Multiple Roles of the Extracellular Vestibule Amino Acid Residues in the Function of the Rat P2X4 Receptor

The binding of ATP to trimeric P2X receptors (P2XR) causes an enlargement of the receptor extracellular vestibule, leading to opening of the cation-selective transmembrane pore, but specific roles of vestibule amino acid residues in receptor activation have not been evaluated systematically. In this study, alanine or cysteine scanning mutagenesis of V47–V61 and F324–N338 sequences of rat P2X4R revealed that V49, Y54, Q55, F324, and G325 mutants were poorly responsive to ATP and trafficking was only affected by the V49 mutation. The Y54F and Y54W mutations, but not the Y54L mutation, rescued receptor function, suggesting that an aromatic residue is important at this position. Furthermore, the Y54A and Y54C receptor function was partially rescued by ivermectin, a positive allosteric modulator of P2X4R, suggesting a rightward shift in the potency of ATP to activate P2X4R. The Q55T, Q55N, Q55E, and Q55K mutations resulted in non-responsive receptors and only the Q55E mutant was ivermectin-sensitive. The F324L, F324Y, and F324W mutations also rescued receptor function partially or completely, ivermectin action on channel gating was preserved in all mutants, and changes in ATP responsiveness correlated with the hydrophobicity and side chain volume of the substituent. The G325P mutant had a normal response to ATP, suggesting that G325 is a flexible hinge. A topological analysis revealed that the G325 and F324 residues disrupt a β-sheet upon ATP binding. These results indicate multiple roles of the extracellular vestibule amino acid residues in the P2X4R function: the V49 residue is important for receptor trafficking to plasma membrane, the Y54 and Q55 residues play a critical role in channel gating and the F324 and G325 residues are critical for vestibule widening.     

ATP binding at human P2X1 receptors. Contribution of aromatic and basic amino acids revealed using mutagenesis and partial agonists

P2X receptors comprise a family of ATP-gated ion channels with the basic amino acids Lys-68, Arg-292, and Lys-309 (P2X(1) receptor numbering) contributing to agonist potency. In many ATP-binding proteins aromatic amino acids coordinate the binding of the adenine group. There are 20 conserved aromatic amino acids in the extracellular ligand binding loop of at least 6 of the 7 P2X receptors. We used alanine replacement mutagenesis to determine the effects of individual conserved aromatic residues on the properties of human P2X(1) receptors expressed in Xenopus oocytes. ATP evoked concentration-dependent (EC(50) approximately 1 microm) desensitizing currents at wild-type receptors and for the majority of mutants there was no change (10 residues) or a <6-fold decrease in ATP potency (6 mutants). Mutants F195A and W259A failed to form detectable channels at the cell surface. F185A and F291A produced 10- and 160-fold decreases in ATP potency. The partial agonists 2',3'-O-(4-benzoyl)-ATP (BzATP) and P(1),P(5)-di(adenosine 5')-pentaphosphate (Ap(5)A) were tested on a range of mutants that decreased ATP potency to determine whether this resulted predominantly from changes in agonist binding or gating of the channel. At K68A and K309A receptors BzATP and Ap(5)A had essentially no agonist activity but antagonized, or for R292A potentiated, ATP responses. At F185A receptors BzATP was an antagonist but Ap(5)A no longer showed affinity for the receptor. These results suggest that residues Lys-68, Phe-185, Phe-291, Arg-292, and Lys-309 contribute to ligand binding at P2X(1) receptors, with Phe-185 and Phe-291 coordinating the binding of the adenine ring of ATP.     

