A Molecular Link between Inward Rectification and Calcium Permeability of Neuronal Nicotinic Acetylcholine alpha 3beta 4 and alpha 4beta 2 Receptors

QUICK SEARCH:

[advanced]

	Author:		Keyword(s):
Year:		Vol:		Page:

HOME | SEARCH | ARCHIVE | SUBSCRIBE | CONTACT | HELP

This Article

Abstract

Full Text (PDF)

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via Web of Science (31)

Citing Articles via Google Scholar

Google Scholar

Articles by Haghighi, A. P.

Articles by Cooper, E.

Search for Related Content

PubMed

PubMed Citation

Articles by Haghighi, A. P.

Articles by Cooper, E.

Previous Article  |  Next Article

The Journal of Neuroscience, January 15, 2000, 20(2):529-541

A Molecular Link between Inward Rectification and Calcium Permeability of Neuronal Nicotinic Acetylcholine $alpha$ 3 $beta$ 4 and $alpha$ 4 $beta$ 2 Receptors
Ali Pejmun Haghighi and Ellis Cooper
Department of Physiology, McGill University, Montréal, Québec, Canada H3G 1Y6

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Many nicotinic acetylcholine receptors (nAChRs) expressed by central neurons are located at presynaptic nerve terminals. Thesereceptors have high calcium permeability and exhibit strong inwardrectification, two important physiological features that enablethem to facilitate transmitter release. Previously, we showedthat intracellular polyamines act as gating molecules to blockneuronal nAChRs in a voltage-dependent manner, leading to inwardrectification. Our goal is to identify the structural determinantsthat underlie the block by intracellular polyamines and governcalcium permeability of neuronal nAChRs. We hypothesize that tworing-like collections of negatively charged amino acids (cytoplasmicand intermediate rings) near the intracellular mouth of the poremediate the interaction with intracellular polyamines and alsoinfluence calcium permeability. Using site-directed mutagenesisand electrophysiology on $alpha$ ₄ $beta$ ₂ and $alpha$ ₃ $beta$ ₄ receptors expressed inXenopus oocytes, we observed that removing the five negative chargesof the cytoplasmic ring had little effect on either inward rectificationor calcium permeability. However, partial removal of negativecharges of the intermediate ring diminished the high-affinity,voltage-dependent interaction between intracellular polyaminesand the receptor, abolishing inward rectification. In addition,these nonrectifying mutant receptors showed a drastic reductionin calcium permeability. Our results indicate that the negativelycharged glutamic acid residues at the intermediate ring form botha high-affinity binding site for intracellular polyamines anda selectivity filter for inflowing calcium ions; that is, a commonsite links inward rectification and calcium permeability of neuronalnAChRs. Physiologically, this molecular mechanism provides insightinto how presynaptic nAChRs act to influence transmitterrelease.

Key words: nicotinic acetylcholine receptor; presynaptic receptors; transmitter release; ion permeation; gating particles

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

A number of studies implicate cholinergic nicotinic receptors in a wide variety of cognitive functions, including visual andauditory processing, nociception, and attention and memory mechanisms(Piciotto et al., 1995; Bannon et al., 1998; Xiang et al., 1998;Marubio et al., 1999; Vetter et al., 1999). Many neurons expressnicotinic acetylcholine receptors (nAChRs) at synapses; at some,nAChRs are located postsynaptically and mediate fast excitatorysynaptic transmission, whereas at many others, nAChRs are locatedpresynaptically and facilitate neurotransmitter release (Clarke,1993; MacDermott et al., 1999). Functionally, neuronal nAChRshave two properties that make them suitable to influence transmitterrelease: they have high calcium permeability (McGehee and Role,1995), and they inwardly rectify, that is, they conduct inwardcurrents at negative potentials but do not conduct outward currentsat positive potentials (Mathie et al., 1990; Sands and Barish,1992; Ifune and Steinbach, 1993). Inward rectification providesan important mechanism to ensure that the receptors do not shortcircuit the action potential in the nerve terminal and reducetransmitterrelease.

That muscle nAChRs have relatively low permeability to calcium (Lewis, 1979; Adams et al., 1980) and do not show inward rectificationsuggests that calcium permeability and inward rectification gohand in hand for nAChRs. Interestingly, this relationship alsoholds for subtypes of glutamate receptors: AMPA/kainate receptorsthat have low calcium permeability show little inward rectification,whereas those that have high calcium permeability show stronginward rectification (Hume et al., 1991; Verdoorn et al., 1991;Dingledine et al., 1999). It is not fortuitous that these twoproperties correlate for AMPA/kainate receptors because the samestructural determinant affects both properties. The purpose ofthis study is to determine the structural element or elementsof neuronal nAChRs that influence calcium permeability and inwardrectification.

Nicotinic AChRs have three ring-like collections of charged residues on either side of the pore (extracellular, cytoplasmic,and intermediate rings) that influence ion conduction; the intermediatering is located at the narrowest region, or gate, of the poreand affects ion selectivity (Imoto et al., 1988; Cooper et al.,1991; Konno et al., 1991; Galzi et al., 1992; Bertrand et al.,1993; Wilson and Karlin, 1998). Previously, we demonstrated thatinward rectification of neuronal nAChRs, like glutamate receptors,results from a voltage-dependent block of the receptor pore byintracellular polyamines (Haghighi and Cooper, 1998a). Our hypothesisis that the cytoplasmic and intermediate rings form the site ofinteraction for intracellularpolyamines.

To test this hypothesis, we use a combined approach of site-directed mutagenesis of neuronal nAChR subunit cDNAs and two-electrodevoltage-clamp and patch-clamp techniques on recombinant receptorsexpressed in Xenopus oocytes. Our results indicate that the negativelycharged residues at the intermediate ring are essential for theinteraction of polyamines with $alpha$ 4 $beta$ 2 and $alpha$ 3 $beta$ 4 neuronal nAChRs.Furthermore, we show that these negatively charged residues influencethe calcium selectivity of the pore, indicating that a commonstructural element governs both inward rectification and calciumpermeability of neuronalnAChRs.

Some of our results have been presented previously (Haghighi and Cooper, 1998b).

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Site-directed mutagenesis
We designed two complementary oligonucleotide primers containing the substituted nucleotide or nucleotides corresponding toamino acids at the cytoplasmic or intermediate ring of $alpha$ 3, $alpha$ 4,and $beta$ 4 nAChR subunits, and used the Quick-Change Site-DirectedMutagenesis kit (Stratagene, La Jolla, CA) to mutate each subunit.Rat $alpha$ 3 and $beta$ 4 cDNAs were cloned into the pCDNA1 expression vector(Invitrogen, San Diego, CA), and chick $alpha$ 4 and $beta$ 2 (gifts from Dr.M. Ballivet, University of Geneva) were cloned into derivativesof pSV2.cat expression vectors (Cooper et al., 1991). For eachreaction, we mixed 5-50 ng of the wild-type plasmid and 125 ngof each of the two primers in a solution containing 5 µl of 10×reaction buffer (Stratagene), 1 µl of dNTP mix (Stratagene), and1 µl of pfu DNA polymerase (2.5 U/ml; Stratagene), diluted withdouble-distilled water to a final volume of 50 µl. The reactionmixture was then cycled in a PCR apparatus (PTC-100; MJ Research)according to the following protocol: 1 cycle at 95°C for 30 secfollowed by 12-18 cycles at 95°C for 30 sec, 55°C for 1 min, and68°C for 2 min. The following amino acids were mutated: $alpha$ 3: asparticacid (D) at position 237 to alanine (A) ( $alpha$ 3_D237A), glutamic acid(E) at position 240 to alanine ( $alpha$ 3_E240A), glutamine (Q) ( $alpha$ 3_E240Q)or aspartic acid (D) ( $alpha$ 3_E240D); $alpha$ 4: glutamic acid (E) at position242 to alanine ( $alpha$ 4_E242A) and glutamic acid at position 245 toalanine ( $alpha$ 4_E245A); $beta$ 4: aspartic acid at position 236 to alanine( $beta$ 4_D236A) and glutamic acid at position 239 to alanine ( $beta$ 4_E239A).All mutations were verified bysequencing.

Expression of nAChR subunit cDNAs in oocytes
Xenopus oocytes were defolliculated and prepared as described by Bertrand et al. (1991). We injected 1-3 ng of pairwise combinationsof cDNAs coding for neuronal nAChR subunits or 3-6 ng of pairwisemutant $alpha$ 4 and $beta$ 2 or $alpha$ 3 and $beta$ 4 into the nucleus of oocytes. Thisdifference in the amount of cDNA injection was to achieve sufficientlevels of expression for the mutant receptors. Oocytes were incubatedat 19°C for 2-7 d before recording. For single-channel experiments,the vitelline membrane surrounding the oocytes wasremoved.

Injection of BAPTA and spermine into the oocytes
To avoid the activation of the endogenous Ca²⁺-activated Cl currents in the presence of extracellular Ca²⁺, we injected oocytes 2-10 min before recording with BAPTA. Theinjection solution contained 100 mM BAPTA with 85 mM Na⁺, 2.5 mM K⁺, and 10 mM HEPES adjusted to pH 7.4 with NaOH. We injected between30 and 60 nl of this solution into oocytes, which correspondsto a concentration of ~5-7 mM in theoocytes.
To examine the effect of the increase in the intracellular concentration of spermine on the wild-type and mutant neuronalnAChRs, we injected oocytes with 60 nl of a solution containing(in mM): 100 spermine, 100 BAPTA, 85 Na⁺, 2.5 K⁺, and 10 HEPES adjusted to pH 7.4. In some recordings a thirdelectrode was used to inject spermine into the oocytes while undertwo-electrode clamp. In all spermine injection experiments, removalof Ca-activated Cl currents was used as an indication of successfulinjection.

