Cytoskeletal Motor Research Articles

Pathogens and polymers: Microbe–host interactions illuminate the cytoskeleton

Intracellular pathogens subvert the host cell cytoskeleton to promote their own survival, replication, and dissemination. Study of these microbes has led to many discoveries about host cell biology, including the identification of cytoskeletal proteins, regulatory pathways, and mechanisms of cytoskeletal function. Actin is a common target of bacterial pathogens, but recent work also highlights the use of microtubules, cytoskeletal motors, intermediate filaments, and septins. The study of pathogen interactions with the cytoskeleton has illuminated key cellular processes such as phagocytosis, macropinocytosis, membrane trafficking, motility, autophagy, and signal transduction.

Coiled coils and SAH domains in cytoskeletal molecular motors

Cytoskeletal motors include myosins, kinesins and dyneins. Myosins move along tracks of actin filaments, whereas kinesins and dyneins move along microtubules. Many of these motors are involved in trafficking cargo in cells. However, myosins are mostly monomeric, whereas kinesins are mostly dimeric, owing to the presence of a coiled coil. Some myosins (myosins 6, 7 and 10) contain an SAH (single α-helical) domain, which was originally thought to be a coiled coil. These myosins are now known to be monomers, not dimers. The differences between SAH domains and coiled coils are described and the potential roles of SAH domains in molecular motors are discussed.

The bacterial actin MreB rotates, and rotation depends on cell-wall assembly

Bacterial cells possess multiple cytoskeletal proteins involved in a wide range of cellular processes. These cytoskeletal proteins are dynamic, but the driving forces and cellular functions of these dynamics remain poorly understood. Eukaryotic cytoskeletal dynamics are often driven by motor proteins, but in bacteria no motors that drive cytoskeletal motion have been identified to date. Here, we quantitatively study the dynamics of the Escherichia coli actin homolog MreB, which is essential for the maintenance of rod-like cell shape in bacteria. We find that MreB rotates around the long axis of the cell in a persistent manner. Whereas previous studies have suggested that MreB dynamics are driven by its own polymerization, we show that MreB rotation does not depend on its own polymerization but rather requires the assembly of the peptidoglycan cell wall. The cell-wall synthesis machinery thus either constitutes a novel type of extracellular motor that exerts force on cytoplasmic MreB, or is indirectly required for an as-yet-unidentified motor. Biophysical simulations suggest that one function of MreB rotation is to ensure a uniform distribution of new peptidoglycan insertion sites, a necessary condition to maintain rod shape during growth. These findings both broaden the view of cytoskeletal motors and deepen our understanding of the physical basis of bacterial morphogenesis.

Ferlins: Regulators of Vesicle Fusion for Auditory Neurotransmission, Receptor Trafficking and Membrane Repair

Ferlins are a family of multiple C2 domain proteins with emerging roles in vesicle fusion and membrane trafficking. Ferlin mutations are associated with muscular dystrophy (dysferlin) and deafness (otoferlin) in humans, and infertility in Caenorhabditis elegans (Fer-1) and Drosophila (misfire), demonstrating their importance for normal cellular functioning. Ferlins show ancient origins in eukaryotic evolution and are detected in all eukaryotic kingdoms, including unicellular eukaryotes and apicomplexian protists, suggesting origins in a common ancestor predating eukaryotic evolutionary branching. The characteristic feature of the ferlin family is their multiple tandem cytosolic C2 domains (five to seven C2 domains), the most of any protein family, and an extremely rare feature amongst eukaryotic proteins. Ferlins also bear a unique nested DysF domain and small conserved 60-70 residue ferlin-specific sequences (Fer domains). Ferlins segregate into two subtypes based on the presence (type I ferlin) or absence (type II ferlin) of the DysF and FerA domains. Ferlins have diverse tissue-specific and developmental expression patterns, with ferlin animal models united by pathologies arising from defects in vesicle fusion. Consistent with their proposed role in vesicle trafficking, ferlin interaction partners include cytoskeletal motors, other vesicle-associated trafficking proteins and transmembrane receptors or channels. Herein we summarize the research history of the ferlins, an intriguing family of structurally conserved proteins with a preserved ancestral function as regulators of vesicle fusion and receptor trafficking.

