Condensing enzymes are essential in type II fatty acid synthesis and are promising targets for antibacterial drug discovery. Recently, a new approach using a xylose-inducible plasmid to express antisense RNA in Staphylococcus aureus has been described; however, the actual mechanism was not delineated. In this paper, the mechanism of decreased target protein production by expression of antisense RNA was investigated using Northern blotting. This revealed that the antisense RNA acts posttranscriptionally by targeting mRNA, leading to 5 mRNA degradation. Using this technology, a two-plate assay was developed in order to identify FabF/ FabH target-specific cell-permeable inhibitors by screening of natural product extracts. Over 250,000 natural product fermentation broths were screened and then confirmed in biochemical assays, yielding a hit rate of 0.1%. All known natural product FabH and FabF inhibitors, including cerulenin, thiolactomycin, thiotetromycin, and Tü3010, were discovered using this whole-cell mechanism-based screening approach. Phomallenic acids, which are new inhibitors of FabF, were also discovered. These new inhibitors exhibited target selectivity in the gel elongation assay and in the whole-cell-based two-plate assay. Phomallenic acid C showed good antibacterial activity, about 20-fold better than that of thiolactomycin and cerulenin, against S. aureus. It exhibited a spectrum of antibacterial activity against clinically important pathogens including methicillinresistant Staphylococcus aureus, Bacillus subtilis, and Haemophilus influenzae.Hundreds of essential proteins have been identified in bacteria as potential drug targets (1,16,18,23). Of these, only a few are targets of therapeutically useful drugs. These include penicillin binding proteins, D-Ala-D-Ala ligase, MurA, undecaprenyl pyrophosphate, and alanine racemase for cell wall; 30S and 50S ribosomal subunits, elongation factor G, and IletRNA synthetase for protein synthesis; RNA polymerase for RNA synthesis; InhA (FabI) for fatty acid synthesis; dihydrofolate reductase (FolA) and p-aminobenzoic acid synthase (FolP) for metabolism; and DNA gyrase and topoisomerase IV for DNA synthesis. In past decades, extensive chemical modification of existing antibiotics has afforded improved activity against their targets. This strategy served well to develop new and effective antibiotics; however, such modification is becoming increasingly difficult and identification of new classes of compounds with different modes of action is critical to combat emerging resistance and meet clinical needs.