Neuronal and myotube cultures
Superior cervical ganglia (SCGs) were dissected from neonatal Sprague Dawley rats (Charles River) and dissociated mechanicallyand enzymatically as previously described (McFarlane and Cooper,1992). Briefly, the ganglia were dissected under sterile conditionsfrom animals killed by cervical dislocation. The ganglia weredissociated at 37°C in collagenase (1 mg/ml, type I; Sigma, St.Louis, MO) for 15 min followed by dispase (2.4 mg/ml, grade II;Boehringer Mannheim, Indianapolis, IN) for 2-3 hr. Dissociatedneurons were washed with L-15 medium supplemented with 10% horseserum and plated onto laminin-coated (40 µg/ml, overnight at 4°C;gift of Dr. S. Carbonetto, McGill University) Aclar coverslips(Allied Chemicals, Clifton, NJ) in modified Petri dishes. Theneurons were incubated in 1.5 ml of L-15 medium supplemented with5% rat serum, vitamins, cofactors, penicillin, streptomycin, andsodium bicarbonate as described previously (Hawrot and Patterson,1979). The media was supplemented with nerve growthfactor.
We used a similar method to isolate neonatal rat myoblasts. Briefly, we dissected strips of pectoral muscles from neonatalrats and dissociated them in collagenase (1 mg/ml) for 15 minat 37°C. Myoblasts were incubated in 1.5 ml of L-15 medium supplementedwith 10% fetal calf serum. Myoblasts fused to form multinucleatedmyotubes 2-4 d after plating. All cultures were maintained at37°C in a humidified incubator with an atmosphere of 5% CO₂ and95%air.

Electrophysiology
Whole-cell recordings from oocytes. To measure the macroscopic ACh-evoked currents in oocytes, we used the two-electrode voltage-clamptechnique (Bertrand et al., 1991). These experiments were performedat room temperature (22-24°C) using a standard voltage-clamp amplifier(built by Mr. A. Sherman, McGill University). During the recordings,oocytes were superfused with control perfusion solution or agonistsolutions at 10-20 ml/min; switching from one solution to anotherwas done manually. Recording electrodes had tip diameters of 10-15µm and were filled with 3 M KCl. All mutant receptors, $alpha$ 3_D237A $beta$ 4, $alpha$ 3 $beta$ 4_D236A, $alpha$ 3_D237A $beta$ 4_D236A, $alpha$ 3_E240A $beta$ 4, $alpha$ 3_E240Q $beta$ 4, $alpha$ 3_E240D $beta$ 4, $alpha$ 3 $beta$ 4_E239A, $alpha$ 4_E242A $beta$ 2 and $alpha$ 4_E245A $beta$ 2, produced ACh-evoked currents when expressedin Xenopus oocytes. For equimolar injections of cDNAs, inwardcurrents at $-$ 90 mV were on average 8-12 times smaller for theintermediate mutant receptors or 2-3 times smaller for the cytoplasmicmutant receptors compared to those for the wild-type receptors.The half-maximal concentration (EC₅₀) for ACh was not significantlydifferent among the mutant and wild-typereceptors.
To measure the current voltage (I-V) relationships, we used a voltage ramp protocol applied within 2-4 sec after the inwardcurrent had reached its maximum amplitude; the speed of the rampwas 333 mV/sec. Voltage ramps were applied for 360-600 msec (correspondingto 120-200 mV), during which time no significant desensitizationwas observed. I-V curves were also obtained by measuring the ACh-evokedcurrents at different membrane potentials (steady-state I-V curves).Both current and voltage traces were monitored and stored foranalysis. Currents were sampled at 100-350 Hz on-line with a Pentiumpersonal computer (PC) (running at 60 MHz and an analog-to-digitalcard; Omega, Stamford, CT). The program PATCHKIT (Alembic Software,Montreal, Québec, Canada) was used for stimulation and dataacquisition.
External perfusion solution contained (in mM): 96 NaCl, 2 KCl, 1 Na₂H₂PO₄, 1 BaCl₂, and 10 HEPES, and 1 µM atropine; pH wasadjusted with NaOH to 7.4-7.5. For Ca²⁺ permeability measurements, we used a control solution containing1 mM CaCl₂ instead of BaCl₂ and compared the reversal potentialchange when we switched to a solution of either (in mM) 100 CaCl₂;10 CaCl₂ and 90 NaCl; 25 CaCl₂ and 75 NaCl; or 50 CaCl₂ and 50NaCl. All solutions were buffered by 10 mM HEPES and NaOH to apH of 7.4-7.5 and contained 1 µM atropine. Spermine (Sigma) wasadded to the control solution containing 1 mM BaCl₂ where indicated.Spermine was dissolved in sterile water, and aliquots were keptfrozen at $-$ 20°C.
Single-channel recordings from oocytes. Only oocytes that gave rise to large inward currents (>1 µA in response to 1 µM AChfor $alpha$ 4 $beta$ 2 expressing oocytes or in response 10 µM ACh for $alpha$ 3 $beta$ 4expressing oocytes when voltage-clamped at $-$ 40 mV) were used forsingle-channel recordings. Outside-out recordings were performedusing a List EPC-7 amplifier at room temperature (22-24°C) (Hamillet al., 1981). Pipette resistance ranged from 5 to 10 M $Omega$ for outside-outrecordings, and electrodes were coated with Sylgard (Dow Corning).Recordings were obtained in the continuous presence of ACh (0.1-0.2µM for $alpha$ 4 $beta$ 2 receptors and 1-10 µM for $alpha$ 3 $beta$ 4) in the recording bath.ACh-evoked single-channel activity gradually diminished afterexcision of the patch (in 2-5 min). Signals were digitized witha pulse code modulation (501; Sony, Tokyo, Japan) and stored onvideocassette recorder tapes. For off-line analysis, stored signalswere filtered at 1.5-2 kHz with an 8-pole Bessel filter (FrequencyDevices) and sampled at 10 kHz using a Pentium-60 PC. The programPATCHKIT was used for stimulation and dataacquisition.
External solution contained (in mM): 100 KCl, 1 CaCl₂, and 10 HEPES, and 1 µM atropine, and pH was 7.4 adjusted with KOH.Recording electrodes contained (in mM): 80 KF, 20 potassium acetate,10 HEPES, and 10 EGTA, and pH was adjusted to 7.4 with KOH. Sperminewas added to the intracellular solution whereindicated.
Whole-cell recordings from rat SCG neurons and cultured myotubes. Whole-cell patch-clamp recordings were performed at roomtemperature (22-24°C) using a List EPC-7 amplifier (Hamill etal., 1981). Throughout the recordings, cells were perfused withthe external solution at a rate of 1 ml/min. ACh was applied bypressure ejection from pipettes with tip diameters of 20-30 µm(Mandelzys et al., 1995). The resistance of patch pipettes rangedfrom 2 to 6 M $Omega$ , and 50-80% of the series resistance was compensated.For experiments with muscle nAChRs, we chose small multinucleatedmyotubes that had grown for 2-4 d inculture.
Both steady-state and ramp I-V curves were obtained for ACh-evoked macroscopic currents recorded from myotubes and SCG neurons.The speed of the voltage ramp protocol was 200-1000 mV/sec; voltageramps were applied 600 msec after the application of ACh and lastedfor 120-600 msec, during which time no significant desensitizationwas observed. Both current and voltage were monitored during therecordings and stored for analysis. Currents were filtered at1.5 kHz with an 8-pole Bessel filter, sampled at 2.5-5 kHz, displayedand stored on-line with a Pentium-60 PC. The program PATCHKITwas used for stimulation and dataacquisition.
External perfusion solution contained (in mM): 140 NaCl, 5.4 KCl, 0.33 NaH₂PO₄, 0.44 KH₂PO₄, 2.8 CaCl₂, 10 HEPES, 5.6 glucose,and 2 glutamine, and 0.5-1 µM TTX (Sigma) and 1 µM atropine; pHwas adjusted to 7.4. Acetylcholine iodide (Ach; Sigma) was dissolvedin the same external perfusion solution (100 µM for SCG neuronsand 20 µM for myotubes). Recording electrodes were filled withintracellular solution containing (in mM): 70 KF, 65 potassiumacetate, 5 NaCl, 1 MgCl₂, 10 EGTA, and 10 HEPES; pH was 7.4, adjustedwithKOH.

Analysis
Whole-cell ACh-evoked I-V curves were obtained by subtracting the current in response to a ramp voltage change in the absenceof agonist from that in the presence of agonist (Haghighi andCooper, 1998a). The G-V curves were obtained by plotting the cordconductance against voltage. The cord conductance was calculatedaccording to the following equation:

(1)

where G is the cord conductance corresponding to each membrane potential (V_m), I is the ACh-evoked current at the correspondingV_m, and E_rev is the reversalpotential.
To measure the amplitude of single-channel currents, we used either all-points histograms of open and closed distributionsor measured the amplitude of the channel openings individuallyusing PATCHKIT. Histograms were fit by Gaussian curves using Origin4.1 graphics software (MicrocalSoftware).
To quantify the voltage-dependent block by intracellular spermine, we fit the single-channel G-V relationships to a derivationof the Woodhull (1973) equation (Johnson and Ascher, 1990; Haghighiand Cooper, 1998a):

(2)

where

and G is the conductance in the presence of spermine at any given V_m, G_max is the maximum unblocked conductance, [S] is theinternal concentration of spermine for outside-out patches oris the equivalent free intracellular polyamine concentration neededto produce macroscopic rectification, K_d is the dissociation constantat a given V_m, K_d(0) is the dissociation constant at 0 mV, z isthe valence of spermine, $delta$ is the fraction of the membrane electricfield sensed by spermine, and F, R, and T have their usual meanings.To estimate the intracellular concentration of spermine, we fitthe macroscopic G-V curves to Equation 2 using the K_d(0) and $delta$ measured from the single-channelexperiments.
To measure the effect of increasing intracellular spermine, we fit the macroscopic G-V curves to the Boltzmann equation:

(3)

where V_1/2 is the membrane potential at which conductance (G) has reduced to half of the maximum conductance (G_max) and kis a slope factor corresponding to the amount of depolarizationneeded to change the conductance e-fold.
Dose-response curves for the effect of extracellular spermine were fit to a derivation of the logistic equation:

(4)

where IC₅₀ is the half-maximal inhibition dose, and [S] is the external concentration ofspermine.
To calculate P_Ca/P_Na, we measured the reversal potential of the I-V curves in external solutions containing different amountsof Ca²⁺ and used these values in a derivation of the Goldman, Hodgkin,and Katz (GHK) constant field voltage equation as presented byLewis (1979):

(5)

where

and P_X is the permeability coefficient of ion X, [X]_o is the extracellular concentration of ionic specie X, and R, T andF have their usual meanings. Concentration of each ion was multipliedby its corresponding activity coefficient (Robinson and Stokes,1960; Butler, 1968), and P_K/P_Na was 1.2 (our unpublished observations).I-V curves were fit to a ninth order polynomial function, andreversal potentials were measured by eye. We compensated for junctionpotentials caused by switching between differentsolutions.
The best fit to the data were achieved by minimizing $chi$ ² using a routine from Origin 4.1 graphics software that is based ona Levenberg-Marquardt algorithm. All data points are presentedas mean ± SEM. Statistical significance between values was examinedusing a paired Student's ttest.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Figure 1 highlights the difference in inward rectification among nAChR subtypes. Figure 1A shows the ACh-evoked whole-cellcurrent-voltage (I-V) relationship for native nAChRs expressedby neonatal rat sympathetic neurons from the SCG; these receptorsshowed strong inward rectification. Figure 1B shows the correspondingACh-evoked I-V curve for native nAChRs expressed by neonatal ratmyotubes. In contrast to nAChRs on SCG neurons, these muscle nAChRsshowed little inward rectification.

View larger version (21K):
[in this window]
[in a new window]
Figure 1. Inward rectification of neuronal nAChRs. A shows the ACh-evoked macroscopic current-voltage relationship (I-V curve) recorded from a neonatal rat SCG neuron. Whole-cell currents were recorded while the membrane potential was ramped from $-$ 80 to +60 mV (333 mV/sec). The I-V curve was obtained by subtracting the control current from the current evoked by 100 µM ACh. The I-V curve is fitted to a ninth order polynomial function and shows strong inward rectification. B shows the ACh-evoked macroscopic I-V curve recorded from a rat myotube (Ach, 20 µM). In contrast to A, this I-V curve shows no inward rectification. C shows a macroscopic ACh-evoked I-V curve for $alpha$ 4 $beta$ 2 neuronal nAChR, and D shows a macroscopic ACh-evoked I-V curve for $alpha$ 3 $beta$ 4 neuronal nAChR expressed in Xenopus oocytes. Similar to native nAChRs on SCG neurons, these recombinant receptors exhibit strong inward rectification. E and F show single-channel records obtained from outside-out patches expressing $alpha$ 4 $beta$ 2 or $alpha$ 3 $beta$ 4 receptors, respectively. In control patches, inward rectification of these receptors is lost. Addition of spermine (20 µM for $alpha$ 4 $beta$ 2 and 50 µM for $alpha$ 3 $beta$ 4) to the patch electrode blocks outward currents at positive potentials and reduces the amplitude of inward currents.

To further investigate the inward rectification of neuronal nAChRs, we studied recombinant receptors in Xenopus oocytes. Figure1, C and D, shows I-V curves for two neuronal nAChR subtypes: $alpha$ 4 $beta$ 2 receptors (Fig. 1C), made up of two subunits widely expressedin the CNS (Wada et al., 1989; Sargent, 1993; McGehee and Role,1995), and $alpha$ 3 $beta$ 4 receptors (Fig. 1D), made up of two subunits highlyexpressed in peripheral autonomic neurons (Boyd et al., 1988;Couturier et al., 1990; Mandelzys et al., 1994). Similar to nAChRson SCG neurons, the ACh-evoked I-V curves for both $alpha$ 4 $beta$ 2 and $alpha$ 3 $beta$ 4receptor exhibited strong inwardrectification.

Previously, we demonstrated that the strong inward rectification of $alpha$ 4 $beta$ 2 receptors results from a voltage-dependent blockof the receptor pore by intracellular polyamines (Haghighi andCooper, 1998a). A similar mechanism holds true for $alpha$ 3 $beta$ 4 receptors.Figure 1, E and F, show examples from single-channel experimentson $alpha$ 4 $beta$ 2 and $alpha$ 3 $beta$ 4 measured in outside-out patches; at positivepotentials (V_m), spermine blocked the outward current from boththese receptors when applied from the intracellular side. To determinethe affinity of $alpha$ 3 $beta$ 4 receptors for polyamines, we repeated thesesingle-channel experiments with four different spermine concentrationsranging from 0.1 to 100 µM on at least three different patchesfor each concentration and used a Woodhull (1973) model (see Materialsand Methods and Haghighi and Cooper, 1998a) to analyze this voltage-dependentblock (data not shown). From these experiments, we determinedthat the affinity of $alpha$ 3 $beta$ 4 receptors for spermine at 0 mV (K _d(0))was 6.7 ± 0.5 µM, approximately twofold higher than K_d(0) for $alpha$ 4 $beta$ 2 receptors (3.6 µM) (Haghighi and Cooper, 1998a); however,the proportion of the membrane field sensed by spermine ( $delta$ , 50-55%)was the same for both receptortypes.

We were interested to determine the site of interaction between intracellular polyamines and neuronal nAChRs. Because polyaminesare highly positively charged, a likely site for the interactionbetween neuronal nAChRs and intracellular polyamines is the negativelycharged region at the cytoplasmic side of the channel pore betweenM1 and M2. Figure 2 shows an amino acid alignment of this regionfor the four neuronal nAChR subunits: $alpha$ 3, $alpha$ 4, $beta$ 2, and $beta$ 4. Theregion between M1 and M2 contains five amino acids, two of whichare negatively charged and are in homologous positions for eachsubunit. The location of the five glutamic acids (E), correspondingto position 240 for $alpha$ 3, has been referred to as the intermediatering, and the site of the negatively charged aspartic acid residues(D) ( $alpha$ 3, $beta$ 2, and $beta$ 4) or E ( $alpha$ 4) closer to M1 has been referredto as the cytoplasmic ring (Imoto et al., 1988; Galzi et al.,1991; Karlin and Akabas, 1995). We hypothesized that these negativelycharged residues form the site of interaction for the positivelycharged polyamines. To test this, we mutated these residues toneutral amino acids, using site-directed mutagenesis, and examinedthe functional properties of these mutant receptors expressedin Xenopus oocytes.

View larger version (14K):
[in this window]
[in a new window]
Figure 2. Charged amino acids flanking the pore region are conserved in neuronal nAChRs subunits. This figure shows the amino acid sequence alignment of neuronal nAChR subunits $alpha$ 3, $alpha$ 4, $beta$ 2, and $beta$ 4 for the cytoplasmic end of M1, M1-M2 loop, M2 segment, and part of the M2-M3 loop. This alignment shows the presence of three ring-like accumulations of charged residues flanking M2: the cytoplasmic ring (corresponding to $alpha$ 3D237), the intermediate ring (corresponding to $alpha$ 3D240), and the extracellular ring (corresponding to $alpha$ 3E261).

Cytoplasmic ring mutations have little effect on inward rectification

First, we investigated the role of the cytoplasmic ring on the rectification of $alpha$ 3 $beta$ 4 receptors by mutating the D at this siteto alanine (A) for both $alpha$ 3 and $beta$ 4 subunits; we refer to thesemutant subunits as $alpha$ 3_D237A and $beta$ 4_D236A, respectively. We coexpressedpairwise combinations of mutant and wild-type $alpha$ 3 and $beta$ 4 cDNAsin Xenopus oocytes to produce three different receptors: $alpha$ 3_D237A $beta$ 4, $alpha$ 3 $beta$ 4_D236A, and $alpha$ 3_D237A $beta$ 4_D236A.

For each receptor, we obtained the macroscopic ACh-evoked I-V curve. To quantify the rectification, we measured the relativeconductance at four membrane potentials, $-$ 40 mV, +20 mV, +40 mV,and +80 mV to that at $-$ 90 mV. For $alpha$ 3_D237A $beta$ 4 or $alpha$ 3 $beta$ 4_D236A receptors,we observed no significant difference in rectification comparedto that for wild-type $alpha$ 3 $beta$ 4 receptors (Fig. 3A, Table 1). TheI-V curves for $alpha$ 3_D237A $beta$ 4_D236A receptors also showed strong inwardrectification up to +20 mV (Fig. 3B); however, at V_m greater than+25 mV, we observed significantly more outward current comparedto wild-type $alpha$ 3 $beta$ 4 receptors. The conductance at +40 mV and thatat +80 mV for $alpha$ 3_D237A $beta$ 4_D236A receptors were approximately 12 timesgreater than those for wild-type $alpha$ 3 $beta$ 4 receptors at these potentials.

View larger version (20K):
[in this window]
[in a new window]
Figure 3. Substitution of negatively charged residues of the intermediate ring abolishes inward-rectification of neuronal nAChRs. A shows an ACh-evoked macroscopic I-V curve obtained from an oocyte expressing the cytoplasmic ring mutant receptor $alpha$ 3 $beta$ 4_D236A. This mutant receptor exhibits inward rectification similar to the wild type $alpha$ 3 $beta$ 4 receptor. B shows an ACh-evoked macroscopic I-V curve obtained from an oocyte expressing the cytoplasmic ring mutant receptor $alpha$ 3_D237A $beta$ 4_D236A. C-F show ACh-evoked macroscopic I-V curves obtained from oocytes expressing intermediate ring mutant receptors $alpha$ 3 $beta$ 4_E239A, $alpha$ 3_E240A $beta$ 4, $alpha$ 3_E240Q $beta$ 4, or $alpha$ 4_E245A $beta$ 2. All four mutant receptors show a nearly linear ACh-evoked I-V relationship from $-$ 90 to +80 mV. Insets in each figure show ACh-evoked currents in response to a voltage ramp and demonstrate that the ACh-evoked currents do not show any significant desensitization. For all insets the length of the trace is 6 sec.


