etr1-1在矮牵牛中诱导表达可提高叶片对灰霉病的抗性

doi:10.3864/j.issn.0578-1752.2014.08.006

Abstract

Abstract: 【Objective】The objective of this study is to clarify the effect of induced etr1-1 expression on petunia response to infection by Botrytis cinerea, the causal agent of gray mold disease. 【Method】Detached leaves of GVG: etr1-1 transgenic petunias treated by DEX were inoculated with B. cinerea, then the regulation mechanism of etr1-1 was investigated by observing disease symptoms, measuring disease severity and analyzing gene expression by quantitative RT-PCR and semi-quantitative RT-PCR. 【Result】Induced etr1-1 expression by dexamethasone resulted in the retarded senescence and reduced disease symptoms on detached leaves. During the period of inoculation, the percentage of increased disease incidence was 0 on DEX-treated leaves, whereas 66.77% on control leaves. The growth rate of the leaf lesions on DEX-treated leaves was 4.69 mm•d-1, whereas 6.29 mm•d-1 on control leaves. qRT-PCR and semi-qRT-PCR provided the following results. The extent of decreased disease incidence was negatively correlated with the etr1-1 expression. Following prolonged induction time, the level of etr1-1 expression was enhanced on DEX-treated leaves and obtained the peak at 3rd day after DEX treatment. 10.71-fold changes were increased on mock-inoculating leaves than that on B. cinerea-inoculating leaves. The maximum expression of Bcact was obtained at 1 dpi on DEX-treated leaves, whereas, at 2 dpi on control leaves. The maximum level of Bcact expression was 20-fold lower on DEX-treated leaves than that on control leaves. Infection of B. cinerea activated CP10 expression and caused the senescence symptom. In comparison, 23.6-fold changes were decreased on DEX-treated leaves than on control leaves. The expression of ACO exhibited a decline after an up on both DEX-treated and control leaves. The peak of expression level was observed at 2 dpi. The peak of expression of ACO was only 6.75 on DEX-treated leaves, which suggested 7.33-fold lower than that on control leaves. On DEX-treated leaves with induced etr1-1 expression, repressed genes expressions in ethylene/JA pathway decreased ERF4 and ERF8 expression and consequently reduced pathogenesis-related gene expression. The expressions of ERS1 and ETR2 were observed and the peak of expression came out at 3 dpi on both DEX-treated and control leaves, however, 51-fold lower expression was observed on DEX-treated leaves than that on control leaves. The expression was suppressed at 1 and 2 dpi, and activated at 3 dpi on DEX-treated leaves. Following the prolonged inoculation time, the level of EIN2 expression was enhanced on control leaves. It was found that the maximum expression on DEX-treated leaves was 31.58-fold lower than that on control leaves. The expression of EIL1 showed the similar patterns as that of EIN2. It was observed that 2-fold lower expression of EIN2 on DEX-treated leaves than that on control leaves. AOC and COI1 played important roles in the biosynthesis and signal pathway of jasmonic acid. The expression of AOC and COI1 was repressed at 1-2 dpi and activated at 3 dpi on DEX-treated leaves, however, the expression level was increased following the prolonged inoculation time on control leaves. It was found that 12.96-fold lower expression on DEX-treated leaves than on control leaves. The expression of COI1 was discovered and obtained the peak at 3 dpi, regardless of DEX-treated leaves and control leaves. It was observed that 6.14-fold lower expression of COI1 on DEX-treated leaves than on control leaves. The expression of ethylene response factors (ERFs), as downstream components, integrated the ethylene and JA signaling pathway. The expression of ERF4 showed up before a decrease pattern on DEX-treated leaves. The expression level of ERF4 showed rising patterns following inoculation. The expressions of ERF8 displayed ascend patterns following the prolonged inoculation time, regardless of DEX-treated and control leaves. It was found that 2.96- and 3.52-fold lower expression of ERF4 and ERF8 on DEX-treated leaves than on control leaves. Little expression of pathogenesis-related genes was monitored on DEX-treated leaves and the peak of all genes was lower than 10, whereas, the expression was enhanced on control leaves, such as, the maximum level of expression of PR1, EX-CHI, OSM, Defense1 and AC-CHI was 10 521.11, 184.95, 184.96, 23.39 and 14.58, respectively.【Conclusion】Induced etr1-1 expression delayed the senescence of leaves of petunia caused by B. cinerea and was consequently responsible for tolerance of GVG: etr1-1 transgenic petunias to B. cinerea.

Key words: petunia ×, hybrida ‘Mitchell diploid&rsquo, Botrytis cinerea , ethylene , jasmonic acid , senescence , defense response

WANG Hong-1, LIN Jing-1, LIU Gang-2, LI Chun-Xia-2, LUO Chang-Guo-3, LI Gang-Bo-2, ZHANG Zhen-2, CHANG You-Hong-1. Induced etr1-1 Expression in Petunias is Responsible for Its Tolerance to Botrytis cinerea[J].Scientia Agricultura Sinica, 2014, 47(8): 1502-1511.

