Bactericidal and Sterilizing Activity of a Novel Regimen with Bedaquiline, Pretomanid, Moxifloxacin, and Pyrazinamide in a Murine Model of Tuberculosis

To truly transform the landscape of tuberculosis treatment, novel regimens containing at least 2 new drugs are needed to simplify the treatment of both drug-susceptible and drug-resistant forms of tuberculosis. As part of an ongoing effort to evaluate novel drug combinations for treatment-shortening potential in a murine model, we performed two long-term, relapse-based experiments. In the first experiment, TMC207 plus pyrazinamide, alone or in combination with any third drug, proved superior to the first-line regimen including rifampin, pyrazinamide, and isoniazid. On the basis of CFU counts at 1 month, clofazimine proved to be the best third drug combined with TMC207 and pyrazinamide, whereas the addition of PA-824 was modestly antagonistic. Relapse results were inconclusive due to the low rate of relapse in all test groups. In the second experiment evaluating 3-drug combinations composed of TMC207, pyrazinamide, PA-824, moxifloxacin, and rifapentine, TMC207 plus pyrazinamide plus either rifapentine or moxifloxacin was the most effective, curing 100% and 67% of the mice treated, respectively, in 2 months of treatment. Four months of the first-line regimen did not cure any mice, whereas the combination of TMC207, PA-824, and moxifloxacin cured 50% of the mice treated. The results reveal new building blocks for novel regimens with the potential to shorten the duration of treatment for both drug-susceptible and drug-resistant tuberculosis, including the combination of TMC207, pyrazinamide, PA-824, and a potent fluoroquinolone.

Novel oral regimens composed of new drugs with potent activity against Mycobacterium tuberculosis and no cross-resistance with existing agents are needed to shorten and simplify treatment for both drug-susceptible and drug-resistant tuberculosis. As part of a continuing effort to evaluate novel drug combinations for treatment-shortening potential in a murine model, we performed two long-term, relapse-based experiments. In the first experiment, several 3- and 4-drug combinations containing new agents currently in phase 2/3 trials (TMC207 [bedaquiline], PA-824 and PNU-100480 [sutezolid], and/or clofazimine) proved superior to the first-line regimen of rifampin, pyrazinamide, and isoniazid. TMC207 plus PNU-100480 was the most effective drug pair. In the second experiment, in which 3- and 4-drug combinations composed of TMC207 and pyrazinamide plus rifapentine, clofazimine, PNU-100480, or both rifapentine and clofazimine were evaluated, the rank order of drugs improving the sterilizing activity of TMC207 and pyrazinamide was as follows: rifapentine plus clofazimine ≥ clofazimine ≥ rifapentine > PNU-100480. The results revealed potential new building blocks for universally active short-course regimens for drug-resistant tuberculosis. The inclusion of pyrazinamide against susceptible isolates may shorten the duration of treatment further.

TMC207 is a first-in-class diarylquinoline with a new mode of action against mycobacteria targeting the ATP synthase. It is metabolized to an active derivative, N-desmethyl TMC207, and both compounds are eliminated with long terminal half-lives (50 to 60 h in mice) reflecting slow release from tissues such as lung and spleen. In vitro, TMC207 is 5-fold more potent against Mycobacterium tuberculosis than N-desmethyl TMC207, and the effects of the two compounds are additive. The pharmacokinetic and pharmacodynamic (PK-PD) response was investigated in the murine model of tuberculosis (TB) infection following oral administration of different doses of TMC207 or N-desmethyl TMC207 at 5 days per week for 4 weeks starting the day after intravenous infection with M. tuberculosis and following administration of different doses of TMC207 at various dosing frequencies for 6 weeks starting 2 weeks after infection. Upon administration of N-desmethyl TMC207, maximum plasma concentration (C(max)), area under the plasma concentration-time curve from time zero to 168 h postdose (AUC(168h)), and minimum plasma concentration (C(min)) were approximately dose proportional between 8 and 64 mg/kg, and the lung CFU counts were strongly correlated with these pharmacokinetic parameters using an inhibitory sigmoid maximum effect (E(max)) model. Administration of the highest dose (64 mg/kg) produced a 4.0-log(10) reduction of the bacillary load at an average exposure (average concentration [C(avg)] or AUC(168h) divided by 168) of 2.7 μg/ml. Upon administration of the highest dose of TMC207 (50 mg/kg) 5 days per week for 4 weeks, the total reduction of the bacillary load was 4.7 log(10). TMC207 was estimated to contribute to a 1.8-log(10) reduction and its corresponding exposure (C(avg)) was 0.5 μg/ml. Optimal bactericidal activity with N-desmethyl TMC207 was reached at a high exposure compared to that achieved in humans, suggesting a minor contribution of the metabolite to the overall bactericidal activity in TB-infected patients treated with TMC207. Following administration of TMC207 at a total weekly dose of 15, 30, or 60 mg/kg fractionated for either 5 days per week, twice weekly, or once weekly, the bactericidal activity was correlated to the total weekly dose and was not influenced by the frequency of administration. Exposures (AUC(168h)) to TMC207 and N-desmethyl TMC207 mirrored this dose response, indicating that the bactericidal activity of TMC207 is concentration dependent and that AUC is the main PK-PD driver on which dose optimization should be based for dosing frequencies up to once weekly. The PK-PD profile supports intermittent administration of TMC207, in agreement with its slow release from tissues.