髙橋 重成

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Name(Kanji/Kana/Abecedarium Latinum)
髙橋 重成/タカハシ ノブアキ/Takahashi, Nobuaki
Primary Affiliation(Org1/Job title)
The HAKUBI Center for Advanced Research/Program-Specific Associate Professor
Contact Address
Type Address(Japanese) Address(English)
Office 京都市西京区京都大学桂キャンパスA4棟219号室
Phone
Type Number
Office 075-383-2763
E-mail Address
E-mail address
takahashi @ sbchem.kyoto-u.ac.jp
Academic Degree
Field(Japanese) Field(English) University(Japanese) University(English) Method
修士(工学) 京都大学
博士(工学) 京都大学
Graduate School
University(Japanese) University(English) Faculty(Japanese) Faculty(English) Major(Japanese) Major(English) Degree
京都大学 大学院工学研究科修士課程合成・生物化学専攻 修了
京都大学 大学院工学研究科博士後期課程合成・生物化学専攻 修了
Undergraduate School / Major(s)
University(Japanese) University(English) Faculty(Japanese) Faculty(English) Major(s)(Japanese) Major(s)(English) Degree
京都大学 工学部工業化学科 卒業
High School
Highschool Kana
立教新座高等学校 りっきょうにいざこうとうがっこう
Work Experience
Period Organization(Japanese) Organization(English) Job title(Japanese) Job title(English)
2010/12/01-2014/05/31 京都大学 先端医工学研究ユニット 特定助教
2014/06/01-2015/05/31 ハーバード大学医学大学院 細胞生物学分野 博士研究員
2015/06/01-2019/03/31 ハーバード大学医学大学院 細胞生物学分野 専任講師
researchmap URL
https://researchmap.jp/0404
Published Papers
Author Author(Japanese) Author(English) Title Title(Japanese) Title(English) Bibliography Bibliography(Japanese) Bibliography(English) Publication date Refereed paper Language Publishing type Disclose
Takahashi N, Chen HY, Harris IS, Stover DG, Selfors LM, Bronson RT, Deraedt T, Cichowski K, Welm AL, Mori Y, Mills GB, Brugge JS Takahashi N, Chen HY, Harris IS, Stover DG, Selfors LM, Bronson RT, Deraedt T, Cichowski K, Welm AL, Mori Y, Mills GB, Brugge JS Takahashi N, Chen HY, Harris IS, Stover DG, Selfors LM, Bronson RT, Deraedt T, Cichowski K, Welm AL, Mori Y, Mills GB, Brugge JS Cancer Cells Co-opt the Neuronal Redox-Sensing Channel TRPA1 to Promote Oxidative-Stress Tolerance. Cancer Cells Co-opt the Neuronal Redox-Sensing Channel TRPA1 to Promote Oxidative-Stress Tolerance. Cancer Cells Co-opt the Neuronal Redox-Sensing Channel TRPA1 to Promote Oxidative-Stress Tolerance. Cancer cell, 33, 6, 985-1003.e7 Cancer cell, 33, 6, 985-1003.e7 Cancer cell, 33, 6, 985-1003.e7 2018/06 Refereed Disclose to all
Miyake T, Nakamura S, Meng Z, Hamano S, Inoue K, Numata T, Takahashi N, Nagayasu K, Shirakawa H, Mori Y, Nakagawa T, Kaneko S Miyake T, Nakamura S, Meng Z, Hamano S, Inoue K, Numata T, Takahashi N, Nagayasu K, Shirakawa H, Mori Y, Nakagawa T, Kaneko S Miyake T, Nakamura S, Meng Z, Hamano S, Inoue K, Numata T, Takahashi N, Nagayasu K, Shirakawa H, Mori Y, Nakagawa T, Kaneko S Distinct Mechanism of Cysteine