研究者業績

大野 伸彦

オオノ ノブヒコ  (Nobuhiko Ohno)

基本情報

所属
自治医科大学 医学部解剖学講座組織学部門 教授
生理学研究所 超微形態研究部門 客員教授
学位
医学博士

J-GLOBAL ID
201301039074350199
researchmap会員ID
B000229500

外部リンク

平成7年 3月 筑波大学付属駒場高等学校 卒
平成13年 3月 東京大学医学部医学科 卒
平成13年 6月 東京大学医学部付属病院 内科初期研修医
平成14年 6月 公立昭和病院 内科初期研修医
平成18年 9月 山梨大学大学院 医学工学総合教育部 博士課程修了 医学博士
平成18年 10月 山梨大学大学院 助手 (解剖学講座第一教室)
平成19年 4月 山梨大学大学院 助教 (解剖学講座分子組織学教室)
平成19年 10月 山梨大学大学院 講師 (解剖学講座分子組織学教室)
平成20年 4月 米国クリーブランドクリニック 博士研究員
(平成21年 7月 全米多発性硬化症協会 ポストドクトラルフェローシップ)
平成24年 8月 山梨大学大学院 准教授 (解剖学講座分子組織学教室)
平成25年 4月 自然科学研究機構 生理学研究所 客員准教授
平成28年 4月 生理学研究所 特任准教授 (分子神経生理部門)
平成29年 5月 自治医科大学 准教授 (解剖学講座組織学部門)
平成29年 5月 生理学研究所 兼任准教授 (分子神経生理部門)
平成30年 4月 自治医科大学 教授 (解剖学講座組織学部門)
平成30年 4月 生理学研究所 教授(兼任) (分子細胞生理研究領域)
平成31年 4月 生理学研究所 客員教授 (超微形態研究部門)

学歴

 2

論文

 247
  • Makoto Abe, Nobuhiko Ohno
    Microscopy (Oxford, England) 2024年10月18日  
    Structural observations are essential for the advancement of life science. Volume electron microscopy has recently realized remarkable progress in the three-dimensional analyses of biological specimens for elucidating complex ultrastructures in several fields of life science. The advancements in volume electron microscopy technologies have led to improvements, including higher resolution, more stability, and the ability to handle larger volumes. Although human applications of volume electron microscopy remain limited, the reported applications in various organs have already provided previously unrecognized features of human tissues and also novel insights of human diseases. Simultaneously, the application of volume electron microscopy to human studies faces challenges, including ethical and clinical hurdles, costs of data storage and analysis, and efficient and automated imaging methods for larger volume. Solutions including the use of residual clinical specimens and data analysis based on artificial intelligence would address those issues and establish the role of volume electron microscopy in human structural research. Future advancements in volume electron microscopy are anticipated to lead to transformative discoveries in basic research and clinical practice, deepening our understanding of human health and diseases for better diagnostic and therapeutic strategies.
  • Yasuyuki Osanai, Yao Lulu Xing, Shinya Mochizuki, Kenta Kobayashi, Jihane Homman-Ludiye, Amali Cooray, Jasmine Poh, Ayumu Inutsuka, Nobuhiko Ohno, Tobias D. Merson
    Molecular Therapy - Methods & Clinical Development 32(3) 101288-101288 2024年9月  
  • Reiji Yamazaki, Nobuhiko Ohno
    Acta histochemica et cytochemica 57(4) 131-135 2024年8月29日  
    Multiple sclerosis, neuromyelitis optica, Guillain-Barré syndrome and chronic inflammatory demyelinating polyradiculoneuropathy are representative demyelinating diseases of the central and peripheral nervous system. Remyelination by myelin forming cells is important for functional recovery from the neurological deficits caused in the demyelinating diseases. Lysophosphatidylcholine-induced demyelination in mice is commonly used to identify and study the molecular pathways of demyelination and remyelination. However, detection of focally demyelinated lesions is difficult and usually requires sectioning of demyelinated lesions in tissues for microscopic analysis. In this review, we describe the development and application of a novel vital staining method for labeling demyelinated lesions using intraperitoneal injection of neutral red (NR) dye. NR labeling reduces the time and effort required to search for demyelinated lesions in tissues, and facilitates electron microscopic analysis of myelin structures. NR labeling also has the potential to contribute to the elucidation of pathologies in the central and peripheral nervous system and assist with identification of drug candidates that promote remyelination.
  • Reiji Yamazaki, Nobuhiko Ohno
    Journal of neurochemistry 168(9) 2264-2274 2024年8月13日  
    Myelin is an insulator that forms around axons that enhance the conduction velocity of nerve fibers. Oligodendrocytes dramatically change cell morphology to produce myelin throughout the central nervous system (CNS). Cytoskeletal alterations are critical for the morphogenesis of oligodendrocytes, and actin is involved in cell differentiation and myelin wrapping via polymerization and depolymerization, respectively. Various protein members of the myosin superfamily are known to be major binding partners of actin filaments and have been intensively researched because of their involvement in various cellular functions, including differentiation, cell movement, membrane trafficking, organelle transport, signal transduction, and morphogenesis. Some members of the myosin superfamily have been found to play important roles in the differentiation of oligodendrocytes and in CNS myelination. Interestingly, each member of the myosin superfamily expressed in oligodendrocyte lineage cells also shows specific spatial and temporal expression patterns and different distributions. In this review, we summarize previous findings related to the myosin superfamily and discuss how these molecules contribute to myelin formation and regeneration by oligodendrocytes.
  • Nobuhiko Ohno, Fuyuki Karube, Fumino Fujiyama
    Neuroscience research 2024年6月22日  
    The brain networks responsible for adaptive behavioral changes are based on the physical connections between neurons. Light and electron microscopy have long been used to study neural projections and the physical connections between neurons. Volume electron microscopy has recently expanded its scale of analysis due to methodological advances, resulting in complete wiring maps of neurites in a large volume of brain tissues and even entire nervous systems in a growing number of species. However, structural approaches frequently suffer from inherent limitations in which elements in images are identified solely by morphological criteria. Recently, an increasing number of tools and technologies have been developed to characterize cells and cellular components in the context of molecules and gene expression. These advancements include newly developed probes for visualization in electron microscopic images as well as correlative integration methods for the same elements across multiple microscopic modalities. Such approaches advance our understanding of interactions between specific neurons and circuits and may help to elucidate novel aspects of the basal ganglia network involving dopamine neurons. These advancements are expected to reveal mechanisms for processing adaptive changes in specific neural circuits that modulate brain functions.

MISC

 104

担当経験のある科目(授業)

 3

共同研究・競争的資金等の研究課題

 14