Your search keyword '"Sean T. Prigge"' showing total 120 results

1. Clinically relevant atovaquone-resistant human malaria parasites fail to transmit by mosquito

Author

Victoria A. Balta, Deborah Stiffler, Abeer Sayeed, Abhai K. Tripathi, Rubayet Elahi, Godfree Mlambo, Rahul P. Bakshi, Amanda G. Dziedzic, Anne E. Jedlicka, Elizabeth Nenortas, Keyla Romero-Rodriguez, Matthew A. Canonizado, Alexis Mann, Andrew Owen, David J. Sullivan, Sean T. Prigge, Photini Sinnis, and Theresa A. Shapiro

Subjects

Science

Abstract

Abstract Long-acting injectable medications, such as atovaquone, offer the prospect of a “chemical vaccine” for malaria, combining drug efficacy with vaccine durability. However, selection and transmission of drug-resistant parasites is of concern. Laboratory studies have indicated that atovaquone resistance disadvantages parasites in mosquitoes, but lack of data on clinically relevant Plasmodium falciparum has hampered integration of these variable findings into drug development decisions. Here we generate atovaquone-resistant parasites that differ from wild type parent by only a Y268S mutation in cytochrome b, a modification associated with atovaquone treatment failure in humans. Relative to wild type, Y268S parasites evidence multiple defects, most marked in their development in mosquitoes, whether from Southeast Asia (Anopheles stephensi) or Africa (An. gambiae). Growth of asexual Y268S P. falciparum in human red cells is impaired, but parasite loss in the mosquito is progressive, from reduced gametocyte exflagellation, to smaller number and size of oocysts, and finally to absence of sporozoites. The Y268S mutant fails to transmit from mosquitoes to mice engrafted with human liver cells and erythrocytes. The severe-to-lethal fitness cost of clinically relevant atovaquone resistance to P. falciparum in the mosquito substantially lessens the likelihood of its transmission in the field.

Published

2023

2. Metabolic responses in blood-stage malaria parasites associated with increased and decreased sensitivity to PfATP4 inhibitors

Author

Shivendra G. Tewari, Rubayet Elahi, Bobby Kwan, Krithika Rajaram, Suyash Bhatnagar, Jaques Reifman, Sean T. Prigge, Akhil B. Vaidya, and Anders Wallqvist

Subjects

Drug resistance, Genome-scale metabolic network model, Metabolomics, Na+ homeostasis, Plasmodium falciparum, Transcriptomics, Arctic medicine. Tropical medicine, RC955-962, Infectious and parasitic diseases, RC109-216

Abstract

Abstract Background Spiroindolone and pyrazoleamide antimalarial compounds target Plasmodium falciparum P-type ATPase (PfATP4) and induce disruption of intracellular Na+ homeostasis. Recently, a PfATP4 mutation was discovered that confers resistance to a pyrazoleamide while increasing sensitivity to a spiroindolone. Transcriptomic and metabolic adaptations that underlie this seemingly contradictory response of P. falciparum to sublethal concentrations of each compound were examined to understand the different cellular accommodation to PfATP4 disruptions. Methods A genetically engineered P. falciparum Dd2 strain (Dd2A211V) carrying an Ala211Val (A211V) mutation in PfATP4 was used to identify metabolic adaptations associated with the mutation that results in decreased sensitivity to PA21A092 (a pyrazoleamide) and increased sensitivity to KAE609 (a spiroindolone). First, sublethal doses of PA21A092 and KAE609 causing substantial reduction (30–70%) in Dd2A211V parasite replication were identified. Then, at this sublethal dose of PA21A092 (or KAE609), metabolomic and transcriptomic data were collected during the first intraerythrocytic developmental cycle. Finally, the time-resolved data were integrated with a whole-genome metabolic network model of P. falciparum to characterize antimalarial-induced physiological adaptations. Results Sublethal treatment with PA21A092 caused significant (p

Published

2023

3. Metabolic adjustments of blood-stage Plasmodium falciparum in response to sublethal pyrazoleamide exposure

Author

Shivendra G. Tewari, Bobby Kwan, Rubayet Elahi, Krithika Rajaram, Jaques Reifman, Sean T. Prigge, Akhil B. Vaidya, and Anders Wallqvist

Subjects

Medicine, Science

Abstract

Abstract Due to the recurring loss of antimalarial drugs to resistance, there is a need for novel targets, drugs, and combination therapies to ensure the availability of current and future countermeasures. Pyrazoleamides belong to a novel class of antimalarial drugs that disrupt sodium ion homeostasis, although the exact consequences of this disruption in Plasmodium falciparum remain under investigation. In vitro experiments demonstrated that parasites carrying mutations in the metabolic enzyme PfATP4 develop resistance to pyrazoleamide compounds. However, the underlying mechanisms that allow mutant parasites to evade pyrazoleamide treatment are unclear. Here, we first performed experiments to identify the sublethal dose of a pyrazoleamide compound (PA21A092) that caused a significant reduction in growth over one intraerythrocytic developmental cycle (IDC). At this drug concentration, we collected transcriptomic and metabolomic data at multiple time points during the IDC to quantify gene- and metabolite-level alterations in the treated parasites. To probe the effects of pyrazoleamide treatment on parasite metabolism, we coupled the time-resolved omics data with a metabolic network model of P. falciparum. We found that the drug-treated parasites adjusted carbohydrate metabolism to enhance synthesis of myoinositol—a precursor for phosphatidylinositol biosynthesis. This metabolic adaptation caused a decrease in metabolite flux through the pentose phosphate pathway, causing a decreased rate of RNA synthesis and an increase in oxidative stress. Our model analyses suggest that downstream consequences of enhanced myoinositol synthesis may underlie adjustments that could lead to resistance emergence in P. falciparum exposed to a sublethal dose of a pyrazoleamide drug.

Published

2022

4. Inter-study and time-dependent variability of metabolite abundance in cultured red blood cells

Author

Shivendra G. Tewari, Krithika Rajaram, Russell P. Swift, Bobby Kwan, Jaques Reifman, Sean T. Prigge, and Anders Wallqvist

Subjects

Human red blood cells, Metabolic network modeling, Metabolism, Metabolomics, Plasmodium falciparum, Arctic medicine. Tropical medicine, RC955-962, Infectious and parasitic diseases, RC109-216

Abstract

Abstract Background Cultured human red blood cells (RBCs) provide a powerful ex vivo assay platform to study blood-stage malaria infection and propagation. In recent years, high-resolution metabolomic methods have quantified hundreds of metabolites from parasite-infected RBC cultures under a variety of perturbations. In this context, the corresponding control samples of the uninfected culture systems can also be used to examine the effects of these perturbations on RBC metabolism itself and their dependence on blood donors (inter-study variations). Methods Time-course datasets from five independent studies were generated and analysed, maintaining uninfected RBCs (uRBC) at 2% haematocrit for 48 h under conditions originally designed for parasite cultures. Using identical experimental protocols, quadruplicate samples were collected at six time points, and global metabolomics were employed on the pellet fraction of the uRBC cultures. In total, ~ 500 metabolites were examined across each dataset to quantify inter-study variability in RBC metabolism, and metabolic network modelling augmented the analyses to characterize the metabolic state and fluxes of the RBCs. Results To minimize inter-study variations unrelated to RBC metabolism, an internal standard metabolite (phosphatidylethanolamine C18:0/20:4) was identified with minimal variation in abundance over time and across all the samples of each dataset to normalize the data. Although the bulk of the normalized data showed a high degree of inter-study consistency, changes and variations in metabolite levels from individual donors were noted. Thus, a total of 24 metabolites were associated with significant variation in the 48-h culture time window, with the largest variations involving metabolites in glycolysis and synthesis of glutathione. Metabolic network analysis was used to identify the production of superoxide radicals in cultured RBCs as countered by the activity of glutathione oxidoreductase and synthesis of reducing equivalents via the pentose phosphate pathway. Peptide degradation occurred at a rate that is comparable with central carbon fluxes, consistent with active degradation of methaemoglobin, processes also commonly associated with storage lesions in RBCs. Conclusions The bulk of the data showed high inter-study consistency. The collected data, quantification of an expected abundance variation of RBC metabolites, and characterization of a subset of highly variable metabolites in the RBCs will help in identifying non-specific changes in metabolic abundances that may obscure accurate metabolomic profiling of Plasmodium falciparum and other blood-borne pathogens.

Published

2021

5. Metabolic alterations in the erythrocyte during blood-stage development of the malaria parasite

Author

Shivendra G. Tewari, Russell P. Swift, Jaques Reifman, Sean T. Prigge, and Anders Wallqvist

Subjects

Plasmodium falciparum, Host–parasite metabolism, Blood-stage infection, Metabolome, Lysophosphatidylglycerol, Polyunsaturated fatty acids, Arctic medicine. Tropical medicine, RC955-962, Infectious and parasitic diseases, RC109-216

Abstract

Abstract Background Human blood cells (erythrocytes) serve as hosts for the malaria parasite Plasmodium falciparum during its 48-h intraerythrocytic developmental cycle (IDC). Established in vitro protocols allow for the study of host–parasite interactions during this phase and, in particular, high-resolution metabolomics can provide a window into host–parasite interactions that support parasite development. Methods Uninfected and parasite-infected erythrocyte cultures were maintained at 2% haematocrit for the duration of the IDC, while parasitaemia was maintained at 7% in the infected cultures. The parasite-infected cultures were synchronized to obtain stage-dependent information of parasite development during the IDC. Samples were collected in quadruplicate at six time points from the uninfected and parasite-infected cultures and global metabolomics was used to analyse cell fractions of these cultures. Results In uninfected and parasite-infected cultures during the IDC, 501 intracellular metabolites, including 223 lipid metabolites, were successfully quantified. Of these, 19 distinct metabolites were present only in the parasite-infected culture, 10 of which increased to twofold in abundance during the IDC. This work quantified approximately five times the metabolites measured in previous studies of similar research scope, which allowed for more detailed analyses. Enrichment in lipid metabolism pathways exhibited a time-dependent association with different classes of lipids during the IDC. Specifically, enrichment occurred in sphingolipids at the earlier stages, and subsequently in lysophospholipid and phospholipid metabolites at the intermediate and end stages of the IDC, respectively. In addition, there was an accumulation of 18-, 20-, and 22-carbon polyunsaturated fatty acids, which produce eicosanoids and promote gametocytogenesis in infected erythrocyte cultures. Conclusions The current study revealed a number of heretofore unidentified metabolic components of the host–parasite system, which the parasite may exploit in a time-dependent manner to grow over the course of its development in the blood stage. Notably, the analyses identified components, such as precursors of immunomodulatory molecules, stage-dependent lipid dynamics, and metabolites, unique to parasite-infected cultures. These conclusions are reinforced by the metabolic alterations that were characterized during the IDC, which were in close agreement with those known from previous studies of blood-stage infection.

