Your search keyword '"Bullen HE"' showing total 40 results

1. Disrupting the Allosteric Interaction between the Plasmodium falciparum cAMP-dependent Kinase and Its Regulatory Subunit

Author

Littler, DR, Bullen, HE, Harvey, KL, Beddoe, Travis, Crabb, BS, Rossjohn, J, and Gilson, PR

Subjects

Uncategorized

Abstract

The ubiquitous second messenger cAMP mediates signal transduction processes in the malarial parasite that regulate host erythrocyte invasion and the proliferation of merozoites. In Plasmodium falciparum, the central receptor for cAMP is the single regulatory subunit (R) of protein kinase A (PKA). To aid the development of compounds that can selectively dysregulate parasite PKA signaling, we solved the structure of the PKA regulatory subunit in complex with cAMP and a related analogue that displays antimalarial activity, (Sp)-2-Cl-cAMPS. Prior to signaling, PKA-R holds the kinase's catalytic subunit (C) in an inactive state by exerting an allosteric inhibitory effect. When two cAMP molecules bind to PKA-R, they stabilize a structural conformation that facilitates its dissociation, freeing PKA-C to phosphorylate downstream substrates such as apical membrane antigen 1. Although PKA activity was known to be necessary for erythrocytic proliferation, we show that uncontrolled induction of PKA activity using membrane-permeable agonists is equally disruptive to growth.

Published

2023

2. A revised mechanism for how Plasmodium falciparum recruits and exports proteins into its erythrocytic host cell

Author

Gabriela, M, Matthews, KM, Boshoven, C, Kouskousis, B, Jonsdottir, TK, Bullen, HE, Modak, Joyanta, Steer, DL, Sleebs, BE, Crabb, BS, De Koning-Ward, Tania, Gilson, PR, Gabriela, M, Matthews, KM, Boshoven, C, Kouskousis, B, Jonsdottir, TK, Bullen, HE, Modak, Joyanta, Steer, DL, Sleebs, BE, Crabb, BS, De Koning-Ward, Tania, and Gilson, PR

Abstract

Plasmodium falciparum exports ~10% of its proteome into its host erythrocyte to modify the host cell’s physiology. The Plasmodium export element (PEXEL) motif contained within the N-terminus of most exported proteins directs the trafficking of those proteins into the erythrocyte. To reach the host cell, the PEXEL motif of exported proteins is processed by the endoplasmic reticulum (ER) resident aspartyl protease plasmepsin V. Then, following secretion into the parasite-encasing parasitophorous vacuole, the mature exported protein must be unfolded and translocated across the parasitophorous vacuole membrane by the Plasmodium translocon of exported proteins (PTEX). PTEX is a protein-conducting channel consisting of the pore-forming protein EXP2, the protein unfoldase HSP101, and structural component PTEX150. The mechanism of how exported proteins are specifically trafficked from the parasite’s ER following PEXEL cleavage to PTEX complexes on the parasitophorous vacuole membrane is currently not understood. Here, we present evidence that EXP2 and PTEX150 form a stable subcomplex that facilitates HSP101 docking. We also demonstrate that HSP101 localises both within the parasitophorous vacuole and within the parasite’s ER throughout the ring and trophozoite stage of the parasite, coinciding with the timeframe of protein export. Interestingly, we found that HSP101 can form specific interactions with model PEXEL proteins in the parasite’s ER, irrespective of their PEXEL processing status. Collectively, our data suggest that HSP101 recognises and chaperones PEXEL proteins from the ER to the parasitophorous vacuole and given HSP101’s specificity for the EXP2-PTEX150 subcomplex, this provides a mechanism for how exported proteins are specifically targeted to PTEX for translocation into the erythrocyte.

Published

2022

3. A revised mechanism for how Plasmodium falciparum recruits and exports proteins into its erythrocytic host cell

Author

Blackman, MJ, Gabriela, M, Matthews, KM, Boshoven, C, Kouskousis, B, Jonsdottir, TK, Bullen, HE, Modak, J, Steer, DL, Sleebs, BE, Crabb, BS, de Koning-Ward, TF, Gilson, PR, Blackman, MJ, Gabriela, M, Matthews, KM, Boshoven, C, Kouskousis, B, Jonsdottir, TK, Bullen, HE, Modak, J, Steer, DL, Sleebs, BE, Crabb, BS, de Koning-Ward, TF, and Gilson, PR

Abstract

Plasmodium falciparum exports ~10% of its proteome into its host erythrocyte to modify the host cell's physiology. The Plasmodium export element (PEXEL) motif contained within the N-terminus of most exported proteins directs the trafficking of those proteins into the erythrocyte. To reach the host cell, the PEXEL motif of exported proteins is processed by the endoplasmic reticulum (ER) resident aspartyl protease plasmepsin V. Then, following secretion into the parasite-encasing parasitophorous vacuole, the mature exported protein must be unfolded and translocated across the parasitophorous vacuole membrane by the Plasmodium translocon of exported proteins (PTEX). PTEX is a protein-conducting channel consisting of the pore-forming protein EXP2, the protein unfoldase HSP101, and structural component PTEX150. The mechanism of how exported proteins are specifically trafficked from the parasite's ER following PEXEL cleavage to PTEX complexes on the parasitophorous vacuole membrane is currently not understood. Here, we present evidence that EXP2 and PTEX150 form a stable subcomplex that facilitates HSP101 docking. We also demonstrate that HSP101 localises both within the parasitophorous vacuole and within the parasite's ER throughout the ring and trophozoite stage of the parasite, coinciding with the timeframe of protein export. Interestingly, we found that HSP101 can form specific interactions with model PEXEL proteins in the parasite's ER, irrespective of their PEXEL processing status. Collectively, our data suggest that HSP101 recognises and chaperones PEXEL proteins from the ER to the parasitophorous vacuole and given HSP101's specificity for the EXP2-PTEX150 subcomplex, this provides a mechanism for how exported proteins are specifically targeted to PTEX for translocation into the erythrocyte.

Published

2022

4. The Plasmodium falciparum parasitophorous vacuole protein P113 interacts with the parasite protein export machinery and maintains normal vacuole architecture

Author

Bullen, HE, Sanders, PR, Dans, MG, Jonsdottir, TK, Riglar, DT, Looker, O, Palmer, CS, Kouskousis, B, Charnaud, SC, Triglia, T, Gabriela, M, Schneider, MP, Chan, J-A, de Koning-Ward, TF, Baum, J, Kazura, JW, Beeson, JG, Cowman, AF, Gilson, PR, Crabb, BS, Bullen, HE, Sanders, PR, Dans, MG, Jonsdottir, TK, Riglar, DT, Looker, O, Palmer, CS, Kouskousis, B, Charnaud, SC, Triglia, T, Gabriela, M, Schneider, MP, Chan, J-A, de Koning-Ward, TF, Baum, J, Kazura, JW, Beeson, JG, Cowman, AF, Gilson, PR, and Crabb, BS

Abstract

Infection with Plasmodium falciparum parasites results in approximately 627,000 deaths from malaria annually. Key to the parasite's success is their ability to invade and subsequently grow within human erythrocytes. Parasite proteins involved in parasite invasion and proliferation are therefore intrinsically of great interest, as targeting these proteins could provide novel means of therapeutic intervention. One such protein is P113 which has been reported to be both an invasion protein and an intracellular protein located within the parasitophorous vacuole (PV). The PV is delimited by a membrane (PVM) across which a plethora of parasite-specific proteins are exported via the Plasmodium Translocon of Exported proteins (PTEX) into the erythrocyte to enact various immune evasion functions. To better understand the role of P113 we isolated its binding partners from in vitro cultures of P. falciparum. We detected interactions with the protein export machinery (PTEX and exported protein-interacting complex) and a variety of proteins that either transit through the PV or reside on the parasite plasma membrane. Genetic knockdown or partial deletion of P113 did not significantly reduce parasite growth or protein export but did disrupt the morphology of the PVM, suggesting that P113 may play a role in maintaining normal PVM architecture.

Published

2022

5. The Medicines for Malaria Venture Malaria Box contains inhibitors of protein secretion in Plasmodium falciparum blood stage parasites

Author

Looker, O, Dans, MG, Bullen, HE, Sleebs, BE, Crabb, BS, Gilson, PR, Looker, O, Dans, MG, Bullen, HE, Sleebs, BE, Crabb, BS, and Gilson, PR

Abstract

Plasmodium falciparum parasites which cause malaria, traffic hundreds of proteins into the red blood cells (RBCs) they infect. These exported proteins remodel their RBCs enabling host immune evasion through processes such as cytoadherence that greatly assist parasite survival. As resistance to all current antimalarial compounds is rising new compounds need to be identified and those that could inhibit parasite protein secretion and export would both rapidly reduce parasite virulence and ultimately lead to parasite death. To identify compounds that inhibit protein export we used transgenic parasites expressing an exported nanoluciferase reporter to screen the Medicines for Malaria Venture Malaria Box of 400 antimalarial compounds with mostly unknown targets. The most potent inhibitor identified in this screen was MMV396797 whose application led to export inhibition of both the reporter and endogenous exported proteins. MMV396797 mediated blockage of protein export and slowed the rigidification and cytoadherence of infected RBCs-modifications which are both mediated by parasite-derived exported proteins. Overall, we have identified a new protein export inhibitor in P. falciparum whose target though unknown, could be developed into a future antimalarial that rapidly inhibits parasite virulence before eliminating parasites from the host.

