Your search keyword '"Marapana, DS"' showing total 25 results

1. Plasmodium falciparum formins are essential for invasion and sexual stage development

Author

Collier, S, Pietsch, E, Dans, M, Ling, D, Tavella, TA, Lopaticki, S, Marapana, DS, Shibu, MA, Andrew, D, Tiash, S, McMillan, PJ, Gilson, P, Tilley, L, Dixon, MWA, Collier, S, Pietsch, E, Dans, M, Ling, D, Tavella, TA, Lopaticki, S, Marapana, DS, Shibu, MA, Andrew, D, Tiash, S, McMillan, PJ, Gilson, P, Tilley, L, and Dixon, MWA

Abstract

The malaria parasite uses actin-based mechanisms throughout its lifecycle to control a range of biological processes including intracellular trafficking, gene regulation, parasite motility and invasion. In this work we assign functions to the Plasmodium falciparum formins 1 and 2 (FRM1 and FRM2) proteins in asexual and sexual blood stage development. We show that FRM1 is essential for merozoite invasion and FRM2 is required for efficient cell division. We also observed divergent functions for FRM1 and FRM2 in gametocyte development. Conditional deletion of FRM1 leads to a delay in gametocyte stage progression. We show that FRM2 controls the actin and microtubule cytoskeletons in developing gametocytes, with premature removal of the protein resulting in a loss of transmissible stage V gametocytes. Lastly, we show that targeting formin proteins with the small molecule inhibitor of formin homology domain 2 (SMIFH2) leads to a multistage block in asexual and sexual stage parasite development.

Published

2023

2. 4D analysis of malaria parasite invasion offers insights into erythrocyte membrane remodeling and parasitophorous vacuole formation

Author

Geoghegan, ND, Evelyn, C, Whitehead, LW, Pasternak, M, McDonald, P, Triglia, T, Marapana, DS, Kempe, D, Thompson, JK, Mlodzianoski, MJ, Healer, J, Biro, M, Cowman, AF, Rogers, KL, Geoghegan, ND, Evelyn, C, Whitehead, LW, Pasternak, M, McDonald, P, Triglia, T, Marapana, DS, Kempe, D, Thompson, JK, Mlodzianoski, MJ, Healer, J, Biro, M, Cowman, AF, and Rogers, KL

Abstract

Host membrane remodeling is indispensable for viruses, bacteria, and parasites, to subvert the membrane barrier and obtain entry into cells. The malaria parasite Plasmodium spp. induces biophysical and molecular changes to the erythrocyte membrane through the ordered secretion of its apical organelles. To understand this process and address the debate regarding how the parasitophorous vacuole membrane (PVM) is formed, we developed an approach using lattice light-sheet microscopy, which enables the parasite interaction with the host cell membrane to be tracked and characterized during invasion. Our results show that the PVM is predominantly formed from the erythrocyte membrane, which undergoes biophysical changes as it is remodeled across all stages of invasion, from pre-invasion through to PVM sealing. This approach enables a functional interrogation of parasite-derived lipids and proteins in PVM biogenesis and echinocytosis during Plasmodium falciparum invasion and promises to yield mechanistic insights regarding how this is more generally orchestrated by other intracellular pathogens.

Published

2021

3. Pan-active imidazolopiperazine antimalarials target the Plasmodium falciparum intracellular secretory pathway

Author

LaMonte, GM, Rocamora, F, Marapana, DS, Gnadig, NF, Ottilie, S, Luth, MR, Worgall, TS, Goldgof, GM, Mohunlal, R, Kumar, TRS, Thompson, JK, Vigil, E, Yang, J, Hutson, D, Johnson, T, Huang, J, Williams, RM, Zou, BY, Cheung, AL, Kumar, P, Egan, TJ, Lee, MCS, Siegel, D, Cowman, AF, Fidock, DA, Winzeler, EA, LaMonte, GM, Rocamora, F, Marapana, DS, Gnadig, NF, Ottilie, S, Luth, MR, Worgall, TS, Goldgof, GM, Mohunlal, R, Kumar, TRS, Thompson, JK, Vigil, E, Yang, J, Hutson, D, Johnson, T, Huang, J, Williams, RM, Zou, BY, Cheung, AL, Kumar, P, Egan, TJ, Lee, MCS, Siegel, D, Cowman, AF, Fidock, DA, and Winzeler, EA

Abstract

A promising new compound class for treating human malaria is the imidazolopiperazines (IZP) class. IZP compounds KAF156 (Ganaplacide) and GNF179 are effective against Plasmodium symptomatic asexual blood-stage infections, and are able to prevent transmission and block infection in animal models. But despite the identification of resistance mechanisms in P. falciparum, the mode of action of IZPs remains unknown. To investigate, we here combine in vitro evolution and genome analysis in Saccharomyces cerevisiae with molecular, metabolomic, and chemogenomic methods in P. falciparum. Our findings reveal that IZP-resistant S. cerevisiae clones carry mutations in genes involved in Endoplasmic Reticulum (ER)-based lipid homeostasis and autophagy. In Plasmodium, IZPs inhibit protein trafficking, block the establishment of new permeation pathways, and cause ER expansion. Our data highlight a mechanism for blocking parasite development that is distinct from those of standard compounds used to treat malaria, and demonstrate the potential of IZPs for studying ER-dependent protein processing.

Published

2020

4. The Metabolite Repair Enzyme Phosphoglycolate Phosphatase Regulates Central Carbon Metabolism and Fosmidomycin Sensitivity in Plasmodium falciparum

Author

David Sibley, L, Dumont, L, Richardson, MB, van der Peet, P, Marapana, DS, Triglia, T, Dixon, MWA, Cowman, AF, Williams, SJ, Tilley, L, McConville, MJ, Cobbold, SA, David Sibley, L, Dumont, L, Richardson, MB, van der Peet, P, Marapana, DS, Triglia, T, Dixon, MWA, Cowman, AF, Williams, SJ, Tilley, L, McConville, MJ, and Cobbold, SA