Structural Insights into the Function of P2X4: An ATP-Gated Cation Channel of Neuroendocrine Cells

The P2X4 receptor (P2X4R) is a member of a family of ATP-gated cation channels that are composed of three subunits. Each subunit has two transmembrane (TM) domains linked by a large extracellular loop and intracellularly located N- and C-termini. The receptors are expressed in excitable and non-excitable cells and have been implicated in the modulation of membrane excitability, calcium signaling, neurotransmitter and hormone release, and pain physiology. P2X4Rs activate rapidly and desensitize within the seconds of agonist application, both with the rates dependent on ATP concentrations, and deactivate rapidly and independently of ATP concentration. Disruption of conserved cysteine ectodomain residues affects ATP binding and gating. Several ectodomain residues of P2X4R were identified as critical for ATP binding, including K67, K313, and R295. Ectodomain residues also account for the allosteric regulation of P2X4R; H140 is responsible for copper binding and H286 regulates receptor functions with protons. Ivermectin sensitized receptors, amplified the current amplitude, and slowed receptor deactivation by binding in the TM region. Scanning mutagenesis of TMs revealed the helical topology of both domains, and suggested that receptor function is critically dependent on the conserved Y42 residue. In this brief article, we summarize this study and re-interpret it using a model based on crystallization of the zebrafish P2X4.1 receptor.     

Identification of Functionally Important Residues of the Rat P2X4 Receptor by Alanine Scanning Mutagenesis of the Dorsal Fin and Left Flipper Domains

Crystallization of the zebrafish P2X4 receptor in both open and closed states revealed conformational differences in the ectodomain structures, including the dorsal fin and left flipper domains. Here, we focused on the role of these domains in receptor activation, responsiveness to orthosteric ATP analogue agonists, and desensitization. Alanine scanning mutagenesis of the R203-L214 (dorsal fin) and the D280-N293 (left flipper) sequences of the rat P2X4 receptor showed that ATP potency/efficacy was reduced in 15 out of 26 alanine mutants. The R203A, N204A, and N293A mutants were essentially non-functional, but receptor function was restored by ivermectin, an allosteric modulator. The I205A, T210A, L214A, P290A, G291A, and Y292A mutants exhibited significant changes in the responsiveness to orthosteric analog agonists 2-(methylthio)adenosine 5′-triphosphate, adenosine 5′-(γ-thio)triphosphate, 2′(3′-O-(4-benzoylbenzoyl)adenosine 5′-triphosphate, and α,β-methyleneadenosine 5′-triphosphate. In contrast, the responsiveness of L206A, N208A, D280A, T281A, R282A, and H286A mutants to analog agonists was comparable to that of the wild type receptor. Among these mutants, D280A, T281A, R282A, H286A, G291A, and Y292A also exhibited increased time-constant of the desensitizing current response. These experiments, together with homology modeling, indicate that residues located in the upper part of the dorsal fin and left flipper domains, relative to distance from the channel pore, contribute to the organization of the ATP binding pocket and to the initiation of signal transmission towards residues in the lower part of both domains. The R203 and N204 residues, deeply buried in the protein, may integrate the output signal from these two domains towards the gate. In addition, the left flipper residues predominantly account for the control of transition of channels from an open to a desensitized state.     

Amino acid residues constituting the agonist binding site of the human P2X3 receptor

Homomeric P2X3 receptors are present in sensory ganglia and participate in pain perception. Amino acid (AA) residues were replaced in the four supposed nucleotide binding segments (NBSs) of the human (h) P2X3 receptor by alanine, and these mutants were expressed in HEK293 cells and Xenopus laevis oocytes. Patch clamp and two-electrode voltage clamp measurements as well as the Ca(2+) imaging technique were used to compare the concentration-response curves of the selective P2X1,3 agonist α,β-methylene ATP obtained at the wild-type P2X3 receptor and its NBS mutants. Within these NBSs, certain Gly (Gly-66), Lys (Lys-63, Lys-176, Lys-284, Lys-299), Asn (Asn-177, Asn-279), Arg (Arg-281, Arg-295), and Thr (Thr-172) residues were of great importance for a full agonist response. However, the replacement of further AAs in the NBSs by Ala also appeared to modify the amplitude of the current and/or [Ca(2+)](i) responses, although sometimes to a minor degree. The agonist potency decrease was additive after the simultaneous replacement of two adjacent AAs by Ala (K65A/G66A, F171A/T172A, N279A/F280A, F280A/R281A) but was not altered after Ala substitution of two non-adjacent AAs within the same NBS (F171A/N177A). SDS-PAGE in the Cy5 cell surface-labeled form demonstrated that the mutants appeared at the cell surface in oocytes. Thus, groups of AAs organized in NBSs rather than individual amino acids appear to be responsible for agonist binding at the hP2X3 receptor. These NBSs are located at the interface of the three subunits forming a functional receptor.     

