Your search keyword '"Glynne RJ"' showing total 5 results

1. Author Correction: Discovery of SARS-CoV-2 antiviral drugs through large-scale compound repurposing.

Author

Riva L, Yuan S, Yin X, Martin-Sancho L, Matsunaga N, Pache L, Burgstaller-Muehlbacher S, De Jesus PD, Teriete P, Hull MV, Chang MW, Chan JF, Cao J, Poon VK, Herbert KM, Cheng K, Nguyen TH, Rubanov A, Pu Y, Nguyen C, Choi A, Rathnasinghe R, Schotsaert M, Miorin L, Dejosez M, Zwaka TP, Sit KY, Martinez-Sobrido L, Liu WC, White KM, Chapman ME, Lendy EK, Glynne RJ, Albrecht R, Ruppin E, Mesecar AD, Johnson JR, Benner C, Sun R, Schultz PG, Su AI, García-Sastre A, Chatterjee AK, Yuen KY, and Chanda SK

Published

2024

2. Discovery and Characterization of Clinical Candidate LXE408 as a Kinetoplastid-Selective Proteasome Inhibitor for the Treatment of Leishmaniases.

Author

Nagle A, Biggart A, Be C, Srinivas H, Hein A, Caridha D, Sciotti RJ, Pybus B, Kreishman-Deitrick M, Bursulaya B, Lai YH, Gao MY, Liang F, Mathison CJN, Liu X, Yeh V, Smith J, Lerario I, Xie Y, Chianelli D, Gibney M, Berman A, Chen YL, Jiricek J, Davis LC, Liu X, Ballard J, Khare S, Eggimann FK, Luneau A, Groessl T, Shapiro M, Richmond W, Johnson K, Rudewicz PJ, Rao SPS, Thompson C, Tuntland T, Spraggon G, Glynne RJ, Supek F, Wiesmann C, and Molteni V

Subjects

Animals, Antiprotozoal Agents therapeutic use, Dogs, Humans, Leishmania donovani drug effects, Leishmania donovani isolation & purification, Leishmania major drug effects, Leishmania major isolation & purification, Leishmaniasis, Visceral parasitology, Liver parasitology, Macaca fascicularis, Mice, Mice, Inbred BALB C, Oxazoles therapeutic use, Proteasome Inhibitors therapeutic use, Pyrimidines therapeutic use, Rats, Rats, Sprague-Dawley, Triazoles chemistry, Antiprotozoal Agents chemistry, Antiprotozoal Agents pharmacology, Leishmaniasis, Visceral drug therapy, Oxazoles chemistry, Oxazoles pharmacology, Proteasome Inhibitors chemistry, Proteasome Inhibitors pharmacology, Pyrimidines chemistry, Pyrimidines pharmacology

Abstract

Visceral leishmaniasis is responsible for up to 30,000 deaths every year. Current treatments have shortcomings that include toxicity and variable efficacy across endemic regions. Previously, we reported the discovery of GNF6702, a selective inhibitor of the kinetoplastid proteasome, which cleared parasites in murine models of leishmaniasis, Chagas disease, and human African trypanosomiasis. Here, we describe the discovery and characterization of LXE408, a structurally related kinetoplastid-selective proteasome inhibitor currently in Phase 1 human clinical trials. Furthermore, we present high-resolution cryo-EM structures of the Leishmania tarentolae proteasome in complex with LXE408, which provides a compelling explanation for the noncompetitive mode of binding of this novel class of inhibitors of the kinetoplastid proteasome.

Published

2020

3. Discovery of SARS-CoV-2 antiviral drugs through large-scale compound repurposing.

Author

Riva L, Yuan S, Yin X, Martin-Sancho L, Matsunaga N, Pache L, Burgstaller-Muehlbacher S, De Jesus PD, Teriete P, Hull MV, Chang MW, Chan JF, Cao J, Poon VK, Herbert KM, Cheng K, Nguyen TH, Rubanov A, Pu Y, Nguyen C, Choi A, Rathnasinghe R, Schotsaert M, Miorin L, Dejosez M, Zwaka TP, Sit KY, Martinez-Sobrido L, Liu WC, White KM, Chapman ME, Lendy EK, Glynne RJ, Albrecht R, Ruppin E, Mesecar AD, Johnson JR, Benner C, Sun R, Schultz PG, Su AI, García-Sastre A, Chatterjee AK, Yuen KY, and Chanda SK

