Your search keyword '"Michael J. Boucher"' showing total 5 results

1. The antimalarial natural product salinipostin A identifies essential α/β serine hydrolases involved in lipid metabolism in P. falciparum parasites

Author

Nina F. Gnädig, Jonathan Z. Long, Yani Zhou, Ouma Onguka, Eranthie Weerapana, David A. Fidock, Barbara H. Stokes, Sachel Mok, Anne-Catrin Uhlemann, Stephanie M. Terrell, Kenji L. Kurita, Piotr Cieplak, Christopher J. Schulze, Tomas Yeo, Roger G. Linington, Ian T. Foe, Matthew Bogyo, Michael J. Boucher, and Euna Yoo

Subjects

0303 health sciences, Natural product, biology, 010405 organic chemistry, Serine hydrolase, Lipid metabolism, Plasmodium falciparum, Drug resistance, biology.organism_classification, 01 natural sciences, 0104 chemical sciences, 3. Good health, Serine, Monoacylglycerol lipase, 03 medical and health sciences, chemistry.chemical_compound, chemistry, Mechanism of action, Biochemistry, parasitic diseases, medicine, medicine.symptom, 030304 developmental biology

Abstract

SUMMARYSalinipostin A (Sal A) is a potent antimalarial marine natural product with an undefined mechanism of action. Using a Sal A-derived activity-based probe, we identify its targets in thePlasmodium falciparumparasite. All of the identified proteins contain α/β serine hydrolase domains, and several are essential for parasite growth. One of the essential targets displays high homology to human monoacylglycerol lipase (MAGL) and is able to process lipid esters including a MAGL acylglyceride substrate. This Sal A target is inhibited by the anti-obesity drug Orlistat, which disrupts lipid metabolism and produces disorganized and stalled schizonts similar to Sal A. Resistance selections yielded parasites that showed only minor reductions in sensitivity and that acquired mutations in a protein linked to drug resistance inToxoplasma gondii. This inability to evolve efficient resistance mechanisms combined with the non-essentiality of human homologs makes the serine hydrolases identified here promising antimalarial targets.

Published

2019

2. The Antimalarial Natural Product Salinipostin a Identifies Essential α/β Serine Hydrolases Involved in Lipid Metabolism in P. Falciparum Parasites

Author

Eranthie Weerapana, Nina F. Gnädig, Barbara H. Stokes, Ian T. Foe, Kenji L. Kurita, Roger G. Linington, Anne-Catrin Uhlemann, Matthew Bogyo, Michael J. Boucher, Jonathan Z. Long, Piotr Cieplak, David A. Fidock, Ouma Onguka, Euna Yoo, Tomas Yeo, Yani Zhou, Christopher J. Schulze, Sachel Mok, and Stephanie M. Terrell

Subjects

050208 finance, Natural product, biology, 05 social sciences, Serine hydrolase, Lipid metabolism, Plasmodium falciparum, Drug resistance, biology.organism_classification, 3. Good health, Serine, Monoacylglycerol lipase, chemistry.chemical_compound, Mechanism of action, Biochemistry, chemistry, parasitic diseases, 0502 economics and business, medicine, 050207 economics, medicine.symptom

Abstract

Salinipostin A (Sal A) is a potent antimalarial marine natural product with an undefined mechanism of action. Using a Sal A-derived activity-based probe, we identify its targets in the Plasmodium falciparum parasite. All of the identified proteins contain α/β serine hydrolase domains and several are essential for parasite growth. One of the essential targets displays high homology to human monoacylglycerol lipase (MAGL) and is able to process lipid esters including a MAGL acylglyceride substrate. This Sal A target is inhibited by the anti-obesity drug Orlistat, which disrupts lipid metabolism and produces disorganized and stalled schizonts similar to Sal A. Resistance selections yielded parasites that showed only minor reductions in sensitivity and that acquired mutations in a protein linked to drug resistance in Toxoplasma gondii. This inability to evolve efficient resistance mechanisms combined with the non-essentiality of human homologs makes the serine hydrolases identified here promising antimalarial targets.

Published

2019

3. Disruption of Apicoplast Biogenesis by Chemical Stabilization of an Imported Protein Evades the Delayed-Death Phenotype in Malaria Parasites

Author

Ellen Yeh and Michael J. Boucher

Subjects

organelle protein import, Molecular Biology and Physiology, Plasmodium, Recombinant Fusion Proteins, Plasmodium falciparum, Druggability, lcsh:QR1-502, malaria, Protozoan Proteins, Biology, Apicoplasts, Microbiology, lcsh:Microbiology, 03 medical and health sciences, Antimalarials, Mice, Animals, Plastid, Molecular Biology, 030304 developmental biology, 0303 health sciences, Apicoplast, apicoplast, Organelle Biogenesis, 030306 microbiology, Drug discovery, Triazines, biology.organism_classification, Fusion protein, QR1-502, 3. Good health, Cell biology, Protein Transport, Tetrahydrofolate Dehydrogenase, Lytic cycle, Biogenesis, Research Article