Abstract

Members of the haloacid dehalogenase (HAD) family of metabolite phosphatases play an important role in regulating multiple pathways in Plasmodium falciparum central carbon metabolism. We show that the P. falciparum HAD protein, phosphoglycolate phosphatase (PGP), regulates glycolysis and pentose pathway flux in asexual blood stages via detoxifying the damaged metabolite 4-phosphoerythronate (4-PE). Disruption of the P. falciparumpgp gene caused accumulation of two previously uncharacterized metabolites, 2-phospholactate and 4-PE. 4-PE is a putative side product of the glycolytic enzyme, glyceraldehyde-3-phosphate dehydrogenase, and its accumulation inhibits the pentose phosphate pathway enzyme, 6-phosphogluconate dehydrogenase (6-PGD). Inhibition of 6-PGD by 4-PE leads to an unexpected feedback response that includes increased flux into the pentose phosphate pathway as a result of partial inhibition of upper glycolysis, with concomitant increased sensitivity to antimalarials that target pathways downstream of glycolysis. These results highlight the role of metabolite detoxification in regulating central carbon metabolism and drug sensitivity of the malaria parasite.IMPORTANCE The malaria parasite has a voracious appetite, requiring large amounts of glucose and nutrients for its rapid growth and proliferation inside human red blood cells. The host cell is resource rich, but this is a double-edged sword; nutrient excess can lead to undesirable metabolic reactions and harmful by-products. Here, we demonstrate that the parasite possesses a metabolite repair enzyme (PGP) that suppresses harmful metabolic by-products (via substrate dephosphorylation) and allows the parasite to maintain central carbon metabolism. Loss of PGP leads to the accumulation of two damaged metabolites and causes a domino effect of metabolic dysregulation. Accumulation of one damaged metabolite inhibits an essential enzyme in the pentose phosphate pathway, leading to substrate accumulation and seco

Published

2019

5. Plasmodium falciparum coronin organizes arrays of parallel actin filaments potentially guiding directional motility in invasive malaria parasites

Author

Olshina, MA, Angrisano, F, Marapana, DS, Riglar, DT, Bane, K, Wong, W, Catimel, B, Yin, M-X, Holmes, AB, Frischknecht, F, Kovar, DR, Baum, J, Olshina, MA, Angrisano, F, Marapana, DS, Riglar, DT, Bane, K, Wong, W, Catimel, B, Yin, M-X, Holmes, AB, Frischknecht, F, Kovar, DR, and Baum, J

Abstract

BACKGROUND: Gliding motility in Plasmodium parasites, the aetiological agents of malaria disease, is mediated by an actomyosin motor anchored in the outer pellicle of the motile cell. Effective motility is dependent on a parasite myosin motor and turnover of dynamic parasite actin filaments. To date, however, the basis for directional motility is not known. Whilst myosin is very likely orientated as a result of its anchorage within the parasite, how actin filaments are orientated to facilitate directional force generation remains unexplained. In addition, recent evidence has questioned the linkage between actin filaments and secreted surface antigens leaving the way by which motor force is transmitted to the extracellular milieu unknown. Malaria parasites possess a markedly reduced repertoire of actin regulators, among which few are predicted to interact with filamentous (F)-actin directly. One of these, PF3D7_1251200, shows strong homology to the coronin family of actin-filament binding proteins, herein referred to as PfCoronin. METHODS: Here the N terminal beta propeller domain of PfCoronin (PfCor-N) was expressed to assess its ability to bind and bundle pre-formed actin filaments by sedimentation assay, total internal reflection fluorescence (TIRF) microscopy and confocal imaging as well as to explore its ability to bind phospholipids. In parallel a tagged PfCoronin line in Plasmodium falciparum was generated to determine the cellular localization of the protein during asexual parasite development and blood-stage merozoite invasion. RESULTS: A combination of biochemical approaches demonstrated that the N-terminal beta-propeller domain of PfCoronin is capable of binding F-actin and facilitating formation of parallel filament bundles. In parasites, PfCoronin is expressed late in the asexual lifecycle and localizes to the pellicle region of invasive merozoites before and during erythrocyte entry. PfCoronin also associates strongly with membranes within the cell, lik

Published

2015

6. Inhibition of Plasmepsin V Activity Demonstrates Its Essential Role in Protein Export, PfEMP1 Display, and Survival of Malaria Parasites

Author

Striepen, B, Sleebs, BE, Lopaticki, S, Marapana, DS, O'Neill, MT, Rajasekaran, P, Gazdik, M, Guenther, S, Whitehead, LW, Lowes, KN, Barfod, L, Hviid, L, Shaw, PJ, Hodder, AN, Smith, BJ, Cowman, AF, Boddey, JA, Striepen, B, Sleebs, BE, Lopaticki, S, Marapana, DS, O'Neill, MT, Rajasekaran, P, Gazdik, M, Guenther, S, Whitehead, LW, Lowes, KN, Barfod, L, Hviid, L, Shaw, PJ, Hodder, AN, Smith, BJ, Cowman, AF, and Boddey, JA

Abstract

The malaria parasite Plasmodium falciparum exports several hundred proteins into the infected erythrocyte that are involved in cellular remodeling and severe virulence. The export mechanism involves the Plasmodium export element (PEXEL), which is a cleavage site for the parasite protease, Plasmepsin V (PMV). The PMV gene is refractory to deletion, suggesting it is essential, but definitive proof is lacking. Here, we generated a PEXEL-mimetic inhibitor that potently blocks the activity of PMV isolated from P. falciparum and Plasmodium vivax. Assessment of PMV activity in P. falciparum revealed PEXEL cleavage occurs cotranslationaly, similar to signal peptidase. Treatment of P. falciparum-infected erythrocytes with the inhibitor caused dose-dependent inhibition of PEXEL processing as well as protein export, including impaired display of the major virulence adhesin, PfEMP1, on the erythrocyte surface, and cytoadherence. The inhibitor killed parasites at the trophozoite stage and knockdown of PMV enhanced sensitivity to the inhibitor, while overexpression of PMV increased resistance. This provides the first direct evidence that PMV activity is essential for protein export in Plasmodium spp. and for parasite survival in human erythrocytes and validates PMV as an antimalarial drug target.

