Your search keyword '"Kon, T."' showing total 21 results

1. Chlamydomonas IC97, an intermediate chain of the flagellar dynein f/I1, is required for normal flagellar and cellular motility.

Author

Yamamoto R, Tanaka Y, Orii S, Shiba K, Inaba K, and Kon T

Subjects

Cell Movement, Mutation, Chlamydomonas genetics, Chlamydomonas metabolism, Chlamydomonas reinhardtii genetics, Chlamydomonas reinhardtii metabolism, Flagella genetics, Flagella physiology, Dyneins metabolism, Dyneins genetics

Abstract

Motile flagella (also called "motile cilia") play a variety of important roles in lower and higher eukaryotes, including cellular motility and fertility. Flagellar motility is driven by several species of the gigantic motor-protein complexes, flagellar dyneins, that reside within these organelles. Among the flagellar-dynein species, a hetero-dimeric dynein called "IDA f/I1" has been shown to be particularly important in controlling the flagellar waveform, and defects in this dynein species in humans cause ciliopathies such as multiple morphological abnormalities of the flagella and asthenoteratozoospermia. IDA f/I1 is composed of many subunits, including two HCs (HCα and HCβ) and three ICs (IC140, IC138, and IC97), and among the three ICs of IDA f/I1, the exact molecular function(s) of IC97 in flagellar motility is not well understood. In this study, we isolated a Chlamydomonas mutant lacking IC97 and analyzed the phenotypes. The ic97 mutant phenocopied several aspects of the previously isolated IDA-f/I1-related mutants in Chlamydomonas and showed slow swimming compared to the wild type but retained the ability to phototaxis. Further analysis revealed that the mutant had low flagellar beat frequency and miscoordination between the two ( cis - and trans -) flagella. In addition, the mutant cells swam in a comparatively straight path compared to the wild-type cells. Taken together, our results highlight the importance of proper assembly of IC97 in the IDA-f/I1 complex for the regulation of flagellar and cellular motility in Chlamydomonas and provide valuable insights into both the molecular functions of IC97 orthologs in higher eukaryotes and the pathogenetic mechanisms of human ciliopathies caused by IDA-f/I1 defects., Importance: IDA f/I1 is a hetero-dimeric flagellar dynein that is particularly important for the regulation of flagellar waveform and whose defects are associated with human ciliopathies. IC97 is an evolutionarily conserved intermediate chain of IDA f/I1, but the detailed molecular functions of IC97 in flagellar motility have not been elucidated. In this study, mutational and biochemical analyses of the previously uncharacterized Chlamydomonas ic97 mutant revealed that IC97 is required for both the normal flagellar and cellular motility. In particular, IC97 appears to play an important role in both the control of flagellar beat frequency and the coordination between the two ( cis - and trans -) flagella in Chlamydomonas . Our results provide important insights into the regulation of IDA-f/I1 activity by IC97 and the pathogenetic mechanisms of human ciliopathies caused by IDA-f/I1 defects., Competing Interests: The authors declare no conflict of interest.

Published

2024

2. Functional and structural significance of the inner-arm-dynein subspecies d in ciliary motility.

Author

Yamamoto R and Kon T

Subjects

Humans, Animals, Cell Movement physiology, Chlamydomonas reinhardtii metabolism, Cilia metabolism, Dyneins metabolism

Abstract

Motile cilia play various important physiological roles in eukaryotic organisms including cell motility and fertility. Inside motile cilia, large motor-protein complexes called "ciliary dyneins" coordinate their activities and drive ciliary motility. The ciliary dyneins include the outer-arm dyneins, the double-headed inner-arm dynein (IDA f/I1), and several single-headed inner-arm dyneins (IDAs a, b, c, d, e, and g). Among these single-headed IDAs, one of the ciliary dyneins, IDA d, is of particular interest because of its unique properties and subunit composition. In addition, defects in this subspecies have recently been associated with several types of ciliopathies in humans, such as primary ciliary dyskinesia and multiple morphologic abnormalities of the flagellum. In this mini-review, we discuss the composition, structure, and motor properties of IDA d, which have been studied in the model organism Chlamydomonas reinhardtii, and further discuss the relationship between IDA d and human ciliopathies. In addition, we provide future perspectives and discuss remaining questions regarding this intriguing dynein subspecies., (© 2024 Wiley Periodicals LLC.)

