C-Mannosylation of Toxoplasma gondii proteins promotes attachment to host cells and parasite virulence

C-Mannosylation is a common modification of thrombospondin type 1 repeats present in metazoans and recently identified also in apicomplexan parasites. This glycosylation is mediated by enzymes of the DPY19 family that transfer α-mannoses to tryptophan residues in the sequence WX2WX2C, which is part of the structurally essential tryptophan ladder. Here, deletion of the dpy19 gene in the parasite Toxoplasma gondii abolished C-mannosyltransferase activity and reduced levels of the micronemal protein MIC2. The loss of C-mannosyltransferase activity was associated with weakened parasite adhesion to host cells and with reduced parasite motility, host cell invasion, and parasite egress. Interestingly, the C-mannosyltransferase–deficient Δdpy19 parasites were strongly attenuated in virulence and induced protective immunity in mice. This parasite attenuation could not simply be explained by the decreased MIC2 level and strongly suggests that absence of C-mannosyltransferase activity leads to an insufficient level of additional proteins. In summary, our results indicate that T. gondii C-mannosyltransferase DPY19 is not essential for parasite survival, but is important for adhesion, motility, and virulence.

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Protein O- and C-Glycosylation pathways in Toxoplasma gondii and Plasmodium falciparum

Parasitology ◽

10.1017/s0031182019000040 ◽

2019 ◽

Vol 146 (14) ◽

pp. 1755-1766 ◽

Cited By ~ 5

Author(s):

Giulia Bandini ◽

Andreia Albuquerque-Wendt ◽

Jan Hegermann ◽

John Samuelson ◽

Françoise H. Routier

Keyword(s):

Plasmodium Falciparum ◽

Toxoplasma Gondii ◽

Protein Glycosylation ◽

Specific Gene ◽

Post Translational Modifications ◽

Apicomplexan Parasites ◽

Causative Agents ◽

Thrombospondin Type 1 Repeats ◽

Great Public Health

AbstractApicomplexan parasites are amongst the most prevalent and morbidity-causing pathogens worldwide. They are responsible for severe diseases in humans and livestock and are thus of great public health and economic importance. Until the sequencing of apicomplexan genomes at the beginning of this century, the occurrence of N- and O-glycoproteins in these parasites was much debated. The synthesis of rudimentary and divergent N-glycans due to lineage-specific gene loss is now well established and has been recently reviewed. Here, we will focus on recent studies that clarified classical O-glycosylation pathways and described new nucleocytosolic glycosylations in Toxoplasma gondii, the causative agents of toxoplasmosis. We will also review the glycosylation of proteins containing thrombospondin type 1 repeats by O-fucosylation and C-mannosylation, newly discovered in Toxoplasma and the malaria parasite Plasmodium falciparum. The functional significance of these post-translational modifications has only started to emerge, but the evidence points towards roles for these protein glycosylation pathways in tissue cyst wall rigidity and persistence in the host, oxygen sensing, and stability of proteins involved in host invasion.

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Exit from Host Cells by the Pathogenic Parasite Toxoplasma gondii Does Not Require Motility

Eukaryotic Cell ◽

10.1128/ec.00301-07 ◽

2007 ◽

Vol 7 (1) ◽

pp. 131-140 ◽

Cited By ~ 33

Author(s):

Mark D. Lavine ◽

Gustavo Arrizabalaga

Keyword(s):

Toxoplasma Gondii ◽

Host Cell ◽

Host Cells ◽

Membrane Tension ◽

Experimental Induction ◽

Intracellular Parasites ◽

Artificial Induction ◽

Host Membrane ◽

Parasite Motility ◽

Parasite Egress

ABSTRACTThe process by which the intracellular parasiteToxoplasma gondiiexits its host cell is central to its propagation and pathogenesis. Experimental induction of motility in intracellular parasites results in parasite egress, leading to the hypothesis that egress depends on the parasite's actin-dependent motility. Using a novel assay to monitor egress without experimental induction, we have established that inhibiting parasite motility does not block this process, although treatment with actin-disrupting drugs does delay egress. However, using an irreversible actin inhibitor, we show that this delay is due to the disruption of host cell actin alone, apparently resulting from the consequent loss of membrane tension. Accordingly, by manipulating osmotic pressure, we show that parasite egress is delayed by releasing membrane tension and promoted by increasing it. Therefore, without artificial induction, egress does not depend on parasite motility and can proceed by mechanical rupture of the host membrane.