Published

2022

6. Characterisation of complexes formed by parasite proteins exported into the host cell compartment of Plasmodium falciparum infected red blood cells

Author

Jonsdottir, TK, Counihan, Natalie, Modak, Joyanta, Kouskousis, B, Sanders, PR, Gabriela, M, Bullen, HE, Crabb, BS, De Koning-Ward, Tania, Gilson, PR, Jonsdottir, TK, Counihan, Natalie, Modak, Joyanta, Kouskousis, B, Sanders, PR, Gabriela, M, Bullen, HE, Crabb, BS, De Koning-Ward, Tania, and Gilson, PR

Published

2021

7. A 4-cyano-3-methylisoquinoline inhibitor of Plasmodium falciparum growth targets the sodium efflux pump PfATP4

Author

Gilson, PR, Kumarasingha, R, Thompson, J, Zhang, X, Sietsma Penington, J, Kalhor, R, Bullen, HE, Lehane, AM, Dans, MG, de Koning-Ward, TF, Holien, JK, Soares da Costa, TP, Hulett, MD, Buskes, MJ, Crabb, BS, Kirk, K, Papenfuss, AT, Cowman, AF, Abbott, BM, Gilson, PR, Kumarasingha, R, Thompson, J, Zhang, X, Sietsma Penington, J, Kalhor, R, Bullen, HE, Lehane, AM, Dans, MG, de Koning-Ward, TF, Holien, JK, Soares da Costa, TP, Hulett, MD, Buskes, MJ, Crabb, BS, Kirk, K, Papenfuss, AT, Cowman, AF, and Abbott, BM

Abstract

We developed a novel series of antimalarial compounds based on a 4-cyano-3-methylisoquinoline. Our lead compound MB14 achieved modest inhibition of the growth in vitro of the human malaria parasite, Plasmodium falciparum. To identify its biological target we selected for parasites resistant to MB14. Genome sequencing revealed that all resistant parasites bore a single point S374R mutation in the sodium (Na+) efflux transporter PfATP4. There are many compounds known to inhibit PfATP4 and some are under preclinical development. MB14 was shown to inhibit Na+ dependent ATPase activity in parasite membranes, consistent with the compound targeting PfATP4 directly. PfATP4 inhibitors cause swelling and lysis of infected erythrocytes, attributed to the accumulation of Na+ inside the intracellular parasites and the resultant parasite swelling. We show here that inhibitor-induced lysis of infected erythrocytes is dependent upon the parasite protein RhopH2, a component of the new permeability pathways that are induced by the parasite in the erythrocyte membrane. These pathways mediate the influx of Na+ into the infected erythrocyte and their suppression via RhopH2 knockdown limits the accumulation of Na+ within the parasite hence protecting the infected erythrocyte from lysis. This study reveals a role for the parasite-induced new permeability pathways in the mechanism of action of PfATP4 inhibitors.

Published

2019

8. Protein Kinase A Is Essential for Invasion of Plasmodium falciparum into Human Erythrocytes

Author

Soldati-Favre, D, Wilde, M-L, Triglia, T, Marapana, D, Thompson, JK, Kouzmitchev, AA, Bullen, HE, Gilson, PR, Cowman, AF, Tonkin, CJ, Soldati-Favre, D, Wilde, M-L, Triglia, T, Marapana, D, Thompson, JK, Kouzmitchev, AA, Bullen, HE, Gilson, PR, Cowman, AF, and Tonkin, CJ

Abstract

Understanding the mechanisms behind host cell invasion by Plasmodium falciparum remains a major hurdle to developing antimalarial therapeutics that target the asexual cycle and the symptomatic stage of malaria. Host cell entry is enabled by a multitude of precisely timed and tightly regulated receptor-ligand interactions. Cyclic nucleotide signaling has been implicated in regulating parasite invasion, and an important downstream effector of the cAMP-signaling pathway is protein kinase A (PKA), a cAMP-dependent protein kinase. There is increasing evidence that P. falciparum PKA (PfPKA) is responsible for phosphorylation of the cytoplasmic domain of P. falciparum apical membrane antigen 1 (PfAMA1) at Ser610, a cAMP-dependent event that is crucial for successful parasite invasion. In the present study, CRISPR-Cas9 and conditional gene deletion (dimerizable cre) technologies were implemented to generate a P. falciparum parasite line in which expression of the catalytic subunit of PfPKA (PfPKAc) is under conditional control, demonstrating highly efficient dimerizable Cre recombinase (DiCre)-mediated gene excision and complete knockdown of protein expression. Parasites lacking PfPKAc show severely reduced growth after one intraerythrocytic growth cycle and are deficient in host cell invasion, as highlighted by live-imaging experiments. Furthermore, PfPKAc-deficient parasites are unable to phosphorylate PfAMA1 at Ser610. This work not only identifies an essential role for PfPKAc in the P. falciparum asexual life cycle but also confirms that PfPKAc is the kinase responsible for phosphorylating PfAMA1 Ser610.IMPORTANCE Malaria continues to present a major global health burden, particularly in low-resource countries. Plasmodium falciparum, the parasite responsible for the most severe form of malaria, causes disease through rapid and repeated rounds of invasion and replication within red blood cells. Invasion into red blood cells is essential for P. falciparum survival, and th

Published

2019

9. Phosphatidic Acid-Mediated Signaling Regulates Microneme Secretion in Toxoplasma

Author

Bullen HE Jia Y Yamaryo-Botté Y Bisio H Zhang O Jemelin NK Marq JB Carruthers V Botté CY So

Subjects

parasitic diseases, lipids (amino acids, peptides, and proteins)

Abstract

The obligate intracellular lifestyle of apicomplexan parasites necessitates an invasive phase underpinned by timely and spatially controlled secretion of apical organelles termed micronemes. In Toxoplasma gondii extracellular potassium levels and other stimuli trigger a signaling cascade culminating in phosphoinositide phospholipase C (PLC) activation which generates the second messengers diacylglycerol (DAG) and IP3 and ultimately results in microneme secretion. Here we show that a delicate balance between DAG and its downstream product phosphatidic acid (PA) is essential for controlling microneme release. Governing this balance is the apicomplexan specific DAG kinase 1 which interconverts PA and DAG and whose depletion impairs egress and causes parasite death. Additionally we identify an acylated pleckstrin homology (PH) domain containing protein (APH) on the microneme surface that senses PA during microneme secretion and is necessary for microneme exocytosis. As APH is conserved in Apicomplexa these findings highlight a potentially widely used mechanism in which key lipid mediators regulate microneme exocytosis.

Published

2016

10. Spatial organization of protein export in malaria parasite blood stages

Author

Charnaud, SC, Jonsdottir, TK, Sanders, PR, Bullen, HE, Dickerman, BK, Kouskousis, B, Palmer, CS, Pietrzak, HM, Laumaea, AE, Erazo, A-B, McHugh, E, Tilley, L, Crabb, BS, Gilson, PR, Charnaud, SC, Jonsdottir, TK, Sanders, PR, Bullen, HE, Dickerman, BK, Kouskousis, B, Palmer, CS, Pietrzak, HM, Laumaea, AE, Erazo, A-B, McHugh, E, Tilley, L, Crabb, BS, and Gilson, PR

Abstract

Plasmodium falciparum, which causes malaria, extensively remodels its human host cells, particularly erythrocytes. Remodelling is essential for parasite survival by helping to avoid host immunity and assisting in the uptake of plasma nutrients to fuel rapid growth. Host cell renovation is carried out by hundreds of parasite effector proteins that are exported into the erythrocyte across an enveloping parasitophorous vacuole membrane (PVM). The Plasmodium translocon for exported (PTEX) proteins is thought to span the PVM and provide a channel that unfolds and extrudes proteins across the PVM into the erythrocyte. We show that exported reporter proteins containing mouse dihydrofolate reductase domains that inducibly resist unfolding become trapped at the parasite surface partly colocalizing with PTEX. When cargo is trapped, loop-like extensions appear at the PVM containing both trapped cargo and PTEX protein EXP2, but not additional components HSP101 and PTEX150. Following removal of the block-inducing compound, export of reporter proteins only partly recovers possibly because much of the trapped cargo is spatially segregated in the loop regions away from PTEX. This suggests that parasites have the means to isolate unfoldable cargo proteins from PTEX-containing export zones to avert disruption of protein export that would reduce parasite growth.