A seesaw model for intermolecular gating in the kinesin motor protein

Recent structural observations of kinesin-1, the founding member of the kinesin group of motor proteins, have led to substantial gains in our understanding of this molecular machine. Kinesin-1, similar to many kinesin family members, assembles to form homodimers that use alternating ATPase cycles of the catalytic motor domains, or “heads”, to proceed unidirectionally along its partner filament (the microtubule) via a hand-over-hand mechanism. Cryo-electron microscopy has now revealed 8-Å resolution, 3D reconstructions of kinesin-1•microtubule complexes for all three of this motor’s principal nucleotide-state intermediates (ADP-bound, no-nucleotide, and ATP analog), the first time filament co-complexes of any cytoskeletal motor have been visualized at this level of detail. These reconstructions comprehensively describe nucleotide-dependent changes in a monomeric head domain at the secondary structure level, and this information has been combined with atomic-resolution crystallography data to synthesize an atomic-level "seesaw" mechanism describing how microtubules activate kinesin’s ATP-sensing machinery. The new structural information revises or replaces key details of earlier models of kinesin’s ATPase cycle that were based principally on crystal structures of free kinesin, and demonstrates that high-resolution characterization of the kinesin–microtubule complex is essential for understanding the structural basis of the cycle. I discuss the broader implications of the seesaw mechanism within the cycle of a fully functional kinesin dimer and show how the seesaw can account for two types of "gating" that keep the ATPase cycles of the two heads out of sync during processive movement.

Multifunctional myosin VI has a multitude of cargoes

In humans, a vast array of cytoskeletal motor proteins (19 dyneins, 43 kinesins, and 39 myosins) (1) move along microtubule and actin filament tracks to generate an enormous range of cellular functions. The kinesin and dynein motor proteins drive long-distance transport along microtubules, whereas the myosins are responsible for short-range delivery along actin filaments (2). The myosin motor proteins are composed of three functional domains: a motor domain with catalytic ATPase and actin-binding sites, a neck (lever arm with 1–6 bound calmodulins), and a cargo-binding tail domain. The mechanochemical properties of the myosins have been studied in great detail, but far less is known about their exact cellular functions (3). Although the kinetic properties of the motor domains of the myosins are fine-tuned for their cellular roles, it is the identity of their cargo-binding proteins that determines their precise cellular functions. In PNAS, Finan et al. (4) use a biochemical interaction screen to identify the cargo-binding partners of myosin VI/Jaguar in Drosophila to further our understanding of the cellular roles of this motor protein.

Moving into the cell: single-molecule studies of molecular motors in complex environments

Much has been learned in the past decades about molecular force generation. Single-molecule techniques, such as atomic force microscopy, single-molecule fluorescence microscopy and optical tweezers, have been key in resolving the mechanisms behind the power strokes, 'processive' steps and forces of cytoskeletal motors. However, it remains unclear how single force generators are integrated into composite mechanical machines in cells to generate complex functions such as mitosis, locomotion, intracellular transport or mechanical sensory transduction. Using dynamic single-molecule techniques to track, manipulate and probe cytoskeletal motor proteins will be crucial in providing new insights.

Non-Muscle Myosin IIA Facilitates Vesicle Trafficking for MG53-Mediated Cell Membrane Repair

Repair of disruptions to the plasma membrane is an essential mechanism for maintenance of cellular homeostasis and integrity, a process that involves coordinated movement of intracellular vesicles to membrane injury sites for patch formation. We have previously identified MG53 as an essential component of the cell membrane repair machinery. In order for MG53 and intracellular vesicles to translocate to membrane injury sites, motor proteins must be involved. Here we show that non-muscle myosin type IIA (NM-IIA) interact with MG53 to regulate vesicle trafficking in both muscle and non-muscle cells. In cells that are deficient for NM-IIA expression, MG53 cannot translocate to acute injury sites, whereas rescue of NM-IIA expression in these cells can restore MG53-mediated membrane repair. Compromised cell membrane repair is observed in cells with RNAi-mediated knockdown of NM-IIA expression, or pharmacological interventions of NM-IIA motor function. Thus, our dada reveal NM-IIA as a key cytoskeletal motor that facilitates vesicle trafficking for MG53-mediated cell membrane repair.

