Identification of an Integration Center for Cross-talk between Protein Kinase C and G Protein Modulation of N-type Calcium Channels*

Jawed HamidDagger , Donald Nelson§, Renee SpaetgensDagger , Stefan J. Dubel§, Terry P. Snutch§parallel , and Gerald W. ZamponiDagger **

From the Dagger  Department of Pharmacology and Therapeutics, Neuroscience Research Group, University of Calgary, Calgary, Alberta T2N 4N1, Canada and the § Biotechnology Laboratory, University of British Columbia, Vancouver, British Columbia, V6T 1Z3 Canada

    ABSTRACT
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Abstract
Introduction
References

The modulation of presynaptic calcium channel activity by second messengers provides a fine tuning mechanism for neurotransmitter release. In neurons, the activation of certain G protein-coupled receptors reduces N-type channel activity by ~60%. In contrast, activation of protein kinase C (PKC) results in an approximately 50% increase in N-type channel activity, and subsequent G protein inhibition is antagonized. Here, we describe the molecular determinants that control the dual effects of PKC-dependent phosphorylation. The double substitution of two adjacent PKC consensus sites in the calcium channel domain I-II linker (Thr422, Ser425) to alanines abolished both PKC-dependent up-regulation and the PKC-G protein cross-talk. The single substitution of Ser425 to glutamic acid abolished PKC up-regulation but had no effect on G protein modulation. Replacement of Thr422 with glutamic acid eliminated PKC-dependent up-regulation and mimicked the effects of PKC phosphorylation on G protein inhibition. Our data suggest that Thr422 mediates the antagonistic effect of PKC on G protein modulation, while phosphorylation of either Thr422 or Ser425 are sufficient to increase N-type channel activity. Thus, Thr422 serves as a molecular switch by which PKC is able to simultaneously trigger the up-regulation of channel activity and antagonize G protein inhibition.

    INTRODUCTION
Top
Abstract
Introduction
References

Calcium influx through neuronal voltage-dependent calcium channels mediates a range of cytoplasmic responses, such as neurotransmitter release, proliferation, and the activation of calcium-dependent enzymes. Most neurons express multiple calcium channel types with distinct functional properties, and molecular cloning has identified genes encoding at least eight different neuronal calcium channel alpha 1 subunits (termed alpha 1A through alpha 1H). Functional expression in heterologous expression systems has revealed that alpha 1A encodes for P/Q-type calcium channels (1-3); alpha 1B defines an omega -conotoxin GVIA-sensitive N-type channel (4-6); alpha 1C, alpha 1D and alpha 1F are L-type calcium channels (7-9); and alpha 1E is a unique calcium channel with properties common to both high threshold and low threshold calcium channels (10, 11). More recently, alpha 1G and alpha 1H have been shown to encode members of the family of T-type calcium channels (12). Among the eight types of alpha 1 subunits, alpha 1A and alpha 1B are predominantly located at more distal dendritic and presynaptic nerve terminals (13, 14) and are directly coupled to the presynaptic vesicle release machinery (15, 16).

The physiological properties of presynaptic calcium channels are extensively modulated by second messenger molecules, including protein kinase C and G protein beta gamma subunits (17-21). The activation of certain G protein-coupled seven-helix transmembrane receptors mediates a pronounced voltage-dependent inhibition of both N-type and P/Q-type calcium currents (Refs. 22-25; for a review, see Ref. 26). This inhibition is probably caused by direct 1:1 binding of G protein beta gamma subunits to the calcium channel alpha 1 subunit, resulting in a reluctance of the channels to undergo opening in response to membrane depolarization (27, 28). In contrast, stimulation of protein kinase C-dependent phosphorylation results in a substantial up-regulation of N-type channel activity (19). PKC1 and Gbeta gamma modulation are functionally coupled (termed cross-talk), such that PKC-dependent phosphorylation of the channel antagonizes subsequent G protein inhibition (20, 21, 29).

We have previously shown that cross-talk between G protein and PKC pathways mainly occurs at the level of the calcium channel alpha 1 subunit (29). In particular, the cytoplasmic linker connecting domains I and II of the alpha 1B subunit is a crucial determinant of both G protein inhibition and PKC-G protein cross-talk. This region has also been implicated in PKC-dependent up-regulation of N-type calcium channels (19), suggesting the possibility of a common mechanism underlying the dual effects of protein kinase C-dependent phosphorylation. Here, we identify individual amino acid residues within the alpha 1B domain I-II linker that mediate up-regulation by PKC-dependent phosphorylation as well as the cross-talk between PKC and G protein pathways. Using site-directed mutagenesis in combination with functional expression in human embryonic kidney cells, we show that phosphorylation of either threonine 422 or serine 425 is sufficient to mediate PKC-dependent up-regulation of the channel. Whereas the nature of serine 425 does not affect G protein inhibition, substitution of the threonine residue to glutamic acid to create a permanent phosphoform drastically reduces the degree of G protein inhibition. We propose a model whereby threonine 422 acts as a molecular switch by which protein kinase C up-regulates the activity of N-type calcium channels and concomitantly antagonizes their inhibition by G protein beta gamma subunits. The remaining (~20%) degree of G protein inhibition is further reduced upon deletion of the 3' third of the alpha 1B carboxyl terminus, suggesting that the calcium channel domain I-II linker and the carboxyl terminus might cooperatively interact with G protein beta gamma subunits.

