Your search keyword '"David L. Gillett"' showing total 15 results

1. Cellular and Structural Basis of Synthesis of the Unique Intermediate Dehydro-F420-0 in Mycobacteria

Author

Rhys Grinter, Blair Ney, Rajini Brammananth, Christopher K. Barlow, Paul R. F. Cordero, David L. Gillett, Thierry Izoré, Max J. Cryle, Liam K. Harold, Gregory M. Cook, George Taiaroa, Deborah A. Williamson, Andrew C. Warden, John G. Oakeshott, Matthew C. Taylor, Paul K. Crellin, Colin J. Jackson, Ralf B. Schittenhelm, Ross L. Coppel, and Chris Greening

Subjects

cofactor biosynthesis, deazaflavin, F420, Mycobacterium, Mycobacterium smegmatis, structural biology, Microbiology, QR1-502

Abstract

ABSTRACT F420 is a low-potential redox cofactor used by diverse bacteria and archaea. In mycobacteria, this cofactor has multiple roles, including adaptation to redox stress, cell wall biosynthesis, and activation of the clinical antitubercular prodrugs pretomanid and delamanid. A recent biochemical study proposed a revised biosynthesis pathway for F420 in mycobacteria; it was suggested that phosphoenolpyruvate served as a metabolic precursor for this pathway, rather than 2-phospholactate as long proposed, but these findings were subsequently challenged. In this work, we combined metabolomic, genetic, and structural analyses to resolve these discrepancies and determine the basis of F420 biosynthesis in mycobacterial cells. We show that, in whole cells of Mycobacterium smegmatis, phosphoenolpyruvate rather than 2-phospholactate stimulates F420 biosynthesis. Analysis of F420 biosynthesis intermediates present in M. smegmatis cells harboring genetic deletions at each step of the biosynthetic pathway confirmed that phosphoenolpyruvate is then used to produce the novel precursor compound dehydro-F420-0. To determine the structural basis of dehydro-F420-0 production, we solved high-resolution crystal structures of the enzyme responsible (FbiA) in apo-, substrate-, and product-bound forms. These data show the essential role of a single divalent cation in coordinating the catalytic precomplex of this enzyme and demonstrate that dehydro-F420-0 synthesis occurs through a direct substrate transfer mechanism. Together, these findings resolve the biosynthetic pathway of F420 in mycobacteria and have significant implications for understanding the emergence of antitubercular prodrug resistance. IMPORTANCE Mycobacteria are major environmental microorganisms and cause many significant diseases, including tuberculosis. Mycobacteria make an unusual vitamin-like compound, F420, and use it to both persist during stress and resist antibiotic treatment. Understanding how mycobacteria make F420 is important, as this process can be targeted to create new drugs to combat infections like tuberculosis. In this study, we show that mycobacteria make F420 in a way that is different from other bacteria. We studied the molecular machinery that mycobacteria use to make F420, determining the chemical mechanism for this process and identifying a novel chemical intermediate. These findings also have clinical relevance, given that two new prodrugs for tuberculosis treatment are activated by F420.

Published

2020

2. Artemisinin kills malaria parasites by damaging proteins and inhibiting the proteasome

Author

Jessica L. Bridgford, Stanley C. Xie, Simon A. Cobbold, Charisse Flerida A. Pasaje, Susann Herrmann, Tuo Yang, David L. Gillett, Lawrence R. Dick, Stuart A. Ralph, Con Dogovski, Natalie J. Spillman, and Leann Tilley

Subjects

Science

Abstract

Artemisinin (ART) is a widely used antimalarial drug, but its mechanism of action is poorly understood. Here, Bridgford et al. show that ART kills parasites by a two-pronged mechanism, causing protein damage and compromising proteasome function, and that accumulation of proteasome substrates activates the ER stress response.