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Identification of the membrane receptor of a class XIV myosin in Toxoplasma gondii

The Journal of Cell Biology ◽

10.1083/jcb.200311137 ◽

2004 ◽

Vol 165 (3) ◽

pp. 383-393 ◽

Cited By ~ 185

Author(s):

Elizabeth Gaskins ◽

Stacey Gilk ◽

Nicolette DeVore ◽

Tara Mann ◽

Gary Ward ◽

...

Keyword(s):

Toxoplasma Gondii ◽

Protein Complex ◽

Integral Membrane Protein ◽

Gliding Motility ◽

Host Cells ◽

Inner Membrane ◽

Apicomplexan Parasites ◽

Membrane Complex ◽

Inner Membrane Complex ◽

Two Stages

Apicomplexan parasites exhibit a unique form of substrate-dependent motility, gliding motility, which is essential during their invasion of host cells and during their spread between host cells. This process is dependent on actin filaments and myosin that are both located between the plasma membrane and two underlying membranes of the inner membrane complex. We have identified a protein complex in the apicomplexan parasite Toxoplasma gondii that contains the class XIV myosin required for gliding motility, TgMyoA, its associated light chain, TgMLC1, and two novel proteins, TgGAP45 and TgGAP50. We have localized this complex to the inner membrane complex of Toxoplasma, where it is anchored in the membrane by TgGAP50, an integral membrane glycoprotein. Assembly of the protein complex is spatially controlled and occurs in two stages. These results provide the first molecular description of an integral membrane protein as a specific receptor for a myosin motor, and further our understanding of the motile apparatus underlying gliding motility in apicomplexan parasites.

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Two Essential Light Chains Regulate the MyoA Lever Arm To Promote Toxoplasma Gliding Motility

mBio ◽

10.1128/mbio.00845-15 ◽

2015 ◽

Vol 6 (5) ◽

Cited By ~ 29

Author(s):

Melanie J. Williams ◽

Hernan Alonso ◽

Marta Enciso ◽

Saskia Egarter ◽

Lilach Sheiner ◽

...

Keyword(s):

Light Chain ◽

Therapeutic Potential ◽

Point Mutations ◽

Gliding Motility ◽

Host Cells ◽

Light Chains ◽

Apicomplexan Parasites ◽

Essential Light Chain ◽

Lever Arm ◽

Parasite Motility

ABSTRACT Key to the virulence of apicomplexan parasites is their ability to move through tissue and to invade and egress from host cells. Apicomplexan motility requires the activity of the glideosome, a multicomponent molecular motor composed of a type XIV myosin, MyoA. Here we identify a novel glideosome component, essential light chain 2 (ELC2), and functionally characterize the two essential light chains (ELC1 and ELC2) of MyoA in Toxoplasma. We show that these proteins are functionally redundant but are important for invasion, egress, and motility. Molecular simulations of the MyoA lever arm identify a role for Ca2+ in promoting intermolecular contacts between the ELCs and the adjacent MLC1 light chain to stabilize this domain. Using point mutations predicted to ablate either the interaction with Ca2+ or the interface between the two light chains, we demonstrate their contribution to the quality, displacement, and speed of gliding Toxoplasma parasites. Our work therefore delineates the importance of the MyoA lever arm and highlights a mechanism by which this domain could be stabilized in order to promote invasion, egress, and gliding motility in apicomplexan parasites. IMPORTANCE Tissue dissemination and host cell invasion by apicomplexan parasites such as Toxoplasma are pivotal to their pathogenesis. Central to these processes is gliding motility, which is driven by an actomyosin motor, the MyoA glideosome. Others have demonstrated the importance of the MyoA glideosome for parasite motility and virulence in mice. Disruption of its function may therefore have therapeutic potential, and yet a deeper mechanistic understanding of how it works is required. Ca2+-dependent and -independent phosphorylation and the direct binding of Ca2+ to the essential light chain have been implicated in the regulation of MyoA activity. Here we identify a second essential light chain of MyoA and demonstrate the importance of both to Toxoplasma motility. We also investigate the role of Ca2+ and the MyoA regulatory site in parasite motility and identify a potential mechanism whereby binding of a divalent cation to the essential light chains could stabilize the myosin to allow productive movement.

