{"id":9,"date":"2020-06-10T10:00:35","date_gmt":"2020-06-10T01:00:35","guid":{"rendered":"http:\/\/www.rib.okayama-u.ac.jp\/PII\/?page_id=9"},"modified":"2025-09-16T12:05:24","modified_gmt":"2025-09-16T03:05:24","slug":"%e7%a0%94%e7%a9%b6%e6%a5%ad%e7%b8%be","status":"publish","type":"page","link":"https:\/\/www.rib.okayama-u.ac.jp\/PII\/publication.html","title":{"rendered":"\u7814\u7a76\u696d\u7e3e"},"content":{"rendered":"

2025<\/span><\/strong><\/p>\n

Kanda Y, Shinya T, Wari D, Hojo Y, Fujiwara Y, Tsuchiya W, Fujimoto Z, Thomma BPHJ, Nishizawa Y, Kamakura T, Galis I, Mori M. Chitin-signaling-dependent responses to insect oral secretions in rice cells propose the involvement of chitooligosaccharides in plant defense against herbivores. Plant J. 121: e17157. doi: 10.1111\/tpj.17157 (2025. 1.)<\/p>\n

Endo Y, Tanaka M, Uemura T, Tanimura K, Desaki Y, Ozawa R, Bonzano S, Maffei ME, Shinya T, Galis I, Arimura GI. Spider mite tetranins elicit different defense responses in different host habitats. Plant J. 121:e70046. doi: 10.1111\/tpj.70046. (2025. 3.)<\/p>\n

Fukumoto, K., Hojo, Y., Nakatani, H., Wari, D., Shinya, T., Galis, I. Flower jasmonates control fertility but largely disconnect from defense metabolites in reproductive tissues of rice (Oryza sativa L.). J Exp Bot 76:2846-2863.\u00a0 doi.org\/10.1093\/jxb\/eraf073 (2025. 7.)<\/p>\n

Aboshi T, Teraishi M, Galis I, Yoshikawa T, Shinya T. Natural variation-based genetic screen in rice identifies the isopentylamine biosynthetic gene that modulates brown planthopper behaviour. Plant Biol (Stuttg). 6: 27:873-882. doi: 10.1111\/plb.70041 (2025.8)<\/p>\n

\u795e\u7530\u606d\u548c\u3001\u65b0\u5c4b\u53cb\u898f\u3001\u68ee\u660c\u6a39\u3001\u30a4\u30cd\u306b\u304a\u3051\u308b\u30ad\u30c1\u30f3\u53d7\u5bb9\u4f53\u3092\u4ecb\u3057\u305f\u5bb3\u866b\u306e\u98df\u5bb3\u611f\u77e5\u6a5f\u69cb\u3001\u30d0\u30a4\u30aa\u30b5\u30a4\u30a8\u30f3\u30b9\u3068\u30a4\u30f3\u30c0\u30b9\u30c8\u30ea\u30fc 83: 390-391 (2025. 9.)<\/p>\n

\n

2024<\/span><\/strong><\/p>\n

Osibe, D.A., Hojo, Y., Shinya, T., Mitani-Ueno, N., Galis, I. Comprehensive analysis of silicon impact on defense and metabolic responses in rice exposed to herbivory stress. Front Plant Sci. 15: 1399562. doi.org\/10.3389\/fpls.2024.1399562 (2024. 5.)<\/p>\n

Osibe D.A. Study on the role of mineral elements in rice defense against herbivores. \u535a\u58eb\u5b66\u4f4d\u8ad6\u6587\uff08\u5ca1\u5c71\u5927\u5b66\uff09(2024. 9.)<\/p>\n

Yamaji, N., Mitani-Ueno, N., Fujii, T., Shinya, T., Shao, J.F., Watanuki, S., Saitoh, Y., Ma, J.F.\u00a0Shoot-Silicon-Signal protein to regulate root silicon uptake in rice.\u00a0Nat Commun<\/i> 15: 10712. doi.org\/10.1038\/s41467-024-55322-7 (2024. 12.)<\/p>\n

\n

2023<\/span><\/strong><\/p>\n

Osinde, C., Sakamoto, W., Kajiya-Kanegae, H., Sobhy, I. S., Tugume, A. K., Nsubuga, A. M., Galis, I. Identification of quantitative trait loci associated with sorghum susceptibility to Asian stem borer damage. J. Plant Interact. 18: 2153182. doi.org\/10.1080\/17429145.2022.2153182 (2023. 1.)<\/p>\n

Matsushima, R., Hisano, H., Galis, I, Miura, S., Crofts, N., Takenaka, Y., Oitome, N. F., Ishimizu, T., Fujita, N., Sato, K. FLOURY ENDOSPERM 6 mutations enhance the sugary phenotype caused by the loss of ISOAMYLASE1 in barley. Theor. Appl. Genet. 136:94. doi.org\/10.1007\/s00122-023-04339-5 (2023. 4.)<\/p>\n

Aboshi, T., Ittou, K., Galis, I., Shinya, T., Murayama, T. Glucosylation prevents autotoxicity of stress inducible DOPA in maize seedlings. Plant Growth Regul. 101:159\u2013167. doi.org\/10.1007\/s10725-023-01009-w (2023. 5.)<\/p>\n

Kanda, Y., Shinya, T., Maeda, S., Mujiono, K., Hojo, Y., Tomita, K., Okada, K., Kamakura, T., Galis, I., Mori, M. BSR1, a Rice Receptor-like Cytoplasmic Kinase, Positively Regulates Defense Responses to Herbivory. Int. J. Mol. Sci. 24:10395. doi.org\/10.3390\/ijms241210395 (2023. 6.)<\/p>\n

Osinde, C., Sobhy, I.S., Wari, D., Dinh, S.T., Hojo, Y., Osibe, D.A., Shinya, T., Tugume, A.K., Nsubuga, M. A., Galis, I. Comparative analysis of sorghum (C4) and rice (C3) plant headspace volatiles induced by artificial herbivory. Plant Signal. Behav. doi.org\/10.1080\/15592324.2023.2243064 (2023. 8.)<\/p>\n