Published

2018

3. Decreased K13 Abundance Reduces Hemoglobin Catabolism and Proteotoxic Stress, Underpinning Artemisinin Resistance

Author

Tuo Yang, Lee M. Yeoh, Madel V. Tutor, Matthew W. Dixon, Paul J. McMillan, Stanley C. Xie, Jessica L. Bridgford, David L. Gillett, Michael F. Duffy, Stuart A. Ralph, Malcolm J. McConville, Leann Tilley, and Simon A. Cobbold

Subjects

Biology (General), QH301-705.5

Abstract

Summary: Increased tolerance of Plasmodium falciparum to front-line artemisinin antimalarials (ARTs) is associated with mutations in Kelch13 (K13), although the precise role of K13 remains unclear. Here, we show that K13 mutations result in decreased expression of this protein, while mislocalization of K13 mimics resistance-conferring mutations, pinpointing partial loss of function of K13 as the relevant molecular event. K13-GFP is associated with ∼170 nm diameter doughnut-shaped structures at the parasite periphery, consistent with the location and dimensions of cytostomes. Moreover, the hemoglobin-peptide profile of ring-stage parasites is reduced when K13 is mislocalized. We developed a pulse-SILAC approach to quantify protein turnover and observe less disruption to protein turnover following ART exposure when K13 is mislocalized. Our findings suggest that K13 regulates digestive vacuole biogenesis and the uptake/degradation of hemoglobin and that ART resistance is mediated by a decrease in heme-dependent drug activation, less proteotoxicity, and increased survival of parasite ring stages. : Artemisinin resistance in P. falciparum is associated with Kelch13 (K13) mutations. Yang et al. report that K13 is located in cytostome-like structures, consistent with a role in hemoglobin uptake. K13 is less abundant in mutants, and hemoglobin catabolism is impaired. The resultant decrease in artemisinin activation likely underpins artemisinin resistance. Keywords: malaria, artemisinin, antimalarial, kelch13, proteomics, SILAC, protein turnover, cytostome

Published

2019

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

Author

Stanley C. Xie, Riley D. Metcalfe, Elyse Dunn, Craig J. Morton, Shih-Chung Huang, Tanya Puhalovich, Yawei Du, Sergio Wittlin, Shuai Nie, Madeline R. Luth, Liting Ma, Mi-Sook Kim, Charisse Flerida A. Pasaje, Krittikorn Kumpornsin, Carlo Giannangelo, Fiona J. Houghton, Alisje Churchyard, Mufuliat T. Famodimu, Daniel C. Barry, David L. Gillett, Sumanta Dey, Clara C. Kosasih, William Newman, Jacquin C. Niles, Marcus C. S. Lee, Jake Baum, Sabine Ottilie, Elizabeth A. Winzeler, Darren J. Creek, Nicholas Williamson, Michael W. Parker, Stephen Brand, Steven P. Langston, Lawrence R. Dick, Michael D.W. Griffin, Alexandra E. Gould, and Leann Tilley

Subjects

Adenosine, Multidisciplinary, Protein Conformation, Plasmodium falciparum, Protozoan Proteins, Crystallography, X-Ray, Antimalarials, Mice, Tyrosine-tRNA Ligase, Protein Biosynthesis, Animals, Humans, Molecular Targeted Therapy, Malaria, Falciparum, Sulfonic Acids

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 ( Pf YRS). 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

5. A nitrite-oxidising bacterium constitutively consumes atmospheric hydrogen

Author

Pok Man Leung, Anne Daebeler, Eleonora Chiri, Iresha Hanchapola, David L. Gillett, Ralf B. Schittenhelm, Holger Daims, and Chris Greening

Subjects

Proteomics, Bacteria, Ammonia, Microbiology, Nitrification, Oxidation-Reduction, Ecology, Evolution, Behavior and Systematics, Nitrites, Hydrogen

