研究業績

原著論文(査読あり)
Google Scholar Citationsはコチラ
  1. Anbutsu H.*, Moriyama M.*, Nikoh N.*, Hosokawa T., Futahashi R., Tanahashi M., Meng X. Y., , Kuriwada T., Mori N., Oshima K., Hattori M., Fujie M., Satoh N., Maeda T., Shigenobu S., Koga R., Fukatsu T. (in press) Symbiosis for beetle’s hardness: symbiont’s tiny genome for supplying a single amino acid, and host’s control of the synthesis pathway. Proceedings of the National Academy of Sciences of the United States of America (*Equal contributions)
  2. Itoh H., Matsuura Y., Hosokawa T., Fukatsu T., Kikuchi Y. (2017) Obligate gut symbiotic association in the sloe bug Dolycoris baccarum (Hemiptera: Pentatomidae). Applied Entomology and Zoology 52: 51-59. 
  3. Hosokawa T.*, Matsuura Y.*, Kikuchi Y., Fukatsu T. (2016) Recurrent evolution of gut symbiotic bacteria in pentatomid stinkbugs. Zoological Letters 2: 24. (*Equal contributions)
  4. Kikuchi Y., Tada A., Musolin D., Hari N., Hosokawa T., Fujisaki K., Fukatsu T. (2016) Collapse of insect gut symbiosis under simulated climate change. mBio 7(5): e01578-16. 
  5. Moriyama M., Hosokawa T., Tanahashi M., Nikoh N., Fukatsu T. (2016) Suppression of bedbug's reproduction by RNA interference of vitellogenin. PLoS ONE 11(4): e0153984.
  6. Hosokawa T., Ishii Y., Nikoh N., Fujie M., Satoh N., Fukatsu T. (2016) Obligate bacterial mutualists evolving from environmental bacteria in natural insect populations. Nature Microbiology 1: 15011.
  7. Moriyama M., Nikoh N., Hosokawa T., Fukatsu T. (2015) Riboflavin provisioning underlies Wolbachia’s fitness contribution to insect host. mBio 6(6): e01732-15.
  8. Hayashi T., Hosokawa T., Meng X. Y., Koga R., Fukatsu T. (2015) Female-specific specialization of a posterior end region of the midgut symbiotic organ in Plautia splendens and allied stinkbugs. Applied and Environmental Microbiology 81: 2603-2611.
  9. Hosokawa T., Koga R., Tanaka K., Moriyama M., Anbutsu H., Fukatsu T. (2015) Nardonella endosymbionts of Japanese pest and non-pest weevils (Coleoptera: Curculionidae). Applied Entomology and Zoology 50: 223-229.
  10. Hosokawa T., Kaiwa N., Matsuura Y., Kikuchi Y., Fukatsu T. (2015) Infection prevalence of Sodalis symbionts among stinkbugs. Zoological Letters 1: 5.
  11. Kaiwa N*., Hosokawa T.*, Nikoh N., Tanahashi M., Moriyama M., Meng X. Y., Maeda T., Yamaguchi K., Shigenobu S., Ito M., Fukatsu T. (2014) Symbiont-supplemented maternal investment underpinning host's ecological adaptation. Current Biology 24: 2465-2470. (*Equal contributions)
  12. Nikoh N.*, Hosokawa T.*, Moriyama M.*, Oshima K., Hattori M., Fukatsu T. (2014) Evolutionary origin of insect-Wolbachia nutritional mutualism. Proceedings of the National Academy of Sciences of the United States of America 111: 10257-10262. (*Equal contributions)
  13. Matsuura Y., Hosokawa T., Serracin M., Tulgetske G., Miller T., Fukatsu T. (2014) Bacterial symbionts of a devastating coffee pest, the stinkbug Antestiopsis thunbergii (Hemiptera: Pentatomidae). Applied and Environmental Microbiology 80: 3769-3775.
  14. Hosokawa T., Nikoh N., Fukatsu T. (2014) Fine-scale geographical origin of an insect pest invading North America. PLoS ONE 9 (2): e89107.
  15. Hosokawa T., Hironaka M., Inadomi K., Mukai H., Nikoh N., Fukatsu T. (2013) Diverse strategies for vertical symbiont transmission among subsocial stinkbugs. PLoS ONE 8 (5): e65081.
  16. Moriyama M., Koga R., Hosokawa T., Nikoh N., Futahashi R., Fukatsu T. (2012) Comparative transcriptomics of the bacteriome and the spermalege of the bedbug Cimex lectularius (Hemiptera: Cimicidae). Applied Entomology and Zoology 47: 433-443.
