乙烯与NO互作对镉胁迫下荷花的抗坏血酸-谷胱甘肽循环的影响

doi:10.13287/j.1001-9332.201810.033

摘要/Abstract

摘要： 以荷花‘微山湖红莲’实生苗为试验材料,研究镉(Cd,50 μmol·L^-1)胁迫下,外源乙烯前体1-氨基环丙烷羧酸(ACC,100 μmol·L^-1)、ACC与一氧化氮合酶(NOS)抑制剂N-硝基-L-精氨酸(L-NNA,200 μmol·L^-1)、ACC与硝酸还原酶(NR)抑制剂钨酸钠(Tu,1 mmol·L^-1),ACC与一氧化氮(NO)清除剂2-苯基-4,4,5,5-四甲基咪唑啉-3-氧代-1-氧(PTIO,200 μmol·L^-1),外源NO供体硝普钠(SNP,500 μmol·L^-1)、SNP与乙烯信号转导抑制剂硫代硫酸银(STS,100 μmol·L^-1)处理下荷花幼苗叶片的受害程度及抗坏血酸(AsA)-谷胱甘肽(GSH)循环的变化情况.结果表明: Cd胁迫下,荷花叶片受害症状明显,其相对电导率、丙二醛(MDA)、AsA和GSH含量显著上升,抗坏血酸过氧化物酶(APX)、谷胱甘肽还原酶(GR)、单脱氢抗坏血酸还原酶(MDHAR)和脱氢抗坏血酸还原酶(DHAR)活性明显降低;ACC的添加进一步增加了Cd对荷花叶片的毒害症状,并加剧了4种抗氧化酶活性的降低,但增加了抗氧化剂的含量;SNP的添加对荷花叶片的伤害起到加重作用,并导致GR和MDHAR活性降低以及AsA和GSH含量的升高;PTIO可显著提高Cd和ACC复合处理下荷花叶片APX、GR、MDHAR和DHAR的活性并降低AsA和GSH的含量,而L-NNA和Tu效果不如PTIO明显;STS可显著缓解Cd和SNP复合处理下荷花叶片的毒害症状,并提高4种抗氧化酶的活性、降低AsA和GSH的含量.由此说明,乙烯和NO在AsA-GSH循环中存在互作,二者相互促进,共同调控AsA-GSH循环,进而参与调控荷花对Cd胁迫的响应.

Abstract: Under the background of Cd (50 μmol·L^-1) stress, we added ethylene precursor ACC (100 μmol·L^-1), ACC + nitric oxide synthase (NOS) inhibitor L-NNA (200 μmol·L^-1), ACC + nitrate reductase (NR) inhibitor Tu (1 mmol·L^-1), ACC + nitric oxide (NO) scavenger PTIO (200 μmol·L^-1), NO donor SNP (500 μmol·L^-1), SNP + ethylene signal inhibitor STS (100 μmol·L^-1) to examine their effects on the damage degree of leaves and response mechanisms of AsA-GSH cycle in lotus ‘Weishanhuhonglian’. Results showed toxic symptom of lotus leaves under Cd stress. The relative conductivity, malondialdehyde (MDA), as well as ascorbic acid (AsA) and glutathione (GSH) contents were significantly increased, but the activities of ascorbate peroxidase (APX), glutathione reductase (GR), monodehydroascorbate reductase (MDHAR) and dehydroascorbate reductase (DHAR) were obviously decreased. Compared with Cd stress, adding ACC significantly increased the damage area of lotus leaves, decreased activities of the above-mentioned four antioxidant enzymes and increased AsA and GSH contents. SNP aggravated the toxic symptom of lotus leaves and decreased GR and MDHAR activities. PTIO significantly relieved the toxic symptom of leaves, increased activities of APX, GR, MDHAR and DHAR, but decreased AsA and GSH contents compared with Cd and ACC treatment. However, the effects of L-NNA and Tu were not as obvious as PTIO’s. In comparison with Cd and SNP treatment, STS relieved the toxic symptom of leaves, increased APX, GR, MDHAR and DHAR activities, and decreased AsA and GSH contents. Taken together, these results showed the synergistic effects of ethylene and NO in regulating lotus responses to Cd stress through AsA-GSH cycle.