\n

2022<\/span><\/strong><\/p>\n

Shiono, K., Yoshikawa, M., Kreszies, T., Yamada, S., Hojo, Y., Matsuura, T., Mori, I. C., Schreiber, L., Yoshioka, T. Abscisic acid is required for exodermal suberization to form a barrier to radial oxygen loss in the adventitious roots of rice (Oryza sativa). New Phytol. 233: 655-669. doi.org\/10.1111\/nph.17751 (2022. 1.)<\/p>\n

Wari, D., Aboshi, T., Shinya, T., Galis, I. Integrated view of plant metabolic defense with particular focus on chewing herbivores. J. Integr. Plant Biol. 64: 449-475. doi.org\/10.1111\/jipb.13204 (2022. 2.)<\/p>\n

Onosato, H., Fujimoto, G., Higami, T., Sakamoto, T., Yamada, A., Suzuki, T., Ozawa, R., Matsunaga, S., Seki, M., Ueda, M., Sako, K., Galis, I., Arimura, G. I. Sustained defense response via volatile signaling and its epigenetic transcriptional regulation. Plant Physiol. 189: 922-933. doi.org\/10.1093\/plphys\/kiac077 (2022. 6.\uff09<\/p>\n

Cho, L. H., Yoon, J., Tun, W., Baek, G., Peng, X., Hong, W. J., Mori, I. C., Hojo, Y., Matsuura, T., Kim, S. R., Kim, S. T., Kwon, S. W., Jung, K. H., Jeon, J. S., An, G. Cytokinin increases vegetative growth period by suppressing florigen expression in rice and maize. Plant J. 110: 1619-1635. doi.org\/10.1111\/tpj.15760 (2022. 6.)<\/p>\n

Shinya, T., Miyamoto, K., Uchida, K., Hojo, Y., Yumoto, E., Okada, K., Yamane, H., Galis, I. Chitooligosaccharide elicitor and oxylipins synergistically elevate phytoalexin production in rice. Plant Mol. Biol. 109: 595-609. doi.org\/10.1007\/s11103-021-01217-w (2022. 7.)<\/p>\n

Valea, I., Motegi, A., Kawamura, N., Kawamoto, K., Miyao, A., Ozawa, R., Takabayashi, J., Gomi, K., Nemoto, K., Nozawa, A., Sawasaki, T., Shinya, T., Galis, I., Miyamoto, K., Nojiri, H., Okada, K. The rice wound-inducible transcription factor RERJ1 sharing same signal transduction pathway with OsMYC2 is necessary for defense response to herbivory and bacterial blight. Plant Mol. Biol. 109: 651-666. doi.org\/10.1007\/s11103-021-01186-0 (2022. 7.)<\/p>\n

\u65b0\u5c4b\u53cb\u898f\u30fb\u5c0f\u7af9\u656c\u4e45\u30fbGalis Ivan\u3000\u690d\u7269\u306e\u81ea\u5df1\u640d\u50b7\u611f\u77e5\u306b\u3088\u308b\u6606\u866b\u98df\u5bb3\u8a8d\u8b58\u6a5f\u69cb\uff0e\u65e5\u672c\u8fb2\u85ac\u5b66\u4f1a\u8a8c 47: 74-77. doi.org\/10.1584\/jpestics.W22-17 (2022. 8.)<\/p>\n

\n

2021<\/span><\/strong><\/p>\n

Aboshi, T., Iitsuka, C., Galis, I., Teraishi, M., Kamo, M., Nishimura, A., Ishihara, A., Mori, N. and Murayama, T. Isopentylamine is a novel defense compound induced by insect feeding in rice. Plant Cell Environ. 44: 247-256. doi.org\/10.1111\/pce.13902 (2021. 1.)<\/p>\n

Wari, D., Kuramitsu, K. and Kavallieratos, N. G. Sap-sucking pests; they do matter. Insects 12: 363. doi: 10.3390\/insects12040363 (2021. 4.)<\/p>\n

Inagaki, H., Miyamoto, K., Ando, N., Murakami, K., Sugisawa, K., Morita, S., Yumoto, E., Teruya, M., Uchida, K., Kato, N., Kaji, T., Takaoka, Y., Hojo, Y., Shinya, T., Galis, I, Nozawa, A., Sawasaki, T., Nojiri, H., Ueda, U. and Okada, K. Deciphering OPDA signaling components in the momilactone-producing moss Calohypnum plumiforme<\/em>. Front. Plant Sci. 12: 688565. doi.org\/10.3389\/fpls.2021.688565 (2021. 5.)<\/p>\n

Mujiono, K., Tohi, T., Sobhy, I. S., Hojo, Y., Shinya, T. and Galis, I. Herbivore-induced and constitutive volatiles are controlled by different oxylipin-dependent mechanisms in rice. Plant Cell Environ. 44: 2687-2699. doi.org\/10.1111\/pce.14126 (2021. 8.)<\/p>\n

Swetha, B., Singiri, J. R., Novoplansky, N., Grandhi, R., Srinivasan, J., Khadka, J., Galis, I. and Grafi, G. Single and combined salinity and heat stresses impact yield and dead pericarp priming activity. Plants 10: 1627. doi.org\/10.3390\/plants10081627 (2021. 8.)<\/p>\n

Yamasaki, Y., Sumioka, H., Takiguchi, M., Uemura, T., Kihara, Y., Shinya, T., Galis, I. and Arimura, G. I. Phytohormonedependent plant defense signaling orchestrated by oral bacteria of the herbivore Spodoptera litura<\/em>. New Phytol. 231: 2029-2038. doi.org\/10.1111\/nph.17444 (2021. 9.)<\/p>\n

Yu, E., Yamaji, N., Mochida, K., Galis, I., Asaka, K. and Ma, J. F. LYSINE KETOGLUTARATE REDUCTASE TRANSSPLICING RELATED 1 is involved in a temperature-dependent root growth in rice. J. Exp. Bot. 72: 6336-6349. doi.
\norg\/10.1093\/jxb\/erab240 (2021. 9.)<\/p>\n

Morita, M., Yamasaki, Y., Shinya, T., Galis, I. and Arimura, G. I. Phytohormone elicitation in maize by oral secretions of specialist Mythimna separata<\/em> and generalist Spodoptera litura. J. Plant Interact. 16: 587-590. doi.org\/10.1080\/17429145.2021.2006334 (2021. 12.)<\/p>\n