Molecular determinants of cardiac K(ATP) channel activation by epoxyeicosatrienoic acids

We have previously reported that epoxyeicosatrienoic acids (EETs), the cytochrome P450 epoxygenase metabolites of arachidonic acid, are potent stereospecific activators of the cardiac K(ATP) channel. The epoxide group in EET is critical for reducing channel sensitivity to ATP, thereby activating the channel. This study is to identify the molecular sites on the K(ATP) channels for EET-mediated activation. We investigated the effects of EETs on Kir6.2delta C26 with or without the coexpression of SUR2A and on Kir6.2 mutants of positively charged residues known to affect channel activity coexpressed with SUR2A in HEK293 cells. The ATP IC50 values were significantly increased in Kir6.2 R27A, R50A, K185A, and R201A but not in R16A, K47A, R54A, K67A, R192A, R195A, K207A, K222A, and R314A mutants. Similar to native cardiac K(ATP) channel, 5 microM 11,12-EET increased the ATP IC50 by 9.6-fold in Kir6.2/SUR2A wild type and 8.4-fold in Kir6.2delta C26. 8,9- and 14,15-EET regioisomers activated the Kir6.2 channel as potently as 11,12-EET. 8,9- and 11,12-EET failed to change the ATP sensitivity of Kir6.2 K185A, R195A, and R201A, whereas their effects were intact in the other mutants. 14,15-EET had a similar effect with K185A and R201A mutants, but instead of R195A, it failed to activate Kir6.2R192A. These results indicate that activation of Kir6.2 by EETs does not require the SUR2A subunit, and the region in the Kir6.2 C terminus from Lys-185 to Arg-201 plays a critical role in EET-mediated Kir6.2 channel activation. Based on computer modeling of the Kir6.2 structure, we infer that the EET-Kir6.2 interaction may allosterically change the ATP binding site on Kir6.2, reducing the channel sensitivity to ATP.     

Promotion of cathepsin L activity in newt spermatogonial apoptosis induced by prolactin

Residues considered essential for ATP binding to the human P2X(7) receptor (hP2X(7)R) were investigated. HEK293 cells or Xenopus oocytes were transfected with wild-type or site-directed mutants of hP2X(7)R constructs and channel/pore activity measured in the presence of ATP or 2',3'-O-(4-benzoylbenzoyl)-ATP (BzATP). Barium uptake and ethidium influx into HEK293 cells were abolished in cells expressing K193A and K311A mutants, and were partially reduced in cells expressing mutant P210A. K193A and K311A mutations also completely abolished responses to ATP and BzATP in Xenopus oocytes as measured by electrophysiology. These results indicate that K193 and K311 are essential residues in ATP binding in the hP2X(7)R.     

Contribution of the region Glu181 to Val200 of the extracellular loop of the human P2X1 receptor to agonist binding and gating revealed using cysteine scanning mutagenesis1

At the majority of mutants in the region Glu181-Val200 incorporating a conserved AsnPheThrΦΦxLys motif cysteine substitution had no effect on sensitivity to ATP, partial agonists, or methanethiosulfonate (MTS) compounds. For the F185C mutant the efficacy of partial agonists was reduced by ∼ 90% but there was no effect on ATP potency or the actions of MTS reagents. At T186C, F188C and K190C mutants ATP potency and partial agonists responses were reduced. The ATP sensitivity of the K190C mutant was rescued towards WT levels by positively charged (2-aminoethyl)methanethiosulfonate hydrobromide and reduced by negatively charged sodium (2-sulfonatoethyl) methanethiosulfonate. Both MTS reagents decreased ATP potency at the T186C mutant, and abolished responses at the F195C mutant. ³²P-2-azido ATP binding to the mutants T186C and K190C was sensitive to MTS reagents consistent with an effect on binding, however binding at F195C was unaffected indicating an effect on gating. The accessibility of the introduced cysteines was probed with (2-aminoethyl)methanethiosulfonate hydrobromide-biotin, this showed that the region Thr186-Ser192 is likely to form a beta sheet and that accessibility is blocked by ATP. Taken together these results suggest that Thr186, Phe188 and Lys190 are involved in ATP binding to the receptor and Phe185 and Phe195 contribute to agonist evoked conformational changes.     

