Personnel Information

写真a

MATSUMOTO Yukihisa


Job title

Associate Professor

Birth date

1971

Mail Address

yukihisa.las@tmd.ac.jp

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Graduating School 【 display / non-display

  • Okayama University, Faculty of Science, 1993, Graduated

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Graduate School 【 display / non-display

  • Okayama University, Graduate School, Division of Science and Technology, Doctor's Course, 1998, Completed

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Degree 【 display / non-display

  • Science, Okayama University

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Campus Career 【 display / non-display

  • 2013.02
    -
    2022.03
    Tokyo Medical and Dental University, College of Liberal Arts and Sciences, Natural Sciences, Biology, Assistant Professor
  • 2022.04
     
     
    Tokyo Medical and Dental University, Institute of Education, Liberal Arts and Sciences Division, Assistant Professor
  • 2022.05
     
     
    Tokyo Medical and Dental University, Institute of Education, Liberal Arts and Sciences Division, Assistant Professor
  • 2022.06
    -
    2023.06
    Tokyo Medical and Dental University, Institute of Education, Liberal Arts and Sciences Division, Assistant Professor
  • 2023.07
    -
    Now
    Tokyo Medical and Dental University, Institute of Education, Liberal Arts and Sciences Division, Associate Professor
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Research Areas 【 display / non-display

  • Animal physiological chemistry, physiology and behavioral biology

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Published Papers & Misc 【 display / non-display

  1. Matsumoto Y, Matsumoto CS, Mizunami M. Critical roles of nicotinic acetylcholine receptors in olfactory memory formation and retrieval in crickets. Frontiers in physiology. 2024; 15 1345397. ( PubMed, DOI )

  2. Chihiro Sato Matsumoto, Yukihisa Matsumoto, Makoto Mizunami. Roles of octopamine neurons in the vertical lobe of the mushroom body for the execution of a conditioned response in cockroaches. Neurobiol Learn Mem. 2023.09; 203 107778. ( PubMed, DOI )

  3. Kulkarni Arpita, Ewen-Campen Ben, Terao Kanta, Matsumoto Yukihisa, Li Yaolong, Watanabe Takayuki, Kao Jonchee A., Parhad Swapnil S., Ylla Guillem, Mizunami Makoto, Extavour Cassandra G.. oskar acts with the transcription factor Creb to regulate long-term memory in crickets PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA. 2023.05; 120 (21): ( DOI )

  4. Terao Kanta, Matsumoto Yukihisa, Alvarez Beatriz, Mizunami Makoto. Spontaneous recovery from overexpectation in an insect SCIENTIFIC REPORTS. 2022.06; 12 (1): 9827. ( PubMed, DOI )

  5. Matsumoto Yukihisa. Learning and memory in the cricket Gryllus bimaculatus PHYSIOLOGICAL ENTOMOLOGY. 2021.11; 47 (3): 147-161. ( DOI )

  6. Iwashita Hikaru, Matsumoto Yukihisa, Maruyama Yusuke, Watanabe Kazuki, Chiba Atsuhiko, Hattori Atsuhiko. The melatonin metabolite N1-acetyl-5-methoxykynuramine facilitates long-term object memory in young and aging mice JOURNAL OF PINEAL RESEARCH. 2021.01; 70 (1): e12703. ( PubMed, DOI )

  7. Mizunami Makoto, Hirohata Sho, Sato Ai, Arai Ryoichi, Terao Kanta, Sato Misato, Matsumoto Yukihisa. Development of behavioural automaticity by extended Pavlovian training in an insect PROCEEDINGS OF THE ROYAL SOCIETY B-BIOLOGICAL SCIENCES. 2019.01; 286 (1894): 20182132. ( PubMed, DOI )

  8. Yukihisa Matsumoto, Chihiro S Matsumoto, Makoto Mizunami. Signaling Pathways for Long-Term Memory Formation in the Cricket. Front Psychol. 2018.06; 9 1014. ( PubMed, DOI )

  9. Makoto Mizunami, Yukihisa Matsumoto. Roles of Octopamine and Dopamine Neurons for Mediating Appetitive and Aversive Signals in Pavlovian Conditioning in Crickets. Front Physiol. 2017.12; 8 1027. ( PubMed, DOI )

  10. Makoto Mizunami, Chihiro Sato-Matsumoto and Yukihisa Matsumoto. Searching for cognitive processes underlying insect learning The Japanese Journal of Animal Pychology. 2017.08; 67 (1): 1-10.

