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プレプリント 原著 総説 著書 新聞発表等 講演

プレプリント

  1. Sato T, Li YI, Jorg DJ, Komeya M, Yamanaka H, Nakamura H, Hirano K, Kondo Y, Aoki K, Takahashi M, Nakata H, Kimura H, Ogawa T, Simons BD, Yoshida S. Self-organization of spermatogenic wave coordinates sustained sperm production in the mouse testis. bioRxiv doi: https://doi.org/10.1101/2024.11.03.621757
  2. Chakravorty A, Simons BD, Yoshida S, Cai L. Spatial Transcriptomics Reveals the Temporal Architecture of the Seminiferous Epithelial Cycle and Precise Sertoli-Germ Synchronization. bioRxiv doi: https://doi.org/10.1101/2024.10.28.620681

原著

( * : corresponding author)

  1. Kawahara T, Suzuki S, Nakagawa T, Kamo Y, Kanouchi M, Fujita M, Hattori M, Suzuki A, Tanemura K, Yoshida S, Hara K. Age-Dependent Clonal Expansion of Non-Sperm-Forming Spermatogonial Stem Cells in Mouse Testes.Aging Cell Feb 22: e70019, 2025, oline ahead of print, DOI: 10.1111/acel.70019
  2. Hu M, Yeh U-H, Maezawa S, Nakagawa T, Yoshida S, Namekawa S. PRC1 directs PRC2-H3K27me3 deposition to shield adult spermatogonial stem cells from differentiation. Nucleic Acids Research 52(5): 2306-2322, (2024), doi: 10.1093/nar/gkad1203
  3. Hirano K, Nonami Y, Nakamura Y, Sato T, Sato T, Ishiguro K, Ogawa T, Yoshida S. Temperature sensitivity of DNA double-strand break repair underpins heat-induced meiotic failure in mouse spermatogenesis. Communications Biology 5, 504 (2022), doi:10.1038/s42003-022-03449-y
  4. * Nakagawa T, Jörg D J, Watanabe H, Mizuno S, Han S, Ikeda T, Omatsu Y, Nishimura K, Fujita M, Takahashi S, Kondoh G, Simons B D, * Yoshida S, *Nagasawa T: A multistate stem cell dynamics maintains homeostasis in mouse spermatogenesis. Cell Reports 37, 109875 (2021), doi:10.1016/j.celrep.2021.109875
  5. Osawa Y, Murata K, Usui M, Kuba Y, Le H, Mikami N, Nakagawa T, Daitoku Y, Kato K, Shawki H, Ikeda Y, Kuno A, Morimoto K, Tanimoto Y, Dinh T, Yagami K, Ema M, Yoshida S, Takahashi S, Mizuno S, Sugiyama F. EXOC1 plays an integral role in spermatogonia pseudopod elongation and spermatocyte stable syncytium formation in mice. eLife 2021;10:e59759 DOI: 10.7554/eLife.59759
  6. Nakamura Y, Jörg DJ, Kon Y, Simons BD and Yoshida S: Transient suppression of transplanted spermatogonial stem cell differentiation restores fertility in mice. Cell Stem Cell, 28: 1443-1456, 2021 doi: 10.1016/j.stem.2021.03.016
  7. D.J. Jörg, Y. Kitadate, S. Yoshida, and B.D. Simons: Stem Cell Populations as Self-Renewing Many-Particle Systems (2021-03-10) Annual Review of Condensed Matter Physics 10.1146/annurev-conmatphys-041720-125707doi:10.1146/annurev-conmatphys-041720-125707
  8. Y.H. Yeh, M. Hu, T. Nakagawa, A. Sakashita, S. Yoshida, S. Maezawa and S.H. Namekawa: Isolation of Murine Spermatogenic Cells using a Violet-Excited Cell-Permeable DNA Binding Dye. J Vis Exp 167 (2021) 10.3791/61666 PubMedLink
  9. C.A. Rezende-Melo, A.L. Caldeira-Brant, A.L. Drumond-Bock, G.M. Buchold, G. Shetty, F.R.C.L. Almeida, M.M. Matzuk, K. Hara, S. Yoshida, M.L. Meistrich and H. Chiarini-Garcia: Spermatogonial asynchrony in Tex14 mutant mice lacking intercellular bridges. Reproduction 160, 205-215 (2020) doi: 10.1530/Rep-20-0118
  10. Sznurkowska MK, Hannezo E, Azzarelli R, Chatzeli L, Ikeda T, Yoshida S, Philpott A and Simons BS. Tracing the cellular basis of islet specification in mouse pancreas. Nature Communications 11(1):5037, 2020 DOI: 10.1038/s41467-020-18837-3 PubMedLink
  11. Seiji Hira, Shoichi Nakamura, Masato Fujiwara, Nasa Miyagata, Takuma Tsuji, Akane Kondo, Hiroshi Kimura, Yuko Shinozuka, Makoto Hayashi, Satoru Kobayashi and Masanori Mukai*: A truncated form of a transcription factor Mamo activates vasa in Drosophila embryos. Communications biology 2:422 (2019) doi:10.1038/s42003-019-0663 DOI
