Dissection of mitogenic and neurodegenerative actions of cystine and glutamate in malignant gliomas.

Malignant glioma represents one of the most aggressive and lethal human neoplasias. A hallmark of gliomas is their rapid proliferation and destruction of vital brain tissue, a process in which excessive glutamate release by glioma cells takes center stage. Pharmacologic antagonism with glutamate signaling through ionotropic glutamate receptors attenuates glioma progression in vivo, indicating that glutamate release by glioma cells is a prerequisite for rapid glioma growth. Glutamate has been suggested to promote glioma cell proliferation in an autocrine or paracrine manner, in particular by activation of the (RS)-α-amino-3-hydroxy-5-methylisoxazole-4-propionic acid hydrate (AMPA) subtype of glutamate receptors. Here, we dissect the effects of glutamate secretion on glioma progression. Glioma cells release glutamate through the amino-acid antiporter system X(c)(-), a process that is mechanistically linked with cystine incorporation. We show that disrupting glutamate secretion by interfering with the system X(c)(-) activity attenuates glioma cell proliferation solely cystine dependently, whereas glutamate itself does not augment glioma cell growth in vitro. Neither AMPA receptor agonism nor antagonism affects glioma growth in vitro. On a molecular level, AMPA insensitivity is concordant with a pronounced transcriptional downregulation of AMPA receptor subunits or overexpression of the fully edited GluR2 subunit, both of which block receptor activity. Strikingly, AMPA receptor inhibition in tumor-implanted brain slices resulted in markedly reduced tumor progression associated with alleviated neuronal cell death, suggesting that the ability of glutamate to promote glioma progression strictly requires the tumor microenvironment. Concerning a potential pharmacotherapy, targeting system X(c)(-) activity disrupts two major pathophysiological properties of glioma cells, that is, the induction of excitotoxic neuronal cell death and incorporation of cystine required for rapid proliferation.

In vivo investigations on the cholinesterase-inhibiting effects of tricyclic quinazolinimines: scopolamine-induced cognitive impairments in rats are attenuated at low dosage and reinforced at higher dosage.

Tricyclic quinazolinimines as a novel class of potent inhibitors of cholinesterases in vitro are micro- and sub-micromolar inhibitors with activities at both acetyl- (AChE) and butyrylcholinesterase (BChE) or at BChE only. To further establish the antiamnesic properties of this class of compounds, an in vivo test system has been established. Cognitive impairment in rats was reversibly induced by scopolamine (0.05 mg/100 g body weight) and evaluated in an eight-arm radial maze. A representative quinazolinimine (MD212) showed attenuation of cognitive deficits at a low dosage (0.01 mg/100 g body weight), whereas at a high dosage (>0.1 mg/100 g body weight) the effect of scopolamine is markedly reinforced. As MD212 applied alone does not influence rat's cognition at all, the reinforcement of scopolamine effect has to be due to the amplification of scopolamine action possibly by (1) inhibition of scopolamine metabolism, (2) influence of scopolamine on MD212 metabolism or (3) allosteric modulation of mACh receptors. Receptor-binding studies proved hypothesis (3): MD212 stabilizes [3H]N-methylscopolamine binding to muscarinic receptors allosterically.

Structure/activity relationships of M2 muscarinic allosteric modulators.

Allosteric modulation of G protein-coupled receptors has been intensively studied at muscarinic acetylcholine receptors. Findings made with archetypal allosteric agents such as gallamine, alcuronium, and bis(ammonio)alkane-type agents revealed that binding of orthosteric ligands that attach to the acetylcholine site can be allosterically decreased or increased or left unaltered in a subtype-selective fashion. Analyses of structure/activity relationships (SARs) help to elucidate the molecular events underlying the allosteric action and they may pilot the development of new allosteric agents with improved properties and therapeutic perspectives. With a focus on SARs, this review illustrates the principles of muscarinic allosteric interactions, gives an overview of SARs in congeners of archetypal allosteric agents, and considers the topology of M(2) muscarinic allosteric interactions that are characterized by divergent binding modes.

