Dash B and Li MD (2014), Analysis of rare variations reveals roles of am...

XB-ART-49767

Mol Brain 2014 May 02;7:35. doi: 10.1186/1756-6606-7-35.

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Analysis of rare variations reveals roles of amino acid residues in the N-terminal extracellular domain of nicotinic acetylcholine receptor (nAChR) alpha6 subunit in the functional expression of human alpha6*-nAChRs.

Dash B , Li MD .

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BACKGROUND: Functional heterologous expression of naturally-expressed and apparently functional mammalian α6*-nicotinic acetylcholine receptors (nAChRs; where '*' indicates presence of additional subunits) has been difficult. Here we wanted to investigate the role of N-terminal domain (NTD) residues of human (h) nAChR α6 subunit in the functional expression of hα6*-nAChRs. To this end, instead of adopting random mutagenesis as a tool, we used 15 NTD rare variations (i.e., Ser43Pro, Asn46Lys, Asp57Asn, Arg87Cys, Asp92Glu, Arg96His, Glu101Lys, Ala112Val, Ser156Arg, Asn171Lys, Ala184Asp, Asp199Tyr, Asn203Thr, Ile226Thr and Ser233Cys) in nAChR hα6 subunit to probe for their effect on the functional expression of hα6*-nAChRs. RESULTS: N-terminal α-helix (Asp57); complementary face/inner β-fold (Arg87 or Asp92) and principal face/outer β-fold (Ser156 or Asn171) residues in the hα6 subunit are crucial for functional expression of the hα6*-nAChRs as variations in these residues reduce or abrogate the function of hα6hβ2*-, hα6hβ4- and hα6hβ4hβ3-nAChRs. While variations at residues Ser43 or Asn46 (both in N-terminal α-helix) in hα6 subunit reduce hα6hβ2*-nAChRs function those at residues Arg96 (β2-β3 loop), Asp199 (loop F) or Ser233 (β10-strand) increase hα6hβ2*-nAChR function. Similarly substitution of NTD α-helix (Asn46), loop F (Asp199), loop A (Ala112), loop B (Ala184), or loop C (Ile226) residues in hα6 subunit increase the function of hα6hβ4-nAChRs. All other variations in hα6 subunit do not affect the function of hα6hβ2*- and hα6hβ4*-nAChRs. Incorporation of nAChR hβ3 subunits always increase the function of wild-type or variant hα6hβ4-nAChRs except for those of hα6(D57N, S156R, R87C or N171K)hβ4-nAChRs. It appears Asp57Lys, Ser156Arg or Asn171Lys variations in hα6 subunit drive the hα6hβ4hβ3-nAChRs into a nonfunctional state as at spontaneously open hα6(D57N, S156R or N171K)hβ4hβ3V9'S-nAChRs (V9'S; transmembrane II 9' valine-to-serine mutation) agonists act as antagonists. Agonist sensitivity of hα6hβ4- and/or hα6hβ4hβ3-nAChRs is nominally increased due to Arg96His, Ala184Asp, Asp199Tyr or Ser233Cys variation in hα6 subunit. CONCLUSIONS: Hence investigating functional consequences of natural variations in nAChR hα6 subunit we have discovered additional bases for cell surface functional expression of various subtypes of hα6*-nAChRs. Variations (Asp57Asn, Arg87Cys, Asp92Glu, Ser156Arg or Asn171Lys) in hα6 subunit that compromise hα6*-nAChR function are expected to contribute to individual differences in responses to smoked nicotine.