Oxidation-Dependent Activation and Cold Sensitization of Human Transient Receptor Potential Ankyrin 1 Channel by High and Low Oxaliplatin. Distinct Mechanism of Cysteine Oxidation-Dependent Activation and Cold Sensitization of Human Transient Receptor Potential Ankyrin 1 Channel by High and Low Oxaliplatin. Distinct Mechanism of Cysteine Oxidation-Dependent Activation and Cold Sensitization of Human Transient Receptor Potential Ankyrin 1 Channel by High and Low Oxaliplatin. Frontiers in physiology, 8, 878 Frontiers in physiology, 8, 878 Frontiers in physiology, 8, 878 2017 Refereed Disclose to all
Mori Y, Takahashi N, Kurokawa T, Kiyonaka S Mori Y, Takahashi N, Kurokawa T, Kiyonaka S Mori Y, Takahashi N, Kurokawa T, Kiyonaka S TRP channels in oxygen physiology: distinctive functional properties and roles of TRPA1 in O<sub>2</sub> sensing. TRP channels in oxygen physiology: distinctive functional properties and roles of TRPA1 in O<sub>2</sub> sensing. TRP channels in oxygen physiology: distinctive functional properties and roles of TRPA1 in O<sub>2</sub> sensing. Proceedings of the Japan Academy. Series B, Physical and biological sciences, 93, 7, 464-482 Proceedings of the Japan Academy. Series B, Physical and biological sciences, 93, 7, 464-482 Proceedings of the Japan Academy. Series B, Physical and biological sciences, 93, 7, 464-482 2017 Refereed Disclose to all
Miyake T, Nakamura S, Zhao M, So K, Inoue K, Numata T, Takahashi N, Shirakawa H, Mori Y, Nakagawa T, Kaneko S Miyake T, Nakamura S, Zhao M, So K, Inoue K, Numata T, Takahashi N, Shirakawa H, Mori Y, Nakagawa T, Kaneko S Miyake T, Nakamura S, Zhao M, So K, Inoue K, Numata T, Takahashi N, Shirakawa H, Mori Y, Nakagawa T, Kaneko S Cold sensitivity of TRPA1 is unveiled by the prolyl hydroxylation blockade-induced sensitization to ROS. Cold sensitivity of TRPA1 is unveiled by the prolyl hydroxylation blockade-induced sensitization to ROS. Cold sensitivity of TRPA1 is unveiled by the prolyl hydroxylation blockade-induced sensitization to ROS. Nature communications, 7, 12840 Nature communications, 7, 12840 Nature communications, 7, 12840 2016/09 Refereed Disclose to all
Shibata T, Takahashi K, Matsubara Y, Inuzuka E, Nakashima F, Takahashi N, Kozai D, Mori Y, Uchida K Shibata T, Takahashi K, Matsubara Y, Inuzuka E, Nakashima F, Takahashi N, Kozai D, Mori Y, Uchida K Shibata T, Takahashi K, Matsubara Y, Inuzuka E, Nakashima F, Takahashi N, Kozai D, Mori Y, Uchida K Identification of a prostaglandin D2 metabolite as a neuritogenesis enhancer targeting the TRPV1 ion channel. Identification of a prostaglandin D2 metabolite as a neuritogenesis enhancer targeting the TRPV1 ion channel. Identification of a prostaglandin D2 metabolite as a neuritogenesis enhancer targeting the TRPV1 ion channel. Scientific reports, 6, 21261 Scientific reports, 6, 21261 Scientific reports, 6, 21261 2016/02 Refereed Disclose to all
