Published online Jun 26 2006. doi:10.1085/jgp.200609485
The Rockefeller University Press, 0022-1295 $8.00
JGP, Volume 128, Number 1, 15-36
Regulation of Maximal Open Probability Is a Separable Function of Cavß Subunit in L-type Ca2+ Channel, Dependent on NH2 Terminus of 
1C (Cav1.2)
Nataly Kanevsky and
Nathan Dascal
Department of Physiology and Pharmacology, Sackler School of Medicine, Tel Aviv University, Ramat Aviv 69978, Israel
Correspondence to Nathan Dascal: dascaln{at}post.tau.ac.il
ß subunits (Cavß) increase macroscopic currents of voltage-dependent Ca2+ channels (VDCC) by increasing surface expression and modulating their gating, causing a leftward shift in conductance–voltage (G-V) curve and increasing the maximal open probability, Po,max. In L-type Cav1.2 channels, the Cavß-induced increase in macroscopic current crucially depends on the initial segment of the cytosolic NH2 terminus (NT) of the Cav1.2
(1C) subunit. This segment, which we term the "NT inhibitory (NTI) module," potently inhibits long-NT (cardiac) isoform of 1C that features an initial segment of 46 amino acid residues (aa); removal of NTI module greatly increases macroscopic currents. It is not known whether an NTI module exists in the short-NT (smooth muscle/brain type) 1C isoform with a 16-aa initial segment. We addressed this question, and the molecular mechanism of NTI module action, by expressing subunits of Cav1.2 in Xenopus oocytes. NT deletions and chimeras identified aa 1–20 of the long-NT as necessary and sufficient to perform NTI module functions. Coexpression of ß2b subunit reproducibly modulated function and surface expression of 1C, despite the presence of measurable amounts of an endogenous Cavß in Xenopus oocytes. Coexpressed ß2b increased surface expression of 1C approximately twofold (as demonstrated by two independent immunohistochemical methods), shifted the G-V curve by 
14 mV, and increased Po,max 2.8–3.8-fold. Neither the surface expression of the channel without Cavß nor ß2b-induced increase in surface expression or the shift in G-V curve depended on the presence of the NTI module. In contrast, the increase in Po,max was completely absent in the short-NT isoform and in mutants of long-NT 1C lacking the NTI module. We conclude that regulation of Po,max is a discrete, separable function of Cavß. In Cav1.2, this action of Cavß depends on NT of 1C and is 1C isoform specific.
Abbreviations used in this paper: aa, amino acid; AID, -interaction domain; CT, COOH terminus; HA, hemagglutinin; HEK, human embryonic kidney; NT, NH2 terminus; NTI, NT inhibitory; PM, plasma membrane; Po, open probability; VDCC, voltage-dependent calcium channel; VDI, voltage-dependent inactivation.
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INTRODUCTION
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Voltage-dependent Ca2+ channels are grouped into three families, Cav1–Cav3 (Ertel et al., 2000
). The main structural component of all Cav channels is the 1 subunit that bears the archetypal features of a voltage-dependent channel, with four membrane-spanning domains and a large cytosolic domain comprising the NH2- and COOH-terminal parts of the protein (NT and CT, respectively), and three large intracellular loops, L1–L3, connecting the membrane-spanning domains (Fig. 1 A
). In addition, members of Cav1 and Cav2 families also contain at least two auxiliary subunits, ß (Cavß1–Cavß4) and 2
(Isom et al., 1994; Varadi et al., 1995; De Waard et al., 1996; Birnbaumer et al., 1998; Walker and De Waard, 1998; Striessnig, 1999; Catterall, 2000). The 2 subunit regulates channel expression and trafficking to the plasma membrane (PM) (Shistik et al., 1995; Yasuda et al., 2004; Canti et al., 2005), increases the open probability (Po) of 1C (Shistik et al., 1995), and regulates some pharmacological properties of the channel (De Waard et al., 1996). Cavß subunits are modular MAGUK-type proteins with an SH3-like and a guanylate kinase (GK)-like domain (Chen et al., 2004; McGee et al., 2004; Opatowsky et al., 2004; Van Petegem et al., 2004). The latter binds with high affinity to a conserved AID (-interaction domain) motif within the first intracellular loop (L1) of 1 (Pragnell et al., 1994). The ß subunits profoundly modulate the properties of voltage-dependent Ca2+ channels. The most prominent effect is a great increase in the magnitude of macroscopic Ca2+ currents, caused by the expression of Cavß on top of 1 or 1+2 in most heterologous expression systems (Mori et al., 1991; Singer et al., 1991; Varadi et al., 1991; Williams et al., 1992; Castellano et al., 1993; Lory et al., 1993), or by the expression of Cavß in cardiac cells (Wei et al., 2000; Colecraft et al., 2002). Accordingly, depletion or elimination of endogenous Cavß subunits by knockdown/knockout strategies greatly reduces voltage-dependent Ca2+ currents in various excitable cells (Gregg et al., 1996; Strube et al., 1996; Leuranguer et al., 1998; Namkung et al., 1998; Chu et al., 2004).