  17. Hosokawa T., Kikuchi Y., Nikoh N., Fukatsu T. (2012) Polyphyly of gut symbionts in stinkbugs of the family Cydnidae. Applied and Environmental Microbiology 78: 4758-4761.
  18. Kikuchi Y., Hayatsu M., Hosokawa T., Nagayama A., Tago K., Fukatsu T. (2012) Symbiont-mediated insecticide resistance. Proceedings of the National Academy of Sciences of the United States of America 109: 8618-8622.
  19. Hosokawa, T.*, Nikoh, N.*, Koga, R.*, Sato, M., Tanahashi, M., Meng, X.-Y., Fukatsu, T. (2012) Reductive genome evolution, host-symbiont co-speciation, and uterine transmission of endosymbiotic bacteria in bat flies. The ISME Journal 6: 577-587. (*Equal contributuions)
  20. Kikuchi, Y., Hosokawa, T., Nikoh, N., Fukatsu, T. (2012) Gut symbiotic bacteria in the cabbage bugs Eurydema rugosa and Eurydema dominulus (Heteroptera: Pentatomidae). Applied Entomology and Zoology 47: 1-8.
  21. Matsuura, Y., Kikuchi, Y., Hosokawa, T., Koga, R., Meng, X.-Y., Kamagata, Y., Nikoh, N., Fukatsu, T. (2012) Evolution of symbiotic organs and endosymbionts in lygaeid stinkbugs. The ISME Journal 6: 397-409. 
  22. Hosokawa T., Hironaka M., Mukai H., Inadomi K., Suzuki N., Fukatsu T. (2012) Mothers never miss the moment: a fine-tuned mechanism for vertical symbiont transmission in a subsocial insect. Animal Behaviour 83: 293-300.
  23. Tada, A., Kikuchi, Y., Hosokawa, T., Musolin, D. L., Fujisaki, K., Fukatsu, T. (2011) Obligate association with gut bacterial symbiont in Japanese populations of the southern green stinkbug Nezara viridula (Heteroptera: Pentatomidae). Applied Entomology and Zoology 46: 483-488. 
  24. Nikoh, N., Hosokawa, T., Oshima, K., Hattori, M., Fukatsu, T. (2011) Reductive evolution of bacterial genome in insect gut environment. Genome Biology and Evolution 3: 702-714.
  25. Kikuchi, Y., Hosokawa, T., Fukatsu, T. (2011) Specific developmental window for establishment of an insect-microbe gut symbiosis. Applied and Environmental Microbiology 77: 4075-4081.
  26. Baba, N., Hironaka, M., Hosokawa, T., Mukai, H., Nomakuchi, S., Ueno, T. (2011) Trophic eggs compensate for poor offspring feeding capacity in a subsocial burrower bug. Biology Letters 7: 194-196.
  27. Kaiwa, N., Hosokawa, T., Kikuchi, Y., Nikoh, N., Meng, X.-Y., Kimura, N., Ito, M., Fukatsu, T. (2011) Bacterial symbionts of the giant jewel stinkbug Eucorysses grandis (Hemiptera: Scutelleridae). Zoological Science 28: 169-174.
  28. Kikuchi, Y., Hosokawa, T., Fukatsu, T. (2011) An ancient but promiscuous host-symbiont association between Burkholderia gut symbionts and their heteropteran hosts. The ISME Journal 5: 446-460.
  29. Kuriwada, T.*, Hosokawa, T.*, Kumano, N., Shiromoto, K., Haraguchi, D., Fukatsu, T. (2010) Biological role of Nardonella endosymbiont in its weevil host. PLoS ONE 5: e13101. (*Equal contributions)
  30. Hosokawa, T., Kikuchi, Y., Nikoh, N., Meng, X.-Y., Hironaka, M., Fukatsu, T. (2010) Phylogenetic position and peculiar genetic traits of a midgut bacterial symbiont of the stinkbug Parastrachia japonensisApplied and Environmental Microbiology 76: 4130-4135.
  31. Kaiwa, N., Hosokawa, T., Kikuchi, Y., Nikoh, N., Meng, X.-Y., Kimura, N., Ito, M., Fukatsu, T. (2010) Primary gut symbiont and secondary Sodalis-allied symbiont in the scutellerid stinkbug Cantao ocellatusApplied and Environmental Microbiology 76: 3486-3494.
  32. Hosokawa, T., Fukatsu, T. (2010) Nardonella endosymbiont in the West Indian sweet potato weevil Euscepes postfasciatus (Coleoptera: Curculionidae). Applied Entomology and Zoology 45: 115-120.
