Significance of Plasmodium berghei Amino Acid Transporter 1 in Food Vacuole Functionality and Its Association with Cerebral Pathogenesis

Food vacuoles of the malaria parasite are involved in the degradation of red blood cell hemoglobin. The amino acids derived from hemoglobin degradation support parasite growth, and the heme released is detoxified into hemozoin. ABSTRACT The food vacuole plays a central role in the blood stage of parasite development by digesting host hemoglobin acquired from red blood cells and detoxifying the host heme released during hemoglobin digestion into hemozoin. Blood-stage parasites undergo periodic schizont bursts, releasing food vacuoles containing hemozoin. Clinical studies in malaria-infected patients and in vivo animal studies have shown the association of hemozoin with disease pathogenesis and abnormal host immune responses in malaria. Here, we perform a detailed in vivo characterization of putative Plasmodium berghei amino acid transporter 1 localized in the food vacuole to understand its significance in the malaria parasite. We show that the targeted deletion of amino acid transporter 1 in Plasmodium berghei leads to a swollen food vacuole phenotype with the accumulation of host hemoglobin-derived peptides. Plasmodium berghei amino acid transporter 1-knockout parasites produce less hemozoin, and the hemozoin crystals display a thin morphology compared with wild-type parasites. The knockout parasites show reduced sensitivity to chloroquine and amodiaquine by showing recrudescence. More importantly, mice infected with the knockout parasites are protected from cerebral malaria and display reduced neuronal inflammation and cerebral complications. Genetic complementation of the knockout parasites restores the food vacuole morphology with hemozoin levels similar to that of wild-type parasites, causing cerebral malaria in the infected mice. The knockout parasites also show a significant delay in male gametocyte exflagellation. Our findings highlight the significance of amino acid transporter 1 in food vacuole functionality and its association with malaria pathogenesis and gametocyte development. IMPORTANCE Food vacuoles of the malaria parasite are involved in the degradation of red blood cell hemoglobin. The amino acids derived from hemoglobin degradation support parasite growth, and the heme released is detoxified into hemozoin. Antimalarials such as quinolines target hemozoin formation in the food vacuole. Food vacuole transporters transport hemoglobin-derived amino acids and peptides from the food vacuole to the parasite cytosol. Such transporters are also associated with drug resistance. Here, we show that the deletion of amino acid transporter 1 in Plasmodium berghei leads to swollen food vacuoles with the accumulation of hemoglobin-derived peptides. The transporter-deleted parasites generate less hemozoin with thin crystal morphology and show reduced sensitivity to quinolines. Mice infected with transporter-deleted parasites are protected from cerebral malaria. There is also a delay in male gametocyte exflagellation, affecting transmission. Our findings uncover the functional significance of amino acid transporter 1 in the life cycle of the malaria parasite.

[1]  V. Costa,et al.  The Multifaceted Role of Annexin A1 in Viral Infections , 2023, Cells.

[2]  G. Padmanaban,et al.  Malaria parasite heme biosynthesis promotes and griseofulvin protects against cerebral malaria in mice , 2022, Nature Communications.

[3]  P. Jagannathan,et al.  Malaria in 2022: Increasing challenges, cautious optimism , 2022, Nature Communications.

[4]  R. Basir,et al.  MODULATING EFFECTS OF IL-4, IL-10 AND IL-13 ON THE COURSE OF PLASMODIUM BERGHEI MALARIA INFECTION IN MICE , 2021, Journal of Health and Translational Medicine.

[5]  E. Hempelmann,et al.  Malaria Pigment Crystals: The Achilles′ Heel of the Malaria Parasite , 2021, ChemMedChem.

[6]  P. E. Van den Steen,et al.  Hemozoin in Malarial Complications: More Questions Than Answers. , 2020, Trends in parasitology.

[7]  M. Llinás,et al.  The natural function of the malaria parasite’s chloroquine resistance transporter , 2020, Nature Communications.

[8]  J. Abrahams,et al.  A lipocalin mediates unidirectional heme biomineralization in malaria parasites , 2020, Proceedings of the National Academy of Sciences.

[9]  Rowena E. Martin The transportome of the malaria parasite , 2019, Biological reviews of the Cambridge Philosophical Society.

[10]  D. Gowda,et al.  Parasite Recognition and Signaling Mechanisms in Innate Immune Responses to Malaria , 2018, Front. Immunol..

[11]  S. Avery,et al.  Heterologous Expression of a Novel Drug Transporter from the Malaria Parasite Alters Resistance to Quinoline Antimalarials , 2018, Scientific Reports.

[12]  Victoria C. Corey,et al.  Mapping the malaria parasite druggable genome by using in vitro evolution and chemogenomics , 2017, Science.

[13]  A. Craig,et al.  A quantitative brain map of experimental cerebral malaria pathology , 2017, PLoS pathogens.

[14]  John M. Pisciotta,et al.  Quantitative characterization of hemozoin in Plasmodium berghei and vivax , 2017, International journal for parasitology. Drugs and drug resistance.