Structural and Functional Modularity of Cytoplasmic Dynein

As molecular machines, motor proteins contain three functional modules; “ATP hydrolyzing”, “force generating” and “track binding” modules. Among cytoskeletal motor proteins, dynein has a unique modular architecture with the distinctive evolutionary history. Here, we summarize recent progress in understanding how dynein coordinates these modules to generate its movements along a microtubule track.

A new delta‐COP on the block – linking pigmentation defects with neurodegeneration

A new delta‐COP on the block – linking pigmentation defects with neurodegeneration

On Force and Function

It was a fabric merchant who first opened a window into the cellular world. In the late 1600s, Antoni van Leeuwenhoek used glass he polished into small spheres to create single-lens microscopes that were the most powerful of the day, revealing sights never seen before: pores in a thin slice of cork, swimming bacteria and protozoa, and a pattern of bands in muscle fibers. Optical microscopes are no longer hand held, but they remain critical tools for uncovering the dynamic inner workings of those cells that van Leeuwenhoek first glimpsed. He would no doubt be amazed that the “animalcules” he first reported in his microscope are themselves composed of molecules, intricately organized to coordinate cellular activity. Seeing, however, is only the first step. Dan Fletcher The past 50 years of cell biology research has succeeded in identifying a multitude of genes and gene products, characterizing their biochemical activity, and localizing them within cells. But knowing the identity of each molecule and where it is at this moment in time does not tell us where it will be the next moment, much less how molecules coordinate to pull off the cellular gymnastics of division or motility. For that we must ask questions about the internal and external forces experienced by cells at the molecular level. How are forces transmitted through cells and transduced into biochemical activity? How do forces shape cellular behaviors and guide fate decisions? Answering these questions requires a different way of looking at cells that captures the flow of forces through them. Constructing a complete mechanical map of the cell, which complements the current molecular map, is a central challenge for cell biology over the next 50 years. That force and function mix comes as no surprise, as life at the cellular level is not for the weak. Single-celled organisms must physically fend for themselves in tumultuous environments on land and in water. Cells within multicellular organisms are routinely exposed to a cacophony of forces, such as tension transmitted to adherent cells through deformation of the extracellular matrix or compression encountered by motile cells as they move through tissue. Even cells that wall themselves off from the outside world must deal with the hustle and bustle of internal forces generated by cytoskeletal filaments and motor proteins. Although there is growing appreciation for the mechanochemistry of individual proteins such as molecular motors, it is less clear how multimolecular structures or entire cells are mechanically organized to respond to different matrix rigidities or changes in their external physical environment. Are the compressive and tensile forces experienced by cells important signals or useless background noise? How does a cell know which tap or tug is functionally important? Is there a secret knock? These questions would be easier to answer if only forces were visible. Alas, just the effect of a force—not the force itself—can be seen, acting through the mechanical properties of a molecule or network of molecules and resulting in movement or deformation. Sometimes, forces on cells are local and temporary, whereas other times they are global and sustained. So how can we create this mechanical map of the cell? A key ingredient is cell biologists who understand (and enjoy) physical science, embracing its mathematical foundations and mechanistic insight. In the absence of vitalism, cell behavior must be explainable by the rules of physics and chemistry, and math is a boon companion. A second ingredient is development of experimental methods for capturing and creating cellular forces, together with computational techniques for modeling them. New force microscopy techniques and specialized optical probes can now be used to quantify stresses and strains in live cells, but more are needed. A third ingredient is use of powerful structural, genetic, and bioinformatic tools to test theories of cell mechanics and their implications for development and disease. In the early 1900s, D'Arcy Thompson extolled the power of physics and mathematics to explain biology in his expansive treatise “On Growth and Form.” For him, forces shaped us as they do clay, providing an alternative explanation to heredity for the morphology of organisms. Although modern molecular biology has clearly shown the role that genetics plays in shaping biology, Thompson's desire to ground biology in the fundamentals of molecular mechanics is still to be realized. As the American Society for Cell Biology celebrates its 50th anniversary, it is worth remembering how dependent scientific progress is on new ideas. Researchers who remain interested and open throughout their careers will have the chance to introduce new perspectives and instruments that can change the way we think. Perhaps the next big discovery will come from an unlikely place, maybe even a fabric merchant.

