Shinji Mitsuiki
Kyushu Sangyo University
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Publication
Featured researches published by Shinji Mitsuiki.
Bioscience, Biotechnology, and Biochemistry | 2006
Shinji Mitsuiki; Zhao Hui; Daishi Matsumoto; Masashi Sakai; Yasushi Moriyama; Kensuke Furukawa; Hiroaki Kanouchi; Tatsuzo Oka
A keratinolytic alkaline proteae (NAPase) from Nocardiopsis sp. TOA-1 degraded a scrapie prion without any chemical or physical treatment. Optimal temperature and pH were 60 °C and above pH 10.0. The scrapie prion was completely degraded within 3 min under optimal conditions.
Journal of Bioscience and Bioengineering | 2012
Shunichi Nakayama; Ken Tabata; Takahiro Oba; Ken-Ichi Kusumoto; Shinji Mitsuiki; Toshimori Kadokura; Atsumi Nakazato
We characterized a high malic acid production mechanism in sake yeast strain No. 28. No considerable differences in the activity of the enzymes that were involved in malic acid synthesis were observed between strain No. 28 and its parent strain, K1001. However, compared with strain K1001, which actively took up rhodamine 123 during staining, the cells of strain No. 28 were only lightly stained, even when cultured in high glucose concentrations. In addition, malic acid production by the respiratory-deficient strain of K1001 was 2.5-fold higher than that of the wild-type K1001 and wild-type No. 28. The findings of this study demonstrated that the high malic acid production by strain No. 28 is attributed to the suppression of mitochondrial activity.
Bioscience, Biotechnology, and Biochemistry | 2011
Takahiro Oba; Hikaru Suenaga; Shunichi Nakayama; Shinji Mitsuiki; Hiroshi Kitagaki; Kosuke Tashiro
We characterized high malic acid-producing strains of Saccharomyces cerevisiae isolated from sake mash. We compared the gene expression of these strains with those of the parental strain by DNA microarray, and found that stress response genes, such as HSP12, were commonly upregulated in the high malate-producing strains, whereas thiamine synthesis genes, such as THI4 and SNZ2, were downregulated in these strains.
Enzyme and Microbial Technology | 2005
Shinji Mitsuiki; Katsuya Mukae; Masashi Sakai; Masatoshi Goto; Shinsaku Hayashida; Kensuke Furukawa
Journal of Molecular Biology | 2007
Brian A. Kelch; Kyle P. Eagen; F. Pinar Erciyas; Elisabeth L. Humphris; Adam R. Thomason; Shinji Mitsuiki; David A. Agard
Annals of Microbiology | 2010
Shinji Mitsuiki; Mikako Takasugi; Yasushi Moriyama; Taiki Futagami; Masatoshi Goto; Hiroaki Kanouchi; Tatsuzo Oka
Journal of the Society of Brewing, Japan | 2008
Takahiro Oba; Hikaru Suenaga; Tokio Ichimatsu; Yudai Hatano; Shinji Mitsuiki; Masae Suzuki
Applied Biochemistry and Biotechnology | 2012
Hui Zhao; Shinji Mitsuiki; Mikako Takasugi; Masashi Sakai; Masatoshi Goto; Hiroaki Kanouchi; Tatsuzo Oka
Journal of applied glycoscience | 2005
Shinji Mitsuiki; Hiroki Utsunomiya; Yasuto Nakama; Masashi Sakai; Katsuya Mukae; Yasushi Moriyama; Masatoshi Goto; Kensuke Furukawa
Memoirs of the Faculty of Agriculture, Kagoshima University | 2007
Shinji Mitsuiki; Yasushi Moriyama; Masatoshi Goto; Masaaki Okabe; Hiroaki Kanouchi; Kensuke Furukawa; Tatsuzo Oka
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National Institute of Advanced Industrial Science and Technology
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