{"id":1023,"date":"2019-05-31T08:28:58","date_gmt":"2019-05-30T23:28:58","guid":{"rendered":"http:\/\/www.pharm.okayama-u.ac.jp\/lab\/meneki\/?page_id=1023"},"modified":"2026-04-10T08:45:41","modified_gmt":"2026-04-09T23:45:41","slug":"%e5%8e%9f%e8%91%97%e8%ab%96%e6%96%87","status":"publish","type":"page","link":"https:\/\/www.pharm.okayama-u.ac.jp\/lab\/bunsei\/publications\/%e5%8e%9f%e8%91%97%e8%ab%96%e6%96%87\/","title":{"rendered":"\u539f\u8457\u8ad6\u6587"},"content":{"rendered":"

\u539f\u8457\u8ad6\u6587<\/span><\/h2>\n

2026<\/h3>\n

(1) Hongu K, Ishikawa K<\/span>, Kosaki T, Miyoshi SI, Furuta K<\/span>, Kaito C<\/span>*
\nOverexpression of Escherichia coli yaiX<\/em> Confers Multidrug Resistance and Enhances Virulence in the Silkworm Infection Model.
\nMicrobiology and Immunology<\/em><\/strong> in press.<\/p>\n

2025<\/span><\/h3>\n

(1) Furuta K<\/span>*, Miyazato K, Kobata K, Ishikawa K<\/span>, Kaito C<\/span>
\n1,2-naphthoquinone enhances IFN-\u03b3-induced MHC-I expression in dendritic cells, thereby inducing CD8 T cell activation
\nBiochemical and Biophysical Research Communications<\/em><\/strong> 12(779):152453. (2025)<\/p>\n

(2) Ishikawa K<\/span>, Yamaguchi S, Tsukaoka T, Tsunoda M, Furuta K<\/span>, Kaito C<\/span>*
\nSulfur-acquisition pathways for cysteine synthesis confer a fitness advantage to bacteria in plant extracts
\nEnvironmental Microbiology <\/em><\/strong>27(6):e70126. (2025)<\/p>\n

(3) Kimura T, Ishikawa K<\/span>, Nakagawa R, Furuta K<\/span>, Kaito C<\/span>*
\nLytic Transglycosylase Deficiency Increases Susceptibility to \u03b2-lactam Antibiotics But Reduces Susceptibility to Vancomycin in Escherichia coli
\n<\/em>Microbiology and Immunology<\/em><\/strong> 69(8):407-417. (2025)<\/p>\n

(4) Kuriu A, Ishikawa K<\/span>, Tsuchiya K, Furuta K<\/span>, Kaito C<\/span>*
\nXenopus laevis<\/em> as an infection model for human pathogenic bacteria.
\nInfection and Immunity<\/strong><\/em> 93(6):e0012625. (2025)
\n“Selected as IAI cover image.”<\/em><\/p>\n

(5) Yamaguchi S, Ishikawa K<\/span>, Furuta K<\/span>, Kaito C<\/span>*
\nEnterobacterial common antigen repeat-unit flippase WzxE is required for Escherichia coli<\/em> growth under acidic conditions, low temperature, and high osmotic stress conditions.
\nApplied and Environmental Microbiology<\/em><\/strong> 91(5):e0259524. (2025)<\/p>\n

(6) Kano T, Ishikawa K<\/span>, Imai L, Furuta K<\/span>, Kaito C<\/span>*
\nRpoB H481Y Rifampicin Resistance Mutation-Associated Oxidative Stress Sensitivity Reduces the Virulence of Staphylococcus aureus<\/em>
\nMicrobiology and Immunology<\/em><\/strong> 69(2):128-131. (2025)<\/p>\n

2024<\/h3>\n

(1) Yamamoto R, Ishikawa K<\/span>, Miyoshi Y, Furuta K<\/span>, Miyoshi SI, Kaito C<\/span>*
\nOverexpression of diglucosyldiacylglycerol synthase leads to daptomycin resistance in Bacillus subtilis<\/em>
\nJ Bacteriol.<\/em><\/strong> 206(10):e0030724. (2024)<\/p>\n

