Two Domains of the Beta Subunit of Neuronal Nicotinic Acetylcholine Receptors Contribute to the Affinity of Substance P

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Vol. 286, Issue 2, 619-626, August 1998

Two Domains of the Beta Subunit of Neuronal Nicotinic Acetylcholine Receptors Contribute to the Affinity of Substance P¹

Grace A. Stafford² , Robert E. Oswald, Antonio Figl³ , Bruce N. Cohen³ and Gregory A. Weiland

Department of Pharmacology, College of Veterinary Medicine, Cornell University, Ithaca, New York (G.A.S., R.E.O., G.A.W.) and Division of Biology, California Institute of Technology, Pasadena, California (A.F., B.N.C.)

	Abstract

Top Abstract Introduction Materials & Methods Results Discussion References

Substance P is known to noncompetitively inhibit activation of muscle and neuronal nicotinic acetylcholine receptors. Neuronalnicotinic receptors formed from different combinations of $alpha$ and $beta$ subunits exhibited differential sensitivity to substance P,with those containing $beta$ -4 subunits having a 25-fold higher affinitythan those having $beta$ -2 subunits. To identify the regions and/oramino acid residues of the $beta$ subunit responsible for this difference,chimeric $beta$ subunits were coexpressed with $alpha$ -3 in Xenopus oocytesand the IC₅₀ values for substance P were determined. Amino acidresidues between 105 and 109 ( $beta$ 4 numbering), in the middle ofthe N-terminal domain, and between 214 and 301, between the extracellularside of M1 and the intracellular side of M3, were identified asmajor contributors to the apparent affinity of substance P. Theaffinity of acetylcholine was only affected by residue changesbetween 105 and 109. Site-directed mutagenesis revealed two aminoacids that are important determinants of the affinity of substanceP, $beta$ 4(V108)/ $beta$ 2(F106), which is in the middle of the first extracellulardomain, and $beta$ 4(F255)/ $beta$ 2(V253), which is within the putative channellining transmembrane domain M2. However, other residues withinthese domains must be making subtle but significant contributions,since simultaneous mutation of both these amino acids did notcause complete interconversion of the $beta$ subunit-dependent differencesin the receptor affinity for substance P.

	Introduction

Top Abstract Introduction Materials & Methods Results Discussion References

The tachykinin SP is a neurotransmitter and neuromodulator in the central and peripheral nervous systems (Nicoll et al., 1980).As a neurotransmitter, SP acts via the NK-1, a member of the seventransmembrane, G protein-coupled receptor superfamily. The bindingof SP to NK-1 receptors leads to activation of phospholipase C,resulting in increased inositol trisphosphate levels and the releaseof calcium from intracellular stores (Mau and Saermark, 1991).In Xenopus oocytes expressing cloned NK-1 receptors, the releaseof calcium causes the activation of chloride currents (Fong etal., 1992). As a neuromodulator, SP has been shown to inhibitagonist-induced nAChR activation, as Steinacker and Highstein(1976) first demonstrated at the Mauther fiber-giant fiber synapsein the hatchet fish. Since then, SP has been shown to modulatenicotinic responses of both neuronal (Livett et al., 1979; Akasuet al., 1983; Clapham and Neher, 1984; Simasko et al., 1985; Simmonset al., 1990; Stafford et al., 1994) and skeletal muscle (Akasuet al., 1983; Simasko et al., 1985; Min and Weiland, 1992) nAChRs.These studies have shown that noncompetitive inhibition by SPis a general characteristic of nAChRs, most consistent with adirect interaction with the receptor at a unique site. This sitehas a pharmacology distinct from that of the G protein-coupledNK receptors. The evidence for a physiological role for this directmodulation is strongest in the adrenal gland where SP-containingneurons innervate the chromaffin cells and SP modulates nAChR-mediatedcatecholamine secretion (Livett and Zhou, 1991). SP may protectthe nAChR from agonist-mediated irreversible deactivation (Boydand Leeman, 1987) and could be involved in maintaining catecholaminesecretion during stress (Livett and Zhou, 1991).

Muscle and neuronal nAChRs are pentameric proteins forming ligand-gated ion channels (Changeux, 1990) that mediate signaltransmission at the neuromuscular junction and in the centraland peripheral nervous systems. Whereas muscle receptors requirefour different subunits ( $alpha$ , $beta$ , $gamma$ , and $delta$ ), functional neuronalreceptors can be formed from a combination of $alpha$ and $beta$ subunits(Boulter et al., 1987) or, in certain cases, a single type of $alpha$ subunit (Couturier et al., 1990). The family of neuronal nAChRsubunits continues to grow and there are currently eight $alpha$ andthree $beta$ neuronal receptor subunits (Papke, 1993; McGehee and Role,1995). Both types of subunits of neuronal receptors have beenshown to be involved in determining the sensitivity of the receptorto agonists and antagonists (Luetje and Patrick, 1991; Figl etal., 1992; Papke et al., 1993; Harvey and Luetje, 1996). Becauseit has been demonstrated that the $gamma$ and $delta$ subunits of the musclenAChR play a role in agonist and antagonist binding (Sine andClaudio, 1991; Czajkowski et al., 1993; Sine, 1993), the involvementof both neuronal subunits is not surprising. Moreover, given theheterogeneity of neuronal nAChR responses in vivo, the "mix andmatch" of various subunits probably provides the molecular basisfor diversity of function (Papke, 1993).