View this table:
[in this window]
[in a new window]
Table 1. The effect of mutations in the cytoplasmic and the intermediate ring on the macroscopic inward rectification and Ca²⁺ permeability of $alpha$ 4 $beta$ 2 and $alpha$ 3 $beta$ 4 nAChRs

In addition to $alpha$ 3 $beta$ 4 receptors, we investigated the role of the cytoplasmic ring on the rectification of $alpha$ 4 $beta$ 2 receptors. Wemutated the E at 240 to A for $alpha$ 4 ( $alpha$ 4_E242A) and coexpressed $alpha$ 4_E242Awith wild-type $beta$ 2 in Xenopus oocytes. We observed no significantdifference in the ACh-evoked I-V curves for $alpha$ 4_E242A $beta$ 2 receptorcompared to that for wild-type $alpha$ 4 $beta$ 2 receptors (Table 1).

Removal of negative charges at the intermediate ring abolishes inward rectification

Next, we investigated the role of the intermediate ring on the rectification of $alpha$ 3 $beta$ 4 receptors by mutating the E to A forboth $alpha$ 3 and $beta$ 4 subunits; we refer to these mutant subunits as $alpha$ 3_E240A and $beta$ 4_E239A, respectively. We coexpressed these mutantsubunits with wild-type $alpha$ 3 and $beta$ 4 in Xenopus oocytes to produceeither $alpha$ 3 $beta$ 4_E239A or $alpha$ 3_E240A $beta$ 4receptors.

These mutations in the intermediate ring had a dramatic effect on inward rectification. Figure 3C shows a result from an oocyteexpressing $alpha$ 3 $beta$ 4_E239A receptors. In contrast to wild-type $alpha$ 3 $beta$ 4receptors, the ACh-evoked I-V curve for $alpha$ 3 $beta$ 4_E239A receptors wasvirtually linear (Fig. 3C); the ACh-evoked current reversed atapproximately $-$ 10 mV (Fig. 3C), and our ion substitution experimentsindicated that this current was carried exclusively by cations(data not shown). We obtained similar results from >30 oocytesexpressing $alpha$ 3 $beta$ 4_E239A receptors. We measured the relative conductanceat $-$ 40 mV, +20 mV, +40 mV, and +80 mV to that at $-$ 90 mV (Table1); we observed no significant difference in conductance at eachpotential (Table 1). The conductance at +40 mV was 93% of thatat $-$ 90 mV, ~100 times greater than that of wild-type $alpha$ 3 $beta$ 4receptors.

Our results with $alpha$ 3 $beta$ 4_E239A receptors indicate that removal of the negative charge in the intermediate ring of $beta$ 4 abolishesthe strong inward rectification of $alpha$ 3 $beta$ 4 receptors. To determinethe effect of a similar mutation in the $alpha$ 3 subunit, we examinedthe rectification properties of $alpha$ 3_E240A $beta$ 4 receptors. The ACh-evokedI-V curve for $alpha$ 3_E240A $beta$ 4 receptors was almost linear, and the currentreversed at approximately $-$ 10 mV (Fig. 3D). The conductance at+40 mV was 79% of that at $-$ 90 mV, ~85 times greater than thatof wild-type $alpha$ 3 $beta$ 4 receptors (Table 1). These results indicatethat removal of the negative charge in the intermediate ring ofthe $alpha$ subunit is sufficient to abolish the strong inward rectificationof $alpha$ 3 $beta$ 4receptors.

To test the effect of different amino acid side chains at the intermediate ring on rectification, we mutated E at 240 to glutamine(Q) or aspartic acid (D) in $alpha$ 3 and coexpressed it with wild-type $beta$ 4. The ACh-evoked I-V curves recorded from $alpha$ 3_E240Q $beta$ 4 receptorswere essentially linear and not significantly different from thoseof $alpha$ 3_E240A $beta$ 4 receptors (Fig. 3E; Table 1). This demonstratesthat neutral amino acid substitution at the intermediate ringabolishes inward rectification regardless of the side-chain size.On the other hand, $alpha$ 3_E240D $beta$ 4 receptors inwardly rectified, althoughnot as strong as wild-type $alpha$ 3 $beta$ 4 receptors (Table 1), indicatingthat the size of the negatively charged side chain influencesthe degree ofrectification.

In addition, to test whether this effect on the rectification was specific to $alpha$ 3 $beta$ 4 receptors, we mutated E at the intermediatering to A in the $alpha$ 4 subunit and coexpressed it with wild-type $beta$ 2 in Xenopus oocytes. As shown in Figure 3F, these $alpha$ 4_E245A $beta$ 2receptors had almost linear I-V curves reversing at approximately $-$ 10 mV. The conductance at +40 mV was 79% of that at $-$ 90 mV, and~90 times greater than that of wild-type $alpha$ 4 $beta$ 2 receptors (Table1). These results demonstrate that, like $alpha$ 3 $beta$ 4 receptors, partialremoval of negatively charged residues in the intermediate ringabolishes strong inward rectification of $alpha$ 4 $beta$ 2receptors.

Elevated intracellular spermine increased inward rectification of $alpha$ 4 $beta$ 2 and $alpha$ 3 $beta$ 4 receptors, but had no effect on nonrectifying $alpha$ 4E245A $beta$ 2 and $alpha$ 3E240A $beta$ 4 receptors

Our results on intermediate ring mutations suggest that a decrease in the net negative charge of the intermediate ring abolishesthe interaction of intracellular polyamines with neuronal nAChRs.To further investigate this possibility, we examined the effectsof increasing the intracellular spermine concentration in Xenopusoocytes expressing either $alpha$ 4 $beta$ 2, $alpha$ 3 $beta$ 4, $alpha$ 4_E245A $beta$ 2, or $alpha$ 3_E240A $beta$ 4receptors. For most experiments, first we recorded the ACh-evokedI-V curve, then we injected the oocytes with spermine and repeatedthe I-V measurements at 2-3 min intervals. To verify that ourinjections worked, we included BAPTA along with spermine; in allinjected oocytes, BAPTA abolished calcium-activated chloride currentswhen we recorded the ACh-evoked current with 1 mM Ca²⁺ as the only divalent cation in the extracellular solution (seeMaterials and Methods). Alone, BAPTA had no effect on inward rectificationof wild-type or mutantreceptors.

For ACh-evoked currents from Xenopus oocytes expressing wild-type $alpha$ 4 $beta$ 2 or $alpha$ 3 $beta$ 4 receptors, we observed that intracellular injectionsof spermine caused a progressive increase in rectification, producingits maximal effect in ~10 min. Figure 4 shows example I-V curvesfrom $alpha$ 4 $beta$ 2 (Fig. 4A) and $alpha$ 3 $beta$ 4 (Fig. 4D) receptors before and afterspermine injection. Increasing intracellular spermine caused asignificant leftward shift in the ACh-evoked I-V and G-V curves,without affecting the ACh-evoked current amplitude at $-$ 90 mV orthe reversal potential (Fig. 4). To quantify the effect of increasingintracellular spermine, we fit the G-V curves to a Boltzmann equation(Eq. 3, see Materials and Methods) and determined V_1/2, the V_mwhere G was reduced to 50% of G_max, and k, the amount of depolarizationneeded to change the conductance e-fold. For $alpha$ 4 $beta$ 2, V_1/2 was shiftedto left by 16 ± 1.3 mV after spermine injection and for $alpha$ 3 $beta$ 4,V_1/2 was shifted to the left by 19 ± 2.4 mV; k decreased from14.5 ± 1.2 to 12 ± 1.5 mV for both $alpha$ 4 $beta$ 2 and $alpha$ 3 $beta$ 4.

View larger version (26K):
[in this window]
[in a new window]
Figure 4. Effect of increasing intracellular spermine. A shows macroscopic ACh-evoked I-V curves obtained from $alpha$ 4 $beta$ 2 receptors expressed in Xenopus oocytes. I-V curves were obtained before and 3 and 10 min after injecting 60 nl of a solution containing 100 mM spermine into the oocytes. B shows the G-V curves corresponding to the I-V curves in A. The solid lines are fits to the G-V curves using the Woodhull equation. The leftward shift in the G-V curve corresponds to an ~10-fold increase in intracellular spermine concentration. C shows macroscopic ACh-evoked I-V curves before and after injection of spermine recorded from an oocyte expressing $alpha$ 4_E245A $beta$ 2 receptors. There was no significant difference between the I-V curves before and after injection of spermine. D and E show the I-V and G-V curves from an oocyte expressing $alpha$ 3 $beta$ 4 receptors before and after injection with 60 nl of a solution containing 100 mM spermine. The solid lines are fits to the G-V curves using the Woodhull equation. The leftward shift in the G-V curve corresponds to an ~15-fold increase in intracellular spermine concentration. F shows the I-V curves for $alpha$ 3_E240A $beta$ 4 receptors before and after spermine injection. Similar to $alpha$ 4_E245A $beta$ 2 receptors, there was no significant difference between the I-V curves before and after injection of spermine.

To estimate the concentration of free spermine in oocytes after injection, we used the Woodhull equation (Eq. 2, see Materialsand Methods). Using values for k_d(0) and $delta$ for $alpha$ 4 $beta$ 2 (Haghighiand Cooper, 1998a) and $alpha$ 3 $beta$ 4 (Fig. 1), we solved the Woodhull equationto estimate the equivalent free intracellular polyamine concentration(see Materials and Methods) [S] that best described the macroscopicG-V curves. The solid lines in Figure 4, B and E, represents thebest fits to the Woodhull equation. Before spermine injections,[S] ranged from 70 to 80 µM in different oocytes (75.6 ± 1.6 µM;n = 37). For the oocyte expressing $alpha$ 4 $beta$ 2 receptors shown in Figure4B, injecting spermine increased [S] ~10-fold; for the oocyteexpressing of $alpha$ 3 $beta$ 4 receptors shown in Figure 4E, spermine injectionincreased [S] by ~15-fold. On average, spermine injection increased[S] by 10.1 ± 1.7-fold (n = 19). These results indicate that raisingfree intracellular spermine levels leads to stronger inward rectificationof $alpha$ 4 $beta$ 2 and $alpha$ 3 $beta$ 4 receptors, providing further evidence that inwardrectification of neuronal nAChRs results from a voltage-dependentblock by intracellular spermine (Haghighi and Cooper, 1998a).