袁满, 徐迎春, 牛叶青, 周慧, 安奕霖, 金奇江, 王彦杰. 乙烯与NO互作对镉胁迫下荷花的抗坏血酸-谷胱甘肽循环的影响[J]. 应用生态学报, 2018, 29(10): 3433-3440.

YUAN Man, XU Ying-chun, NIU Ye-qing, ZHOU Hui, AN Yi-lin, JIN Qi-jiang, WANG Yan-jie. Effects of ethylene and NO on AsA-GSH in lotus under cadmium stress[J]. Chinese Journal of Applied Ecology, 2018, 29(10): 3433-3440.

参考文献

[1] Alloway BJ. Sources of Heavy Metals and Metalloids in Soils. Heidelberg, Germany: Springer, 2013
[2] Cuypers A, Smeets K, Vangronsveld J. Heavy Metal Stress in Plants. Weinheim: Wiley-VCH Verlag Press, 2009
[3] Ali H, Khan E, Sajad MA. Phytoremediation of heavy metals: Concepts and applications. Chemosphere, 2013, 91: 869-881
[4] Shi X-L (施雪黎). Study on Cd and Pb Accumulation in Aquatic and Wetlan Plants. Masters Thesis. Hangzhou: Zhejiang University, 2016 (in Chinese)
[5] Schützendübel A, Polle A. Plant responses to abiotic stresses: Heavy metal-induced oxidative stress and protection by mycorrhization. Journal of Experimental Botany, 2002, 53: 1351-1365
[6] Kong D-Z (孔德政), Pei K-K (裴康康), Li Y-H (李永华), et al. Effect of Cd, Zn and Pb stresses on phy-siology and biochemistry of lotus. Journal of Henan Agricultural University (河南农业大学学报), 2010, 44(4): 402-407 (in Chinese)
[7] Yang H (杨微), Wang H-Y (王红艳), Yu K-Y (于开源), et al. Effects of elevated Cd, Zn and their combined effects on antioxidant system of tobacco. Chinese Journal of Applied Ecology (应用生态学报), 2017, 28(6): 1948-1954 (in Chinese)
[8] Cobbett CS. Phytochelatins and their roles in heavy metal detoxification. Plant Physiology, 2000, 123: 825-832
[9] Keunen E, Schellingen K, Vangronsveld J, et al. Ethy-lene and metal stress: Small molecule, big impact. Frontiers in Plant Science, 2016, 7:23-29
[10] Yakimova ET, Kapchina-Toteva VM, Laarhoven LJ, et al. Involvement of ethylene and lipid signalling in cadmium-induced programmed cell death in tomato suspension cells. Plant Physiology & Biochemistry, 2006, 44: 581-589
[11] Schellingen K, Straeten D, Vandenbussche F, et al. Cadmium-induced ethylene production and responses in Arabidopsis thaliana rely on ACS2 and ACS6 gene expression. BMC Plant Biology, 2014, 14: 214-227
[12] Chen HJ, Huang CS, Huang GJ, et al. NADPH oxidase inhibitor diphenyleneiodonium and reduced glutathione mitigate ethephon-mediated leaf senescence, H₂O₂, elevation and senescence-associated gene expression in sweet potato (Ipomoea batatas). Journal of Plant Physio-logy, 2013, 170: 1471-1483
[13] Wang J-J (王嘉佳). Research on Regulation of Cadmium Accumulation and Transport by Ethylene in Arabidopsis under Cadmium Stress. Master Thesis. Harbin: Northeast Forestry University, 2014 (in Chinese)
[14] Masood A, Iqbal N, Khan NA. Role of ethylene in alleviation of cadmium-induced photosynthetic capacity inhibition by sulphur in mustard. Plant, Cell & Environment, 2012, 35: 524-533
[15] Iakimova ET, Woltering EJ, Kapchinatoteva VM, et al. Cadmium toxicity in cultured tomato cells: Role of ethy-lene, proteases and oxidative stress in cell death signaling. Cell Biology International, 2008, 32: 1521-1529