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Species referenced: Xenopus
Genes referenced: chrna4

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	Figure 1. Localizations of N-terminal variations to primary/secondary structure of nAChR hÎ±6 subunits. (A) Degree of conservation of variant residues in nAChR hÎ±6 subunit in relation to other human nAChR Î± subunits: Human nAChR Î± subunits (Î±1-Î±7, Î±9 and Î±10) are aligned using ClustalW. Indicated residues in nAChR hÎ±6 subunits undergoing variation are fully (Asp92 and Ser156), strongly (Arg87 and Asn171) and weakly (Asp57, Asp199 and Asn203) conserved in human nAChR Î± subunits. Some of the variations in nAChR hÎ±6 subunit are localized to indicated loop regions: Ala112Val (loop A), Ala184Asp (loop B), Ile226Thr (loop C), Asp92Glu (loop D), Asp199Tyr (loop F) and Asn203Thr (loop F) and Asn171Lys (cysteine-loop). (B) Degree of conservation of variant residues in nAChR hÎ±6 subunit in relation to nAChR Î±6 subunits from other organisms: nAChR Î±6 protein sequences extracted from (GenBank) NP_067344.2 (Mouse), NP_004189.1 (Human), NP_990695.1 (Chicken), NP_476532.1 (Rat), NP_001029266.1 (Chimpanzee), XP_001099152.1 (Monkey), XP_584902.3 (Cow) and NP_001036149.1 (Zebrafish) are aligned by using ClustalW. For both (A) and (B); numbering begins at translation start methionine of nAChR hÎ±6 subunit and is shown in the regions of interest. However, only segments of the alignment are presented to identify WT nAChR hÎ±6 subunit AA residues (shaded, upward arrow mark and numbers above them) and their corresponding variations (noted above the numberings). Symbols below sequences indicate fully (), strongly (:) or weakly (.) conserved residues: hÎ±6 subunit AA residues at positions 87 (Arg), 92 (Asp), 156 (Ser) and 171 (Asn) are conserved in both human nAChR Î± subunits and nAChR Î±6 subunits of other organisms. Also shown (shaded) are the nAChR hÎ±6 subunit residues including the loop E residue N143 that alone or in combination Met145 influences the function of hÎ±6-nAChRs [26].
	Figure 2. Localizations of AA variations to secondary structures and interfaces of nAChR hÎ±6 subunit. [(A) and (B)] AA residues undergoing variation are identified in a 3D model of the nAChR hÎ±6 subunit: A 3D homology model of the nAChR hÎ±6 subunit was generated based on the crystal structure of Torpedo muscle nAChR Î± subunit (PDB code: 2BG9:A). Hence structural features are approximate and may deviate from what seen with Î± subunit of Torpedo muscle nAChR. Î² strands constitute inner Î²-sheet (strand Î²1-Î²3, Î²5, Î²6 and Î²8) and outer Î²-sheet (strand Î²4, Î²7, Î²9 and Î²10); and are connect to each other via loops. These loops constitute positive (+) (loops A, B and C) and negative face (loops D, E and F) of Î±6 subunit and contribute to subunit assembly, ligand binding, and formation of ligand binding pocket and/or coupling agonist binding to channel gating. Cysteine loop and other loop residues undergone variations are also identified. [(C)-(E)] Interfaces contributed by Î±6 subunit to formation of Î±6-nAChR: Adhering to the canonical rule of pentamer formation, Î±6Î²2-nAChR would be formed out of three Î±6 and two Î²2 subunits [i.e., (i) (Î±6)3(Î²2)2-nAChR] or two Î±6 and three Î²2 subunits [i.e., (ii) (Î±6)2(Î²2)3-nAChR]. In the event Î²3 or gain-of-function Î²3 (i.e., Î²3V9âS) subunits to be integrated into Î±6Î²2-nAChR complexes these subunits would take the position of 3rd Î±6 subunit in the 1st (i) configuration or 3rd Î²2 subunit in the 2nd (ii) configuration [i.e., (iii) (Î±6)2(Î²2)2(Î²3or Î²3V9âS)-nAChR]. Similarly, Î²4 subunit would substitute Î²2 subunit for formation human Î±6Î²4-[i.e., (Î±6)3(Î²4)2 and (Î±6)2(Î²4)3]-nAChR. For formation of (Î±6)2(Î²4)2Î²3- or (Î±6)2(Î²4)2Î²3V9âS-nAChR Î²3 or Î²3V9âS subunits would substitute one Î±6 subunit in (Î±6)3(Î²4)2 configuration or one Î²4 subunit in (Î±6)2(Î²4)3 configuration. Two presumed agonist (ACh or nicotine and others) binding sites in the interface of Î±6(+) and Î²2(â) subunits are identified as ovals. Variations in the structural loops in the (â)-ve face (loop D, E and F) and (+)-ve face (loop A, B and C) of the hÎ±6 subunit are expected to affect the function of hÎ±6*-nAChRs involving interfaces identified by arrow marks.