    MATERIALS AND METHODS

Molecular Biology-- DNA encoding wild type alpha 1B channels was subcloned into the cytomegalovirus expression vector. The alpha 1B-cytomegalovirus construct was cut with SpeI and SplI, and the SpeI-SplI fragment was then subcloned into a modified pSL1180 Bluescript vector (which had been cut with StuI and SmaI and recircularized to eliminate a Kpn2I site in the polylinker). A Kpn2I fragment was excised from this construct and subcloned into a modified pSL1180 vector (in which a NarI-NarI fragment was deleted). Site-directed mutagenesis of PKC consensus sites was carried out on this construct using the Quick Change site-directed mutagenesis kit (Stratagene). The mutations were confirmed via DNA sequencing. The Kpn2I fragment was subsequently subcloned into the SpeI-SplI construct in pSL1180, and the SpeI-SplI fragment was ligated into the full-length alpha 1B construct in cytomegalovirus. After completion of subcloning, the 900-base pair Kpn2I fragment contained in the full-length sequence was completely sequenced to confirm the presence of the mutations and to eliminate the possibility of cloning and polymerase chain reaction artifacts.

A carboxyl-terminal deletion mutant lacking amino acid residues 1955-2336 was constructed by eliminating an XbaI fragment contained between an XbaI site in the alpha 1B carboxyl terminus and a second XbaI site in the 3' portion of the polylinker of the cytomegalovirus expression vector. The construct was cut with XbaI and recircularized, and the successful elimination of the XbaI fragment was confirmed via enzyme analysis and DNA sequencing.

Transient Transfection-- Human embryonic kidney TSA 201 cells were grown in standard Dulbecco's modified Eagle's medium, supplemented with 10% fetal bovine serum and 0.4 mg/ml neomycin. The cells were grown to 85% confluency, split with trypsin EDTA, and plated on glass coverslips at 10% confluency 12 h prior to transfection. Immediately prior to transfection, the medium was replaced, and the cells were transiently transfected with cDNAs encoding for calcium channel alpha 1B, beta 1b, and alpha 2 subunits (at a 1:1:1 molar ratio) using a standard calcium phosphate protocol. After 12 h, the medium was replaced with fresh Dulbecco's modified Eagle's medium, and the cells were allowed to recover for 12 h. Subsequently, the cells were incubated at 28 °C in 5% CO2 for 1-2 days prior to recording.

Electrophysiology-- Immediately prior to recording, individual coverslips were transferred to a 3-cm culture dish containing recording solution composed of 20 mM BaCl2, 1 mM MgCl2, 10 mM HEPES, 40 mM triethanolamine chloride, 10 mM glucose, 65 mM CsCl (pH 7.2). Whole cell patch clamp recordings were performed using an Axopatch 200B amplifier (Axon Instruments, Foster City, CA) linked to a personal computer equipped with pCLAMP version 6.0. Patch pipettes (Sutter borosilicate glass; BF150-86-15) were pulled using a Sutter P-87 microelectrode puller, fire-polished using a Narashige microforge, and showed typical resistances of 2-3 megaohms. The internal pipette solution contained 105 mM CsCl, 25 mM triethanolamine chloride, 1 mM CaCl2, 11 mM EGTA, 10 mM HEPES (pH 7.2), supplemented with nystatin. Nystatin was dissolved in Me2SO at 100 mg/ml and diluted directly into the pipette solution. After seal formation, nystatin was allowed to equilibrate into the patch for 5-10 min to permit electrical access.

Currents were typically elicited from a holding potential of -100 mV to various test potentials using Clampex software (Axon Instruments). Current-voltage relations were generated by utilizing a ramp protocol (dV/dt = 1 mV/ms) as reported previously (30). Somatostatin (RBI Chemicals) was dissolved in water to give a stock solution of 1 mM, and PMA (RBI) was dissolved in Me2SO at a stock concentration of 2 mM. These compounds were diluted into the external recording solution at the appropriate final concentrations and perfused directly onto the cell using a gravity-driven microperfusion system. At the applicable concentrations, Me2SO by itself had no effect on calcium channel activity. In every case, peak current inhibition was assessed 15 s after somatostatin application. Data were filtered at 1 kHz and recorded directly onto the hard drive of the computer. Data were analyzed using Clampfit (Axon Instruments). All curve fitting was carried out in Sigmaplot 4.0 (Jandel Scientific). Unless stated otherwise, all error bars represent S.E. values, numbers in parentheses displayed in the figures reflect numbers of experiments, and p values given reflect Student's t tests.

    RESULTS

The Domain I-II Linker Mediates both PKC and G Protein Modulatory Effects on N-type Channels-- We have previously shown that N-type (alpha 1B + alpha 2delta  + beta 1b) calcium channels transiently expressed in human embryonic kidney cells are reversibly inhibited by 50-70% via activation of endogenous somatostatin receptors (Ref. 29; see Fig. 1C). In contrast, activation of protein kinase C with 100-400 nM of the phorbol ester PMA results in a pronounced (50-60%) up-regulation of alpha 1B N-type currents (Ref. 29; see Fig. 1D). Subsequent to PMA treatment, inhibition of N-type channel activity by somatostatin is dramatically reduced (see Fig. 1D), consistent with previous observations in intact neurons (20, 21). Synthetic peptides directed against two subregions of the alpha 1B calcium channel domain I-II linker block the modulatory effects of exogenously applied Gbeta gamma subunits (29). One of the peptides is a substrate for in vitro phosphorylation by protein kinase C, and when phosphorylated in vitro, it loses the ability to interfere with G protein modulation (29). These results suggested that cross-talk between protein kinase C and G protein pathways might occur in this subregion of the alpha 1B domain I-II linker.