Some of the structural determinants for SP modulation of nAChRs are now becoming apparent. Min et al. (1993) found that the $gamma$ and $delta$ subunits of Torpedo nAChRs were affinity labeled witheither [³H]SP and a bifunctional cross-linker or the photoaffinity reagent[¹²⁵I]p-benzoylphenylalanine-SP. Blanton et al. (1994) demonstratedthat [¹²⁵I]p-benzoylphenylalanine-SP labeled the M2 region of the Torpedo $delta$ subunit. Using the oocyte expression system we recently foundthat the $beta$ subunit of the neuronal receptor contributes to theIC₅₀ for SP inhibition, with $beta$ -4 subunit-containing receptorshaving a 25-fold higher apparent affinity for SP than $beta$ -2-containingreceptors, whether coexpressed with $alpha$ -3 or $alpha$ -4 (Stafford et al.,1994). These findings suggested that, using molecular biologicalapproaches and the Xenopus oocyte expression system, the structuraldomains of the nAChR involved in the interaction of SP with thenAChR might be resolved as they had been previously for severalagonists and antagonists (Figl et al., 1992; Luetje et al., 1993;Papke et al., 1993).

We undertook to identify the region(s) and amino acid(s) responsible for the difference in the IC₅₀ for $beta$ -4- vs. $beta$ -2-containingreceptors, taking advantage of the significant sequence similaritiesbetween the subunits. A series of chimeric $beta$ -4/ $beta$ -2 subunits wereexpressed with the $alpha$ -3 subunit in Xenopus oocytes and by quantitatingthe inhibition of agonist-induced current by SP, we were ableto identify two regions that appeared to be the determinants ofthe difference between the subunits. Site-directed mutagenesisof the candidate residues individually demonstrated the importancethese amino acids; however, mutation of both residues togetherwas not sufficient to completely interconvert each receptor'ssensitivity to SP. It is apparent from these results that moreglobal structural and conformational issues are involved in thebinding and inhibition of nAChR activity by SP which cannot beduplicated with two single amino acid changes.

	Materials and Methods

Top Abstract Introduction Materials & Methods Results Discussion References

Construct and plasmid preparation. Plasmid containing cDNA coding for rat $alpha$ -3 was kindly supplied by Dr. Roger Papke (University of Florida, Gainesville, FL).Chimeras between rat neuronal nAChR subunits $beta$ -2 and $beta$ -4 weregenerated as previously described (Figl et al., 1992). The cDNAcoding for some of the chimeric subunits were subcloned into theoocyte DNA expression vector pOEV (a gift of Dr. William L. Taylor,Vanderbilt University) at the polylinker sequence which is locatedbetween a TFIIIA promoter and an SV40 transcription terminator(Pfaff et al., 1990). Plasmids were propagated in the Escherichiacoli host (Dh5 $alpha$ strain) and purified using the Wizard miniprepkit (Promega, Madison, WI). mRNA was transcribed using SP6 andT3 Ampliscribe (Epicentre, Madison, WI) and capped by the inclusionof diguanosine triphosphate.

Point mutations were introduced by sequential PCR (Cormack, 1994

), using GeneAmp (Perkin Elmer Cetus, Norwalk, CT). For eachmutation, two primers were designed to match sites that were about300 to 800 nucleotides apart and flanked the mutation site. Twooverlapping but oppositely oriented primers were designed to introducethe desired mutations. A silent restriction site was simultaneouslyintroduced to allow screening using restriction enzymes. The PCR-generatedcDNA containing the mutations was digested with restriction enzymesto cut two unique sites. The fragment was then ligated into theoriginal cloned gene that had also been cleaved with the sameenzymes. The vector was reintroduced into bacteria for plasmidamplification and the inserts with the mutations were sequencedin the laboratory by the dideoxy method or at the Cornell BiotechnologyProgram Sequencing Facility.

The nomenclature for the chimeras is that of Figl et al. (1992)

and identifies the residues from each subunit. The subunitfrom which the amino terminus is derived is named first, withthe ordinal denoting the number of N-terminal residues from thatsubunit. The name of the subunit providing the remaining residuesfollows the colon. Thus the chimera $beta$ -4 (105): $beta$ -2 contains theN-terminal 105 amino acids from $beta$ -4 and the remaining C-terminalresidues from $beta$ -2. The mutated residues are identified by theirnumber in the parent subunit, with the wild-type amino acid writtenfirst, followed by the residue number, and then the amino acidto which it has been changed, e.g., $beta$ -4(F255V).

Preparation and injection of Xenopus oocytes. Oocytes were harvested from adult Xenopus laevis (Nasco, Fort Atkinson, WI) under anesthesia (0.15% MS222) and manually dissectedinto groups of several dozen. The follicle layers were removedby incubation in Ca⁺⁺-free oocyte saline solution (82.5 mM NaCl, 2.5 mM KCl, 1 mM Na₂HPO₄,15 mM HEPES, 1 mM MgCl₂, pH 7.4) containing collagenase type I(1-2 mg/ml). Oocytes were maintained at 18°C in oocyte salinesolution (with 1 mM CaCl₂) containing 5% horse serum, 5 U/ml penicillin,5 µg/ml streptomycin and 150 µg/ml amikacin, and the medium waschanged daily. Four to five days before recording, 10 nl of DNA(~2 ng of plasmid DNA) was injected into the nucleus. Alternatively,50 nl of RNA (2 to 5 ng/subunit) was injected into the cytoplasm3 to 5 days before recording. Injections were made using the Nanojectpositive displacement oocyte injector (Drummond, Broomall, PA).