The role of positively charged amino acids in ATP recognition by human P2X(1) receptors

P2X receptors for ATP are a family of ligand-gated cation channels. There are 11 conserved positive charges in the extracellular loop of P2X receptors. We have generated point mutants of these conserved residues (either Lys --> Arg, Lys --> Ala, Arg --> Lys, or Arg --> Ala) in the human P2X(1) receptor to determine their contribution to the binding of negatively charged ATP. ATP evoked concentration-dependent (EC(50) approximately 0.8 microm) desensitizing responses at wild-type (WT) P2X(1) receptors expressed in Xenopus oocytes. Suramin produced a parallel rightward shift in the concentration response curve with an estimated pK(B) of 6.7. Substitution of amino acids at positions Lys-53, Lys-190, Lys-215, Lys-325, Arg-202, Arg-305, and Arg-314 either had no effect or only a small change in ATP potency, time course, and/or suramin sensitivity. Modest changes in ATP potency were observed for mutants at K70R and R292K/A (20- and 100-fold decrease, respectively). Mutations at residues K68A and K309A reduced the potency of ATP by >1400-fold and prolonged the time course of the P2X(1) receptor current but had no effect on suramin antagonism. Lys-68, Lys-70, Arg-292, and Lys-309 are close to the predicted transmembrane domains of the receptor and suggest that the ATP binding pocket may form close to the channel vestibule.     

Inter-subunit disulfide cross-linking in homomeric and heteromeric P2X receptors

P2X receptors are ATP-gated cation channels and assembled as homotrimers or heterotrimers from seven cloned subunits. Each subunit contains two transmembrane domains connected by a large extracellular loop. We have previously shown that replacement of two conserved residues, K68 and F291, by cysteine residues leads to disulfide cross-linking between neighbouring P2X₁ subunits. Since mutation of these residues results in a reduced ATP potency and cysteine cross-linking is prevented in the presence of ATP, we suggested an inter-subunit ATP binding site. To investigate whether the proximity of these residues is preserved in other P2X subtypes, we tested for spontaneous cystine formation between the corresponding P2X₂ (K69C, F289C), P2X₃ (K63C, F280C), and P2X₄ (K67C, F294C) mutants upon pairwise expression in Xenopus laevis oocytes. Non-reducing SDS-PAGE analysis of the purified receptors revealed a specific dimer formation between P2X₂K69C and P2X₂F289C mutants. Likewise, co-expression of P2X₁K68C and P2X₂F289C, but not P2X₁F291C and P2X₂K69C, mutants resulted in dimer formation between the respective subunits. Cross-linked P2X_1/2 heteromers showed strongly reduced or absent function that was selectively recovered upon treatment with DTT. Cross-linking was less efficient between P2X₃ or P2X₄ mutants but could be enhanced by the short cysteine-reactive cross-linker MTS-2-MTS. These results show that the spatial proximity and/or orientation of residues analogous to positions K68 and F291 in P2X₁ are preserved in P2X₂ receptors and at one of two possible interfaces in heteromeric P2X_1/2 receptors but appears to be redundant for P2X₃ and P2X₄ receptor function. EBSA Satellite Meeting: Ion channels, Leeds, July 2007.     

Identification and analysis of conserved sequence motifs in cytochrome P450 family 2. Functional and structural role of a motif 187RFDYKD192 in CYP2B enzymes

