Discovery of an anti-malarial compound, burnettiene A, with a multidrug-sensitive Saccharomyces cerevisiae screening system based on mitochondrial function inhibitory activity.

In this paper, we describe our discovery of burnettiene A (1) as an anti-malarial compound from the culture broth of Lecanicillium primulinum (Current name: Flavocillium primulinum) FKI-6715 strain utilizing our original multidrug-sensitive yeast system. This polyene-decalin polyketide natural product was originally isolated as an anti-fungal active compound from Aspergillus burnettii. However, the anti-fungal activity of 1 has been revealed in only one fungal species for and the mechanism of action of 1 remains unknown. After the validation of mitochondrial function inhibitory of 1, we envisioned a new anti-malarial drug discovery platform based on mitochondrial function inhibitory activity. We evaluated anti-malarial activity and 1 showed anti-malarial activity against Plasmodium falciparum FCR3 (chloroquine sensitive) and K1 strain (chloroquine resistant). Our study revealed the utility of our original screening system based on a multidrug-sensitive yeast and mitochondrial function inhibitory activity for the discovery of new anti-malarial drug candidates.

A new tetronomycin analog, broad-spectrum and potent antibiotic against drug-resistant Gram-positive bacteria.

We discovered a new tetronomycin analog, C-32-OH tetronomycin (2) from the Streptomyces sp. K20-0247 strain, which produces tetronomycin (1). After NMR analysis of 2, we determined the planar structure. Futhermore, the absolute stereochemistry of 2 was deduced based on the biosynthetic pathway of 1 in the K20-0247 strain and a comparison of experimental electronic circular dichroism (ECD) results of 1 with 2. While 2 exihibits potent antibacterial activity aganist Gram-positive baceria including vancomycin-intermediate Staphylococcus aureus (VISA) strains and vancomycin-resistant Enterococci (VRE), the antibacterial activity of 2 shows 16-32-folds weaker than that of 1 suggesting that the C-34 methyl group in 1 is one of the very important functinal group. Moreover, we evaluated the ionophore activity of 1 and 2 and neither compound shows ionophore activity at reasonable concetrations. Our research suggests that 1 and 2 would have different target(s) from an ionophore mechanism in the antibacterial activity and tetronomycins are promising natural products for broad-spectrum antibiotics.

Re-evaluation and a Structure-Activity Relationship Study for the Selective Anti-anaerobic Bacterial Activity of Luminamicin toward Target Identification.

Luminamicin (1) isolated in 1985, is a macrodiolide compound exhibiting selective antibacterial activity against anaerobes. However, the antibacterial activity of 1 was not fully examined. In this research, re-evaluation of the antibacterial activity of 1 revealed that 1 is a narrow spectrum and potent antibiotic againstClostridioides difficile(C. difficile) and effective against fidaxomicin resistantC. difficilestrain. This prompted us to obtain luminamicin resistantC. difficilestrains for the determination of the molecular target of 1 inC. difficile. Sequence analysis of 1-resistantC. difficileindicated that the mode of action of 1 differs from that of fidaxomicin. This is because no mutation was observed in RNA polymerase and mutations were observed in a hypothetical protein and cell wall protein. Furthermore, we synthesized derivatives from 1 to study the structure-activity relationship. This research indicated that the maleic anhydride and the enol ether moieties seem to be pivotal functional groups to maintain the antibacterial activity againstC. difficileand the 14-membered lactone may contribute to taking an appropriate molecular conformation.

Rediscovery of Tetronomycin as a Broad-Spectrum and Potent Antibiotic against Drug-Resistant Gram-Positive Bacteria.

Tetronomycin (1), first isolated from a cultured broth of Streptomyces sp. by Juslen et al. in 1974, is a polycyclic polyether compound. However, the biological activity of 1 has not been thoroughly examined. In this study, we found that 1 exhibits more potent antibacterial activity than two well-known antibacterial drugs (vancomycin and linezolid) and is effective against several drug-resistant clinical isolates including methicillin-resistant Staphylococcus aureus and vancomycin-resistant Enterococci. Furthermore, we reassigned the 13C NMR spectra of 1 and performed a preliminary structure-activity relationship study of 1 to synthesize a chemical probe for target identification, which implied different targets based on its ionophore activity.