  33. Hosokawa, T., Koga, R., Kikuchi, Y., Meng, X.-Y., Fukatsu, T. (2010) Wolbachia as a bacteriocyte-associated nutritional mutualist. Proceedings of the National Academy of Sciences of the United States of America 107: 769-774.
  34. Toju, H., Hosokawa, T., Koga, R., Nikoh, N., Meng, X. Y., Kimura, N., Fukatsu, T. (2010) “Candidatus Curculioniphilus buchneri”, a novel clade of bacterial endocellular symbionts from weevils of the genus CurculioApplied and Environmental Microbiology 76: 275-282.
  35. Fukatsu, T., Hosokawa, T., Koga, R., Nikoh, N., Kato, T., Hayama, S., Takefushi, H., Tanaka, I. (2009) Intestinal endocellular symbiotic bacterium of the macaque louse Pedicinus obtusus: distinct endosymbiont origins in anthropoid primate lice and the Old World monkey louse. Applied and Environmental Microbiology 75: 3796-3799.
  36. Kikuchi, Y., Hosokawa, T., Nikoh, N., Meng, X. Y., Kamagata, Y., Fukatsu, T. (2009) Host-symbiont co-speciation and reductive genome evolution in gut symbiotic bacteria of acanthosomatid stinkbugs. BMC Biology 7: 2.
  37. Hosokawa, T., Kikuchi, Y., Shimada, M., Fukatsu, T. (2008) Symbiont acquisition alters behavior of stinkbug nymphs. Biology Letters 4: 45-48.
  38. Kikuchi, Y., Hosokawa, T., Fukatsu, T. (2007) Insect-microbe mutualism without vertical transmission: a stinkbug acquires a beneficial gut symbiont from the environment every generation. Applied and Environmental Microbiology 73: 4308-4316.
  39. Hosokawa, T., Kikuchi, Y., Fukatsu, T. (2007) How many symbionts are provided by mothers, acquired by offspring, and needed for successful vertical transmission in an obligate insect-bacterium mutualism? Molecular Ecology 16: 5316-5325.
  40. Hosokawa, T., Kikuchi, Y., Shimada, M., Fukatsu, T. (2007) Obligate symbiont involved in pest status of host insect. Proceedings of the Royal Society B 274: 1979-1984.
  41. Kageyama, D., Anbutsu, H., Watada, M., Hosokawa, T., Shimada, M., Fukatsu, T. (2006) Prevalence of a non-male-killing Spiroplasma in natural populations of Drosophila hydeiApplied and Environmental Microbiology 72: 6667-6673.
  42. Himuro, C., Hosokawa, T., Suzuki, N. (2006) Alternative mating strategy of small male Megacopta punctatissima (Hemiptera: Plataspidae) in the presence of large intraspecific males. Annals of Entomological Society of America 99: 974-977.
  43. Hosokawa, T., Kikuchi, Y., Nikoh, N., Shimada, M., Fukatsu, T. (2006) Strict host-symbiont cospeciation and reductive genome evolution in insect gut bacteria. PLoS Biology 4: e337.
  44. Hosokawa, T., Kikuchi, Y., Meng, X. Y., Fukatsu, T. (2005) The making of symbiont capsule in the plataspid stinkbug Megacopta punctatissima. FEMS Microbiology Ecology 54: 471-477.
  45. Fukatsu, T., Hosokawa, T. (2002) Capsule-transmitted gut symbiotic bacterium of the Japanese common plataspid stinkbug, Megacopta punctatissimaApplied and Environmental Microbiology 68: 389-396.
  46. Hosokawa, T., Suzuki, N. (2001) Significance of prolonged copulation under the restriction of daily reproductive time in the stink bug, Megacopta punctatissima (Heteroptera: Plataspidae). Annals of Entomological Society of America 94: 750-754.
  47. Hosokawa, T., Suzuki, N. (2000) Mating aggregation and copulatory success by males of the stink bug, Megacopta punctatissima (Heteroptera: Plataspidae). Applied Entomology and Zoology 35: 93-99.

英文(査読なし)
  1. Fukatsu, T., Hosokawa, T. (2008) Capsule-transmitted obligate gut bacterium of plataspid stinkbugs. In Insect Symbiosis Volume 3 (eds. K. Bourtzis and T. A. Miller), pp. 95-121. CRC Press, Boca Raton, USA
  2. Kikuchi, Y., Hosokawa, T., Fukatsu, T. (2008) Diversity of bacterial symbiosis in stinkbugs. In Microbial Ecology Research Trends (ed. T. V. Dijk), pp. 39-63. Nova Science Publishers Inc., N. Y.

