Nicotinic Stimulation Produces Multiple Forms of Increased Glutamatergic Synaptic Transmission

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The Journal of Neuroscience, September 15, 1998, 18(18):7075-7083

Nicotinic Stimulation Produces Multiple Forms of Increased Glutamatergic Synaptic Transmission
Kristofer A. Radcliffe and John A. Dani
Division of Neuroscience, Baylor College of Medicine, Houston, Texas 77030-3498

  ABSTRACT

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Synaptic modulation and long-term synaptic changes are thought to be the cellular correlates for learning and memory (Madisonet al., 1991; Aiba et al., 1994; Goda and Stevens, 1996). Thehippocampus is a center for learning and memory that receivesabundant cholinergic innervation and has a high density of nicotinicacetylcholine receptors (nAChRs) (Wada et al., 1989; Woolf, 1991).We report that strong, brief stimulation of nAChRs enhanced hippocampalglutamatergic synaptic transmission on two independent time scalesand altered the relationship between consecutively evoked synapticcurrents. The nicotinic synaptic enhancement required extracellularcalcium and was produced by the activation of presynaptic $alpha$ 7-containingnAChRs. Although one form of glutamatergic enhancement lastedonly for seconds, another form lasted for minutes after the nicotinicstimulation had ceased and the nicotinic agonist had been washedaway. The synaptic enhancement lasting minutes suggests that nAChRactivity can initiate calcium-dependent mechanisms that are knownto induce glutamatergic synaptic plasticity. The results withevoked synaptic currents showed that nAChR activity can alterthe relationship between the incoming presynaptic activity andoutgoing postsynaptic signaling along glutamatergic fibers. Thus,the same information arriving along the same glutamatergic afferentswill be processed differently when properly timed nicotinic activityconverges onto the glutamatergic presynaptic terminals. Influencinginformation processing at glutamatergic synapses may be one wayin which nicotinic cholinergic activity influences cognitive processes.Disruption of these nicotinic cholinergic mechanisms may contributeto the deficits associated with the degeneration of cholinergicfunctions during Alzheimer's disease.

Key words: glutamate synaptic transmission; nicotinic acetylcholine receptors; hippocampal cultures; synaptic modulation; learning; memory

  INTRODUCTION

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Certain forms of the synaptic changes that are thought to underlie learning and memory (Madison et al., 1991; Aiba et al.,1994; Goda and Stevens, 1996; McHugh et al., 1996) can be influencedby cholinergic interaction with glutamatergic transmission (Ohnoet al., 1993; Maurice et al., 1994; Aigner, 1995). In vivo studieshave shown that cholinergic neurons contribute to arousal, attention,learning, and memory (Levin, 1992), but the synaptic events underlyingthose functions are poorly understood. It is known that the hippocampusreceives cholinergic innervation mainly from the medial septum-diagonalband complex (Kasa, 1986; Woolf, 1991; Alonso and Amaral, 1995;Yoshida and Oka, 1995). Choline acetyltransferase and acetylcholinesteraseshare a similar wide distribution in the hippocampus, supportingthe conclusion that there are dense cholinergic fibers in theinfrapyramidal layer. Ligand binding studies and in situ hybridizationfor nicotinic acetylcholine receptor (nAChR) subuinit-specificmRNA indicate that there is strong expression of the $alpha$ 7 and $beta$ 2subunits throughout the rat hippocampus, with weaker expressionof other subunits (Deneris et al., 1988; Wada et al., 1989; Ciminoet al., 1992; Dineley-Miller and Patrick, 1992; Séguéla et al.,1993).

Neuronal nAChRs are composed of five subunits that are arranged around a central cation-selection ion channel (Cooper et al.,1991; Unwin, 1995). Although many subtypes of nAChRs can be constructedfrom different subunit combinations, two main neuronal categoriescan be identified on the basis of their function and pharmacology.In heterologous expression systems most neuronal nAChRs are constructedfrom combinations of $alpha$ - and $beta$ -subunits (Conroy et al., 1992; Sargent,1993; McGehee and Role, 1995; Ramirez-Latorre et al., 1996; Roleand Berg, 1996; Wonnacott, 1997). Only $alpha$ 7, $alpha$ 8, and $alpha$ 9 can formhomo-oligomeric receptors that are inhibited by $alpha$ -bungarotoxin( $alpha$ -BGT), and only $alpha$ 7 is widely expressed in the mammalian brain(Couturier et al., 1990; Schoepfer et al., 1990; Bertrand et al.,1993; Séguéla et al., 1993). The function and complete compositionof native $alpha$ -BGT-sensitive nAChRs found in neurons are still understudy. These native $alpha$ -BGT receptors share properties with $alpha$ 7 homo-oligomericchannels expressed in oocytes, leading to the conclusion that $alpha$ 7 is among the subunits that comprise native mammalian $alpha$ -BGT-sensitiveneuronal nAChRs (Alkondon and Albuquerque, 1993; Amar et al.,1993; Anand et al., 1993; Séguéla et al., 1993; Castro and Albuquerque,1995; Flood et al., 1997).

