Neurotransmitter Activation of Inwardly Rectifying Potassium Current in Dissociated Hippocampal CA3 Neurons: Interactions among Multiple Receptors

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The Journal of Neuroscience, October 15, 1998, 18(20):8153-8162

Neurotransmitter Activation of Inwardly Rectifying Potassium Current in Dissociated Hippocampal CA3 Neurons: Interactions among Multiple Receptors
Deborah L. Sodickson and Bruce P. Bean
Department of Neurobiology, Harvard Medical School, Boston, Massachusetts 02115, and Vollum Institute, Oregon Health Sciences University, Portland, Oregon 97201

  ABSTRACT

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

We characterized potassium current activated by G-protein-coupled receptors in acutely dissociated hippocampal CA3 neurons.Agonists for serotonin, adenosine, and somatostatin receptorsreliably activated a potassium-selective conductance that wasinwardly rectifying and that was blocked by 1 mM external Ba²⁺. The conductance had identical properties to that activated byGABA_B receptors in the same cells. In one-half of the CA3 neuronsthat were tested, the metabotropic glutamate agonist 1S,3R-ACPDalso activated inwardly rectifying Ba²⁺-sensitive potassium current. Activation of the current by serotoninand adenosine agonists occurred with a time constant of 200-700msec after a lag of 50-100 msec; on removal of agonist the currentdeactivated with a time constant of 1-2 sec after a lag of 200-400msec. These kinetics are similar to GABA_B-activated current andconsistent with a direct action of G-protein on the channels.For somatostatin, both activation and deactivation were approximatelyfourfold slower, probably limited by agonist binding and unbinding.The half-maximally effective agonist concentrations were ~75 nMfor somatostatin, ~100 nM for serotonin, and ~400 nM for 2-chloroadenosine.Dose-response relationships had Hill coefficients of 1.2-1.9,suggesting cooperativity in the receptor-to-channel coupling mechanism.At saturating concentrations of agonists, the combined applicationof baclofen and either somatostatin, serotonin, or 2-chloroadenosineproduced effects that were subadditive and often completely occlusive.However, at subsaturating concentrations the effects of baclofenand 2-chloroadenosine were supra-additive. Thus, low levels ofdifferent transmitters can act synergistically in activating inwardlyrectifying potassium current.

Key words: serotonin; somatostatin; adenosine; baclofen; metabotropic glutamate receptor; GABA_B; GIRK

  INTRODUCTION

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Many neurons have inwardly rectifying potassium channels activated by neurotransmitters acting via G-proteins (Andrade etal., 1986; North et al., 1987; North, 1989). As with G-protein-activatedinward-rectifier potassium (GIRK) channels in cardiac atrial muscle,neuronal GIRK channels probably are activated by the direct bindingof $beta$ $gamma$ subunits of G-proteins (Reuveny et al., 1994; Wickman etal., 1994; Huang et al., 1995, 1997; Inanobe et al., 1995; Kofujiet al., 1995; Krapivinsky et al., 1995; Nakajima et al., 1996)(see Jan and Jan, 1997).

In many types of neurons, multiple G-protein-coupled receptors activate inwardly rectifying potassium current. The responseto the combined application of pairs of transmitters is sometimesno larger than the response to a single transmitter, suggestingshared elements in the coupling pathways used by different receptors(North and Williams, 1985; Andrade et al., 1986; North et al.,1987; Christie and North, 1988). So far, most experiments examiningthe combined application of agonists have used saturating concentrationsof agonists, partly because of the difficulty of controlling lowconcentrations in brain slice preparations. However, under physiologicalconditions the stimulation of G-protein-coupled receptors oftenmay involve lower concentrations of transmitters. In general,such receptors may not be localized in discrete postsynaptic sitesexposed to large concentrations of transmitter but may be exposedmore often to low levels of transmitters more diffusely released(Hille, 1992; Isaacson et al., 1993; Bunin and Wightman, 1998).It is therefore important to examine interactions between differentreceptors at low as well as at high concentrations.

Hippocampal pyramidal neurons are likely to be exposed to multiple transmitters, including glutamate, GABA, serotonin (Brownand Zador, 1990; Knowles, 1992), somatostatin (Kohler et al.,1987; Brown and Zador, 1990; Sivilotti and Nistri, 1991), andadenosine (Zetterstrom et al., 1982; Greene and Haas, 1985; Gordon,1986; Dunwiddie and Diao, 1994). Of these, GABA, serotonin, andadenosine have been found to activate inwardly rectifying potassiumcurrent in hippocampal pyramidal neurons (Segal, 1982; Gähwilerand Brown, 1985; Andrade et al., 1986; Trussell and Jackson, 1987;Alzheimer and ten Bruggencate, 1991; Beck et al., 1992; Thompsonet al., 1992; Okuhara and Beck, 1994; Lüscher et al., 1997).Somatostatin has not been reported to activate inwardly rectifyingpotassium current in hippocampal neurons but does so in otherneurons (Mihara et al., 1987; Inoue et al., 1988; North, 1989;Tatsumi et al., 1990; Takano et al., 1997) and modulates othercurrents in hippocampal neurons (Moore et al., 1988). Hippocampalneurons have G-protein-linked metabotropic glutamate receptorsthat modulate calcium channels (Swartz and Bean, 1992) and thatcan couple to GIRK channels in heterologous expression systems(Saugstad et al., 1996), but the activation of GIRK channels innative central neurons has not been reported.