  11. Shouhei Hosono, Yukihisa Matsumoto, Makoto Mizunami. Interaction of inhibitory and facilitatory effects of conditioning trials on long-term memory formation. Learn. Mem.. 2016.12; 23 (12): 669-678. ( PubMed, DOI )

  12. Seigo Sugimachi, Yukihisa Matsumoto, Makoto Mizunami, Jiro Okada. Effects of Caffeine on Olfactory Learning in Crickets. Zool. Sci.. 2016.10; 33 (5): 513-519. ( PubMed, DOI )

  13. Yukihisa Matsumoto, Chihiro S Matsumoto, Toshihumi Takahashi, Makoto Mizunami. Activation of NO-cGMP Signaling Rescues Age-Related Memory Impairment in Crickets. Front Behav Neurosci. 2016.07; 10 166. ( PubMed, DOI )

  14. Hiroko Awata, Ryo Wakuda, Yoshiyasu Ishimaru, Yuji Matsuoka, Kanta Terao, Satomi Katata, Yukihisa Matsumoto, Yoshitaka Hamanaka, Sumihare Noji, Taro Mito, Makoto Mizunami. Roles of OA1 octopamine receptor and Dop1 dopamine receptor in mediating appetitive and aversive reinforcement revealed by RNAi studies. Sci Rep. 2016.07; 6 29696. ( PubMed, DOI )

  15. Yukihisa Matsumoto, Chihiro-Sato Matsumoto, Ryo Wakuda, Saori Ichihara, Makoto Mizunami. Roles of octopamine and dopamine in appetitive and aversive memory acquisition studied in olfactory conditioning of maxillary palpi extension response in crickets. Front Behav Neurosci. 2015.09; 9 230. ( PubMed, DOI )

  16. Kanta Terao, Yukihisa Matsumoto, Makoto Mizunami. Critical evidence for the prediction error theory in associative learning. Sci Rep. 2015.03; 5 8929. ( PubMed, DOI )

  17. Makoto Mizunami, Yuko Nemoto, Kanta Terao, Yoshitaka Hamanaka, Yukihisa Matsumoto. Roles of calcium/calmodulin-dependent kinase II in long-term memory formation in crickets. PLoS ONE. 2014.09; 9 (9): e107442. ( PubMed, DOI )

  18. Yukihisa Matsumoto, Jean-Christophe Sandoz, Jean-Marc Devaud, Flore Lormant, Makoto Mizunami, Martin Giurfa. Cyclic nucleotide-gated channels, calmodulin, adenylyl cyclase, and calcium/calmodulin-dependent protein kinase II are required for late, but not early, long-term memory formation in the honeybee. Learn. Mem.. 2014.04; 21 (5): 272-286. ( PubMed, DOI )

  19. Matsumoto CS, Shidara H, Matsuda K, Nakamura T, Mito T, Matsumoto Y, Oka K, Ogawa H. Targeted gene delivery in the cricket brain, using in vivo electroporation. J Insect Physiol. 2013.12; 59 (12): 1235-1241. ( PubMed, DOI )

  20. Matsumoto Y, Hirashima D, Mizunami M. Analysis and modeling of neural processes underlying sensory preconditioning. Neurobiol Learn Mem. 2013.02; ( PubMed, DOI )

  21. Matsumoto CS, Kuramochi T, Matsumoto Y, Watanabe H, Nishino H, Mizunami M. Participation of NO signaling in formation of long-term memory in salivary conditioning of the cockroach. Neurosci Lett. 2013.01; ( PubMed, DOI )

