広島大学

Basic Information

Academic Degrees

• Doctor of Science, Hiroshima University
• Master of Science, Hiroshima University

Research Fields

• Agricultural sciences;Boundary agriculture;Environmental agriculture(including landscape science)

Research Keywords

• transgenic plant
• phytoremediation
• Nitroge dioxide
• Nitrogen metabolism

Educational Activity

Course in Charge

1. 2024, Liberal Arts Education Program1, 2Term, Introductory Seminar for First-Year Students
2. 2024, Undergraduate Education, 1Term, Seminar on Biological Science
3. 2024, Undergraduate Education, Second Semester, Seminar for Molecular Plant Biology
4. 2024, Undergraduate Education, First Semester, Practice for Fundamental Biology I
5. 2024, Undergraduate Education, Second Semester, Practice for Fundamental Biology IV
6. 2024, Undergraduate Education, 3Term, Laboratory Work in Biology A
7. 2024, Graduate Education (Master's Program) , 2Term, Topical Seminar in Life Science A
8. 2024, Graduate Education (Master's Program) , 4Term, Topical Seminar in Life Science B

Research Activities

Academic Papers

1. Prolonged exposure to atmospheric nitrogen dioxide increases fruit yield of tomato plants, PLANT BIOTECHNOLOGY, 28(5), 485-487, 2011
   Link to Paper Search Results by DOI
2. Structure-function relationship of assimilatory nitrite reductases from the leaf and root of tobacco based on high-resolution structures, PROTEIN SCIENCE, 21(3), 383-395, 201203
   Link to Paper Search Results by DOI
3. MUTANTS OF FICUS PUMILA PRODUCED BY ION BEAM IRRADIATION WITH AN IMPROVED ABILITY TO UPTAKE AND ASSIMILATE ATMOSPHERIC NITROGEN DIOXIDE, INTERNATIONAL JOURNAL OF PHYTOREMEDIATION, 14(3), 275-281, 2012
   Link to Paper Search Results by DOI
4. The reductive reaction mechanism of tobacco nitrite reductase derived from a combination of crystal structures and ultraviolet-visible microspectroscopy, PROTEINS-STRUCTURE FUNCTION AND BIOINFORMATICS, 80(8), 2035-2045, 201208
   Link to Paper Search Results by DOI
5. X-Ray Crystal Structure of a Mutant Assimilatory Nitrite Reductase That Shows Sulfite Reductase-Like Activity, CHEMISTRY & BIODIVERSITY, 9(9), 1989-1999, 201209
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6. Nitrogen dioxide regulates organ growth by controlling cell proliferation and enlargement in Arabidopsis, NEW PHYTOLOGIST, 201(4), 1304-1315, 201403
   Link to Paper Search Results by DOI
7. Dual selective nitration in Arabidopsis: Almost exclusive nitration of PsbO and PsbP, and highly susceptible nitration of four non-PSII proteins, including peroxiredoxin II E, ELECTROPHORESIS, 36(20), 2569-2578, 201510
   Link to Paper Search Results by DOI
8. Kinematic evidence that atmospheric nitrogen dioxide increases the rates of cell proliferation and enlargement to stimulate leaf expansion in Arabidopsis, PLANT SIGNALING & BEHAVIOR, 10(12), 20151202
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9. Nitration is exclusive to defense-related PR-1, PR-3 and PR-5 proteins in tobacco leaves, PLANT SIGNALING & BEHAVIOR, 11(7), 2016
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10. Differential abilities of nitrogen dioxide and nitrite to nitrate proteins in thylakoid membranes isolated from Arabidopsis leaves, PLANT SIGNALING & BEHAVIOR, 11(10), 2016
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11. Light-triggered selective nitration of PsbO1 in isolated Arabidopsis thylakoid membranes is inhibited by photosynthetic electron transport inhibitors, PLANT SIGNALING & BEHAVIOR, 11(12), 2016
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12. Selective nitration of PsbO1 inhibits oxygen evolution from isolated Arabidopsis thylakoid membranes, PLANT SIGNALING & BEHAVIOR, 12(4), 2017
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13. Nitrate, but not nitrite, derived from nitrogen dioxide accumulates in Arabidopsis leaves following exposure to N-15-labeled nitrogen dioxide, PLANT SIGNALING & BEHAVIOR, 14(2), 2019
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14. Dual nitrogen species involved in foliar uptake of nitrogen dioxide in Arabidopsis thaliana, PLANT SIGNALING & BEHAVIOR, 14(4), 20190403
