Personnel Information

写真a

SUZUKI Hiroshi


Job title

Project Associate Professor
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Campus Career 【 display / non-display

  • 2020.04
    -
    2022.04
    Tokyo Medical and Dental University, TMDU Advanced Research Institute (TMDU-ARIS), , Associate Professor
  • 2022.05
    -
    2022.06
    Tokyo Medical and Dental University, TMDU Advanced Research Institute (TMDU-ARIS), , Project Associate Professor
  • 2022.07
    -
    Now
    Tokyo Medical and Dental University, TMDU Advanced Research Institute (TMDU-ARIS), , Cellular and Structural Physiology Laboratory (CeSPL), Project Associate Professor
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Published Papers & Misc 【 display / non-display

  1. A Structural Model of the Endogenous Human BAF Complex Informs Disease Mechanisms 2020.10; 183 (3): 802-817.e24. ( DOI )

  2. New approach for membrane protein reconstitution into peptidiscs and basis for their adaptability to different proteins. 2020.03; 9 ( PubMed, DOI )

  3. Morphologic determinant of tight junctions revealed by claudin-3 structures. 2019.02; 10 (1): 816. ( PubMed, DOI )

  4. Structural Insights into Mdn1, an Essential AAA Protein Required for Ribosome Biogenesis. 2018.10; 175 (3): 822-834. ( PubMed, DOI )

  5. Crystal structures of the gastric proton pump. 2018.04; 556 (7700): 214-218. ( PubMed, DOI )

  6. The cryo-EM structure of gastric H+,K+-ATPase with bound BYK99, a high-affinity member of K+-competitive, imidazo[1,2-a]pyridine inhibitors. 2017.07; 7 (1): 6632. ( PubMed, DOI )

  7. Crystal structures of claudins: insights into their intermolecular interactions. 2017.06; 1397 (1): 25-34. ( PubMed, DOI )

  8. Tight junctions. Structural insight into tight junction disassembly by Clostridium perfringens enterotoxin. 2015.02; 347 (6223): 775-8. ( PubMed, DOI )

  9. Model for the architecture of claudin-based paracellular ion channels through tight junctions. 2015.01; 427 (2): 291-7. ( PubMed, DOI )

  10. Crystal structure of a claudin provides insight into the architecture of tight junctions. 2014.04; 344 (6181): 304-7. ( PubMed, DOI )

  11. Electron Crystallography of Euglenoid Four-Transmembrane Protein Revealed the Linear Polymerization by a Combination of Three-Ways of Intermolecular Interaction 2013.01; 104 (2): 42A.

  12. H. Suzuki, Y. Ito, Y. Yamazaki, K. Mineta, M. Uji, K. Abe, K. Tani, Y. Fujiyoshi, S. Tsukita. Strand formation by a trimeric unit repeat of four-transmembrane proteins in Euglena Nat. Commun. 2013; 4 ( DOI )

  13. The four-transmembrane protein IP39 of Euglena forms strands by a trimeric unit repeat. 2013; 4 1766. ( PubMed, DOI )

  14. Structure and inhibitor of water channel in brain 2010.11; 179-204. ( DOI )

  15. Influence of the cytoplasmic domains of aquaporin-4 on water conduction and array formation. 2010.10; 402 (4): 669-81. ( PubMed, DOI )

  16. Formation of aquaporin-4 arrays is inhibited by palmitoylation of N-terminal cysteine residues. 2008.04; 1778 (4): 1181-9. ( PubMed, DOI )

  17. Assembly of Aquaporin-4 into square arrays is restricted by palmitoylation of N-terminal cysteine residues 2008; 61 S148.

  18. Implications of the aquaporin-4 structure on array formation and cell adhesion. 2006.01; 355 (4): 628-39. ( PubMed )

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