Muscarinic allosteric modulation: M2/M3 subtype selectivity of gallamine is independent of G-protein coupling specificity.

Among the five subtypes of muscarinic acetylcholine receptors, the sensitivity towards allosteric modulation is generally higher in M2 and M4 receptors that preferentially couple to inhibitory G-proteins of the Gi/o type than in M1, M3, and M5 that preferentially couple to stimulatory G-proteins such as Gq/11. We aimed to check whether the high allosteric sensitivity of the M2 receptor compared to M3 is related to the differential G-protein coupling preference. As the third intracellular loop (i3) is known to be the major determinant in receptor G-protein coupling specificity, we used wild-type M2 and M3 receptors and the related chimeric constructs with exchanged i3-loops, i.e., M2 containing M3-i3 (M2/M3-i3) and M3 containing M2-i3 (M3/M2-i3). The allosteric effect of the archetypal modulator gallamine on the dissociation and the equilibrium binding of [3H]N-methylscopolamine ([3H]NMS) was measured in membranes of mouse A9L cells stably expressing the wild-type and the chimeric receptors (4 mM Na2HPO4, 1 mM KH2PO4, pH 7.4, 23 degrees C). The dissociation of [3H]NMS was monophasic under all conditions studied. Control values of t 1/2 were (means +/- SEM, n = 4-7): M2: 3.8 +/- 0.2 min, M2/M3-i3: 4.8 +/- 0.3 min, M3:43.3 +/- 4.2 min, M3/M2-i3: 41.1 +/- 3.6 min. At M2 receptors, 0.2 microM gallamine allosterically reduced the apparent rate constant of dissociation k-1 to 51 +/- 5% of the control value (n = 5). At M2/M3-i3 the allosteric potency of gallamine was not significantly changed (0.2 microM gallamine --> k-1 = 61 +/- 4%, n = 7). At M3, a 20-fold higher concentration was required for an equieffective allosteric action (10 microM gallamine --> k-1 = 51 +/- 5%, n = 5). The potency of gallamine at M3/M2-i3 was not increased compared with M3 receptors (10 microM gallamine --> k-1 = 73 +/- 2%, n = 4) but even significantly diminished. [3H]NMS equilibrium binding experiments revealed that neither the binding constants of gallamine at free receptor subtypes (pKA,M2: 7.57 +/- 0.04, n = 4; pKA,M3: 5.56 +/- 0.13, n = 3) nor the factors of negative cooperativity with [3H]NMS (alphaM2 = 31 +/- 1, alphaM3 = 3 +/- 0.4) were affected by the exchanged i3-loops (pKA,M2/M3-i3: 7.65 +/- 0.03, pKA,M3/M2-i2: 5.35 +/- 0.24, alphaM2/M3-i3= 30 +/- 2, alphaM3/M2-i2 = 3 +/- 0.7). In conclusion, the different sensitivities of M2 and M3 receptors towards allosteric modulation by gallamine are not related to the G-protein coupling specificity of the receptors.

Hexamethonium-type allosteric modulators of the muscarinic receptors bearing lateral dibenzazepine moieties.

Alkane-bisammonium compounds carrying lateral phthalimido substituents are known to have a high affinity for the allosteric binding site of the acetylcholine M2 receptor. The purpose of this study was to replace the lateral phthalimido moieties with rigid tricyclic skeletons of a large volume in order to learn more about the function of the lateral heterocycles. In addition, methyl groups were introduced into the lateral connecting chains. Allosteric inhibition of the dissociation of [3H]N-methylscopolamine from the M2 receptors in porcine cardiac homogenates served to indicate binding of the test compounds to the allosteric site. The phthalimido groups could be replaced with dibenzazepine moieties without any loss in potency. Interestingly, the additional methyl group in the lateral spacer seems to have a significant influence on the allosteric behaviour.

Bisquaternary caracurine V derivatives as allosteric modulators of ligand binding to M2 acetylcholine receptors.