Recently, it was found in both hippocampal slices and tissue culture that low concentrations of nicotine applied for minutescan increase the frequency of miniature EPSCs (mEPSCs; Gray etal., 1996) (also see Vidal and Changeux, 1993; McGehee et al.,1995; Lena and Changeux, 1997). That synaptic enhancement wasshort-lived, however, peaking and then declining while nicotinewas present. Furthermore, that weak nicotinic stimulation didnot induce the concerted activation of nAChRs that might be expectedduring cholinergic synaptic activity. In this study we used brief,strong agonist applications to activate nAChRs synchronously andfound that nicotinic stimulation can initiate multiple forms ofenhanced glutamatergic transmission in cultured rat hippocampalneurons.

  MATERIALS AND METHODS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Tissue culture. Hippocampal cell cultures were prepared as described previously (Zarei and Dani, 1994, 1995; Gray et al.,1996). Sprague Dawley rats (<3 d old) were anesthetized with halothaneand were decapitated. Hippocampi were dissected in ice-cold balancedsalt solution [BSS; containing (in mM) 1.8 CaCl₂, 0.81 MgSO₄,5.4 KCl, 140 NaCl, 5.55 D-glucose, and 5 HEPES with 0.01-0.1 gm/lphenol red, pH 7.3] and were incubated in a sterile enzyme solution(BSS supplemented with 1.5 mM CaCl₂, 0.5 mM EDTA, 0.2 mg/ml L-cysteine,and 20 U/ml papain) at 37°C in 5% CO₂ for 30 min with gentle rocking.The tissue was washed and dissociated by trituration in MEM supplementedwith 10% fetal bovine serum (FBS; HyClone Laboratories, Logan,UT), 10% horse serum (HS; Life Technologies, Gaithersburg, MD),20 mM glucose, 1 µl/ml serum extender (Mito +; Collaborative BiomedicalProducts), 50 U/ml penicillin/streptomycin (Life Technologies),2.5 mg/ml trypsin inhibitor, and 2.5 mg/ml BSA. Cells were platedat 70,000-450,000 cells/ml onto microislands (Bekkers and Stevens,1991) that were prepared by coating coverslips with a thin layerof 0.15% agarose. Then the slips were sprayed with a mixture of0.05 mg/ml poly-D-lysine and 0.25 mg/ml collagen, using a glassmicroatomizer. Cells were kept at 37°C in 5% CO₂ and fed 2-3 timesper week with MEM supplemented with 5% HS, 20 mM glucose, 50 U/mlpenicillin/streptomycin, 1 µl/ml serum extender, 10 mM MgCl₂,0-0.5 µM tetrodotoxin (TTX), 0-1 nM methyllycaconitine (MLA),and 0-0.5% w/v BSA and were studied between days 15 and 25. TTXand MLA were used often in the culture media to decrease synapticactivity that might have produced excitotoxicity or may have overlypotentiated the synapses before our electrophysiology studies.Glial proliferation was inhibited on days 3-5 by 5 µM cytosinearabinofuroside. Animal care was in accordance with institutionalguidelines.

Electrophysiology and solutions. Electrophysiology and solution exchange techniques were as we have described previously (Grayet al., 1996). Patch pipettes for patch-clamp recordings wereprepared from glass capillary tubing (Garner Glass, Claremont,CA), and currents were amplified and filtered at 1-2 kHz. Veryrapid agonist applications were achieved by using a linear arrayof flow pipes (375 µm inner diameter; Garner Glass) controlledby computer via valves (General Valve, Fairfield, NJ) in the solutionpathway. The distance between the flow pipe opening and the cellwas typically 100-150 µm, which produced rapid solution exchange(peak currents in <10 msec) and slower washout when the valvesclosed again (complete in ~200 msec). The five rapid nicotinicagonist applications that were used to increase the frequencyof mEPSCs were delivered at 8.5 sec intervals to allow the nAChRsto recover partially from desensitization. These agonist applicationsand all solution changes influenced all of the nAChRs on the surfaceof the voltage-clamped neuron and on the presynaptic terminalsfrom other neurons that formed synapses on the clamped neuron.For the studies of mEPSCs there were usually one to five neuronson the tissue culture microisland. Thus, any one or more of thoseneurons could have had vesicular glutamate release enhanced bythe nicotine application. This experimental condition led to ahigher probability of seeing nicotinic enhancement of mEPSC frequency.Electrical artifacts arising from valves were blanked from thetraces for display purposes.