  12. T. Shinozuka, R. Takada, S. Yoshida, S. Yonemura and S. Takada: Wnt produced by stretched roof-plate cells is required for the promotion of cell proliferation around the central canal of the spinal cord. Development 146, (2019) doi: 10.1242/dev.159343PubMedLink
  13. Kitadate Y, Jörg DJ, Tokue M, Maruyama A, Ichikawa R, Tsuchiya S, Segi-Nishida E, Nakagawa T, Uchida A, Kimura-Yoshida C, Mizuno S, Sugiyama F, Azami T, Ema M, Noda C, Kobayashi S, Matsuo I, Kanai Y, Nagasawa T, Sugimoto Y, Takahashi S, Simons BD and *Yoshida S.: Competition for mitogens regulates spermatogenic stem cell homeostasis in an open niche. Celll Stem Cell 24(1): 79-92, 2019 PubMedLink
  14. S. Sakamoto, D. Thumkeo, H. Ohta, Z. Zhang, S.R. Huang, P. Kanchenawong, T. Fuu, S. Watanabe, K. Shimada, Y. Fujihara, S. Yoshida, M. Ikawa, N. Watanabe, M. Saitou and S. Narumiya: mDia1/3 generate cortical F-actin meshwork in Sertoli cells that is continuous with contractile F-actin bundles and indispensable for spermatogenesis and male fertility. PLoS Biology 16(9):e2004874 https://journals.plos.org/plosbiology/article?id=10.1371/journal.pbio.2004874 Sep 26, 2018
  15. Suzuki N, Hirano K, Ogino H and Ochi H: Arid3a regulates nephric tubule regeneration via evolutionarily conserved regeneration signal-response enhancers. eLife https://doi.org/10.7554/eLife.43186 January 8, 2019
  16. H. H. Shawki, H. Oishi, T. Usui, Y. Kitadate, W. A. Basha, A. M. Abdellatif, K. Hasegawa, R. Okada, K. Mochida, H. A. El-Shemy, M. Muratani, A. Ogura, S. Yoshida and S. Takahashi: MAFB is dispensable for the fetal testis morphogenesis and the maintenance of spermatogenesis in adult mice. PLOS one https://doi.org/10.1371/journal.pone.0190800 January 11, 2018
  17. Tokue, M., Ikami, K., Mizuno, S., Takagi, C., Miyagi, A., Takada, R., Noda, C., Kitadate, Y., Hara, K., Mizuguchi, H., Sato, T., Taketo, M. M., Sugiyama, F., Ogawa, T., Kobayashi, S., Ueno, N., Takahashi,, S., Takada, S., and *Yoshida, S. SHISA6 confers resistance to differentiation-promoting Wnt/beta-catenin signaling in mouse spermatogenic stem cells. Stem Cell Reports 8: 561-575, 2017PubMedLink
  18. Ikami, K., Tokue, M., Sugimoto, R., Noda, C., Kobayashi, S., Hara, K., and *Yoshida, S. Hierarchical differentiation competence in response to retinoic acid ensures stem cell maintenance during mouse spermatogenesis. Development 142:1582-1592, 2015PubMedLink
  19. K. Ikegami, Y. Atsumi, E. Yorinaga, H. Ono, I. Murayama, Y. Nakane, W. Ota, N. Arai, A. Tega, M. Iigo, V. M. Darras, K. Tsutsui, Y. Hayashi, S. Yoshida, and *T. Yoshimura: Low temperature-induced circulating triiodothyronine accelerates seasonal testicular regression. Endocrinology Published Online: November 18, 2014PubMedLink
  20. K. Hara, T. Nakagawa, H. Enomoto, M. Suzuki, M. Yamamoto, *B. D. Simons and *S. Yoshida: Mouse spermatogenic stem cells continually interconvert between equipotent singly isolated and syncytial states. Cell Stem Cell 14:658-672, 2014PubMedLink
  21. Y. Nakamura, M. Tasai, K. Takeda, K. Nirasawa and T. Tagami: Production of functional gametes from cryopresereved primordial germ cells of the Japanese quail. Journal of Reproduction and Development 59, 580-7, 2013PubMedLink
  22. Y. Nonami, K. Narita, H. Nakamura, T. Inoue and S. Takeda: Developmental changes in ciliary motility on choroid plexus epithelial cells during the perinatal period. Cytoskeleton (Hoboken) 70, 797-803, 2013PubMedLink
