研究者業績
基本情報
- 所属
- 国立研究開発法人情報通信研究機構 未来ICT研究所 主管研究員 (NICT Fellow)兵庫県立大学 大学院 理学研究科 教授大阪大学大学院生命機能研究科 招聘教授
- 学位
- Ph. D.(The University of Tokyo)
- J-GLOBAL ID
- 200901042704978912
- researchmap会員ID
- 0000046003
- 外部リンク
学歴
1988年 (昭和63年) 東京大学大学院理学系研究科 博士課程修了 (理学博士)
職歴
1988年 帝京大学医学部助手、同講師を経て1993年(平成 5年)通信総合研究所(現在の情報通信研究機構)に入所。以来、関西支所(現在の未来ICT研究所)勤務。
1995年(平成7年)生体物性研究室室長、以降 バイオICTグループ グループリーダーを経て、2008年(平成20年)未来ICT研究センター長、2011年(平成23年)未来ICT研究所 所長 を歴任。2013年(平成25年) NICT Fellowとなり、同年、研究現場に主管研究員として復帰。2024年(令和6年)AI研究開発推進ユニット長、現在に至る。
受賞等
2005年(平成17年)第23回大阪科学賞
2005 年(平成17年)米国生物物理学会 Biophysical Society, Motility Subgroup Chair
2007年(平成19年)アルバータ大学・工学部・化学・物質工学科の DB Robinson Distinguished Speakers Series講演者
2009年(平成21年) 日本学術振興会 科学研究費優秀審査員表彰
2020年(令和2年)令和2年度 科学技術分野の文部科学大臣表彰 科学技術賞 研究部門
Service
2013年(平成25年)- 2019年 米国生物物理学会 Biophysical Journal Editorial Board members
2012年(平成24年)- 2024年 J. Muscle Res. Cell Motil. Executive Editor
研究概要
試験管内でタンパク質モータの機能を再構築する技術 (インビトロ運動アッセイ)を駆使して、タンパク質モータ 特にダイニンの運動機能の解明や制御の研究を推進してきた。また、このインビトロ運動アッセイを拡張することで、タンパク質フィラメントの運動方向制御の技術を開発するなど先駆的研究開発を行っている。
研究分野
1経歴
14-
2024年9月 - 現在
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2015年4月 - 現在
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2013年1月 - 現在
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2013年1月 - 2015年3月
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2011年4月 - 2012年12月
学歴
4-
- 1988年
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- 1988年
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- 1983年
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- 1983年
委員歴
4-
2016年 - 2017年
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2010年4月 - 2011年3月
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2008年1月 - 2008年12月
受賞
3論文
228-
Cell structure and function 50(1) 41-51 2025年2月18日The motility of biological molecular motors has typically been analyzed by in vitro reconstitution systems using motors isolated and purified from organs or expressed in cultured cells. The behavior of biomolecular motors within cells has frequently been reported to be inconsistent with that observed in reconstituted systems in vitro. Although this discrepancy has been attributed to differences in ionic strength and intracellular crowding, understanding how such parameters affect the motility of motors remains challenging. In this report, we investigated the impact of intracellular crowding in vitro on the mechanical properties of kinesin under a high ionic strength that is comparable to the cytoplasm. Initially, we characterized viscosity in a cell by using a kinesin motor lacking the cargo-binding domain. We then used polyethylene glycol to create a viscous environment in vitro comparable to the intracellular environment. Our results showed that kinesin frequently dissociated from microtubules under high ionic strength conditions. However, under conditions of both high ionic strength and crowding with polymers, the processive movement of kinesin persisted and increased in frequency. This setting reproduces the significant variations in the mechanical properties of motors measured in the intracellular environment and suggests a mechanism whereby kinesin maintains motility under the high ionic strengths found in cells.Key words: kinesin motility, molecular crowding, ionic strength, intracellular transport, processivity of molecular motors.
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Nano letters 2024年6月25日Mechanical stress significantly affects the physiological functions of cells, including tissue homeostasis, cytoskeletal alterations, and intracellular transport. As a major cytoskeletal component, microtubules respond to mechanical stimulation by altering their alignment and polymerization dynamics. Previously, we reported that microtubules may modulate cargo transport by one of the microtubule-associated motor proteins, dynein, under compressive mechanical stress. Despite the critical role of tensile stress in many biological functions, how tensile stress on microtubules regulates cargo transport is yet to be unveiled. The present study demonstrates that the low-level tensile stress-induced microtubule deformation facilitates dynein-driven transport. We validate our experimental findings using all-atom molecular dynamics simulation. Our study may provide important implications for developing new therapies for diseases that involve impaired intracellular transport.