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Fig. 1.   Effect of a double substitution of I-II linker protein kinase C consensus sites for alanines on PKC and G protein action. A, current records illustrating G protein inhibition of the double alanine mutant. Somatostatin reversibly reduces the peak current amplitude of the mutant channel to 65% of its control value. The currents were leak-subtracted using a p/5 protocol. The holding potential was -100 mV, and the test potential was +20 mV. B, application of PMA does not affect current amplitude and has no adverse effects on G protein inhibition mediated by somatostatin (holding potential -100 mV, test potential = +20 mV). Inset, proposed transmembrane topology of voltage-dependent calcium channels and amino acid sequence of part of the alpha 1B channel I-II linker. The bar above the amino acid sequence indicates a previously identified putative target region for G protein/PKC cross-talk. The Thr422 and Ser425 residues were substituted to alanine residues. C, degree of somatostatin (100 nM) inhibition of wild type alpha 1B channel and the alanine (422 and 425) mutant channels (each coexpressed with beta 1b and alpha 2) with or without prior application of 100 nM PMA. Note that the alanine substitution slightly but significantly reduces the degree of somatostatin inhibition. While PMA reduces the G protein sensitivity of the wild type channel, the G protein inhibition of the double mutant is not affected. D, up-regulation of channel activity by 100 nM PMA. Note that the up-regulation seen with the wild type channel is blocked by the double alanine substitution. Error bars represent S.E. values; the test potential in C and D was +20 mV.

Two putative protein kinase C consensus sites, Thr422 and Ser425, are contained with this region of the channel (Fig. 1, inset). To test whether one or both of these residues might mediate PKC/Gbeta gamma cross-talk, we replaced both sites with alanine residues. Fig. 1A depicts current records obtained from the double alanine mutant in the absence and the presence of 100 nM somatostatin. Similar to that observed with the wild type channel (Fig. 1), activation of somatostatin receptors mediates a reversible and pronounced inhibition of channel activity, paired with a slowing of activation kinetics and an apparent slowing of inactivation. Fig. 1B illustrates the effect of PMA on channel activity and on somatostatin modulation of the alanine double mutant. While application of 100 nM PMA had no detectable effect on channel activity, the subsequent application of 100 nM somatostatin produced the same degree of G protein inhibition as that observed in the absence of PMA. Fig. 1, C and D, illustrates the effect of alanine substitution for a number of experiments. There are two effects evident. First, the alanine mutation per se significantly reduces the degree of somatostatin inhibition seen with the wild type channel from 53 ± 5 to 36 ± 5% (p = 0.02) (Fig. 1C). Second, while PMA treatment reduced the somatostatin effect for the wild type channel, the somatostatin sensitivity of the double mutant was not altered by PMA (36 ± 5 versus 37 ± 5%, p = 0.86; Fig. 1C), indicating that cross-talk between PKC and G protein pathways is blocked by the double alanine substitution. In addition, the PMA-induced up-regulation observed with the wild type channels was reduced from 49 ± 14 to 6 ± 5% when both PKC consensus sites were simultaneously replaced with alanines (Fig. 1D). Thus, the critical structures mediating up-regulation of channel activity and inhibition of direct G protein action appear to reside within overlapping regions of the calcium channel domain I-II linker and contain one or both of Thr422 and Ser425.

To elucidate which of the two residues mediate the effects of PKC, we "permanently phosphorylated" either Thr422 or Ser425 by replacing them individually with glutamic acid residues. As shown in Fig. 2A, the S425E mutant exhibits a somatostatin response comparable with that of the wild type channel (p = 0.41), suggesting that phosphorylation of Ser425 does not antagonize G protein action. PMA treatment had no significant effect on current amplitude (p = 0.83, paired t test; see also Fig. 3B), suggesting that replacing Ser425 with glutamic acid mimics a permanently up-regulated state of the channel. Nonetheless, PMA treatment significantly attenuated the degree of somatostatin inhibition from 46 ± 7 to 15 ± 4% (p = 0.004) (Figs. 2B and 3A), suggesting that replacement of Ser425 with glutamic acid does not preclude phosphorylation of the adjacent Thr422 residue and that cross-talk between PKC and Gbeta gamma modulation is probably mediated by Thr422 rather than Ser425. If this is correct, then mimicking phosphorylation of Thr422 (i.e. T422E) should reduce the degree of G protein inhibition to those levels observed after PKC phosphorylation of the wild-type channel. This is supported by the current records shown in Fig. 2, C and D, and the data presented in Fig. 3A. The T422E mutant showed a significantly reduced somatostatin sensitivity, which was comparable in magnitude with that observed with the wild type channel after PMA treatment (WT (with PMA) = 20 ± 5%; T422E (without PMA) = 20 ± 3%, p = 0.91). These data indicate that replacing Thr422 with a negatively charged side group mimics the antagonistic effect of PKC on G protein inhibition. PMA application did not further affect somatostatin sensitivity of T422E (T422E (with PMA) = 14 ± 3%, p = 0.29). Also, PMA failed to increase the peak current amplitude of T422E (p = 0.71) (Figs. 2D and 3B), suggesting that similar to S425E, the T422E construct is likely be tonically up-regulated. Overall, the data suggest that whereas only Thr422 is capable of mediating the cross-talk effect, phosphorylation of either Ser425 or Thr422 is sufficient to fully up-regulate channel activity.