Published

2024

3. Elastic properties of dynein motor domain obtained from all-atom molecular dynamics simulations.

Author

Kamiya N, Mashimo T, Takano Y, Kon T, Kurisu G, and Nakamura H

Subjects

Adenosine Diphosphate metabolism, Adenosine Triphosphate metabolism, Movement, Protein Domains, Dyneins chemistry, Dyneins metabolism, Elasticity, Molecular Dynamics Simulation

Abstract

Dyneins are large microtubule motor proteins that convert ATP energy to mechanical power. High-resolution crystal structures of ADP-bound cytoplasmic dynein have revealed the organization of the motor domain, comprising the AAA(+) ring, the linker, the stalk/strut and the C sequence. Recently, the ADP.vanadate-bound structure, which is similar to the ATP hydrolysis transition state, revealed how the structure of dynein changes upon ATP binding. Although both the ADP- and ATP-bound state structures have been resolved, the dynamic properties at the atomic level remain unclear. In this work, we built two models named 'the ADP model' and 'the ATP model', where ADP and ATP are bound to AAA1 in the AAA(+) ring, respectively, to observe the initial procedure of the structural change from the unprimed to the primed state. We performed 200-ns molecular dynamics simulations for both models and compared their structures and dynamics. The motions of the stalk, consisting of a long coiled coil with a microtubule-binding domain, significantly differed between the two models. The elastic properties of the stalk were analyzed and compared with the experimental results., (© The Author 2016. Published by Oxford University Press.)

Published

2016

4. A flipped ion pair at the dynein-microtubule interface is critical for dynein motility and ATPase activation.

Author

Uchimura S, Fujii T, Takazaki H, Ayukawa R, Nishikawa Y, Minoura I, Hachikubo Y, Kurisu G, Sutoh K, Kon T, Namba K, and Muto E

Subjects

Amino Acid Sequence, Animals, Conserved Sequence, Cryoelectron Microscopy, Dictyostelium, Dyneins ultrastructure, Enzyme Activation, Microtubules ultrastructure, Models, Molecular, Protein Binding, Protein Interaction Domains and Motifs, Protein Structure, Quaternary, Protozoan Proteins ultrastructure, Sus scrofa, Dyneins chemistry, Microtubules chemistry, Protozoan Proteins chemistry

Abstract

Dynein is a motor protein that moves on microtubules (MTs) using the energy of adenosine triphosphate (ATP) hydrolysis. To understand its motility mechanism, it is crucial to know how the signal of MT binding is transmitted to the ATPase domain to enhance ATP hydrolysis. However, the molecular basis of signal transmission at the dynein-MT interface remains unclear. Scanning mutagenesis of tubulin identified two residues in α-tubulin, R403 and E416, that are critical for ATPase activation and directional movement of dynein. Electron cryomicroscopy and biochemical analyses revealed that these residues form salt bridges with the residues in the dynein MT-binding domain (MTBD) that work in concert to induce registry change in the stalk coiled coil and activate the ATPase. The R403-E3390 salt bridge functions as a switch for this mechanism because of its reversed charge relative to other residues at the interface. This study unveils the structural basis for coupling between MT binding and ATPase activation and implicates the MTBD in the control of directional movement., (© 2015 Uchimura et al.)

Published

2015

5. Structure of the entire stalk region of the Dynein motor domain.

Author

Nishikawa Y, Oyama T, Kamiya N, Kon T, Toyoshima YY, Nakamura H, and Kurisu G

Subjects

Adenosine Triphosphatases metabolism, Adenosine Triphosphate metabolism, Amino Acid Sequence, Animals, Binding Sites, Crystallography, X-Ray, Dictyostelium, Mice, Microtubules metabolism, Models, Molecular, Molecular Dynamics Simulation, Molecular Sequence Data, Protein Binding, Protein Structure, Tertiary, Thermus thermophilus enzymology, Thermus thermophilus metabolism, Dyneins chemistry, Dyneins ultrastructure