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15. Nitrogen Dioxide at Ambient Concentrations Induces Nitration and Degradation of PYR/PYL/RCAR Receptors to Stimulate Plant Growth: A Hypothetical Model, PLANTS-BASEL, 8(7), 201907
    Link to Paper Search Results by DOI
16. The RNAi-Mediated Silencing of Xanthine Dehydrogenase Impairs Growth and Fertility and Accelerates Leaf Senescence in Transgenic Arabidopsis Plants, Plant and Cell Physiology, 48(10), 1484-1495, 20071001
17. Functional complementation in yeast reveals a protective role of chloroplast 2-Cys peroxiredoxin against reactive nitrogen species., Functional complementation in yeast reveals a protective role of chloroplast 2-Cys peroxiredoxin against reactive nitrogen species., 33(5), 2003
18. Functional complementation in yeast reveals a protective role of chloroplast 2-Cys peroxiredoxin against reactive nitrogen species., Functional complementation in yeast reveals a protective role of chloroplast 2-Cys peroxiredoxin against reactive nitrogen species., 33(5), 2003
19. Functional complementation in yeast reveals a protective role of chloroplast 2-Cys peroxiredoxin against reactive nitrogen species., Functional complementation in yeast reveals a protective role of chloroplast 2-Cys peroxiredoxin against reactive nitrogen species., 33(5), 2003
20. Screening and genetic manipulation of plants for decontamination of pollutants from the environments., Screening and genetic manipulation of plants for decontamination of pollutants from the environments., 22(1-2), 2003
21. Screening and genetic manipulation of plants for decontamination of pollutants from the environments., Screening and genetic manipulation of plants for decontamination of pollutants from the environments., 22(1-2), 2003
22. Formation of unidentified nitrogen in plants: an implication for a novel nitrogen metabolism., Formation of unidentified nitrogen in plants: an implication for a novel nitrogen metabolism., 219(1), 2004
23. Formation of unidentified nitrogen in plants: an implication for a novel nitrogen metabolism., Formation of unidentified nitrogen in plants: an implication for a novel nitrogen metabolism., 219(1), 2004
24. Formation of unidentified nitrogen in plants: an implication for a novel nitrogen metabolism., Formation of unidentified nitrogen in plants: an implication for a novel nitrogen metabolism., 219(1), 2004
25. Differential expression of the nitrite reductase gene family in tobacco as revealed by quantitative competitive RT-PCR., Differential expression of the nitrite reductase gene family in tobacco as revealed by quantitative competitive RT-PCR., 55(403), 2004
26. Differential expression of the nitrite reductase gene family in tobacco as revealed by quantitative competitive RT-PCR., Differential expression of the nitrite reductase gene family in tobacco as revealed by quantitative competitive RT-PCR., 55(403), 2004
27. Differential expression of the nitrite reductase gene family in tobacco as revealed by quantitative competitive RT-PCR., Differential expression of the nitrite reductase gene family in tobacco as revealed by quantitative competitive RT-PCR., 55(403), 2004
28. Three distinct Arabidopsis hemoglobins exhibit peroxidase-like activity and differentially mediate nitrite-dependent protein nitration., Three distinct Arabidopsis hemoglobins exhibit peroxidase-like activity and differentially mediate nitrite-dependent protein nitration., 572(1-3), 2004
29. Three distinct Arabidopsis hemoglobins exhibit peroxidase-like activity and differentially mediate nitrite-dependent protein nitration., Three distinct Arabidopsis hemoglobins exhibit peroxidase-like activity and differentially mediate nitrite-dependent protein nitration., 572(1-3), 2004
30. Three distinct Arabidopsis hemoglobins exhibit peroxidase-like activity and differentially mediate nitrite-dependent protein nitration., Three distinct Arabidopsis hemoglobins exhibit peroxidase-like activity and differentially mediate nitrite-dependent protein nitration., 572(1-3), 2004
