Tesi sul tema "Plasmodium parasites"

Persistence of drug resistant Plasmodium falciparum is a major problem to management and control malaria in endemic areas. The focus of this thesis was to study the dynamics of resistant P. falciparum parasites. The study was performed in two African countries: 1) Sudan: Asar village in eastern Sudan, here we examined the persistence of drug sensitive and resistant P. falciparum genotypes among individuals with single-clone and multiple clones infection during the dry season. We genotyped microsatellite loci in the vicinity of the dihydrofolate reductase gene (dhfr) and the dihydropteroate synthase gene (dhps). Microsatellite investigation showed that asymptomatic parasitemia persisted in some patients for several months throughout the dry season and into the next transmission season. In some samples mixed infections were detected, and we noted several cases where the microsatellite haplotype varied from month to month, suggesting turnover of different parasite populations in the blood. This demonstrates that even during asymptomatic infections there can be dynamics within the parasite population in an individual. In addition, we calculated the parasite density throughout the dry season to the next transmission season by using allele-specific quantitative PCR. Parasite density during the dry season fluctuated, but was generally lower than in the first transmission season. A significant difference (P<0.05) between dry and first transmission season was found in regard to the parasite density, whereas no significant difference was observed when dry and second transmission season were compared (P>0.05). 2) Ethiopia: West Arsi zone, one of the malaria endemic zones of the Oromia region. In the first study we determined the prevalence of asymptomatic malaria carriages from November-December 2012. According to PCR the prevalence of sub-microscopic P. falciparum carriage was 19.2%, microscopy-based prevalence was 3.7% while the prevalence was 6.9% using RDT. Based on this, PCR was considered a better tool for measuring Plasmodium prevalence than microscopy and RDT. A second study addressed the genetic diversity of chloroquine resistance (CQR) in P. falciparum by analysing four microsatellite markers in and around the pfcrt gene. Although CQ was withdrawn for more than a decade, 100% of the parasites still carried the Pfcrt K76T mutation. Only the CVIET haplotype was identified. Based on combinations of MS markers, seven different Ethiopian CQR variants (E1-E7) were identified. Both intronic and MS flanking the pfcrt gene showed low levels of diversity.

The development of a vaccine is essential for the elimination and eventual eradication of malaria. However, despite many years of effort, a successful malaria vaccine has not yet been achieved. Many of the subunit vaccine candidates tested in clinical trials have provided limited efficacy; therefore, efforts to develop an effective vaccine against malaria need to continue. The development of a whole parasite blood-stage vaccine would maximise the number of blood-stage antigens presented to the immune system, including conserved parasite antigens. Chemical treatment has been used to develop attenuated whole organism vaccines against pathogens, such as viruses. A blood-stage vaccine approach using DNA- binding drugs to chemically attenuate Plasmodium parasites was first demonstrated using ring stage Plasmodium chabaudi parasites in mice. However, it was not clear whether this approach would apply to other parasites and as such have potential for translation to human malaria species. We have thus tested the use of these drugs as attenuating agents for another blood-stage Plasmodium spp., Plasmodium yoelii.
Thesis (PhD Doctorate)
Doctor of Philosophy (PhD)
Institute for Glycomics
Science, Environment, Engineering and Technology
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Malaria causes substantial morbidity and mortality worldwide. Although there has been a considerable decline in global malaria incidence and mortality rates since 2000, it is estimated that more than 400,000 deaths occurred in 2015 as a result of this parasitic disease. The lack of a broadly effective licensed vaccine and the threat of malaria parasite resistance to current drugs means there is an urgent need for the development of new therapies with novel parasite targets. With a renewed call for global malaria eradication, novel therapeutic strategies are crucial to continue progress achieved over the last decade in combating malaria and to achieving a malaria-free world. Targeting epigenetic mechanisms within Plasmodium parasites represents a promising therapeutic approach for malaria. Histone deacetylase (HDAC) enzymes, the focus of this thesis, act in conjunction with histone acetyltransferases (HATs) to reversibly acetylate histone and non-histone proteins. Some HDACs, in particular class I and II HDACs, are already validated drug targets for cancer therapy and are showing promise as antimalarial drug targets. However, besides their classical role in regulating gene expression, knowledge of the roles that HDACs play in the Plasmodium parasites, is limited. Like higher eukaryotic HDACs, P. falciparum HDACs (PfHDACs) are believed to localise in multi-protein complexes with accessory proteins and to regulate lysine acetylation of both histones and non-histone proteins.
Thesis (PhD Doctorate)
Doctor of Philosophy (PhD)
School of Natural Sciences
Science, Environment, Engineering and Technology
Full Text

Dissertation presented to obtain the Ph.D degree in Biology
Malaria is one of the world´s leading causes of death, responsible for over 700,000 deaths per year, the majority of which are African children under 5 years of age. Malaria disease is caused by the transmission of an Apicomplexa parasite, Plasmodium, through the bit of a female Anopheles mosquito, and transmitted parasites quickly reach the mammalian host liver, where the first round of replication begins. Plasmodium sporozoites, once inside the liver, must invade and survive within hepatocytes until the first replicative stage within the mammalian host is accomplished. Upon migration through various cells, sporozoites are able to actively enter hepatocytes, forming a Parasitophorous Vacuole Membrane (PVM) around itself. Once this intracellular niche is established, parasite replication and growth is initiated. Dramatic morphological as well as gene expression modifications occur at this stage, and the parasite achieves one of the highest replication rates known within eukaryotic species (Sinnis and Sim, 1997). Although the Plasmodium life-cycle has been extensively characterized, relatively little is known about sporozoite interaction with host organelles, vesicles and proteins. To address this issue, Plasmodium interactions with the host cell endomembranes was analyzed at various stages of liver infection using indirect immunofluorescence. Plasmodium parasites were seen closely associated with host endoplasmic reticulum (ER) and the Golgi apparatus. Surprisingly, late endosomes/lysosomes, observed with the membrane markers Rab7a, CD63 and LAMP1, aggregated around the parasite. No interaction with host peroxisomes, early and recycling endosomes was observed.(...)
Financial support was provided by Fundação para a Ciência e Tecnologia. Portugal, through the Ph.D. fellowship grant SFRH/BD/27705/2006.

Nous avons analyse par electrophorese d'isoenzymes (7 a 12 loci) le polymorphisme genetique de 5 populations (113 stocks) du plasmodium falciparum, l'agent de la forme la plus severe de paludisme. Les resultats ont ete interpretes en termes de genetique des populations, dans le but d'analyser la structure des populations naturelles de ce parasite. Un fort desequilibre de liaison apparait dans trois des populations etudiees, ainsi que dans l'echantillon global. Une quatrieme population montre egalement des indices de desequilibre, quoique dans une moindre mesure. Une seule serie n'a montre aucune deviation par rapport aux predictions de la panmixie. Ces resultats ne sont explicables, ni par la structuration geographique des populations, ni par la selection naturelle. L'hypothese la plus parcimonieuse pour rendre compte de nos donnees est l'existence d'une propagation uniparentale chez p. Falciparum dans certaines circonstances. De forts indices d'autofecondation peuvent expliquer ce resultat. La structure des populations naturelles de plasmodium falciparum et le mode de reproduction du parasite ont des consequences importantes sur l'epidemiologie de la maladie. Le modele subclonal ou partiellement clonal que nous proposons ici est radicalement different, quant a ses implications taxonomiques et epidemiologiques, du modele potentiellement panmictique qui avait ete propose pour p. Falciparum. En effet, si des lignees parasitaires subissent une propagation uniparentale, elles se comportent comme des clones, et gardent intactes leurs caracteristiques genetiques d'une generation a l'autre, tandis que le patrimoine genetique de chaque genotype fait l'objet d'un brassage energique a chaque generation dans le cas du modele potentiellement panmictique. Les problemes poses sont: (a) la nature du processus de reproduction uniparentale; (b) l'importance respective des cycles sexues et asexues; (c) la stabilite dans l'espace et dans le temps des lignees uniparentales

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Dentre as várias estratégias utilizadas com o intuito de induzir imunidade antimalárica está o uso de doses ultra-baixas de parasitos vivos de fase sanguínea dos plasmódios. Contudo, apesar desse método aparentemente induzir imunidade transcendente a cepa e espécie dois pontos precisam ser esclarecidos: 1- nenhum estudo tem avaliado se imunizações com parasitos vivos de baixa virulência são capazes de proteger contra o desenvolvimento de quadros graves da doença incluindo malária cerebral; 2 - considerando que crianças africanas frequentemente apresentam malária grave somente após reexposição a parasitos altamente virulentos, a relação entre o uso de parasitos vivos e o possível desenvolvimento de infecções graves precisa ser investigada. Para esclarecer tais questões, animais C57BL/6 foram imunizados uma ou duas vezes com 10³ hemácias infectadas por P. berghei NK65 ou P. berghei ANKA e posteriormente desafiados com 10^5 hemácias parasitadas por P. berghei ANKA. Imediatamente após primeira imunização, somente animais imunizados com P. berghei NK65 apresentaram níveis positivos de anticorpos IgG, os quais reconheceram tanto o antígeno homólogo quanto heterólogo. Independentemente do protocolo de imunização, animais imunizados uma vez apresentaram, tanto no cérebro quanto nos pulmões, menos áreas com acúmulo de hemácias e infiltrado inflamatório que animais somente desafiados ou imunizados duas vezes. Apesar das imunizações (uma ou duas vezes) com P. berghei ANKA e P. berghei NK65 terem controlado o desenvolvimento da parasitemia sanguínea por P. berghei ANKA, somente animais imunizados com P. berghei NK65 permaneceram vivos por até 30 dias após desafio experimental com P. berghei ANKA. Tanto no cérebro quanto nos pulmões, os níveis de TNF-α tenderam a elevar-se em relação ao IFN-ꝩ em animais que sofreram dois ciclos de imunizações, o que pode espelhar os maiores danos teciduais observados nesses animais. Contudo, os padrões de citocinas antiinflamatórias e pró-inflamatórias observados nesse estudo não explicam a mortalidade ou sobrevivência observada em animais imunizados com P. berghei ANKA e P. berghei NK65, respectivamente, e desafiados com P. berghei ANKA.
The use of ultra-low doses of live blood stage parasites is one of several strategies used to induce anti-malarial immunity. Although this method apparently induces cross-species and strain-transcendent immune response, there are two points that need to be explored: 1) no study has assessed whether immunization with live low virulence parasites is able to protect against the development of severe malaria, including cerebral malaria; 2) African children often develop severe malaria only after re-exposure to highly virulent parasites. Thus, the relationship between the use of live parasites and possible development of serious infections needs to be investigated. To clarify these two points, C57BL/6 mice were immunized once or twice with 10³ erythrocytes infected with P. berghei NK65 or P. berghei ANKA, and subsequently challenged with 10^5 P. berghei ANKA-parasitized erythrocytes. After the first immunization, only P. berghei NK65 immunized animals showed positive levels of IgG antibodies, which recognizes both homologous and heterologous antigen. In animals immunized only once, both brain and lungs exhibited fewer regions with accumulation of red blood cells and inflammation, when compared to control group or twice-immunized animals. Regardless of immunization protocols, all of the mice exhibit controlled development of P. berghei ANKA blood parasitemia. However, only P. berghei NK65 immunized animals remained alive 30 days after the being challenged with P. berghei ANKA. The TNF-α levels, on both brain and lungs, tended to rise in relation to IFN-ꝩ in animals undergoing two cycles of immunizations, which might reflect the higher tissue damage observed in these animals. However, the patterns of pro and anti-inflammatory cytokines present do not explain the observed mortality and survival rate in animals immunized with P. berghei ANKA and P. berghei NK65, respectively.

Cerebral malaria is characterised by an accumulation of infected erythrocytes in the microvasculature of the brain. Plasmodium falciparum infected erythrocytes have been shown to bind to a Human Brain Endothelial Cell line (HBEC-5i) in vitro. This provides a model for the investigation of interactions between P. falcuparum and human brain endothelium. Currently neither the parasite adhesion ligands on infected erythrocytes, nor the host endothelial cell receptors necessary for this interaction have been identified. In this work, the identity of the host receptor on brain endothelial cells was addressed by binding assays of selected and unselected parasites on a wide range of malaria-associated host molecules. The identity of the parasite ligand was investigated by microarray analysis of parasites after selection for cytoadherence to HBEC-5i. The hypothesis being tested was that the gene encoding the parasite cytoadherence ligand would show significant upregulation in selected compared to unselected paarasites. The P. falciparum laboratory strains 3D7, HB3 and IT/FCR3 were selected for binding to HBEC-5i using a panning assay. Compared to unselected parasites, HBEC-5i selected parasites showed a distinct phenotype with reduced platelet-mediated clumping. There was no significant increase in binding of parasites to any of the known endothelial cytoadherence receptors for P. falciparum after selection on HBEC-5i. Binding inhibition assays with various antibodies and soluble receptors did not greatly block the adhesion of parasites to HBEC-5i except for heparin. Altogether, the receptor(s) mediating the interation with HBEC-5i remains unknown. In order to carry out transcriptional analysis of selected and unselected paarasites form all three parasite strains, it was necessary to update the existing microarray chip which is based on the 3D7 genome. This is because each parasite train has a unique repertoire of variant surface antigens (VSAs) including var, rif and stevor genes. Therefore, to fully analysis HB3 and IT genomes. Unique oligonnucleotide probes were then designed for each new sequence and the 3D7-based microarray chip was updated. Transcriptional analysis was then carried out on selected and unselected parasites of all strains. Microarray data clearly indicated that the most highly upregulated genes after selection were group A or group A-like var genes (HB3var3, 3D7_PFDOO2Oc, ITvar7 and ITvar19), showing 11 to over 100 fold upregulation in selected parasites. The rif gene adjacent to the upregulated var gene was also highly expressed. To a lesser extent some exported proteins like RESA-1, PfEMP3 or PHIST family members also showed increased transcription in HBEC-selected parasites (2-3 fold upregulation). Reverse transcriptase-PCR confirmed the upregulation of group A var genes in selected parasites, suggessted that the group A PfEMP1 variants are major candidate ligands for parasite binding to HBEC-5i. These findings are consistent with previous work showing an association between Group A var genes and cerebral malaria.

