钙对枳生长发育及柑橘溃疡病抗性的影响

doi:10.3864/j.issn.0578-1752.2022.19.007

中国农业科学 ›› 2022, Vol. 55 ›› Issue (19): 3767-3778.doi: 10.3864/j.issn.0578-1752.2022.19.007

钙对枳生长发育及柑橘溃疡病抗性的影响

肖桂华^1,^2,³(),文康^1,^2,³,韩健⁴,郝晨星^1,^2,³,叶蓉春^1,^2,³,朱亦赤^1,^2,³,萧顺元¹,邓子牛^1,^2,³,马先锋^1,^2,³()

¹湖南农业大学园艺学院,长沙 410128
²园艺作物种质创新与新品种选育教育部工程研究中心,长沙 410128
³国家柑橘改良中心长沙分中心,长沙 410128
⁴湖南省园艺研究所,长沙 410125

收稿日期:2022-04-11 接受日期:2022-05-17 出版日期:2022-10-01 发布日期:2022-10-10
通讯作者: 马先锋
作者简介:肖桂华,E-mail： 17843096258@163.com。
基金资助:
国家重点研发计划(2018YFD1000300);湖湘高层次人才聚集工程(2019RS1052)

Effects of Calcium on Growth and Development of Poncirus trifoliata and Resistance to Citrus Canker

XIAO GuiHua^1,^2,³(),WEN Kang^1,^2,³,HAN Jian⁴,HAO ChenXing^1,^2,³,YE RongChun^1,^2,³,ZHU YiChi^1,^2,³,XIAO ShunYuan¹,DENG ZiNiu^1,^2,³,MA XianFeng^1,^2,³()

¹College of Horticulture, Hunan Agricultural University, Changsha 410128
²Engineering Research Center for Horticultural Crop Germplasm Creation and New Variety Breeding, Ministry of Education, Changsha 410128
³National Center for Citrus Improvement (Changsha), Changsha 410128
⁴Hunan Institute of Horticulture, Changsha 410125

Received:2022-04-11 Accepted:2022-05-17 Online:2022-10-01 Published:2022-10-10
Contact: XianFeng MA

摘要/Abstract

摘要：

【背景】柑橘溃疡病是由柑橘黄单胞杆菌柑橘致病变种（Xanthomonas citri subsp. citri,Xcc）引起的细菌性病害,可侵染枝、叶、果,危害几乎所有的柑橘主栽品种。前期对湖南省39个柑橘园的调查结果显示柑橘果园土壤酸化和交换性钙缺乏严重,叶片中均存在钙缺乏现象。钙是植物所需大量元素之一,钙缺乏会造成植物营养失衡,生长势下降,植物免疫水平受影响。然而,钙元素对柑橘溃疡病抗性的影响尚不明确。【目的】分析对柑橘溃疡病敏感的枳（Poncirus trifoliata）在不同钙浓度处理下叶片注射接种Xcc后的致病差异,探讨钙在Xcc侵染枳叶片过程中的作用。【方法】采用沙培法对枳实生苗进行0、0.75、3、30 mmol·L^-1钙浓度处理,分别测定枳生长期的生物量、叶绿素a和b浓度、根系和叶片钙元素含量、观察根系活性氧（ROS）的产生和胼胝质沉积,并分析枳叶片接种Xcc后细胞壁合成相关基因及免疫途径相关基因诱导表达变化特征。【结果】以3 mmol·L^-1钙处理为对照,0、0.75和30 mmol·L^-1钙处理后,枳地上部和地下部生长发育均受抑制,叶绿素a和b浓度降低;根系与叶片中的钙含量与外源钙施加量成正比;不同钙浓度处理后根系中产生ROS和胼胝质沉积,在3 mmol·L^-1处理时达到最大值;枳叶片接种Xcc后,随着钙浓度增加,叶片症状逐渐减轻,但Xcc的生长量无明显差异;相较于3 mmol·L^-1处理,参与细胞壁合成相关基因PtCESA4在0 mmol·L^-1处理下受Xcc诱导先上调表达后下调表达,在30 mmol·L^-1处理下受Xcc诱导上调表达,PtPME和PtFLA在0 mmol·L^-1处理下受Xcc诱导下调表达,在30 mmol·L^-1处理下受Xcc诱导上调表达;叶片接种Xcc 0、2、4、6 dpi后免疫途径相关基因PtGSL、PtGST1、PtWRKY22在30 mmol·L^-1处理下受Xcc诱导表达水平高于0 和3 mmol·L^-1处理。【结论】钙缺乏和过量均会影响枳生长发育,引起叶片失绿,根系产生ROS和胼胝质沉积均有所减少。施钙后接种Xcc,叶片表面的感病症状明显减弱,但菌含量与对照无显著差异。钙可能通过调控细胞壁合成相关基因促使细胞壁增厚,从而抑制Xcc突破叶片表皮形成典型症状。

