His Biochemistry study frequently draws connections between related disciplines such as Thermophile. In his work, he performs multidisciplinary research in Enzyme and Membrane. Masasuke Yoshida merges Membrane with Enzyme in his research. Many of his studies on ATPase apply to ATP synthase gamma subunit as well. His ATPase research extends to ATP synthase gamma subunit, which is thematically connected. By researching both Biophysics and Quantum mechanics, he produces research that crosses academic boundaries. While working on this project, Masasuke Yoshida studies both Quantum mechanics and Biophysics. Borrowing concepts from Cell biology, Masasuke Yoshida weaves in ideas under Gene. He combines Cell biology and Gene in his research.
Masasuke Yoshida performs integrative Biochemistry and Biophysics research in his work. Masasuke Yoshida merges many fields, such as Biophysics and Biochemistry, in his writings. His multidisciplinary approach integrates Enzyme and Thermophile in his work. His work often combines Gene and Protein subunit studies. His research ties ATP synthase gamma subunit and ATPase together. Masasuke Yoshida integrates Escherichia coli and Thermus thermophilus in his studies. Masasuke Yoshida incorporates Thermus thermophilus and Escherichia coli in his studies. He integrates several fields in his works, including Stereochemistry and Enzyme. In his research, Masasuke Yoshida undertakes multidisciplinary study on ATP hydrolysis and ATP synthase.
In the subject of general Snail, his work in Ecology is often linked to Biophysics, thereby combining diverse domains of study. His Ecology study frequently draws connections between related disciplines such as Helix (gastropod). Masasuke Yoshida integrates Helix (gastropod) and Snail in his research. Biophysics and Biochemistry are two areas of study in which he engages in interdisciplinary work. Borrowing concepts from Cell biology, he weaves in ideas under Biochemistry. His Cell biology study typically links adjacent topics like Mitochondrion. He merges Mitochondrion with V-ATPase in his research. Masasuke Yoshida combines V-ATPase and ATPase in his research. ATPase is closely attributed to ATP synthase gamma subunit in his work.
His studies link Inhibitor protein with Biochemistry. He performs multidisciplinary studies into Enzyme and Mutant in his work. Mutant and Biochemistry are frequently intertwined in his study. In his articles, he combines various disciplines, including ATP synthase and Chemiosmosis. By researching both Chemiosmosis and Chloroplast, Masasuke Yoshida produces research that crosses academic boundaries. Masasuke Yoshida integrates several fields in his works, including Chloroplast and ATP synthase. He performs multidisciplinary study in the fields of ATP hydrolysis and ATPase via his papers. He performs integrative ATPase and F-ATPase research in his work. He performs multidisciplinary study on F-ATPase and Adenosine triphosphate in his works.
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Evolution of the Vacuolar H + -ATPase: Implications for the Origin of Eukaryotes
Johann Peter Gogarten;Henrik Kibak;Peter Dittrich;Lincoln Taiz.
Proceedings of the National Academy of Sciences of the United States of America (1989)
Mechanically driven ATP synthesis by F1-ATPase.
Hiroyasu Itoh;Akira Takahashi;Kengo Adachi;Hiroyuki Noji.
The Structure of ClpB: A Molecular Chaperone that Rescues Proteins from an Aggregated State
Sukyeong Lee;Mathew E. Sowa;Yo Hei Watanabe;Paul B. Sigler.
Coupling of rotation and catalysis in F1-ATPase revealed by single-molecule imaging and manipulation
Kengo Adachi;Kazuhiro Oiwa;Takayuki Nishizaka;Shou Furuike.
The crystal structure of the nucleotide-free α3β3 subcomplex of F1-ATPase from the thermophilic Bacillus PS3 is a symmetric trimer
Yasuo Shirakihara;Andrew G. W. Leslie;Jan Pieter Abrahams;John E. Walker.
Heat-inactivated proteins are rescued by the DnaK.J-GrpE set and ClpB chaperones.
Ken Motohashi;Yohei Watanabe;Masafumi Yohda;Masasuke Yoshida.
Proceedings of the National Academy of Sciences of the United States of America (1999)
Catalysis and rotation of F1 motor: Cleavage of ATP at the catalytic site occurs in 1 ms before 40° substep rotation
Katsuya Shimabukuro;Ryohei Yasuda;Eiro Muneyuki;Kiyotaka Y. Hara.
Proceedings of the National Academy of Sciences of the United States of America (2003)
A highly stable adenosine triphosphatase from a thermophillie bacterium. Purification, properties, and reconstitution.
M Yoshida;N Sone;H Hirata;Y Kagawa.
Journal of Biological Chemistry (1975)
Stepping rotation of F1-ATPase visualized through angle-resolved single-fluorophore imaging
Kengo Adachi;Ryohei Yasuda;Hiroyuki Noji;Hiroyasu Itoh.
Proceedings of the National Academy of Sciences of the United States of America (2000)
Reconstitution of adenosine triphosphatase of thermophilic bacterium from purified individual subunits.
M Yoshida;N Sone;H Hirata;Y Kagawa.
Journal of Biological Chemistry (1977)
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