the L-type Ca2+ current. The absence of significant changes in I Ca,L over the duration of the experiment (10–15 min) suggests that loss of endogenous sorcin from the cardiomyocytes by dialysis via the pipette was of minor consideration.
Preparation and testing of RNAi virus
A partial rabbit sorcin sequence was amplified using primers based on the known human sorcin sequence by reverse transcription of RNA from a chinchilla bastard rabbit. Sense and antisense oligonucleotides were chosen to target the 19 nucleotide (nt) segment complementary to the rabbit sorcin mRNA sequence GCAAGAUCACCUUCGAUGA and ligated downstream of a U6 promoter into vector pSIREN-DNR (BD Biosciences Clontec, Palo Alto, USA). Recombination with the remaining adenoviral genome using pAdeno-X vector was carried out according to manufacturers instructions (BD Adeno-X Expression System, BD, Biosciences Clontec, Palo Alto, CA, USA) and virus upscaling and purification was undertaken as described before [6].
Adenoviral infection with a multiplicity of infection of 100 was performed to produce 2 populations of adenovirus-transfected cardiomyocytes: (1) expressing the Sorcin RNAi (Ad-SorRNAi) and (2) expressing β-galactosidase as control (Ad-LacZ). Infected cardiomyocytes were subsequently cultured in supplemented medium M199 (Sigma) for 96 h. Western blot analysis indicated the level of down-regulation to be 0.27 ± 0.7 (n = 5, P < 0.05) of that in Ad-LacZ transfected cells (Fig. 5).
Immunoblotting used the NuPAGE system (Invitrogen) with 10% Bis–Tris gels and MOPS buffer. CSQ in cell lysates from Ad-LacZ and Ad-Sorcin-RNAi transfected cells was detected with mouse monoclonal anti-CSQ at 1:200 dilution. CSQ protein levels in both experimental groups were used as a standard. Sorcin antibody (rabbit polyclonal, a kind gift from Dr. Valdivia, Madison, WI, USA) was used at 1:10,000 dilution. Immunoblots were quantified using image analysis software (Quantity One, BioRad)
Data analysis and statistics
Peak I Ca,L was taken as the difference current between the current peak and steady state at the end of the test voltage pulse and is expressed as a function of cellular capacitance. I Ca,L CDI is evident as a Ca2+-dependent inactivation best described by a double exponential function fitted to the decay phase of the current [19].
A measure of the Ca2+ buffering imposed by EGTA and BAPTA within the cell was gained using the following equation: \({\rm{length}}\,{\rm{constant}}\,{\rm{of}}\,{\rm{buffer}} = \surd \left( {{{{\rm{D}}_{{\rm{Ca}}} } \mathord{\left/ {\vphantom {{{\rm{D}}_{{\rm{Ca}}} } {K_{{\rm{on}}} \cdot {\rm{B}}_{\rm{T}} }}} \right. \kern-\nulldelimiterspace} {K_{{\rm{on}}} \cdot {\rm{B}}_{\rm{T}} }}} \right)\) [21], where DCa is the diffusion of Ca2+ in the cytosol, K on is the rate of Ca2+ binding by the buffer and B T is the buffer concentration. Estimates of the equation constants were taken from Soeller and Cannell and Naraghi and Neher [21, 22]. The length constants are described in the relevant sections. Data were statistically analyzed using unpaired t tests or one-way analysis of variance (ANOVA), with interactions where appropriate using Sigma Stat (Jandel Scientific), and significance was taken at 5%.
Results
Retention of CDI despite buffering of bulk cytoplasmic Ca2+
Figure 1a illustrates the lack of significant changes in I Ca,L (amplitude and inactivation see inset) and the progressive decrease in the amplitude of the Ca2+ transient as the [EGTA] in the patch pipette is progressively increased ([Ca2+] ∼170 nM). At 50 mM EGTA, there was no detectable change in bulk intracellular [Ca2+]. Figure 1b shows the mean values of amplitude and rate of inactivation. Also shown for comparison are the mean values for I Ca,L amplitude and rate of inactivation recorded from cells with minimal EGTA (10 μM) in solutions containing normal Na+ and K+ (square symbols). Under these conditions (50 mM EGTA), Ca2+ influences LTCC in a spatially restricted region, and so the next series of experiments examined the modulatory influence of sorcin on I Ca,L in the absence of changes in bulk cytoplasmic [Ca2+].
