阿拉伯芥之油菜素類固醇透過 BZR1 調控缺氮下
花青素之累積
篩選參與抗病反應之阿拉伯芥 NPF 轉運蛋白突變株

Guan-Yu Louh; 駱冠宇

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/73846

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	王雅筠
dc.contributor.author	Guan-Yu Louh	en
dc.contributor.author	駱冠宇	zh_TW
dc.date.accessioned	2021-06-17T08:11:45Z	-
dc.date.available	2022-08-29
dc.date.copyright	2019-08-29
dc.date.issued	2019
dc.date.submitted	2019-08-15
dc.identifier.citation	Anwar, A., Liu, Y., Dong, R., Bai, L., Yu, X., and Li, Y. (2018). The physiological and molecular mechanism of brassinosteroid in response to stress: a review. Biological Research 51, 46-46. Bao, F., Shen, J., Brady, S.R., Muday, G.K., Asami, T., and Yang, Z. (2004). Brassinosteroids interact with auxin to promote lateral root development in Arabidopsis. Plant Physiology 134, 1624-1631. Bellegarde, F., Gojon, A., and Martin, A. (2017). Signals and players in the transcriptional regulation of root responses by local and systemic N signaling in Arabidopsis thaliana. Journal of Experimental Botany 68, 2553-2565. Bishop, G.J., and Koncz, C. (2002). Brassinosteroids and plant steroid hormone signaling. The Plant Cell 14, S97-S110. Bloom, A.J., Burger, M., Asensio, J.S.R., and Cousins, A.B. (2010). Carbon dioxide enrichment inhibits nitrate assimilation in wheat and Arabidopsis. Science 328, 899-903. Caño-Delgado, A., Yin, Y., Yu, C., Vafeados, D., Mora-García, S., Cheng, J.-C., Nam, K.H., Li, J., and Chory, J. (2004). BRL1 and BRL3 are novel brassinosteroid receptors that function in vascular differentiation in Arabidopsis. Development 131, 5341. Chandler, J.W., Cole, M., Flier, A., and Werr, W. (2009). BIM1, a bHLH protein involved in brassinosteroid signalling, controls Arabidopsis embryonic patterning via interaction with DORNRÖSCHEN and DORNRÖSCHEN-LIKE. Plant Molecular Biology 69, 57-68. Chung, Y., and Choe, S. (2013). The regulation of brassinosteroid biosynthesis in Arabidopsis. Critical Reviews in Plant Sciences 32, 396-410. Davidson, E., Carvalho, C., Guimarães Vieira, I., Figueiredo, R., Moutinho, P., Ishida, Y., Tereza Primo dos Santos, M., Guerrero, J., Kalif, K., and Tuma Sabá, R. (2004). Nitrogen and phosphorus limitation of biomass growth in a tropical secondary forest Ecological Applications 14, 150-163. De Pessemier, J., Chardon, F., Juraniec, M., Delaplace, P., and Hermans, C. (2013). Natural variation of the root morphological response to nitrate supply in Arabidopsis thaliana. Mechanisms of Development 130, 45-53. Dong, S., Lau, V., Song, R., Ierullo, M., Esteban, E., Wu, Y., Sivieng, T., Nahal, H., Gaudinier, A., Pasha, A., Oughtred, R., Dolinski, K., Tyers, M., Brady, S.M., Grene, R., Usadel, B., and Provart, N.J. (2019). Proteome-wide, structure-based prediction of protein-protein interactions: new molecular interactions viewer. Plant Physiology 179, 1893. Engelsberger, W.R., and Schulze, W.X. (2012). Nitrate and ammonium lead to distinct global dynamic phosphorylation patterns when resupplied to nitrogen-starved Arabidopsis seedlings. The Plant Journal 69, 978-995. Espinosa-Ruiz, A., Martínez, C., de Lucas, M., Fàbregas, N., Bosch, N., Caño-Delgado, A.I., and Prat, S. (2017). TOPLESS mediates brassinosteroid control of shoot boundaries and root meristem development in Arabidopsis thaliana. Development 144, 1619. Fan, S.C., Lin, C.S., Hsu, P.K., Lin, S.H., and Tsay, Y.F. (2009). The Arabidopsis nitrate transporter NRT1.7, expressed in phloem, is responsible for source-to-sink remobilization of nitrate. Plant Cell 21, 2750-2761. Franklin, O., Näsholm, T., Högberg, P., and Högberg, M.N. (2014). Forests trapped in nitrogen limitation--an ecological market perspective on ectomycorrhizal symbiosis. The New Phytologist 203, 657-666. Fujioka, S., Li, J., Choi, Y.H., Seto, H., Takatsuto, S., Noguchi, T., Watanabe, T., Kuriyama, H., Yokota, T., Chory, J., and Sakurai, A. (1997). The Arabidopsis deetiolated2 mutant is blocked early in brassinosteroid biosynthesis. The Plant Cell 9, 1951. Gaudinier, A., Rodriguez-Medina, J., Zhang, L., Olson, A., Liseron-Monfils, C., Bågman, A.-M., Foret, J., Abbitt, S., Tang, M., Li, B., Runcie, D.E., Kliebenstein, D.J., Shen, B., Frank, M.J., Ware, D., and Brady, S.M. (2018). Transcriptional regulation of nitrogen-associated metabolism and growth. Nature 563, 259-264. Geisler-Lee, J., Toole, N., Ammar, R., Provart, N.J., Millar, A.H., and Geisler, M. (2007). A Predicted Interactome for Arabidopsis. Plant Physiology 145, 317. Ger, M.