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Biophysics and Physicobiology 21(2) n/a-n/a 2024年
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Communications chemistry 6(1) 80-80 2023年4月26日By facilitating a water/water phase separation (w/wPS), crowded biopolymers in cells form droplets that contribute to the spatial localization of biological components and their biochemical reactions. However, their influence on mechanical processes driven by protein motors has not been well studied. Here, we show that the w/wPS droplet spontaneously entraps kinesins as well as microtubules (MTs) and generates a micrometre-scale vortex flow inside the droplet. Active droplets with a size of 10-100 µm are generated through w/wPS of dextran and polyethylene glycol mixed with MTs, molecular-engineered chimeric four-headed kinesins and ATP after mechanical mixing. MTs and kinesin rapidly created contractile network accumulated at the interface of the droplet and gradually generated vortical flow, which can drive translational motion of a droplet. Our work reveals that the interface of w/wPS contributes not only to chemical processes but also produces mechanical motion by assembling species of protein motors in a functioning manner.
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Chemistry – A European Journal 28(30) 2022年5月25日 査読有り
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Science (New York, N.Y.) 375(6585) 1159-1164 2022年3月11日Intracellular transport is the basis of microscale logistics within cells and is powered by biomolecular motors. Mimicking transport for in vitro applications has been widely studied; however, the inflexibility in track design and control has hindered practical applications. Here, we developed protein-based motors that move on DNA nanotubes by combining a biomolecular motor dynein and DNA binding proteins. The new motors and DNA-based nanoarchitectures enabled us to arrange the binding sites on the track, locally control the direction of movement, and achieve multiplexed cargo transport by different motors. The integration of these technologies realized microscale cargo sorters and integrators that automatically transport molecules as programmed in DNA sequences on a branched DNA nanotube. Our system should provide a versatile, controllable platform for future applications.
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The Journal of cell biology 220(7) 2021年7月5日Multiciliated cells (MCCs) in tracheas generate mucociliary clearance through coordinated ciliary beating. Apical microtubules (MTs) play a crucial role in this process by organizing the planar cell polarity (PCP)-dependent orientation of ciliary basal bodies (BBs), for which the underlying molecular basis remains elusive. Herein, we found that the deficiency of Daple, a dishevelled-associating protein, in tracheal MCCs impaired the planar polarized apical MTs without affecting the core PCP proteins, causing significant defects in the BB orientation at the cell level but not the tissue level. Using live-cell imaging and ultra-high voltage electron microscope tomography, we found that the apical MTs accumulated and were stabilized by side-by-side association with one side of the apical junctional complex, to which Daple was localized. In vitro binding and single-molecule imaging revealed that Daple directly bound to, bundled, and stabilized MTs through its dimerization. These features convey a PCP-related molecular basis for the polarization of apical MTs, which coordinate ciliary beating in tracheal MCCs.
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Biochemical and biophysical research communications 523(4) 1014-1019 2020年3月19日 査読有りDynein motor proteins usually work as a group in vesicle transport, mitosis, and ciliary/flagellar beating inside cells. Despite the obvious importance of the functions of dynein, the effect of inter-dynein interactions on collective motility remains poorly understood due to the difficulty in building large dynein ensembles with defined geometry. Here, we describe a method to build dynein ensembles to investigate the collective motility of dynein on microtubules. Using electron microscopy, we show that tens to hundreds of cytoplasmic dynein monomers were anchored along a 4- or 10-helix DNA nanotube with an average periodicity of 19 or 44 nm (a programmed periodicity of 14 or 28 nm, respectively). They drove the sliding movement of DNA nanotubes along microtubules at a velocity of 170-620 nm/s. Reducing the stiffness of DNA nanotubes made the nanotube movement discontinuous and considerably slower. Decreasing the spacing between motors simply slowed down the nanotube movement. This slowdown was independent of the number of motors involved but heavily dependent on motor-motor distance. This suggests that steric hindrance or mechanical coupling between dynein molecules was responsible for the slowdown. Furthermore, we observed cyclical buckling of DNA nanotubes on microtubules, reminiscent of ciliary/flagellar beating. These results highlight the importance of the geometric arrangement of dynein motors on their collective motility.