Abstract

Chemolithoautotrophic nitrite-oxidising bacteria (NOB) of the genus Nitrospira contribute to nitrification in diverse natural environments and engineered systems. Nitrospira are thought to be well-adapted to substrate limitation owing to their high affinity for nitrite and capacity to use alternative energy sources. Here, we demonstrate that the canonical nitrite oxidiser Nitrospira moscoviensis oxidises hydrogen (H2) below atmospheric levels using a high-affinity group 2a nickel-iron hydrogenase [Km(app) = 32 nM]. Atmospheric H2 oxidation occurred under both nitrite-replete and nitrite-deplete conditions, suggesting low-potential electrons derived from H2 oxidation promote nitrite-dependent growth and enable survival during nitrite limitation. Proteomic analyses confirmed the hydrogenase was abundant under both conditions and indicated extensive metabolic changes occur to reduce energy expenditure and growth under nitrite-deplete conditions. Thermodynamic modelling revealed that H2 oxidation theoretically generates higher power yield than nitrite oxidation at low substrate concentrations and significantly contributes to growth at elevated nitrite concentrations. Collectively, this study suggests atmospheric H2 oxidation enhances the growth and survival of NOB amid variability of nitrite supply, extends the phenomenon of atmospheric H2 oxidation to an eighth phylum (Nitrospirota), and reveals unexpected new links between the global hydrogen and nitrogen cycles. Long classified as obligate nitrite oxidisers, our findings suggest H2 may primarily support growth and survival of certain NOB in natural environments.

Published

2021

6. Design of proteasome inhibitors with oral efficacy in vivo against

Author

Stanley C, Xie, Riley D, Metcalfe, Hirotake, Mizutani, Tanya, Puhalovich, Eric, Hanssen, Craig J, Morton, Yawei, Du, Con, Dogovski, Shih-Chung, Huang, Jeffrey, Ciavarri, Paul, Hales, Robert J, Griffin, Lawrence H, Cohen, Bei-Ching, Chuang, Sergio, Wittlin, Ioanna, Deni, Tomas, Yeo, Kurt E, Ward, Daniel C, Barry, Boyin, Liu, David L, Gillett, Benigno F, Crespo-Fernandez, Sabine, Ottilie, Nimisha, Mittal, Alisje, Churchyard, Daniel, Ferguson, Anna Caroline C, Aguiar, Rafael V C, Guido, Jake, Baum, Kirsten K, Hanson, Elizabeth A, Winzeler, Francisco-Javier, Gamo, David A, Fidock, Delphine, Baud, Michael W, Parker, Stephen, Brand, Lawrence R, Dick, Michael D W, Griffin, Alexandra E, Gould, and Leann, Tilley

Subjects

Boron Compounds, Models, Molecular, Proteasome Endopeptidase Complex, Plasmodium, Plasmodium falciparum, Administration, Oral, Mice, SCID, Biological Sciences, Biochemistry, Mice, proteasome, Mice, Inbred NOD, Catalytic Domain, parasitic diseases, Animals, Humans, cryo-EM, Malaria, Falciparum, Proteasome Inhibitors, peptide boronate, antimalarial drug

Abstract

Significance Here, we describe inhibitors of the Plasmodium proteasome, an enzymatic complex that malaria parasites rely on to degrade proteins. Starting from inhibitors developed to treat cancer, derivatives were designed and synthesized with the aim of increasing potency against the Plasmodium proteasome and decreasing activity against the human enzyme. Biochemical and cellular assays identified compounds that exhibit selectivity and potency, both in vitro and in vivo, at different stages of the parasite’s lifecycle. Cryo-electron microscopy revealed that the inhibitors bind in a hydrophobic pocket that is structurally different in the human proteasome—underpinning their selectivity. The work will help develop antimalarial therapeutics, which are desperately needed to treat a disease that kills nearly half a million people annually., The Plasmodium falciparum proteasome is a potential antimalarial drug target. We have identified a series of amino-amide boronates that are potent and specific inhibitors of the P. falciparum 20S proteasome (Pf20S) β5 active site and that exhibit fast-acting antimalarial activity. They selectively inhibit the growth of P. falciparum compared with a human cell line and exhibit high potency against field isolates of P. falciparum and Plasmodium vivax. They have a low propensity for development of resistance and possess liver stage and transmission-blocking activity. Exemplar compounds, MPI-5 and MPI-13, show potent activity against P. falciparum infections in a SCID mouse model with an oral dosing regimen that is well tolerated. We show that MPI-5 binds more strongly to Pf20S than to human constitutive 20S (Hs20Sc). Comparison of the cryo-electron microscopy (EM) structures of Pf20S and Hs20Sc in complex with MPI-5 and Pf20S in complex with the clinically used anti-cancer agent, bortezomib, reveal differences in binding modes that help to explain the selectivity. Together, this work provides insights into the 20S proteasome in P. falciparum, underpinning the design of potent and selective antimalarial proteasome inhibitors.

