Toward an optimized therapy for tuberculosis? Drugs in clinical trials and in preclinical development

A Review of the Development of Multitarget Molecules against HIV-TB Coinfection Pathogens

The human immunodeficiency virus (HIV) produces the pathologic basis of acquired immunodeficiency syndrome (AIDS). An increase in the viral load in the body leads to a decline in the number of T lymphocytes, compromising the patient's immune system. Some opportunistic diseases may result, such as tuberculosis (TB), which is the most common in seropositive patients. Long-term treatment is required for HIV-TB coinfection, and cocktails of drugs for both diseases are used concomitantly. The most challenging aspects of treatment are the occurrence of drug interactions, overlapping toxicity, no adherence to treatment and cases of resistance. Recent approaches have involved using molecules that can act synergistically on two or more distinct targets. The development of multitarget molecules could overcome the disadvantages of the therapies used to treat HIV-TB coinfection. This report is the first review on using molecules with activities against HIV and Mycobacterium tuberculosis (MTB) for molecular hybridization and multitarget strategies. Here, we discuss the importance and development of multiple targets as a means of improving adherence to therapy in cases of the coexistence of these pathologies. In this context, several studies on the development of structural entities to treat HIV-TB simultaneously are discussed.

Molecular dynamics simulation and binding free energy studies of novel leads belonging to the benzofuran class inhibitors of Mycobacterium tuberculosis Polyketide Synthase 13

In this work, the binding mechanism of new Polyketide Synthase 13 (Pks13) inhibitors has been studied through molecular dynamics simulation and free energy calculations. The drug Tam1 and its analogs, belonging to the benzofuran class, were submitted to 100 ns simulations, and according to the results obtained for root mean square deviation, all the simulations converged from approximately 30 ns. For the analysis of backbone flotation, the root mean square fluctuations were plotted for the Cα atoms; analysis revealed that the greatest fluctuation occurred in the residues that are part of the protein lid domain. The binding free energy value (ΔG_bind) obtained for the Tam16 lead molecule was of -51.43 kcal/mol. When comparing this result with the ΔG_bind values for the remaining analogs, the drug Tam16 was found to be the highest ranked: this result is in agreement with the experimental results obtained by Aggarwal and collaborators, where it was verified that the IC₅₀ for Tam16 is the smallest necessary to inhibit the Pks13 (IC₅₀ = 0.19 μM). The energy decomposition analysis suggested that the residues which most interact with inhibitors are: Ser1636, Tyr1637, Asn1640, Ala1667, Phe1670, and Tyr1674, from which the greatest energy contribution to Phe1670 was particularly notable. For the lead molecule Tam16, a hydrogen bond with the hydroxyl of the phenol not observed in the other analogs induced a more stable molecular structure. Aggarwal and colleagues reported this hydrogen bonding as being responsible for the stability of the molecule, optimizing its physic-chemical, toxicological, and pharmacokinetic properties.

Tuberculosis-a World Health Organization Perspective

Tuberculosis (TB) is an important cause of morbidity and mortality worldwide. The World Health Organization (WHO) has implemented and scaled-up three important global public health strategies (i.e., DOTS, Stop TB, and End TB) to improve the international scenario. Their epidemiological impact was relevant, as they decreased the number of potential new cases of disease and death. However, the emergence and spread of TB/HIV coinfection and multidrug-resistant TB have hindered the progress towards the elimination of TB by 2050. More efforts are required to increase the global annual decline of the TB incidence rate. Political commitment is necessary, with global and national strategies oriented to the adoption and adaptation of the international, evidence-based recommendations on diagnosis, treatment, and prevention. Research and development activities should be planned to improve the current tools adopted to fight the disease. New rapid diagnostics, an updated and effective therapeutic armamentarium, and an effective preventive vaccine could represent the solution to address the current epidemiological threats.