An Axobasic program from the laboratory of Dr. Charles F. Zorumski (Washington University, St. Louis, MO) was adapted forthe off-line analysis of mEPSCs. To follow the minutes-scale enhancementof mEPSC frequency, we continually monitored synaptic activityfor many minutes before and following $approx$ 2 sec after the last offive rapid nicotine applications. These mEPSCs were collectedbefore nicotine arrived (as the control) and after the nicotinehad been washed off completely. Thus, the minutes-scale changesin mEPSC frequency continued well after the nicotine was removed.In this case the mEPSCs were collected into 15 sec bins for frequencyplots and into 3 pA bins for amplitude plots. The short-lastingseconds-scale enhancement of mEPSC frequency did not last longenough to follow with continuous recordings. This burst of mEPSCsimmediately followed a nicotine application. The acquisition ofthis seconds-scale enhancement of mEPSCs occurred during the protocolof the five nicotine applications. Therefore, this increased frequencyof mEPSCs was not grouped with and was on a very different timescale from the continuous recordings of synaptic events collectedbefore and after the nicotine applications. Baseline noise wasmonitored throughout the analysis at least every 102.4 msec. Datawere discarded from analysis for any one of several reasons: changesin leak after nicotine application, changes in baseline noisewhen comparing before with after nicotine application, poor signal-to-noiseratio for mEPSC analysis, and instability of the baseline frequencyof mEPSCs. CNQX (10 µM; 6-cyano-7-nitroquinoxaline-2,3-dione)with 1 mM MgCl₂ completely blocked the mEPSCs, indicating glutamatergictransmission. In some cases the mEPSC traces were filtered digitallyoff-line for clarity.

Solutions for the patch-clamp experiments were as follows: external (in mM), 150 NaCl, 0-5 CaCl₂, 0-2 MgCl₂, 2.5 KCl, 10 glucose,10 HEPES, 0-0.2 CdCl₂, and 0-0.1 picrotoxin plus 1 µM TTX, 1 µMatropine sulfate, and 0-1 µM strychnine, pH 7.3, 310-325 mOsm;internal solution in the patch pipette (in mM), 140 CsMeSO₃, 5NaCl, 2 Na₂ATP, 2 MgATP, 0-0.3 Na₃GTP, 0.2 EGTA, and 10 HEPES,pH 7.3, 300-310 mOsm. Picrotoxin was usually, but not always,present to inhibit GABAergic synaptic transmission to producemore quiet baselines for the mEPSCs. In some experiments the NMDAsubtype of glutamate receptors was inhibited by 50-250 µM AP-5,and 1 mM MgCl₂ was usually present. For the pharmacological characterizationof the rapid nicotinic currents, 10 µM CNQX was included to inhibitexcitatory synaptic transmission to allow for better visualizationof the nicotinic currents. Internal solutions often were supplementedwith an ATP-regenerating system (20 mM phosphocreatine and 60U/ml creatine phosphokinase) to decrease the rundown of nicotiniccurrents (Lester and Dani, 1994). Perforated patches (Rae et al.,1991) were used for all four experiments in Figure 2B (Gray etal., 1996).

  RESULTS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Seconds-scale enhancement of mEPSCs

Figure 1A shows a paradigm for enhanced vesicular release of glutamate that occurred on the time scale of seconds (secondsscale; Alkondon et al., 1996). After the application of 0.5 mMnicotine (or 1-3 mM acetylcholine) to activate nAChR currents,there was an immediate increase in the frequency of mEPSCs (n= 19 of 27 neurons). The mEPSCs were shown to be glutamatergicbecause they were inhibited completely by glutamate receptor antagonists,10 µM CNQX plus 100 µM AP-5 and/or 1 mM MgCl₂ (data not shown).During these experiments the voltage-gated sodium and calciumchannels were inhibited by 1 µM TTX and 200 µM CdCl₂, respectively.The burst of mEPSCs decayed back to the baseline frequency beforethe next nicotine application (8.5 sec later). The recovery canbe noted by the quiet baseline before each of the five applicationsof nicotine in Figure 1A.