Subjects

Adenosine Monophosphate analogs & derivatives, Adenosine Monophosphate pharmacology, Alanine analogs & derivatives, Alanine pharmacology, Alveolar Epithelial Cells cytology, Alveolar Epithelial Cells drug effects, Betacoronavirus growth & development, COVID-19, Cell Line, Cysteine Proteinase Inhibitors analysis, Cysteine Proteinase Inhibitors pharmacology, Dose-Response Relationship, Drug, Drug Synergism, Gene Expression Regulation drug effects, Humans, Hydrazones, Induced Pluripotent Stem Cells cytology, Models, Biological, Morpholines analysis, Morpholines pharmacology, Pandemics, Pyrimidines, Reproducibility of Results, SARS-CoV-2, Small Molecule Libraries analysis, Small Molecule Libraries pharmacology, Triazines analysis, Triazines pharmacology, Virus Internalization drug effects, Virus Replication drug effects, COVID-19 Drug Treatment, Antiviral Agents analysis, Antiviral Agents pharmacology, Betacoronavirus drug effects, Coronavirus Infections drug therapy, Coronavirus Infections virology, Drug Evaluation, Preclinical, Drug Repositioning, Pneumonia, Viral drug therapy, Pneumonia, Viral virology

Abstract

The emergence of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) in 2019 has triggered an ongoing global pandemic of the severe pneumonia-like disease coronavirus disease 2019 (COVID-19) 1 . The development of a vaccine is likely to take at least 12-18 months, and the typical timeline for approval of a new antiviral therapeutic agent can exceed 10 years. Thus, repurposing of known drugs could substantially accelerate the deployment of new therapies for COVID-19. Here we profiled a library of drugs encompassing approximately 12,000 clinical-stage or Food and Drug Administration (FDA)-approved small molecules to identify candidate therapeutic drugs for COVID-19. We report the identification of 100 molecules that inhibit viral replication of SARS-CoV-2, including 21 drugs that exhibit dose-response relationships. Of these, thirteen were found to harbour effective concentrations commensurate with probable achievable therapeutic doses in patients, including the PIKfyve kinase inhibitor apilimod 2-4 and the cysteine protease inhibitors MDL-28170, Z LVG CHN2, VBY-825 and ONO 5334. Notably, MDL-28170, ONO 5334 and apilimod were found to antagonize viral replication in human pneumocyte-like cells derived from induced pluripotent stem cells, and apilimod also demonstrated antiviral efficacy in a primary human lung explant model. Since most of the molecules identified in this study have already advanced into the clinic, their known pharmacological and human safety profiles will enable accelerated preclinical and clinical evaluation of these drugs for the treatment of COVID-19.

Published

2020

4. Proteasome inhibition for treatment of leishmaniasis, Chagas disease and sleeping sickness.

Author

Khare S, Nagle AS, Biggart A, Lai YH, Liang F, Davis LC, Barnes SW, Mathison CJ, Myburgh E, Gao MY, Gillespie JR, Liu X, Tan JL, Stinson M, Rivera IC, Ballard J, Yeh V, Groessl T, Federe G, Koh HX, Venable JD, Bursulaya B, Shapiro M, Mishra PK, Spraggon G, Brock A, Mottram JC, Buckner FS, Rao SP, Wen BG, Walker JR, Tuntland T, Molteni V, Glynne RJ, and Supek F

Subjects

Animals, Chagas Disease parasitology, Chymotrypsin antagonists & inhibitors, Chymotrypsin metabolism, Disease Models, Animal, Female, Humans, Inhibitory Concentration 50, Leishmaniasis parasitology, Mice, Molecular Structure, Molecular Targeted Therapy, Proteasome Inhibitors adverse effects, Proteasome Inhibitors classification, Pyrimidines adverse effects, Pyrimidines chemistry, Pyrimidines therapeutic use, Species Specificity, Triazoles adverse effects, Triazoles chemistry, Triazoles therapeutic use, Trypanosomiasis, African parasitology, Chagas Disease drug therapy, Kinetoplastida drug effects, Kinetoplastida enzymology, Leishmaniasis drug therapy, Proteasome Endopeptidase Complex drug effects, Proteasome Inhibitors pharmacology, Proteasome Inhibitors therapeutic use, Pyrimidines pharmacology, Triazoles pharmacology, Trypanosomiasis, African drug therapy