Ogawa N, Kurokawa T, Fujiwara K, Polat OK, Badr H, Takahashi N, Mori Y Ogawa N, Kurokawa T, Fujiwara K, Polat OK, Badr H, Takahashi N, Mori Y Ogawa N, Kurokawa T, Fujiwara K, Polat OK, Badr H, Takahashi N, Mori Y Functional and Structural Divergence in Human TRPV1 Channel Subunits by Oxidative Cysteine Modification. Functional and Structural Divergence in Human TRPV1 Channel Subunits by Oxidative Cysteine Modification. Functional and Structural Divergence in Human TRPV1 Channel Subunits by Oxidative Cysteine Modification. The Journal of biological chemistry, 291, 8, 4197-4210 The Journal of biological chemistry, 291, 8, 4197-4210 The Journal of biological chemistry, 291, 8, 4197-4210 2016/02 Refereed Disclose to all
Mori Y, Takahashi N, Ogawa N, Gudermann T Mori Y, Takahashi N, Ogawa N, Gudermann T Mori Y, Takahashi N, Ogawa N, Gudermann T Oxygen physiology: sensors and ion channels. Oxygen physiology: sensors and ion channels. Oxygen physiology: sensors and ion channels. Pflugers Archiv : European journal of physiology, 468, 1, 1-2 Pflugers Archiv : European journal of physiology, 468, 1, 1-2 Pflugers Archiv : European journal of physiology, 468, 1, 1-2 2016/01 Disclose to all
Mori Y, Takahashi N, Polat OK, Kurokawa T, Takeda N, Inoue M Mori Y, Takahashi N, Polat OK, Kurokawa T, Takeda N, Inoue M Mori Y, Takahashi N, Polat OK, Kurokawa T, Takeda N, Inoue M Redox-sensitive transient receptor potential channels in oxygen sensing and adaptation. Redox-sensitive transient receptor potential channels in oxygen sensing and adaptation. Redox-sensitive transient receptor potential channels in oxygen sensing and adaptation. Pflugers Archiv : European journal of physiology, 468, 1, 85-97 Pflugers Archiv : European journal of physiology, 468, 1, 85-97 Pflugers Archiv : European journal of physiology, 468, 1, 85-97 2016/01 Refereed Disclose to all
Shimizu S, Yonezawa R, Hagiwara T, Yoshida T, Takahashi N, Hamano S, Negoro T, Toda T, Wakamori M, Mori Y, Ishii M Shimizu S, Yonezawa R, Hagiwara T, Yoshida T, Takahashi N, Hamano S, Negoro T, Toda T, Wakamori M, Mori Y, Ishii M Shimizu S, Yonezawa R, Hagiwara T, Yoshida T, Takahashi N, Hamano S, Negoro T, Toda T, Wakamori M, Mori Y, Ishii M Inhibitory effects of AG490 on H2O2-induced TRPM2-mediated Ca(2+) entry. Inhibitory effects of AG490 on H2O2-induced TRPM2-mediated Ca(2+) entry. Inhibitory effects of AG490 on H2O2-induced TRPM2-mediated Ca(2+) entry. European journal of pharmacology, 742, 22-30 European journal of pharmacology, 742, 22-30 European journal of pharmacology, 742, 22-30 2014/11 Refereed Disclose to all
