Medical Biology - Theses

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Type: PhD thesis × Subject: merozoite ×

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    A conserved molecular mechanism of erythrocyte invasion by malaria parasites
    Seager, Benjamin Andrew ( 2023-10)
    Malaria is major global health burden causing over 240 million cases every year and leading to over 600,000 deaths mostly in pregnant women and children under the age of five. There is an urgent need to development novel therapeutic interventions for the control and elimination of malaria. During infection, malaria parasites must invade host erythrocytes in order to live within them. Invasion is a complex multi-step process that involves many molecular host-parasite interactions. In Plasmodium falciparum, the deadliest species of the parasite, the invasion protein PfRh5 assembles into a complex to bind its receptor basigin on the erythrocyte surface. Recent work has revealed two novel members of this complex, PfPTRAMP and PfCSS, form a heterodimeric platform for PfRipr, PfCyRPA, and PfRh5 binding. The PfPTRAMP-PfCSS-PfRipr-PfCyRPA-PfRh5 (PCRCR) complex, and its engagement with basigin, is essential for P. falciparum invasion. PfRh5 does not have an orthologue in all species of malaria, however PTRAMP, CSS and Ripr orthologues are present across the entire Plasmodium genus. This thesis sought to investigate these conserved proteins in other malaria species to further dissect the essentiality of these proteins for Plasmodium invasion more broadly. Orthologues of PTRAMP, CSS and Ripr from two important species of malaria, P. vivax and P. knowlesi, were investigated using recombinant expression and biophysical analysis. Assessment of complex formation shows a conserved assembly of the three proteins in both species, with similarities to P. falciparum. Structural determination of part of the complex revealed the basis of heterodimer formation between PTRAMP and CSS. Antibodies and nanobodies were produced and exhibit a high degree of cross-reactivity between species. A novel protein was identified that may bind to the complex and impart an erythrocyte binding function. The function of the complex and its components in invasion was confirmed using ex vivo invasion assays in Cambodian P. vivax field isolates. Taken together, this thesis shows that a three-membered complex consisting of PTRAMP, CSS and Ripr is conserved in three species of Plasmodium, likely forming a common invasion scaffold in all species of the genus, suggesting a conserved invasion mechanism with implications for cross-species vaccine development for the control of both P. vivax and P. falciparum malaria.
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    Merozoite surface protein 1: insights into complex formation and function in erythrocyte invasion
    Lin, Clara Shujuan ( 2016)
    The invasion of Plasmodium falciparum into host erythrocytes during the parasites’ asexual blood stage is a critical step in the perpetuation of symptomatic infection of malaria in the human host. Merozoites, the invasive form of the parasite, express a glycosylphosphatidylinositol-anchored 190 kDa Merozoite Surface Protein 1 (MSP1) on the surface. This abundant, essential protein exists in a large complex that includes other peripheral Merozoite Surface Proteins (MSPs). Together, these large macromolecular complexes are thought to mediate the initial stages of invasion. MSPs are of great interest to the field as they are exposed to the host immune system and also contribute directly to the invasion process. Therefore, there is a strong consideration for considering them as therapeutic targets. The majority of the work assessing these molecules as potential vaccine candidates has been performed with single MSP antigens and vaccine trials on these MSPs have shown variable results. A main concern arising from these trials is the fact that these antigens are often found in complex with other antigens and therefore have regions that are masked when found on the parasite surface. In order to address this, the work presented in this thesis utilises parasite-derived complexes to understand how peripheral MSPs: MSP3, MSP6, MSPDBL1, MSPDBL2 and MSP7 utilise MSP1 as a platform to be presented on the merozoite surface to form an array of complexes with different functional roles. In addition, multiple forms of erythrocyte binding complexes were found to have overlapping functions in invasion. Complexes that are involved in erythrocyte binding were characterised, where two components, MSPDBL1 and MSPDBL2 were shown to mediate erythrocyte binding directly. Overall, this study has identified and validated the presence of multiple Merozoite Surface Protein 1 complexes that are involved in mediating the interaction of the merozoite to receptors on the red blood cell surface, which is a vital process for successful invasion of parasites into host erythrocytes. Together, these findings have provided valuable insights into the complexity of MSP1 complexes and have contributed to the most complete model for the molecular arrangements that occur on the parasite surface to date.