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Fig. 2.   Effect of individual replacement of I-II linker PKC consensus sites with glutamic acid residues. The holding potential was -100 mV, the test potential was +20 mV, and currents were leak-subtracted using a p/5 protocol. A and C, inhibition of mutant channels by 100 nM somatostatin. Note that the threonine substitution dramatically reduces G protein sensitivity. B and D, effect of PMA on channel activity and on the degree of somatostatin inhibition. Either mutation blocks up-regulation of the channel by PMA. S425E shows a reduced sensitivity to somatostatin inhibition following application of PMA (i.e. cross-talk remains intact), while no additional effect of PMA on G protein inhibition of T422E is evident.


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Fig. 3.   A, effect of somatostatin on calcium channel N-type channel activity with or without prior application of 100 nM PMA. The S425E mutant exhibits a somatostatin sensitivity that is not significantly different from that of the wild type channel. With prior application of PMA, the degree of somatostatin inhibition of both the wild type and the S425E mutant is reduced to similar levels. In contrast, even in the absence of PMA, the T422E mutant exhibits a somatostatin sensitivity that parallels that of a PMA-treated wild type channel, and PMA does not further effect somatostatin sensitivity. The holding potential was -100 mV, and the test potential was typically +20 mV. Error bars represent S.E. values. B, up-regulation of wild type and mutant channels by 100 nM PMA. Note that the glutamic acid substitution of either Thr422 or Ser425 blocks up-regulation by PMA. Experimental conditions were as described for A.

To confirm this hypothesis, we created two additional mutants in which Thr422 and Ser425 were substituted individually by alanines in order to further define the relative contributions of the individual PKC consensus sites to the overall action of PKC. As shown in Fig. 4A, T422A exhibits a somatostatin sensitivity that closely parallels that seen with the T422A/S425A double mutant shown in Fig. 1. After treatment with 100 nM PMA, the degree of somatostatin inhibition of T422A did not decrease significantly (37 ± 5% (without PMA) versus 32 ± 3% (with PMA), p = 0.42) and remained significantly (p < 0.003) larger than that of the PMA-treated wild type channel (20 ± 5%). These data indicate that cross-talk between PKC and G protein pathways is blocked upon selective removal of the Thr442 PKC substrate. Consistent with this notion, removal of the Ser425 PKC substrate (i.e. S425A) did not significantly change G protein sensitivity (p = 0.49), nor did it affect cross-talk between the G protein and PKC pathways (48 ± 7% (without PMA) versus 18 ± 3% (with PMA), p < 0.002, Fig. 4A). Both T422A and S425A exhibited a similar degree of PKC-dependent up-regulation (Fig. 4B), which did not differ significantly from that observed with the wild type channel (p > 0.79). This further supports the notion that N-type channel activity is fully up-regulated upon phosphorylation of either Thr422 or Ser425, whereas only Thr422 is capable of mediating the cross-talk between PKC and G protein pathways.


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Fig. 4.   Effect of individual alanine substitutions in the I-II linker PKC consensus sites on PKC and G protein inhibition of N-type calcium channels. Error bars represent S.E. values, and numbers in parentheses indicate the numbers of experiments. The dotted lines indicate the levels of G protein inhibition (A) or PKC-dependent up-regulation (B) depicted in Fig. 1. A, inhibition of T422A and S425A by 100 nM somatostatin with and without prior application of 100 nM PMA. Note that T422A does not permit PKC activation to antagonize somatostatin inhibition, whereas the S425A mutant exhibits the behavior seen with the wild type channel. The level of somatostatin-induced inhibition of T422A closely parallels that observed with the T422A/S425A double mutant examined in Fig. 1B. The PKC-dependent up-regulation observed with T422A and S425A is similar to that observed with the wild type channel. The dotted line indicates the level of up-regulation of the wild type channel.

Voltage Dependence of G Protein Modulation-- To examine the voltage dependence of the T422E mutant, we utilized a ramp protocol to allow the acquisition of complete current-voltage relations without contamination from receptor desensitization. Fig. 5 compares the somatostatin response of wild type channels to that of the T422E mutant at a number of test potentials. In both cases, the effect of somatostatin is dependent on membrane potential and is consistent with the direct inhibition of native N-type calcium channels by G proteins (18, 23, 24, 31, 32). As evident from Fig. 5, somatostatin produced a significantly greater inhibition of the wild type channels at all potentials. Although the T422E mutant is capable of undergoing G protein modulation, the voltage dependence of Gbeta gamma dissociation appears be shifted toward more hyperpolarized potentials in the mutant channel.