Takahashi N, Hamada-Nakahara S, Itoh Y, Takemura K, Shimada A, Ueda Y, Kitamata M, Matsuoka R, Hanawa-Suetsugu K, Senju Y, Mori MX, Kiyonaka S, Kohda D, Kitao A, Mori Y, Suetsugu S Takahashi N, Hamada-Nakahara S, Itoh Y, Takemura K, Shimada A, Ueda Y, Kitamata M, Matsuoka R, Hanawa-Suetsugu K, Senju Y, Mori MX, Kiyonaka S, Kohda D, Kitao A, Mori Y, Suetsugu S Takahashi N, Hamada-Nakahara S, Itoh Y, Takemura K, Shimada A, Ueda Y, Kitamata M, Matsuoka R, Hanawa-Suetsugu K, Senju Y, Mori MX, Kiyonaka S, Kohda D, Kitao A, Mori Y, Suetsugu S TRPV4 channel activity is modulated by direct interaction of the ankyrin domain to PI(4,5)P₂. TRPV4 channel activity is modulated by direct interaction of the ankyrin domain to PI(4,5)P₂. TRPV4 channel activity is modulated by direct interaction of the ankyrin domain to PI(4,5)P₂. Nature communications, 5, 4994 Nature communications, 5, 4994 Nature communications, 5, 4994 2014/09 Refereed Disclose to all
Takahashi N, Mori Y Takahashi N, Mori Y Takahashi N, Mori Y The O(2)-sensing TRPA1 channel illustrates the significance of vagal nerves in cardio-respiratory adaptation to hypoxia. The O(2)-sensing TRPA1 channel illustrates the significance of vagal nerves in cardio-respiratory adaptation to hypoxia. The O(2)-sensing TRPA1 channel illustrates the significance of vagal nerves in cardio-respiratory adaptation to hypoxia. Acta physiologica (Oxford, England), 210, 4, 705-707 Acta physiologica (Oxford, England), 210, 4, 705-707 Acta physiologica (Oxford, England), 210, 4, 705-707 2014/04 Disclose to all
Kozai D, Kabasawa Y, Ebert M, Kiyonaka S, Firman., Otani Y, Numata T, Takahashi N, Mori Y, Ohwada T Kozai D, Kabasawa Y, Ebert M, Kiyonaka S, Firman., Otani Y, Numata T, Takahashi N, Mori Y, Ohwada T Kozai D, Kabasawa Y, Ebert M, Kiyonaka S, Firman., Otani Y, Numata T, Takahashi N, Mori Y, Ohwada T Transnitrosylation directs TRPA1 selectivity in N-nitrosamine activators. Transnitrosylation directs TRPA1 selectivity in N-nitrosamine activators. Transnitrosylation directs TRPA1 selectivity in N-nitrosamine activators. Molecular pharmacology, 85, 1, 175-185 Molecular pharmacology, 85, 1, 175-185 Molecular pharmacology, 85, 1, 175-185 2014/01 Refereed Disclose to all
Shimizu S, Takahashi N, Mori Y Shimizu S, Takahashi N, Mori Y Shimizu S, Takahashi N, Mori Y TRPs as chemosensors (ROS, RNS, RCS, gasotransmitters). TRPs as chemosensors (ROS, RNS, RCS, gasotransmitters). TRPs as chemosensors (ROS, RNS, RCS, gasotransmitters). Handbook of experimental pharmacology, 223, 767-794 Handbook of experimental pharmacology, 223, 767-794 Handbook of experimental pharmacology, 223, 767-794 2014 Refereed Disclose to all