  23. Shirakawa T, Yaman-Deveci R, Tomizawa S, Kamizato Y, Nakajima K, Sone H, Sato Y, Sharif J, Yamashita A, Takada-Horisawa Y, Yoshida S, Ura K, Muto M, Koseki H, Suda T and Ohbo K. An epigenetic switch is crucial for spermatogonia to exit the undifferentiated state toward a Kit-positive identity. Development140, 3565-3576, 2013PubMedLink
  24. Uemura M, Ozawa A, Nagata T, Kurasawa K, Tsunekawa N, Nobuhisa I, Taga T, Hara K, Kudo A, Kawakami H, Saijoh Y, Kurohmaru M, Kanai-Azuma M and Kanai Y. Sox17 haploinsufficiency results in perinatal biliary atresia and hepatitis in C57BL/6 background mice. Development 140: 639-648 , 2013PubMedLink
  25. Sato T, Yokonishi T, Komeya M, Katagiri K, Kubota Y, Matoba S, Ogonuki N, Ogura A, Yoshida S and Ogawa T. Testis tissue explantation cures spermatogenic failure in c-Kit ligand mutant mice. Proc. Natl. Acad. Sci. USA 109(47): 16934-16938, 2012PubMedLink
  26. *Nakamura Y, Usui F, Miyahara D, Mori T, Ono T, Kagami H, Takeda K, Nirasawa K and Tagami T. X-irradiation removes endogenous primordial germ cells (PGCs) and increases germline transmission of donor PGCs in chimeric chickens. Journal of Reproduction and Development 58: 432-437, 2012PubMedLink
  27. Narita K, Kozuka-Hata H, Nonami Y, Ao-Kondo H, Suzuki T, Nakamura H, Yamakawa K, Oyama M, Inoue T, Takeda S. Proteomic analysis of multiple primary cilia reveals a novel mode of ciliary development in mammals. Biology Open1(8): 815-25, 2012PubMedLink
  28. Koyanagi S, Hamasaki H, Sakiguchi S, Hara K, Ishii Y, Kyuwa S and Yoshikawa Y. Effects of ubiquitin C-terminal hydrolase -L1 deficiency on mouse ova. Reproduction 143(3): 271-279, 2012PubMedLink
  29. R. Sugimoto, Y-i. Nabeshima and *S. Yoshida. Retinoic acid metabolism links the periodical differentiation of germ cells with the cycle of Sertoli cells in mouse seminiferous epithelium. Mechanisms of Development 128(11-12): 610-624, 2012 PubMedLink
  30. T. Sato, Y. Aiyama, M. Ishii-Inagaki, K. Hara, N. Tsunekawa, K. Harikae, M. Uemura-Kamata, M. Shinomura, X. B. Zhu, S. Maeda, S. Kuwahara-Otani, A. Kudo, H. Kawakami, M. Kanai-Azuma, M. Fujiwara, Y. Miyamae, S. Yoshida, M. Seki, M. Kurohmaru and *Y. Kanai. Cyclical and patch-like GDNF distribution along the basal surface of sertoli cells in mouse and hamster testes. PLoS ONE 6(12): e28367 (2011)PubMedLink
  31. A. Gely-Pernot, M. Raverdeau, C. Célébi, C. Dennefeld, B. Feret, M. Klopfenstein, S. Yoshida, N. B. Ghyselinck, and *M. Mark. Spermatogonia differentiation requires retinoic acid receptor gamma. Endocrinology 153(1): 438-449 (2011)PubMedLink
  32. C.K. Matson, M.W. Murphy, M.D. Griswold, S. Yoshida, V.J. Bardwell and *D. Zarkower. The mammalian Doublesex homolog DMRT1 is a transcriotional gatekeeper that control the mitosis versus meiosis decision in male germ cells. Developmental Cell 19(4): 612-624 (2010)PubMedLink
  33. A.M. Klein, T. Nakagawa, R. Ichikawa, *S. Yoshida, *B.D. Simons. Mouse germ line stem cells undergo rapid and stochastic turnover. Cell Stem Cell 7(2): 214-224 (2010)PubMedLink
  34. Y. Nakane, K. Ikegami, H. Ono, N. Yamamoto, S. Yoshida, K. Hirunagi, S. Ebihara, Y. Kubo and *T. Yoshimura. A mammalian neural tissue opsin (Opsin 5) is a deep brain photoreceptor in birds. Proc. Natl. Acad. Sci. USA. 107(34): 15264-15268 (2010)PubMedLink
  35. Y. Kitadate and *S. Kobayashi. Notch and Egfr signaling act antagonistically to regulate germline stem cell niche formation in Drosophila male embryonic gonads. Proc. Natl. Acad. Sci. USA. 107(32): 14241-14246 (2010)PubMedLink
  36. T. Nakagawa, M. Sharma, Y-i. Nabeshima, R.E. Braun, *S. Yoshida. Functional hierarchy and reversibility within the murine spermatogenic stem cell compartment. Science 328(5974): 62-67 (2010) PubMedLink

