Structurally diverse MDM2-p53 antagonists act as modulators of MDR-1 function in neuroblastoma.

BACKGROUND: A frequent mechanism of acquired multidrug resistance in human cancers is overexpression of ATP-binding cassette transporters such as the Multi-Drug Resistance Protein 1 (MDR-1). Nutlin-3, an MDM2-p53 antagonist, has previously been reported to be a competitive MDR-1 inhibitor. METHODS: This study assessed whether the structurally diverse MDM2-p53 antagonists, MI-63, NDD0005, and RG7388 are also able to modulate MDR-1 function, particularly in p53 mutant neuroblastoma cells, using XTT-based cell viability assays, western blotting, and liquid chromatography-mass spectrometry analysis. RESULTS: Verapamil and the MDM2-p53 antagonists potentiated vincristine-mediated growth inhibition in a concentration-dependent manner when used in combination with high MDR-1-expressing p53 mutant neuroblastoma cell lines at concentrations that did not affect the viability of cells when given alone. Liquid chromatography-mass spectrometry analyses showed that verapamil, Nutlin-3, MI-63 and NDD0005, but not RG7388, led to increased intracellular levels of vincristine in high MDR-1-expressing cell lines. CONCLUSIONS: These results show that in addition to Nutlin-3, other structurally unrelated MDM2-p53 antagonists can also act as MDR-1 inhibitors and reverse MDR-1-mediated multidrug resistance in neuroblastoma cell lines in a p53-independent manner. These findings are important for future clinical trial design with MDM2-p53 antagonists when used in combination with agents that are MDR-1 substrates.

Dopamine D5 receptors: a challenge to medicinal chemists.

Due to the lack of highly selective dopamine D(1) or D(5) receptor ligands, only few data about activation or blocking of these receptor subtypes are available. The present review collects the available information about molecules with notable affinity for D(5) receptor subtype with the purpose to help the researchers to design novel D(5) selective ligands, whose discovery may enrich the knowledge about the physiological function of such a receptor, provide information about its topography, as well as lead to novel potential therapeutic tools.

Binding of nicotine and homoazanicotine analogues at neuronal nicotinic acetylcholinergic (nACh) receptors.

A total of 20 substituted analogues of nicotine (1a) and homoazanicotine (3a) were examined in order to determine whether or not they might bind in a similar manner at alpha4beta2 nicotinic acetylcholinergic (nACh) receptors. It was found that parallel structural changes in the two series resulted in parallel shifts in affinity. Evidence suggests that the two series are binding in a comparable fashion.

Homoazanicotine: a structure-affinity study for nicotinic acetylcholine (nACh) receptor binding.

We have recently identified 3-[(1-methyl)-4,5-dihydro-1H-imidazol-2-yl)methyl]pyridine (homoazanicotine, 8) as a novel nicotinic acetylcholinergic (nACh) receptor ligand. In the present investigation, after we determined that 8 binds selectively at nicotinic (K(i) = 7.8 nM) vs muscarinic (K(i) > 10,000 nM) acetylcholinergic receptors, we examined its structure-affinity relationships for nACh receptor binding. The features investigated included the influence of (i) the composition of connector that separates the two rings, (ii) the N-methyl group, (iii) the ring opening of the imidazoline ring, (iv) the pyridine nitrogen atom, and (v) the aromatization of the imidazoline ring on nACh receptor affinity. As with nicotine, the parent structure seems optimal and most structural changes reduce nACh receptor affinity. Also, as with nicotine analogues, alteration of the spacer group influences affinity in a manner that is somewhat different than that seen with the parent structure.

Chain-lengthened and imidazoline analogues of nicotine.

Analogues of nicotine (1) and azanicotine (3) were prepared with an additional methylene group inserted between the two rings (i.e., homonicotine and homoazanicotine; 6 and 5, respectively). Although 6 (Ki = 3110 nM) and 3 (Ki = 206 nM) bind at nACh receptors with > or = 100-fold lower affinity than nicotine (Ki = 2.1 nM), 5 displays high affinity (Ki = 7.8 nM). Like nicotine (ED50 = 12 microg/mouse), both 3 and 5 (ED50 = 21 and 19 microg/mouse, respectively) produced antinociceptive activity in the tail-flick assay following intrathecal administration. The antinociceptive actions of 3 and 5, unlike those of nicotine, were not antagonized by mecamylamine. Compounds 3 and 5 might represent novel analgesic agents that act via a non-nicotinic mechanism, or via a nicotinic mechanism that is distinct from that mediating the antinociceptive actions of nicotine.