Voltage-clamp measurements and analysis. Two electrode voltage-clamp measurements were made at room temperature using a Turbo Tec 01C amplifier (Adams & List, Westbury,NY). The voltage electrode was filled with 3 M KCl and had a resistanceof 0.4 to 2 M $Omega$ . The current electrode was filled with 250 mM CsCl,250 mM CsF and 100 mM EGTA, pH 7.3. The resistance of the currentelectrode was between 0.5 and 2 M $Omega$ . Cells were routinely voltage-clampedat -70 mV. Bath solution (oocyte saline with 1 mM CaCl₂ and 1µM atropine to prevent activation of muscarinic acetylcholinereceptors) was delivered at ~6 ml/min through a linear perfusionsystem to oocytes placed in a Delrin chamber with a total volumeof 0.45 ml. ACh/peptide solutions were delivered by preloading2 ml in a loop at the terminus of the perfusion system using asyringe. A Mariotte flask filled with oocyte saline solution wasused to maintain constant hydrostatic pressure, and the ACh/peptideapplication was initiated by a computer-triggered stream-switchingvalve (Rainin, Emeryville, CA). The time between applicationswas 6 to 10 min to allow recovery from ACh-induced desensitization.Data were collected on-line with an IBM AT computer using softwaredeveloped in the laboratory. Current traces were recorded at thesame time on a chart recorder. The digitized recordings were transferredfrom the IBM AT to a Sun 4/330 computer for further analysis usingPLOT (Gradient Software, Ithaca, NY).

ACh activation curves and SP inhibition curves were analyzed by nonlinear least squares fitting using KaleidaGraph (SynergySoftware, Reading, PA) on a Macintosh computer. The EC₅₀, apparentHill coefficient (n_H), and maximum current (I_max) for ACh wereestimated from the concentration dependence of ACh-induced currentusing a form of the Hill equation:

I=<FR><NU>I<SUB><UP>max</UP></SUB>[<UP>ACh</UP>]<SUP>n<SUB><UP>H</UP></SUB></SUP></NU><DE>[<UP>ACh</UP>]<SUP>n<SUB>H</SUB></SUP>+EC<SUP>n<SUB><UP>H</UP></SUB></SUP><SUB>50</SUB></DE></FR>

(1)

where I is the peak current measured in the presence of [ACh]. Because of the slow perfusion system used, the current profilesreflect the time-dependent sum of the kinetics of drug diffusion,channel activation and desensitization, which in general willincrease the EC₅₀ value. Additionally, at high agonist concentrations,channel blockade by ACh is likely (Sine and Steinbach, 1984

).The IC₅₀ for SP was determined using the equation:

I=<FR><NU>I<SUB><UP>max</UP></SUB>IC<SUB>50</SUB></NU><DE>[<UP>SP</UP>]+IC<SUB>50</SUB></DE></FR>

(2)

where I is the peak current in the presence of [SP] and I_max is the peak current in the absence of SP. When a Hill coefficientwas incorporated into equation 2, the values of n_H determinedfrom the fits were not significantly different from 1. To compareSP sensitivity at comparable current responses, SP dose-responsecurves were determined at ACh concentrations near the EC₅₀ valuefor the subunit combination tested.

	Results

Top Abstract Introduction Materials & Methods Results Discussion References

Dependence of inhibition by substance P on subunit structure. Because of the significant sequence identity between the beta subunits (63% overall and more than 90% in some regions, seefig. 1), a series of chimeric $beta$ -4/ $beta$ -2 constructs were coexpressedwith $alpha$ -3 in Xenopus oocytes to attempt to identify the regionsresponsible for the 25-fold difference in the IC₅₀ of SP for $beta$ -4-vs. $beta$ -2-containing receptors (fig. 2). The chimeric beta subunitsexamined focused on two potentially important areas, the extracellularN-terminal domain [ $beta$ -4(214): $beta$ -2, $beta$ -4(116): $beta$ -2, $beta$ -4(113): $beta$ -2, $beta$ -4(111): $beta$ -2, $beta$ -4(109): $beta$ -2 and $beta$ -4(105): $beta$ -2] and the first three transmembranedomains [ $beta$ -4(301): $beta$ -2, $beta$ -4(214): $beta$ -2 and $beta$ -2(299): $beta$ -4] which includethe putative pore-lining M2 region. We expected the N-terminalregion to be important since it comprises more than 90% of theextracellular domain and had previously been shown to be importantin the interaction of agonists with the receptor (Figl et al.,1992). We were also particularly interested in the M2 region,because biochemical studies had indicated it contributed to thebinding site of SP (Min et al., 1993; Blanton et al., 1994). Thelarge intracellular loop and fourth transmembrane region werealso examined [ $beta$ -4(301): $beta$ -2, $beta$ -4(325): $beta$ -2, $beta$ -2(299): $beta$ -4, $beta$ -2(323): $beta$ -4and $beta$ -2(421): $beta$ -4]. Based on the results of these studies, severalpoint-mutated subunits were generated and characterized (fig.2).

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Fig. 1. Aligned amino acid sequences of $beta$ 2 (top) and $beta$ 4 (bottom). Dots between sequences indicate identical residues. The four putative transmembrane regions are denoted by horizontal bars.