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Fig. 5.   Voltage dependence of G protein inhibition for wild type (n = 7) and mutant T422E (n = 12) alpha 1B channels elicited by application of 100 nM somatostatin. The data were obtained via ramp protocols as described under "Materials and Methods" 15 s after somatostatin application. Note that the voltage dependence of somatostatin inhibition is shifted toward more hyperpolarizing potentials for the mutant channels, resulting in a significantly greater inhibition of the wild type channels at each potential. Error bars represent S.E. values.

Contribution of the alpha 1B Carboxyl Region in PKC and G Protein Modulation-- Several studies have implicated the carboxyl terminus in the direct G protein modulation of voltage-dependent calcium channels (33, 34). Furthermore, the carboxyl terminus contains several putative protein kinase C consensus sites. To examine the possibility that the carboxyl terminus might contribute to the modulation of N-type calcium channels by PKC and G proteins, we examined a deletion mutant in which the last third of the carboxyl terminus of alpha 1B (residues 1955-2336) was deleted (alpha 1BDelta COOH). Fig. 6B depicts a current record obtained with the deletion mutant in the presence and absence of somatostatin. Although somatostatin reduces the peak current amplitude and mediates the slowing of activation kinetics typical of direct Gbeta gamma modulation, the degree of inhibition is reduced compared with the wild type channel (from 53 ± 5% to 32 ± 2%, p = 0.02). In contrast, up-regulation by PMA remains intact (Fig. 6C and inset), suggesting that the deleted portion of the carboxyl-terminal does not directly mediate PKC-dependent changes in channel activity. Following pretreatment with PMA, somatostatin application resulted in only a small effect on peak current amplitude (4 ± 2% inhibition), at a test potential of +20 mV (Fig. 6D). Hence, PKC-dependent phosphorylation in combination with deletion of the carboxyl terminus further reduces the degree of Gbeta gamma modulation. To further examine this observation, we deleted the carboxyl-terminal region of the T422E mutant. As seen from Fig. 6D, this mutant showed only a ~10% inhibition in response to somatostatin at a test potential of +20 mV. The degree of inhibition did not differ significantly from that seen with mutant T422E after PMA treatment (p = 0.1) but was significantly lower than the sensitivity of the alpha 1BDelta COOH construct (p = 0.025). These data indicate that deletion of the carboxyl terminus and replacement of Thr422 with glutamic acid produce additive effects on G protein sensitivity. This particular construct did not express well in HEK cells, and we were unable to systematically examine the voltage dependence of somatostatin action.


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Fig. 6.   Effect of deletion of residues 1955-2336 of the alpha 1B carboxyl terminus on G protein and PKC sensitivity. A, schematic representation of the proposed calcium channel transmembrane topology indicating the deletion of part of the carboxyl terminus region. B, current record elicited by a step depolarization from -100 to +20 mV and leak-subtracted via a p/5 protocol. Deletion of the 3' third of the carboxyl terminus region results in a slowing of inactivation kinetics as well as in a reduced degree of G protein inhibition as evident by application of 100 nM somatostatin. C, time course of up-regulation of current activity by 100 nM PMA. The bar graphs depicted in the inset illustrate the degree of PMA up-regulation as defined by the peak current ratio I (with PMA)/I(without PMA) for the wild type channel and the deletion mutant. D, degree of somatostatin-mediated G protein inhibition of the wild type channel and the deletion mutant in the presence and absence of 100 nM PMA. Note that the degree of G protein inhibition is significantly attenuated upon deletion of the 3' portion of the alpha 1B carboxyl terminus. Pretreatment with 100 nM PMA almost completely abolished G protein inhibition at test potentials of +20 mV. A double mutant (Delta COOH,T422E) also exhibited a reduced G protein sensitivity that did not differ significantly from that seen with T422E after PMA treatment. Error bars represent S.E. values.

Overall, the data suggest that the carboxyl region mediates an important role in stabilizing the Gbeta gamma interaction with the calcium channel alpha 1 subunit, especially when PKC sites in the alpha 1B domain I-II linker are phosphorylated.

    DISCUSSION

Protein Kinase C-dependent Up-regulation Is Mediated by the Calcium Channel I-II Linker-- Whole cell currents of exogenously expressed alpha 1B N-type channels are up-regulated by activation of protein kinase C by either phorbol esters (such as PMA) or activation of coexpressed metabotropic glutamate receptors (19). Here, we have used application of 100 nM PMA to stimulate protein kinase C in human embryonic kidney cells expressing alpha 1B channels. Consistent with the results of Stea and co-workers (19), PMA application resulted in a pronounced increase in channel activity for wild type alpha 1B channels that was blocked by pretreatment with staurosporine. In their study, Stea and co-workers (19) were able to confer aspects of PKC sensitivity of alpha 1B onto the less sensitive alpha 1A channels by inserting the domain I-II linker of alpha 1B into alpha 1A. We have previously shown that a fusion protein directed against the alpha 1B I-II linker region is a substrate for PKC-dependent phosphorylation (29). Two considerations have led us to focus on a pair of PKC consensus sites (Thr422 and Ser425) located within a 20-amino acid stretch (residues 410-428) of the alpha 1B I-II linker. First, this stretch of residues is both a substrate for in vitro phosphorylation by PKC and has also been implicated in the PKC-mediated antagonism of G protein inhibition of wild type alpha 1B channels (29). Second, certain amino acid substitutions in the vicinity of the corresponding region in alpha 1A increases PKC sensitivity of alpha 1A.2