Apicomplexa parasites are the cause of two of the world’s most widespread diseases; malaria and toxoplasmosis. Malaria affects two billion people worldwide in some of the poorest regions of the world. Over a million people a year die from malaria, the majority of which are pregnant women or children under the age of 5. Plasmodium falciparum is by far the most lethal cause of malaria and is endemic to many regions of sub-Saharan Africa. Toxoplasma gondii is the most common parasitic infection of human brain and eyes and is suspected to affect one third of the world’s population. Rising drug resistance and the inadequacies of current treatments have spurred a global effort for the development of new therapies targeting these parasites Cytochrome bc1 (cyt. bc1) is a proven drug target for both treatment and prophylaxis of P. falciparum and T. gondii. Atovaquone, a potent broad- spectrum anti-parasitic drug, targets the Qo site, one of two active sites within cytochrome, b collapsing the mitochondrial membrane potential and killing the parasites. Single mutations within the Qo site render atovaquone ineffective and incidences of resistance are rising. Previous work has focussed on overcoming resistance through the design/redesign of compounds targeting the well understood Qo site. Here we show the binding modes of GSK’s next-generation antimalarial 4(1H)-pyridones and a novel 4(1H)-quinolone to the Qi site of cyt. bc1. These structures reveal the mechanism by which the compounds are able to overcome resistance and point in a new direction for antimalarial drug development. This work reaffirms the importance of structural observation in drug development. Merozoite surface protein 1–19 (MSP119) is an important target in vaccine development against malaria. Recent work has shown that cupredoxins bind MSP119 of P. falciparum and result in death for the parasite. Rusticyanin, the most potent of these, has been extensively studied and various mutants have been produced a range of redox potentials and acid stability properties. Here, initial studies of the complex between P. falciparum MSP119 and rusticyanin are carried out and analysed.

Le paludisme est une maladie dévastatrice causée par un parasite du genre Plasmodium. Du fait de la propagation de souches résistantes aux actuels antipaludéens, il est nécessaire de comprendre les fonctions physiologiques essentielles du parasite afin de trouver de nouvelles cibles thérapeutiques. Les transporteurs membranaires sont une classe importante de cibles chez l'homme du fait de leur rôle physiologique essentiel pour la cellule. Cependant, chez les parasite du genre Plasmodium, seulement quelques transporteurs ont été biochimiquement caractérisés. Des études récentes de délétion de gènes dans un model murin ont montrées que l’ATPase de type P4, ou flippase, ATP2 de Plasmodium est essentielle pour le parasite. Chez les Eucaryotes, l’activité de translocation des lipides des ATPases de type P4 est nécessaire pour maintenir l’asymétrie des membranes, un élément clé dans de nombreux processus essentiels comme la formation de vésicules ou l’apoptose. Les flippases forment des complexes hétéromériques avec les protéines de la famille Cdc50 qui sont également trouvées dans le génome de Plasmodium. Pour comprendre le rôle fonctionnel de ces transporteurs putatifs durant l’infection par le parasite, nous avons besoin d’étudier leur mécanisme de transport et d’identifier leur (s) substrat (s). Nous avons entrepris l’expression hétérologue chez Saccharomyces cerevisiae d’ATP2, en complexe avec les sous unités Cdc50, de trois espèces différentes de Plasmodium. Nous avons réussi à co-exprimer l’orthologue ATP2 de P. chabaudi (PcATP2) et les sous unités PcCdc50 correspondantes. Par co-immunoprécipitation et une chromatographie d’exclusion stérique détectée par fluorescence, nous sommes parvenus à identifier la sous unité s’associant à PcATP2 : PcCdc50.1. Nous avons ensuite purifié le complexe PcATP2/PcCdc50.1 en utilisant des nanobodies reconnaissant la GFP fusionnée à l’extrémité C-terminale de PcATP2 et nous avons initié la caractérisation fonctionnelle avec des tests de phosphorylation et d’activité ATPasique
Malaria is a devastating disease caused by a parasite of the genus Plasmodium. Due to the spread of strains resistant to current antimalarial drugs, it is necessary to understand essential physiological functions of the parasite in order to find new drug targets. Membrane transport proteins are an important class of drug targets in humans, as they perform essential physiological roles of the cell. However, for Plasmodium parasites, just a few membrane transporters have been biochemically described. Recent gene-deletion studies in malaria mouse models have shown that the Plasmodium P4-ATPase, or lipid flippase, ATP2 is essential for the parasite. In eukaryotes, the phospholipid translocation activity of P4-ATPases is needed to maintain the asymmetric distribution of membranes, a key element in many essential processes like vesicle budding or apoptosis. Lipid flippases form heteromeric complexes with members of the Cdc50 protein family, also found in the genomes of Plasmodium parasites. To understand the functional role of these still putative transporters during malaria infection we need to study their transport mechanism and identify their substrate(s). We have conducted the heterologous expression in Saccharomyces cerevisiae of ATP2 in complex with the Cdc50 subunits from three different Plasmodium species. We succeeded to co-express the ATP2 ortholog of P. chabaudi (PcATP2) and the related putative PcCdc50 proteins. By co-immunoprecipitation and Fluorescence-detection Size Exclusion Chromatography, we have managed to identify the Cdc50 β-subunit that associates to PcATP2: PcCdc50.1. We then purified the complex PcATP2/PcCdc50.1 using immobilized nanobodies that recognize the GFP fused at the C-terminal end of PcATP2 and we initiated the functional characterization using ATPase and phosphorylation activity assays

The Plasmodium falciparum parasite is the causative agent of the most severe form of malaria. The increase in resistance against the majority of antimalarial compounds underpins the need for the development of new antimalarial compounds, targeting novel biological activities of the parasite. As the P. falciparum parasite develops through its life cycle stages, the parasite is exposed to different environments, resulting in both strategy-specific differences between the asexual (proliferation) and gametocyte (differentiation) stages, as well as stage-specific (i.e. ring – schizont stages; stage I - V gametocytes) differences within each strategy. These strategy- and stage-specific differences might be supported by the presence of different membrane transport proteins (MTPs) in the asexual and gametocyte stages. P. falciparum-encoded MTPs (permeome) are promising novel drug targets because they are specific to P. falciparum and essential for the survival of the P. falciparum parasite as these proteins mediate the uptake and removal of metabolites and waste products. However, to propose parasite-encoded MTPs as potential novel drug targets in the asexual and gametocyte stages, the presence of these MTPs in these stages should be investigated. The P. falciparum-encoded permeome is well characterised in the asexual stages. However, limited knowledge is available about the permeome in the gametocyte stages. Therefore, to address this knowledge gap, the strategy- and stage-specific expression of the entire complement of parasite-encoded MTPs were investigated in the asexual and gametocyte stages to infer the presence of MTP transcripts in the absence of biochemical uptake data. The transcript expression of the permeome revealed strategy-specific expression, with the entire permeome expressed during asexual stages, as expected, given the metabolic adaptations that support the high proliferation rate. By contrast, the gametocyte stages that are undergoing sexual differentiation towards transmission, as opposed to active proliferation, less than half of the permeome were expressed, indicating a reduced range of MTPs active in the gametocyte stages. Subsequently, stage-specific expression of the permeome was investigated by correlating stage-specific metabolic processes that occur within the asexual and gametocyte stages, to the expression profiles of MTP genes involved in these processes. Most of the MTPs involved in these processes showed stage-specific expression, with a few MTP genes showing no stage-specific expression within the asexual and gametocyte stages, respectively. When comparing the stage-specific expression between the asexual and gametocyte stages, it was observed that during the gametocyte stages, there was an absence of some MTPs (decreased expression) that were expressed during the asexual stages, suggesting that the gametocyte stages require only certain metabolites to maintain the investigated metabolic processes. In conclusion, these expression profiles of the permeome in the asexual and gametocyte stages suggest the differential expression of the permeome in these stages. The data presented in this study provides the first complete evaluation of expression of the permeome across P. falciparum asexual and gametocyte stages and serves as a blueprint for future biochemical investigations of transport in these stages, thereby providing a foundation for identifying novel MTP drug targets in future drug development programmes.
Dissertation (MSc)--University of Pretoria, 2018.
NRF
Biochemistry
MSc
Unrestricted

Rosetting is an adhesion property of malaria parasites whereby infected erythrocytes bind to two or more uninfected erythrocytes, forming a so-called rosette. Rosetting of Plasmodium falciparum is associated with disease severity and high parasitaemia in sub-Saharan Africa, although currently the function of rosetting remains unknown. An early IFNg response elicited from the innate immune system is associated with resolution of malaria infection in mice. Published data suggests that optimal IFNg production may require contact between peripheral blood mononuclear cells and P. falciparum infected erythrocytes. The first part of this thesis investigates the hypothesis that rosetting is an immune evasion strategy to hide infected erythrocytes from detection by innate immune cells. Across five laboratory strains of P. falciparum rosetting was not associated with differential IFNg production when parasites were grown in group O blood. Reappraisal of the data with respect to blood group for one strain found that rosetting significantly reduced the IFNg response to parasites grown in group A blood (P=0.022, Wilcoxon signed-rank test), where it is known that rosettes are bigger and stronger. This is consistent with the hypothesis that rosetting is an immune evasion strategy and the first study to find evidence for a function of rosetting. Further work is needed in order to generalise this finding. The cytokine response to P. falciparum varies between people and this variation may be indicative of disease progression. In mice infected with malaria it is also apparent that parasite strain can determine the cytokine response of the host. It is unclear whether P. falciparum strains vary in their ability to induce cytokines. The second part of this thesis investigates variation in cytokine induction between P. falciparum strains. Across four laboratory strains of P. falciparum, IFNg production was significantly dependent on parasite strain (F3,178= 48.49, P<0.001). Production of GM-CSF, IL-1b, IL-6, IL-10 and TNFa significantly correlated with production of IFNg (P<0.001, Pearson correlation) and followed the same strain-dependent pattern. The ratio of pro-inflammatory cytokines to IL-10 was also dependent on parasite strain. These data provide strong evidence for P. falciparum strain-dependent cytokine responses which may be an important determinant of disease outcome. Phagocytosis by splenic macrophages is proposed to be the principle mechanism of parasitaemia control in malaria infection. CD36 mediated phagocytosis may by an important mechanism of non-opsonic parasite clearance. The final part of this thesis investigates the hypothesis that rosetting is an immune evasion strategy of P. falciparum in order to evade phagocytic clearance, in particular that mediated by CD36. Overall the data obtained were inconsistent. Phagocytosis was significantly reduced in rosetting versus non-rosetting parasites in some strains (e.g. R29; P=0.048, paired T test), whereas others showed no effect (e.g. Muz12; P=0.228, paired T test) or increased versus non-rosetting parasites (e.g. HB3, P=0.004, paired T test). The relationship between CD36 binding and phagocytosis was also unclear, and anti-CD36 antibody did not effectively block phagocytosis, suggesting the involvement of alternative mechanisms. Further experiments are needed to clarify these observations. Data presented in this thesis are suggestive that rosetting in non-group O blood may be an immune evasion strategy with regard to IFNg production by innate immune cells, mechanistically linking rosetting with enhanced parasitaemia and disease severity. Furthermore, parasite strain significantly affects cytokine production and may be a determinant of disease outcome. This thesis demonstrates the importance of continued research into the effect of parasite virulence on the immune response, with particular emphasis on rosetting.