  22. Matsumoto Y, Hirashima D, Terao K, Mizunami M. Roles of NO signaling in long-term memory formation in visual learning in an insect. PLoS ONE. 2013; 8 (7): e68538. ( PubMed, DOI )

  23. Matsumoto Y, Menzel R, Sandoz JC, Giurfa M. Revisiting olfactory classical conditioning of the proboscis extension response in honey bees: a step toward standardized procedures. J Neurosci Methods. 2012.10; 211 (1): 159-167. ( PubMed, DOI )

  24. Matsumoto CS, Matsumoto Y, Watanabe H, Nishino H, Mizunami M. Context-dependent olfactory learning monitored by activities of salivary neurons in cockroaches. Neurobiol Learn Mem. 2012.01; 97 (1): 30-36. ( PubMed, DOI )

  25. Mizunami M, Matsumoto Y. Roles of aminergic neurons in formation and recall of associative memory in crickets. Front Behav Neurosci. 2010; 4 172. ( PubMed, DOI )

  26. Matsumoto Y, Hatano A, Unoki S, Mizunami M. Stimulation of the cAMP system by the nitric oxide-cGMP system underlying the formation of long-term memory in an insect. Neurosci Lett. 2009.12; 467 (2): 81-85. ( PubMed, DOI )

  27. Nakatani Y, Matsumoto Y, Mori Y, Hirashima D, Nishino H, Arikawa K, Mizunami M. Why the carrot is more effective than the stick: different dynamics of punishment memory and reward memory and its possible biological basis. Neurobiol Learn Mem. 2009.10; 92 (3): 370-380. ( PubMed, DOI )

  28. Takahashi T, Hamada A, Miyawaki K, Matsumoto Y, Mito T, Noji S, Mizunami M. Systemic RNA interference for the study of learning and memory in an insect. J Neurosci Methods. 2009.04; 179 (1): 9-15. ( PubMed )

  29. Mizunami M, Unoki S, Mori Y, Hirashima D, Hatano A, Matsumoto Y. Roles of octopaminergic and dopaminergic neurons in appetitive and aversive memory recall in an insect. BMC Biol. 2009; 7 46. ( PubMed, DOI )

  30. Perisse E, Raymond-Delpech V, Néant I, Matsumoto Y, Leclerc C, Moreau M, Sandoz JC. Early calcium increase triggers the formation of olfactory long-term memory in honeybees. BMC Biol. 2009; 7 30. ( PubMed, DOI )

  31. Matsumoto Y, Mizunami M. Olfactory memory capacity of the cricket Gryllus bimaculatus. Biol Lett. 2006.12; 2 (4): 608-610. ( PubMed, DOI )

  32. Unoki S, Matsumoto Y, Mizunami M. Roles of octopaminergic and dopaminergic neurons in mediating reward and punishment signals in insect visual learning. Eur J Neurosci. 2006.10; 24 (7): 2031-2038. ( PubMed, DOI )

  33. Sato C, Matsumoto Y, Sakura M, Mizunami M. Contextual olfactory learning in cockroaches. Neuroreport. 2006.04; 17 (5): 553-557. ( PubMed, DOI )

  34. Matsumoto Y, Unoki S, Aonuma H, Mizunami M. Critical role of nitric oxide-cGMP cascade in the formation of cAMP-dependent long-term memory. Learn Mem. 2006; 13 (1): 35-44. ( PubMed, DOI )

  35. Unoki S, Matsumoto Y, Mizunami M. Participation of octopaminergic reward system and dopaminergic punishment system in insect olfactory learning revealed by pharmacological study. Eur J Neurosci. 2005.09; 22 (6): 1409-1416. ( PubMed, DOI )

  36. Matsumoto Y, Mizunami M. Formation of long-term olfactory memory in the cricket Gryllus bimaculatus. Chem Senses. 2005.01; 30 Suppl 1 i299-300. ( PubMed, DOI )