Yonemitsu T, Kuroki C, Takahashi N, Mori Y, Kanmura Y, Kashiwadani H, Ootsuka Y, Kuwaki T Yonemitsu T, Kuroki C, Takahashi N, Mori Y, Kanmura Y, Kashiwadani H, Ootsuka Y, Kuwaki T Yonemitsu T, Kuroki C, Takahashi N, Mori Y, Kanmura Y, Kashiwadani H, Ootsuka Y, Kuwaki T TRPA1 detects environmental chemicals and induces avoidance behavior and arousal from sleep. TRPA1 detects environmental chemicals and induces avoidance behavior and arousal from sleep. TRPA1 detects environmental chemicals and induces avoidance behavior and arousal from sleep. Scientific reports, 3, 3100 Scientific reports, 3, 3100 Scientific reports, 3, 3100 2013/10 Refereed Disclose to all
Numata T, Ogawa N, Takahashi N, Mori Y Numata T, Ogawa N, Takahashi N, Mori Y Numata T, Ogawa N, Takahashi N, Mori Y TRP channels as sensors of oxygen availability. TRP channels as sensors of oxygen availability. TRP channels as sensors of oxygen availability. Pflugers Archiv : European journal of physiology, 465, 8, 1075-1085 Pflugers Archiv : European journal of physiology, 465, 8, 1075-1085 Pflugers Archiv : European journal of physiology, 465, 8, 1075-1085 2013/08 Refereed Disclose to all
Takahashi N, Kozai D, Mori Y Takahashi N, Kozai D, Mori Y Takahashi N, Kozai D, Mori Y TRP channels: sensors and transducers of gasotransmitter signals. TRP channels: sensors and transducers of gasotransmitter signals. TRP channels: sensors and transducers of gasotransmitter signals. Frontiers in physiology, 3, 324 Frontiers in physiology, 3, 324 Frontiers in physiology, 3, 324 2012 Refereed Disclose to all
Takahashi N, Kozai D, Kobayashi R, Ebert M, Mori Y Takahashi N, Kozai D, Kobayashi R, Ebert M, Mori Y Takahashi N, Kozai D, Kobayashi R, Ebert M, Mori Y Roles of TRPM2 in oxidative stress. Roles of TRPM2 in oxidative stress. Roles of TRPM2 in oxidative stress. Cell calcium, 50, 3, 279-287 Cell calcium, 50, 3, 279-287 Cell calcium, 50, 3, 279-287 2011/09 Refereed Disclose to all
Takahashi N, Kuwaki T, Kiyonaka S, Numata T, Kozai D, Mizuno Y, Yamamoto S, Naito S, Knevels E, Carmeliet P, Oga T, Kaneko S, Suga S, Nokami T, Yoshida J, Mori Y Takahashi N, Kuwaki T, Kiyonaka S, Numata T, Kozai D, Mizuno Y, Yamamoto S, Naito S, Knevels E, Carmeliet P, Oga T, Kaneko S, Suga S, Nokami T, Yoshida J, Mori Y Takahashi N, Kuwaki T, Kiyonaka S, Numata T, Kozai D, Mizuno Y, Yamamoto S, Naito S, Knevels E, Carmeliet P, Oga T, Kaneko S, Suga S, Nokami T, Yoshida J, Mori Y TRPA1 underlies a sensing mechanism for O2. TRPA1 underlies a sensing mechanism for O2. TRPA1 underlies a sensing mechanism for O2. Nature chemical biology, 7, 10, 701-711 Nature chemical biology, 7, 10, 701-711 Nature chemical biology, 7, 10, 701-711 2011/08 Refereed Disclose to all