Malaria wird durch den einzelligen Parasiten Plasmodium verursacht. Hierbei handelt es sich um einen obligat intrazellulären, eukaryotischen Erreger, der zum Phylum der Apicomplexa gehört. Apicomplexa zeichnen sich durch das einzigartige Vorhandensein eines ungewöhnlichen Plastids, genannt Apicoplast, aus. Die Exklusivität dieser Organelle und ihre metabolische Notwendigkeit für das Parasitenwachstum haben sie als attraktives pharmakologisches Ziel bestätigt. In dieser Arbeit wurden, unter Anwendung des Nagetier-Malariaerregers Plasmodium berghei, zwei verschiedene Aspekte von Apicoplast Proteinfunktionen untersucht. Zum Ersten wurde ein bislang unbeschriebenes Plasmodium Apicoplast Protein, Plasmodium-specific Apicoplast protein important for Liver Merozoite formation (PALM), charakterisiert. Drei voneinander unabhängige palm— Parasitenlinien, wurden durch zielgerichtete Gendeletion generiert. Die PALM Knockout-Mutanten entwickelten sich während eines Großteils des Lebenszyklus normal, jedoch war die Abgabe von Merozoiten in den Blutstrom und die Fähigkeit eine Blutstadien-Infektion zu etablieren signifikant beeinträchtigt. Experimentelle Immunisierung von Mäusen mit palm— Sporozoiten bewirkte einen starken und langanhaltenden Schutz gegen Reinfektion mit Malaria. Diese Ergebnisse lassen darauf schließen, dass Parasiten mit einem Arrest in den finalen Schritten der Bildung von Leberstadien-Merozoiten einen Vorteil gegenüber genetisch attenuierten Parasiten der ersten Generation haben, die in der frühen Leberstadienentwicklung arretiert sind. Zum Zweiten wurden die sechs Nucleus-kodierten Komponenten der [Fe-S] Cluster Biosynthese im Apicoplast systematisch durch experimentelle Genetik analysiert. Insgesamt zeigen meine Studien, dass bisher unbekannte Ziele im Plasmodium Apicoplast für Interventionsstrategien gegen Malaria geeignet sind.
Malaria is caused by Plasmodium, an obligate intracellular eukaryotic pathogen that belongs to the phylum Apicomplexa. Apicomplexan parasites harbor an unusual plastid organelle, termed apicoplast. Because this unique organelle is indispensable for parasite growth it is a validated and attractive drug target. Using the rodent malaria parasite Plasmodium berghei, two different aspects of apicoplast protein functions were analyzed in this study. Firstly, a previously uncharacterized Plasmodium apicoplast protein, Plasmodium-specific Apicoplast protein important for Liver Merozoite formation (PALM), was investigated. Three independent palm— knockout parasite lines were generated by targeted gene deletion. While the resulting knockout mutants developed normally for most of the life cycle, merozoite release into the blood stream and the ability to establish an infection was severely impaired. Experimental immunization of mice with palm— sporozoites elicited unprecedented potent and long-lasting protection against malaria re-infection. The results indicate that a tailor-made arrest in the final steps of hepatic merozoite formation could be an improvement over first-generation early liver-stage genetically arrested parasites (GAPs). Secondly, the six nuclear-encoded components of the apicoplast [Fe-S] cluster biosynthesis pathway were systematically targeted by experimental genetics. Together, my studies show that the Plasmodium apicoplast harbors previously unrecognized targets for anti-malaria intervention strategies.

Ce travail a eu pour objectif de caractériser les parasites P. falciparum, infectant les femmes enceintes et responsables du paludisme associé à la grossesse. Dans la première partie de ce travail, le phénotype d’adhérence et le profil d'expression des gènes var chez les parasites infectant les femmes enceintes ont été étudiés. Ces analyses ont été réalisées sur des isolats parasitaires collectés dans deux études menées au Bénin entre 2008 et 2013. La première étude, sur des isolats prélevés dans le cadre d'une étude de cohorte de femmes enceintes dans les zones rurales au Bénin, a montré que les parasites qui infectent les femmes dans le premier trimestre de la grossesse expriment déjà un phénotype placentaire. Dans une deuxième étude, portant sur les isolats prélevés en prospective chez des femmes enceintes se présentant en consultations prénatales dans les centres de santé à Cotonou, une analyse plus détaillée des propriétés d'adhérence des hématies parasitées par P. falciparum, a confirmé nos premiers résultats. Cette étude a souligné une plus grande complexité dans les propriétés d’adhérence des isolats obtenus pendant le premier trimestre de grossesse qui adhèrent sur plusieurs récepteurs. Tout au long de la grossesse cette diversité phénotypique s’affine vers des phénotypes typiquement placentaires. Ce travail a également démontré, qu'au-delà de la parasitémie, l'adhérence à la CSA est un facteur important au regard de l’issue défavorable de la grossesse ; les parasites qui infectent les primigestes adhèrent en moyenne plus à la CSA que ceux provenant des multigestes. Conformément aux travaux antérieurs, les études menées au Bénin ont montré que le gène var2csa est le membre de la famille des gènes var qui est préférentiellement transcrit par les parasites infectant la femme enceinte. L’expression de la protéine correspondante à la surface des érythrocytes infectés a été démontrée grâce à des anticorps spécifiques. Cette expression a été étroitement associée à la capacité des isolats à adhérer, in vitro, à la CSA. La deuxième partie de ce travail a examiné le potentiel vaccinal de VAR2CSA par l’exploration des régions peptidiques impliquées dans l'acquisition d'anticorps « anti-adhérence ». En utilisant une approche d'immunisation génétique chez la souris, nous avons été en mesure d'identifier la région minimale de VAR2CSA située dans son extrémité N-terminale comme étant le site qui concentre les épitopes anti-adhérence. Les IgG induites contre la région NTS-DBL2X de VAR2CSA ont été capables d’inhiber l'adhérence de plus de 60% ??des isolats naturels de P. falciparum à la CSA. Cette étude a par ailleurs mis en évidence des propriétés fonctionnelles des IgG qui seraient souche-spécifique ainsi qu’a aidé à formuler une hypothèse concernant la combinaison antigénique des variants de VAR2CSA nécessaires pour garantir une activité optimale sur des isolats de terrain. La dernière partie de ce travail a porté sur l'analyse du polymorphisme des séquences de VAR2CSA dans sa partie N-terminale chez les isolats de terrain. Ces analyses ont démontré l'existence d'une région dimorphique dans le domaine structurellement critique ID1, qui a révélé une association très intéressante avec la survenue d'infections à très forte densité de parasite. Le travail développé dans cette thèse a permis de mettre à jour les connaissances sur les parasites qui infectent les femmes pendant la grossesse et de formuler des hypothèses sur les pistes d'optimisation moléculaire, nécessaires au développement d'un vaccin efficace à base de VAR2CSA
This thesis aimed to characterize the P. falciparum parasites infecting pregnant women and causing pregnancy-associated malaria (PAM). In the first part of this work, cytoadherence phenotype and var genes expression profile of pregnant women parasites have been investigated on parasite isolates collected in two studies conducted in Benin between 2008 and 2013. The first study on isolates collected as part of a cohort study of pregnant women in rural areas in Benin, showed that parasites which infect women in the first trimester of pregnancy already express placental phenotype. In a second study on isolates collected prospectively from pregnant women attending antenatal clinics in health centers in Cotonou, the analysis of the adhesion phenotype using multiple host receptors described so far confirmed the first results and highlighted a greater complexity of the binding properties in isolates collected during the first trimester and those obtained from multigravidae. This study also demonstrated that beyond parasitaemia, adhesion to CSA is a major factor for poor pregnancy outcomes. Consistent with previous reports, studies in Benin showed that var2csa was the most transcribed var gene by PAM-isolates and its surface expression on infected erythrocyte (IE) was demonstrated with specific antibodies. This was closely linked to the ability of isolates to adhere to CSA in vitro. The second part of the work investigated the vaccine potency of VAR2CSA by exploring the region of var2csa involved in the acquisition of anti-adhesion antibodies. Using a DNA immunization approach performed in mice, we were able to identify the var2csa minimal region located in its N-terminus as the site that concentrates the anti-adhesion epitopes. The NTS-DBL2X region of VAR2CSA has been found to induce cross-reactive antibodies that inhibit adhesion of more than 60% of field P. falciparum isolates to CSPG. This study highlighted some strain-specific properties in functionality of the antibodies induced and helped formulate a hypothesis of antigenic FCR3 and 3D7 variants combination for optimal activity on field isolates. The last part of this work focused on the analysis of sequence polymorphism in the N-terminal part of VAR2CSA expressed by field isolates. The analysis demonstrated the existence of a dimorphic region within the structurally critical ID1 domain that revealed a very interesting association with the occurrence of infections with very high parasite density. The work developed in this thesis updates knowledge on parasites infecting women during pregnancy and formulates hypotheses on the molecular optimization tracks necessary for the development of an effective VAR2CSA-based vaccine

Depuis plusieurs années, des expériences nombreuses et diverses ont fait supposer l'existence, vraisemblablement dans les lymphatiques, de formes de latence chez les plasmodium de muridae. Ces hypothèses sont confirmées expérimentalement par la mise en évidence, dans le réseau lymphatique, de différentes formations contenant des merozoites qui résistent aux phénomènes de lyse survenant pour les autres stades parasitaires. Ces merozoites en latence se présentent sous trois formes différentes :- merozoites isoles dans des polynucléaires neutrophiles ; - merozoites isoles dans des macrophages ; - sacs merophores, qui sont des collections de merozoites, devenus souvent extracellulaires, ont conservé leur membrane et contiennent de nombreux merozoites. Dans le cas de P. Y. Nigeriensis (qui se prête mieux à l'expérimentation, car il infecte le rat) ces formations ont été mises en évidence dans le liquide lymphatique qui est toujours infectant lorsqu'il est inocule a des souris neuves (thèse F. Coquelin). La mise en latence des merozoites s'effectue dans différents organes, mais essentiellement dans la rate. Peu de temps après la schizogonie, certains schizontes ou merozoites, sont ingérés par les macrophages ou les polynucléaires et leur abondance est proportionnelle au nombre de schizontes qui ont muri au cours de cette schizogonie. Les trois espèces étudiées sont différentes : P. Y. Nigeriensis a de très nombreux sacs merophores mais pratiquement aucun leucocyte merophore. La grande majorité des sacs merophores semble rejoindre rapidement le sang par la voie des canaux lymphatiques, mais un petit nombre est retenu dans le réseau lymphatique et reste présent, dans des ganglions par exemple, alors que la parasitemie a cessé. P. C. Chabaudi a des sacs merophores et des leucocytes merophores, les uns et les autres en moyenne abondance. P. V. Petteri n'a presque aucun sac merophore mais seulement des merozoites isolés dans des macrophages merophores et surtout des neutrophiles merophores. Cependant, les différences entre, d'une part, P. Yoelii et P. Vinckei qui, chez l'hôte naturel, ont des infections sporadiques et, d'autre part, P. Chabaudi qui reste constamment présent dans le sang du rongeur, ne sont pas expliquées puisque les formes de latence de P. Chabaudi sont intermédiaires entre celles de P. Yoelii (sacs merophores) et celles de P. Vinckei (leucocytes merophores). Les plasmodium murins sont très proches de ceux des primates et en particulier de ceux de l'homme. Les phénomènes de latence, les infections chroniques et les recrudescences sont analogues chez l'homme et le rongeur et il parait improbable que le mécanisme en soit diffèrent et que l'existence de merozoites circulant sous une forme ou une autre dans le réseau lymphatique soient particuliers aux paludismes murins.

Despite over a century of research, malaria parasites (Plasmodium) still remain a major cause of mortality and morbidity worldwide. In recent years, the application of theoretical principles from ecology and evolutionary biology to the study of these parasites has started to provide insight into variety of fundamental subjects from the evolution of virulence to the facultative strategies (i.e. phenotypic plasticity) that parasites use to maximize their transmission. It is now becoming increasingly clear that to understand and predict population level patterns of virulence and transmission, the processes that occur at the between-host level must be studied in light of the interactions that happen within hosts (between parasites and between parasites and hosts). In this thesis I combine concepts from evolutionary biology and ecology with tools from molecular and cellular biology and evolutionary genetics, which allow me to study rodent malaria parasites at both evolutionary and ecological timescales. The work I present in this thesis has the following four components: 1. Phylogenetics (chapter 2): I applied recently developed phylogenetic methods to a large DNA sequence dataset that I generated, to provide a better understanding of the phylogeny of rodent malaria parasites and investigate how selection has shaped their genomes. I show that all rodent malaria subspecies can be considered species, provide the first time line for the evolution of this group of parasites and demonstrate that most loci are under purifying selection. 2. Hybridization and reproductive isolation (chapter 3): I show that hybridization between two rodent malaria parasites (P. berghei and P. yoelii) can occur, but only occurs at high levels when one of two proteins (P230 or P48/45) is absent from the surface of female gametes, which indicates that these proteins are involved in gamete recognition. I find that P230, P48/45 and P47 (a possible interaction partner) are evolving under positive selection, a feature often observed in gamete recognition proteins of other taxa. Finally, I show that the fertilization success of P. berghei is reduced in the presence of P. yoelii, but not vice-versa, which indicates asymmetric reproductive interference. 3. Sex allocation (chapter 4): I carry the first test of sex allocation’s assumption that immunity impacts on the fertility of Plasmodium male gametocytes/gametes more than on the fertility of females. I show that while the fertility of both males and females is equally affected, males are affected during gametogenesis and females are mostly affected through gamete dysfunction (i.e. gametes can mate but zygotes fail to develop), which is in agreement with the assumptions of theory. In collaboration, I incorporate these effects into sex allocation theory and predict that malaria parasites can minimize the effects of factors that kill gametocytes/gametes by adjusting their sex ratios. On the other hand sex ratio adjustment cannot compensate for gamete dysfunction or zygote death. These results have applied implications for transmission-blocking vaccines. 4. Infection dynamics of mixed-species infections (chapter 5): I develop a series of experiments to test how a focal parasite species (P. yoelii) is affected by competition with heterospecifics (P. chabaudi) and how the interaction between the two species is mediated by immunity and resource availability. I show that P. chabaudi can boost P. yoelii above its single species level (i.e. facilitation) and that this is mediated by resource availability. On the other hand, P. yoelii’s performance can also be hindered in mice that were exposed to a P. chabaudi infection. My results also reveal that host mortality is exacerbated in mixed-species infections of naïve mice, which may be due to an inability of the host to achieve the right balance between the production and the destruction of red blood cells, when dealing with a mixed-species infection. The work I present here tackles fundamental questions concerning the transmission biology and the within-host interactions of malaria parasites The results presented demonstrate the importance of interactions between hosts and parasites and between different parasite species (at the molecular and the whole organism levels) for determining the outcome of transmission, virulence and within-host parasite performance.

