cAMP-Dependent Enhancement of Dihydropyridine-Sensitive Calcium Channel Availability in Hippocampal Neurons

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Volume 17, Number 14, Issue of July 15, 1997 pp. 5334-5348
Copyright ©1997 Society for Neuroscience

cAMP-Dependent Enhancement of Dihydropyridine-Sensitive Calcium Channel Availability in Hippocampal Neurons

Ege T. Kavalali, Katherine S. Hwang, and Mark R. Plummer
Department of Biological Sciences, Rutgers University, Piscataway, New Jersey 08855-1059

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Dihydropyridine-sensitive calcium channels can be strongly modulated by cAMP-dependent phosphorylation. This modulation takesthe form of increased channel availability in cardiac myocytes(for review, see McDonald et al., 1994) and has been suggestedto be essential for voltage-dependent facilitation in adrenalchromaffin cells (Artalejo et al., 1992) and skeletal muscle (Sculptoreanuet al., 1993b). To determine the role of cAMP-dependent phosphorylationon dihydropyridine-sensitive calcium channels in hippocampal neurons,we have used both single-channel and whole-cell recording techniquesand have examined the effects of the membrane-permeable cAMP analog8-(4-chlorophenylthio) (CPT)-cAMP and the protein kinase inhibitors1-(5-isoquinolinesulfonyl)-2-methylpiperazine (H-7) and N-[2-(p-bromocinnamyl-amino)ethyl]-5-isoquinolinesulfonamide(H-89).
Hippocampal neurons contain two kinds of dihydropyridine-sensitive calcium channel activity: Ls and Lp (Kavalali and Plummer,1994). The Ls channel closely resembles the cardiac L-type channel,whereas the Lp channel shows a novel low-voltage form of voltage-dependentpotentiation (Kavalali and Plummer, 1996). 8-CPT-cAMP increasedthe availability of both the Ls and Lp channels and caused a parallelincrease in Lp channel reopenings at the repolarization potentialthat result from voltage-dependent potentiation. This effect wascompletely blocked by the broad spectrum kinase inhibitor H-7and by the protein kinase A-specific inhibitor H-89. The two inhibitors,however, did not disrupt baseline potentiation of the Lp channel,suggesting that cAMP-dependent protein kinase activity can enhanceLs and Lp channel activity but is not required for voltage-dependentpotentiation in hippocampal neurons.
Key words: calcium channel; hippocampus; potentiation; phosphorylation; facilitation; dihydropyridine; cAMP; protein kinase A; H-7; H-89

INTRODUCTION

Voltage-gated calcium channels, key regulators of calcium entry into cells, are subject to extensive modulation. For example,L-type calcium channels in cardiac cells show enhanced activityafter application of $beta$ -adrenergic agonists, an effect mediatedby cAMP-dependent protein kinase A (PKA), which leads to increasedstrength of muscle contraction (for review, see McDonald et al.,1994). Neuronal N-type channel activity is decreased by neurotransmitters(for review, see Anwyl, 1991), which can have the functional consequenceof presynaptic inhibition (Scholz and Miller, 1991; Toth et al.,1993). N-type channel inhibition is mediated by G-protein-coupledreceptors, and the actions of neurotransmitters can be blockedby agents such as pertussis toxin or GDP- $beta$ -S (for review, seeHille, 1994).

Another form of modulation is voltage-dependent potentiation of calcium channel activity in which conditioning prepulses dramaticallyenhance the responsiveness of calcium channels to subsequent testpulses. First studied using whole-cell recording from adrenalchromaffin cells (Fenwick et al., 1982), the potentiation wasdescribed as an alteration in the gating of a dihydropyridine(DHP)-sensitive channel in which prolonged tail currents wereseen after a large depolarization (Hoshi and Smith, 1987). Subsequentreports referred to the phenomenon as voltage-dependent facilitationand suggested instead that the enhanced calcium current was attributableto recruitment of a normally silent DHP-sensitive channel type(Artalejo et al., 1991a,b). Voltage-dependent facilitation ofnon-DHP-sensitive channels, attributed to a voltage-dependentrelief of G-protein inhibition, has also been described (Elmslieet al., 1990; Ikeda, 1991; Kasai, 1991).

A detailed investigation of the mechanism of calcium channel potentiation in adrenal chromaffin cells suggested that the processwas not intrinsic to the channel and required the involvementof an unknown protein kinase (Artalejo et al., 1992). This samemechanism has also been posited to apply to skeletal muscle calciumchannels (Sculptoreanu et al., 1993b) and cardiac calcium channel $alpha$ ₁ subunits (Sculptoreanu et al., 1993a), although the resultis somewhat controversial (Foley and Pelzer, 1994; Kleppisch etal., 1994).

In hippocampal neurons, we have recently described voltage-dependent potentiation of DHP-sensitive calcium channels (Kavalaliand Plummer, 1994). One kind of channel, Ls, shows prolonged openingsafter large depolarizing pulses (Kavalali and Plummer, 1996) thatstrongly resemble the potentiation described for cardiac L-typechannels (Pietrobon and Hess, 1990). This high-voltage potentiation(HVP) is also shown by a second kind of DHP-sensitive channel,Lp. In addition to HVP, the Lp channel shows a different kindof potentiation characterized by bursts of reopenings at the repolarizationpotential after relatively modest depolarizations (Kavalali andPlummer, 1996). This low-voltage potentiation (LVP) is found exclusivelyin Lp channels.

In this paper we have characterized the effect of cAMP-dependent protein kinase activity on Ls and Lp channels. We show thatboth Ls and Lp channels are subject to extrinsic modulation byPKA, manifested as an increase in channel availability. We found,however, that the low- and high-voltage forms of potentiationare insensitive to protein kinase inhibitors and thus may be intrinsicto the channel.

MATERIALS AND METHODS
For single-channel recordings, hippocampal neurons were obtained from embryonic day 18 Sprague Dawley rats and were platedon Falcon Primaria dishes at a final density of 10⁶ cells per dish. Cultures were prepared according to the methodof Lu et al. (1991) and maintained in serum-free medium (SFM)at 37°C in a 95% air/5% CO₂ humidified incubator. SFM consistedof a 1:1 (v/v) mixture of Ham's F-12 and Eagle's minimum essentialmedium and supplemented with insulin (25 µg/ml), transferrin (100µg/ml), putrescine (60 µM), progesterone (20 nM), selenium (30nM), glucose (6 mg/ml), and penicillin-streptomycin (0.5 U/mland 0.5 mg/ml, respectively). Recordings were performed 3-10 dafter dissociation.

