Alain Philippe Poncelet

Diarylquinolines Are Bactericidal for Dormant Mycobacteria as a Result of Disturbed ATP Homeostasis

An estimated one-third of the world population is latently infected with Mycobacterium tuberculosis. These nonreplicating, dormant bacilli are tolerant to conventional anti-tuberculosis drugs, such as isoniazid. We recently identified diarylquinoline R207910 (also called TMC207) as an inhibitor of ATP synthase with a remarkable activity against replicating mycobacteria. In the present study, we show that R207910 kills dormant bacilli as effectively as aerobically grown bacilli with the same target specificity. Despite a transcriptional down-regulation of the ATP synthase operon and significantly lower cellular ATP levels, we show that dormant mycobacteria do possess residual ATP synthase enzymatic activity. This activity is blocked by nanomolar concentrations of R207910, thereby further reducing ATP levels and causing a pronounced bactericidal effect. We conclude that this residual ATP synthase activity is indispensable for the survival of dormant mycobacteria, making it a promising drug target to tackle dormant infections. The unique dual bactericidal activity of diarylquinolines on dormant as well as replicating bacterial subpopulations distinguishes them entirely from the current anti-tuberculosis drugs and underlines the potential of R207910 to shorten tuberculosis treatment.

Diarylquinolines, synthesis pathways and quantitative structure-activity relationship studies leading to the discovery of TMC207

The emergence of multidrug-resistant strains of Mycobacterium tuberculosis and resistance to current anti-TB drugs call for the discovery and development of new effective anti-TB drugs. TMC207 is the lead candidate of a novel class of antimycobacterial agents, the diarylquinolines, which specifically inhibit mycobacterial ATP synthase and displays high activity against both drug-susceptible and multidrug-resistant strains of Mycobacterium tuberculosis. This article covers both synthesis pathways as well as qualitative and quantitative analyses of the structure-activity relationships of the diarylquinoline series on Mycobacterium smegmatis activity.

Extending kinome coverage by analysis of kinase inhibitor broad profiling data

The explored kinome was extended with broad profiling using the DiscoveRx and Millipore assay panels. The analysis of the profiling of 3368 selected inhibitors on 456 kinases in the DiscoveRx format delivered several insights. First, the coverage depended on the threshold of the selectivity parameter. Second, the relation between hit confirmation rates and inhibitor selectivity showed unexpectedly that higher selectivity can increase the likelihood of false positives. Third, comparing the coverage of a focused to that of a random library showed that the design based on a maximum number of scaffolds was superior to a limited number of scaffolds. Therefore, selective compounds can be used in target validation, enable the jumpstarting of new kinase drug discovery projects, and chart new biological space via phenotypic screening.

Abstract DDT02-04: A novel PRMT5 inhibitor with potent in vitro and in vivo activity in preclinical lung cancer models

PRMT5 is a type II methyltransferase that specifically adds methyl groups to arginine as a long-lasting post-translational modification. The PRMT5/MEP50 complex regulates a plethora of cellular processes, such as epigenetics and splicing, which are notable events involved in tumorigenesis. Although not frequently mutated or amplified in tumors, elevated PRMT5 protein levels in lung and hematologic cancers are correlated with poorer survival. The PRMT5 inhibitor JNJ-64619178 has been selected as a clinical candidate based on its high selectivity and potency (subnanomolar range) under different in vitro and cellular conditions, paired with favorable pharmacokinetics and safety properties. JNJ-64619178 binds into the SAM binding pocket and reaches the substrate binding pocket to inhibit PRMT5/MEP50 function in a time-dependent manner. Broad cell line panel profiling of JNJ-64619178 revealed a wide range of sensitivity, which is indicative of a genomic dependency instead of a general cytotoxic on-target consequence of PRMT5 inhibition. Further investigations indicate a synthetic lethal correlation between PRMT5 inhibition and key cancer driver pathways. JNJ-64619178, dosed orally (10 mg/kg, every day), showed selective and efficient blockage of the methylation of SMD1/3 proteins, which are crucial components of the spliceosome and substrates of PRMT5/MEP50. JNJ-64619178 also demonstrated tumor regression in a biomarker-driven human small cell lung cancer xenograft model (NCI-H1048) and prolonged tumor growth inhibition after dosing cessation. In rodent and nonrodent toxicology studies, a tolerated dose of JNJ-64619178 has been identified, with the observed toxicity consistent with on-target activity. In summary, JNJ-64619178 has a favorable preclinical package that supports clinical testing in patients diagnosed with lung cancer and hematologic malignancies. Citation Format: Dirk Brehmer, Tongfei Wu, Geert Mannens, Lijs Beke, Petra Vinken, Dana Gaffney, Weimei Sun, Vineet Pande, Jan-Willem Thuring, Hillary Millar, Italo Poggesi, Ivan Somers, An Boeckx, Marc Parade, Erika van Heerde, Thomas Nys, Carol Yanovich, Barbara Herkert, Tinne Verhulst, Marc Du Jardin, Lieven Meerpoel, Christopher Moy, Gaston Diels, Marcel Viellevoye, Wim Schepens, Alain Poncelet, Joannes T. Linders, Edward C. Lawson, James P. Edwards, Dushen Chetty, Sylvie Laquerre, Matthew V. Lorenzi. A novel PRMT5 inhibitor with potent in vitro and in vivo activity in preclinical lung cancer models [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr DDT02-04. doi:10.1158/1538-7445.AM2017-DDT02-04