-J., Louh, G.-Y., Lin, Y.-H., Feng, T.-Y., and Huang, H.-E. (2014). Ectopically expressed sweet pepper ferredoxin PFLP enhances disease resistance to Pectobacterium carotovorum subsp. carotovorum affected by harpin and protease-mediated hypersensitive response in Arabidopsis. Molecular Plant Pathology 15, 892-906. Giehl, R.F., and von Wiren, N. (2014). Root nutrient foraging. Plant Physiology 166, 509-517. Gou, J.Y., Felippes, F.F., Liu, C.J., Weigel, D., and Wang, J.W. (2011). Negative regulation of anthocyanin biosynthesis in Arabidopsis by a miR156-targeted SPL transcription factor. Plant Cell 23, 1512-1522. Gruber, B.D., Giehl, R.F., Friedel, S., and von Wiren, N. (2013). Plasticity of the Arabidopsis root system under nutrient deficiencies. Plant Physiol 163, 161-179. Gruszka, D. (2013). The brassinosteroid signaling pathway-new key players and interconnections with other signaling networks crucial for plant development and stress tolerance. International Journal of Molecular Sciences 14, 8740-8774. Guan, P. (2017). Dancing with Hormones: A Current Perspective of Nitrate Signaling and Regulation in Arabidopsis. Frontiers in Plant Science 8, 1697. Högberg, P., Näsholm, T., Franklin, O., and Högberg, M.N. (2017). Tamm Review: On the nature of the nitrogen limitation to plant growth in Fennoscandian boreal forests. Forest Ecology and Management 403, 161-185. Hardtke, C.S., Dorcey, E., Osmont, K.S., and Sibout, R. (2007). Phytohormone collaboration: zooming in on auxin-brassinosteroid interactions. Trends in Cell Biology 17, 485-492. He, J.-X., Gendron, J.M., Sun, Y., Gampala, S.S.L., Gendron, N., Sun, C.Q., and Wang, Z.-Y. (2005). BZR1 is a transcriptional repressor with dual roles in brassinosteroid homeostasis and growth responses. Science 307, 1634-1638. Hojin, R., Hyunwoo, C., Kangmin, K., and and Ildoo, H. (2010). Phosphorylation Dependent Nucleocytoplasmic Shuttling of BES1 Is a Key Regulatory Event in Brassinosteroid Signaling. Molecules and Cells 29, 283-290. Huang, P.-Y., Zhang, J., Jiang, B., Chan, C., Yu, J.-H., Lu, Y.-P., Chung, K., and Zimmerli, L. (2018). NINJA-associated ERF19 negatively regulates Arabidopsis pattern-triggered immunity. Journal of Experimental Botany 70, 1033-1047. James, M., Masclaux-Daubresse, C., Marmagne, A., Azzopardi, M., Laîné, P., Goux, D., Etienne, P., and Trouverie, J. (2019). A New Role for SAG12 Cysteine Protease in Roots of Arabidopsis thaliana. Frontiers in Plant Science 9, 1998-1998. Jung, J.K., and McCouch, S. (2013). Getting to the roots of it: Genetic and hormonal control of root architecture. Frontiers in Plant Science 4, 186. Kang, B., Wang, H., Nam, K.H., Li, J., and Li, J. (2010). Activation-tagged suppressors of a weak brassinosteroid receptor mutant. Molecular Plant 3, 260-268. Khoo, H.E., Azlan, A., Tang, S.T., and Lim, S.M. (2017). Anthocyanidins and anthocyanins: colored pigments as food, pharmaceutical ingredients, and the potential health benefits. Food & Nutrition Research 61, 1361779. Kiba, T., Kudo, T., Kojima, M., and Sakakibara, H. (2011). Hormonal control of nitrogen acquisition: roles of auxin, abscisic acid, and cytokinin. Journal of Experimental Botany 62, 1399-1409. Kiba, T., Feria-Bourrellier, A.B., Lafouge, F., Lezhneva, L., Boutet-Mercey, S., Orsel, M., Brehaut, V., Miller, A., Daniel-Vedele, F., Sakakibara, H., and Krapp, A. (2012). The Arabidopsis nitrate transporter NRT2.4 plays a double role in roots and shoots of nitrogen-starved plants. Plant Cell 24, 245-258. Kim, T.-W., Guan, S., Burlingame, A.L., and Wang, Z.-Y. (2011). The CDG1 kinase mediates brassinosteroid signal transduction from BRI1 receptor kinase to BSU1 phosphatase and GSK3-like kinase BIN2. Molecular cell 43, 561-571. Kim, T.-W., Guan, S., Sun, Y., Deng, Z., Tang, W., Shang, J.-X., Sun, Y., Burlingame, A.L., and Wang, Z.-Y. (2009). Brassinosteroid signal transduction from cell-surface receptor kinases to nuclear transcription factors. Nature Cell Biology 11, 1254. Kim, Y., Song, J.-H., Park, S.-U., Jeong, Y.-S., and Kim, S.