Extensive studies in heterologous expression systems revealed a multitude of effects of ß subunits on biosynthesis and gating of VDCCs. First, Cavß increases the surface expression of 1, by improving its trafficking from the ER to the PM (Chien et al., 1995; Brice et al., 1997; Tareilus et al., 1997; Gao et al., 1999), probably by relieving an ER retention signal (Bichet et al., 2000). Second, Cavß regulates several gating properties of VDCCs. The extent of regulation varies among subtypes and isoforms of Cavß and Cav1. The most prominent changes in macroscopic currents include hyperpolarizing (leftward) shifts in current–voltage (I-V) (or conductance–voltage, G-V) and steady-state inactivation curves, an increase in the rate of activation, and changes in the kinetics of voltage-dependent inactivation (for reviews see Birnbaumer et al., 1998; Stotz and Zamponi, 2001; Dolphin, 2003). The shift in G-V curve reflects an improved coupling between gating charge movement and channel opening (Neely et al., 1993, 2004). On the single channel level, coexpression of Cavß increases the open probability, Po, without changing the single channel conductance (Wakamori et al., 1993; Shistik et al., 1995; Costantin et al., 1998).
The overall increase in macroscopic Ca2+ channel currents caused by heterologous expression of Cavß results both from increased surface expression, and from changes in gating that lead to increased Po. Regulation of trafficking by Cavß is clearly separable from modulation of gating; changes in trafficking and gating occur on distinct time and Cavß concentration scales, and mutations that disrupt the high-affinity interaction between AID and Cavß disrupt colocalization of 1 and ß in the PM and membrane targeting of 1, but spare some or all of the ß-induced changes in gating parameters. Thus, the high-affinity binding of Cavß to AID is obligatory for the regulation of trafficking but not gating (Yamaguchi et al., 1998; Canti et al., 1999, 2001; Gerster et al., 1999; Hullin et al., 2003; McGee et al., 2004; Leroy et al., 2005; Maltez et al., 2005). The SH3–GK domain interaction may also play an important role in regulating trafficking (Takahashi et al., 2005). Among gating effects of Cavß, at least one, the regulation of kinetics of voltage-dependent inactivation (VDI), is separable from the others. A palmitoylated isoform of ß2a (usually designated simply as ß2a) decelerates the VDI of several Cav, whereas all other ß subunits, including a nonpalmitoylated isoform of ß2a (np-ß2a of rabbit, and its human orthologue ß2b), accelerate VDI. At the same time, the enhanced trafficking of 1 and the hyperpolarizing shift in G-V curve are independent of palmitoylation of Cavß (Olcese et al., 1994; Chien et al., 1996; Qin et al., 1996, 1998; Gao et al., 1999). The separability of different effects of Cavß implies that they are determined by distinct molecular interactions between different parts of ß and/or 1. Some actions of ß may rely upon low-affinity interactions of ß (the SH3 domain in particular) with regions outside the AID in 1, either in L1 or in the CT in some types of 1 (Tareilus et al., 1997; Walker et al., 1999; Takahashi et al., 2004; Maltez et al., 2005). At present, it is unclear whether gating effects of Cavß other than change in kinetics are also separable, and what is the molecular basis of separate effects of Cavß on different gating parameters.
It is notable that cells most widely used for heterologous expression of Ca2+ channels, Xenopus oocytes and human embryonic kidney (HEK) cells, contain small but measurable amounts of an endogenous Cavß protein that undoubtedly aids the "ß-less" channels to reach the PM (Tareilus et al., 1997; Canti et al., 2001; Leroy et al., 2005). Arguably, the presence of a minimal amount of endogenous Cavß may be obligatory for surface expression of at least some subtypes of Cav1 and Cav2 channels (Tareilus et al., 1997; Leroy et al., 2005). An absence of such endogenous Cavß may explain the reports that in some cell lines transfected with 1C alone or even with 1C+ 2, no functional Ca2+ channel expression is observed (Gao et al., 1999; Harry et al., 2004; Kobrinsky et al., 2004). The presence of the endogenous Cavß, which is permissive for trafficking of 1 to PM, does not impair the ability of coexpressed or exogenously added Cavß protein to modulate the biophysical properties of the channel (Tareilus et al., 1997; Yamaguchi et al., 1998; Garcia et al., 2002). Therefore, it has been proposed that the endogenous ß only "chaperones" 1, helping it to leave the ER without staying with it in the PM; the added exogenous ß then binds to 1 and modulates the gating (the single Cavß-binding model). An alternative multiple Cavß-binding model contends that the endogenous ß remains irreversibly bound to AID, and additional ß subunit(s) modulate channel gating by interacting with other parts of 1 (discussed by Birnbaumer et al., 1998; Jones, 2002; Dolphin, 2003). A recent study that used a ß2b subunit tethered to the end of 1C strongly supports a functional 1:1 1-ß stoichiometry (Dalton et al., 2005); unfortunately, not all functions of ß were fully recovered by the tethered ß, leaving this fundamental issue open for argument.