For whole-cell recordings, an acute dissociation technique, based on the method described by Johnson and Byerly (1994), wasused. Hippocampi from 7- to 16-d-old Sprague Dawley rats wereremoved rapidly and cut into 300- to 400-µm-thick slices usinga McIlwain tissue chopper (Brinkmann Instruments, Westbury, NY).These slices were incubated at 35°C in PIPES saline (in mM: 120NaCl, 5 KCl, 1 CaCl₂, 1 MgCl₂, 20 PIPES, and 25 glucose, pH 7.0)with added protease (2 mg/ml; type XIV, Sigma, St. Louis, MO)for 10 min and continuously bubbled with medical grade oxygen.Tissue slices were later rinsed in the PIPES saline without proteaseand placed into a scintillation vial, where they were constantlystirred in an O₂ atmosphere. As needed, hippocampal neurons weretriturated onto poly-L-lysine-coated Petri dishes in the PIPESsaline without protease. Neurons prepared this way were viablefor up to 5 hr, and they had few or no processes, making themsuitable for voltage clamp. To date, single-channel recordingsfrom acutely dissociated cells have revealed no differences inthe properties of Lp channels compared with those obtained fromembryonic neurons. The lower channel density in the embryonicneurons, however, makes them more favorable for single-channelexperiments.

Cell-attached single-channel recordings were made with barium as the charge carrier (in mM): 110 BaCl₂ and 10 HEPES-TEAOH,pH 7.5, and a depolarizing external recording solution was usedto bring the intracellular potential to ~0 mV (in mM): 140 potassiumgluconate, 10 HEPES-KOH, and 5 EGTA, pH 7.5. Unless otherwisespecified, 0.1 µM DHP agonist (+)-(S)-202-791 (a gift from Sandoz,Basel, Switzerland) was added to the bath solution to clarifythe number and types of calcium channels in the patch. Recordingswere made with an Axopatch 200 amplifier (Axon Instruments, FosterCity, CA). Data were sampled with an INDEC Systems (Capitola,CA) 15125 analog-to-digital converter at 5 kHz and filtered at1 kHz. Eight hundred millisecond voltage pulses (typically 160,320, and 320 msec at holding, test, and holding potentials, respectively)were delivered at 5 sec intervals. Linear leak and capacitativecurrents were subtracted digitally. All recording parameters werecontrolled by programs written in Borland C⁺⁺ using INDEC-supplied driver libraries.

Whole-cell recordings were made with barium as the charge carrier (in mM): 20 BaAc₂, 135 TEACl, 0.001 TTX, and 10 HEPES, pH7.4. The pipette contained (in mM) 108 cesium methanesulfonate,4 MgCl₂, 9 EGTA, 9 HEPES, 4 MgATP, 14 creatine phosphate, 0.3Na₃GTP, 50 U/ml creatine phosphokinase, pH 7.4. Series resistanceswere 7-9 M $Omega$ before compensation. All experiments were carriedout at room temperature. Data were sampled at 10 kHz and filteredat 5 kHz. Four hundred millisecond msec voltage pulses (typically80, 80, and 240 msec at holding, test, and holding potentials,respectively) were delivered at 4 sec intervals. Leak currentswere measured with hyperpolarizing pulses to 1/10 of the steppotential.

Open times and open probabilities were obtained from sweeps idealized with a half-amplitude crossing criterion and cubic splineinterpolation (Colquhoun and Sigworth, 1983). Incomplete openings,such as tail current openings, were excluded from analysis. Valueswere plotted on square root-log coordinates, and mean open timeswere estimated from maximum likelihood fitting (Sigworth and Sine,1987). Open times were evaluated in two ways. The first was toaverage values obtained from individual experiments for the purposesof statistical comparison. In Results, these data are presentedas averages ± SEM. The second method was to sum data from allexperiments and treat it as a single distribution. This gave usthe best quality fit, and extracted values are presented in thefigures as individual open times. The summed distributions werecompared statistically with the Kolmogorov-Smirnov test. Overallopen probability was calculated by evaluating activity for theentire recording, including null sweeps. A conditional open probabilitywas also calculated after exclusion of null sweeps. For patchesthat contained two of the same kind of channel, open probabilitywas measured for both channels and divided by two. Similarly,null sweep probability was calculated by taking the square rootof the proportion of null sweeps. This assumes that the two channelshave similar but independent gating characteristics and givesvalues appropriate for a single channel. Unless otherwise stated,statistical comparisons were made with Student's t test. Dataanalysis was accomplished by programs written in Microsoft VisualBasic.

Lp and Ls channels were identified according to criteria described previously (Kavalali and Plummer, 1994). In brief, Lp activitywas identified by the presence of reopenings during repolarizationto $-$ 40 mV after a voltage pulse to +20 mV. When studied in thepresence of the DHP agonist (+)-202-701, Lp channels could befurther distinguished from Ls channels on the basis of unitarycurrent amplitude and relatively shorter open times. Three kindsof recordings were selected for detailed analysis. The first wasfrom patches that contained only a single channel, evidenced bytotal absence of superimposed openings during a recording of atleast 20 min in duration. Patches of this type were encounteredrelatively infrequently, although they yielded the most usefulinformation. The second was from patches that contained two ofthe same kind of channel, determined by the presence of superimposedopenings of a single type. Patches that seemed to contain threeof the same kind of channel were not used. The third type of recordingwas from multichannel patches that contained both Lp and Ls channels(typically one to three Ls and one or two Lp channels). Thesepatches were used exclusively for studies of Lp potentiation,because only Lp channels are active after repolarization to $-$ 40mV (Kavalali and Plummer, 1994). Patches containing non-DHP-sensitivechannels (e.g., T-, N-, and P-type channels, which typically showedmore openings when tested from a holding potential of $-$ 90 mV comparedwith $-$ 40 mV) were not used.

Unless otherwise specified, all chemicals were obtained from Sigma. Drugs were applied by preincubation for at least 30 minwhile the cells were still in the humidified incubator and werealso added to the extracellular recording solution. 1-(5-isoquinolinesulfonyl)-2-methylpiperazine(H-7) and N-[2-(p-bromocinnamyl- amino)ethyl]-5-isoquinolinesulfonamide(H-89; Calbiochem, La Jolla, CA) were dissolved in DMSO and diluted1:1000 and 1:10,000, respectively, in media for preincubationand bath solution for recording.