关键词: 柑橘溃疡病, 柑橘黄单胞杆菌柑橘致病变种, 钙, 枳, 免疫

Abstract:

【Background】 Citrus canker is a bacterial disease caused by Xanthomonas citri subsp. citri (Xcc), which can infect branches, leaves and fruits, and affects almost all major citrus varieties. The results of a previous survey of 39 citrus orchards in Hunan Province showed that soil acidification and exchange calcium deficiency in citrus orchards were serious and calcium deficiency existed in all leaves. Calcium is one of the elements required by plants in large quantities, and calcium deficiency causes nutritional imbalance, reduced growth potential and compromised plant immunity level. However, the effect of calcium element on the process of citrus infection with canker is not clear. 【Objective】 The objective of this study is to analyze the pathogenic differences after inoculation with Xcc in Poncirus trifoliata (sensitive to citrus canker) leaves under different calcium concentrations, and to explore the role of calcium in Xcc infection of P. trifoliata leaves. 【Method】 The seedlings of P. trifoliata were sand cultured with calcium concentrations of 0, 0.75, 3, and 30 mmol·L^-1. During the growth period of P. trifoliata, the biomass, chlorophyll a and b concentrations, and calcium content in roots and leaves were determined, as well as the formation of reactive oxygen species (ROS) in roots and callose deposition. The effects of Xcc inoculation on cell wall synthesis-related genes and immune-related genes in P. trifoliata leaves were investigated. 【Result】 Compared with 3 mmol·L^-1 calcium treatment, 0, 0.75 and 30 mmol·L^-1 calcium treatments inhibited the growth and development of aboveground and underground parts of P. trifoliate, and chlorophyll a and b concentrations decreased. The calcium content in roots and leaves was proportional to the amount of exogenous calcium. ROS and callose deposition were generated in roots after treatment with different calcium concentrations, reaching the maximum at 3 mmol·L^-1. After inoculation with Xcc, the leaf symptoms gradually decreased with the increase of calcium concentration, but the growth of Xcc had no significant difference. Compared with 3 mmol·L^-1 treatment, PtCESA4, a gene involved in cell wall synthesis, was up-regulated and then down-regulated by Xcc under 0 mmol·L^-1 treatment, and up-regulated by Xcc under 30 mmol·L^-1 treatment. PtPME and PtFLA were down-regulated by Xcc under 0 mmol·L^-1 treatment, and up-regulated by Xcc under 30 mmol·L^-1 treatment. The expression levels of immune pathway related genes PtGSL, PtGST1 and PtWRKY22 induced by Xcc at 30 mmol·L^-1 were higher than those at 0 and 3 mmol·L^-1 after inoculation with Xcc at 0, 2, 4 and 6 dpi. 【Conclusion】 The growth and development of P. trifoliate is affected by calcium deficiency and excess, resulting in leaf chlorosis, and ROS production and callose deposition in roots decreased. The sensitive symptoms on the leaf surface caused by Xcc were greatly attenuated after calcium application, but the bacterial content was not significantly different from that of the control. Calcium may promote cell wall thickening by regulating genes related to cell wall synthesis, thereby inhibiting Xcc from breaking through leaf epidermis and forming typical symptoms.

Key words: citrus canker, Xanthomonas citri subsp. citri (Xcc), calcium, Poncirus trifoliata, immunity

肖桂华,文康,韩健,郝晨星,叶蓉春,朱亦赤,萧顺元,邓子牛,马先锋. 钙对枳生长发育及柑橘溃疡病抗性的影响[J]. 中国农业科学, 2022, 55(19): 3767-3778.

XIAO GuiHua,WEN Kang,HAN Jian,HAO ChenXing,YE RongChun,ZHU YiChi,XIAO ShunYuan,DENG ZiNiu,MA XianFeng. Effects of Calcium on Growth and Development of Poncirus trifoliata and Resistance to Citrus Canker[J]. Scientia Agricultura Sinica, 2022, 55(19): 3767-3778.