The allosteric effect on muscarinic acetylcholine M2 receptors of 11 bisquaternary salts of the Strychnos alkaloid caracurine V was determined. The effect was indicated by the concentration which retarded the rate of dissociation of the antagonist [3H]-N-methylscopolamine from porcine cardiac cholinoceptors by a factor of 2 (EC50). The most potent compounds carry allyl and propargyl substituents, respectively. Introduction of more bulky substituents (e.g., benzyl groups) resulted in a considerably reduced allosteric potency. The wide range of EC50 values (3 nM for R = allyl. 1750 nM for R = 2-naphthyl) suggests a sterically restricted binding pocket. Molecular modeling studies indicated that the caracurine V ring system satisfies the pharmacophore model for the allosteric interaction.

Probing the selectivity of allosteric modulators of muscarinic receptors at other G-protein-coupled receptors.

1. The aim of the present investigation was to analyse whether three prototype allosteric modulators of ligand binding to muscarinic receptors, i.e. alcuronium, gallamine, and the alkane-bis-ammonium compound W84 (hexane-1,6-bis[dimethyl-3'-phthalimidopropylammonium bromide]), may have allosteric effects on radioligand-binding characteristics at other G-protein-coupled receptors, such as cerebral A1 adenosine receptors (Gi-coupled), cardiac left ventricular alpha1-adrenoceptors (Gq), and beta-adrenoceptors (Gs). 2. The modulators were applied at concentrations known to be high with regard to the allosteric delay of the dissociation of the antagonist [3H]-N-methylscopolamine (NMS) from muscarinic M2-receptors: 30 micromol l(-1) W84, 30 micromol l(-1) alcuronium, 1000 micromol l(-1) gallamine. As radioligands, we used the adenosine A1-receptor ligand [3H]-cyclopentyl-dipropylxanthine (CPX), the alpha1-adrenoceptor ligand [3H]-prazosin (PRAZ), and the beta-adrenoceptor ligand (-)-[125I]-iodocyanopindolol (ICYP). Allosteric actions on ligand dissociation and the equilibrium binding were measured in the membrane fractions of rat whole forebrain (CPX) and of rat cardiac left ventricle (PRAZ, ICYP, NMS), respectively. 3. CPX and PRAZ showed a monophasic dissociation with half-lives of 5.88+/-0.15 and 12.27+/-0.46 min, respectively. In the case of CPX, neither the binding at equilibrium nor the dissociation characteristics were influenced by the allosteric agents. With PRAZ, the binding at equilibrium remained almost unaltered in the presence of W84, whereas it was reduced to 36+/-2% of the control value with alcuronium and to 42+/-2% with gallamine. The dissociation of PRAZ was not affected by W84, whereas it was moderately accelerated by alcuronium and gallamine. In the case of ICYP, the binding at equilibrium was not affected by the allosteric modulators. The dissociation of ICYP was slow, and after 3 h, more than 50% of the radioligand was still bound, so that a reliable half-life could not be calculated. ICYP dissociation was not affected by W84. In the presence of alcuronium and gallamine, the dissociation curve of ICYP revealed an initial drop from the starting level, followed by the major phase of dissociation being parallel to the control curve. 4. In summary, the allosteric action of the applied agents is not a common feature of G-protein-coupled receptors and appears to be specific for muscarinic receptors.

Structure-activity relationships in a series of bisquaternary bisphthalimidine derivatives modulating the muscarinic M(2)-receptor allosterically.

Hexane-bisammonium-type compounds containing lateral phthalimide moieties are well-established ligands of the common allosteric binding site of muscarinic M(2) receptors. Previous structure-activity relationships (SAR) revealed two positively charged centers and two lateral phthalimide moieties in a defined arrangement to be essential of a high allosteric potency. The purpose of this study was to replace one carbonyl group of the phthalimides with hydrogens, hydroxy, alkoxy, phenyl, benzyl, and benzylidene groups in order to check the influence of these substituents on the allosteric activity in antagonist-linked receptors. The analysis of the quantitative SAR indicated that a high allosteric potency is related to a certain amount of rigidity as well as polarizibility and the ability to form hydrophobic interactions.

