Clark, GC; Basak, AK; Titball, RW; (2007) The rational design of bacterial toxin inhibitors. Current computer-aided drug design, 3 (1). pp. 1-12. ISSN 1573-4099 https://researchonline.lshtm.ac.uk/id/eprint/9221
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Abstract
Protein toxins play key roles in many infectious diseases of humans which are caused by bacteria. In some cases the toxin alone is directly responsible for the majority of the symptoms of the disease (e.g. tetanus, anthrax, diphtheria). In others the toxin is one of an arsenal of virulence factors which allow the bacterium to cause disease. Antibiotics are currently the mainstay for the treatment of bacterial infections. However, increasing levels of antibiotic resistance and the indiscreet nature of antibiotic therapy are limitations. Prior to the availability of antibiotics, antisera against toxins were often used to treat bacterial disease. Nowadays, animal-sourced products, such as antisera, are generally not acceptable for use in humans. Against the background there is an increasing interest in the development of low molecular weight inhibitors of toxins for the treatment of disease. For some toxins, like anthrax toxin, botulinum toxin and shigella toxin, low molecular weight inhibitors demonstrate proof of principle of this concept. For most other toxins the design and development of inhibitors is now a very real prospect; the crystal structures of many toxins are available, and in most cases the identity of the substrate or receptor is known. This article describes in detail the rational design of bacterial toxin inhibitors.