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Figure 1. Nicotine-induced currents increase the frequency of mEPSCs on the seconds time scale. A, Applications of 0.5 mM nicotine (solid bar) activate nAChR currents that are followed by an abrupt increase in glutamatergic mEPSC frequency. Before the next nicotine application (8.5 sec) the mEPSC frequency declined to the baseline value, as can be seen by the quiet baseline before each nicotine application. B, To test for artifacts, we applied nicotine-free solutions (control) using the same solution/application methods. Five applications of the control solution (five traces are overlaid) did not increase the frequency of mEPSCs, but nicotine applied before (top five traces overlaid) and after (bottom three traces overlaid) the control did increase the frequency. C, In six separate attempts that are aligned (arrow, nic), 3-20 applications of nicotine did not increase the frequency of mEPSCs for this same neuron on the minutes time scale (15 sec/bin beginning 2 sec after the last nicotine application). The time taken for the nicotine applications is not shown. During the nicotine applications the mEPSC frequency increased on average 830%, but this seconds-scale increase did not last long enough to be observed by the recordings beginning 2 sec after the last nicotine application. The mEPSC frequency before the nicotine applications is normalized to one for plotting purposes. D, The amplitudes of the mEPSCs do not change after activating nAChR currents. Cumulative amplitude distributions were created from the mEPSCs before (open circles) each nicotine application and for the 400 msec after the nicotinic current (filled circles). The two distributions overlap.

The solution changes used to apply nicotine were extremely rapid, requiring computer-controlled valves. Therefore, we testedwhether the solution changes could be causing some unexpectedartifact, for instance, by deforming the membrane. To the sameneuron that was used in Figure 1A, we applied bath solution (control)by the same method used to apply nicotine (Fig. 1B). This controldid not increase the mEPSC frequency, but nicotine applicationsbefore and after the control did produce bursts of mEPSCs, indicatingthat the nicotinic currents underlie the seconds-scale frequencyincrease.

Nicotine was applied to this neuron in six separate series, with up to 20 nicotine applications per series. On a time scaleof seconds, each nicotine application increased mEPSC frequencyabove the baseline by an average of 830% ± 90% (±SEM). Despitethe burst of mEPSCs immediately after each nicotine application,there was no change in frequency seen on a longer time scale.In Figure 1C the six separate series of nicotine applicationsare aligned at the downward arrow. The time that it took for thenicotine applications is not shown. The normalized number of mEPSCswas collected into 15 sec bins, beginning $approx$ 2 sec after the lastnicotine application in each series. On that longer time scale,no increase in mEPSC frequency was observed because the briefincrease in mEPSC frequency had returned to baseline in much lessthan one bin.

Although the frequency of the mEPSCs was increased by nicotinic currents, the amplitudes were not. Figure 1D shows that theamplitudes of the mEPSCs were the same before the nicotine applicationsas they were during the peak of the increased frequency.

Most of the neurons (64%) displayed nicotinic currents. The vast majority of the responding neurons had currents with rapidactivation and desensitization kinetics (163 of 167 neurons),which are indicative of $alpha$ -BGT-sensitive nAChRs that contain the $alpha$ 7 subunit (Couturier et al., 1990; Alkondon and Albuquerque,1991, 1993; Alkondon et al., 1992; Zorumski et al., 1992; Séguélaet al., 1993; Zhang et al., 1994; Gray et al., 1996). Those nicotiniccurrents were inhibited completely by 50 nM $alpha$ -BGT (n = 9) or another $alpha$ 7-specific inhibitor, 5 nM MLA (n = 14). In all cases, when thenicotinic currents were inhibited, the seconds-scale enhancementof mEPSCs was prevented (Fig. 2A). Although the inhibition ofnicotinic currents by $alpha$ -BGT was irreversible during >1 hr of wash(n = 3), inhibition by MLA was reversed by washing for 5 min (n= 4; Fig. 2B).

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Figure 2. The nicotine-induced seconds-scale increase in mEPSC frequency has the pharmacology of $alpha$ 7-containing nAChRs and requires external calcium. A, A specific inhibitor of $alpha$ 7-containing nAChRs, 5 nM MLA, completely blocked the nicotine-induced currents (0.5 mM nic, solid bars) and prevented the mEPSCs that followed the nicotinic currents. B, Nicotinic currents were inhibited completely by 0.5 nM MLA (solid bar), but those currents recovered after being washed. The time course for inhibition and recovery of the nicotinic currents is shown (n = 4 neurons, ± SEM). The peak nAChR currents before MLA treatment were normalized to one to average currents from different neurons. C, In a solution containing 5 mM Ca²⁺, the frequency of mEPSCs increased after nicotinic currents were activated (0.5 mM, solid bar). In the same cell when the Ca²⁺ was absent (0 mM Ca²⁺), nicotine applications (solid bar) did not increase mEPSC frequency. D, In Ca²⁺-free and 5 mM Ca²⁺ solutions, the frequency of mEPSCs was measured in the same neurons (n = 4) immediately after nicotine-induced currents. The frequency of mEPSCs before nicotine was applied was normalized to one to combine results from different neurons. The frequency of mEPSCs increased only after nicotinic currents that were activated in the Ca²⁺-containing solution.