Probing the size of a hydrophobic binding pocket within the allosteric site of muscarinic acetylcholine M2-receptors.

Hexane-bisammonium-type compounds containing lateral phthalimide moieties are known to have a rather high affinity for the allosteric site of muscarinic M2 receptors. In order to get more insight into the contribution of the lateral substituents for alloster binding affinity, a series of compounds with unilaterally varying imide substituents were synthesized and tested for their ability to retard allosterically the dissociation of [3H]N-methylscopolamine from the receptor protein (control t1/2 = 2 min; 3 mM MgHCO4, 50 mM Tris, pH 7.3, 37 degrees C). Among the test compounds, the naphthalimide containing agent (half maximum effect at ECs5,diss = 60 nM) revealed the highest potency. Apparently, its affinity for the allosteric site in NMS-occupied receptors is 20fold higher compared with the phthalimide containing parent compound W 84. Analysis of quantitative structure-activity relationships yielded a parabolic correlation between the volume of the lateral substituents and the allosteric potency. The maximal volume was determined to be approximately 600 A3 suggesting that the allosteric binding site contains a binding pocket of a defined size for the imide moiety.

Ligands for the common allosteric site of acetylcholine M2-receptors: development and application.

Ligands for the allosteric site of acetylcholine M2 receptors are able to retard the dissociation of simultaneously bound ligands for the orthosteric site. This effect promotes receptor occupation by the orthosteric ligand. The allosteric effect opens various therapeutic perspectives, e.g., in organophosphorus poisoning. The aim of our studies was to optimize the affinity of the modulators for the common allosteric binding site of muscarinic M2 receptors, the orthosteric site of which was liganded with the N-methylscolopamine. The phthalimido substituted hexane-bisammonium compound W84 served as a starting point. Previous molecular modelling studies revealed two positive charges and two aromatic imides in a sandwich-like arrangement to be essential for a high allosteric potency. A three-dimensional quantitative structure activity relationship (3D QSAR) analysis predicted compounds with substituents of increasing size on the lateral imide moieties to enhance the affinity for the allosteric binding site. Thus, we synthesized and pharmacologically evaluated compounds bearing "saturated" phthalimide moieties as well as phthalimidines with substituents of systematically increasing size in position 3 or on the aromatic ring at one or both ends of the molecule. Within each series, QSAR could be derived: 1. "Saturation" of the aromatic ring of the phthalimide moiety results in less potent compounds. 2. Increasing the size of the substituents in position 3 of the phthalimide enhances the potency. 3. Putting substituents on the aromatic part of the phthalimide increases the potency more effectively: the introduction of a methyl group in position 5 gave a compound with a potency in the nanomolar concentration range which was subsequently developed as the first radioligand for the allosteric binding site.

Testing the specificity of allosteric modulators of muscarinic receptors in phylogenetically closely related histamine H1-receptors.

Gallamine, alcuronium and W84 (hexane-1,6-bis[dimethyl-3'-phthalimidopropyl-ammonium bromide]) are prototype allosteric modulators of the G-protein coupled muscarinic acetylcholine receptor family, especially of the M2-subtype. In order to probe the specificity of muscarinic allosteric modulation, we checked whether these agents interact with histamine H1-receptors which have a high homology with muscarinic receptors. Binding experiments (38 mM Na2HPO4, 12 mM KH2PO4, pH 7.5) were performed with the H1-receptor antagonist [3H]mepyramine ([3H]MEP) in guinea pig cerebellar homogenates. For the sake of comparison, binding of [3H]N-methylscopolamine ([3H]NMS) at muscarinic M2-receptors was measured in porcine cardiac homogenates under identical conditions. The modulators retarded [3H]NMS dissociation (t1/2 control=1.3 min) concentration-dependently indicating their allosteric action with half-maximum effects for gallamine at EC50,discs=27 microM, for alcuronium at EC50,diss=53 nM, and for W84 at EC50,diss=170 nM. In contrast, [3H]MEP dissociation from H1-receptors (t1/2,control=2.6 min) remained unchanged up to concentrations of 1 mM of the modulators. Equilibrium binding of [3H]NMS (KD=0.46 nM, Bmax=98 fmol/mg protein) was inhibited by gallamine, elevated by alcuronium and left almost unchanged by W84, indicating negative, positive and nearly neutral cooperativity, respectively, with the radioligand. The ternary complex model of allosteric actions yielded the equilibrium dissociation constants K(A) for the binding of the allosteric modulators to free M2-receptors: K(A,gallamine)=100 nM, K(A,alcuronium)=450 nM, K(A,W84)=69 nM. In H1-receptors, more than 1,000-fold higher concentrations than in M2-receptors were required to elicit an effect on the binding of [3H]MEP (KD=1.2 nM, Bmax=205 fmol/mg protein). Half-maximal reduction was observed at 10 mM for gallamine, 1 mM for alcuronium and 92 microM for W84. In conclusion, the muscarinic modulators have little effect on the histamine H1-receptors.