References

[1]Chang C, Kwok S F, Bleecker A B, Meyerowitz E M. Arabidopsis ethylene-response gene ETR1: similarity of product to two-component regulators. Science, 1993, 262(5133): 539-544.

[2]O'Donnell P J, Calvert C, Atzorn R, Wasternack C, Leyser H M O, Bowles D J. Ethylene as a signal mediating the wound response of tomato plants. Science, 1996, 274(5294): 1914-1917.

[3]Hoffman T, Schmidt J S, Zheng X, Bent A F. Isolation of ethylene-insensitive soybean mutants that are altered in pathogen susceptibility and gene for gene disease resistance. Plant Physiology, 1999, 119: 935-949.

[4]Thomma B P H J, Eggermont K, Tierens K F M J, Broekaert W F. Requirement of functional ethylene-insensitive 2 gene for efficient resistance of Arabidopsis to infection by Botrytis cinerea. Plant Physiology, 1999, 121: 1093-1101.

[5]Knoester M, van Loon L C, van den Heuvel J, Hennig J, Bol J F, Linthorst H J M. Ethylene-insensitive tobacco lacks nonhost resistance against soil-borne fungi. Proceedings of the National Academy of Sciences of the United States of America, 1998, 95: 1933-1937.

[6]Balaji V, Mayrose M, Sherf O, Jacob-Hirsch J, Eichenlaub R, Iraki N, Manulis-Sasson S, Rechavi G, Barash I, Sessa G. Tomato transcriptional changes in response to Clavibacter michiganensis subsp. michiganensis reveal a role for ethylene in disease development. Plant Physiology, 2008, 146(4): 1797-1809.

[7]Jones M L, Chaffin G S, Eason J R, Clark D G. Ethylene-sensitivity regulates proteolytic activity and cysteine protease gene expression in petunia corollas. Journal of Experimental Botany, 2005, 56(420): 2733-2744.

[8]Serek M, Woltering E, Sisler E, Frello S, Sriskandarajah S. Controlling ethylene responses in flowers at the receptor level. Biotechnology Advances, 2006, 24(4): 368-381.

[9]Clark D G, Gubrium E K, Barrett J E, Nell T A, Klee H J. Root formation in ethylene-insensitive plants. Plant Physiology, 1999, 121(1): 53-59.

[10]Gubrium E K, Clevenger D J, Clark D G, Barrett J E, Nell T A. Reproduction and horticultural performance of transgenic ethylene- insensitive petunias. Journal of America Society of Horticultural Science, 2000, 125(3): 277-281.

[11]Wang H, Steir G, Lin J, Gang L, Zhang Z, Chang Y, Reid M S, Jiang C Z. Transcriptome changes associated with delayed flower senescence on transgenic petunia by inducing expression of etr1-1, a mutant ethylene receptor. PLos One, 2013, 8(7): e65800.

[12]Cantu D, Vicente A R, Greve L C, Dewey F M, Bennett A B, Labavitch J M, Powell A L T. The intersection between cell wall disassembly, ripening, and fruit susceptibility to Botrytis cinerea. Proceedings of the National Academy of Sciences of the United States of America, 2008, 105(3): 859-864.

[13]Asselbergh B, Curvers K, França S C, Audenaert K, Vuylsteke M, Van Breusegem F, Höfte M. Resistance to Botrytis cinerea in sitiens, an abscisic acid-deficient tomato mutant, involves timely production of hydrogen peroxide and cell wall modifications in the epidermis. Plant Physiology, 2007, 144(4): 1863-1877.

[14]Craft J, Samalova M, Baroux C, Townley H, Martinez A, Jepson I, Tsiantis M, Moore I. New pOp/LhG4 vectors for stringent glucocorticoid-dependent transgene expression in Arabidopsis. The Plant Journal, 2005, 41(6): 899-918.

[15]Wang H, Liu G, Li C, Powell A L, Reid M S, Zhang Z, Jiang C Z. Defence responses regulated by jasmonate and delayed senescence caused by ethylene receptor mutation contribute to the tolerance of petunia to Botrytis cinerea. Molecular Plant Pathology, 2013, 14(5): 453-469.

[16]Benito E P, ten Have A, van’t Klooster J W, van Kan J A L. Fungal and plant gene expression during synchronized infection of tomato leaves by Botrytis cinerea. European Journal of Plant Pathology, 1998, 104(2): 207-220.

[17]Díza J, ten Have A, van Kan J A L. The role of ethylene and wound signaling in resistance of tomato to Botrytis cinerea. Plant Physiology, 2002, 129: 1341-1351.

