In Vitro Interactions of Costus speciosus (J. Koenig) Sm., Cymbopogon citratus (Dc. Ex Nees) Stapf. and Tabernaemontana coronaria (L.) Willd. with First-Line Anti-Tuberculosis Drugs Against Mycobacterium tuberculosis H37rv

Global tuberculosis (TB) burden underscores the importance of developing new effective anti-TB drugs. This study was concerned with prospecting for potential anti-TB agents from Malaysian medicinal plants. In our previous study, we have reported that n-hexane fractions of Costus speciosus (C. speciosus) (J. Koening) Sm., Cymbopogon citratus (C. citratus ) (DC.) Stapf. and Tabernaemontana coronaria (T. coronaria) (Jacq.) posses promising anti-TB activity against Mycobacterium tuberculosis (M. tuberculosis) H37Rv with minimum inhibitory concentrations (MICs) of 200–100 µg/mL. This study aimed to investigate the interactions of these active fractions with first-line anti-TB drugs (isoniazid, rifampicin, ethambutol and streptomycin) against M. tuberculosis H37Rv using the microdilution checkerboard method. C. citratus (stem-rhizome) n-hexane fraction exhibited synergism with all drugs except ethambutol which showed additive interaction. Synergistic was also observed when C. speciosus (stem-flower) n-hexane and T. coronaria (leaf) n-hexane fractions in combination with rifampicin. C. speciosus (stem-flower) n-hexane and T. coronaria (leaf) n-hexane exhibited additive interaction with isoniazid, ethambutol and streptomycin. Hence, these active plants are worthy of further investigations for the discovery of anti-TB drug leads.

Evaluation of Different Mycobacterial Species for Drug Discovery and Characterisation of Novel Inhibitors of Mycobacterium Tuberculosis

<p>Tuberculosis (Tb) has plagued mankind for many centuries and is still a leading cause of death worldwide. A worrying development is the emergence of drug-resistant Tb that poses further challenges to the control of the disease. The global Tb burden and high mortality rate indicate that new drugs are needed for Tb treatment. While no new anti-Tb agents have been introduced to the market for about three decades, drugs with novel mechanisms of action can amend the current Tb treatment regimen and may provide an effective solution to drug resistance. The main objectives of this study were to identify an appropriate in vitro model that could be used for anti-Tb drug high-throughput screening (HTS), and to use this model to identify a novel candidate anti-tubercular drug and its cognate cellular target. A sensitive growth inhibition assay was set up with a GFP-labelled Tb vaccine strain, M. bovis BCG, using standard first and second line anti-tubercular drugs. HTS of the drug libraries was performed with various in vitro models to evaluate their efficacy for use in anti-Tb drug discovery. Approximately 50% of the M. tuberculosis inhibitors were not detected in screening with the surrogate species, M. smegmatis; whereas, only 21% of hits were not detected with M. bovis BCG. A comparative genomic study revealed that 97% of M. bovis BCG proteins, compared to 70% in M. smegmatis have conserved orthologues in M. tuberculosis H37Rv. Therefore, M. bovis BCG represented a more sensitive model than M. smegmatis for detecting anti-M. tuberculosis compounds. M. bovis BCG was then used to screen for novel anti-Tb agents by HTS of compound libraries and various plant extracts, followed by validation of new compounds in M. tuberculosis H37Ra. A number of novel M. tuberculosis inhibitors were identified, including sappanone A dimethyl ether from plant sources and compounds NSC112200 and NSC402959 from NIH chemical libraries. The inhibitors that were validated using M. tuberculosis H37Ra were also validated in the virulent Tb strain, M. tuberculosis H37Rv. In addition, their activity was further investigated using a suite of other clinically important human pathogens. One of the key anti-mycobacterial hits identified in this study, NSC402959, has previously been detected in screens for compounds that inhibit ribonuclease H (RNase H), an enzyme that is required for a number of essential cellular processes. NSC402959 inhibited RNase H proteins from HIV as well as from E. coli. Since HIV and Tb are major pandemics, previously-known anti-HIV RNase H compounds were imported and tested for their anti-proliferative activity towards M. tuberculosis H37Ra. HIV RNase H inhibitors, NSC35676, NSC112200, NSC133457 and NSC668394, exhibited good anti-mycobacterial activity in this study. In silico analysis suggested a plausible interaction of these inhibitors with mycobacterial RNase HI. A biochemical assay further confirmed NSC112200 to be specific against RNase HI from M. tuberculosis. These interesting inhibitors were not only structurally different from existing anti-Tb drugs but some of them were also non-toxic to mammalian cells and may have a unique mechanism of action. Thus, these compounds showed good potential for development as dual inhibitors of Tb and HIV; therefore, future studies in animal infection models to determine their dual anti-mycobacterial and anti-HIV activities are warranted.</p>

Evaluation of Different Mycobacterial Species for Drug Discovery and Characterisation of Novel Inhibitors of Mycobacterium Tuberculosis