Published

2020

6. Roles of Ferredoxin-Dependent Proteins in the Apicoplast of Plasmodium falciparum Parasites

Author

Russell P. Swift, Krithika Rajaram, Rubayet Elahi, Hans B. Liu, and Sean T. Prigge

Subjects

apicoplast, iron-sulfur cluster, ferredoxin, ferredoxin reductase, Plasmodium, lipoate synthase, Microbiology, QR1-502

Abstract

ABSTRACT Ferredoxin (Fd) and ferredoxin-NADP+ reductase (FNR) form a redox system that is hypothesized to play a central role in the maintenance and function of the apicoplast organelle of malaria parasites. The Fd/FNR system provides reducing power to various iron-sulfur cluster (FeS)-dependent proteins in the apicoplast and is believed to help to maintain redox balance in the organelle. While the Fd/FNR system has been pursued as a target for antimalarial drug discovery, Fd, FNR, and the FeS proteins presumably reliant on their reducing power play an unknown role in parasite survival and apicoplast maintenance. To address these questions, we generated genetic deletions of these proteins in a parasite line containing an apicoplast bypass system. Through these deletions, we discovered that Fd, FNR, and certain FeS proteins are essential for parasite survival but found that none are required for apicoplast maintenance. Additionally, we addressed the question of how Fd and its downstream FeS proteins obtain FeS cofactors by deleting the FeS transfer proteins SufA and NfuApi. While individual deletions of these proteins revealed their dispensability, double deletion resulted in synthetic lethality, demonstrating a redundant role in providing FeS clusters to Fd and other essential FeS proteins. Our data support a model in which the reducing power from the Fd/FNR system to certain downstream FeS proteins is essential for the survival of blood-stage malaria parasites but not for organelle maintenance, while other FeS proteins are dispensable for this stage of parasite development. IMPORTANCE Ferredoxin (Fd) and ferredoxin-NADP+ reductase (FNR) form one of the few known redox systems in the apicoplast of malaria parasites and provide reducing power to iron-sulfur (FeS) cluster proteins within the organelle. While the Fd/FNR system has been explored as a drug target, the essentiality and roles of this system and the identity of its downstream FeS proteins have not been determined. To answer these questions, we generated deletions of these proteins in an apicoplast metabolic bypass line (PfMev) and determined the minimal set of proteins required for parasite survival. Moving upstream of this pathway, we also generated individual and dual deletions of the two FeS transfer proteins that deliver FeS clusters to Fd and downstream FeS proteins. We found that both transfer proteins are dispensable, but double deletion displayed a synthetic lethal phenotype, demonstrating their functional redundancy. These findings provide important insights into apicoplast biochemistry and drug development.

Published

2022

7. Short-term metabolic adjustments in Plasmodium falciparum counter hypoxanthine deprivation at the expense of long-term viability

Author

Shivendra G. Tewari, Krithika Rajaram, Patric Schyman, Russell Swift, Jaques Reifman, Sean T. Prigge, and Anders Wallqvist

Subjects

Purine deprivation, Plasmodium falciparum, Transcriptome, Metabolome, Metabolic network model, Gene set enrichment analysis, Arctic medicine. Tropical medicine, RC955-962, Infectious and parasitic diseases, RC109-216

Abstract

Abstract Background The malarial parasite Plasmodium falciparum is an auxotroph for purines, which are required for nucleic acid synthesis during the intra-erythrocytic developmental cycle (IDC) of the parasite. The capabilities of the parasite and extent to which it can use compensatory mechanisms to adapt to purine deprivation were studied by examining changes in its metabolism under sub-optimal concentrations of hypoxanthine, the primary precursor utilized by the parasite for purine-based nucleic acid synthesis. Methods The concentration of hypoxanthine that caused a moderate growth defect over the course of one IDC was determined. At this concentration of hypoxanthine (0.5 μM), transcriptomic and metabolomic data were collected during one IDC at multiple time points. These data were integrated with a metabolic network model of the parasite embedded in a red blood cell (RBC) to interpret the metabolic adaptation of P. falciparum to hypoxanthine deprivation. Results At a hypoxanthine concentration of 0.5 μM, vacuole-like structures in the cytosol of many P. falciparum parasites were observed after the 24-h midpoint of the IDC. Parasites grown under these conditions experienced a slowdown in the progression of the IDC. After 72 h of deprivation, the parasite growth could not be recovered despite supplementation with 90 µM hypoxanthine. Simulations of P. falciparum metabolism suggested that alterations in ubiquinone, isoprenoid, shikimate, and mitochondrial metabolism occurred before the appearance of these vacuole-like structures. Alterations were found in metabolic reactions associated with fatty acid synthesis, the pentose phosphate pathway, methionine metabolism, and coenzyme A synthesis in the latter half of the IDC. Furthermore, gene set enrichment analysis revealed that P. falciparum activated genes associated with rosette formation, Maurer’s cleft and protein export under two different nutrient-deprivation conditions (hypoxanthine and isoleucine). Conclusions The metabolic network analysis presented here suggests that P. falciparum invokes specific purine-recycling pathways to compensate for hypoxanthine deprivation and maintains a hypoxanthine pool for purine-based nucleic acid synthesis. However, this compensatory mechanism is not sufficient to maintain long-term viability of the parasite. Although P. falciparum can complete a full IDC in low hypoxanthine conditions, subsequent cycles are disrupted.

Published

2019

8. Redesigned TetR-Aptamer System To Control Gene Expression in Plasmodium falciparum

Author

Krithika Rajaram, Hans B. Liu, and Sean T. Prigge

Subjects

malaria, protein knockdown, tetracycline, tetracycline repressor, RNA aptamers, TetR-DOZI, Microbiology, QR1-502

Abstract

ABSTRACT One of the most powerful approaches to understanding gene function involves turning genes on and off at will and measuring the impact at the cellular or organismal level. This particularly applies to the cohort of essential genes where traditional gene knockouts are inviable. In Plasmodium falciparum, conditional control of gene expression has been achieved by using multicomponent systems in which individual modules interact with each other to regulate DNA recombination, transcription, or posttranscriptional processes. The recently devised TetR-DOZI aptamer system relies on the ligand-regulatable interaction of a protein module with synthetic RNA aptamers to control the translation of a target gene. This technique has been successfully employed to study essential genes in P. falciparum and involves the insertion of several aptamer copies into the 3′ untranslated regions (UTRs), which provide control over mRNA fate. However, aptamer repeats are prone to recombination and one or more copies can be lost from the system, resulting in a loss of control over target gene expression. We rectified this issue by redesigning the aptamer array to minimize recombination while preserving the control elements. As proof of concept, we compared the original and modified arrays for their ability to knock down the levels of a putative essential apicoplast protein (PF3D7_0815700) and demonstrated that the modified array is highly stable and efficient. This redesign will enhance the utility of a tool that is quickly becoming a favored strategy for genetic studies in P. falciparum. IMPORTANCE Malaria elimination efforts have been repeatedly hindered by the evolution and spread of multidrug-resistant strains of Plasmodium falciparum. The absence of a commercially available vaccine emphasizes the need for a better understanding of Plasmodium biology in order to further translational research. This has been partly facilitated by targeted gene deletion strategies for the functional analysis of parasite genes. However, genes that are essential for parasite replication in erythrocytes are refractory to such methods, and require conditional knockdown or knockout approaches to dissect their function. One such approach is the TetR-DOZI system that employs multiple synthetic aptamers in the untranslated regions of target genes to control their expression in a tetracycline-dependent manner. Maintaining modified parasites with intact aptamer copies has been challenging since these repeats can be lost by recombination. By interspacing the aptamers with unique sequences, we created a stable genetic system that remains effective at controlling target gene expression.

Published

2020

9. Using a genome-scale metabolic network model to elucidate the mechanism of chloroquine action in Plasmodium falciparum

Author

Shivendra G. Tewari, Sean T. Prigge, Jaques Reifman, and Anders Wallqvist

Subjects

Infectious and parasitic diseases, RC109-216

Abstract

Chloroquine, long the default first-line treatment against malaria, is now abandoned in large parts of the world because of widespread drug-resistance in Plasmodium falciparum. In spite of its importance as a cost-effective and efficient drug, a coherent understanding of the cellular mechanisms affected by chloroquine and how they influence the fitness and survival of the parasite remains elusive. Here, we used a systems biology approach to integrate genome-scale transcriptomics to map out the effects of chloroquine, identify targeted metabolic pathways, and translate these findings into mechanistic insights. Specifically, we first developed a method that integrates transcriptomic and metabolomic data, which we independently validated against a recently published set of such data for Krebs-cycle mutants of P. falciparum. We then used the method to calculate the effect of chloroquine treatment on the metabolic flux profiles of P. falciparum during the intraerythrocytic developmental cycle. The model predicted dose-dependent inhibition of DNA replication, in agreement with earlier experimental results for both drug-sensitive and drug-resistant P. falciparum strains. Our simulations also corroborated experimental findings that suggest differences in chloroquine sensitivity between ring- and schizont-stage P. falciparum. Our analysis also suggests that metabolic fluxes that govern reduced thioredoxin and phosphoenolpyruvate synthesis are significantly decreased and are pivotal to chloroquine-based inhibition of P. falciparum DNA replication. The consequences of impaired phosphoenolpyruvate synthesis and redox metabolism are reduced carbon fixation and increased oxidative stress, respectively, both of which eventually facilitate killing of the parasite. Our analysis suggests that a combination of chloroquine (or an analogue) and another drug, which inhibits carbon fixation and/or increases oxidative stress, should increase the clearance of P. falciparum from the host system. Keywords: Plasmodium, Chloroquine, Metabolic network modeling, Redox metabolism, Carbon fixation

Published

2017

10. Using Lipoamidase as a Novel Probe To Interrogate the Importance of Lipoylation in Plasmodium falciparum

Author

Hugo Jhun, Maroya S. Walters, and Sean T. Prigge

Subjects

acetyl-CoA, lipoamidase, lipoate, lipoic acid, malaria, mitochondrion, Microbiology, QR1-502

Abstract

ABSTRACT Lipoate is a redox active cofactor that is covalently bound to key enzymes of oxidative metabolism. Plasmodium falciparum is auxotrophic for lipoate during the intraerythrocytic stages, but it is not known whether lipoate attachment to protein is required or whether attachment is required in a specific subcellular compartment of the parasite. To address these questions, we used an enzyme called lipoamidase (Lpa) as a probe of lipoate metabolism. Lpa was first described in Enterococcus faecalis, and it specifically cleaves protein-bound lipoate, inactivating enzymes requiring this cofactor. Enzymatically active Lpa could be expressed in the cytosol of P. falciparum without any effect on protein lipoylation or parasite growth. Similarly, Lpa could be expressed in the apicoplast, and although protein lipoylation was reduced, parasite growth was not inhibited. By contrast, while an inactive mutant of Lpa could be expressed in the mitochondrion, the active enzyme could not. We designed an attenuated mutant of Lpa and found that this enzyme could be expressed in the parasite mitochondrion, but only in conjunction with a chemical bypass system. These studies suggest that acetyl-CoA production and a cryptic function of the H protein are both required for parasite survival. Our study validates Lpa as a novel probe of metabolism that can be used in other systems and provides new insight into key aspects of mitochondrial metabolism that are responsible for lipoate auxotrophy in malaria parasites. IMPORTANCE Lipoate is an essential cofactor for a small number of enzymes that are important for central metabolism. Malaria parasites require lipoate scavenged from the human host for growth and survival; however, it is not known why this cofactor is so important. To address this question, we designed a probe of lipoate activity based on the bacterial enzyme lipoamidase (Lpa). Expression of this probe in different subcellular locations allowed us to define the mitochondrion as the compartment housing essential lipoate metabolism. To gain further insight into the specific uses of lipoate in the mitochondrion, we designed a series of catalytically attenuated probes and employed the probes in conjunction with a chemical bypass system. These studies suggest that two lipoylated proteins are required for parasite survival. We were able to express Lpa with different catalytic abilities in different subcellular compartments and driven by different promoters, demonstrating the versatility of this tool and suggesting that it can be used as a probe of lipoate metabolism in other organisms.