Previous research has shown that $alpha$ 7-containing nAChRs have a relatively high Ca²⁺ permeability (Vijayaraghavan et al., 1992; Séguéla et al.,1993; Pugh and Berg, 1994; Castro and Albuquerque, 1995); therefore,we tested whether external Ca²⁺ was required for the nicotinic enhancement of glutamate release.In Ca²⁺-free solutions the nicotine applications did not increase thefrequency of mEPSCs on the seconds time scale (n = 9). Furthermore,when nicotinic stimulation produced an increase in mEPSC frequency,if we then removed the external Ca²⁺, nicotinic currents could no longer increase the frequency ofmEPSCs on the seconds scale (n = 4; Fig. 2C). When compared withthe currents in 2 or 5 mM calcium, it was typical that the peaksof the nicotinic currents were smaller and the kinetics slowerin calcium-free solutions. This modulation of nicotinic currentsby external Ca²⁺ changes has been described previously (Mulle et al., 1992; Verninoet al., 1992; Amador and Dani, 1995; Bonfante-Cabarcas et al.,1996). This Ca²⁺ modulation was not the basis for preventing nicotine-inducedenhancement of mEPSC frequency, because even with large nicotiniccurrents the mEPSC frequency did not increase in calcium-freeexternal solutions. In Figure 2D the frequency of mEPSCs is normalizedto the rate before the nicotinic currents were activated separatelyin both 0 and 5 mM calcium (n = 4). Only when applied in the calcium-containingsolution did nicotine increase the frequency of mEPSCs.

Minutes-scale enhancement of mEPSCs

Synchronous activation of nAChR currents also could increase the frequency of mEPSCs on the time scale of minutes (minutesscale, Fig. 3A). Again these were glutamatergic mEPSCs that couldbe inhibited completely by 10 µM CNQX and 100 µM AP-5 and/or 1mM Mg²⁺. After monitoring the baseline frequency of mEPSCs for severalminutes, we rapidly applied 0.5 mM nicotine (or 1-3 mM acetylcholine)for five consecutive times to activate nAChRs (Fig. 3A, middlecurrent traces). The nicotine was applied for 200 msec and immediatelywashed away each time to allow 8.5 sec for recovery from desensitizationbefore the next application. After the fifth and last nicotineapplication the nicotine was washed away, and in 2 sec the recordingsof mEPSCs began again. During these experiments the voltage-gatedsodium and calcium channels were inhibited by 1 µM TTX and 200µM CdCl₂, respectively. The frequency of the mEPSCs (Fig. 3B),but not the amplitudes (Fig. 3C), increased on the minutes timescale (n = 10 of 27 neurons). The standard protocol for activatingnicotinic currents was five applications of agonist. When thatstimulation failed to increase the frequency of mEPSCs, more applicationsof nicotine sometimes could elicit an increase (n = 2 of 7 trials;Fig. 4). This result suggests that stronger stimulation is morelikely to achieve some threshold that is not reached by fewerapplications of agonist.

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Figure 3. Nicotine-induced currents increase the frequency of mEPSCs on the minutes time scale. A, Glutamatergic mEPSCs are shown before and after five applications of 0.5 mM nicotine. The nicotine-induced nAChR currents (middle five records) rapidly activated and desensitized. After each 200 msec nicotine application the nicotine was washed away rapidly to allow 8.5 sec for recovery from desensitization before the next application. Nicotine was not present when the mEPSC recordings recommenced 2 sec after the last nicotine application. B, The mEPSC frequency increased after activating the nAChR currents (arrow). After $approx$ 4 min, the frequency returned to the baseline. The mEPSC frequency before nicotine was normalized to a baseline of one (dotted line) so that experiments with different baseline frequencies could be averaged. The arrow indicates the five applications of 0.5 mM nicotine (13 trials from 10 neurons, ± SEM). The nicotine applications took $approx$ 35 sec, but that time gap is not shown. The continuous recording of mEPSCs was restarted within a couple of seconds after the last nicotine application. C, The amplitudes of the mEPSCs did not change after activating nAChR currents. Cumulative amplitude distributions were created from the mEPSCs before (open circles) and after (closed circles) the five nicotine applications. The two distributions overlap.

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Figure 4. A larger number of nicotine applications is more likely to increase the frequency of mEPSCs. Five applications of 0.5 mM nicotine (arrow, 5 nic) activated nAChR currents but did not increase the frequency of mEPSCs. However, 25 applications of nicotine (arrow, 25 nic) did increase the frequency. Representative recordings of mEPSCs are shown before nicotine (a), after five applications of nicotine (b), and after 25 applications of nicotine (c). The time course of the frequency of mEPSCs during the experiment is shown below, with letters indicating when the traces shown above the time course were collected. The time taken for the nicotine applications (arrows) is not shown.

