Your search keyword '"Giannangelo, C"' showing total 6 results

1. Reaction hijacking of tyrosine tRNA synthetase as a new whole-of-life-cycle antimalarial strategy

Author

Xie, SC, Metcalfe, RD, Dunn, E, Morton, CJ, Huang, S-C, Puhalovich, T, Du, Y, Wittlin, S, Nie, S, Luth, MR, Ma, L, Kim, M-S, Pasaje, CFA, Kumpornsin, K, Giannangelo, C, Houghton, FJ, Churchyard, A, Famodimu, MT, Barry, DC, Gillett, DL, Dey, S, Kosasih, CC, Newman, W, Niles, JC, Lee, MCS, Baum, J, Ottilie, S, Winzeler, EA, Creek, DJ, Williamson, N, Parker, MW, Brand, S, Langston, SP, Dick, LR, Griffin, MDW, Gould, AE, Tilley, L, Xie, SC, Metcalfe, RD, Dunn, E, Morton, CJ, Huang, S-C, Puhalovich, T, Du, Y, Wittlin, S, Nie, S, Luth, MR, Ma, L, Kim, M-S, Pasaje, CFA, Kumpornsin, K, Giannangelo, C, Houghton, FJ, Churchyard, A, Famodimu, MT, Barry, DC, Gillett, DL, Dey, S, Kosasih, CC, Newman, W, Niles, JC, Lee, MCS, Baum, J, Ottilie, S, Winzeler, EA, Creek, DJ, Williamson, N, Parker, MW, Brand, S, Langston, SP, Dick, LR, Griffin, MDW, Gould, AE, and Tilley, L

Abstract

Aminoacyl transfer RNA (tRNA) synthetases (aaRSs) are attractive drug targets, and we present class I and II aaRSs as previously unrecognized targets for adenosine 5'-monophosphate-mimicking nucleoside sulfamates. The target enzyme catalyzes the formation of an inhibitory amino acid-sulfamate conjugate through a reaction-hijacking mechanism. We identified adenosine 5'-sulfamate as a broad-specificity compound that hijacks a range of aaRSs and ML901 as a specific reagent a specific reagent that hijacks a single aaRS in the malaria parasite Plasmodium falciparum, namely tyrosine RS (PfYRS). ML901 exerts whole-life-cycle-killing activity with low nanomolar potency and single-dose efficacy in a mouse model of malaria. X-ray crystallographic studies of plasmodium and human YRSs reveal differential flexibility of a loop over the catalytic site that underpins differential susceptibility to reaction hijacking by ML901.

Published

2022

2. Dimeric Artesunate Glycerophosphocholine Conjugate Nano-Assemblies as Slow-Release Antimalarials to Overcome Kelch 13 Mutant Artemisinin Resistance

Author

Du, Y, Giannangelo, C, He, W, Shami, GJ, Zhou, W, Yang, T, Creek, DJ, Dogovski, C, Li, X, Tilley, L, Du, Y, Giannangelo, C, He, W, Shami, GJ, Zhou, W, Yang, T, Creek, DJ, Dogovski, C, Li, X, and Tilley, L

Abstract

Current best practice for the treatment of malaria relies on short half-life artemisinins that are failing against emerging Kelch 13 mutant parasite strains. Here, we introduce a liposome-like self-assembly of a dimeric artesunate glycerophosphocholine conjugate (dAPC-S) as an amphiphilic prodrug for the short-lived antimalarial drug, dihydroartemisinin (DHA), with enhanced killing of Kelch 13 mutant artemisinin-resistant parasites. Cryo-electron microscopy (cryoEM) images and the dynamic light scattering (DLS) technique show that dAPC-S typically exhibits a multilamellar liposomal structure with a size distribution similar to that of the liposomes generated using thin-film dispersion (dAPC-L). Liquid chromatography-mass spectrometry (LCMS) was used to monitor the release of DHA. Sustainable release of DHA from dAPC-S and dAPC-L assemblies increased the effective dose and thus efficacy against Kelch 13 mutant artemisinin-resistant parasites in an in vitro assay. To better understand the enhanced killing effect, we investigated processes for deactivation of both the assemblies and DHA, including the roles of serum components and trace levels of iron. Analysis of parasite proteostasis pathways revealed that dAPC assemblies exert their activity via the same mechanism as DHA. We conclude that this easily prepared multilamellar liposome-like dAPC-S with long-acting efficacy shows potential for the treatment of severe and artemisinin-resistant malaria.

Published

2022

3. Peroxide Antimalarial Drugs Target Redox Homeostasis in Plasmodium falciparum Infected Red Blood Cells

Author

Siddiqui, G, Giannangelo, C, De Paoli, A, Schuh, AK, Heimsch, KC, Anderson, D, Brown, TG, MacRaild, CA, Wu, J, Wang, X, Dong, Y, Vennerstrom, JL, Becker, K, Creek, DJ, Siddiqui, G, Giannangelo, C, De Paoli, A, Schuh, AK, Heimsch, KC, Anderson, D, Brown, TG, MacRaild, CA, Wu, J, Wang, X, Dong, Y, Vennerstrom, JL, Becker, K, and Creek, DJ

Abstract

Plasmodium falciparum causes the most lethal form of malaria. Peroxide antimalarials based on artemisinin underpin the frontline treatments for malaria, but artemisinin resistance is rapidly spreading. Synthetic peroxide antimalarials, known as ozonides, are in clinical development and offer a potential alternative. Here, we used chemoproteomics to investigate the protein alkylation targets of artemisinin and ozonide probes, including an analogue of the ozonide clinical candidate, artefenomel. We greatly expanded the list of proteins alkylated by peroxide antimalarials and identified significant enrichment of redox-related proteins for both artemisinins and ozonides. Disrupted redox homeostasis was confirmed by dynamic live imaging of the glutathione redox potential using a genetically encoded redox-sensitive fluorescence-based biosensor. Targeted liquid chromatography-mass spectrometry (LC-MS)-based thiol metabolomics also confirmed changes in cellular thiol levels. This work shows that peroxide antimalarials disproportionately alkylate proteins involved in redox homeostasis and that disrupted redox processes are involved in the mechanism of action of these important antimalarials.