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Recombinant feline herpesvirus type 1 expressing Toxoplasma gondii ROP2 antigen inducible protective immunity in cats

Parasitology Research ◽

10.1007/s004360100429 ◽

2002 ◽

Vol 88 (2) ◽

pp. 144-149 ◽

Cited By ~ 37

Author(s):

Masayuki Mishima ◽

Xuenan Xuan ◽

Naoaki Yokoyama ◽

Ikuo Igarashi ◽

Kozo Fujisaki ◽

...

Keyword(s):

Toxoplasma Gondii ◽

Protective Immunity ◽

Herpesvirus Type ◽

Feline Herpesvirus ◽

Feline Herpesvirus Type 1

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A Toxoplasma gondii Ortholog of Plasmodium GAMA Contributes to Parasite Attachment and Cell Invasion

mSphere ◽

10.1128/msphere.00012-16 ◽

2016 ◽

Vol 1 (1) ◽

Cited By ~ 10

Author(s):

My-Hang Huynh ◽

Vern B. Carruthers

Keyword(s):

Toxoplasma Gondii ◽

Host Cell ◽

Cell Invasion ◽

Genetic Evidence ◽

Specific Role ◽

Host Cells ◽

Human Pathogen ◽

Content Type ◽

Apicomplexan Parasites ◽

Adhesive Proteins

ABSTRACT Toxoplasma gondii is a successful human pathogen in the same phylum as malaria-causing Plasmodium parasites. Invasion of a host cell is an essential process that begins with secretion of adhesive proteins onto the parasite surface for attachment and subsequent penetration of the host cell. Conserved invasion proteins likely play roles that were maintained through the divergence of these parasites. Here, we identify a new conserved invasion protein called glycosylphosphatidylinositol-anchored micronemal antigen (GAMA). Tachyzoites lacking TgGAMA were partially impaired in parasite attachment and invasion of host cells, yielding the first genetic evidence of a specific role in parasite entry into host cells. These findings widen our appreciation of the repertoire of conserved proteins that apicomplexan parasites employ for cell invasion. Toxoplasma gondii and its Plasmodium kin share a well-conserved invasion process, including sequential secretion of adhesive molecules for host cell attachment and invasion. However, only a few orthologs have been shown to be important for efficient invasion by both genera. Bioinformatic screening to uncover potential new players in invasion identified a previously unrecognized T. gondii ortholog of Plasmodium glycosylphosphatidylinositol-anchored micronemal antigen (TgGAMA). We show that TgGAMA localizes to the micronemes and is processed into several proteolytic products within the parasite prior to secretion onto the parasite surface during invasion. TgGAMA from parasite lysate bound to several different host cell types in vitro, suggesting a role in parasite attachment. Consistent with this function, tetracycline-regulatable TgGAMA and TgGAMA knockout strains showed significant reductions in host cell invasion at the attachment step, with no defects in any of the other stages of the parasite lytic cycle. Together, the results of this work reveal a new conserved component of the adhesive repertoire of apicomplexan parasites. IMPORTANCE Toxoplasma gondii is a successful human pathogen in the same phylum as malaria-causing Plasmodium parasites. Invasion of a host cell is an essential process that begins with secretion of adhesive proteins onto the parasite surface for attachment and subsequent penetration of the host cell. Conserved invasion proteins likely play roles that were maintained through the divergence of these parasites. Here, we identify a new conserved invasion protein called glycosylphosphatidylinositol-anchored micronemal antigen (GAMA). Tachyzoites lacking TgGAMA were partially impaired in parasite attachment and invasion of host cells, yielding the first genetic evidence of a specific role in parasite entry into host cells. These findings widen our appreciation of the repertoire of conserved proteins that apicomplexan parasites employ for cell invasion.

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Not a Simple Tether: Binding of Toxoplasma gondii AMA1 to RON2 during Invasion Protects AMA1 from Rhomboid-Mediated Cleavage and Leads to Dephosphorylation of Its Cytosolic Tail

mBio ◽

10.1128/mbio.00754-16 ◽

2016 ◽

Vol 7 (5) ◽

Cited By ~ 13

Author(s):

Shruthi Krishnamurthy ◽

Bin Deng ◽

Roxana del Rio ◽

Kerry R. Buchholz ◽

Moritz Treeck ◽

...