RESULTS
These experiments were designed (1) to characterize cAMP-dependent modulation of hippocampal Lp and Ls calcium channels and(2) to determine whether voltage-dependent phosphorylation isrequired for Lp channel potentiation. The first aim was accomplishedby measuring Ls and Lp channel activity during a standard testpulse to +20 mV from a holding potential of $-$ 40 mV from cellsin which we had directly stimulated PKA with the membrane-permeablecAMP analog 8-(4-chlorophenylthio) (CPT)-cAMP (1 mM). Recordingsfrom these cells were compared with controls, which had receivedvehicle solution. The cAMP analog was applied by pretreating cellsfor a minimum of 30 min before recording. We chose the preincubationapproach to examine effects of steady state cAMP elevation ratherthan observe the time course of the response. Because both Lpand Ls channels show considerable sweep-to-sweep variability,it was necessary to use conditions that allowed substantial datacollection under stable conditions. Moreover, it is not alwaysthe case that receptor-activated second messengers can travelto areas underneath cell-attached recording pipettes (Forscherand Oxford, 1985; Lipscombe et al., 1989; Foehring, 1996), sowe also avoided the potential problem of limited diffusion of8-CPT-cAMP. The results of this paper are based on >200 recordingsof Lp and Ls channels, of which 121 were of sufficient durationsto be analyzed in detail. Of these, 20 were from patches thatcontained only a single Ls channel, 11 were from patches thatcontained two Ls channels, 8 were from patches that containedonly a single Lp channel, and 1 was from a patch that containedtwo Lp channels. The remainder were multichannel recordings thatcontained no more than three Ls channels and one or two Lp channels.

The second aim, studies of Lp potentiation, was accomplished by quantifying activity during the $-$ 40 mV repolarization periodin all recordings and during the +20 mV test pulse in patcheswith single channels. According to our working model, initialopenings elicited by the +20 mV test pulse represent activationof the unpotentiated channel. At some time during the test pulsedepolarization, the channel can enter a potentiated state in whichits activation threshold is reduced. This results in the channelcontinuing to open even when the membrane voltage is returnedto the holding potential of $-$ 40 mV, a voltage that will not activatethe unpotentiated channel. The Lp channel will then reopen atthe holding potential until it reverts to its initial state. Thus,if voltage-dependent potentiation of the Lp channel requires phosphorylation,it should be possible to enhance or eliminate repolarization reopeningswith phosphorylation activators or inhibitors while preservingactivity that results from the nonpotentiated state.

cAMP-dependent modulation of Ls and Lp channels
cAMP-dependent modulation of hippocampal calcium currents was examined with cell-attached single-channel recording to identifyprecisely the target and nature of the effects. Our initial recordingswere made without DHP agonist, to ensure that (+)-202-791 didnot alter calcium channel modulation. Under these conditions,we focused on channel openings that occurred during the repolarizationperiod, because we have previously shown that these result exclusivelyfrom Lp channels at a holding potential of $-$ 40 mV (Kavalali andPlummer, 1994). Although the openings were brief and not completelyresolved, we were able to identify a clear enhancement of Lp channelactivity in recordings obtained from cells that had been pretreatedwith 1 mM 8-CPT-cAMP (Fig. 1A).
Fig. 1. Exposure to 8-CPT-cAMP increases repolarization reopenings in cell-attached patches from hippocampal neurons. A, Two setsof traces from patches with multiple unidentified channels anda single Lp channel. Sweeps from cells pretreated with 1 mM 8-CPT-cAMP(right) show more reopenings than sweeps from control cells (left).The boxed area indicates the period analyzed, because openingsthere result exclusively from Lp channels under these conditions.Because of sampling limitations, not all openings reach the fullcurrent amplitude expected for the Lp channel. B, Plot of reopeningprobability from control patches (n = 12) and those treated with8-CPT-cAMP (n = 15). C, Plot of number of reopenings from controlpatches and those treated with 8-CPT-cAMP. In both B and C, asterisksindicate significant difference (p < 0.01). D, Open time distributionsfrom reopenings at $-$ 40 mV after test pulses to +40 mV from a holdingpotential at $-$ 40 mV. Data are summed from all recordings. E, Opentime distributions from patches exposed to 1 mM 8-CPT-cAMP. Voltagesare the same as in D. Data are summed from all recordings.
[View Larger Version of this Image (43K GIF file)]

To compare Lp channel activity from control and 8-CPT-cAMP-treated cells, we selected patches that contained only a singleLp channel. Our criteria for this determination in the absenceof fully resolved openings was to use the predicted current amplitudeof the open channel at $-$ 40 mV and to discard patches that containedopenings larger than this value. To examine the reliability ofthis method, DHP agonist was applied at the end of the recordingto prolong the open time and to allow accurate assessment of thenumber of channels in the patch. In four of four recordings examinedin this fashion, only a single Lp channel was present in the patch.

From these experiments, we measured open probability during the repolarization period ("reopening probability") and countedthe number of openings. For both measures, 8-CPT-cAMP caused agreater than twofold enhancement of Lp channel activity (Fig.1B,C). We also calculated mean open time from these patches butdid not find a difference between the control and 8-CPT-cAMP-treatedcells (Fig. 1D,E). Because of the long observation times required,the sampling interval used did not adequately capture submillisecondopen times. Thus the fitted distributions are not accurate forthe briefest openings. Nonetheless, the method was sufficientfor longer openings, and the absence of apparent differences suggestedthat 8-CPT-cAMP increased reopening probability by enhancing channelavailability rather than mean open time.

To obtain more dependable estimates of the number of channels in a patch, as well as to optimize conditions for quantitativeanalysis, subsequent experiments were done in the presence ofthe DHP agonist (+)-202-791. As in the absence of DHP, patchesexposed to 8-CPT-cAMP showed increased activity of DHP-sensitivecalcium channels when compared with control patches that containedthe same kinds and numbers of channels (Fig. 2). Enhanced activitywas evident both during a test pulse of +20 mV and after repolarizationto $-$ 40 mV. Inspection of individual traces suggested that bothLs and Lp channel types were affected. Lp channel activity canbe seen as reopenings during the repolarization. The longest durationopenings, especially visible in the traces from the cell treatedwith the cAMP analog, represent activity of the Ls channel. Theeffect of the 8-CPT-cAMP was clear in average currents, whichshowed a doubling of magnitude. Examination of tail currents,in which Lp activity predominates at these voltages (Kavalaliand Plummer, 1996), showed an increase in the frequency of sweepswith reopenings.
Fig. 2. 8-CPT-cAMP enhances calcium channel activity in cell-attached patches. A, Ten consecutive sweeps from a patch with one Lsand two Lp channels. In this and all subsequent figures, the DHPagonist (+)-(S)-202-791 is in the bath (0.1 µM). Lp channel reopeningscan be seen in (from top) traces 3, 4, 6-8, and 10. B, Ten consecutivesweeps from a patch with the same channel composition as in A.The cell was pretreated with 1 mM 8-CPT-cAMP. Lp reopenings arepresent in all traces. The bottom traces in both A and B are ensembleaverage currents from 114 and 100 sweeps, respectively.
[View Larger Version of this Image (35K GIF file)]