Published

2021

7. The structure of the PA28–20S proteasome complex from Plasmodium falciparum and implications for proteostasis

Author

Andrew Leis, Michael D. W. Griffin, Tuo Yang, David L. Gillett, Lawrence R. Dick, Michael J. Kuiper, Natalie J. Spillman, Christopher Tsu, Wilson Wong, Michael W. Parker, Craig J. Morton, Stanley C. Xie, Eric Hanssen, Riley D. Metcalfe, and Leann Tilley

Subjects

Models, Molecular, Microbiology (medical), Proteasome Endopeptidase Complex, Protein Conformation, Cryo-electron microscopy, Plasmodium falciparum, Immunology, Protozoan Proteins, Regulator, Plasma protein binding, Molecular Dynamics Simulation, Crystallography, X-Ray, Applied Microbiology and Biotechnology, Microbiology, 03 medical and health sciences, Protein structure, X-Ray Diffraction, Scattering, Small Angle, Genetics, 030304 developmental biology, 0303 health sciences, biology, 030306 microbiology, Chemistry, Cryoelectron Microscopy, Cell Biology, biology.organism_classification, Artemisinins, Proteostasis, Proteasome, Structural biology, Biophysics, Protein Multimerization

Abstract

The activity of the proteasome 20S catalytic core is regulated by protein complexes that bind to one or both ends. The PA28 regulator stimulates 20S proteasome peptidase activity in vitro, but its role in vivo remains unclear. Here, we show that genetic deletion of the PA28 regulator from Plasmodium falciparum (Pf) renders malaria parasites more sensitive to the antimalarial drug dihydroartemisinin, indicating that PA28 may play a role in protection against proteotoxic stress. The crystal structure of PfPA28 reveals a bell-shaped molecule with an inner pore that has a strong segregation of charges. Small-angle X-ray scattering shows that disordered loops, which are not resolved in the crystal structure, extend from the PfPA28 heptamer and surround the pore. Using single particle cryo-electron microscopy, we solved the structure of Pf20S in complex with one and two regulatory PfPA28 caps at resolutions of 3.9 and 3.8 A, respectively. PfPA28 binds Pf20S asymmetrically, strongly engaging subunits on only one side of the core. PfPA28 undergoes rigid body motions relative to Pf20S. Molecular dynamics simulations support conformational flexibility and a leaky interface. We propose lateral transfer of short peptides through the dynamic interface as a mechanism facilitating the release of proteasome degradation products. Small-angle X-ray scattering and crystal structures of the PA28 proteasome regulator from Plasmodium falciparum, combined with cryo-electron microscopy structures of the 20S proteasome in complex with these regulatory PA28 proteins and molecular dynamics simulations, elucidate the regulatory mechanisms of parasite proteasome degradation.

Published

2019

8. High Throughput Screening to Identify Selective and Nonpeptidomimetic Proteasome Inhibitors As Antimalarials

Author

Raquel Vida Fernández, Maria G. Gomez-Lorenzo, Stanley C. Xie, Francisco-Javier Gamo, Esther Fernández, David L. Gillett, Joanne Coyle, Alvaro Cortes Cabrera, Mercedes García, Benigno Crespo, Leann Tilley, and Lydia Mata-Cantero

