氯化鈣噴施與高磷養液對番茄尻腐病發生率及細胞內鈣離子分布之影響

黃念慈; Nian-Ci Huang

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/77277

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	林淑怡	zh_TW
dc.contributor.advisor	Shu-I, Lin	en
dc.contributor.author	黃念慈	zh_TW
dc.contributor.author	Nian-Ci Huang	en
dc.date.accessioned	2021-07-10T21:53:52Z	-
dc.date.available	2024-08-17	-
dc.date.copyright	2019-08-26	-
dc.date.issued	2019	-
dc.date.submitted	2002-01-01	-
dc.identifier.citation	林佳螢。2014。利用農桿菌滲入法及農桿菌注射法建立植體含磷狀態之系統。國立臺灣大學園藝學系碩士論文。台北。李佳穎。2015。鈣與硼對番茄果實品質之影響。國立臺灣大學園藝學系碩士論文。台北。李宜庭。2016。鈣與磷對番茄果實尻腐病與鈣運移相關基因表現之影響。國立臺灣大學園藝學系碩士論文。台北。李宜庭、林淑怡。2018。磷對番茄果實尻腐病發生率與品質之影響。臺灣園藝。64(2): 91-112。陳正次。1998。番茄育種。蔬菜育種技術研習會專刊農業試驗所特刊第73號。台中農業試驗所印行。231-283。戴振洋。2004。談番茄尻腐病發生之預防方法。台中區農情月刊。62:2。戴振洋。2015。設施果菜養液灌溉管理實例介紹。台中區農業專訊。89: 20-25。聯合國糧農組織（FAO）統計資料 http://faostat.fao.org（下載日期：2019.03.16）。 Adams, P. and A.M. El-Gizawy. 1988. Effect of calcium stress on the calcium status of tomatoes grown in NFT. Notes. 222:15-22. Bangerth, F. 1979. Calcium-related physiological disorder of plants. Ann. Rev. Phytopathol. 17: 97-122. Barbier-Brygoo, H., M. Vinauger, J. Colcombet, G. Ephritikhine, J.M. Frachisse, and C. Maurel. 2000. Anion channels in higher plants: functional characterization, molecular structure and physiological role. Biochim. Biophys. Acta. 1465(1-2): 199-218. Basirat, M., M.A. Malboobi, A. Mousavi, A. Asgharzadeh, and S. Samavat. 2011. Effects of phosphorous supply on growth, phosphate distribution and expression of transporter genes in tomato plants. Aust. J. Crop Sci. 5 (5): 537-543. Bradfield, E. and C. Guttridge. 1984. Effects of night-time humidity and nutrient solution concentration on the calcium content of tomato fruit. Sci. Hort. 22:207-217. Coolong, T., S. Mishra, C. Barickman, and C. Sams. 2014. Impact of supplemental calcium chloride on yield, quality, nutrient status, and postharvest attributes of tomato. J. Plant Nutr. 37(14): 2316-2330. De Freitas, S.T., K.A. Shackel, and E.J. Mitcham. 2011a. Abscisic acid triggers whole-plant and fruit-specific mechanisms to increase fruit calcium uptake and prevent blossom end rot development in tomato fruit. J. Exp. Bot. 62:2645-2656. De Freitas, S.T., M. Padda, Q. Wu, S. Park, and E.J. Mitcham. 2011b. Dynamic alternations in cellular and molecular components during blossom-end rot development in tomatoes expressing sCAX1, a constitutively active Ca2+/H+ antiporter from Arabidopsis. Plant. Physiol. 156: 844-855. De Freitas, S.T. and E.J. Mitcham. 2012a. Factors involved in fruit calcium deficiency disorders. Hortic. Rev. 40: 107-146. De Freitas, S.T., C.Z. Jiang, and E.J. Mitcham. 2012b. Mechanisms involved in calcium deficiency development in tomato fruit in response to gibberellins. J. Plant. Growth. Regul. 31:221-234. De Kreij, C. 1996. Interactive effects of air humidity, calcium and phosphate on blossom‐end rot, leaf deformation, production and nutrient contents of tomato. J. Plant Nutr. 19(2): 361-377. Fujita, K., M. Okada , K. Lei, J. Ito, K. Ohkura, , J.J. Adu‐Gyamfi, and P.K. Mohapatra. 