[18]Swartzberg D, Kirshner B, Rav-David D, Elad Y, Granot D. Botrytis cinerea induces senescence and is inhibited by autoregulated expression of the IPT gene. European Journal of Plant Pathology, 2008, 120(3): 289-297.

[19]Ahkami A H, Lischewski S, Haensch K T, Porfirova S, Hofmann J, Rolletschek H, Melzer M, Franken P, Hause B, Druege U, Hajirezaei M R. Molecular physiology of adventitious root formation in Petunia hybrida cuttings: involvement of wound response and primary metabolism. New Phytologist, 2009, 181(3): 613-625.

[20]Breuillin F, Schramm J, Hajirezaei M, Ahkami A, Favre P, Druege U, Hause B, Bucher M, Kretzschmar T, Bossolini E, Kuhlemeier C, Martinoia E, Franken P, Scholz U, Reinhardt D. Phosphate systemically inhibits development of arbuscular mycorrhiza in Petunia hybrida and represses genes involved in mycorrhizal functioning. The Plant Journal, 2010, 64(6): 1002-1017.

[21]Feys B, Benedetti C E, Penfold C N, Turner J G. Arabidopsis mutants selected for resistance to the phytotoxin coronatine are male sterile, insensitive to methyl jasmonate, and resistant to a bacterial pathogen. The Plant Cell, 1994, 6: 751-759.

[22]Xie D X, Feys B F, James S, Nieto-Rostro M, Turner J G. COI1: an Arabidopsis gene required for jasmonate-regulated defense and fertility. Science, 1998, 280(5366): 1091-1094.

[23]Lorenzo O, Piqueras R, Sanchez-Serrano J J, Solano R. Ethylene Response Factor1 integrates signals from ethylene and jasmonate pathways in plant defense. The Plant Cell, 2003, 15(1): 165-178.

[24]Leon-Reyes A, Du Y, Koornneef A, Proietti S, Korbes A P, Memelink J, Pieterse C M, Ritsema T. Ethylene signaling renders the jasmonate response of Arabidopsis insensitive to future suppression by salicylic acid. Molucular Plant-Microbe Interaction, 2010, 23(2): 187-197.

[25]Broekaert W F, Delaure S L, De Bolle M F, Cammue B P. The role of ethylene in host-pathogen interactions. Annual Review of Phytopathology, 2006, 44: 393-416.

[26]Tsuchisaka A, Yu G X, Jin H L, Alonso J M, Ecker J R, Zhang X M, Gao S, Theologis A. A combinatorial interplay among the 1-aminocyclopropane-1-carboxylate isoforms regulates ethylene biosynthesis in Arabidopsis thaliana. Genetics, 2009, 183(3): 979-1003.

[27]Grbi? V, Bleecker A B. Ethylene regulates the timing of leaf senescence in Arabidopsis. The Plant Journal, 1995, 8(4): 595-602.

[28]Kende H. Ethylene biosynthesis. Annual Review of Plant Physiology, 1993, 44(1): 283-307.

[29]Yang S F, Hoffman N E. Ethylene biosynthesis and its regulation in higher plants. Annual Review of Plant Physiology, 1984, 35(1): 155-189.

[30]Penninckx I A M A, Thomma B P H J, Buchala A, Métraux J P, Broekaerta W F. Concomitant activation of jasmonate and ethylene response pathways is required for induction of a plant defensin gene in Arabidopsis. The Plant Cell, 1998, 10(12): 2103-2113.

[31]Plett J M, Cvetkovska M, Makenson P, Xing T, Regan S. Arabidopsis ethylene receptors have different roles in fumonisin B1-induced cell death. Physiological and Molecular Plant Pathology, 2009, 74(1): 18-26.