Keyword(s):

Toxoplasma Gondii ◽

Host Cell ◽

Cell Invasion ◽

Transmembrane Domain ◽

Critical Role ◽

Host Cells ◽

Receptor Protein ◽

Host Cell Invasion ◽

Cell Binding ◽

Apicomplexan Parasites

ABSTRACT Apical membrane antigen 1 (AMA1) is a receptor protein on the surface of Toxoplasma gondii that plays a critical role in host cell invasion. The ligand to which T . gondii AMA1 (TgAMA1) binds, TgRON2, is secreted into the host cell membrane by the parasite during the early stages of invasion. The TgAMA1-TgRON2 complex forms the core of the “moving junction,” a ring-shaped zone of tight contact between the parasite and host cell membranes, through which the parasite pushes itself during invasion. Paradoxically, the parasite also expresses rhomboid proteases that constitutively cleave the TgAMA1 transmembrane domain. How can TgAMA1 function effectively in host cell binding if its extracellular domain is constantly shed from the parasite surface? We show here that when TgAMA1 binds the domain 3 (D3) peptide of TgRON2, its susceptibility to cleavage by rhomboid protease(s) is greatly reduced. This likely serves to maintain parasite-host cell binding at the moving junction, a hypothesis supported by data showing that parasites expressing a hypercleavable version of TgAMA1 invade less efficiently than wild-type parasites do. Treatment of parasites with the D3 peptide was also found to reduce phosphorylation of S527 on the cytoplasmic tail of TgAMA1, and parasites expressing a phosphomimetic S527D allele of TgAMA1 showed an invasion defect. Taken together, these data suggest that TgAMA1-TgRON2 interaction at the moving junction protects TgAMA1 molecules that are actively engaged in host cell penetration from rhomboid-mediated cleavage and generates an outside-in signal that leads to dephosphorylation of the TgAMA1 cytosolic tail. Both of these effects are required for maximally efficient host cell invasion. IMPORTANCE Nearly one-third of the world’s population is infected with the protozoan parasite Toxoplasma gondii , which causes life-threatening disease in neonates and immunocompromised individuals. T. gondii is a member of the phylum Apicomplexa, which includes many other parasites of veterinary and medical importance, such as those that cause coccidiosis, babesiosis, and malaria. Apicomplexan parasites grow within their hosts through repeated cycles of host cell invasion, parasite replication, and host cell lysis. Parasites that cannot invade host cells cannot survive or cause disease. AMA1 is a highly conserved protein on the surface of apicomplexan parasites that is known to be important for invasion, and the work presented here reveals new and unexpected insights into AMA1 function. A more complete understanding of the role of AMA1 in invasion may ultimately contribute to the development of new chemotherapeutics designed to disrupt AMA1 function and invasion-related signaling in this important group of human pathogens.

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Blocking Palmitoylation of Toxoplasma gondii Myosin Light Chain 1 Disrupts Glideosome Composition but Has Little Impact on Parasite Motility

mSphere ◽

10.1128/msphere.00823-20 ◽

2021 ◽

Vol 6 (3) ◽

Author(s):

Pramod K. Rompikuntal ◽

Robyn S. Kent ◽

Ian T. Foe ◽

Bin Deng ◽

Matthew Bogyo ◽

...

Keyword(s):

Toxoplasma Gondii ◽

Current Model ◽

Severe Disease ◽

Gliding Motility ◽

The Body ◽

Content Type ◽

Apicomplexan Parasites ◽

Myosin Motor ◽

Animal Pathogens ◽

Parasite Motility

ABSTRACT Toxoplasma gondii is a widespread apicomplexan parasite that causes severe disease in immunocompromised individuals and the developing fetus. Like other apicomplexans, T. gondii uses an unusual form of substrate-dependent gliding motility to invade cells of its hosts and to disseminate throughout the body during infection. It is well established that a myosin motor consisting of a class XIVa heavy chain (TgMyoA) and two light chains (TgMLC1 and TgELC1/2) plays an important role in parasite motility. The ability of the motor to generate force at the parasite periphery is thought to be reliant upon its anchoring and immobilization within a peripheral membrane-bound compartment, the inner membrane complex (IMC). The motor does not insert into the IMC directly; rather, this interaction is believed to be mediated by the binding of TgMLC1 to the IMC-anchored protein, TgGAP45. Therefore, the binding of TgMLC1 to TgGAP45 is considered a key element in the force transduction machinery of the parasite. TgMLC1 is palmitoylated, and we show here that palmitoylation occurs on two N-terminal cysteine residues, C8 and C11. Mutations that block TgMLC1 palmitoylation completely abrogate the binding of TgMLC1 to TgGAP45. Surprisingly, the loss of TgMLC1 binding to TgGAP45 in these mutant parasites has little effect on their ability to initiate or sustain movement. These results question a key tenet of the current model of apicomplexan motility and suggest that our understanding of gliding motility in this important group of human and animal pathogens is not yet complete. IMPORTANCE Gliding motility plays a central role in the life cycle of T. gondii and other apicomplexan parasites. The myosin motor thought to power motility is essential for virulence but distinctly different from the myosins found in humans. Consequently, an understanding of the mechanism(s) underlying parasite motility and the role played by this unusual myosin may reveal points of vulnerability that can be targeted for disease prevention or treatment. We show here that mutations that uncouple the motor from what is thought to be a key structural component of the motility machinery have little impact on parasite motility. This finding runs counter to predictions of the current, widely held “linear motor” model of motility, highlighting the need for further studies to fully understand how apicomplexan parasites generate the forces necessary to move into, out of, and between cells of the hosts they infect.