The effect of sorcin on the time-dependant inactivation of I Ca,L
As shown in Fig. 1c(i), the rate of inactivation of I Ca,L following a depolarizing step to 0 mV (0.5 Hz) was significantly slowed by the inclusion of sorcin in the pipette solution [τ fast control 8.8 ± 0.9 ms, n = 14; τ fast sorcin 15.1 ± 1.7 ms, n = 9, Fig. 1c(ii)]. Inactivation rate was not significantly altered following dialysis of the EGTA and TRIS-containing buffer used for the suspension of sorcin in the absence of the protein (τ fast buffer 9.9 ± 2.1 ms, n = 4, vs. τfast control, 8.8 ± 0.9 ms, n = 14) or when sorcin was denatured by boiling for 5 min (10.9 ± 0.9 ms, n = 6, P > 0.05 vs. control). Sorcin did not modulate the slow component of inactivation (τ slow) which remained almost an order of magnitude larger than τ fast as described previously [19] (τ slow control 68.4 ± 6 ms, n = 14; sorcin, 71.1 ± 15 ms, n = 9, P > 0.05). This effect of sorcin was also observed in a limited set of experiments where I Ca,L was elicited by a step depolarization from –80 to 0 mV (without the prepulse to –40 mV) in the absence of extracellular Na+.
The effect of sorcin on the I–V relationship of I Ca,L
Current voltage and steady-state current activation and inactivation relations were generated using the voltage protocols illustrated in Fig. 2a(i–ii). Sorcin increased peak current at −10 and 0 mV (P < 0.05; Fig. 2b). The family of activation curves generated by the double pulse protocol indicates a negative shift in activation voltage (V half) associated with sorcin, which was significantly different at –10 and 0 mV [P < 0.05; Fig. 2c(i)]. Under control conditions, V half was −4.2 ± 0.08 mV, while in the presence of sorcin, activation was more negative (V half was −7.3 mV ± 0.02, P < 0.05). The double pulse protocol also reveals the steady-state inactivation properties of I Ca,L which were not significantly altered at any of the test voltages [Fig. 2c(ii)]. It appears that the major effects of sorcin on macroscopic current properties are alterations to steady-state activation. However, since the rate of CDI is not altered at –10 and 0 mV, changes in current magnitude do not explain the effect of sorcin on the inactivation of I Ca,L [19]. The next series of experiments therefore examined potential mechanisms for the modulatory influence of sorcin on the time-dependant inactivation of I Ca,L.
The ability of sorcin to modulate inactivation of I Ca,L after inhibition of the SR
The activity of the SR was inhibited using thapsigargin (25 μM; 10 min) or ryanodine (30 μM; 10 min). Inhibition of the SR slowed inactivation of ICa,L following a step depolarization to 0 mV [Fig. 3a(i–ii)]. Under these conditions, there was no significant modulation of I Ca,L by sorcin (Fig. 3b(i–ii). The loss of sorcin’s action on I Ca,L after SR inhibition may be linked to diminished [Ca2+] release into the junctional cleft during activation. To test this hypothesis, Ca2+ entry through the LTCC was increased by elevating extracellular [Ca2+] to 5.4 and 20 mM Ca2+ in the presence of thapsigargin; this increased whole cell current from 6.0 ± 0.5 pA/pF ([Ca2+]o = 1.8 mM) to 18.4 ± 5.8 pA/pF (n = 5; P < 0.05; [Ca2+]o = 20 mM) Raising extracellular [Ca2+] resulted in faster inactivation despite the absence SR Ca2+ release (Fig. 3c black triangles). However, the rate of inactivation was not altered significantly by sorcin at 5.4 mM Ca2+ (step to 0 mV) or 20 mM Ca2+ (step to +10 mV, Fig. 3c open triangles). Sorcin was also without effect on inactivation at +20 mV with 20 mM extracellular Ca2+. Data in the absence of thapsigargin is shown for comparison (open and filled circles). These data strongly suggest that sorcin activation requires the conditions prevalent in the junctional cleft/dyad. This was tested further by examining the effect of sorcin in the presence of the faster Ca2+ buffer BAPTA.