Using a preparation of acutely isolated CA3 pyramidal neurons that allows for the application of transmitter with no metabolismor uptake, we have characterized the activation of inwardly rectifyingpotassium current by GABA_B, adenosine, serotonin, somatostatin,and metabotropic glutamate receptors. At subsaturating concentrations,GABA_B and adenosine agonists applied together showed supra-additiveeffects. Thus, shared elements in receptor-to-channel couplingcan produce cooperative effects of multiple transmitters at lowconcentrations.

  MATERIALS AND METHODS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Preparation of freshly dissociated neurons. Hippocampi from 7- to 12-d-old Long-Evans rats were dissected in ice-cold oxygenateddissociation solution containing (in mM) 82 Na₂SO₄, 30 K₂SO₄,5 MgCl₂, 10 HEPES, 10 glucose, and 0.001% phenyl red indicator,pH 7.4. Slices (400 µm) were cut with a tissue chopper and incubatedfor 9 min at 37°C in dissociation solution containing 3 mg/mlprotease (Type XXIII, Sigma, St. Louis, MO). Then the enzyme solutionwas replaced with dissociation solution containing 1 mg/ml trypsininhibitor and 1 mg/ml bovine serum albumin, and the slices wereallowed to cool to room temperature under an oxygen atmosphere.As cells were needed, slices were withdrawn, and the CA3 regionwas dissected out and triturated to release individual cells.Cells were placed in the recording chamber in Tyrode's solutioncontaining (in mM) 150 NaCl, 4 KCl, 2 CaCl₂, 2 MgCl₂, 10 glucose,and 10 HEPES, pH 7.4 with NaOH. Cells were used within 6-8 hrof slice preparation.

CA3 pyramidal neurons were identified morphologically on the basis of size and shape. Cells identified as pyramidal neuronshad a large pyramidal-shaped cell body (12-16 µm width, 20-36µm length) with a thick apical dendritic stump (4-6 µm width,18-24 µm length).

Whole-cell voltage-clamp recordings. Patch pipettes were pulled from 100 µl Boralex micropipettes (Dynalab, Rochester, NY).Pipette resistances ranged from 2 to 5 M $Omega$ when filled with internalsolution containing (in mM) 108 KH₂PO₄, 4.5 MgCl₂, 9 HEPES, 9EGTA, 14 creatine phosphate (Tris salt), 4 Mg-ATP, and 0.3 GTP(Tris salt), pH-adjusted to 7.4 with 135.4 mM KOH. The creatinephosphate, ATP, and GTP were added to the internal solution toprevent cell dialysis-induced run-down of GTP-dependent responses.Phosphates were added from 10× concentrated aliquots stored at $-$ 70°C. To prevent nucleotide hydrolysis, we kept the final internalsolution on ice after phosphates were added.

The use of EGTA may have helped in isolating GIRK currents by suppressing additional conductances that have been reportedwith some of the agonists used, many of which are activated bythe entry or release of internal Ca (Alzheimer and ten Bruggencate,1991; Uneyama et al., 1993; Wakamori et al., 1993; Rainnie etal., 1994; Harata et al., 1996).

Seals were formed, and the whole-cell configuration was obtained in bath Tyrode's solution. Then the cell was bathed by agravity-driven constant stream of external solution flowing throughmicrocapillary perfusion pipes positioned directly in front ofthe cell. The perfusion pipes consisted of a linear array of 12microcapillary tubes, with internal diameters of 200 or 250 µm,glued together side by side and fed from separate reservoirs.Solutions were changed by moving the perfusion pipes.

External recording solutions consisted of modified Tyrode's solution with 16 or 60 mM KCl, with KCl substituted for an equimolaramount of NaCl. Tetrodotoxin (TTX) was included at 2-3 µM in allsolutions to block sodium currents. All agonists were stored asconcentrated aliquots at $-$ 70 or $-$ 20°C and diluted into the recordingsolution on the day of the experiment. Whole-cell currents wererecorded with an Axopatch 200A patch-clamp amplifier, filteredat 2 kHz, digitized at 20-50 KHz, and stored by using a Digidata1200 interface and pClamp6 software (Axon Instruments, FosterCity, CA). Membrane potentials were corrected for a liquid junctionpotential (Neher, 1992) of $-$ 12 mV between the internal solutionand Tyrode's solution (in which the current was zeroed beforea seal was obtained).

Current-voltage curves. Current-voltage curves were determined by using voltage ramps 100 msec in duration. To smooth thevoltage signal, we low-pass-filtered it at 0.5 kHz (four-poleBessel filter) before applying the signal to the patch-clamp amplifier.The voltage was corrected for the delay resulting from the filtering.Agonist-induced currents were obtained by subtracting ramp currentsbefore and after the application of an agonist.