Although multichannel recordings provided evidence of increased activity in response to application of 8-CPT-cAMP, two issuesneeded to be resolved. First, the simultaneous Ls and Lp openingsmade it difficult to determine the nature of the effects on theindividual channel types. Second, to address voltage-dependentpotentiation, it was necessary to measure Lp activity during thetest pulse and during repolarization independently. To answerthese questions, we analyzed in detail recordings from patchesthat contained either a single channel, or two of the same kindof channel (Figs. 3, 4).
Fig. 3. Recordings from patches containing single Ls channels showed increased activity after exposure to 8-CPT-cAMP. A, Two setsof five consecutive sweeps of Ls channel activity from a controlpatch (left) and one that had been pretreated with 1 mM 8-CPT-cAMP(right). Both patches contain only one Ls channel. B, Plot ofp_o from control patches (n = 10) and those treated with 8-CPT-cAMP(n = 11). C, Plot of null sweep probability from control patchesand those treated with 8-CPT-cAMP. In both B and C, asterisksindicate significant difference (p < 0.001). D, Open time distributionsfrom test pulses to +20 mV from a holding potential at $-$ 40 mV.Data are summed from all recordings. E, Open time distributionsfrom patches exposed to 1 mM 8-CPT-cAMP. Voltages are the sameas in D. Data are summed from all recordings.
[View Larger Version of this Image (40K GIF file)]

Fig. 4. 8-CPT-cAMP produces parallel increases in Lp channel test pulse and repolarization activity. A, Two sets of five consecutivesweeps of Lp channel activity from a control patch (left) andone that had been pretreated with 1 mM 8-CPT-cAMP (right). Bothpatches contain only one Lp channel. B, Plot of p_o from controlpatches (n = 3) and those treated with 8-CPT-cAMP (n = 3). C,Plot of null sweep probability from control patches and thosetreated with 8-CPT-cAMP. In both B and C, asterisks indicate significantdifference (p < 0.05). D, Open time distributions from test pulsesto +20 mV from a holding potential at $-$ 40 mV. Data are summedfrom all recordings. E, Open time distributions from patches exposedto 1 mM 8-CPT-cAMP. Voltages are the same as in D. F-I, Same formatas B-E, except that measurements are for reopenings during therepolarization period. Example reopenings are seen in A in (fromtop) traces 3-5 on the left and all traces on the right.
[View Larger Version of this Image (58K GIF file)]

Ls channels Comparisons of single Ls channel patches from control and pretreated cells showed an obvious increase in activity in cellsexposed to 8-CPT-cAMP (Fig. 3A). This difference was statisticallysignificant for open probability (p_o) between control cells (0.1± 0.02; n = 10) and 8-CPT-cAMP-treated cells (0.35 ± 0.05; n =11; p < 0.001; Fig. 3B). To gain some insight into the mechanismof the effect, we measured both the frequency of sweeps with noopenings (null sweeps) and mean dwell times in open states. Theprobability of null sweeps declined in cells treated with 8-CPT-cAMP(0.093 ± 0.015) compared with controls (0.42 ± 0.06; Fig. 3C).This was not accompanied, however, by a significant change inthe prominent components of mean open time. For Ls channels, bestfits to the data were obtained with three-exponential functions.Control recordings showed average mean open times of 0.93 ± 0.26,6.34 ± 0.8, and 44.1 ± 13.5 msec compared with 0.68 ± 0.06, 8.14± 0.96, and 24.9 ± 4.9 msec for cells treated with 8-CPT-cAMP(p > 0.2, 0.1, and 0.1, respectively). Summed data from all recordingsalso did not show any significant differences between controland cAMP conditions (Figs. 3D,E; p > 0.05, Kolmogorov-Smirnovtest).
Lp channels Recordings from single Lp channels showed that 8-CPT-cAMP increased activity both during the test voltage pulse and the repolarizationperiod (Fig. 4). According to our model, the repolarization reopeningsrepresent activity of the potentiated Lp channel, and they ceaseonce the Lp channel leaves this potentiated state or set of states.Openings observed during the test pulse, however, are initiallycaused by activity of the unpotentiated channel, which then makesa transition to the potentiated state. Therefore, test pulse andrepolarization openings represent the onset and decay of potentiation,respectively, and we analyzed the two kinds of activity separately.Inspection of individual traces again suggested that the effectof 8-CPT-cAMP was largely attributable to an increased numberof sweeps with activity, as well as an increased number of openings,but was not attributable to changes in the characteristics ofthe openings or independent effects on test pulse or repolarizationactivity (Fig. 4).

Analysis of openings during the test pulse showed a significant increase in overall open probability for cells exposed tothe 8-CPT-cAMP (0.13 ± 0.03; n = 3) compared with patches fromcontrol cells (0.039 ± 0.01; n = 3; p < 0.05; Fig. 4B). As withthe Ls channel, there was a concomitant decrease in the probabilityof null sweeps (0.5 ± 0.035 vs 0.15 ± 0.07; p < 0.05; Fig. 4C)but little change in open times obtained from summed data forall experiments (control, 0.82, 3.4, and 22.9 msec; cAMP, 0.78,3.1, and 13.2 msec; p > 0.05, Kolmogorov-Smirnov test; Figs. 4D,E).Statistical comparisons of open times extracted from individualrecordings also showed no significant differences between meanopen times for controls (0.99 ± 0.23, 3.8 ± 0.4, and 24.7 ± 3.7msec) and cAMP-treated cells (0.86 ± 0.23, 3.4 ± 0.4, and 19.6± 4.8; p > 0.7, 0.5, and 0.4, respectively) or for their relativeproportions in control (0.79 ± 0.04, 0.21 ± 0.04, and 0.007 ±0.004 msec) and cAMP-treated cells (0.63 ± 0.09, 0.35 ± 0.09,and 0.01 ± 0.005; p > 0.2, 0.2, and 0.6, respectively). Comparisonof the distributions of summed data were also not significantlydifferent (Figs. 4D,E; p > 0.05, Kolmogorov-Smirnov test).

The activity of Lp channels during the repolarization period paralleled that seen during the test pulse when cells were exposedto 8-CPT-cAMP. Overall open probability increased (Fig. 4F), andthe probability of null sweeps (sweeps with no reopenings) decreased(Fig. 4G). Each of the effects was significant (p < 0.05). Aswith the test pulse results, there were no large changes in themagnitudes or distributions of open times in the individual data(control, 1.36 ± 0.47, 4.4 ± 0.7, and 27.6 ± 9.8 msec; cAMP, 1.18± 0.34, 6.3 ± 0.5, and 33.9 ± 6.9 msec; p > 0.7, 0.08, and 0.6,respectively). No differences were apparent in the summed dataeither in the values of open time (control, 1.6, 4.9, and 24.5msec; cAMP, 1.27, 5.2, and 31.6 msec) or in the shape of the distributions(Figs. 4H,I; p > 0.05, Kolmogorov-Smirnov test).