Abstract

Chagas disease, leishmaniasis and sleeping sickness affect 20 million people worldwide and lead to more than 50,000 deaths annually. The diseases are caused by infection with the kinetoplastid parasites Trypanosoma cruzi, Leishmania spp. and Trypanosoma brucei spp., respectively. These parasites have similar biology and genomic sequence, suggesting that all three diseases could be cured with drugs that modulate the activity of a conserved parasite target. However, no such molecular targets or broad spectrum drugs have been identified to date. Here we describe a selective inhibitor of the kinetoplastid proteasome (GNF6702) with unprecedented in vivo efficacy, which cleared parasites from mice in all three models of infection. GNF6702 inhibits the kinetoplastid proteasome through a non-competitive mechanism, does not inhibit the mammalian proteasome or growth of mammalian cells, and is well-tolerated in mice. Our data provide genetic and chemical validation of the parasite proteasome as a promising therapeutic target for treatment of kinetoplastid infections, and underscore the possibility of developing a single class of drugs for these neglected diseases., Competing Interests: Patents related to this work has been filed (WO 2015/095477 A1, WO 2014/151784 A1, WO 2014/151729). Several authors own shares of Novartis.

Published

2016

5. Utilizing Chemical Genomics to Identify Cytochrome b as a Novel Drug Target for Chagas Disease.

Author

Khare S, Roach SL, Barnes SW, Hoepfner D, Walker JR, Chatterjee AK, Neitz RJ, Arkin MR, McNamara CW, Ballard J, Lai Y, Fu Y, Molteni V, Yeh V, McKerrow JH, Glynne RJ, and Supek F

Subjects

Animals, Antimycin A metabolism, Chagas Disease genetics, Cytochromes b genetics, Electron Transport drug effects, Electron Transport immunology, Genomics, Mice, Mitochondria drug effects, Mitochondria metabolism, Mutation, Oxygen Consumption drug effects, Trypanosoma cruzi isolation & purification, Trypanosoma cruzi metabolism, Antifungal Agents pharmacology, Chagas Disease drug therapy, Chagas Disease microbiology, Cytochromes b metabolism, Trypanosoma cruzi drug effects

Abstract

Unbiased phenotypic screens enable identification of small molecules that inhibit pathogen growth by unanticipated mechanisms. These small molecules can be used as starting points for drug discovery programs that target such mechanisms. A major challenge of the approach is the identification of the cellular targets. Here we report GNF7686, a small molecule inhibitor of Trypanosoma cruzi, the causative agent of Chagas disease, and identification of cytochrome b as its target. Following discovery of GNF7686 in a parasite growth inhibition high throughput screen, we were able to evolve a GNF7686-resistant culture of T. cruzi epimastigotes. Clones from this culture bore a mutation coding for a substitution of leucine by phenylalanine at amino acid position 197 in cytochrome b. Cytochrome b is a component of complex III (cytochrome bc1) in the mitochondrial electron transport chain and catalyzes the transfer of electrons from ubiquinol to cytochrome c by a mechanism that utilizes two distinct catalytic sites, QN and QP. The L197F mutation is located in the QN site and confers resistance to GNF7686 in both parasite cell growth and biochemical cytochrome b assays. Additionally, the mutant cytochrome b confers resistance to antimycin A, another QN site inhibitor, but not to strobilurin or myxothiazol, which target the QP site. GNF7686 represents a promising starting point for Chagas disease drug discovery as it potently inhibits growth of intracellular T. cruzi amastigotes with a half maximal effective concentration (EC50) of 0.15 µM, and is highly specific for T. cruzi cytochrome b. No effect on the mammalian respiratory chain or mammalian cell proliferation was observed with up to 25 µM of GNF7686. Our approach, which combines T. cruzi chemical genetics with biochemical target validation, can be broadly applied to the discovery of additional novel drug targets and drug leads for Chagas disease.

Published

2015