All statistics are given as the mean ± SEM.

  RESULTS

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Transmitter activation of inwardly rectifying potassium current

In all of the cells that were tested, multiple agonists reliably activated inwardly rectifying potassium current. Figure 1Ashows records from a typical dissociated CA3 pyramidal neuronexposed to baclofen, serotonin, the adenosine agonist 2-chloroadenosine,and the peptide hormone somatostatin. All four agonists elicitedinward current when they were applied at a holding potential of $-$ 92 mV. The current-voltage relationships, measured with voltageramps from $-$ 160 to $-$ 30 mV, were identical for the currents elicitedby baclofen, serotonin, 2-chloroadenosine, and somatostatin (Fig.1B). With 16 mM external potassium the current elicited by allfour agonists reversed at $-$ 51 mV, close to the predicted reversalpotential for a purely potassium-selective conductance ( $-$ 56 mV),and displayed strong inward rectification.

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Figure 1. Activation of inwardly rectifying potassium current by multiple agonists in CA3 neurons. A, Agonist-induced currents measured in a single neuron. Shown are inward currents elicited by 6-7 sec applications of 50 µM baclofen, 50 µM 2-chloroadenosine (2-CA), 30 µM serotonin, and 1 µM somatostatin applied at a holding potential of $-$ 92 mV, with 60 mM external K⁺. B, Current-voltage relationships for current elicited by baclofen (BAC; 50 µM), serotonin (5-HT; 1 µM), 2-chloroadenosine (2-CA; 10 µM), and somatostatin (SOM; 1 µM) in a single cell, with 16 mM external K⁺. Current was measured at voltages from $-$ 160 to $-$ 30 mV, varied by a voltage ramp lasting 100 msec. Each trace is the difference between current in an agonist (signal was averaged from 7-12 traces) and control current (signal was averaged from 8-15 traces). Reversal potential for all four agonist responses is $-$ 51 mV.

Activation of inwardly rectifying potassium current was quite reliable for each of the four agonists illustrated in Figure1. Baclofen induced current in 465 of 466 cells, serotonin in52 of 56 cells, 2-chloroadenosine in 66 of 67 cells, and somatostatinin 79 of 80 cells. Taking advantage of the ease and rapidity ofsolution exchange that was possible with the dissociated cellpreparation, we determined the dose-response relationship foreach agonist. Serotonin at concentrations of 30 nM and above consistentlygave measurable current, and 1 µM gave saturating effects. Figure2A shows the dose dependence of currents elicited in a singleneuron by various concentrations of serotonin. The dose-reponserelationship could be fit well with a half-maximally effectiveconcentration (EC₅₀) of 97 nM and a Hill coefficient of 1.5. Insix cells that were tested with serotonin from 1 nM to 10 µM,the average EC₅₀ was 93 ± 5 nM and the average Hill coefficientwas 1.3 ± 0.1. 2-Chloroadenosine activated substantial potassiumcurrent at concentrations $>=$ 100 nM (Fig. 2B), with an average EC₅₀of 376 ± 67 nM and a Hill coefficient of 1.2 ± 0.1 (n = 4). Somatostatinwas the most potent of the four agonists, activating measurablecurrent at concentrations of 10 nM and above, with an averageEC₅₀ of 75 ± 6 nM (n = 7). Somatostatin also had the steepestdose-response relationship, with an average Hill coefficient of1.9 ± 0.3. Baclofen had an average EC₅₀ of 3.3 ± 0.3 µM and anaverage Hill coefficient of 1.06 ± 0.04 (n = 9; Fig. 2D) (seeSodickson and Bean, 1996).

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Figure 2. Dose-response relationship for activation of potassium current (60 mM external K⁺) by serotonin (A), 2-chloroadenosine (B), somatostatin (C), and baclofen (D). The dose-reponse for each agonist was determined in a single cell, with responses normalized to the maximal response. The solid lines are the best least-squares fit to the logistic equation, 1/(1 + (EC₅₀/[agonist])ⁿ), where EC₅₀ is the half-maximally effective concentration and n is the Hill coefficient.

With the rapid application and removal of the agonist, the potassium current induced by baclofen or GABA has sigmoidal activationand deactivation kinetics (Sodickson and Bean, 1996) quite similarto the kinetics of synaptically elicited GABA_B responses (Otiset al., 1993). The kinetics of potassium current activation anddeactivation by serotonin, 2-chloroadenosine, and somatostatinwere also sigmoidal, with initial lags followed by rising andfalling phases that were fit well by a single exponential. Figure3A shows an example of current activated by a saturating concentrationof 2-chloroadenosine recorded with high time resolution. The agonistwas applied and removed in <20 msec by solenoid movement of thecell between two solutions (Sodickson and Bean, 1996). The generalkinetic characteristics of the current induced by 2-chloroadenosinewere similar to those of baclofen-activated current in the samecell (Fig. 3B), except that the lag before activation was longerfor 2-chloroadenosine (~100 msec) than for baclofen (~50 msec),as was the lag before deactivation (~600 msec for 2-chloroadenosineand ~150 msec for baclofen). After the initial lag the risingphase of 2-chloroadenosine-activated current could be fit wellby a time constant ( $tau$ ) of 0.85 sec, slower than the rising phaseof baclofen-activated current in the same cell ( $tau$ = 0.29 sec).Although baclofen-induced current declined or desensitized slightlyafter ~1 sec of exposure, 2-chloroadenosine-induced current didnot. On removal of the agonist the main phase of deactivation(after the initial lag) could be fit well by an exponential decline,with kinetics for 2-chloroadenosine ( $tau$ = 1.1 sec) very similarto those for baclofen ( $tau$ = 1.2 sec).