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参考文献 43

[1]	赵宜波, 韩健, 杨贵兵, 龙立长, 谭振华, 李先信, 周卫军, 邓子牛, 马先锋. 湖南省甜橙主产区土壤和叶果矿质元素状况分析. 中国南方果树, 2020, 49(6): 27-33.
	ZHAO Y B, HAN J, YANG G B, LONG L C, TAN Z H, LI X X, ZHOU W J, DENG Z N, MA X F. Analysis of soil and leaf and fruit mineral elements in main producing areas of sweet orange in Hunan Province. South China Fruits, 2020, 49(6): 27-33. (in Chinese)
[2]	杨利玲, 张桂兰. 土壤中的钙化学与植物的钙营养. 甘肃农业, 2006(10): 272-273.
	YANG L L, ZHANG G L. Calcium chemistry in soil and calcium nutrition in plants. Gansu Agriculture, 2006(10): 272-273. (in Chinese)
[3]	WHITE P J, BROADLEY M R. Calcium in plants. Annals of Botany, 2003, 92(4): 487-511. pmid: 12933363
[4]	HEPLER P K. Calcium: A central regulator of plant growth and development. The Plant Cell, 2005, 17(8): 2142-2155. doi: 10.1105/tpc.105.032508
[5]	BASCOM C S, HEPLER P K, BEZANILLA M. Interplay between ions, the cytoskeleton, and cell wall properties during tip growth. Plant Physiology, 2018, 176(1): 28-40. doi: 10.1104/pp.17.01466 pmid: 29138353
[6]	YAMAMOTO T, NAKAMURA A, IWAI H, ISHII T, MA J F, YOKOYAMA R, NISHITANI K, SATOH S, FURUKAWA J. Effect of silicon deficiency on secondary cell wall synthesis in rice leaf. Journal of Plant Research, 2012, 125(6): 771-779. doi: 10.1007/s10265-012-0489-3 pmid: 22527842
[7]	GIOVANE A, SERVILLO L, BALESTRIERI C, RAIOLA A, D’AVINO R, TAMBURRINI M, CIARDIELLO M A, CAMARDELLA L. Pectin methylesterase inhibitor. Biochimica et Biophysica Acta, 2004, 1696(2): 245-252. pmid: 14871665
[8]	WANG H, JIANG C, WANG C, YANG Y, YANG L, GAO X, ZHANG H. Antisense expression of the fasciclin-like arabinogalactan protein FLA6 gene in Populus inhibits expression of its homologous genes and alters stem biomechanics and cell wall composition in transgenic trees. Journal of Experimental Botany, 2015, 66(5): 1291-1302. doi: 10.1093/jxb/eru479
[9]	HIRSCHI K D. The calcium conundrum. Both versatile nutrient and specific signal. Plant Physiology, 2004, 136(1): 2438-2442. pmid: 15375199
[10]	DODD A N, KUDLA J, SANDERS D. The language of calcium signaling. Annual Review of Plant Biology, 2010, 61: 593-620. doi: 10.1146/annurev-arplant-070109-104628 pmid: 20192754
[11]	FINKA A, CUENDET A F, MAATHUIS F J, SAIDI Y, GOLOUBINOFF P. Plasma membrane cyclic nucleotide gated calcium channels control land plant thermal sensing and acquired thermotolerance. The Plant Cell, 2012, 24(8): 3333-3348. doi: 10.1105/tpc.112.095844 pmid: 22904147
[12]	TUNC-OZDEMIR M, TANG C, ISHKA M R, BROWN E, GROVES N R, MYERS C T, RATO C, POULSEN L R, MCDOWELL S, MILLER G, MITTLER R, HARPER J F. A cyclic nucleotide-gated channel (CNGC16) in pollen is critical for stress tolerance in pollen reproductive development. Plant Physiology, 2013, 161(2): 1010-1020. doi: 10.1104/pp.112.206888
[13]	TOYOTA M, SPENCER D, SAWAI-TOYOTA S, JIAQI W, ZHANG T, KOO A J, HOWE G A, GILROY S. Glutamate triggers long-distance, calcium-based plant defense signaling. Science, 2018, 361(6407): 1112-1115. doi: 10.1126/science.aat7744 pmid: 30213912
[14]	JIANG Z, ZHOU X, TAO M, YUAN F, LIU L, WU F, WU X, XIANG Y, NIU Y, LIU F, et al. Plant cell-surface GIPC sphingolipids sense salt to trigger Ca²⁺ influx. Nature, 2019, 572(7769): 341-346. doi: 10.1038/s41586-019-1449-z
[15]	CALDWELL D, KIM B S, IYER-PASCUZZI A S. Ralstonia solanacearum differentially colonizes roots of resistant and susceptible tomato plants. Phytopathology, 2017, 107(5): 528-536. doi: 10.1094/PHYTO-09-16-0353-R