Modes of allosteric interactions with free and [3H]N-methylscopolamine-occupied muscarinic M2 receptors as deduced from buffer-dependent potency shifts.

Muscarinic M2 acetylcholine receptors contain an allosteric site that is probably located at the entrance of the ligand binding pocket above the orthosteric binding site. With the orthosteric area not occupied, allosteric agents might gain access to this site. The interaction of allosteric agents with orthoster-occupied receptors is known to depend on the buffer conditions in an alloster-specific fashion. Utilizing the buffer-dependent potency shift as an indicator, we aimed to find out for two rod-like shaped and flexible allosteric agents whether or not there is evidence for a switch in the site of attachment in free compared with [3H]N-methylscopolamine ([3H]NMS)-occupied porcine heart M2 receptors. These agents are the bispyridinium compounds WDuo3 (1,3-bis[4-(phthalimidomethoxyimino-methyl)-pyridinium-1-yl] propane dibromide) and Duo3 (4,4'-bis-[(2,6-dichloro-benzyloxy-imino)-methyl]-1,1'-propane-1,3-diyl-bis-pyridinium dibromide). The prototype allosteric agents gallamine and alcuronium were included. Inhibition of [3H]NMS association was taken to reflect alloster interaction with free receptors, inhibition of [3H]NMS dissociation indicated binding to [3H]NMS-occupied receptors. In Na,K,Pi buffer (4 mM Na2HPO4, 1 mM KH2PO4, pH 7.4 at 23 degrees C) compared with Mg,Tris,Cl,Pi buffer (45 mM Tris-HCl, 2.6 mM MgHPO4, pH 7.3 at 37 degrees C) WDuo3 underwent the same loss of potency for the interaction with either free or [3H]NMS-liganded receptors. The loss of potency was quantified by a potency ratio (PR), i.e. the ratio between the concentrations of the modulator leading to a half-maximal delay of [3H]NMS association or dissociation, respectively, in Mg,Tris,Cl,Pi compared with Na,K,Pi. For WDuo3 the ratios were PRass=27 and PRdiss=22, respectively. For Duo3, the interaction with free and [3H]NMS-occupied receptors only slightly depended on the composition of the incubation medium: PRass=1.3, PRdiss=2.8. In contrast to the other agents, the concentration-effect curves of which had slope factors nH not different from unity, the curves of Duo3 were steep (nH about -1.6). For alcuronium the shift factors amounted to PRass=29 and PRdiss=25, for gallamine to PRass=216 and PRdiss=159. In conclusion, there was a wide variation between the allosteric agents with regard to the respective buffer dependence of action. Yet, for a given allosteric agent, the interaction with either free or [3H]NMS-occupied receptors was always characterized by the same buffer-dependent shift. Thus, even the applied rod-shaped allosteric agents do not appear to switch to the orthosteric site in free compared with orthoster-occupied M2 receptors.

Using a radioalloster to test predictions of the cooperativity model for gallamine binding to the allosteric site of muscarinic acetylcholine M(2) receptors.