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Figure 3. Comparison of kinetics of current elicited by 2-chloroadenosine and baclofen in the same cell. A, Application of 10 µM 2-chloroadenosine. Superimposed lines are single exponentials with time constants of 0.85 sec (activation) and 1.1 sec (deactivation). B, Application of 50 µM baclofen. Superimposed lines are single exponentials with time constants of 0.29 sec (activation) and 1.2 sec (deactivation). Holding potential was $-$ 92 mV, with 60 mM external K⁺.

With all of the agonists the kinetics of activation were dependent on the agonist concentration. As the concentration wasraised, the activation kinetics were accelerated until a saturationpoint was reached. At saturating concentrations the activationtime constants were 217 ± 10 msec for baclofen (n = 10), 487 ±40 msec for serotonin (n = 25), 686 ± 60 msec for 2-chloroadenosine(n = 26), and 809 ± 92 msec for somatostatin (n = 37). The meandeactivation time constants were 1.1 ± 0.1 sec for baclofen (n= 38), 0.95 ± 0.07 msec for serotonin (n = 25 cells), 1.9 ± 0.1sec for 2-chloroadenosine (n = 26 cells), and 8.0 ± 0.5 sec forsomatostatin (n = 33 cells).

The similarity in current-voltage relationships and in kinetic properties suggests that all four agonists activate similarinwardly rectifying potassium channels and do so via similar couplingpathways. However, several of the agonists have been reportedto activate or increase various noninwardly rectifying potassiumcurrents, including calcium-activated potassium current (Wakamori,1993; Gerber and Gähwiler, 1994; Shirasaki et al., 1994) andM current (Moore et al., 1988). As a further test of whether eachagonist activated a single type of conductance under our conditions,we examined sensitivity to external barium, a potent blocker ofG-protein-activated inwardly rectifying potassium channels. Currentselicited by baclofen, serotonin, 2chloroadenosine, and somatostatinwere all inhibited reversibly by 1 mM Ba²⁺ applied externally (Fig. 4). In all cases both the inward andoutward current was blocked completely (n = 3 for each agonist).The completeness and lack of voltage dependence of the Ba²⁺ block, along with the other similarities, suggest that each transmitteractivates the same type of potassium channel and no other conductance.

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Figure 4. Complete block by Ba²⁺ of currents elicited by four different agonists in a single cell. A, Current elicited by 50 µM baclofen with and without 1 mM Ba²⁺. B, Current elicited by 1 µM serotonin with and without 1 mM Ba²⁺. C, Current elicited by 10 µM 2-chloroadenosine with and without 1 mM Ba²⁺. D, Current elicited by 1 µM somatostatin with and without 1 mM Ba²⁺. Each trace is the difference between the current in an agonist (signal was averaged from 7-12 traces) and the control current (signal was averaged from 8-15 traces). For determinations with Ba²⁺, 1 mM BaCl₂ was present in both the control and agonist-containing solutions; 16 mM external K⁺.

Activation of inwardly rectifying potassium current by metabotropic glutamate receptors

The metabotropic glutamate receptor agonist 1S,3R-1-aminocyclopentane-1,3-dicarboxylic acid (1S,3R-ACPD) was also capableof activating inwardly rectifying potassium current in CA3 pyramidalneurons, although it did so less reliably than the other fouragonists. Activation of current by 1S,3R-ACPD was observed in22 of 44 neurons tested. Figure 5A shows the activation of currentin an individual CA3 neuron by baclofen and 1S,3R-ACPD, determinedwith 60 mM external K⁺. Figure 5B compares the current-voltage relationships measuredfrom the same neuron. Like the baclofen-activated current, the1S,3R-ACPD response was strongly inwardly rectifying and reversedat $-$ 30 mV, close to the predicted potassium equilibrium potential( $-$ 21 mV). Figure 5C shows the effects of 1 mM external bariumon the 1S,3R-ACPD-activated inwardly rectifying current. Boththe inward and outward currents were blocked completely. In someneurons, multiple conductances appeared to be affected by 1S,3R-ACPD,because the current-voltage relationship for 1S,3R-ACPD-inducedcurrent sometimes had an additional component that appeared toreverse near 0 mV and was not inwardly rectifying (data not shown).This could correspond to the nonselective cation conductance reportedby Guerineau and colleagues (1995).