  37. Matsumoto Y, Mizunami M. Context-dependent olfactory learning in an insect. Learn Mem. 2004; 11 (3): 288-293. ( PubMed, DOI )

  38. Watanabe H, Kobayashi Y, Sakura M, Matsumoto Y, Mizunami M. Classical olfactory conditioning in the cockroach Periplaneta americana. Zool Sci. 2003.12; 20 (12): 1447-1454. ( PubMed )

  39. Matsumoto Y, Noji S, Mizunami M. Time course of protein synthesis-dependent phase of olfactory memory in the cricket Gryllus bimaculatus. Zool Sci. 2003.04; 20 (4): 409-416. ( PubMed )

  40. Matsumoto Y, Mizunami M. Temporal determinants of long-term retention of olfactory memory in the cricket Gryllus bimaculatus. J Exp Biol. 2002.05; 205 (Pt 10): 1429-1437. ( PubMed )

  41. Matsumoto Y, Mizunami M. Lifetime olfactory memory in the cricket Gryllus bimaculatus. J Comp Physiol A Neuroethol Sens Neural Behav Physiol. 2002.05; 188 (4): 295-299. ( PubMed, DOI )

  42. Matsumoto Y, Sakai M. Brain control of mating behavior in the male cricket Gryllus bimaculatus DeGeer: excitatory control of copulation actions. Zool Sci. 2001; 18 659-669.

  43. Matsumoto Y, Mizunami M. Olfactory learning in the cricket Gryllus bimaculatus. J Exp Biol. 2000.09; 203 (Pt 17): 2581-2588. ( PubMed )

  44. Matsumoto Y, Sakai M. Brain control of mating behavior in the male cricket Gryllus bimaculatus DeGeer: brain neurons responsible for inhibition of copulation actions. J Insect Physiol. 2000.04; 46 (4): 539-552. ( PubMed )

  45. Matsumoto Y, Sakai M. Brain control of mating behavior in the male cricket Gryllus bimaculatus DeGeer: the center for inhibition of copulation actions. J Insect Physiol. 2000.04; 46 (4): 527-538. ( PubMed )

  46. Sakai M, Matsumoto Y, Takemori N, Taoda Y, Fujino M. Post-copulatory sexual refractoriness is maintained under the control of the terminal abdominal ganglion in the male cricket Gryllus bimaculatus DeGeer. J Insect Physiol. 1995; 41 1055-1070.

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Books etc 【 display / non-display

  1. M. Mizunami, Y. Matsumoto. Crickets as a model organism: development, regeneration and behavior. . Springer, 2017.05 Chapter 9 Learning and memory.

  2. Y. Matsumoto, C. S. Matsumoto, M. Mizunami. Crickets as a model organism: development, regeneration and behavior. . Springer, 2017.05 Chapter 17 Protocols for olfactory conditioning.

  3. M. Sakai, M. Kumashiro, Y. Matsumoto, M. Ureshi, T. Otsubo. Crickets as a model organism: development, regeneration and behavior. . Springer, 2017.05 Chapter 16 Reproductive behavior and physiology in the cricket Gryllus bimaculatus.

  4. Methods in Neuroethological Research. Springer, 2013 (ISBN : 978-4-431-54331-2)

  5. Invertebrate Learning and Memory. Elsevier, 2013 (ISBN : 978-0-12-415823-8)

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Conference Activities & Talks 【 display / non-display

  1. Yukihisa MATSUMOTO. Parental ages affect the memory formation ability of the offspring in crickets. Non-Traditional Arthropod Model Systems (NTrMS) 2 2024.08.22 Tokyo, Japan

  2. Yukihisa Matsumoto . Melatonin eliminates the negative effects of parental age on the memory formation ability of offspring in crickets. 日本比較生理生化学会第45回大会 2023.12.03 大阪(大阪大学)

  3. Kanta Terao, Beatriz Álvarez, Shun Fujimaki, Yutaka Kosaki, Yukihisa Matsumto, Makoto Mizunami. Extinction and renewal in classical conditioning in an insect. 日本比較生理生化学会第45回大会 2023.12.03 大阪(大阪大学)