\n

2020<\/span><\/strong><\/p>\n

Takafuji, K., Rim, H., Kawauchi, K., Mujiono, K., Shimokawa, S., Ando, Y., Shiojiri, K., Galis, I. Arimura, GI.\u00a0 Evidence that ERF transcriptional regulators serve as possible key molecules for natural variation in defense against herbivores in tall goldenrod. Sci. Rep. 10: 5352. https:\/\/doi.org\/10.1038\/s41598-020-62142-4 (2020. 3.)<\/p>\n

Shinya, T., Shibuya, N., Kaku, H. Affinity labeling and purification of plant chitin-binding LysM receptor with chitin octasaccharide derivatives. In: Hirabayashi J. (eds) Lectin Purification and Analysis. Methods Mol. Biol. 2132: 401-412. https:\/\/doi.org\/10.1007\/978-1-0716-0430-4_39 (2020. 4.)<\/p>\n

Uemura, T., Hachisu, M., Desaki, Y., Ito, A., Hoshino, R., Sano, Y., Nozawa, A., Mujiono, K., Galis, I., Yoshida, A., Nemoto, K., Miura, S., Nishiyama, M., Nishiyama, C., Horito, S., Sawasaki, T. Arimura, GI. Soy and Arabidopsis receptor-like kinases respond to polysaccharide signals from Spodoptera<\/em> species and mediate herbivore resistance. Commun. Biol. 3: 224. https:\/\/doi.org\/10.1038\/s42003-020-0959-4 (2020. 5.)<\/p>\n

Raviv, B., Khadka, J., Swetha, B., Singiri, JR., Grandhi, R., Shapira, E., Novoplansky, N., Gutterman, Y., Galis, I., Sternberg, M. and Grafi, G. Extreme drought alters progeny dispersal unit properties of winter wild oat (Avena sterilis<\/em> L.). Planta 252: 77. https:\/\/doi.org\/10.1007\/s0042 5-020-03491 -2 (2020.7)<\/p>\n

Khadka, J., Raviv, B., Swetha, B., Grandhi, R., Singiri, JR., Novoplansky, N., Gutterman, Y., Galis, I., Huang, Z. Grafi, G. Maternal environment alters dead pericarp biochemical properties of the desert annual plant Anastatica hierochuntica<\/em> L. PLoS One 15: e0237045. https:\/\/doi.org\/10.1371\/journal.pone.0237045 (2020. 7.)<\/p>\n

Ye, W., Munemasa, S., Shinya, T., Wu, W., Ma, T., Lu, J., Kinoshita, T., Kaku, H., Shibuya, N. Murata, Y. Stomatal immunity against fungal invasion comprises not only chitin-induced stomatal closure but also chitosan-induced guard cell death. Proc. Natl. Acad. Sci. USA.\u00a0 117: 20932-20942. https:\/\/doi.org\/10.1073\/pnas.1922319117 (2020. 8.)<\/p>\n

Kiba, A., Nakano, M., Hosokawa, M., Galis, I., Nakatani, H., Shinya, T., Ohnishi, H., Hikichi, Y. Phosphatidylinositol-phospholipase C2 regulates pattern-triggered immunity in Nicotiana benthamiana<\/em>. J. Exp. Bot. 71: 5027\u20135038. https:\/\/doi.org\/10.1093\/jxb\/eraa233 (2020.8.)<\/p>\n

Andama, J.B., Mujiono, K., Hojo, Y., Shinya, T., Galis, I. Non-glandular silicified trichomes are essential for rice defense against chewing herbivores. Plant Cell Environ.\u00a0 43: 2019\u20132032.\u00a0 https:\/\/doi.org\/10.1111\/pce.13775 (2020. 9.)<\/p>\n

Kiba, A., Fukui, K., Mitani, M., Galis, I., Hojo, Y., Shinya, T., Ohnishi, K., Hikichi, Y.\u00a0 Silencing of phosphoinositide dependent protein kinase orthologs reduces hypersensitive cell death in Nicotiana benthamiana<\/em>. Plant Biotech. 37: 363-367. https:\/\/doi.org\/10.5511\/plantbiotechnology.20.0511b (2020. 9.)<\/p>\n

Mujiono, K., Tohi, T., Sobhy, S. I., Hojo, Y., Ho, T. N., Shinya, T. Galis, I. Ethylene functions as a suppressor of volatile production in rice. J. Exp. Bot. 71: 6494-6511. https:\/\/doi: 10.1093\/jxb\/eraa341. (2020. 10.)<\/p>\n

\n

2019<\/span><\/strong><\/p>\n

Wari, D., Alamgir, KMd., Mujiono, K., Hojo, Y., Shinya, T., Tani, A., Nakatani, H., Galis, I. Honeydew-associated microbes elicit defense responses against brown planthopper in rice. J. Exp. Bot. 70: 1683-1696. doi.org\/10.1093\/jxb\/erz041 (2019. 2.)<\/p>\n

Iida, J., Desaki, Y., Hata, K., Uemura, T., Yasuno, A., Islam, M., Maffei, ME., Ozawa, R., Nakajima, T., Galis, I., Arimura, G. Tetranins: new putative spider mite elicitors of host plant defense. New Phytol. 224: 875-885. doi.org\/10.1111\/nph.15813 (2019. 3.)<\/p>\n

Mitalo, OW, Tokiwa, S., Kondo, Y., Otsuki, T., Galis, I., Suezawa, K., Kataoka, I., Doan, AT., Nakano, R., Ushijima, K. and Kubo, Y., Low temperature storage stimulates fruit softening and sugar accumulation without ethylene and aroma volatile production in kiwifruit. Front Plant Sci. 10: 888. doi: 10.3389\/fpls.2019.00888 (2019. 7.)<\/p>\n

Wari, D., Alamgir, KMd., Mujiono, K., Hojo, Y., Tani, A., Shinya, T., Nakatani, H., Galis, I. Brown planthopper honeydew-associated symbiotic microbes elicit momilactones in rice.\u00a0Plant Signal. Behav. 14: 1655335.\u00a0https:\/\/doi.org\/10.1080\/15592324.2019.1655335 (2019. 8.)<\/p>\n