-H. (2017). Brassinosteroid-induced transcriptional repression and dephosphorylation-dependent protein degradation negatively regulate BIN2-interacting AIF2 (a BR signaling-negative regulator) bHLH transcription factor. Plant and Cell Physiology 58, 227-239. Kinoshita, T., Caño-Delgado, A., Seto, H., Hiranuma, S., Fujioka, S., Yoshida, S., and Chory, J. (2005). Binding of brassinosteroids to the extracellular domain of plant receptor kinase BRI1. Nature 433, 167-171. Kovinich, N., Kayanja, G., Chanoca, A., Otegui, M.S., and Grotewold, E. (2015). Abiotic stresses induce different localizations of anthocyanins in Arabidopsis. Plant Signaling & Behavior 10, e1027850-e1027850. Krapp, A., Berthome, R., Orsel, M., Mercey-Boutet, S., Yu, A., Castaings, L., Elftieh, S., Major, H., Renou, J.P., and Daniel-Vedele, F. (2011a). Arabidopsis roots and shoots show distinct temporal adaptation patterns toward nitrogen starvation. Plant Physiology 157, 1255-1282. Kuo, Y.-M., Zhou, B., Cosco, D., and Gitschier, J. (2001). The copper transporter CTR1 provides an essential function in mammalian embryonic development. Proceedings of the National Academy of Sciences of the United States of America 98, 6836. Léran, S., Edel, K.H., Pervent, M., Hashimoto, K., Corratgé-Faillie, C., Offenborn, J.N., Tillard, P., Gojon, A., Kudla, J., and Lacombe, B. (2015). Nitrate sensing and uptake in Arabidopsis are enhanced by ABI2, a phosphatase inactivated by the stress hormone abscisic acid. Science Signaling 8, 10.1126. Lezhneva, L., Kiba, T., Feria-Bourrellier, A.-B., Lafouge, F., Boutet-Mercey, S., Zoufan, P., Sakakibara, H., Daniel-Vedele, F., and Krapp, A. (2014). The Arabidopsis nitrate transporter NRT2.5 plays a role in nitrate acquisition and remobilization in nitrogen-starved plants. The Plant Journal 80, 230-241. Li, J., and Chory, J. (1997). A putative Leucine-Rich Repeat Receptor Kinase involved in brassinosteroid signal transduction. Cell 90, 929-938. Li, J., Nam, K.H., Vafeados, D., and Chory, J. (2001). BIN2, a new brassinosteroid-insensitive locus in Arabidopsis. Plant Physiology 127, 14. Li, J., Wen, J., Lease, K.A., Doke, J.T., Tax, F.E., and Walker, J.C. (2002). BAK1, an Arabidopsis LRR Receptor-like Protein Kinase, interacts with BRI1 and modulates brassinosteroid signaling. Cell 110, 213-222. Li, Q.-F., and He, J.-X. (2016). BZR1 Interacts with HY5 to mediate brassinosteroid- and light-regulated cotyledon opening in Arabidopsis in darkness. Molecular Plant 9, 113-125. Li, Q.-F., Lu, J., Yu, J.-W., Zhang, C.-Q., He, J.-X., and Liu, Q.-Q. (2018). The brassinosteroid-regulated transcription factors BZR1/BES1 function as a coordinator in multisignal-regulated plant growth. Biochimica et Biophysica Acta (BBA) - Gene Regulatory Mechanisms 1861, 561-571. Liang, J., and He, J. (2018). Protective role of anthocyanins in plants under low nitrogen stress. Biochemical and Biophysical Research Communications 498, 946-953. Liang, T., Mei, S., Shi, C., Yang, Y., Peng, Y., Ma, L., Wang, F., Li, X., Huang, X., Yin, Y., and Liu, H. (2018). UVR8 Interacts with BES1 and BIM1 to Regulate Transcription and Photomorphogenesis in Arabidopsis. Developmental Cell 44, 512-523.e515. Lin, Y.-T., Chen, L.-J., Herrfurth, C., Feussner, I., and Li, H.-M. (2016). Reduced biosynthesis of digalactosyldiacylglycerol, a major chloroplast membrane lipid, leads to oxylipin overproduction and phloem cap lignification in Arabidopsis. The Plant cell 28, 219-232. Liu, K.H., Huang, C.Y., and Tsay, Y.F. (1999). CHL1 is a dual-affinity nitrate transporter of Arabidopsis involved in multiple phases of nitrate uptake. The Plant cell 11, 865-874. Liu, W., Sun, Q., Wang, K., Du, Q., and Li, W.X. (2017). Nitrogen Limitation Adaptation (NLA) is involved in source-to-sink remobilization of nitrate by mediating the degradation of NRT1.7 in Arabidopsis. New Phytologist 214, 734-744. Liu, Y., Tikunov, Y., Schouten, R.E., Marcelis, L.F.M., Visser, R.G.F., and Bovy, A. (2018). Anthocyanin biosynthesis and degradation mechanisms in Solanaceous vegetables: A Review. Frontiers in Chemistry 6. Ma, W., Li, J., Qu, B., He, X., Zhao, X., Li, B., Fu, X., and Tong, Y. (2014a). Auxin biosynthetic gene TAR2 is involved in low nitrogen-mediated reprogramming of root architecture in Arabidopsis. The Plant Journal 78, 70-79. Misyura, M., Colasanti, J., and Rothstein, S.J. (2013). Physiological and genetic analysis of Arabidopsis thaliana anthocyanin biosynthesis mutants under chronic adverse environmental conditions. Journal of Experimental Botany 64, 229-240. Mora-García, S., Vert, G., Yin, Y., Caño-Delgado, A., Cheong, H., and Chory, J. (2004). Nuclear protein phosphatases with Kelch-repeat domains modulate the response to brassinosteroids in Arabidopsis. Genes & Development 18, 448-460. Morris, M., Kelly, V.A., Kopicki, R.J., and Byerlee, D. (2007). Fertilizer