Published

2018

11. Knockdown of the translocon protein EXP2 in Plasmodium falciparum reduces growth and protein export

Author

Spielmann, T, Charnaud, SC, Kumarasingha, R, Bullen, HE, Crabb, BS, Gilson, PR, Spielmann, T, Charnaud, SC, Kumarasingha, R, Bullen, HE, Crabb, BS, and Gilson, PR

Abstract

Malaria parasites remodel their host erythrocytes to gain nutrients and avoid the immune system. Host erythrocytes are modified by hundreds of effector proteins exported from the parasite into the host cell. Protein export is mediated by the PTEX translocon comprising five core components of which EXP2 is considered to form the putative pore that spans the vacuole membrane enveloping the parasite within its erythrocyte. To explore the function and importance of EXP2 for parasite survival in the asexual blood stage of Plasmodium falciparum we inducibly knocked down the expression of EXP2. Reduction in EXP2 expression strongly reduced parasite growth proportional to the degree of protein knockdown and tended to stall development about half way through the asexual cell cycle. Once the knockdown inducer was removed and EXP2 expression restored, parasite growth recovered dependent upon the length and degree of knockdown. To establish EXP2 function and hence the basis for growth reduction, the trafficking of an exported protein was monitored following EXP2 knockdown. This resulted in severe attenuation of protein export and is consistent with EXP2, and PTEX in general, being the conduit for export of proteins into the host compartment.

Published

2018

12. Plasmodium falciparum parasites deploy RhopH2 into the host erythrocyte to obtain nutrients, grow and replicate

Author

Counihan, NA, Chisholm, SA, Bullen, HE, Srivastava, A, Sanders, PR, Jonsdottir, TK, Weiss, GE, Ghosh, S, Crabb, BS, Creek, DJ, Gilson, PR, de Koning-Ward, TF, Counihan, NA, Chisholm, SA, Bullen, HE, Srivastava, A, Sanders, PR, Jonsdottir, TK, Weiss, GE, Ghosh, S, Crabb, BS, Creek, DJ, Gilson, PR, and de Koning-Ward, TF

Abstract

Plasmodium falciparum parasites, the causative agents of malaria, modify their host erythrocyte to render them permeable to supplementary nutrient uptake from the plasma and for removal of toxic waste. Here we investigate the contribution of the rhoptry protein RhopH2, in the formation of new permeability pathways (NPPs) in Plasmodium-infected erythrocytes. We show RhopH2 interacts with RhopH1, RhopH3, the erythrocyte cytoskeleton and exported proteins involved in host cell remodeling. Knockdown of RhopH2 expression in cycle one leads to a depletion of essential vitamins and cofactors and decreased de novo synthesis of pyrimidines in cycle two. There is also a significant impact on parasite growth, replication and transition into cycle three. The uptake of solutes that use NPPs to enter erythrocytes is also reduced upon RhopH2 knockdown. These findings provide direct genetic support for the contribution of the RhopH complex in NPP activity and highlight the importance of NPPs to parasite survival.

Published

2017

13. Proteomic analysis reveals novel proteins associated with the Plasmodium protein exporter PTEX and a loss of complex stability upon truncation of the core PTEX component, PTEX150

Author

Elsworth, B, Sanders, PR, Nebl, T, Batinovic, S, Kalanon, M, Nie, CQ, Charnaud, SC, Bullen, HE, Ward, TFDK, Tilley, L, Crabb, BS, Gilson, PR, Elsworth, B, Sanders, PR, Nebl, T, Batinovic, S, Kalanon, M, Nie, CQ, Charnaud, SC, Bullen, HE, Ward, TFDK, Tilley, L, Crabb, BS, and Gilson, PR

Abstract

The Plasmodium translocon for exported proteins (PTEX) has been established as the machinery responsible for the translocation of all classes of exported proteins beyond the parasitophorous vacuolar membrane of the intraerythrocytic malaria parasite. Protein export, particularly in the asexual blood stage, is crucial for parasite survival as exported proteins are involved in remodelling the host cell, an essential process for nutrient uptake, waste removal and immune evasion. Here, we have truncated the conserved C-terminus of one of the essential PTEX components, PTEX150, in Plasmodium falciparum in an attempt to create mutants of reduced functionality. Parasites tolerated C-terminal truncations of up to 125 amino acids with no reduction in growth, protein export or the establishment of new permeability pathways. Quantitative proteomic approaches however revealed a decrease in other PTEX subunits associating with PTEX150 in truncation mutants, suggesting a role for the C-terminus of PTEX150 in regulating PTEX stability. Our analyses also reveal three previously unreported PTEX-associated proteins, namely PV1, Pf113 and Hsp70-x (respective PlasmoDB numbers; PF3D7_1129100, PF3D7_1420700 and PF3D7_0831700) and demonstrate that core PTEX proteins exist in various distinct multimeric forms outside the major complex.

Published

2016

14. Spatial association with PTEX complexes defines regions for effector export into Plasmodium falciparum-infected erythrocytes

Author

Riglar, DT, Rogers, KL, Hanssen, E, Turnbull, L, Bullen, HE, Charnaud, SC, Przyborski, J, Gilson, PR, Whitchurch, CB, Crabb, BS, Baum, J, Cowman, AF, Riglar, DT, Rogers, KL, Hanssen, E, Turnbull, L, Bullen, HE, Charnaud, SC, Przyborski, J, Gilson, PR, Whitchurch, CB, Crabb, BS, Baum, J, and Cowman, AF

Abstract

Export of proteins into the infected erythrocyte is critical for malaria parasite survival. The majority of effector proteins are thought to export via a proteinaceous translocon, resident in the parasitophorous vacuole membrane surrounding the parasite. Identification of the Plasmodium translocon of exported proteins and its biochemical association with exported proteins suggests it performs this role. Direct evidence for this, however, is lacking. Here using viable purified Plasmodium falciparum merozoites and three-dimensional structured illumination microscopy, we investigate remodelling events immediately following parasite invasion. We show that multiple complexes of the Plasmodium translocon of exported proteins localize together in foci that dynamically change in clustering behaviour. Furthermore, we provide conclusive evidence of spatial association between exported proteins and exported protein 2, a core component of the Plasmodium translocon of exported proteins, during native conditions and upon generation of translocation intermediates. These data provide the most direct cellular evidence to date that protein export occurs at regions of the parasitophorous vacuole membrane housing the Plasmodium translocon of exported proteins complex.

Published

2013

15. Biosynthesis, Localization, and Macromolecular Arrangement of the Plasmodium falciparum Translocon of Exported Proteins (PTEX)

Author

Bullen, HE, Charnaud, SC, Kalanon, M, Riglar, DT, Dekiwadia, C, Kangwanrangsan, N, Torii, M, Tsuboi, T, Baum, J, Ralph, SA, Cowman, AF, de Koning-Ward, TF, Crabb, BS, Gilson, PRD, Bullen, HE, Charnaud, SC, Kalanon, M, Riglar, DT, Dekiwadia, C, Kangwanrangsan, N, Torii, M, Tsuboi, T, Baum, J, Ralph, SA, Cowman, AF, de Koning-Ward, TF, Crabb, BS, and Gilson, PRD

Abstract

To survive within its host erythrocyte, Plasmodium falciparum must export hundreds of proteins across both its parasite plasma membrane and surrounding parasitophorous vacuole membrane, most of which are likely to use a protein complex known as PTEX (Plasmodium translocon of exported proteins). PTEX is a putative protein trafficking machinery responsible for the export of hundreds of proteins across the parasitophorous vacuole membrane and into the human host cell. Five proteins are known to comprise the PTEX complex, and in this study, three of the major stoichiometric components are investigated including HSP101 (a AAA(+) ATPase), a protein of no known function termed PTEX150, and the apparent membrane component EXP2. We show that these proteins are synthesized in the preceding schizont stage (PTEX150 and HSP101) or even earlier in the life cycle (EXP2), and before invasion these components reside within the dense granules of invasive merozoites. From these apical organelles, the protein complex is released into the host cell where it resides with little turnover in the parasitophorous vacuole membrane for most of the remainder of the following cell cycle. At this membrane, PTEX is arranged in a stable macromolecular complex of >1230 kDa that includes an ∼600-kDa apparently homo-oligomeric complex of EXP2 that can be separated from the remainder of the PTEX complex using non-ionic detergents. Two different biochemical methods undertaken here suggest that PTEX components associate as EXP2-PTEX150-HSP101, with EXP2 associating with the vacuolar membrane. Collectively, these data support the hypothesis that EXP2 oligomerizes and potentially forms the putative membrane-spanning pore to which the remainder of the PTEX complex is attached.