Abstract

Dyneins are large microtubule-based motor complexes that power a range of cellular processes including the transport of organelles, as well as the beating of cilia and flagella. The motor domain is located within the dynein heavy chain and comprises an N-terminal mechanical linker element, a central ring of six AAA+ modules of which four bind or hydrolyze ATP, and a long stalk extending from the AAA+ring with a microtubule-binding domain (MTBD) at its tip. A crucial mechanism underlying the motile activity of cytoskeletal motor proteins is precise coupling between the ATPase and track-binding activities. In dynein, a stalk region consisting of a long (~15nm) antiparallel coiled coil separates these two activities, which must facilitate communication between them. This communication is mediated by a small degree of helix sliding in the coiled coil. However, no high-resolution structure is available of the entire stalk region including the MTBD. Here, we have reported the structure of the entire stalk region of mouse cytoplasmic dynein in a weak microtubule-binding state, which was determined using X-ray crystallography, and have compared it with the dynein motor domain from Dictyostelium discoideum in a strong microtubule-binding state and with a mouse MTBD with its distal portion of the coiled coil fused to seryl-tRNA synthetase from Thermus thermophilus. Our results strongly support the helix-sliding model based on the complete structure of the dynein stalk with a different form of coiled-coil packing. We also propose a plausible mechanism of helix sliding together with further analysis using molecular dynamics simulations. Our results present the importance of conserved proline residues for an elastic motion of stalk coiled coil and imply the manner of change between high-affinity state and low-affinity state of MTBD., (Copyright © 2014 Elsevier Ltd. All rights reserved.)

Published

2014

6. Tug-of-war of microtubule filaments at the boundary of a kinesin- and dynein-patterned surface.

Author

Ikuta J, Kamisetty NK, Shintaku H, Kotera H, Kon T, and Yokokawa R

Subjects

Algorithms, Biological Transport, Dyneins metabolism, Kinesins metabolism, Kinetics, Microtubules metabolism, Models, Biological, Models, Molecular, Molecular Motor Proteins metabolism, Protein Binding, Protein Conformation, Protein Multimerization, Videotape Recording, Dyneins chemistry, Kinesins chemistry, Microtubules chemistry, Molecular Motor Proteins chemistry

Abstract

Intracellular cargo is transported by multiple motor proteins. Because of the force balance of motors with mixed polarities, cargo moves bidirectionally to achieve biological functions. Here, we propose a microtubule gliding assay for a tug-of-war study of kinesin and dynein. A boundary of the two motor groups is created by photolithographically patterning gold to selectively attach kinesin to the glass and dynein to the gold surface using a self-assembled monolayer. The relationship between the ratio of two antagonistic motor numbers and the velocity is derived from a force-velocity relationship for each motor to calculate the detachment force and motor backward velocity. Although the tug-of-war involves >100 motors, values are calculated for a single molecule and reflect the collective dynein and non-collective kinesin functions when they work as a team. This assay would be useful for detailed in vitro analysis of intracellular motility, e.g., mitosis, where a large number of motors with mixed polarities are involved.

Published

2014

7. Functions and mechanics of dynein motor proteins.

Author

Roberts AJ, Kon T, Knight PJ, Sutoh K, and Burgess SA

Subjects

Animals, Dyneins chemistry, Humans, Models, Biological, Dyneins metabolism

Abstract

Fuelled by ATP hydrolysis, dyneins generate force and movement on microtubules in a wealth of biological processes, including ciliary beating, cell division and intracellular transport. The large mass and complexity of dynein motors have made elucidating their mechanisms a sizable task. Yet, through a combination of approaches, including X-ray crystallography, cryo-electron microscopy, single-molecule assays and biochemical experiments, important progress has been made towards understanding how these giant motor proteins work. From these studies, a model for the mechanochemical cycle of dynein is emerging, in which nucleotide-driven flexing motions within the AAA+ ring of dynein alter the affinity of its microtubule-binding stalk and reshape its mechanical element to generate movement.

Published

2013

8. X-ray structure of a functional full-length dynein motor domain.

Author

Kon T, Sutoh K, and Kurisu G

Subjects

Adenosine Diphosphate chemistry, Adenosine Diphosphate metabolism, Crystallography, X-Ray, Dyneins metabolism, Models, Molecular, Protein Structure, Quaternary, Protozoan Proteins metabolism, Dictyostelium chemistry, Dyneins chemistry, Protozoan Proteins chemistry

Abstract

Dyneins are large microtubule-based motors that power a wide variety of cellular processes. Here we report a 4.5-Å X-ray crystallographic analysis of the entire functional motor domain of cytoplasmic dynein with ADP from Dictyostelium discoideum, which has revealed the detailed architecture of the functional units required for motor activity, including the ATP-hydrolyzing ring, the long coiled-coil microtubule-binding stalk and the force-generating rod-like linker. We discovered a Y-shaped protrusion composed of two long coiled coils-the stalk and the newly identified 'strut'. This structure supports our model in which the strut coiled coil actively contributes to communication between the primary ATPase site in the ring and the microtubule-binding site at the tip of the stalk coiled coil. Our work also provides insight into how the two motor domains are arranged and how they interact with each other in a functional dimer form of cytoplasmic dynein.