Next, we investigated whether increased intracellular free spermine would be sufficient to confer inward rectification toACh-evoked currents for the intermediate ring mutant receptors.Figure 4 shows example I-V curves for $alpha$ 4_E245A $beta$ 2 (Fig. 4C) and $alpha$ 3_E240A $beta$ 4 (Fig. 4F) receptors before and after spermine injection.Increasing intracellular spermine caused no significant shiftin the ACh-evoked I-V or G-V curves for either receptor. Furthermore,increasing intracellular spermine had no effect on the ACh-evokedcurrent amplitudes or the reversal potential (Fig. 4C,F). We observedsimilar results from 26 of 26 oocytes. These results suggest thatthe reduction in the net negative charge at the intermediate ringdramatically decreases the affinity of intracellular polyaminesfor thereceptor.

Extracellular spermine blocks nonrectifying mutant receptors

To determine whether the intermediate ring mutations affected polyamine permeability, we performed ion substitution experiments.We expressed $alpha$ 4_E245A $beta$ 2 receptors in Xenopus oocytes and then measuredACh-evoked currents in the extracellular solution containing differentconcentrations of spermine. With spermine as the only conductingion in the extracellular solution, this mutant receptor failedto produce detectable ACh-evoked currents, even at $-$ 120 mV holdingpotential (data not shown). With an extracellular solution containing90 mM Na⁺ and 10 mM spermine, we found that spermine blocked >95% of theACh-evoked current without affecting the reversal potential. Wefound that the block by extracellular spermine had little voltagedependence and reversed relatively slowly (~80% in 3-5 min). Theseresults suggest that spermine has negligible permeability through $alpha$ 4_E245A $beta$ 2 receptors. To examine the block by extracellular spermine,we measured ACh-evoked currents at 3 min intervals after coapplicationof 1 µM ACh with increasing concentrations of spermine. Figure5A shows the spermine inhibition curves for $alpha$ 4 $beta$ 2 and $alpha$ 4_E245A $beta$ 2receptors; by first approximation, these curves can be describedby a logistic equation (Eq. 4). From the spermine inhibition curves,we obtained the IC₅₀ for mutant $alpha$ 4_E245A $beta$ 2 receptors (62.3 ± 13.3µM; n = 6) and wild-type $alpha$ 4 $beta$ 2 receptors (42.8 ± 5.7 µM; n = 8),which were not significantly different (p > 0.05).

View larger version (14K):
[in this window]
[in a new window]
Figure 5. Extracellular spermine blocks nonrectifying mutant receptors. A shows the dose inhibition curves for the effect of extracellular spermine on $alpha$ 4 $beta$ 2 and $alpha$ 4_E245A $beta$ 2, and B shows the dose inhibition curves for $alpha$ 3 $beta$ 4 and $alpha$ 3_E240A $beta$ 4. Data points were fitted to a logistic equation (see Materials and Methods). There is no significant difference in the block by extracellular spermine for all four receptors.

We repeated these measurements on wild-type $alpha$ 3 $beta$ 4 receptors and mutant $alpha$ 3_E240A $beta$ 4 (Fig. 5B). We observed no significant differencein the spermine inhibition curves between wild-type $alpha$ 3 $beta$ 4 (IC₅₀= 45.1 ± 7.2 µM; n = 5) and mutant $alpha$ 3_E240A $beta$ 4 receptors (IC₅₀ =65.4 ± 12.3 µM; n = 5) (Fig. 5B). We observed similar block byextracellular spermine for $alpha$ 3_E240Q $beta$ 4 and $alpha$ 3 $beta$ 4_E239A (data not shown).The cytoplasmic ring mutant, $alpha$ 3_D237A $beta$ 4_D236A, was also blockedby extracellular spermine in a similar manner (IC₅₀ = 43.8 ± 4.9µM; n = 5; data not shown). These results indicate that mutationsin the intermediate ring that abolish inward rectification havelittle effect on the block by extracellularspermine.

Relative calcium permeability

The Ca²⁺ to Na⁺ permeability ratios (P_Ca/P_Na) for neuronal nAChRs have been reported to range from 0.7 to 10 depending on thesubunit composition of the receptors (Sands and Barish, 1991;Adams and Nutter, 1992; Trouslard et al., 1993; Bertrand et al.,1993). Because the intermediate ring has been shown to influencepermeability of cations (Konno et al., 1991; Galzi et al., 1992;Corringer et al., 1999), we compared P_Ca/P_Na among wild-type andmutant $alpha$ 4 $beta$ 2 and $alpha$ 3 $beta$ 4 receptors expressed in Xenopus oocytes. Toavoid contaminating ACh-evoked currents with the endogenous Ca²⁺-activated chloride currents in these cells (Miledi and Parker,1984), we injected oocytes with BAPTA before our electrophysiologicalmeasurements (see Materials and Methods). In Figure 6A, we recordedthe ACh-evoked I-V curve from $alpha$ 3 $beta$ 4 receptors in control externalsolution (98 mM Na⁺, 2 mM K⁺, and 1 mM Ca²⁺) and repeated the measurement in a solution containing equimolarCa²⁺. In 100 mM Ca²⁺, we observed a rightward shift in the reversal potential of 3.6mV. From the modified GHK equation (Eq. 5; Lewis, 1979; see Materialsand Methods), we obtained an average P_Ca/P_Na of 0.78 ± 0.02 for $alpha$ 3 $beta$ 4 receptors (n = 8) (Table 1). We repeated these experimentswith external solutions of either 10 mM Ca²⁺ and 90 mM Na⁺, 25 mM Ca²⁺ and 75 mM Na⁺, or 50 mM Ca²⁺ and 50 mM Na⁺. We found that P_Ca/P_Na for $alpha$ 3 $beta$ 4 in all three solutions (n = 4at each concentration) was not significantly different from thatwhen we made equimolar substitutions of Na⁺ and K⁺ with Ca²⁺. We observed a significant reduction of ACh-evoked currents whenCa²⁺ in the external solutions was >25 mM (Fig. 6A); this observationis consistent with the decrease in single-channel conductancefor neuronal nAChRs when Ca²⁺ is the main charge carrier (Adams and Nutter, 1992; Mulle etal., 1992; Vernino et al., 1992).

View larger version (20K):
[in this window]
[in a new window]
Figure 6. Substitution of the negatively charged residues of the intermediate ring with neutral amino acids drastically reduces Ca²⁺ permeability of $alpha$ 4 $beta$ 2 and $alpha$ 3 $beta$ 4 receptors. A and B show I-V curves for $alpha$ 3 $beta$ 4 and $alpha$ 4 $beta$ 2 receptors expressed in Xenopus oocytes, respectively. Switching from the control solution to one containing 100 mM Ca²⁺ causes a rightward shift of the reversal potential for both receptors. C shows ACh-evoked I-V curves for the mutant $alpha$ 3_D237A $beta$ 4_D236A receptor in the presence of the control solution and one containing 100 mM Ca²⁺. Switching to 100 mM Ca²⁺ causes a rightward shift of the reversal potential, similar to that observed for $alpha$ 3 $beta$ 4 wild-type receptor. D-F shows I-V curves for $alpha$ 4_E245A $beta$ 2, $alpha$ 3_E240Q $beta$ 4, and $alpha$ 3 $beta$ 4_E239A, respectively. Switching to 100 mM Ca²⁺ causes a significant leftward shift in the reversal potential for all three receptors, indicating low relative Ca²⁺ permeability for these receptors.

We also measured P_Ca/P_Na for $alpha$ 4 $beta$ 2 receptors (Fig. 6B). After switching the control external solution to 100 mM Ca²⁺, we observed an average rightward shift in the reversal potentialof 15.5 ± 0.28 mV (n = 8); from the GHK equation we calculatedan average P_Ca/P_Na of 1.65 ± 0.15 for $alpha$ 4 $beta$ 2 receptors (n = 8),approximately twice that for $alpha$ 3 $beta$ 4 receptors (Table 1). We repeatedthese experiments with an external solution of 10 mM Ca²⁺ and 90 mM Na⁺ and found similar values for P_Ca/P_Na (n = 6). Consistent withthe higher value for $alpha$ 4 $beta$ 2, we found that we needed to pre-injectgreater amounts of BAPTA to ensure that we did not activate Ca²⁺-activated chloridecurrents.

Next, we investigated whether mutations of negatively charged residues at the cytoplasmic and intermediate ring alter therelative calcium permeability of $alpha$ 4 $beta$ 2 and $alpha$ 3 $beta$ 4 receptors. Afterswitching the control external solution to 100 mM Ca²⁺, we observed a rightward shift in the reversal potential for $alpha$ 3_D237A $beta$ 4_D236A receptors similar to that for $alpha$ 3 $beta$ 4 (Fig. 6C, Table1). We obtained similar results in six of six oocytes expressing $alpha$ 3_D237A $beta$ 4_D236A receptors (Table 1). These results indicate thatthe negatively charged residues of the cytoplasmic ring have littleinfluence on calciumpermeability.

