The medicinal chemistry of botulinum, ricin and anthrax toxins.

The potential use of weapons of mass destruction (nuclear, biological or chemical) by terrorist organizations represents a major threat to world peace and safety. Only a limited number of vaccines are available to protect the general population from the medical consequences of these weapons. In addition there are major health concerns associated with a pre-exposure mass vaccination of the general population. To reduce or eliminate the impact of these terrible threats, new drugs must be developed to safely treat individuals exposed to these agents. A review of all therapeutic agents under development for the treatment of the illnesses and injuries that result from exposure to nuclear, biological or chemical warfare agents is beyond the scope of any single article. The intent here is to provide a focused review for medicinal and organic chemists of three widely discussed and easily deployed biological warfare agents, botulinum neurotoxin and ricin toxins and the bacteria Bacillus anthracis. Anthrax will be addressed because of its similarity in both structure and mechanism of catalytic activity with botulinum toxin. The common feature of these three agents is that they exhibit their biological activity via toxin enzymatic hydrolysis of a specific bond in their respective substrate molecules. A brief introduction to the history of each of the biological warfare agents is presented followed by a discussion on the mechanisms of action of each at the molecular level, and a review of current potential inhibitors under investigation.

Nuclear magnetic resonance and molecular modeling analysis of the interaction of the antimalarial drugs artelinic acid and artesunic acid with beta-cyclodextrin.

The artemisinin derivatives artelinic acid and artesunic acid are members of a class of compounds that have shown promise for the treatment of multidrug resistant strains of Plasmodium falciparum. Unfortunately, these compounds exhibit poor solubility and stability in aqueous solution. The research presented herein was conducted to determine whether complexation of artelinic acid or artesunic acid with beta-cyclodextrin would result in complexes with increased aqueous solubility while retaining the potent antimalarial activity of these compounds. Preliminary complexation studies with natural beta-cyclodextrins were conducted as a proof of concept, with a primary focus on understanding the electrostatic interactions that stabilize the resulting complexes. Complex formation was monitored using UV spectroscopy. The structures of the resulting complexes were determined using multidimensional nuclear magnetic resonance spectroscopy (NMR) and molecular modeling. NMR results are most consistent for artelinic acid and beta-cyclodextrin forming complexes in a ratio of 2:1; however, the presence of 1:1, 2:2, and 3:1 complexes in solution cannot be excluded based on the experimental data collected. The NMR data also indicate selective insertion of artelinic acid into the hydrophobic cavity of the beta-cyclodextrin via the primary face. NMR results indicate artesunic acid forms a similar complex with beta-cyclodextrin in a ratio of 1:1; again however, the presence of 1:1, 2:2, and 3:1 complexes in solution cannot be ruled out.

Structure-activity relationship study of antimalarial indolo [2,1-b]quinazoline-6,12-diones (tryptanthrins). Three dimensional pharmacophore modeling and identification of new antimalarial candidates.

A widely applicable three-dimensional QSAR pharmacophore model for antimalarial activity was developed from a set of 17 substituted antimalarial indolo[2,1-b]quinazoline-6,12-diones (tryptanthrins) that exhibited remarkable in vitro activity (below 100 ng/mL) against sensitive and multidrug-resistant Plasmodium falciparum malaria. The pharmacophore, which contains two hydrogen bond acceptors (lipid) and two hydrophobic (aromatic) features, was found to map well onto many well-known antimalarial drug classes including quinolines, chalcones, rhodamine dyes, Pfmrk cyclin dependent kinase inhibitors, malarial FabH inhibitors, and plasmepsin inhibitors. The phamacophore allowed searches for new antimalarial candidates from multiconformer 3D databases and enabled custom designed synthesis of new potent analogues.

Recognition of cell-specific binding of phage display derived peptides using an acoustic wave sensor.

ASSLNIA, a peptide selected for murine myofibers using phage display technology, was immobilized onto an acoustic wave sensor. The sensor responded to murine and feline muscle homogenates indicating crosspieces interactions. Kidney, liver, and brain preparations produced insignificant responses.