    evaluation:
    Spradling A and Fan C-M.: Counterfeiting the family jewels. Cell Stem Cell 6(5):405-406 (2010) Preview

  37. M. Uemura, K. Hara, H. Shitara, R. Ishii, N. Tsunekawa, Y. Miura, M. Kurohmaru, C. Taya, H. Yonekawa, M. Kanai-Azuma, *Y. Kanai. Expression and function of mouse Sox17 gene in the specification of gallbladder/bile-duct progenitors during early foregut morphogenesis. Biochem. Biophys. Res. Commun. 391(1):357-363 (2010) PubMedLink
  38. H. Suzuki, A. Sada, S. Yoshida and *Y. Saga: The heterogeneity of spermatogonia is revealed by their topology and expression of marker proteins including the germ cell-specific proteins Nanos2 and Nanos3. Developmental Biology 336(2): 222-31 (2009) PubMedLink
  39. Y. Sato, T. Watanabe, D. Saito, T. Takahashi1, S. Yoshida, J. Kohyama, E. Ohata, H. Okano, and *Y. Takahashi: Notch signaling mediates the segmental specification of angioblasts in somites and their directed migration toward the dorsal aorta in avian embryos. Developmental Cell 14, 890-901 (2008) PubMedLink
  40. *S. Yoshida, M. Sukeno and Y-i. Nabeshima: A vasculature-associated niche for undifferentiated spermatogonia in the mouse testis. Science 317, 1772-1776 (2007) PubMedLink

    evaluations:
    S. DiNardo and R. E. Braun: Home for the Precious Few. Science 317, 1696-1697 (2007) Perspective
    G. Shetty and M. L. Meistrich: The Missing Niche for Spermatogonial Stem Cells: Do Blood Vessels Point the Way? Cell Stem Cell 1, 361-363 (2007) Preview
    Fuculty of 1000: Must Read

  41. T. Nakagawa, Y-i. Nabeshima and *S. Yoshida: Functional identification of the actual and potential stem cell compartments in mouse spermatogenesis. Developmental Cell 12, 195-206 (2007) PubMedLink

    evaluations:
    A. Simon and J. Frisen: From Stem Cell to Progenitor and Back Again. Cell 128, 825-826 (2007) Preview
    Personal sperm bank. Nature 445, 798 (2007) Research Highlights
    Fuculty of 1000: Must Read