Takahashi N, Mori Y Takahashi N, Mori Y Takahashi N, Mori Y TRP Channels as Sensors and Signal Integrators of Redox Status Changes. TRP Channels as Sensors and Signal Integrators of Redox Status Changes. TRP Channels as Sensors and Signal Integrators of Redox Status Changes. Frontiers in pharmacology, 2, 58 Frontiers in pharmacology, 2, 58 Frontiers in pharmacology, 2, 58 2011 Refereed Disclose to all
Mori Y, Kajimoto T, Nakao A, Takahashi N, Kiyonaka S Mori Y, Kajimoto T, Nakao A, Takahashi N, Kiyonaka S Mori Y, Kajimoto T, Nakao A, Takahashi N, Kiyonaka S Receptor signaling integration by TRP channelsomes. Receptor signaling integration by TRP channelsomes. Receptor signaling integration by TRP channelsomes. Advances in experimental medicine and biology, 704, 373-389 Advances in experimental medicine and biology, 704, 373-389 Advances in experimental medicine and biology, 704, 373-389 2011 Disclose to all
Yamamoto S, Takahashi N, Mori Y Yamamoto S, Takahashi N, Mori Y Yamamoto S, Takahashi N, Mori Y Chemical physiology of oxidative stress-activated TRPM2 and TRPC5 channels. Chemical physiology of oxidative stress-activated TRPM2 and TRPC5 channels. Chemical physiology of oxidative stress-activated TRPM2 and TRPC5 channels. Progress in biophysics and molecular biology, 103, 1, 18-27 Progress in biophysics and molecular biology, 103, 1, 18-27 Progress in biophysics and molecular biology, 103, 1, 18-27 2010/09 Refereed Disclose to all
Bogeski I, Kummerow C, Al-Ansary D, Schwarz EC, Koehler R, Kozai D, Takahashi N, Peinelt C, Griesemer D, Bozem M, Mori Y, Hoth M, Niemeyer BA Bogeski I, Kummerow C, Al-Ansary D, Schwarz EC, Koehler R, Kozai D, Takahashi N, Peinelt C, Griesemer D, Bozem M, Mori Y, Hoth M, Niemeyer BA Bogeski I, Kummerow C, Al-Ansary D, Schwarz EC, Koehler R, Kozai D, Takahashi N, Peinelt C, Griesemer D, Bozem M, Mori Y, Hoth M, Niemeyer BA Differential redox regulation of ORAI ion channels: a mechanism to tune cellular calcium signaling. Differential redox regulation of ORAI ion channels: a mechanism to tune cellular calcium signaling. Differential redox regulation of ORAI ion channels: a mechanism to tune cellular calcium signaling. Science signaling, 3, 115, ra24 Science signaling, 3, 115, ra24 Science signaling, 3, 115, ra24 2010/03 Refereed Disclose to all
