A Macrophage Infection Model to Predict Drug Efficacy Against<i>Mycobacterium Tuberculosis</i>

Schaaf, Kaitlyn; Hayley, Virginia; Speer, Alexander; Wolschendorf, Frank; Niederweis, Michael; Kutsch, Olaf; Sun, Jim

doi:10.1089/adt.2016.717

Cited by 17 publications

(22 citation statements)

References 49 publications

(79 reference statements)

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“…Moreover, the granuloma is a good predictor of a drug’s in vivo efficacy. 226 However, it is important to be mindful that in vivo Mtb does not only reside inside the cellular granuloma. For example, extracellular Mtb is found in the caseum of the necrotic granuloma, and infection may be found outside the lung.…”

Section: Replicating Infection Conditions In Whole-cell Screeningmentioning

confidence: 99%

Hit Generation in TB Drug Discovery: From Genome to Granuloma

2018

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Current tuberculosis (TB) drug development efforts are not sufficient to end the global TB epidemic. Recent efforts have focused on the development of whole-cell screening assays because biochemical, target-based inhibitor screens during the last two decades have not delivered new TB drugs. Mycobacterium tuberculosis (Mtb), the causative agent of TB, encounters diverse microenvironments and can be found in a variety of metabolic states in the human host. Due to the complexity and heterogeneity of Mtb infection, no single model can fully recapitulate the in vivo conditions in which Mtb is found in TB patients, and there is no single “standard” screening condition to generate hit compounds for TB drug development. However, current screening assays have become more sophisticated as researchers attempt to mirror the complexity of TB disease in the laboratory. In this review, we describe efforts using surrogates and engineered strains of Mtb to focus screens on specific targets. We explain model culture systems ranging from carbon starvation to hypoxia, and combinations thereof, designed to represent the microenvironment which Mtb encounters in the human body. We outline ongoing efforts to model Mtb infection in the lung granuloma. We assess these different models, their ability to generate hit compounds, and needs for further TB drug development, to provide direction for future TB drug discovery.

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Section: Replicating Infection Conditions In Whole-cell Screeningmentioning

confidence: 99%

Hit Generation in TB Drug Discovery: From Genome to Granuloma

2018

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“…Kinome analysis provided us with a basic understanding of the protein-protein interaction network governed by PPM1A and allowed us to identify pharmacologically addressable targets to bring proof of principle that therapeutic restoration of the ability of macrophages to undergo apoptosis in response to Mtb infection can be achieved. Beyond this, we demonstrate that selective killing of Mtb -infected macrophages increased the efficacy of the first-line anti-tuberculosis drug rifampicin, which has been reported to be less effective against intracellular Mtb 26 27 due to inefficient penetration into cells 28 29 . As such, a “release and kill” strategy to deprive the replicative niche of Mtb by inducing Mtb -infected macrophage cell death would be a means to more efficiently expose the bacteria to already existing Mtb drugs, thereby shortening the currently long treatment times.…”

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confidence: 67%

“…Apoptosis of infected macrophages stimulates the antibacterial response 5 and plays a significant role in promoting adaptive immunity 3 . Alternatively, given reports that several key TB drugs such as rifampicin 26 27 , streptomycin, and fluoroquinolones have decreased efficacy against intracellular Mtb likely due to penetration properties 29 , induction of apoptosis may also improve the ability of existing antimicrobial chemotherapy against Mtb .…”

Section: Resultsmentioning

confidence: 99%

“…Beyond this, drug-induced selective killing of Mtb -infected macrophages could likely increase the efficacy of existing anti- Mtb drugs as they gain better access to the bacteria. This approach would be particularly useful as adjunctive TB therapy since the commonly used anti- Mtb drugs rifampicin 26 27 , streptomycin, and fluoroquinolones having decreased efficacy against intracellular Mtb likely due to penetration properties 29 . Indeed, in a process we term “release and kill”, our results show that anisomycin induced killing of Mtb -infected macrophages removes the protective niche of the bacteria and increases the efficacy of rifampicin to kill Mtb at concentrations that are normally inactive against intracellular Mtb .…”