Published

2014

7. Spatial Localisation of Actin Filaments across Developmental Stages of the Malaria Parasite

Author

Templeton, TJ, Angrisano, F, Riglar, DT, Sturm, A, Volz, JC, Delves, MJ, Zuccala, ES, Turnbull, L, Dekiwadia, C, Olshina, MA, Marapana, DS, Wong, W, Mollard, V, Bradin, CH, Tonkin, CJ, Gunning, PW, Ralph, SA, Whitchurch, CB, Sinden, RE, Cowman, AF, McFadden, GI, Baum, J, Templeton, TJ, Angrisano, F, Riglar, DT, Sturm, A, Volz, JC, Delves, MJ, Zuccala, ES, Turnbull, L, Dekiwadia, C, Olshina, MA, Marapana, DS, Wong, W, Mollard, V, Bradin, CH, Tonkin, CJ, Gunning, PW, Ralph, SA, Whitchurch, CB, Sinden, RE, Cowman, AF, McFadden, GI, and Baum, J

Abstract

Actin dynamics have been implicated in a variety of developmental processes during the malaria parasite lifecycle. Parasite motility, in particular, is thought to critically depend on an actomyosin motor located in the outer pellicle of the parasite cell. Efforts to understand the diverse roles actin plays have, however, been hampered by an inability to detect microfilaments under native conditions. To visualise the spatial dynamics of actin we generated a parasite-specific actin antibody that shows preferential recognition of filamentous actin and applied this tool to different lifecycle stages (merozoites, sporozoites and ookinetes) of the human and mouse malaria parasite species Plasmodium falciparum and P. berghei along with tachyzoites from the related apicomplexan parasite Toxoplasma gondii. Actin filament distribution was found associated with three core compartments: the nuclear periphery, pellicular membranes of motile or invasive parasite forms and in a ring-like distribution at the tight junction during merozoite invasion of erythrocytes in both human and mouse malaria parasites. Localisation at the nuclear periphery is consistent with an emerging role of actin in facilitating parasite gene regulation. During invasion, we show that the actin ring at the parasite-host cell tight junction is dependent on dynamic filament turnover. Super-resolution imaging places this ring posterior to, and not concentric with, the junction marker rhoptry neck protein 4. This implies motor force relies on the engagement of dynamic microfilaments at zones of traction, though not necessarily directly through receptor-ligand interactions at sites of adhesion during invasion. Combined, these observations extend current understanding of the diverse roles actin plays in malaria parasite development and apicomplexan cell motility, in particular refining understanding on the linkage of the internal parasite gliding motor with the extra-cellular milieu.

Published

2012

8. Subcompartmentalisation of Proteins in the Rhoptries Correlates with Ordered Events of Erythrocyte Invasion by the Blood Stage Malaria Parasite

Author

Spielmann, T, Zuccala, ES, Gout, AM, Dekiwadia, C, Marapana, DS, Angrisano, F, Turnbull, L, Riglar, DT, Rogers, KL, Whitchurch, CB, Ralph, SA, Speed, TP, Baum, J, Spielmann, T, Zuccala, ES, Gout, AM, Dekiwadia, C, Marapana, DS, Angrisano, F, Turnbull, L, Riglar, DT, Rogers, KL, Whitchurch, CB, Ralph, SA, Speed, TP, and Baum, J

Abstract

Host cell infection by apicomplexan parasites plays an essential role in lifecycle progression for these obligate intracellular pathogens. For most species, including the etiological agents of malaria and toxoplasmosis, infection requires active host-cell invasion dependent on formation of a tight junction - the organising interface between parasite and host cell during entry. Formation of this structure is not, however, shared across all Apicomplexa or indeed all parasite lifecycle stages. Here, using an in silico integrative genomic search and endogenous gene-tagging strategy, we sought to characterise proteins that function specifically during junction-dependent invasion, a class of proteins we term invasins to distinguish them from adhesins that function in species specific host-cell recognition. High-definition imaging of tagged Plasmodium falciparum invasins localised proteins to multiple cellular compartments of the blood stage merozoite. This includes several that localise to distinct subcompartments within the rhoptries. While originating from the same organelle, however, each has very different dynamics during invasion. Apical Sushi Protein and Rhoptry Neck protein 2 release early, following the junction, whilst a novel rhoptry protein PFF0645c releases only after invasion is complete. This supports the idea that organisation of proteins within a secretory organelle determines the order and destination of protein secretion and provides a localisation-based classification strategy for predicting invasin function during apicomplexan parasite invasion.

Published

2012

9. Spatial localisation of actin filaments across developmental stages of the malaria parasite

Author

Angrisano, F, Riglar, DT, Sturm, A, Volz, JC, Delves, MJ, Zuccala, ES, Turnbull, L, Dekiwadia, C, Olshina, MA, Marapana, DS, Wong, W, Mollard, V, Bradin, CH, Tonkin, CJ, Gunning, PW, Ralph, SA, Whitchurch, CB, Sinden, RE, Cowman, AF, McFadden, GI, Baum, J, Angrisano, F, Riglar, DT, Sturm, A, Volz, JC, Delves, MJ, Zuccala, ES, Turnbull, L, Dekiwadia, C, Olshina, MA, Marapana, DS, Wong, W, Mollard, V, Bradin, CH, Tonkin, CJ, Gunning, PW, Ralph, SA, Whitchurch, CB, Sinden, RE, Cowman, AF, McFadden, GI, and Baum, J

Abstract

Actin dynamics have been implicated in a variety of developmental processes during the malaria parasite lifecycle. Parasite motility, in particular, is thought to critically depend on an actomyosin motor located in the outer pellicle of the parasite cell. Efforts to understand the diverse roles actin plays have, however, been hampered by an inability to detect microfilaments under native conditions. To visualise the spatial dynamics of actin we generated a parasite-specific actin antibody that shows preferential recognition of filamentous actin and applied this tool to different lifecycle stages (merozoites, sporozoites and ookinetes) of the human and mouse malaria parasite species Plasmodium falciparum and P. berghei along with tachyzoites from the related apicomplexan parasite Toxoplasma gondii. Actin filament distribution was found associated with three core compartments: the nuclear periphery, pellicular membranes of motile or invasive parasite forms and in a ring-like distribution at the tight junction during merozoite invasion of erythrocytes in both human and mouse malaria parasites. Localisation at the nuclear periphery is consistent with an emerging role of actin in facilitating parasite gene regulation. During invasion, we show that the actin ring at the parasite-host cell tight junction is dependent on dynamic filament turnover. Super-resolution imaging places this ring posterior to, and not concentric with, the junction marker rhoptry neck protein 4. This implies motor force relies on the engagement of dynamic microfilaments at zones of traction, though not necessarily directly through receptor-ligand interactions at sites of adhesion during invasion. Combined, these observations extend current understanding of the diverse roles actin plays in malaria parasite development and apicomplexan cell motility, in particular refining understanding on the linkage of the internal parasite gliding motor with the extra-cellular milieu. © 2012 Angrisano et al.