2003. Effect of P‐deficiency on photoassimilate partitioning and rhythmic changes in fruit and stem diameter of tomato (Lycopersicon esculentum) during fruit growth. J. Exp. Bot. 54(392): 2519-2528. Ghoname, A.A., A.M. El-Bassiouny, A.M.R. Abdel-Mawgoud, W.A. El-Tohamy, and N. Gruda. 2012. Growth, yield and blossom-end rot incidence in bell pepper as affected by phosphorus level and amino acid applications Gesunde Pflanzen. 64 (1): 29-37. Ho, L.C. 1998. To quantify environmental and physiological factors controlling calcium uptake, transport and utilization on yield and quality of tomato and sweet peppers in glasshouses. Final report on MAFF project HH1309SPC. Ho, L.C., and P.J. White. 2005. A cellular hypothesis for the induction of blossom-end rot in tomato fruit. Ann. Bot. 95:571-581. Hirschi, K.D. 1999. Expression of Arabidopsis CAX1 in tobacco: altered calcium homeostasis and increased stress sensitivity. Plant Cell. 11(11): 2113-2122. Hirschi, K.D. 2001. Vacuolar H+/Ca2+ transport: who's directing the traffic?. Trends in plant science. 6(3): 100-104. Malboobi, M.A., K. Zamani, T. Lohrasebi, M.R. Sarikhani, A. Samaian, and M.S. Sabet. 2014. Phosphate: the silent challenge. Prog. Biol. Sci. 4 (1): 1-32. Malone, M., and J. Andrews. 2001. The distribution of xylem hydraulic resistance in the fruiting truss of tomato. Plant Cell Environ. 24(5): 565-570. Manohar, M., T. Shigaki, H. Mei, S. Park, J. Marshall, J. Aguilar, and K.D. Hirschi. 2011. Characterization of Arabidopsis Ca2+/H+ Exchanger CAX3. Biochemistry. 50: 6189–6195. Mestre, C.T., F. Garcia-Sanchez, F. Rubio, V. Martinez, and R.M. Rivero. 2012. Glutathione homeostasis as an important and novel factor controlling blossom-end rot development in calcium-deficient tomato fruits. J. Plant. Physiol. 169(17): 1719-1727. Nonami, H., T. Fukuyama, M. Yamamoto, L. Yang, and Y. Hashimoto. 1995. Blossom-end rot of tomato plants may not be directly caused by calcium deficiency. Acta. Hortic. 395:107-114. Nukaya, A., K. Goto, H. Jang, A. Kano, and K. Ohkawa. 1995. Effect of K/Ca Ratio in the nutrient solution on incidence of blossom-end rot and gold specks of tomato fruit grown in rockwool. Acta. Hortic. 396:123-130. Nukaya, A., K. Goto, H. Jang, A. Kano, and K. Ohkawa. 1995. Effect of NH4-N level in the nutrient solution on incidence of blossom-end rot and gold specks of tomato fruit grown in rockwool. Acta. Hortic. 401:381-388. Pittman, J.K. and K.D. Hirschi 2001. Regulation of CAX1, an Arabidopsis Ca2+/H+ antiporter. Identification of an N-terminal autoinhibitory domain. Plant Physiol. 127(3): 1020–1029. Saure, M.C. 2001. Blossom-end rot of tomato (Lycopersicon esculentum Mill.)—a calcium or a stress-related disorder? Scientia Horticulturae 90: 193–208. Spurr, A. 1959. Anatomical aspects of blossom-end rot in the tomato with special reference to calcium nutrition. Hilgardia. 28(12): 269-295. Suzuki, K., M. Shono, and Y. Egawa. 2003. Localization of calcium in the pericarp cells of tomato fruits during the development of blossom-end rot. Protoplasma. 222:149-156. Taylor, M.D. and S.J. Locascio. 2004. Blossom-end rot: A calcium deficiency. J. Plant Nutri. 