Updated on 2024/12/21

写真a

 
EGUCHI Masatoshi
 
Organization
Academic Assembly Institute of Medicine and Dentistry Specially Appointed Assistant Professor
Graduate School of Medical and Dental Sciences Specially Appointed Assistant Professor
Title
Specially Appointed Assistant Professor
External link

Degree

  • 博士(理学) ( 東京大学 )

Research Interests

  • 生物発光

  • バイオイメージング

  • ルシフェラーゼ

  • タンパク質

Research Areas

  • Nanotechnology/Materials / Bio chemistry

  • Others / Others  / 分析化学

  • Life Science / Molecular biology

Research History (researchmap)

  • Niigata University   Graduate School of Medical and Dental Sciences   Specially Appointed Assistant Professor

    2024.3

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  • The University of Tokyo   Graduate School of Science Department of Chemistry

    2022.4 - 2024.2

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Research History

  • Niigata University   Graduate School of Medical and Dental Sciences   Specially Appointed Assistant Professor

    2024.3

  • Niigata University   Institute of Medicine and Dentistry, Academic Assembly   Specially Appointed Assistant Professor

    2024.3

 

Papers

  • A Method for Bioluminescence-Based RNA Monitoring Using Split-Luciferase Reconstitution Techniques

    Masatoshi Eguchi, Hideaki Yoshimura, Takeaki Ozawa

    Methods in Molecular Biology   2875   9 - 20   2025

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    Authorship:Lead author   Publishing type:Part of collection (book)  

    A bioluminescence-based RNA monitoring method in living cells was developed using a split NanoLuc (NLuc) reconstitution technique. For specific recognition of a target RNA sequence, a mutant PUM-HD (mPUM) was used. The method was applied to β-actin mRNA in various cells, including primary cultures of rat hippocampal neurons. It allowed for continuous observation of intracellular localization distribution of the target mRNA in living cells, providing insights into various biological phenomena involving intracellular RNA localization and dynamics.

    DOI: 10.1007/978-1-0716-4248-1_2

    Scopus

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  • Split Luciferase-Fragment Reconstitution for Unveiling RNA Localization and Dynamics in Live Cells. Reviewed International journal

    Masatoshi Eguchi, Hideaki Yoshimura, Yoshibumi Ueda, Takeaki Ozawa

    ACS sensors   8 ( 11 )   4055 - 4063   2023.11

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    Authorship:Lead author   Language:English   Publishing type:Research paper (scientific journal)  

    The intracellular distribution and dynamics of RNAs play pivotal roles in various physiological phenomena. The ability to monitor the amount and localization of endogenous RNAs in living cells allows for elucidating the mechanisms of various intracellular events. Protein-based fluorescent RNA probes are now widely used to visualize and analyze RNAs in living cells. However, continuously monitoring the temporal changes in RNA localization and dynamics in living cells is challenging. In this study, we developed a bioluminescent probe for spatiotemporal monitoring of RNAs in living cells by using a split-luciferase reconstitution technique. The probe consists of split fragments of a bioluminescent protein, NanoLuc, connected with RNA-binding protein domains generated from a custom-made mutation of a PUM-HD. The probe showed rapid luminescence intensity changes in response to an increase or decrease in the amount of a target RNA in vitro. In live-cell imaging, temporal alteration of the intracellular distribution of endogenous β-actin mRNA was visualized in response to extracellular stimulation. Furthermore, the application of the probe to the visualization of the specific localization of β-actin mRNA in primary hippocampal neurons was conducted. These results demonstrate the capability of the bioluminescent RNA probe to monitor the changes in localization, dynamics, and the amount of target RNA in living cells.

    DOI: 10.1021/acssensors.3c01080

    PubMed

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  • A Series of Furimazine Derivatives for Sustained Live-Cell Bioluminescence Imaging and Application to the Monitoring of Myogenesis at the Single-Cell Level. Reviewed International journal

    Mariko Orioka, Masatoshi Eguchi, Yuki Mizui, Yuma Ikeda, Akihiro Sakama, Qiaojing Li, Hideaki Yoshimura, Takeaki Ozawa, Daniel Citterio, Yuki Hiruta

    Bioconjugate chemistry   33 ( 3 )   496 - 504   2022.3

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    Language:English   Publishing type:Research paper (scientific journal)  