Takahashi N, Mizuno Y, Kozai D, Yamamoto S, Kiyonaka S, Shibata T, Uchida K, Mori Y Takahashi N, Mizuno Y, Kozai D, Yamamoto S, Kiyonaka S, Shibata T, Uchida K, Mori Y Takahashi N, Mizuno Y, Kozai D, Yamamoto S, Kiyonaka S, Shibata T, Uchida K, Mori Y Molecular characterization of TRPA1 channel activation by cysteine-reactive inflammatory mediators. Molecular characterization of TRPA1 channel activation by cysteine-reactive inflammatory mediators. Molecular characterization of TRPA1 channel activation by cysteine-reactive inflammatory mediators. Channels (Austin, Tex.), 2, 4, 287-298 Channels (Austin, Tex.), 2, 4, 287-298 Channels (Austin, Tex.), 2, 4, 287-298 2008/07 Refereed Disclose to all
Yamamoto S, Shimizu S, Kiyonaka S, Takahashi N, Wajima T, Hara Y, Negoro T, Hiroi T, Kiuchi Y, Okada T, Kaneko S, Lange I, Fleig A, Penner R, Nishi M, Takeshima H, Mori Y Yamamoto S, Shimizu S, Kiyonaka S, Takahashi N, Wajima T, Hara Y, Negoro T, Hiroi T, Kiuchi Y, Okada T, Kaneko S, Lange I, Fleig A, Penner R, Nishi M, Takeshima H, Mori Y Yamamoto S, Shimizu S, Kiyonaka S, Takahashi N, Wajima T, Hara Y, Negoro T, Hiroi T, Kiuchi Y, Okada T, Kaneko S, Lange I, Fleig A, Penner R, Nishi M, Takeshima H, Mori Y TRPM2-mediated Ca2+influx induces chemokine production in monocytes that aggravates inflammatory neutrophil infiltration. TRPM2-mediated Ca2+influx induces chemokine production in monocytes that aggravates inflammatory neutrophil infiltration. TRPM2-mediated Ca2+influx induces chemokine production in monocytes that aggravates inflammatory neutrophil infiltration. Nature medicine, 14, 7, 738-747 Nature medicine, 14, 7, 738-747 Nature medicine, 14, 7, 738-747 2008/07 Refereed Disclose to all
Yoshida T, Inoue R, Morii T, Takahashi N, Yamamoto S, Hara Y, Tominaga M, Shimizu S, Sato Y, Mori Y Yoshida T, Inoue R, Morii T, Takahashi N, Yamamoto S, Hara Y, Tominaga M, Shimizu S, Sato Y, Mori Y Yoshida T, Inoue R, Morii T, Takahashi N, Yamamoto S, Hara Y, Tominaga M, Shimizu S, Sato Y, Mori Y Nitric oxide activates TRP channels by cysteine S-nitrosylation. Nitric oxide activates TRP channels by cysteine S-nitrosylation. Nitric oxide activates TRP channels by cysteine S-nitrosylation. Nature chemical biology, 2, 11, 596-607 Nature chemical biology, 2, 11, 596-607 Nature chemical biology, 2, 11, 596-607 2006/11 Refereed Disclose to all

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Title language:
Books etc
Author Author(Japanese) Author(English) Title Title(Japanese) Title(English) Publisher Publisher(Japanese) Publisher(English) Publication date Language Type Disclose
高橋 重成 高橋 重成 がん細胞はワサビ受容体を発現することで酸化ストレス耐性を亢進させている がん細胞はワサビ受容体を発現することで酸化ストレス耐性を亢進させている 実験医学 実験医学 2018/10 Disclose to all
高橋重成、森泰生、Joan S. Brugge 高橋重成、森泰生、Joan S. Brugge がん細胞は感覚受容の分子機構をハイジャックすることで酸化ストレス耐性機能を亢進させている がん細胞は感覚受容の分子機構をハイジャックすることで酸化ストレス耐性機能を亢進させている 新着論文レビュー 新着論文レビュー 2018/06 Disclose to all
末次志郎, 高橋重成, 伊藤弓弦, 竹村和浩, 嶋田 睦, 北尾彰朗, 森 泰生 末次志郎, 高橋重成, 伊藤弓弦, 竹村和浩, 嶋田 睦, 北尾彰朗, 森 泰生 TRPV4イオンチャネルのアンキリンリピート ドメインとPI(4,5)P2の相互作用による新たな制御機構 TRPV4イオンチャネルのアンキリンリピート ドメインとPI(4,5)P2の相互作用による新たな制御機構 生物物理 生物物理 2015/07 Disclose to all