Abstract

Malaria is a major cause of global childhood mortality. To sustain progress in disease control made in the last decade, new antimalarial therapies are needed to combat emerging drug resistance. Malaria parasites contain a relict chloroplast called the apicoplast, which harbors new targets for drug discovery. Unfortunately, some drugs targeting apicoplast pathways exhibit a delayed-death phenotype, which results in a slow onset-of-action that precludes their use as fast-acting, frontline therapies. Identification of druggable apicoplast biogenesis factors that will avoid the delayed-death phenotype is an important priority. Here, we find that chemical stabilization of an apicoplast-targeted mDHFR domain disrupts apicoplast biogenesis and inhibits parasite growth after a single lytic cycle, suggesting a non-delayed-death target. Our finding indicates that further interrogation of the mechanism-of-action of this exogenous fusion protein may reveal novel therapeutic avenues., Malaria parasites (Plasmodium spp.) contain a nonphotosynthetic plastid organelle called the apicoplast, which houses essential metabolic pathways and is required throughout the parasite life cycle. The biogenesis pathways responsible for apicoplast growth, division, and inheritance are of key interest as potential drug targets. Unfortunately, several known apicoplast biogenesis inhibitors are of limited clinical utility because they cause a peculiar “delayed-death” phenotype in which parasites do not stop replicating until the second lytic cycle posttreatment. Identifying apicoplast biogenesis pathways that avoid the delayed-death phenomenon is a priority. Here, we generated parasites targeting a murine dihydrofolate reductase (mDHFR) domain, which can be conditionally stabilized with the compound WR99210, to the apicoplast. Surprisingly, chemical stabilization of this exogenous fusion protein disrupted parasite growth in an apicoplast-specific manner after a single lytic cycle. WR99210-treated parasites exhibited an apicoplast biogenesis defect beginning within the same lytic cycle as drug treatment, indicating that stabilized mDHFR perturbs a non-delayed-death biogenesis pathway. While the precise mechanism-of-action of the stabilized fusion is still unclear, we hypothesize that it inhibits apicoplast protein import by stalling within and blocking translocons in the apicoplast membranes. IMPORTANCE Malaria is a major cause of global childhood mortality. To sustain progress in disease control made in the last decade, new antimalarial therapies are needed to combat emerging drug resistance. Malaria parasites contain a relict chloroplast called the apicoplast, which harbors new targets for drug discovery. Unfortunately, some drugs targeting apicoplast pathways exhibit a delayed-death phenotype, which results in a slow onset-of-action that precludes their use as fast-acting, frontline therapies. Identification of druggable apicoplast biogenesis factors that will avoid the delayed-death phenotype is an important priority. Here, we find that chemical stabilization of an apicoplast-targeted mDHFR domain disrupts apicoplast biogenesis and inhibits parasite growth after a single lytic cycle, suggesting a non-delayed-death target. Our finding indicates that further interrogation of the mechanism-of-action of this exogenous fusion protein may reveal novel therapeutic avenues.

Published

2019

4. Evidence that disruption of apicoplast protein import in malaria parasites evades delayed-death growth inhibition

Author

Ellen Yeh and Michael J. Boucher

Subjects

0303 health sciences, Apicoplast, biology, 030306 microbiology, biology.organism_classification, Fusion protein, Plasmodium, 3. Good health, Cell biology, 03 medical and health sciences, chemistry.chemical_compound, Lytic cycle, chemistry, Transit Peptide, Growth inhibition, Plastid, Biogenesis, 030304 developmental biology

Abstract

Malaria parasites (Plasmodium spp.) contain a nonphotosynthetic plastid organelle called the apicoplast, which houses essential metabolic pathways and is required throughout the parasite life cycle. Hundreds of proteins are imported across 4 membranes into the apicoplast to support its function and biogenesis. The machinery that mediates this import process is distinct from proteins in the human host and may serve as ideal drug targets. However, a significant concern is whether inhibition of apicoplast protein import will result in a “delayed-death” phenotype that limits clinical use, as observed for inhibitors of apicoplast housekeeping pathways. To assess the growth inhibition kinetics of disrupting apicoplast protein import, we targeted a murine dihydrofolate reductase (mDHFR) domain, which is stabilized by the compound WR99210, to the apicoplast to enable inducible blocking of apicoplast-localized protein translocons. We show that stabilization of this apicoplast-targeted mDHFR disrupts parasite growth within a single lytic cycle in an apicoplast-specific manner. Consistent with inhibition of apicoplast protein import, stabilization of this fusion protein disrupted transit peptide processing of endogenous apicoplast proteins and caused defects in apicoplast biogenesis. These results indicate that disruption of apicoplast protein import avoids delayed-death growth inhibition and that target-based approaches to develop inhibitors of import machinery may yield viable next-generation antimalarials.ImportanceMalaria is a major cause of global childhood mortality. To sustain progress in disease control made in the last decade, new antimalarial therapies are needed to combat emerging drug resistance. Malaria parasites contain a relict chloroplast called the apicoplast, which harbors new targets for drug discovery, including import machinery that transports hundreds of critical proteins into the apicoplast. Unfortunately, some drugs targeting apicoplast pathways show delayed growth inhibition, which results in a slow onset-of-action that precludes their use as fast-acting, frontline therapies. We used a chemical biology approach to disrupt apicoplast protein import and showed that chemical disruption of this pathway avoids delayed growth inhibition. Our finding indicates that prioritization of proteins involved in apicoplast protein import for target-based drug discovery efforts may aid in the development of novel fast-acting antimalarials.

