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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

The Role of PfEMP1 Expression and Immunity in Ugandian Children with Severe Malaria

Fernander, Elizabeth M. 05 1900 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Severe malaria, primarily caused by Plasmodium falciparum infection, is among the leading causes of childhood mortality globally. A key virulence factor and source of antigenic variation and immune evasion during infection is P. falciparum erythrocyte membrane protein 1 (PfEMP1). Encoded for by approximately 60 var genes, this complex protein mediates cytoadherence of infected erythrocytes to the host endothelium and is a prominent immune target for the anti-malarial immune response in children. During severe malaria, specific domains of PfEMP1 that bind to endothelial protein C receptor (EPCR) and intercellular adhesion molecule-1 (ICAM-1) on host endothelial cells, are more prevalently expressed. The interaction of these proteins and infected erythrocytes mediates the sequestration of infected erythrocytes and plays a role in severe malaria pathogenesis. Antibodies to these domains develop over time with exposure to the parasite and are thought to contribute to immunity against severe malaria in children. In this study, whole blood samples from children with different forms of severe malaria, enrolled in two observational prospective cohort studies were used to quantify the expression of PfEMP1 domains using RT-qPCR and to measure the antibody response to PfEMP1 domains via a bead-based multiplex immunoassay. Using these samples, we demonstrated that although the expression of var transcripts encoding PfEMP1 domains was generally similar across children with different forms of severe malaria, the expression of variants encoding specific EPCR-binding domains was associated with thrombocytopenia and severe anemia. The antibody response to PfEMP1 domains in children with severe malaria was highest in children with SMA and children with asymptomatic parasitemia, but not associated with decreased risk of additional malaria episodes. Overall, the results of this study suggest that PfEMP1 is acting similarly across different forms of severe malaria but that it can be related to pathogenesis and severe malaria immunity.
2

Paludisme A Plasmodium Falciparum pendant la grossesse et l'enfance : caractérisation moléculaire et immunologique / Plasmodium falciparum malaria in pregnancy and childhood : molecular and immunological caracterization

Moussiliou, Azizath 15 December 2015 (has links)
Ce travail avait pour objectif, de caractériser le poids des infections au cours de la grossesse et d’étudier la construction de l’immunité anti-PfEMP1 chez le jeune enfant. La première partie, aborde la conséquence des infections et l’efficacité des traitements chez la mère. Cette étude réalisée sur la cohorte de femmes d’une étude prospective au Bénin, a démontré l’impact des infections à bas bruit sur le taux d’hémoglobine maternel et le faible poids de l’enfant. Le TPI-SP, a montré les limites quant à sa capacité à débarrasser les femmes enceintes infectées au moment du traitement de leur parasite. Nos résultats soutiennent davantage la nécessité de trouver des moyens alternatifs de prévention qui offrent une meilleure couverture de la grossesse. La deuxième partie aborde la construction de l’immunité anti-PfEMP1 dans la première année de vie chez l’enfant. Un résultat majeur de cette étude est la démonstration que l’acquisition des anticorps contre les PfEMP1 associés aux complications du paludisme est dépendante des infections patentes de l’enfant. La troisième partie aborde les phénotypes des parasites responsables de diverses formes cliniques du paludisme chez l’enfant Africain âgé de 0 à 5 ans. Cette étude a permis de mettre en évidence un marqueur de mauvais pronostic du paludisme cérébral. Sur un deuxième volet, nous avions montré que les isolats adhérant faiblement à ICAM-1, transcrivent fortement les gènes codant pour les PfEMP1 contenant des motifs DC8. Ces résultats soulèvent la question du rôle de EPCR dans la physiopathologie du neuropaludisme. Le travail développé dans cette thèse a permis de décrire pour la première fois la construction de l’immunité anti-PfEMP1 dans la première année de vie, de mettre à jour les connaissances sur la physiopathologie du paludisme cérébral chez le jeune enfant et de dégager des pistes à explorer prioritairement dans la perspective du développement d'un vaccin contre les formes graves du paludisme. / This work aimed to characterize the burden of P. falciparum infections during pregnancy and to study the construction of the anti-PfEMP1 immunity in the early life. The first part discusses the consequence of infection and the effectiveness of treatments in the mother. This study on the cohort of women from a prospective study in Benin, demonstrated the impact of infections with low parasitemia on the maternal hemoglobin and low weight of the child. IPT-SP, has shown the limits of its ability to rid infected pregnant women in the processing of their parasite. Our results further support the need to find alternative means of prevention that provide better coverage of pregnancy. The second part treated the construction of the anti-PfEMP1 immunity in the first year of life in children. A major finding of this study is the demonstration that the acquisition of antibodies against the PfEMP1 associated with complications of malaria depends on patentes infections in children. The third part studies parasites phenotypes responsible of various clinical forms of malaria in African children aged 0-5 years. This study allowed finding a marker of poor prognosis of cerebral malaria. On a second component, we showed that isolates bind to ICAM-1, highly transcribe the genes encoding PfEMP1 containing DC8. These results raise the question of the role of EPCR in the pathophysiology of cerebral malaria. The work developed in this thesis has allowed describing for the first time the construction of the anti-PfEMP1 immunity in the first year of life, to update knowledge on the pathophysiology of cerebral malaria in young children and identify Options to be primarily from the perspective of developing a vaccine against severe forms of malaria.
3