Published

2018

11. Critical role for isoprenoids in apicoplast biogenesis by malaria parasites

Author

Megan Okada, Krithika Rajaram, Russell P Swift, Amanda Mixon, John Alan Maschek, Sean T Prigge, and Paul A Sigala

Subjects

malaria, isoprenoids, apicoplast, organelle biogenesis, polyprenol synthase, Medicine, Science, Biology (General), QH301-705.5

Abstract

Isopentenyl pyrophosphate (IPP) is an essential metabolic output of the apicoplast organelle in Plasmodium falciparum malaria parasites and is required for prenylation-dependent vesicular trafficking and other cellular processes. We have elucidated a critical and previously uncharacterized role for IPP in apicoplast biogenesis. Inhibiting IPP synthesis blocks apicoplast elongation and inheritance by daughter merozoites, and apicoplast biogenesis is rescued by exogenous IPP and polyprenols. Knockout of the only known isoprenoid-dependent apicoplast pathway, tRNA prenylation by MiaA, has no effect on blood-stage parasites and thus cannot explain apicoplast reliance on IPP. However, we have localized an annotated polyprenyl synthase (PPS) to the apicoplast. PPS knockdown is lethal to parasites, rescued by IPP and long- (C50) but not short-chain (≤C20) prenyl alcohols, and blocks apicoplast biogenesis, thus explaining apicoplast dependence on isoprenoid synthesis. We hypothesize that PPS synthesizes long-chain polyprenols critical for apicoplast membrane fluidity and biogenesis. This work critically expands the paradigm for isoprenoid utilization in malaria parasites and identifies a novel essential branch of apicoplast metabolism suitable for therapeutic targeting.

Published

2022

12. The NTP generating activity of pyruvate kinase II is critical for apicoplast maintenance in Plasmodium falciparum

Author

Russell P Swift, Krithika Rajaram, Cyrianne Keutcha, Hans B Liu, Bobby Kwan, Amanda Dziedzic, Anne E Jedlicka, and Sean T Prigge

Subjects

apicoplast, malaria, Pyruvate Kinase, plasmodium, microarray, carbon metabolism, Medicine, Science, Biology (General), QH301-705.5

Abstract

The apicoplast of Plasmodium falciparum parasites is believed to rely on the import of three-carbon phosphate compounds for use in organelle anabolic pathways, in addition to the generation of energy and reducing power within the organelle. We generated a series of genetic deletions in an apicoplast metabolic bypass line to determine which genes involved in apicoplast carbon metabolism are required for blood-stage parasite survival and organelle maintenance. We found that pyruvate kinase II (PyrKII) is essential for organelle maintenance, but that production of pyruvate by PyrKII is not responsible for this phenomenon. Enzymatic characterization of PyrKII revealed activity against all NDPs and dNDPs tested, suggesting that it may be capable of generating a broad range of nucleotide triphosphates. Conditional mislocalization of PyrKII resulted in decreased transcript levels within the apicoplast that preceded organelle disruption, suggesting that PyrKII is required for organelle maintenance due to its role in nucleotide triphosphate generation.

Published

2020

13. A Chemical Proteomic Strategy Reveals Inhibitors of Lipoate Salvage in Bacteria and Parasites

Author

Jan-Niklas Dienemann, Shu-Yu Chen, Manuel Hitzenberger, Montana L. Sievert, Stephan M. Hacker, Sean T. Prigge, Martin Zacharias, Michael Groll, and Stephan Axel Sieber

Subjects

General Chemistry, Catalysis

Published

2023

14. The Plasmodium falciparum apicoplast cysteine desulfurase provides sulfur for both iron-sulfur cluster assembly and tRNA modification

Author

Rubayet Elahi, Russell P Swift, Krithika Rajaram, Hans B Liu, and Sean T Prigge

Subjects

General Immunology and Microbiology, General Neuroscience, General Medicine, General Biochemistry, Genetics and Molecular Biology

Abstract

Iron-sulfur clusters (FeS) are ancient and ubiquitous protein cofactors that play fundamental roles in many aspects of cell biology. These cofactors cannot be scavenged or trafficked within a cell and thus must be synthesized in any subcellular compartment where they are required. We examined the FeS synthesis proteins found in the relict plastid organelle, called the apicoplast, of the human malaria parasite Plasmodium falciparum. Using a chemical bypass method, we deleted four of the FeS pathway proteins involved in sulfur acquisition and cluster assembly and demonstrated that they are all essential for parasite survival. However, the effect that these deletions had on the apicoplast organelle differed. Deletion of the cysteine desulfurase SufS led to disruption of the apicoplast organelle and loss of the organellar genome, whereas the other deletions did not affect organelle maintenance. Ultimately, we discovered that the requirement of SufS for organelle maintenance is not driven by its role in FeS biosynthesis, but rather, by its function in generating sulfur for use by MnmA, a tRNA modifying enzyme that we localized to the apicoplast. Complementation of MnmA and SufS activity with a bacterial MnmA and its cognate cysteine desulfurase strongly suggests that the parasite SufS provides sulfur for both FeS biosynthesis and tRNA modification in the apicoplast. The dual role of parasite SufS is likely to be found in other plastid-containing organisms and highlights the central role of this enzyme in plastid biology.

Published

2023

15. Author response: The Plasmodium falciparum apicoplast cysteine desulfurase provides sulfur for both iron-sulfur cluster assembly and tRNA modification

Author

Rubayet Elahi, Russell P Swift, Krithika Rajaram, Hans B Liu, and Sean T Prigge

Published

2023

16. The mitochondrion of Plasmodium falciparum is required for cellular acetyl-CoA metabolism and protein acetylation

Author

Sethu C. Nair, Justin T. Munro, Alexis Mann, Manuel Llinás, and Sean T. Prigge

Subjects

Multidisciplinary

Abstract

Coenzyme A (CoA) biosynthesis is an excellent target for antimalarial intervention. While most studies have focused on the use of CoA to produce acetyl-CoA in the apicoplast and the cytosol of malaria parasites, mitochondrial acetyl-CoA production is less well understood. In the current study, we performed metabolite-labeling experiments to measure endogenous metabolites in Plasmodium falciparum lines with genetic deletions affecting mitochondrial dehydrogenase activity. Our results show that the mitochondrion is required for cellular acetyl-CoA biosynthesis and identify a synthetic lethal relationship between the two main ketoacid dehydrogenase enzymes. The activity of these enzymes is dependent on the lipoate attachment enzyme LipL2, which is essential for parasite survival solely based on its role in supporting acetyl-CoA metabolism. We also find that acetyl-CoA produced in the mitochondrion is essential for the acetylation of histones and other proteins outside of the mitochondrion. Taken together, our results demonstrate that the mitochondrion is required for cellular acetyl-CoA metabolism and protein acetylation essential for parasite survival.

Published

2023

17. Transmissibility of clinically relevant atovaquone-resistantPlasmodium falciparumby anopheline mosquitoes

Author

Victoria A. Balta, Deborah Stiffler, Abeer Sayeed, Abhai K. Tripathi, Rubayet Elahi, Godfree Mlambo, Rahul P. Bakshi, Amanda G. Dziedzic, Anne E. Jedlicka, Elizabeth Nenortas, Keyla Romero-Rodriguez, Matthew A. Canonizado, Alexis Mann, Andrew Owen, David J. Sullivan, Sean T. Prigge, Photini Sinnis, and Theresa A. Shapiro

Subjects

Article

Abstract

Rising numbers of malaria cases and deaths underscore the need for new interventions. Long-acting injectable medications, such as those now in use for HIV prophylaxis, offer the prospect of a malaria “chemical vaccine”, combining the efficacy of a drug (like atovaquone) with the durability of a biological vaccine. Of concern, however, is the possible selection and transmission of drug-resistant parasites. We addressed this question by generating clinically relevant, highly atovaquone-resistant,Plasmodium falciparummutants competent to infect mosquitoes. Isogenic paired strains, that differ only by a single Y268S mutation in cytochrome b, were evaluated in parallel in southeast Asian (Anopheles stephensi) or African (Anopheles gambiae) mosquitoes, and thence in humanized mice. Fitness costs of the mutation were evident along the lifecycle, in asexual parasite growth in vitro and in a progressive loss of parasites in the mosquito. In numerous independent experiments, microscopic exam of salivary glands from hundreds of mosquitoes failed to detect even one Y268S sporozoite, a defect not rescued by coinfection with wild type parasites. Furthermore, despite uniformly successful transmission of wild type parasites fromAn. stephensito FRG NOD huHep mice bearing human hepatocytes and erythrocytes, multiple attempts with Y268S-fed mosquitoes failed: there was no evidence of parasites in mouse tissues by microscopy, in vitro culture, or PCR. These studies confirm a severe-to-lethal fitness cost of clinically relevant atovaquone-resistantP. falciparumin the mosquito, and they significantly lessen the likelihood of their transmission in the field.SignificanceNew tools are needed to protect individuals from malaria and to control malaria in the field. Atovaquone plus proguanil is a commonly used and well-tolerated medicine to prevent malaria. No drug resistance has been reported from its prophylactic use, but tablets must be taken daily. Giving atovaquone as a single injection may provide much longer-lasting protection, against both falciparum and vivax malaria, but there is concern this may create drug resistance. In this study we showed that clinically relevant atovaquone-resistant malaria parasites survive poorly, if at all, in mosquitoes, and that mosquitoes do not transmit drug-resistant parasites to humanized mice. These findings lessen the likelihood that an atovaquone “chemical vaccine” would lead to the spread of atovaquone resistance.

Published

2023

18. ThePlasmodium falciparumapicoplast cysteine desulfurase provides sulfur for both iron sulfur cluster assembly and tRNA modification

Author

Russell P. Swift, Rubayet Elahi, Krithika Rajaram, Hans B. Liu, and Sean T. Prigge

Abstract

Iron sulfur clusters (FeS) are ancient and ubiquitous protein cofactors that play fundamental roles in many aspects of cell biology. These cofactors cannot be scavenged or trafficked within a cell and thus must be synthesized in any subcellular compartment where they are required. We examined the FeS synthesis proteins found in the relict plastid organelle, called the apicoplast, of the human malaria parasitePlasmodium falciparum.Using a chemical bypass method, we deleted four of the FeS pathway proteins involved in sulfur acquisition and cluster assembly and demonstrated that they are all essential for parasite survival. However, the effect that these deletions had on the apicoplast organelle differed. Deletion of the cysteine desulfurase SufS led to disruption of the apicoplast organelle and loss of the organellar genome, whereas the other deletions did not affect organelle maintenance. Ultimately, we discovered that the requirement of SufS for organelle maintenance is not driven by its role in FeS biosynthesis, but rather, by its function in generating sulfur for use by MnmA, a tRNA modifying enzyme that we localized to the apicoplast. By complementing the activity of the parasite MnmA and SufS with a bacterial MnmA and its cognate cysteine desulfurase, we showed that the parasite SufS provides sulfur for both FeS biosynthesis and tRNA modification in the apicoplast. The dual role of parasite SufS is likely to be found in other plastid-containing organisms and highlights the central role of this enzyme in plastid biology.