Because the nAChR currents could be inhibited by MLA and then could recover during a 5 min wash, we used MLA to test whether $alpha$ 7-containing receptors mediated the minutes-scale increase inmEPSC frequency. MLA inhibited the nicotinic currents and theminutes-scale enhancement of mEPSC frequency (n = 7; Fig. 5A),but after MLA was washed away, nicotinic stimulation could increasethe frequency of mEPSCs (n = 1 of 3; Fig. 5B).

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Figure 5. The minutes-scale increase in mEPSC frequency shows the pharmacology of $alpha$ 7-containing nAChRs and requires external calcium. A, In the presence of 5 nM MLA (solid bar), five nicotine applications (arrow) did not increase the mEPSC frequency (n = 7). B, Five applications of nicotine (arrow) in the presence of 5 nM MLA (solid bar) did not enhance the mEPSC frequency, but five nicotine applications (arrow) after the washout of MLA did increase the frequency. C, In Ca²⁺-free solutions (0 or 50 µM Ca²⁺), nicotine applications (arrow, nic $-$ Ca) did not increase mEPSC frequency (n = 9). D, Five applications of nicotine in Ca²⁺-free solution (arrow, nic $-$ Ca) did not increase mEPSC frequency; however, in a solution containing 2.5 mM Ca²⁺, five nicotine applications (arrow, nic + Ca) did increase the frequency. The time taken for the nicotine applications is not shown.

The minutes-scale increase in mEPSC frequency required external calcium. When Ca²⁺ was removed from the external solution, nicotine stimulationno longer increased the frequency of mEPSCs (n = 9; Fig. 5C).However, after 1-2.5 mM Ca²⁺ was added back to the external solution in seven of the nineexperiments, the frequency could be increased (n = 2 of 7; Fig.5D).

Initially, we incorrectly thought that the seconds-scale increase in mEPSC frequency (see Fig. 1) was required to obtain thelonger minutes-scale form of glutamatergic enhancement (see Fig.3). We reasoned that inducing the minutes-scale effect requireda higher threshold of stimulation than was needed for the seconds-scaleenhancement. Although that simple threshold hypothesis may holdin some cases, it does not always apply. We found that 19 of 27neurons showed a seconds-scale increase in mEPSC frequency and10 of 27 showed the minutes-scale increase, but only 7 of 27 neuronsshowed both forms. Stated in an alternative manner, 12 of 27 neuronshad a seconds-scale increase without the minutes-scale form, and3 of 27 had a minutes-scale increase without the seconds-scaleform. Thus, the two forms of increased mEPSC frequency are notnecessarily linked, and it seems they can occur independentlyof each other.

Nicotinic currents affect evoked EPSCs

Nicotinic modulation also was observed during evoked glutamatergic synaptic transmission (eEPSC) at autaptic synapses or atsynapses between two coupled hippocampal neurons (see Mennerickand Zorumski, 1995, 1996). Pairs of voltage stimulations separatedby 100 msec were applied to the presynaptic neuron (Fig. 6A).Individual pairs of eEPSCs were separated by 16 sec. During that16 sec the nAChR currents could be activated by nicotine applications(Fig. 6A, arrowheads). The first currents of each eEPSC pair thatare displayed in Figure 6A are plotted as open circles in Figure6B. The solid bar indicates the period of time when nicotiniccurrents were being activated. The electrical stimulations duringthe nicotine-induced currents evoked larger glutamatergic eEPSCs.Figure 6B also shows the usual trend that the eEPSCs became steadilysmaller as the experiment progressed, as noted by the slight downwardslope of the eEPSC amplitudes. In the three cases in which itwas tested, a second set of nicotine applications coming at latertimes caused a smaller or no increase in the eEPSC amplitude (Fig.6B, second bar). On average, the amplitude of the first eEPSCof the pair increased by 46% ± 24% (n = 10 trials in 8 of 26 neurons).

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Figure 6. Nicotinic stimulation enhanced the amplitude of evoked EPSCs and altered the relationship between pairs of eEPSCs. A, The experimental paradigm was as follows: pairs of eEPSCs (100 msec apart) were measured every 16 sec before and during interleaved applications of 0.5 mM nicotine (arrowheads, nic). The nicotine applications were 8 sec apart. The nAChR currents decreased in size as the experiment progressed (in large part) because there was accumulative desensitization. Calibration: 0.5 nA, 0.4 sec. B, The amplitude of the first eEPSC is plotted versus time, and the solid bars indicate when nicotine applications were interleaved between the eEPSCs. The first 14 eEPSCs, which are shown in A, are plotted as open circles. The gradual decrease in the amplitude of the eEPSCs over the course of the experiment was common, but not always present. The second set of nicotine applications (second solid bar) induces a smaller increase in the amplitude of the eEPSCs. C, An example indicates the typical change in the relationship between the pairs of eEPSCs compared before nicotine (control) and during interleaved nicotine applications (nic). D, The average ratio of eEPSC2/eEPSC1 is plotted before (control) and at the maximum of the enhancement (with nic) for each experiment (n = 10). In every case the ratio decreased.