  4. Kanta TERAO, Yutaka KOSAKI, Yusuke Maruyama, Kazuki WATANABE, Kosuke KATAOKA, Atushiko HATTORI, Yukihisa MATSUMOTO. Social contexts mediate reward systems in a cricket Gryllus bimaculatus. Non-Traditional Arthropod Model Systems: Studying Form and Function (NTrMS) 2023.08.04 Brunswick, USA

  5. Kanta Terao、Yutaka Kosaki、Yusuke Maruyama、Atsuhiko Hattori、Yukihisa Matsumoto. Effects of social isolation in crickets Gryllus bimaculatus. 日本動物心理学会第82回大会 2022.10.16 東京(早稲田大学)

  6. Nishino Hiroshi, Domae Mana, Matsumoto Yukihisa, Takanashi Takuma. コオロギの聴覚器官の比較研究から明らかになった耳小骨様の構造と鼓膜の変化(Comparative study of cricket auditory organs highlights modification of ossicles-like structures and tympanal membranes). 比較生理生化学 2022.04.01

  7. Nishino Hiroshi, Domae Mana, Matsumoto Yukihisa, Takanashi Takuma. Comparative study of cricket auditory organs highlights modification of ossicles-like structures and tympanal membranes(和訳中). 日本比較生理生化学会第43回大会 2021.12.05

  8. Matsumoto Yukihisa. Parental ages affect the memory formation ability of offspring in crickets. 日本比較生理生化学会第43回大会 2021.12.04 札幌(オンライン)

  9. Kanta Terao, Yukihisa Matsumoto, Yutaka Kosaki. Extinction learning in crickets. 日本比較生理生化学会第43回大会 2021.12.04 札幌(オンライン)

  10. Y. Matsumoto. Olfactory memory in the crickets. The 10th International Congress of Comparative Physiology and Biochemistry Symposium 2019.08.05 Ottawa, Canada

  11. Y.Matsumoto, Y. Maruyama, S.C. Matsumoto, A. Iwashita, A. Chiba, A. Hattori. Melatonin metabolites rescue age-related memory impairment in the cricket Gryllus bimaculatus. The 22th International Congress of Zoology 2016.11.16 Okinawa

  12. NO-cGMP signaling is involved in age-related memory impairment in the cricket.. The 2nd International Conference on the Cricket (Tokushima, Japan) 2012, March 2012

  13. Analysis and modeling of sensory preconditioning in crickets.. The 10th Congress of the International Society for Neuroethology (Maryland, USA) 2012, August 2012

  14. Systemic RNA interference for the study of learning and memory in the cricket Gryllus bimaculatus.. The 2nd International Conference on the Cricket (Tokushima, Japan) 2012, March 2012

  15. Memory molecules in insects: from behavioral pharmacological studies of olfactory learning in crickets Gryllus bimaculatus.. The 35th Annual Meeting of the Japan Neuroscience Society Symposium: Potential of Insect Neuroscience -Beyond the Drosophila- (Nagoya, Japan) 2012, September 2012

  16. Habit formation by extended Pavlovian training in crickets. The 8th International Congress of Comparative Physiology and Biochemistry (Nagoya, Japan) 2011, June 2011

  17. Age-related memory impairment and its pharmacological rescue in the cricket Gryllus bimaculatus.. The 1st International Conference on the Cricket (Tokushima, Japan) 2011, March 2011

  18. Sensory preconditioning in the cricket Gryllus bimaculatus: Associations between neutral sensory stimuli.. The 8th International Congress of Comparative Physiology and Biochemistry (Nagoya, Japan) 2011, June 2011

  19. "Cognitive" aspects of insect classical conditioning revealed by studying the roles of aminergic neurons in associative memory recall.. The 9th Congress of the International Society for Neuroethology (Salamanca, Spain) 2010, August 2010

  20. NO-cGMP signaling is involved in age-related memory impairment in the cricket Gryllus bimaculatus.. Neuro2010 (Kobe, Japan) 2010, September 2010