P107. Regulation of interkinetic nuclear migration by cell cycle-coupled active and passive mechanisms in the developing brain

Background A hallmark of neurogenesis in the vertebrate brain is the apical-basal nuclear oscillation in polarized neural progenitor cells in the germinal zone. Known as interkinetic nuclear migration (INM), these movements are synchronized with the cell cycle such that nuclei move basally during G1-phase and apically during G2-phase. Such nuclear movements are considered to be critical for progenitor self-renewal. While basal-to-apical nuclear migration is known to involve cytoskeletal motor systems, how migrations in opposite directions are related and linked with the cell cycle are unknown. Results We found that the microtubule-associated protein Tpx2 promotes apical nuclear migration cell-autonomously during G2-phase. Tpx2 becomes detectable in the nucleus during S-phase, and redistributes to the apical process during S to G2 progression to alter microtubule organization. Thus, Tpx2 links cell cycle progression and apical nuclear migration. In contrast, in vivo observations of implanted microbeads, acute S-phase arrest of surrounding cells, and computational modeling suggest that the basal migration of G1-phase nuclei depends on nuclear displacement by G2-phase nuclei migrating apically. Conclusions We conclude that INM proceeds through the intimate linkage of cell-autonomous and non-autonomous mechanisms, in a cell cycle-dependent manner. Autonomous apical nuclear migration is linked with G2-phase through Tpx2, and contributes to the basal migration of G1-phase nuclei non-autonomously. This model of INM not only explains how nuclear migration is associated with the cell cycle, but also describes a robust system enabling the coordination of progenitor cell proliferation with the pseudostratified epithelial architecture of the developing brain.

Probing Intracellular Motor Protein Activity Using an Inducible Cargo Trafficking Assay

Although purified cytoskeletal motor proteins have been studied extensively with the use of in vitro approaches, a generic approach to selectively probe actin and microtubule-based motor protein activity inside living cells is lacking. To examine specific motor activity inside living cells, we utilized the FKBP-rapalog-FRB heterodimerization system to develop an in vivo peroxisomal trafficking assay that allows inducible recruitment of exogenous and endogenous kinesin, dynein, and myosin motors to drive specific cargo transport. We demonstrate that cargo rapidly redistributes with distinct dynamics for each respective motor, and that combined (antagonistic) actions of more complex motor combinations can also be probed. Of importance, robust cargo redistribution is readily achieved by one type of motor protein and does not require the presence of opposite-polarity motors. Simultaneous live-cell imaging of microtubules and kinesin or dynein-propelled peroxisomes, combined with high-resolution particle tracking, revealed that peroxisomes frequently pause at microtubule intersections. Titration and washout experiments furthermore revealed that motor recruitment by rapalog-induced heterodimerization is dose-dependent but irreversible. Our assay directly demonstrates that robust cargo motility does not require the presence of opposite-polarity motors, and can therefore be used to characterize the motile properties of specific types of motor proteins.