Published

2012

10. Subcompartmentalisation of Proteins in the Rhoptries Correlates with Ordered Events of Erythrocyte Invasion by the Blood Stage Malaria Parasite

Author

Zuccala, ES, Gout, AM, Dekiwadia, C, Marapana, DS, Angrisano, F, Turnbull, L, Riglar, DT, Rogers, KL, Whitchurch, CB, Ralph, SA, Speed, TP, Baum, J, Zuccala, ES, Gout, AM, Dekiwadia, C, Marapana, DS, Angrisano, F, Turnbull, L, Riglar, DT, Rogers, KL, Whitchurch, CB, Ralph, SA, Speed, TP, and Baum, J

Abstract

Host cell infection by apicomplexan parasites plays an essential role in lifecycle progression for these obligate intracellular pathogens. For most species, including the etiological agents of malaria and toxoplasmosis, infection requires active host-cell invasion dependent on formation of a tight junction - the organising interface between parasite and host cell during entry. Formation of this structure is not, however, shared across all Apicomplexa or indeed all parasite lifecycle stages. Here, using an in silico integrative genomic search and endogenous gene-tagging strategy, we sought to characterise proteins that function specifically during junction-dependent invasion, a class of proteins we term invasins to distinguish them from adhesins that function in species specific host-cell recognition. High-definition imaging of tagged Plasmodium falciparum invasins localised proteins to multiple cellular compartments of the blood stage merozoite. This includes several that localise to distinct subcompartments within the rhoptries. While originating from the same organelle, however, each has very different dynamics during invasion. Apical Sushi Protein and Rhoptry Neck protein 2 release early, following the junction, whilst a novel rhoptry protein PFF0645c releases only after invasion is complete. This supports the idea that organisation of proteins within a secretory organelle determines the order and destination of protein secretion and provides a localisation-based classification strategy for predicting invasin function during apicomplexan parasite invasion. © 2012 Zuccala et al.

Published

2012

11. Super-resolution dissection of coordinated events during malaria parasite invasion of the human erythrocyte

Author

Riglar, DT, Richard, D, Wilson, DW, Boyle, MJ, Dekiwadia, C, Turnbull, L, Angrisano, F, Marapana, DS, Rogers, KL, Whitchurch, CB, Beeson, JG, Cowman, AF, Ralph, SA, Baum, J, Riglar, DT, Richard, D, Wilson, DW, Boyle, MJ, Dekiwadia, C, Turnbull, L, Angrisano, F, Marapana, DS, Rogers, KL, Whitchurch, CB, Beeson, JG, Cowman, AF, Ralph, SA, and Baum, J

Abstract

Erythrocyte invasion by the merozoite is an obligatory stage in Plasmodium parasite infection and essential to malaria disease progression. Attempts to study this process have been hindered by the poor invasion synchrony of merozoites from the only in vitro culture-adapted human malaria parasite, Plasmodium falciparum. Using fluorescence, three-dimensional structured illumination, and immunoelectron microscopy of filtered merozoites, we analyze cellular and molecular events underlying each discrete step of invasion. Monitoring the dynamics of these events revealed that commitment to the process is mediated through merozoite attachment to the erythrocyte, triggering all subsequent invasion events, which then proceed without obvious checkpoints. Instead, coordination of the invasion process involves formation of the merozoite-erythrocyte tight junction, which acts as a nexus for rhoptry secretion, surface-protein shedding, and actomyosin motor activation. The ability to break down each molecular step allows us to propose a comprehensive model for the molecular basis of parasite invasion. © 2011 Elsevier Inc.

Published

2011

12. Plasmodium falciparum formins are essential for invasion and sexual stage development.

Author

Collier S, Pietsch E, Dans M, Ling D, Tavella TA, Lopaticki S, Marapana DS, Shibu MA, Andrew D, Tiash S, McMillan PJ, Gilson P, Tilley L, and Dixon MWA

Subjects

Formins, Cell Division, Cytoskeleton, Actins genetics, Plasmodium falciparum genetics

Abstract

The malaria parasite uses actin-based mechanisms throughout its lifecycle to control a range of biological processes including intracellular trafficking, gene regulation, parasite motility and invasion. In this work we assign functions to the Plasmodium falciparum formins 1 and 2 (FRM1 and FRM2) proteins in asexual and sexual blood stage development. We show that FRM1 is essential for merozoite invasion and FRM2 is required for efficient cell division. We also observed divergent functions for FRM1 and FRM2 in gametocyte development. Conditional deletion of FRM1 leads to a delay in gametocyte stage progression. We show that FRM2 controls the actin and microtubule cytoskeletons in developing gametocytes, with premature removal of the protein resulting in a loss of transmissible stage V gametocytes. Lastly, we show that targeting formin proteins with the small molecule inhibitor of formin homology domain 2 (SMIFH2) leads to a multistage block in asexual and sexual stage parasite development., (© 2023. Springer Nature Limited.)

Published

2023

13. Targeted protein degradation at the host-pathogen interface.

Author

Grohmann C, Marapana DS, and Ebert G

Subjects

Proteins metabolism, Proteolysis, Ubiquitin metabolism, Ubiquitination, Proteasome Endopeptidase Complex metabolism, Ubiquitin-Protein Ligases metabolism

Abstract

Infectious diseases remain a major burden to global health. Despite the implementation of successful vaccination campaigns and efficient drugs, the increasing emergence of pathogenic vaccine or treatment resistance demands novel therapeutic strategies. The development of traditional therapies using small-molecule drugs is based on modulating protein function and activity through the occupation of active sites such as enzyme inhibition or ligand-receptor binding. These prerequisites result in the majority of host and pathogenic disease-relevant, nonenzymatic and structural proteins being labeled "undruggable." Targeted protein degradation (TPD) emerged as a powerful strategy to eliminate proteins of interest including those of the undruggable variety. Proteolysis-targeting chimeras (PROTACs) are rationally designed heterobifunctional small molecules that exploit the cellular ubiquitin-proteasome system to specifically mediate the highly selective and effective degradation of target proteins. PROTACs have shown remarkable results in the degradation of various cancer-associated proteins, and several candidates are already in clinical development. Significantly, PROTAC-mediated TPD holds great potential for targeting and modulating pathogenic proteins, especially in the face of increasing drug resistance to the best-in-class treatments. In this review, we discuss advances in the development of TPD in the context of targeting the host-pathogen interface and speculate on their potential use to combat viral, bacterial, and parasitic infection., (© 2021 The Authors. Molecular Microbiology published by John Wiley & Sons Ltd.)