The muscarinic M(2) receptor contains an orthosteric and an allosteric site. Binding of an allosteric agent may induce a shift alpha of the equilibrium dissociation constant K(D) of a radioligand for the orthosteric site. According to the cooperativity model, the K(A) of alloster binding is expected to be shifted to an identical extent depending on whether the orthosteric site is occupied by the orthoster or not. Here, the novel radioalloster [(3)H]dimethyl-W84 (N,N'-bis[3-(1,3-dihydro-1, 3-dioxo-4-methyl-2H-isoindol-2-yl)propyl]-N,N,N',N'-tetramethyl-1, 6-hexanediaminium diiodide) was applied to directly measure the K(A) shift induced for the prototype allosteric modulator gallamine by binding of N-methylscopolamine (NMS) to the orthosteric site of porcine heart M(2) receptors (4 mM Na(2)HPO(4), 1 mM KH(2)PO(4), pH 7.4; 23 degrees C; data are means +/- S.E.). First, in the common way, the concentration-dependent inhibition by gallamine of [(3)H]NMS equilibrium binding was measured and analyzed using the cooperativity model, which yielded for the affinity of gallamine binding at free receptors a pK(A)= 8.35 +/- 0.09 and a cooperativity factor alpha = 46 (n = 5). The dissociation constant for gallamine binding at NMS-occupied receptors was predicted as p(alpha. K(A)) = 6.69. Labeling of the allosteric site by [(3)H]dimethyl-W84 allowed the measure of competitive displacement curves for gallamine. The K(i) for gallamine at free receptors amounted to pK(i,-NMS) = 8.27 +/- 0.39 (n = 5), which is in line with the prediction of the cooperativtiy model. In the presence of 1 microM NMS, to occupy the orthosteric site, gallamine displaced [(3)H]dimethyl-W84 with pK(i, +NMS) = 6.60 +/- 0.19 (n = 3). Thus, the NMS-induced pK(i) shift amounted to 47, which matches the predicted value of alpha = 46. These results validate the cooperativity model.

[3H]Pramipexole: a selective radioligand for the high affinity dopamine D2 receptor in bovine striatal membranes.

The characterization of [3H]pramipexole binding to bovine striatal membranes is reported in full experimental detail. According to kinetic experiments, saturation and competition studies a single binding site can be selectively labeled which turned out to be the high affinity D2 receptor. Addition of GPP(NH)P resulted in almost complete loss of specific binding. The bovine D2 subtype shows high sequence identity with the human D2 receptor indicating that the heterologous competition assays are of interest for the evaluation of neurotropic drug candidates. Using the representative D2 agonists (+)-7-OH-DPAT, (-)-3-PPP and (S)-7-dipropylaminotetrahydroindolizine the same rank order of affinities was determined as described for rat striata labeled with [3H]pramipexole, however, the Ki values turned out to be significantly higher. Furthermore, the system facilitates structure activity relationship studied on D2 affinity modulating peptides. Using L-prolyl-L-leucyl-glycinamide as an example a significant increase of specific radioligand binding could be measured.

Bisquaternary ligands of the common allosteric site of M2 acetylcholine receptors: search for the minimum essential distances between the pharmacophoric elements.

Structurally diverse molecules, such as alcuronium, gallamine, and tubocurarine as well as W84 and WDUO, are known to interact allosterically with ligand binding to muscarinic M2 acetylcholine receptors. Preliminary molecular modeling studies revealed two positive charges in the middle and two lateral aromatic areas to be essential elements of a high allosteric potency. To find out the optimum distances between these pharmacophoric elements, a systematic variation of the spacer in the series of W84, WDUO, and IWDUO compounds was performed. The allosteric reduction of the rate of dissociation of the antagonist [3H]-N-methylscopolamine from porcine heart M2 receptors served as a test system. The minimal essential distance between the positive charges was found to be 10 A. The length of the peripheral spacers connecting the positive charge and the lateral aromatic moiety appears to depend on the chemical functionality; the peripheral spacers have to be long and flexible enough to position the aromatic skeletons in the spatial neighborhood of the alkane middle chain: in the case of an oxime ether containing peripheral spacer, six atoms are required, and in the case of an alkane chain, four carbon atoms are necessary to adopt the pharmacophoric S-shape conformation.