Sorcin’s action on I Ca,L in the presence of BAPTA
In order to investigate the effects of sorcin on I Ca,L in the absence of Ca2+-dependant inactivation, 10 mM BAPTA with identical diastolic Ca2+ to previous measurements (170 nM Ca2+) was used in the patch pipette to further limit the rise in [Ca2+] in the microdomain. Calculations suggest that 10 mM BAPTA is capable of buffering intracellular Ca2+ at distances of ∼7 nm [21]. In the presence of sorcin, τ fast was significantly faster following a step depolarization to 0 mV [Fig. 4a(i–ii)]. In separate experiments, I Ca,L was elicited from a holding potential of –80 in 10 mV increments to a range of test pulses as described previously. In the presence of sorcin, peak current density was significantly larger at +10 mV (P < 0.05; Fig. 4bi). The values of V half for activation and inactivation were not significantly different [Fig. 4b(ii–iii)]. Separate experiments in the presence of BAPTA showed that inhibition of the SR had no further effect on inactivation rate (data not shown). These data therefore suggest that, in the presence of BAPTA (170 nM Ca2+), sorcin has modest effects on the I–V relationship of I Ca,L but the rate of I Ca,L inactivation is significantly increased, in contrast to that observed in the presence of EGTA. To test whether this effect is due to minimizing Ca2+-dependant inactivation by BAPTA, measurements were repeated using Ba2+ as the charge carrier.
Is a rise in sub-sarcolemmal Ca2+ a requirement for the action of sorcin on the LTCC?
To remove Ca2+ completely from the junctional cleft, 1.8 mM Ba2+ was substituted for Ca2+ in the extracellular perfusate and I Ca(Ba) recorded using 50 mM EGTA (170 nM Ca2+) in the patch pipette solution. Under these conditions, sorcin significantly increased the rate of inactivation [τ fast control 75 ± 11 ms, n = 11; τ fast sorcin 46.3 ± 6 ms, n = 10, P < 0.05, Fig. 4c(i–ii)]. If BAPTA (10 mM) was added to the patch pipette without correction of free Ca2+, the free [Ca2+] in the patch pipette (and therefore within the cell) is reduced to <1 nM, and under these conditions, addition of sorcin did not significantly modulate current inactivation with a Ca2+-containing extracellular perfusate [Fig. 4d(i–ii)], suggesting that sorcin was ineffective at modulating I Ca,L when cytoplasmic [Ca2+] is below 1 nM.
Does-endogenous sorcin modulate the LTCC?
An RNAi adenovirus construct was used to down-regulate native sorcin expression to 27 ± 7% of control value in adult cultured cardiomyocytes [Fig. 5a(i–ii)]. Examination of I Ca,L (170 nM Ca2+) showed that the rate of inactivation was significantly slowed compared to control [Ad-LacZ infected; Fig. 5b(i–ii)] indicating a modulatory role for endogenous sorcin.
Truncated construct of sorcin indicates C-terminal interaction with LTCC
Biochemical analysis has demonstrated key regions of the sorcin protein involved in the interaction with target proteins. Specifically, these sites are located at the C- and N-terminals of the protein [20]. We investigated the domain involved in interaction with I Ca,L using a truncated form of sorcin that contains only the C-terminus (sorcin–calcium-binding-domain, SCBD) [20]. Inclusion of SCBD in the patch pipette did not significantly alter current inactivation [Fig. 6a(i–ii)], but repeating these experiments in the presence of BAPTA (170 nM Ca2+) resulted in a significant increase in the rate of current inactivation [Fig. 6b(i–ii)]. These results suggest that a C-terminus interaction dominates in the interaction with LTCC.
Are kinase pathways involved in the mechanism of action of sorcin on I Ca,L?