[16]	SUGIMOTO T, WATANABE K, YOSHIDA S, AINO M, FURIKI M, SHIONO M, MATOH T, BIGGS A R. Field application of calcium to reduce phytophthora stem rot of soybean, and calcium distribution in plants. Plant Disease, 2010, 94(7): 812-819. doi: 10.1094/PDIS-94-7-0812 pmid: 30743551
[17]	RAZ V, FLUHR R. Calcium requirement for ethylene-dependent responses. The Plant Cell, 1992, 4(9): 1123-1130. pmid: 12297671
[18]	BOLLER T, HE S Y. Innate immunity in plants: An arms race between pattern recognition receptors in plants and effectors in microbial pathogens. Science, 2009, 324(5928): 742-744. doi: 10.1126/science.1171647 pmid: 19423812
[19]	MORALES J, KADOTA Y, ZIPFEL C, MOLINA A, TORRES M A. The Arabidopsis NADPH oxidases RbohD and RbohF display differential expression patterns and contributions during plant immunity. Journal of Experimental Botany, 2016, 67(6): 1663-1676. doi: 10.1093/jxb/erv558
[20]	VOIGT C A. Callose-mediated resistance to pathogenic intruders in plant defense-related papillae. Frontiers in Plant Science, 2014, 5: 168. doi: 10.3389/fpls.2014.00168 pmid: 24808903
[21]	WOJTASZEK P. Oxidative burst: An early plant response to pathogen infection. The Biochemical Journal, 1997, 322(3): 681-692. doi: 10.1042/bj3220681
[22]	TORRES M A, ONOUCHI H, HAMADA S, MACHIDA C, HAMMOND-KOSACK K E, JONES J D. Six Arabidopsis thaliana homologues of the human respiratory burst oxidase (gp91phox). The Plant Journal, 1998, 14(3): 365-370. doi: 10.1046/j.1365-313X.1998.00136.x
[23]	KLOTH K J, WIEGERS G L, BUSSCHER-LANGE J, VAN HAARST J C, KRUIJER W, BOUWMEESTER H J, DICKE M, JONGSMA M A. AtWRKY22 promotes susceptibility to aphids and modulates salicylic acid and jasmonic acid signalling. Journal of Experimental Botany, 2016, 67(11): 3383-3396. doi: 10.1093/jxb/erw159 pmid: 27107291
[24]	WANG Y, LI X F, FAN B F, ZHU C, CHEN Z X. Regulation and function of defense-related callose deposition in plants. International Journal of Molecular Science, 2021, 22(5): 2393. doi: 10.3390/ijms22052393
[25]	李合生. 现代植物生理学. 3版. 北京: 高等教育出版社, 2012.
	LI H S. Modern Plant Physiology. 3rd ed. Beijing: Higher Education Press, 2012. (in Chinese)
[26]	ZHANG Q, XIE Z, ZHANG R, XU P, LIU H, YANG H, DOBLIN M S, BACIC A, LI L. Blue light regulates secondary cell wall thickening via MYC2/MYC4 activation of the NST1-directed transcriptional network in Arabidopsis. The Plant Cell, 2018, 30(10): 2512-2528. doi: 10.1105/tpc.18.00315
[27]	张海平, 单世华, 蔡来龙, 官德义, 李毓, 庄伟建. 钙对花生植株生长和叶片活性氧防御系统的影响. 中国油料作物学报, 2004, 26(3): 33-36.
	ZHANG H P, SHAN S H, CAI L L, GUAN D Y, LI Y, ZHUANG W J. Effects of calcium on peanut plant growth and defense system of active oxygen in leaves. Chinese Journal of Oil Crop Sciences, 2004, 26(3): 33-36. (in Chinese)
[28]	任城帅, 李慧, 翁小航, 张淞著, 刘丽颖, 周永斌. 外源钙对水曲柳生长、光合特性及水分利用效率的影响. 沈阳农业大学学报, 2020, 51(6): 663-669.
	REN C S, LI H, WENG X H, ZHANG S Z, LIU L Y, ZHOU Y B. Effects of exogenous calcium on growth, photosynthetic characteristics and water use efficiency of Fraxinus mandshurica. Journal of Shenyang Agricultural University, 2020, 51(6): 663-669. (in Chinese)
[29]	姚棋, 韩天云, 梁祎, 石玉, 侯雷平, 张毅. 外源钙和EBR处理对番茄果实品质特性的影响. 中国瓜菜, 2021, 34(10): 74-79.
	YAO Q, HAN T Y, LIANG Y, SHI Y, HOU L P, ZHANG Y. Effects of exogenous calcium and EBR treatment on fruit quality characteristics of tomato. China Cucurbits and Vegetables, 2021, 34(10): 74-79. (in Chinese)
[30]	张芳, 宋敏, 彭晚霞, 曾馥平, 杜虎, 胡芳, 陈莉, 苏樑. 不同钙浓度对两种岩溶植物幼苗生长及其酶活性的影响. 广西植物, 2017, 37(6): 707-715.
	ZHANG F, SONG M, PENG W X, ZENG F P, DU H, HU F, CHEN L, SU L. Effects of different calcium concentrations on seedling growth and enzyme activities of two karst plant species. Guihaia, 2017, 37(6): 707-715. (in Chinese)