Use in African Agriculture: Lessons Learned and Good Practice Guidelines. (The World Bank). Nagata, T., Todoriki, S., Masumizu, T., Suda, I., Furuta, S., Du, Z., and Kikuchi, S. (2003). Levels of active oxygen species are controlled by ascorbic acid and anthocyanin in Arabidopsis. Journal of Agricultural and Food Chemistry 51, 2992-2999. Nakamura, A., Higuchi, K., Goda, H., Fujiwara, M.T., Sawa, S., Koshiba, T., Shimada, Y., and Yoshida, S. (2003). Brassinolide induces IAA5, IAA19, and DR5, a synthetic auxin response element in Arabidopsis, implying a cross talk point of brassinosteroid and auxin signaling. Plant Physiology 133, 1843-1853. Nam, K.H., and Li, J. (2002). BRI1/BAK1, a Receptor Kinase Pair Mediating Brassinosteroid Signaling. Cell 110, 203-212. Nawrath, C., and Métraux, J.-P. (1999). Salicylic acid induction–deficient mutants of Arabidopsis express PR-2 and PR-5 and accumulate high levels of camalexin after pathogen inoculation. The Plant Cell 11, 1393. Nemie-Feyissa, D., Olafsdottir, S.M., Heidari, B., and Lillo, C. (2014). Nitrogen depletion and small R3-MYB transcription factors affecting anthocyanin accumulation in Arabidopsis leaves. Phytochemistry 98, 34-40. Noguchi, T., Fujioka, S., Takatsuto, S., Sakurai, A., Yoshida, S., Li, J., and Chory, J. (1999). Arabidopsis det2 is defective in the conversion of (24R)-24-methylcholest-4-En-3-one to (24R)-24-methyl-5alpha-cholestan-3-one in brassinosteroid biosynthesis. Plant Physiology 120, 833-840. Noguero, M., and Lacombe, B. (2016). Transporters involved in root nitrate uptake and sensing by Arabidopsis. Front Plant Science 7, 1391. Nolan, T., Chen, J., and Yin, Y. (2017). Cross-talk of Brassinosteroid signaling in controlling growth and stress responses. The Biochemical Journal 474, 2641-2661. Nosaki, S., Miyakawa, T., Xu, Y., Nakamura, A., Hirabayashi, K., Asami, T., Nakano, T., and Tanokura, M. (2018). Structural basis for brassinosteroid response by BIL1/BZR1. Nature Plants 4, 771-776. O’Malley, Ronan C., Huang, S.-shan C., Song, L., Lewsey, Mathew G., Bartlett, A., Nery, Joseph R., Galli, M., Gallavotti, A., and Ecker, Joseph R. (2016). Cistrome and Epicistrome Features Shape the Regulatory DNA Landscape. Cell 165, 1280-1292. Oh, E., Zhu, J.-Y., Ryu, H., Hwang, I., and Wang, Z.-Y. (2014). TOPLESS mediates brassinosteroid-induced transcriptional repression through interaction with BZR1. Nature Communications 5, 4140. Ohnishi, T. (2018). Recent advances in brassinosteroid biosynthetic pathway: insight into novel brassinosteroid shortcut pathway. Journal of Pesticide Science 43, 159-167. Outchkourov, N.S., Karlova, R., Hölscher, M., Schrama, X., Blilou, I., Jongedijk, E., Simon, C.D., van Dijk, A.D.J., Bosch, D., Hall, R.D., and Beekwilder, J. (2018). Transcription factor-mediated control of anthocyanin biosynthesis in vegetative tissues. Plant Physiology 176, 1862. Para, A., Li, Y., Marshall-Colón, A., Varala, K., Francoeur, N.J., Moran, T.M., Edwards, M.B., Hackley, C., Bargmann, B.O.R., Birnbaum, K.D., McCombie, W.R., Krouk, G., and Coruzzi, G.M. (2014). Hit-and-run transcriptional control by bZIP1 mediates rapid nutrient signaling in Arabidopsis. Proceedings of the National Academy of Sciences of the United States of America 111, 10371-10376. Peng, M., Hudson, D., Schofield, A., Tsao, R., Yang, R., Gu, H., Bi, Y.-M., and Rothstein, S.J. (2008). Adaptation of Arabidopsis to nitrogen limitation involves induction of anthocyanin synthesis which is controlled by the NLA gene. Journal of Experimental Botany 59, 2933-2944. Perchlik, M., and Tegeder, M. (2017). Improving plant nitrogen use efficiency through alteration of amino acid transport processes. Plant Physiology 175, 235-247. Planas-Riverola, A., Gupta, A., Betegón-Putze, I., Bosch, N., Ibañes, M., and Caño-Delgado, A.I. (2019). Brassinosteroid signaling in plant development and adaptation to stress. Development 146, dev151894. Reddy, M.M., and Ulaganathan, K. (2015). Nitrogen nutrition, its regulation and biotechnological approaches to improve crop productivity. American Journal of Plant Sciences 06, 2745-2798. Remans, T., Nacry, P., Pervent, M., Girin, T., Tillard, P., Lepetit, M., and Gojon, A. (2006). A central role for the nitrate transporter NRT2.1 in the integrated morphological and physiological responses of the root system to nitrogen limitation in Arabidopsis. Plant Physiology 140, 909-921. Ren, H., Willige, B.C., Jaillais, Y., Geng, S., Park, M.Y., Gray, W.M., and Chory, J. (2019). BRASSINOSTEROID-SIGNALING KINASE 3, a plasma membrane-associated scaffold protein involved in early brassinosteroid signaling. PLOS Genetics 15, e1007904. Ristova, D., Carré, C., Pervent, M., Medici, A., Kim, G.J., Scalia, D., Ruffel, S., Birnbaum, K.D., Lacombe, B., and Busch, W. (2016). Combinatorial interaction network of transcriptomic and phenotypic responses to nitrogen and hormones in the Arabidopsis thaliana root. Science Signaling. 