[Tuberculosis]

Tuberculosis (TB) continues to be an important public health problem. Currently, 2,100 million people--one third of the world population--are infected by Mycobacterium tuberculosis, with an estimated annual rate of 9.4 million new cases, and 440,000 cases of multidrug-resistant (MDR) TB in 2008; furthermore, cases of extensively-resistant (XDR) TB have been detected in 57 countries. While TB cases are constantly declining in industrialized countries, the rates and mortality due to this infection in developing countries remain alarming and will continue to be so in the future. Although the priorities in these countries are at present simpler, methods allowing rapid diagnosis of TB and of resistant strains will obviously contribute to better control of the disease. Nucleic acid amplification techniques allow M. tuberculosis detection in clinical samples in a few hours, while liquid media cultures may yield positive results in only 2 to 4 weeks, half the time that is usually required for growth in conventional solid media, which also allows more rapid determination of drug susceptibilities. Similarly, based on molecular biology, several approaches may rapidly identify gene mutations associated with resistance to antituberculosis drugs in clinical samples. Finally, the main obstacle to treatment adherence among patients--its length--could be minimized in the future if the new combinations of drugs currently under investigation, and some promising new vaccines, confirm similar rates of efficacy to those used at present.

Drugs in development for tuberculosis

Tuberculosis (TB) drug research and development efforts have resurged in the past 10 years to meet urgent medical needs, but enormous challenges remain. These urgent needs are largely driven by the current long and arduous multidrug regimens, which have significant safety, tolerability and compliance issues; rising and disturbing rates of multidrug- and extensively drug-resistant TB; the existence of approximately 2 billion individuals already latently infected with Mycobacterium tuberculosis, the causative pathogen of TB; and a global TB-HIV co-epidemic. Stakeholders in TB drug development are moving to enable and streamline development and registration of novel, multidrug treatment regimens, comprised of multiple new chemical entities with novel mechanisms of action that do not demonstrate cross-resistance to current first- and second-line TB drugs. Ideally, these new regimens will ultimately provide a short, simple treatment suitable for essentially all TB patients, whether sensitive or resistant to the current anti-TB agents, whether HIV-positive or -negative, and irrespective of patient age. This article reviews the challenges faced by those trying to develop these novel regimens and the key agents currently in clinical testing for TB; the latter are organized for discussion into three categories: (i) novel drugs (TMC207, SQ109, sudoterb [LL3858]); (ii) present first-line TB drugs being re-evaluated to optimize their efficacy (rifampicin, rifapentine); and (iii) currently licensed drugs for other indications and 'next-generation' compounds of the same chemical class being repurposed for TB (gatifloxacin and moxifloxacin; linezolid, PNU100480 and AZD5847; metronidazole, OPC-67683 and PA-824).

New antituberculous drugs in development

There have been no new antituberculous drugs since the introduction of rifampin in 1952. The collision of the HIV and tuberculosis (TB) epidemics in developing regions of the world together with the emergence of multidrug resistance and extensively drug-resistant strains of TB has emphasized the urgent need for newer antituberculous drugs. There is a need for drugs that are safe, effective against resistant strains, are able to shorten the course of treatment, are effective for latent TB infection, and that have minimal interactions with antiretroviral drugs. Drugs that are currently in phase 3 development are moxifloxacin and gatifloxacin. In phase 2 development are PA-824 and TMC207; and in phase 1 are SQ109, AZD5847, and linezolid. Nanotechnology holds future promise for targeted drug delivery. Immunotherapy such as new vaccines and vitamin D may serve as adjunctive treatment for prevention and active disease, together with shortening the course of treatment. Bringing newer and more effective antituberculous drugs to market is a global priority and the process must be accelerated.

The chemical biology of new drugs in the development for tuberculosis

With the worldwide emergence of multidrug-resistant (MDR) and extensively drug-resistant (XDR) strains of Mycobacterium tuberculosis (Mtb), there are serious concerns about the continued ability to contain this disease. We discuss the most promising new drugs in late-stage development that might be useful in treating MDR and XDR forms of the disease. These agents have novel mechanisms of action that are not targeted by the standard drugs used presently to treat susceptible strains.