Using a multiple alignment of 175 cytochrome P450 (CYP) family 2 sequences, 20 conserved sequence motifs (CSMs) were identified with the program PCPMer. Functional importance of the CSM in CYP2B enzymes was assessed from available data on site-directed mutants and genetic variants. These analyses suggested an important role of the CSM 8, which corresponds to(187)RFDYKD(192) in CYP2B4. Further analysis showed that residues 187, 188, 190, and 192 have a very high rank order of conservation compared with 189 and 191. Therefore, eight mutants (R187A, R187K, F188A, D189A, Y190A, K191A, D192A, and a negative control K186A) were made in an N-terminal truncated and modified form of CYP2B4 with an internal mutation, which is termed 2B4dH/H226Y. Function was examined with the substrates 7-methoxy-4-(trifluoromethyl)coumarin (7-MFC), 7-ethoxy-4-(trifluoromethyl)coumarin (7-EFC), 7-benzyloxy-4-(trifluoromethyl)coumarin (7-BFC), and testosterone and with the inhibitors 4-(4-chlorophenyl)imidazole (4-CPI) and bifonazole (BIF). Compared with the template and K186A, the mutants R187A, R187K, F188A, Y190A, and D192A showed > or =2-fold altered substrate specificity, k(cat), K(m), and/or k(cat)/K(m) for 7-MFC and 7-EFC and 3- to 6-fold decreases in differential inhibition (IC(50,BIF)/IC(50,4-CPI)). Subsequently, these mutants displayed 5-12 degrees C decreases in thermal stability (T(m)) and 2-8 degrees C decreases in catalytic tolerance to temperature (T(50)) compared with the template and K186A. Furthermore, when R187A and D192A were introduced in CYP2B1dH, the P450 expression and thermal stability were decreased. In addition, R187A showed increased activity with 7-EFC and decreased IC(50,BIF)/IC(50,4-CPI) compared with 2B1dH. Analysis of long range residue-residue interactions in the CYP2B4 crystal structures indicated strong hydrogen bonds involving Glu(149)-Asn(177)-Arg(187)-Tyr(190) and Asp(192)-Val(194), which were significantly-reduced/abolished by the Arg(187)-->Ala and Asp(192)-->Alasubstitutions, respectively.     

Mutagenesis studies of conserved proline residues of human P2X receptors for ATP indicate that proline 272 contributes to channel function

Proline residues can play a major role in the secondary structure of proteins. In the extracellular ATP binding loop of P2X receptors there are four totally conserved proline residues (P2X1 receptor numbering; P93, P166, P228 and P272) and three less conserved residues P196 (six of seven isoforms), P174 and P225 (five of seven isoforms). We have mutated individual conserved proline residues in the human P2X1 receptor and determined their properties. Mutants were expressed in Xenopus oocytes and characterized using a two-electrode voltage clamp. Mutants P166A, P174A, P196A, P225A and P228A had no effect on ATP potency compared with wild-type and P93A had a fourfold decrease in ATP potency. The P272A, P272D and P272K receptor mutants were expressed at the cell surface; however, these mutants were non-functional. In contrast, P272I, P272G and P272F produced functional channels, with either no effect or a 2.5- or 6.5-fold increase in ATP potency, respectively. At P272F receptors the apparent affinity of the ATP analogue antagonist 2',3'-O-(2,4,6-trinitrophenyl)-ATP was increased by 12.5-fold. These results suggest that individual proline residues are not essential for normal P2X receptor function and that the receptor conformation around P272 contributes to ATP binding at the receptor.     

Targeted suppression of the ferroxidase and iron trafficking activities of the multicopper oxidase Fet3p from<Emphasis Type="Italic"> Saccharomyces cerevisiae</Emphasis>

The Fet3 protein in Saccharomyces cerevisiae is a multicopper oxidase tethered to the outer surface of the yeast plasma membrane. Fet3p catalyzes the oxidation of Fe(2+) to Fe(3+); this ferroxidation reaction is an obligatory first step in high-affinity iron uptake through the permease Ftr1p. Here, kinetic analyses of several Fet3p mutants identify residues that contribute to the specificity that Fet3p has for Fe(2+), one of which is essential also to the coupling of the ferroxidase and uptake processes. The spectral and kinetic properties of the D278A, E185D and A, Y354F and A, and E185A/Y354A mutants of a soluble form of Fet3p showed that all of the mutants exhibited the normal absorbance at 330 nm and 608 nm due to the type 3 and type 1 copper sites in Fet3p, respectively. The EPR spectra of the mutants were also equivalent to wild-type, showing that the type 1 and type 2 Cu(II) sites in the proteins were not perturbed. The only marked kinetic defects measured in vitro were increases in K(M) for Fe(2+) exhibited by the D278A, E185A, Y354A, and E185A/Y354A mutants. These results suggest that these three residues contribute to the ferroxidase specificity site in Fet3p. In vivo analysis of these mutant proteins in their membrane-bound form showed that only E185 mutants exhibited kinetic defects in (59)Fe uptake. For the Fet3p(E185D) mutant, K(M) for iron was 300-fold greater than the wild-type K(M), while Fet3p(E185A) was completely inactive in support of iron uptake. In situ fluorescence demonstrated that all of the mutant Fet3 proteins, in complex with an Ftr1p:YFP fusion protein, were trafficked normally to the plasma membrane. These results suggest that E185 contributes to Fe(2+ )binding to Fet3p and to the subsequent trafficking of the Fe(3+) produced to Ftr1p.     