和文(査読はあったりなかったり)
  1. 細川貴弘(2015)カメムシ類の生活を栄養面で支える共生細菌.昆虫と自然 50: 8-11.
  2. 細川貴弘(2012)マルカメムシ類と腸内共生細菌イシカワエラの絶対的共生−切り貼り自由な共生システム.種生物学会和文誌第35号「種間関係の生物学:共生・寄生・捕食の新しい姿」 p. 245-262.
  3. 細川貴弘(2011)吸血性昆虫トコジラミの菌細胞内に存在する相利共生型ボルバキアの発見.生物科学 63: 17-23.
  4. 細川貴弘(2011)マルカメムシのカプセルと腸内共生細菌−ありふれた昆虫の知られざる行動.遺伝 65: 36-42.
  5. 弘中満太郎・向井裕美・細川貴弘(2011)ベニツチカメムシは孵化直前に細菌を渡す.遺伝 65: 49-54.
  6. 貝和奈穂美・細川貴弘(2011)クヌギカメムシの卵塊ゼリー.遺伝 65: 55-60.
  7. 細川貴弘(2009)マルカメムシ類と腸内共生細菌イシカワエラ:内部共生研究の新しいモデル共生系.日本生態学会関東地区会会報 58: 9-13.
  8. 細川貴弘(2009)カメムシ類における腸内共生細菌の伝播・獲得様式の多様性.昆虫と自然 44 (11): 17-20.
  9. 細川貴弘(2008)マルカメムシ類の腸内共生細菌と利用できるエサ植物.植物防疫 62: 18-22.
  10. 深津武馬・細川貴弘(2007)マルカメムシがダイズ上で繁殖できる能力を腸内共生細菌が規定する.ブレインテクノニュース 124: 27-30.
その他の執筆
  1. 行動生物学辞典(2013, 東京化学同人)分担執筆.
学位論文
平成15年3月25日 九州大学大学院理学府(甲第867号)
「マルカメムシの交尾時間のばらつきを生じさせる要因」
主査:粕谷英一(九州大学)、副査:矢原徹一(九州大学)、宮竹貴久(岡山大学)

アウトリーチ活動
  1. 細川貴弘(2011)カメムシのおかあさんの置き土産〜母から子へ伝えられる腸内細菌のひみつ〜.慶應義塾大学教養研究センター極東証券寄付講座「生命の教養学」一般公開ゼミ サイエンスカフェ22.
  2. 細川貴弘・深津武馬(2007)利用できるエサ植物は腸内共生細菌で決まる.むしむしコラム・おーどーこん-近くて不思議な虫の世界-http://column.odokon.org/archives/2007/0802_170330.php
  3. 細川貴弘・深津武馬(2007)マルカメムシの共生細菌カプセル.むしむしコラム・おーどーこん-近くて不思議な虫の世界- http://column.odokon.org/archives/2007/0802_171507.php
競争的資金獲得状況
  1. 平成29〜31年度:日本学術振興会科学研究費助成事業基盤研究(B)17H03946.(代表)「南西諸島で発見された新興共生細菌はどんなカメムシとも共生可能か?」:8,800千円
  2. 平成29〜33年度:日本学術振興会科学研究費助成事業新学術領域「進化の制約と方向性 〜微生物から多細胞までを貫く表現型進化原理の解明〜」計画研究A04(分担)「昆虫―微生物共生可能性の探索と分子基盤の解明」:4,000千円
  3. 平成27〜28年度:日本学術振興会科学研究費助成事業若手研究(B)15K21209.(代表)「カメムシ類の必須共生細菌はなぜ南西諸島でのみ多様化したのか?」:3,100千円.
  4. 平成27〜28年度:日本学術振興会科学研究費助成事業基盤研究(S).(分担)「昆虫―大腸菌人工共生系による共生進化および分子機構の解明」:3,000千円
  5. 平成26年度:琉球大学後援財団教育研究奨励事業、若手研究者による琉球・沖縄研究への支援.(代表)「なぜ琉球列島だけで昆虫の共生細菌が多様化したのか?:土壌中に存在する共生細菌ソースの比較分析」:500千円.
  6. 平成25年度:琉球大学後援財団教育研究奨励事業、若手研究者による琉球・沖縄研究への支援.(代表)「琉球列島のカメムシ類における体内共生細菌の多様性とその形成過程および維持機構の解明」:500千円.
  7. 平成15〜17年度:日本学術振興会特別研究員研究費PD.(代表)「マルカメムシにおける宿主−共生細菌間の相互作用と共進化」:3,300千円.
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