The multifunctional nature of Alzheimer's disease (AD) provides the logical foundation for the development of an innovative drug design strategy centered on multi-target-directed-ligands (MTDLs). In recent years, the MTDL concept has been exploited to design different ligands hitting different biological targets. Our first rationally designed MTDL was the polyamine caproctamine (1), which provided a synergistic cholinergic action against AD by antagonizing muscarinic M(2) autoreceptors and inhibiting acetylcholinesterase (AChE). Lipocrine (7) represented the next step in our research. Due to its ability to inhibit AChE catalytic and non-catalytic functions together with oxidative stress, 7 emerged as an interesting pharmacological tool for investigating the neurodegenerative mechanism underlying AD. Memoquin (9) is a quinone-bearing polyamine endowed with a unique multifunctional profile. With its development, we arrived at the proof of concept of the MTDL drug discovery approach. Experiments in vitro and in vivo confirmed its multimodal mechanisms of action and its interaction with different end-points of the neurotoxic cascade leading to AD. More recently, the MTDL approach led to carbacrine (12). In addition to the multiple activities displayed by 7, 12 displayed an interesting modulation of NMDA receptor activity. The pivotal role played by this target in AD pathogenesis suggests that 12 may be a promising new chemical entity in the MTDL gold rush.
Alzheimer's disease (AD) is a progressive neurodegenerative disorder that destroys patient memory and cognition, communication ability with the social environment and the ability to carry out daily activities. Despite extensive research into the pathogenesis of AD, a neuroprotective treatment - particularly for the early stages of disease - remains unavailable for clinical use. In this review, we advance the suggestion that lipoic acid (LA) may fulfil this therapeutic need. A naturally occurring precursor of an essential cofactor for mitochondrial enzymes, including pyruvate dehydrogenase (PDH) and alpha-ketoglutarate dehydrogenase (KGDH), LA has been shown to have a variety of properties which can interfere with pathogenic principles of AD. For example, LA increases acetylcholine (ACh) production by activation of choline acetyltransferase and increases glucose uptake, thus supplying more acetyl-CoA for the production of ACh. LA chelates redox-active transition metals, thus inhibiting the formation of hydroxyl radicals and also scavenges reactive oxygen species (ROS), thereby increasing the levels of reduced glutathione. Via the same mechanisms, downregulation redox-sensitive inflammatory processes is also achieved. Furthermore, LA can scavenge lipid peroxidation products such as hydroxynonenal and acrolein. The reduced form of LA, dihydrolipoic acid (DHLA), is the active compound responsible for most of these beneficial effects. R-alpha-LA can be applied instead of DHLA, as it is reduced by mitochondrial lipoamide dehydrogenase, a part of the PDH complex. In this review, the properties of LA are explored with particular emphasis on how this agent, particularly the R-alpha-enantiomer, may be effective to treat AD and related dementias.
The coupling of two different pharmacophores, each endowed with different biological properties, afforded the hybrid compound lipocrine (7), whose biological profile was markedly improved relative to those of prototypes tacrine and lipoic acid. Lipocrine is the first compound that inhibits the catalytic activity of AChE and AChE-induced amyloid-beta aggregation and protects against reactive oxygen species. Thus, it emerged as a valuable pharmacological tool to investigate Alzheimer's disease and as a promising lead compound for new anti-Alzheimer drugs.