Published

2022

14. 4D analysis of malaria parasite invasion offers insights into erythrocyte membrane remodeling and parasitophorous vacuole formation.

Author

Geoghegan ND, Evelyn C, Whitehead LW, Pasternak M, McDonald P, Triglia T, Marapana DS, Kempe D, Thompson JK, Mlodzianoski MJ, Healer J, Biro M, Cowman AF, and Rogers KL

Subjects

Animals, Erythrocyte Membrane metabolism, Humans, Merozoites, Parasites, Plasmodium metabolism, Plasmodium falciparum metabolism, Protozoan Proteins metabolism, Erythrocyte Membrane parasitology, Erythrocytes parasitology, Four-Dimensional Computed Tomography methods, Host-Parasite Interactions physiology, Malaria parasitology, Vacuoles metabolism

Abstract

Host membrane remodeling is indispensable for viruses, bacteria, and parasites, to subvert the membrane barrier and obtain entry into cells. The malaria parasite Plasmodium spp. induces biophysical and molecular changes to the erythrocyte membrane through the ordered secretion of its apical organelles. To understand this process and address the debate regarding how the parasitophorous vacuole membrane (PVM) is formed, we developed an approach using lattice light-sheet microscopy, which enables the parasite interaction with the host cell membrane to be tracked and characterized during invasion. Our results show that the PVM is predominantly formed from the erythrocyte membrane, which undergoes biophysical changes as it is remodeled across all stages of invasion, from pre-invasion through to PVM sealing. This approach enables a functional interrogation of parasite-derived lipids and proteins in PVM biogenesis and echinocytosis during Plasmodium falciparum invasion and promises to yield mechanistic insights regarding how this is more generally orchestrated by other intracellular pathogens.

Published

2021

15. Pan-active imidazolopiperazine antimalarials target the Plasmodium falciparum intracellular secretory pathway.

Author

LaMonte GM, Rocamora F, Marapana DS, Gnädig NF, Ottilie S, Luth MR, Worgall TS, Goldgof GM, Mohunlal R, Santha Kumar TR, Thompson JK, Vigil E, Yang J, Hutson D, Johnson T, Huang J, Williams RM, Zou BY, Cheung AL, Kumar P, Egan TJ, Lee MCS, Siegel D, Cowman AF, Fidock DA, and Winzeler EA

Subjects

Chromatography, High Pressure Liquid, Endoplasmic Reticulum drug effects, Endoplasmic Reticulum metabolism, Inhibitory Concentration 50, Mass Spectrometry, Protozoan Proteins metabolism, Pyrazoles pharmacology, Saccharomyces cerevisiae drug effects, Saccharomyces cerevisiae metabolism, Secretory Pathway drug effects, Antimalarials pharmacology, Plasmodium falciparum drug effects

Abstract

A promising new compound class for treating human malaria is the imidazolopiperazines (IZP) class. IZP compounds KAF156 (Ganaplacide) and GNF179 are effective against Plasmodium symptomatic asexual blood-stage infections, and are able to prevent transmission and block infection in animal models. But despite the identification of resistance mechanisms in P. falciparum, the mode of action of IZPs remains unknown. To investigate, we here combine in vitro evolution and genome analysis in Saccharomyces cerevisiae with molecular, metabolomic, and chemogenomic methods in P. falciparum. Our findings reveal that IZP-resistant S. cerevisiae clones carry mutations in genes involved in Endoplasmic Reticulum (ER)-based lipid homeostasis and autophagy. In Plasmodium, IZPs inhibit protein trafficking, block the establishment of new permeation pathways, and cause ER expansion. Our data highlight a mechanism for blocking parasite development that is distinct from those of standard compounds used to treat malaria, and demonstrate the potential of IZPs for studying ER-dependent protein processing.

Published

2020

16. The Metabolite Repair Enzyme Phosphoglycolate Phosphatase Regulates Central Carbon Metabolism and Fosmidomycin Sensitivity in Plasmodium falciparum.

Author

Dumont L, Richardson MB, van der Peet P, Marapana DS, Triglia T, Dixon MWA, Cowman AF, Williams SJ, Tilley L, McConville MJ, and Cobbold SA

Subjects

Fosfomycin pharmacology, Glycolysis drug effects, Humans, Lactates pharmacology, Malaria, Falciparum drug therapy, Malaria, Falciparum metabolism, Sugar Acids pharmacology, Antimalarials pharmacology, Carbon metabolism, Drug Resistance drug effects, Fosfomycin analogs & derivatives, Phosphoric Monoester Hydrolases metabolism, Plasmodium falciparum drug effects, Plasmodium falciparum metabolism

Abstract

Members of the haloacid dehalogenase (HAD) family of metabolite phosphatases play an important role in regulating multiple pathways in Plasmodium falciparum central carbon metabolism. We show that the P. falciparum HAD protein, phosphoglycolate phosphatase (PGP), regulates glycolysis and pentose pathway flux in asexual blood stages via detoxifying the damaged metabolite 4-phosphoerythronate (4-PE). Disruption of the P. falciparum pgp gene caused accumulation of two previously uncharacterized metabolites, 2-phospholactate and 4-PE. 4-PE is a putative side product of the glycolytic enzyme, glyceraldehyde-3-phosphate dehydrogenase, and its accumulation inhibits the pentose phosphate pathway enzyme, 6-phosphogluconate dehydrogenase (6-PGD). Inhibition of 6-PGD by 4-PE leads to an unexpected feedback response that includes increased flux into the pentose phosphate pathway as a result of partial inhibition of upper glycolysis, with concomitant increased sensitivity to antimalarials that target pathways downstream of glycolysis. These results highlight the role of metabolite detoxification in regulating central carbon metabolism and drug sensitivity of the malaria parasite. IMPORTANCE The malaria parasite has a voracious appetite, requiring large amounts of glucose and nutrients for its rapid growth and proliferation inside human red blood cells. The host cell is resource rich, but this is a double-edged sword; nutrient excess can lead to undesirable metabolic reactions and harmful by-products. Here, we demonstrate that the parasite possesses a metabolite repair enzyme (PGP) that suppresses harmful metabolic by-products (via substrate dephosphorylation) and allows the parasite to maintain central carbon metabolism. Loss of PGP leads to the accumulation of two damaged metabolites and causes a domino effect of metabolic dysregulation. Accumulation of one damaged metabolite inhibits an essential enzyme in the pentose phosphate pathway, leading to substrate accumulation and secondary inhibition of glycolysis. This work highlights how the parasite coordinates metabolic flux by eliminating harmful metabolic by-products to ensure rapid proliferation in its resource-rich niche., (Copyright © 2019 Dumont et al.)

