The development of selective ligands targeting neuronal nicotinic acetylcholine receptors to alleviate symptoms associated with neurodegenerative diseases presents the advantage of affecting multiple deficits that are the hallmarks of these pathologies. TC-1734 is an orally active novel neuronal nicotinic agonist with high selectivity for neuronal nicotinic receptors. Microdialysis studies indicate that TC-1734 enhances the release of acetylcholine from the cortex. TC-1734, by either acute or repeated administration, exhibits memory enhancing properties in rats and mice and is neuroprotective following excitotoxic insult in fetal rat brain in cultures and against alterations of synaptic transmission induced by deprivation of glucose and oxygen in hippocampal slices. At submaximal doses, TC-1734 produced additive cognitive effects when used in combination with tacrine or donepezil. Unlike (-)-nicotine, behavioral sensitization does not develop following repeated administration of TC-1734. Its pharmacokinetic (PK) profile (half-life of 2 h) contrasts with the long lasting improvement in working memory (18 h) demonstrating that cognitive improvement extends beyond the lifetime of the compound. The very low acute toxicity of TC-1734 and its receptor activity profile provides additional mechanistic basis for its suggested potential as a clinical candidate. TC-1734 was very well tolerated in acute and chronic oral toxicity studies in mice, rats and dogs. Phase I clinical trials demon-
We explore the significance of pi-cation interactions in the binding of ligands to nicotinic acetylcholine receptors. Specifically, the Austin method of semiempirical molecular orbital theory is utilized to estimate the interaction of aromatic amino acid side chains with the cation-containing heterocyclic ring fragments of nicotinic ligands. Variational interaction energies (E(i)) of side chain-ligand fragment pairs are shown to be distance-dependent and follow a Morse-like potential function. The tryptophan side chain shows the most pronounced interaction with the cation fragments, followed by tyrosine and phenylalanine. For a given side chain, cationic fragments exhibit characteristically different E(i) profiles, with the azabicyclo[2.2.1]heptane fragment of the potent nicotinic ligand epibatidine eliciting the greatest interaction energy of the study set. Most significantly, the minimum energy values calculated for numerous fragments correlate with the binding affinity of the parent ligands- we show this to be the case for heteropentameric (alpha4beta2) and homopentameric (alpha7) nicotinic acetylcholine receptor subtypes. Furthermore, intermolecular distances corresponding to the Morse-like potential minimum also correlate with high-affinity binding. A number of parallel calculations were conducted at the Hartree-Fock 6-31G ab initio level of theory in an effort to substantiate these findings.
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