  42. M. Kanatsu-Shinohara, K. Inoue, N. Ogonuki, H. Miki, S. Yoshida, S. Toyokuni, J. Lee, A. Ogura, and *T. Sinohara: Leukemia inhibitory factor enhances germ cell colony formation in neonatal mouse testis culture. Biol. Reprod. 76, 55-62 (2007) PubMedLink
  43. S. Shiraishi, C. Zhou, T. Aoki, N. Sato, T. Chiba, K. Tanaka, S. Yoshida, Y. Nabeshima, and Y-i. Nabeshima, and *T. Tamura: TBP-interacting protein 120b (TIP120B) /cullin-associated and neddylation-dissociated 2 (CAND2) inhibits SCF-dependent ubiquitination of myogenin and accelerates myogenic differentiaton. J. Biol. Chem. 282, 9017-28 (2007) PubMedLink
  44. *S. Yoshida, M. Sukeno, T. Nakagawa, K. Ohbo, G. Nagamatsu, T. Suda, and Y-i. Nabeshima: The first round of mouse spermatogenesis is a distinctive program that lacks the self-renewing spermatogonia stage. Development 133, 1495-1505 (2006) PubMedLink

    evaluated by Fuculty of 1000: Recommended

  45. G. Nagamatsu, M. Ohmura, T. Mizukami, I. Hamaguchi, S. Hirabayashi, S. Yoshida, Y. Hata, T. Suda, and *K. Ohbo: CTX family cell adhesion molecule, JAM4, expresses in stem cell- and progenitor cell-populations of both male germ cell and hematopoietic cell lineages. Mol. Cell. Biol. 26, 8498-506 (2006) PubMedLink
  46. *S. Yoshida, A. Takakura, K. Ohbo, K. Abe, J. Wakabayashi, M. Yamamoto, T. Suda, and Y-i. Nabeshima: neurogenin3 delineates the earliest stages of spermatogenesis in the mouse testis. Developmental Biology 269, 447-458 (2004) PubMedLink
  47. M. Ohmura, S. Yoshida, Y. Ide, G. Nakamatsu, T. Suda, and *K. Ohbo: Spatial analysis of germ stem cell development in Oct-4/EGFP transgenic mouse. Arch. Histol. Cytol. 67, 285-296 (2004) PubMedLink
  48. K. Ohbo, S. Yoshida, M. Ohmura, O. Ohneda, M. Ogawa, H. Tsuchiya, T. Kuwana, J. Kehler, K. Abe, HR. Schöler and *T. Suda: Identification and characterization of stem cells in pre-pubertal spermatogenesis in mice. Developmental Biology 258, 209-225 (2003) PubMedLink
  49. *H. Takebayashi, Y. Nabeshima, S. Yoshida, O. Chisaka, K. Ikenaka and Y-i. Nabeshima: The basic helix-loop-helix factor Olig2 is essential for development of motoneuron and oligodendrocyte lineages. Current Biology, 12, 1157-1163 (2002) PubMedLink
  50. *S. Yoshida, K. Ohbo, A. Takakura, H. Takebayashi, T. Okada, K. Abe and Y-i Nabeshima: Sgn1, a basic helix-loop-helix transcription factor delineates the salivary gland duct cell lineage in mice. Developmental Biology 240, 517-530 (2001) PubMedLink
  51. R. Mizuguchi, M. Sugimori, H. Takebayashi, H. Kosako, M. Nagao, S. Yoshida, Y-i. Nabeshima, K. Shimamura and *M. Nakafuku: Combinatorial roles of Olig2 and Neurogenin2 in the coordinated induction of pan-neuronal and subtype-specific properties of motoneurons. Neuron 31, 757-771 (2001) PubMedLink
  52. *H. Takebayashi, S. Yoshida, M. Sugimori, H. Kosako, R. Kominami, M. Nakafuku and Y-i. Nabeshima: Dynamic expression of basic helix-loop-helix Olig family members: implication of Olig2 in neuron and oligodendrocyte differentiation and identification of a new member, Olig3. Mech. Dev. 99, 143-148 (2000) PubMedLink
  53. N. Yoshida, *S. Yoshida, M. Araie, H. Handa and Y-i. Nabeshima: Ets family transcription factor ESE-1 is expressed in corneal epithelial cells and is involved in their differentiation. Mech. Dev. 97, 27-34 (2000) PubMedLink
  54. Y. Sugiyama, A. Suzuki, M. Kishikawa, R. Akutsu, T. Hirose, M. M. Y. Way, S. K. W. Tsui, S. Yoshida, and *S. Ohno: Muscle develops a specific form of small heat shock protein complex composed of MKBP/HSPB2 and HSPB3 during myogenic differentiation. J. Biol. Chem. 275, 1095-1104 (2000) PubMedLink
  55. §N. Yoshida, *§S. Yoshida, K. Koishi, K. Masuda and Y-i. Nabeshima: Cell heterogeneity upon myogenic differentiation: down-regulation of MyoD and Myf-5 generates the "reserve cells". J. Cell Science 111,769-779 (1998) §co-first authors PubMedLink
  56. *S. Yoshida, A. Fujisawa-Sehara, T. Taki, K-i. Arai and Y-i. Nabeshima: Lysophosphatidic acid and bFGF control different modes in proliferating myoblasts. J. Cell Biol. 132,181-193 (1996) PubMedLink
  57. R. Nishinakamura, N. Nakayama, Y. Hirabayashi, T. Inoue, D. Aud, T.McNeil, S. Azuma, S. Yoshida, Y. Toyoda, K-i. Arai, A.Miyajima and *R. Murray: Mice deficient for the IL-3/GM-CSF/IL-5 beta-c receptor exhibit lung pathology and impaired immune response, while beta-IL3 receptor-deficient mice are normal. Immunity 2, 211-222 (1995) PubMedLink