Published

2019

17. Plasmepsin V cleaves malaria effector proteins in a distinct endoplasmic reticulum translocation interactome for export to the erythrocyte.

Author

Marapana DS, Dagley LF, Sandow JJ, Nebl T, Triglia T, Pasternak M, Dickerman BK, Crabb BS, Gilson PR, Webb AI, Boddey JA, and Cowman AF

Subjects

Aspartic Acid Endopeptidases genetics, Biological Transport genetics, Biological Transport physiology, Cell Membrane physiology, Malaria, Falciparum pathology, Plasmodium falciparum pathogenicity, SEC Translocation Channels genetics, Virulence Factors, Aspartic Acid Endopeptidases metabolism, Endoplasmic Reticulum metabolism, Erythrocytes metabolism, Plasmodium falciparum metabolism, SEC Translocation Channels metabolism

Abstract

Plasmodium falciparum exports hundreds of virulence proteins within infected erythrocytes, a process that requires cleavage of a pentameric motif called Plasmodium export element or vacuolar transport signal by the endoplasmic reticulum (ER)-resident protease plasmepsin V. We identified plasmepsin V-binding proteins that form a unique interactome required for the translocation of effector cargo into the parasite ER. These interactions are functionally distinct from the Sec61-signal peptidase complex required for the translocation of proteins destined for the classical secretory pathway. This interactome does not involve the signal peptidase (SPC21) and consists of PfSec61, PfSPC25, plasmepsin V and PfSec62, which is an essential component of the post-translational ER translocon. Together, they form a distinct portal for the recognition and translocation of a large subset of Plasmodium export element effector proteins into the ER, thereby remodelling the infected erythrocyte that is required for parasite survival and pathogenesis.

Published

2018

18. Mefloquine targets the Plasmodium falciparum 80S ribosome to inhibit protein synthesis.

Author

Wong W, Bai XC, Sleebs BE, Triglia T, Brown A, Thompson JK, Jackson KE, Hanssen E, Marapana DS, Fernandez IS, Ralph SA, Cowman AF, Scheres SHW, and Baum J

Subjects

Antimalarials pharmacology, Mefloquine pharmacology, Plasmodium falciparum drug effects, Protein Biosynthesis drug effects, Protein Synthesis Inhibitors pharmacology, Ribosomes drug effects

Abstract

Malaria control is heavily dependent on chemotherapeutic agents for disease prevention and drug treatment. Defining the mechanism of action for licensed drugs, for which no target is characterized, is critical to the development of their second-generation derivatives to improve drug potency towards inhibition of their molecular targets. Mefloquine is a widely used antimalarial without a known mode of action. Here, we demonstrate that mefloquine is a protein synthesis inhibitor. We solved a 3.2 Å cryo-electron microscopy structure of the Plasmodium falciparum 80S ribosome with the (+)-mefloquine enantiomer bound to the ribosome GTPase-associated centre. Mutagenesis of mefloquine-binding residues generates parasites with increased resistance, confirming the parasite-killing mechanism. Furthermore, structure-guided derivatives with an altered piperidine group, predicted to improve binding, show enhanced parasiticidal effect. These data reveal one possible mode of action for mefloquine and demonstrate the vast potential of cryo-electron microscopy to guide the development of mefloquine derivatives to inhibit parasite protein synthesis.

Published

2017

19. Plasmodium falciparum coronin organizes arrays of parallel actin filaments potentially guiding directional motility in invasive malaria parasites.

Author

Olshina MA, Angrisano F, Marapana DS, Riglar DT, Bane K, Wong W, Catimel B, Yin MX, Holmes AB, Frischknecht F, Kovar DR, and Baum J

Subjects

Actin Cytoskeleton metabolism, Animals, Erythrocytes parasitology, Humans, Malaria, Falciparum parasitology, Microfilament Proteins metabolism, Models, Molecular, Plasmodium falciparum metabolism, Plasmodium falciparum pathogenicity, Protozoan Proteins metabolism, Rabbits, Actin Cytoskeleton chemistry, Microfilament Proteins chemistry, Plasmodium falciparum chemistry, Plasmodium falciparum physiology, Protozoan Proteins chemistry

Abstract

Background: Gliding motility in Plasmodium parasites, the aetiological agents of malaria disease, is mediated by an actomyosin motor anchored in the outer pellicle of the motile cell. Effective motility is dependent on a parasite myosin motor and turnover of dynamic parasite actin filaments. To date, however, the basis for directional motility is not known. Whilst myosin is very likely orientated as a result of its anchorage within the parasite, how actin filaments are orientated to facilitate directional force generation remains unexplained. In addition, recent evidence has questioned the linkage between actin filaments and secreted surface antigens leaving the way by which motor force is transmitted to the extracellular milieu unknown. Malaria parasites possess a markedly reduced repertoire of actin regulators, among which few are predicted to interact with filamentous (F)-actin directly. One of these, PF3D7_1251200, shows strong homology to the coronin family of actin-filament binding proteins, herein referred to as PfCoronin., Methods: Here the N terminal beta propeller domain of PfCoronin (PfCor-N) was expressed to assess its ability to bind and bundle pre-formed actin filaments by sedimentation assay, total internal reflection fluorescence (TIRF) microscopy and confocal imaging as well as to explore its ability to bind phospholipids. In parallel a tagged PfCoronin line in Plasmodium falciparum was generated to determine the cellular localization of the protein during asexual parasite development and blood-stage merozoite invasion., Results: A combination of biochemical approaches demonstrated that the N-terminal beta-propeller domain of PfCoronin is capable of binding F-actin and facilitating formation of parallel filament bundles. In parasites, PfCoronin is expressed late in the asexual lifecycle and localizes to the pellicle region of invasive merozoites before and during erythrocyte entry. PfCoronin also associates strongly with membranes within the cell, likely mediated by interactions with phosphatidylinositol-4,5-bisphosphate (PI(4,5)P2) at the plasma membrane., Conclusions: These data suggest PfCoronin may fulfil a key role as the critical determinant of actin filament organization in the Plasmodium cell. This raises the possibility that macro-molecular organization of actin mediates directional motility in gliding parasites.