	Figure 3. Variations in nAChR hÎ±6 subunit influence the current responses of human Î±6Î²2Î²3V9âS-nAChRs expressed in oocytes using codon optimized nAChR hÎ²2 subunits. Mean (Â±SEM) peak inward current responses upon exposure to 100Â Î¼M nicotine (5Â sec exposure; ordinate) are estimated from oocytes (nâ=â3-7) voltage clamped at â70Â mV and heterologously expressing the indicated nAChR subunits. Current responses of hÎ±6hÎ²2hÎ²3V9âS-nAChR are completely abolished (D57N or S156R), partially abolished (S43P, N46K, R87C, D92E or N171K), not changed (E101K, A112V, A184D, N203T or I226T) and increased (R96H, D199Y or S233C) as a result of the indicated variations in nAChR hÎ±6 subunits. Oocytes coexpressing nAChR hÎ±6(D199Y) subunits, codon optimized hÎ²2 subunits and hÎ²3V9âS subunits yield largest current responses to nicotine. Comparisons of peak current responses between control (hÎ±6hÎ²2hÎ²3V9âS-nAChR) and variant nAChR groups were analyzed using one-way ANOVA with Dunnettâs multiple comparisons test (, pâ<â0.05; and *, pâ<â0.01).
	Figure 4. Variations in nAChR hÎ±6 subunit influence the current responses of human Î±6Î²2Î²3V9âS-nAChR expressed in oocytes using WT nAChR hÎ²2 subunits. Attempts were made to verify the results obtained for human Î±6Î²2Î²3V9âS-nAChR using WT nAChR hÎ²2 subunits instead of codon optimized hÎ²2 subunits. Mean (Â±SEM) peak inward current responses upon exposure to 100Â Î¼M nicotine (5Â sec exposure; ordinate) are estimated from oocytes (nâ=â3-7) voltage clamped at â70Â mV and heterologously expressing the indicated nAChR subunits. (A) Oocytes coexpressing nAChR hÎ±6(R96H, D199Y or S233C), hÎ²2WT and hÎ²3V9âS subunits yield current responses to nicotine that are higher than those expressing nAChR hÎ±6, hÎ²2WT and hÎ²3V9âS subunits. These results are in agreement with those obtained using codon optimized hÎ²2 subunits. (B) Initial recordings 3Â days after cRNA injection indicated that oocytes expressing WT hÎ±6 or variant hÎ±6(E101K, A112V, A184D, N203T or I226T) subunits along with WT hÎ²2 and hÎ²3V9âS subunits yield ~10-30Â nA of current in response to 100Â Î¼M nicotine [see the hÎ±6hÎ²2hÎ²3V9âS-nAChR response in (A)]. However recordings done after 2 additional days of waiting indicated that nicotine elicited current responses from human Î±6E101KÎ²2Î²3V9âS-, Î±6A112VÎ²2Î²3V9âS-, Î±6A184DÎ²2Î²3V9âS-, Î±6N203TÎ²2Î²3V9âS- or Î±6I226TÎ²2Î²3V9âS-nAChRs are equal (pâ>â0.05) to those obtained from human Î±6Î²2Î²3V9âS-nAChRs. These results are in agreement with those obtained using codon optimized hÎ²2 subunits. Comparisons between groups were analyzed using one-way ANOVA with Tukeyâs post hoc comparison and only those differ from the control (hÎ±6hÎ²2hÎ²3V9âS-nAChR) are shown with asterisks. , pâ<â0.05; and *, pâ<â0.01.