Published

2011

9. Helix sliding in the stalk coiled coil of dynein couples ATPase and microtubule binding.

Author

Kon T, Imamula K, Roberts AJ, Ohkura R, Knight PJ, Gibbons IR, Burgess SA, and Sutoh K

Subjects

Amino Acid Sequence, Animals, Binding Sites, Dictyostelium, Locomotion, Models, Molecular, Molecular Sequence Data, Protein Binding, Protein Structure, Secondary, Adenosine Triphosphatases metabolism, Dyneins chemistry, Dyneins metabolism, Microtubules metabolism, Protozoan Proteins chemistry, Protozoan Proteins metabolism

Abstract

Coupling between ATPase and track binding sites is essential for molecular motors to move along cytoskeletal tracks. In dynein, these sites are separated by a long coiled coil stalk that must mediate communication between them, but the underlying mechanism remains unclear. Here we show that changes in registration between the two helices of the coiled coil can perform this function. We locked the coiled coil at three specific registrations using oxidation to disulfides of paired cysteine residues introduced into the two helices. These trapped ATPase activity either in a microtubule-independent high or low state, and microtubule binding activity either in an ATP-insensitive strong or weak state, depending on the registry of the coiled coil. Our results provide direct evidence that dynein uses sliding between the two helices of the stalk to couple ATPase and microtubule binding activities during its mechanochemical cycle.

Published

2009

10. AAA+ Ring and linker swing mechanism in the dynein motor.

Author

Roberts AJ, Numata N, Walker ML, Kato YS, Malkova B, Kon T, Ohkura R, Arisaka F, Knight PJ, Sutoh K, and Burgess SA

Subjects

Animals, Dictyostelium metabolism, Dyneins ultrastructure, Green Fluorescent Proteins metabolism, Microscopy, Electron, Protozoan Proteins ultrastructure, Dictyostelium ultrastructure, Dyneins metabolism, Protozoan Proteins metabolism

Abstract

Dynein ATPases power diverse microtubule-based motilities. Each dynein motor domain comprises a ring-like head containing six AAA+ modules and N- and C-terminal regions, together with a stalk that binds microtubules. How these subdomains are arranged and generate force remains poorly understood. Here, using electron microscopy and image processing of tagged and truncated Dictyostelium cytoplasmic dynein constructs, we show that the heart of the motor is a hexameric ring of AAA+ modules, with the stalk emerging opposite the primary ATPase site (AAA1). The C-terminal region is not an integral part of the ring but spans between AAA6 and near the stalk base. The N-terminal region includes a lever-like linker whose N terminus swings by approximately 17 nm during the ATPase cycle between AAA2 and the stalk base. Together with evidence of stalk tilting, which may communicate changes in microtubule binding affinity, these findings suggest a model for dynein's structure and mechanism.

Published

2009

11. Protein engineering approaches to study the dynein mechanism using a Dictyostelium expression system.

Author

Kon T, Shima T, and Sutoh K

Subjects

Animals, Biological Assay, Biotin metabolism, Dictyostelium genetics, Dyneins chemistry, Fluorescence Resonance Energy Transfer, Kymography, Microtubules metabolism, Protein Conformation, Protein Transport, Recombinant Proteins biosynthesis, Dictyostelium metabolism, Dyneins metabolism, Protein Engineering methods

Abstract

Dyneins are microtubule-based motor complexes that power a wide variety of motile processes within eukaryotic cells, including the beating of cilia and flagella and intracellular trafficking along microtubules. Mechanistic studies on dynein have been hampered by their enormous size (molecular masses of 0.5-3MDa) and molecular complexity. However, the recent establishment of recombinant expression systems for cytoplasmic dynein, together with structural and functional analyses, has advanced our understanding of the molecular mechanisms of dynein motility. Here, we describe several protocols for protein engineering approaches to the dynein mechanism using a Dictyostelium discoideum expression system. We first describe the design and preparation of recombinant dynein suitable for mechanistic studies. We then discuss two distinct functional assays that take advantage of the recombinant dynein. One is for detection of dynein's conformational changes during the ATPase cycle. Another is an in vitro motility assay at multiple- and single-molecule levels for examination of the dynamic behavior of dynein moving on a microtubule., (2009 Elsevier Inc. All rights reserved.)