Mitalo, OW., Tosab, Y., Tokiwa, S., Kondo, Y., Azimi, A., Hojo, Y., Matsuura, T., Mori, IC., Nakano, R., Akagi, T., Ushijima, K., Kubo, Y. \u2018Passe Crassane<\/em>\u2019 pear fruit (Pyrus communis<\/em> L.) ripening: Revisiting the role of low temperature via integrated physiological and transcriptome analysis. Postharvest Biol. Technol. 158: 110949. doi.org\/ 10.1016\/j.postharvbio.2019.110949 (2019. 12.)<\/p>\n

\n

2018<\/span><\/strong><\/p>\n

Shinya T, Yasuda S, Hyodo K, Tani R, Hojo Y, Fujiwara Y, Hiruma K, Ishizaki T, Fujita Y, Saijo Y, Galis I Integration of danger peptide signals with HAMP signaling amplifies the anti-herbivore defense responses in rice. Plant J. 94: 626-637. doi: 10.1111\/tpj.13883 (2018. 3.)<\/p>\n

\n

2017<\/span><\/strong><\/p>\n

Tzin, V., Hojo, Y., Strickler, S. R., Bartsch, L. J., Archer, C. M., Ahern, K. R., Zhou, S., Christensen, S. A.,\u00a0Galis, I.,\u00a0<\/u>Mueller, L. A. and Jander, G. Rapid defense responses in maize leaves induced by Spodoptera exigua<\/em> caterpillar feeding. J. Exp. Bot. 68: 4709-4723. doi: 10.1093\/jxb\/erx274 (2017. 8.)<\/p>\n

Wari David\u00a0<\/u>\u30fb\u4f50\u85e4 \u7ffc\u30fb\u5c71\u4e0b \u7d14\u30fb\u5712\u7530\u660c\u53f8 \u30ab\u30d6\u30ea\u30c0\u30cb\u985e\uff08\u30c0\u30cb\u76ee\uff1a\u30ab\u30d6\u30ea\u30c0\u30cb\u79d1\uff09\u306e\u5929\u6575\u6e29\u5b58\u690d\u7269\u30e4\u30a4\u30c8\u30d0\u30ca\uff08\u30a2\u30ab\u30cd\u79d1\uff09\u304c\u30e2\u30e2\u5703\u5834\u306b\u304a\u3051\u308b\u30cf\u30c0\u30cb\u985e\uff08\u30c0\u30cb\u76ee\uff1a\u30cf\u30c0\u30cb\u79d1\uff09\u306e\u767a\u751f\u306b\u53ca\u307c\u3059\u5f71\u97ff. \u65e5\u672c\u5fdc\u7528\u52d5\u7269\u6606\u866b\u5b66\u4f1a\u8a8c61: 178-183. (2017. 8.)<\/p>\n

Sobhy, I. S., Miyake, A., Shinya, T. and Galis, I.\u00a0<\/u>Oral secretions affect HIPVs induced by generalist (Mythimnaloreyi<\/em>) and specialist (Parnara guttata<\/em>) herbivores in rice. J. Chem. Ecol. 43: 929-943. doi:10.1007\/s10886-017-0882-4 (2017. 9.)<\/p>\n

Sumida, S., Ito, M.,\u00a0Galis, I., Nakatani, H., Shinya, T.,<\/u>\u00a0Ohnishi, K., Hikichi, Y. and Kiba, A. Phosphoinositide 3-kinase participates in L-methionine sulfoximine-induced cell death via salicylic acid mediated signaling in Nicotiana benthamiana<\/em>. J. Plant Physiol. 218: 167-170. doi: 10.1016\/j.jplph.2017.07.016 (2017. 11.)<\/p>\n

Matsumura, M., Sanada-Morimura, S., Otuka, A.,\u00a0Sonoda, S.,<\/u>\u00a0Van Thanh, D., Van Chien, H., Van Tuong, P., Loc, P. M., Liu, Z. W., Zhu, Z. R., Li, J. H., Wu, G. and Huang, S. H. Insecticide susceptibilities of the two rice planthoppers Nilaparvata lugens and Sogatella furcifera in East Asia, the Red River Delta, and the Mekong Delta. Pest Manag. Sci. doi: 10.1002\/ps.4729 (2017. 9. Online preview)<\/p>\n

\n

2016<\/span><\/strong><\/p>\n

Alamgir, K.M., Hojo Y., Christeller, J.T., Fukumoto, K., Isshiki, R., Shinya, T.<\/u>, Baldwin, I.T. and\u00a0Galis, I.<\/u>\u00a0Systematic analysis of rice (Oryza sativa<\/em>) metabolic responses to herbivory. Plant Cell Environ. 39: 453-466. doi: 10.1111\/pce.12640<\/p>\n

\u65b0\u5c4b\u53cb\u898f.<\/u>\u00a0\u89aa\u548c\u6027\u6a19\u8b58\u5b9f\u9a13. \u690d\u7269\u7d30\u80de\u58c1\u5b9f\u9a13\u6cd5 \uff08\u77f3\u4e95\u5fe0\u3089\u7de8\uff09. \u5f18\u524d\u5927\u5b66\u51fa\u7248\u4f1a. 374-376.<\/p>\n

Kiba, A., Imanaka, Y., Nakano, M.,\u00a0Galis, I., Hojo, Y., Shinya, T.<\/u>, Ohnishi, K. and Hikichi, Y. Silencing of Nicotiana benthamiana<\/em> SEC14 phospholipid transfer protein reduced jasmonic acid dependent defense against Pseudomonas syringae. Plant Biotech. 33: 111-115. doi: 10.5511\/plantbiotechnology.16.0503a<\/p>\n

Shinya, T.<\/u>, Desaki, Y. and Shibuya, N. Oligosaccharin receptors in plant immunity. Research Progress in Oligosaccharins. Springer New York. (edited by Heng Yin and Yuguang Du). 29-39. doi: 10.1007\/978-1-4939-3518-5_3.<\/p>\n