Avian malaria parasites are responsible for severe diseases in some domestic and wild birds. These parasites are cosmopolitan in distribution; they are widespread in Europe, including the Baltic region. A peculiarity of current studies of avian Plasmodium species is that information about ecology, distribution, prevalence and other aspects of their biology has been accumulated using free-living birds. To elucidate the significance of malaria infections and their impact on host fitness, behaviour, sexual selection and parasite-host co-evolution, experimental information about Plasmodium spp. virulence, specificity and dynamics of parasitemia in different avian hosts is crucial. Unfortunately such studies remain uncommon. Theobjective of this study was to obtain new field and laboratory experimental data about the biology of avian malaria parasites and to link PCR-based information with data from traditional parasitology. It was demonstrated that prevalence of avian malaria and other haemosporidian parasites is estimated equally well by microscopy and currently used nested PCR-based methods. Both methods have advantages and disadvantages. So we encourage using both these tools in parallel during studies of haemosporidians. Lineages for molecular identification of P. relictum (lineage SGS1) and P. circumflexum (TURDUS1) were determined, also new methods of single cell dissection, DNA extraction and PCR-based analysis of avian malaria and closely related blood parasites were... [to full text]
Paukščių maliariniai parazitai sukelia pavojingas naminių ir laukinių paukščių ligas. Šie parazitai dažnai sutinkami įvairiose paukščių grupėse ir yra plačiai paplitę Europoje, tame tarpe ir Baltijos regione. Dabartinių maliarinių parazitų studijų ypatumas yra tas, kad informacija apie šių parazitų ekologiją, paplitimą, įvairovę ir kitus biologijos aspektus yra surenkama iš laisvai gyvenančių paukščių. Vertinant maliarinių parazitų įtaką paukščių fizinei būklei, elgsenai, lytinei atrankai ir parazitų-šeimininkų ko-evoliucijai yra būtina surinkti informaciją apie maliarinių parazitų specifiškumą, virulentiškumą ir parazitemijos vystymąsi skirtinguose paukščiuose. Tokie duomenys gali būti gaunami atliekant eksperimentinius tyrimus. Deja, tokių studijų kol kas yra nedaug. Disertacijos tikslas – lauko ir eksperimentinių tyrimų pagalba surinkti naują medžiagą apie paukščių maliarinių parazitų biologiją bei susieti PGR paremtais metodais gautą informaciją su tradicinės parazitologijos duomenimis. Šių tyrimų metu įrodyta, kad PGR paremtų ir tradicinės parazitologijos (mikroskopijos) metodų, naudojamų tiriant paukščių maliarinius parazitus ir kitas hemosporidijas, tikslumas nesiskiria. Abu metodai turi savų privalumų ir trūkumų, todėl rekomenduojame naudoti mikroskopijos ir PGR paremtų metodų kombinaciją. Taip pat išvystytas Plasmodium relictum (linija SGS1) ir P. circumflexum (TURDUS1) molekulinis identifikavimas, bei sukurti nauji paukščių maliarinių ir susijusių kraujo parazitų... [toliau žr. visą tekstą]

Dans une ère où les moustiques modifiés commencent à être utilisés ou envisagés pour contrôler les épidémies de Dengue ou malaria, le manque de connaissance sur l’immunité des insectes vecteurs envers certains pathogènes se fait cruellement ressentir. Pourtant la possibilité de changements de vecteurs, dû à un changement de leur immunité, provoquée par l’Homme est réelle. Pour déterminer la contribution de l’immunité dans différents compartiments du vecteur contre divers pathogènes avons étudié la réponse antivirale dans la première barrière de transmission chez le moustique vecteur de la malaria après une infection par un repas sanguin. Nous montrons que les réponses antivirales sont différentes entre compartiments, et proposons un modèle où des interactions tripartites entre le virus, l’immunité du moustique et la flore entérique interagissent pour contrôler l’infection précoce du moustique après le repas sanguin. De façon surprenante, nous avons également montré que la voie de l’ARN interférence n’a pas d’effet antiviral dans ce compartiment. Nous suggérons que cette voie est utilisée par le parasite Plasmodium pour détourner la réponse antiparasitaire médiée par Toll, grâce à un facteur de virulence de nature ARN double brin. Nous avons également montré que des biais expérimentaux lors de l’infection des insectes ont conduit à l’élaboration d’un dogme disant que la voie de l’ARN interférence est la voie antivirale principale des insectes, mais nos resultats suggèrent que malgré l’importance de cette voie pour controler l’intensité de la réplication virale lors de l’infection disséminée, cette voie n’a aucune fonction antivirale lors de l’infection initiale du tube digestif. Néanmoins, le séquençage des produits de cette voie permet d’assembler de-novo des génomes de virus commensaux. Les résultats de ces travaux montrent très clairement qu’il faut évaluer le rôle et l’impact de toute modification d’insectes vecteurs pour plusieurs classes de pathogènes. Cela ouvre également de nombreux nouveaux champs de recherches et pose de nombreuses nouvelles questions
In an era where modified mosquitoes are starting to be used in nature for controlling malaria and Dengue, lack of knowledge about immunity of mosquito vectors to some pathogen classes are becoming more evident. The risks for human-provoked vector shifts of pathogens transmission have not been examined. To fill these gaps, we assessed the antiviral immunity of the malaria vector, Anopheles gambiae, in the strongest mosquito bottleneck for pathogens, the midgut infection barrier after an infective bloodmeal. This work shows that the antiviral responses are different and highly compartmentalized between the midgut and systemic immunity. We propose a model where tripartite interactions between virus, mosquito immunity and enteric flora control early arboviral infection in the midgut. Surprisingly, we showed that while the siRNA pathway had no evident anti-arbovirus activity in the midgut, it was used by Plasmodium to evade mosquito immunity. A virus-like elicitor of double strand RNA nature is transferred from the parasite at the ookinete stage to the mosquito midgut cells, resulting in a shift of immune balance from anti-parasite response to an antiviral-like response. Importantly, our work shows that biases in experimental infection methods led to the misconstruction of a dogma stating that siRNA is the main antiviral pathways in insects, at least in the midgut compartment. And that the use of the pathway products can be successfully used to de-novo assemble previously unknown viruses from the virome. This work indicates that immune modifications in vectors need to be evaluated for changes of vectorial competence to different pathogens. It also opens numerous avenues of research and raises a lot of interesting questions that will need to be investigated in the future

This study investigates P. falciparum adaption to human activities to control malaria. Patient data analysis, genetic screening and molecular phylogeny were used to understand the drug resistance and diagnostic test-evasion profiles of P. falciparum imported to NSW and collected in Thailand. Artemisinin resistance (ART Rx) markers were found, including from PNG (resistance not previously reported). A geographically informative barcoding protocol was developed to identify evolutionary origins. Findings support the hypothesis that genetic background is crucial to the (ART Rx) phenotype. Putative P. vivax drug resistance markers (Pvmdr, Pvcrt-o, Pvdfr, and Pvdhps) and P. falciparum ART Rx markers (Pfkelch13) were analysed from samples collected in four provinces of South Thailand. Numerous P. vivax chloroquine and antifolate Rx-associated mutations were observed. The C580Y coding mutation was detected in 60-100% of P. falciparum samples originating from Ranong and Yala - the first reports of ART Rx genotypes south of the Rx perimeter in Southeast Asia. This study determined the pfhrp2/pfhrp3 deletion status of imported P. falciparum (genes underlying the protein detected by HPR2-based Rapid Diagnostic Tests). The study detected gene-deleted parasites from several African countries without reported data, with >10% from Sudan, South Sudan, and Nigeria, posing a risk of false-negative HRP2-RDT results. Microsatellite analysis was used to investigate genetic diversity and relatedness. Country cohorts were compared to Eritrean parasites, which have undergone selection for gene-deleted lineages. Selection signatures were not observed. The surprising diversity (including Rx genotypes) from populations lacking genetic data redefined ongoing surveillance targets. We conclude that malaria surveillance in Australia is a valuable global data gathering tool and necessary to pre-empt treatment failure and modify diagnostic testing algorithms in light of the genetic changes detected.

Apicomplexan parasites are responsible for some of the most devastating human and veterinarian diseases and are parasites of great economic importance. Apicomplexa include Plasmodium, Toxoplasma and Babesia species. The pathogenic mechanisms developed by Apicomplexa parasites, in particular those that reside in a parasitophorous vacuole, involve considerable changes to the host cell, including the expression of variable surface proteins required for immune evasion. In Plasmodium falciparum infections, host cell remodeling is responsible for disease symptomology and severity in the human host. This work represents a multi-faceted study of antigenic secretion and the role of secreted antigens in pathogenesis. We study in detail the mechanisms of antigen secretion in Apicomplexa parasites. By use of comparative genomics, we find Plasmodium Export Element (PEXEL)-like motifs in a subset of Cryptosporidium and Babesia secreted proteins. However, in Babesia the motif functions as a spherical body targeting sequence, suggesting that secretory mechanisms in Apicomplexa are adapted to the parasite's intracellular lifestyle. To elucidate the relationship and function of exported antigens, we first focused on P. falciparum to determine gene co-expression modules. We found that in vivo, export modules are composed of constitutively or variably expressed genes, the latter group associated with patient clinical phenotypes. We then focused on a novel gene family called "phist" and show, using transcriptional expression profiling, its role in P. falciparum cytoadherence. In total, we demonstrate that antigen secretion is an evolutionary mechanism in Apicomplexa parasites and that variant expression of the genes encoding these antigens may allow parasites to adapt to environmental stresses.

Parasites can influence evolutionary patterns in their hosts by generating a mosaic of selection pressures across populations. Variations in parasite prevalence and host-specificity can determine how parasites are distributed among hosts and, ultimately, how parasite interactions influence host biogeography. However, our understanding of how host-parasite interactions influence biogeographic patterns is limited by a lack of appropriate model systems. Avian malaria parasites (Plasmodium and Haemoproteus; Haemosporida) are a diverse, globally distributed group of vector-borne blood parasites. Because avian malaria prevalence and community composition can vary across host populations, these parasites have potential to impose spatially divergent selective pressures in birds. This thesis generates new perspectives on the evolutionary importance of avian malaria by exploring patterns in malaria prevalence, diversity and host-specificity in the under-studied South Pacific. Specifically, I sample wild birds for malaria to test whether (a) these parasites conform to classic global and island biogeography patterns, and (b) whether variation in parasite prevalence and host-specificity may influence the distributions and evolutionary trajectories of their avian hosts.
Thesis (PhD Doctorate)
Doctor of Philosophy (PhD)
Griffith School of Environment
Science, Environment, Engineering and Technology
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Thesis advisor: Marc Muskavitch
The ubiquitin-proteasome system (UPS), composed of classes of proteins central to the process of cellular protein turnover in eukaryotes, is essential to the life cycle of the malaria parasite, Plasmodium falciparum. Although the UPS has been well characterized in other organisms, the extent of its involvement in different stages of P. falciparum growth and development has not been investigated in depth. MG132, a small-molecule proteasome inhibitor known to target the 20S proteasome core (part of the catalytic center for selective protein degradation), has been used successfully in many research studies that require proteasome inhibition. We present data supportive of the conclusion that MG132 is highly effective as a tool for P. falciparum research. In this thesis, I describe the effects of partial and complete proteasome inhibition on parasite growth and development by the use of variable concentrations of MG132. I also assess the effects of MG132 on 20S P. falciparum proteasome enzymatic activities. I have generated parasite lines that exhibit tolerance, or low-level resistance, to MG132, through intermittent compound exposure. Sequencing of the catalytic β-5 subunit of the MG132-tolerant parasites reveals non-synonymous point mutations in three tolerant parasite lines. The use of MG132 as a tool compound for study of the UPS in P. falciparum facilitates research into detailed roles of the proteasome using reversible partial and complete inhibition. MG132-tolerant lines are also valuable tools for studying the genesis of different levels of drug resistance and cross-resistance in parasite evolution
Thesis (PhD) — Boston College, 2015
Submitted to: Boston College. Graduate School of Arts and Sciences
Discipline: Biology

Sex ratio theory is a focus in evolutionary biology that explores how natural selection shapes investment in males and females. It has provided some of the best quantitative evidence of evolution and could find utility in public health efforts through its application to malaria parasites. These parasites have distinct male and female forms that are produced following massive asexual replication, and they mate within the blood-feeding insects that transmit them between vertebrate hosts. A very similar population structure is assumed by local mate competition (LMC), a model from sex ratio theory that predicts female-biased sex ratios dependent on the degree of selfing within a mating patch. In this dissertation, I test a series of predictions from LMC for the lizard malaria parasite Plasmodium mexicanum. These include: (i) sex ratios have heritable variation that is not constrained by other life history traits; (ii) single-genotype infections have female-biased sex ratios that are determined by male fecundity; (iii) multiple-genotype infections have less biased sex ratios than single genotype infections; (iv) if males are limiting, sex ratios may be less biased when there are fewer parasites present (an extension of LMC called fertility insurance); and (v) less biased sex ratios may also be favored if increased female production yields diminishing returns on transmission to a new vertebrate host. To test these predictions, I combined the study of natural and experimental infections, microscopy (parasite density and sex ratio), molecular genetics (infection genetic diversity), and mathematical modeling (of how transmission patterns might affect sex ratio evolution). Overall, the results were qualitatively consistent with both LMC and my new model predictions. Sex ratios showed evidence of heritable variation that was unlinked to other life history traits measured. Sex ratios in single-genotype infections were female biased and consistent with the male fecundity observed, and were lower than sex ratios in experimental multiple-genotype infections, as predicted. Sex ratios were not less biased with lower sexual cell density, suggesting that males were not limiting. In fact, the opposite trend was sometimes observed: sex ratios were less biased with more sexual cells. This pattern has been observed previously in this and other species, and the only model that currently predicts such a trend is the new transmission model I outline. This dissertation contributes to our understanding of sex ratio evolution for malaria parasites in a number of ways. First, it adds evidence to the idea that the selective forces implicated in LMC are at work in malaria parasites and that malaria parasites are able to detect and respond to relevant cues. Second, it helps account for discrepancies in existing data, which have often reached conflicting conclusions. Third, it offers one of the first detailed studies of malaria parasite male fecundity, an essential piece of the sex ratio puzzle. Finally, it outlines a new theoretical extension of LMC that provides novel predictions and highlights areas of study that may be fruitful for future work on malaria parasites and other organisms.