Contribution of conserved polar glutamine, asparagine and threonine residues and glycosylation to agonist action at human P2X1 receptors for ATP

The role of conserved polar glutamine, asparagine and threonine residues in the large extracellular loop, and glycosylation, to agonist action at human P2X1 receptors was tested by generating alanine substitution mutants. For the majority of mutants (Q56A, Q95A, T104A, T109A, Q112A, Q114A, T146A, N153A, T158A, N184A, N191A, N242A, N300A) alanine substitution had no effect on ATP potency. The mutants Q95A, Q112A, Q114A and T158A showed changes in efficacy for the partial agonists BzATP and Ap5A, suggesting that these polar residues may contribute to the gating of the channel. The mutants T186A, N204A and N290A had six-, three- and 60-fold decreases in ATP potency, respectively. For T186A and N290A, the partial agonists BzATP and Ap5A were no longer agonists but still bind to the receptor as shown by the ability to modulate the response to co-applied ATP. N153, N184 and N242 are glycosylated in the endoplasmic reticulum and N300 acquires complex glycosylation in the golgi. These results aid in refining a model for ATP binding at the P2X1 receptor where the residues F185T186, and the conserved triplet N290F291R292, are likely to play a role in ATP action at the receptor.     

Identification of a major heparin-binding site in kallistatin

Kallistatin is a heparin-binding serine proteinase inhibitor (serpin), which specifically inhibits human tissue kallikrein by forming a covalent complex. The inhibitory activity of kallistatin is blocked upon its binding to heparin. In this study we attempted to locate the heparin-binding site of kallistatin using synthetic peptides derived from its surface regions and by site-directed mutagenesis of basic residues in these surface regions. Two synthetic peptides, containing clusters of positive-charged residues, one derived from the F helix and the other from the region encompassing the H helix and C2 sheet of kallistatin, were used to assess their heparin binding activity. Competition assay analysis showed that the peptide derived from the H helix and C2 sheet displayed higher and specific heparin binding activity. The basic residues in both regions were substituted to generate three kallistatin double mutants K187A/K188A (mutations in the F helix) and K307A/R308A and K312A/K313A (mutations in the region between the H helix and C2 sheet), using a kallistatin P1Arg variant as a scaffold. Analysis of these mutants by heparin-affinity chromatography showed that the heparin binding capacity of the variant K187A/K188A was not altered, whereas the binding capacity of K307A/R308A and K312A/K313A mutants was markedly reduced. Titration analysis with heparin showed that the K312A/K313A mutant has the highest dissociation constant. Like kallistatin, the binding activity of K187A/K188A to tissue kallikrein was blocked by heparin, whereas K307A/R308A and K312A/K313A retained significant binding and inhibitory activities in the presence of heparin. These results indicate that the basic residues, particularly Lys(312)-Lys(313), in the region between the H helix and C2 sheet of kallistatin, comprise a major heparin-binding site responsible for its heparin-suppressed tissue kallikrein binding.     