Subjects

0301 basic medicine, High-throughput screening, 030106 microbiology, Plasmodium falciparum, 03 medical and health sciences, chemistry.chemical_compound, Antimalarials, parasitic diseases, High-Throughput Screening Assays, medicine, Humans, Malaria, Falciparum, Caspase, biology, Chemistry, biology.organism_classification, Trypsin, 030104 developmental biology, Infectious Diseases, Biochemistry, Proteasome, biology.protein, Growth inhibition, Proteasome Inhibitors, Function (biology), medicine.drug

Abstract

The Ubiquitin Proteasome System is the main proteolytic pathway in eukaryotic cells, playing a role in key cellular processes. The essentiality of the Plasmodium falciparum proteasome is well validated, underlying its potential as an antimalarial target, but selective compounds are required to avoid cytotoxic effects in humans. Almost 550000 compounds were tested for the inhibition of the chymotrypsin-like activity of the P. falciparum proteasome using a Proteasome-GLO luminescence assay. Hits were confirmed in an orthogonal enzyme assay using Rho110-labeled peptides, and selectivity was assessed against the human proteasome. Four nonpeptidomimetic chemical families with some selectivity for the P. falciparum proteasome were identified and characterized in assays of proteasome trypsin and caspase activities and in parasite growth inhibition assays. Target engagement studies were performed, validating our approach. Hits identified are good starting points for the development of new antimalarial drugs and as tools to better understand proteasome function in P. falciparum.

Published

2021

9. Design of proteasome inhibitors with oral efficacy in vivo against Plasmodium falciparum and selectivity over the human proteasome

Author

Benigno F. Crespo-Fernandez, Eric Hanssen, Elizabeth A. Winzeler, Ioanna Deni, Lawrence Cohen, Du Yawei, Daniel C. Barry, Leann Tilley, Riley D. Metcalfe, David L. Gillett, Kurt E. Ward, Bei-Ching Chuang, Hirotake Mizutani, Lawrence R. Dick, Anna Caroline Campos Aguiar, David A. Fidock, Kirsten K. Hanson, Boyin Liu, Alexandra E. Gould, Stanley C. Xie, Rafael Victorio Carvalho Guido, Francisco-Javier Gamo, Tanya Puhalovich, Shih-Chung Huang, Daniel Ferguson, Paul Hales, Con Dogovski, Sabine Ottilie, Nimisha Mittal, Craig J. Morton, Sergio Wittlin, Robert J. Griffin, Delphine Baud, Tomas Yeo, Michael D. W. Griffin, Jake Baum, Stephen Brand, Alisje Churchyard, Jeffrey Ciavarri, and Michael W. Parker

Subjects

0303 health sciences, Multidisciplinary, biology, 010405 organic chemistry, Chemistry, Bortezomib, Plasmodium vivax, Active site, Plasmodium falciparum, QUÍMICA MÉDICA, Pharmacology, biology.organism_classification, 01 natural sciences, 3. Good health, 0104 chemical sciences, 03 medical and health sciences, Proteasome, In vivo, parasitic diseases, biology.protein, medicine, Potency, Selectivity, 030304 developmental biology, medicine.drug

Abstract

The Plasmodium falciparum proteasome is a potential antimalarial drug target. We have identified a series of amino-amide boronates that are potent and specific inhibitors of the P. falciparum 20S proteasome (Pf20S) beta5 active site and that exhibit fast-acting antimalarial activity. They selectively inhibit the growth of P. falciparum compared with a human cell line and exhibit high potency against field isolates of P. falciparum and Plasmodium vivax They have a low propensity for development of resistance and possess liver stage and transmission-blocking activity. Exemplar compounds, MPI-5 and MPI-13, show potent activity against P. falciparum infections in a SCID mouse model with an oral dosing regimen that is well tolerated. We show that MPI-5 binds more strongly to Pf20S than to human constitutive 20S (Hs20Sc). Comparison of the cryo-electron microscopy (EM) structures of Pf20S and Hs20Sc in complex with MPI-5 and Pf20S in complex with the clinically used anti-cancer agent, bortezomib, reveal differences in binding modes that help to explain the selectivity. Together, this work provides insights into the 20S proteasome in P. falciparum, underpinning the design of potent and selective antimalarial proteasome inhibitors.