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Figure 5. Activation of inwardly rectifying potassium current by 1S,3R-ACPD. A, Effects of 50 µM baclofen and 200 µM 1S,3R-ACPD applied at a holding potential of $-$ 92 mV, with 60 mM external K⁺. B, Current-voltage relationships of the current elicited by 1S,3R-ACPD and baclofen (same cell as in A). C, Block of 1S,3R-ACPD-activated current by 1 mM external Ba²⁺. Each trace is the difference between the current in 1S,3R-ACPD and the control (signal was averaged from 5-11 traces). For determinations with Ba²⁺, 1 mM BaCl₂ was present in both the control and agonist-containing solutions; 16 mM external K⁺.

We also tested agonists to a variety of other receptors that have been reported to activate inwardly rectifying potassiumcurrent in various types of neurons. A number of such agonistsfailed to elicit responses in the dissociated CA3 pyramidal neurons.Among these were muscarine (0 of 15 cells), dopamine (0 of 13cells), platelet-activating factor (0 of 6), and the µ-opiateTyr-D-Ala-Gly-MePhe-Gly-ol (DAGO) (0 of 3 cells). Noradrenalineproduced an inward current at $-$ 92 mV in 4 of 30 neurons; however,the responses were very small, and we were not able to determineclear current-voltage relationships. Neuropeptide Y elicited inwardcurrent in 5 of 20 neurons. In three of the five cells the characteristicsof the neuropeptide Y-induced current were obviously differentfrom the inwardly rectifying potassium current elicited by otherreceptors. The development of current was very slow, with currentcontinuing to increase for many seconds, and the current reversednear 0 mV, far from the potassium equilibrium potential ( $-$ 21 mVunder the conditions of the experiment). We did not characterizethe neuropeptide Y-induced current further.

Interactions among agonists at saturating concentrations

We next examined interactions among the four receptors that reliably elicited inwardly rectifying potassium current, usingas agonists baclofen, 2-chloroadenosine, serotonin, and somatostatin.In the first set of experiments the agonists were applied at saturatingconcentrations (from 100 µM to 1 mM baclofen, 10-100 µM 2-chloroadenosine,1-5 µM serotonin, and 1-10 µM somatostatin). In cells that weretested with agonists for all four receptors, baclofen almost alwayselicited the largest current, as in Figure 1. The current elicitedby each of the other agonists applied to a given cell was stronglycorrelated with that elicited by baclofen, as shown in Figure6. The current elicited by a saturating concentration of 2-chloroadenosinewas typically ~70% of that elicited by baclofen (Fig. 6A), whereascurrents induced by somatostatin and serotonin were ~75 and ~40%,respectively, of the baclofen-induced current (Fig. 6B,C). Thestrong correlation between the magnitude of the currents inducedby the different agonists over a wide range of absolute currentlevels suggests either that levels of expression of the four differentreceptors are highly correlated or that current levels reflectthe expression levels of elements used in common, such as G-proteinsor potassium channels.

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Figure 6. Comparison of the magnitude of potassium current activated by saturating concentrations of baclofen, 2-chloroadenosine, serotonin, and somatostatin. Currents were elicited as in Figure 1 from a holding potential of $-$ 92 mV, with 60 mM external K⁺. A, Current elicited by 2-chloroadenosine (10-100 µM) is plotted as a function of that elicited by baclofen (100 µM) in the same cell. Each point represents a different cell. B, Current elicited by somatostatin (1-10 µM) versus that elicited by baclofen (100 µM) in the same cell. C, Current elicited by serotonin (1-5 µM) versus that elicited by baclofen (100 µM) in the same cell. The lines are the best fit of a straight line passing through the origin (fit in A has excluded outlying point at I_Baclofen = 2.2 nA). Correlation coefficients were 0.74 for 2-chloroadenosine/baclofen, 0.88 for somatostatin/baclofen, and 0.82 for serotonin/baclofen.

Andrade et al. (1986) found that simultaneous stimulation of serotonin and GABA_B receptors in hippocampal pyramidal neuronsactivated current no larger than that activated by GABA_B receptorsalone. We therefore examined the effects of simultaneous exposureto pairs of agonists in single CA3 neurons. First, we comparedthe activation of inward rectifier potassium current by saturatingconcentrations of agonists applied separately and together. Figure7 shows the effects in two different neurons of individual andsimultaneous applications of 100 µM baclofen and 10 µM 2-chloroadenosine.For the cell in Figure 7A, the response to simultaneous applicationwas completely occlusive with the baclofen response: the magnitudeof current elicited with baclofen plus 2-chloroadenosine was identicalto that of baclofen applied individually. For the cell in Figure5B, the response to simultaneous application was not completelyocclusive, but it was also far less than the sum of the responsesto each transmitter alone. In this and other cells the order inwhich baclofen, 2-chloroadenosine, or baclofen plus 2-chloroadenosinewas applied made no difference in the magnitudes of the responses.

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Figure 7. Nonadditivity of current activated by baclofen and 2-chloroadenosine. A, Currents in a neuron with complete occlusion between the effects of baclofen and 2-chloroadenosine. B, Responses in a different cell in which there was not complete occlusion. Dashed lines indicate the magnitude of response to baclofen alone. Dotted line indicates the sum of the responses to each agonist applied individually. Conditions are as in Figure 1.