Published

2012

16. A Novel Family of Apicomplexan Glideosome-associated Proteins with an Inner Membrane-anchoring Role

Author

Bullen, HE, Tonkin, CJ, O'Donnell, RA, Tham, W-H, Papenfuss, AT, Gould, S, Cowman, AF, Crabb, BS, Gilson, PR, Bullen, HE, Tonkin, CJ, O'Donnell, RA, Tham, W-H, Papenfuss, AT, Gould, S, Cowman, AF, Crabb, BS, and Gilson, PR

Abstract

The phylum Apicomplexa are a group of obligate intracellular parasites responsible for a wide range of important diseases. Central to the lifecycle of these unicellular parasites is their ability to migrate through animal tissue and invade target host cells. Apicomplexan movement is generated by a unique system of gliding motility in which substrate adhesins and invasion-related proteins are pulled across the plasma membrane by an underlying actin-myosin motor. The myosins of this motor are inserted into a dual membrane layer called the inner membrane complex (IMC) that is sandwiched between the plasma membrane and an underlying cytoskeletal basket. Central to our understanding of gliding motility is the characterization of proteins residing within the IMC, but to date only a few proteins are known. We report here a novel family of six-pass transmembrane proteins, termed the GAPM family, which are highly conserved and specific to Apicomplexa. In Plasmodium falciparum and Toxoplasma gondii the GAPMs localize to the IMC where they form highly SDS-resistant oligomeric complexes. The GAPMs co-purify with the cytoskeletal alveolin proteins and also to some degree with the actin-myosin motor itself. Hence, these proteins are strong candidates for an IMC-anchoring role, either directly or indirectly tethering the motor to the cytoskeleton.

Published

2009

17. A Pyridyl-Furan Series Developed from the Open Global Health Library Block Red Blood Cell Invasion and Protein Trafficking in Plasmodium falciparum through Potential Inhibition of the Parasite's PI4KIIIB Enzyme.

Author

Ling DB, Nguyen W, Looker O, Razook Z, McCann K, Barry AE, Scheurer C, Wittlin S, Famodimu MT, Delves MJ, Bullen HE, Crabb BS, Sleebs BE, and Gilson PR

Subjects

Animals, Plasmodium falciparum genetics, Global Health, Erythrocytes, Protein Transport, Furans, Parasites

Abstract

With the resistance increasing to current antimalarial medicines, there is an urgent need to discover new drug targets and to develop new medicines against these targets. We therefore screened the Open Global Health Library of Merck KGaA, Darmstadt, Germany, of 250 compounds against the asexual blood stage of the deadliest malarial parasite Plasmodium falciparum, from which eight inhibitors with low micromolar potency were found. Due to its combined potencies against parasite growth and inhibition of red blood cell invasion, the pyridyl-furan compound OGHL250 was prioritized for further optimization. The potency of the series lead compound ( WEHI-518 ) was improved 250-fold to low nanomolar levels against parasite blood-stage growth. Parasites selected for resistance to a related compound, MMV396797, were also resistant to WEHI-518 as well as KDU731, an inhibitor of the phosphatidylinositol kinase PfPI4KIIIB, suggesting that this kinase is the target of the pyridyl-furan series. Inhibition of PfPI4KIIIB blocks multiple stages of the parasite's life cycle and other potent inhibitors are currently under preclinical development. MMV396797-resistant parasites possess an E1316D mutation in PfPKI4IIIB that clusters with known resistance mutations of other inhibitors of the kinase. Building upon earlier studies that showed that PfPI4KIIIB inhibitors block the development of the invasive merozoite parasite stage, we show that members of the pyridyl-furan series also block invasion and/or the conversion of merozoites into ring-stage intracellular parasites through inhibition of protein secretion and export into red blood cells.

Published

2023

18. Protein disulfide isomerases - a way to tackle malaria.

Author

Angrisano F, Ford A, Blagborough AM, and Bullen HE

Subjects

Humans, Protein Disulfide-Isomerases metabolism, Malaria drug therapy, Malaria prevention & control, Plasmodium metabolism

Abstract

Protein disulfide isomerases (PDIs) ensure that specific substrate proteins are correctly folded. PDI activity plays an essential role in malaria transmission. Here we provide an overview of the role of PDIs in malaria-causing Plasmodium parasites and outline why PDI inhibition could be a novel way to treat malaria and prevent transmission., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2023 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2023

19. PTEX helps efficiently traffic haemoglobinases to the food vacuole in Plasmodium falciparum.

Author

Jonsdottir TK, Elsworth B, Cobbold S, Gabriela M, Ploeger E, Parkyn Schneider M, Charnaud SC, Dans MG, McConville M, Bullen HE, Crabb BS, and Gilson PR

Subjects

Animals, Vacuoles metabolism, Protein Transport, Protozoan Proteins genetics, Protozoan Proteins metabolism, Erythrocytes parasitology, Peptide Hydrolases metabolism, Plasmodium falciparum genetics, Plasmodium falciparum metabolism, Parasites metabolism

Abstract

A key element of Plasmodium biology and pathogenesis is the trafficking of ~10% of the parasite proteome into the host red blood cell (RBC) it infects. To cross the parasite-encasing parasitophorous vacuole membrane, exported proteins utilise a channel-forming protein complex termed the Plasmodium translocon of exported proteins (PTEX). PTEX is obligatory for parasite survival, both in vitro and in vivo, suggesting that at least some exported proteins have essential metabolic functions. However, to date only one essential PTEX-dependent process, the new permeability pathways, has been described. To identify other essential PTEX-dependant proteins/processes, we conditionally knocked down the expression of one of its core components, PTEX150, and examined which pathways were affected. Surprisingly, the food vacuole mediated process of haemoglobin (Hb) digestion was substantially perturbed by PTEX150 knockdown. Using a range of transgenic parasite lines and approaches, we show that two major Hb proteases; falcipain 2a and plasmepsin II, interact with PTEX core components, implicating the translocon in the trafficking of Hb proteases. We propose a model where these proteases are translocated into the PV via PTEX in order to reach the cytostome, located at the parasite periphery, prior to food vacuole entry. This work offers a second mechanistic explanation for why PTEX function is essential for growth of the parasite within its host RBC., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2023 Jonsdottir et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2023

20. The Medicines for Malaria Venture Malaria Box contains inhibitors of protein secretion in Plasmodium falciparum blood stage parasites.

Author

Looker O, Dans MG, Bullen HE, Sleebs BE, Crabb BS, and Gilson PR

Subjects

Animals, Erythrocytes parasitology, Humans, Plasmodium falciparum metabolism, Protozoan Proteins metabolism, Antimalarials metabolism, Antimalarials pharmacology, Antimalarials therapeutic use, Malaria, Malaria, Falciparum drug therapy, Malaria, Falciparum parasitology, Parasites metabolism

Abstract

Plasmodium falciparum parasites which cause malaria, traffic hundreds of proteins into the red blood cells (RBCs) they infect. These exported proteins remodel their RBCs enabling host immune evasion through processes such as cytoadherence that greatly assist parasite survival. As resistance to all current antimalarial compounds is rising new compounds need to be identified and those that could inhibit parasite protein secretion and export would both rapidly reduce parasite virulence and ultimately lead to parasite death. To identify compounds that inhibit protein export we used transgenic parasites expressing an exported nanoluciferase reporter to screen the Medicines for Malaria Venture Malaria Box of 400 antimalarial compounds with mostly unknown targets. The most potent inhibitor identified in this screen was MMV396797 whose application led to export inhibition of both the reporter and endogenous exported proteins. MMV396797 mediated blockage of protein export and slowed the rigidification and cytoadherence of infected RBCs-modifications which are both mediated by parasite-derived exported proteins. Overall, we have identified a new protein export inhibitor in P. falciparum whose target though unknown, could be developed into a future antimalarial that rapidly inhibits parasite virulence before eliminating parasites from the host., (© 2022 The Authors. Traffic published by John Wiley & Sons Ltd.)

Published

2022

21. The Plasmodium falciparum parasitophorous vacuole protein P113 interacts with the parasite protein export machinery and maintains normal vacuole architecture.

Author

Bullen HE, Sanders PR, Dans MG, Jonsdottir TK, Riglar DT, Looker O, Palmer CS, Kouskousis B, Charnaud SC, Triglia T, Gabriela M, Parkyn Schneider M, Chan JA, de Koning-Ward TF, Baum J, Kazura JW, Beeson JG, Cowman AF, Gilson PR, and Crabb BS

Subjects

Animals, Erythrocytes parasitology, Humans, Plasmodium falciparum genetics, Plasmodium falciparum metabolism, Protein Transport genetics, Protozoan Proteins genetics, Protozoan Proteins metabolism, Vacuoles metabolism, Malaria, Falciparum parasitology, Parasites metabolism

Abstract

Infection with Plasmodium falciparum parasites results in approximately 627,000 deaths from malaria annually. Key to the parasite's success is their ability to invade and subsequently grow within human erythrocytes. Parasite proteins involved in parasite invasion and proliferation are therefore intrinsically of great interest, as targeting these proteins could provide novel means of therapeutic intervention. One such protein is P113 which has been reported to be both an invasion protein and an intracellular protein located within the parasitophorous vacuole (PV). The PV is delimited by a membrane (PVM) across which a plethora of parasite-specific proteins are exported via the Plasmodium Translocon of Exported proteins (PTEX) into the erythrocyte to enact various immune evasion functions. To better understand the role of P113 we isolated its binding partners from in vitro cultures of P. falciparum. We detected interactions with the protein export machinery (PTEX and exported protein-interacting complex) and a variety of proteins that either transit through the PV or reside on the parasite plasma membrane. Genetic knockdown or partial deletion of P113 did not significantly reduce parasite growth or protein export but did disrupt the morphology of the PVM, suggesting that P113 may play a role in maintaining normal PVM architecture., (© 2022 The Authors. Molecular Microbiology published by John Wiley & Sons Ltd.)