In addition to the increased amplitude of the first eEPSC, nicotine pulses also altered the relationship between the two eEPSCsof the pair (Fig. 6C,D). While obtaining the baseline eEPSCs,we occasionally saw paired-pulse facilitation (eEPSC2 > eEPSC1)(3 of 10). Usually, however, there was paired-pulse depression(eEPSC2 < eEPSC1) (Wu and Saggau, 1994; Mennerick and Zorumski,1995, 1996; Stevens and Wang, 1995). In all cases in which nicotineincreased the amplitude of the evoked currents, eEPSC1 increasedmore than eEPSC2 (Fig. 6D). The paired-pulse ratio (PPR) of theamplitudes (eEPSC2/eEPSC1) always decreased.

  DISCUSSION

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Nicotinic stimulation initiated multiple forms of enhanced glutamatergic synaptic transmission. In each case the effect ofnicotine was dependent on the presence of extracellular Ca²⁺ and occurred via the activation of presynaptic $alpha$ 7-containingnAChRs. Two apparently independent forms of modulation increasethe frequency of spontaneous miniature EPSCs. One form is on thetime scale of seconds, whereas the other is on the time scaleof minutes. Synchronous stimulation of nAChRs also can increasethe amplitude of evoked EPSCs. The enhanced evoked release ofglutamate continues for several minutes. On a much shorter timescale of 100 msec, nicotinic currents decrease the ratio of evokedpairs of EPSCs (PPR). The first evoked EPSC of a pair was increasedmore than the second eEPSC.

Role of presynaptic nAChRs

Previously published results and aspects of the present data indicate that presynaptic nAChRs are important. Nicotinic AChRslocated at presynaptic terminals or at preterminal locations havebeen shown to enhance the release of various neurotransmittersin tissue culture, brain slices, and synaptosomes (for review,see McGehee and Role, 1995; Role and Berg, 1996; Wonnacott, 1997).Particularly at GABAergic synapses, the activation of preterminalnAChRs is thought to depolarize the membrane locally, leadingto the activation of voltage-dependent channels that directlymediate the Ca²⁺ influx underlying enhanced GABA release (Lena et al., 1993; McMahonet al., 1994; Alkondon et al., 1997; Lena and Changeux, 1997).The agonist-induced effect mediated by preterminal nAChRs wasinhibited by TTX, which blocks Na channels and thereby preventsthe regenerative voltage activation of Ca²⁺ channels in the terminal. GABAergic terminals also can have nAChRs.In hippocampal cultures, evidence supports the conclusion thatpresynaptic nAChRs can affect GABA release much as they affectglutamate release (Radcliffe et al., 1998).

At glutamatergic synapses, low concentrations of nicotine were found to increase the frequency of mEPSCs and to elevate presynapticCa²⁺ via a TTX-insensitive mechanism (McGehee et al., 1995; Gray etal., 1996). In those cases, presynaptic $alpha$ 7-containing nAChRs werecapable of directly mediating a Ca²⁺ influx that initiated the enhanced glutamate release. It seemsextremely likely that nAChRs located on terminals and preterminalshave varying degrees of importance in regulating the release ofmany neurotransmitters in different areas of the brain (Vidaland Changeux, 1993; Alkondon et al., 1996; Albuquerque et al.,1997; Lena and Changeux; 1997; Wonnacott, 1997; Guo et al., 1998;Li et al., 1998).

In this study, presynaptic $alpha$ 7-containing nAChRs are capable of mediating the effects we observed. In all of our experimentsin which we measured mEPSCs, action potentials were blocked byTTX, and in most cases Cd²⁺ also was used to inhibit voltage-gated Ca²⁺ channels. The decrease in the PPR and the increase in the frequency,but not the amplitude, of the mEPSCs both suggest that the finalexpression of nicotinic stimulation resides presynaptically. Thatis not to say, however, that nAChRs located away from presynapticterminals or located postsynaptically are not important (see Wangand Kelly, 1997; Wonnacott, 1997). The hypothesis that the presentforms of nicotinic modulation reside presynaptically is consistentwith results from hippocampal slices showing that low concentrationsof nicotine directly increase the presynaptic concentration ofCa²⁺ (Gray et al., 1996) (also see Alkondon et al., 1996; Role andBerg, 1996; Wonnacott, 1997). The nicotine-induced Ca²⁺ influx was monitored with fura-2 from single mossy fiber presynapticterminals while inhibiting glutamate, Na⁺, and Ca²⁺ channels (Gray et al., 1996). The density and distribution ofnAChRs, particularly the highly Ca²⁺ permeable $alpha$ 7-containing receptors, will influence the strengthand type of synaptic modification initiated by cholinergic activity(see Moss and Role, 1993; Rathouz and Berg, 1994; Rathouz et al.,1995; Wilson Horch and Sargent, 1996; Ullian et al., 1997). Evidenceis accumulating that these mechanisms are active at many differenttypes of synapses, including GABA, 5-HT, ACh, dopamine, and norepinephrine,as well as the glutamatergic synapses that were examined here(for review, see McGehee and Role, 1995; Role and Berg, 1996;Albuquerque et al., 1997; Wonnacott, 1997).