We also analyzed closed times during the repolarization period but found no differences between the distributions obtainedfrom summing the control and 8-CPT-cAMP data (p > 0.05, Kolmogorov-Smirnovtest). For both sets of cells, the briefest closures were notwell resolved, but three other components for controls (0.69,8.1, and 60.5 msec) and 8-CPT-cAMP cells (0.68, 9.9, and 62.3msec) were similar (data not shown).

To compare the magnitude of the 8-CPT-cAMP effect on test pulse activity with that seen during repolarization, we calculatedthe average charge transferred for each period. We used this approachbecause open probability does not take the differences in unitarycurrent into account. At $-$ 40 mV, Lp channel currents are almostthree times larger than those seen at +20 mV, thus providing substantialcation influx. Under control conditions, the average charge measuredwas 10.63 ± 3.24 femtocoulombs (fC) for the test pulse and 17.08± 3.47 fC for repolarization (data not shown). In cells exposedto 8-CPT-cAMP, the amount of charge was increased for both testpulse and repolarization openings. Despite the lower open probabilityduring repolarization, however, the amount of charge transferredduring the two periods was almost identical, being 35.26 ± 9.49fC for the test pulse and 32.16 ± 3.52 fC for repolarization (datanot shown). Thus the enhanced activity produced by 8-CPT-cAMPis equally significant during the voltage pulse and after it.

The above data suggest that the increased open probability seen in the presence of 8-CPT-cAMP could be entirely explainedby the reduction in null sweeps. To examine this possibility,we grouped all control data and all 8-CPT-cAMP data and comparedLp channel reopening probability and the number of repolarizationopenings. When all sweeps were used, the difference between controland 8-CPT-cAMP was highly significant for both parameters. Reopeningprobability in 8-CPT-cAMP was 0.054 ± 0.006 compared with thecontrol value of 0.02 ± 0.003 (n = 18 and 14, respectively; p< 0.001). Similarly, the average number of openings in cells treatedwith 8-CPT-cAMP was 4.26 ± 0.56 compared with 1.67 ± 0.3 for controls(p < 0.01). If the differences were attributable to the decreasein null sweeps, then a conditional analysis in which null sweepswere excluded should make the control and 8-CPT-cAMP reopen probabilitiesand number of openings equal. This was not the case, however.Although the magnitude was smaller, differences in reopen probability(control, 0.049 ± 0.007; 8-CPT-cAMP, 0.077 ± 0.007; p < 0.01)and numbers of openings (control, 4.62 ± 0.61; 8-CPT-cAMP, 7.06± 0.93; p < 0.05) were still significant.

Phosphorylation dependence of Lp potentiation
The preceding results suggested that cAMP-dependent protein kinase activity primarily increased Lp and Ls channel availability.Moreover, the similarity of the increase in Lp test pulse openingsand reopenings suggested that the repolarization activity couldbe increased by, but may not require, cAMP. We explored this possibilityfurther by studying Lp channel activity in excised inside-outpatches, with the assumption that this cell-free recording conditionmay disrupt the normal action of cytoplasmic kinases.
Excised patches If potentiation depends on prepulse-induced phosphorylation, as suggested by work on adrenal chromaffin cells (Artalejo etal., 1992) and skeletal muscle (Sculptoreanu et al., 1993b), wehypothesized that excision of the patch could lead to a loss ofreopenings that would proceed independently of a reduction intest pulse openings. Initial multichannel recordings showed theexpected rundown of Ls channels, but surprisingly, Lp channelreopenings persisted for the duration of the recording (n = 5;data not shown). Addition of 4 mM MgATP did not prevent Ls channelrundown and had no effect on Lp channels in excised patches (n= 8). When examined in patches that contained only a single channel,excision did not uncouple Lp potentiation from activity duringthe test pulse (Fig. 5), and individual traces were indistinguishablebefore or many minutes after excision (Fig. 5A). Measurement ofsweep-by-sweep open probability during the 30 min of the recordingshowed little decline for both test pulse and repolarization activity(Fig. 5B,C). When data from three experiments of this type werebinned and averaged, in no case did we observe a separation ofLp potentiation from test pulse activity (Fig. 5D,E). In markedcontrast to the rapid decline in Ls activity after excision (Fig.5F), the resistance of the Lp channel to rundown was striking.
Fig. 5. Lp channels retain their characteristic gating patterns in cell-free membrane patches. A, Five consecutive sweeps before (left)and after (right) excision of a patch containing a single Lp channel.B, Time course of Lp test pulse open probability at +20 mV froma holding potential of $-$ 40 mV. The patch was excised 8 min intothe recording (dashed line). Lp channel activity remained fairlystable over the course of the 30 min recording. C, Time courseof Lp reopening probability during the same recording illustratedin B. Note that reopenings persisted during the 30 min periodsimilar to that of test pulse activity. D, Binned and averageddata from recordings of Lp test pulse activity (n = 3; for twoof these the bath solution contained 4 mM ATP). Open bars indicatemeasurements taken before excision; shaded bars show measurementonce the patch was excised. E, Same format as D, except for repolarizationreopenings. F, Same format as D, expect for patches containingLs channels (n = 10; for five of these the bath solution contained4 mM ATP). Note the rapid rundown compared with both Lp test pulseopenings and Lp reopenings.
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H-7 and H-89 To show that the responses to 8-CPT-cAMP were mediated by protein kinase activity and were not attributable to a direct effecton the calcium channel and to determine whether Lp reopeningscould be blocked pharmacologically, we examined the effects oftwo kinase inhibitors, the broad spectrum inhibitor H-7 and therelatively PKA-specific H-89 (Chijiwa et al., 1990). Because wewere primarily interested in Lp potentiation, we restricted ouranalysis to Lp channel reopenings after repolarization. This enabledus to use multichannel patches in addition to single-channel patches,because tail current reopenings exclusively represented the activityof Lp channels (Kavalali and Plummer, 1994).

