Your search keyword '"Russell P. Swift"' showing total 21 results

1. 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

2. 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

3. 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

4. The Plasmodium falciparum apicoplast 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

Subjects

plasmodium, MnmA, SufS, iron-sulfur cluster, tRNA modification, Medicine, Science, Biology (General), QH301-705.5

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

5. 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

6. 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

7. 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

8. 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

9. 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

10. 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

11. 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

12. 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

13. 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

14. 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

15. 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

16. 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

17. 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

18. 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

19. 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

20. 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

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

Author

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

Subjects

Immunologic diseases. Allergy, RC581-607, Biology (General), QH301-705.5

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.

Published

2020