Published

2009

12. Simultaneous and bidirectional transport of kinesin-coated microspheres and dynein-coated microspheres on polarity-oriented microtubules.

Author

Yokokawa R, Tarhan MC, Kon T, and Fujita H

Subjects

Adsorption, Coated Materials, Biocompatible chemistry, Dyneins ultrastructure, Kinesins ultrastructure, Materials Testing, Microspheres, Molecular Conformation, Molecular Motor Proteins ultrastructure, Motion, Protein Binding, Static Electricity, Dyneins chemistry, Kinesins chemistry, Molecular Motor Proteins chemistry

Abstract

Artificial nanotransport systems inspired by intracellular transport processes have been investigated for over a decade using the motor protein kinesin and microtubules. However, only unidirectional cargo transport has been achieved for the purpose of nanotransport in a microfluidic system. Here, we demonstrate bidirectional nanotransport by integrating kinesin and dynein motor proteins. Our molecular system allows microtubule orientation of either polarity in a microfluidic channel to construct a transport track. Each motor protein acts as a nanoactuators that transports microspheres in opposite directions determined by the polarity of the oriented microtubules: kinesin-coated microspheres move toward the plus end of microtubules, whereas dynein-coated microspheres move toward the minus end. We demonstrate both unidirectional and bidirectional transport using kinesin- and dynein-coated microspheres on microtubules oriented and glutaraldehyde-immobilized in a microfluidic channel. Tracking and statistical analysis of microsphere movement demonstrate that 87-98% of microspheres move in the designated direction at a mean velocity of 0.22-0.28 microm/s for kinesin-coated microspheres and 0.34-0.39 microm/s for dynein-coated microspheres. This bidirectional nanotransport goes beyond conventional unidirectional transport to achieve more complex artificial nanotransport in vitro.

Published

2008

13. Molecular mechanism of force generation by dynein, a molecular motor belonging to the AAA+ family.

Author

Numata N, Kon T, Shima T, Imamula K, Mogami T, Ohkura R, Sutoh K, and Sutoh K

Subjects

Adenosine Triphosphate metabolism, Animals, Biomechanical Phenomena, Dyneins chemistry, Metalloendopeptidases chemistry, Microtubules metabolism, Protein Structure, Tertiary, Dyneins metabolism, Metalloendopeptidases metabolism

Abstract

Dynein is an AAA+ (ATPase associated with various cellular activities)-type motor complex that utilizes ATP hydrolysis to actively drive microtubule sliding. The dynein heavy chain (molecular mass >500 kDa) contains six tandemly linked AAA+ modules and exhibits full motor activities. Detailed molecular dissection of this motor with unique architecture was hampered by the lack of an expression system for the recombinant heavy chain, as a result of its large size. However, the recent success of recombinant protein expression with full motor activities has provided a method for advances in structure-function studies in order to elucidate the molecular mechanism of force generation.

Published

2008

14. Three-dimensional structure of cytoplasmic dynein bound to microtubules.

Author

Mizuno N, Narita A, Kon T, Sutoh K, and Kikkawa M

Subjects

Adenosine Triphosphate chemistry, Animals, Cryoelectron Microscopy, Imaging, Three-Dimensional, Microtubules metabolism, Models, Biological, Models, Molecular, Molecular Conformation, Protein Conformation, Protein Structure, Tertiary, Recombinant Proteins chemistry, Cytoplasm metabolism, Dictyostelium metabolism, Dyneins chemistry, Microtubules chemistry

Abstract

Cytoplasmic dynein is a large, microtubule-dependent molecular motor (1.2 MDa). Although the structure of dynein by itself has been characterized, its conformation in complex with microtubules is still unknown. Here, we used cryoelectron microscopy (cryo-EM) to visualize the interaction between dynein and microtubules. Most dynein molecules in the nucleotide-free state are bound to the microtubule in a defined conformation and orientation. A 3D image reconstruction revealed that dynein's head domain, formed by a ring-like arrangement of AAA+ domains, is located approximately 280 A away from the center of the microtubule. The order of the AAA+ domains in the ring was determined by using recombinant markers. Furthermore, a 3D helical image reconstruction of microtubules with a dynein's microtubule binding domain [dynein stalk (DS)] revealed that the stalk extends perpendicular to the microtubule. By combining the 3D maps of the dynein-microtubule and DS-microtubule complexes, we present a model for how dynein in the nucleotide-free state binds to microtubules and discuss models for dynein's power stroke.