Combating drug resistant malaria has been historically challenging, and remains so today. Recent reports from Southeast Asia show that Plasmodium falciparum is developing resistance to even our best defenses; artemisinin-based therapies. This development threatens to become a significant challenge in controlling malaria infections worldwide, making research into developing and characterizing new antimalarial drugs increasingly important. The purpose of this study was to characterize the resistance potential of novel antimalarial compound JPC-3210 in vitro using P. falciparum clones. JPC-3210 is a new long acting drug with potential to be used in combination with fast-acting drugs like artemisinins to cure drug resistant malaria. In this study several methods were used to characterize the efficacy and resistance potential of JPC-3210. To determine the frequency of resistance generation in P. falciparum clones, parasites were kept under continuous drug pressure for thirty days, at which point drug pressure was removed and cultures were observed for signs of recrudescence. P. falciparum clones also were exposed to increasing levels of intermittent drug pressure that involved 3-4 days of drug exposure followed by a recovery period. The step-wise experiment was conducted over three months with drug pressure being increased step-wise until a maximal concentration of 700 ng/ml of JPC-3210; resistance was measured phenotypically in drug susceptibility assays at multiple time points. Additionally, the ability of JPC-3210 to induce dormant stage parasites, and its effect on dihydroartemisinin (DHA)-induced dormant stages was assessed in both a chloroquine resistant parasite (W2) and in an artemisinin resistant clone (4G). Results showed that the frequency of resistance against JPC-3210 in W2 clones was less when compared to that of atovaquone. The step-wise pulse exposure of JPC-3210 induced resistance in W2 clones, however, resistance proved unstable. Dormant stage parasites were not induced by JPC-3210, even at high concentrations in W2 or 4G clones, furthermore, the effect of JPC-3210 on dormant-induced parasites was found to be dose dependent, yet the drug did not kill DHA-induced dormant rings. JPC-3210 appears to be a good drug to use in combination with other antimalarial compounds for treatment of P. falciparum, but further research is needed. Future studies to assess the field performance of new antimalarial compounds by investigating resistance and dormancy profiles in vitro, and thereby maximizing out understanding of such drugs and their optimal implementation, are of the utmost importance.

Toxoplasma gondii und Plasmodium Spezies sind obligat intrazelluläre Parasiten, die Zucker zur Energiehomöostase als auch für die Synthese lebenswichtiger Makromoleküle verwenden. Die hier vorgestellten Daten zeigen, dass der Glukosetransporter von T. gondii, TgGT1, und die homologen Transporter von P. falciparum und P. berghei, PfHT1 und PbHT1, neben Glukose auch Mannose, Fructose und Galactose transportieren. Toxoplasma Tachyzoiten exprimieren neben TgGT1 noch einen weiteren putative Zuckertransporter (TgST2) an der Parasitenoberfläche. Beide Proteine sind nicht essentiell, wie durch ihre individuelle und gleichzeitige Gendeletion belegt wird. Die Deletion von TgGT1 bewirkt einen geringen Wachstumsdefekt. Die Mutante ?tggt1 zeigt keine Glukoseaufnahmeaktivität und folglich eine verminderte glukoseabhängige Motilität. In ?tggt1 Parasiten wird ein verstärkter Glutaminstoffwechsel nachgewiesen, der ausreichend ist dessen Motilität und Replikationsaktivität zu erhalten. Die ?tggt1 Mutante gewährt Einblick in die Anpassungsfähigkeit von T. gondii an unterschiedliche Wirtszellen. Im Gegensatz zu T. gondii benötigen erythrozytäre Plasmodien Glukose und der Transporter PfHT1 wird derzeit als drug-target eingestuft. Hier wird gezeigt, dass das PfHT1-Homolog, PbHT1, essentiell in Blutstadien des Nagerparasiten Plasmodium berghei ist, jedoch auch während des gesamten Lebenszyklus des Parasiten exprimiert wird. Ein PfHT1- und PbHT1-spezifischer Inhibitor (Compound 3361) kann die Entwicklung von P. berghei Leberstadien und Okineten stark hemmen. Um zukünftig PfHT1-Inhibitoren im Hochdurchsatzverfahren zu identifizieren und testen zu können, wurden auf Saccharomyces cerevisiae und P. berghei basierende Expressionssysteme für PfHT1 entwickelt. Abschließend stellt diese Arbeit die Unterschiedlichkeit des zentralen Kohlenstoffwechsels von Toxoplasma und Plasmodium Parasiten durch bisher unbekannter Aspekte heraus.
Toxoplasma gondii and Plasmodium species are obligate intracellular pathogens that utilize host sugars for energy homeostasis and macro molecular synthesis. Here, we report that the T. gondii glucose transporter, TgGT1, and of its homologs of P. falciparum and P. berghei (PfHT1 and PbHT1) transport glucose, mannose, galactose and fructose. Besides TgGT1, Toxoplasma harbours one additional surface localized putative sugar transporter (TgST2). Surprisingly both Proteins are nonessential and only the deletion of TgGT1 inflicts a mild defect in the parasite replication. The ?tggt1 mutant is unable to import glucose and consequently displays an attenuated glucose-dependent motility, which is completely rescued by glutamine. ?tggt1 performs increased glutamine metabolism that is sufficient to sustain motility and replication. The ?tggt1 strain provides a model for further investigating its adaptation to disparate host cells. In contrast to T. gondii, erythrocytic stages of Plasmodium species critically depend on glucose uptake, and the PfHT1 transporter is considered as a drug target against human malaria. Here, we report that PbHT1 (a PfHT1 homolog) is also essential for blood stage development in the rodent malaria parasite P. berghei. PbHT1 is expressed throughout the life cycle. Moreover, a PfHT1- and PbHT1-specific sugar analogue, compound 3361, can inhibit the hepatic development and ookinete formation in P. berghei. These results signify that PbHT1 and exogenous glucose are also required during the ex-erythrocytic stages of P. berghei. To permit a high-throughput screening of selective PfHT1 inhibitors and their subsequent in vivo assessment, we have established a PfHT1-expressing Saccharomyces cerevisiae mutant and generated a PfHT1-dependent ?pbht1 of P. berghei strain. This thesis underscores various previously unknown aspects of sugar metabolism in Toxoplasma and Plasmodium, and unravel their metabolic differences.

Malaria was identified as one of the first infectious diseases recognised to spread through blood transfusion. Although transfusion acquired malaria is rare, nevertheless it can be lethal if it not diagnosed or treated immediately. It is a continuous challenge for the blood services to identify and exclude asymptomatic malaria infected donors, while minimising the exclusion of uninfected donors. The diagnostic tests in current use present certain limitations which include the use of inherently antigenically variable vaccine candidate proteins that have limited sensitivity against all human malaria species. Additionally, the blood transfusion services also require alternative methods for test and reagents that may be critical to the blood supply. There is therefore a scientific and an operational requirement to use alternative strategies to develop sensitive tests to all the species of malaria. In this study, we have used immunoproteomic approach to define conserved immunogenic malaria proteins. A total of 17 target P. falciparum proteins have been identified using cohorts of malaria immune sera from adults living in endemic areas, as well as by control sera from Europeans, who have never been exposed to malaria. The identified blood stage target antigens were cloned and expressed as recombinant proteins in a suitable bacterial system. In total, 15 target proteins have been expressed with 13 of them have been successfully purified. An ELISA-based system was developed, and the antigenicity of nine target antigens were evaluated using both non-malaria and malaria sera. Single antigen testing gave overall sensitivity of 50 - 84 %, with specificity consistently over 90%. Antigens such as Alpha tubulin and 26s protease showed promising immunogenicity, while Nucleosome assembly protein achieved 100% specificity. Further development of multiple antigens in an ELISA test will be required for continued evaluation of these antigens and the humoral immune response in malaria in general.

Malaria is a critical and global public health problem, affecting over 200 million people every year, resulting in over 500,000 deaths. A vaccine is not currently available and only one drug, primaquine, is effective against the dormant stages of Plasmodium vivax. Preclinical assessment of novel therapeutic drugs and vaccines is hampered by the lack of an in vitro liver model for P. falciparum and P. vivax. To provide a stable human hepatocyte-based culture platform for parasite development, we engineered a microfluidic bilayer device capable of both simple and complex culture methods, including perfusion and co-culture, to better understand the requirements of both hepatocytes as host cells and parasite liver stage development. As only the mechanical compaction of the device channels was found necessary for stable hepatocyte culture, and only a validated host cell lot was found necessary for improved parasite development rates, we present an efficient and simple Plasmodium liver model capable of supporting P. vivax dormant forms. Device liver platforms were used to generate kill curves of P. vivax and P. falciparum after three days under primaquine drug pressure. Furthermore, an anti-CSP antibody-based inhibition of development assay with P. falciparum successfully demonstrated antibody-specific liver stage inhibition. Ongoing studies aim to identify the minimal unit of the culture system necessary to be multiplexed in a fully functional and efficient drug and vaccine discovery platform.

Le paludisme reste l'une des plus redoutables maladies infectieuses avec plus de 200 millions d'infections et près de 430 000 décès chaque année, principalement des enfants de moins de 5 ans vivant en Afrique subsaharienne. L'espèce Plasmodium falciparum est responsable de la grande majorité de la mortalité. Le contrôle de l'endémie palustre reste encore aujourd'hui un problème majeur de santé publique, notamment à cause des résistances aux antipaludiques développées par les parasites. L'apparition de ces résistances s'opère par la pression de sélection médicamenteuse, et leur diffusion progressive se fait principalement via le déplacement des hôtes infectés. Cependant, la dynamique d'émergence, de diffusion et de persistance des parasites résistants résulte d'interactions complexes entre les antipaludiques, l'Homme, le parasite et le vecteur. Le travail présenté ici participe à la démarche de lutte contre le paludisme en proposant tout d'abord un état des lieux de la résistance de Plasmodium aux antipaludiques utilisés au Cameroun, avec des outils moléculaires, phénotypiques et cliniques. Une deuxième partie explore, in vitro, les possibles conséquences d'une utilisation prolongée des dérivés d'artémisinine sur le phénotype de P. falciparum, alors que la résistance à cette molécule est déjà installée. Le modèle in vitro utilisé a permis de mettre en évidence un nouveau profil de pluri-résistance suite à des pressions continues à l'artémisinine. Enfin, une dernière partie de ce travail analyse le rôle du moustique dans l'épidémiologie des résistances et montre que la sporogonie favoriserait la diffusion des allèles minoritaires, résistants ou non, présents chez l'Homme. L'ensemble de ces travaux confirme la multiplicité des facteurs agissants sur la dynamique de résistance et la complexité de leurs interactions rendant toute prévision très spéculative. Même si une meilleure connaissance des phénomènes sociétaux, épidémiologiques, biologiques et pharmacologiques impliqués dans les résistances reste une priorité, la surveillance phénotypique et génotypique régulière sur le terrain apparait à ce jour, le meilleur outil pour adapter au mieux les stratégies de contrôle du paludisme
Malaria remains one of the most terrible infectious diseases with more than 200 million infections and 430,000 deaths each year, mostly children under five years old in sub-Saharan Africa. Plasmodium falciparum is responsible for the vast majority of malaria mortality cases. Control of malaria still remains a major public health problem, in particular because of resistances to antimalarials that parasites developed. The apparition of these resistances is due to the drug pressure, and their progressive diffusion is mainly via the travelling of infected hosts. However, the dynamics of emergence, diffusion and persistence of resistant parasites result from complex interactions between the antimalarials, the Human, the parasite and the vector. The work presented here participates in the malaria control process by first proposing an inventory of Plasmodium resistance to antimalarials used in Cameroon, thanks to molecular, phenotypic and clinical tools. A second part explores the possible consequences of prolonged use of artemisinin derivatives on the P. falciparum phenotype, in areas where resistance to this molecule is already established. The in vitro model used showed that continuous artemisinin pressures induced a new pluri-resistance profile. Finally, a last part analyses the role of the mosquito in the epidemiology of resistances and shows that the sporogony favours the diffusion of minority alleles, resistant or not, presented in humans. All this work confirms the multiplicity of forces acting on the dynamics of resistances and the complexity of their interactions making any prediction very speculative. Even if better knowledge of the societal, epidemiological, biological and pharmacological phenomena involved in resistances is a priority, regular phenotypic and genotypic surveillance in the field remains the best tool for adapting malaria control strategies

Protozoan infections such as Malaria, Leishmaniasis, Toxoplasmosis, Chaga’s disease and African trypanosomiasis caused by the Plasmodium, Leishmania, Toxoplasma and Trypanosoma genuses respectively; inflict a huge economic, health and social impact in endemic regions particularly tropical and sub-tropical regions. The combined infections are estimated at over a billion annually and approximately 1.1 million deaths annually. The global burden of the protozoan infections is worsened by the increased drug resistance, toxicity and the relatively high cost of treatment and prophylaxis. Therefore there has been a high demand for new drugs and drug targets that play a role in parasite virulence. Cysteine proteases have been validated as viable drug targets due to their role in the infectivity stage of the parasites within the human host. There is a variety of cysteine proteases hence they are subdivided into families and in this study we focus on the clan CA, papain family C1 proteases. The current inhibitors for the protozoan cysteine proteases lack selectivity and specificity which contributes to drug toxicity. Therefore there is a need to identify the differences and similarities between the host, vector and protozoan proteases. This study uses a variety of bioinformatics tools to assess these differences and similarities. The Plasmodium cysteine protease FP-2 is the most characterized protease hence it was used as a reference to all the other proteases and its homologs were retrieved, aligned and the evolutionary relationships established. The homologs were also analysed for common motifs and the physicochemical properties determined which were validated using the Kruskal-Wallis test. These analyses revealed that the host and vector cathepsins share similar properties while the parasite cathepsins differ. At sub-site level sub-site 2 showed greater variations suggesting diverse ligand specificity within the proteases, a revelation that is vital in the design of antiprotozoan inhibitors.