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Fig. 2. Linear maps and IC₅₀ values for substance P inhibition and EC₅₀ values for acetylcholine-induced currents of chimeric and mutated $beta$ subunits coexpressed with $alpha$ 3. Black areas represent amino acids from $beta$ 4, white areas represent amino acids from $beta$ 2, amino acid residues are numbered at the bottom, and lines above the subunits denote putative transmembrane regions. Inhibition by SP was determined at a concentration of ACh within a factor of 1.7 (0.60-1.43) of its EC₅₀ value and the responses for each oocyte were normalized to the current measured in the presence of ACh alone. IC₅₀ values and standard errors were obtained by nonlinear fitting equation 2 to all the data from each subunit/construct (6-24 points). To determine EC₅₀ values for ACh, peak current was measured in the presence of increasing concentrations of ACh and normalized to 100 µM ACh. The parameters of ACh activation were determined by fitting equation 1 to all the data from each subunit/construct. Hill coefficients ranged from 0.71 ± 0.08 ( $beta$ 2) to 2.5 ± 0.09 ( $beta$ 4(105): $beta$ 2). Data from each subunit combination were pooled from (n) oocytes. The constructs $beta$ 2(107): $beta$ 4, $beta$ 2(109): $beta$ 4, $beta$ 2(111): $beta$ 4, $beta$ 4(423): $beta$ 2 and $beta$ 2(V253F) did not produce measurable ACh-induced currents when coinjected with $alpha$ 3, presumably for technical rather than structural reasons. ND, Not determined.

SP inhibited ACh-induced currents for all $alpha$ 3 $beta$ subunit combinations that expressed functional receptors. Representative currenttraces for the effect of 5 µM SP on ACh-induced current for severalsubunit combinations are shown in figure 3. Because the EC₅₀ forACh was dependent on the subunit combination expressed, in orderto be able to compare IC₅₀ values for SP, the concentration-dependencesof SP inhibition were determined for each subunit combinationat an ACh concentration within less than a factor of 2 of itsEC₅₀ value (fig. 2). Determination of the EC₅₀ values for activationby ACh for each subunit combination is presented in the next section.

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Fig. 3. Currents induced by application of acetylcholine (solid line) or acetylcholine plus 5 µM substance P (broken line). Drugs were applied for 20 sec, as shown by horizontal bar. Current traces shown in the presence and absence of SP are from the same oocyte. The concentrations of ACh used were 10 µM for $alpha$ 3 $beta$ 2(F106V;V253F), 25 µM for $alpha$ 3 $beta$ 4(109): $beta$ 2 and $alpha$ 3 $beta$ 2(323): $beta$ 4 and 100 µM for the others.

From the concentration-dependences of SP inhibition for the chimeras, it was apparent that both the N-terminal extracellulardomain and the region of the first three transmembrane domainscontributed to the difference in the affinity for SP (figs. 2,4 and 5). About half of the difference between $beta$ 4 and $beta$ 2 residedbetween $beta$ 4(105) and $beta$ 4(109) and half between $beta$ 4(214) and $beta$ 4(301).

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Fig. 4. Concentration-dependence of substance P inhibition of acetylcholine-induced currents for wild-type $beta$ 4 and $beta$ 2 and several chimeric $beta$ 4: $beta$ 2 subunits coexpressed with $alpha$ 3. Peak current responses to ACh were measured in the presence of increasing concentrations of SP. ACh concentrations were 100 µM for $alpha$ 3 $beta$ 4, $alpha$ 3 $beta$ 4(301): $beta$ 2, $alpha$ 3 $beta$ 4(214): $beta$ 2, $alpha$ 3 $beta$ 4(116): $beta$ 2, and $alpha$ 3 $beta$ 4(105): $beta$ 2; 50 µM for $alpha$ 3 $beta$ 2. Data for each subunit combination are from three to six oocytes. For each oocyte the responses were normalized to the current measured in the presence of ACh alone. Each point is the mean of one to four measurements at each concentration. Error bars represent the S.E.M.; if there are no error bars, SEM is smaller than the symbol or only one determination was made at that concentration. The lines are nonlinear fits of equation 2 to all the data from each subunit/construct (6-24 points).

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Fig. 5. IC₅₀ values for SP and EC₅₀ values for ACh of receptors containing $alpha$ 3 and chimeric $beta$ subunits. Value of zero amino acids on the x-axis is the $beta$ 2 subunit, 475 is $beta$ 4. Data are from figure 2. Lines were drawn to connect data points which appear continuous. Discontinuities in the IC₅₀ values between $beta$ 4 residues 105 and 116 and between 214 and 301 reflect the importance of these regions in the interaction of SP with the receptor.

The receptor containing the first 105 $beta$ 4 amino terminal residues exhibited an IC₅₀ for SP such as $alpha$ 3 $beta$ 2 (61 vs. 67 µM, fig.2). Extending the number of $beta$ 4 residues by only four more aminoacids to 109 shifted the SP inhibition curve to the left, abouthalfway to the value for $alpha$ 3 $beta$ 4 (14 vs. 3.3 µM; figs. 2, 4 and 5).Additional $beta$ 4 residues to 214 resulted in no further decreasein the IC₅₀. Thus the sequence between 105 and 109 appeared tocontain the amino acid residue(s) important for at least halfof the difference in SP sensitivity between $beta$ 4 and $beta$ 2. Comparisonof the amino acid sequences of the two subunits in this regionrevealed only a single amino acid difference (fig. 1). At position108, $beta$ 4 has a valine, while $beta$ 2 has a phenylalanine at the homologousposition (106).