Unfortunately, the exact extent of regulation of different Cav channels by various Cavß is still debated (discussed in Yasuda et al., 2004), and the contribution of different mechanisms to the increase in whole-cell current has not yet been precisely assessed. The variations are aggravated by apparent inconsistencies between results obtained in different cells and the use of different isoforms of Cav1 and Cavß. To properly understand the molecular principles underlying the different actions of Cavß, one needs to reliably monitor both the surface expression of 1 and a defined set of gating parameters, in a well characterized system. In this report, we implemented such an approach to analyze the mechanism of regulation of Cav1.2 (1C), the L-type channel present in most excitable tissues, by ß2b. The study focused on the parameters of channel activity that lead to changes in the magnitude of the macroscopic Ba2+ current (IBa), leaving the regulation of inactivation out of scope. We have previously found that in the cardiac (long-NT) isoform of 1C, the first 46 aa of the cytosolic NT constitute an NH2-terminal inhibitory (NTI) module whose removal greatly increases the macroscopic current and the Po. The presence of the NTI module is also crucial for ß2b-induced increase in IBa via the long-NT isoform 1C in Xenopus oocytes. We therefore proposed that the ß subunit acts, in part, by functionally counteracting the inhibitory effect of this module (Shistik et al., 1998; Ivanina et al., 2000). Here we demonstrate that the long-NT initial segment selectively regulates a single action of ß2b: the elevation of Po,max. This modulation is absent in deletion mutants lacking the initial NT segment, and in a short-NT isoform of 1C (smooth muscle/brain subtype), in which the initial 46 aa encoded by exon 1a are replaced by a partially homologous stretch of 16 aa encoded by exon 1. Other effects of ß (trafficking, G-V curve shift) are preserved. This is the first report on a discrete regulation by Cavß of Po,max in Cav1.2. These findings bear upon the isoform-specific physiological properties of the L-type Ca2+ channel and upon the physiological role of Cavß in different tissues.
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MATERIALS AND METHODS
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DNA Constructs and mRNA
cDNAs of rabbit heart 1C (X15539), rabbit heart np-ß2a (L06110) (here termed ß2b), skeletal muscle 2-1 (P13806) subunits, and the 1C NH2-terminal truncation mutants 1C
5, 1C20, 1C46, and 1C139 were prepared and used as described previously (Shistik et al., 1998). The mutants 6-20, 21-46, T10A/Y13F/P15A, NTSL, and NTLS chimeras were constructed by standard PCR methods. To create 1C-HA, the hemagglutinin (HA) tag (SRYPYDVPDYA; the first two amino acids SR were added in order to create an XbaI restriction site in the corresponding cDNA sequence) has been inserted into the extracellular loop after the S5 transmembrane segment of 1C-wt, between amino acids Q713 and T714, by two consecutive PCRs. The 21-46-HA and NTLS-HA were then produced by standard subcloning procedures. All mutations and PCR products were verified by nucleotide sequencing at the Tel Aviv University Sequencing Facility.
All cDNA constructs of 1C and mutants were inserted into the same vector, pGEM-HE-GSB (Shistik et al., 1998), which is a derivative of pGEM-HE (Liman et al., 1992). This vector provides the necessary 5' and 3' untranslated regions (UTR) from Xenopus -globin. Therefore, only the coding sequences of all 1C derivatives, without any residual original UTRs, were inserted into the vector. To minimize any variability that may be caused by variations in quality and quantity of RNAs, in each series of experiments all tested RNAs (all mutants of 1C under study and the wt 1C) were synthesized anew on the same day.
Oocyte Culture and Electrophysiology
All the experiments were performed in accordance with the Tel Aviv University Institutional Animal Care and Use Committee (permits no. 11–99-47 and 11–05-064). Xenopus laevis frogs were maintained and operated, and oocytes were collected, defolliculated, and injected with RNA as previously described (Dascal and Lotan, 1992). In brief, female frogs, maintained at 20 ± 2°C on an 11-h light/13-h dark cycle, were anaesthetized in a 0.15% solution of procaine methanesulfonate (MS222), and portions of ovary were removed through a small incision on the abdomen. The incision was sutured, and the animal was returned to a separate tank until it had fully recovered from the anesthesia, and afterwards was returned to a large tank where, together with the other postoperational animals, it was allowed to recover for at least 4 wk until the next surgery. The animals did not show any signs of postoperational distress. The oocytes were injected with the mRNAs of 1C or its mutants, 2, and ß2b, according to the design of experiment (0.3–5 ng for electrophysiology and 2.5–5 ng for imaging). Unless indicated otherwise, equal amounts (by weight) of different RNAs were injected. The oocytes were incubated for 3–5 d at 20–22°C in ND96 solution (96 mM NaCl, 2 mM KCl, 1 mM MgCl2, 1 mM CaCl2, 5 mM HEPES, pH 7.5) supplemented with 2.5 mM Na-pyruvate and 50 µg/ml gentamycin. In some batches with high endogenous chloride currents, oocytes were injected with 25–30 nl/oocyte of the Ca2+ chelator EGTA (50–100 mM), giving a final concentration of 2–5 mM within the oocyte (assuming oocyte's free water volume of 0.5 µl).
Whole cell currents were recorded using the Gene Clamp 500 amplifier (Axon Instruments) using the two-electrode voltage clamp technique, in a solution containing 40 mM Ba(OH)2, 50 mM NaOH, 2 mM KOH, and 5 mM HEPES, titrated to pH 7.5 with methanesulfonic acid (Shistik et al., 1995). Stimulation, data acquisition, and analysis were performed using pCLAMP software (Axon Instruments). Current–voltage (I-V) relation of Ba2+ currents was measured by 60-ms, 10-mV steps given every 10 s from a holding potential of –80 mV. In each cell, the net IBa was obtained by subtraction of the residual currents recorded with the same protocols after applying 200 µM Cd2+.