	Figure 5. Variations in nAChR hÎ±6 subunit influence the current responses of hÎ±6hÎ²4-nAChRs. Mean (Â±SE) peak inward current responses upon exposure to 100Â Î¼M nicotine (5Â sec exposure; ordinate) are estimated from oocytes (nâ=â6-9) voltage clamped at â70Â mV and heterologously expressing the indicated nAChR subunits. Oocytes coexpressing hÎ±6A184D (variation in loop D) and hÎ²4 subunits yield largest current responses to 100Â Î¼M nicotine. Comparisons of peak current responses between control (hÎ±6hÎ²4-nAChR) and variant groups were analyzed using one-way ANOVA with Dunnettâs multiple comparisons test (, pâ<â0.05; and *, pâ<â0.01).
	Figure 6. Variations in nAChR hÎ±6 subunit influence the current responses of hÎ±6hÎ²4hÎ²3-nAChRs. Mean (Â±SE) peak inward current responses upon exposure to 100Â Î¼M nicotine (5Â sec exposure; ordinate) are estimated from oocytes (nâ=â6-11) voltage clamped at â70Â mV and heterologously expressing the indicated nAChR subunits. Oocytes coexpressing hÎ±6(D57N, R87C, S156R or N171K) subunits plus hÎ²4 and hÎ²3 subunits do not yield current responses to nicotine though those coexpressing hÎ±6, hÎ²4 and hÎ²3 subunit yield fairly robust current responses. hÎ±6 subunit variation Asp92Glu (in loop D) partially abolishes the peak current responses of hÎ±6hÎ²4hÎ²3-nAChRs. hÎ±6 subunit variations Asn46Lys, Arg96His, Glu101Lys, Ala112Val, Ala184Asp, Asn203Thr, Ile226Thr or Ser233Cys do not affect nicotine elicited peak current responses of hÎ±6hÎ²4hÎ²3-nAChRs. Comparisons between control (hÎ±6hÎ²4hÎ²3) and variant groups were analyzed using one-way ANOVA with Dunnettâs multiple comparisons test (, pâ<â0.05; and *, pâ<â0.01).
	Figure 7. Nicotinic agonists act as antagonists at hÎ±6(D57N, S156R or N171K)hÎ²4hÎ²3V9âS-nAChRs. (A) Representative traces are shown for inward or outward current responses from oocytes (voltage clamped at -70 mV) responding to the application of indicated concentrations of nicotine or atropine (shown with the duration of drug exposure as black bars above or below the traces) and expressing hÎ±6hÎ²4hÎ²3V9âS- [(A) (i) and (v)], hÎ±6D57NhÎ²4hÎ²3V9âS-[(A) (ii) and (vi)], hÎ±6S156RhÎ²4hÎ²3V9âS[(A) (iii) and (vii)] or hÎ±6N171KhÎ²4hÎ²3V9âS- [(A) (iv) and (viii)] nAChRs. Calibration bars are for 200 (i), 40 [(ii), (iii) and (iv)] or 100 [(v), (vi), (vii) and (viii)] nA currents (vertical) or 5 sec (horizontal). Results for these and other studies were used to estimate mean (Â±SE) peak outward current responses to 100 Î¼M nicotine (B), 100 Î¼M ACh (C) or 1000 Î¼M atropine (D) from oocytes (n=3-6) heterologously expressing the indicated nAChR subunits. hÎ±6(D57N,S156RorN171K)hÎ²4hÎ²3V9âS-nAChRs elicit outward (positive) current in response to nicotine (B) or ACh (C) which is completely absent from hÎ±6hÎ²4hÎ²3V9âS-nAChRs [(B) and (C)]. hÎ±6(D57N,S156RorN171K)hÎ²4hÎ²3V9âS-nAChRs in rare occasion display minuscule inward currents in response to ACh or nicotine (data not shown). Comparisons between groups were analyzed using one-way ANOVA with Tukeyâs post hoc comparison and only those differ from the control (hÎ±6hÎ²4hÎ²3V9âS-nAChR) are marked with asterisks. ***; p < 0.001.