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ACS Applied Materials and Interfaces 2020年
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Science advances 6(4) eaax7413 2020年1月 査読有りKinesin is a motor protein that plays important roles in a variety of cellular functions. In vivo, multiple kinesin molecules are bound to cargo and work as a team to produce larger forces or higher speeds than a single kinesin. However, the coordination of kinesins remains poorly understood because of the experimental difficulty in controlling the number and arrangement of kinesins, which are considered to affect their coordination. Here, we report that both the number and spacing significantly influence the velocity of microtubules driven by nonprocessive kinesin-14 (Ncd), whereas neither the number nor the spacing changes the velocity in the case of highly processive kinesin-1. This result was realized by the optimum nanopatterning method of kinesins that enables immobilization of a single kinesin on a nanopillar. Our proposed method enables us to study the individual effects of the number and spacing of motors on the collective dynamics of multiple motors.
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Advanced biosystems 3(9) e1900130 2019年9月Multielectrode arrays (MEAs) are versatile tools that are used for chronic recording and stimulation of neural cells and tissues. Driven by the recent progress in understanding of how neuronal growth and function respond to scaffold stiffness, development of MEAs with a soft cell-to-device interface has gained importance not only for in vivo but also for in vitro applications. However, the passivation layer, which constitutes the majority of the cell-device interface, is typically prepared with stiff materials. Herein, a fabrication of an MEA device with an ultrasoft passivation layer is described, which takes advantage of inkjet printing and a polydimethylsiloxane (PDMS) gel with a stiffness comparable to that of the brain. The major challenge in using the PDMS gel is that it cannot be patterned to expose the sensing area of the electrode. This issue is resolved by printing 3D micropillars at the electrode tip. Primary cortical neurons are grown on the fabricated device, and effective stimulation of the culture confirms functional cell-device coupling. The 3D MEA device with an ultrasoft interface provides a novel platform for investigating evoked activity and drug responses of living neuronal networks cultured in a biomimetic environment for both fundamental research and pharmaceutical applications.
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Nanoscale 11(20) 9879-9887 2019年5月28日 査読有りMotor proteins function in in vivo ensembles to achieve cargo transport, flagellum motion, and mitotic cell division. Although the cooperativity of multiple motors is indispensable for physiological function, reconstituting the arrangement of motors in vitro is challenging, so detailed analysis of the functions of motor ensembles has not yet been achieved. Here, we developed an assay platform to study the motility of microtubules driven by a defined number of kinesin motors spaced in a definite manner. Gold (Au) nano-pillar arrays were fabricated on a silicon/silicon dioxide (Si/SiO2) substrate with spacings of 100 nm to 500 nm. The thiol-polyethylene glycol (PEG)-biotin self-assembled monolayer (SAM) and silane-PEG-CH3 SAM were then selectively formed on the pillars and SiO2 surface, respectively. This allowed for both immobilization of kinesin molecules on Au nano-pillars in a precise manner and repulsion of kinesins from the SiO2 surface. Using arrayed kinesin motors, we report that motor number and spacing do not influence the motility of microtubules driven by kinesin-1 motors. This assay platform is applicable to all kinds of biotinylated motors, allows the study of the effects of motor number and spacing, and is expected to reveal novel behaviors of motor proteins.