We also considered whether sorcin influenced I Ca,L indirectly by affecting intracellular signaling pathways that alter I Ca,L by phosphorylation of LTCC. The two main kinases responsible are protein kinase A (PKA) and calcium–calmodulin-dependant kinase type II (CaMKII). CaMKII is thought to be responsible for mediating frequency-dependent facilitation (FDF) of I Ca,L [23], which is manifested by an increase in peak current and a slowing of inactivation as the frequency of contraction increases. From a holding potential of –80 mV, I Ca,L displayed facilitation following an increase in stimulation frequency from 0.1 to 1 Hz: inactivation kinetics were slowed on the fifth pulse at 1 Hz compared to the first pulse [Fig. 7a(i) and b], while current magnitude increased (the ratio of peak current at beat 5 compared to beat 1 (B5/B1) increased to 1.26 ± 0.02, n = 8). Five micromolars of KN-93 (a CaMKII inhibitor) abolished the rate-dependent slowing of inactivation [Fig. 7a(ii) and b], while B5/B1 was decreased to 0.88 ± 0.02 (n = 8). No significant effect of KN-93 was observed on I Ca,L density during facilitation. This data confirms the involvement of CaMKII in mediating facilitation of I Ca,L and provides evidence that KN-93 treatment was effectively blocking CaMKII activity. Under these conditions, sorcin-mediated changes in I Ca,L inactivation were not blocked by the presence of KN-93 [Fig. 7c(i–ii)], suggesting that inhibition of CaMKII does not influence the effect of sorcin on I Ca,L inactivation kinetics.
We also investigated the role of protein kinase A (PKA) using the inhibitory peptide (PKI). The inclusion of PKI in the patch pipette did not significantly affect the ability of sorcin to modulate inactivation of I Ca,L [Fig. 8a(i–iii)]. These data are consistent with sorcin’s actions on I Ca,L without the involvement of CaMKII and PKA.
Discussion
This paper presents novel data describing the effects of sorcin on I Ca,L in rabbit ventricular myocytes. Sorcin (3 µM) increased I Ca,L over a limited range of voltages but had two distinct and opposing effects on the inactivation of I Ca,L: (1) slowing the rate of CDI and (2) enhancing the rate of CII/VDI.
Is the modulation of I Ca,L by sorcin due to an effect on the I–V relationship?
The inclusion of sorcin in the patch pipette had small but significant effects on I Ca,L current–voltage relations consistent with a leftward shift in the activation curve of the current. In addition to the effects on the current–voltage relationship, sorcin had significant effects on the time course of activation, evident at 0 and +10 mV but not at −10 mV. These data and the previously published relationship between inactivation rates and voltage [19] indicate that the effect of sorcin on time-dependent inactivation is a distinct action and not a consequence of the changes in the current voltage relationship.
Modulation of CDI and VDI by sorcin
Sorcin’s action on I Ca,L inactivation was observed when 50 mM EGTA was used to buffer cytoplasmic Ca2+, indicating that a transient rise in bulk cytoplasmic [Ca2+] was not required for modulation. The ability of sorcin to influence I Ca,L inactivation appeared to require a functional SR, since there was no apparent effect of sorcin after ryanodine or thapsigargin treatment. This would suggest that the action of sorcin on the LTCC required the transiently high Ca2+ signal that exists within the junctional cleft as a result of SR Ca2+ release. However, the data in the presence of BAPTA would tend to argue against this. The more rapid buffering by BAPTA (170 nM Ca2+), which limits the rise of Ca2+ in the junctional cleft results in much slower I Ca,L inactivation than was observed following SR inhibition. This is as expected if Ca2+-dependent inactivation was substantially attenuated. This indicates that SR inhibition alone reduces but does not abolish Ca2+-dependent inactivation, i.e., it does not abolish the increase in [Ca2+] in the cleft. The slower inactivation of I Ca,L in the presence of 10 mM BAPTA was unaffected by SR inhibition (data not shown) indicating that 10 mM BAPTA was capable of preventing SR Ca2+ release from influencing cleft [Ca2+]. Under these conditions, only voltage-dependent processes dictated the inactivation rate of I Ca,L; here sorcin enhanced the inactivation of I Ca,L, i.e., the opposite effect to that seen when Ca2+-dependent inactivation was present. This is similar to the effects observed by Meyers and co-workers [7] who used EGTA-containing pipette solutions. Under these circumstances, free [Ca2+] within the cell would be very much lower, thereby reducing the influence of Ca2+-dependent inactivation allowing voltage-dependant inactivation to dominate over Ca2+-dependent inactivation. Therefore, the data by Meyers et al. [7] that appear at first sight to the opposite of those reported in this study, can be explained by the effects of sorcin on voltage-dependent inactivation. Similar effects of sorcin were observed when Ba2+ was used as the charge carrier; this reinforces the conclusion that sorcin has a distinct action on the LTCC in the absence of Ca2+-dependent inactivation, i.e., when voltage-dependent alone determines the rate of inactivation. This latter result also indicates that sorcin does not require Ca2+ influx to mediate its effects. However, in the absence of intracellular Ca2+ (<1 nM, 10 mM BAPTA), addition of sorcin did not affect inactivation, indicating that diastolic Ca2+ levels (∼150 nM) are sufficient to mediate sorcin’s Ca2+-sensitive actions. Only one binding site for sorcin has been demonstrated in the C-terminal region of α1C subunit. The site at residues 1,622–2,171 overlaps with the CaM-binding domain [4]. The consequences of sorcin binding at this site on the activity of the LTCC have yet to be elucidated.
