Your search keyword '"Trybus KM"' showing total 6 results

1. Mechanism of small molecule inhibition of Plasmodium falciparum myosin A informs antimalarial drug design.

Author

Moussaoui D, Robblee JP, Robert-Paganin J, Auguin D, Fisher F, Fagnant PM, Macfarlane JE, Schaletzky J, Wehri E, Mueller-Dieckmann C, Baum J, Trybus KM, and Houdusse A

Subjects

Plasmodium falciparum, Actins, Biological Assay, Antimalarials, Nonmuscle Myosin Type IIA, Folic Acid Antagonists

Abstract

Malaria results in more than 500,000 deaths per year and the causative Plasmodium parasites continue to develop resistance to all known agents, including different antimalarial combinations. The class XIV myosin motor PfMyoA is part of a core macromolecular complex called the glideosome, essential for Plasmodium parasite mobility and therefore an attractive drug target. Here, we characterize the interaction of a small molecule (KNX-002) with PfMyoA. KNX-002 inhibits PfMyoA ATPase activity in vitro and blocks asexual blood stage growth of merozoites, one of three motile Plasmodium life-cycle stages. Combining biochemical assays and X-ray crystallography, we demonstrate that KNX-002 inhibits PfMyoA using a previously undescribed binding mode, sequestering it in a post-rigor state detached from actin. KNX-002 binding prevents efficient ATP hydrolysis and priming of the lever arm, thus inhibiting motor activity. This small-molecule inhibitor of PfMyoA paves the way for the development of alternative antimalarial treatments., (© 2023. The Author(s).)

Published

2023

2. The actomyosin interface contains an evolutionary conserved core and an ancillary interface involved in specificity.

Author

Robert-Paganin J, Xu XP, Swift MF, Auguin D, Robblee JP, Lu H, Fagnant PM, Krementsova EB, Trybus KM, Houdusse A, Volkmann N, and Hanein D

Subjects

Actins metabolism, Cryoelectron Microscopy, Malaria, Falciparum parasitology, Myosins metabolism, Protein Conformation, Protozoan Proteins metabolism, Actin Cytoskeleton metabolism, Actomyosin metabolism, Cell Movement physiology, Plasmodium falciparum physiology, Plasmodium falciparum ultrastructure

Abstract

Plasmodium falciparum, the causative agent of malaria, moves by an atypical process called gliding motility. Actomyosin interactions are central to gliding motility. However, the details of these interactions remained elusive until now. Here, we report an atomic structure of the divergent Plasmodium falciparum actomyosin system determined by electron cryomicroscopy at the end of the powerstroke (Rigor state). The structure provides insights into the detailed interactions that are required for the parasite to produce the force and motion required for infectivity. Remarkably, the footprint of the myosin motor on filamentous actin is conserved with respect to higher eukaryotes, despite important variability in the Plasmodium falciparum myosin and actin elements that make up the interface. Comparison with other actomyosin complexes reveals a conserved core interface common to all actomyosin complexes, with an ancillary interface involved in defining the spatial positioning of the motor on actin filaments.

Published

2021

3. Plasmodium myosin A drives parasite invasion by an atypical force generating mechanism.

Author

Robert-Paganin J, Robblee JP, Auguin D, Blake TCA, Bookwalter CS, Krementsova EB, Moussaoui D, Previs MJ, Jousset G, Baum J, Trybus KM, and Houdusse A

Subjects

Cell Movement, Crystallography, X-Ray, Erythrocytes parasitology, Nonmuscle Myosin Type IIA chemistry, Nonmuscle Myosin Type IIA metabolism, Phosphorylation, Protozoan Proteins chemistry, Protozoan Proteins metabolism, Nonmuscle Myosin Type IIA physiology, Plasmodium falciparum pathogenicity, Protozoan Proteins physiology

Abstract

Plasmodium parasites are obligate intracellular protozoa and causative agents of malaria, responsible for half a million deaths each year. The lifecycle progression of the parasite is reliant on cell motility, a process driven by myosin A, an unconventional single-headed class XIV molecular motor. Here we demonstrate that myosin A from Plasmodium falciparum (PfMyoA) is critical for red blood cell invasion. Further, using a combination of X-ray crystallography, kinetics, and in vitro motility assays, we elucidate the non-canonical interactions that drive this motor's function. We show that PfMyoA motor properties are tuned by heavy chain phosphorylation (Ser19), with unphosphorylated PfMyoA exhibiting enhanced ensemble force generation at the expense of speed. Regulated phosphorylation may therefore optimize PfMyoA for enhanced force generation during parasite invasion or for fast motility during dissemination. The three PfMyoA crystallographic structures presented here provide a blueprint for discovery of specific inhibitors designed to prevent parasite infection.