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総説

( * : corresponding author)

  1. *Y. Kitadate and S. Yoshida: Regulation of spermatogenic stem cell homeostasis by mitogen competition in an open niche microenvironment. Genes & Genetic Systems 96, 1-11 (2021)
  2. S. Yoshida: Mouse Spermatogenesis Reflects the Unity and Diversity of Tissue Stem Cell Niche Systems. Cold Spring Harb Perspect Biol, (2020) 10.1101/cshperspect.a036186
  3. S. Yoshida: Heterogeneous, dynamic, and stochastic nature of mammalian spermatogenic stem cells. Curr Top Dev Biol. 135, 245-285 (2019). doi: 10.1016/bs.ctdb.2019.04.008.
  4. S. Yoshida: Open niche regulation of mouse spermatogenic stem cells. Dev Growth Differ 60, 542-552 (2018) 10.1111/dgd.12574
  5. Yoshida, S. (2018). Chapter 12: Regulatory mechanism of spermatogenic stem cells in mice: their dynamic and context-dependent behavior. Chapter 4 in Reproductive and Developmental Strategies, ed. Kazuya Kobayashi, Takeshi Kitano, Yasuhiro Iwao, and Mariko Kondo, Springer Japan KK, part of Springer Nature 47-67.
  6. 吉田松生:精子幹細胞と精巣の開放型ニッチ 特集「幹細胞の恒常性維持とその破綻」月刊細胞 6月号, 15-18, Vol.50 No.7 (通巻666号)(2018)
  7. 吉田松生:生殖細胞:それは次の世代に命をつなげるバトン 特集「発生ー卵から始まる生き物の形づくり」国立科学博物館milsil 56号, 13-14, 3月1日発行 (2017)
  8. *Yoshida S. : From cyst to tubule: innovations in vertebrate spermatogenesis. WIREs Developmental Biology 5, 119-131, 2015
  9. 吉田松生:ギルバート発生生物学 第17章(翻訳)
    Develpomental Biology, tenth edition
    Scott F. Gilebert 2013年刊 メディカルサイエンスインターナショナルP599-635, 2015年3月
  10. 吉田松生:マウス精子幹細胞の動態からニッチの本質を考える.実験医学 32(16), 2567-2573 (2014)
  11. *Nakamura Y, Kagami H and Tagami T. Development, differentiation and manipulation of chicken germ cells. Develop. Growth Differ., 55; 20-40, 2013PubMedLink
  12. *Yoshida S. Elucidating the identity and behavior of spermatogenic stem cells in the mouse testis. Reproduction, 144: 293-302, 2012PubMedLink
  13. 吉田松生:配偶子幹細胞 世代をつなぐキープレーヤーの正体と可能性.(監修) 細胞工学 29 (2010)
  14. 吉田松生:配偶子幹細胞 世代をつなぐキープレーヤーの正体と可能性.基礎の基礎. 細胞工学 29, 634-637 (2010)
  15. 北舘 祐、吉田松生:マウスの精子形成幹細胞集団とニッチ.細胞工学 29, 652-657 (2010)
  16. *S. Yoshida: Stem cells in mammalian spermatogenesis. Development, Growth and Differentiation 52(3): 311-317 (2010) PubMedLink
  17. *S. Yoshida: Casting back to stem cells. Nature Cell Biology 11, 118-120 (2009) PubMedLink

