DNA binding compounds targeting fungal pathogens: an emerging concept in the discovery of novel antifungal agents.

With the urgent need for novel agents to combat emerging fungal resistance to existing drugs, activity in the exploration of small molecule DNA binders has increased. Recently, selected cationic heterocyclic compounds belonging to a broad class of molecules known to bind to the minor groove of DNA were revealed to have potent antifungal activity. These molecules are different from the conventional DNA-interacting drugs such as topoisomerase inhibitors, DNA alkylators or intercalators. Selected compounds are fungicidal towards a variety of pathogenic yeasts and molds, and a selected lead compound is efficacious in a mouse model of systemic candidosis.

Minor groove DNA binders as antimicrobial agents. 1. Pyrrole tetraamides are potent antibacterials against vancomycin resistant Enterococci [corrected] and methicillin resistant Staphylococcus aureus.

A new series of short pyrrole tetraamides are described whose submicromolar DNA binding affinity is an essential component for their strong antibacterial activity. This class of compounds is related to the linked bis-netropsins and bis-distamycins, but here, only one amino-pyrrole-carboxamide unit and an amidine tail is connected to either side of a central dicarboxylic acid linker. The highest degree of DNA binding, measured by compound-induced changes in UV melting temperatures of an AT-rich DNA oligomer, was observed for flat, aromatic linkers with no inherent bent, i.e., terephthalic acid or 1,4-pyridine-dicarboxylic acid. However, the antibacterial activity is critically linked to the size of the N-alkyl substiutent of the pyrrole unit. None of the tetraamides with the commonly used methyl-pyrrole showed antibacterial activity. Isoamyl- or cyclopropylmethylene-substituted dipyrrole derivatives have the minimum inhibitory concentrations in the submicromolar range. In vitro toxicity against human T-cells was studied for all compounds. The degree to which compounds inhibited cell growth was neither directly correlated to DNA binding affinity nor directly correlated to antibacterial activity but seemed to depend strongly on the nature of the N-alkyl pyrrole substituents.