	Figure 8. Variations in nAChR hÎ±6 subunit influence the ACh sensitivity of hÎ±6hÎ²4*-nAChRs. (A) Representative traces are shown for current responses from oocytes (voltage clamped at â70Â mV) responding to the application of indicated concentrations of ACh (shown with the duration of drug exposure as black bars above the traces) and expressing indicated nAChR (i.e., R1: hÎ±6A184DhÎ²4-nAChR, R2: hÎ±6A184DhÎ²4hÎ²3-nAChR, R3: hÎ±6hÎ²4hÎ²3-nAChR]. (B) Results averaged across experiments were used to produce concentration-response (CR) curves (ordinate-mean normalized currentâÂ±âSEM; abscissa - ligand concentration in log Î¼M) for inward current responses to ACh as indicated for the nAChR expressed in oocytes and voltage clamped at â70Â mV. Current amplitudes are represented as a fraction of the peak inward current amplitude in response to the most efficacious concentration of ACh. Leftward shifts in ACh CR curves for hÎ±6R96HhÎ²4hÎ²3-(â) [(B) (i)], hÎ±6A184DhÎ²4hÎ²3-(â) [(B) (ii)], hÎ±6D199YhÎ²4hÎ²3-(â) [(B) (iii)], or hÎ±6S233ChÎ²4hÎ²3-(â) [(B) (iv)] nAChR are evident relative to that of hÎ±6hÎ²4hÎ²3-nAChR (â). Furthermore ACh curves for hÎ±6A184DhÎ²4-(â ) [(B) (ii)], hÎ±6D199YhÎ²4-(â ) [(B) (iii)], or hÎ±6S233ChÎ²4-(â ) [(B) (iv)] nAChR are shifted leftward relative to those nAChR containing the same subunits but in the additional presence of hÎ²3 subunits. See TableÂ 3 for parameters of ACh action.

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	Figure 1. Localizations of N-terminal variations to primary/secondary structure of nAChR hÎ±6 subunits. (A) Degree of conservation of variant residues in nAChR hÎ±6 subunit in relation to other human nAChR Î± subunits: Human nAChR Î± subunits (Î±1-Î±7, Î±9 and Î±10) are aligned using ClustalW. Indicated residues in nAChR hÎ±6 subunits undergoing variation are fully (Asp92 and Ser156), strongly (Arg87 and Asn171) and weakly (Asp57, Asp199 and Asn203) conserved in human nAChR Î± subunits. Some of the variations in nAChR hÎ±6 subunit are localized to indicated loop regions: Ala112Val (loop A), Ala184Asp (loop B), Ile226Thr (loop C), Asp92Glu (loop D), Asp199Tyr (loop F) and Asn203Thr (loop F) and Asn171Lys (cysteine-loop). (B) Degree of conservation of variant residues in nAChR hÎ±6 subunit in relation to nAChR Î±6 subunits from other organisms: nAChR Î±6 protein sequences extracted from (GenBank) NP_067344.2 (Mouse), NP_004189.1 (Human), NP_990695.1 (Chicken), NP_476532.1 (Rat), NP_001029266.1 (Chimpanzee), XP_001099152.1 (Monkey), XP_584902.3 (Cow) and NP_001036149.1 (Zebrafish) are aligned by using ClustalW. For both (A) and (B); numbering begins at translation start methionine of nAChR hÎ±6 subunit and is shown in the regions of interest. However, only segments of the alignment are presented to identify WT nAChR hÎ±6 subunit AA residues (shaded, upward arrow mark and numbers above them) and their corresponding variations (noted above the numberings). Symbols below sequences indicate fully (), strongly (:) or weakly (.) conserved residues: hÎ±6 subunit AA residues at positions 87 (Arg), 92 (Asp), 156 (Ser) and 171 (Asn) are conserved in both human nAChR Î± subunits and nAChR Î±6 subunits of other organisms. Also shown (shaded) are the nAChR hÎ±6 subunit residues including the loop E residue N143 that alone or in combination Met145 influences the function of hÎ±6-nAChRs [26].