Similar results were obtained with paired application of both somatostatin and serotonin with baclofen. In each case in somecells the effects of the combined transmitters were identicalwith those of baclofen applied alone (Figs. 8A, 9A). In othercells some additional current was elicited by the addition ofserotonin or somatostatin to baclofen, but the current elicitedby the combined transmitters was, with rare exceptions, significantlyless than the sum of the currents elicited by each transmitter.

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Figure 8. Nonadditivity of current activated by baclofen and somatostatin. A, Currents in a neuron with complete occlusion between the effects of baclofen and somatostatin. B, Responses in a different cell in which somatostatin elicited some additional current when applied together with baclofen. Dashed lines indicate the magnitude of response to baclofen alone. Dotted line indicates the sum of the responses to each agonist applied individually. Conditions are as in Figure 1.

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Figure 9. Nonadditivity of current activated by baclofen and serotonin. A, Currents in a neuron with complete occlusion between the effects of baclofen and serotonin. B, Responses in a different cell in which serotonin elicited some additional current when applied together with baclofen. Dashed lines indicate the magnitude of response to baclofen alone. Dotted line indicates the sum of the responses to each agonist applied individually. Conditions are as in Figure 1.

Figure 10 summarizes the degree of additivity for each pair of agonists seen in a number of cells. The degree of additivitywas quantified for each cell by calculating the fractional additivityas (I_Pair $-$ I_Max)/I_Min, where I_Pair is the current elicited byboth agonists applied simultaneously, I_Max is the response tothe single agonist giving the largest response (almost alwaysbaclofen), and I_Min is the response to the other agonist. Thus,1 corresponds to complete additivity and 0 to complete occlusionof the responses. Collected data were obtained from 20 cells forbaclofen/adenosine experiments, 10 cells for baclofen/somatostatinexperiments, and 10 cells for experiments with baclofen/serotonin.The fractional additivity varied from cell to cell. On average,it was smallest for somatostatin (0.15 ± 0.03, n = 10), for whichmost responses were nearly completely occlusive with baclofen.Both serotonin (0.53 ± 0.11, n = 10) and 2-chloroadenosine (0.36± 0.05, n = 20) showed more variability from cell to cell, fromcompletely occlusive to nearly additive.

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Figure 10. Fractional additivity of the responses to pairs of agonists at saturating concentrations. Fractional additivity of 2-chloroadenosine, somatostatin, and serotonin is expressed as (I_Pair $-$ I_Max)/I_Min, where I_Pair is the current elicited by both agonists applied simultaneously, I_Max is the current elicited by the agonist giving the largest response, and I_Min is the response to the other agonist. A completely additive response has a fractional additivity of 1, and a completely occlusive response has as a fractional additivity of 0. A, Pooled data from 20 neurons tested like those in Figure 7 with baclofen and 2-chloroadenosine. B, Pooled data from 10 neurons tested like those in Figure 8 with baclofen and somatostatin. C, Pooled data from 10 neurons tested like those in Figure 9 with baclofen and serotonin.

Interactions among agonists at subsaturating concentrations

Physiologically, it is likely that the exposure of cells to transmitters such as somatostatin, serotonin, or adenosine usuallyinvolves subsaturating concentrations of the transmitters. Wetherefore explored interactions among different agonist receptorsin activating inward rectifier potassium channels at subsaturatingconcentrations. For this purpose we tested submaximal concentrationsof baclofen and 2-chloroadenosine. Agonist concentrations werechosen to be approximately one-third of the EC₅₀. Figure 11 illustratesthe responses of a cell to 1 µM baclofen and 150 nM 2-chloroadenosineapplied separately and together. The current elicited with simultaneousagonist application was substantially larger (203 pA) than thesum (124 pA) of the currents elicited by baclofen (86 pA) and2-chloroadenosine (38 pA) applied alone. Thus, in contrast tothe subadditivity that was seen with pairs of agonists appliedat saturating concentrations, low concentrations applied togethergave supra-additive effects. The supra-additivity was quantifiedas 100 × [I_Bac+Aden $-$ [I_Bac + I_Aden]]/[I_Bac + I_Aden], thepercentage of "extra" current obtained with the pair of agonists.The order in which agonists were applied made no difference inthe supra-additivity. Supra-additive responses were obtained ineight of eight cells that were tested (Table 1), with an averagesupra-additivity of 32 ± 7% (range, 12-58%).

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Figure 11. Supra-additivity of responses to baclofen and 2-chloroadenosine at submaximal concentrations. Inward currents were elicited from a holding potential of $-$ 92 mV (60 mM external K⁺) with individual or simultaneous application of 1 µM baclofen and 150 nM 2-chloroadenosine. The dashed line represents the sum of the individual responses to baclofen and 2-chloroadenosine.


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Table 1. Comparison of currents evoked at subsaturating and saturating concentrations of baclofen and 2-chloroadenosine in eight cells

There was cell-to-cell variability in the degree to which there was occlusion at saturating concentrations of transmitters,and there was also cell-to-cell variability in the degree of supra-additivitythat was seen with low concentrations. We asked whether therewas any correlation between these two properties by testing thesame cells for both properties, with 2-chloroadenosine and baclofenapplied either alone or together at two different concentrationranges. The results are shown in Table 1. Cells showing moresupra-additivity at low concentrations tended to show less completeocclusion at saturating concentrations (sample correlation coefficient,0.84).