We tested whether mutations of charged residues at the intermediate ring alter calcium permeability by measuring P_Ca/P_Na formutant $alpha$ 3_E240A $beta$ 4, $alpha$ 3_E240Q $beta$ 4, $alpha$ 3 $beta$ 4_E239A, and $alpha$ 4_E245A $beta$ 2 receptors.Figure 6D-F shows example I-V curves for $alpha$ 3_E240Q $beta$ 4, $alpha$ 3 $beta$ 4_E239A,and $alpha$ 4_E245A $beta$ 2 receptors with either Na⁺ or Ca²⁺ as the main charge carrier. After substituting Na⁺ and K⁺ in the external solution with 100 mM Ca²⁺, we observed a significant leftward shift in the I-V curves forall four intermediate ring mutant receptors (Table 1). Usingthe GHK equation (Eq. 4), we calculated that these intermediatering mutations reduced P_Ca/P_Na by 13- to 18-fold for $alpha$ 3 $beta$ 4 receptorsand >25-fold for $alpha$ 4 $beta$ 2 receptors (Table 1). Our results indicatethat the negatively charged residues of the intermediate ringconstitute a common site that governs both inward rectificationand Ca²⁺ permeability of $alpha$ 3 $beta$ 4 and $alpha$ 4 $beta$ 2nAChRs.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Our results add to our previous findings that strong inward rectification of neuronal nAChRs results from a voltage-dependentblock by intracellular polyamines (Haghighi and Cooper, 1998a).We show that $alpha$ 3 $beta$ 4 receptors have a K_d(0) for intracellular spermineof 6.7 µM, similar to the K_d(0) for $alpha$ 4 $beta$ 2 receptors (3.6 µM). Normally,vertebrate cells have free intracellular spermine concentrationsof 20-100 µM (Seiler and Schmidt-Glenewinkel, 1975; Watanabe etal., 1991; Ficker et al., 1994); this is more than sufficientto block these neuronal nAChRs. Furthermore, we show that increasingfree spermine concentrations 10- to 15-fold increases this rectificationby shifting the G-V curves toward more hyperpolarized potentials.These results provide further evidence that inward rectificationof neuronal nAChRs results from a voltage-dependent block by intracellularpolyamines (Haghighi and Cooper, 1998a).

We find that mutating the negatively charged glutamic acid residues of the intermediate ring to neutral amino acids removesrectification of $alpha$ 4 $beta$ 2 and $alpha$ 3 $beta$ 4 receptors. This is also the casefor homomeric $alpha$ 7 receptors (Forster and Bertrand, 1995). The I-Vcurves of mutant $alpha$ 4_E245A $beta$ 2, $alpha$ 3_E240A $beta$ 4, and $alpha$ 3 $beta$ 4_E239A receptorsare essentially linear, showing very little voltage dependence.The dramatic reduction of inward rectification after alanine substitutionresults from the lack of charge of alanine and not from its shorterside chain length because we observed identical results with $alpha$ 3_E240Q $beta$ 4receptors.

Because $alpha$ 4 $beta$ 2 and $alpha$ 3 $beta$ 4 receptors have pentameric structures composed of two $alpha$ subunits and three $beta$ subunits (Cooper et al.,1991), we took advantage of this known subunit stoichiometry toinvestigate the number of negatively charged residues in the intermediatering necessary for inward rectification. We demonstrate that mutatingthe negatively charged glutamic acid at the intermediate ringof either the $alpha$ or the $beta$ subunit removes rectification of $alpha$ 4 $beta$ 2and $alpha$ 3 $beta$ 4 receptors. Therefore, we conclude that removal of onlytwo negative charges is sufficient to disrupt the interactionof intracellularpolyamines.

Interaction between polyamines and neuronal nAChRs

To explain our results, we propose that the intermediate ring forms a high-affinity binding site for intracellular polyamines;polyamines are attracted to this site under the influence of themembrane electrical field and are held there through an electrostaticinteraction with the negatively charged glutamic acids. Becausethe intermediate ring is at the narrowest part of the pore (Wilsonand Karlin, 1998), polyamines at this site occlude the pore preventingthe flow ofions.

Our model assumes that polyamines have negligible permeation through the pore. Consistent with this, our experiments on theeffects of extracellular polyamines indicate that polyamines permeatethe channel very poorly. We find that extracellular spermine blocks $alpha$ 4_E245A $beta$ 2, $alpha$ 3_E240A $beta$ 4, $alpha$ 3_E240Q $beta$ 4, and $alpha$ 3 $beta$ 4_E239A receptors in asimilar manner to wild-type receptors. At 70-80 µM, concentrationssimilar to that of the cytoplasm, spermine blocks >50% of theACh-evoked current at all membrane potentials, and at 800-1200µM spermine blocks 80-90% of the current. This indicates thatspermine has difficulty crossing the pore and likely interactswith polar and nonpolar amino acid side chains in M2 (Cui et al.,1998). If intracellular spermine could access the pore in thenonrectifying mutant receptors, we would expect it to block thechannel, similar to extracellular spermine. However, even increasingintracellular spermine several fold had no effect on ACh-evokedI-V curve for the nonrectifying, intermediate ring mutant receptors.Therefore, it is likely that $alpha$ 4_E245A $beta$ 2, $alpha$ 3_E240A $beta$ 4, $alpha$ 3_E240Q $beta$ 4,and $alpha$ 3 $beta$ 4_E239A receptors do not rectify because the intermediatering, with a lower net negative charge, no longer forms a high-affinitybinding site forpolyamines.

The region between M1 and M2 has two rings of negatively charged residues; however, the intermediate ring appears to be themajor site of interaction between intracellular polyamines andthe pore. Removing the negative charges at the cytoplasmic ringof either the $alpha$ or $beta$ subunit has no significant effect on inwardrectification. Even receptors with mutations at the cytoplasmicring of both $alpha$ and $beta$ subunits inwardly rectify, although thesereceptors do conduct outward current at membrane potentials greaterthan +25 mV; this suggests that the cytoplasmic ring also interactswith intracellular polyamines. Because spermine is approximately20 A° long (Araneda et al., 1999) and could span both rings, wespeculate that the cytoplasmic ring helps stabilize polyaminesat the mouth of the pore; without these five negatively chargedresidues, intracellular K⁺ ions destabilize the interaction of polyamines with the receptorat large depolarizations and flow out through the channel. Thismodel has similarities to one proposed for polyamine block ofAMPA receptors (Washburn et al., 1997).

Comparison to AMPA/kainate receptors

Inward rectification of calcium-permeable AMPA/kainate receptors is mediated by a voltage-dependent block by polyamines witha comparable K_d(0) to heteromeric $alpha$ 4 $beta$ 2 and $alpha$ 3 $beta$ 4 nAChR (Bowie andMayer, 1995), suggesting that the underlying mechanisms are similar.However, there are a few important differences. These AMPA/kainatereceptors conduct considerable outward current at depolarizedpotentials (from +50 to +100 mV) (Bowie and Mayer, 1995; Koh etal., 1995), whereas we observe very little outward current from $alpha$ 4 $beta$ 2 and $alpha$ 3 $beta$ 4 receptors at these potentials. Furthermore, nonrectifyingAMPA/kainate receptors, whose subunits have undergone RNA editingsubstituting a glutamine (Q) to an arginine (R) in the pore region,are not blocked by extracellular spermine (Washburn and Dingledine,1996; Bähring et al., 1997; Washburn et al., 1997); in contrast,extracellular spermine blocks nonrectifying mutant $alpha$ 4 $beta$ 2 and $alpha$ 3 $beta$ 4receptors. These differences may be explained, in part, by differencesin the putative location of the high-affinity polyamine binding-sitein the pore. For AMPA/kainate receptors, this site appears tobe near the middle of the pore (Kuner et al., 1996; Washburn etal., 1997), whereas for neuronal nAChRs, this site is most likelyat the cytoplasmic mouth of the pore (Imoto et al., 1988; Wilsonand Karlin, 1998). The high-affinity polyamine site in rectifyingAMPA/kainate receptors is formed the by a ring of glutamine residuesas well as by negatively charged aspartate or glutamate residuesfour amino acids downstream (Washburn et al., 1997). Similarly,the high-affinity polyamine site in neuronal nAChRs is formedthe by the intermediate and cytoplasmic rings, which are fouramino acids apart. Interestingly, substituting two glutamic acidresidues with glutamines at the intermediate ring of neuronalnAChRs abolishes inward rectification, suggesting that the geometryof the high-affinity polyamine site in AMPA/ kainate receptorsand neuronal nAChRs isdifferent.

A common site affects both inward rectification and calcium permeability

For AMPA/kainate receptors, there is a strong correlation between calcium permeability and inward rectification (Verdoornet al., 1991; Hume et al., 1991; Dingledine et al., 1999). Thiscorrelation holds true for nAChRs as well. Muscle nAChRs, whichrectify slightly, have low calcium permeability (Adams et al.,1980; Villarroel and Sakmann, 1996), whereas neuronal nAChRs,which show strong inward rectification, have high calcium permeability(McGehee and Role, 1995). Calcium permeability of nAChRs appearsto be influenced by residues in the M2 as well as residues inthe intermediate ring (Bertrand et al., 1993; Villarroel and Sakmann,1996). Our results on relative calcium permeability for $alpha$ 4 $beta$ 2 and $alpha$ 3 $beta$ 4 receptors are consistent with this. Our ion substitutionexperiments indicate that P_Ca/P_Na is 1.65 for $alpha$ 4 $beta$ 2 receptors and0.8 for $alpha$ 3 $beta$ 4 receptors; the amino acid differences in the M2 betweenthese receptors likely underlie the differences in Ca²⁺permeability.

In addition, we show that partial removal of negative charges in the intermediate ring reduces P_Ca/P_Na by ~15-fold for $alpha$ 3 $beta$ 4and 25-fold for $alpha$ 4 $beta$ 2 receptors. We observe similar reduction inP_Ca/P_Na when we substitute glutamic acid residues by either alanineor glutamine residues in the intermediate ring; this indicatesthat the reduction in calcium permeability is caused by a changein net negative charge of the intermediate ring and not by alterationin the size or polarity of the amino acid side chains. We findthat substituting all five negatively charged residues with neutralresidues at the cytoplasmic ring has no effect on P_Ca/P_Na, furtherdemonstrating the important role of the intermediate ring in determiningcalcium permeability. Therefore, a common structural element ofneuronal nAChRs governs both interaction with intracellular polyaminesand high calciumpermeability.