Takahara, H., Hacquard, S., Kombrink, A., Hughes, H.B., Hiruma, K.,\u00a0Shinya, T.<\/u>, Neumann, U., Shibuya, N., Thomma, B. and O\u2019Connell, R. Chitin-binding Colletotrichum higginsianum<\/em> extracellular LysM proteins are essential for biotrophic growth in plant cells. New Phytol. 211:1323-1337. doi: 10.1111\/nph.13994.<\/p>\n

Shinya, T., Hojo, Y.<\/u>, Desaki, Y., Christeller, J.T., Okada, K., Shibuya, N. and\u00a0Galis I.<\/u>, Modulation of plant defense responses to herbivores by simultaneous recognition of different herbivore-associated elicitors in rice. Sci. Rep. 6: 32537. doi: 10.1038\/srep32537<\/p>\n

Sasaki, T., Tsuchiya, Y., Ariyoshi, M., Nakano, R., Ushijima, K., Kubo, Y., Mori, I.C., Higashiizumi, E.,\u00a0Galis, I.<\/u>, and Yamamoto, Y. Two Members of the Aluminum-Activated Malate Transporter Family, SlALMT4 and SlALMT5, are Expressed during Fruit Development, and the Overexpression of SlALMT5 Alters Organic Acid Contents in Seeds in Tomato (Solanum lycopersicum). Plant Cell Physiol. 57: 2367-2379. doi: 10.1093\/pcp\/pcw157.<\/p>\n

Tanabe, K., Hojo, Y., Shinya, T. and Galis, I.<\/span> Molecular evidence for biochemical diversification of phenolamide biosynthesis in rice plants. J Integr Plant Biol. 58(11):903-913. doi: 10.1111\/jipb.12480.<\/p>\n

\n

2015<\/span><\/strong><\/p>\n

Wari, D.<\/u>, Funayama, K., Kishimoto, H., Toyama, M. and\u00a0Sonoda, S.<\/u>\u00a0Molecular verification of dispersal of phytoseiid mites from groundcover plants to tree leaves in Japanese peach orchards. Biological Control 80: 143-155.<\/p>\n

Funayama, K., Komatsu, M.,\u00a0Sonoda, S.<\/u>, Takahashi, I. and Hara, K. Management of apple orchards to conserve generalist phytoseiid mites suppresses two-spotted spider mite, Tetranychus urticae<\/em> (Acari: Tetranychidae). Experimental and Applied Acarology 65: 43-54.<\/p>\n

Meldau, S., Woldemariam M. G., Fatangare, A., Svatos, A. and\u00a0Galis, I.<\/u>\u00a0Using 2-deoxy-2-[18F]fluoro-D-glucose ([18F]FDG) to study carbon allocation in plants after herbivore attack. BMC Res. Notes 8: 45. (2015. 2.)<\/p>\n

Sobhy, I. S.<\/u>, Mandour, N. S. and Sarhan, A. A. Tomato treatment with chemical inducers reduces the performance of Spodoptera littoralis<\/em> (Lepidoptera: Noctuidae). Appl. Entomol. Zool. 50: 175-182.<\/p>\n

Viens, P., Dubeau, M.P., Kimura, A., Desaki, Y.,\u00a0Shinya, T.<\/u>, Shibuya, N., Saito, A. and Brzezinski, R. Uptake of chitosan-derived D-glucosamine oligosaccharides in Streptomyces coelicolor A3(2). FEMS Microbiol. Lett. 362: doi: 10. 1093\/femsle\/fnv048.<\/p>\n

\u65b0\u5c4b\u53cb\u898f<\/u>\u30fb\u6e0b\u8c37\u76f4\u4eba\uff0e \u690d\u7269\u514d\u75ab\u3068\u7d30\u80de\u58c1. \u690d\u7269\u306e\u751f\u9577\u8abf\u7bc0 50, pp. 76 -82.<\/p>\n

Bao, W. X., Kataoka, Y., Fukada, K. and Sonoda, S.<\/u>\u00a0Imidacloprid resistance of melon thrips, Thrips palmi, is conferred YP450-mediated detoxification. Journal of Pesticide Science 40: 65-68.<\/p>\n

Izumi, Y., Tian, R.,\u00a0Sonoda, S.<\/u>, Imayoshi, Y., Iwabuchi, H., Miyashita, Y., Kanazaki, S. and Tsumuki, H. Analysis of peach fruit headspace volatiles and response by the fruit-piercing moth Oraesia excavate<\/em> (Lepidoptera: Noctuidae). Applied Entomology and Zoology 50: 231-238.<\/p>\n

Shinya, T.<\/u>, Nakagawa, T., Kaku, H. and Shibuya, N. Chitin-mediated plant-fungal interactions: Catching, hiding and handshaking. Curr. Opin. Plant Biol. 50: 64-71.<\/p>\n

Alamgir, K. M., Hojo, Y., Christeller, J. T., Fukumoto, K., Isshiki, R., Shinya, T.<\/u>, Baldwin, I. T. and\u00a0Galis, I.<\/u>\u00a0Systematic analysis of rice (Oryza sativa<\/em>) metabolic responses to herbivory. Plant Cell Environ. doi: 10.1111\/pce.12640<\/p>\n

\n

2014<\/span><\/strong><\/p>\n

Yamashita, J., Enomoto, T., Yamada, M., Ono, T., Hanafusa, T., Nagamatsu, T.,\u00a0Sonoda, S<\/u>. and Yamamoto, Y. 2014. Estimation of soil-to-plant transfer factors of radiocesium in 99 wild plant species grown in arable lands one year after Fukushima Daiichi Nuclear Power Station accident. J. Plant Res. 127: 11-22.<\/p>\n

\u5712\u7530\u660c\u53f8\u30fb\u7247\u5ca1\u6d0b\u5b50<\/u>\u30fb\u5c0f\u539f\u967d\u5b50\u30fb\u4e2d\u91ce\u4eae\u30fb\u4e95\u6751\u6709\u91cc\u30fb\u9234\u6c5f\u5149\u826f\uff0e2014. \u7d2b\u5916\u7ddaLED\u3068\u6c34\u76e4\u30c8\u30e9\u30c3\u30d7\u3092\u7528\u3044\u305f\u83cc\u5e8a\u30b7\u30a4\u30bf\u30b1\u683d\u57f9\u65bd\u8a2d\u306b\u767a\u751f\u3059\u308b\u30cf\u30a8\u76ee\u6606\u866b\u306e\u6355\u7372. \u5fdc\u52d5\u6606 58: 32-35.<\/p>\n