Identification of a [3H]Ligand for the common allosteric site of muscarinic acetylcholine M2 receptors.

Muscarinic acetylcholine receptors bind allosteric modulators at a site apart from the orthosteric site used by conventional ligands. We tested in cardiac tissue whether modulator binding to ligand-occupied muscarinic M2 receptors is a preferential event that can be detected using a radioactive allosteric agent. The newly synthesized dimethyl-W84 (N,N'-bis[3-(1,3-dihydro-1, 3-dioxo-4-methyl-2H-isoindol-2-yl)propyl]-N,N,N',N'-tetramethyl-1, 6-hexanediaminium diiodide) has a particular high potency at M2 receptors occupied by the conventional antagonist N-methylscopolamine (NMS); dissociation of [3H]NMS is half-maximally retarded at an EC50,diss value of 3 nM. Using obidoxime as an "allosteric antagonist," evidence was found that dimethyl-W84 interacts with the postulated common allosteric site. Binding of [3H]dimethyl-W84 (0.3 nM; specific activity, 168 Ci/mmol) was measured in porcine heart homogenates (4 mM Na2HPO4, 1 mM KH2PO4, pH 7.4, 23 degrees) in the presence of 1 microM NMS. Homologous competition experiments revealed two components of saturable radioligand binding: one with a high affinity (KD = 2 nM) and small capacity ( approximately 30% of total saturable binding) and the other with a 20,000-fold lower affinity. The Bmax value of the high affinity sites (68 fmol/mg protein) matched muscarinic receptor density as determined by [3H]NMS (79 fmol/mg). Prototype allosteric agents, alcuronium, W84 (the parent compound of the radioligand), and gallamine, displaced high affinity [3H]dimethyl-W84 binding concentration-dependently (pKi values = 8.62, 7.83, and 6.72, respectively). The binding affinities of the modulators were in excellent correlation with their potencies to allosterically stabilize NMS/receptor complexes (EC50,diss = 8.40, 7.72, and 6.74, respectively). We conclude that high affinity binding of [3H]dimethyl-W84 reflects occupation of the common allosteric site of M2 receptors.

Interaction of Mg2+ with the allosteric site of muscarinic M2 receptors.

Mg2+-ions have been suspected to attenuate the inhibitory effect of allosteric modulators on the dissociation of orthosteric ligands from muscarinic M2 receptors. It was aimed to gain more insight into the molecular events underlying the effect of Mg2+. The interaction of Mg2+ with the allosteric model compounds W84 (hexane-1,6-bis [dimethyl-3'-phthalimidopropylammonium bromide]) and Chin3/6 (hexane-1 ,6-bis[dimethyl-3'-¿4-oxo-2-phenyl-3,4-dihydro-2H-quinazolin-1-yl propylammonium bromide]) was studied in porcine heart muscarinic receptors, the primary binding site of which was occupied by the ligand [3H]N-methylscopolamine ([3H]NMS). The incubation buffer was composed of 4 mM Na2HPO4 and 1 mM KH2PO4 (pH 7.4, 23 degrees C). The retardation of [3H]NMS dissociation (control t1/2=5.6 min) induced by the allosteric test compounds was diminished by 3 mM Mg2+ to a greater extent than to be expected with regard to its contribution to the ionic strength of the buffer solution. Concentration-effect curves for the allosteric retardation of [3H]NMS dissociation by W84 (half maximal effective concentration EC0.5=24 nM in the absence of Mg2+) and by Chin3/6 (EC0.5=28 nM) were shifted by Mg2+ to the right in a parallel fashion. The curve-shift was compatible with a competitive interplay between Mg2+ and the modulators. The pKb-values as a measure of the antagonistic potency of Mg2+, however, differed depending on the modulator, i.e. pKb=3.4 with W84 and pKb=2.8 with Chin3/6. Mg2+ itself was capable of slowing the dissociation of [3H]NMS; the maximal retardation of [3H]NMS dissociation was about 3 fold, the concentration-effect relationship was compatible with a two-site model using the above-mentioned pKb-values as affinity constants. Since the equilibrium-binding of [3H]NMS remained unchanged up to a Mg2+-concentration of 3 mM, the cation appears to inhibit the association and dissociation of [3H]NMS to the same extent in this concentration range. Taken together, the findings indicate that Mg2+ may bind to the allosteric region of muscarinic M2 receptors and that more than one site is involved in this interaction. The sites of action may represent divalent cation binding sites.