9, rs13-rs13. Ronchi, A., Farina, G., Gozzo, F., and Tonelli, C. (1997). Effects of a triazolic fungicide on maize plant metabolism: modifications of transcript abundance in resistance-related pathways. Plant Science 130, 51-62. Rubin, G., Tohge, T., Matsuda, F., Saito, K., and Scheible, W.R. (2009a). Members of the LBD family of transcription factors repress anthocyanin synthesis and affect additional nitrogen responses in Arabidopsis. Plant Cell 21, 3567-3584. Ryu, H., Kim, K., Cho, H., Park, J., Choe, S., and Hwang, I. (2007). Nucleocytoplasmic shuttling of BZR1 mediated by phosphorylation is essential in Arabidopsis brassinosteroid signaling. Plant Cell 19, 2749-2762. Saini, S., Sharma, I., and Pati, P.K. (2015). Versatile roles of brassinosteroid in plants in the context of its homoeostasis, signaling and crosstalks. Frontiers In Plant Science 6, 950. Schwessinger, B., Roux, M., Kadota, Y., Ntoukakis, V., Sklenar, J., Jones, A., and Zipfel, C. (2011). Phosphorylation-dependent differential regulation of plant growth, cell death, and innate immunity by the regulatory receptor-like kinase BAK1. PLOS Genetics 7, e1002046. Shi, M.-Z., and Xie, D.-Y. (2014). Biosynthesis and metabolic engineering of anthocyanins in Arabidopsis thaliana. Recent Patents On Biotechnology 8, 47-60. Smeriglio, A., Barreca, D., Bellocco, E., and Trombetta, D. (2016). Chemistry, pharmacology and health benefits of anthocyanins. Phytotherapy Research 30, 1265-1286. Sun, Y., Fan, X.-Y., Cao, D.-M., Tang, W., He, K., Zhu, J.-Y., He, J.-X., Bai, M.-Y., Zhu, S., Oh, E., Patil, S., Kim, T.-W., Ji, H., Wong, W.H., Rhee, S.Y., and Wang, Z.-Y. (2010). Integration of brassinosteroid signal transduction with the transcription network for plant growth regulation in Arabidopsis. Developmental Cell 19, 765-777. Tang, W., Kim, T.-W., Oses-Prieto, J.A., Sun, Y., Deng, Z., Zhu, S., Wang, R., Burlingame, A.L., and Wang, Z.-Y. (2008). BSKs mediate signal transduction from the receptor kinase BRI1 in Arabidopsis. Science 321, 557-560. Toufighi, K., Brady, S.M., Austin, R., Ly, E., and Provart, N.J. (2005). The botany array tesource: e-Northerns, expression angling, and promoter analyses. The Plant Journal 43, 153-163. Varala, K., Marshall-Colón, A., Cirrone, J., Brooks, M.D., Pasquino, A.V., Léran, S., Mittal, S., Rock, T.M., Edwards, M.B., Kim, G.J., Ruffel, S., McCombie, W.R., Shasha, D., and Coruzzi, G.M. (2018). Temporal transcriptional logic of dynamic regulatory networks underlying nitrogen signaling and use in plants. Proceedings of the National Academy of Sciences of the United States of America 115, 6494. Veronese, P., Nakagami, H., Bluhm, B., AbuQamar, S., Chen, X., Salmeron, J., Dietrich, R.A., Hirt, H., and Mengiste, T. (2006). The Membrane-anchored;BOTRYTIS-INDUCED KINASE1 plays distinct roles in Arabidopsis resistance to necrotrophic and biotrophic pathogens. The Plant Cell 18, 257. Vranová, E., Coman, D., and Gruissem, W. (2012). Structure and dynamics of the isoprenoid pathway network. Molecular Plant 5, 318-333. Wang, J., Wang, Y., Yang, J., Ma, C., Zhang, Y., Ge, T., Qi, Z., and Kang, Y. (2015). Arabidopsis ROOT HAIR DEFECTIVE3 is involved in nitrogen starvation-induced anthocyanin accumulation. Journal of Integrative Plant Biology 57, 708-721. Wang, W., Bai, M.Y., and Wang, Z.Y. (2014). The brassinosteroid signaling network-a paradigm of signal integration. Current Opinion in Plant Biology 21, 147-153. Wang, Y.-Y., Hsu, P.-K., and Tsay, Y.-F. (2012). Uptake, allocation and signaling of nitrate. Trends in Plant Science 17, 458-467. Wang, Y.-Y., Cheng, Y.-H., Chen, K.-E., and Tsay, Y.-F. (2018). Nitrate transport, signaling, and use efficiency. Annual Review of Plant Biology 69, 85-122. Wang, Y., Cao, J.-J., Wang, K.-X., Xia, X.-J., Shi, K., Zhou, Y.-H., Yu, J.-Q., and Zhou, J. (2019). BZR1 Mediates Brassinosteroid-induced autophagy and nitrogen starvation in tomato. Plant Physiology 179, 671. Wang, Z.