[15]  M. Molyneux,et al.  Cytokine Profiles in Malawian Children Presenting with Uncomplicated Malaria, Severe Malarial Anemia, and Cerebral Malaria , 2017, Clinical and Vaccine Immunology.

[16]  X. Su,et al.  Genome-wide association analysis identifies genetic loci associated with resistance to multiple antimalarials in Plasmodium falciparum from China-Myanmar border , 2016, Scientific Reports.

[17]  K. Matuschewski,et al.  Functional profiles of orphan membrane transporters in the life cycle of the malaria parasite , 2016, Nature Communications.

[18]  M. Llinás,et al.  Sequestration and metabolism of host cell arginine by the intraerythrocytic malaria parasite Plasmodium falciparum , 2016, Cellular microbiology.

[19]  M. Llinás,et al.  Mutations in the Plasmodium falciparum chloroquine resistance transporter, PfCRT, enlarge the parasite’s food vacuole and alter drug sensitivities , 2015, Scientific Reports.

[20]  Douglas T. Golenbock,et al.  Innate sensing of malaria parasites , 2014, Nature Reviews Immunology.

[21]  Martin Olivier,et al.  Malarial Pigment Hemozoin and the Innate Inflammatory Response , 2014, Front. Immunol..

[22]  Kellen L. Olszewski,et al.  Metabolic QTL Analysis Links Chloroquine Resistance in Plasmodium falciparum to Impaired Hemoglobin Catabolism , 2014, PLoS genetics.

[23]  V. S. Reddy,et al.  Protein complex directs hemoglobin-to-hemozoin formation in Plasmodium falciparum , 2013, Proceedings of the National Academy of Sciences.

[24]  D. Hansen,et al.  Isolation and analysis of brain-sequestered leukocytes from Plasmodium berghei ANKA-infected mice. , 2013, Journal of visualized experiments : JoVE.

[25]  B. Wickstead,et al.  A Unique Protein Phosphatase with Kelch-Like Domains (PPKL) in Plasmodium Modulates Ookinete Differentiation, Motility and Invasion , 2012, PLoS pathogens.

[26]  P. E. Van den Steen,et al.  Improved methods for haemozoin quantification in tissues yield organ-and parasite-specific information in malaria-infected mice , 2012, Malaria Journal.

[27]  K. Reiss,et al.  Digestive vacuole of Plasmodium falciparum released during erythrocyte rupture dually activates complement and coagulation. , 2012, Blood.

[28]  A. Craig,et al.  Cerebral malaria pathogenesis: revisiting parasite and host contributions. , 2012, Future microbiology.

[29]  L. Cui,et al.  Gametocytogenesis in malaria parasite: commitment, development and regulation. , 2011, Future microbiology.

[30]  K. Reiss,et al.  Digestive vacuoles of Plasmodium falciparum are selectively phagocytosed by and impair killing function of polymorphonuclear leukocytes. , 2011, Blood.

[31]  P. Uhlén,et al.  PfMDR1: Mechanisms of Transport Modulation by Functional Polymorphisms , 2011, PloS one.

[32]  A. Pain,et al.  Transition of Plasmodium Sporozoites into Liver Stage-Like Forms Is Regulated by the RNA Binding Protein Pumilio , 2011, PLoS pathogens.

[33]  F. Ginhoux,et al.  CD8+ T Cells and IFN-γ Mediate the Time-Dependent Accumulation of Infected Red Blood Cells in Deep Organs during Experimental Cerebral Malaria , 2011, PloS one.

[34]  M. Olivier,et al.  Innate inflammatory response to the malarial pigment hemozoin. , 2010, Microbes and infection.

[35]  G. Zimmerman,et al.  Persistent cognitive impairment after cerebral malaria: models, mechanisms and adjunctive therapies , 2010, Expert review of anti-infective therapy.

[36]  K. Haldar,et al.  A Rapid Murine Coma and Behavior Scale for Quantitative Assessment of Murine Cerebral Malaria , 2010, PloS one.

[37]  F. Russel,et al.  The ABCs of multidrug resistance in malaria. , 2010, Trends in parasitology.

[38]  K. Kirk,et al.  Membrane transport proteins of the malaria parasite , 2009, Molecular microbiology.

[39]  F. Sutterwala,et al.  Malarial Hemozoin Activates the NLRP3 Inflammasome through Lyn and Syk Kinases , 2009, PLoS pathogens.

[40]  Kellen L. Olszewski,et al.  Host-parasite interactions revealed by Plasmodium falciparum metabolomics. , 2009, Cell host & microbe.

[41]  L. Rénia,et al.  Control of pathogenic CD8+ T cell migration to the brain by IFN‐γ during experimental cerebral malaria , 2008, Parasite immunology.

[42]  H. Vial,et al.  Food vacuole proteome of the malarial parasite Plasmodium falciparum , 2008, PROTEOMICS - Clinical Applications.

[43]  J. Andersen,et al.  HDP—A Novel Heme Detoxification Protein from the Malaria Parasite , 2008, PLoS pathogens.