Sorcin’s modulation of the LTCC as the sum of two independent effects
The data presented in this study indicates that sorcin influences both Ca2+-dependent and voltage-dependent inactivation processes. The interrelationship between these two actions is unclear. While voltage-dependent inactivation can be studied in the absence of Ca2+-dependent inactivation, the opposite is not true.
A number of different models could be used to account for sorcin’s bifunctional modulatory influence on I Ca,L. One model may be the exclusive influence of sorcin on Ca2+-dependent and voltage-dependent inactivation separately with different Ca2+-dependent thresholds. However, if it is assumed that both mechanisms normally operate simultaneously to determine the rate of inactivation of I Ca,L, then under control conditions, the net effect of sorcin is the sum of both Ca2+-dependent and voltage-dependent inactivation effects. Using this assumption, the effects on Ca2+-dependent inactivation alone can be estimated by subtraction as shown in Table 1 for both sorcin and SCBD. The slowing of inactivation of I Ca,L by sorcin is a consequence of a larger effect on Ca2+-dependant inactivation than voltage-dependent. On inhibition of the SR, the absence of any effect of sorcin on I Ca,L inactivation rate reflects a smaller effect of sorcin on Ca2+-dependent inactivation which balances the effects on voltage-dependent inactivation. Further work is required on the molecular basis of sorcin’s action on LTCC to verify the independent nature of the effects on Ca2+-dependent and voltage-dependent inactivation.
Effect of raising extracellular Ca2+ after SR inhibition
As described above, the absence of any significant effect of sorcin after SR inhibition may be due to a smaller effect of sorcin on Ca2+-dependent inactivation (Table 1). To test this hypothesis, extracellular [Ca2+] was increased after SR inhibition to try and increase Ca2+ influx, restore the cleft Ca2+ signal, and therefore the rate of Ca2+-dependent inactivation. While the rate of inactivation was restored too close to control conditions (Fig. 3c), sorcin had no significant effects The reasons why this manipulation did not restore sorcin’s effects on inactivation is unclear but may be related to complex effects of raising extracellular [Ca2+] on surface charge, as well as current flow [24, 25] and may therefore not replicate the changes in cleft Ca2+ that occur when the SR is functional.
Possible mechanisms of action of sorcin on CDI
Sorcin may modulate Ca2+-dependent inactivation by reducing the transient rise of [Ca2+] in the cleft. This could be achieved by several mechanisms: (1) sorcin may modulate [Ca2+] within the cleft by reducing the open probability of RyR2. However, previous studies have shown that manipulations to reduce RyR2 activity will only cause a transient reduction of SR Ca2+ release; no effects are observed in the steady state as SR Ca2+ content, and consequently, SR Ca2+ release increases back to control values [26]. (2) Ca2+-dependent inactivation may also be slowed by sorcin buffering [Ca2+] in the junctional cleft. Simplistically, this appears unlikely since only an additional 3 µM sorcin was added to the cytosol and concentrations ∼1,000 times this value (i.e., ∼3 mM) or more would be required to buffer cleft Ca2+ sufficiently to slow Ca2+-dependent inactivation. There may be mechanisms to concentrate sorcin within the cleft, and certainly, the expression pattern of sorcin observed in isolated myocytes suggests preferential binding in the T-tubule area [3]. (3) sorcin may reduce the affinity of the Ca2+-binding site on the cytoplasmic domain of the α1C-subunit of the LTCC, but this possibility remains to be investigated.