Related Articles 15

[1]	ZHANG DongMei, ZHOU XinXin, XIAO GuiLin, ZENG XiangGuo, WANG ChunYan, WANG ZeXian, HAN YongChao. Phenotypic Characteristics of Strawberry Floral Organs in Response to Botrytis cinerea Infection and Methods for Gray Mold Resistance Evaluation [J]. Scientia Agricultura Sinica, 2026, 59(7): 1456-1466.
[2]	LIU Jie, HOU Rui, ZHOU ZeHua, YI TuYong. Antibacterial Activity of Polyhexamethylene Guanidine Against Xanthomonas citri pv. citri [J]. Scientia Agricultura Sinica, 2025, 58(9): 1779-1790.
[3]	ZHANG TianYu, LI Bai, ZANG JinPing, CAO HongZhe, DONG JinGao, XING JiHong, ZHANG Kang. Genome-Wide Identification and Expression Analysis of HMG Family Genes in Botrytis cinerea [J]. Scientia Agricultura Sinica, 2025, 58(4): 704-718.
[4]	ZHAO Ya, ZHANG Wen, WANG Du, ZHANG LiangXiao, ZHANG Qi, HAN Qin, WANG Wei, LI PeiWu. Effects of ARC Microbial Agent on Alleviating Functional Decline of Peanut Root Nodules Under Dark Stress [J]. Scientia Agricultura Sinica, 2025, 58(22): 4617-4627.
[5]	CAI HaiLin, HUANG XinRong, ZENG WeiAi, PENG ZhiXin, ZHAO AJuan, BO ChunBin, XIANG ShiPeng, GAO PengCheng, ZHANG ChengSheng, ZHAO DongLin. Structure and Herbicidal Activity of 3,5-Dimethylorsellinic Acid-Derived Meroterpenoids from Penicillium sclerotiorum HY5 [J]. Scientia Agricultura Sinica, 2025, 58(22): 4673-4687.
[6]	ZHAO YuLei, XIN JiaLu, LI ChengNan, LI Shan, XIE XuFei, YIN Xiao. Screening of Target Genes Downstream of VviERF045, a Transcription Factor Associated with Gray Mold Resistance in Vitis vinifera [J]. Scientia Agricultura Sinica, 2025, 58(13): 2578-2590.
[7]	ZHOU Qi, ZHANG Liang, PAN Yu, TU Zhi, WANG Zheng, LIU HangHang, XIAN LingJin, XIA YunHong, PAN HongMei, LONG Xi. Effects of Cycloastragenol on Cellular Senescence of Pig Donor Fibroblast, Cytoskeletal Dynamic, and Early Developmental Stage of Nuclear Transfer Embryo [J]. Scientia Agricultura Sinica, 2025, 58(12): 2453-2474.
[8]	FENG YingMing, NONG Wei, CHEN XingYun, HAN HongXiang, ZHENG YuXin, TIAN Xiao, TANG Jiao, GUO YiWei, HUANG ChaoZheng, LI XueWen, SHI Lei, YU Min. Physiological Mechanism of Aluminum Tolerance of Rice Root Border Cells and Root Tips Induced by Nano Silica Biomineralization Deposition [J]. Scientia Agricultura Sinica, 2024, 57(24): 4871-4883.
[9]	LI Jie, LIANG ZhiLin, SUN Yan, TAN GenJia, HUAI BaoYu. Functional Analysis of SlSnRK1.2 in Regulating Tomato Resistance to Grey Mould [J]. Scientia Agricultura Sinica, 2024, 57(21): 4238-4247.
[10]	LIANG LiJuan, CHENG LiXiang, YUAN JianLong, SA Gang, ZHANG Feng. Jasmonic Acid Regulates the Changes of Major Metabolites in Potato Tuber Development in vitro [J]. Scientia Agricultura Sinica, 2024, 57(13): 2525-2538.
[11]	FAN Xin, LI YuXin, KUANG JiWei, YANG Ting, LIU MiaoMiao, CAO YunGang, HUANG JunRong. Preparation of Ultrasound-Assisted Zein Ethylene Scavenger Film and Its Preservation Property of Bananas [J]. Scientia Agricultura Sinica, 2023, 56(8): 1574-1584.
[12]	GU WenDong, LIU ChunJuan, LI Bang, LIU Chang, ZHOU YuFei. Effects of Exogenous Tryptophan on C/N Balance and Senescence Characteristics of Sorghum Seedlings Under Low Nitrogen Stress [J]. Scientia Agricultura Sinica, 2023, 56(7): 1295-1310.
[13]	ZHANG YaLin, JIANG Yan, ZHAO LiHong, FENG ZiLi, FENG HongJie, WEI Feng, ZHOU JingLong, ZHU HeQin, MA ZhiYing. Effect of Temperature on the Occurrence of Cotton Verticillium Wilt and Host Defense Response [J]. Scientia Agricultura Sinica, 2023, 56(23): 4671-4683.
[14]	XU FuChun, ZHAO JingRuo, ZHANG ZhenNan, HU GaiYuan, LONG Lu. Cloning and Functional Characterization of GhCPR5 in Disease Resistance of Gossypium hirsutum [J]. Scientia Agricultura Sinica, 2023, 56(19): 3747-3758.
[15]	SONG Ci, GU FengXu, XING ZhenZhen, ZHANG JunMing, HE WenXue, WANG TianBo, WANG YuLu, CHEN JunYing. Physiological Changes and Integrity of ATP Synthase Subunits mRNA in Naturally Aged Cotton Seeds [J]. Scientia Agricultura Sinica, 2023, 56(10): 1827-1837.

Metrics

Viewed

Full text

Abstract

Cited

Shared

Discussed

Comments

Recommended 0

No Suggested Reading articles found!

Induced etr1-1 Expression in Petunias is Responsible for Its Tolerance to Botrytis cinerea

RichHTML

PDF