Our first test was to assess the effectiveness of the kinase inhibitor H-89 by coapplying it with 8-CPT-cAMP. The concentrationchosen was based on work by Ono and Fozzard (1993), which showedthat 1 µM H-89 prevented the action of okadaic acid on cardiacL-type calcium channels. We found in five experiments that thismanipulation completely blocked the effect of the cAMP analogon Lp channels. Inspection of individual traces showed no differencesbetween control cells and those exposed to both 8-CPT-cAMP andH-89 (Fig. 6A; compare Lp reopening activity between the two conditions).There were also no remarkable differences in the time coursesof the recordings, with both control and experimental cells havingcomparable rates of activity and rundown (Figs. 6B,C). These resultswere unlike what had been seen with 8-CPT-cAMP alone (Fig. 2B;compare Lp reopenings) and indicated that H-89 was efficaciousin this system.
Fig. 6. Protein kinase inhibitors H-89 and H-7 prevent effects of 8-CPT-cAMP but do not reduce baseline activity. A, Two sets of fiveconsecutive sweeps of Lp channel activity from a control patch(left) and one that had been pretreated with 1 mM 8-CPT-cAMP plus1 µM H-89 (right). Both multichannel patches contained only oneLp channel, but the control patch contained three Ls channels,and the treated patch contained two Ls channels. Note that activityof the Lp channel in the patch on the right was similar to Lpactivity in the patch on the left, unlike what occurred aftertreatment with 1 mM 8-CPT-cAMP alone (compare Lp reopenings insweeps with the multichannel recording in Fig. 2B). B, C, Timecourse of Lp reopening probability for recordings illustratedin A. Note that activity in 8-CPT-cAMP plus H-89 (C) was similarto that of control (B). D, Probability of Lp reopenings underfour different experimental conditions using H-89 (n = 7, 8, 5,and 5 for control, 8-CPT-cAMP, 8-CPT-cAMP plus H-89, and H-89,respectively). E, Same format as C, except for H-7 (n = 4, 7,6, and 2 for control, 8-CPT-cAMP, 8-CPT-cAMP plus H-7, and H-7,respectively). Asterisks indicate significant differences (p <0.05).
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We next looked at effects of H-89 on cells taken from a single set of cultures and compared reopening probability under thefollowing conditions: control, 1 mM 8-CPT-cAMP, 1 mM 8-CPT-cAMPplus 1 µM H-89, and 1 µM H-89 alone (Fig. 6D). Compared with controlrecordings, 1 mM 8-CPT-cAMP significantly increased Lp reopening(0.063 ± 0.01 vs 0.022 ± 0.006; n = 8 and 7; p < 0.01), whereasthe combination of 1 mM 8-CPT-cAMP and 1 µM H-89 showed reopeningscomparable to control levels (0.027 ± 0.009; n = 5; p > 0.6).Treatment with H-89 alone produced no obvious effect, with patchesagain showing a reopening p_o value that was not distinguishablefrom control (0.026 ± 0.003; n = 5; p > 0.9). Parallel experimentswith 100 µM H-7 on a separate set of cultures produced comparableresults (Fig. 6E); 8-CPT-cAMP enhanced the Lp reopening p_o (0.049± 0.01 vs 0.015 ± 0.005; n = 7 and 4; p < 0.05), and this enhancementwas abolished by coapplication of H-7 (0.012 ± 0.002; n = 6; p> 0.6). H-7 alone also had no effect (0.015 ± 0.007; n = 2; p> 0.15).

To complete our analysis of these data, we also obtained the mean dwell times of Lp channel openings during repolarizationunder the different conditions. The averaged data from individualrecordings can be summarized as follows: compared with control,the briefest component of open time (1.34 ± 0.23 msec) was notsignificantly different under all conditions tested (cAMP, 1.64± 0.22 msec; cAMP plus H-89, 2.0 ± 0.33 msec; and H-89 alone,1.7 ± 0.38 msec). With the sole exception of the cAMP-treatedcells, this was also true for the medium (control, 3.8 ± 0.16;cAMP, 5.86 ± 0.8; cAMP plus H-89, 6 ± 1.5; and H-89 alone, 5.8± 1.0) and long duration components (control, 15.4 ± 3.4; cAMP,32.2 ± 7.2; cAMP plus H-89, 28.6 ± 14.4; and H-89 alone, 25.3± 4.5). None of the comparisons of the relative proportions ofopen time components was significant. Data summed from all recordingsalso showed no significant differences between conditions (Fig.7A; p > 0.05, Kolmogorov-Smirnov test).
Fig. 7. Open time distributions are not strongly affected by 8-CPT-cAMP or by the kinase inhibitors H-89 and H-7. A, Open time distributionfor Lp channel reopenings under control and three experimentalconditions: 1 mM 8-CPT-cAMP, 1 mM 8-CPT-cAMP plus 1 µM H-89, and1 µM H-89. Recordings are the same as illustrated in Figure 6.B, H-7 experiments. The format is the same as A, except for theuse of 100 µM H-7.
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The set of experiments with the kinase inhibitor H-7 did not reveal any effects of the different treatments on open time orthe open time distributions (Fig. 7B; p > 0.05, Kolmogorov-Smirnovtest). For example, the medium duration component was similarfor both control (5.22 ± 1.8) and cAMP (5.18 ± 0.4), was longerfor H-7 only (7.04 ± 2.9), and was shorter for cAMP plus H-7 (3.25± 0.46). The long duration component was highest for cAMP (32.5± 7.0) compared with control (19.4 ± 1.4), cAMP plus H-7 (21.3± 2.9), and H-7 alone (25.7 ± 9.1).

From these experiments we concluded that application of 1 mM 8-CPT-cAMP increased the overall open probability of both Lpand Ls channels, and that this effect was attributable largelyto increased availability rather than changes in open time durationsor shifts between open states. We also showed that both inhibitorsH-89 and H-7 were able to prevent the action of cAMP without havingany obvious effects of their own. This stability of baseline activityindicated that the Lp potentiation observed under control conditionsdid not require phosphorylation by PKA or other H-7-sensitiveprotein kinases. To follow up this point, we specifically examinedthe actions of H-7 on Lp potentiation.
Effect of H-7 on low- and high-voltage potentiation We have reported previously that there are two kinds of voltage-dependent potentiation of Lp channel activity (Kavalali andPlummer, 1996), a type induced by low-voltage prepulses (LVP)and one induced by high-voltage prepulses (HVP). The results abovesuggest that the Lp potentiation does not require protein kinaseactivity, and we tested this idea explicitly with both single-channeland whole-cell recordings using the same voltage protocols thatwere used to separate LVP and HVP.