    comment on: News and Views for Barroca et al., Nature Cell Biology 11, 190-196 (2009)

  18. 中川俊徳、吉田松生:哺乳類精子形成の継続性を保証する幹細胞メカニズム.実験医学 27, 373-379 (2009)
  19. 吉田松生:マウス精子形成の幹細胞ニッチに“形”はあるか? 細胞工学, 27, (2008)
  20. 吉田松生:マウス精子形成から見えてきた「しなやかな」幹細胞-ニッチシステム. 蛋白質核酸酵素 53, 1125-1132 (2008)
  21. 吉田松生:ほ乳類精子形成幹細胞研究の展開と展望. 生化学 80 9-13 (2008)
  22. *S. Yoshida, Y-i. Nabeshima, and T. Nakagawa: Stem Cell Heterogeneity: Actual and Potential Stem Cell Compartments in the Mouse Spermatogenesis. Annals NY Acad Sci. 1120, 47-58 (2007) PubMedLink
  23. 吉田松生:哺乳類精巣における精子形成幹細胞システム. 蛋白質核酸酵素 増刊「生殖細胞の発生・エピジェネティクスと再プログラム化」2080-2086 (2007)
  24. 吉田松生:生殖幹細胞ニッチ −“モデル動物”から“哺乳類”を考える. 医学のあゆみ, 221 569-574, (2007)
  25. 吉田松生:骨格筋分化の転写制御. 転写因子・転写制御キーワードブック 羊土社 (2006)
  26. 吉田松生:MyoDファミリー. 転写因子・転写制御キーワードブック 羊土社 (2006)
  27. 吉田松生:MEF-2ファミリー. 転写因子・転写制御キーワードブック 羊土社 (2006)
  28. 吉田松生:MyoDファミリー. BioScience 新用語ライブラリー転写因子 改訂第2版 羊土社 (1999)
  29. 吉田松生:骨格筋の分化と増殖はどのように制御されているか? 実験医学 15, 380-386 (1997)
  30. 吉田松生、鍋島陽一: 筋細胞の決定、増殖、分化とMyoDファミリー. 細胞工学 14, 781-788 (1995)

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著書

  1. 吉田松生 : 配偶子形成. "遺伝学の百科事典ー継承と多様性の源" 日本遺伝学会編 丸善出版 2022
  2. S. Yoshida: Regulatory Mechanism of Spermatogenic Stem Cells in Mice: Their Dynamic and Context-Dependent Behavior. “Reproductive and Developmental Strategies” The Continuity of Life, Part I: Divesity in Reproductive Stragegies and Germ Cell Differentiation Mechanisms, Chapter 4, Editors: Kazuya Kobayashi, Takeshi Kitano, Yasuhiro Iwao, and Mariko Kondo, Springer Japan KK, part of Springer Nature 2018, 47-67, (2018) https://doi.org/10.1007/978-4-431-56609-0, ISSN 2509-5536
  3. *S. Yoshida: Stem cell niche system in mouse spermatogenesis. Stem Cell Biology and Regenerative Medicine Series, "Male Germline Stem Cells: Developmental and Regenerative Potential" Humana Press, 159-175 (2011)
  4. *S. Yoshida: Spermatogenic stem cell system in the mouse testis. Cold Spring Harbor Laboratory Symposia on Quantitative Biology Series, "Control and Regulation of Stem Cells" Cold Spring Harbor Laboratory Press, 73, 25-32 (2009) PubMedLink