Synthesis, molecular modeling, and pharmacological testing of bis-quinolinium cyclophanes: potent, non-peptidic blockers of the apamin-sensitive Ca(2+)-activated K(+) channel.

The synthesis and pharmacological testing of two series of novel bis-quinolinium cyclophanes as blockers of the apamin-sensitive Ca(2+)-activated K(+) (SK(Ca)) channel are presented. In these cyclophanes the two 4-aminoquinolinium groups are joined at the ring N atoms (linker L) and at the exocyclic N atoms (linker A). In those cases where A and L contain two or more aromatic rings each, the activity of the compound is not critically dependent upon the nature of the linkers. When A and L each have only one benzene ring, the blocking potency changes dramatically with simple structural variations in the linkers. One of these smaller cyclophanes having A = benzene-1,4-diylbis(methylene) and L = benzene-1, 3-diylbis(methylene) (3j, 6,10-diaza-1,5(1,4)-diquinolina-3(1,3),8(1, 4)-dibenzenacyclodecaphanedium tritrifluoroacetate, UCL 1684) has an IC(50) of 3 nM and is the most potent non-peptidic SK(Ca) channel blocker described to date. Conformational analysis on the smaller cyclophanes using molecular modeling techniques suggests that the differences in the blocking potencies of the compounds may be attributable to their different conformational preferences.

Evaluation of an agonist index: affinity ratio for compounds active on muscarinic cholinergic M2 receptors.

A protocol for predicting full agonist, partial agonist, and antagonist profiles of compounds with M2 muscarinic cholinergic receptor activity was developed using radioligand binding assay techniques with [3H]-N-methyl scopolamine (NMS) and [3H]-Oxotremorine-M (Oxo-M) as radioligands. Full muscarinic cholinergic receptor agonists such as muscarine and oxotremorine-M expressed a high agonist index (> 3000 for M1 muscarinic cholinergic receptors and > 900 for M2 muscarinic cholinergic receptor), whereas muscarinic receptor antagonists (selective or non-selective) for different receptor subtypes gave a low (0.5-10) agonist index. Functional studies performed on preparations of guinea-pig ileum and heart were consistent with radioligand binding assay experiments. The above results suggest that similarly as already established for the M1 muscarinic cholinergic receptor subtype, evaluation of the [3H]-NMS/[3H]-Oxo-M ratio may provide useful information on the profile of compounds acting at the M2 muscarinic cholinergic receptor subtype. The availability of simple and predictive techniques for the characterization of muscarinic M2 cholinergic receptor agonists, may help the identification of new compounds in therapeutic areas in which stimulation or inhibition of this receptor is desirable.

Structure-activity relationships in 1,4-benzodioxan-related compounds. 6. Role of the dioxane unit on selectivity for alpha(1)-adrenoreceptor subtypes.

WB 4101-related benzodioxans 3-9 were synthesized, and their biological profiles at alpha(1)-adrenoreceptor subtypes and 5-HT(1A) serotoninergic receptors were assessed by binding assays in CHO and HeLa cells membranes expressing the human cloned receptors. Furthermore, receptor selectivity of selected benzodioxan derivatives was further determined in functional experiments in isolated rat vas deferens (alpha(1A)) and aorta (alpha(1D)) and guinea pig spleen (alpha(1B)), in additional receptor binding assays in rat cortex membranes containing alpha(2)-adrenoreceptors and 5-HT(2) serotoninergic receptors, and in rat striatum membranes containing D(2) dopaminergic receptors. An analysis of the results of receptor binding experiments for benzodioxan-modified derivatives 3-9 showed high affinity and selectivity toward the alpha(1a)-adrenoreceptor subtype for compounds 3-5 and 7 and a reversed selectivity profile for 9, which was a selective alpha(1d) antagonist. Furthermore, the majority of structural modifications performed on the prototype 1 (WB 4101) led to a marked decrease in the affinity for 5-HT(1A) serotoninergic receptors, which may have relevance in the design of selective alpha(1A)-adrenoreceptor antagonists. The exception to these findings was the chromene derivative 8, which exhibited a 5-HT(1A) partial agonist profile.

Ligand binding to I2 imidazoline receptor: the role of lipophilicity in quantitative structure-activity relationship models.

A series of 2-trans-styryl-imidazoline (tracizoline) congeners were designed and tested to develop 2-D and 3-D QSAR models for their binding to imidazoline (I2) receptor. The important role of lipophilicity was assessed by classical 2-D QSAR study (Hansch approach) and by comparative molecular field analysis (CoMFA) with the inclusion of the molecular lipophilicity potential (MLP), as an additional descriptor, besides standard steric and electrostatic fields. Results from these studies were compared to those obtained in a previous modeling study of I2 receptor ligands and integrated into a new, comprehensive model, based on about sixty I2 receptor ligands. This model revealed, at the three-dimensional level, the most significant steric, electrostatic, and lipophilic interactions accounting for high I2 receptor affinity.