[44]  S. Dalal,et al.  Roles for Two Aminopeptidases in Vacuolar Hemoglobin Catabolism in Plasmodium falciparum* , 2007, Journal of Biological Chemistry.

[45]  M. Mota,et al.  Heme oxygenase-1 and carbon monoxide suppress the pathogenesis of experimental cerebral malaria , 2007, Nature Medicine.

[46]  B. Monks,et al.  Malaria hemozoin is immunologically inert but radically enhances innate responses by presenting malaria DNA to Toll-like receptor 9 , 2007, Proceedings of the National Academy of Sciences.

[47]  Caroline Rae,et al.  Immunopathogenesis of cerebral malaria. , 2006, International journal for parasitology.

[48]  C. Janse,et al.  Development and application of a positive–negative selectable marker system for use in reverse genetics in Plasmodium , 2006, Nucleic acids research.

[49]  A. Craig,et al.  The role of ICAM-1 in Plasmodium falciparum cytoadherence. , 2005, European journal of cell biology.

[50]  Kiaran Kirk,et al.  The malaria parasite's chloroquine resistance transporter is a member of the drug/metabolite transporter superfamily. , 2004, Molecular biology and evolution.

[51]  O. Doumbo,et al.  Serum Levels of the Proinflammatory Cytokines Interleukin-1 Beta (IL-1β), IL-6, IL-8, IL-10, Tumor Necrosis Factor Alpha, and IL-12(p70) in Malian Children with Severe Plasmodium falciparum Malaria and Matched Uncomplicated Malaria or Healthy Controls , 2004, Infection and Immunity.

[52]  Christopher J. Tonkin,et al.  Localization of organellar proteins in Plasmodium falciparum using a novel set of transfection vectors and a new immunofluorescence fixation method. , 2004, Molecular and biochemical parasitology.

[53]  P. Rosenthal,et al.  Gene disruption confirms a critical role for the cysteine protease falcipain-2 in hemoglobin hydrolysis by Plasmodium falciparum. , 2004, Proceedings of the National Academy of Sciences of the United States of America.

[54]  B. Tekwani,et al.  Spectrophotometric determination of de novo hemozoin/beta-hematin formation in an in vitro assay. , 2004, Analytical biochemistry.

[55]  D. Sullivan,et al.  The shape and size of hemozoin crystals distinguishes diverse Plasmodium species. , 2003, Molecular and biochemical parasitology.

[56]  T. Tiffert,et al.  Excess hemoglobin digestion and the osmotic stability of Plasmodium falciparum-infected red blood cells. , 2003, Blood.

[57]  Emmanuel Quevillon,et al.  The Plasmodium falciparum family of Rab GTPases. , 2003, Gene.

[58]  Jun Liu,et al.  Four plasmepsins are active in the Plasmodium falciparum food vacuole, including a protease with an active-site histidine , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[59]  Y Zhai,et al.  A web-based program (WHAT) for the simultaneous prediction of hydropathy, amphipathicity, secondary structure and transmembrane topology for a single protein sequence. , 2001, Journal of molecular microbiology and biotechnology.

[60]  M. Foley,et al.  Histidine-rich protein 2 of the malaria parasite, Plasmodium falciparum, is involved in detoxification of the by-products of haemoglobin degradation. , 2001, Molecular and biochemical parasitology.

[61]  E. Gulbins,et al.  Streptolysin O‐permeabilized granulocytes shed L‐selectin concomitantly with ceramide generation via neutral sphingomyelinase , 2000, Journal of leukocyte biology.

[62]  L. Rénia,et al.  Involvement of IFN‐γ receptor‐mediated signaling in pathology and anti‐malarial immunity induced by Plasmodium berghei infection , 2000 .

[63]  Kiaran Kirk,et al.  pH Regulation in the Intracellular Malaria Parasite, Plasmodium falciparum , 1999, The Journal of Biological Chemistry.

[64]  D. Goldberg,et al.  Identification and Characterization of Falcilysin, a Metallopeptidase Involved in Hemoglobin Catabolism within the Malaria Parasite Plasmodium falciparum* , 1999, The Journal of Biological Chemistry.

[65]  J. Vennerstrom,et al.  Haematin (haem) polymerization and its inhibition by quinoline antimalarials , 1997 .

[66]  S. Meshnick,et al.  Patterns of haemozoin accumulation in tissue , 1996, Parasitology.

[67]  T. Egan,et al.  Quinoline anti‐malarial drugs inhibit spontaneous formation of β‐haematin (malaria pigment) , 1994 .

[68]  J. Whisstock,et al.  Plasmodium falciparum neutral aminopeptidases: new targets for anti-malarials. , 2010, Trends in biochemical sciences.

[69]  D. Sullivan,et al.  Hemoglobin metabolism in the malaria parasite Plasmodium falciparum. , 1997, Annual review of microbiology.

[70]  K. Tracey,et al.  Malaria-specific metabolite hemozoin mediates the release of several potent endogenous pyrogens (TNF, MIP-1 alpha, and MIP-1 beta) in vitro, and altered thermoregulation in vivo. , 1995, Journal of inflammation.