Based on these results with the chimeras, it was expected that substitution of a phenylalanine for the valine in $beta$ 4 at 108and a valine for the phenylalanine in $beta$ 2 at 106 would result inreceptors exhibiting SP sensitivity about halfway between thetwo wild-types. Although this was partially true for $beta$ 4(V108F),which was approximately 3-fold less sensitive to SP than wild-type $beta$ 4 (IC₅₀ = 9.8 vs. 3.3 µM; figs. 2 and 6), $beta$ 2(F106V) resultedin receptors that had a slightly lower affinity for SP than $alpha$ 3 $beta$ 2wild-type (IC₅₀ = 148 vs. 67 µM; fig. 2).

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Fig. 6. Concentration-dependence of substance P inhibition of acetylcholine-induced currents for wild-type $beta$ 4 and $beta$ 2 and point-mutations of $beta$ 4 coexpressed with $alpha$ 3. ACh concentrations were near the EC₅₀ value determined for each mutant as shown in figure 2. Data for each subunit combination are from two to five oocytes. For each oocyte the responses were normalized to the current measured in the presence of ACh alone. Each point is the mean of one to six measurements at each concentration. Error bars represent the S.E.M.; if there are no error bars, S.E.M. is smaller than the symbol or only one determination was made at that concentration. The lines are nonlinear fits of equation 2 to all the data from each subunit/construct (6-24 points).

Approximately half of the affinity difference between the $beta$ subunits appeared to lie between $beta$ 4(214) and $beta$ 4(301), which encompassesthe transmembrane domains M1-M3. Within this region there areonly five amino acid residues that differ between $beta$ 4 and $beta$ 2 (fig.1). Of these, only one is a nonconservative difference, $beta$ 4(F255)/ $beta$ 2(V253).Significantly, this residue is within M2, the putative liningof the ion channel pore. In addition to the evidence that theM2 region was involved in the binding of SP (Blanton et al., 1994

),residue 255/253 was chosen for investigation because mutationsin the pore region have been shown to affect the interaction ofchannel blockers (Leonard et al., 1988

; Charnet et al., 1990

)and to alter the pharmacological properties (Bertrand et al.,1992

; Devillers-Thiéry et al., 1992

) of the receptor. Receptorscontaining valine substituted for phenylalanine in $beta$ 4 [ $alpha$ 3 $beta$ 4(V255F)]had an IC₅₀ value for SP (19 µM), increased about halfway to thatof the $alpha$ 3 $beta$ 2 wild-type (fig. 2), consistent with a significantcontribution of this residue either to the binding site of thepeptide or to the transduction of binding into inhibition of receptoractivation. Unfortunately, $alpha$ 3 $beta$ 2(V253F) did not produce functionalreceptors, despite several attempts.

Because the single mutation at $beta$ 4(F255V) reduced the sensitivity of the receptor to SP about halfway to $alpha$ 3 $beta$ 2 and the pointmutation $beta$ 4(V108F) had also reduced the sensitivity towards wild-type $beta$ 2, these residues appeared to be critical determinants of thedifference in SP affinity for the $beta$ subunits. If the structuraldifferences created by these residue changes were independent,then the double point mutation of $beta$ 4 (V108F; F255V) should resultin the conversion of $beta$ 4 affinity for SP into that of $beta$ 2. As shownin figures 2 and 6, this was not the case and the double mutanthad approximately the same affinity for SP as either single mutationhad, about halfway between $beta$ 2 and $beta$ 4. This was also found to betrue for the double mutation of $beta$ 2 (F106V/V253F), which displayedan affinity for SP about halfway between the wild-type $beta$ subunits(fig. 2).

Based on these results, we hypothesized that although the residues preceding 108/106 initially did not seem to be importantfor the difference in sensitivity, they might be indirectly involvedand could be important in determining the three dimensional structurearound the amino acid at $beta$ 4(108)/ $beta$ 2(106). To investigate this,a point mutation at $beta$ 2(V253F) was introduced into the chimericsubunit $beta$ 4(109): $beta$ 2 to generate $beta$ 4(109): $beta$ 2(V253F), a $beta$ subunitwith the first 109 amino acids from $beta$ 4 and the remainder from $beta$ 2, except that the M2 domain is $beta$ 4. Although receptors formedwith this $beta$ construct were somewhat more sensitive to SP thanthose containing the two point mutations $beta$ 2(F106V;V253F) (IC₅₀= 14 vs. 32 µM; fig. 2), the apparent affinity was not significantlydifferent from that of the chimera $beta$ 4(109): $beta$ 2.

Acetylcholine dose-responses. The EC₅₀ value of ACh for each subunit/chimera/mutation combined with $alpha$ 3 was determined so that SP inhibition could be investigatedusing concentrations of ACh that gave comparable relative responses.A 20-sec application of ACh induced activation of inward cationiccurrents, as shown in figure 3 (solid lines). EC₅₀ values forall the expressed receptor subunit combinations are shown in figure2. In this study we observed only about a 4-fold difference inEC₅₀ values of ACh for receptors containing $beta$ 2 or $beta$ 4 subunits(37 vs. 143 µM, fig. 2). This is in contrast to the near 20-folddifference (10 vs. 210 µM) previously reported (Cohen et al.,1995). The discrepancies in the EC₅₀ values for ACh most likelyreflect 1) differences in the method of agonist application (inthe current study we used a relatively slow bath perfusion, whilethe previous study used a more rapid U-tube application), 2) differencesin the holding potential (-70 mV in the current study and -50mV in the previous report) and 3) differences in the compositionof perfusion solutions, most notably 1 µM atropine was includedin the current study. It is not unexpected that differences inthe rate of drug application would cause discrepancies in thequantitative values determined (especially EC₅₀ values of agonistswhere desensitization can significantly affect the peak currentobserved). For example, Harvey and Luetje (1996) reported onlya 3-fold difference in EC₅₀ values of ACh for $alpha$ 3 $beta$ 2 vs. $alpha$ 3 $beta$ 4 receptors(71 vs. 210 µM), using a relatively slow perfusion method andwith a holding potential of $-$ 70 mV. It should be noted that despitethese differences in EC₅₀ values, both these studies and the currentone (data not shown) found significant differences in the apparentcooperativity for ACh activation of $beta$ 2- vs. $beta$ 4-containing receptors.For all these studies the Hill coefficient for ACh was near 1.0for $alpha$ 3 $beta$ 2 and near 2.0 for $alpha$ 3 $beta$ 4.