Published

2007

15. The coordination of cyclic microtubule association/dissociation and tail swing of cytoplasmic dynein.

Author

Imamula K, Kon T, Ohkura R, and Sutoh K

Subjects

Adenine Nucleotides metabolism, Animals, Biophysical Phenomena, Biophysics, Cytoplasm metabolism, Dictyostelium genetics, Dictyostelium metabolism, Dyneins genetics, In Vitro Techniques, Kinetics, Microtubules metabolism, Mutagenesis, Site-Directed, Protein Structure, Tertiary, Protozoan Proteins genetics, Recombinant Fusion Proteins chemistry, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism, Dyneins chemistry, Dyneins metabolism, Protozoan Proteins chemistry, Protozoan Proteins metabolism

Abstract

The dynein motor domain is composed of a tail, head, and stalk and is thought to generate a force to microtubules by swinging the tail against the head during its ATPase cycle. For this "power stroke," dynein has to coordinate the tail swing with microtubule association/dissociation at the tip of the stalk. Although a detailed picture of the former process is emerging, the latter process remains to be elucidated. By using the single-headed recombinant motor domain of Dictyostelium cytoplasmic dynein, we address the questions of how the interaction of the motor domain with a microtubule is modulated by ATPase steps, how the two mechanical cycles (the microtubule association/dissociation and tail swing) are coordinated, and which ATPase site among the multiple sites in the motor domain regulates the coordination. Based on steady-state and pre-steady-state measurements, we demonstrate that the two mechanical cycles proceed synchronously at most of the intermediate states in the ATPase cycle: the motor domain in the poststroke state binds strongly to the microtubule with a K(d) of approximately 0.2 microM, whereas most of the motor domains in the prestroke state bind weakly to the microtubule with a K(d) of >10 microM. However, our results suggest that the timings of the microtubule affinity change and tail swing are staggered at the recovery stroke step in which the tail swings from the poststroke to the prestroke position. The ATPase site in the AAA1 module of the motor domain was found to be responsible for the coordination of these two mechanical processes.

Published

2007

16. Kinetic characterization of tail swing steps in the ATPase cycle of Dictyostelium cytoplasmic dynein.

Author

Mogami T, Kon T, Ito K, and Sutoh K

Subjects

Animals, Dyneins genetics, Kinetics, Plasmids, Protozoan Proteins genetics, Protozoan Proteins metabolism, Recombinant Fusion Proteins chemistry, Recombinant Fusion Proteins metabolism, Spectrometry, Fluorescence, Dictyostelium enzymology, Dyneins chemistry, Dyneins metabolism

Abstract

According to the power stroke model of dynein deduced from electron microscopic and fluorescence resonance energy transfer studies, the power stroke and the recovery stroke are expected to take place at the two isomerization steps of the ATPase cycle at the primary ATPase site. Here, we have conducted presteady-state kinetic analyses of these two isomerization steps with the single-headed motor domain of Dictyostelium cytoplasmic dynein by employing fluorescence resonance energy transfer to probe ATPase steps at the primary site and tail positions. Our results show that the recovery stroke at the first isomerization step proceeds quickly ( approximately 180 s(-1)), whereas the power stroke at the second isomerization step is very slow ( approximately 0.2 s(-1)) in the absence of microtubules, and that the presence of microtubules accelerates the second but not the first step. Moreover, a comparison of the microtubule-induced acceleration of the power stroke step and that of steady-state ATP hydrolysis implies the intriguing possibility that microtubules simultaneously accelerate the ATPase activity not only at the primary site but also at other site(s) in the motor domain.