Immunocytochemistry and Confocal Imaging
Immunocytochemistry in giant PM patches was done essentially as previously described (Singer-Lahat et al., 2000; Peleg et al., 2002), as illustrated in Fig. 3. Oocytes were devitellinized by peeling off the vitelline membrane in ND96, and placed on plastic coverslips (Thermanox plastic coverslip; Nunc). After sticking to the coverslip, the oocyte was removed mechanically and/or by washing with a strong jet of solution. Pieces of membranes strongly attached to the coverslip were continuously washed until the membrane patch became transparent without any visible cytosolic content and pigment granules. After fixation for 10 min in 1% formaldehyde, the membranes were washed three times with 1% BSA dissolved in TBS solution (135 mM NaCl, 10 mM Tris-HCl, pH 7.4). Blocking of nonspecific binding sites was done with donkey immunoglobulin G (IgG, whole molecule, 1/200, Jackson ImmunoResearch Laboratories) for 30 min. Each coverslip was incubated for 1 h with CT4 antibody against 1C COOH terminus (1:500; provided by M. Hosey, Northwestern University, Chicago, IL; see Gao et al., 2001) or against L2 (1:500; Alomone Labs.). Residual antibody was washed out with 1% BSA three times, 5 min each. This was followed by a 30-min incubation with secondary antibody (Cy3 donkey anti–rabbit IgG, 1:400; Jackson ImmunoResearch Laboratories). Free secondary antibody was then washed out with 1% BSA three times, 5 min each in darkness and the coverslips were mounted on a glass slide. The fluorescent labeling was examined by a confocal laser scanning microscope (LSM 410 or LSM 510, Zeiss, Germany). 40x NA/1.2 C-apochromat water-immersion lens (Axiovert 135 M, Zeiss) was used for imaging. The Cy3-conjugated secondary antibody was excited at 488 nm and the emitted light at >568 nm was collected. The fluorescent signals were analyzed by measuring total luminosity (optical density) of the whole image using the Tina 2.1 (Raytest Isotopenmelgerilte GmbH) or Carl Zeiss MicroImaging, Inc. LSM5 software. In all confocal imaging procedures, care was taken to completely avoid saturation of the signal. The gain of the photomultiplier was kept <75% of maximum. In each experiment, all oocytes from the different groups were studied using a constant set of imaging parameters. The normalized intensities were always calculated relative to the control group of the same experiment. Net fluorescence intensity per unit area was obtained by subtracting an averaged background signal measured in the same way in membranes of native (uninjected) oocytes from the same batch.
Immunocytochemistry and imaging of whole oocytes has been done as follows. 3–4 d after the injection of RNA, the oocytes were fixated in 4% formaldehyde (37%) in Ca-free ND96 solution for 15 min. Blocking of nonspecific binding sites was done by 5% skim milk for 1 h. Then the oocytes were incubated for 1 h with the mouse monoclonal IgG2a antibody against HA (Santa Cruz Biotechnology), diluted 1:400 in 2.5% skim milk. Residual antibody was washed out with 2.5% skim milk three times, 5 min each. This was followed by 1 h incubation with the secondary antibody (Alexa-conjugated anti–mouse IgG, 1:400; Jackson ImmunoResearch Laboratories) in dark. Free secondary antibody was then washed out with Ca-free ND96. Oocytes were placed in a chamber with a transparent bottom, and fluorescence imaging of optical slices was performed with LSM 510 (x20 objective, zoom = 1, pinhole 3 Airy units). Alexa was excited at 594 nm and the emitted light was collected using long-pass (LP) 615-nm filter. The fluorescent signals were usually analyzed as described in Fig. 4 D. Alternatively, the intensity of fluorescence in the PM was measured by averaging the signal obtained from six standard circular regions of interest. Net fluorescence intensity per unit area was obtained by subtracting the background signal measured in native oocytes.
Data Analysis
Current–voltage (I-V) curve was fitted to the Boltzmann equation in the form
 | (1) |
where Ka is the slope factor, V1/2 is the voltage that causes half maximal activation, Gmax is the maximal macroscopic conductance, Vm is membrane voltage, IBa is the current measured at the same voltage, and Vrev is the reversal potential of IBa. The obtained parameters of Gmax and Vrev were then used to calculate fractional conductance at each Vm, G/Gmax, using the equation
 | (2) |
where G is the total macroscopic conductance at Vm. The conductance–voltage (G-V) curves were plotted with the values of V1/2 and Ka obtained from the fit of the I-V curves, using the following form of the Boltzmann equation:
 | (3) |
The results were summarized from many groups of oocytes from different donors ("batches"). To avoid series resistance artifacts associated with very large currents (Schreibmayer et al., 1994), or inaccuracies resulting from a contribution from the small endogenous oocyte's Ca2+, Cl–, or K+ channel currents when the macroscopic IBa was low (mainly in oocytes expressing 1C+ 2 without ß2b; Dascal, 1987; Dascal et al., 1992), these quantitative analyses were performed only in experiments in which, at the peak of the I-V curve, 0.1 µA 
IBa 6 µA.