Published

2015

20. Inhibition of Plasmepsin V activity demonstrates its essential role in protein export, PfEMP1 display, and survival of malaria parasites.

Author

Sleebs BE, Lopaticki S, Marapana DS, O'Neill MT, Rajasekaran P, Gazdik M, Günther S, Whitehead LW, Lowes KN, Barfod L, Hviid L, Shaw PJ, Hodder AN, Smith BJ, Cowman AF, and Boddey JA

Subjects

Endoplasmic Reticulum metabolism, Erythrocytes parasitology, Humans, Protein Transport drug effects, Protozoan Proteins metabolism, Aspartic Acid Endopeptidases antagonists & inhibitors, Aspartic Acid Proteases antagonists & inhibitors, Oligopeptides pharmacology, Protozoan Proteins antagonists & inhibitors, Sulfonamides pharmacology

Abstract

The malaria parasite Plasmodium falciparum exports several hundred proteins into the infected erythrocyte that are involved in cellular remodeling and severe virulence. The export mechanism involves the Plasmodium export element (PEXEL), which is a cleavage site for the parasite protease, Plasmepsin V (PMV). The PMV gene is refractory to deletion, suggesting it is essential, but definitive proof is lacking. Here, we generated a PEXEL-mimetic inhibitor that potently blocks the activity of PMV isolated from P. falciparum and Plasmodium vivax. Assessment of PMV activity in P. falciparum revealed PEXEL cleavage occurs cotranslationaly, similar to signal peptidase. Treatment of P. falciparum-infected erythrocytes with the inhibitor caused dose-dependent inhibition of PEXEL processing as well as protein export, including impaired display of the major virulence adhesin, PfEMP1, on the erythrocyte surface, and cytoadherence. The inhibitor killed parasites at the trophozoite stage and knockdown of PMV enhanced sensitivity to the inhibitor, while overexpression of PMV increased resistance. This provides the first direct evidence that PMV activity is essential for protein export in Plasmodium spp. and for parasite survival in human erythrocytes and validates PMV as an antimalarial drug target., Competing Interests: The authors have declared that no competing interests exist.

Published

2014

21. Malaria parasite signal peptide peptidase is an ER-resident protease required for growth but not for invasion.

Author

Marapana DS, Wilson DW, Zuccala ES, Dekiwadia CD, Beeson JG, Ralph SA, and Baum J

Subjects

Animals, Aspartic Acid Endopeptidases antagonists & inhibitors, Erythrocytes enzymology, Erythrocytes parasitology, Humans, Merozoites enzymology, Plasmodium falciparum growth & development, Plasmodium falciparum pathogenicity, Protease Inhibitors pharmacology, Aspartic Acid Endopeptidases metabolism, Endoplasmic Reticulum enzymology, Plasmodium falciparum enzymology

Abstract

The establishment of parasite infection within the human erythrocyte is an essential stage in the development of malaria disease. As such, significant interest has focused on the mechanics that underpin invasion and on characterization of parasite molecules involved. Previous evidence has implicated a presenilin-like signal peptide peptidase (SPP) from the most virulent human malaria parasite, Plasmodium falciparum, in the process of invasion where it has been proposed to function in the cleavage of the erythrocyte cytoskeletal protein Band 3. The role of a traditionally endoplasmic reticulum (ER) protease in the process of red blood cell invasion is unexpected. Here, using a combination of molecular, cellular and chemical approaches we provide evidence that PfSPP is, instead, a bona fide ER-resident peptidase that remains intracellular throughout the invasion process. Furthermore, SPP-specific drug inhibition has no effect on erythrocyte invasion whilst having low micromolar potency against intra-erythrocytic development. Contrary to previous reports, these results show that PfSPP plays no role in erythrocyte invasion. Nonetheless, PfSPP clearly represents a potential chemotherapeutic target to block parasite growth, supporting ongoing efforts to develop antimalarial-targeting protein maturation and trafficking during intra-erythrocytic development., (© 2012 John Wiley & Sons A/S.)

Published

2012

22. Spatial localisation of actin filaments across developmental stages of the malaria parasite.

Author

Angrisano F, Riglar DT, Sturm A, Volz JC, Delves MJ, Zuccala ES, Turnbull L, Dekiwadia C, Olshina MA, Marapana DS, Wong W, Mollard V, Bradin CH, Tonkin CJ, Gunning PW, Ralph SA, Whitchurch CB, Sinden RE, Cowman AF, McFadden GI, and Baum J

Subjects

Actin Cytoskeleton chemistry, Animals, Humans, Life Cycle Stages physiology, Merozoites metabolism, Mice, Plasmodium berghei metabolism, Plasmodium falciparum metabolism, Protein Structure, Secondary, Sporozoites metabolism, Actin Cytoskeleton metabolism, Malaria parasitology, Protozoan Proteins metabolism

Abstract

Actin dynamics have been implicated in a variety of developmental processes during the malaria parasite lifecycle. Parasite motility, in particular, is thought to critically depend on an actomyosin motor located in the outer pellicle of the parasite cell. Efforts to understand the diverse roles actin plays have, however, been hampered by an inability to detect microfilaments under native conditions. To visualise the spatial dynamics of actin we generated a parasite-specific actin antibody that shows preferential recognition of filamentous actin and applied this tool to different lifecycle stages (merozoites, sporozoites and ookinetes) of the human and mouse malaria parasite species Plasmodium falciparum and P. berghei along with tachyzoites from the related apicomplexan parasite Toxoplasma gondii. Actin filament distribution was found associated with three core compartments: the nuclear periphery, pellicular membranes of motile or invasive parasite forms and in a ring-like distribution at the tight junction during merozoite invasion of erythrocytes in both human and mouse malaria parasites. Localisation at the nuclear periphery is consistent with an emerging role of actin in facilitating parasite gene regulation. During invasion, we show that the actin ring at the parasite-host cell tight junction is dependent on dynamic filament turnover. Super-resolution imaging places this ring posterior to, and not concentric with, the junction marker rhoptry neck protein 4. This implies motor force relies on the engagement of dynamic microfilaments at zones of traction, though not necessarily directly through receptor-ligand interactions at sites of adhesion during invasion. Combined, these observations extend current understanding of the diverse roles actin plays in malaria parasite development and apicomplexan cell motility, in particular refining understanding on the linkage of the internal parasite gliding motor with the extra-cellular milieu.

