Native New Zealand plants with inhibitory activity towards Mycobacterium tuberculosis.

BACKGROUND: Plants have long been investigated as a source of antibiotics and other bioactives for the treatment of human disease. New Zealand contains a diverse and unique flora, however, few of its endemic plants have been used to treat tuberculosis. One plant, Laurelia novae-zelandiae, was reportedly used by indigenous Maori for the treatment of tubercular lesions. METHODS: Laurelia novae-zelandiae and 44 other native plants were tested for direct anti-bacterial activity. Plants were extracted with different solvents and extracts screened for inhibition of the surrogate species, Mycobacterium smegmatis. Active plant samples were then tested for bacteriostatic activity towards M. tuberculosis and other clinically-important species. RESULTS: Extracts of six native plants were active against M. smegmatis. Many of these were also inhibitory towards M. tuberculosis including Laurelia novae-zelandiae (Pukatea). M. excelsa (Pohutukawa) was the only plant extract tested that was active against Staphylococcus aureus. CONCLUSIONS: Our data provide support for the traditional use of Pukatea in treating tuberculosis. In addition, our analyses indicate that other native plant species possess antibiotic activity.

Detection of inhibitors of phenotypically drug-tolerant Mycobacterium tuberculosis using an in vitro bactericidal screen.

Many whole cell screens of chemical libraries currently in use are based on inhibition of bacterial growth. The goal of this study was to develop a chemical library screening model that enabled detection of compounds that are active against drug-tolerant non-growing cultures of Mycobacterium tuberculosis. An in vitro model of low metabolically active mycobacteria was established with 8 and 30 day old cultures of M. smegmatis and M. tuberculosis, respectively. Reduction of resazurin was used as a measure of viability and the assay was applied in screens of chemical libraries for bactericidal compounds. The model provided cells that were phenotypically-resilient to killing by first and second-line clinical drugs including rifampicin. Screening against chemical libraries identified proteasome inhibitors, NSC310551 and NSC321206, and a structurally-related series of thiosemicarbazones, as having potent killing activity towards aged cultures. The inhibitors were confirmed as active against virulent M. tuberculosis strains including multi- and extensively-drug resistant clinical isolates. Our library screen enabled detection of compounds with a potent level of bactericidal activity towards phenotypically drug-tolerant cultures of M. tuberculosis.

Evaluation of the Mycobacterium smegmatis and BCG models for the discovery of Mycobacterium tuberculosis inhibitors.

The objective of this study was to measure the efficacy of Mycobacterium smegmatis as a surrogate in vitro model for the detection of compounds which are inhibitory to the growth of Mycobacterium tuberculosis. A chemical screen of the LOPAC library for anti-mycobacterial compounds was performed using M. smegmatis. Parallel screens were conducted with another tuberculosis model, Mycobacterium bovis BCG, and with M. tuberculosis under identical growth conditions and the inhibitors detected across the three species were compared. 50% of compounds that were detected as active against M. tuberculosis were not detected using M. smegmatis compared to 21% of compounds using M. bovis BCG. To examine whether these findings were unique to LOPAC, screens were performed with the NIH Diversity Set and Spectrum Collection. An even higher proportion of M. tuberculosis inhibitors were not detected from the NIH Diversity Set and Spectrum Collection using M. smegmatis compared to M. bovis BCG. These data reveal that a significant proportion of M. tuberculosis inhibitors are missed in library screening with M. smegmatis. The basis of the variation in the inhibitory profiles of M. smegmatis and M. tuberculosis has yet to be fully determined, however, our genomic comparisons indicate that approximately 30% of M. tuberculosis proteins lack conserved orthologues in M. smegmatis compared to 3% being absent in M. bovis BCG. In conclusion, although M. smegmatis offers some technical benefits such as a shorter generation time and negligible risk to laboratory workers, it is significantly less effective in the detection of anti-M. tuberculosis compounds relative to M. bovis BCG. This limitation needs to be taken into consideration when selecting an in vitro screening model for tuberculosis drug discovery.