M2 receptor binding of the selective antagonist AF-DX 384: possible involvement of the common allosteric site.

The hypothesis was tested that M2-selective antagonists partially utilize the allosteric site of muscarinic M2 receptors. The interactions of the allosteric agent W84 (hexane-1, 6-bis[dimethyl-3'-phthalimidopropyl-ammonium bromide]) were studied with the M2/M4-selective AF-DX 384 [(+/-)-5, 11-dihydro-11-([(2-(2-[(dipropylamino)methyl]-1-piperidinyl)ethyl)amino]carbonyl)-6H-pyrido(2,3-b)(1,4)-benzodiazepine-6-one], the nonselective N-methylscopolamine (NMS), and a number of other muscarinic antagonists. In isolated paced guinea pig atria, the antagonistic effect of W84 against oxotremorine- and arecaidine propargyl ester-induced negative inotropic actions reached a limiting value at higher W84 concentrations, revealing negative cooperativity (factors of cooperativity alpha = 311 and alpha = 495, respectively). The antagonistic potency of W84 in this M2 receptor model (W84 binding constant KA approximately 160 nM) was higher than at M1/M4-like receptors of rabbit vas deferens (KB approximately 800 nM) and at M3 receptors of guinea pig ileum (KB approximately 4,000 nM). In paced atria, combinations of W84 with muscarinic antagonists yielded more-than-additive antagonistic effects against oxotremorine in case of conventional antagonists such as NMS (alpha = 18) but less-than-additive effects with the M2-preferring AF-DX 384 (alpha = 444). In guinea pig heart homogenates, the equilibrium binding of [3H]NMS was only partially inhibited by W84 (alpha = 2.4), whereas [3H]AF-DX 384 binding could be suppressed completely (alpha = 194). The difference in cooperativity reflects that W84 inhibits [3H]NMS dissociation with a approximately 40-fold higher potency (ECdiss = 900 nM) than [3H]AF-DX 384 dissociation (ECdiss = 33,300 nM). [3H]NMS dissociation also could be retarded by AF-DX 384 (ECdiss = 22,000 nM), probably via an interaction with the site used by W84. The results suggest that the binding domain of AF-DX 384 partially overlaps with the common allosteric site of the M2 receptor protein.

Contribution of lateral substituents in heptane-bisammonium derivatives to the allosteric stabilization of antagonist binding to M2-receptors.

Phthalimide-containing heptane-bisammonium-type compounds retard the dissociation of the antagonist [3H]-N-methylscopolamine ([3H]NMS) from muscarinic M2-receptor allosterically with high potency. To study the contribution of the lateral substituents to this effect, a series of derivatives was synthesized in which the phthalimide moiety was truncated. The potency of the compounds to delay [3H]NMS dissociation was measured in porcine heart homogenates (50 mM Tris-HCl, 3 mM MgHPO4, pH 7.3, 37 degrees C). Potency declined with diminuition of the lateral substituents, e.g. loss of the aromatic ring of the phthalimide resulted in a 400fold reduction in potency. In the hexahydrophthalimide derivatives, the cis-stereoisomer was about fivefold more potent than the trans-isomer. In conclusion, almost flat hydrophobic lateral moieties appear to be pivotal for high allosteric potency, suggesting a hydrophobic interaction of these parts of the molecule with the [3H]NMS occupied receptor protein.