(2) Uneme M, Ishikawa K<\/span>, Furuta K<\/span>, Yamashita A, Kaito C<\/u>*
\nOverexpression of the flagellar motor protein MotB sensitizes Bacillus subtilis<\/em> to aminoglycosides in a motility-independent manner
\nPLOS ONE <\/em><\/strong>19(4):e0300634. (2024)<\/p>\n

(3) Kano T, Ishikawa K<\/span>, Furuta K<\/span>, Kaito C<\/span>*
\nKnockout of adenylosuccinate synthase purA<\/em> increases susceptibility to colistin in Escherichia coli<\/em>
\nFEMS Microbiol Lett.<\/em><\/strong> 371:fnae007. (2024)<\/p>\n

(4) Nakajima I, Fukuda K*, Ishida W, Kishimoto T, Kuwana A, Suzuki T, Kaito C<\/span>, Yamashiro K
\nStaphylococcus aureus<\/em>-derived virulent phenol-soluble modulin \u03b1 triggers alarmin release to drive IL-36-dependent corneal inflammation
\nMicrobes and Infection <\/strong><\/em>26(1-2):105237. (2024)<\/p>\n

(5) Oka M, Akaki S, Ohno O, Terasaki M, Hamaoka-Tamura Y, Saito M, Kato S, Inoue A, Aoki J, Matsuno K, Furuta K<\/span>, Tanaka S*
\nSuppression of Mast Cell Activation by GPR35: GPR35 Is a Primary Target of Disodium Cromoglycate
\nJ Pharmacol Exp Ther<\/em><\/strong> 389(1):76-86. (2024)<\/p>\n

(6) Ishikawa K<\/span>, Kodama Y*
\nBilirubin distribution in plants at the subcellular and tissue levels
\nPlant Cell Physiol.<\/em><\/strong> 65(5):762-769. (2024)<\/p>\n

(7) Thaweecheep W, Kaito C<\/span>, Chanawong A, Tippayawat P, Tavichakorntrakool R, Lulitanond A*
\nDecreased colony spreading in Staphylococcus aureus with reduced vancomycin susceptibility
\nScienceAsia<\/em><\/strong> 50(5) 1-5. (2024)<\/p>\n

2023<\/span><\/h3>\n

(1) Inamoto T, Furuta K<\/span>*, Han C, Uneme M, Kano T, Ishikawa K<\/span>, Kaito C<\/span>
\nShort-chain fatty acids stimulate dendrite elongation in dendritic cells by inhibiting histone deacetylase
\nFEBS J<\/strong>\u00a0<\/em> 290(24):5794-5810. (2023)<\/p>\n

(2) Shirakawa R, Ishikawa K<\/span>, Furuta K<\/span>, Kaito C<\/span>*
\nKnockout of ribosomal protein RpmJ leads to zinc resistance in Escherichia coli
\n<\/em>PLOS ONE\u00a0<\/strong><\/em>18(3): e0277162. (2023)<\/p>\n

(3) Furuta K<\/span>*, Onishi H, Ikada Y, Masaki K, Tanaka S, Kaito C<\/span>
\nATP and its metabolite adenosine cooperatively upregulate the antigen-presenting molecules on dendritic cells leading to IFN-\u03b3 production by T cells
\nJ Biol Chem.<\/em><\/strong> 299(4):104587. (2023)<\/p>\n

(4) Furuta K<\/span>*, Yoshioka T, Nishikaze K, Yoshikawa N, Nakamura K, Kaito C<\/span>
\nNicotine- and tar-removed cigarette smoke extract modulates the antigen presentation function of mouse bone marrow-derived dendritic cells
\nMicrobiol Immunol.<\/em><\/strong>\u00a067(5):264-273. (2023)<\/p>\n

(5) Nigo F, Nakagawa R, Hirai Y, Imai L, Suzuki Y, Furuta K<\/span>, Kaito C<\/u>*
\nStaphylococcus aureus<\/em> MazG hydrolyzes oxidized guanine nucleotides and contributes to oxidative stress resistance
\nBiochimie<\/em> <\/strong>209:52-60. (2023)<\/p>\n

(6) Ishikawa K<\/span>, Xie X, Osaki Y, Miyawaki A, Numata K, Kodama Y*
\nBilirubin is produced nonenzymatically in plants to maintain chloroplast redox status
\nScience Advances<\/em><\/strong> 9(23) eadh478. (2023)<\/p>\n