Published

2022

22. A revised mechanism for how Plasmodium falciparum recruits and exports proteins into its erythrocytic host cell.

Author

Gabriela M, Matthews KM, Boshoven C, Kouskousis B, Jonsdottir TK, Bullen HE, Modak J, Steer DL, Sleebs BE, Crabb BS, de Koning-Ward TF, and Gilson PR

Subjects

Animals, Erythrocytes parasitology, Protein Transport physiology, Protozoan Proteins metabolism, Parasites metabolism, Plasmodium falciparum metabolism

Abstract

Plasmodium falciparum exports ~10% of its proteome into its host erythrocyte to modify the host cell's physiology. The Plasmodium export element (PEXEL) motif contained within the N-terminus of most exported proteins directs the trafficking of those proteins into the erythrocyte. To reach the host cell, the PEXEL motif of exported proteins is processed by the endoplasmic reticulum (ER) resident aspartyl protease plasmepsin V. Then, following secretion into the parasite-encasing parasitophorous vacuole, the mature exported protein must be unfolded and translocated across the parasitophorous vacuole membrane by the Plasmodium translocon of exported proteins (PTEX). PTEX is a protein-conducting channel consisting of the pore-forming protein EXP2, the protein unfoldase HSP101, and structural component PTEX150. The mechanism of how exported proteins are specifically trafficked from the parasite's ER following PEXEL cleavage to PTEX complexes on the parasitophorous vacuole membrane is currently not understood. Here, we present evidence that EXP2 and PTEX150 form a stable subcomplex that facilitates HSP101 docking. We also demonstrate that HSP101 localises both within the parasitophorous vacuole and within the parasite's ER throughout the ring and trophozoite stage of the parasite, coinciding with the timeframe of protein export. Interestingly, we found that HSP101 can form specific interactions with model PEXEL proteins in the parasite's ER, irrespective of their PEXEL processing status. Collectively, our data suggest that HSP101 recognises and chaperones PEXEL proteins from the ER to the parasitophorous vacuole and given HSP101's specificity for the EXP2-PTEX150 subcomplex, this provides a mechanism for how exported proteins are specifically targeted to PTEX for translocation into the erythrocyte., Competing Interests: The authors have declared that no competing interests exist.

Published

2022

23. Property activity refinement of 2-anilino 4-amino substituted quinazolines as antimalarials with fast acting asexual parasite activity.

Author

Ashton TD, Ngo A, Favuzza P, Bullen HE, Gancheva MR, Romeo O, Parkyn Schneider M, Nguyen N, Steel RWJ, Duffy S, Lowes KN, Sabroux HJ, Avery VM, Boddey JA, Wilson DW, Cowman AF, Gilson PR, and Sleebs BE

Subjects

Amination, Aniline Compounds therapeutic use, Animals, Antimalarials therapeutic use, Female, Humans, Malaria parasitology, Mice, Plasmodium physiology, Plasmodium falciparum drug effects, Plasmodium falciparum physiology, Quinazolines therapeutic use, Aniline Compounds chemistry, Aniline Compounds pharmacology, Antimalarials chemistry, Antimalarials pharmacology, Malaria drug therapy, Plasmodium drug effects, Quinazolines chemistry, Quinazolines pharmacology

Abstract

Malaria is a devastating disease caused by Plasmodium parasites. Emerging resistance against current antimalarial therapeutics has engendered the need to develop antimalarials with novel structural classes. We recently described the identification and initial optimization of the 2-anilino quinazoline antimalarial class. Here, we refine the physicochemical properties of this antimalarial class with the aim to improve aqueous solubility and metabolism and to reduce adverse promiscuity. We show the physicochemical properties of this class are intricately balanced with asexual parasite activity and human cell cytotoxicity. Structural modifications we have implemented improved LipE, aqueous solubility and in vitro metabolism while preserving fast acting P. falciparum asexual stage activity. The lead compounds demonstrated equipotent activity against P. knowlesi parasites and were not predisposed to resistance mechanisms of clinically used antimalarials. The optimized compounds exhibited modest activity against early-stage gametocytes, but no activity against pre-erythrocytic liver parasites. Confoundingly, the refined physicochemical properties installed in the compounds did not engender improved oral efficacy in a P. berghei mouse model of malaria compared to earlier studies on the 2-anilino quinazoline class. This study provides the framework for further development of this antimalarial class., (Copyright © 2021 Elsevier Inc. All rights reserved.)

Published

2021

24. Characterisation of complexes formed by parasite proteins exported into the host cell compartment of Plasmodium falciparum infected red blood cells.

Author

Jonsdottir TK, Counihan NA, Modak JK, Kouskousis B, Sanders PR, Gabriela M, Bullen HE, Crabb BS, de Koning-Ward TF, and Gilson PR

Subjects

Animals, Erythrocyte Membrane metabolism, Erythrocytes metabolism, Humans, Protein Transport, Protozoan Proteins metabolism, Parasites metabolism, Plasmodium falciparum metabolism

Abstract

During its intraerythrocytic life cycle, the human malaria parasite Plasmodium falciparum supplements its nutritional requirements by scavenging substrates from the plasma through the new permeability pathways (NPPs) installed in the red blood cell (RBC) membrane. Parasite proteins of the RhopH complex: CLAG3, RhopH2, RhopH3, have been implicated in NPP activity. Here, we studied 13 exported proteins previously hypothesised to interact with RhopH2, to study their potential contribution to the function of NPPs. NPP activity assays revealed that the 13 proteins do not appear to be individually important for NPP function, as conditional knockdown of these proteins had no effect on sorbitol uptake. Intriguingly, reciprocal immunoprecipitation assays showed that five of the 13 proteins interact with all members of the RhopH complex, with PF3D7_1401200 showing the strongest association. Mass spectrometry-based proteomics further identified new protein complexes; a cytoskeletal complex and a Maurer's clefts/J-dot complex, which overall helps clarify protein-protein interactions within the infected RBC (iRBC) and is suggestive of the potential trafficking route of the RhopH complex itself to the RBC membrane., (© 2021 The Authors. Cellular Microbiology published by John Wiley & Sons Ltd.)

Published

2021

25. Protein Kinase A Is Essential for Invasion of Plasmodium falciparum into Human Erythrocytes.

Author

Wilde ML, Triglia T, Marapana D, Thompson JK, Kouzmitchev AA, Bullen HE, Gilson PR, Cowman AF, and Tonkin CJ

Subjects

Antigens, Protozoan metabolism, Catalytic Domain, Cyclic AMP-Dependent Protein Kinases genetics, Humans, Membrane Proteins metabolism, Phosphorylation, Protein Processing, Post-Translational, Cyclic AMP-Dependent Protein Kinases metabolism, Endocytosis, Erythrocytes parasitology, Plasmodium falciparum growth & development, Protozoan Proteins metabolism

Abstract

Understanding the mechanisms behind host cell invasion by Plasmodium falciparum remains a major hurdle to developing antimalarial therapeutics that target the asexual cycle and the symptomatic stage of malaria. Host cell entry is enabled by a multitude of precisely timed and tightly regulated receptor-ligand interactions. Cyclic nucleotide signaling has been implicated in regulating parasite invasion, and an important downstream effector of the cAMP-signaling pathway is protein kinase A (PKA), a cAMP-dependent protein kinase. There is increasing evidence that P. falciparum PKA (PfPKA) is responsible for phosphorylation of the cytoplasmic domain of P. falciparum apical membrane antigen 1 (PfAMA1) at Ser610, a cAMP-dependent event that is crucial for successful parasite invasion. In the present study, CRISPR-Cas9 and conditional gene deletion (dimerizable cre) technologies were implemented to generate a P. falciparum parasite line in which expression of the catalytic subunit of PfPKA (PfPKAc) is under conditional control, demonstrating highly efficient dimerizable Cre recombinase (DiCre)-mediated gene excision and complete knockdown of protein expression. Parasites lacking PfPKAc show severely reduced growth after one intraerythrocytic growth cycle and are deficient in host cell invasion, as highlighted by live-imaging experiments. Furthermore, PfPKAc-deficient parasites are unable to phosphorylate PfAMA1 at Ser610. This work not only identifies an essential role for PfPKAc in the P. falciparum asexual life cycle but also confirms that PfPKAc is the kinase responsible for phosphorylating PfAMA1 Ser610. IMPORTANCE Malaria continues to present a major global health burden, particularly in low-resource countries. Plasmodium falciparum , the parasite responsible for the most severe form of malaria, causes disease through rapid and repeated rounds of invasion and replication within red blood cells. Invasion into red blood cells is essential for P. falciparum survival, and the molecular events mediating this process have gained much attention as potential therapeutic targets. With no effective vaccine available, and with the emergence of resistance to antimalarials, there is an urgent need for the development of new therapeutics. Our research has used genetic techniques to provide evidence of an essential protein kinase involved in P. falciparum invasion. Our work adds to the current understanding of parasite signaling processes required for invasion, highlighting PKA as a potential drug target to inhibit invasion for the treatment of malaria., (Copyright © 2019 Wilde et al.)