Published

2019

4. Mechanoregulated inhibition of formin facilitates contractile actomyosin ring assembly.

Author

Zimmermann D, Homa KE, Hocky GM, Pollard LW, De La Cruz EM, Voth GA, Trybus KM, and Kovar DR

Subjects

Actin Cytoskeleton, Actomyosin genetics, Cytoskeletal Proteins genetics, Fetal Proteins genetics, Fetal Proteins metabolism, Formins, Microfilament Proteins genetics, Microfilament Proteins metabolism, Microscopy, Fluorescence methods, Myosin Heavy Chains genetics, Myosin Heavy Chains metabolism, Myosin Type II genetics, Myosin Type II metabolism, Nuclear Proteins genetics, Nuclear Proteins metabolism, Schizosaccharomyces cytology, Schizosaccharomyces pombe Proteins genetics, Actomyosin metabolism, Cytoskeletal Proteins metabolism, Schizosaccharomyces metabolism, Schizosaccharomyces pombe Proteins metabolism

Abstract

Cytokinesis physically separates dividing cells by forming a contractile actomyosin ring. The fission yeast contractile ring has been proposed to assemble by Search-Capture-Pull-Release from cytokinesis precursor nodes that include the molecular motor type-II myosin Myo2 and the actin assembly factor formin Cdc12. By successfully reconstituting Search-Capture-Pull in vitro, we discovered that formin Cdc12 is a mechanosensor, whereby myosin pulling on formin-bound actin filaments inhibits Cdc12-mediated actin assembly. We mapped Cdc12 mechanoregulation to its formin homology 1 domain, which facilitates delivery of new actin subunits to the elongating actin filament. Quantitative modeling suggests that the pulling force of the myosin propagates through the actin filament, which behaves as an entropic spring, and thereby may stretch the disordered formin homology 1 domain and impede formin-mediated actin filament elongation. Finally, live cell imaging of mechano-insensitive formin mutant cells established that mechanoregulation of formin Cdc12 is required for efficient contractile ring assembly in vivo.The fission yeast cytokinetic ring assembles by Search-Capture-Pull-Release from precursor nodes that include formin Cdc12 and myosin Myo2. The authors reconstitute Search-Capture-Pull in vitro and find that Myo2 pulling on Cdc12-associated actin filaments mechano-inhibits Cdc12-mediated assembly, which enables proper ring assembly in vivo.

Published

2017

5. Myosin Va molecular motors manoeuvre liposome cargo through suspended actin filament intersections in vitro.

Author

Lombardo AT, Nelson SR, Ali MY, Kennedy GG, Trybus KM, Walcott S, and Warshaw DM

Subjects

Actins chemistry, Biological Transport, Calibration, Cytoskeleton metabolism, Diffusion, Imaging, Three-Dimensional, Kinesins chemistry, Lasers, Microscopy, Fluorescence, Models, Biological, Protein Binding, Actin Cytoskeleton chemistry, Liposomes chemistry, Myosin Heavy Chains chemistry

Abstract

Intracellular cargo transport relies on myosin Va molecular motor ensembles to travel along the cell's three-dimensional (3D) highway of actin filaments. At actin filament intersections, the intersecting filament is a structural barrier to and an alternate track for directed cargo transport. Here we use 3D super-resolution fluorescence imaging to determine the directional outcome (that is, continues straight, turns or terminates) for an ∼10 motor ensemble transporting a 350 nm lipid-bound cargo that encounters a suspended 3D actin filament intersection in vitro. Motor-cargo complexes that interact with the intersecting filament go straight through the intersection 62% of the time, nearly twice that for turning. To explain this, we develop an in silico model, supported by optical trapping data, suggesting that the motors' diffusive movements on the vesicle surface and the extent of their engagement with the two intersecting actin tracks biases the motor-cargo complex on average to go straight through the intersection.

Published

2017

6. Single-molecule reconstitution of mRNA transport by a class V myosin.

Author

Sladewski TE, Bookwalter CS, Hong MS, and Trybus KM

Subjects

Microscopy, Electron, Transmission, Microscopy, Fluorescence, Models, Molecular, Myosin Heavy Chains genetics, Myosin Heavy Chains metabolism, Myosin Type V genetics, Myosin Type V metabolism, RNA, Messenger metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism, Molecular Motor Proteins physiology, RNA Transport physiology, RNA, Messenger physiology, Ribonucleoproteins metabolism, Saccharomyces cerevisiae physiology

Abstract

Molecular motors are instrumental in mRNA localization, which provides spatial and temporal control of protein expression and function. To obtain mechanistic insight into how a class V myosin transports mRNA, we performed single-molecule in vitro assays on messenger ribonucleoprotein (mRNP) complexes reconstituted from purified proteins and a localizing mRNA found in budding yeast. mRNA is required to form a stable, processive transport complex on actin--an elegant mechanism to ensure that only cargo-bound motors are motile. Increasing the number of localizing elements ('zip codes') on the mRNA, or configuring the track to resemble actin cables, enhanced run length and event frequency. In multi-zip-code mRNPs, motor separation distance varied during a run, thus showing the dynamic nature of the transport complex. Building the complexity of single-molecule in vitro assays is necessary to understand how these complexes function within cells.

Published

2013