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新聞発表等

  1. 毎日新聞(夕刊)(2019年1月11日)精子生成の仕組み解明 基生研 男性不妊症の究明に期待
  2. 中日新聞(2018年12月22日)一定数に保たれる「精子幹細胞」基生研、仕組み解明
  3. 東海愛知新聞(2018年12月21日)動き回る精子幹細胞 タンパク質取り込み一定数維持
  4. 朝日新聞(2018年12月21日)精子作る力 細胞増やすたんぱく質カギ?
  5. プレスリリース 2018年12月21日 「精子幹細胞の数を一定に保つ新たな仕組みを発見」
  6. 朝日新聞Digital(2019年12月21日)「精子幹細胞数を保つ仕組み解明 不妊対策につながるか」
  7. Yahoo!ニュース(2019年12月21日)「精子幹細胞数を保つ仕組み解明 不妊対策につながるか」
  8. auヘッドライン(2019年12月21日)「精子幹細胞数を保つ仕組み解明 不妊対策につながるか」
  9. gooニュース(2019年12月21日)「精子幹細胞数を保つ仕組み解明 不妊対策につながるか」
  10. Livedoorニュース(2019年12月21日)「精子幹細胞数を保つ仕組み解明 不妊対策につながるか」
  11. プレスリリース 2017年02月10日 「精子幹細胞の分化と自己複製を両立する新たなメカニズムの発見〜幹細胞は分化シグナルからどのように守られるのか〜」
  12. 科学新聞 (2015年5月15日) 精子幹細胞が尽きることなく精子を作り続けるメカニズム 〜分化する細胞としない細胞はどのようにして決まるのか?〜
  13. 中日新聞(2015年04月28日 3面) 精子生成の仕組み解明
  14. 東海愛知新聞(2015年04月28日 1面) 精子作り続ける仕組み解明
  15. プレスリリース 2015年04月28日 「精子幹細胞が尽きることなく精子を作り続けるメカニズム〜分化する細胞としない細胞はどのようにして決まるのか?〜」
  16. 科学新聞(2014年5月16日1面) 精子幹細胞の未知の性質 マウスを使って明らかに
  17. 東海愛知新聞(2014年5月2日 1面) 精子幹細胞の性質解明 男性不妊治療に光明か
  18. 科学新聞(2010年8月27日 1面) 幹細胞の寿命は意外にも短かった! マウスの精子幹細胞で基生研グループ突き止める
  19. 日経産業新聞(2010年8月20日 11面) 精子幹細胞、寿命1〜2週 分裂の仕組み解明
  20. 日刊工業新聞(2010年8月3日 22面) ウズラ脳内で光感知 名大、たんぱく質を特定
  21. Newton(2010年6月号 P120)膨大な量の精子をつくりつづけるしくみとは?
  22. 科学新聞(2010年4月2日 1面) 精子形成幹細胞の挙動 生きたまま顕微鏡観察 多く、長く、精子作る秘訣解明
  23. 日経産業新聞(2010年3月19日 11面) 精子作る細胞 成長途中から再び幹細胞に 哺乳類で解明
  24. 日刊工業新聞(2010年3月19日 28面) As型精原細胞→精子 変化過程で逆行確認
  25. 朝日新聞(2007年9月7日夕刊 17面) 精子増殖の源撮影
  26. 京都新聞(2007年9月7日 27面) 精原細胞の動き確認
  27. 産経新聞(2007年9月7日 2面) 精子分化の撮影に成功
  28. 日刊工業新聞(2007年9月7日 20面) 未分化型精原細胞 精巣内の挙動映像化
  29. 日本経済新聞(2007年9月7日 15面) 精子となる細胞 分化の動き解明
  30. 毎日新聞(2007年9月7日 3面) 精子のおおもと細胞 存在場所を特定
  31. 読売新聞(2007年9月7日 2面) 精子になる細胞 動きをキャッチ

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大学共同利用機関法人 自然科学研究機構 基礎生物学研究所 発生生物学領域 生殖細胞研究部門
〒444-8787 岡崎市明大寺町字東山5−1 shosei@nibb.ac.jp(吉田)

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