-Y., Seto, H., Fujioka, S., Yoshida, S., and Chory, J. (2001). BRI1 is a critical component of a plasma-membrane receptor for plant steroids. Nature 410, 380-383. Wang, Z.-Y., Nakano, T., Gendron, J., He, J., Chen, M., Vafeados, D., Yang, Y., Fujioka, S., Yoshida, S., Asami, T., and Chory, J. (2002). Nuclear-localized BZR1 mediates brassinosteroid-induced growth and feedback suppression of brassinosteroid biosynthesis. Developmental Cell 2, 505-513. Widiez, T., El Kafafi, E.S., Girin, T., Berr, A., Ruffel, S., Krouk, G., Vayssières, A., Shen, W.-H., Coruzzi, G.M., Gojon, A., and Lepetit, M. (2011). High nitrogen insensitive 9 (HNI9)-mediated systemic repression of root NO3- uptake is associated with changes in histone methylation. Proceedings of the National Academy of Sciences of the United States of America 108, 13329-13334. Xu, Z., Mahmood, K., and Rothstein, S.J. (2017). ROS induces anthocyanin production via late biosynthetic genes and anthocyanin deficiency confers the hypersensitivity to ROS-generating stresses in Arabidopsis. Plant and Cell Physiology 58, 1364-1377. Yan, Z., Zhao, J., Peng, P., Chihara, R.K., and Li, J. (2009). BIN2 functions redundantly with other Arabidopsis GSK3-like kinases to regulate brassinosteroid signaling. Plant Physiology 150, 710. Ye, H., Liu, S., Tang, B., Chen, J., Xie, Z., Nolan, T.M., Jiang, H., Guo, H., Lin, H.-Y., Li, L., Wang, Y., Tong, H., Zhang, M., Chu, C., Li, Z., Aluru, M., Aluru, S., Schnable, P.S., and Yin, Y. (2017). RD26 mediates crosstalk between drought and brassinosteroid signalling pathways. Nature Communications 8, 14573. Yin, R., Messner, B., Faus-Kessler, T., Hoffmann, T., Schwab, W., Hajirezaei, M.-R., von Saint Paul, V., Heller, W., and Schäffner, A.R. (2012). Feedback inhibition of the general phenylpropanoid and flavonol biosynthetic pathways upon a compromised flavonol-3-O-glycosylation. Journal of Experimental Botany 63, 2465-2478. Yin, Y., Wang, Z.-Y., Mora-Garcia, S., Li, J., Yoshida, S., Asami, T., and Chory, J. (2002). BES1 accumulates in the nucleus in response to brassinosteroids to regulate gene expression and promote stem elongation. Cell 109, 181-191. Yu, X., Li, L., Zola, J., Aluru, M., Ye, H., Foudree, A., Guo, H., Anderson, S., Aluru, S., Liu, P., Rodermel, S., and Yin, Y. (2011). A brassinosteroid transcriptional network revealed by genome-wide identification of BESI target genes in Arabidopsis thaliana. The Plant Journal 65, 634-646. Zhang, H., Rong, H., and Pilbeam, D. (2007). Signalling mechanisms underlying the morphological responses of the root system to nitrogen in Arabidopsis thaliana. Journal of Experimental Botany 58, 2329-2338. Zhao, B., and Li, J. (2012). Regulation of brassinosteroid biosynthesis and inactivationF. Journal of Integrative Plant Biology 54, 746-759. Zhiponova, M.K., Vanhoutte, I., Boudolf, V., Betti, C., Dhondt, S., Coppens, F., Mylle, E., Maes, S., González-García, M.-P., Caño-Delgado, A.I., Inzé, D., Beemster, G.T.S., De Veylder, L., and Russinova, E. (2013). Brassinosteroid production and signaling differentially control cell division and expansion in the leaf. New Phytologist 197, 490-502. Zhu, J.Y., Sae-Seaw, J., and Wang, Z.Y. (2013). Brassinosteroid signalling. Development 140, 1615-1620.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/73846	-
dc.description.abstract	缺氮造成植物生長發育受限制，使植物演化各種對抗缺氮逆境的方式。在地下部，過去大多數研究表明植物可透過根部構型來做抵抗逆境的方式，且缺氮逆境下，會透過荷爾蒙作為訊號來促進根部生長，然而，在地上部的研究極少，儘管地上部花青素的累積，過去被證實參與調控對抗缺氮逆境的一種方式，但其調控方式及訊號尚未闡明。我們研究透過反向遺傳學，以逆境相關荷爾蒙突變株進行篩選，發現油菜素類固醇生合成及受器皆為缺氮逆境下花青素生合成之必要因子。為了瞭解油菜素類固醇如何調控缺氮下花青素之生合成，本研究發現是透過油菜素類固醇的轉錄因子BZR1 來直接抑制目前已知最上層之花青素負調控因子LBD37及LBD38的轉錄表現。同時，油菜素類固醇含量及訊號也扮演植物於缺氮逆境下保留較多重量之關鍵。以及，本研究也提出一個調控機制來說明，油菜素類固醇如何參與到植物的氮源的吸收及利用。總結，在植物地上部，油菜素類固醇在缺氮逆境中的重要性，並且影響花青素產生以及地上部生物量。 NITRATE TRANSPORTER1/PEPTIDE TRANSPORTER family 轉運蛋白已被報導可藉由調節受質之分布並影響許多植物生理功能。雖然許多 NPF 之功能已被研究，但對於 NPF 是否參與及調控生物性逆境仍然未知。本研究，透過分析過去資料，研究在病原感染下之 53 個 NPF 的基因表現量，並選出 11 個 NPF 基因來做感染測試。透過感染結果分析後，選出 NRT1.5/NPF7.3 及 PTR3/NPF5.2 兩組基因做更多測試。透過細菌型番茄斑點病源， Pst DC3000 感染後，其中 nrt1.5/npf7.3 顯示叫野生種 Col-0 較為感病，暗示根部至地上部硝酸鹽運輸可能參與植株的抗病能力。除此之外，NRT1.5/NPF7.3 之轉錄表現也會受 Pst DC3000 及鞭毛 (Flg22) 誘導。但是是否透過根部至地上部之硝酸鹽運輸進而影響抗病，仍需更多研究證實。雙胜肽運輸蛋白 PTR3/NPF5.2 之轉錄表現會受 Pst DC3000、鞭毛 (Flg22)、及水楊酸誘導。雖然 PTR3/NPF5.2 並不影響植株基礎抗性，但在 ptr3 突變株中發現，突變株會失去部分系統性抗病。但 PTR3/NPF5.2 突變株如何參與在系統性抗病仍須要更多研究。總結，本研究發現 NPF 轉運蛋白不只參與在營養分布，也會參與在生物性逆境。然而，詳細功能及如何參與仍需更多研究來證實。	zh_TW