The $beta$ 4: $beta$ 2 chimeras that contained more than the first 116 N-terminal residues of $beta$ 4 exhibited a high EC₅₀ value ( $alpha$ 3 $beta$ 4-like),as did $alpha$ 3 $beta$ 4(105): $beta$ 2 (figs. 2 and 6). The three chimeras between $beta$ 4(105) and $beta$ 4(116), however, displayed low EC₅₀ values, suchas $beta$ 2. This region ( $beta$ 4(105-116)/ $beta$ 2(103-114)) had previously beenshown to be a structural "hot spot" for the action of the partialagonists cytisine, TMA and nicotine (Figl et al., 1992

) and acetylcholine(Cohen et al., 1995

), and may contribute to an agonist bindingsite that bridges the $alpha$ and $beta$ subunits in neuronal receptors (Cohenet al., 1995

With the exception of $beta$ 4(V108F), the single point mutations had little effect on the EC₅₀ values of the receptors (fig. 2).The EC₅₀ value for $alpha$ 3 $beta$ 2(F106V) was essentially that of $alpha$ 3 $beta$ 2 and $alpha$ 3 $beta$ 4(F255V) was not significantly different from $alpha$ 3 $beta$ 4. However, $alpha$ 3 $beta$ 4(V108F) had an EC₅₀ value no different from that of $alpha$ 3 $beta$ 2.Combining the two mutations in $beta$ 4 resulted in a receptor, $alpha$ 3 $beta$ 4(V108F;F255V),with an EC₅₀ (110 µM) close to wild-type $alpha$ 3 $beta$ 4. $alpha$ 3 $beta$ 2(F106V;V253F)was the most sensitive of all the receptors to ACh (EC₅₀ = 7 µM).The chimera with a point mutation, $beta$ 4(109): $beta$ 2(V253F), had an EC₅₀(78 µM) like wild-type $beta$ 4, in contrast to its parent chimera, $beta$ 4(109): $beta$ 2, which was more like $beta$ 2.

Thus as previously reported (Cohen et al., 1995

), the difference in the affinity for ACh appears in large part to be determinedby the first 116 N-terminal residues of the $beta$ subunit, with theconversion from the high affinity $beta$ 2 form to the low affinity $beta$ 4 form occurring between 108 and 116 of $beta$ 4. Unlike for substanceP, however, the most critical residues appear to be $beta$ 4(115) and $beta$ 4(116), where conversion from high to low affinity for ACh occurred.In general point mutations had little effect of the affinity forACh, although $beta$ 4(V108F) was not significantly different from $beta$ 2and $beta$ 2(F106V;V253F) had an unexpectedly high affinity for agonist.

	Discussion

Top Abstract Introduction Materials & Methods Results Discussion References

We had previously found that neuronal nAChRs containing $beta$ 4 subunits have a higher affinity for SP than do $beta$ 2-containing receptors,whether they are coexpressed with $alpha$ 3 or $alpha$ 4 (Stafford et al., 1994).We identified two separate regions of the $beta$ subunit that are importantfor this difference in the sensitivity of the receptors to SP:between $beta$ 4(105) and $beta$ 4(116) and between $beta$ 4(214) and $beta$ 4(301). Chimericsubunits containing portions of the two $beta$ subunits were used tolocate these regions, and point mutations were introduced to attemptto determine the individual amino acids involved. The amino acidsV108 and F255 of $beta$ 4 and the homologous $beta$ 2 residues (F106 and V255)were identified as important determinants of the affinity forSP, although the double mutations did not convert one subtypeto the other, indicating other residues are making significant,but more subtle, contributions to the interaction with the peptide.

The $beta$ subunit has previously been shown to affect many properties of neuronal nAChRs, including the single channel characteristics.Papke and Heinemann (1991) have shown that the $beta$ subunit affectsthe rate of ACh dissociation and the rate of channel opening.Receptors containing $beta$ 4 are much more sensitive to the ganglionicstimulants cytisine and nicotine (Luetje and Patrick, 1991; Figlet al., 1992) but much less sensitive to the neurotransmitterACh (Cohen et al., 1995) and the antagonists DH $beta$ E (Harvey andLuetje, 1996) and nBGT (Papke et al., 1993; Harvey and Luetje,1996) than are $beta$ 2 containing receptors. Chimeric $beta$ 4/ $beta$ 2 subunitshave been used to map the regions responsible for most of thesedifferences. From these studies it is clear that the extracellularN-terminus is the most important region of the $beta$ subunit for theinteractions of these compounds with the receptor. Amino acids $beta$ 4(108) and $beta$ 4(110) can account for much of the relative sensitivityto cytisine, although the difference in nicotine sensitivity couldnot be localized to a particular region of the $beta$ subunit (Figlet al., 1992). The first 121 amino acids of the $beta$ subunit determinedthe kinetics of nBGT block (Papke et al., 1993). The major determinantof DH $beta$ E and nBGT affinity was shown to be $beta$ 4(K61)/ $beta$ 2(T59) withother minor determinants in the first 100 residues of the N-terminus(Harvey and Luetje, 1996). Chimeras of $beta$ 4/ $beta$ 2 subunits were usedby Cohen et al. (1995) to demonstrate the importance of the first120 residues in determining the EC₅₀ for ACh, with residues between $beta$ 2(104) and (120) accounting for the relative sensitivity of $alpha$ 3 $beta$ 2to cytisine, TMA, and ACh.