The calculation of changes in Po,max was based on the following considerations. The total macroscopic conductance, estimated by measuring peak currents at different voltages, is a linear function of Po:
 | (4) |
where 
is the single channel conductance, and N is the total number of functional channels in the PM (Hille, 2002). In Cav channels, Po is voltage dependent whereas and N are not. Po reaches a maximal value, Po,max, at positive voltages where a maximal macroscopic conductance, Gmax, is attained. Both Gmax and Po,max are empirical parameters that are considered voltage independent and are interrelated as follows:
 | (5) |
The fold change in N caused by a treatment, RN, is defined as Ntreatment/Ncontrol. From here, if is constant, the change in Po,max caused by a treatment is given by
 | (6) |
In this study, RN was monitored by imaging measurements in giant PM patches or in whole oocytes. Eq. 6 is similar to those used previously (Wei et al., 1994; Takahashi et al., 2004) to assess changes in Po; in these studies, RN was estimated from the measurement of Qmax (the maximal gating charge).
To compare parameters (I40, surface 1C labeling, or Gmax) observed or calculated in oocytes of different batches, data from individual cells were averaged across batches using the following normalization procedure (Sharon et al., 1997). The value of the parameter in each cell was normalized to the mean value of this parameter in the control group of the same batch. This procedure was also applied to the cells of the control group, thus providing a useful measure of variability in this group and enabling an accurate statistical analysis. Normalized values were then averaged from all cells across all batches. The results are presented as means ± SEM Multiple group comparisons were done by one-way analysis of variance (ANOVA) test followed by Tukey's test. Two-group comparisons were done using Student's t test.
Online Supplemental Material
Table S1 (available at http://www.jgp.org/cgi/content/full/jgp.200609485/DC1) shows the mean values of Gmax and Vrev obtained in Boltzmann equation fits for some of the 1C constructs used in this study.
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RESULTS
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Mapping the Part of NT Crucial for the Regulation of Gmax
Deletions of initial segment of long-NT 1C increase the amplitude of IBa but attenuate the current enhancement caused by Cavß. It is not known if the same structural elements of NT alter both macroscopic currents and modulation by Cavß. To address this problem, we sought to delineate the regions that are important for these modulations. Fig. 1 B shows the protein sequences of the NH2-terminal part of long-NT and short-NT isoforms of rabbit and human 1C (the corresponding sequences in rat and mouse are also highly homologous; see Blumenstein et al., 2002). The cytosolic NT consists of 124 (short-NT) or 154 aa (long-NT), which are the products of transcription of alternative initial exons 1 or 1a, respectively, and an invariable exon 2 encoding 108 aa. Amino acids 6–20 of the long-NT show partial homology with the first 16 aa of the short-NT (Shistik et al., 1998); in particular, the amino acids T10, Y13, and P15 (which we call TxxYxP motif; numbering by long-NT) are conserved in both isoforms (Fig. 1 B, gray boxes). In the previous studies, we have created several NT deletion mutants of rabbit cardiac long-NT 1C. The logic of these deletions was dictated by the comparison of nucleotide sequences of long- and short-NT isoforms. Initially, we deleted amino acid stretches from the first methionine up to the positions corresponding to the boundaries of the region of partial homology (mutants 1C5 and 1C20), and then up to the beginning of the high homology region (1C46). We also deleted almost all of the cytosolic part of the NT (1C139). In the previous studies, only 1C46 and 1C139 have been characterized in detail; voltage-dependent characteristics, protein expression levels, and the effect of ß subunit have not been compared systematically in most mutants. Such a comparative study has been done in the experiments described below. In addition, we have deleted the region of partial homology with short-NT 1C, aa 6–20, from long-NT 1C (mutant 1C6-20). We also mutated the TxxYxP motif, creating the T10A/Y13F/P15A (1CTYP) mutant.
To delineate the region of long-NT that regulates the magnitude of IBa, either long-NT wild-type 1C (1C-wt) or the various NT deletion mutants were expressed without Cavß. The expression of 1C-wt alone in Xenopus oocytes results in very small (a few nA) Ba2+ currents that are difficult to reliably resolve and analyze, and often difficult to separate from currents via oocyte's endogenous Cav channels, which are non–L type (Singer et al., 1991; Dascal et al., 1992; Singer-Lahat et al., 1994). Therefore, 2 was coexpressed in all experiments. The latter greatly increases IBa compared with 1C-wt alone, but does not increase the current via the endogenous channels. 2 aids trafficking 1C to the PM (Shistik et al., 1995; Yasuda et al., 2004; Canti et al., 2005) and produces certain synergistic (more than additive) effects with some ß subunits (Singer et al., 1991; Yamaguchi et al., 2000), but most of the actions of ß2b are similar in the presence or absence of 2 (see Table IV). In oocytes expressing 1C+2 or 1C+2+ß2b, the contribution of endogenous channels to IBa was negligible; IBa was reduced by >95% by 10 µM of the dihydropyridine L-type Ca2+ channel blockers nitrendipine and nifedipine (Singer-Lahat et al., 1994; unpublished data).
Fig. 2 A
shows the routine experimental protocol used to analyze the I-V characteristic of the expressed channels. Ca2+ channel currents were elicited by 60-ms depolarizing pulses from a holding potential of –80 mV, in 10-mV steps, in a solution containing 40 mM Ba2+ using the two-electrode voltage clamp technique. Net IBa was obtained by subtracting currents elicited by the same voltage protocol in the presence of 200 µM CdCl2 (Fig. 2 A, left). The absolute amplitude of IBa depended on the amount of RNA injected, period of incubation, and also varied among oocyte batches. The amount of the injected RNA (of both 1C-wt and 2) varied in our experiments between 1 and 5 ng/oocyte, depending on the experimental design. In this range, greater amounts of RNA always resulted in larger IBa. The right panel of Fig. 2 A shows a typical I-V curve of net IBa, averaged from six oocytes of the same batch (donor frog). Without Cavß, IBa was maximal at 30 mV. In the following, to compare IBa across different groups and treatments, we chose to use the value of IBa measured at +40 mV (I40) rather than at the peak of the I-V curve, because the latter varied between different treatments. Also, at +40 mV, the whole-cell Ba2+ conductance is close to maximum under most conditions (Figs. 2 and 4), therefore changes in I40 should approximately reflect changes in Gmax.