植田誉志史、高橋重成、森泰生 植田誉志史、高橋重成、森泰生 TRPA1チャネルを介した酸素・活性酸素種センシング TRPA1チャネルを介した酸素・活性酸素種センシング 実験医学 実験医学 2012/10 Disclose to all
高橋重成, 植田誉志史, 森泰生 高橋重成, 植田誉志史, 森泰生 TRP チャネルを介する新しい酸素センシング機構 TRP チャネルを介する新しい酸素センシング機構 実験医学 実験医学 2012/05 Disclose to all
高橋 重成 高橋 重成 TRPA1チャネルによる酸素感受性 TRPA1チャネルによる酸素感受性 医学のあゆみ 医学のあゆみ 2012/04 Disclose to all
森泰生、高橋重成 森泰生、高橋重成 酸素を検知する生体内ケモセンサーイオンチャネル 酸素を検知する生体内ケモセンサーイオンチャネル 化学マスター講座 一般化学(丸善) 化学マスター講座 一般化学(丸善) 2012 Disclose to all
植田誉志史、高橋重成、森泰生 植田誉志史、高橋重成、森泰生 新たな酸素センサー/チャネルによる低酸素応答制御 新たな酸素センサー/チャネルによる低酸素応答制御 血管医学 血管医学 2012 Disclose to all
清中茂樹、高橋重成、森泰生 清中茂樹、高橋重成、森泰生 活性酸素で活性化されるTRPチャネル 活性酸素で活性化されるTRPチャネル ファルマシア ファルマシア 2012 Disclose to all
高橋 重成、森 泰生 高橋 重成、森 泰生 TRPA1チャネルが担う生体における新しいO2センサー機構 TRPA1チャネルが担う生体における新しいO2センサー機構 新着論文レビュー 新着論文レビュー 2011/09 Disclose to all
森泰生、沼田朋大, 高橋重成 森泰生、沼田朋大, 高橋重成 生体内センサーとしてのイオンチャネル 総論 生体内センサーとしてのイオンチャネル 総論 トランスポートソームの世界 トランスポートソームの世界 2011 Disclose to all
森泰生、高橋重成 森泰生、高橋重成 イオンチャネル イオンチャネル トランスポートソームの世界 トランスポートソームの世界 2011 Disclose to all
高橋 重成 高橋 重成 TRPチャネル TRPチャネル Medical Tribuneことばのカルテ Medical Tribuneことばのカルテ 2009/11 Disclose to all
沼田朋大、香西大輔、高橋重成、加藤賢太、瓜生幸嗣、山本伸一郎、金子雄、眞本達生、森泰生 沼田朋大、香西大輔、高橋重成、加藤賢太、瓜生幸嗣、山本伸一郎、金子雄、眞本達生、森泰生 TRP チャネルの構造と多様な機能 TRP チャネルの構造と多様な機能 生化学 生化学 2009/11 Disclose to all
高橋重成, 山本伸一郎, 森泰生 高橋重成, 山本伸一郎, 森泰生 酸化ストレス作動性TRP チャネルの化学生理 酸化ストレス作動性TRP チャネルの化学生理 実験医学 実験医学 2009/09 Disclose to all
清中茂樹、高橋重成、香西大輔、森泰生 清中茂樹、高橋重成、香西大輔、森泰生 化学物質の感覚分子生物学―TRPチャネルはどのように物質を感知し脳へ伝えるか― 化学物質の感覚分子生物学―TRPチャネルはどのように物質を感知し脳へ伝えるか― 化学 化学 2009 Disclose to all
山本伸一郎、高橋重成、清中茂樹、森泰生 山本伸一郎、高橋重成、清中茂樹、森泰生 活性化学種感応のチャネル機構の探求 活性化学種感応のチャネル機構の探求 蛋白質核酸酵素 蛋白質核酸酵素 2009 Disclose to all
高橋重成, 秋山智志, 水野雄介, 井上隆司, 森泰生 高橋重成, 秋山智志, 水野雄介, 井上隆司, 森泰生 TRPCチャネルによる血管トーヌスの調節 TRPCチャネルによる血管トーヌスの調節 医学のあゆみ 医学のあゆみ 2007/12 Disclose to all
清中茂樹、加藤賢太、高橋重成、正木隆男、森泰生 清中茂樹、加藤賢太、高橋重成、正木隆男、森泰生 カルシウムシグナル制御チャネルの作用化合物と創薬 カルシウムシグナル制御チャネルの作用化合物と創薬 医学のあゆみ 医学のあゆみ 2007 Disclose to all

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Title language:
Awards
Title(Japanese) Title(English) Organization name(Japanese) Organization name(English) Date
鈴木紘一メモリアル賞 日本生化学会 2011/09/11
優秀発表賞 特定領域研究「G蛋白質シグナル」&「膜輸送複合体」合同若手ワークショップ2008 2008/01/27
鈴木紘一メモリアル賞 日本生化学会 2012/12/16
佐川喜一賞 日本生理学会 2013/03/28
井上研究奨励賞 井上科学振興財団 2014/02/04
"Hot topic" Research The Society for Neuroscience 2011/08/11
Newspaper articles
Title Media name Column name Date
体内摂取酸素量調節たんぱく質 読売新聞 2011/08/29
タンパク質「TRPA1」 産経新聞 2011/09/01
体内酸素センサー発見 京都新聞 2011/08/29
たんぱく質「TRPA1」 酸素の体内供給制御 日刊工業新聞 2011/08/29
たんぱく質 酸素濃度を検知 日経産業新聞 2011/08/29
酸素 必要なのに時には毒性 体内でどう処理する? 科学新聞 2011/09/16
Academic organizaions (conference chair)
Organization name Group name Date
第17回MPO研究会 2011/10/29