Julia M. Sattler scite author profile

Parasites causing malaria need to migrate in order to penetrate tissue barriers and enter host cells. Here we show that the actin filament-binding protein coronin regulates gliding motility in Plasmodium berghei sporozoites, the highly motile forms of a rodent malaria-causing parasite transmitted by mosquitoes. Parasites lacking coronin show motility defects that impair colonization of the mosquito salivary glands but not migration in the skin, yet result in decreased transmission efficiency. In non-motile sporozoites low calcium concentrations mediate actin-independent coronin localization to the periphery. Engagement of extracellular ligands triggers an intracellular calcium release followed by the actin-dependent relocalization of coronin to the rear and initiation of motility. Mutational analysis and imaging suggest that coronin organizes actin filaments for productive motility. Using coronin-mCherry as a marker for the presence of actin filaments we found that protein kinase A contributes to actin filament disassembly. We finally speculate that calcium and cAMP-mediated signaling regulate a switch from rapid parasite motility to host cell invasion by differentially influencing actin dynamics.

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Inter-subunit interactions drive divergent dynamics in mammalian and Plasmodium actin filaments

Douglas

Nandekar

Aktories

et al. 2018

PLoS Biol

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Cell motility is essential for protozoan and metazoan organisms and typically relies on the dynamic turnover of actin filaments. In metazoans, monomeric actin polymerises into usually long and stable filaments, while some protozoans form only short and highly dynamic actin filaments. These different dynamics are partly due to the different sets of actin regulatory proteins and partly due to the sequence of actin itself. Here we probe the interactions of actin subunits within divergent actin filaments using a comparative dynamic molecular model and explore their functions using Plasmodium, the protozoan causing malaria, and mouse melanoma derived B16-F1 cells as model systems. Parasite actin tagged to a fluorescent protein (FP) did not incorporate into mammalian actin filaments, and rabbit actin-FP did not incorporate into parasite actin filaments. However, exchanging the most divergent region of actin subdomain 3 allowed such reciprocal incorporation. The exchange of a single amino acid residue in subdomain 2 (N41H) of Plasmodium actin markedly improved incorporation into mammalian filaments. In the parasite, modification of most subunit–subunit interaction sites was lethal, whereas changes in actin subdomains 1 and 4 reduced efficient parasite motility and hence mosquito organ penetration. The strong penetration defects could be rescued by overexpression of the actin filament regulator coronin. Through these comparative approaches we identified an essential and common contributor, subdomain 3, which drives the differential dynamic behaviour of two highly divergent eukaryotic actins in motile cells.

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Evolutionarily distant I domains can functionally replace the essential ligand-binding domain of Plasmodium TRAP

Klug

Goellner

Kehrer

et al. 2020

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Inserted (I) domains function as ligand-binding domains in adhesins that support cell adhesion and migration in many eukaryotic phyla. These adhesins include integrin αβ heterodimers in metazoans and single subunit transmembrane proteins in apicomplexans such as TRAP in Plasmodium and MIC2 in Toxoplasma. Here we show that the I domain of TRAP is essential for sporozoite gliding motility, mosquito salivary gland invasion and mouse infection. Its replacement with the I domain from Toxoplasma MIC2 fully restores tissue invasion and parasite transmission, while replacement with the aX I domain from human integrins still partially restores liver infection. Mutations around the ligand binding site allowed salivary gland invasion but led to inefficient transmission to the rodent host. These results suggest that apicomplexan parasites appropriated polyspecific I domains in part for their ability to engage with multiple ligands and to provide traction for emigration into diverse organs in distant phyla.

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Structure and Function of a G-actin Sequestering Protein with a Vital Role in Malaria Oocyst Development inside the Mosquito Vector

Hliscs

Sattler

Tempel

et al. 2010

Journal of Biological Chemistry

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Cyclase-associated proteins (CAPs) are evolutionary conserved G-actin-binding proteins that regulate microfilament turnover. CAPs have a modular structure consisting of an N-terminal adenylate cyclase binding domain, a central proline-rich segment, and a C-terminal actin binding domain. Protozoan parasites of the phylum Apicomplexa, such as Cryptosporidium and the malaria parasite Plasmodium, express small CAP orthologs with homology to the C-terminal actin binding domain (C-CAP). Here, we demonstrate by reverse genetics that C-CAP is dispensable for the pathogenic Plasmodium blood stages. However, c-cap(-) parasites display a complete defect in oocyst development in the insect vector. By trans-species complementation we show that the Cryptosporidium parvum ortholog complements the Plasmodium gene functions. Purified recombinant C. parvum C-CAP protein binds actin monomers and prevents actin polymerization. The crystal structure of C. parvum C-CAP shows two monomers with a right-handed ␤-helical fold intercalated at their C termini to form the putative physiological dimer. Our results reveal a specific vital role for an apicomplexan G-actin-binding protein during sporogony, the parasite replication phase that precedes formation of malaria transmission stages. This study also exemplifies how Plasmodium reverse genetics combined with biochemical and structural analyses of orthologous proteins can offer a fast track toward systematic gene characterization in apicomplexan parasites.Single cell eukaryotes of the phylum of Apicomplexa are obligate intracellular parasites in human and in a wide range of domestic and wild animals. They include pathogens of enormous medical and veterinary importance, such as Plasmodium, the causative agent of malaria, Toxoplasma and Cryptosporidium, two opportunistic and potentially life-threatening infections, and Theileria, which inflicts huge economic losses to cattle herders in the tropics. Toward drug target validation availability of near-complete apicomplexan genomes (1, 2), in combination with experimental genetics in the model rodent malaria parasites Plasmodium berghei and P. yoelii, comprehensive in vivo characterization of parasite genes throughout the complex life cycle in the vertebrate and invertebrate hosts is feasible. However, complementary biochemical and structural analyses are often hindered by difficulties to express and purify the corresponding proteins, partly due to the high genomic A/T content and the abundance of low complexity regions in Plasmodium proteins. Thus, combining the versatile model rodent malaria system with high throughput expression, purification, crystallization, and structural refinement of orthologous proteins from related apicomplexan parasites may offer an attractive path to prioritize targets for anti-infectives development.This approach was taken here to characterize the cyclaseassociated protein (CAP) 5 homology protein of apicomplexan parasites (3). CAPs are ubiquitous regulators of the dynamic turnover of actin cytoskeletal structures...

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Julia M. Sattler

The Actin Filament-Binding Protein Coronin Regulates Motility in Plasmodium Sporozoites

Inter-subunit interactions drive divergent dynamics in mammalian and Plasmodium actin filaments

Evolutionarily distant I domains can functionally replace the essential ligand-binding domain of Plasmodium TRAP

Structure and Function of a G-actin Sequestering Protein with a Vital Role in Malaria Oocyst Development inside the Mosquito Vector

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