27:123-139. Turhan, E., L. Karni, H. Aktas, G. Deventurero, D.C. Chang, A. Bar-Tal, and B. Aloni. 2006. Apoplastic anti-oxidants in pepper (Capsicum annuum L.) fruit and their relationship to blossom-end rot. J Hortic Sci Biotechnol., 81(4): 661-667. White, P.J. 2001. The pathways of calcium movement to the xylem. J. Exp. Bot. 52(358):891-899. White, P.J., and M.R. Broadley. 2003. Calcium in plants. Ann. Bot. 92:487-511. Willumsen, J., K. Kaack, and K.K. Petersen. 1996. Yield and blossom-end rot of tomato as affected by salinity and cation activity ratios in the root zone. J. Hort. Sci. Biotech. 71:81-98.	-
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/77277	-
dc.description.abstract	番茄尻腐病(blossom-end rot)為影響果實外觀及產量的生理障礙(physiological disorder)。多數研究認為果實果臍端(blossom-end)缺鈣為尻腐病發生的主要生理原因，然而後來的研究發現尻腐病果實具有與健康果實相似的總鈣濃度。近年有學者提出細胞中鈣離子體內失衡可能為尻腐病發生原因之假說。葉面及果實施鈣為農民常使用之防治方法，提高水耕養液中鈣和磷濃度也被證實能減緩尻腐病發生率，但鈣和磷彼此間對尻腐病的交互作用機制尚未被闡明。本研究使用對尻腐病敏感之大果番茄‘Heinz 1706’進行試驗，先前研究多是以水耕番茄進行鈣、磷濃度相關試驗，然臺灣農民多以土壤或無土介質栽培番茄。因此本研究採用介質耕方式搭配肥液滴灌系統進行，使用不同防治方法，探討其對番茄果實外觀、尻腐病發生率及嚴重度、營養元素濃度、細胞鈣離子濃度及分布之影響。試驗一處理為果實噴施0.5%氯化鈣水溶液與否，結果顯示，噴施0.5%氯化鈣水溶液果實呈現較低的果長、果寬、單果重、尻腐病發生率及嚴重度、細胞膜滲漏度，同時具有較高的總鈣含量、質外體鈣離子濃度(apoplastic Ca2+ concentration, [Ca2+]apoplast)及細胞質液鈣離子濃度(cytosolic Ca2+ concentration, [Ca2+]cyt)，以及大量鈣離子沈澱於細胞膜與細胞壁間。以授粉後45天果實而言，對照組與處理組之無發病果實較尻腐病果實具有較高之細胞質液鈣離子濃度，以及較多鈣離子沈澱於細胞膜與細胞壁間。試驗二為調控養液中磷濃度與鹽濃度。磷濃度不影響果實外觀、尻腐病發生率及嚴重度；與於中磷濃度養液中生長的果實相比，高磷處理僅在紅熟果顯示出較高的總鈣濃度；不同磷濃度處理並不顯著影響質外體鈣離子濃度，但高磷處理細胞質液鈣離子濃度高於中磷處理。相較無鹽處理，高鹽果實較小且有較高尻腐病發生率及嚴重度；不同鹽度處理對質外體鈣離子濃度與細胞質液鈣離子濃度無顯著影響。上述結果顯示噴施0.5%氯化鈣水溶液處理能有效降低尻腐病發生，磷養液處理效果則不明顯，因此防治尻腐病仍應以噴施0.5%氯化鈣水溶液效用較佳。尻腐病果實具有較低質外體鈣離子濃度、細胞質液鈣離子濃度與細胞層級鈣離子分布，支持了細胞中鈣離子體內失衡可能誘發尻腐病的假說。	zh_TW
dc.description.abstract	Tomato blossom-end rot (BER) is a physiological disorder which affects fruit appearance and yield. In most studies, calcium deficiency in distal part of fruit is considered to be the major physiological cause of BER. However, fruits with BER are found to have similar total calcium concentration to healthy fruits in later researches. Recently, researchers proposed a hypothesis that the imbalance of calcium ion (Ca2+) homeostasis in cell could trigger BER. Farmers spray calcium on leaves and fruits as a common prevention of BER. Increasing calcium and phosphorus concentration in nutrient solution is also proved to alleviate BER incidence. However, the interactive effect between calcium and phosphorus to BER has not been elucidated. In this research, BER-sensitive tomato cultivar ‘Heinz 1706’ were used as the material. Most previous studies related to BER were undertaken by hydroponic culture, while most tomatoes in Taiwan are cultivated by soil or soilless substrate. Therefore, this research used substrate culture with trickle fertigation system to investigate the effects of different preventions on tomato fruit appearance, BER incidence, BER severity, concentration of mineral elements, and cellular calcium concentration and distribution. In experiment I, fruits were sprayed with/without 0.5% calcium chloride (CaCl2) solution. The results showed that fruit sprayed with 0.5% CaCl2 solution displayed smaller length, width, and single fruit