(7) Ishikawa K<\/span>, Kobayashi M, Kusano M, Numata K, Kodama Y*
\nUsing the organelle glue technique to engineer the plant cell metabolome
\nPlant Cell Reports <\/em><\/strong>(2022) 42(3):599-607. (2023)<\/p>\n

(8) Inaba H, Oikawa K, Ishikawa K<\/span>, Kodama Y, Matsuura K, Numata K*
\nBinding of Tau-derived peptide-fused GFP to plant microtubules in Arabidopsis thaliana
\nPLOS ONE<\/strong><\/em> 18(6) e0286421. (2023)<\/p>\n

2022<\/span><\/h3>\n

(1) Ishikawa K<\/span>, Shirakawa R, Takano D, Kosaki T, Furuta K<\/span>, Kaito C<\/u>*
\nKnockout of ykcB<\/em>, a putative glycosyltransferase, leads to reduced susceptibility to vancomycin in Bacillus subtilis
\n<\/em>J Bacteriol.<\/em><\/strong> 204(12):e0038722. (2022)<\/p>\n

(2) Ichikawa S, Ishikawa K<\/span>, Miyakawa H, Kodama Y*
\nLive\u2010cell imaging of the chloroplast outer envelope membrane using fluorescent dyes
\nPlant Direct<\/em><\/strong> 6(11): e462 (2022)<\/p>\n

(3) Ichikawa S, Kato S, Fujii Y, Ishikawa K<\/span>, Numata K, Kodama Y*
\nOrganellar Glue: A Molecular Tool to Artificially Control Chloroplast\u2013Chloroplast Interactions
\nACS Synthetic Biology<\/em><\/strong>\u00a011: 3190\u22123197. (2022)<\/p>\n

(4)\u00a0Panthee S, Hamamoto H, Paudel A, Kaito C<\/span>, Suzuki Y, Sekimizu K*
\nHybrid assembly using long reads resolves repeats and completes the genome sequence of a laboratory strain of Staphylococcus aureus <\/em>subsp. Aureus RN4220
\nHeliyon<\/strong><\/em> 8(11):e11376. (2022)<\/p>\n

(5) Miyashita A, Sekimizu K,\u00a0Kaito C<\/span>*
\nSurrounding gas composition affects the calling song development in the two-spotted cricket (Gryllus bimaculatus<\/em>)
\nDrug Discoveries and Therapeutics<\/em><\/strong>\u00a0<\/strong>16(5):204-209.\u00a0<\/strong>(2022)<\/p>\n

(6) Nasu H\u2021, Shirakawa R\u2021 (\u2021equally contribution), Furuta K<\/span>, Kaito C<\/span>*
\nKnockout of mlaA<\/em> increases Escherichia coli<\/em> virulence in a silkworm infection model
\nPLOS ONE<\/strong><\/em> 17(7): e0270166. (2022)<\/p>\n

(7) Ishikawa K<\/span>, Konno R, Hirano S, Fujii Y, Fujiwara M, Fukao Y, Kodama Y*
\nThe endoplasmic reticulum membrane\u2013bending protein RETICULON facilitates chloroplast relocation movement in Marchantia polymorpha<\/em>
\nThe Plant Journal<\/strong> <\/em>111(1): 205-216. (2022)<\/p>\n

2021<\/h3>\n

(1)\u00a0Murakami K\u2021<\/sup>, Nasu H\u2021<\/sup> (\u2021<\/sup>equally contribution), Fujiwara T, Takatsu N, Yoshida N, Furuta K<\/span>, Kaito C<\/span>*
\nThe absence of osmoregulated periplasmic glucan confers antimicrobial resistance and increases virulence in Escherichia coli
\n<\/em>J Bacteriol.<\/em><\/strong> 203(12):e0051520. (2021)<\/p>\n

(2)\u00a0Kanaida M, Kimishima A, Eguchi S, Iwatsuki M, Watanabe Y, Honsho M, Hirose T, Noguchi Y, Nonaka K, Sennari G, Matsui H, Kaito C<\/span>, Hanaki H, Asami Y, Sunazuka T*
\nTotal Syntheses and Chemical Biology Studies of Hymeglusin and Fusarilactone A, Novel Circumventors of \u03b2-Lactam Drug Resistance in Methicillin-Resistant Staphylococcus aureus<\/em>
\nChemMedChem.<\/strong> <\/em>16(13):2106-2111.\u00a0(2021)<\/p>\n