Published

2007

17. Two modes of microtubule sliding driven by cytoplasmic dynein.

Author

Shima T, Kon T, Imamula K, Ohkura R, and Sutoh K

Subjects

Animals, Biological Assay instrumentation, Biological Assay methods, Biotin metabolism, Dictyostelium chemistry, Dyneins chemistry, Dyneins genetics, Microtubules chemistry, Microtubules genetics, Microtubules ultrastructure, Protein Structure, Tertiary, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism, Streptavidin metabolism, Cytoplasm metabolism, Dyneins metabolism, Microtubules metabolism, Models, Molecular

Abstract

Dynein is a huge multisubunit microtubule (MT)-based motor, whose motor domain resides in the heavy chain. The heavy chain comprises a ring of six AAA (ATPases associated with diverse cellular activities) modules with two slender protruding domains, the tail and stalk. It has been proposed that during the ATP hydrolysis cycle, this tail domain swings against the AAA ring as a lever arm to generate the power stroke. However, there is currently no direct evidence to support the model that the tail swing is tightly linked to dynein motility. To address the question of whether the power stroke of the tail drives MT sliding, we devised an in vitro motility assay using genetically biotinylated cytoplasmic dyneins anchored on a glass surface in the desired orientation with a biotin-streptavidin linkage. Assays on the dyneins with the site-directed biotin tag at eight different locations provided evidence that robust MT sliding is driven by the power stroke of the tail. Furthermore, the assays revealed slow MT sliding independent of dynein orientation on the glass surface, which is mechanically distinct from the sliding driven by the power stroke of the tail.

Published

2006

18. Head-head coordination is required for the processive motion of cytoplasmic dynein, an AAA+ molecular motor.

Author

Shima T, Imamula K, Kon T, Ohkura R, and Sutoh K

Subjects

Adenosine Triphosphate metabolism, Amino Acid Sequence, Animals, Dictyostelium, Dimerization, Dyneins genetics, Dyneins isolation & purification, Dyneins metabolism, Hydrolysis, Microtubules metabolism, Microtubules physiology, Models, Chemical, Molecular Motor Proteins genetics, Molecular Motor Proteins isolation & purification, Molecular Motor Proteins metabolism, Molecular Sequence Data, Motion, Recombinant Proteins chemistry, Recombinant Proteins metabolism, Time Factors, Cytoplasm metabolism, Dyneins chemistry, Dyneins physiology, Molecular Motor Proteins chemistry, Molecular Motor Proteins physiology

Abstract

Cytoplasmic dynein is an AAA(+)-type molecular motor whose major components are two identical heavy chains containing six AAA(+) modules in tandem. It moves along a single microtubule in multiple steps which are accompanied with multiple ATP hydrolysis. This processive sliding is crucial for cargo transports in vivo. To examine how cytoplasmic dynein exhibits this processivity, we performed in vitro motility assays of two-headed full-length or truncated single-headed heavy chains. The results indicated that four to five molecules of the single-headed heavy chain were required for continuous microtubule sliding, while approximately one molecule of the two-headed full-length heavy chain was enough for the continuous sliding. The ratio of the stroking time to the total ATPase cycle time, which is a quantitative indicator of the processivity, was approximately 0.2 for the single-headed heavy chain, while it was approximately 0.6 for the full-length molecule. When two single-headed heavy chains were artificially linked by a coiled-coil of myosin, the processivity was restored. These results suggest that the two heads of a single cytoplasmic dynein communicate with each other to take processive steps along a microtubule.

Published

2006

19. ATP hydrolysis cycle-dependent tail motions in cytoplasmic dynein.

Author

Kon T, Mogami T, Ohkura R, Nishiura M, and Sutoh K

Subjects

Amino Acid Sequence, Animals, Binding Sites, Cytoplasm enzymology, Dictyostelium enzymology, Hydrolysis, Kinetics, Models, Biological, Mutation, Protein Conformation, Adenosine Triphosphate metabolism, Dyneins chemistry, Dyneins metabolism

Abstract

The motor protein dynein is predicted to move the tail domain, a slender rod-like structure, relative to the catalytic head domain to carry out its power stroke. Here, we investigated ATP hydrolysis cycle-dependent conformational dynamics of dynein using fluorescence resonance energy transfer analysis of the dynein motor domain labeled with two fluorescent proteins. We show that dynein adopts at least two conformational states (states I and II), and the tail undergoes ATP-induced motions relative to the head domain during transitions between the two states. Our measurements also suggest that in the course of the ATP hydrolysis cycle of dynein, the tail motion from state I to state II takes place in the ATP-bound state, whereas the motion from state II to state I occurs in the ADP-bound state. The latter tail motion may correspond to the predicted power stroke of dynein.