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Figure 2. Effects of NH2-terminal deletions and T10A/Y13F/P15A mutation on IBa in the absence of Cavß (the 1C2 subunit composition). (A) The standard procedure used to monitor IBa, and an averaged I-V curve. See explanations in the text. (B) Comparison of IBa in 1C-wt and 1C5 (2.5 ng RNA/oocyte of each subunit). Panel a shows representative current traces recorded at +40 mV in oocytes of one batch (donor). A current trace obtained in an oocyte expressing the 146 mutant is shown for comparison. Panel b shows averaged I-V curves from 1C-wt and 15 groups (n = 9 oocytes, N = 2 batches). The normalized values of I40 are shown in panel c. (C) Panel a shows the summary of relative I40 in the various mutants. I40 in each oocyte was normalized to the average I40 of 1C-wt of the same batch, as explained in Materials and Methods. Panels b and c show normalized I-V and G-V curves, respectively, of the indicated channel constructs, averaged from oocytes of two representative batches (n = 8–14, N = 2). Amount of injected RNA was varied from 0.3 ng/oocyte in NT mutants to 5 ng/oocyte in 1-wt to reach comparable IBa amplitudes in order to minimize the fitting artifacts. Note that Boltzmann fits have been performed separately in each oocyte. For illustration purposes, in averaged I-V and G-V curves shown in C and in the following figures, the solid lines through averaged experimental points were drawn using Boltzmann equation with values of V1/2 and Ka from Table I. In this and the following figures, the numbers above bars indicate the number of cells tested, and asterisks indicate statistically significant differences, as follows: *, P < 0.05; **, P < 0.01; ***, P < 0.001.
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As reported previously (Shistik et al., 1999), in the 1C5 mutant, I40 increased about twofold compared with 1C-wt, without any significant change in the voltage dependence of activation (Fig. 2 B). The calculated increase in Gmax in the 1C5 mutant was 66% (Table II). In comparison, the deletion of 20 or more aa of the long-NT initial segment caused a robust seven to ninefold increase in I40 and in the calculated Gmax (Fig. 2, Ba and Ca, and Table II). For a summary of the absolute values of Gmax in the different groups, injected with the same RNA amount of 1 ng/oocyte, see Table S1 (available at http://www.jgp.org/cgi/content/full/jgp.200609485/DC1).
As reported earlier (Wei et al., 1996; Shistik et al., 1998), the I-V curves in 1C46 and 1C139 appeared similar to 1C-wt. However, an exhaustive comparison of a large amount of records revealed a small hyperpolarizing shift caused by the NT deletions, as illustrated in normalized averaged I-V curves (Fig. 2 Cb). To assure that the shift was not an artifact resulting form a larger current amplitude in the NT deletion mutants, in two batches (14–16 oocytes) oocytes were injected with amounts of RNA adjusted to produce IBa of similar amplitude in 1C-wt, 1C46, and 1C20. The I-V curve shift was observed in all cases. Fitting I-V curves to Boltzmann equation (solid lines in Fig. 2 Cb) indicated a statistically significant 5–7 mV shift in the half activation voltage, V1/2, in all NT deletion mutants studied except 1C5 (Table I
). The leftward shift in the G-V curves is more clearly seen in conductance–voltage (G-V) curves that were drawn through the data points using the Boltzmann equation parameters obtained in I-V curve fits (Fig. 2 Cc). In addition, the slope appears to be increased by the NT deletions. Indeed, the slope factor Ka was slightly but statistically significantly reduced, from 9.6 mV in 1C-wt to 7.9 mV in most mutants (Table I). None of the mutations caused any changes in the reversal potential of IBa (see Table S1).
The robust increase in IBa and the shift in G-V curve were also observed in the 1C6-20 mutant lacking the 16 aa of the partial homology region. Mutation of the conserved TxxYxP motif produced similar but milder changes (Fig. 2 and Table I). The changes in Gmax (calculated from the Boltzmann fits) were similar to changes in the measured I40 (Table II). Taken together, these data imply that amino acids 6–20 of the long-NT isoform constitute a crucial part of the NTI module. The increase in IBa and in Gmax is accompanied by a moderate hyperpolarizing shift in the G-V curve; this effect is also fully dependent on the presence of the same 16 aa. The T10A/Y13F/P15A mutation interferes with the function of the NTI module by a mechanism yet to be determined.