Here, we show that the double substitution of Thr422 and Ser425 for alanines abolishes the PKC-dependent up-regulation of alpha 1B channels, suggesting that phosphorylation of one or both of these residues is sufficient to mediate up-regulation. Individual substitutions of these residues for glutamic acid also precluded the effect of PKC stimulation. In contrast, individual substitution of these two residues for alanines had no adverse effect on PKC-dependent up-regulation. These data imply that the effects of phosphorylation of the two PKC consensus sites are nonadditive and that phosphorylation of either Thr422 or Ser425 is sufficient to mediate complete up-regulation of channel activity in an all or none manner. At present, the molecular mechanisms by which the phosphorylation event affects channel activity remain to be determined. It is possible that phosphorylation induces a conformational change in the domain I-II linker that directly affects activation. Alternatively, phosphorylation of these residues might alter the interaction with the calcium channel beta  subunit, which in turn may affect channel activation. Such a mechanism would be consistent with data of Stea and co-workers (19), who reported that the calcium channel beta  subunit is required for PKC-dependent up-regulation.

Recently, Shistik et al. (35) showed that deletion of N-terminal residues 2-46 abolished PKC-dependent up-regulation of rabbit heart alpha 1C channels expressed in Xenopus oocytes. The N-terminal region of rat brain alpha 1B N-type calcium channel is 51 residues shorter than that of the rabbit heart alpha 1C channel and thus lacks the motif identified by Shistik et al. (35). Furthermore, there is no counterpart to Thr422 present in the rabbit heart alpha 1C sequence, and the analog to Ser425 (Ser499 in the rabbit heart alpha 1C sequence) is not part of a PKC consensus motif. This suggests that the molecular mechanism underlying the PKC-dependent modulation of N-type calcium channel activity is fundamentally different from that for the rabbit cardiac L-type isoform.

Model for the G Protein Inhibition of N-type Calcium Channels-- Over the past several years, a number of studies have examined the molecular determinants of G protein modulation of presynaptic calcium channels (18, 28, 29, 31-34, 36-40). It is now widely accepted that the Gbeta gamma subunits are the active G protein species mediating the antagonistic effect on presynaptic calcium channel activity (28, 29, 31, 32). The G protein beta gamma subunits are able to interact with two separate regions within the calcium channel domain I-II linker (29, 36). We have previously suggested that the PKC dependent phosphorylation of one of these two I-II linker Gbeta gamma binding motifs might mediate the previously identified antagonistic effect of PKC stimulation on G protein sensitivity (29). Here, we present further confirmation for the involvement of the domain I-II linker region in direct G protein modulation of N-type calcium channels. Each, the double alanine mutant and the T422E and T422A constructs, exhibited a significantly reduced sensitivity to somatostatin-induced Gbeta gamma modulation. Neither of these substitutions resulted in significant changes in current kinetics or half-activation potential, minimizing the possibility of an indirect effect due to changes in channel gating. We suggest the possibility that these substitutions more likely reduce the affinity of the channel for binding Gbeta gamma .

In addition to the domain I-II linker, the carboxyl terminus (33, 34) as well as domain I (38) and the amino terminus (39) of the calcium channel alpha 1 subunit have all been implicated in direct G protein modulation. Here, we present corroborating evidence that the carboxyl terminus contributes to a portion of the overall G protein inhibition of N-type channels. A deletion of one-third of the carboxyl-terminal region significantly reduced but did not eliminate the somatostatin-induced inhibition of alpha 1B channels. The deleted portion contains a highly conserved motif that was recently implicated in Gbeta gamma binding to alpha 1E channels (33). Together with our results, it appears that while the carboxyl terminus probably contributes to Gbeta gamma binding to N-type calcium channels, the major determinant of G protein action is the domain I-II linker. That the carboxyl terminus contributes to Gbeta gamma binding could account for the observation that alpha 1B or alpha 1E channel constructs containing the alpha 1C I-II linker remain sensitive to G protein inhibition (33, 34)3 despite the fact that alpha 1C I-II linker fusion proteins do not bind Gbeta gamma . It is possible that the carboxyl region cooperatively enhances binding to the alpha 1C I-II linker in these chimeric constructs.

Kinetic modeling of G protein inhibition of single N-type calcium channels has shown that G protein binding results in a reluctance of channels to undergo transitions from the closed states to channel opening (27). Upon membrane depolarization, G proteins dissociate from the channels prior to opening, and the associated increase in first latency to opening results in a decrease in peak current amplitude. Within the framework of this model, the binding of Gbeta gamma to the domain I-II linker and perhaps the carboxyl terminus mediates the stabilization of the closed state by inducing a conformational change in the channel protein. The translation of G protein binding into a change in channel function may be mediated by residues located in domain I, consistent with previous studies (34, 38, 39).

Overall, a model emerges in which Gbeta gamma interacts with two high affinity regions within the calcium channel domain I-II linker (residues 353-389 and 410-428 (29, 36) and a lower affinity site in the carboxyl terminus (33). PKC-dependent phosphorylation probably destabilizes Gbeta gamma binding to the second site within the I-II linker Gbeta gamma binding domain (i.e. residues 410-428), thereby shifting the voltage dependence of Gbeta gamma dissociation to more hyperpolarized potentials and perhaps reducing the increase in first latency to opening associated with Gbeta gamma binding (27). Single channel experiments will ultimately be required to confirm any effects of phosphorylation (and of the T422E substitution) on first latency.

