論文・総説 - 田賀 哲也

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  1. Tanakorn Tarapongpun, Nattawat Onlamoon, Kouichi Tabu, Suebwong Chuthapisith, Tetsuya Taga. The optimized priming effect of FGF-1 and FGF-2 enhances preadipocyte lineage commitment in human adipose-derived mesenchymal stem cells. Genes Cells. 2024.03; 29 (3): 231-253. ( PubMed, DOI )

  2. Murota Y, Nagane M, Wu M, Santra M, Venkateswaran S, Tanaka S, Bradley M, Taga T, Tabu K. A niche-mimicking polymer hydrogel-based approach to identify molecular targets for tackling human pancreatic cancer stem cells. Inflammation and regeneration. 2023.09; 43 (1): 46. ( PubMed, DOI )

  3. Melig Gerel, Nobuhisa Ikuo, Saito Kiyoka, Tsukahara Ryota, Itabashi Ayumi, Kanai Yoshiakira, Kanai-Azuma Masami, Osawa Mitsujiro, Oshima Motohiko, Iwama Atsushi, Taga Tetsuya. A Sox17 downstream gene Rasip1 is involved in the hematopoietic activity of intra-aortic hematopoietic clusters in the midgestation mouse embryo Inflammation and Regeneration. 2023.08; 43 (1): 41. ( PubMed, DOI )

  4. Kashiwagi Taichi, Takazawa Yuuki, Kagawa Tetsushi, Taga Tetsuya. Organization of self-advantageous niche by neural stem/progenitor cells during development via autocrine VEGF-A under hypoxia Inflammation and Regeneration. 2023.02; 43 (1): 8. ( PubMed, DOI )

  5. Wenqian Wang, Kouichi Tabu, Alapati Aimaitijiang, Tetsuya Taga. Therapy-resistant nature of cancer stem cells in view of iron metabolism Inflammation and Regeneration. 2022.11; 42 (1): 34.

  6. Tabu Kouichi, Taga Tetsuya. Cancer ego-system in glioma: an iron-replenishing niche network systemically self-organized by cancer stem cells Inflammation and Regeneration. 2022.11; 42 (1): 54. ( PubMed, DOI )

  7. Yoshitaka Murota, Kouichi Tabu, Tetsuya Taga. Cancer Stem Cell-Associated Immune Microenvironment in Recurrent Glioblastomas Cells. 2022.06; 11 (13): 2054.

  8. Aimaitijiang Alapati, Tabu Kouichi, Wang Wenqian, Nobuhisa Ikuo, Taga Tetsuya. Glioma cells remotely promote erythropoiesis as a self-expanding strategy of cancer stem cells GENES TO CELLS. 2022.01; 27 (1): 25-42. ( PubMed, DOI )

  9. Suzuki I, Yoshida S, Tabu K, Kusunoki S, Matsumura Y, Izumi H, Asanoma K, Yagi H, Onoyama I, Sonoda K, Kohno K, Taga T, Takeda S, Kato K. YBX2 and cancer testis antigen 45 contribute to stemness, chemoresistance and a high degree of malignancy in human endometrial cancer Scientific Reports. 2021.02; 11 (1): 4220.

  10. Anani M, Nobuhisa I, Taga T. Sry-related High Mobility Group Box 17 Functions as a Tumor Suppressor by Antagonizing the Wingless-related Integration Site Pathway. Journal of Cancer Prevention. 2020.12; 25 (4): 204-212. ( PubMed, DOI )

  11. Takahashi S, Nobuhisa I, Saito K, Melig G, Itabashi A, Harada K, Osawa M, Endo AT, Iwama A,Taga T. Sox17-mediated expression of adherent molecules is required for the maintenance of undifferentiated hematopoietic cluster formation in midgestation mouse embryos Differentiation. 2020.09; 115 53-61. ( DOI )

  12. Tabu K, Liu W, Kosaku A, Terashima K, Murota Y, Aimaitijiang A, Nobuhisa I, Hide T, Taga T. Glioma stem cell (GSC)-derived autoschizis-like products confer GSC niche properties involving M1-like tumor-associated macrophages. Stem cells (Dayton, Ohio). 2020.08; 38 (8): 921-935. ( PubMed, DOI )

  13. Nobuhisa Ikuo, Saito Kiyoka, Tsukahara Ryota, Azuma Koya, Melig Gerel, Itabashi Ayumi, Taga Tetsuya. Hematopoiesis and Immune Environment Involvement of TET1 inthe maintenance of the hematopoietic capacity in hematopoietic cell clusters in the dorsal aorta in midgestation mouse embryo(和訳中) 日本免疫学会総会・学術集会記録. 2019.11; 48 (Proceedings): 1-H. ( 医中誌 )

  14. 椨 康一, 田賀 哲也. グリオーマの新規治療標的としての単球動員がん幹細胞の可視化と検証(Visualization and validation of monocyte-recruiting cells as a potential target of glioma stem cells) 日本癌学会総会記事. 2019.09; 78回 P-3064. ( 医中誌 )

  15. AIMAITIJIANG ALAPATI, 椨 康一, 田賀 哲也. グリオーマ幹細胞によるマウス骨髄赤芽球分化の促進(Glioma stem cells modulate erythropoiesis in mouse bone marrow) 日本癌学会総会記事. 2019.09; 78回 P-3065. ( 医中誌 )

  16. Tabu Kouichi, Taga Tetsuya. A monocyte-recruiting phenotype defines functional heterogeneity of glioma cells with stemness and chemoresistance CANCER SCIENCE. 2018.12; 109 1308.

  17. 椨 康一, 田賀 哲也. グリオーマにおける単球動員亜集団は幹細胞性と薬剤耐性を有する(A monocyte-recruiting phenotype defines functional heterogeneity of glioma cells with stemness and chemoresistance) 日本癌学会総会記事. 2018.09; 77回 2314. ( 医中誌 )

  18. Saito K, Nobuhisa I, Harada K, Takahashi S, Anani M, Lickert H, Kanai-Azuma M, Kanai Y, and Taga T . Maintenance of hematopoietic stem and progenitor cells in fetal intra-aortic hematopoietic clusters by the Sox17-Notch1-Hes1 axis Exp Cell Res. 2018.04; 365 (1): 145-155. ( DOI )

  19. Ito K, Noguchi A, Uosaki Y, Taga T, Arakawa H, Takizawa.. Gfap and Osmr regulation by BRG1 and STAT3 via interchromosomal gene clustering in astrocytes. Mol Biol Cell. 2018.01; 29 209-219. ( DOI )

  20. Murota Yoshitaka, Tabu Kouichi, Taga Tetsuya. Establishment of glioma mouse model by transducing oncogenic H-RasV12 gene into the p53 deficient astrocytes CANCER SCIENCE. 2018.01; 109 631.

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