Conformational changes during human P2X7 receptor activation examined by structural modelling and cysteine-based cross-linking studies

The P2X7 receptor (P2X7R) is important in mediating a range of physiological functions and pathologies associated with tissue damage and inflammation and represents an attractive therapeutic target. However, in terms of their structure-function relationships, the mammalian P2X7Rs remain poorly characterised compared to some of their other P2XR counterparts. In this study, combining cysteine-based cross-linking and whole-cell patch-clamp recording, we examined six pairs of residues (A44/I331, D48/I331, I58/F311, S60/L320, I75/P177 and K81/V304) located in different parts of the extracellular and transmembrane domains of the human P2X7R. These residues are predicted to undergo substantial movement during the transition of the receptor ion channel from the closed to the open state, predictions which are made based on structural homology models generated from the crystal structures of the zebrafish P2X4R. Our results provide evidence that among the six pairs of cysteine mutants, D48C/I133C and K81C/V304C formed disulphide bonds that impaired the channel gating to support the notion that such conformational changes, particularly those in the outer ends of the transmembrane domains, are critical for human P2X7R activation.     

The role of NH2-terminal positive charges in the activity of inward rectifier KATP channels

Approximately half of the NH(2) terminus of inward rectifier (Kir) channels can be deleted without significant change in channel function, but activity is lost when more than approximately 30 conserved residues before the first membrane spanning domain (M1) are removed. Systematic replacement of the positive charges in the NH(2) terminus of Kir6.2 with alanine reveals several residues that affect channel function when neutralized. Certain mutations (R4A, R5A, R16A, R27A, R39A, K47A, R50A, R54A, K67A) change open probability, whereas an overlapping set of mutants (R16A, R27A, K39A, K47A, R50A, R54A, K67A) change ATP sensitivity. Further analysis of the latter set differentiates mutations that alter ATP sensitivity as a consequence of altered open state stability (R16A, K39A, K67A) from those that may affect ATP binding directly (K47A, R50A, R54A). The data help to define the structural determinants of Kir channel function, and suggest possible structural motifs within the NH(2) terminus, as well as the relationship of the NH(2) terminus with the extended cytoplasmic COOH terminus of the channel.     

Mg(2+) inhibits ATP-activated current mediated by rat P2X4 receptors expressed in Xenopus oocytes

To investigate the modulation of Mg(2+) on rat P2X4 receptors and its underlying mechanism, we transcribed cDNA coding for wild-type and mutant P2X4 receptors to cRNA in vitro, injected the cRNA to oocytes of Xenopus laevis using the microinjection technique and revealed the effect of Mg(2+) on ATP-activated currents (I(ATP)) mediated by P2X4 receptors using the two-electrode whole-cell voltage clamp technique. The effects of extracellular Mg(2+) on I(ATP) were as follows: (1) In oocytes expressing P2X4 receptors, Mg(2+) with concentration ranging from 0.5-10 mmol/L inhibited the amplitude of I(ATP) in a concentration-dependent and reversible manner, with a 50% inhibitory concentration value (IC(50)) of (1.24 ± 0.07) mmol/L for current activated by 100 μmol/L ATP. (2) Mg(2+) (1 mmol/L) shifted the dose-response curve for I(ATP) right-downward without changing the EC(50), but reduced the maximal current (E(max)) by (42.0 ± 2.1)%. (3) After being preincubated with Mg(2+) for 80 s, the inhibitory effect of the Mg(2+) on I(ATP) reached the maximum. (4) The inhibition of Mg(2+) on I(ATP) was independent of membrane potential from -120 mV to +60 mV. (5) Compared with the current activated by 100 μmol/L ATP in the wild-type P2X4 receptors, mutant P2X4 D280Q responded to the application of 100 μmol/L ATP with a smaller current. The peak current was only (4.12 ± 0.15)% of that seen in wild-type receptors. Mutant P2X4 D280E responded to ATP stimulation with a current similar to that observed in cells expressing wild-type receptors. (6) When Asp280 was removed from P2X4, the current amplitude of I(ATP) was increased almost one-fold, and Mg(2+) with concentration ranging from 0.5-10 mmol/L did not affect the I(ATP) significantly. The results suggest that Mg(2+) inhibits I(ATP) mediated by P2X4 receptors non-competitively, reversibly, concentration-dependently, time-dependently and voltage-independently. The inhibitory effect of Mg(2+) might be realized by acting on the site Asp280 of the P2X4 receptors.