Published

2022

19. Screening the Pathogen Box for Inhibition of Plasmodium falciparum Sporozoite Motility Reveals a Critical Role for Kinases in Transmission Stages

Author

Sachie Kanatani, Rubayet Elahi, Sukanat Kanchanabhogin, Natasha Vartak, Abhai K. Tripathi, Sean T. Prigge, and Photini Sinnis

Subjects

Pharmacology, Mammals, Antimalarials, Infectious Diseases, Sporozoites, Anopheles, Plasmodium falciparum, Animals, Humans, Pharmacology (medical), Experimental Therapeutics, Malaria, Falciparum, Malaria

Abstract

As the malaria parasite becomes resistant to every drug that we develop, the identification and development of novel drug candidates are essential. Many studies have screened compounds designed to target the clinically important blood stages. However, if we are to shrink the malaria map, new drugs that block the transmission of the parasite are needed. Sporozoites are the infective stage of the malaria parasite, transmitted to the mammalian host as mosquitoes probe for blood. Sporozoite motility is critical to their ability to exit the inoculation site and establish infection, and drug-like compounds targeting motility are effective at blocking infection in the rodent malaria model. In this study, we established a moderate-throughput motility assay for sporozoites of the human malaria parasite Plasmodium falciparum, enabling us to screen the 400 drug-like compounds from the pathogen box provided by the Medicines for Malaria Venture for their activity. Compounds exhibiting inhibitory effects on P. falciparum sporozoite motility were further assessed for transmission-blocking activity and asexual-stage growth. Five compounds had a significant inhibitory effect on P. falciparum sporozoite motility in the nanomolar range. Using membrane feeding assays, we demonstrate that four of these compounds had inhibitory activity against the transmission of P. falciparum to the mosquito. Interestingly, of the four compounds with inhibitory activity against both transmission stages, three are known kinase inhibitors. Together with a previous study that found that several of these compounds could inhibit asexual blood-stage parasite growth, our findings provide new antimalarial drug candidates that have multistage activity.

Published

2022

20. Screening the Pathogen Box Compounds for Activity Against Plasmodium falciparum Sporozoite Motility

Author

Sachie Kanatani, Rubayet Elahi, Sukanat Kanchanabhogin, Natasha Vartek, Abhai K. Tripathi, Sean T. Prigge, and Photini Sinnis

Subjects

parasitic diseases

Abstract

As the malaria parasite becomes resistant to every drug that we develop, identification and development of novel drug candidates is essential. Many studies have screened compounds designed to target the clinically important blood stages. However, if we are to shrink the malaria map, new drugs that block transmission of the parasite are needed. Sporozoites are the infective stage of the malaria parasite, transmitted to the mammalian host as mosquitoes probe for blood. Sporozoite motility is critical to their ability to exit the inoculation site and establish infection and drug-like compounds targeting motility are effective in blocking infection in the rodent malaria model. In this study, we established a moderate throughput motility assay for sporozoites of the human malaria parasite Plasmodium falciparum, enabling us to screen the 400 drug-like compounds from the Pathogen box provided by Medicines for Malaria Venture for their activity. Compounds exhibiting inhibitory effects on P. falciparum sporozoite motility were further assessed against transmission-blocking activity and asexual stage growth. Five compounds had a significant inhibitory effect on P. falciparum sporozoite motility at 1 μM concentration and four of these compounds also showed significant inhibition on transmission of P. falciparum gametocytes to the mosquito and of these four, three had previously been shown to have inhibitory activity on asexual blood stage parasites. Our findings provide new antimalarial drug candidates that have multi-stage activity.

Published

2022

21. The mitochondrion of Plasmodium falciparum generates essential acetyl-CoA for protein acetylation

Author

Sethu C. Nair, Justin T. Munro, Alexis Mann, Manuel Llinás, and Sean T. Prigge

Abstract

Coenzyme A (CoA) biosynthesis is an excellent target for antimalarial intervention. While most studies have focused on the use of CoA to produce acetyl-CoA in the apicoplast and the cytosol of malaria parasites, mitochondrial acetyl-CoA production is less well understood. In the current study, we performed metabolite labeling experiments to measure endogenous metabolites in Plasmodium falciparum lines with genetic deletions affecting mitochondrial dehydrogenase activity. Our results show that mitochondrial acetyl-CoA biosynthesis is essential for parasite growth and identify a catalytic redundancy between the two main ketoacid dehydrogenase enzymes, both of which are able to produce acetyl-CoA. The activity of these enzymes is dependent on the lipoate attachment enzyme LipL2, which is essential for parasite survival solely based on its role in supporting acetyl-CoA metabolism. We also find that acetyl-CoA produced in the mitochondrion is essential for the acetylation of histones and other proteins outside of the mitochondrion. Taken together, our results demonstrate that the mitochondrion is an essential de novo source of acetyl-CoA and is required for P. falciparum protein acetylation critical to parasite survival.

Published

2022

22. Author response: Critical role for isoprenoids in apicoplast biogenesis by malaria parasites

Author

Megan Okada, Krithika Rajaram, Russell P Swift, Amanda Mixon, John Alan Maschek, Sean T Prigge, and Paul A Sigala

Published

2022

23. New insights into apicoplast metabolism in blood-stage malaria parasites

Author

Rubayet, Elahi and Sean T, Prigge

Subjects

Microbiology (medical), Infectious Diseases, Microbiology

Abstract

The apicoplast of Plasmodium falciparum is the only source of essential isoprenoid precursors and Coenzyme A (CoA) in the parasite. Isoprenoid precursor synthesis relies on the iron-sulfur cluster (FeS) cofactors produced within the apicoplast, rendering FeS synthesis an essential function of this organelle. Recent reports provide important insights into the roles of FeS cofactors and the use of isoprenoid precursors and CoA both inside and outside the apicoplast. Here, we review the recent insights into the roles of these metabolites in blood-stage malaria parasites and discuss new questions that have been raised in light of these discoveries.

Published

2023

24. Critical role for isoprenoids in apicoplast biogenesis by malaria parasites

Author

Russell P. Swift, Sean T. Prigge, Krithika Rajaram, John Alan Maschek, Amanda Mixon, Paul A. Sigala, and Megan Okada

Subjects

Plasmodium falciparum, Isopentenyl pyrophosphate, Protozoan Proteins, Biology, Apicoplasts, General Biochemistry, Genetics and Molecular Biology, Polyprenols, chemistry.chemical_compound, Prenylation, Organelle, Animals, Parasites, Malaria, Falciparum, Apicoplast, ATP synthase, General Immunology and Microbiology, Terpenes, General Neuroscience, General Medicine, biology.organism_classification, Cell biology, chemistry, Transfer RNA, biology.protein, Biogenesis

Abstract

Isopentenyl pyrophosphate (IPP) is an essential metabolic output of the apicoplast organelle in Plasmodium falciparum malaria parasites and is required for prenylation-dependent vesicular trafficking and other cellular processes. We have elucidated a critical and previously uncharacterized role for IPP in apicoplast biogenesis. Inhibiting IPP synthesis blocks apicoplast elongation and inheritance by daughter merozoites, and apicoplast biogenesis is rescued by exogenous IPP and polyprenols. Knockout of the only known isoprenoid-dependent apicoplast pathway, tRNA prenylation by MiaA, has no effect on blood-stage parasites and thus cannot explain apicoplast reliance on IPP. However, we have localized an annotated polyprenyl synthase (PPS) to the apicoplast. PPS knockdown is lethal to parasites, rescued by IPP and long- (C50) but not short-chain (≤C20) prenyl alcohols, and blocks apicoplast biogenesis, thus explaining apicoplast dependence on isoprenoid synthesis. We hypothesize that PPS synthesizes long-chain polyprenols critical for apicoplast membrane fluidity and biogenesis. This work critically expands the paradigm for isoprenoid utilization in malaria parasites and identifies a novel essential branch of apicoplast metabolism suitable for therapeutic targeting.

Published

2021

25. Inter-study and time-dependent variability of metabolite abundance in cultured red blood cells

Author

Russell P. Swift, Krithika Rajaram, Bobby Kwan, Sean T. Prigge, Jaques Reifman, Anders Wallqvist, and Shivendra G. Tewari

Subjects

0301 basic medicine, Metabolic network modeling, Erythrocytes, Metabolite, 030106 microbiology, RC955-962, Plasmodium falciparum, Context (language use), Infectious and parasitic diseases, RC109-216, Pentose phosphate pathway, 03 medical and health sciences, chemistry.chemical_compound, Metabolomics, Arctic medicine. Tropical medicine, Glycolysis, Malaria, Falciparum, Research, Human red blood cells, Glutathione, Metabolism, Metabolic network modelling, 030104 developmental biology, Infectious Diseases, chemistry, Biochemistry, Metabolome, Parasitology

Abstract

Background Cultured human red blood cells (RBCs) provide a powerful ex vivo assay platform to study blood-stage malaria infection and propagation. In recent years, high-resolution metabolomic methods have quantified hundreds of metabolites from parasite-infected RBC cultures under a variety of perturbations. In this context, the corresponding control samples of the uninfected culture systems can also be used to examine the effects of these perturbations on RBC metabolism itself and their dependence on blood donors (inter-study variations). Methods Time-course datasets from five independent studies were generated and analysed, maintaining uninfected RBCs (uRBC) at 2% haematocrit for 48 h under conditions originally designed for parasite cultures. Using identical experimental protocols, quadruplicate samples were collected at six time points, and global metabolomics were employed on the pellet fraction of the uRBC cultures. In total, ~ 500 metabolites were examined across each dataset to quantify inter-study variability in RBC metabolism, and metabolic network modelling augmented the analyses to characterize the metabolic state and fluxes of the RBCs. Results To minimize inter-study variations unrelated to RBC metabolism, an internal standard metabolite (phosphatidylethanolamine C18:0/20:4) was identified with minimal variation in abundance over time and across all the samples of each dataset to normalize the data. Although the bulk of the normalized data showed a high degree of inter-study consistency, changes and variations in metabolite levels from individual donors were noted. Thus, a total of 24 metabolites were associated with significant variation in the 48-h culture time window, with the largest variations involving metabolites in glycolysis and synthesis of glutathione. Metabolic network analysis was used to identify the production of superoxide radicals in cultured RBCs as countered by the activity of glutathione oxidoreductase and synthesis of reducing equivalents via the pentose phosphate pathway. Peptide degradation occurred at a rate that is comparable with central carbon fluxes, consistent with active degradation of methaemoglobin, processes also commonly associated with storage lesions in RBCs. Conclusions The bulk of the data showed high inter-study consistency. The collected data, quantification of an expected abundance variation of RBC metabolites, and characterization of a subset of highly variable metabolites in the RBCs will help in identifying non-specific changes in metabolic abundances that may obscure accurate metabolomic profiling of Plasmodium falciparum and other blood-borne pathogens.

Published

2021

26. Development of a conditional localization approach to control apicoplast protein trafficking in malaria parasites

Author

Sean T. Prigge, Alfredo J. Guerra, Aleah D. Roberts, and Sethu C. Nair

Subjects

Plasmodium falciparum, Protozoan Proteins, Apicoplasts, Protein Sorting Signals, Biology, Biochemistry, Protein biotinylation, Article, 03 medical and health sciences, 0302 clinical medicine, Structural Biology, Transit Peptide, Coenzyme A Ligases, parasitic diseases, Genetics, medicine, Molecular Biology, 030304 developmental biology, 0303 health sciences, Apicoplast, Cell Biology, medicine.disease, biology.organism_classification, Cell biology, Protein Transport, Secretory protein, Holocarboxylase synthetase, 030217 neurology & neurosurgery, Function (biology), Malaria

Abstract

Secretory proteins are of particular importance to apicomplexan parasites and comprise over 15% of the genomes of the human pathogens that cause diseases like malaria, toxoplasmosis and babesiosis as well as other diseases of agricultural significance. Here, we developed an approach that allows us to control the trafficking destination of secretory proteins in the human malaria parasite Plasmodium falciparum. Based on the unique structural requirements of apicoplast transit peptides, we designed three conditional localization domains (CLD1, 2, and 3) that can be used to control protein trafficking via the addition of a cell permeant ligand. Studies comparing the trafficking dynamics of each CLD show that CLD2 has the most optimal trafficking efficiency. To validate this system, we tested whether CLD2 could conditionally localize a biotin ligase called Holocarboxylase Synthetase 1 (HCS1) without interfering with the function of the enzyme. In a parasite line expressing CLD2-HCS1, we were able to control protein biotinylation in the apicoplast in a ligand-dependent manner, demonstrating the full functionality of the CLD tool. We have developed and validated a novel molecular tool that may be used in future studies to help elucidate the function of secretory proteins in malaria parasites.