31. Novel metabolism of nitrogen in plants., Novel metabolism of nitrogen in plants., 60(3-4)
32. Novel metabolism of nitrogen in plants., Novel metabolism of nitrogen in plants., 60(3-4)
33. Novel metabolism of nitrogen in plants., Novel metabolism of nitrogen in plants., 60(3-4)
34. Tolerance to, and uptake and degradation of 2,4,6-trinitrotoluene (TNT) are enhanced by the expression of a bacterial nitroreductase gene in Arabidopsis thaliana., Tolerance to, and uptake and degradation of 2,4,6-trinitrotoluene (TNT) are enhanced by the expression of a bacterial nitroreductase gene in Arabidopsis thaliana., 60(3-4)
35. Tolerance to, and uptake and degradation of 2,4,6-trinitrotoluene (TNT) are enhanced by the expression of a bacterial nitroreductase gene in Arabidopsis thaliana., Tolerance to, and uptake and degradation of 2,4,6-trinitrotoluene (TNT) are enhanced by the expression of a bacterial nitroreductase gene in Arabidopsis thaliana., 60(3-4)
36. Tolerance to, and uptake and degradation of 2,4,6-trinitrotoluene (TNT) are enhanced by the expression of a bacterial nitroreductase gene in Arabidopsis thaliana., Tolerance to, and uptake and degradation of 2,4,6-trinitrotoluene (TNT) are enhanced by the expression of a bacterial nitroreductase gene in Arabidopsis thaliana., 60(3-4)
37. Nocturnal uptake and assimilation of nitrogen dioxide by C3 and CAM plants., Nocturnal uptake and assimilation of nitrogen dioxide by C3 and CAM plants., 60(3-4)
38. Nocturnal uptake and assimilation of nitrogen dioxide by C3 and CAM plants., Nocturnal uptake and assimilation of nitrogen dioxide by C3 and CAM plants., 60(3-4)
39. Nocturnal uptake and assimilation of nitrogen dioxide by C3 and CAM plants., Nocturnal uptake and assimilation of nitrogen dioxide by C3 and CAM plants., 60(3-4)
40. Atmospheric nitrogen dioxide gas is a plant vitalization signal to increase plant size and the contents of cell constituents., Atmospheric nitrogen dioxide gas is a plant vitalization signal to increase plant size and the contents of cell constituents., 168(1), 2005
41. Atmospheric nitrogen dioxide gas is a plant vitalization signal to increase plant size and the contents of cell constituents., Atmospheric nitrogen dioxide gas is a plant vitalization signal to increase plant size and the contents of cell constituents., 168(1), 2005
42. Atmospheric nitrogen dioxide gas is a plant vitalization signal to increase plant size and the contents of cell constituents., Atmospheric nitrogen dioxide gas is a plant vitalization signal to increase plant size and the contents of cell constituents., 168(1), 2005
43. Differential assimilation of nitrogen dioxide by 70 taxa of roadside trees at an urban pollution level., Differential assimilation of nitrogen dioxide by 70 taxa of roadside trees at an urban pollution level., 61(5), 2005
44. Differential assimilation of nitrogen dioxide by 70 taxa of roadside trees at an urban pollution level., Differential assimilation of nitrogen dioxide by 70 taxa of roadside trees at an urban pollution level., 61(5), 2005
45. Differential assimilation of nitrogen dioxide by 70 taxa of roadside trees at an urban pollution level., Differential assimilation of nitrogen dioxide by 70 taxa of roadside trees at an urban pollution level., 61(5), 2005
46. Nitrogen dioxide at an ambient level improves the capability of kenaf (Hibiscus cannabinus) to decontaminate cadmium., Nitrogen dioxide at an ambient level improves the capability of kenaf (Hibiscus cannabinus) to decontaminate cadmium., 10(1)
47. Nitrogen dioxide at an ambient level improves the capability of kenaf (Hibiscus cannabinus) to decontaminate cadmium., Nitrogen dioxide at an ambient level improves the capability of kenaf (Hibiscus cannabinus) to decontaminate cadmium., 10(1)
48. Nitrogen dioxide at an ambient level improves the capability of kenaf (Hibiscus cannabinus) to decontaminate cadmium., Nitrogen dioxide at an ambient level improves the capability of kenaf (Hibiscus cannabinus) to decontaminate cadmium., 10(1)
49. Molecular characterization of atmospheric NO2-responsive germin-like proteins in azalea leaves., Molecular characterization of atmospheric NO2-responsive germin-like proteins in azalea leaves., 377(3), 2008