Published

2019

26. A 4-cyano-3-methylisoquinoline inhibitor of Plasmodium falciparum growth targets the sodium efflux pump PfATP4.

Author

Gilson PR, Kumarasingha R, Thompson J, Zhang X, Penington JS, Kalhor R, Bullen HE, Lehane AM, Dans MG, de Koning-Ward TF, Holien JK, Soares da Costa TP, Hulett MD, Buskes MJ, Crabb BS, Kirk K, Papenfuss AT, Cowman AF, and Abbott BM

Subjects

Cell Membrane drug effects, Drug Resistance drug effects, Erythrocytes parasitology, Isoquinolines chemistry, Isoquinolines pharmacology, Models, Molecular, Plasmodium falciparum genetics, Plasmodium falciparum metabolism, Point Mutation, Protozoan Proteins chemistry, Protozoan Proteins genetics, Protozoan Proteins metabolism, Sodium, Sodium-Potassium-Exchanging ATPase chemistry, Sodium-Potassium-Exchanging ATPase genetics, Whole Genome Sequencing, Erythrocytes drug effects, Isoquinolines chemical synthesis, Plasmodium falciparum drug effects, Sodium-Potassium-Exchanging ATPase antagonists & inhibitors

Abstract

We developed a novel series of antimalarial compounds based on a 4-cyano-3-methylisoquinoline. Our lead compound MB14 achieved modest inhibition of the growth in vitro of the human malaria parasite, Plasmodium falciparum. To identify its biological target we selected for parasites resistant to MB14. Genome sequencing revealed that all resistant parasites bore a single point S374R mutation in the sodium (Na + ) efflux transporter PfATP4. There are many compounds known to inhibit PfATP4 and some are under preclinical development. MB14 was shown to inhibit Na + dependent ATPase activity in parasite membranes, consistent with the compound targeting PfATP4 directly. PfATP4 inhibitors cause swelling and lysis of infected erythrocytes, attributed to the accumulation of Na + inside the intracellular parasites and the resultant parasite swelling. We show here that inhibitor-induced lysis of infected erythrocytes is dependent upon the parasite protein RhopH2, a component of the new permeability pathways that are induced by the parasite in the erythrocyte membrane. These pathways mediate the influx of Na + into the infected erythrocyte and their suppression via RhopH2 knockdown limits the accumulation of Na + within the parasite hence protecting the infected erythrocyte from lysis. This study reveals a role for the parasite-induced new permeability pathways in the mechanism of action of PfATP4 inhibitors.

Published

2019

27. The triumvirate of signaling molecules controlling Toxoplasma microneme exocytosis: Cyclic GMP, calcium, and phosphatidic acid.

Author

Bullen HE, Bisio H, and Soldati-Favre D

Subjects

Animals, Host-Parasite Interactions, Humans, Organelles parasitology, Protein Transport, Protozoan Proteins metabolism, Signal Transduction, Calcium metabolism, Cyclic GMP metabolism, Exocytosis physiology, Organelles metabolism, Phosphatidic Acids metabolism, Toxoplasma physiology, Toxoplasmosis parasitology

Abstract

To elicit effective invasion and egress from infected cells, obligate intracellular parasites of the phylum Apicomplexa rely on the timely and spatially controlled exocytosis of specialized secretory organelles termed the micronemes. The effector molecules and signaling events underpinning this process are intricate; however, recent advances within the field of Toxoplasma gondii research have facilitated a broader understanding as well as a more integrated view of this complex cascade of events and have unraveled the importance of phosphatidic acid (PA) as a lipid mediator at multiple steps in this process., Competing Interests: The authors have declared that no competing interests exist.

Published

2019

28. Knockdown of the translocon protein EXP2 in Plasmodium falciparum reduces growth and protein export.

Author

Charnaud SC, Kumarasingha R, Bullen HE, Crabb BS, and Gilson PR

Subjects

Erythrocytes metabolism, Erythrocytes parasitology, Gene Knockdown Techniques, Humans, Life Cycle Stages genetics, Protein Transport genetics, Protozoan Proteins genetics, Protozoan Proteins metabolism, Carrier Proteins genetics, Carrier Proteins metabolism, Plasmodium falciparum genetics, Plasmodium falciparum growth & development

Abstract

Malaria parasites remodel their host erythrocytes to gain nutrients and avoid the immune system. Host erythrocytes are modified by hundreds of effector proteins exported from the parasite into the host cell. Protein export is mediated by the PTEX translocon comprising five core components of which EXP2 is considered to form the putative pore that spans the vacuole membrane enveloping the parasite within its erythrocyte. To explore the function and importance of EXP2 for parasite survival in the asexual blood stage of Plasmodium falciparum we inducibly knocked down the expression of EXP2. Reduction in EXP2 expression strongly reduced parasite growth proportional to the degree of protein knockdown and tended to stall development about half way through the asexual cell cycle. Once the knockdown inducer was removed and EXP2 expression restored, parasite growth recovered dependent upon the length and degree of knockdown. To establish EXP2 function and hence the basis for growth reduction, the trafficking of an exported protein was monitored following EXP2 knockdown. This resulted in severe attenuation of protein export and is consistent with EXP2, and PTEX in general, being the conduit for export of proteins into the host compartment., Competing Interests: The authors have declared that no competing interests exist.

Published

2018

29. Spatial organization of protein export in malaria parasite blood stages.

Author

Charnaud SC, Jonsdottir TK, Sanders PR, Bullen HE, Dickerman BK, Kouskousis B, Palmer CS, Pietrzak HM, Laumaea AE, Erazo AB, McHugh E, Tilley L, Crabb BS, and Gilson PR

Subjects

Animals, Erythrocytes parasitology, Humans, Malaria, Falciparum blood, Mice, Vacuoles parasitology, Malaria, Falciparum parasitology, Parasites metabolism, Plasmodium falciparum metabolism, Protein Transport physiology, Protozoan Proteins metabolism

Abstract

Plasmodium falciparum, which causes malaria, extensively remodels its human host cells, particularly erythrocytes. Remodelling is essential for parasite survival by helping to avoid host immunity and assisting in the uptake of plasma nutrients to fuel rapid growth. Host cell renovation is carried out by hundreds of parasite effector proteins that are exported into the erythrocyte across an enveloping parasitophorous vacuole membrane (PVM). The Plasmodium translocon for exported (PTEX) proteins is thought to span the PVM and provide a channel that unfolds and extrudes proteins across the PVM into the erythrocyte. We show that exported reporter proteins containing mouse dihydrofolate reductase domains that inducibly resist unfolding become trapped at the parasite surface partly colocalizing with PTEX. When cargo is trapped, loop-like extensions appear at the PVM containing both trapped cargo and PTEX protein EXP2, but not additional components HSP101 and PTEX150. Following removal of the block-inducing compound, export of reporter proteins only partly recovers possibly because much of the trapped cargo is spatially segregated in the loop regions away from PTEX. This suggests that parasites have the means to isolate unfoldable cargo proteins from PTEX-containing export zones to avert disruption of protein export that would reduce parasite growth., (© 2018 John Wiley & Sons A/S. Published by John Wiley & Sons Ltd.)

Published

2018

30. Plasmodium falciparum parasites deploy RhopH2 into the host erythrocyte to obtain nutrients, grow and replicate.

Author

Counihan NA, Chisholm SA, Bullen HE, Srivastava A, Sanders PR, Jonsdottir TK, Weiss GE, Ghosh S, Crabb BS, Creek DJ, Gilson PR, and de Koning-Ward TF

Subjects

Animals, Cytoskeleton metabolism, Humans, Mice, Pyrimidines metabolism, Vitamins metabolism, Erythrocytes parasitology, Host-Pathogen Interactions, Plasmodium falciparum growth & development, Plasmodium falciparum metabolism, Protozoan Proteins metabolism

Abstract

Plasmodium falciparum parasites, the causative agents of malaria, modify their host erythrocyte to render them permeable to supplementary nutrient uptake from the plasma and for removal of toxic waste. Here we investigate the contribution of the rhoptry protein RhopH2, in the formation of new permeability pathways (NPPs) in Plasmodium -infected erythrocytes. We show RhopH2 interacts with RhopH1, RhopH3, the erythrocyte cytoskeleton and exported proteins involved in host cell remodeling. Knockdown of RhopH2 expression in cycle one leads to a depletion of essential vitamins and cofactors and decreased de novo synthesis of pyrimidines in cycle two. There is also a significant impact on parasite growth, replication and transition into cycle three. The uptake of solutes that use NPPs to enter erythrocytes is also reduced upon RhopH2 knockdown. These findings provide direct genetic support for the contribution of the RhopH complex in NPP activity and highlight the importance of NPPs to parasite survival.

Published

2017

31. Optimization of 2-Anilino 4-Amino Substituted Quinazolines into Potent Antimalarial Agents with Oral in Vivo Activity.