Published

2019

27. Short-term metabolic adjustments in Plasmodium falciparum counter hypoxanthine deprivation at the expense of long-term viability

Author

Russell P. Swift, Krithika Rajaram, Sean T. Prigge, Jaques Reifman, Patric Schyman, Anders Wallqvist, and Shivendra G. Tewari

Subjects

Purine, Gene set enrichment analysis, Time Factors, lcsh:Arctic medicine. Tropical medicine, Survival, lcsh:RC955-962, 030231 tropical medicine, Plasmodium falciparum, Pentose phosphate pathway, lcsh:Infectious and parasitic diseases, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Animals, Metabolomics, lcsh:RC109-216, 030212 general & internal medicine, Purine metabolism, Hypoxanthine, Fatty acid synthesis, Metabolic network model, biology, Chemistry, Gene Expression Profiling, Research, Metabolism, biology.organism_classification, Adaptation, Physiological, Stress response pathways, Infectious Diseases, Biochemistry, Purine deprivation, Nucleic acid, Metabolome, Parasitology, Transcriptome, Metabolic Networks and Pathways

Abstract

Background The malarial parasite Plasmodium falciparum is an auxotroph for purines, which are required for nucleic acid synthesis during the intra-erythrocytic developmental cycle (IDC) of the parasite. The capabilities of the parasite and extent to which it can use compensatory mechanisms to adapt to purine deprivation were studied by examining changes in its metabolism under sub-optimal concentrations of hypoxanthine, the primary precursor utilized by the parasite for purine-based nucleic acid synthesis. Methods The concentration of hypoxanthine that caused a moderate growth defect over the course of one IDC was determined. At this concentration of hypoxanthine (0.5 μM), transcriptomic and metabolomic data were collected during one IDC at multiple time points. These data were integrated with a metabolic network model of the parasite embedded in a red blood cell (RBC) to interpret the metabolic adaptation of P. falciparum to hypoxanthine deprivation. Results At a hypoxanthine concentration of 0.5 μM, vacuole-like structures in the cytosol of many P. falciparum parasites were observed after the 24-h midpoint of the IDC. Parasites grown under these conditions experienced a slowdown in the progression of the IDC. After 72 h of deprivation, the parasite growth could not be recovered despite supplementation with 90 µM hypoxanthine. Simulations of P. falciparum metabolism suggested that alterations in ubiquinone, isoprenoid, shikimate, and mitochondrial metabolism occurred before the appearance of these vacuole-like structures. Alterations were found in metabolic reactions associated with fatty acid synthesis, the pentose phosphate pathway, methionine metabolism, and coenzyme A synthesis in the latter half of the IDC. Furthermore, gene set enrichment analysis revealed that P. falciparum activated genes associated with rosette formation, Maurer’s cleft and protein export under two different nutrient-deprivation conditions (hypoxanthine and isoleucine). Conclusions The metabolic network analysis presented here suggests that P. falciparum invokes specific purine-recycling pathways to compensate for hypoxanthine deprivation and maintains a hypoxanthine pool for purine-based nucleic acid synthesis. However, this compensatory mechanism is not sufficient to maintain long-term viability of the parasite. Although P. falciparum can complete a full IDC in low hypoxanthine conditions, subsequent cycles are disrupted. Electronic supplementary material The online version of this article (10.1186/s12936-019-2720-3) contains supplementary material, which is available to authorized users.

Published

2019

28. Dephospho‐CoA kinase, a nuclear‐encoded apicoplast protein, remains active and essential after Plasmodium falciparum apicoplast disruption

Author

Sean T. Prigge, Russell P. Swift, Hans B. Liu, and Krithika Rajaram

Subjects

Coenzyme A, Plasmodium falciparum, Isopentenyl pyrophosphate, malaria, Protozoan Proteins, coenzyme A, Apicoplasts, General Biochemistry, Genetics and Molecular Biology, Article, Pantothenic Acid, DPCK, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Organelle, Molecular Biology, Heme, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, Apicoplast, apicoplast, General Immunology and Microbiology, biology, General Neuroscience, Articles, biology.organism_classification, Microbiology, Virology & Host Pathogen Interaction, Cell biology, Metabolic pathway, Phosphotransferases (Alcohol Group Acceptor), Enzyme, Metabolism, chemistry, 030217 neurology & neurosurgery

Abstract

Malaria parasites contain an essential organelle called the apicoplast that houses metabolic pathways for fatty acid, heme, isoprenoid, and iron–sulfur cluster synthesis. Surprisingly, malaria parasites can survive without the apicoplast as long as the isoprenoid precursor isopentenyl pyrophosphate (IPP) is supplemented in the growth medium, making it appear that isoprenoid synthesis is the only essential function of the organelle in blood‐stage parasites. In the work described here, we localized an enzyme responsible for coenzyme A synthesis, DPCK, to the apicoplast, but we were unable to delete DPCK, even in the presence of IPP. However, once the endogenous DPCK was complemented with the E. coli DPCK (EcDPCK), we were successful in deleting it. We were then able to show that DPCK activity is required for parasite survival through knockdown of the complemented EcDPCK. Additionally, we showed that DPCK enzyme activity remains functional and essential within the vesicles present after apicoplast disruption. These results demonstrate that while the apicoplast of blood‐stage P. falciparum parasites can be disrupted, the resulting vesicles remain biochemically active and are capable of fulfilling essential functions., Production of coenzyme A is an indispensable function of the apicoplast organelle in blood‐stage malaria parasites.

Published

2021

29. Metabolic changes accompanying the loss of fumarate hydratase and malate–quinone oxidoreductase in the asexual blood stage of Plasmodium falciparum

Author

Krithika Rajaram, Shivendra G. Tewari, Anders Wallqvist, and Sean T. Prigge

Subjects

Fumarates, Plasmodium falciparum, Malates, Quinones, Animals, Cell Biology, Malaria, Falciparum, Oxidoreductases, Molecular Biology, Biochemistry, Fumarate Hydratase

Abstract

In the glucose-rich milieu of red blood cells, asexually replicating malarial parasites mainly rely on glycolysis for ATP production, with limited carbon flux through the mitochondrial tricarboxylic acid (TCA) cycle. By contrast, gametocytes and mosquito-stage parasites exhibit an increased dependence on the TCA cycle and oxidative phosphorylation for more economical energy generation. Prior genetic studies supported these stage-specific metabolic preferences by revealing that six of eight TCA cycle enzymes are completely dispensable during the asexual blood stages of Plasmodium falciparum, with only fumarate hydratase (FH) and malate-quinone oxidoreductase (MQO) being refractory to deletion. Several hypotheses have been put forth to explain the possible essentiality of FH and MQO, including their participation in a malate shuttle between the mitochondrial matrix and the cytosol. However, using newer genetic techniques like CRISPR and dimerizable Cre, we were able to generate deletion strains of FH and MQO in P. falciparum. We employed metabolomic analyses to characterize a double knockout mutant of FH and MQO (ΔFM) and identified changes in purine salvage and urea cycle metabolism that may help to limit fumarate accumulation. Correspondingly, we found that the ΔFM mutant was more sensitive to exogenous fumarate, which is known to cause toxicity by modifying and inactivating proteins and metabolites. Overall, our data indicate that P. falciparum is able to adequately compensate for the loss of FH and MQO, rendering them unsuitable targets for drug development.

Published

2022

30. Metabolic Survival Adaptations of Plasmodium falciparum Exposed to Sublethal Doses of Fosmidomycin

Author

Russell P. Swift, Jaques Reifman, Krithika Rajaram, Sean T. Prigge, Shivendra G. Tewari, and Anders Wallqvist

Subjects

Purine, Plasmodium falciparum, Apicoplasts, 03 medical and health sciences, chemistry.chemical_compound, Antimalarials, Prenylation, Fosfomycin, parasitic diseases, medicine, Parasite hosting, Humans, Pharmacology (medical), Nucleotide, Malaria, Falciparum, Mechanisms of Action: Physiological Effects, 030304 developmental biology, Pharmacology, chemistry.chemical_classification, 0303 health sciences, Apicoplast, biology, 030306 microbiology, Ribosomal RNA, biology.organism_classification, Fosmidomycin, Infectious Diseases, Biochemistry, chemistry, medicine.drug

Abstract

The malaria parasite Plasmodium falciparum contains the apicoplast organelle that synthesize isoprenoids, which are metabolites necessary for post-translational modification of Plasmodium proteins. We used fosmidomycin, an antibiotic that inhibits isoprenoid biosynthesis, to identify mechanisms that underlie the development of the parasite's adaptation to the drug at sub-lethal concentrations. We first determined a concentration of fosmidomycin that reduced parasite growth by ∼50% over one intraerythrocytic developmental cycle (IDC). At this dose, we maintained synchronous parasite cultures for one full IDC, and collected metabolomic and transcriptomic data at multiple time points to capture global and stage-specific alterations. We integrated the data with a genome-scale metabolic model of P. falciparum to characterize the metabolic adaptations of the parasite in response to fosmidomycin treatment. Our simulations showed that, in treated parasites, the synthesis of purine-based nucleotides increased, whereas the synthesis of phosphatidylcholine during the trophozoite and schizont stages decreased. Specifically, the increased polyamine synthesis led to increased nucleotide synthesis, while the reduced methyl-group cycling led to reduced phospholipid synthesis and methyltransferase activities. These results indicate that fosmidomycin-treated parasites compensate for the loss of prenylation modifications by directly altering processes that affect nucleotide synthesis and ribosomal biogenesis to control the rate of RNA translation during the IDC. This also suggests that combination therapies with antibiotics that target the compensatory response of the parasite, such as nucleotide synthesis or ribosomal biogenesis, may be more effective than treating the parasite with fosmidomycin alone.