In malaria-endemic regions, Plasmodium falciparum (P. falciparum) infection is characterized by extensive genetic/antigenic diversity. Describing this diversity provides important information about the local molecular epidemiology of infecting P. falciparum parasites. Intriguingly, one of the major obstacles to the development of an effective malaria vaccine has been the genetic polymorphisms exhibited by P. falciparum genes encoding targets of human immune system. This situation has necessitated the development of polyvalent vaccines with wide antigenic coverage that would increase the likelihood of vaccine efficacy that covers wide geographical areas of malaria endemic countries. Limited reports are available on the population genetic diversity and structure of P. falciparum in Malawi, and this is of particular concern as the country has put in place several interventions to combat the disease. The primary aim of the research project was to determine the genetic diversity and population structure of P. falciparum isolates and comparing complexity from four different epidemiological settings in Malawi using msp-2 gene polymorphisms. Samples were collected from four epidemiological locations in the north, centre and southern regions of Malawi. The diversity and genetic differentiation of P. falciparum populations were analyzed based on the highly polymorphic block 3 msp-2 gene. One hundred and twenty patient samples who presented with signs and symptoms of malaria and who had microscopically confirmed P. falciparum infection were enrolled in the study after they had satisfied the inclusion criteria. Parasite DNA was extracted from the blood spot on to filter paper and analyzed by genotyping the msp-2 gene using allele-specific nested PCR. A total of 28 msp-2 block 3 fragments, defined by the size and the allelic types were detected in the 102 patients. The length variants of the PCR product ranged from 240basepairs (bp) to 450bp for the K1/FC and 410bp to 780bp for the 3D7/IC allelic families. Isolates of the 3D7 alleles were predominant in the population (59 percent), compared to isolates of the K1/ FC27 alleles (41 percent) and for 3D7 and K1 most of the isolates were monoclonal infections. In comparisons between the sites, we observed the highest prevalence of mixed infection in Mwanza (46.7 percent) followed by Dwangwa (23.3 percent) compared to Bolero (16.7 percent) and Mitundu (16.7 percent). The difference in prevalence of mixed infections between Mwanza and the other sites was statistically significant (p=0.041). There was also a non-significant trend towards a higher mean genotype number per isolate in the children aged >5 years compared to those below 5 years of age. These data suggest differences in prevalence rates of mixed infections in different geographical/epidemiological settings in Malawi. Further studies are needed to confirm, with larger sample sizes, the observation of a non-significant trend towards higher multiclonality of infection in older children in malaria endemic areas of Malawi.

RESUMO: A Malária é causada por parasitas do género Plasmodium, sendo a doença parasitária mais fatal para o ser humano. Apesar de, durante o século passado, o desenvolvimento económico e a implementação de diversas medidas de controlo, tenham permitido erradicar a doença em muitos países, a Malária continua a ser um problema de saúde grave, em particular nos países em desenvolvimento. A Malária é transmitida através da picada de uma fêmea de mosquito do género Anopheles. Durante a picada, os esporozoítos são injetados na pele do hospedeiro, seguindo-se a fase hepática e obrigatória do ciclo de vida. No fígado, os esporozoítos infetam os hepatócitos onde se replicam, dentro de um vacúolo parasitário (VP) e de uma forma imunitária silenciosa, em centenas de merozoitos. Estas novas formas do parasita são as responsáveis por infetar os eritrócitos, iniciando a fase sanguínea da doença, onde se os primeiros sintomas se manifestam, tais como a característica febre cíclica. A fase hepática da doença é a menos estudada e compreendida. Mais ainda, as interações entre o VP e os organelos da células hospedeira estão ainda pouco caracterizados. Assim, neste estudo, as interações entre os organelos endocíticos e autofágicos da célula hospedeira e o VP foram dissecados, observando-se que os anfisomas, que são organelos resultantes da intersecção do dois processos de tráfego intracelular, interagem com o parasita. Descobrimos que a autofagia tem também uma importante função imunitária durante a fase hepática inicial, ao passo, que durante o desenvolvimento do parasita, já numa fase mais tardia, o parasita depende da interação com os endossomas tardios e anfisomas para crescer. Vesiculas de BSA, EGF e LC3, foram, também, observadas dentro do VP, sugerindo que os parasitas são capazes de internalizar material endocítico e autofágico do hospedeiro. Mais ainda, mostramos que esta interação depende da cinase PIKfyve, responsável pela conversão do fosfoinositidio-3-fosfato no fosfoinositidio-3,5-bifosfato, uma vez que inibindo esta cinase o parasita não é capaz de crescer normalmente. Finalmente, mostramos que a proteína TRPML1, uma proteína efetora do fosfoinositidio-3,5-bifosfato, e envolvida no processo de fusão das membranas dos organelos endocíticos e autofágicos, também é necessária para o crescimento do parasita. Desta forma, o nosso estudo sugere que a membrana do VP funde com vesiculas endocíticas e autofágicas tardias, de uma forma dependente do fositidio-3,5-bifosfato e do seu effetor TRPML1, permitindo a troca de material com a célula hospedeira. Concluindo, os nossos resultados evidenciam que o processo autofágico que ocorre na célula hospedeira tem um papel duplo durante a fase hepática da malaria. Enquanto numa fase inicial os hepatócitos usam o processo autofágico como forma de defesa contra o parasita, já durante a fase de replicação o VP funde com vesiculas autofágicas e endocíticas de forma a obter os nutrientes necessários ao seu desenvolvimento.--------- ABSTRACT: Malaria, which is caused by parasites of the genus Plasmodium, is the most deadly parasitic infection in humans. Although economic development and the implementation of control measures during the last century have erradicated the disease from many areas of the world, it remains a serious human health issue, particularly in developing countries. Malaria is transmitted by female mosquitoes of the genus Anopheles. During the mosquito blood meal, Plasmodium spp. sporozoites are injected into the skin dermis of the vertebrate host, followed by an obligatory liver stage. Upon entering the liver, Plasmodium parasites infect hepatocytes and silently replicate inside a host cell-derived parasitophorous vacuole (PV) into thousands of merozoites. These new parasite forms can infect red blood cells initiating the the blood stage of the disease which shows the characteristic febrile malaria episodes. The liver stage is the least characterized step of the malaria infection. Moreover, the interactions between the Plasmodium spp. PV and the host cell trafficking pathways are poorly understood. We dissected the interaction between Plasmodium parasites and the host cell endocytic and autophagic pathways and we found that both pathways intersect and interconnect in the close vicinity of the parasite PV, where amphisomes are formed and accumulate. Interestingly, we observed a clearance function for autophagy in hepatocytes infected with Plasmodium berghei parasites at early infection times, whereas during late liver stage development late endosomes and amphisomes are required for parasite growth. Moreover, we found the presence of internalized BSA, EGF and LC3 inside parasite vacuoles, suggesting that the parasites uptake endocytic and autophagic cargo. Furthermore, we showed that the interaction between the PV and host traffic pathways is dependent on the kinase PIKfyve, which converts the phosphoinositide PI(3)P into PI(3,5)P2, since PIKfyve inhibition caused a reduction in parasite growth. Finally, we showed that the PI(3,5)P2 effector protein TRPML1, which is involved in late endocytic and autophagic membrane fusion, is also required for parasite development. Thus, our studies suggest that the parasite parasitophorous vacuole membrane (PVM) is able to fuse with late endocytic and autophagic vesicles in a PI(3,5)P2- and TRPML1-dependent manner, allowing the exchange of material between the host cell and the parasites, necessary for the rapid development of the latter that is seen during the liver stage of infection. In conclusion, we present evidence supporting a specific and essential dual role of host autophagy during the course of Plasmodium liver infection. Whereas in the initial hours of infection the host cell uses autophagy as a cell survival mechanism to fight the infection, during the replicative phase the PV fuses with host autophagic and endocytic vesicles to obtain nutrients required for parasite growth.

La chimioresistance de plasmodium falciparum est etudiee a travers les populations impaludees et au sein des populations plasmodiales. Les trois outils mis en uvre sont l'epidemiologie, la recherche clinique et la recherche fondamentale. Les resultats concernant les populations impaludees portent sur l'evolution des taux d'incidence d'acces palustre chez les voyageurs, l'evolution des taux de prevalence et des niveaux de chimioresistance en afrique de l'ouest et le role de la biodisponibilite dans l'interpretation des echecs therapeutiques. Les travaux portant sur les populations plasmodiales contribuent a l'etude des clones parasitaires, revelent une resistance croisee entre les aryls-amino-alcools et reproduisent experimentalement les effets de la pression medicamenteuse in vitro. Nous poursuivons nos recherches avec le meme objectif qu'est de degager des alternatives therapeutiques au vu de donnees fondamentales, cliniques et epidemiologiques dans l'espoir de contribuer a la lutte antipaludique

Les mecanismes de l'endocytose, phenomene actif impliquant l'interaction de structures parietales de l'hematie hote et du plasmodium parasite sont encore tres imparfaitement elucides. Cette recherche se propose de preciser le role de deux constituants de la membrane erythrocytaire: le cholesterol et les dimeres proteiques de la bande 3, dans l'endocytose plasmodiale. Pour cela, des hematies humaines ont ete enrichies en cholesterol par le biais de liposomes jusqu'a atteindre un enrichissement effectif (evalue par la methode de liebermann) de 28%, a la limite de l'hemolyse. La bande 3 a ete purifiee a partir de membranes erythrocytaires, d'abord par chromatographie sur resine echangeuse d'ions, puis d'apres une methode utilisant une colonne de thiol-sepharose. La paroi des erythrocytes a ete enrichie en bande 3 en utilisant des liposomes multilamellaires de phosphatidylcholine. Les hematies ainsi modifiees et enrichies, soit en cholesterol, soit en bande 3, ont servi de substrat pour la culture de p. Falciparum selon la methode de trager et jensen. Cette culture in vitro des formes de la schizogonie intra-erythrocytaire de p; falciparum souche sge 1 et l'evaluation des parasitemies observees dans les differentes conditions de l'experimentation, ont permis une evaluation chiffree des resultats. Ceux-ci demontrent que la teneur en cholesterol n'influence en aucune facon l'endocytose de p. Falciparum contrairement aux conclusions de breuer. Pour la bande 3, ils suggerent qu'elle intervient effectivement dans le processus d'invasion car dans les diverses conditions realisees au cours de l'experimentation, des variations considerables de la parasitemie ont ete relevees en fonction du niveau d'enrichissement des erythrocytes servant de substrat a la culture et des conditions du contact globule rouge-liposome (conditions d'incubation)