Section: Discussionmentioning

confidence: 99%

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Mycobacterium tuberculosis exploits the PPM1A signaling pathway to block host macrophage apoptosis

Schaaf

Smith

Duverger

et al. 2017

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The ability to suppress host macrophage apoptosis is essential for M. tuberculosis (Mtb) to replicate intracellularly while protecting it from antibiotic treatment. We recently described that Mtb infection upregulated expression of the host phosphatase PPM1A, which impairs the antibacterial response of macrophages. Here we establish PPM1A as a checkpoint target used by Mtb to suppress macrophage apoptosis. Overproduction of PPM1A suppressed apoptosis of Mtb-infected macrophages by a mechanism that involves inactivation of the c-Jun N-terminal kinase (JNK). Targeted depletion of PPM1A by shRNA or inhibition of PPM1A activity by sanguinarine restored JNK activation, resulting in increased apoptosis of Mtb-infected macrophages. We also demonstrate that activation of JNK by subtoxic concentrations of anisomycin induced selective apoptotic killing of Mtb-infected human macrophages, which was completely blocked in the presence of a specific JNK inhibitor. Finally, selective killing of Mtb-infected macrophages and subsequent bacterial release enabled rifampicin to effectively kill Mtb at concentrations that were insufficient to act against intracellular Mtb, providing proof of principle for the efficacy of a “release and kill” strategy. Taken together, these findings suggest that drug-induced selective apoptosis of Mtb-infected macrophages is achievable.

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“…Using a combination of New Zealand White rabbits, imaging mass spectrometry, three first-line anti-TB drugs (INH, RIF, and PZA), and the fluoroquinolone MXF, the group demonstrated that drug plasma concentration was indeed a poor proxy for drug concentration in TB lesions (8). The lack of data on how this might translate into humans combined with the absence of cellular protein binding data were acknowledged as weaknesses by the authors; nevertheless, this work prompted a growing appreciation of the need to include permeation studies in their drug development pipeline (16,129,130). …”

Section: Introductionmentioning

confidence: 99%

Drug permeation and metabolism in Mycobacterium tuberculosis: Prioritising local exposure as essential criterion in new TB drug development

et al. 2018

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Anti-tuberculosis (TB) drugs possess diverse abilities to penetrate the different host tissues and cell types in which infecting Mycobacterium tuberculosis bacilli are located during active disease. This is important since there is increasing evidence that the respective "lesion-penetrating" properties of the front-line TB drugs appear to correlate well with their specific activity in standard combination therapy. In turn, these observations suggest that rational efforts to discover novel treatment-shortening drugs and drug combinations should incorporate knowledge about the comparative abilities of both existing and experimental anti-TB agents to access bacilli in defined physiological states at different sites of infection, as well as avoid elimination by efflux or inactivation by host or bacterial metabolism. However, while there is a fundamental requirement to understand the mode of action and pharmacological properties of any current or experimental anti-TB agent within the context of the obligate human host, this is complex and, until recently, has been severely limited by the available methodologies and models. Here, we discuss advances in analytical models and technologies which have enabled investigations of drug metabolism and pharmacokinetics (DMPK) for new TB drug development. In particular, we consider the potential to shift the focus of traditional pharmacokinetic-pharmacodynamic analyses away from plasma to a more specific "site of action" drug exposure as an essential criterion for drug development and the design of dosing strategies. Moreover, in summarising approaches to determine DMPK data for the "unit of infection" comprising host macrophage and intracellular bacillus, we evaluate the potential benefits of including these analyses at an early stage in the preclinical drug development algorithm. © 2018 IUBMB Life, 70(9):926-937, 2018.

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A Macrophage Infection Model to Predict Drug Efficacy AgainstMycobacterium Tuberculosis

Cited by 17 publications

References 49 publications

Hit Generation in TB Drug Discovery: From Genome to Granuloma

Hit Generation in TB Drug Discovery: From Genome to Granuloma

Mycobacterium tuberculosis exploits the PPM1A signaling pathway to block host macrophage apoptosis

Drug permeation and metabolism in Mycobacterium tuberculosis: Prioritising local exposure as essential criterion in new TB drug development

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