Published

2020

31. Redesigned TetR-Aptamer System To Control Gene Expression in Plasmodium falciparum

Author

Hans B. Liu, Sean T. Prigge, and Krithika Rajaram

Subjects

Untranslated region, Molecular Biology and Physiology, Aptamer, Plasmodium falciparum, lcsh:QR1-502, malaria, Computational biology, Biology, Proof of Concept Study, Microbiology, lcsh:Microbiology, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Gene expression, TetR, RNA, Messenger, RNA aptamers, Molecular Biology, Gene, Gene knockout, Oligonucleotide Array Sequence Analysis, tetracycline, 030304 developmental biology, 0303 health sciences, Gene knockdown, Apicoplast, Genes, Essential, tetracycline repressor, Aptamers, Nucleotide, QR1-502, Gene Expression Regulation, chemistry, TetR-DOZI, Trans-Activators, protein knockdown, 030217 neurology & neurosurgery, Research Article

Abstract

Malaria elimination efforts have been repeatedly hindered by the evolution and spread of multidrug-resistant strains of Plasmodium falciparum. The absence of a commercially available vaccine emphasizes the need for a better understanding of Plasmodium biology in order to further translational research. This has been partly facilitated by targeted gene deletion strategies for the functional analysis of parasite genes. However, genes that are essential for parasite replication in erythrocytes are refractory to such methods, and require conditional knockdown or knockout approaches to dissect their function. One such approach is the TetR-DOZI system that employs multiple synthetic aptamers in the untranslated regions of target genes to control their expression in a tetracycline-dependent manner. Maintaining modified parasites with intact aptamer copies has been challenging since these repeats can be lost by recombination. By interspacing the aptamers with unique sequences, we created a stable genetic system that remains effective at controlling target gene expression., One of the most powerful approaches to understanding gene function involves turning genes on and off at will and measuring the impact at the cellular or organismal level. This particularly applies to the cohort of essential genes where traditional gene knockouts are inviable. In Plasmodium falciparum, conditional control of gene expression has been achieved by using multicomponent systems in which individual modules interact with each other to regulate DNA recombination, transcription, or posttranscriptional processes. The recently devised TetR-DOZI aptamer system relies on the ligand-regulatable interaction of a protein module with synthetic RNA aptamers to control the translation of a target gene. This technique has been successfully employed to study essential genes in P. falciparum and involves the insertion of several aptamer copies into the 3′ untranslated regions (UTRs), which provide control over mRNA fate. However, aptamer repeats are prone to recombination and one or more copies can be lost from the system, resulting in a loss of control over target gene expression. We rectified this issue by redesigning the aptamer array to minimize recombination while preserving the control elements. As proof of concept, we compared the original and modified arrays for their ability to knock down the levels of a putative essential apicoplast protein (PF3D7_0815700) and demonstrated that the modified array is highly stable and efficient. This redesign will enhance the utility of a tool that is quickly becoming a favored strategy for genetic studies in P. falciparum. IMPORTANCE Malaria elimination efforts have been repeatedly hindered by the evolution and spread of multidrug-resistant strains of Plasmodium falciparum. The absence of a commercially available vaccine emphasizes the need for a better understanding of Plasmodium biology in order to further translational research. This has been partly facilitated by targeted gene deletion strategies for the functional analysis of parasite genes. However, genes that are essential for parasite replication in erythrocytes are refractory to such methods, and require conditional knockdown or knockout approaches to dissect their function. One such approach is the TetR-DOZI system that employs multiple synthetic aptamers in the untranslated regions of target genes to control their expression in a tetracycline-dependent manner. Maintaining modified parasites with intact aptamer copies has been challenging since these repeats can be lost by recombination. By interspacing the aptamers with unique sequences, we created a stable genetic system that remains effective at controlling target gene expression.

Published

2020

32. The NTP generating activity of pyruvate kinase II is critical for apicoplast maintenance in Plasmodium falciparum

Author

Cyrianne Keutcha, Amanda Dziedzic, Sean T. Prigge, Hans B. Liu, Bobby Kwan, Krithika Rajaram, Russell P. Swift, and Anne E. Jedlicka

Subjects

carbon metabolism, QH301-705.5, Science, Pyruvate Kinase, malaria, Chemical biology, Biology, General Biochemistry, Genetics and Molecular Biology, Organelle, Nucleotide, Biology (General), Gene, chemistry.chemical_classification, Apicoplast, apicoplast, General Immunology and Microbiology, General Neuroscience, Plasmodium falciparum, General Medicine, biology.organism_classification, Cell biology, Enzyme, plasmodium, chemistry, Medicine, microarray, Pyruvate kinase

Abstract

The apicoplast of Plasmodium falciparum parasites is believed to rely on the import of three-carbon phosphate compounds for use in organelle anabolic pathways, in addition to the generation of energy and reducing power within the organelle. We generated a series of genetic deletions in an apicoplast metabolic bypass line to determine which genes involved in apicoplast carbon metabolism are required for blood-stage parasite survival and organelle maintenance. We found that pyruvate kinase II (PyrKII) is essential for organelle maintenance, but that production of pyruvate by PyrKII is not responsible for this phenomenon. Enzymatic characterization of PyrKII revealed activity against all NDPs and dNDPs tested, suggesting that it may be capable of generating a broad range of nucleotide triphosphates. Conditional mislocalization of PyrKII resulted in decreased transcript levels within the apicoplast that preceded organelle disruption, suggesting that PyrKII is required for organelle maintenance due to its role in nucleotide triphosphate generation.

Published

2020

33. Decision letter: A single point mutation in the Plasmodium falciparum FtsH1 metalloprotease confers actinonin resistance

Author

Sean T. Prigge, Jon Clardy, and Ellen Yeh

Subjects

Genetics, Metalloproteinase, chemistry.chemical_compound, biology, chemistry, Point mutation, Plasmodium falciparum, biology.organism_classification, Actinonin

Published

2020

34. Author response: The NTP generating activity of pyruvate kinase II is critical for apicoplast maintenance in Plasmodium falciparum

Author

Russell P. Swift, Cyrianne Keutcha, Krithika Rajaram, Bobby Kwan, Anne E. Jedlicka, Sean T. Prigge, Hans B. Liu, and Amanda Dziedzic

Subjects

Apicoplast, Biochemistry, Plasmodium falciparum, Biology, biology.organism_classification, Pyruvate kinase

Published

2020

35. A redesigned TetR-aptamer system to control gene expression in Plasmodium falciparum

Author

Krithika Rajaram, Hans B. Liu, and Sean T. Prigge

Subjects

Untranslated region, Apicoplast, chemistry.chemical_compound, chemistry, Transcription (biology), Aptamer, Gene expression, TetR, Computational biology, Biology, Gene, Gene knockout

Abstract

One of the most powerful approaches to understanding gene function involves turning genes on and off at will and measuring the impact at the cellular or organismal level. This particularly applies to the cohort of essential genes where traditional gene knockouts are inviable. In Plasmodium falciparum, conditional control of gene expression has been achieved by using multi-component systems in which individual modules interact with each other to regulate DNA recombination, transcription or posttranscriptional processes. The recently devised TetR-DOZI aptamer system relies on the ligand-regulatable interaction of a protein module with synthetic RNA aptamers to control the translation of a target gene. This technique has been successfully employed to study essential genes in P. falciparum and involves the insertion of several aptamer copies into their 3’ untranslated regions (UTRs) which provide control over mRNA fate. However, aptamer repeats are prone to recombination and one or more copies can be lost from the system, resulting in a loss of control over target gene expression. We rectified this issue by redesigning the aptamer array to minimize recombination while preserving the control elements. As proof of concept, we compared the original and modified arrays for their ability to knock down the levels of a putative essential apicoplast protein (PF3D7_0815700) and demonstrated that the modified array is highly stable and efficient. This redesign will enhance the utility of a tool that is quickly becoming a favored strategy for genetic studies in P. falciparum.ImportanceMalaria elimination efforts have been repeatedly hindered by the evolution and spread of multidrug-resistant strains of Plasmodium falciparum. The absence of a commercially available vaccine emphasizes the need for a better understanding of Plasmodium biology in order to further translational research. This has been partly facilitated by targeted gene deletion strategies for the functional analysis of parasite genes. However, genes that are essential for parasite replication in erythrocytes are refractory to such methods, and require conditional knockdown or knockout approaches to dissect their function. One such approach is the TetR-DOZI system that employs multiple synthetic aptamers in the untranslated regions of target genes to control their expression in a tetracycline-dependent manner. Maintaining modified parasites with intact aptamer copies has been challenging since these repeats are frequently lost by recombination. By interspacing the aptamers with unique sequences, we created a stable genetic system that remains effective at controlling target gene expression.

Published

2020

36. The amidase domain of lipoamidase specifically inactivates lipoylated proteins in vivo.

Author

Maroya D Spalding and Sean T Prigge

Subjects

Medicine, Science

Abstract

BACKGROUND:In the 1950s, Reed and coworkers discovered an enzyme activity in Streptococcus faecalis (Enterococcus faecalis) extracts that inactivated the Escherichia. coli and E. faecalis pyruvate dehydrogenase complexes through cleavage of the lipoamide bond. The enzyme that caused this lipoamidase activity remained unidentified until Jiang and Cronan discovered the gene encoding lipoamidase (Lpa) through the screening of an expression library. Subsequent cloning and characterization of the recombinant enzyme revealed that lipoamidase is an 80 kDa protein composed of an amidase domain containing a classic Ser-Ser-Lys catalytic triad and a carboxy-terminal domain of unknown function. Here, we show that the amidase domain can be used as an in vivo probe which specifically inactivates lipoylated enzymes. METHODOLOGY/PRINCIPAL FINDINGS:We evaluated whether Lpa could function as an inducible probe of alpha-ketoacid dehydrogenase inactivation using E. coli as a model system. Lpa expression resulted in cleavage of lipoic acid from the three lipoylated proteins expressed in E. coli, but did not result in cleavage of biotin from the sole biotinylated protein, the biotin carboxyl carrier protein. When expressed in lipoylation deficient E. coli, Lpa is not toxic, indicating that Lpa does not interfere with any other critical metabolic pathways. When truncated to the amidase domain, Lpa retained lipoamidase activity without acquiring biotinidase activity, indicating that the carboxy-terminal domain is not essential for substrate recognition or function. Substitution of any of the three catalytic triad amino acids with alanine produced inactive Lpa proteins. CONCLUSIONS/SIGNIFICANCE:The enzyme lipoamidase is active against a broad range of lipoylated proteins in vivo, but does not affect the growth of lipoylation deficient E. coli. Lpa can be truncated to 60% of its original size with only a partial loss of activity, resulting in a smaller probe that can be used to study the effects of alpha-ketoacid dehydrogenase inactivation in vivo.

Published

2009

37. Crystal structure of lipoate-bound lipoate ligase 1, LipL1, from Plasmodium falciparum

Author

Sean T. Prigge, Alfredo J. Guerra, and Gustavo A. Afanador

Subjects

0301 basic medicine, chemistry.chemical_classification, DNA ligase, biology, 030106 microbiology, Plasmodium falciparum, Crystal structure, Mitochondrion, biology.organism_classification, Biochemistry, In vitro, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, Lipoylation, Biotin, chemistry, Structural Biology, parasitic diseases, Lipoate-protein ligase, Molecular Biology

Abstract

Plasmodium falciparum lipoate protein ligase 1 (PfLipL1) is an ATP-dependent ligase that belongs to the biotin/lipoate A/B protein ligase family (PFAM PF03099). PfLipL1 is the only known canonical lipoate ligase in Pf and functions as a redox switch between two lipoylation routes in the parasite mitochondrion. Here, we report the crystal structure of a deletion construct of PfLipL1 (PfLipL1Δ243-279 ) bound to lipoate, and validate the lipoylation activity of this construct in both an in vitro lipoylation assay and a cell-based lipoylation assay. This characterization represents the first step in understanding the redox dependence of the lipoylation mechanism in malaria parasites. Proteins 2017; 85:1777-1783. © 2017 Wiley Periodicals, Inc.