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Loss of a conserved MAPK causes catastrophic failure in assembly of a specialized cilium-like structure in Toxoplasma gondii

10.1101/2020.02.02.931022 ◽

2020 ◽

Cited By ~ 2

Author(s):

William J. O’Shaughnessy ◽

Xiaoyu Hu ◽

Tsebaot Beraki ◽

Matthew McDougal ◽

Michael L. Reese

Keyword(s):

Toxoplasma Gondii ◽

Primary Cilia ◽

Host Cells ◽

Catastrophic Failure ◽

Severe Phenotype ◽

New Host ◽

Apicomplexan Parasites ◽

Cellular Processes

AbstractPrimary cilia are important organizing centers that control diverse cellular processes. Apicomplexan parasites like Toxoplasma gondii have a specialized cilium-like structure called the conoid that organizes the secretory and invasion machinery critical for the parasites’ lifestyle. The proteins that initiate the biogenesis of this structure are largely unknown. We identified the Toxoplasma ortholog of the conserved kinase ERK7 as essential to conoid assembly. Parasites in which ERK7 has been depleted lose their conoids late during maturation and are immotile and thus unable to invade new host cells. This is the most severe phenotype to conoid biogenesis yet reported, and is made more striking by the fact that ERK7 is not a conoid protein, as it localizes just basal to the structure. ERK7 has been recently implicated in ciliogenesis in metazoan cells, and our data suggest that this kinase has an ancient and central role in regulating ciliogenesis throughout Eukaryota.

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Systematic Analysis of Clemastine, a Candidate Apicomplexan Parasite-Selective Tubulin-Targeting Agent

International Journal of Molecular Sciences ◽

10.3390/ijms23010068 ◽

2021 ◽

Vol 23 (1) ◽

pp. 68

Author(s):

Izra Abbaali ◽

Danny A. Truong ◽

Shania D. Day ◽

Nancy Haro-Ramirez ◽

Naomi S. Morrissette

Keyword(s):

Toxoplasma Gondii ◽

Host Cells ◽

Proof Of Concept ◽

Systematic Analysis ◽

Apicomplexan Parasites ◽

Microtubule Disruption ◽

Antiparasitic Drugs ◽

General Response ◽

Babesia Spp

Apicomplexan parasites, such as Toxoplasma gondii, Plasmodium spp., Babesia spp., and Cryptosporidium spp., cause significant morbidity and mortality. Existing treatments are problematic due to toxicity and the emergence of drug-resistant parasites. Because protozoan tubulin can be selectively disrupted by small molecules to inhibit parasite growth, we assembled an in vitro testing cascade to fully delineate effects of candidate tubulin-targeting drugs on Toxoplasma gondii and vertebrate host cells. Using this analysis, we evaluated clemastine, an antihistamine that has been previously shown to inhibit Plasmodium growth by competitively binding to the CCT/TRiC tubulin chaperone as a proof-of-concept. We concurrently analyzed astemizole, a distinct antihistamine that blocks heme detoxification in Plasmodium. Both drugs have EC50 values of ~2 µM and do not demonstrate cytotoxicity or vertebrate microtubule disruption at this concentration. Parasite subpellicular microtubules are shortened by treatment with either clemastine or astemizole but not after treatment with pyrimethamine, indicating that this effect is not a general response to antiparasitic drugs. Immunoblot quantification indicates that the total α-tubulin concentration of 0.02 pg/tachyzoite does not change with clemastine treatment. In conclusion, the testing cascade allows profiling of small-molecule effects on both parasite and vertebrate cell viability and microtubule integrity.

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