<p>Tuberculosis (Tb) has plagued mankind for many centuries and is still a leading cause of death worldwide. A worrying development is the emergence of drug-resistant Tb that poses further challenges to the control of the disease. The global Tb burden and high mortality rate indicate that new drugs are needed for Tb treatment. While no new anti-Tb agents have been introduced to the market for about three decades, drugs with novel mechanisms of action can amend the current Tb treatment regimen and may provide an effective solution to drug resistance. The main objectives of this study were to identify an appropriate in vitro model that could be used for anti-Tb drug high-throughput screening (HTS), and to use this model to identify a novel candidate anti-tubercular drug and its cognate cellular target. A sensitive growth inhibition assay was set up with a GFP-labelled Tb vaccine strain, M. bovis BCG, using standard first and second line anti-tubercular drugs. HTS of the drug libraries was performed with various in vitro models to evaluate their efficacy for use in anti-Tb drug discovery. Approximately 50% of the M. tuberculosis inhibitors were not detected in screening with the surrogate species, M. smegmatis; whereas, only 21% of hits were not detected with M. bovis BCG. A comparative genomic study revealed that 97% of M. bovis BCG proteins, compared to 70% in M. smegmatis have conserved orthologues in M. tuberculosis H37Rv. Therefore, M. bovis BCG represented a more sensitive model than M. smegmatis for detecting anti-M. tuberculosis compounds. M. bovis BCG was then used to screen for novel anti-Tb agents by HTS of compound libraries and various plant extracts, followed by validation of new compounds in M. tuberculosis H37Ra. A number of novel M. tuberculosis inhibitors were identified, including sappanone A dimethyl ether from plant sources and compounds NSC112200 and NSC402959 from NIH chemical libraries. The inhibitors that were validated using M. tuberculosis H37Ra were also validated in the virulent Tb strain, M. tuberculosis H37Rv. In addition, their activity was further investigated using a suite of other clinically important human pathogens. One of the key anti-mycobacterial hits identified in this study, NSC402959, has previously been detected in screens for compounds that inhibit ribonuclease H (RNase H), an enzyme that is required for a number of essential cellular processes. NSC402959 inhibited RNase H proteins from HIV as well as from E. coli. Since HIV and Tb are major pandemics, previously-known anti-HIV RNase H compounds were imported and tested for their anti-proliferative activity towards M. tuberculosis H37Ra. HIV RNase H inhibitors, NSC35676, NSC112200, NSC133457 and NSC668394, exhibited good anti-mycobacterial activity in this study. In silico analysis suggested a plausible interaction of these inhibitors with mycobacterial RNase HI. A biochemical assay further confirmed NSC112200 to be specific against RNase HI from M. tuberculosis. These interesting inhibitors were not only structurally different from existing anti-Tb drugs but some of them were also non-toxic to mammalian cells and may have a unique mechanism of action. Thus, these compounds showed good potential for development as dual inhibitors of Tb and HIV; therefore, future studies in animal infection models to determine their dual anti-mycobacterial and anti-HIV activities are warranted.</p>

Isoniazid-Isatin Hydrazone Derivatives: Synthesis, Antitubercular Activity and Molecular Docking Studies

This study examined the synthesis of isoniazid-isatin hydrazone derivatives 5-7, followed by an investigation on the in vitro antitubercular activity against Mycobacterium tuberculosis H37Rv, and molecular docking. A yield of 81 - 92 % of these compounds was achieved, with structural characterization by spectroscopic methods (FTIR, NMR, HRMS). The in vitro antitubercular activity was evaluated against M. tuberculosis H37Rv, and the highest effect was observed in compound 7, with a minimum inhibitory concentration (MIC) of 0.017 mM, lower than rifampicin (MIC 0.048 mM), which served as the positive control. In addition, the molecular docking of 5-7 was performed to visualize the interaction of isoniazid-isatin hydrazone derivatives with the active site of InhA receptor, which was in agreement with the experimental data. The hydrogen bonding with Ser94 and pi-pi interaction with Phe41 and/or Phe97 on the InhA active site was pivotal for the antitubercular activity. HIGHLIGHTS Tuberculosis caused by Mycobacterium tuberculosis is one of the top ten leading causes of death globally The first and second lines of antituberculosis drugs are the prevalent treatment for this disease, but they show several drawbacks and are exacerbated by the occurrence of drug resistance The isoniazid-isatin hydrazone derivatives were designed through molecular hybridization and synthesized effectively and exhibited moderate to high activity against tuberculosis H37Rv Molecular docking study demonstrated that the hydrogen bonding with Ser94 and the pi-pi interaction with Phe41 and/or Phe97 are important for antitubercular activity GRAPHICAL ABSTRACT

Challenges in Defining the Functional, Non-Coding, Expressed Genome of Pathogenic Mycobacteria

A definitive transcriptome atlas for the non-coding expressed elements of pathogenic mycobacteria does not exist. Incomplete lists of non-coding transcripts can be obtained for some of the reference genomes (e.g. Mycobacterium tuberculosis H37Rv) but to what extent these transcripts have homologues in closely related species or even strains is not clear. This has implications for the analysis of transcriptomic data; non-coding parts of the transcriptome are often ignored in the absence of formal, reliable annotation. Here, we review the state of our knowledge of non-coding RNAs in pathogenic mycobacteria, emphasising the disparities in the information included in commonly used databases. We then proceed to review ways of combining computational solutions for predicting the non- coding transcriptome with experiments that can help refine and confirm these predictions.