dc.description.abstract	Nitrogen (N) limitation inhibits plant growth and development, leading to plant evolves diverse ways to adapt it. Most researches revealed that plant could modify the root architecture via hormone as a signal to resist N limitation. Nevertheless, the regardless of shoot researches let the shoot part still obscure. Even though anthocyanin accumulation in shoot have been proven which is one of the important strategy to challenge N limitation, the mechanism and signaling are still not elucidated. Here, through reverse genetics, screening of stress-related hormone mutants, the results exhibited that brassinosteroid (BR) biosynthesis and receptor were necessary for anthocyanin production under N limitation. The master transcription factor of BR signaling, BZR1, was then identified as the key hub for anthocyanin production by inhibiting anthocyanin repressors, LBD37 and LBD38, directly. Meanwhile, BR is also required for the biomass maintaining to N limitation by maintaining more biomass. Our investigation propose a model explaining how BR involves in plant nitrogen uptakes and utilizations. In conclusion, our research validated that BR is a key hormone for plant anthocyanin production; for plant biomass maintaining under N limitation, especially in shoot. NITRATE TRANSPORTER1/PEPTIDE TRANSPORTER family (NPF) has been reported to involve in plant physiological functions through mediating distribution of various substrates. Although the functions of these proteins have been studied, the roles of NPF transporters upon biotic stresses remain unclear. In this study, we first analyzed the transcription level of all 53 genes in NPF family upon pathogen infection from BAR microarray database (e-Northerns w. Expression Browser), and 17 NPF genes showed altered expression patterns. After the pathogenicity test by Pst DC3000 infection, some NPF mutants showed different responses compared to wild-type plants. Two genes were selected to study further, which are NRT1.5/NPF7.3, PTR3/NPF5.2, The nrt1.5/npf7.3 mutants showed more susceptibility to Pst DC3000, suggesting that NRT1.5/NPF7.3 which mediates root-to-shoot nitrate transport is required for plant resistance to Pst DC3000. In addition, the transcription level of NRT1.5/NPF7.3 is induced by both Pst DC3000 and Flg22. Whether root-to-shoot nitrate transport by NRT1.5/NPF7.3 enhances the plant defense responses will be further investigated. The expression of PTR3/NPF5.2, a dipeptide transporter, is induced by Pst DC3000, Flg22, and salicylic acid (SA). Although PTR3 has no effect on local defense responses, the two ptr3 T-DNA insertion mutants lost the systemic acquired resistance (SAR) to Pst DC3000. What is the role of PTR3/NPF5.2 in SAR will be analyzed. Taken together, transport activity of NPF proteins is not only important for nutrient distribution, but also participates in adjust physiological responses upon biotic stresses. However, the detailed functions of how NPF transporters are able to resist pathogen need further examination.	en
dc.description.provenance	Made available in DSpace on 2021-06-17T08:11:45Z (GMT). No. of bitstreams: 1 ntu-108-R04b42011-1.pdf: 6198620 bytes, checksum: 009479de59d0f75fc3c946fd90606021 (MD5) Previous issue date: 2019	en
dc.description.tableofcontents	中文摘要 5 Abstract 6 Introduction 7 1. Nitrogen (N) Limitation in our world 7 2. Nitrogen problems in plant world 8 2.1. Strategy to N limitation 8 2.1.1. Accumulation of anthocyanins 8 2.1.2. Root development 12 2.1.3. N Sensing to signaling transduction 12 3. Hormone’s role in N Limitation 14 4. Brassinosteroids (BRs) 16 Materials and Methods 21 Plant Growth Conditions and Genetic Analysis 21 Plant Materials 21 Anthocyanin and Flavonol Analysis 22 RNA Expression Analysis 22 Nitrogen Content Analysis 23 Results 25 Stress Hormones Act Pivotal Roles in Anthocyanin Accumulation under Nitrogen Limitation 25 Brassiosteroids Biosynthesis Enzyme, DET2, and Receptor, BRI1, Are Fully Required for Anthocyanin Accumulation under N limitation 28 Exogenous BR Contributes Anthocyanin Accumulation under N Limitation 29 BR Signaling Positively Regulates Anthocyanin Accumulation via BZR1 under N limitation 30 BZR1 and BES1 Positively Regulate Shoot Biomass under Nitrogen Limitation 32 BZR1 Directly Regulated Anthocyanin Transcription Factors and Biosynthesis Enzymes 34 BR Involved in Many Aspects of Nitrogen Regulation 36 Discussion 38 Figures 43 Fig 1. Anthocyanin contents of hormone-related mutants under 20 mM, and 1 mM NH4NO3. 