Possible mechanisms of action of sorcin on VDI
The data concerning the effects of sorcin on voltage-dependent inactivation is similar to that previously reported for I Ca,L currents measured in Xenopus oocytes [7]. In this expression system, Ca2+-dependent inactivation would not be expected to operate, and therefore, the measurements made in the oocyte expression system are comparable to measurements made in adult myocytes with BAPTA or using Ba2+ as a charge carrier. This study is also the first to provide evidence that endogenous sorcin has a tonic effect on the rate of inactivation of I Ca,L. Down-regulation using an RNAi strategy caused a slowing of CII/VDI using BAPTA pipette solutions suggesting a tonic influence of endogenous protein on CII/VDI. It would be anticipated that endogenous sorcin would also affect CDI, but this was not tested in the current study.
The molecular mechanism underlying this effect is unclear; di-hydropyridine (DHP) agonists such as Bay-K-8644 cause enhanced inactivation by a shift in single channel gating in favor of longer single channel open times without alteration to channel amplitude (mode two gating) [27, 28]. Alternatively, stimulation of the β-adrenergic pathway causes a more negative shift in the current–voltage relationship and alters the CII/VDI in a similar fashion to sorcin [29, 29]. This is also thought to be due to a shift in single channel gating to one with longer open times and hence higher open probability [30]. Measurements on single channel currents would provide an insight into sorcin’s molecular mechanisms.
The effect of SCBD
Our data describing the effect of the SCBD on I Ca,L inactivation finds no significant effect when compared to control currents. However, an enhancement of inactivation kinetics is revealed when Ca2+-dependent inactivation is diminished in the presence of BAPTA. The SCBD data suggests that, like the sorcin–RyR2 interaction [20], that with the α-subunit is also via interaction with the C-terminal of sorcin. The lack of the normal N-terminal region appears to enhance the effect of the protein, implying that the N-terminal region may exert a mild inhibitory influence.
Involvement of phosphorylation pathways
Phosphorylation of α1C by CaMKII and PKA are important physiological modulators of I Ca,L, underlying the response to alterations in stimulation rate and β-adrenergic stimulation [24, 31–33]. The current study used the phenomenon of frequency-dependent facilitation (FDF) as an assay for CaMKII activity. Inhibition of CaMKinase II abolished FDF but not the action of sorcin, nor was inhibition of PKA effective in blocking sorcin’s action on the inactivation of I Ca,L. Since these pathways can also act to phosphorylate sorcin directly [9], the data indicates that phosphorylation of sorcin is not an essential step, despite previous reports to the contrary [34].
Physiological role of sorcin within the Ca2+ microdomain
Under physiological conditions, sorcin would be expected to tonically influence Ca2+-dependent inactivation via changes in Ca2+ within the microdomain of the dyadic cleft. This action would be in parallel with the direct influence of Ca2+ on LTCC, the net result of which would be to endow Ca2+-dependent inactivation with an extra degree of cooperation. However, this influence on I Ca,L cannot be considered in isolation since the documented inhibitory action of sorcin on RyR2 [5, 6] and the stimulatory action on NCX [6, 8] will also contribute to the final cleft Ca2+ signal. In doing so, sorcin endows the LTCC, NCX, and RyR2 within the microdomain with a Ca2+-dependence that these proteins would not possess outside this region. This Ca2+-dependence would be dictated by the Ca2+ affinity and kinetics of Ca2+ binding to sorcin in response to the transient nature of the cleft Ca2+ signal. Preliminary data indicate that sorcin levels may be altered in heart failure [35]; this would be anticipated to influence E–C coupling by changing the Ca2+ dependence of LTCC, RyR2, and NCX within the cleft.
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Acknowledgements
The authors would like to thank Aileen Rankin and June Irvine for preparation of cardiomyocytes. This work was funded by the British Heart Foundation (Mark Fowler and Godfrey Smith) and the Deutsche Forschungsgemeinschaft (DFG, grant 1233/7-3 (Gerd Hasenfuß and Tim Seidler); the authors would also like to thank Carlotta Zamparelli and Daniela Verzili for help in generation and purification of recombinant proteins.
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Fowler, M.R., Colotti, G., Chiancone, E. et al. Complex modulation of L-type Ca2+ current inactivation by sorcin in isolated rabbit cardiomyocytes. Pflugers Arch - Eur J Physiol 457, 1049–1060 (2009). https://doi.org/10.1007/s00424-008-0575-5
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DOI: https://doi.org/10.1007/s00424-008-0575-5