Chimeric subunits followed by site-directed mutation have been used to identify amino acids of the $gamma$ and $delta$ subunits involvedin curare binding to muscle nAChRs (Sine, 1993) and of the $alpha$ subunitsthat contribute to agonist and antagonist sensitivity of neuronalnAChRs (Luetje et al., 1993). Sine (1993) expressed $gamma$ / $delta$ chimerasto identify two regions in mouse $gamma$ and $delta$ subunits that were determinantsof curare affinity. Interestingly, two of the residues identifiedin the mouse $gamma$ subunit (I116 and Y117) are homologous to $beta$ subunitresidues $beta$ 2(I118) and $beta$ 2(F119) that are very near the region wefound to affect ACh and substance P interactions with the receptor(see fig. 1). Luetje et al. (1993) used chimeric $alpha$ 2/ $alpha$ 3 subunitsexpressed with $beta$ 2 in Xenopus oocytes to identify the determinantsof nBGT sensitivity and the relative nicotine/ACh sensitivitiesbetween $alpha$ 2 and $alpha$ 3 coexpressed with $beta$ 2.

We have identified two regions of the $beta$ subunit that were responsible for the difference in sensitivity to SP inhibition ofACh-induced current in nAChRs. Receptors containing chimeric $beta$ subunits with the first 105 amino terminal residues from $beta$ 4 displayedthe same sensitivity as $beta$ 2-containing receptors. If the aminoterminal $beta$ 4 residues were extended to 109, the resultant receptorsdisplayed SP sensitivity intermediate between $alpha$ 3 $beta$ 2 and $alpha$ 3 $beta$ 4. Extendingthe amino terminal $beta$ 4 residues to 214, thus including the entireN-terminal extracellular domain, had no additional effect andresulted in receptors with similar intermediate sensitivity. However,when the chimeric $beta$ subunits contained $beta$ 4 amino terminal residuespast the third transmembrane domain (~300 amino terminal residues),the receptors displayed SP sensitivity of wild-type $alpha$ 3 $beta$ 4. Similarly,receptors with chimeric subunits having $beta$ 2 past M3 had wild-type $alpha$ 3 $beta$ 2 SP sensitivity. Each of these regions, $beta$ 4(105-109) and $beta$ 4(214-301),accounted for approximately half of the difference in sensitivityto SP of the two wild-type receptors (see figs. 2 and 5).

There is a single amino acid in the region of $beta$ 4(105) and $beta$ 4(109) that differs between $beta$ 2 and $beta$ 4: a phenylalanine at $beta$ 2(106)is replaced by a valine at $beta$ 4(108). It was expected that substitutionof that residue with the homologous one would result in receptorswith intermediate IC₅₀ values for SP. Receptors with the singlemutation $alpha$ 3 $beta$ 4(V108F) were only slightly less sensitive to SP thanwild-type $alpha$ 3 $beta$ 4, and $alpha$ 3 $beta$ 2(F106V) had an IC₅₀ for SP of about 150µM, much greater than $alpha$ 3 $beta$ 2 wild-type. This lack of reciprocitywhen exchanging residues between subtypes was also seen by Luetjeet al. (1993) for the relative sensitivity of nicotine vs. ACh,and probably reflects subtle, but significant, contributions byother residues. Because this region has also been shown to beimportant in the interaction of agonists (fig. 5; Figl et al.,1992; Cohen et al., 1995) and inhibition by SP is noncompetitive(Stallcup and Patrick, 1980; Simasko et al., 1987; Stafford etal., 1994), it is most likely that this region is not involveddirectly in the binding of SP. These residues may contribute tothe agonist binding site as suggested by Cohen et al. (1995) ormay participate in conformational changes involved in agonist-inducedactivation or desensitization, which could indirectly affect theapparent affinity of SP by altering agonist properties. Even ifthese residues are within the agonist binding site, they can contributeto the gating properties of the channel as has been shown, forexample, by Chen et al. (1995) who found mutation of tyrosine190 within the ACh binding site of the $alpha$ -subunit affected bothagonist binding and activation kinetics (for review see Arias,1997).