Myosin cleft closure determines the energetics of the actomyosin interaction

Formation of the strong binding interaction between actin and myosin is essential for force generation in muscle and in cytoskeletal motor systems. To clarify the role of the closure of myosin's actin-binding cleft in the actomyosin interaction, we performed rapid kinetic, spectroscopic, and calorimetric experiments and atomic-level energetic calculations on a variety of myosin isoforms for which atomic structures are available. Surprisingly, we found that the endothermic actin-binding profile of vertebrate skeletal muscle myosin subfragment-1 is unique among studied myosins. We show that the diverse propensity of myosins for cleft closure determines different energetic profiles as well as structural and kinetic pathways of actin binding. Depending on the type of myosin, strong actin binding may occur via induced-fit or conformational preselection mechanisms. However, cleft closure does not directly determine the kinetics and affinity of actin binding. We also show that cleft closure is enthalpically unfavorable, reflecting the development of an internal strain within myosin in order to adopt precise steric complementarity to the actin filament. We propose that cleft closure leads to an increase in the torsional strain of myosin's central β-sheet that has been proposed to serve as an allosteric energy-transducing spring during force generation.

Structured Post-IQ Domain Governs Selectivity of Myosin X for Fascin-Actin Bundles

Without guidance cues, cytoskeletal motors would traffic components to the wrong destination with disastrous consequences for the cell. Recently, we identified a motor protein, myosin X, that identifies bundled actin filaments for transport. These bundles direct myosin X to a unique destination, the tips of cellular filopodia. Because the structural and kinetic features that drive bundle selection are unknown, we employed a domain-swapping approach with the nonselective myosin V to identify the selectivity module of myosin X. We found a surprising role of the myosin X tail region (post-IQ) in supporting long runs on bundles. Moreover, the myosin X head is adapted for initiating processive runs on bundles. We found that the tail is structured and biases the orientation of the two myosin X heads because a targeted insertion that introduces flexibility in the tail abolishes selectivity. Together, these results suggest how myosin motors may manage to read cellular addresses.

Rab11 and Actin Cytoskeleton Participate in Giardia lamblia Encystation, Guiding the Specific Vesicles to the Cyst Wall

Background Giardia passes through two stages during its life cycle, the trophozoite and the cyst. Cyst formation involves the synthesis of cyst wall proteins (CWPs) and the transport of CWPs into encystation-specific vesicles (ESVs). Active vesicular trafficking is essential for encystation, but the molecular machinery driving vesicular trafficking remains unknown. The Rab proteins are involved in the targeting of vesicles to several intracellular compartments through their association with cytoskeletal motor proteins.Methodology and Principal FindingsIn this study, we found a relationship between Rab11 and the actin cytoskeleton in CWP1 transport. Confocal microscopy showed Rab11 was distributed throughout the entire trophozoite, while in cysts it was translocated to the periphery of the cell, where it colocalized with ESVs and microfilaments. Encystation was also accompanied by changes in rab11 mRNA expression. To evaluate the role of microfilaments in encystation, the cells were treated with latrunculin A. Scanning electron microscopy showed this treatment resulted in morphological damages to encysted parasites. The intensity of fluorescence-labeled Rab11 and CWP1 in ESVs and cyst walls was reduced, and rab11 and cwp1 mRNA levels were down-regulated. Furthermore, knocking down Rab11 with a hammerhead ribozyme resulted in an up to 80% down-regulation of rab11 mRNA. Although this knockdown did not appear lethal for trophozoites and did not affect cwp1 expression during the encystation, confocal images showed CWP1 was redistributed throughout the cytosol.Conclusions and SignificanceOur results indicate that Rab11 participates in the early and late encystation stages by regulating CWP1 localization and the actin-mediated transport of ESVs towards the periphery. In addition, alterations in the dynamics of actin affected rab11 and cwp1 expression. Our results provide new information about the molecules involved in Giardia encystation and suggest that Rab11 and actin may be useful as novel pharmacological targets.