	Figure 2. Localizations of AA variations to secondary structures and interfaces of nAChR hÎ±6 subunit. [(A) and (B)] AA residues undergoing variation are identified in a 3D model of the nAChR hÎ±6 subunit: A 3D homology model of the nAChR hÎ±6 subunit was generated based on the crystal structure of Torpedo muscle nAChR Î± subunit (PDB code: 2BG9:A). Hence structural features are approximate and may deviate from what seen with Î± subunit of Torpedo muscle nAChR. Î² strands constitute inner Î²-sheet (strand Î²1-Î²3, Î²5, Î²6 and Î²8) and outer Î²-sheet (strand Î²4, Î²7, Î²9 and Î²10); and are connect to each other via loops. These loops constitute positive (+) (loops A, B and C) and negative face (loops D, E and F) of Î±6 subunit and contribute to subunit assembly, ligand binding, and formation of ligand binding pocket and/or coupling agonist binding to channel gating. Cysteine loop and other loop residues undergone variations are also identified. [(C)-(E)] Interfaces contributed by Î±6 subunit to formation of Î±6-nAChR: Adhering to the canonical rule of pentamer formation, Î±6Î²2-nAChR would be formed out of three Î±6 and two Î²2 subunits [i.e., (i) (Î±6)3(Î²2)2-nAChR] or two Î±6 and three Î²2 subunits [i.e., (ii) (Î±6)2(Î²2)3-nAChR]. In the event Î²3 or gain-of-function Î²3 (i.e., Î²3V9âS) subunits to be integrated into Î±6Î²2-nAChR complexes these subunits would take the position of 3rd Î±6 subunit in the 1st (i) configuration or 3rd Î²2 subunit in the 2nd (ii) configuration [i.e., (iii) (Î±6)2(Î²2)2(Î²3or Î²3V9âS)-nAChR]. Similarly, Î²4 subunit would substitute Î²2 subunit for formation human Î±6Î²4-[i.e., (Î±6)3(Î²4)2 and (Î±6)2(Î²4)3]-nAChR. For formation of (Î±6)2(Î²4)2Î²3- or (Î±6)2(Î²4)2Î²3V9âS-nAChR Î²3 or Î²3V9âS subunits would substitute one Î±6 subunit in (Î±6)3(Î²4)2 configuration or one Î²4 subunit in (Î±6)2(Î²4)3 configuration. Two presumed agonist (ACh or nicotine and others) binding sites in the interface of Î±6(+) and Î²2(â) subunits are identified as ovals. Variations in the structural loops in the (â)-ve face (loop D, E and F) and (+)-ve face (loop A, B and C) of the hÎ±6 subunit are expected to affect the function of hÎ±6*-nAChRs involving interfaces identified by arrow marks.
	Figure 3. Variations in nAChR hÎ±6 subunit influence the current responses of human Î±6Î²2Î²3V9âS-nAChRs expressed in oocytes using codon optimized nAChR hÎ²2 subunits. Mean (Â±SEM) peak inward current responses upon exposure to 100Â Î¼M nicotine (5Â sec exposure; ordinate) are estimated from oocytes (nâ=â3-7) voltage clamped at â70Â mV and heterologously expressing the indicated nAChR subunits. Current responses of hÎ±6hÎ²2hÎ²3V9âS-nAChR are completely abolished (D57N or S156R), partially abolished (S43P, N46K, R87C, D92E or N171K), not changed (E101K, A112V, A184D, N203T or I226T) and increased (R96H, D199Y or S233C) as a result of the indicated variations in nAChR hÎ±6 subunits. Oocytes coexpressing nAChR hÎ±6(D199Y) subunits, codon optimized hÎ²2 subunits and hÎ²3V9âS subunits yield largest current responses to nicotine. Comparisons of peak current responses between control (hÎ±6hÎ²2hÎ²3V9âS-nAChR) and variant nAChR groups were analyzed using one-way ANOVA with Dunnettâs multiple comparisons test (, pâ<â0.05; and *, pâ<â0.01).