    Bioluminescence (BL) imaging, which utilizes light emitted through the enzymatic reaction of luciferase oxidizing its substrate luciferin, enables sensitive and noninvasive monitoring of life phenomena. Herein, we developed a series of caged furimazine (FMZ) derivatives by introducing a protective group at the C-3 position and a hydroxy group at the C-6 phenyl ring to realize long-term live-cell BL imaging based on the NanoLuc (NLuc)/NanoKAZ (NKAZ)-FMZ system. The membrane permeability and cytotoxicity of the substrates were evaluated and related to their hydrophobicity. Among the series, the derivative with the bulkiest protective group (adamantanecarbonyl group) and a hydroxy substituent (named Ad-FMZ-OH) showed significantly prolonged and constant BL signal in cells expressing NLuc compared to the native FMZ substrate. This derivative enabled continuous BL imaging at the single-cell level for 24 h. Furthermore, we applied Ad-FMZ-OH to BL imaging of myocyte fusion and succeeded in the consecutive and sensitive monitoring at a single-cell level over a day. In summary, NLuc/NKAZ-caged FMZ derivatives have the potential to be applied to live-cell BL imaging of various life phenomena that require long-term observation.

    DOI: 10.1021/acs.bioconjchem.2c00035

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  • Long-term single cell bioluminescence imaging with C-3 position protected coelenterazine analogues. Reviewed International journal

    Yuki Mizui, Masatoshi Eguchi, Masanobu Tanaka, Yuma Ikeda, Hideaki Yoshimura, Takeaki Ozawa, Daniel Citterio, Yuki Hiruta

    Organic & biomolecular chemistry   19 ( 3 )   579 - 586   2021.1

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    Authorship:Lead author   Language:English   Publishing type:Research paper (scientific journal)  

    Bioluminescence is a powerful imaging modality for monitoring biological phenomena both in vitro and in vivo. Bioluminescence imagin (BLI) is becoming a seamless imaging technology covering the range from cells to organs of small animals. Long-term imaging at the single cell level would lead to a true understanding of the dynamics of life phenomena. This work presents a long-term single cell bioluminescence imaging technology accomplished with C-3 position protected furimazines (FMZs), a CTZ analogues, which generate intense blue emission when paired with a highly stable engineered luciferase, Nanoluc. Four types of FMZs protected at the C-3 position have been synthesized. The type and steric bulkiness of the protection group strongly contributed to storage stability and the kinetics of the bioluminescence reactions of the analogues in human living cells. In particular, two developed FMZ analogues resulted in significantly longer bioluminescence emission with higher S/N ratio than FMZ at single cell level. Long-term bioluminescence single cell imaging technology with the developed FMZ analogues will lead to seamless imaging in the range from cells to organs of small animals.

    DOI: 10.1039/d0ob02020f

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  • Spatiotemporal analysis with a genetically encoded fluorescent RNA probe reveals TERRA function around telomeres. Reviewed International journal

    Toshimichi Yamada, Hideaki Yoshimura, Rintaro Shimada, Mitsuru Hattori, Masatoshi Eguchi, Takahiro K Fujiwara, Akihiro Kusumi, Takeaki Ozawa

    Scientific reports   6   38910 - 38910   2016.12

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    Language:English   Publishing type:Research paper (scientific journal)  

    Telomeric repeat-containing RNA (TERRA) controls the structure and length of telomeres through interactions with numerous telomere-binding proteins. However, little is known about the mechanism by which TERRA regulates the accessibility of the proteins to telomeres, mainly because of the lack of spatiotemporal information of TERRA and its-interacting proteins. We developed a fluorescent probe to visualize endogenous TERRA to investigate its dynamics in living cells. Single-particle fluorescence imaging revealed that TERRA accumulated in a telomere-neighboring region and trapped diffusive heterogeneous nuclear ribonucleoprotein A1 (hnRNPA1), thereby inhibiting hnRNPA1 localization to the telomere. These results suggest that TERRA regulates binding of hnRNPA1 to the telomere in a region surrounding the telomere, leading to a deeper understanding of the mechanism of TERRA function.

    DOI: 10.1038/srep38910

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MISC

  • Development of Bioluminescent Probes for Real-time Visualization and Detection of Endogenous RNA in Living Single Cells

    江口正敏, 吉村英哲, 上田善文, 小澤岳昌

    日本分子生物学会年会プログラム・要旨集(Web)   44th   2021

  • 生物発光プローブ開発を通じた生細胞内在性RNA1細胞可視化定量法の創出

    江口正敏, 吉村英哲, 小澤岳昌

    日本分析化学会年会講演要旨集(Web)   69th   2020

  • 発光プローブによる生細胞内RNAの可視化定量を志向した分析法の開発

    江口正敏, 吉村英哲, 小澤岳昌

    日本分析化学会年会講演要旨集(Web)   68th   2019

  • 生体内RNA定量可視化を志向した新規発光プローブの開発

    江口正敏, 吉村英哲, 小澤岳昌

    分析化学討論会講演要旨集   79th   2019