Use of frozen sections for the pharmacological characterization of compounds active on neurotransmitter receptors.

Radioligand binding assay represents an important technique in pharmacological and pharmaceutical research for assessing the receptor profile of new drugs or of compounds under development. In this study, the pharmacological profile and the receptor specificity of compounds active on dopamine and muscarinic cholinergic receptor subtypes were evaluated using as a receptor source, membrane preparations or frozen sections. Dopamine D1-like receptors were assayed in membrane preparations or frozen sections of rat striatum and kidney with [3H]-SCH 23390 as a ligand. Rat striatum, kidney and atrium were used as a source of dopamine D2-like receptors with [3H]-spiperone as a ligand. The non-selective muscarinic cholinergic receptor antagonist [3H]-N-methyl-scopolamine was used to label muscarinic cholinergic receptors in the rat. Frontal cortex represented the source of M1 receptor subtype, heart the source of M2 receptor subtype, sub maxillary gland the source of M3 receptor subtype and striatum the source of M4 receptor subtype. With the exception of cardiac tissue, no significant differences were noticeable in the affinity of dopaminergic or muscarinic cholinergic compounds tested using membrane particles or 8 microns thick slide-mounted section. In the heart, frozen sections gave lower dissociation constant and inhibition constant values than membranes. The above findings suggest that radioligand binding assay on slide-mounted tissue sections may represent a suitable technique for assessing the receptor profile of drugs under development for the treatment of disorders characterised by dopaminergic or muscarnic cholinergic dysfunction.

Imidazoline receptors: qualitative structure-activity relationships and discovery of tracizoline and benazoline. Two ligands with high affinity and unprecedented selectivity.

The observation that all the attempts to characterize imidazoline (I) receptors have been carried out with non-selective or poorly selective ligands prompted us to undertaken research aimed at developing selective ligand(s). In previous work using, as a starting point, cirazoline I, a potent alpha 1-adrenergic receptor agonist that also binds to I receptors, we showed that removal of the cyclopropyl ring (2) retains high affinity for I2 receptors while reducing alpha 1-adrenergic agonist activity. However, it was felt that this residual, albeit modest, alpha 1-adrenergic agonist activity might diminish the usefulness of compound 2, and we now report on our continuing efforts in this field. Starting from compound 2, we first eliminated the alpha 1-agonist component by isosteric replacement and then, by means of conformational restrictions on compound 7, succeeded in discovering tracizoline (9) and benazoline (12). These two new ligands with high affinity (pKi value 8.74 and 9.07, respectively) and unprecedented selectivity with respect to both alpha 2- (I2/alpha 2 7,762 and 18,621) and alpha 1- (I2/alpha 1 2,344 and 2,691) adrenergic receptors, are valuable tools in the study of I receptor structure and function. In addition, the large number of derivatives studied has allowed us to establish congruent qualitative structure-activity relationships and identify some structural elements governing affinity and selectivity.

Synthesis and structure-activity relationship studies in a series of 2-substituted 1,3-dioxolanes modified at the cationic head.

To develop ligands that may be useful in exploring muscarinic receptor heterogeneity, we synthesized a series of analogues of 2,2-diphenyl-[1,3]-dioxolan-4-ylmethyl-dimethylamine oxalate and methiodide bearing a modified cationic head. These compounds, when tested on tissues containing the three subtypes M1, M2, and M3, behaved as muscarinic antagonists whose results showed that different substituents on the quaternary and tertiary nitrogen affect affinity and selectivity in different ways. In particular comparison of the affinities of these ligands with those of the reference compounds points out that compounds bearing an ethyl substituent improve the affinity of the molecule at the three subtypes while compounds bearing a phenethyl substituent are more selective for the M3 sites.

Muscarinic thioligands with cyclopentane nucleus.

Some thio- and the benzoyl-derivatives of deoxamuscarine were synthesized and tested as muscarinic agonists using radioligand binding assays and functional tests. In comparison with deoxamuscarine, used as reference compound, no dimension/distance modification is tolerated for correct lipophilic pocket recognition. The substitution of the ammonium group with a sulphonium group significantly decreased muscarinic potency. The so-called 'muscarinic sub-site' accepts relatively bulky functions as long as it is bound to the cyclopentane carrier by an oxygen bridge. Esterification of this moiety increases the M2 subtype selectivity, while etherification heightens that of M3.