Published

2012

23. Subcompartmentalisation of proteins in the rhoptries correlates with ordered events of erythrocyte invasion by the blood stage malaria parasite.

Author

Zuccala ES, Gout AM, Dekiwadia C, Marapana DS, Angrisano F, Turnbull L, Riglar DT, Rogers KL, Whitchurch CB, Ralph SA, Speed TP, and Baum J

Subjects

Blotting, Western, Fluorescent Antibody Technique, Host-Parasite Interactions, Humans, Microscopy, Immunoelectron, Organelles ultrastructure, Erythrocytes parasitology, Malaria parasitology, Organelles metabolism, Plasmodium falciparum metabolism, Plasmodium falciparum pathogenicity, Protozoan Proteins metabolism

Abstract

Host cell infection by apicomplexan parasites plays an essential role in lifecycle progression for these obligate intracellular pathogens. For most species, including the etiological agents of malaria and toxoplasmosis, infection requires active host-cell invasion dependent on formation of a tight junction - the organising interface between parasite and host cell during entry. Formation of this structure is not, however, shared across all Apicomplexa or indeed all parasite lifecycle stages. Here, using an in silico integrative genomic search and endogenous gene-tagging strategy, we sought to characterise proteins that function specifically during junction-dependent invasion, a class of proteins we term invasins to distinguish them from adhesins that function in species specific host-cell recognition. High-definition imaging of tagged Plasmodium falciparum invasins localised proteins to multiple cellular compartments of the blood stage merozoite. This includes several that localise to distinct subcompartments within the rhoptries. While originating from the same organelle, however, each has very different dynamics during invasion. Apical Sushi Protein and Rhoptry Neck protein 2 release early, following the junction, whilst a novel rhoptry protein PFF0645c releases only after invasion is complete. This supports the idea that organisation of proteins within a secretory organelle determines the order and destination of protein secretion and provides a localisation-based classification strategy for predicting invasin function during apicomplexan parasite invasion.

Published

2012

24. Minimal requirements for actin filament disassembly revealed by structural analysis of malaria parasite actin-depolymerizing factor 1.

Author

Wong W, Skau CT, Marapana DS, Hanssen E, Taylor NL, Riglar DT, Zuccala ES, Angrisano F, Lewis H, Catimel B, Clarke OB, Kershaw NJ, Perugini MA, Kovar DR, Gulbis JM, and Baum J

Subjects

Actin Depolymerizing Factors chemistry, Actin Depolymerizing Factors genetics, Amino Acid Sequence, Animals, Binding Sites genetics, Crystallography, X-Ray, Humans, Immunoblotting, Malaria parasitology, Microscopy, Fluorescence methods, Models, Molecular, Molecular Sequence Data, Mutation, Plasmodium falciparum genetics, Plasmodium falciparum metabolism, Protein Binding, Protein Structure, Secondary, Protein Structure, Tertiary, Protozoan Proteins chemistry, Protozoan Proteins genetics, Sequence Homology, Amino Acid, Actin Cytoskeleton metabolism, Actin Depolymerizing Factors metabolism, Actins metabolism, Protozoan Proteins metabolism

Abstract

Malaria parasite cell motility is a process that is dependent on the dynamic turnover of parasite-derived actin filaments. Despite its central role, actin's polymerization state is controlled by a set of identifiable regulators that is markedly reduced compared with those of other eukaryotic cells. In Plasmodium falciparum, the most virulent species that affects humans, this minimal repertoire includes two members of the actin-depolymerizing factor/cofilin (AC) family of proteins, P. falciparum actin-depolymerizing factor 1 (PfADF1) and P. falciparum actin-depolymerizing factor 2. This essential class of actin regulator is involved in the control of filament dynamics at multiple levels, from monomer binding through to filament depolymerization and severing. Previous biochemical analyses have suggested that PfADF1 sequesters monomeric actin but, unlike most eukaryotic counterparts, has limited potential to bind or depolymerize filaments. The molecular basis for these unusual properties and implications for parasite cell motility have not been established. Here we present the crystal structure of an apicomplexan AC protein, PfADF1. We show that PfADF1 lacks critical residues previously implicated as essential for AC-mediated actin filament binding and disassembly, having a substantially reduced filament-binding loop and C-terminal α4 helix. Despite this divergence in structure, we demonstrate that PfADF1 is capable of efficient actin filament severing. Furthermore, this severing occurs despite PfADF1's low binding affinity for filaments. Comparative structural analysis along with biochemical and microscopy evidence establishes that severing is reliant on the availability of an exposed basic residue in the filament-binding loop, a conserved minimal requirement that defines AC-mediated filament disassembly across eukaryotic cells.

Published

2011

25. Super-resolution dissection of coordinated events during malaria parasite invasion of the human erythrocyte.

Author

Riglar DT, Richard D, Wilson DW, Boyle MJ, Dekiwadia C, Turnbull L, Angrisano F, Marapana DS, Rogers KL, Whitchurch CB, Beeson JG, Cowman AF, Ralph SA, and Baum J

Subjects

Cell Adhesion, Humans, Imaging, Three-Dimensional, Merozoites physiology, Merozoites ultrastructure, Microscopy, Fluorescence, Microscopy, Immunoelectron, Models, Biological, Erythrocytes parasitology, Erythrocytes ultrastructure, Malaria, Falciparum parasitology, Malaria, Falciparum pathology, Plasmodium falciparum pathogenicity, Plasmodium falciparum ultrastructure

Abstract

Erythrocyte invasion by the merozoite is an obligatory stage in Plasmodium parasite infection and essential to malaria disease progression. Attempts to study this process have been hindered by the poor invasion synchrony of merozoites from the only in vitro culture-adapted human malaria parasite, Plasmodium falciparum. Using fluorescence, three-dimensional structured illumination, and immunoelectron microscopy of filtered merozoites, we analyze cellular and molecular events underlying each discrete step of invasion. Monitoring the dynamics of these events revealed that commitment to the process is mediated through merozoite attachment to the erythrocyte, triggering all subsequent invasion events, which then proceed without obvious checkpoints. Instead, coordination of the invasion process involves formation of the merozoite-erythrocyte tight junction, which acts as a nexus for rhoptry secretion, surface-protein shedding, and actomyosin motor activation. The ability to break down each molecular step allows us to propose a comprehensive model for the molecular basis of parasite invasion., (Copyright © 2011 Elsevier Inc. All rights reserved.)

Published

2011