Bao, W. X., Kataoka, Y.,<\/u>\u00a0Kohara, Y. and Sonoda, S. 2014. Genomic analyses of sodium channel \u03b1-subunit genes from strains of melon thrips, Thrips palmi, with different sensitivities to cypermethrin. Pestic. Biochem. Physiol. 108: 80-85.<\/p>\n

Sonoda, S.,<\/u>\u00a0Shi, X., Song, D., Liang, P., Gao, X., Zhang, Y., Li, J., Liu, Y., Li, M., Matsumura, M., Sanada-Morimura, S., Minakuchi, C., Tanaka, T. and Miyata T. 2014. Duplication of acetylcholinesterase gene in diamondback moth strains with different sensitivities to acephate. Insect Biochem. Mol. Biol. 48: 83-90.<\/p>\n

Wari, D.,<\/u>\u00a0Yamashita, J., Kataoka, Y., Kohara, Y., Hinomoto, N., Kishimoto, H., Toyoshima, S. and Sonoda, S. 2014. Population survey of phytoseiid mites and spider mites on peach leaves and wild plants in Japanese peach orchard. Exp. Appl. Acarol. 63: 313-332.<\/p>\n

Bao, W. X.,<\/u>\u00a0Narai Y., Nakano, A., Kaneda T., Murai, T. and Sonoda, S. 2014. Spinosad resistance of melon thrips, Thrips palmi, is conferred by G275E mutation in \u03b16 subunit of nicotinic acetylcholine receptor and cytochrome P450 detoxification. Pestic. Biochem. Physiol. 112: 51-55.<\/p>\n

\u585a\u539f\u4f73\u5b5d\u30fb\u4e2d\u7b4b\u623f\u592b\u30fb\u5712\u7530\u660c\u53f8<\/u>\u30fb\u7a4d\u6728\u4e45\u660e\uff0e2014. \u65e5\u672c\u306b\u304a\u3051\u308b\u30b3\u30ca\u30ac\u306e\u5206\u5e03\u57df\u306e\u63a8\u5b9a 2. \u4f4e\u6e29\u8010\u6027\u3068\u8d8a\u51ac. \u5fdc\u52d5\u6606\u4e2d\u56fd\u652f\u90e8\u4f1a\u5831 56: 1-9.<\/p>\n

Funayama, K. and\u00a0Sonoda, S.<\/u>\u00a02014. Plantago asiatica<\/em> groundcover supports Amblyseius tsugawai<\/em> (Acari: hytoseiidae) 3 populations in apple orchards. Appl. Entomol. Zool. 49: 607-611.<\/p>\n

Shinya, T.,<\/u>\u00a0Yamaguchi, K., Desaki, Y., Yamada, K., Narisawa, T., Kobayashi, Y., Maeda, K., Suzuki, M., Tanimoto, T., Takeda, J., Nakashima, M, Funama, R., Narusaka, M., Narusaka, Y., Kaku, H., Kawasaki, T. and Shibuya, N. 2014. Selective regulation of chitin-induced defense response by the Arabidopsis receptor-like cytoplasmic kinase PBL27. Plant J. 79: 56-66.<\/p>\n

Christeller, J. T.,<\/u>\u00a0McGhie, T. K., Poulton, J. and Markwick N. P. 2014. Triterpene acids from apple peel inhibit lepidopteran larval midgut lipases and larval growth. Arch. Insect. Biochem. Physiol. 86: 137-150.<\/p>\n

Sobhy, I. S.,<\/u>\u00a0Abdul-Hamid, A. M., Sarhan, A. A., Shoukry, A. A., Mandour, N. S. and Reitz, S. R. 2014. Life history traits of Blaptostethus pallescens<\/em> (Hemiptera: Anthocoridae), a candidate for use in augmentative biological control in Egypt. Appl. Entomol. Zool. 49: 315-324.<\/p>\n

Mitsunami, T., Nishihara, M.,\u00a0Galis, I., Alamgir, K.Md., Hojo, Y.,<\/u>\u00a0Fujita, K., Sasaki, N., Nemoto, K., Sawasaki, T. and Arimura, G. 2014. Overexpression of the PAP1 transcription factor reveals a complex regulation of flavonoid and phenylpropanoid metabolism in Nicotiana tabacum plants attacked by Spodoptera litura. PloS One 9: e108849.<\/p>\n

Christeller, J. T. and Galis, I.<\/u>\u00a02014. \u03b1-Linolenic acid concentration and not wounding per se is the key regulator of octadecanoid (oxylipin) pathway activity in rice (Oryza sativa<\/em> L.) leaves. Plant Physiol. Biochem. 83: 117-125.<\/p>\n

Kiba, A.,\u00a0Galis, I., Hojo, Y.,<\/u>\u00a0Ohnishi, K., Yoshioka, H. and Hikichi, Y. 2014. SEC14 phospholipid transfer protein is involved in lipid signaling-mediated plant immune responses in Nicotiana benthamiana<\/em>. PloS One 9: e98150.<\/p>\n

Woldemariam, M. G.,\u00a0Galis, I.<\/u>\u00a0and Baldwin, I. T. 2014. Jasmonoyl-L-isoleucine hydrolase 1 (JIH1) contributes to a termination of jasmonate signaling in N. attenuata<\/em>. Plant Signal. Behav. 9: e28973. (Short Communication)<\/p>\n

Sugimoto, K., Matsui, K., Iijima, Y., Akakabe, Y., Muramoto, S., Ozawa, R., Sasaki, R., Alamgir, K. Md., Akitake, S., Nobuke, T.,\u00a0Galis, I.,<\/u>\u00a0Aoki, K., Shibata, D. and Takabayashi, J. 2014. Intake and transformation to a glycoside of (Z)-3-hexenol from neighbors reveals a new mode of plant odor reception and defense. Proc. Nat. Acad. Sci. USA 111: 7144-7149.<\/p>\n