Published

2021

10. Cellular and Structural Basis of Synthesis of the Unique Intermediate Dehydro-F420-0 in Mycobacteria

Author

Blair Ney, Christopher K. Barlow, Rajini Brammananth, Ross L. Coppel, Paul K. Crellin, Matthew C. Taylor, David L. Gillett, Gregory M. Cook, Colin J. Jackson, Ralf B. Schittenhelm, Liam K. Harold, Max J. Cryle, Rhys Grinter, Andrew C. Warden, John G. Oakeshott, Thierry Izoré, George Taiaroa, Paul R. F. Cordero, Deborah A Williamson, and Chris Greening

Subjects

Molecular Biology and Physiology, Physiology, Mycobacterium smegmatis, lcsh:QR1-502, F420, 010402 general chemistry, Biochemistry, Microbiology, 01 natural sciences, lcsh:Microbiology, Cofactor, Mycobacterium, 03 medical and health sciences, chemistry.chemical_compound, Biosynthesis, Genetics, structural biology, Molecular Biology, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, biology, 030306 microbiology, cofactor biosynthesis, Prodrug, biology.organism_classification, QR1-502, Computer Science Applications, 0104 chemical sciences, 3. Good health, Enzyme, Structural biology, chemistry, deazaflavin, Modeling and Simulation, Pretomanid, biology.protein, Phosphoenolpyruvate carboxykinase, Bacteria, Research Article

Abstract

Mycobacteria are major environmental microorganisms and cause many significant diseases, including tuberculosis. Mycobacteria make an unusual vitamin-like compound, F420, and use it to both persist during stress and resist antibiotic treatment. Understanding how mycobacteria make F420 is important, as this process can be targeted to create new drugs to combat infections like tuberculosis. In this study, we show that mycobacteria make F420 in a way that is different from other bacteria. We studied the molecular machinery that mycobacteria use to make F420, determining the chemical mechanism for this process and identifying a novel chemical intermediate. These findings also have clinical relevance, given that two new prodrugs for tuberculosis treatment are activated by F420., F420 is a low-potential redox cofactor used by diverse bacteria and archaea. In mycobacteria, this cofactor has multiple roles, including adaptation to redox stress, cell wall biosynthesis, and activation of the clinical antitubercular prodrugs pretomanid and delamanid. A recent biochemical study proposed a revised biosynthesis pathway for F420 in mycobacteria; it was suggested that phosphoenolpyruvate served as a metabolic precursor for this pathway, rather than 2-phospholactate as long proposed, but these findings were subsequently challenged. In this work, we combined metabolomic, genetic, and structural analyses to resolve these discrepancies and determine the basis of F420 biosynthesis in mycobacterial cells. We show that, in whole cells of Mycobacterium smegmatis, phosphoenolpyruvate rather than 2-phospholactate stimulates F420 biosynthesis. Analysis of F420 biosynthesis intermediates present in M. smegmatis cells harboring genetic deletions at each step of the biosynthetic pathway confirmed that phosphoenolpyruvate is then used to produce the novel precursor compound dehydro-F420-0. To determine the structural basis of dehydro-F420-0 production, we solved high-resolution crystal structures of the enzyme responsible (FbiA) in apo-, substrate-, and product-bound forms. These data show the essential role of a single divalent cation in coordinating the catalytic precomplex of this enzyme and demonstrate that dehydro-F420-0 synthesis occurs through a direct substrate transfer mechanism. Together, these findings resolve the biosynthetic pathway of F420 in mycobacteria and have significant implications for understanding the emergence of antitubercular prodrug resistance. IMPORTANCE Mycobacteria are major environmental microorganisms and cause many significant diseases, including tuberculosis. Mycobacteria make an unusual vitamin-like compound, F420, and use it to both persist during stress and resist antibiotic treatment. Understanding how mycobacteria make F420 is important, as this process can be targeted to create new drugs to combat infections like tuberculosis. In this study, we show that mycobacteria make F420 in a way that is different from other bacteria. We studied the molecular machinery that mycobacteria use to make F420, determining the chemical mechanism for this process and identifying a novel chemical intermediate. These findings also have clinical relevance, given that two new prodrugs for tuberculosis treatment are activated by F420.