Published

2018

5. Integrative proteomics and bioinformatic prediction enable a high-confidence apicoplast proteome in malaria parasites

Author

Stuart A. Ralph, An Ju, Se Won Jang, Joshua E. Elias, Lichao Zhang, Avantika Lal, Michael J. Boucher, Shuying Zhang, Sreejoyee Ghosh, Xinzi Wang, James Zou, and Ellen Yeh

Subjects

Proteomics, B Vitamins, 0301 basic medicine, Plasmodium, Proteome, Proteomes, Cell Membranes, Protozoan Proteins, Endoplasmic Reticulum, Biochemistry, Homology (biology), Biology (General), Post-Translational Modification, Databases, Protein, Integral membrane protein, Protozoans, 0303 health sciences, Secretory Pathway, Endosymbiosis, Organic Compounds, General Neuroscience, Methods and Resources, Malarial Parasites, Eukaryota, Vitamins, 3. Good health, Chemistry, Cell Processes, Physical Sciences, Cellular Structures and Organelles, General Agricultural and Biological Sciences, Algorithms, Signal Peptides, Signal peptide, QH301-705.5, Plasmodium falciparum, Biotin, Computational biology, Apicoplasts, Biology, Green Fluorescent Protein, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Parasite Groups, Organelle, Animals, Parasites, Integral Membrane Proteins, Plastid, 030304 developmental biology, Apicoplast, General Immunology and Microbiology, 030306 microbiology, Organic Chemistry, Chemical Compounds, Organisms, Computational Biology, Biology and Life Sciences, Proteins, Membrane Proteins, Cell Biology, Parasitic Protozoans, Malaria, Luminescent Proteins, 030104 developmental biology, Parasitology, Apicomplexa, Biogenesis

Abstract

Malaria parasites (Plasmodium spp.) and related apicomplexan pathogens contain a nonphotosynthetic plastid called the apicoplast. Derived from an unusual secondary eukaryote–eukaryote endosymbiosis, the apicoplast is a fascinating organelle whose function and biogenesis rely on a complex amalgamation of bacterial and algal pathways. Because these pathways are distinct from the human host, the apicoplast is an excellent source of novel antimalarial targets. Despite its biomedical importance and evolutionary significance, the absence of a reliable apicoplast proteome has limited most studies to the handful of pathways identified by homology to bacteria or primary chloroplasts, precluding our ability to study the most novel apicoplast pathways. Here, we combine proximity biotinylation-based proteomics (BioID) and a new machine learning algorithm to generate a high-confidence apicoplast proteome consisting of 346 proteins. Critically, the high accuracy of this proteome significantly outperforms previous prediction-based methods and extends beyond other BioID studies of unique parasite compartments. Half of identified proteins have unknown function, and 77% are predicted to be important for normal blood-stage growth. We validate the apicoplast localization of a subset of novel proteins and show that an ATP-binding cassette protein ABCF1 is essential for blood-stage survival and plays a previously unknown role in apicoplast biogenesis. These findings indicate critical organellar functions for newly discovered apicoplast proteins. The apicoplast proteome will be an important resource for elucidating unique pathways derived from secondary endosymbiosis and prioritizing antimalarial drug targets., Author summary Plasmodium parasites, which cause malaria, and related pathogens belonging to the phylum Apicomplexa contain a relict chloroplast called the apicoplast. During evolution, the apicoplast lost photosynthetic functions but retained critical metabolic pathways that are required for host cell infection. Because of its importance for parasite survival and its unusual evolutionary origin, the apicoplast is of major interest for its unique biology and its potential to yield new antimalarial drug targets. However, an accurate inventory of proteins that localize to the apicoplast is lacking, hindering our ability to study the most novel and biologically interesting aspects of apicoplast biology. To address this limitation, we combine proximity biotinylation-based proteomics and a new machine learning algorithm to identify apicoplast proteins in an accurate and unbiased manner. We identify 346 candidate apicoplast proteins with high confidence and find that many of these proteins are new and expected to be important for parasite survival. This proteomic resource will therefore be a valuable tool for elucidating the unique cell biology of the apicoplast and for identifying new antimalarial drug targets.

Published

2018