  DISCUSSION

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Baclofen, serotonin, somatostatin, and 2-chloroadenosine each reliably activated an inwardly rectifying conductance with highsensitivity to external barium. These similarities, along withthe occlusion frequently seen with saturating concentrations ofagonists, are consistent with the idea that the different receptorsactivate the same type of GIRK channel. The molecular compositionof G-protein-activated channels in hippocampal neurons is notyet known precisely, but the channels appear to contain GIRK2subunits, because baclofen- and adenosine-activated current isabsent in CA3 neurons from mice lacking the gene for GIRK2 channelsubunits (Lüscher et al., 1997) (see also Liao et al., 1996;Slesinger et al., 1996). The single-channel properties and theshape of the current-voltage curve of heterologously expressedGIRK1/GIRK2 channels (Velimirovic et al., 1996) resemble thoseof native G-protein-gated channels in neurons (Oh et al., 1995;Grigg et al., 1996) (see Fig. 1B). However, although native currentsare blocked with high affinity and no apparent voltage dependenceby external Ba²⁺ (see Fig. 4), Ba²⁺ block of GIRK1/GIRK2 channels occurs with lower affinity andis strongly voltage-dependent (Velimirovic et al., 1996).

Somatostatin has not been reported previously to activate inwardly rectifying potassium currents in hippocampal pyramidalneurons but, rather, to increase voltage-dependent M current (Mooreet al., 1988; Schweitzer et al., 1990). The potassium conductanceactivated by somatostatin in our experiments is clearly distinctfrom M current, because it is prominent at a steady holding potentialof $-$ 92 mV at which M current would not be activated and, unlikeM current, is strongly inwardly rectifying.

Dose-response

The use of isolated neurons allowed us to determine the sensitivity of hippocampal neurons to well defined concentrationsof serotonin, 2-chloroadenosine, and somatostatin. The EC₅₀ forserotonin (83 nM) is in the range of extrasynaptic serotonin evokedby brief stimuli in other CNS regions (Bunin and Wightman, 1998).The high sensitivity to serotonin is striking, because that determinedfrom hippocampal slice recordings was ~90-fold lower, with estimatedEC₅₀ values of 5-10 µM (Andrade and Nicoll, 1987; Okuhara andBeck, 1994). The lower sensitivity in slice recordings probablyreflects the reduction of serotonin concentrations at the neuronalsurface by efficient local uptake. A high sensitivity to serotonin(EC₅₀ = 30 nM) also was seen for the activation of potassium currentin dissociated dorsal raphe neurons (Penington et al., 1993).

2-Chloroadenosine, which is approximately equipotent with adenosine at A1 receptors, had an average EC₅₀ of 380 nM. [The IC₅₀of 660 nM for 2-chloroadenosine inhibition of synaptic transmissionin slice experiments is not much higher (Dunwiddie et al., 1986),consistent with the lack of uptake or metabolism.] Because adenosineis present in extracellular fluid at bulk concentrations of 140-200nM (Dunwiddie and Diao, 1994), even basal levels of adenosinemay produce significant activation of the current, as previouslysuggested (Haas and Greene, 1988; Dunwiddie and Diao, 1994). Theincreased levels of adenosine that are seen with seizure activityand during ischemia (Fowler, 1993) would be even more effective.Basal extracellular GABA also may be high enough to activate GIRKcurrent significantly (see Sodickson and Bean, 1996).

For serotonin, 2-chloroadenosine, and somatostatin the Hill coefficients for the dose-response curve were >1, as they arefor GABA (Sodickson and Bean, 1996). This suggests cooperativitysomewhere in the coupling mechanism. One step in the pathway knownto be cooperative is the activation of GIRK channels by $beta$ $gamma$ subunits,with reported Hill coefficients between 1.5 and 3 (Ito et al.,1992; Krapivinsky et al., 1995). This step would be in commonto all of the different receptors. However, the degree of cooperativityin the overall response might be different according to the exactstoichiometry of receptors, G-proteins, and channels, which mustbe somewhat different for each case.

Kinetics

The sigmoidal kinetics of activation and deactivation are consistent with a multi-step process consisting of agonist bindingto receptor, receptor activation of G-proteins, and G-proteinactivation of channels. Deactivation rates of baclofen- and serotonin-activatedcurrents ( $tau$ ~ 1 sec) and 2-chloroadenosine-activated currents( $tau$ ~ 2 sec) are similar to those of cloned GIRK channels coexpressedwith regulators of G protein signaling (RGS) proteins (Doupniket al., 1997). RGS proteins accelerate the GTPase activity ofG $alpha$ subunits, which may be rate-limiting (see Breitwieser and Szabo,1988; Doupnik et al., 1997), at least for the agonists with thefastest deactivation. The slower deactivation of somatostatin-activatedcurrents ( $tau$ ~ 8 sec) may reflect slower unbinding of this higher-affinityagonist. Interestingly, somatostatin had only slightly higherpotency (EC₅₀ = 67 nM) than serotonin (EC₅₀ = 97 nM) but had aneightfold slower rate of deactivation. Both binding and unbindingrates may be slow for somatostatin, a large molecule that mayneed to collide with its receptor in a particular conformation.