Published

2020

11. Artemisinin kills malaria parasites by damaging proteins and inhibiting the proteasome

Author

Stuart A. Ralph, Leann Tilley, Simon A. Cobbold, Tuo Yang, Susann Herrmann, Natalie J. Spillman, Stanley C. Xie, Charisse Flerida A. Pasaje, Lawrence R. Dick, Jessica L. Bridgford, Con Dogovski, and David L. Gillett

Subjects

0301 basic medicine, medicine.medical_treatment, Science, 030106 microbiology, General Physics and Astronomy, Dihydroartemisinin, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, medicine, Protein biosynthesis, Artemisinin, lcsh:Science, Multidisciplinary, biology, Kinase, Plasmodium falciparum, Translation (biology), General Chemistry, biology.organism_classification, Cell biology, 030104 developmental biology, Proteasome, Mechanism of action, lcsh:Q, medicine.symptom, medicine.drug

Abstract

Artemisinin and its derivatives (collectively referred to as ARTs) rapidly reduce the parasite burden in Plasmodium falciparum infections, and antimalarial control is highly dependent on ART combination therapies (ACTs). Decreased sensitivity to ARTs is emerging, making it critically important to understand the mechanism of action of ARTs. Here we demonstrate that dihydroartemisinin (DHA), the clinically relevant ART, kills parasites via a two-pronged mechanism, causing protein damage, and compromising parasite proteasome function. The consequent accumulation of proteasome substrates, i.e., unfolded/damaged and polyubiquitinated proteins, activates the ER stress response and underpins DHA-mediated killing. Specific inhibitors of the proteasome cause a similar build-up of polyubiquitinated proteins, leading to parasite killing. Blocking protein synthesis with a translation inhibitor or inhibiting the ubiquitin-activating enzyme, E1, reduces the level of damaged, polyubiquitinated proteins, alleviates the stress response, and dramatically antagonizes DHA activity.

Published

2018

12. Decreased K13 Abundance Reduces Hemoglobin Catabolism and Proteotoxic Stress, Underpinning Artemisinin Resistance

Author

Malcolm J. McConville, Madel V Tutor, Matthew W. A. Dixon, Paul J. McMillan, Stuart A. Ralph, Stanley C. Xie, Lee M. Yeoh, David L. Gillett, Tuo Yang, Jessica L. Bridgford, Leann Tilley, Michael F. Duffy, and Simon A. Cobbold

Subjects

0301 basic medicine, medicine.medical_treatment, Cell, Plasmodium falciparum, Dihydroartemisinin, medicine.disease_cause, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Hemoglobins, 0302 clinical medicine, parasitic diseases, medicine, Humans, Artemisinin, Malaria, Falciparum, lcsh:QH301-705.5, Mutation, biology, Protein turnover, biology.organism_classification, Artemisinins, Cell biology, 030104 developmental biology, medicine.anatomical_structure, Proteotoxicity, lcsh:Biology (General), Hemoglobin, 030217 neurology & neurosurgery, medicine.drug