For cell-attached single-channel recordings, a step pulse protocol was used in which Lp channel activity was measured duringa 320 msec test pulse at $-$ 30 mV. The test pulse was immediatelypreceded by a 160 msec conditioning prepulse of +40 or +120 mVto elicit LVP or LVP plus HVP, respectively. We conducted theseexperiments on cells that had been exposed to 100 µM H-7 for atleast 30 min before recording. This concentration of H-7 has beenshown to block LTP (Malinow et al., 1989) and voltage-dependentphosphorylation of facilitation channels in adrenal chromaffincells (Artalejo et al., 1992). Under these conditions, LVP wasclearly evident in single traces, revealed by numerous reopeningsat $-$ 30 mV when the test pulse followed the conditioning pulse,but not in the test pulse alone (Fig. 8A, left and middle setsof sweeps). HVP was also observed in these experiments, seen asthe appearance of exceptionally long duration openings at $-$ 30mV when the test pulse followed a conditioning pulse of +120 mV,but not after a conditioning pulse of +40 mV or alone (Fig. 8A,compare right set of sweeps to middle and left). Quantitativecomparison of open probability in control cells with those pretreatedwith H-7 showed no difference between the two conditions for eitherLVP (control, 0.028 ± 0.01; n = 8; H-7, 0.03 ± 0.003; n = 5; p> 0.8) or HVP (control, 0.068 ± 0.017; n = 8; H-7, 0.077 ± 0.01;n = 5; p > 0.7; Fig. 8B).
Fig. 8. H-7 does not block low- or high-voltage Lp channel potentiation measured with single-channel or whole-cell recordings. A,Lp channel activity during a $-$ 30 mV test pulse alone (left) orafter 160 msec prepulses to +40 mV (middle) or +120 mV (right).The cell was treated with 100 µM H-7 before this recording, andH-7 was present in the bath during the recording. B, Average Lpopen probability at $-$ 30 mV after prepulses to +40 or +120 mV inthe absence (light bars; n = 6) or presence (dark bars; n = 3)of H-7. Values were not significantly different for +40 or +120mV (p > 0.8 and 0.7, respectively). C, Plot of tail current amplitudeversus prepulse potential at several time points after repolarization.For whole-cell recording, the pipette (intracellular) and bathsolution both contained 100 µM H-7. Tail current measurementsbegan 5-10 min after breaking into a cell. Each point representsmeasurements from five recordings. Values were normalized foreach experiment to the maximum tail current measured at the 5msec time point. Data points for each series were fit with thesum of a Boltzmann and exponential function. D, Comparison ofthe actual values of the peak current during the test pulse (+40mV) and tail currents at 5, 10, and 15 msec after repolarizationfrom experiments with H-7 in the pipette (dark bars; n = 5) withcontrol (light bars; n = 16). Data were not significantly different(p > 0.2, 0.7, 0.9, and 0.6 for peak and 5, 10, and 15 msec, respectively).Inset, Representative whole-cell traces evoked by depolarizationsto $-$ 20, +40, and +100 mV from a holding potential of $-$ 40 mV inthe presence of H-7. Control whole-cell data were those obtainedfrom a previous study (Kavalali and Plummer, 1996).
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To corroborate the single-channel data, we also made whole-cell recordings in the absence of the DHP agonist used for channelidentification in the cell-attached recordings. As described previously(Kavalali and Plummer, 1996), we evaluated both LVP and HVP fromwhole-cell recordings by measuring the amplitude of tail currentat $-$ 40 mV after voltage pulses from $-$ 30 to +100 mV. Measurementof tail current at a series of time points after repolarizationwas used to quantify the magnitude of LVP and HVP. The increasein the tail current amplitude at 5 msec after repolarization (whichshould exclude the non-DHP-sensitive channels) showed a prominentbiphasic rise (Fig. 8C). Based on correlation with our single-channeldata, we have interpreted the early portion of the increase asLVP and the subsequent secondary rise as HVP (Kavalali and Plummer,1996). Both components were present, despite the pretreatmentwith H-7 at the same concentration that completely blocked the8-CPT-cAMP effects seen in single-channel recordings and inclusionof H-7 in the recording pipette. Measurements of tail currentamplitude at later time points showed the expected decline inamplitude as well as the differential loss of HVP relative toLVP. Statistical comparison of the amplitude of peak current duringthe test pulse and three time points along the tail current showedno difference between control cells (peak, 157.5 ± 24.5 pA; 5msec, 58.7 ± 8.4 pA; 10 msec, 29.1 ± 4.4 pA; 15 msec, 22.1 ± 4.4pA; n = 16) and those exposed to H-7 (peak, 211 ± 35.1 pA; 5 msec,54.8 ± 10.6 pA; 10 msec, 28.6 ± 5.9 pA; 15 msec, 19.1 ± 4.1 pA;n = 5; p > 0.2, 0.7, 0.9, and 0.6, respectively; Fig. 8D).

DISCUSSION
Stimulation of $beta$ -adrenergic receptors on cardiac muscle can significantly enhance cardiac contractility and heart rate byincreasing calcium current (Reuter, 1965, 1966), an effect mediatedthrough a cAMP-dependent pathway (Tsien et al., 1972; Reuter,1974; Reuter and Scholz, 1977). $beta$ -Adrenergic receptors are coupledto a cholera toxin-sensitive GTP-binding protein (G_s) that canstimulate adenylyl cyclase, leading to an increase in intracellularcAMP levels that promotes phosphorylation of cardiac L-type calciumchannels by PKA (for review, see Trautwein and Hescheler, 1990;McDonald et al., 1994), although the exact site on the channelremains unknown (Charnet et al., 1995).

At the single-channel level, cAMP-dependent phosphorylation increases the likelihood that the channel will open during depolarization(Cachelin et al., 1983; Trautwein and Pelzer, 1988). This correspondsto a shift toward mode 1 from mode 0 in the scheme of Hess etal. (1984) and can be detected as an increase in the number offunctional channels in a noise analysis of macroscopic currents(Bean et al., 1984). Additional experiments have also revealedan increase in the frequency of mode 2 openings of L-type channelsin the presence of cAMP, indicating that phosphorylation can leadto a global redistribution of the time spent in different openstates (Yue et al., 1990).

Compared with the wealth of information available from cardiac cells, relatively little is known about the actions of PKAon neuronal L-type channels. Enhancement of hippocampal neuroncalcium channel types after application of noradrenaline or isoprenalinehas been found (Gray and Johnston, 1987; Fisher and Johnston,1990), and recent work has suggested that this effect may constitutepart of a positive feedback loop in which NMDA receptor-mediatedincreases in cAMP could augment further calcium influx by increasingthe activity of voltage-gated calcium channels (Chetkovich etal., 1991).

The data presented in this paper have extended earlier work on cAMP-dependent enhancement of cardiac calcium channel availabilityto neurons and have shown that both the Lp and Ls subtypes ofthe DHP-sensitive calcium channel are affected. In hippocampalneurons, as in cardiac myocytes, the predominant effect was areduction in null sweeps. When considering DHP-sensitive calciumchannels as members of a population, the greater availabilitynot only would increase calcium influx for an individual channel,but would also lead to simultaneous opening of many channels.This larger overall percentage of active channels would enhancecalcium entry, an effect that has been proposed to be importantfor transmitter release (Llinás et al., 1992; but see Stanley,1993) and other processes sensitive to the concentration of subcellularlevels of calcium.