Effect of hemoglobins S and C on the in vivo expression and immune recognition of Plasmodium falciparum erythrocyte membrane protein 1 variants in Malian children

Beaudry, Jeanette T. January 2012 (has links)
The enormous mortality burden exerted by P. falciparum malaria has evolutionarily selected for red blood cell (RBC) polymorphisms which confer protection against the severe manifestations of this disease. Although the epidemiological protection by these polymorphisms has been well-established for the past half-century, the mechanisms underlying this protection are still being uncovered. Recent studies implicate impaired cytoadherence to microvascular endothelial cells (MVECs) due to reduced surface levels and altered display of Plasmodium falciparum erythrocyte membrane protein 1 (PfEMP1) as a mechanism of protection against severe malaria by sickle hemoglobin (Hb) S and HbC. Consequently, in this thesis, I have described three separate, but related investigations into whether hemoglobins S and C influence a parasite’s cytoadherence binding phenotype (Chapter 3), the PfEMP1 variants that parasites express in vivo (Chapter 4), and the IgG recognition of PfEMP1 domains in Malian children (Chapter 5). We found that parasites from HbAS children show statistically insignificant increased binding to MVECs and that parasites did not express a restricted subset of var genes in HbAS and HbAC children. Compared to HbAA and HbAC children, HbAS children demonstrated a slower rate of acquisition of IgG responses to a repertoire of PfEMP1 domains. These findings suggest that, although hemoglobin type influences the binding phenotype of P. falciparum isolates and the acquisition of PfEMP1-specific IgG responses, other factors more likely determine the expressed var gene repertoire within parasites than hemoglobin type.
4

Análise de seqüências var de populações naturais de Plasmodium falciparum da Amazônia Brasileira / Analysis of var sequences from natural parasite populations of Plasmodium falciparum in the Brazilian Amazon

Kirchgatter, Karin 06 March 2002 (has links)
Os genes var de Plasmodium falciparum codificam a proteína PfEMP1 expressa na superfície de eritrócitos infectados e que medeia os fenômenos de citoaderência e \"rosetting\". Ambos os fenômenos estão diretamente associados à malária grave, e seu domínio mais N-terminal, DBL1alfa, media especificamente \"rosetting\". Análise de seqüências DBL1alfa de isolados brasileiros e de outros países revelou que a similaridade entre elas não pode predizer origem geográfica. Com o objetivo de determinar se existem seqüências DBL1alfa associadas à malária grave, analisamos as seqüências DBL1alfa expressas em parasitas obtidos de pacientes brasileiros com esta manifestação clínica e encontramos que as seqüências predominantemente expressas apresentavam uma ou duas deleções de cisteínas. Significativamente, apesar de freqüentes no genoma de parasitas de pacientes com malária não grave, essas seqüências foram raramente expressas. Esses dados demonstram a primeira associação de seqüências PfEMP1 expressas e malária grave em pacientes da Amazônia Brasileira. / Plasmodium falciparum var genes code for PfEMP1, a protein expressed on the surface of infected erythrocytes, and which mediates cytoadherence and rosetting. Both phenomena are directly associated with severe malaria and the most N-terminal domain, DBL1alfa, specifically mediates rosetting. DBL1alfa sequence analysis from Brazilian and worldwide isolates revealed that sequence similarities cannot predict geographical origin. To determine whether there are DBL1alfa sequences associated with severe malaria, we examined expressed var DBL1alfa sequences in patients with severe malaria from the Brazilian Amazon and found that the predominantly expressed DBL1alfa sequences from these parasites lacked 1-2 cysteine residues. Significantly, these sequences were amply found on the genomic repertoire of parasites from patients with mild malaria and yet they were rarely expressed. These data demonstrate the first association of particular PfEMP1 expressed sequences and severe malaria in patients from the Brazilian Amazon.
5

Análise de seqüências var de populações naturais de Plasmodium falciparum da Amazônia Brasileira / Analysis of var sequences from natural parasite populations of Plasmodium falciparum in the Brazilian Amazon