Abstract

Summary: Increased tolerance of Plasmodium falciparum to front-line artemisinin antimalarials (ARTs) is associated with mutations in Kelch13 (K13), although the precise role of K13 remains unclear. Here, we show that K13 mutations result in decreased expression of this protein, while mislocalization of K13 mimics resistance-conferring mutations, pinpointing partial loss of function of K13 as the relevant molecular event. K13-GFP is associated with ∼170 nm diameter doughnut-shaped structures at the parasite periphery, consistent with the location and dimensions of cytostomes. Moreover, the hemoglobin-peptide profile of ring-stage parasites is reduced when K13 is mislocalized. We developed a pulse-SILAC approach to quantify protein turnover and observe less disruption to protein turnover following ART exposure when K13 is mislocalized. Our findings suggest that K13 regulates digestive vacuole biogenesis and the uptake/degradation of hemoglobin and that ART resistance is mediated by a decrease in heme-dependent drug activation, less proteotoxicity, and increased survival of parasite ring stages. : Artemisinin resistance in P. falciparum is associated with Kelch13 (K13) mutations. Yang et al. report that K13 is located in cytostome-like structures, consistent with a role in hemoglobin uptake. K13 is less abundant in mutants, and hemoglobin catabolism is impaired. The resultant decrease in artemisinin activation likely underpins artemisinin resistance. Keywords: malaria, artemisinin, antimalarial, kelch13, proteomics, SILAC, protein turnover, cytostome

Published

2019

13. Target Validation and Identification of Novel Boronate Inhibitors of the Plasmodium falciparum Proteasome

Author

Stanley C, Xie, David L, Gillett, Natalie J, Spillman, Christopher, Tsu, Madeline R, Luth, Sabine, Ottilie, Sandra, Duffy, Alexandra E, Gould, Paul, Hales, Benjamin A, Seager, Carlie L, Charron, Frank, Bruzzese, Xiaofeng, Yang, Xiansi, Zhao, Shih-Chung, Huang, Craig A, Hutton, Jeremy N, Burrows, Elizabeth A, Winzeler, Vicky M, Avery, Lawrence R, Dick, and Leann, Tilley

Subjects

Models, Molecular, Proteasome Endopeptidase Complex, Plasmodium falciparum, Drug Evaluation, Preclinical, Drug Resistance, Boronic Acids, Article, Cell Line, Catalytic Domain, Drug Design, parasitic diseases, Animals, Humans, Amino Acid Sequence, Proteasome Inhibitors

Abstract

The Plasmodium proteasome represents a potential antimalarial drug target for compounds with activity against multiple life cycle stages. We screened a library of human proteasome inhibitors (peptidyl boronic acids) and compared activities against purified P. falciparum and human 20S proteasomes. We chose four hits that potently inhibit parasite growth and show a range of selectivities for inhibition of the growth of P. falciparum compared with human cell lines. P. falciparum was selected for resistance in vitro to the clinically used proteasome inhibitor, bortezomib, and whole genome sequencing was applied to identify mutations in the proteasome β5 subunit. Active site profiling revealed inhibitor features that enable retention of potent activity against the bortezomib-resistant line. Substrate profiling reveals P. falciparum 20S proteasome active site preferences that will inform attempts to design more selective inhibitors. This work provides a starting point for the identification of antimalarial drug leads that selectively target the P. falciparum proteasome.

Published

2018

14. Structure and Function of the Proteasome Activator PA28 of the Malaria Parasite Plasmodium falciparum

Author

Michael D. W. Griffin, Eric Hanssen, Craig J. Morton, Andrew Leis, Stanley C. Xie, David L. Gillett, Wilson Wong, Michael W. Parker, Riley Metcalf, and Leann Tilley

Subjects

Proteasome, Activator (genetics), medicine, Parasite hosting, Plasmodium falciparum, Biology, medicine.disease, biology.organism_classification, Instrumentation, Virology, Malaria, Structure and function

Published

2019

15. The structure of the Plasmodium falciparum 20S proteasome in complex with the PA28 activator

Author

Michael D. W. Griffin, Eric Hanssen, T. Yang, Andrew Leis, Riley D. Metcalfe, Michael J. Kuiper, David L. Gillett, C. Tsu, Craig J. Morton, Michael W. Parker, L.R. Dick, Natalie J. Spillman, Wilson Wong, Leann Tilley, and S.C. Xie

Subjects

Inorganic Chemistry, biology, Structural Biology, Chemistry, Activator (genetics), General Materials Science, Plasmodium falciparum, Physical and Theoretical Chemistry, Condensed Matter Physics, biology.organism_classification, Biochemistry, 20s proteasome, Cell biology

Published

2019