Implications of Dual PKC Sites for Calcium Channel Modulation-- Our data indicate that up-regulation of N-type channel activity occurs via phosphorylation of either Thr422 or Ser425, whereas G protein modulation is antagonized by phosphorylation of only Thr422. The selective phosphorylation of Ser425 would result in up-regulation by ~50%, and the subsequent stimulation of the G protein pathway would produce a ~50% inhibition of the PKC-enhanced current, resulting in an overall inhibition of ~25%. Phosphorylation of Thr422 (or of both residues simultaneously) would also result in the 50% up-regulation, but subsequent G protein inhibition would be attenuated to ~20% and result in a net up-regulation by ~20%. Since activation of PKC and G protein pathways individually would respectively produce a 50% increase and a 50% decrease in control current levels, Thr422 and Ser425 may function as an integration center for inputs from PKC and G protein pathways to produce multiple levels of calcium channel activity. Together with recent reports that protein kinase C-dependent phosphorylation disrupts the interactions between syntaxin and the calcium channel II-III linker (16), this convergence of second messenger pathways directly at the level of the calcium channel alpha 1 subunit would provide a mechanism to precisely control neurotransmitter release at presynaptic nerve terminals.

    FOOTNOTES

* This work was supported by operating grants from the Medical Research Council of Canada (MRC) (to G. W. Z. and T. P. S.) and by an operating grant from the Heart and Stroke Foundation of Canada (to G. W. Z.).The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Recipient of a studentship award from the Alberta Heritage Foundation for Medical Research (AHFMR).

parallel Recipient of an MRC Scientist Award.

** Recipient of scholarship awards from the MRC and the AHFMR. To whom correspondence should be addressed: Dept. of Pharmacology and Therapeutics, University of Calgary, 3330 Hospital Dr. NW, Calgary, Alberta T2N 4N1, Canada. Tel.: 403-220-8687; Fax: 403-283-8731; E-mail: Zamponi{at}acs.ucalgary.ca.

2 G. W. Zamponi and T. P. Snutch, unpublished observations.

3 E. Bourinet, personal communication.

    ABBREVIATIONS

The abbreviations used are: PKC, protein kinase C; PMA, phorbol 12-myristate 13-acetate.