Between residues $beta$ 4(214) and $beta$ 4(301) there are five amino acid differences, but only a single nonconservative change. In theM2 region, $beta$ 2 has a valine at 253 and $beta$ 4 has a phenylalanine atthe comparable position (255). The receptor $alpha$ 3 $beta$ 4(F255V) had anIC₅₀ for SP about halfway between the two wild-type receptors.We believe that the single residue $beta$ 4(255) alone can account forthe difference in SP sensitivity mapped to between $beta$ 4(214) and $beta$ 4(301) because the difference in the IC₅₀ between wild-type $beta$ 4and $beta$ 4(F255V) (3.3 vs. 19 µM) is essentially the same as the differencebetween $beta$ 4(301): $beta$ 2 and $beta$ 4(214): $beta$ 2 (5.5 vs. 20 µM). Because $alpha$ 3 $beta$ 2(V253F)would not express, the effect of the single mutation in M2 of $beta$ 2 remains unknown. The amino acid $beta$ 4(F255) [and the homologousresidue, $beta$ 2(V253)] is located in the middle of the putative secondtransmembrane domain, which is the believed to line the channelpore (Imoto et al., 1986; Oiki et al., 1988). $beta$ 4(F255)/ $beta$ 2(V253)is four amino acids nearer the extracellular mouth of the receptorthan the highly conserved leucine [ $beta$ 2(L249)/ $beta$ 4(L251), see fig.1] that is thought to face the lumen and contribute to the narrowestregion of the pore (Unwin, 1993). Therefore, it should also facethe lumen of the pore, whether M2 is an $alpha$ -helix or $beta$ -structure.It is not unlikely that SP is binding in the channel near thisresidue, because Blanton et al. (1994) have cross-linked the affinitylabel [¹²⁵I]p-benzoylphenylalanine-SP to the M2 region of the $delta$ subunitfrom Torpedo. The greater sensitivity of $beta$ 4 containing receptorsto SP inhibition could then be explained by the stabilizationof the positive charges on SP by the aromatic $pi$ electrons of thephenylalanine, much as the aromatic amino acids stabilize AChin the binding pocket of acetylcholinesterase (Dougherty and Stauffer,1990; Sussman et al., 1991). This could account for the reductionin SP IC₅₀ for $alpha$ 3 $beta$ 2(F106V;V253F) receptors over $alpha$ 3 $beta$ 2(F106V) receptors.However, longer range effects cannot be ruled out, as found withmutations in M2 of $alpha$ 7 where agonist and antagonist interactionswith the receptor were affected by point mutations in the channelregion (Revah et al., 1991; Bertrand et al., 1992; Devillers-Thiéryet al., 1992).

Combining the two single mutations in $beta$ 4 did not produce an additive effect, and did not result in the predicted conversionof $beta$ 4 to $beta$ 2 sensitivity to SP. $alpha$ 3 $beta$ 4(V108F;F255V) receptors hadessentially the same IC₅₀ as $alpha$ 3 $beta$ 4(F255V). The double mutant inthe $beta$ 2 subunit, $alpha$ 3 $beta$ 2(F106V;V253F) had an intermediate IC₅₀ forSP, demonstrating that the phenylalanine in the M2 could renderthe $beta$ 2 containing receptor more sensitive to SP. However, changing $beta$ 2(253) from a valine to a phenylalanine in the chimera $beta$ 4(109): $beta$ 2had no effect on SP sensitivity. This suggests, as discussed previously,that the differences in affinity for substance P are not due toonly these two amino acids, but other residues are involved, makingsubtle, three-dimensional structural contributions that are notapparent from the results with the chimeras.

Using chimeric $beta$ subunits coexpressed with $alpha$ 3 in Xenopus oocytes, it has been possible to define two areas of the $beta$ subunitthat contribute to the differences in sensitivity to SP of $beta$ 2-and $beta$ 4-containing nAChRs. Although the two amino acids identifiedcould not account for all of the difference, $beta$ 4(108) and $beta$ 4(255)[and the $beta$ 2 homologs, $beta$ 2(106) and $beta$ 2(253)], clearly play importantroles in the inhibition of nAChR activation by SP. Most likely $beta$ 4(255) is involved in the binding of SP to the receptor while $beta$ 4(108) may be involved in agonist binding and/or receptor activationand indirectly participate in the inhibitory action of the peptide.

	Acknowledgments

The authors thank Drs. Jim Boulter, Roger Papke, Marc Ballivet and William L. Taylor for supplying cDNA and plasmids; Dr.Roger Papke for helpful discussions and Ms. Chris Bian for herexcellent technical assistance.

	Footnotes

Accepted for publication April 1, 1998.

Received for publication October 28, 1997.

¹ This work was supported by Grant BNS-8911782 from the National Science Foundation and by Cooperative State Research, Education,and Extension Service, USDA (Project Number NYC-425-432) to G.A.W.and by Grant RO1 NS 18660 from the National Institutes of Healthto R.E.O. G.A.S. was supported by the Cornell Biotechnology Instituteand the Pharmaceutical Manufacturers Association Foundation.

² Current address: Wadsworth Center, Albany, NY 12201-2002.

³ Current address: Division of Biomedical Sciences, University of California at Riverside, Riverside, CA 9521-0121.

Send reprint requests to: Dr. Gregory A. Weiland, Department of Pharmacology, College of Veterinary Medicine, Cornell University, Ithaca, NY 14853.

	Abbreviations

ACh, acetylcholine; DH $beta$ E, dihydro- $beta$ -erythroidine; G protein, heterotrimeric GTP binding protein; nAChR, nicotinic acetylcholine receptor; nBGT, neuronal bungarotoxin; NK, neurokinin; n_H, Hill coefficient; SP, substance P; TMA, tetramethylammonium.

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Two Domains of the Beta Subunit of Neuronal Nicotinic Acetylcholine Receptors Contribute to the Affinity of Substance P1

Two Domains of the Beta Subunit of Neuronal Nicotinic Acetylcholine Receptors Contribute to the Affinity of Substance P¹