Toshiyuki Nemoto scite author profile

Toshiyuki Nemoto

5Publications

83Citation Statements Received

104Citation Statements Given

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Affiliations

Research Organization for Information Science and Technology, Showa University, Tohoku Medical and Pharmaceutical University

Publications

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A possible overestimation of the effect of acetylation on lysine residues in KQ mutant analysis

Fujimoto

Higuchi

Koike³

et al. 2011

J Comput Chem

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Acetylation of lysine residues, one of the most common protein post-transcriptional modifications, is thought to regulate protein affinity with other proteins or nucleotides. Experimentally, the effects of acetylation have been studied using recombinant mutants in which lysine residues (K) are substituted with glutamine (Q) as a mimic of acetyl lysine (KQ mutant), or with arginine (R) as a mimic of nonacetylated lysine (KR mutant). These substitutions, however, have not been properly validated. The effects lysine acetylation on Ku, a multifunctional protein that has been primarily implicated in DNA repair and cell survival, are characterized herein using a series of computer simulations. The binding free energy was reduced in the KQ mutant, while the KR mutant had no effect, which is consistent with previous experimental results. Unexpectedly, the binding energy between Ku and DNA was maintained at almost the same level as in the wild type protein despite full acetylation of the lysine residues. These results suggest that the effects of acetylation may be overestimated when the KQ mutant is used as a mimic of the acetylated protein.

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Molecular dynamics simulation of clustered DNA damage sites containing 8‐oxoguanine and abasic site

et al. 2005

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Clustered DNA damage sites induced by ionizing radiation have been suggested to have serious consequences to organisms, such as cancer, due to their reduced probability to be repaired by the enzymatic repair machinery of the cell. Although experimental results have revealed that clustered DNA damage sites effectively retard the efficient function of repair enzymes, it remains unclear as to what particular factors influence this retardation. In this study, approaches based on molecular dynamics (MD) simulation have been applied to examine conformational changes and energetic properties of DNA molecules containing clustered damage sites consisting of two lesioned sites, namely 7,8-dihydro-8-oxoguanine (8-oxoG) and apurinic/apyrimidinic (AP) site, located within a few base pairs of each other. After 1 ns of MD simulation, one of the six DNA molecules containing a clustered damage site develops specific characteristic features: sharp bending at the lesioned site and weakening or complete loss of electrostatic interaction energy between 8-oxoG and bases located on the complementary strand. From these results it is suggested that these changes would make it difficult for the repair enzyme to bind to the lesions within the clustered damage site and thereby result in a reduction of its repair capacity.

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Structural analysis of base mispairing in DNA containing oxidative guanine lesion

Fujimoto

Pinák

Nemoto

et al. 2007

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Classical molecular dynamics methods were used to analyze the importance of 8-oxoguanine (8-oxoG) pairing with other DNA bases in order to determine the impact of oxidative guanine lesions on DNA structure. Six lesioned molecules, each containing 8-oxoG mispaired with one of the four normal bases on the the opposite strand at the center of 40-mer DNA, and one non-damaged DNA molecule, were simulated for 2 nanoseconds of real time. The 8-oxoG lesioned bases were found to incorporate opposite all normal bases. There are observed conformational and energetical differences among these parings. 8-oxoG in anti-form creates firm hydrogen bonds with cytosine and this bonding has a strong attractive electrostatic interaction energy similar to that of a native base pair-guanine to cytosine. Meanwhile, it does not form a stable base pair with purine bases (adenine and guanine) nor with the pyrimidine base thymine. On the other hand, the 8-oxoG in syn-form was found to pair with adenine.

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A case of sialodochitis fibrinosa (Kussmaul's disease) bilaterally affecting the submandibular glands

Nemoto

Matsui

Ohno

et al. 2006

Jpn. J. Oral Maxillofac. Surg.

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Sialodochitis fibrinosa (Kussmaul's disease) is a rare disease characterized by recurrent swelling of the salivary glands due to obstruction of the duct system by a fibrinous plug. This paper describes a 58-year-old woman with sialodochitis fibrinosa bilaterally affecting the submandibular glands. The patient had recurrent swelling of the submandibular glands. Histopathological examination revealed numerous eosinophils and epithelial cells in a fibrinous plug extruding from Wharton' s ducts. Symptoms were relieved by enlargement of the ori-

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DNA strand break: Structural and electrostatic properties studied by molecular dynamics simulation

Bunta

Laaksonen

Pinák

et al. 2006

Computational Biology and Chemistry

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