43 Fig 2. Morphology of Col-0, ctr1-1, ein2-5, ein3-1 under 20 mM, 2.5 mM and 1 mM NH4NO3. 44 Fig 3. Morphology of Col-0, det2-1, bri1-301 under 20 mM, 2.5 mM and 1 mM NH4NO3. 45 Fig 4. Anthocyanin contents of Col-0, det2-1, bri1-301 under 20 mM, 2.5 mM and 1 mM NH4NO3. 46 Fig 5. Flavonols contents of Col-0, det2-1, bri1-301 under 20 mM, 2.5 mM and 1 mM NH4NO3. 47 Fig 6. Anthocyanin contents of Col-0 under 20 mM, 2.5 mM, 1 mM, 0.5mM NH4NO3 with/without exogenous brassinolide. 48 Fig 7. Anthocyanin contents of Col-0 under 20 mM, 2.5 mM, 1 mM, 0.5 mM NH4NO3 with/without exogenous brassinolide. 49 Fig 8. Flavonol contents of Col-0 under 20 mM, 2.5 mM, 1 mM, 0.5mM NH4NO3 with/without exogenous brassinolide. 50 Fig 9. Anthocyanin contents of Col-0, bri1-301, det2-1 under 20 mM, 1 mM NH4NO3 with/without exogenous brassinolide. 51 Fig 10. Morphology of Col-0, bri1-301, bzr1-D, 35S::BZR1-YFP 1-1, Ws under 20 mM, 1 mM NH4NO3 with/without exogenous brassinolide. 52 Fig 11. Anthocyanin contents and fresh weight of Col-0 under 20 mM, 1 mM NH4NO3 with/without exogenous propiconazole (PCZ) treatment. 53 Fig 12. Anthocyanin contents of Col-0, bri1-301, det2-1, Ws under 20 mM, 1 mM NH4NO3 with/without exogenous BIKININ (BK). 54 Fig 13. Morphology of Col-0, det2-1, bzr1-D, 35S:: (S)-bes1-D, bik1 under 20 mM, 2.5 mM and 1 mM NH4NO3. 55 Fig 14. Anthocyanin contents of Col-0, bzr1-D, 35S::bes1-D, bik1 under 20 mM, 2.5 mM and 1 mM NH4NO3. 56 Fig 15. Morphology of En-2, bes1-D under 20 mM, 1 mM, 0.5 mM NH4NO3. 57 Fig 16. Anthocyanin contents of Col-0, bes1-D under 20 mM, 1 mM, 0.5 mM NH4NO3. 58 Fig 17. BR-caused growth inhibition under N sufficient condition (20 mM). 59 Fig 18. The total and shoot fresh weight of Col-0, det2-1, bzr1-D, 35S:: bes1-D, En-2, bes1-D under 20 mM, 2.5 mM and 1 mM NH4NO3. 60 Fig. 19. The shoot fresh weight under 20 mM and 1 mM NH4NO3. with/without BR. 61 Fig 20. LBD37 and LBD38 are regulated by BZR1. 62 Fig 21. Phosphorylated BZR1-YFP protein level was declined under N limitation. 63 Fig 22. Potential models on how BR regulates anthocyanin accumulations under nitrogen limitations. 64 Fig 23. A novel network of BR-regulated transcription factors in nitrogen regulation. 65 Fig 24. BZR1 directly regulate nitrogen-related genes. 66 Fig 25. BR is required for the expression of nitrogen uptake gene (NRT1.1/CHL1). 67 Fig 26. BZR1 and BR mediates the expression levels of nitrogen transporters. 68 Fig 27. BZR1-targeted NPF transporter genes transcription in Col-0 and bzr1-1D mutant. 69 Supplementary 1. The shoot and root fresh weight under 20 mM, 2.5 mM and 1 mM NH4NO3. with/without BR (50 nM). 70 Supplementary 2. The root fresh weight under 20 mM, 1 mM and 0.5 mM NH4NO3. in Col-0 and det2-1. 71 Supplementary 3. Growth development of Col-0, bzr1-D, En-2, bes1-D under 20 mM, 2.5 mM, 1 mM and 0.5 mM NH4NO3. 72 Supplementary 4. The CHIP data of BZR1 and BES1 in anthocyanin transcription factors. 73 Supplementary 5. BZR1/BES1-targeted anthocyanin bio. synthesis genes. 74 Supplementary 5. BZR1/BES1-targeted anthocyanin bio. synthesis genes. 74 Supplementary 6. BZR-regulated anthocyanin bio. synthesis genes. 75 Supplementary 7. Chloroplast-related genes were co-repressed in bzr1-Dxbri1-301 and N limitation condition. 76 Supplementary 8. 35S::BZR1-YFP overexpressed-line checked by Western blot and Confocal. 77 Supplementary 9. bes1-D mutant check. 78 Supplementary 10. BZR1-targeted N-related genes without N-related transcription factors. 80 Table 1. BZR1-targeted/regulated anthocyanin-related genes 81 Reference 82
dc.language.iso	en
dc.subject	花青素	zh_TW
dc.subject	缺氮	zh_TW
dc.subject	油菜素類固醇	zh_TW
dc.subject	brassinosteroid	en
dc.subject	anthocyanin	en
dc.subject	nitrogen limitation	en
dc.title	阿拉伯芥之油菜素類固醇透過 BZR1 調控缺氮下花青素之累積篩選參與抗病反應之阿拉伯芥 NPF 轉運蛋白突變株	zh_TW
dc.title	Brassinosteroids Regulate Anthocyanin Accumulations via BZR1 under Nitrogen Limitation condition in Arabidopsis Screening for Arabidopsis NPF transporter mutants in Pathogen Responses	en
dc.type	Thesis
dc.date.schoolyear	107-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	蔡宜芳,張英?
dc.subject.keyword	油菜素類固醇,花青素,缺氮,	zh_TW
dc.subject.keyword	brassinosteroid,anthocyanin,nitrogen limitation,	en
dc.relation.page	137
dc.identifier.doi	10.6342/NTU201903535
dc.rights.note	有償授權
dc.date.accepted	2019-08-16
dc.contributor.author-college	生命科學院	zh_TW
dc.contributor.author-dept	植物科學研究所	zh_TW
顯示於系所單位：	植物科學研究所

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