Physiological implications

In the CNS, many neuronal nAChRs are located at presynaptic nerve terminals (MacDermott et al., 1999). Given the small sizeand high input impedance of nerve terminals together with therelatively large single-channel conductance of neuronal nAChRs,activation of only a few nAChRs would likely trigger action potentialsin the terminal and evoke transmitter release. Support for thisidea comes from studies on adrenal chromaffin cells in which activationof a single nAChR is sufficient to evoke action potentials (Fenwicket al., 1982). In the absence of inward rectification, the ACh-evokedconductance in the terminal would act to shunt the action potential,preventing it from reaching its full amplitude. Considering thesteep relationship between presynaptic depolarization and transmitterrelease, a reduction in action potential amplitude in the terminalwould severely affect release. To ensure that the action potentialreaches its full amplitude, intracellular polyamines rapidly blockneuronal nAChRs by interacting with the intermediate ring in avoltage-dependentmanner.

In this study, we provide a molecular understanding of inward rectification of neuronal nAChRs and establish a link betweentwo important physiological properties of these receptors, calciumpermeability and inward rectification. By linking these two propertiesthrough a common structural element, neuronal nAChRs limit theinflow of calcium into the cell, thereby preventing excitotoxicity.Equally important, small depolarizations from rest can lead toscreening of the negative charges at the intermediate ring byintracellular polyamines, thereby modulating calcium inflow throughthesereceptors.

  FOOTNOTES

Received Aug. 30, 1999; revised Oct. 22, 1999; accepted Oct. 22, 1999.

This work was supported by the Medical Research Council of Canada. We thank L. Cooper for helpful discussions on writing scientificmanuscripts.
Correspondence should be addressed to Dr. Ellis Cooper, Department of Physiology, McGill University, McIntyre Medical Building,3655 Drummond Street, Montréal, Québec, Canada H3G 1Y6. E-Mail:ecooper{at}med.mcgill.ca.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Adams DJ, Nutter TJ (1992) Calcium permeability and modulation of nicotinic acetylcholine receptor-channels in rat parasympathetic neurons. J Physiol (Lond) 86:67-76.
Adams DJ, Dwyer TM, Hille B (1980) The permeability of endplate channels in monovalent and divalent metal cations. J Gen Physiol 75:493-510[Abstract/Free Full Text].
Araneda R, Lan JY, Zheng X, Zukin S, Bennett VL (1999) Spermine and arcaine block and permeate N-methyl-D-aspartate receptor channels. Biophys J 76:2899-2911[Web of Science][Medline].
Bähring R, Bowie D, Benveniste M, Mayer ML (1997) Permeation and block of rat GluR6 glutamate receptor channels by internal and external polyamines. J Physiol (Lond) 502:575-589[Abstract/Free Full Text].
Bannon AW, Decker MW, Holladay MW, Curzon P, Donnelly-Roberts D, Puttfarcken PS, Bitner RS, Diaz A, Dickenson AH, Porsolt RD, Williams M, Arneric SP (1998) Broad-spectrum, non-opioid analgesic activity by selective modulation of neuronal nicotinic acetylcholine receptors. Science 279:77-81[Abstract/Free Full Text].
Bertrand D, Cooper E, Valera S, Rungger D, Ballivet M (1991) Electrophysiology of neuronal nicotinic acetylcholine receptors expressed in Xenopus oocytes following nuclear injection of genes or cDNAs. Methods Neurosci 4:174-193.
Bertrand D, Galzi JL, Devillers-Thiéry A, Bertrand S, Changeux JP (1993) Mutations at two distinct sites within the channel domain M2 alter calcium permeability of neuronal a7 nicotinic receptor. Proc Natl Acad Sci USA 90:6971-6975[Abstract/Free Full Text].
Bowie D, Mayer ML (1995) Inward rectification of both AMPA and kainate subtype glutamate receptors generated by polyamine-mediated ion channel block. Neuron 15:453-462[Web of Science][Medline].
Boyd RT, Jacob MH, Couturier S, Ballivet M, Berg DK (1988) Expression and regulation of neuronal acetylcholine receptor mRNA in chick ciliary ganglia. Neuron 1:495-502[Web of Science][Medline].
Butler JN (1968) The thermodynamic activity of calcium ion in sodium chloride-calcium chloride electrolytes. Biophys J 8:1426-1433.
Clarke PBS (1993) Nocotinic receptors in mammalian brain: localization and relation to cholinergic innervation. Prog Brain Res 98:77-83[Web of Science][Medline].
Cooper E, Couturier S, Ballivet M (1991) Pentameric structure and subunit stoichiometry of a neuronal nicotinic acetylcholine receptor. Nature 350:235-238[Medline].
Corringer PJ, Bertrand S, Galzi JL, Devillers-Thiery A, Changeux JP, Bertrand D (1999) Mutational analysis of the charge selectivity filter of the $alpha$ 7 nicotinic acetylcholine receptor. Neuron 22:831-843[Web of Science][Medline].
Couturier S, Erkman L, Valera S, Rungger D, Bertrand S, Boulter J, Ballivet M, Bertrand D (1990) $alpha$ ₅, $alpha$ ₃ and non- $alpha$ ₃: three clustered avian genes encoding neuronal nicotinic acetylcholine receptor-related subunits. J Biol Chem 265:17560-17567[Abstract/Free Full Text].
Cui C, Bähring R, Mayer ML (1998) The role of hydrophobic interactions in binding of polyamines to non NMDA receptor ion channels. Neuropharmacology 37:1381-1391[Web of Science][Medline].
Dingledine R, Borges K, Bowie D, Traynelis SF (1999) The glutamate receptor ion channels. Pharmacol Rev 51:7-61[Abstract/Free Full Text].
Fenwick E, Marty A, Neher E (1982) A patch-clamp study of bovine chromaffin cells and of their sensitivity to acetylcholine. J Physiol (Lond) 331:577-597[Abstract/Free Full Text].
Ficker E, Taglialatela M, Wible BA, Henley CM, Brown AM (1994) Spermine and spermidine as gating molecules for inward rectifier K⁺ channels. Science 266:1068-1072[Abstract/Free Full Text].
Forster I, Bertrand D (1995) Inward rectification of neuronal nicotinic acetylcholine receptors investigated by using the homomeric $alpha$ 7 receptor. Proc R Soc Lond B Biol Sci 260:139-148[Medline].
Galzi JL, Revah F, Bessis A, Changeux JP (1991) Functional architecture of the nicotinic acetylcholine receptor: from electric organ to brain. Annu Rev Pharmacol 31:37-72[Web of Science][Medline].
Galzi JL, Devillers-Thiery A, Hussy N, Bertrand S, Changeux JP, Bertrand D (1992) Mutations in the channel domain of a neuronal nicotinic receptor convert ion selectivity from cationic to anionic. Nature 359:500-505[Medline].
Haghighi AP, Cooper E (1998a) Neuronal nicotinic acetylcholine receptors are blocked by intracellular spermine in a voltage-dependent manner. J Neurosci 18:4050-4062[Abstract/Free Full Text].
Haghighi AP, Cooper E (1998b) Neuronal nicotinic acetylcholine receptors inwardly rectify through an interaction between intracellular polyamines and negatively charged residues on the cytoplasmic side of the pore. Soc Neurosci Abstr V24:1340.
Hamill OP, Marty A, Neher E, Sakmann B, Sigworth F (1981) Improved patch clamp techniques for high resolution current recording from cells and cell-free membrane patches. Pflügers Arch 391:85-100[Web of Science][Medline].
Hawrot E, Patterson P (1979) Long-term culture of dissociated sympathetic neurons. Methods Enzymol 58:574-584[Medline].
Hume RI, Dingledine R, Heinemann SF (1991) Identification of a site in glutamate receptor subunits that controls calcium permeability. Science 253:1028-1031[Abstract/Free Full Text].
Ifune CK, Steinbach JH (1993) Modulation of acetylcholine-elicited currents in clonal rat phaeochromocytoma (PC12) cells by internal polyphosphates. J Physiol (Lond) 463:431-447[Abstract/Free Full Text].
Imoto K, Busch C, Sakmann B, Mishina M, Konno T, Nakai J, Bujo H, Mori Y, Fukuda K, Numa S (1988) Rings of negatively charged amino acids determine the acetylcholine receptor channel conductance. Nature 335:645-648[Medline].
Johnson JW, Ascher P (1990) Voltage-dependent block by intracellular Mg⁺⁺ of N-methyl-D-aspartate-activated channels. Biophys J 57:1085-1090[Web of Science][Medline].
Karlin A, Akabas MH (1995) Toward a structural basis for the function of nicotinic acetylcholine receptors and their cousins. Neuron 15:1231-1244[Web of Science][Medline].
Koh DS, Burnashev N, Jonas P (1995) Block of native Ca2+-permeable AMPA receptors in rat brain by intracellular polyamines generates double rectification. J Physiol (Lond) 486:305-312[Abstract/Free Full Text].
Konno T, Busch C, Von Kitzing E, Imoto K, Wang F, Nakai J, Mishina M, Numa S, Sakmann B (1991) Rings of anionic amino acids as structural determinants of ion selectivity in the acetylcholine receptor channel. Proc R Soc Lond B Biol Sci 244:69-79[Medline].
Kuner T, Wollmuth LP, Karlin A, Seeburg PH, Sakmann B (1996) Structure of the NMDA receptor channel M2 segment inferred from the accessibility of substituted cysteines. Neuron 17:343-352[Web of Science][Medline].
Lewis CA (1979) Ion-concentration dependence of the reversal potential and the single channel conductance of ion channels at the frog neuromuscular junction. J Physiol (Lond) 286:417-445[Abstract/Free Full Text].
Mandelzys A, Pie B, Deneris ES, Cooper E (1994) The developmental increase in ACh current densities on rat sympathetic neurons correlates with changes in nicotinic ACh receptor a-subunit gene expression and occurs independent of innervation. J Neurosci 14:2357-2364[Abstract].
Mandelzys A, De Koninck P, Cooper E (1995) Agonist and toxin sensitivities of ACh-evoked currents on neurons expressing multiple nicotinic ACh receptor subunits. J Neurophysiol 74:1212-1221[Abstract/Free Full Text].
Marubio LM, Del-Mar-Arroyo-Jimenez M, Cordero-Erausquin M, Léna C, LeNovèrre N, De Kerchove d'Exaerde A, Huchet M, Damaj I, Changeux JP (1999) Reduced antinociception in mice lacking neuronal nicotinic receptor subunits. Nature 398:805-810[Medline].
Mathie A, Colquhoun D, Cull-Candy SG (1990) Rectification of currents activated by nicotinic acetylcholine receptors in rat sympathetic ganglion neurons. J Physiol (Lond) 427:625-655[Abstract/Free Full Text].
MacDermott AB, Role LW, Siegelbaum D (1999) Presynaptic ionotropic receptors and the control of transmitter release. Annu Rev Neurosci 22:443-485[Web of Science][Medline].
McFarlane S, Cooper E (1992) Postnatal development of voltage-gated K currents on rat sympathetic neurons. J Neurosci 67:1291-1300.
McGehee DS, Role LW (1995) Physiological diversity of nicotinic acethylcholine receptors expressed by vertebrate neurons. Annu Rev Physiol 57:521-546[Web of Science][Medline].
Miledi R, Parker I (1984) Chloride currents induced by injection of Ca⁺⁺ into Xenopus oocytes. J Physiol (Lond) 357:173-183[Abstract/Free Full Text].
Mulle C, Léna C, Changeux JP (1992) Potentiation of nicotinic receptor response by external calcium in rat central neurons. Neuron 8:937-945[Web of Science][Medline].
Picciotto MR, Zoll M, Léna C, Bessis A, Lallemand Y, LeNovèrre N, Vincent P, Pich EM, Brulet P, Changeux JP (1995) Abnormal avoidance learning in mice lacking functional high-affinity nicotine receptor in the brain. Nature 374:65-67[Medline].
Robinson RA, Stokes RH (1960) In: Electrolyte solutions. London: Butterworths Scientific Publication.
Sands SB, Barish ME (1991) Calcium permeability of neuronal nicotinic acetylcholine receptor channels in PC12 cells. Brain Res 560:38-42[Web of Science][Medline].
Sands SB, Barish ME (1992) Neuronal nicotinic acetylcholine receptor currents in phaeochromocytoma (PC12) cells: dual mechanisms of rectification. J Physiol (Lond) 447:467-487[Abstract/Free Full Text].
Sargent PB (1993) The diversity of neuronal nicotinic acetylcholine receptors. Annu Rev Neurosci 16:403-443[Web of Science][Medline].
Seiler N, Schmidt-Glenewinkel T (1975) Regional distribution of putrescine, spermidine and spermine in relation to the distribution of RNA and DNA in the rat nervous system. J Neurochem 24:791-795[Web of Science][Medline].
Trouslard J, Marsh SJ, Brown DA (1993) Calcium entry through nicotinic receptor channels and calcium channels in cultured rat superior cervical ganglion cells. J Physiol (Lond) 468:53-71[Abstract/Free Full Text].
Vetter DE, Liberman MC, Mann J, Barhanin J, Boulter J, Brown MC, Saffiote-Kolman J, Heinemann SF, Elgohhen AB (1999) Role of alpha 9 nicotinic ACh receptor subunits in the development and function of cochlear efferent innervation. Neuron 23:93-103[Web of Science][Medline].
Verdoorn TA, Burnashev N, Monyer H, Seeburg PH, Sakmann B (1991) Structural determinants of ion flow through recombinant glutamate receptor channels. Science 252:1715-1718[Abstract/Free Full Text].
Vernino S, Amador M, Luetje CW, Patrick J, Dani JA (1992) Calcium modulation and high calcium permeability of neuronal nicotinic acetylcholine receptors. Neuron 8:127-134[Web of Science][Medline].
Villarroel A, Sakmann B (1996) Calcium permeability increase of endplate channels in rat muscle during postnatal development. J Physiol (Lond) 496:331-338[Abstract/Free Full Text].
Wada E, Wada K, Boulter J, Deneris E, Heinemann S, Patrick J, Swanson LW (1989) Distribution of $alpha$ ₂, $alpha$ ₃, $alpha$ ₄, and $beta$ ₂ neuronal nicotinic receptor subunit mRNA in the central nervous system: a hybridization histochemical study in the rat. J Comp Neurol 284:314-335[Web of Science][Medline].
Washburn MS, Dingledine R (1996) Block of $alpha$ -amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA receptors by polyamines and polyamine toxins. J Pharmacol Exp Ther 278:669-678[Abstract/Free Full Text].
Washburn MS, Numberger M, Zhang S, Dingledine R (1997) Differential dependence on GluR2 expression of three characteristic features on AMPA receptors. J Neurosci 17:9393-9406[Abstract/Free Full Text].
Watanabe S, Kusama-Eguchi K, Kobayashi H, Igarashi K (1991) Estimation of polyamine binding to macromolecules at ATP in bovine lymphocytes and rat liver. J Biol Chem 266:20803-20809[Abstract/Free Full Text].
Wilson GG, Karlin A (1998) The location of the gate in the acetylcholine receptor. Neuron 20:1269-1281[Web of Science][Medline].
Woodhull AM (1973) Ionic blockage of sodium channels in nerve. J Gen Physiol 61:687-708[Abstract/Free Full Text].
Xiang Z, Hunguenard JR, Prince DA (1998) Cholinergic switching within neocortical inhibitory networks. Science 281:985-988[Abstract/Free Full Text].