Previously, controversial results have been reported regarding the surface expression of 1C with NT deletions of 40 aa or more from a long-NT 1C, expressed in Xenopus oocytes. Wei et al. (1996) reported an approximately sixfold increase in surface expression on the basis of measurements of Qmax in cut-open oocytes. In contrast, we did not observe any changes in surface expression in 1C46 either by counting channels in cell-attached patches, or by immunoprecipitating 1C from manually separated plasma membranes (Shistik et al., 1998). Here we confirm these results by an independent imaging method (Singer-Lahat et al., 2000; Peleg et al., 2002). Proteins expressed in the PM were visualized by immunostaining in giant membrane patches in which the cytosolic surface of the PM is exposed to external solution (Fig. 3 A
). The membrane protein in the patch is labeled with an antibody against a cytosolic segment, then with a fluorescently labeled secondary antibody, and visualized using a confocal microscope (see Materials and Methods for details). The image captures a randomly selected 105 x 105 µm area within a (larger) patch. The large size of the imaged area ensures a fair averaging of channel density even if the channels are clustered. Patches from many tens of oocytes can be screened during a 1-d experiment, providing statistically reliable data. This is a big advantage over the previously employed method of immunoprecipitation of 1C from manually separated PM of metabolically labeled oocytes (Shistik et al., 1995, 1998), which produced one experimental point for 20–30 whole-oocyte membranes.
Fig. 3 B shows images of representative membrane patches from oocytes of one batch expressing 1C-wt or various NT mutants of 1C without the ß subunit. The antibody labeling was clearly detected in all channel constructs, and no significant labeling was observed in uninjected oocytes at these imaging parameters. The data from two oocyte batches are summarized in Fig. 3 Ca, showing that there were no significant differences in the expression of any of the channel variants tested. This result was reproduced later in a separate series of experiments (see Fig. 4, A and B
) and also using an alternative imaging method (see Fig. 7 C). At the same time, IBa measured in oocytes of one of these two batches was enhanced by the NT mutations, as usual (Fig. 3 Cb). We conclude that physical or functional removal of the NTI module of the long NH2 terminus does not alter the surface expression of 1C. Since the single channel conductance is not changed either (Shistik et al., 1998), all of the increase in Gmax caused by these mutations must result from an increase in Po,max. Indeed, calculations using Eq. 6 show that all these mutations cause a greater than sixfold increase in Po,max (Table II), except 1C5, which shows only a 37% increase. The increase in I40 was essentially identical (Table II).
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Figure 4. Coexpression of ß2b increases the surface expression of 1C-wt and of NT mutants. (A) Examples of confocal images of 1C-wt, 1C46, 1C20, and 1CTYP in giant PM patches, in absence and presence of ß2b subunit. (B) Surface expression of the mutant proteins in 12 subunit composition, without ß2b, normalized to 1C-wt. This series of experiments included two oocyte batches and was separate from that shown in Fig. 3. Injected RNA was 5 ng/oocyte. (C) Summary of the effects of ß2b on the surface expression of 1C mutants. For each construct, the surface expression in the presence of ß2b was normalized to the average expression measured without ß2b. (D) The effect of ß2b on surface expression of 1C-HA; panel a shows representative confocal images of whole oocytes, either native (uninjected) or expressing 1C-HA + 2/ ("1C-HA") or 1C-HA + 2/ + ß2b ("1C-HA+ß2b"). Injected RNA was 5 ng/oocyte. The dimensions of the image are 0.45 x 0.45 mm. The rightmost image exemplifies the method used to analyze the intensity of fluorescent labeling. A rectangle of a fixed width was superimposed on the image, and a profile of optical density (shown in b) along the axis approximately perpendicular to the PM (arrow) was obtained using the TINA software. (Optical density and distance were measured in arbitrary units inherent to the software). (b) Quantitative analysis of optical density profiles. The intensity was defined as the integral of the shaded area. The width of this area was defined as constant for all images taken in an experiment. The net intensity in each 1C-HA–expressing oocyte was calculated by subtracting the average intensity measured in uninjected oocytes of the same experiment, and then normalized to the average net intensity of [1C-HA+2/]-expressing oocytes of this experiment. The normalized values, shown in c, were summarized across all experiments (N = 3).
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Regulation by ß2b Subunit of Po,max, But Not of Other Parameters, Depends on NT of 1C
We used the nonpalmitoylated np-ß2a (Hullin et al., 1992), which is the rabbit orthologue of human ß2b (96% identity), the most abundant cardiac ß subunit in rat and humans (Colecraft et al., 2002; Hullin et al., 2003). To avoid confusion between palmitoylated and nonpalmitoylated forms of ß2a, we refer to np-ß2a as ß2b. Unlike the palmitoylated splice variant isoform (ß2a) of the same gene, ß2b does not slow down the VDI and does not reside in PM in the absence of 1C (Olcese et al., 1994; Chien et al., 1998). When expressed in Xenopus oocytes, ß2b accelerates the VDI of Cav1.2, and in addition causes a robust increase in the whole-cell current and affects all gating parameters (Hullin et al., 1992; Shistik et al., 1995). However, it is not clear whether coexpression of either ß2a or ß2b improves the trafficking of 1C to the PM in Xenopus oocytes. No change (Neely et al., 1993, 2004) or a mild 50% increase (Shistik et al., 1995) have been reported (see Table IV and Discussion).
Using the imaging method shown in Fig. 3, we have examined the effect of coexpression of ß2b on the amount of 1C-wt, 1C20, 1C46, and 1CTYP in two to four batches of oocytes; 2 was always coexpressed (Fig. 4). As before, in the absence of Cavß, the surface expression of NT mutants was similar to that of 1C-wt (Fig. 4, A and B). In contrast, ß2b induced a mild but reproducible and statistically significant 70% increase (P < 0.001) in the surface expression in all 1C constructs (Fig. 4, A and C).