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    Merozoite antigens of Plasmodium falciparum elicit strain transcending opsonising immunity
    Hill, Danika Lea ( 2015)
    Despite progress towards reducing the global burden, malaria continues to cause approximately 200 million cases and 600,000 deaths annually (World Health Organization, 2014). Although several malaria vaccines are currently in clinical trials, no advanced vaccine candidate has yet demonstrated sufficient efficacy to be a stand-alone vaccine against the highly variant Plasmodium falciparum parasite. Development of effective vaccine strategies requires knowledge of the essential mechanisms for protective immunity and robust assays to serve as correlates of protective immunity. However, exactly which antibody functions are necessary to control parasitemia and clinical symptoms during natural infection remains unclear. The merozoite represents an attractive vaccine target, as antibodies to numerous merozoite antigens have been associated with protective immunity in human cohort studies. This thesis aimed to investigate the importance of merozoite opsonising antibodies for immunity to malaria. Opsonising antibodies, and the Fc Receptor-mediated functions these antibodies elicit, have been poorly studied in malaria partly due to limitations of in vitro assays. Therefore, in this thesis a merozoite phagocytosis assay was developed and validated (Chapter 3), and robust and reproducible phagocytosis responses from THP-1 cells were observed. This assay was then used to measure merozoite opsonisation in a longitudinal study of semi-children from Papua New Guinea (PNG), and phagocytosis responses were demonstrated to correlate with protection from clinical disease and high-density parasitemia (Chapter 4). Due to the highly diverse nature of P. falciparum merozoites, it was important to assess whether merozoite opsonisation involved strain-specific or strain-transcending specificities (Chapter 5). Highly consistent opsonisation and associations with immunity were observed across a panel of common laboratory strains and PNG parasites adapted to growth in vitro. Through use of transgenic parasite lines, the absence of MSP3, MSP6, MSPDBL1 or MSP1-19 was not observed to impact the overall level of merozoite phagocytosis. By depleting antibody reactivity to 3D7 merozoites, opsonisation of merozoites from PNG strains also declined, suggestive of conserved antigenic targets across parasite strains. The findings in this thesis have demonstrated the importance of opsonising antibodies and their associated phagocytic responses for protective immunity to malaria. Robust, reproducible and well-validated assays are a priority to aid pre-clinical and clinical malaria vaccine development. The consistent responses and protective associations provide strong support for merozoite opsonisation as a robust correlate of protective immunity in malaria endemic populations. As the majority of merozoite opsonising antibodies were strain-transcending, uncovering these conserved domains within merozoite surface antigens may yield important novel vaccine candidates with which to tackle this deadly disease.
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    Cell-cell interactions during malaria parasite invasion of the human erythrocyte
    ZUCCALA, ELIZABETH ( 2015)
    Red blood cells are remarkably resilient, flexible and dynamic structures. These properties are required for their passage through small capillaries and are imparted by the cytoskeleton, a network of proteins that underlies and links to the cell membrane. To successfully invade the blood stage malaria parasite, called a merozoite, must induce rapid and drastic changes to the structure of the target erythrocyte, including the formation of a tight junction and a new cellular compartment, the parasitophorous vacuole. These key modifications involve the infolding of the red blood cell membrane, membrane fusion and fission events and the secretion of parasite proteins into the host. Although detailed cellular descriptions of merozoite invasion have been achieved over the past few decades, comparatively little is known about the molecular basis of how the host cell responds to parasite entry. In fact, in contrast to what is known about the invasion strategies of most other intracellular pathogens, the prevailing model of Apocomplexan invasion imagines a largely binary system within which an active parasite, driven by its acto-­‐ myosin motor, invades a passive host cell. There is a growing body of evidence, however, that suggests that Apicomplexan host cells may not be as inactive as initially thought. Nonetheless, to date, there is no direct evidence for the notion that erythrocytes contribute actively to merozoite invasion. This PhD took at its starting point the hypothesise that to invade, merozoites interface with endogenous erythrocyte pathways that regulate membrane and cytoskeletal remodelling, and that the tight junction is a key structure that coordinates the this host-­‐pathogen interaction during the brief moment of entry. To address this proposition, this PhD studied P. falciparum merozoite invasion using a combination of in silico bioinformatic screening, high-­‐definition imaging, quantitative and high-­‐throughput invasion inhibition assays and quantitative phospho-­‐proteomics. Work presented in this thesis further elaborates the molecular architecture of the P. falciparum merozoite tight junction, outlines a model for the secretion of virulence factors by the parasite during entry, establishes that an active erythrocyte is a prerequisite for successful merozoite invasion and demonstrates, for the first time, that the red blood cell responds to early invasion events through the phosphorylation of components of its membrane and cytoskeleton. Taken together, these findings provide strong support for a shift in how we conceptualise invasion, from paradigm that focuses almost exclusively on the activity of the parasite towards one in which both the merozoite and the erythrocyte act cooperatively to achieve the requisite remodelling events that lead to successful intracellular infection. By further expounding the way in which the malaria merozoite orchestrates its interaction with its target red blood cell during invasion, and in particular shedding light on the potential host-­‐cell contribution to this process, this work informs future endeavours aimed at the development of novel chemotherapeutic targets to stop invasion and hence prevent or treat malaria disease.