Copyright © 2000 Society for Neuroscience 0270-6474/00/202529-13$05.00/0

This article has been cited by other articles:

G. Zolles, E. Wagner, A. Lampert, and B. Sutor
Functional Expression of Nicotinic Acetylcholine Receptors in Rat Neocortical Layer 5 Pyramidal Cells
Cereb Cortex, May 1, 2009; 19(5): 1079 - 1091.
[Abstract] [Full Text] [PDF]

J. Wu, Q. Liu, K. Yu, J. Hu, Y.-P. Kuo, M. Segerberg, P. A. St John, and R. J. Lukas
Roles of nicotinic acetylcholine receptor {beta} subunits in function of human {alpha}4-containing nicotinic receptors
J. Physiol., October 1, 2006; 576(1): 103 - 118.
[Abstract] [Full Text] [PDF]

C. Fonck, B. N. Cohen, R. Nashmi, P. Whiteaker, D. A. Wagenaar, N. Rodrigues-Pinguet, P. Deshpande, S. McKinney, S. Kwoh, J. Munoz, et al.
Novel Seizure Phenotype and Sleep Disruptions in Knock-In Mice with Hypersensitive {alpha}4* Nicotinic Receptors
J. Neurosci., December 7, 2005; 25(49): 11396 - 11411.
[Abstract] [Full Text] [PDF]

N. O. Rodrigues-Pinguet, T. J. Pinguet, A. Figl, H. A. Lester, and B. N. Cohen
Mutations Linked to Autosomal Dominant Nocturnal Frontal Lobe Epilepsy Affect Allosteric Ca2+ Activation of the {alpha}4{beta}2 Nicotinic Acetylcholine Receptor
Mol. Pharmacol., August 1, 2005; 68(2): 487 - 501.
[Abstract] [Full Text] [PDF]

J. C. Holt, M. Lioudyno, and P. S. Guth
A Pharmacologically Distinct Nicotinic ACh Receptor Is Found in a Subset of Frog Semicircular Canal Hair Cells
J Neurophysiol, September 1, 2003; 90(3): 1526 - 1536.
[Abstract] [Full Text] [PDF]

N. Rodrigues-Pinguet, L. Jia, M. Li, A. Figl, A. Klaassen, A. Truong, H. A Lester, and B. N Cohen
Five ADNFLE mutations reduce the Ca2+ dependence of the mammalian {alpha}4{beta}2 acetylcholine response
J. Physiol., July 1, 2003; 550(1): 11 - 26.
[Abstract] [Full Text] [PDF]

J. A. van Hooft and W. J. Wadman
Ca2+ Ions Block and Permeate Serotonin 5-HT3 Receptor Channels in Rat Hippocampal Interneurons
J Neurophysiol, April 1, 2003; 89(4): 1864 - 1869.
[Abstract] [Full Text] [PDF]

E. Christophe, A. Roebuck, J. F. Staiger, D. J. Lavery, S. Charpak, and E. Audinat
Two Types of Nicotinic Receptors Mediate an Excitation of Neocortical Layer I Interneurons
J Neurophysiol, September 1, 2002; 88(3): 1318 - 1327.
[Abstract] [Full Text] [PDF]

J. A. Kozak, H. H. Kerschbaum, and M. D. Cahalan
Distinct Properties of CRAC and MIC Channels in RBL Cells
J. Gen. Physiol., July 30, 2002; 120(2): 221 - 235.
[Abstract] [Full Text] [PDF]

G. Abdrakhmanova, J. Dorfman, Y. Xiao, and M. Morad
Protons Enhance the Gating Kinetics of the alpha 3/beta 4 Neuronal Nicotinic Acetylcholine Receptor by Increasing Its Apparent Affinity to Agonists
Mol. Pharmacol., February 1, 2002; 61(2): 369 - 378.
[Abstract] [Full Text] [PDF]

M. E. Nelson, F. Wang, A. Kuryatov, C. H. Choi, V. Gerzanich, and J. Lindstrom
Functional Properties of Human Nicotinic Achrs Expressed by Imr-32 Neuroblastoma Cells Resemble Those of {alpha}3{beta}4 Achrs Expressed in Permanently Transfected Hek Cells
J. Gen. Physiol., November 1, 2001; 118(5): 563 - 582.
[Abstract] [Full Text] [PDF]

This Article

Abstract

Full Text (PDF)

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via Web of Science (31)

Citing Articles via Google Scholar

Google Scholar

Articles by Haghighi, A. P.

Articles by Cooper, E.

Search for Related Content

PubMed

PubMed Citation

Articles by Haghighi, A. P.

Articles by Cooper, E.