Multiple time scales for nicotinic enhancement of mEPSC frequency

It is reasonable to hypothesize that the presynaptic action of calcium entering via $alpha$ 7-containing nAChRs contributes to theobserved increase in mEPSC frequency. On the seconds time scaleor when the changes in PPR are considered, nAChRs might providea sufficient local Ca²⁺ signal to increase directly the probability of vesicular releaseor to increase the availability of vesicles (Wu and Saggau, 1994;Stevens and Wang, 1995). On the minutes time scale, however, itis extremely unlikely that Ca²⁺ remains elevated during the enhanced release (see Zucker, 1993;Augustine et al., 1994; Delaney and Tank, 1994; Regehr et al.,1994; Liu and Tsien, 1995; Tank et al., 1995; Neveu and Zucker,1996). The data show that the enhanced release continued for minutesafter the nicotine had been washed away.

The forms of enhancement lasting minutes might require that the incoming calcium acts as a second messenger to modify indirectlyexocytotic processes leading to minutes-scale enhancement of synaptictransmission (Zucker, 1993; Augustine et al., 1994; Neveu andZucker, 1996). Previous studies of glutamatergic synaptic plasticity,such as short-term and long-term potentiation and depression,suggest mechanisms for synaptic changes that might be initiatedby nAChR activity (Kauer et al., 1988; Malgaroli and Tsien, 1992;Malenka and Nicoll, 1993; Stevens et al., 1994; Tong et al., 1996).It seems reasonable to anticipate that a properly localized Ca²⁺ influx mediated by nAChRs could initiate enzymatic activity thatis known to modify glutamatergic synapses under other circumstances.However, final verification of those mechanisms must await furtherexperimentation.

Nicotine also increased the amplitude of evoked EPSCs. This result indicates that the activation of nAChRs can modulate theresponsiveness of the presynaptic terminal to a subsequent actionpotential. The influx of Ca²⁺ through presynaptic voltage-gated channels in response to anaction potential normally increases the probability of releasingneurotransmitter. However, the presynaptic action potential doesnot guarantee release (Huang and Stevens, 1997). Therefore, theactivation of presynaptic nAChRs just before or during the arrivalof an action potential can increase the probability of successfulsynaptic transmission because the Ca²⁺ entry via the two pathways integrates in the presynaptic terminal.Consequently, properly timed nicotinic activity can increase thefidelity of particular synaptic events.

Not only can nicotinic activity change the amplitude of evoked EPSCs, but it also can alter the relationship between closelytimed synaptic events. Our results with eEPSCs show that nicotiniccholinergic activity can reverse the strength of paired eEPSCs.Without nicotinic activity the first eEPSC of a closely spacedpair is smaller, giving paired-pulse facilitation to the secondeEPSC. During nicotinic activity, however, that relationship reversesso that the first eEPSC of the pair can become substantially largerthan the second, giving paired-pulse depression. Thus, cholinergicstimulation mediated by nAChRs can alter the relationship betweenthe incoming presynaptic activity and outgoing postsynaptic signalingalong glutamatergic fibers. The same information arriving alongthe same glutamatergic afferents will be processed differentlywhen properly timed nicotinic activity converges onto the glutamatergicterminals. Early in the progression of Alzheimer's disease, cholinergicinputs degenerate and the number of hippocampal nAChRs decreases(Rinne et al., 1991; Nordberg, 1994; Perry et al., 1995). Thecognitive deficits associated with Alzheimer's disease could arise,in part, from loss of the cholinergic synaptic mechanisms thatmodulate the gain and fidelity of hippocampal synaptic transmission.Related mechanisms are also likely to be important elsewhere inthe brain.

  FOOTNOTES

Received April 1, 1998; revised June 11, 1998; accepted June 24, 1998.

This work was supported by grants from the National Institute of Neurological Disorders and Stroke (NS21229) and the NationalInstitute of Drug Abuse (DA09411). K.R. was supported in partby the William Stamps Farish Fund.
Correspondence should be addressed to Dr. John A. Dani, Division of Neuroscience, Baylor College of Medicine, Houston, TX77030-3498.

  REFERENCES

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

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