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Scientific Reports 8(1) 15550 2018年10月19日 査読有り
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Cell Structure and Function 43(1) 1-14 2018年1月1日 査読有り
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22nd International Conference on Miniaturized Systems for Chemistry and Life Sciences, MicroTAS 2018 4 2256-2257 2018年
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2017 IEEE 17th International Conference on Nanotechnology, NANO 2017 311-314 2017年11月21日 査読有り
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JOURNAL OF BIOLOGICAL CHEMISTRY 292(26) 10998-11008 2017年6月 査読有り
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Proceedings of the National Academy of Sciences of the United States of America 110(2) 501-506 2017年3月14日 査読有り
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NATURE NANOTECHNOLOGY 12(3) 233-+ 2017年3月 査読有り
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Dyneins: Dynein Mechanics, Dysfunction, and Disease: Second Edition 2 2-35 2017年 査読有り招待有り
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SCIENTIFIC REPORTS 7 39902 2017年1月 査読有り
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BIOPHYSICAL JOURNAL 111(2) 373-385 2016年7月 査読有り
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BICT 2015 - 9th EAI International Conference on Bio-Inspired Information and Communications Technologies 2016年5月24日 査読有り
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IEEE INTELLIGENT SYSTEMS 30(5) 2-7 2015年9月 査読有り
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BIOPHYSICAL JOURNAL 108(12) 2843-2853 2015年6月 査読有り
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FASEB JOURNAL 29(1) 81-94 2015年1月 査読有り
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NATURE CELL BIOLOGY 16(11) 1118-+ 2014年11月 査読有り
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BIOPHYSICAL JOURNAL 106(10) 2157-2165 2014年5月 査読有り
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Journal of Cellular Automata 9(2-3) 111-123 2014年
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生物物理 54(1) S221 2014年
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生物物理 53(3) 149-152 2013年5月25日A vortex lattice of microtubules emerges in a dynein-microtubule motility assay. To clarify the physical mechanism of this collective behavior, the trajectory of isolated microtubules and the interaction between microtubules were experimentally examined. We found that the trajectory of an isolated microtubule has a long correlation time of its curvature and microtubules interact with each other through only nematic steric interaction. We developed the mathematical model based on the experimentally confirmed characteristics and concluded that long correlation time of the motion of an isolated microtubule and high density of microtubules are the key factors for the vortex lattice emergence.<br>
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JOURNAL OF MUSCLE RESEARCH AND CELL MOTILITY 34(2) 115-123 2013年5月 査読有り
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JOURNAL OF BACTERIOLOGY 195(5) 958-964 2013年3月 査読有り
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生物物理 53(1) S239 2013年
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2013 INTERNATIONAL SYMPOSIUM ON COMPUTATIONAL MODELS FOR LIFE SCIENCES 1559 343-352 2013年 査読有り
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PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA 110(2) 501-506 2013年1月 査読有り
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Proceedings of the National Academy of Sciences of the United States of America 109(50) 20497-20502 2012年12月 査読有り
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STRUCTURE 20(10) 1670-1680 2012年10月 査読有り
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JOURNAL OF BIOLOGICAL CHEMISTRY 287(36) 30711-30718 2012年8月 査読有り
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Nature communications 3 1022 2012年8月 査読有り
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JOURNAL OF STRUCTURAL BIOLOGY 178(3) 329-337 2012年6月 査読有り
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NATURE 483(7390) 448-452 2012年3月 査読有り
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JAPANESE JOURNAL OF APPLIED PHYSICS 51(2) 2012年2月 査読有り
MISC
133-
International Journal of Molecular Sciences 21(8) 2020年4月2日
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BIOPHYSICAL JOURNAL 116(3) 257A-257A 2019年2月
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2018年6月4日Active matter consists of self-propelled elements exhibits fascinating collective motions ranging from biological to artificial systems. Among wide varieties of active matter systems, reconstituted bio-filaments moving on molecular motor turf interacting purely by physical interactions provides the fundamental test ground for understanding biological motility. However, until now, multi-filament collisions,depletion agents or binding molecules has been required for the emergence of ordered patterns in motility assay. Thus, whether simple physical interactions during collisions such as steric effect without depletion nor binding agents are sufficient or not for producing ordered patterns in motility assays remains still elusive. In this article, we constructed a motility assay purely consists of kinesin motor and microtubule in which the frequency of binary collision can be controlled without using depletion nor binding agents. By controlling strength of steric interaction and density of microtubules, we found different states; disordered state, long-range orientationally ordered state, liquid-gas-like phase separated state, and transitions between them. We found that a balance between cross over and aligning events in collisions controls transition from disorder to global ordered state, while excessively strong steric effect leads to the phase separated clusters. Furthermore, macroscopic chiral symmetry breaking observed as a global rotation of nematic order observed in this experiment could be attributed to the chirality at molecular level. Numerical simulations in which we change strength of volume exclusion reproduce these experimental results. Moreover, it reveals the transition from long-range alignment to nematic bands then to aggregations. This study may provide new insights into dynamic ordering by self-propelled elements through a purely physical interaction.
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PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA 114(11) E2264-E2264 2017年3月
書籍等出版物
6所属学協会
4共同研究・競争的資金等の研究課題
22-
日本学術振興会 科学研究費助成事業 2021年4月 - 2025年3月
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日本学術振興会 科学研究費助成事業 2021年4月 - 2025年3月
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日本学術振興会 科学研究費助成事業 2020年7月 - 2024年3月
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日本学術振興会 科学研究費補助金 基盤研究(C) 2017年4月 - 2020年3月
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日本学術振興会 科学研究費助成事業 2015年4月 - 2018年3月
産業財産権
3-
特開2002-69092
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特開2003-114185
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特開2004-109695