Medical Biology - Theses

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Subject: malaria × Subject: invasion ×

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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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    Analysis of 6-cys proteins and calcium fluxes during erythrocyte invasion by Plasmodium falciparum parasites
    TAECHALERTPAISARN, TANA ( 2015)
    Plasmodium parasites amplify their population within the human host by invading, growing and replicating within the body’s erythrocytes. When the population becomes high enough, the damage caused produces symptomatic malaria disease. To develop new drugs and vaccines against malaria it is therefore important to know as much possible about how parasites grow within the human host and particularly about how the extracellular merozoite stage invades erythrocytes, since this short-lived stage is highly vulnerable. This thesis provides new information from the most deadly human malaria pathogen P. falciparum, on the biochemical characteristics of a little known family of merozoite surface proteins which were thought to facilitate erythrocyte invasion as well revealing with unprecedented resolution, new details about how merozoites enter erythrocytes. P12, P38, P41, and P92 comprise a group of blood-stage merozoite surface proteins that belong to the 6-cys family and all except P41 are predicted to have membrane anchors. To functionally characterize the proteins, specific antibodies were made and were then employed to block merozoite invasion by interfering with the binding of 6-cys to erythrocytes. The effect of the antibodies was very weak and therefore not indicative of a major role for 6-cys in invasion. The antibodies were then used as localization probes and indicated that P12 and P41 were at the merozoite periphery with some concentrated towards the apex. In addition, the non-anchored P41 was held on the merozoite surface through heterodimerization with the membrane anchored P12. Despite the P12/P41 heterodimer being in prime position to bind erythrocytes during invasion no evidence for binding could be established. Characterisation of P92 was next conducted and revealed that like the P12/P41 heterodimer, it was tightly associated with the parasite membrane and later cleaved off possibly during invasion. On the other hand, P38 did not shed from the merozoite surface, and it was carried into the erythrocyte. P92 was strictly localised to the apical end of the merozoite while P38 displayed both apical and surface localisation. Similar to the P12/P41 heterodimer, P92 does not appear to bind erythrocytes. In a final attempt to derive a function for the blood stage 6-cys, their genes were individually knocked out but none of the mutants produced any defective growth or invasion phenotypes suggestive of function. To further study invasion, the morphology and kinetics of this process in P. falciparum merozoites was examined with high-speed live-cell microscopy. With greater temporal resolution, novel cellular actions of the merozoites were observed. For example, during the 7.5 s pre-invasion phase the merozoite deforms the erythrocyte plasma membrane multiple times whilst re-orientating. After a brief rest, the merozoite invaded over a ~17 s period forming a vacuole mainly from wrapping the erythrocyte’s membrane around itself. About 18.5 s after entry, the merozoite began spinning in a clockwise direction to possibly to help disconnect itself from the erythrocyte membrane. After spinning had commenced the host erythrocyte began to develop a spiculated appearance called echinocytosis. Suspecting that calcium influx into the erythrocyte during invasion might be responsible for the echinocytosis, the appearance of these fluxes was monitored during invasion by live cell imaging. These observations confirmed for the first time, that a calcium flux originated as an intense spot emanating from the area of contact between the merozoite and erythrocyte suggestive of pore formation between the cells. Further experiments with modified levels of calcium indicated the ion is required for efficient invasion and may play role in causing echinocytosis. Other work using the calcium flux as a visual marker indicated that pore formation coincided with the deployment of tight adhesive proteins from the merozoite that commit it to invasion. The live cell imaging work presented therefore sheds considerable light on many details of merozoite invasion that could inform future drug and vaccine development. Supplementary Videos: Video 1. High-speed time-lapse acquisition of 3D7 merozoite invading the erythrocyte (40 fps). Video 2. The 3D7 merozoite invading the BODIPY FL C12-sphingomyelin labelled erythrocyte (2 fps, 2× real speed). Video 3. The 3D7 merozoite invading the erythrocyte in the presence of Fluo-4 AM showing the punctate apical calcium and calcium influx in the infected erythrocyte (3 fps, 8× real speed) Video 4. Fluo-4-stained 3D7 parasite culture showing merozoites attempting to invade in the presence of R1 peptide (3 fps, 8× real speed). The punctate apical calcium and influx in the attached erythrocyte were detectable. Video 5. Fluo-4-stained 3D7 parasite culture showing merozoites attempting to invade in the presence of R1 peptide (variable speed). The echinocytotic erythrocyte had not recovered after ~20 min of recording. Video 6. CytD-treated 3D7 merozoite attempting to invade the Fluo-4 labelled erythrocyte (variable speed). The punctate apical calcium was visible but the calcium influx was difficult to observe. The echinocytotic erythrocyte had not recovered after ~20 min of recording.
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    Dissection of the coordinated events during Plasmodium falciparum infection of the human erythrocyte
    Riglar, David Thomas ( 2013)
    Malaria disease continues to place significant social and economic burdens on the developing world. Of the Plasmodium parasites responsible for the disease, P. falciparum causes the most severe form and thus kills up to 1 million people each year. Unfortunately, recent years have seen rising signs of resistance to even our most successful drug-based therapies and a continued underperformance of promising vaccine prospects during clinical trials. This signals a need for continued research, particularly that focussed on providing new targets for therapy and on the development of methods to more effectively understand new and existing therapeutic approaches during their early stages of development. Invasion and subsequent remodelling of the erythrocyte by the merozoite form of the parasite mark two areas of particular interest. Indeed, both are critical for the establishment of symptomatic infection. Despite their importance and interest as therapeutic targets, study of the P. falciparum merozoite, erythrocyte invasion and early remodelling events have all been hampered by shortfalls in methodology. This has left much to be understood about this period of the lifecycle. Using recent advances in our ability to isolate free, viable, P. falciparum merozoites, I therefore develop methods to fix parasites at each step of, and in the minutes following, erythrocyte invasion. For the first time, this allows detailed imaging of these processes on a molecular level using various imaging platforms, including widefield deconvolution, ‘super-resolution’ three-dimensional structured illumination, and transmission electron microscopies, along with electron tomography. In particular, the application of cutting edge microscopy combined with sophisticated quantitative imaging analysis makes for a powerful investigative approach. Initially, these techniques are developed and used to investigate a number of processes that are critical for merozoite invasion: attachment, tight junction formation, surface protein shedding, actomyosin motor activation and organelle secretion. This study identifies interactions mediated by merozoite surface adhesins as the important initiator of subsequent invasion processes, which all follow without further checkpoints. It also points to the tight junction as a nexus that organises and directs these processes. I then dissect aspects of erythrocyte remodelling, providing previously lacking cellular evidence for the role of the Plasmodium translocon of exported proteins (PTEX) complex during protein export from the parasite. In particular, this study identifies key events that occur in the latter parts of invasion which are critical for subsequent protein export. This points to an important level of coordination between invasion and remodelling events that may be occurring up to 24 hours later. Together the contributions made during this PhD provide the most complete model for invasion and early parasite remodelling to date. The methods developed also provide an important platform from which others can develop our understanding of these critical events in the future.