50. Molecular characterization of atmospheric NO2-responsive germin-like proteins in azalea leaves., Molecular characterization of atmospheric NO2-responsive germin-like proteins in azalea leaves., 377(3), 2008
51. Molecular characterization of atmospheric NO2-responsive germin-like proteins in azalea leaves., Molecular characterization of atmospheric NO2-responsive germin-like proteins in azalea leaves., 377(3), 2008
52. Mutants of Ficus pumila produced by ion beam irradiation with an improved ability to uptake and assimilate atmospheric nitrogen dioxide., Mutants of Ficus pumila produced by ion beam irradiation with an improved ability to uptake and assimilate atmospheric nitrogen dioxide., 14(3), 2012
53. Mutants of Ficus pumila produced by ion beam irradiation with an improved ability to uptake and assimilate atmospheric nitrogen dioxide., Mutants of Ficus pumila produced by ion beam irradiation with an improved ability to uptake and assimilate atmospheric nitrogen dioxide., 14(3), 2012
54. Mutants of Ficus pumila produced by ion beam irradiation with an improved ability to uptake and assimilate atmospheric nitrogen dioxide., Mutants of Ficus pumila produced by ion beam irradiation with an improved ability to uptake and assimilate atmospheric nitrogen dioxide., 14(3), 2012
55. Nitrogen dioxide regulates organ growth by controlling cell proliferation and enlargement in Arabidopsis., Nitrogen dioxide regulates organ growth by controlling cell proliferation and enlargement in Arabidopsis., 201(4), 2014
56. Nitrogen dioxide regulates organ growth by controlling cell proliferation and enlargement in Arabidopsis., Nitrogen dioxide regulates organ growth by controlling cell proliferation and enlargement in Arabidopsis., 201(4), 2014
57. Nitrogen dioxide regulates organ growth by controlling cell proliferation and enlargement in Arabidopsis., Nitrogen dioxide regulates organ growth by controlling cell proliferation and enlargement in Arabidopsis., 201(4), 2014
58. Nitrogen dioxide is a positive regulator of plant growth., Nitrogen dioxide is a positive regulator of plant growth., 9(2), 2014
59. Nitrogen dioxide is a positive regulator of plant growth., Nitrogen dioxide is a positive regulator of plant growth., 9(2), 2014
60. Nitrogen dioxide is a positive regulator of plant growth., Nitrogen dioxide is a positive regulator of plant growth., 9(2), 2014
61. Differential responses of Arabidopsis thaliana accessions to atmospheric nitrogen dioxide at ambient concentrations., Differential responses of Arabidopsis thaliana accessions to atmospheric nitrogen dioxide at ambient concentrations., 9(3), 2014
62. Differential responses of Arabidopsis thaliana accessions to atmospheric nitrogen dioxide at ambient concentrations., Differential responses of Arabidopsis thaliana accessions to atmospheric nitrogen dioxide at ambient concentrations., 9(3), 2014
63. Differential responses of Arabidopsis thaliana accessions to atmospheric nitrogen dioxide at ambient concentrations., Differential responses of Arabidopsis thaliana accessions to atmospheric nitrogen dioxide at ambient concentrations., 9(3), 2014
64. Nitrogen dioxide accelerates flowering without changing the number of leaves at flowering in Arabidopsis thaliana., Nitrogen dioxide accelerates flowering without changing the number of leaves at flowering in Arabidopsis thaliana., 9(10), 2014
65. Nitrogen dioxide accelerates flowering without changing the number of leaves at flowering in Arabidopsis thaliana., Nitrogen dioxide accelerates flowering without changing the number of leaves at flowering in Arabidopsis thaliana., 9(10), 2014
66. Nitrogen dioxide accelerates flowering without changing the number of leaves at flowering in Arabidopsis thaliana., Nitrogen dioxide accelerates flowering without changing the number of leaves at flowering in Arabidopsis thaliana., 9(10), 2014

Patented

1. Patent, 5700661, 2015/02/27

External Funds

Acceptance Results of Competitive Funds

1. KAKENHI, 2015, 2017
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