Metabotropic glutamate receptor activation of inwardly rectifying potassium channels

Metabotropic glutamate receptors can activate GIRK channels in heterologous expression systems (Saugstad et al., 1996), butsuch activation has not been seen previously in native centralneurons. The inwardly rectifying current activated by 1S,3R-ACPDthat we observed in CA3 neurons was essentially identical to thatactivated by the other agonists, suggesting that it is carriedby similar GIRK channels. From the rapid kinetics, it seems likelythat receptor-channel coupling is membrane-delimited, as in othercases of transmitter activation of GIRK channels. Metabotropicglutamate receptors in CA3 neurons also can activate differentpotassium channels that are not inwardly rectifying and requirea diffusible intracellular messenger (Premkumar and Chung, 1995).The activation of calcium-dependent potassium conductances byglutamate receptors (Rainnie et al., 1994; Imanishi et al., 1996)might be minimized in our experiments by the presence of internalEGTA.

Excitatory synaptic activation of potassium current in CA3 neurons has not been reported, even though the stimulation of metabotropicreceptors probably requires less glutamate than the activationof AMPA receptors (Swartz and Bean, 1992). Possibly metabotropicglutamate receptors are mostly extrasynaptic, as hypothesizedfor GABA_B receptors.

Simultaneous exposure to pairs of agonists

The cooperativity observed in potassium current activation when submaximal concentrations of baclofen and adenosine are appliedtogether indicates interactions at some level of their signalingpathways. The simplest interpretation is that the cooperativitywith combined transmitters has the same cause as that for cooperativitywith a single transmitter, as reflected by Hill coefficients >1for the dose-response curves. Most likely, individual potassiumchannels require the binding of multiple $beta$ $gamma$ subunits, and individualpotassium channels sense a pool of G-proteins that can be activatedby multiple receptors.

An important unresolved question is how many different activated G-proteins are accessible to a single K channel, and viceversa (see Neubig, 1994). At one extreme, receptor-G-protein-channelcomplexes might be so spatially restricted that each receptormolecule activates a separate pool of G-proteins and channel molecules.This can be ruled out, because different transmitters then wouldproduce additive responses at both saturating and subsaturatingconcentrations. At the other extreme, each K channel may be ina cluster of proteins that includes all possible transmitter receptorsas well as G-proteins. This may be closer to the actual situation.In cells with completely occlusive responses at saturating concentrationsof transmitters, the same channel molecules apparently can beactivated by receptor molecules for multiple transmitters. (Thesaturation could reflect limiting numbers of G-proteins ratherthan K channels, but if so, the same G-protein molecules probablywould affect a single pool of K channel molecules.) Because 2-chloroadenosine,serotonin, and somatostatin typically activated substantiallyless current than baclofen, some fraction of K channels apparentlycan be activated by GABA_B receptors, but not others. A model consistentwith the results in a typical cell is that ~30% of clusters haveonly GABA_B receptors and ~70% have GABA_B receptors together withadenosine and somatostatin receptors, of which approximately one-halfalso have serotonin receptors. In the uncommon cells in whichadding another transmitter to saturating baclofen activated substantialadditional current, there must be a fraction of clusters thatlack GABA_B receptors (or have too few GABA_B receptors to producemaximal activation of G-proteins and K channels even at saturatingbaclofen).

There was cell-to-cell variability in the extent of interaction among transmitters at both low and high concentrations. Forbaclofen and 2-chloroadenosine, greater supra-additivity at lowconcentrations was moderately correlated with less complete occlusionat saturating concentrations (Table 1). One possible interpretationis that, in cells with the most supra-additivity at low concentrations,the limiting factor within clusters is the number of G-proteins.Less occlusive responses at saturating agonist concentrationsand a high degree of cooperativity at low concentrations couldbe produced in clusters in which potassium channels are in excessof G-proteins and therefore are more sensitive to changes in thenumbers of activated G-proteins.

Regardless of its molecular basis, the supra-additivity seen at low concentrations of agonists may be significant physiologically.As already noted, basal extracellular levels of some transmittersin the hippocampus, including GABA and adenosine, may be highenough to produce some activation of inwardly rectifying potassiumcurrent in pyramidal neurons. Such effects would be enhanced bycooperativity in the action of multiple transmitters.

  FOOTNOTES

Received April 20, 1998; revised July 29, 1998; accepted Aug. 3, 1998.

This work was supported by National Institutes of Health (HL35034). We thank Dr. Gabriela Greif for helpful discussion.
Correspondence should be addressed to Dr. Bruce P. Bean, Department of Neurobiology, Harvard Medical School, 220 LongwoodAvenue, Boston, MA 02115.

Dr. Sodickson's present address is Volen Center, Brandeis University, 415 South Street, Waltham, MA 02254.

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Results
Discussion
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