[31]	THOR K. Calcium-nutrient and messenger. Frontiers in Plant Science, 2019, 10: 440. doi: 10.3389/fpls.2019.00440 pmid: 31073302
[32]	李敏, 吉文丽, 张恒, 李程程, 杨静萱, 张延龙. 外源Ca²⁺对油用牡丹凤丹白幼苗光合特性的影响. 西北林学院学报, 2017, 32(5): 39-45.
	LI M, JI W L, ZHANG H, LI C C, YANG J X, ZHANG Y L. Effects of exogenous calcium on photosynthetic characteristics and biomass of oil Paeonia ostii ‘Fengdan White’. Journal of Northwest Forestry University, 2017, 32(5): 39-45. (in Chinese)
[33]	汪雷, 马琛, 高海立, 徐涛. 钙对半夏生理特性及光合生理的影响. 浙江理工大学学报(自然科学版), 2018, 39(4): 461-467.
	WANG L, MA C, GAO H L, XU T. Effects of calcium on physiological characteristics and photosynthetic physiology of Pinellia ternata. Journal of Zhejiang Sci-Tech University (Natural Sciences), 2018, 39(4): 461-467. (in Chinese)
[34]	杨阳, 王恒振, 王咏梅, 管雪强, 尹向田, 苏玲. 喷钙对干旱胁迫下葡萄光合作用及叶绿素荧光参数的影响. 安徽农业科学, 2017, 45(27): 62-64, 189.
	YANG Y, WANG H Z, WANG Y M, GUAN X Q, YIN X T, SU L. Effects of calcium spray on photosynthesis and chlorophyll fluorescence of grape under drought stress. Journal of Anhui Agricultural Sciences, 2017, 45(27): 62-64, 189. (in Chinese)
[35]	FORAND A D, FINFROCK Y Z, LAVIER M, STOBBS J, QIN L, WANG S, KARUNAKARAN C, WEI Y, GHOSH S, TANINO K K. With a little help from my cell wall: Structural modifications in pectin may play a role to overcome both dehydration stress and fungal pathogens. Plants, 2022, 11(3): 385. doi: 10.3390/plants11030385
[36]	LANGER S E, MARINA M, BURGOS J L, MARTíNEZ G A, CIVELLO P M, VILLARREAL N M. Calcium chloride treatment modifies cell wall metabolism and activates defense responses in strawberry fruit (Fragaria × ananassa, Duch). Journal of the Science of Food and Agriculture, 2019, 99(8): 4003-4010. doi: 10.1002/jsfa.9626
[37]	ZHUANG Y, WEI M, LING C, LIU Y, AMIN A K, LI P, LI P, HU X, BAO H, HUO H, SMALLE J, WANG S. EGY3 mediates chloroplastic ROS homeostasis and promotes retrograde signaling in response to salt stress in Arabidopsis. Cell Reports, 2021, 36(2): 109384. doi: 10.1016/j.celrep.2021.109384
[38]	MÜLLER J, TOEV T, HEISTERS M, TELLER J, MOORE K L, HAUSE G, DINESH D C, BÜRSTENBINDER K, ABEL S. Iron-dependent callose deposition adjusts root meristem maintenance to phosphate availability. Developmental Cell, 2015, 33(2): 216-230. doi: 10.1016/j.devcel.2015.02.007 pmid: 25898169
[39]	RASMUSSEN M W, ROUX M, PETERSEN M, MUNDY J. MAP kinase cascades in Arabidopsis innate immunity. Frontiers in Plant Sciences, 2012, 3: 169.
[40]	ABBRUSCATO P, NEPUSZ T, MIZZI L, DEL CORVO M, MORANDINI P, FUMASONI I, MICHEL C, PACCANARO A, GUIDERDONI E, SCHAFFRATH U, MOREL J B, PIFFANELLI P, FAIVRE-RAMPANT O. OsWRKY22, a monocot WRKY gene, plays a role in the resistance response to blast. Molecular Plant Pathology, 2012, 13(8): 828-841. doi: 10.1111/j.1364-3703.2012.00795.x pmid: 22443363
[41]	HSU F C, CHOU M Y, CHOU S J, LI Y R, PENG H P, SHIH M C. Submergence confers immunity mediated by the WRKY22 transcription factor in Arabidopsis. The Plant Cell, 2013, 25(7): 2699-2713. doi: 10.1105/tpc.113.114447
[42]	HUSSAIN A, LI X, WENG Y H, LIU Z Q, ASHRAF M F, NOMAN A, YANG S, IFNAN M, QIU S S, YANG Y J, GUAN D Y, HE S L. CaWRKY22 acts as a positive regulator in pepper response to Ralstonia solanacearum by constituting networks with CaWRKY6, CaWRKY27, CaWRKY40, and CaWRKY58. International Journal of Molecular Science, 2018, 19(5): 1426. doi: 10.3390/ijms19051426
[43]	ELLINGER D, VOIGT C A. Callose biosynthesis in Arabidopsis with a focus on pathogen response: What we have learned within the last decade. Annals of Botany, 2014, 114(6): 1349-1358. doi: 10.1093/aob/mcu120