The effect of ß2b on surface expression of 1C was additionally verified using an independent method, using a modified 1C (termed 1C-HA) with an extracellular HA tag inserted in the extracellular loop following the S5 segment of domain I. A similar construct was previously used to study the trafficking of 1C in mammalian cells (Altier et al., 2002). Ba2+ currents via channels formed by 1C-HA, coexpressed with 2/ with or without ß2b, did not differ in amplitude or voltage dependency from 1C-wt (unpublished data; Table I). Surface expression of the HA label was measured using a confocal microscope in whole intact oocytes fixated with formaldehyde and treated with an anti-HA antibody and a secondary antibody conjugated to a fluorescent dye (Fig. 4 D). As shown in Fig. 4 Da, the expression of ß2b caused a clear increase in surface expression of 1C-HA. The results were quantified as explained in Fig. 4 legend, and showed a 2.09 ± 0.34-fold increase in the intensity of fluorescence caused by ß2b (Fig. 4 Dc). This estimate, though somewhat higher than by measuring the effect of ß2b in giant PM patches, was not significantly different when compared in the same oocyte batch (not depicted). These results unequivocally demonstrate that, despite the theoretical possibility that some of the fluorescent signal in the giant membrane patches arises from 1C found in submembrane ER, the latter method provides a realistic estimate of 1C levels in the PM. We conclude that, despite the presence of an endogenous Cavß in the oocytes, the expressed ß2b further increases the surface expression of Cav1.2 channels about twofold (in the presence of 2). The ability of ß2b to do so is not affected by the elimination of the NTI module.
Coexpression of ß2b also increased the macroscopic currents in wt and all NT mutants. Examples are shown in Fig. 5 A
for 1C-wt and 1C46. Note that ß2b accelerated the inactivation kinetics in both cases, despite the fact that without Cavß, they were already faster in 1C46 than in 1C-wt. This was a recurrent result in most mutants (unpublished data). Thus, although VDI is out of the scope of this paper, and although it is clear that the NH2 terminus itself plays a role in VDI (see also Shistik et al., 1998; Kobrinsky et al., 2004), we construe that the elimination of the NTI module does not impair the ability of ß2b to speed up the VDI.
The I-V curves of all 1C mutants, and of the 1C-wt, were shifted to the left by coexpression of ß2b. Examples of averaged I-V curves of oocytes from representative batches are shown in Fig. 5 B, and a full summary of normalized I-V and G-V curves averaged from all oocytes is presented in Fig. 5 (C and D). The hyperpolarizing shift produced by ß2b is observed both in 1C-wt and in all mutants lacking the NTI module. A closer examination of the results of Boltzmann fits in Table I reveals that the net change in V1/2 and Ka parameters caused by ß2b in 1C-wt (14 and 2.4 mV, respectively) was somewhat greater than in some of the NT mutants (11–13 and 1.5–2 mV). However, these differences are small and may be within the experimental or fitting error. In all, we conclude that elimination of NT inhibitory module does not impair the ability of ß2b to cause a hyperpolarizing shift in the voltage dependency of channel activation.
In contrast to parameters considered so far, the extent of increase in IBa and in Gmax caused by coexpression of ß2b was altered dramatically by NT mutations (Figs. 5 B, Fig. 6
, and Table III).
In agreement with previous reports regarding 1C20, 1C46, and 1C139 (Shistik et al., 1998, 1999), all mutations that impaired the function of the NTI module also greatly reduced the ability of ß2b to increase IBa (Fig. 6, A and B). The differences were more pronounced at less positive potentials, because at least part of the increase in IBa at these potentials is due to the leftward shift in the I-V curve, as illustrated in Fig. 6 A for some of the mutants. However, even at +40 mV, the difference between 1C-wt and the various mutants is still very substantial (Fig. 6 B). The ß2b-induced increase in the calculated Gmax, which in 1C-wt was 4.65 ± 0.39-fold, was diminished to only 1.92 ± 0.23-fold in 1C46 (P < 0.01; Table III). A similar, though slightly milder, reduction was observed in 1C20 and 1CTYP (Table III). The only outlier is 1C5. The ß2b-induced change in I40 was even greater in this mutant than in 1C-wt, as measured in two batches of oocytes (Fig. 6 C). This is at odds with a previous observation (Fig. 2 F in Shistik et al., 1999), but a comprehensive investigation into the reasons of controversy is not possible, because in the experiment reported in 1999, the effect of ß2b was studied only marginally (Shistik et al., 1999); IBa was measured only at +10 mV, and no analysis of voltage dependency has been performed. Thus, dose-dependent or batch-dependent effects of ß2b on 1C5 cannot be excluded at present.
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Figure 6. The NTI module regulates the effect of ß2b subunit. (A) The increase in IBa caused by coexpression of ß2b (relative to currents observed in the same 1C constructs without ß2b) is much smaller in NT deletion mutants than in 1C-wt, at all voltages. Shown are results of two representative experiments (n = 10–18). (B) A general summary of the effect of coexpression of ß2b. Shown is the fold increase in relative I40 in the various constructs; numbers of assayed cells are indicated above the bars. N = 2–7 experiments. (C) The increase in IBa ca | |
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ABSTRACT
INTRODUCTION