Karin Kirchgatter 06 March 2002 (has links)
Os genes var de Plasmodium falciparum codificam a proteína PfEMP1 expressa na superfície de eritrócitos infectados e que medeia os fenômenos de citoaderência e \"rosetting\". Ambos os fenômenos estão diretamente associados à malária grave, e seu domínio mais N-terminal, DBL1alfa, media especificamente \"rosetting\". Análise de seqüências DBL1alfa de isolados brasileiros e de outros países revelou que a similaridade entre elas não pode predizer origem geográfica. Com o objetivo de determinar se existem seqüências DBL1alfa associadas à malária grave, analisamos as seqüências DBL1alfa expressas em parasitas obtidos de pacientes brasileiros com esta manifestação clínica e encontramos que as seqüências predominantemente expressas apresentavam uma ou duas deleções de cisteínas. Significativamente, apesar de freqüentes no genoma de parasitas de pacientes com malária não grave, essas seqüências foram raramente expressas. Esses dados demonstram a primeira associação de seqüências PfEMP1 expressas e malária grave em pacientes da Amazônia Brasileira. / Plasmodium falciparum var genes code for PfEMP1, a protein expressed on the surface of infected erythrocytes, and which mediates cytoadherence and rosetting. Both phenomena are directly associated with severe malaria and the most N-terminal domain, DBL1alfa, specifically mediates rosetting. DBL1alfa sequence analysis from Brazilian and worldwide isolates revealed that sequence similarities cannot predict geographical origin. To determine whether there are DBL1alfa sequences associated with severe malaria, we examined expressed var DBL1alfa sequences in patients with severe malaria from the Brazilian Amazon and found that the predominantly expressed DBL1alfa sequences from these parasites lacked 1-2 cysteine residues. Significantly, these sequences were amply found on the genomic repertoire of parasites from patients with mild malaria and yet they were rarely expressed. These data demonstrate the first association of particular PfEMP1 expressed sequences and severe malaria in patients from the Brazilian Amazon.
6

Antigenic variation and its evolution in P. falciparum malaria

Noble, Robert John January 2014 (has links)
This thesis investigates antigenic variation and its evolution in Plasmodium falciparum, the cause of the most deadly form of human malaria. Antigenic variation is a strategy for evading immunity by switching between antigenic variants during infection. In P. falciparum, such variable antigens confer different binding phenotypes that may affect parasite survival and have also been linked to pathology. Here, a new statistical method is described for determining the switching patterns that underlie antigenic variation. This method is then applied to experimental data to yield a full description of an antigenic switching network in P. falciparum. In light of the findings, theoretical modelling is used to show how immune selection and binding phenotypes may have contributed to the evolution of antigenic repertoire structure, expression order and virulence. Related models are also used to investigate parasite population diversity, providing possible explanations for observations reported here and elsewhere, with implications for vaccine design. Together, these chapters advance understanding of P. falciparum immune evasion and how it relates to pathology. This work further reinforces the role of host immunity in shaping pathogen population diversity at multiple levels.
7

Interaction of PfEMP1 with the Human Immune System and the Prospect of PfEMP1-based Vaccine for Malaria

Magale, Hussein Issak January 2016 (has links)
Malaria is a leading cause of death in some developing countries. The malaria parasite has been around for over a century, and has coevolved with humans. Coming up with an effective vaccine for P. falciparum will save millions of lives and reduce the morbidity and mortality of malaria globally. Understanding the role of exported parasite proteins i.e PfEMP1 a virulence factor and major cause of malarial pathogenesis, has been of great interest to vaccine researchers in the last decade. The focus of this review is to provide a literature review on PfEMP1s, their interaction with the human immune system, and their role in helping P. falciparum parasite to evade the immune system. This review will primarily focus on the intra-erythrocytic stage, which is the stage that results in the symptoms of malaria. A review is necessary to understand the antigenic variation of PfEMP1s, and how PfEMP1s challenge the different arms of the immune response, both the innate and adaptive. This review is unique in touching on the major parts of the immune system's interaction with the PfEMP1 antigen. Furthermore, the review explores the discussion of future research and therapeutic opportunities based on our knowledge of PfEMP1 antigens.
8