Published

2017

38. Metabolic alterations in the erythrocyte during blood-stage development of the malaria parasite

Author

Jaques Reifman, Anders Wallqvist, Shivendra G. Tewari, Russell P. Swift, and Sean T. Prigge

Subjects

0301 basic medicine, lcsh:Arctic medicine. Tropical medicine, Erythrocytes, lcsh:RC955-962, 030106 microbiology, Plasmodium falciparum, Parasitemia, Microbiology, lcsh:Infectious and parasitic diseases, 03 medical and health sciences, Metabolomics, Metabolome, Parasite hosting, lcsh:RC109-216, Malaria, Falciparum, Lysophosphatidylglycerol, biology, Research, Lipid metabolism, Host–parasite metabolism, Metabolism, biology.organism_classification, Sphingolipid, In vitro, 3. Good health, Blood-stage infection, 030104 developmental biology, Infectious Diseases, Parasitology, Polyunsaturated fatty acids

Abstract

Background Human blood cells (erythrocytes) serve as hosts for the malaria parasite Plasmodium falciparum during its 48-h intraerythrocytic developmental cycle (IDC). Established in vitro protocols allow for the study of host–parasite interactions during this phase and, in particular, high-resolution metabolomics can provide a window into host–parasite interactions that support parasite development. Methods Uninfected and parasite-infected erythrocyte cultures were maintained at 2% haematocrit for the duration of the IDC, while parasitaemia was maintained at 7% in the infected cultures. The parasite-infected cultures were synchronized to obtain stage-dependent information of parasite development during the IDC. Samples were collected in quadruplicate at six time points from the uninfected and parasite-infected cultures and global metabolomics was used to analyse cell fractions of these cultures. Results In uninfected and parasite-infected cultures during the IDC, 501 intracellular metabolites, including 223 lipid metabolites, were successfully quantified. Of these, 19 distinct metabolites were present only in the parasite-infected culture, 10 of which increased to twofold in abundance during the IDC. This work quantified approximately five times the metabolites measured in previous studies of similar research scope, which allowed for more detailed analyses. Enrichment in lipid metabolism pathways exhibited a time-dependent association with different classes of lipids during the IDC. Specifically, enrichment occurred in sphingolipids at the earlier stages, and subsequently in lysophospholipid and phospholipid metabolites at the intermediate and end stages of the IDC, respectively. In addition, there was an accumulation of 18-, 20-, and 22-carbon polyunsaturated fatty acids, which produce eicosanoids and promote gametocytogenesis in infected erythrocyte cultures. Conclusions The current study revealed a number of heretofore unidentified metabolic components of the host–parasite system, which the parasite may exploit in a time-dependent manner to grow over the course of its development in the blood stage. Notably, the analyses identified components, such as precursors of immunomodulatory molecules, stage-dependent lipid dynamics, and metabolites, unique to parasite-infected cultures. These conclusions are reinforced by the metabolic alterations that were characterized during the IDC, which were in close agreement with those known from previous studies of blood-stage infection.

Published

2019

39. The NTP generating activity of pyruvate kinase II is critical for apicoplast maintenance in

Author

Russell P, Swift, Krithika, Rajaram, Cyrianne, Keutcha, Hans B, Liu, Bobby, Kwan, Amanda, Dziedzic, Anne E, Jedlicka, and Sean T, Prigge

Subjects

Microbiology and Infectious Disease, apicoplast, plasmodium, carbon metabolism, Biochemistry and Chemical Biology, Plasmodium falciparum, Pyruvate Kinase, Protozoan Proteins, malaria, Apicoplasts, P. falciparum, microarray, Research Article

Abstract

The apicoplast of Plasmodium falciparum parasites is believed to rely on the import of three-carbon phosphate compounds for use in organelle anabolic pathways, in addition to the generation of energy and reducing power within the organelle. We generated a series of genetic deletions in an apicoplast metabolic bypass line to determine which genes involved in apicoplast carbon metabolism are required for blood-stage parasite survival and organelle maintenance. We found that pyruvate kinase II (PyrKII) is essential for organelle maintenance, but that production of pyruvate by PyrKII is not responsible for this phenomenon. Enzymatic characterization of PyrKII revealed activity against all NDPs and dNDPs tested, suggesting that it may be capable of generating a broad range of nucleotide triphosphates. Conditional mislocalization of PyrKII resulted in decreased transcript levels within the apicoplast that preceded organelle disruption, suggesting that PyrKII is required for organelle maintenance due to its role in nucleotide triphosphate generation.

Published

2019

40. Author response for 'Development of a conditional localization approach to control apicoplast protein trafficking in malaria parasites'

Author

null Aleah D. Roberts, null Sethu C. Nair, null Alfredo J. Guerra, and null Sean T. Prigge

Published

2019

41. Decision letter: The Plasmodium liver-specific protein 2 (LISP2) is an early marker of liver stage development

Author

Sean T. Prigge

Subjects

Specific protein, Liver stage, Biology, biology.organism_classification, Virology, Plasmodium

Published

2019

42. A mevalonate bypass system facilitates elucidation of plastid biology in malaria parasites

Author

Krista Ann Matthews, Namandjé N. Bumpus, Hugo Jhun, Hans B. Liu, Krithika Rajaram, Sean T. Prigge, Aleah D. Roberts, Anne E. Jedlicka, Russell P. Swift, Amanda Dziedzic, Shivendra G. Tewari, and Anders Wallqvist

Subjects

Plasmodium, Protozoan Proteins, Isopentenyl pyrophosphate, Azithromycin, Biochemistry, Transcriptome, chemistry.chemical_compound, Drug Metabolism, Medicine and Health Sciences, Metabolites, Plastids, Biology (General), Protein Metabolism, Protozoans, 0303 health sciences, 030302 biochemistry & molecular biology, Malarial Parasites, Eukaryota, Isoprenoids, Lipids, Anti-Bacterial Agents, 3. Good health, Cell biology, Cellular Structures and Organelles, Research Article, medicine.drug, QH301-705.5, Plasmodium falciparum, Immunology, Mevalonic Acid, Apicoplasts, Biology, Microbiology, 03 medical and health sciences, Hemiterpenes, Organophosphorus Compounds, Metabolomics, Fosfomycin, Virology, Parasite Groups, Organelle, Parasitic Diseases, Genetics, medicine, Animals, Humans, Parasites, Pharmacokinetics, Plastid, Molecular Biology, 030304 developmental biology, Pharmacology, Apicoplast, Organisms, Biology and Life Sciences, Cell Biology, RC581-607, medicine.disease, Parasitic Protozoans, Fosmidomycin, Malaria, Metabolism, chemistry, Parasitology, Immunologic diseases. Allergy, Apicomplexa

Abstract

Malaria parasites rely on a plastid organelle for survival during the blood stages of infection. However, the entire organelle is dispensable as long as the isoprenoid precursor, isopentenyl pyrophosphate (IPP), is supplemented in the culture medium. We engineered parasites to produce isoprenoid precursors from a mevalonate-dependent pathway, creating a parasite line that replicates normally after the loss of the apicoplast organelle. We show that carbon-labeled mevalonate is specifically incorporated into isoprenoid products, opening new avenues for researching this essential class of metabolites in malaria parasites. We also show that essential apicoplast proteins, such as the enzyme target of the drug fosmidomycin, can be deleted in this mevalonate bypass parasite line, providing a new method to determine the roles of other important apicoplast-resident proteins. Several antibacterial drugs kill malaria parasites by targeting basic processes, such as transcription, in the organelle. We used metabolomic and transcriptomic methods to characterize parasite metabolism after azithromycin treatment triggered loss of the apicoplast and found that parasite metabolism and the production of apicoplast proteins is largely unaltered. These results provide insight into the effects of apicoplast-disrupting drugs, several of which have been used to treat malaria infections in humans. Overall, the mevalonate bypass system provides a way to probe essential aspects of apicoplast biology and study the effects of drugs that target apicoplast processes., Author summary Malaria parasites rely on an organelle called the apicoplast for growth and survival. Antimalarial drugs such as azithromycin inhibit basic processes in the apicoplast and result in the disruption of the organelle. Surprisingly, addition of a single metabolite, isopentenyl pyrophosphate (IPP), allows the parasites to survive in culture after disruption of the apicoplast. Unfortunately, using IPP to study this phenomenon has several limitations: IPP is prohibitively expensive, has to be used at high concentrations, and has a half-life less than 5 hours. To address these problems, we engineered parasites to express four enzymes from an alternative pathway capable of producing IPP in the parasites. We validated this new system and used it to metabolically label essential metabolites, to delete an essential apicoplast protein, and to characterize the state of apicoplast-disrupted parasites. A key finding from these studies comes from transcriptomic and metabolomic analysis of parasites treated with the drug azithromycin. We found that apicoplast disruption results in few changes in parasite metabolism. In particular, the expression of hundreds of nuclear-encoded apicoplast proteins are not affected by disruption of the apicoplast organelle, making it likely that apicoplast metabolic pathways and processes are still functional in apicoplast-disrupted parasites.

Published

2020

43. Using Lipoamidase as a Novel Probe To Interrogate the Importance of Lipoylation in Plasmodium falciparum

Author

Sean T. Prigge, Hugo Jhun, and Maroya S. Walters

Subjects

0301 basic medicine, Molecular Biology and Physiology, Lipoylation, Plasmodium falciparum, Protozoan Proteins, malaria, Apicoplasts, Mitochondrion, Microbiology, Cofactor, Amidohydrolases, 03 medical and health sciences, chemistry.chemical_compound, lipoate, Acetyl Coenzyme A, Virology, mitochondrion, Apicoplast, biology, acetyl-CoA, biology.organism_classification, lipoic acid, QR1-502, Mitochondria, 3. Good health, lipoamidase, Lipoic acid, Cytosol, 030104 developmental biology, chemistry, Biochemistry, Mutation, biology.protein, Research Article, Protein lipoylation

Abstract

Lipoate is an essential cofactor for a small number of enzymes that are important for central metabolism. Malaria parasites require lipoate scavenged from the human host for growth and survival; however, it is not known why this cofactor is so important. To address this question, we designed a probe of lipoate activity based on the bacterial enzyme lipoamidase (Lpa). Expression of this probe in different subcellular locations allowed us to define the mitochondrion as the compartment housing essential lipoate metabolism. To gain further insight into the specific uses of lipoate in the mitochondrion, we designed a series of catalytically attenuated probes and employed the probes in conjunction with a chemical bypass system. These studies suggest that two lipoylated proteins are required for parasite survival. We were able to express Lpa with different catalytic abilities in different subcellular compartments and driven by different promoters, demonstrating the versatility of this tool and suggesting that it can be used as a probe of lipoate metabolism in other organisms., Lipoate is a redox active cofactor that is covalently bound to key enzymes of oxidative metabolism. Plasmodium falciparum is auxotrophic for lipoate during the intraerythrocytic stages, but it is not known whether lipoate attachment to protein is required or whether attachment is required in a specific subcellular compartment of the parasite. To address these questions, we used an enzyme called lipoamidase (Lpa) as a probe of lipoate metabolism. Lpa was first described in Enterococcus faecalis, and it specifically cleaves protein-bound lipoate, inactivating enzymes requiring this cofactor. Enzymatically active Lpa could be expressed in the cytosol of P. falciparum without any effect on protein lipoylation or parasite growth. Similarly, Lpa could be expressed in the apicoplast, and although protein lipoylation was reduced, parasite growth was not inhibited. By contrast, while an inactive mutant of Lpa could be expressed in the mitochondrion, the active enzyme could not. We designed an attenuated mutant of Lpa and found that this enzyme could be expressed in the parasite mitochondrion, but only in conjunction with a chemical bypass system. These studies suggest that acetyl-CoA production and a cryptic function of the H protein are both required for parasite survival. Our study validates Lpa as a novel probe of metabolism that can be used in other systems and provides new insight into key aspects of mitochondrial metabolism that are responsible for lipoate auxotrophy in malaria parasites.