Synthesis, absolute configuration, and biological profile of the enantiomers of trans-[2-(2,6-dimethoxyphenoxy)ethyl] [(3-p-tolyl-2,3-dihydro-1,4-benzodioxin-2-yl)methyl]amine (mephendioxan), a potent competitive alpha 1A-adrenoreceptor antagonist.

The enantiomers of trans-[2-(2,6-dimethoxyphenoxy)ethyl] [(3-p-tolyl-2,3-dihydro-1,4-benzodioxin-2-yl) methyl]amine (mephendioxan, 2) were synthesized from the chiral trans-3-p-tolyl-2,3-dihydro-1,4-benzodioxin-2-carboxylic acids [(+)-3 and (-)-3] which in turn were obtained through the resolution of the racemic acid with (R)- and (S)-alpha-methylbenzylamine. Comparison of CD spectra of the enantiomers of 2 with that of (2S,3S)-3-methyl-2-phenyl-1,4-benzodioxane allowed the assignment of the 2S,3S configuration to the (-)-enantiomer of 2 and of the 2R,3R configuration to the other enantiomer. The binding profile of the enantiomers of 2 was assessed at alpha 1, alpha 2, D2, and 5-HT1A receptors, in comparison to WB 4101 (1), 5-methylurapidil, and (+)-niguldipine. In addition, the two enantiomers were investigated at native and cloned alpha 1-adrenoreceptor subtypes. (-)-2 was 10-30 times as potent as the (+)-enantiomer at alpha 1-adrenoreceptor subtypes in both functional and binding assays. It was 36-fold selective for the alpha 1A- versus alpha 1B-adrenoreceptor and 60- and 20-fold selective in binding to the alpha 1a-adrenoreceptor relative to alpha 1b and alpha 1d subtypes, respectively. Furthermore, the enantiomer (-)-2 displayed selectivities of 12000-, 2500-, and 250-fold in binding to alpha 1a-adrenoreceptors relative to alpha 2-adrenoreceptors and 5-HT1A and D2 receptors. These results indicate that (-)-2 may be a valuable tool in the characterization of alpha 1-adrenoreceptor subtypes.

Bicyclic dioxolanes as potential antimuscarinic agents.

A series of rigid compounds--derivatives of 2,2-diphenyl-[1,3]-dioxolan-4-ylmethyl-dimethylamine methiodide (1b)--has been synthesized and tested to evaluate affinity and selectivity for M1, M2, and M3 muscarinic receptors. The stereochemistry of the annulation does not influence the activity; the optimal distance between nitrogen and the benzhydryl group seems to be that with the nitrogen in the rigid ring (2b) or the nitrogen directly bound at the cyclopentane nucleus (9b, 11b). The different structure-activity relationships between tertiary amines (a series) and the corresponding quartnerary salts (b series) suggest a different binding to the receptor sites.

Structure-activity relationships in 1,4-benzodioxan-related compounds. 5. Effects of modification of the side chain on alpha-adrenoreceptor blocking activity.

The observation that the insertion of a phenyl ring at position 3 of WB 4101 (1) afforded a potent and selective alpha 1-adrenoreceptor antagonist, phendioxan (2), prompted us to investigate the effect on alpha-adrenoreceptor blocking activity of replacing a hydrogen atom at the 2-position or on the 2-ylmethyl moiety of 1 and 2 by a methyl, ethyl or phenyl group. Thus compounds 3-11 were synthesized and their blocking activity and relative selectivity on alpha 1- and alpha 2-adrenoreceptors were evaluated in the isolated rat vas deferens in comparison to 1 and 2. The results of such investigation showed that this structural modification caused a decrease in affinity for alpha-adrenoreceptors.

Synthesis and muscarinic properties of (1S*,3R*,5R*)-trimethyl(1-methyl-6-oxabicyclo[3.1.0]hex-3-yl)methyl ammonium iodide.

To acquire more information about the so-called "muscarinic subsite", compound 4 was synthesized and tested. The results show that in comparison with deoxamuscarine (23) the muscarinic potency of 4 on M2 and M3 subtypes is not significantly altered by the presence of an epoxidic function, which confirms the donor-acceptor hydrogen bonding character of this receptive site. Conversely, there is a negative influence on the transduction processes. In addition, a second hydroxylic function bound on the carbon carrying the terminal methyl of the fourth substituent on the nitrogen dramatically affects the muscarinic behavior; the resulting compounds (11-14) lack any agonist or antagonist activity.