Published

2005

20. Distinct functions of nucleotide-binding/hydrolysis sites in the four AAA modules of cytoplasmic dynein.

Author

Kon T, Nishiura M, Ohkura R, Toyoshima YY, and Sutoh K

Subjects

Actin Cytoskeleton enzymology, Actin Cytoskeleton genetics, Actin Cytoskeleton physiology, Adenosine Triphosphate chemistry, Amino Acid Motifs genetics, Animals, Cytoplasm enzymology, Cytoplasm genetics, Dictyostelium enzymology, Dictyostelium genetics, Dictyostelium metabolism, Dyneins genetics, Dyneins isolation & purification, Enzyme Activation genetics, Green Fluorescent Proteins, Histidine genetics, Hydrolysis, Luminescent Proteins genetics, Microtubules enzymology, Microtubules metabolism, Microtubules physiology, Oligopeptides, Peptide Fragments genetics, Peptide Fragments metabolism, Peptide Fragments physiology, Peptides genetics, Photochemistry, Protein Binding genetics, Protein Structure, Tertiary genetics, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins isolation & purification, Recombinant Proteins metabolism, Subcellular Fractions enzymology, Subcellular Fractions metabolism, Ultraviolet Rays, Vanadates chemistry, Adenosine Triphosphate metabolism, Cytoplasm chemistry, Cytoplasm metabolism, Dyneins chemistry, Dyneins physiology

Abstract

Cytoplasmic dynein is a microtubule-based motor protein that is responsible for most intracellular retrograde transports along microtubule filaments. The motor domain of dynein contains six tandemly linked AAA (ATPases associated with diverse cellular activities) modules, with the first four containing predicted nucleotide-binding/hydrolysis sites (P1-P4). To dissect the functions of these multiple nucleotide-binding/hydrolysis sites, we expressed and purified Dictyostelium dynein motor domains in which mutations were introduced to block nucleotide binding at each of the four AAA modules, and then examined their detailed biochemical properties. The P1 mutant was trapped in a strong-binding state even in the presence of ATP and lost its motile activity. The P3 mutant also showed a high affinity for microtubules in the presence of ATP and lost most of the microtubule-activated ATPase activity, but retained microtubule sliding activity, although the sliding velocity of the mutant was more than 20-fold slower than that of the wild type. In contrast, mutation in the P2 or P4 site did not affect the apparent binding affinity of the mutant for microtubules in the presence of ATP, but reduced ATPase and microtubule sliding activities. These results indicate that ATP binding and its hydrolysis only at the P1 site are essential for the motor activities of cytoplasmic dynein, and suggest that the other nucleotide-binding/hydrolysis sites regulate the motor activities. Among them, nucleotide binding at the P3 site is not essential but is critical for microtubule-activated ATPase and motile activities of cytoplasmic dynein.

Published

2004

21. A single-headed recombinant fragment of Dictyostelium cytoplasmic dynein can drive the robust sliding of microtubules.

Author

Nishiura M, Kon T, Shiroguchi K, Ohkura R, Shima T, Toyoshima YY, and Sutoh K

Subjects

Animals, Dictyostelium, Dyneins genetics, Peptide Fragments physiology, Recombinant Proteins metabolism, Dyneins physiology, Microtubules physiology

Abstract

A cytoplasmic dynein is a microtubule-based motor protein involved in diverse cellular functions, such as organelle transport and chromosome segregation. The dynein has two ring-shaped heads that contain six repeats of the AAA domain responsible for ATP hydrolysis. It has been proposed that the ATPase-dependent swing of a stalk and a stem emerging from each of the heads generates the power stroke (Burgess, S.A. (2003) Nature 421, 715-718). To understand the molecular mechanism of the dynein power stroke, it is essential to establish an easy and reproducible method to express and purify the recombinant dynein with full motor activities. Here we report the expression and purification of the C-terminal 380-kDa fragment of the Dictyostelium cytoplasmic dynein heavy-chain fused with an affinity tag and green fluorescent protein. The purified single-headed recombinant protein drove the robust minus-end-directed sliding of microtubules at a velocity of 1.2 microm/s. This recombinant protein had a high basal ATPase activity (approximately 4s(-1)), which was further activated by >15-fold on the addition of 40 microM microtubules. These results show that the 380-kDa recombinant fragment retains all the structures required for motor functions, i.e. the ATPase activity highly stimulated by microtubules and the robust motility.

Published

2004