基因Gene	引物名称Primer name	引物序列Primer sequence (5′-3′)	Tm (℃)
PtGSL	PtGSL-qPCR-F	GGTGGGATGGAGAACAAGAACACC	59.8
PtGSL	PtGSL-qPCR-R	GGTACCAAATCTTCGTCTGCCCAT	59.3
PtWAKY22	PtWAKY22-qPCR-F	GCGGATTGTCTCGCATGTG	59.6
PtWAKY22	PtWAKY22-qPCR-R	TTATGGGTTTCTGCCCGTATTT	60.0
PtGST1	PtGST1-qPCR-F	GCCCGTTTGTCTCAGTCCAA	59.8
PtGST1	PtGST1-qPCR-R	TGCAAATCGACCAAGGTGAA	59.7
PtCESA4	PtCESA4-qPCR-F	GATGGGCTCTTGGCTCTGTT	59.2
PtCESA4	PtCESA4-qPCR-R	GGTGTTGGTGTATGCAAGCC	59.4
Actin	Actin-qPCR-F	CACACTGGAGTGATGGTTGG	59.4
Actin	Actin-qPCR-R	ATTGGCCTTGGGGTTAAGAG	60.0
PtPME	PtPME-qPCR-F	GAACCTAACGGAAGCCCACA	58.6
PtPME	PtPME-qPCR-R	GACTCCGTTGCTCGACTTCA	59.3
PtFLA	PtFLA-qPCR-F	GACCCTCTACCCGAACCTCT	59.4
PtFLA	PtFLA-qPCR-R	GCAGCGTCATGTTGAACGAA	59.1
PtRbohD	PtRbohD-qPCR-F	GTAAATTGCGCTGCCGTCTC	58.3
PtRbohD	PtRbohD-qPCR-R	GTCCAATCGCCCAAAGTTCG	59.2
PtRbohF	PtRbohF-qPCR-F	GACCTTGTCAAAGGGGCAGA	59.6
PtRbohF	PtRbohF-qPCR-R	CCTATCGAAGGGCTTTGGCA	58.1

钙对枳生长发育及柑橘溃疡病抗性的影响

Effects of Calcium on Growth and Development of Poncirus trifoliata and Resistance to Citrus Canker

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