	Figure 4. Variations in nAChR hÎ±6 subunit influence the current responses of human Î±6Î²2Î²3V9âS-nAChR expressed in oocytes using WT nAChR hÎ²2 subunits. Attempts were made to verify the results obtained for human Î±6Î²2Î²3V9âS-nAChR using WT nAChR hÎ²2 subunits instead of codon optimized hÎ²2 subunits. Mean (Â±SEM) peak inward current responses upon exposure to 100Â Î¼M nicotine (5Â sec exposure; ordinate) are estimated from oocytes (nâ=â3-7) voltage clamped at â70Â mV and heterologously expressing the indicated nAChR subunits. (A) Oocytes coexpressing nAChR hÎ±6(R96H, D199Y or S233C), hÎ²2WT and hÎ²3V9âS subunits yield current responses to nicotine that are higher than those expressing nAChR hÎ±6, hÎ²2WT and hÎ²3V9âS subunits. These results are in agreement with those obtained using codon optimized hÎ²2 subunits. (B) Initial recordings 3Â days after cRNA injection indicated that oocytes expressing WT hÎ±6 or variant hÎ±6(E101K, A112V, A184D, N203T or I226T) subunits along with WT hÎ²2 and hÎ²3V9âS subunits yield ~10-30Â nA of current in response to 100Â Î¼M nicotine [see the hÎ±6hÎ²2hÎ²3V9âS-nAChR response in (A)]. However recordings done after 2 additional days of waiting indicated that nicotine elicited current responses from human Î±6E101KÎ²2Î²3V9âS-, Î±6A112VÎ²2Î²3V9âS-, Î±6A184DÎ²2Î²3V9âS-, Î±6N203TÎ²2Î²3V9âS- or Î±6I226TÎ²2Î²3V9âS-nAChRs are equal (pâ>â0.05) to those obtained from human Î±6Î²2Î²3V9âS-nAChRs. These results are in agreement with those obtained using codon optimized hÎ²2 subunits. Comparisons between groups were analyzed using one-way ANOVA with Tukeyâs post hoc comparison and only those differ from the control (hÎ±6hÎ²2hÎ²3V9âS-nAChR) are shown with asterisks. , pâ<â0.05; and *, pâ<â0.01.
	Figure 5. Variations in nAChR hÎ±6 subunit influence the current responses of hÎ±6hÎ²4-nAChRs. Mean (Â±SE) peak inward current responses upon exposure to 100Â Î¼M nicotine (5Â sec exposure; ordinate) are estimated from oocytes (nâ=â6-9) voltage clamped at â70Â mV and heterologously expressing the indicated nAChR subunits. Oocytes coexpressing hÎ±6A184D (variation in loop D) and hÎ²4 subunits yield largest current responses to 100Â Î¼M nicotine. Comparisons of peak current responses between control (hÎ±6hÎ²4-nAChR) and variant groups were analyzed using one-way ANOVA with Dunnettâs multiple comparisons test (, pâ<â0.05; and *, pâ<â0.01).
	Figure 6. Variations in nAChR hÎ±6 subunit influence the current responses of hÎ±6hÎ²4hÎ²3-nAChRs. Mean (Â±SE) peak inward current responses upon exposure to 100Â Î¼M nicotine (5Â sec exposure; ordinate) are estimated from oocytes (nâ=â6-11) voltage clamped at â70Â mV and heterologously expressing the indicated nAChR subunits. Oocytes coexpressing hÎ±6(D57N, R87C, S156R or N171K) subunits plus hÎ²4 and hÎ²3 subunits do not yield current responses to nicotine though those coexpressing hÎ±6, hÎ²4 and hÎ²3 subunit yield fairly robust current responses. hÎ±6 subunit variation Asp92Glu (in loop D) partially abolishes the peak current responses of hÎ±6hÎ²4hÎ²3-nAChRs. hÎ±6 subunit variations Asn46Lys, Arg96His, Glu101Lys, Ala112Val, Ala184Asp, Asn203Thr, Ile226Thr or Ser233Cys do not affect nicotine elicited peak current responses of hÎ±6hÎ²4hÎ²3-nAChRs. Comparisons between control (hÎ±6hÎ²4hÎ²3) and variant groups were analyzed using one-way ANOVA with Dunnettâs multiple comparisons test (, pâ<â0.05; and *, pâ<â0.01).