Traffic of cytoskeletal motors with disordered attachment rates

Motivated by experimental results on the interplay between molecular motors and tau proteins, we extend lattice-based models of intracellular transport to include a second species of particle which locally influences the motor-filament attachment rate. We consider various exactly solvable limits of a stochastic multiparticle model before focusing on the low-motor-density regime. Here, an approximate treatment based on the random-walk behavior of single motors gives good quantitative agreement with simulation results for the tau dependence of the motor current. Finally, we discuss the possible physiological implications of our results.

New Roles for the LKB1-NUAK Pathway in Controlling Myosin Phosphatase Complexes and Cell Adhesion

The AMPK-related kinases NUAK1 and NUAK2 are activated by the tumor suppressor LKB1. We found that NUAK1 interacts with several myosin phosphatases, including the myosin phosphatase targeting-1 (MYPT1)-protein phosphatase-1beta (PP1beta) complex, through conserved Gly-Ile-Leu-Lys motifs that are direct binding sites for PP1beta. Phosphorylation of Ser(445), Ser(472), and Ser(910) of MYPT1 by NUAK1 promoted the interaction of MYPT1 with 14-3-3 adaptor proteins, thereby suppressing phosphatase activity. Cell detachment induced phosphorylation of endogenous MYPT1 by NUAK1, resulting in 14-3-3 binding to MYPT1 and enhanced phosphorylation of myosin light chain-2. Inhibition of the LKB1-NUAK1 pathway impaired cell detachment. Our data indicate that NUAK1 controls cell adhesion and functions as a regulator of myosin phosphatase complexes. Thus, LKB1 can influence the phosphorylation of targets not only through the AMPK family of kinases but also by controlling phosphatase complexes.

An atomic-level mechanism for activation of the kinesin molecular motors

Kinesin cytoskeletal motors convert the energy of ATP hydrolysis into stepping movement along microtubules. A partial model of this process has been derived from crystal structures, which show that movement of the motor domain relative to its major microtubule binding element, the switch II helix, is coupled to docking of kinesin's neck linker element along the motor domain. This docking would displace the cargo in the direction of travel and so contribute to a step. However, the crystal structures do not reveal how ATP binding and hydrolysis govern this series of events. We used cryoelectron microscopy to derive 8-9 A-resolution maps of four nucleotide states encompassing the microtubule-attached kinetic cycle of a kinesin motor. The exceptionally high quality of these maps allowed us to build in crystallographically determined conformations of kinesin's key subcomponents, yielding novel arrangements of kinesin's switch II helix and nucleotide-sensing switch loops. The resulting atomic models reveal a seesaw mechanism in which the switch loops, triggered by ATP binding, propel their side of the motor domain down and thereby elicit docking of the neck linker on the opposite side of the seesaw. Microtubules engage the seesaw mechanism by stabilizing the formation of extra turns at the N terminus of the switch II helix, which then serve as an anchor for the switch loops as they modulate the seesaw angle. These observations explain how microtubules activate kinesin's ATP-sensing machinery to promote cargo displacement and inform the mechanism of kinesin's ancestral relative, myosin.

Bicaudal-D binds clathrin heavy chain to promote its transport and augments synaptic vesicle recycling

Cargo transport by microtubule-based motors is essential for cell organisation and function. The Bicaudal-D (BicD) protein participates in the transport of a subset of cargoes by the minus-end-directed motor dynein, although the full extent of its functions is unclear. In this study, we report that in Drosophila zygotic BicD function is only obligatory in the nervous system. Clathrin heavy chain (Chc), a major constituent of coated pits and vesicles, is the most abundant protein co-precipitated with BicD from head extracts. BicD binds Chc directly and interacts genetically with components of the pathway for clathrin-mediated membrane trafficking. Directed transport and subcellular localisation of Chc is strongly perturbed in BicD mutant presynaptic boutons. Functional assays show that BicD and dynein are essential for the maintenance of normal levels of neurotransmission specifically during high-frequency electrical stimulation and that this is associated with a reduced rate of recycling of internalised synaptic membrane. Our results implicate BicD as a new player in clathrin-associated trafficking processes and show a novel requirement for microtubule-based motor transport in the synaptic vesicle cycle.