La forme la plus sévère de paludisme est causée par le parasite unicellulaire P. falciparum. Lors de la phase intra-érythrocytaire de son développement, P. falciparum met en place des fonctions métaboliques nécessaires à son développement dans l'érythrocyte, à sa multiplication et enfin à sa dissémination vers d'autres érythrocytes. Comprendre et élucider les structures et les dynamiques du réseau métabolique chez le parasite, permettent de découvrir de nouvelles voies métaboliques et des étapes clefs qui peuvent jouer un rôle important dans le développement du parasite. Elles permettent également de déterminer le mécanisme d'action des agents antipaludiques et de mieux comprendre les résistances associées aux traitements existants. Dans cet objectif, une approche métabolomique ciblée, utilisant la chromatographie liquide couplée à la spectrométrie de masse en tandem (LC-MS/MS) a été utilisée. Cette approche consiste en une quantification absolue de métabolites impliqués dans les voies de biosynthèse des phospholipides membranaires du parasite mais également d'autres métabolites qui reflètent son statut métabolique. Nous avons dans un premier temps, déterminé les distributions et les quantités absolues des métabolites présents dans un érythrocyte infecté par P. falciparum en comparaison avec un érythrocyte sain. Nous avons également mis en évidence les perturbations causées par cette infection sur le métabolisme de l'érythrocyte humain ainsi que les différents échanges qu'entretien le parasite avec sa cellule hôte mais également avec le milieu extracellulaire. Le métabolisme phospholipidique de Plasmodium est complexe car il possède plusieurs voies de synthèses opérant à partir de précurseurs initiaux distincts et conduisant à la synthèse d'un même produit final. Dans l'objectif d'étudier la contribution relative des différentes voies métaboliques dans la biosynthèse des phospholipides majoritaires chez P. falciparum (PC et PE), nous avons développé une approche qui consiste à incuber les érythrocytes infectés en présence de précurseurs marqués
The most severe form of malaria is caused by the single-celled parasite P. falciparum. During the intra-erythrocytic stage of its development, P. falciparum implements several metabolic functions necessary for its development in the erythrocyte, its multiplication and finally to its spread to other erythrocytes. Understand and elucidate the structures and the dynamics of the parasite's metabolic network is useful to discover new metabolic pathways and key steps that may play an important role in the development of the parasite. They also help determine the mechanism of action of antimalarial agents and better understand the resistances associated with available treatments. For this purpose, a targeted metabolomics approach, using liquid chromatography-tandem mass spectrometry (LC-MS/MS) was used. This approach consists of an absolute quantitation of metabolites involved in the biosynthesis of membrane phospholipids of the parasite but also other metabolites that reflect its metabolic status. We initially determined the distributions and the absolute amounts of metabolites in infected erythrocytes in comparison with healthy erythrocytes. We also highlighted the disruption caused by this infection on the metabolism of the human erythrocyte and the various interactions between the parasite and its host cell as well as the extracellular medium. The phospholipids metabolism of Plasmodium is complex because it has several synthetic pathways operating from separate initial precursor and leading to the synthesis of a single end product. With the aim to study the relative contribution of these different metabolics pathways in the biosynthesis of the most important phospholipids in P. falciparum (PC and PE), we have developed an approach that involves incubation of infected erythrocytes in the presence of labeled precursors

Le paludisme est causé par un parasite appelé Plasmodium falciparum, transmis lors de la piqûre d'un moustique. Au stade sanguin, ce parasite unicellulaire, de forme ovoïde, envahit les globules rouges, s'y multiplie avant d'être libéré pour une nouvelle invasion à la fin d'un cycle de 48 heures. Ce travail de thèse porte sur le mouvement du parasite au cours du processus d'invasion. L'étape préalable à la pénétration du parasite dans sa cellule hôte est le mouvement de réorientation permettant de mettre en contact son complexe apical avec la membrane de la cellule hôte. Afin de comprendre comment le parasite génère les mouvements nécessaires à cette réorientation sans l'aide de flagelle, de cil ou de déformation, notre approche est d'observer et de décrire le mouvement des parasites sur un substrat rigide, au travers d'une analyse détaillée des trajectoires du parasite. Nous observons que le parasite explore tous les degrés de liberté qui lui sont accessibles compte tenu de son attachement au substrat: translation et rotation dans le plan et réorientation de sa partie apicale. Nous avons identifié trois types de mouvement: confiné, dirigé et circulaire. Nous caractérisons ces trajectoires et mouvements en utilisant une analyse de corrélation et en discutant les mécanismes possibles à l'origine de ces trajectoires particulières. Enfin, nous examinons le rôle des constituants du cytosquelette sur le mouvement du parasite, en affectant spécifiquement les filaments d'actine et les microtubules. Les conséquences de la polymérisation de ces structures sur le mouvement du parasites sont discutées
Malaria is caused by a parasite called Plasmodium falciparum, transmitted via mosquito's bites. At the blood stage, these unicellular ovoidal parasites invade red blood cells (RBCs), multiply and are released at the end of a 48h cycle, ready for new invasions. This work is focused on the motion of the parasite during the invasion process. To penetrate into the host cell, the parasite reorient its apical part towards the RBC membrane. For this purpose, the parasite generates different movements that allow him to find the correct position to form a specific junction to invade the cell. To understand how the parasite is able to move and reorient without the aid of cilia, flagella or deformations, we performed a detailed analysis of the parasite trajectories and orientation on rigid substrate. We observe that the substrate-attached parasite explores all degrees of freedom with in-plane rotation, translation and flipping. Three types of motion have been identified: confined, directed circular . We characterize these trajectories and motions using correlation analysis and we discuss the possible mechanisms that could explain these peculiar trajectories. Finally, to determine the role of the cytoskeleton components in the parasite motion, specific structures such as the actin filaments and the microtubules have been specifically affected. We will describe and discuss the consequences of depolymerizing or stabilizing these structures

Hest shock protein 70 (Hsp70) class of chaperones is highly conserved and present ubiquitously in all cellular organisms They play important role in folding of nascent polypeptides and translocation of precursor proteins to endoplasmic reticulum, mitochondria and chloroplast Hsp70 assists in assembly of proteins complexes as well as in disassembly e g uncoatmg of clathrin coated vesicles Chaperone function of Hsp70 is modulated by cochaperones of DnaJ class, Hip, Hop etc Hsp70 is a component of multi chaperone complex with Hsp90 and helps in maturation of kinases or transcription factors. Plasmodium falciparum is responsible for most severe form of human malaria Plasmodmm in its intraerythrocytic cycle presents an example of a cell with multiple, complex membrane bound structures both inside the parasite as well as m the infected erythrocyte cytosol Parasite deploys proteins in host erythrocyte cytosol, at erythrocyte plasma membrane or traffics them for secretion outside the infected cell in addition to trafficking of proteins to its own organelles like mitochondria, apicoplast, food vacuole, ER etc It is of interest to malaria biologists to understand these trafficking events and role of chaperones in regulating them This study was aimed at understanding the function(s) of Hsp70 in Plasmodium infected erythrocyte in protein maturation and trafficking events We have attempted to study Hsp70 chaperone present in Plasmodium infected erythrocytes We have largely focused on the cytosohc Hsp70, PfHsp70, in the parasite and systematically analyzed its expression, localization, abundance and complexes in the intraerythrocytic cycle To gain insight into its function, we have identified a subset of PfHsp70 interacting proteins, parasite Hsp90, Hsp70-3, Hsp60 and beta tubulin by coimmunoprecipitation experiments in conjunction with proteomic tools like 2DGE and mass spectrometry Parasite Hsp60 is a mitochondria-targeted protein and we have examined the involvement of PfHsp70 in translocation of Hsp60 precursor protein to parasite mitochondrion PfHsp70 and PfHsp90 were found to be present in a complex Geldanarnycm, a drug that affects Hsp70-Hsp90 complex, was used to investigate the role of PfHsp70 in parasite protein trafficking Since there are no known parasite derived chaperones in erythrocyte cytosol compartment, we have examined the possible "involvement of host Hsp70 in supporting transport and assembly of parasite proteins in erythrocyte cytosol Hsp70 in Plasmodium falciparum intraerythrocytic cycle P. falciparum genome codes for five Hsp70 homologs Two of these, pfHsp70-l and PfBiP are expressed in intraerythrocytic stage and have been localized to nucleocytoplasmic and endoplasmic reticulum fraction of the parasite respectively We have focused this study on PfHsp70 of the parasite We show that PfHsp70 is an abundant protein in the cytosol constituting about 2% of the total soluble pool It gets further induced during stress like heat shock and translocates to nuclear fraction indicating that PfHsp70 may be involved in protective function in the parasite nucleus during stress Nuclear translocation of mammalian Hsp70 during stress has been linked to its phosphorylation at Tyr524 We found PfHsp70 to be phosphorylated by in vivo phosphate labeling m the parasite Analysis of PfHsp70 by 2-dimensional gel electrophoresis on narrow gradient IPG strips indicated that it exists in four forms differing in their isoelectnc points (pi) Phosphatase treatment combined with analysis using a phosphorylation prediction tool,Proteomod (http //www biochem use ernet in/proteomod html) suggested that PfHsp70 is phosphorylated at three residues in the parasite The extent of phosphorylation of PfHsp70 may determine substrate specificity or subcellular localization or both Using 2DGE and mass spectrometry approach, we also identified chaperones like Hsp909 BiP, Hsp60, and protein disulphide isomerase (PDI) m P falciparum proteome In summary, PfHsp70 appears to be a highly abundant, cytosohc chaperone It is inducible by stress and multiply phosphorylated and is likely to participate in multiple processes in the parasite. PfHsp70 complexes and interacting proteins in the parasite To gam insight into the functions of Hsp70, we looked for PfHsp70 interacting proteins in the parasite We used gel filtration chromatography to resolve and enrich PfHsp70 complexes and also employed coimmunoprecipitation approach to identify interacting proteins We found parasite Hsp90, Hsp70-3, Hsp60 and beta-tubulin interact with PfHsp70 Fractionation of parasite lysate indicated that PfHsp70 is present in two major complexes of 200 kDa and 450 kDa We find that PfHsp90 interacts with PfHsp70 and both are present in 450 kDa complex Our analysis indicated that 450-kDa complex is like Hsp70-Hsp90 multichaperone complex described in mammalian cells while 200 kDa complex is likely to be an Hsp70-cochaperone complex Smaller complex appears to be a precursor for multichaperone complex Use of an Hsp90 inhibitor, geldanamycin (GA), to study the function of this multi chaperone showed that GA inhibits parasite growth Maturation of four phosphoproteins interacting with PfHsp70 was affected by GA implicating them in regulation of parasite growth GA appeared to mediate its effects by inhibiting H§p^0 phosphorylation Amongst the other three interacting proteins, PfHsp70-3 is amoveJ/Hsp70 homolog that was found at the protein level for the first time in this study PfHsp60 is mitochondria-targeted protein in the parasite and it is likely that cytoshc PfHsp70 helps in translocation of PfHsp60 to mitochondria from cytosol Tubuhn is a cytoskeletal protein and its interaction with PfHsp70 suggests possible role of PfHsp70 in cytoskeleton organization during invasion, growth or cell division In all, we find that Hsp70 in the parasite exist in a multi chaperone complex with Hsp90 which might be responsible for maturation of signaling molecules important for growth The smaller complex of PfHsp70 is a precursor of multi chaperone complex and is likely to be an Hsp70- co chaperone complex Role of Hsp70 in protein translocation and trafficking Cytosolic Hsp70 aids in translocation of precursor proteins from cytosol to mitochondria (or chloroplast) We found a mitochondnal chaperone, PfHsp60, interact with PfHsp70 and we examined the possibility that PfHsp60 translocation is assisted by cytosolic PfHsp70 We found that PfHsp60 had a cleavable, N-thermal targeting sequence Examination of PfHsp60 forms present in mitochondnal and cytosolic fraction of the parasite showed that mitochondnal form was more acidic in pi than cytosolic form as expected after targeting sequence cleavage Cytosolic PfHsp60 interacted with both PfHsp70 and PfHsp90 Interestingly, while mitochondnal PfHsp60 appeared to be in a chaperonm like complex, as expected, cytosolic form was present in smaller ohgomeric complex of about 450 kDa This suggested that PfHsp60 precursor form could be bound to multichperone complex All these experiments together strongly indicated that PfHsp60 precursor interacts with cytosolic Hsp70 and Hsp90 before former's translocation into mitochondria This interaction might be required to keep the precursor in the transport competent state P falciparum lives inside a vacuole in the infected cells but it deploys a number of proteins to host cell cytosol and to the plasma membrane To examine the involvement of multichaperone complex in trafficking, we studied the effect of GA on targeting of two parasite proteins, knob associated histidme-rich protein (KAHRP) and glycogen synthase kinase (GSK) KAHRP is indispensable for the formation of cytoadherence complexes called knobs at erythrocyte plasma membrane We found that KAHRP transport to erythrocyte plasma membrane was blocked in GA-treated parasites and it appeared all over the infected cell Further analysis showed that GA caused block in KAHRP transport at some step beyond its exit from parasite ER The targeting of GSK to membranous inclusions in the infected RBC cytosol was not severely affected m the GA-treated parasites suggesting that GSK transport may not be regulated by multi chaperone complex It also indicated that parasite may be using different pathways for trafficking of proteins to the host compartment In summary, PfHsp70 and PfHsp90 interact with PfHsp60 precursor in the cytosol They probably help keep the precursor in transport competent form before arrival at the translocase complex of mitochondria The multi chaperone complex may also be important for trafficking of at least one parasite protein, KAHRP, to the host cell compartment Analysis of erythrocyte Hsp70 in Plasmodium falciparum infected cells The remodeled plasma membrane of parasite-infected erythrocytes is important for the cytoadherence property of the infected cells Knobs, supramolecular complexes on the infected cell surface, formed by parasite proteins, PfEMPl, KAHRP, and PfEMP3 are responsible for cytoadherence of infected cells to vascular endothehum or placenta KAHRP transport is BFA-sensitive inside the parasite while PfEMP proteins undergo vesicle mediated trafficking in the erythrocyte cytosol The involvement of molecular chaperones has been implicated in the trafficking and assembly of knob components in the erythrocyte cytosol There is no evidence for the presence of bona fide parasite derived chaperones in the host compartment The chaperones of the erythrocyte origin, Hsp70, Hsp90, Hip and Hop were readily detected in the host cytosol, on the other hand By analyzing localization, abundance and biochemical characteristics of the host chaperones of erythrocyte origin, we examined if host chaperones are being utilized by the parasite for its functions Localization experiment showed that while PfHsp70, PfHsp90 and PfBiP were present in the parasite compartment, host-Hsp70 was present in erythrocyte cytosol fraction Host~Hsp70 was about 60% as abundant as PfHsp70 and was potentially capable of facilitating chaperone function in the erythrocyte cytosol Though host-Hsp70 was soluble in unmfected cells, it was present in membrane bound, triton-insoluble complexes, containing KAHRP, in infected cells Since knobs are triton-insoluble complexes at the erythrocyte plasma membrane, we isolated erythrocyte ghost (plasma membrane) fraction and could detect both Hsp70 and KAHRP Hsp70 association with erythrocyte plasma membrane was specific as it could be crosshnked to KAHRP in ghost fraction of infected cells Host-hsp70 was present in purified cytoskeleton fraction containing knobs from infected cells along with cochaperone Hop All these evidences suggest that parasite may be exploiting host-Hsp70 in erythrocyte cytosol compartment Summary This study gives insight into some functions performed by PfHsp70 in mtraerythrocytic cycle of malarial parasite PfHsp70 is an abundant cytosohc chaperone in the parasite It gets induced during stress and translocates to the nucleus It is also phosphorylated at three sites Analysis of Pfhsp70 complexes shows that it is present in bimodal complexes (450 kDa and 200 kDa), which are in equilibrium PfHsp70 and PfHsp90 interact and are part of 450 kDa multichaperone complex This multichaperone complex appears to regulate trafficking of one parasite protein to host cytosol compartment In addition, PfHsp70 and PfHsp90 are also bound to mitochondria-targeted PfHsp60 precursor in the cytosol probably keeping them m a transport competent state In addition to PfHsp90 and PfHsp60, PfHsp70 interacts with a novel Hsp70 homolog of the parasite, PfHsp70-3, and cytoskeletal protein, beta-tubuhn Examination of chaperones available in erythrocyte cytosol, showed that parasite chaperones were absent while host chaperone (Hsp70) was present and exhibited altered properties during parasite infection It was associated with membrane-bound, triton-insoluble complexes on the infected cell plasma membrane suggesting that host-Hsp70 might be involved in trafficking and/or assembly of parasite proteins In all, PfHsp70, as part of multichaperone complex, appears to be regulating translocation and trafficking of parasite proteins to organellar locations or outside the parasite Host-Hsp70, in erythrocyte cytosol, might also be engaged in specific chaperone function upon infection