	Figure 7. Nicotinic agonists act as antagonists at hÎ±6(D57N, S156R or N171K)hÎ²4hÎ²3V9âS-nAChRs. (A) Representative traces are shown for inward or outward current responses from oocytes (voltage clamped at -70 mV) responding to the application of indicated concentrations of nicotine or atropine (shown with the duration of drug exposure as black bars above or below the traces) and expressing hÎ±6hÎ²4hÎ²3V9âS- [(A) (i) and (v)], hÎ±6D57NhÎ²4hÎ²3V9âS-[(A) (ii) and (vi)], hÎ±6S156RhÎ²4hÎ²3V9âS[(A) (iii) and (vii)] or hÎ±6N171KhÎ²4hÎ²3V9âS- [(A) (iv) and (viii)] nAChRs. Calibration bars are for 200 (i), 40 [(ii), (iii) and (iv)] or 100 [(v), (vi), (vii) and (viii)] nA currents (vertical) or 5 sec (horizontal). Results for these and other studies were used to estimate mean (Â±SE) peak outward current responses to 100 Î¼M nicotine (B), 100 Î¼M ACh (C) or 1000 Î¼M atropine (D) from oocytes (n=3-6) heterologously expressing the indicated nAChR subunits. hÎ±6(D57N,S156RorN171K)hÎ²4hÎ²3V9âS-nAChRs elicit outward (positive) current in response to nicotine (B) or ACh (C) which is completely absent from hÎ±6hÎ²4hÎ²3V9âS-nAChRs [(B) and (C)]. hÎ±6(D57N,S156RorN171K)hÎ²4hÎ²3V9âS-nAChRs in rare occasion display minuscule inward currents in response to ACh or nicotine (data not shown). Comparisons between groups were analyzed using one-way ANOVA with Tukeyâs post hoc comparison and only those differ from the control (hÎ±6hÎ²4hÎ²3V9âS-nAChR) are marked with asterisks. ***; p < 0.001.
	Figure 8. Variations in nAChR hÎ±6 subunit influence the ACh sensitivity of hÎ±6hÎ²4*-nAChRs. (A) Representative traces are shown for current responses from oocytes (voltage clamped at â70Â mV) responding to the application of indicated concentrations of ACh (shown with the duration of drug exposure as black bars above the traces) and expressing indicated nAChR (i.e., R1: hÎ±6A184DhÎ²4-nAChR, R2: hÎ±6A184DhÎ²4hÎ²3-nAChR, R3: hÎ±6hÎ²4hÎ²3-nAChR]. (B) Results averaged across experiments were used to produce concentration-response (CR) curves (ordinate-mean normalized currentâÂ±âSEM; abscissa - ligand concentration in log Î¼M) for inward current responses to ACh as indicated for the nAChR expressed in oocytes and voltage clamped at â70Â mV. Current amplitudes are represented as a fraction of the peak inward current amplitude in response to the most efficacious concentration of ACh. Leftward shifts in ACh CR curves for hÎ±6R96HhÎ²4hÎ²3-(â) [(B) (i)], hÎ±6A184DhÎ²4hÎ²3-(â) [(B) (ii)], hÎ±6D199YhÎ²4hÎ²3-(â) [(B) (iii)], or hÎ±6S233ChÎ²4hÎ²3-(â) [(B) (iv)] nAChR are evident relative to that of hÎ±6hÎ²4hÎ²3-nAChR (â). Furthermore ACh curves for hÎ±6A184DhÎ²4-(â ) [(B) (ii)], hÎ±6D199YhÎ²4-(â ) [(B) (iii)], or hÎ±6S233ChÎ²4-(â ) [(B) (iv)] nAChR are shifted leftward relative to those nAChR containing the same subunits but in the additional presence of hÎ²3 subunits. See TableÂ 3 for parameters of ACh action.