We did not see any large changes in open times or their fractional distribution, either in averaged data from individual recordingsor in summed data from all recordings. The absence of strong effectscomparable to those seen in cardiac cells (Yue et al., 1990) mayresult from use of the DHP agonist, which already biases channelactivity toward mode 2 openings. This did not compromise the mainaction of 8-CPT-cAMP, however, because the increase in availabilitywas dramatic and robust under the conditions used in this study.Because of the extreme heterogeneity of calcium channels in centralneurons (Regan et al., 1991; Mintz et al., 1992; Randall and Tsien,1995), it was not feasible to do these experiments in the absenceof an agonist and still be certain of channel identification.Explicit tests of kinetic mechanism must await cloning and expressionof the Lp channel.

In bovine adrenal chromaffin cells, voltage-dependent potentiation of the "facilitation" channel can be blocked by the nonspecificprotein kinase inhibitors H-7 and K-252a (Artalejo et al., 1992)and induced by membrane-permeable analogs of cAMP (Artalejo etal., 1990). Taken together, these observations suggested thatpotentiation involved voltage-dependent phosphorylation of thefacilitation channel (Artalejo et al., 1992). Our work with proteinkinase inhibitors has shown that hippocampal neuron Lp potentiationdoes not work by a similar mechanism. Neither LVP nor HVP wasblocked by H-7, and treatment with 8-CPT-cAMP caused a parallelincrease in test pulse openings and repolarization reopenings.These results differ from those of Sculptoreanu et al. (1995),who found that activation of PKA was essential for potentiationof neuronal L-type channels. This may be attributable to the celltype studied, because their own work showed greater potentiationfor parasympathetic neurons than dorsal root ganglion neurons,and potentiation may be different still in hippocampal neurons.Another possibility is that we were examining Lp channels, whichmay not be present in peripheral neurons, and we were using conditioningvoltage pulses (+40 mV) that were substantially lower than thoseused by Sculptoreanu et al. (+100 mV). Our data agree, however,with studies of cloned neuronal (Bourinet et al., 1994) and smoothmuscle $alpha$ _1C (Kleppisch et al., 1994) channels, which did not findevidence of voltage-dependent phosphorylation essential to potentiation.

In addition to modulation by cAMP, two new facets of Lp channel activity were revealed by the present study. First, Lp channelswere much less sensitive to excision than Ls channels. As expected,Ls channel activity rapidly declined under cell-free conditions;Lp channels continued opening for many minutes, however, despiteseparation from the cytoplasm. From this, it may be possible toconclude that Lp activity is less dependent on phosphorylationthan Ls activity. It is also plausible, however, that the Lp channelhas a tightly associated constitutively active kinase that maintainsits activity such as in calcium-activated potassium channels (Chunget al., 1991; for review, see Mochly-Rosen, 1995). Although itis not clear why the Lp channel should be resistant to excisionwhen the Ls channel is not, one possible consequence of this maybe that the Lp channel would still be active under conditionsof metabolic stress such as hypoxia. Because there is some evidenceof the involvement of DHP-sensitive channels in neurotoxic celldeath (Weiss et al., 1990), it may be that the Lp channel is primarilyresponsible, because the Ls channel would be expected to be silentafter depletion of ATP.

A second noteworthy observation is that the characteristic gating patterns of the Lp and Ls channels were stable in all experimentsregardless of excision or the presence of 8-CPT-cAMP. It is notyet known whether Lp channels are truly distinct from the Ls channelsor whether Lp activity represents a long-lived Ls gating mode.The absence of Lp to Ls interconversions, even in the presenceof 8-CPT-cAMP, which increased Ls and Lp activity, as well asthe differential rate of rundown, adds support for the idea thatthe two kinds of channels are different. This is certainly reasonablegiven that diverse transcripts generated by alternate splicingcan differ in properties such as DHP inhibition (Soldatov et al.,1995) and even the recent observation that different calcium channelsize forms can be dynamically constructed (Hell et al., 1995).

The ubiquitous nature of calcium signaling (for review, see Clapham, 1995; Ghosh and Greenberg, 1995) suggests numerous possiblefunctions for Lp and Ls channel modulation by cAMP. Anatomicalevidence indicates that DHP-sensitive calcium channels are localizedto dendritic spines and cell bodies (Westenbroek et al., 1990;Hell et al., 1993, 1995), and calcium influx through DHP-sensitivecalcium channels can stimulate growth factor receptor signal transduction(Rosen et al., 1996), can affect cell migration (Moran, 1991),may contribute to aging-related disorders (Thompson et al., 1990;Landfield, 1994; Thibault and Landfield, 1996), and can initiateexpression of immediate early genes (Murphy et al., 1991; Badinget al., 1993; Thompson et al., 1995).

At present, most evidence suggests that non-DHP-sensitive channels provide the presynaptic calcium influx that triggers neurotransmitterrelease from central neurons (Turner et al., 1992; Turner et al.,1993; Regehr and Mintz, 1994; Wheeler et al., 1994; Dunlap etal., 1995; Elliott et al., 1995; Scholz and Miller, 1995), althoughDHP-sensitive channels may participate in dendritic release (Simmonset al., 1995). This does not mean, however, that L-type calciumchannels are not involved in the modulation of synaptic strength.DHP-sensitive calcium channels have been implicated in mossy fiberlong-term potentiation (for review, see Johnston et al., 1992)and in a short-term form of postsynaptic potentiation (Kullmannet al., 1992; Wyllie et al., 1994). Enhancement of Lp or Ls activityby cAMP could work in concert with other PKA-dependent mechanismsthat increase synaptic strength, such as phosphorylation of neurotransmitterreceptors (Blackstone et al., 1994; Raman et al., 1996).

An interesting feature of the Lp channel is that the potentiated openings have a voltage dependence that is quite differentfrom that of the unpotentiated channel (Kavalali and Plummer,1996). This could mean that recently described calcium channelopenings that occur in response to subthreshold synaptic inputs(Markram and Sakmann, 1994; Magee and Johnston, 1995) as wellas DHP-sensitive calcium currents at resting membrane potentials(Avery and Johnston, 1996; Magee et al., 1996) may also involvethe potentiated Lp channel. This channel has a much larger conductancethan the T-type channel, and because its activity can be modulatedby PKA, stimuli that cause the Lp channel to enter its potentiatedstate may produce significant calcium influx even when at subthresholdvoltages. This becomes more significant when one considers theincreased driving force at negative potentials and that the declinein Lp potentiation occurs more slowly than T-type channel deactivation.

FOOTNOTES

Received Jan. 24, 1997; revised May 5, 1997; accepted May 7, 1997.

Supported by National Institutes of Health Grant NS 34061. We are grateful to Dr. R. L. Davis for helpful discussions andcomments on this manuscript.

Correspondence should be addressed to Mark R. Plummer, Department of Biological Sciences, Rutgers University, Nelson Lab,Busch Campus, Piscataway, NJ 08855-1059.

Dr. Kavalali's present address: Department of Molecular and Cellular Physiology, Beckman Center, Stanford University MedicalCenter, Stanford, CA 94305.

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