Structural studies of malaria proteins

Mayer, Christina January 2012 (has links)
Malaria is a disease of global importance, causing hundreds of thousand of deaths a year. The majority or deaths are caused by Plasmodium falciparum, a parasite transmitted by the mosquito Anopheles. Its pathogenicity largely results from an ability to transform infected erythrocytes by creating knob-like structures that result in endothelial adhesion. Two major components of these knob structures have been identified as P. falciparum erythrocyte membrane protein 1 (PfEMP1) and knob-associated histidine rich protein (KAHRP). The extracellular fragment of PfEMP1 is responsible for antigenic variability and cytoadherence while its intracellular domain (ATS) connects to the cytoskeleton via interactions with other plasmodium-encoded proteins. In addition, perforin-like proteins (PLPs) with a MACPF domain have been identified in the genome of Plasmodium. PLPs are highly conserved and are expressed in various life-cycle stages of the parasite. They are believed to form pores in membranes of the host cell but their structure is yet unknown. The aim of the work in this thesis was to obtain new information about the structure and role of malaria proteins, thus giving a better understanding of the disease and its possible treatment. Studies of numerous designed constructs of the ATS family were carried out using biophysical methods including high resolution NMR and CD. These revealed that ATS domains are mainly unstructured with a relatively small folded core, consisting of a bundle of α-helices. Surprisingly, no evidence could be found for ATS binding to KAHRP in solution conditions although previous pull-down data had indicated an interaction. Bioinformatics analysis and yeast-two-hybrid data suggested, however, that there is a conserved protein interaction epitope on the central flexible part of ATS. It was shown, using fluorescence anisotropy measurements, that this part of ATS associates with a parasite protein containing a PHIST (Plasmodium helical interspersed sub-telomeric) domain. Expression constructs of the PLP protein family were designed and manufactured, with the aim of enabling structural studies of this putative pore protein.
9

Identifying genetic determinants of impaired PfEMP1 export in Plasmodium falciparum-infected erythrocytes

Neal, Aaron T. January 2014 (has links)
The virulence of Plasmodium falciparum is largely attributed to the ability of asexual blood-stage parasites to cytoadhere to the microvascular endothelium of the human host. This pathogenic behavior is mediated by the primary parasite virulence factor P. falciparum erythrocyte membrane protein 1 (PfEMP1), an understanding of which is crucial to develop interventions to ameliorate the morbidity and mortality of P. falciparum malaria. The work presented in this thesis describes the application of a phenotype-to-genotype experimental approach to identify novel parasite proteins involved in the trafficking and display of PfEMP1. Guided by the overall hypothesis that the in vitro culture-adapted parasite line 3D7 harbors 1 or more genetic determinants of impaired PfEMP1 trafficking, surface PfEMP1 levels were first measured in 3D7, the presumably trafficking-competent parasite line HB3, and 16 unique progeny from an HB3 x 3D7 genetic cross (chapter 2). These phenotypes were then combined with genome-wide SNP data in QTL analysis to identify genetic polymorphisms potentially responsible for the impaired trafficking in 3D7 (chapter 3). A near-significant QTL containing a single protein-coding gene, the putative kinesin Pf3D7_1245600, was identified, characterized, and investigated in CRISPR-Cas9-driven allele-exchange parasite transfection experiments to establish a causal link between the gene and PfEMP1 trafficking (chapter 4). The parasite transfections were unsuccessful, but the potential role of Pf3D7_1245600 in PfEMP1 trafficking was indirectly assessed through the disruption of microtubules with colchicine (chapter 4), which significantly impacted the surface PfEMP1 levels of HB3 but not 3D7. The findings of this thesis suggest that kinesins and microtubules may play previously unconsidered roles in the regulation, production, or trafficking of PfEMP1.
10

Multi-scale immune selection and the maintenance of structured antigenic diversity in the malaria parasite Plasmodium falciparum

Holding, Thomas Mitchell January 2018 (has links)
The most virulent malaria parasite, Plasmodium falciparum, makes use of extensive antigenic diversity to maximise its transmission potential. Parasite genomes contain several highly polymorphic gene families, whose products are the target of protective immune responses. The best studied of these are the PfEMP1 surface proteins, which are encoded by the var multi-gene family and are important virulence factors. During infection, the parasite switches expression between PfEMP1 variants in order to evade adaptive immune responses and prolong infection. On the population level, parasites appear to be structured with respect to their var genes into non-overlapping repertoires, which can lead to high reinfection rates. This non-random structuring of antigenic diversity can also be found at the level of individual var gene repertoires and var genes themselves. However, not much is known about the evolutionary determinants which select for and maintain this structure at different ecological scales. In this thesis I investigate the mechanisms by which multi-scale immune selection and other ecological factors influence the evolution of structured diversity. Using a suite of theoretical frameworks I show that treating diversity as a dynamic property, which emerges from the underlying infection and transmission processes, has a major effect on the relationship between the parasite’s transmis- sion potential and disease prevalence, with important implications for monitoring control efforts. Furthermore, I show that an evolutionary trade-off between within-host and between-host fitness together with functional constraints on diversification can explain the structured diversity found at both the repertoire and parasite population level and might also account for empirically observed exposure-dependent acquisition of immunity. Together, this work highlights the need to consider evolutionary factors acting at different ecological scales to gain a more comprehensive understanding of the complex immune-epidemiology of P. falciparum malaria.

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