weight, along with lower incidence and severity of BER, and electrolyte leakage. In the mean time they had higher total calcium concentration, fruit apoplastic calcium concentration ([Ca2+]apoplast), cytosolic calcium concentration ([Ca2+]cyt), and abundant Ca2+ precipitated between cell membrane and cell wall. In the case of fruit 45 days after pollination (DAP), the healthy fruits of the control group and the treated group had higher [Ca2+]cyt than the BER fruits, and more Ca2+ precipitated between cell membrane and cell wall. Adjusting phosphorus concentration and salinity in nutrient solution were carried out in experiment II. Phosphorus concentration had no effect on fruit appearance, BER incidence and severity. Compared to fruits grown in nutrient solution with medium phosphorus concentration, the ones treated with high phosphorus concentration showed higher total calcium concentration only during red stage. Different phosphorus concentrations treatment did not significantly affect [Ca2+]apoplast. But high phosphorus treatment had higher [Ca2+]cyt than medium phosphorus treatment. High salinity treated fruits showed smaller size, higher BER incidence and severity than the ones without salinity treatment. Different salinity treatment did not significantly affect [Ca2+]apoplast and [Ca2+]cyt. The above results indicate that spraying 0.5% CaCl2 solution effectively decreases BER incidence, while the effect of high phosphorus in nutrient solution is not obvious. Therefore, spraying 0.5% CaCl2 solution is a better treatment to prevent BER. Fruits with BER have lower [Ca2+]apo, [Ca2+]cyt and cellular Ca2+ distribution, which supports the hypothesis that BER could be triggered by the imbalance of Ca2+ homeostasis in cell.	en
dc.description.provenance	Made available in DSpace on 2021-07-10T21:53:52Z (GMT). No. of bitstreams: 1 ntu-108-R06628113-1.pdf: 4733027 bytes, checksum: 2b044886a7bd9b7540c55769301a7862 (MD5) Previous issue date: 2019	en
dc.description.tableofcontents	致謝 I 摘要 III Abstract V 前言 1 前人研究 2 一、世界番茄產業重要性 2 二、番茄尻腐病徵狀及可能發生原因 2 三、番茄尻腐病與鈣之關聯性 3 四、番茄尻腐病與磷之關聯 5 五、尻腐病目前防治方法 6 材料與方法 8 一、植物材料與栽培管理方式 8 二、試驗設計 11 三、調查項目 11 結果 29 試驗一、0.5%氯化鈣水溶液噴施處理對番茄尻腐病生理影響 29 試驗二、磷濃度與鹽度處理對番茄尻腐病生理影響 35 討論 94 結論 99 參考文獻 100 附錄 105	-
dc.language.iso	zh_TW	-
dc.title	氯化鈣噴施與高磷養液對番茄尻腐病發生率及細胞內鈣離子分布之影響	zh_TW
dc.title	Effects of calcium chloride solution spray and high phosphorus nutrient solution on blossom-end rot incidence and cellular distribution of calcium ion in tomato	en
dc.type	Thesis	-
dc.date.schoolyear	107-2	-
dc.description.degree	碩士	-
dc.contributor.oralexamcommittee	羅筱鳳;陳荷明	zh_TW
dc.contributor.oralexamcommittee	Hsiao-Feng, Lo;Ho-Ming Chen	en
dc.subject.keyword	氯化鈣,高磷,高鹽,養液,鈣離子濃度,尻腐病,	zh_TW
dc.subject.keyword	calcium chloride,high phosphorus,high salinity,nutrient solution,calcium ion concentration,blossom-end rot,	en
dc.relation.page	114	-
dc.identifier.doi	10.6342/NTU201903125	-
dc.rights.note	未授權	-
dc.date.accepted	2019-08-12	-
dc.contributor.author-college	生物資源暨農學院	-
dc.contributor.author-dept	園藝暨景觀學系	-
顯示於系所單位：	園藝暨景觀學系

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