Hest shock protein 70 (Hsp70) class of chaperones is highly conserved and present ubiquitously in all cellular organisms They play important role in folding of nascent polypeptides and translocation of precursor proteins to endoplasmic reticulum, mitochondria and chloroplast Hsp70 assists in assembly of proteins complexes as well as in disassembly e g uncoatmg of clathrin coated vesicles Chaperone function of Hsp70 is modulated by cochaperones of DnaJ class, Hip, Hop etc Hsp70 is a component of multi chaperone complex with Hsp90 and helps in maturation of kinases or transcription factors. Plasmodium falciparum is responsible for most severe form of human malaria Plasmodmm in its intraerythrocytic cycle presents an example of a cell with multiple, complex membrane bound structures both inside the parasite as well as m the infected erythrocyte cytosol Parasite deploys proteins in host erythrocyte cytosol, at erythrocyte plasma membrane or traffics them for secretion outside the infected cell in addition to trafficking of proteins to its own organelles like mitochondria, apicoplast, food vacuole, ER etc It is of interest to malaria biologists to understand these trafficking events and role of chaperones in regulating them This study was aimed at understanding the function(s) of Hsp70 in Plasmodium infected erythrocyte in protein maturation and trafficking events We have attempted to study Hsp70 chaperone present in Plasmodium infected erythrocytes We have largely focused on the cytosohc Hsp70, PfHsp70, in the parasite and systematically analyzed its expression, localization, abundance and complexes in the intraerythrocytic cycle To gain insight into its function, we have identified a subset of PfHsp70 interacting proteins, parasite Hsp90, Hsp70-3, Hsp60 and beta tubulin by coimmunoprecipitation experiments in conjunction with proteomic tools like 2DGE and mass spectrometry Parasite Hsp60 is a mitochondria-targeted protein and we have examined the involvement of PfHsp70 in translocation of Hsp60 precursor protein to parasite mitochondrion PfHsp70 and PfHsp90 were found to be present in a complex Geldanarnycm, a drug that affects Hsp70-Hsp90 complex, was used to investigate the role of PfHsp70 in parasite protein trafficking Since there are no known parasite derived chaperones in erythrocyte cytosol compartment, we have examined the possible "involvement of host Hsp70 in supporting transport and assembly of parasite proteins in erythrocyte cytosol Hsp70 in Plasmodium falciparum intraerythrocytic cycle P. falciparum genome codes for five Hsp70 homologs Two of these, pfHsp70-l and PfBiP are expressed in intraerythrocytic stage and have been localized to nucleocytoplasmic and endoplasmic reticulum fraction of the parasite respectively We have focused this study on PfHsp70 of the parasite We show that PfHsp70 is an abundant protein in the cytosol constituting about 2% of the total soluble pool It gets further induced during stress like heat shock and translocates to nuclear fraction indicating that PfHsp70 may be involved in protective function in the parasite nucleus during stress Nuclear translocation of mammalian Hsp70 during stress has been linked to its phosphorylation at Tyr524 We found PfHsp70 to be phosphorylated by in vivo phosphate labeling m the parasite Analysis of PfHsp70 by 2-dimensional gel electrophoresis on narrow gradient IPG strips indicated that it exists in four forms differing in their isoelectnc points (pi) Phosphatase treatment combined with analysis using a phosphorylation prediction tool,Proteomod (http //www biochem use ernet in/proteomod html) suggested that PfHsp70 is phosphorylated at three residues in the parasite The extent of phosphorylation of PfHsp70 may determine substrate specificity or subcellular localization or both Using 2DGE and mass spectrometry approach, we also identified chaperones like Hsp909 BiP, Hsp60, and protein disulphide isomerase (PDI) m P falciparum proteome In summary, PfHsp70 appears to be a highly abundant, cytosohc chaperone It is inducible by stress and multiply phosphorylated and is likely to participate in multiple processes in the parasite. PfHsp70 complexes and interacting proteins in the parasite To gam insight into the functions of Hsp70, we looked for PfHsp70 interacting proteins in the parasite We used gel filtration chromatography to resolve and enrich PfHsp70 complexes and also employed coimmunoprecipitation approach to identify interacting proteins We found parasite Hsp90, Hsp70-3, Hsp60 and beta-tubulin interact with PfHsp70 Fractionation of parasite lysate indicated that PfHsp70 is present in two major complexes of 200 kDa and 450 kDa We find that PfHsp90 interacts with PfHsp70 and both are present in 450 kDa complex Our analysis indicated that 450-kDa complex is like Hsp70-Hsp90 multichaperone complex described in mammalian cells while 200 kDa complex is likely to be an Hsp70-cochaperone complex Smaller complex appears to be a precursor for multichaperone complex Use of an Hsp90 inhibitor, geldanamycin (GA), to study the function of this multi chaperone showed that GA inhibits parasite growth Maturation of four phosphoproteins interacting with PfHsp70 was affected by GA implicating them in regulation of parasite growth GA appeared to mediate its effects by inhibiting H§p^0 phosphorylation Amongst the other three interacting proteins, PfHsp70-3 is amoveJ/Hsp70 homolog that was found at the protein level for the first time in this study PfHsp60 is mitochondria-targeted protein in the parasite and it is likely that cytoshc PfHsp70 helps in translocation of PfHsp60 to mitochondria from cytosol Tubuhn is a cytoskeletal protein and its interaction with PfHsp70 suggests possible role of PfHsp70 in cytoskeleton organization during invasion, growth or cell division In all, we find that Hsp70 in the parasite exist in a multi chaperone complex with Hsp90 which might be responsible for maturation of signaling molecules important for growth The smaller complex of PfHsp70 is a precursor of multi chaperone complex and is likely to be an Hsp70- co chaperone complex Role of Hsp70 in protein translocation and trafficking Cytosolic Hsp70 aids in translocation of precursor proteins from cytosol to mitochondria (or chloroplast) We found a mitochondnal chaperone, PfHsp60, interact with PfHsp70 and we examined the possibility that PfHsp60 translocation is assisted by cytosolic PfHsp70 We found that PfHsp60 had a cleavable, N-thermal targeting sequence Examination of PfHsp60 forms present in mitochondnal and cytosolic fraction of the parasite showed that mitochondnal form was more acidic in pi than cytosolic form as expected after targeting sequence cleavage Cytosolic PfHsp60 interacted with both PfHsp70 and PfHsp90 Interestingly, while mitochondnal PfHsp60 appeared to be in a chaperonm like complex, as expected, cytosolic form was present in smaller ohgomeric complex of about 450 kDa This suggested that PfHsp60 precursor form could be bound to multichperone complex All these experiments together strongly indicated that PfHsp60 precursor interacts with cytosolic Hsp70 and Hsp90 before former's translocation into mitochondria This interaction might be required to keep the precursor in the transport competent state P falciparum lives inside a vacuole in the infected cells but it deploys a number of proteins to host cell cytosol and to the plasma membrane To examine the involvement of multichaperone complex in trafficking, we studied the effect of GA on targeting of two parasite proteins, knob associated histidme-rich protein (KAHRP) and glycogen synthase kinase (GSK) KAHRP is indispensable for the formation of cytoadherence complexes called knobs at erythrocyte plasma membrane We found that KAHRP transport to erythrocyte plasma membrane was blocked in GA-treated parasites and it appeared all over the infected cell Further analysis showed that GA caused block in KAHRP transport at some step beyond its exit from parasite ER The targeting of GSK to membranous inclusions in the infected RBC cytosol was not severely affected m the GA-treated parasites suggesting that GSK transport may not be regulated by multi chaperone complex It also indicated that parasite may be using different pathways for trafficking of proteins to the host compartment In summary, PfHsp70 and PfHsp90 interact with PfHsp60 precursor in the cytosol They probably help keep the precursor in transport competent form before arrival at the translocase complex of mitochondria The multi chaperone complex may also be important for trafficking of at least one parasite protein, KAHRP, to the host cell compartment Analysis of erythrocyte Hsp70 in Plasmodium falciparum infected cells The remodeled plasma membrane of parasite-infected erythrocytes is important for the cytoadherence property of the infected cells Knobs, supramolecular complexes on the infected cell surface, formed by parasite proteins, PfEMPl, KAHRP, and PfEMP3 are responsible for cytoadherence of infected cells to vascular endothehum or placenta KAHRP transport is BFA-sensitive inside the parasite while PfEMP proteins undergo vesicle mediated trafficking in the erythrocyte cytosol The involvement of molecular chaperones has been implicated in the trafficking and assembly of knob components in the erythrocyte cytosol There is no evidence for the presence of bona fide parasite derived chaperones in the host compartment The chaperones of the erythrocyte origin, Hsp70, Hsp90, Hip and Hop were readily detected in the host cytosol, on the other hand By analyzing localization, abundance and biochemical characteristics of the host chaperones of erythrocyte origin, we examined if host chaperones are being utilized by the parasite for its functions Localization experiment showed that while PfHsp70, PfHsp90 and PfBiP were present in the parasite compartment, host-Hsp70 was present in erythrocyte cytosol fraction Host~Hsp70 was about 60% as abundant as PfHsp70 and was potentially capable of facilitating chaperone function in the erythrocyte cytosol Though host-Hsp70 was soluble in unmfected cells, it was present in membrane bound, triton-insoluble complexes, containing KAHRP, in infected cells Since knobs are triton-insoluble complexes at the erythrocyte plasma membrane, we isolated erythrocyte ghost (plasma membrane) fraction and could detect both Hsp70 and KAHRP Hsp70 association with erythrocyte plasma membrane was specific as it could be crosshnked to KAHRP in ghost fraction of infected cells Host-hsp70 was present in purified cytoskeleton fraction containing knobs from infected cells along with cochaperone Hop All these evidences suggest that parasite may be exploiting host-Hsp70 in erythrocyte cytosol compartment Summary This study gives insight into some functions performed by PfHsp70 in mtraerythrocytic cycle of malarial parasite PfHsp70 is an abundant cytosohc chaperone in the parasite It gets induced during stress and translocates to the nucleus It is also phosphorylated at three sites Analysis of Pfhsp70 complexes shows that it is present in bimodal complexes (450 kDa and 200 kDa), which are in equilibrium PfHsp70 and PfHsp90 interact and are part of 450 kDa multichaperone complex This multichaperone complex appears to regulate trafficking of one parasite protein to host cytosol compartment In addition, PfHsp70 and PfHsp90 are also bound to mitochondria-targeted PfHsp60 precursor in the cytosol probably keeping them m a transport competent state In addition to PfHsp90 and PfHsp60, PfHsp70 interacts with a novel Hsp70 homolog of the parasite, PfHsp70-3, and cytoskeletal protein, beta-tubuhn Examination of chaperones available in erythrocyte cytosol, showed that parasite chaperones were absent while host chaperone (Hsp70) was present and exhibited altered properties during parasite infection It was associated with membrane-bound, triton-insoluble complexes on the infected cell plasma membrane suggesting that host-Hsp70 might be involved in trafficking and/or assembly of parasite proteins In all, PfHsp70, as part of multichaperone complex, appears to be regulating translocation and trafficking of parasite proteins to organellar locations or outside the parasite Host-Hsp70, in erythrocyte cytosol, might also be engaged in specific chaperone function upon infection