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    Plasmodium falciparum merozoite invasion mechanisms and inhibitors of invasion
    Boyle, Michelle Jacqueline ( 2012)
    Malaria threatens 40% of the global population resulting in approximately 225 million cases of disease and 800 000 deaths per year. Recently marked improvements in the implementation of control measures and increased use of artemisinin combination therapies (ACTs) have contributed to a reduction in malaria mortality and morbidity (World Health Organization, Global Malaria Programme, 2010). Furthermore the licensing and roll-out of the first malaria vaccine, RTS,S, is hoped to occur by 2015 (White, 2011; Agnandji et al., 2011). However, a sustained reduction in malaria burden and eradication of malaria seems unlikely with current control strategies alone. The largest malaria burden is caused by infection with P. falciparum parasites. All symptomatic illness occurs during asexual replication in the blood that is initiated when the merozoite form of the parasite invades red blood cells (RBCs). A limited understanding of merozoite invasion and immune mechanisms inhibiting invasion has hampered rational vaccine and drug development targeting this stage of the parasite life cycle. This thesis is based on the study of merozoite invasion of the RBC with a particular focus on the role of merozoite surface proteins in invasion and mechanisms of inhibition targeting these proteins. Part of the difficulty in studying P. falciparum merozoite invasion is due to the lack of efficient techniques to isolate merozoites that maintain invasive capacity. Chapter 3 describes the development of methods to isolate merozoites that maintain viability. Importantly, the method only requires basic laboratory equipment, therefore is accessible to both resource rich and developing laboratories. Highly synchronized cultures were treated with a cysteine protease inhibitor to block schizont rupture and then merozoites isolated via membrane filtration (Boyle et al., 2010a). Approximately 15% of isolated merozoites maintained viability and were able to successfully invade when incubated with RBCs. This allowed for the development of methods to fix merozoites during invasion for microscopy and invasion inhibition assays. Invasion of isolated merozoites was independent of serum components and the invasive half-life of merozoites was approximately 8 minutes. Merozoite isolation and invasion assays are now being used by a number of research groups and are a powerful technique to study merozoite invasion mechanisms (Riglar et al., 2011) and inhibitors of invasion. In Chapter 4, microscopy of invading merozoites is used to investigate the shedding of merozoite surface antigens during invasion. The initial steps of merozoite invasion are hypothesized to be mediated by merozoite surface proteins that contact with the RBC via weak receptor-ligand interactions. During invasion it is thought that merozoite surface proteins are cleaved and then shed from the merozoite to allow invasion to occur. This has been most clearly demonstrated for MSP1, with compounds that inhibit MSP1 cleavage and/or shedding also inhibiting invasion (Blackman et al., 1994; Singh et al., 2006; Woehlbier et al., 2010; Fleck et al., 2003; Blackman and Holder, 1992). Contrary to the current paradigm, it was found that merozoite surface proteins MSP2 and MSP4 were not shed from the merozoite surface during invasion and were instead carried into the RBC without apparent cleavage. Post invasion, MSP2 was rapidly degraded within a few minutes, whereas MSP4 was maintained for a number of hours. Interestingly, during invasion some MSP2 antibodies were found to be internalized into the RBC. Internalized antibodies were maintained for approximately 24 hours post invasion. This work establishes that there is differential cleavage and shedding of merozoite surface proteins during invasion and suggests that some merozoite surface proteins may have roles outside initial contact events. Chapter 5 investigates the mechanisms by which antibodies inhibit merozoite invasion in the presence of physiological relevant concentrations of complement-active serum. This work was possible due to capacity of isolated merozoites to invade in both the absence of serum and high serum concentrations. While the importance of IgG in mediating parasite clearance is well established (Sabchareon et al., 1991; McGregor, 1964b), the mechanisms of antibody function remain poorly understood. Naturally acquired antibodies from malaria-exposed individuals, as well as antibodies from vaccinated rabbits and humans had complement-dependent inhibition activity targeting merozoite invasion. The complement component C1q was required and appeared to be sufficient for complement-dependent inhibition. MSP1 and MSP2 were identified as targets of complement-dependent antibody mediated inhibition. Antibody mediated complement-dependent inhibition of invasion is a novel mechanism targeting merozoites that may be important in understanding protective immunity and for evaluating candidate merozoite vaccines. Finally, Chapter 6 explores the interaction of heparin with merozoite surface proteins and the potential of heparin-like-molecules (HLMs) as the basis for novel drug development. Heparin is a known inhibitor of merozoite invasion, and appears to act by inhibiting early contact events. Utilizing a heparin-binding assay with native merozoite proteins, heparin was shown to bind the processed fragment of MSP1, known as MSP1- 42. A panel of novel HLMs were screened for growth/invasion inhibition activity and a number of highly inhibitory compounds were identified. This work will be a basis for further studies to identify novel invasion inhibitors that may be used as the basis for drug development. The development of a method to isolate viable merozoites has allowed this thesis to explore a number of aspects of merozoite invasion mechanisms and inhibition of invasion. As well as increasing our understanding of P. falciparum merozoite biology and immunity to malaria, it is hoped that this work will contribute to the development of tools to combat malaria disease.