(3)\u00a0Domon H, Maekawa T, Isono T, Furuta K<\/span>, Kaito C<\/span>, Terao Y*
\nProteolytic cleavage of HLA class II by human neutrophil elastase in pneumococcal pneumonia
\nSci Rep.<\/em><\/strong>\u00a028;11(1):2432. (2021)<\/p>\n

2020<\/h3>\n

(1) Masaki K\u2020, Hiraki Y\u2020(\u2020: equal contribution) , Onishi H, Satoh Y, Roche PA, Tanaka S, Furuta K<\/span>*
\nLigation of MHC Class II Induces PKC-Dependent Clathrin-Mediated Endocytosis of MHC Class II
\nCells<\/strong><\/em> 9(8): 1810. (2020)<\/p>\n

(2) Yoshida K, Ito MA, Sato N, Obayashi K, Yamamoto K, Koizumi S, Tanaka S, Furuta K<\/span>, Matsuoka I*
\nExtracellular ATP Augments Antigen-Induced Murine Mast Cell Degranulation and Allergic Responses via P2X4 Receptor Activation
\nJ Immunol<\/em><\/strong> 204(12): 3077-3085. (2020)<\/p>\n

(3) Kakinoki A, Kameo T, Yamashita S, Furuta K<\/span>, Tanaka S*
\nEstablishment and Characterization of a Murine Mucosal Mast Cell Culture Model
\nInt J Mol Sci<\/em><\/strong> 21(1): 236. (2020)<\/p>\n

(4) Kaito C<\/u>*, Yoshikai H, Wakamatsu A, Miyashita A, Matsumoto Y, Fujiyuki T, Kato M, Ogura Y, Hayashi T, Isogai T, Sekimizu K
\nNon-pathogenic Escherichia coli<\/em> acquires virulence by mutating a growth-essential LPS transporter
\nPLOS Pathogens <\/em><\/strong>16(4): e1008469. (2020)<\/p>\n

(5) Yoshida N*, Kaito C<\/span>
\nDataset for de novo<\/em> transcriptome assembly of the African bullfrog Pyxicephalus adspersus<\/em>
\nData in Brief<\/strong><\/em>\u00a0 6(30):105388. (2020)<\/p>\n

(6) Tabuchi F, Lulitanond A, Lulitanond V, Thunyaharn S, Kaito C<\/u>*
\nEpidemiological study on the relationship between toxin production and psm-mec<\/em> mutations in MRSA isolates in Thailand
\nMicrobiology and Immunology<\/em><\/strong>\u00a0 64(3):219-225. (2020)<\/p>\n

2019<\/h3>\n

(1) Mitsutomi S, Akimitsu N, Sekimizu K, Kaito C<\/u>*
\nIdentification of 2H phosphoesterase superfamily proteins with 2\u00b4-CPDase activity
\nBiochimie\u00a0<\/em><\/strong>165:235-244. (2019)<\/p>\n

(2) Ryuno H, Nigo F, Naguro I, Sekimizu K, Kaito C<\/u>*
\nStaphylococcus aureus<\/em> aggregation in the plasma fraction of silkworm hemolymph
\nPLOS ONE<\/em><\/strong> 14(5):e0217517. (2019)<\/p>\n

(3) Uchida R, Egawa T, Fujita Y, Furuta K<\/span>, Taguchi H, Tanaka S, Nishida K*
\nIdentification of the minimal region of peptide derived from ADP-ribosylation factor1 (ARF1) that inhibits IgE-mediated mast cell activation
\nMol Immunol.<\/em><\/strong> 105:32-37. (2019)<\/p>\n

(4) Yamada K, Sato H, Sakamaki K, Kamada M, Okuno Y, Fukuishi N, Furuta K<\/span>, Tanaka S*
\nSuppression of IgE-Independent Degranulation of Murine Connective Tissue-Type Mast Cells by Dexamethasone
\nCells<\/em>\u00a0<\/strong>8(2):pii:E112. (2019)<\/p>\n","protected":false},"excerpt":{"rendered":"

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