    REFERENCES
Top
Abstract
Introduction
References
  1. Mori, Y., Friedrich, T., Kim, M.-S., Mikami, A., Nakai, J., Ruth, P., Bosse, E., Hofmann, F., Flockerzi, V., Furuichi, T., Mikoshiba, K., Imoto, K., Tanabe, T., and Numa, S. (1991) Nature 350, 398-402[CrossRef][Medline] [Order article via Infotrieve]
  2. Sather, W. A., Tanabe, T., Zhang, J. F., Mori, Y., Adams, M. E., and Tsien, R. W. (1993) Neuron 11, 291-303[Medline] [Order article via Infotrieve]
  3. Stea, A., Tomlinson, W. J., Bourinet, E., Dubel, S. J., Vincent, S. R., and Snutch, T. P. (1994) Proc. Natl. Acad. Sci. U. S. A. 91, 10567-10580
  4. Williams, M. E., Brust, P. F., Feldman, D. H., Patthi, S., Simerson, S., Maroufi, A., McCue, A. F., Velicelebi, G., Ellis, S. B., and Harpold, M. (1992) 257, 389-395
  5. Dubel, S. J., Starr, T. V. B., Hell, J., Ahlijanian, M. K., Enyeart, J. J., Catterall, W. A., and Snutch, T. P. (1992) Proc. Natl. Acad. Sci. U. S. A. 89, 5058-5062[Abstract]
  6. Fujita, Y., Mynlieff, M., Dirksen, R. T., Kim, M., Niidome, T., Nakai, J., Friedrich, T., Iwabe, N., Miyata, T., Furuichi, T., Furutama, D., Mikoshiba, K., Mori, Y., and Beam, K. G. (1993) Neuron 10, 585-598[Medline] [Order article via Infotrieve]
  7. Williams, M. E., Feldman, D. H., McCue, A. F., Brenner, R., Velicelebi, G., Ellis, S. B., and Harpold, M. M. (1992) Neuron 8, 71-84[Medline] [Order article via Infotrieve]
  8. Tomlinson, W. J., Stea, A., Bourinet, E., Charnet, P., Nargeot, J., and Snutch, T. P. (1993) Neuropharmacology 32, 1117-1126[CrossRef][Medline] [Order article via Infotrieve]
  9. Fisher, S. E., Ciccodicola, A., Tanaka, K., Curci, A., Desicato, S., D'Urso, M., and Craig, I. W. (1997) Genomics 45, 340-347[CrossRef][Medline] [Order article via Infotrieve]
  10. Soong, T. W., Stea, A., Hodson, C. D., Dubel, S. J., Vincent, S. R., and Snutch, T. P. (1993) Science 260, 1133-1136[Medline] [Order article via Infotrieve]
  11. Williams, M. E., Marubio, L. M., Deal, C. R., Hans, M., Brust, P. F., Philipson, L. H., Miller, R. J., Johnson, E. C., Harpold, M. M., and Ellis, S. B. (1994) J. Biol. Chem. 269, 22347-22357[Abstract/Free Full Text]
  12. Perez-Reyes, E., Cribbs, L. L., Daud, A., Lacerda, A. E., Barclay, J., Williamson, M. P., Fox, M., Rees, M., and Lee, J. H. (1998) Nature 391, 896-900[CrossRef][Medline] [Order article via Infotrieve]
  13. Westenbroek, R. E., Hell, J. W., Warberm, C., Dubel, S. J., Snutch, T. P., and Catterall, W. A. (1992) Neuron 9, 1099-1115[Medline] [Order article via Infotrieve]
  14. Westenbroek, R. E., Sakurai, T., Elliott, E. M., Hell, J. W., Starr, T. V., Snutch, T. P., and Catterall, W. A. (1995) J. Neurosci. 15, 6403-6418[Medline] [Order article via Infotrieve]
  15. Sheng, Z., Rettig, T., Takahashi, M., and Catterall, W. A. (1994) Neuron 13, 1303-1313[Medline] [Order article via Infotrieve]
  16. Yokoyama, C. T., Sheng, Z., and Catterall, W. A. (1997) J. Neurocsi. 17, 6929-6938[Abstract/Free Full Text]
  17. Dunlap, K., and Fischbach, G. D. (1981) J. Physiol. 317, 519-535[Abstract]
  18. Bourinet, E., Soong, T. W., Stea, A., and Snutch, T. P. (1996) Proc. Natl. Acad. Sci. U. S. A. 93, 1486-1491[Abstract/Free Full Text]
  19. Stea, A., Soong, T. W., and Snutch, T. P. (1995) Neuron 5, 929-940
  20. Swartz, K. J., Merrit, A., Bean, B. P., and Lovinger, D. M. (1993) Nature 361, 165-168[CrossRef][Medline] [Order article via Infotrieve]
  21. Swartz, K. J. (1993) Neuron 11, 305-320[Medline] [Order article via Infotrieve]
  22. Ikeda, S. R., and Schofield, G. (1989) J. Physiol. 409, 221-240[Abstract]
  23. Bean, B. P. (1989) Nature 340, 153-156[CrossRef][Medline] [Order article via Infotrieve]
  24. Boland, L. M., and Bean, B. P. (1993) J. Neurosci. 13, 515-533
  25. Mintz, I. M., and Bean, B. P. (1993) Neuron 10, 889-898[Medline] [Order article via Infotrieve]
  26. Hille, B. (1994) Trends Neurosci. 17, 531-536[CrossRef][Medline] [Order article via Infotrieve]
  27. Patil, P. G., deLeon, M., Reed, R. R., Dubel, S., Snutch, T. P., and Yue, D. T. (1996) Biophys. J. 71, 2509-2521[Abstract]
  28. Zamponi, G. W., and Snutch, T. P. (1998) Proc. Natl. Acad. Sci. U. S. A. 95, 4035-4039[Abstract/Free Full Text]
  29. Zamponi, G. W., Bourinet, E., Nelson, D., Nargeot, J., and Snutch, T. P. (1997) Nature 385, 442-446[CrossRef][Medline] [Order article via Infotrieve]
  30. Zamponi, G. W., Bourinet, E., and Snutch, T. P. (1996) J. Membr. Biol. 151, 77-90[CrossRef][Medline] [Order article via Infotrieve]
  31. Herlitze, S., Garcia, D. E., Mackie, K., Hille, B., Scheuer, T., and Catterall, W. A. (1996) Nature 280, 258-262
  32. Ikeda, S. R. (1996) Nature 380, 255-258[CrossRef][Medline] [Order article via Infotrieve]
  33. Quin, N., Platano, Olcese, R., Stefani, E., and Birnbaumer, L. (1997) Proc. Natl. Acad. Sci. U. S. A. 94, 8866-8871[Abstract/Free Full Text]
  34. Zhang, J. F., Ellinor, P. T., Aldrich, R. W., and Tsien, R. W. (1996) Neuron 17, 991-1003[Medline] [Order article via Infotrieve]
  35. Shistik, E., Ivanina, T., Blumenstein, Y., and Dascal, N. (1998) J. Biol Chem. 273, 17901-17909[Abstract/Free Full Text]
  36. DeWaard, M., Liu, H., Walker, D., Scott, V. E. S., Gurnett, C. A., and Campbell, K. P. (1997) Nature 385, 446-450[CrossRef][Medline] [Order article via Infotrieve]
  37. Page, K. M., Stephens, G. J., Berrow, N. S., and Dolphin, A. C. (1997) J. Neurosci. 17, 1330-1338[Abstract/Free Full Text]
  38. Stephens, G. J., Canti, C., Page, K. M., and Dolphin, A. C. (1998) J. Physiol. 509, 163-169[Abstract/Free Full Text]
  39. Page, K. M., Canti, C., Stephens, G. J., Berrow, N. S., and Dolphin, A. C. (1998) J. Neurosci. 18, 4815-4824[Abstract/Free Full Text]
  40. Herlitze, S., Hockermann, G. H., Scheuer, T., and Catterall, W. A. (1997) Proc. Natl. Acad. Sci. U. S. A. 94, 1512-1516[Abstract/Free Full Text]


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