Published

2022

4. System-wide biochemical analysis reveals ozonide antimalarials initially act by disruptingPlasmodium falciparumhaemoglobin digestion

Author

Egan, TJ, Giannangelo, C, Siddiqui, G, De Paoli, A, Anderson, BM, Edgington-Mitchell, LE, Charman, SA, Creek, DJ, Egan, TJ, Giannangelo, C, Siddiqui, G, De Paoli, A, Anderson, BM, Edgington-Mitchell, LE, Charman, SA, and Creek, DJ

Abstract

Ozonide antimalarials, OZ277 (arterolane) and OZ439 (artefenomel), are synthetic peroxide-based antimalarials with potent activity against the deadliest malaria parasite, Plasmodium falciparum. Here we used a "multi-omics" workflow, in combination with activity-based protein profiling (ABPP), to demonstrate that peroxide antimalarials initially target the haemoglobin (Hb) digestion pathway to kill malaria parasites. Time-dependent metabolomic profiling of ozonide-treated P. falciparum infected red blood cells revealed a rapid depletion of short Hb-derived peptides followed by subsequent alterations in lipid and nucleotide metabolism, while untargeted peptidomics showed accumulation of longer Hb-derived peptides. Quantitative proteomics and ABPP assays demonstrated that Hb-digesting proteases were increased in abundance and activity following treatment, respectively. Ozonide-induced depletion of short Hb-derived peptides was less extensive in a drug-treated K13-mutant artemisinin resistant parasite line (Cam3.IIR539T) than in the drug-treated isogenic sensitive strain (Cam3.IIrev), further confirming the association between ozonide activity and Hb catabolism. To demonstrate that compromised Hb catabolism may be a primary mechanism involved in ozonide antimalarial activity, we showed that parasites forced to rely solely on Hb digestion for amino acids became hypersensitive to short ozonide exposures. Quantitative proteomics analysis also revealed parasite proteins involved in translation and the ubiquitin-proteasome system were enriched following drug treatment, suggestive of the parasite engaging a stress response to mitigate ozonide-induced damage. Taken together, these data point to a mechanism of action involving initial impairment of Hb catabolism, and indicate that the parasite regulates protein turnover to manage ozonide-induced damage.

Published

2020

5. Ozonide Antimalarial Activity in the Context of Artemisinin-Resistant Malaria

Author

Giannangelo, C, Fowkes, FJI, Simpson, JA, Charman, SA, Creek, DJ, Giannangelo, C, Fowkes, FJI, Simpson, JA, Charman, SA, and Creek, DJ

Abstract

The ozonides are one of the most advanced drug classes in the antimalarial development pipeline and were designed to improve on limitations associated with current front-line artemisinin-based therapies. Like the artemisinins, the pharmacophoric peroxide bond of ozonides is essential for activity, and it appears that these antimalarials share a similar mode of action, raising the possibility of cross-resistance. Resistance to artemisinins is associated with Plasmodium falciparum mutations that allow resistant parasites to escape short-term artemisinin-mediated damage (elimination half-life ~1 h). Importantly, some ozonides (e.g., OZ439) have a sustained in vivo drug exposure profile, providing a major pharmacokinetic advantage over the artemisinin derivatives. Here, we describe recent progress made towards understanding ozonide antimalarial activity and discuss ozonide utility within the context of artemisinin resistance.

Published

2019

6. Comparison of the Exposure Time Dependence of the Activities of Synthetic Ozonide Antimalarials and Dihydroartemisinin against K13 Wild-Type and Mutant Plasmodium falciparum Strains

Author

Yang, T, Xie, SC, Cao, P, Giannangelo, C, McCaw, J, Creek, DJ, Charman, SA, Klonis, N, Tilley, L, Yang, T, Xie, SC, Cao, P, Giannangelo, C, McCaw, J, Creek, DJ, Charman, SA, Klonis, N, and Tilley, L

Abstract

Fully synthetic endoperoxide antimalarials, namely, OZ277 (RBx11160; also known as arterolane) and OZ439 (artefenomel), have been approved for marketing or are currently in clinical development. We undertook an analysis of the kinetics of the in vitro responses of Plasmodium falciparum to the new ozonide antimalarials. For these studies we used a K13 mutant (artemisinin resistant) isolate from a region in Cambodia and a genetically matched (artemisinin sensitive) K13 revertant. We used a pulsed-exposure assay format to interrogate the time dependence of the response. Because the ozonides have physicochemical properties different from those of the artemisinins, assay optimization was required to ensure that the drugs were completely removed following the pulsed exposure. Like that of artemisinins, ozonide activity requires active hemoglobin degradation. Short pulses of the ozonides were less effective than short pulses of dihydroartemisinin; however, when early-ring-stage parasites were exposed to drugs for periods relevant to their in vivo exposure, the ozonide antimalarials were markedly more effective.

Published

2016