[16] Liu Y-L (刘玲玉). The Molecular Mechanism of Cd-induced Ethylene Production and Its Role in Cd Response in Arabidopsis. Master Thesis. Hangzhou: Zhejiang University, 2016 (in Chinese)
[17] Schellingen K, Van D, Remans T, et al. Ethylene signalling is mediating the early cadmium-induced oxidative challenge in Arabidopsis thaliana. Plant Science, 2015, 239:137-146
[18] Zhang R-R (张然然), Zhang P (张鹏), Du S-T (都韶婷). Oxidative stress-related signals and their regulation under Cd stress: A review. Chinese Journal of Applied Ecology (应用生态学报), 2016, 27(3): 981-992 (in Chinese)
[19] Xia H-W (夏海威), Shi G-X (施国兴), Huang M (黄敏), et al. Advances on effects of nitric oxide on resistances of plants to heavy metal stress. Acta Ecologica Sinica (生态学报), 2015, 35(10): 3139-3147 (in Chinese)
[20] Yang L-M (杨丽明), He R-R (何瑞荣). Effects of L-NNA and NO donors on spontaneous activity of rostral ventrolateral medulla neurons. Acta Physiologica Sinica (生理学报), 1996, 48(4): 320-328 (in Chinese)
[21] Zhou W-H (周万海), Feng R-Z (冯瑞章), Shi S-L (师尚礼), et al. Nitric oxide protection of alfalfa seedling roots against salt-induced inhibition of growth and oxidative damage. Acta Ecologica Sinica (生态学报), 2015, 35(11): 3606-3614 (in Chinese)
[22] Bao A-M (包敖民), Liu Y (刘艳), Ma H (马慧), et al. Effects of nitric oxide on wounding induction of pea seedling leaves antioxidant system. Chinese Agricultural Science Bulletin (中国农学通报), 2015, 31(25): 60-65 (in Chinese)
[23] Qiu ZB, Guo JL, Zhang MM, et al. Nitric oxide acts as a signal molecule in microwave pretreatment induced cadmium tolerance in wheat seedlings. Acta Physiologiae Plantarum, 2013, 35: 65-73
[24] Małgorzata K, Magdalena S, Edward A. Effects of exoge-nous nitric oxide on the antioxidant capacity of cadmium-treated soybean cell suspension. Acta Physiologiae Plantarum, 2006: 28: 525-536
[25] Ye Y, Li Z, Xing D. Nitric oxide promotes MPK6-media-ted caspase-3-like activation in cadmium-induced Arabidopsis thaliana programmed cell death. Plant, Cell & Environment, 2012, 36: 1-15
[26] Ma W, Xu W, Xu H, et al. Nitric oxide modulates cadmium influx during cadmium-induced programmed cell death in tobacco BY-2 cells. Planta, 2010, 232: 325-335
[27] Panda P, Nath S, Chanu T, et al. Cadmium stress-induced oxidative stress and role of nitric oxide in rice (Oryza sativa L.). Acta Physiologiae Plantarum, 2011, 33: 1737-1747
[28] Ma X-L (马晓丽), Ji R-P (冀瑞萍), Tian B-H (田保华), et al. Effects of nitric oxide on oxidative damage metabolism in wheat seedling under Cadmium stress. Biotechnology Bulletin (生物技术通报), 2017, 33(5): 102-107 (in Chinese)
[29] Wang YB, Feng HY, Qu Y, et al. The relationship between reactive oxygen species and nitric oxide in ultraviolet-B-induced ethylene production in leaves of maize seedlings. Environmental and Experimental Botany, 2006, 57: 51-61
[30] Cui H-W (崔华威), Yang Y-L (杨艳丽), Li J-T (黎敬涛), et al. A fast method for measuring relative lesion area on leaves based on software photoshop. Journal of Anhui Agricultural Sciences (安徽农业科学),2009, 37(22): 10760-10762 (in Chinese)