\n

2013<\/span><\/strong><\/p>\n

Isshiki R, Galis I\u00a0<\/u>and Tanakamaru S (2014) Farinose flavonoids are associated with high freezing tolerance in fairy primrose (Primula malacoides<\/em>) plants. Journal of Integrative Plant Biology 56(2): 181?188<\/p>\n

Dinh ST, Baldwin IT and\u00a0Galis I<\/u>\u00a0(2013) Multiple interactions of NaHER1 protein with abscisic acid signaling in\u00a0Nicotiana attenuata<\/i>\u00a0plants. Plant Signaling & Behavior 8: e26365. doi: 10.4161\/psb.26365 (Short Communication)<\/p>\n

Dinh ST, Baldwin IT and\u00a0Galis I<\/u>\u00a0(2013) The HERBIVORE ELICITOR-REGULATED1 (HER1) gene enhances abscisic acid levels and defenses against herbivores in\u00a0Nicotiana attenuata\u00a0<\/i>plants. Plant Physiology 162:2106-2124. doi: 10.1104\/pp.113.221150<\/p>\n

Woldemariam MG, Dinh ST, Oh Y, Gaquerel E, Baldwin IT and\u00a0Galis I\u00a0<\/u>(2013) NaMYC2 transcription factor regulates a subset of plant defense responses in\u00a0Nicotiana attenuata<\/i>. BMC Plant Biology 13: 73. doi:10.1186\/1471-2229-13-73<\/p>\n

Fukumoto K<\/u>, Alamgir K Md, Yamashita Y, Mori IC, Matsuura H and Galis I (2013) Response of rice to insect elicitors and the role of OsJAR1 in wound and herbivory-induced JA-Ile accumulation. Journal of Integrative Plant Biology 55: 775-784. doi: 10.1111\/jipb.12057<\/p>\n

Gaquerel E, Kotkar H, Onkokesung N,\u00a0Galis I<\/u>\u00a0and Baldwin IT (2013) Silencing an N-acyltransferase-like involved in lignin biosynthesis in Nicotiana attenuata dramatically alters herbivory-induced phenolamide metabolism. PLoS ONE, 8: e62336. DOI:10.1371\/journal.pone.0062336<\/p>\n

Galis I<\/u>, Schuman MC, Gase K, Hettenhausen C, Hartl M, Dinh ST, Wu J, Bonaventure G and Baldwin IT (2013) The use of VIGS technology to study plant-herbivore interactions.\u00a0In<\/i>: Methods in Molecular Biology – Virus-induced gene silencing: Methods and protocols. Eds. A. Becker, Humana Press Inc., Totowa, New Jersey, 109-138<\/p>\n

Oh Y, Baldwin IT and\u00a0Galis I<\/u>\u00a0(2013) A jasmonate ZIM-domain protein NaJAZd regulates floral jasmonic acid levels and counteracts flower abscission in\u00a0Nicotiana attenuata<\/i>\u00a0plants. PLoS ONE, in press<\/p>\n

Dinh ST,\u00a0Galis I<\/u>\u00a0and Baldwin IT (2013) UVB radiation and 17-hydroxygeranyllinalool diterpene glycosides provide durable resistance against mirid (Tupiocoris notatus<\/i>) attack in field-grown\u00a0Nicotiana attenuata<\/i>\u00a0plants. Plant Cell and Environment 36: 590-606<\/p>\n

\n

2012<\/span><\/strong><\/p>\n

Zhang L, Oh Y, Li H, Baldwin IT and\u00a0Galis I<\/u>\u00a0(2012) Alternative oxidase in resistance to biotic stresses:\u00a0Nicotiana attenuata<\/i>\u00a0AOX contributes to resistance to a pathogen and a piercing-sucking insectt but not Manduca sexta larvae. Plant Physiology 160: 1453-1467<\/p>\n

Woldemariam MG, Onkokesung N, Baldwin IT and\u00a0Galis I<\/u>\u00a0(2012) Jasmonoyl-L-isoleucine hydrolase 1 (JIH1) regulates jasmonoyl-L-isoleucine levels and attenuates plant defenses against herbivores. The Plant Journal 72: 758-767<\/p>\n

Kaur H, Shaker K, Heinzel N, Ralph J,\u00a0Galis I<\/u>\u00a0and Baldwin IT (2012) Environmental stresses of field growth allow cinnamyl alcohol dehydrogenase-deficient\u00a0Nicotiana attenuata<\/i>\u00a0plants to compensate for their structural deficiencies. Plant Physiology, 159: 1545-1570<\/p>\n

Oh Y, Baldwin IT and\u00a0Galis I\u00a0<\/u>(2012) NaJAZh regulates a subset of defense responses against herbivores and spontaneous leaf necrosis in\u00a0Nicotiana attenuata<\/i>\u00a0plants. Plant Physiology 159: 769-788<\/p>\n

Onkokesung N, Gaquerel E, Kotkar H, Kaur H, Baldwin IT and\u00a0Galis I<\/u>\u00a0(2012) MYB8 controls inducible phenolamide levels by activating three novel hydroxycinnamoyl-CoA: polyamine transferases in\u00a0Nicotiana attenuata<\/i>. Plant Physiology 158: 389-407<\/p>\n

Bao, WX and\u00a0Sonoda S<\/u>\u00a0(2012) Resistance to cypermethrin in melon thrips,\u00a0Thrips palmi<\/i>\u00a0(Thysanoptera: Thripidae), is conferred by reduced sensitivity of the sodium channel and CYP450-mediated detoxification.Applied Entomology and Zoology 47: 443-448<\/p>\n

Sonoda S<\/u>\u00a0(2012) Method to estimate phytoseiid mite species composition using quantitative sequencing. Plant Protection 66: 337-341 (in Japanese)<\/p>\n

Sonoda S\u00a0<\/u>(2012) Mechanisms of insecticide resistance. Plant Protection 66: 162-167 (in Japanese)<\/p>\n

Sonoda S<\/u>, Shi X, Song D, Zhang Y, Li J, Wu G, Liu Y, Li M, Liang P, Wari D, Matsumura M, Minakuchi C, Tanaka T, Miyata T and Gao X (2012) Frequencies of the M918I mutation in the sodium channel of the diamondback moth in China, Thailand and Japan and its association with pyrethroid resistance. Pesticide Biochemistry and Physiology 102: 102-105<\/p>\n