Author

Gilson PR, Tan C, Jarman KE, Lowes KN, Curtis JM, Nguyen W, Di Rago AE, Bullen HE, Prinz B, Duffy S, Baell JB, Hutton CA, Jousset Subroux H, Crabb BS, Avery VM, Cowman AF, and Sleebs BE

Subjects

Administration, Oral, Animals, Antimalarials administration & dosage, Antimalarials pharmacology, Disease Models, Animal, Mice, Plasmodium falciparum drug effects, Quinazolines administration & dosage, Quinazolines pharmacology, Structure-Activity Relationship, Antimalarials therapeutic use, Quinazolines therapeutic use

Abstract

Novel antimalarial therapeutics that target multiple stages of the parasite lifecycle are urgently required to tackle the emerging problem of resistance with current drugs. Here, we describe the optimization of the 2-anilino quinazoline class as antimalarial agents. The class, identified from publicly available antimalarial screening data, was optimized to generate lead compounds that possess potent antimalarial activity against P. falciparum parasites comparable to the known antimalarials, chloroquine and mefloquine. During the optimization process, we defined the functionality necessary for activity and improved in vitro metabolism and solubility. The resultant lead compounds possess potent activity against a multidrug resistant strain of P. falciparum and arrest parasites at the ring phase of the asexual stage and also gametocytogensis. Finally, we show that the lead compounds are orally efficacious in a 4 day murine model of malaria disease burden.

Published

2017

32. Disrupting the Allosteric Interaction between the Plasmodium falciparum cAMP-dependent Kinase and Its Regulatory Subunit.

Author

Littler DR, Bullen HE, Harvey KL, Beddoe T, Crabb BS, Rossjohn J, and Gilson PR

Subjects

Allosteric Regulation, Cyclic AMP-Dependent Protein Kinases antagonists & inhibitors, Cyclic AMP-Dependent Protein Kinases metabolism, Protozoan Proteins antagonists & inhibitors, Protozoan Proteins metabolism, Cyclic AMP analogs & derivatives, Cyclic AMP chemistry, Cyclic AMP-Dependent Protein Kinases chemistry, Plasmodium falciparum enzymology, Protozoan Proteins chemistry

Abstract

The ubiquitous second messenger cAMP mediates signal transduction processes in the malarial parasite that regulate host erythrocyte invasion and the proliferation of merozoites. In Plasmodium falciparum, the central receptor for cAMP is the single regulatory subunit (R) of protein kinase A (PKA). To aid the development of compounds that can selectively dysregulate parasite PKA signaling, we solved the structure of the PKA regulatory subunit in complex with cAMP and a related analogue that displays antimalarial activity, (S p )-2-Cl-cAMPS. Prior to signaling, PKA-R holds the kinase's catalytic subunit (C) in an inactive state by exerting an allosteric inhibitory effect. When two cAMP molecules bind to PKA-R, they stabilize a structural conformation that facilitates its dissociation, freeing PKA-C to phosphorylate downstream substrates such as apical membrane antigen 1. Although PKA activity was known to be necessary for erythrocytic proliferation, we show that uncontrolled induction of PKA activity using membrane-permeable agonists is equally disruptive to growth., (© 2016 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2016

33. Proteomic analysis reveals novel proteins associated with the Plasmodium protein exporter PTEX and a loss of complex stability upon truncation of the core PTEX component, PTEX150.

Author

Elsworth B, Sanders PR, Nebl T, Batinovic S, Kalanon M, Nie CQ, Charnaud SC, Bullen HE, de Koning Ward TF, Tilley L, Crabb BS, and Gilson PR

Subjects

Cells, Cultured, Humans, Multiprotein Complexes metabolism, Protein Domains, Protein Interaction Maps, Protein Stability, Protein Transport, Erythrocytes parasitology, Membrane Transport Proteins physiology, Plasmodium falciparum physiology, Proteome metabolism, Protozoan Proteins physiology

Abstract

The Plasmodium translocon for exported proteins (PTEX) has been established as the machinery responsible for the translocation of all classes of exported proteins beyond the parasitophorous vacuolar membrane of the intraerythrocytic malaria parasite. Protein export, particularly in the asexual blood stage, is crucial for parasite survival as exported proteins are involved in remodelling the host cell, an essential process for nutrient uptake, waste removal and immune evasion. Here, we have truncated the conserved C-terminus of one of the essential PTEX components, PTEX150, in Plasmodium falciparum in an attempt to create mutants of reduced functionality. Parasites tolerated C-terminal truncations of up to 125 amino acids with no reduction in growth, protein export or the establishment of new permeability pathways. Quantitative proteomic approaches however revealed a decrease in other PTEX subunits associating with PTEX150 in truncation mutants, suggesting a role for the C-terminus of PTEX150 in regulating PTEX stability. Our analyses also reveal three previously unreported PTEX-associated proteins, namely PV1, Pf113 and Hsp70-x (respective PlasmoDB numbers; PF3D7_1129100, PF3D7_1420700 and PF3D7_0831700) and demonstrate that core PTEX proteins exist in various distinct multimeric forms outside the major complex., (© 2016 John Wiley & Sons Ltd.)

Published

2016

34. A central role for phosphatidic acid as a lipid mediator of regulated exocytosis in apicomplexa.

Author

Bullen HE and Soldati-Favre D

Subjects

Apicomplexa metabolism, Apicomplexa pathogenicity, Diglycerides metabolism, Lipid Metabolism genetics, Lipids chemistry, Lipids genetics, Signal Transduction, Apicomplexa genetics, Exocytosis genetics, Phosphatidic Acids, Phosphatidylcholines metabolism

Abstract

Lipids are commonly known for the structural roles they play, however, the specific contribution of different lipid classes to wide-ranging signalling pathways is progressively being unravelled. Signalling lipids and their associated effector proteins are emerging as significant contributors to a vast array of effector functions within cells, including essential processes such as membrane fusion and vesicle exocytosis. Many phospholipids have signalling capacity, however, this review will focus on phosphatidic acid (PA) and the enzymes implicated in its production from diacylglycerol (DAG) and phosphatidylcholine (PC): DGK and PLD respectively. PA is a negatively charged, cone-shaped lipid identified as a key mediator in specific membrane fusion and vesicle exocytosis events in a variety of mammalian cells, and has recently been implicated in specialised secretory organelle exocytosis in apicomplexan parasites. This review summarises the recent work implicating a role for PA regulation in exocytosis in various cell types. We will discuss how these signalling events are linked to pathogenesis in the phylum Apicomplexa., (© 2016 Federation of European Biochemical Societies.)

Published

2016

35. Phosphatidic Acid-Mediated Signaling Regulates Microneme Secretion in Toxoplasma.

Author

Bullen HE, Jia Y, Yamaryo-Botté Y, Bisio H, Zhang O, Jemelin NK, Marq JB, Carruthers V, Botté CY, and Soldati-Favre D

Subjects

Diacylglycerol Kinase metabolism, Diglycerides metabolism, Organelles drug effects, Organelles metabolism, Phosphatidic Acids metabolism, Protozoan Proteins metabolism, Signal Transduction, Toxoplasma physiology

Abstract

The obligate intracellular lifestyle of apicomplexan parasites necessitates an invasive phase underpinned by timely and spatially controlled secretion of apical organelles termed micronemes. In Toxoplasma gondii, extracellular potassium levels and other stimuli trigger a signaling cascade culminating in phosphoinositide-phospholipase C (PLC) activation, which generates the second messengers diacylglycerol (DAG) and IP3 and ultimately results in microneme secretion. Here we show that a delicate balance between DAG and its downstream product, phosphatidic acid (PA), is essential for controlling microneme release. Governing this balance is the apicomplexan-specific DAG-kinase-1, which interconverts PA and DAG, and whose depletion impairs egress and causes parasite death. Additionally, we identify an acylated pleckstrin-homology (PH) domain-containing protein (APH) on the microneme surface that senses PA during microneme secretion and is necessary for microneme exocytosis. As APH is conserved in Apicomplexa, these findings highlight a potentially widely used mechanism in which key lipid mediators regulate microneme exocytosis., (Copyright © 2016 Elsevier Inc. All rights reserved.)