Published

2018

44. Author response for 'Development of a conditional localization approach to control apicoplast protein trafficking in malaria parasites'

Author

Alfredo J. Guerra, Sethu C. Nair, Sean T. Prigge, and Aleah D. Roberts

Subjects

Apicoplast, medicine, Computational biology, Biology, medicine.disease, Protein trafficking, Malaria

Published

2018

45. Decision letter: Elucidating the mitochondrial proteome of Toxoplasma gondii reveals the presence of a divergent cytochrome c oxidase

Author

Sean T. Prigge and Akhil B. Vaidya

Subjects

biology, Biochemistry, biology.protein, Toxoplasma gondii, Cytochrome c oxidase, biology.organism_classification, Mitochondrial proteome

Published

2018

46. Host biotin is required for liver stage development in malaria parasites

Author

Satish Mishra, Krithika Rajaram, Sean T. Prigge, Christopher D. Goodman, Teegan A. Dellibovi-Ragheb, Photini Sinnis, Daniel R.T. Ragheb, Geoffrey I. McFadden, Maroya S. Walters, Krista Ann Matthews, and Hugo Jhun

Subjects

0301 basic medicine, Plasmodium, Protozoan Proteins, Biotin, Apicoplasts, Microbiology, Host-Parasite Interactions, Mice, 03 medical and health sciences, chemistry.chemical_compound, medicine, Animals, Humans, Carbon-Nitrogen Ligases, Apicoplast, apicoplast, Multidisciplinary, biology, Acetyl-CoA carboxylase, Hep G2 Cells, Biological Sciences, medicine.disease, biology.organism_classification, holocarboxylase synthetase, Malaria, 3. Good health, Pyruvate carboxylase, acetyl-CoA carboxylase, 030104 developmental biology, Liver, PNAS Plus, chemistry, Biotinylation, Holocarboxylase synthetase, biotin ligase

Abstract

Significance Malaria parasites require certain host nutrients for growth and survival. In this project, we examined the role of the human vitamin biotin in all stages of the malaria life cycle. We cultured blood- and liver-stage malaria parasites in the absence of biotin and found that, whereas blood-stage replication was unaffected, liver-stage parasites deprived of biotin were no longer capable of establishing a blood-stage infection. Interestingly, biotin depletion resulted in more severe developmental defects than the genetic disruption of parasite biotin metabolism. This finding suggests that host biotin metabolism also contributes to parasite development. Because neither the parasite nor the human host can synthesize biotin, parasite infectivity may be affected by the nutritional status of the host., Acetyl-CoA carboxylase (ACC) is a biotin-dependent enzyme that is the target of several classes of herbicides. Malaria parasites contain a plant-like ACC, and this is the only protein predicted to be biotinylated in the parasite. We found that ACC is expressed in the apicoplast organelle in liver- and blood-stage malaria parasites; however, it is activated through biotinylation only in the liver stages. Consistent with this observation, deletion of the biotin ligase responsible for ACC biotinylation does not impede blood-stage growth, but results in late liver-stage developmental defects. Biotin depletion increases the severity of the developmental defects, demonstrating that parasite and host biotin metabolism are required for normal liver-stage progression. This finding may link the development of liver-stage malaria parasites to the nutritional status of the host, as neither the parasite nor the human host can synthesize biotin.

Published

2018

47. Redox-dependent lipoylation of mitochondrial proteins inPlasmodium falciparum

Author

Jolyn E. Gisselberg, David Bartee, Krista Ann Matthews, Gustavo A. Afanador, Caren L. Freel Meyers, Maroya S. Walters, and Sean T. Prigge

Subjects

chemistry.chemical_classification, DNA ligase, biology, Plasmodium falciparum, Dehydrogenase, Mitochondrion, biology.organism_classification, Microbiology, Homology (biology), Lipoylation, Biochemistry, chemistry, Ligase activity, Branched-chain alpha-keto acid dehydrogenase complex, Molecular Biology

Abstract

Lipoate scavenging from the human host is essential for malaria parasite survival. Scavenged lipoate is covalently attached to three parasite proteins: the H-protein and the E2 subunits of branched chain amino acid dehydrogenase (BCDH) and α-ketoglutarate dehydrogenase (KDH). We show mitochondrial localization for the E2 subunits of BCDH and KDH, similar to previously localized H-protein, demonstrating that all three lipoylated proteins reside in the parasite mitochondrion. The lipoate ligase 1, LipL1, has been shown to reside in the mitochondrion and it catalyses the lipoylation of the H-protein; however, we show that LipL1 alone cannot lipoylate BCDH or KDH. A second mitochondrial protein with homology to lipoate ligases, LipL2, does not show ligase activity and is not capable of lipoylating any of the mitochondrial substrates. Instead, BCDH and KDH are lipoylated through a novel mechanism requiring both LipL1 and LipL2. This mechanism is sensitive to redox conditions where BCDH and KDH are exclusively lipoylated under strong reducing conditions in contrast to the H-protein which is preferentially lipoylated under less reducing conditions. Thus, malaria parasites contain two different routes of mitochondrial lipoylation, an arrangement that has not been described for any other organism.

Published

2014

48. The benzimidazole based drugs show good activity against T. gondii but poor activity against its proposed enoyl reductase enzyme target

Author

Martin J. McPhillie, David W. Rice, Craig W. Roberts, Rima McLeod, Colin W. G. Fishwick, Craig Wilkinson, Gustavo A. Afanador, Ying Zhou, Sean T. Prigge, Shaun Rawson, Farzana Khaliq, Stephen P. Muench, and Stuart Woods

Subjects

Benzimidazole, Antiparasitic, medicine.drug_class, Clinical Biochemistry, Pharmaceutical Science, Microbial Sensitivity Tests, Reductase, Crystallography, X-Ray, Biochemistry, Article, Enoyl reductase, Inhibitory Concentration 50, chemistry.chemical_compound, Enzyme activator, Drug Delivery Systems, Oxidoreductase, parasitic diseases, Drug Discovery, medicine, Molecular Biology, chemistry.chemical_classification, Antiparasitic Agents, Molecular Structure, Organic Chemistry, Enoyl-(Acyl-Carrier-Protein) Reductase (NADH), Antiparasitic agent, Triclosan, 3. Good health, Enzyme Activation, Enzyme, chemistry, Molecular Medicine, Benzimidazoles, NAD+ kinase, Toxoplasma

Abstract

The enoyl acyl-carrier protein reductase (ENR) enzyme of the apicomplexan parasite family has been intensely studied for antiparasitic drug design for over a decade, with the most potent inhibitors targeting the NAD+ bound form of the enzyme. However, the higher affinity for the NADH co-factor over NAD+ and its availability in the natural environment makes the NADH complex form of ENR an attractive target. Herein, we have examined a benzimidazole family of inhibitors which target the NADH form of Francisella ENR, but despite good efficacy against Toxoplasma gondii, the IC50 for T. gondii ENR is poor, with no inhibitory activity at 1μM. Moreover similar benzimidazole scaffolds are potent against fungi which lack the ENR enzyme and as such we believe that there may be significant off target effects for this family of inhibitors.

Published

2014

49. Modification of Triclosan Scaffold in Search of Improved Inhibitors for Enoyl-Acyl Carrier Protein (ACP) Reductase inToxoplasma gondii

Author

Gustavo A. Afanador, Kamal El Bissati, Rima McLeod, Patty J. Lee, Sean T. Prigge, Alan P. Kozikowski, Jozef Stec, Stuart Woods, Jennifer M. Auschwitz, Ying Zhou, Mark Hickman, Susan E. Leed, Stephen P. Muench, Craig W. Roberts, Bo Shiun Lai, David W. Rice, Alina Fomovska, and Caroline Sommervile

Subjects

Models, Molecular, Plasmodium falciparum, Antiprotozoal Agents, Reductase, Biochemistry, Permeability, Article, law.invention, Microbiology, Mice, Structure-Activity Relationship, chemistry.chemical_compound, Parasitic Sensitivity Tests, law, parasitic diseases, Drug Discovery, Animals, Humans, Potency, Structure–activity relationship, Enzyme Inhibitors, General Pharmacology, Toxicology and Pharmaceutics, Pharmacology, chemistry.chemical_classification, Dose-Response Relationship, Drug, Molecular Structure, biology, Organic Chemistry, Toxoplasma gondii, biology.organism_classification, Enoyl-(Acyl-Carrier-Protein) Reductase (NADH), Triclosan, Disease Models, Animal, Acyl carrier protein, Enzyme, chemistry, Recombinant DNA, biology.protein, Molecular Medicine, Caco-2 Cells, Toxoplasma, Toxoplasmosis

Abstract

Through our focused effort to discover new and effective agents against toxoplasmosis, a structure-based drug design approach was used to develop a series of potent inhibitors of the enoyl-acyl carrier protein (ACP) reductase (ENR) enzyme in Toxoplasma gondii (TgENR). Modifications to positions 5 and 4' of the well-known ENR inhibitor triclosan afforded a series of 29 new analogues. Among the resulting compounds, many showed high potency and improved physicochemical properties in comparison with the lead. The most potent compounds 16 a and 16 c have IC50 values of 250 nM against Toxoplasma gondii tachyzoites without apparent toxicity to the host cells. Their IC50 values against recombinant TgENR were found to be 43 and 26 nM, respectively. Additionally, 11 other analogues in this series had IC50 values ranging from 17 to 130 nM in the enzyme-based assay. With respect to their excellent in vitro activity as well as improved drug-like properties, the lead compounds 16 a and 16 c are deemed to be excellent starting points for the development of new medicines to effectively treat Toxoplasma gondii infections.

Published

2013

50. A key role for lipoic acid synthesis duringPlasmodiumliver stage development

Author

Christina Deschermeier, David A. Fidock, Sonia Gulati, T. R. Santha Kumar, Brie Falkard, Krista Ann Matthews, Leonie Hecht, Philipp P. Henrich, Sean T. Prigge, Photini Sinnis, Rebecca E. Lewis, Volker Heussler, Micah J. Manary, and Elizabeth A. Winzeler

Subjects

chemistry.chemical_classification, Apicoplast, biology, Immunology, Fatty acid, Lipid metabolism, Mitochondrion, biology.organism_classification, Pyruvate dehydrogenase complex, Microbiology, Plasmodium, Lipoic acid, chemistry.chemical_compound, chemistry, Biochemistry, Virology, parasitic diseases, lipids (amino acids, peptides, and proteins), Plasmodium berghei

Abstract

The successful navigation of malaria parasites through their life cycle, which alternates between vertebrate hosts and mosquito vectors, requires a complex interplay of metabolite synthesis and salvage pathways. Using the rodent parasite Plasmodium berghei, we have explored the synthesis and scavenging pathways for lipoic acid, a short-chain fatty acid derivative that regulates the activity of α-ketoacid dehydrogenases including pyruvate dehydrogenase. In Plasmodium, lipoic acid is either synthesized de novo in the apicoplast or is scavenged from the host into the mitochondrion. Our data show that sporozoites lacking the apicoplast lipoic acid protein ligase LipB are markedly attenuated in their infectivity for mice, and in vitro studies document a very late liver stage arrest shortly before the final phase of intra-hepaticparasite maturation. LipB-deficient asexual blood stage parasites show unimpaired rates of growth in normal in vitro or in vivo conditions. However, these parasites showed reduced growth in lipid-restricted conditions induced by treatment with the lipoic acid analogue 8-bromo-octanoate or with the lipid-reducing agent clofibrate. This finding has implications for understanding Plasmodium pathogenesis in malnourished children that bear the brunt of malarial disease. This study also highlights the potential of exploiting lipid metabolism pathways for the design of genetically attenuated sporozoite vaccines.

Published

2013