Sonoda S<\/u>, Kohara Y, Siqingerile, Toyoshima S, Kishimoto H and Hinomoto N (2012) Phytoseiid mite species composition in Japanese peach orchards estimated using quantitative sequencing. Experimetal and Applied Acarology 56: 9-22<\/p>\n

\n

2011<\/span><\/strong><\/p>\n

Colquhoun TA, Schwieterman ML, Wedde AE, Schimmel BCG, Marciniak DM, Verdonk JC, Kim JY, Oh Y,\u00a0Galis I<\/u>, Baldwin IT and Clark DG (2011)\u00a0EOBII<\/i>\u00a0controls flower opening by functioning as a general transcriptomic switch. Plant Physiology156: 974-984<\/p>\n

Woldemariam MG, Baldwin IT and\u00a0Galis I<\/u>\u00a0(2011) Transcriptional regulation of plant inducible defenses against herbivores: A mini-review. Journal of Plant Interactions 6: 113-119<\/p>\n

Sonoda S<\/u>, Izumi Y, Kohara Y, Koshiyama Y, Yoshida H (2011) Effects of pesticides on insect biodiversity in peach orchards. Applied Entomology and Zoology 46: 335-342<\/p>\n

Dong W, Tang B,\u00a0Sonoda S<\/u>, Liang P and Gao X (2011) Sequencing and characterization of two cDNA putatively encoding prophenoloxidases in the diamondback moth,\u00a0Plutella xylostella<\/i>\u00a0(L.) (Lepidoptera: Yponomeutidae). Applied Entomology and Zoology 46: 211-221<\/p>\n

Sonoda S<\/u>, Yamashita J, Kohara Y, Izumi Y, Yoshida H and Enomoto T (2011) Population survey of spiders using mt-DNA (COI) sequences in Japanese peach orchards. Applied Entomology and Zoology 46: 81-86<\/p>\n

\n

2010<\/span><\/strong><\/p>\n

Onkokesung N,\u00a0Galis\u00a0<\/u>I, von Dahl CC, Matsuoka K, Saluz H-P and Baldwin IT (2010) Jasmonic acid and ethylene modulate local responses to wounding and simulated herbivory in\u00a0Nicotiana attenuata<\/i>\u00a0leaves. Plant Physiology 153: 785?798<\/p>\n

Kaur H, Heinzel N, Schottner M, Baldwin IT and\u00a0Galis I<\/u>\u00a0(2010) R2R3-NaMYB8 regulates the accumulation of phenylpropanoid-polyamine conjugates which are essential for local and systemic defense against insect herbivores in\u00a0Nicotiana attenuata<\/i>. Plant Physiology 152: 1731?1747<\/p>\n

Zhang L, Gase K, Baldwin IT and\u00a0Galis I<\/u>\u00a0(2010) Enhanced fluorescence imaging in chlorophyll-suppressed tobacco tissues using virus-induced gene silencing of the phytoene desaturase gene. BioTechniques 48: 125-133<\/p>\n

Onkokesung N, Baldwin IT and Galis I (2010) The role of jasmonic acid and ethylene crosstalk in direct defense of\u00a0Nicotiana attenuata<\/i>\u00a0plants against chewing herbivores. Plant Signaling & Behavior 5: 1305-1307<\/p>\n

Galis\u00a0<\/u>I, Onkokesung N and Baldwin IT (2010) New insights into mechanisms regulating differential accumulation of phenylpropanoid-polyamine conjugates (PPCs) in herbivore-attacked\u00a0Nicotiana attenuata<\/i>\u00a0plants. Plant Signaling & Behavior 5: 610-613<\/p>\n

Sonoda S<\/u>\u00a0and Igaki C (2010) Characterization of acephate resistance in the diamondback moth\u00a0Plutella xylostella<\/i>. Pesticide Biochemistry and Physiology 98: 121-127<\/p>\n

Sonoda S<\/u>\u00a0(2010) Molecular analysis of pyrethroid resistance conferred by target insensitivity and increased metabolic detoxification in\u00a0Plutella xylostella<\/i>. Pest Management Science 66: 572-575<\/p>\n

Sonoda S\u00a0<\/u>and Tsumuki H (2010) Characterization of alternatively spliced trascripts encoding heat shock transcription factor in cultured cells of the cabbage armyworm,\u00a0Mamestra brassicae<\/i>. Archives of Insect Biochemistry and Physiology 73: 49-60<\/p>\n

\n

2009<\/span><\/strong><\/p>\n

Kato K,\u00a0Galis I<\/u>, Suzuki S, Araki S, Demura T, Criqui MC, Potuschak T, Genschik P, Fukuda H, Matsuoka K and Ito M (2009) Preferential up-regulation of G2\/M phase-specific genes by overexpression of the hyperactive form of NtmybA2 lacking its negative regulation domain in tobacco BY2 cells. Plant Physiology 149: 1945-1957<\/p>\n

Stork W, Diezel C, Halitschke R,\u00a0Galis I<\/u>\u00a0and Baldwin IT (2009) An ecological analysis of the herbivory-elicited JA burst and its metabolism: Plant memory processes and predictions of the moving target model. PLoS ONE 4: e4697<\/p>\n

Galis I<\/u>, Gaquerel E, Pandey SP and Baldwin IT (2009) Molecular mechanisms underlying plant memory in JA-mediated defense responses. Plant Cell Environment 32: 617-627<\/p>\n

Sonoda S<\/u>\u00a0(2009) Alternative splicing of\u00a0para<\/i>-sodium channel a-subunit genes from diamondback moth strains with different sensitivity toa pyrethroid. Journal of Pesticide Science 34: 173-176<\/p>\n

Izumi Y, Katagiri C,\u00a0Sonoda S<\/u>\u00a0and Tsumuki H (2009) Seasonal changes of phospholipids on last instar larvae of the rice stem borer,\u00a0Chilo suppressalis<\/i>\u00a0Walker (Lepidoptera: Pyralidae). Entomological Science 12: 376-381<\/p>\n

\n

\u00a0Before 2009<\/a><\/span><\/p>\n","protected":false},"excerpt":{"rendered":"

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