Published

2016

36. Characterization of a serine hydrolase targeted by acyl-protein thioesterase inhibitors in Toxoplasma gondii.

Author

Kemp LE, Rusch M, Adibekian A, Bullen HE, Graindorge A, Freymond C, Rottmann M, Braun-Breton C, Baumeister S, Porfetye AT, Vetter IR, Hedberg C, and Soldati-Favre D

Subjects

Amino Acid Sequence, Enzyme Inhibitors chemistry, Humans, Lactones chemistry, Models, Molecular, Molecular Sequence Data, Protozoan Proteins chemistry, Protozoan Proteins genetics, Protozoan Proteins metabolism, Structural Homology, Protein, Thiolester Hydrolases chemistry, Thiolester Hydrolases genetics, Thiolester Hydrolases metabolism, Toxoplasma genetics, Toxoplasmosis drug therapy, Toxoplasmosis enzymology, Toxoplasmosis genetics, Enzyme Inhibitors pharmacology, Lactones pharmacology, Protozoan Proteins antagonists & inhibitors, Thiolester Hydrolases antagonists & inhibitors, Toxoplasma enzymology

Abstract

In eukaryotic organisms, cysteine palmitoylation is an important reversible modification that impacts protein targeting, folding, stability, and interactions with partners. Evidence suggests that protein palmitoylation contributes to key biological processes in Apicomplexa with the recent palmitome of the malaria parasite Plasmodium falciparum reporting over 400 substrates that are modified with palmitate by a broad range of protein S-acyl transferases. Dynamic palmitoylation cycles require the action of an acyl-protein thioesterase (APT) that cleaves palmitate from substrates and conveys reversibility to this posttranslational modification. In this work, we identified candidates for APT activity in Toxoplasma gondii. Treatment of parasites with low micromolar concentrations of β-lactone- or triazole urea-based inhibitors that target human APT1 showed varied detrimental effects at multiple steps of the parasite lytic cycle. The use of an activity-based probe in combination with these inhibitors revealed the existence of several serine hydrolases that are targeted by APT1 inhibitors. The active serine hydrolase, TgASH1, identified as the homologue closest to human APT1 and APT2, was characterized further. Biochemical analysis of TgASH1 indicated that this enzyme cleaves substrates with a specificity similar to APTs, and homology modeling points toward an APT-like enzyme. TgASH1 is dispensable for parasite survival, which indicates that the severe effects observed with the β-lactone inhibitors are caused by the inhibition of non-TgASH1 targets. Other ASH candidates for APT activity were functionally characterized, and one of them was found to be resistant to gene disruption due to the potential essential nature of the protein.

Published

2013

37. Spatial association with PTEX complexes defines regions for effector export into Plasmodium falciparum-infected erythrocytes.

Author

Riglar DT, Rogers KL, Hanssen E, Turnbull L, Bullen HE, Charnaud SC, Przyborski J, Gilson PR, Whitchurch CB, Crabb BS, Baum J, and Cowman AF

Subjects

Animals, Cluster Analysis, Erythrocytes metabolism, Erythrocytes pathology, Erythrocytes ultrastructure, Green Fluorescent Proteins metabolism, Humans, Intracellular Membranes metabolism, Intracellular Membranes ultrastructure, Merozoites cytology, Merozoites metabolism, Merozoites ultrastructure, Models, Biological, Parasites cytology, Parasites metabolism, Parasites ultrastructure, Plasmodium falciparum cytology, Plasmodium falciparum ultrastructure, Protein Structure, Tertiary, Protein Transport, Protein Unfolding, Protozoan Proteins chemistry, Recombinant Fusion Proteins metabolism, Time Factors, Vacuoles metabolism, Vacuoles ultrastructure, Erythrocytes parasitology, Malaria, Falciparum metabolism, Malaria, Falciparum parasitology, Plasmodium falciparum metabolism, Protozoan Proteins metabolism

Abstract

Export of proteins into the infected erythrocyte is critical for malaria parasite survival. The majority of effector proteins are thought to export via a proteinaceous translocon, resident in the parasitophorous vacuole membrane surrounding the parasite. Identification of the Plasmodium translocon of exported proteins and its biochemical association with exported proteins suggests it performs this role. Direct evidence for this, however, is lacking. Here using viable purified Plasmodium falciparum merozoites and three-dimensional structured illumination microscopy, we investigate remodelling events immediately following parasite invasion. We show that multiple complexes of the Plasmodium translocon of exported proteins localize together in foci that dynamically change in clustering behaviour. Furthermore, we provide conclusive evidence of spatial association between exported proteins and exported protein 2, a core component of the Plasmodium translocon of exported proteins, during native conditions and upon generation of translocation intermediates. These data provide the most direct cellular evidence to date that protein export occurs at regions of the parasitophorous vacuole membrane housing the Plasmodium translocon of exported proteins complex.

Published

2013

38. Recent insights into the export of PEXEL/HTS-motif containing proteins in Plasmodium parasites.

Author

Bullen HE, Crabb BS, and Gilson PR

Subjects

Cell Membrane metabolism, Erythrocytes parasitology, Intracellular Membranes metabolism, Protein Transport, Amino Acid Motifs, Plasmodium metabolism, Protozoan Proteins metabolism

Abstract

Protein export in intra-erythrocytic Plasmodium parasites is of considerable interest in the malaria field because the process is inextricably linked to virulence and survival mechanisms in the human host. Despite many and varied functions, a common link between many exported proteins is their actual mode of export. Most exported proteins must traverse two membranes to their destination in the infected erythrocyte cytosol, the parasite plasma membrane and surrounding parasitophorous vacuole membrane (PVM). In recent years, several studies have shone light on the common molecular mechanism by which the major class of exported proteins, the so-called PEXEL/HTS motif-containing proteins, are translocated across these membranes. Roles for parasite-specific molecular processes in two distinct sites, the endoplasmic reticulum and the PVM have been revealed., (Copyright © 2012 Elsevier Ltd. All rights reserved.)

Published

2012

39. Biosynthesis, localization, and macromolecular arrangement of the Plasmodium falciparum translocon of exported proteins (PTEX).

Author

Bullen HE, Charnaud SC, Kalanon M, Riglar DT, Dekiwadia C, Kangwanrangsan N, Torii M, Tsuboi T, Baum J, Ralph SA, Cowman AF, de Koning-Ward TF, Crabb BS, and Gilson PR

Subjects

Humans, Membrane Proteins genetics, Multiprotein Complexes genetics, Plasmodium falciparum genetics, Protein Transport physiology, Protozoan Proteins genetics, Schizonts metabolism, Vacuoles genetics, Intracellular Membranes metabolism, Membrane Proteins biosynthesis, Multiprotein Complexes biosynthesis, Plasmodium falciparum metabolism, Protozoan Proteins biosynthesis, Vacuoles metabolism

Abstract

To survive within its host erythrocyte, Plasmodium falciparum must export hundreds of proteins across both its parasite plasma membrane and surrounding parasitophorous vacuole membrane, most of which are likely to use a protein complex known as PTEX (Plasmodium translocon of exported proteins). PTEX is a putative protein trafficking machinery responsible for the export of hundreds of proteins across the parasitophorous vacuole membrane and into the human host cell. Five proteins are known to comprise the PTEX complex, and in this study, three of the major stoichiometric components are investigated including HSP101 (a AAA(+) ATPase), a protein of no known function termed PTEX150, and the apparent membrane component EXP2. We show that these proteins are synthesized in the preceding schizont stage (PTEX150 and HSP101) or even earlier in the life cycle (EXP2), and before invasion these components reside within the dense granules of invasive merozoites. From these apical organelles, the protein complex is released into the host cell where it resides with little turnover in the parasitophorous vacuole membrane for most of the remainder of the following cell cycle. At this membrane, PTEX is arranged in a stable macromolecular complex of >1230 kDa that includes an ∼600-kDa apparently homo-oligomeric complex of EXP2 that can be separated from the remainder of the PTEX complex using non-ionic detergents. Two different biochemical methods undertaken here suggest that PTEX components associate as EXP2-PTEX150-HSP101, with EXP2 associating with the vacuolar membrane. Collectively, these data support the hypothesis that EXP2 oligomerizes and potentially forms the putative membrane-spanning pore to which the remainder of the PTEX complex is attached.

Published

2012

40. A novel family of Apicomplexan glideosome-associated proteins with an inner membrane-anchoring role.

Author

Bullen HE, Tonkin CJ, O'Donnell RA, Tham WH, Papenfuss AT, Gould S, Cowman AF, Crabb BS, and Gilson PR

Subjects

Amino Acid Sequence, Animals, Cytoplasm metabolism, Cytoskeleton metabolism, Models, Biological, Molecular Sequence Data, Movement, Myosins metabolism, Phylogeny, Plasmodium falciparum metabolism, Protein Structure, Tertiary, Sequence Homology, Amino Acid, Toxoplasma metabolism, Apicomplexa metabolism, Cell Membrane metabolism

Abstract

The phylum Apicomplexa are a group of obligate intracellular parasites responsible for a wide range of important diseases. Central to the lifecycle of these unicellular parasites is their ability to migrate through animal tissue and invade target host cells. Apicomplexan movement is generated by a unique system of gliding motility in which substrate adhesins and invasion-related proteins are pulled across the plasma membrane by an underlying actin-myosin motor. The myosins of this motor are inserted into a dual membrane layer called the inner membrane complex (IMC) that is sandwiched between the plasma membrane and an underlying cytoskeletal basket. Central to our understanding of gliding motility is the characterization of proteins residing within the IMC, but to date only a few proteins are known. We report here a novel family of six-pass transmembrane proteins, termed the GAPM family, which are highly conserved and specific to Apicomplexa. In Plasmodium falciparum and Toxoplasma gondii the GAPMs localize to the IMC where they form highly SDS-resistant oligomeric complexes. The GAPMs co-purify with the cytoskeletal alveolin proteins and also to some degree with the actin-myosin motor itself. Hence, these proteins are strong candidates for an IMC-anchoring role, either directly or indirectly tethering the motor to the cytoskeleton.

Published

2009