  21. Effect of epinastine on acquisition and retrieval of appetitive olfactory memory in the cockroach.. The 9th Congress of the International Society for Neuroethology (Salamanca, Spain) 2010, August 2010

  22. Age-related memory impairment and its pharmacological rescue in the cricket.. The 9th Congress of the International Society for Neuroethology (Salamanca, Spain) 2010, August 2010

  23. Systemic RNAi for long-term memory in an insect. ZAO Conference, the 1st International Conference of Tohoku Neuroscience GCOE; "from GENES to development and behavior" (Sendai, Japan) 2008, January 2008

  24. CNG channel, calmodulin and CaMKII underlie olfactory long-term memory formation in the honeybee.. Neuro2007 (Yokohama, Japan) 2007, September 2007

  25. Nitric oxide synthase dsRNA interfere with long-term memory formation in an insect.. Neuro2007 (Yokohama, Japan) 2007, September 2007

  26. Context-dependent learning in cockroaches.. The 8th Congress of the International Society for Neuroethology (Vancouver, Canada) 2007, July 2007

  27. Context-dependent olfactory conditioning in cockroaches.. Neuro2007 (Yokohama, Japan) 2007, September 2007

  28. Cyclic nucleotide-gated cation channels and calmodulin underlie olfactory long-term memory in the honeybee Apis mellifera.. The 5th Congress of the Forum of European Neuroscience (Vienna, Austria) 2006, July 2006

  29. Formation of long-term olfactory memory in the cricket Gryllus bimaculatus.. The 14th International Symposium on Olfaction and Taste, and the 38th Japanese Association for Taste and Smell (ISOT/JASTS 2004) (Kyoto, Japan) Symposium 2004, July 2004

  30. A mechanism of long-term memory formation in the cricket.. Japanese-French Postdoc Meeting on Insect Neuroethology (Toulouse, France) 2004, March 2004

  31. Different memory dynamics in appetitive learning and aversive learning in the cricket.. The 14th International Symposium on Olfaction and Taste, and the 38th Japanese Association for Taste and Smell (ISOT/JASTS 2004) (Kyoto, Japan) Symposium 2004, July 2004

  32. Different memory dynamics in appetitive learning and aversive learning in the cricket.. Symposium on Chemical Sense and Insect Behavior (Kyoto, Japan) Symposium 2004, July 2004

  33. Different memory dynamics of, and neurotransmitters involved in, appetitive learning and aversive learning in the cricket.. The 7th Congress of the International Society for Neuroethology (Nyborg, Denmark) 2004, August 2004

  34. Nitric oxide-cGMP pathway is critical for cAMP-dependent long-term memory formation in the cricket.. The 7th Congress of the International Society for Neuroethology (Nyborg, Denmark) 2004, August 2004

  35. NO-cGMP signaling mediates medium-term memory in the crickets.. The 3th Congress of the Forum of European Neuroscience (Paris, France) 2002, July 2002

  36. Olfactory memory phases in the crickets Gryllus bimachlatus.. The 6th International Congress of Neuroethology (Bonn, Germany) 2001, August 2001

  37. Elementary and context-dependent olfactory learning in crickets.. The 6th International Congress of Neuroethology (Bonn, Germany) Symposium 2001

  38. Olfactory learning in crickets.. The 18th Tsukuba Insect Science Symposium: Learning in Insect Foraging (Tsukuba, Japan) 2000

  39. Olfactory learning in cockroaches and crickets.. The 1st RIES-Hokudai Symposium (Sapporo, Japan) 1999, December 1999

  40. The brain facilitates copulatory action using octopamine in the male cricket.. The 4th International Congress of Neuroethology (Cambridge, U. K.) 1995, May 1995

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Patents 【 display / non-display

  • LONG-TERM MEMORY INDUCING AGENT

    Patent Number: 10266482

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Campus class subject 【 display / non-display

  • GKSK,2021 - Now

  • S-Marin Biology in English,2016

  • KSK,2014 - 2020

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