[31] Blum A, Ebercon A. Genotypic responses in sorghum to drought stress. III. Free proline accumulation and drought resistance. Crop Science, 1976, 16: 428-431
[32] Kumar GNM, Knowles NR. Changes in lipid peroxidation and lipolytic and free-radical scavenging enzyme activities during aging and sprouting of potato (Solanum tuberosum) seed-tubers. Plant Physiology, 1993, 102: 115-124
[33] Nakano Y, Asada K. Hydrogen peroxide is scavenged by ascorbate-specific peroxidase in spinach chloroplasts. Plant & Cell Physiology, 1981, 22: 867-880
[34] Zhu H, Cao Z, Zhang L, et al. Glutathione and glutathione-linked enzymes in normal human aortic smooth muscle cells: Chemical inducibility and protection against reactive oxygen and nitrogen species-induced injury. Molecular & Cellular Biochemistry, 2007, 301: 47-59
[35] Erkan M, Wang SY, Wang CY. Effect of UV treatment on antioxidant capacity, antioxidant enzyme activity and decay in strawberry fruit. Postharvest Biology & Techno-logy, 2008, 48: 163-171
[36] Yoshida S, Tamaoki M, Shikano T, et al. Cytosolic dehydroascorbate reductase is important for ozone tolerance in Arabidopsis thaliana. Plant & Cell Physiology, 2006, 47: 304-308
[37] Bailly C, Kranner I. Analyses of reactive oxygen species and antioxidants in relation to seed longevity and germination. Methods in Molecular Biology, 2011, 773: 343-367
[38] Suzuki N, Miller G, Morales J, et al. Respiratory burst oxidases: The engines of ROS signaling. Current Opinion in Plant Biology, 2011, 14: 691-699
[39] Hasanuzzaman M, Nahar K, Anee TI, et al. Exogenous silicon attenuates cadmium-induced oxidative stress in Brassica napus L. by modulating AsA-GSH pathway and glyoxalase system. Frontiers in Plant Science, 2017, 8: 1061-1068
[40] Wang D-F (王达菲). The Effects and Mechanisms of Exogenous Nitric Oxide on the Tolernce agaist Cadmium in Boehmeria nivea (L.) Gaud. Master Thesis. Changsha: Hunan University, 2015 (in Chinese)
[41] Rodríguez-Serrano M, Romero-Puertas MC, Zabalza A, et al. Cadmium effect on oxidative metabolism of pea (Pisum sativum L.) roots. Imaging of reactive oxygen species and nitric oxide accumulation in vivo. Plant, Cell & Environment, 2010, 29: 1532-1544
[42] Gallego SM, Benavídes MP, Tomaro ML. Effect of heavy metal ion excess on sunflower leaves: Evidence for involvement of oxidative stress. Plant Science, 1996, 121: 151-159
[43] Nehnevajova E, Lyubenova L, Herzig R, et al. Metal accumulation and response of antioxidant enzymes in seedlings and adult sunflower mutants with improved metal removal traits on a metal-contaminated soil. Environmental & Experimental Botany, 2012, 76: 39-48
[44] Zhang Z, Wang J, Zhang R, et al. The ethylene response factor AtERF98 enhances tolerance to salt through the transcriptional activation of ascorbic acid synthesis in Arabidopsis. Plant Journal for Cell & Mole-cular Biology, 2012, 71: 273-287
[45] Chmielowska-Bąk J, Gzyl J, Rucińska-Sobkowiak R, et al. The new insights into cadmium sensing. Frontiers in Plant Science, 2014, 5: 245-258
[46] Yi TH, Kao CH. Cadmium toxicity is reduced by nitric oxide in rice leaves. Plant Growth Regulation, 2004, 42: 227-238