ULTRASTRUCTURAL LOCALIZATION AND EFFECT OF LEAD ON MINERAL ELEMENTS IN CALLUS OF ALTERNANTHERA PHILOXEROIDES

WANG Juan; ZHANG Le-Le; KANG Yi-Ning; SHI Guo-Xin

doi:10.3724/SP.J.1035.2012.00307

Volume 36 Issue 2

Mar. 2014

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ACTA HYDROBIOLOGICA SINICA > 2012 > 36(2): 307-315. > DOI: 10.3724/SP.J.1035.2012.00307

WANG Juan, ZHANG Le-Le, KANG Yi-Ning, SHI Guo-Xin. ULTRASTRUCTURAL LOCALIZATION AND EFFECT OF LEAD ON MINERAL ELEMENTS IN CALLUS OF ALTERNANTHERA PHILOXEROIDES[J]. ACTA HYDROBIOLOGICA SINICA, 2012, 36(2): 307-315. DOI: 10.3724/SP.J.1035.2012.00307

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ULTRASTRUCTURAL LOCALIZATION AND EFFECT OF LEAD ON MINERAL ELEMENTS IN CALLUS OF ALTERNANTHERA PHILOXEROIDES

Jiangsu Key Lab of Biodiversity and Biotechnology, College of Life Science, Nanjing Normal University, Nanjing 210046, China

Received Date: January 04, 2011
Rev Recd Date: November 09, 2011
Published Date: March 24, 2012

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Abstract

Heavy metal pollution of water bodies has become an increasingly serious environmental problem. Understand the principles of heavy metal contamination and heavy metals in water treatment have become a topic that must be addressed. Heavy metals can cause serious health hazards to animals and humans through the food chain due to the refractory, easy accumulation, toxicity and other characteristics. Therefore, much attention has been devoted to the studies on the mechanisms of heavy metal tolerance in plants and how to improve heavy metal tolerance of plants. Although antioxidative reactions of plants subjected to Pb2+ have been studied by several authors, there are few reports on the research of callus response to heavy metals. In view of this, callus of Alternanthera philoxeroides was cultured to overcome the uncontrollability of light, temperature, moisture and plant growth and development in the natural state, so that the experimental data is more repeated and scientific. Callus of Alternanthera philoxeroides stems was cultured in 1/2 MS medium including 6-BA (3.0 mg/L) and NAA (0.2 mg/L) after the disinfection of 70% ethanol 30s, 5% sodium hypochlorite 10min and 0.1% mercuric chloride 10min, was used as experimental material, and Pb2+ was selected as the stress factor. The toxic effects of Pb gradient concentrations (0, 0.2, 0.4, 0.8 and 1.6 mmol/L) on the accumulation, subcellular distribution, ultrastructural localization and mineral elements were studied. The results indicated that, with the increasing of Pb concentration, (1) Alternanthera philoxeroides callus was able to accumulate lead, the bioconcentration factor was 2341-2681; (2) Subcellular fraction analysis revealed that the contents of Pb increased gradually in cell wall, organelles and soluble fraction, but the distribution ratio was obviously unequal, and the Pb levels occurred in different parts of callus cell with the following sequence cell wall>organelles>soluble fraction. The toxic symptoms of callus showed an evident correlation between dose and effect and the ultrastructural damage was closely related to the distribution of Pb; (3) Ultrastructural localization observation showed that Pb mainly appeared in cell wall, and was also found in cell membrane structure and cell matrix; (4) The effects of lead on mineral elements in three subcellular fractions were different, of which the absorption of macroelements P, K, Mg and microelements Na, Zn, Mn were inhibited; the content of Ca increased at first and then decreased in cell wall, decreased gradually in organelles, increased gradually in soluble fraction; Fe and B increased at first and then decreased in subcellular fractions; the content of Cu in cell wall and organelles displayed with increase trends, increased at first and then decreased in soluble fraction; the content of Si in cell wall decreased gradually, increased at first and then decreased in organelles, while it was not able to be measured in soluble fraction. It could clearly be seen that the ion equilibrium in subcellular fractions was disrupted under Pb stress, resulting in disorder of physiological metabolism. All of these were major performance of lead on callus of Alternanthera philoxeroides.
- Callus,
- Alternanthera philoxeroides,
- Pb,
- Subcellular distribution,
- Ultrastructural localization,
- Mineral elements

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[1]	Zhao L H, Li S X, Ke B, et al. Lead pollution and phytoremediationmechanism [J]. Journal of Wuhan BioengineeringInstitute, 2006, 2(1): 43-46 [赵丽红, 李素霞, 柯滨, 等.铅污染现状及其修复机理研究进展. 武汉生物工程学院学报, 2006, 2(1): 43-46]
[2]	Yu H, Yang Z Y, Yang Z J, et al. Chemical forms and subcellularand molecular distribution of Cd in two Cd-accumulationrice genotypes [J]. Journal of Applied Ecology, 2008,19(10): 2221-2226 [于辉, 杨中艺, 杨知建, 等. 不同类型镉积累水稻细胞镉化学形态及亚细胞和分子分布. 应用生态学报, 2008, 19(10): 2221-2226]
[3]	Wan M, Zhou W, Lin B. Subcelluar and molecular distributionof cadmium in two wheat genotypes differing inshoot/root Cd partitioning [J]. Scientia Agricultura Sinica,2003, 36(6): 671-675 [万敏, 周卫, 林葆. 镉积累不同类型的小麦细胞镉的亚细胞和分子分布. 中国农业科学,2003, 36(6): 671-675]
[4]	Li D M, Zhu Z J. Cadmium subcellular distribution in plantsof Brassica campestris ssp. Chinensis L. [J]. Bulletin of Scienceand Technology, 2004, 20(4): 278-282 [李德明, 朱祝军. 镉在不同品种小白菜中的亚细胞分布. 科技通报,2004, 20(4): 278-282]
[5]	Liu J, Duan C Q, Zhang X H, et al. Subcellular distributionof chromium in accumulating plant Leersia hexandra Swartz[J]. Plant Soil, 2009, 322: 187-195
[6]	Weigel H J, J?ger H J. Subcellular distribution and chemicalform of cadmium in bean plants [J]. Plant Physiology, 1980,65: 480-482
[7]	Wu C B. Effects of different pH and heavy metal concentrationon rooting of Alternanthera philoxeroides [J]. Journal ofAnhui Agriculture Science, 2007, 35(19): 5695-5696, 5709[吴传兵. 不同pH 和重金属浓度对水花生生根的影响. 安徽农业科学, 2007, 35(19): 5695-5696, 5709]
[8]	Yuan Y, Sheng J P, Wang H D, et al. Callus induction androot differentiation from Alternanthera philoxeroides [J].Acta Hydrobiologica Sinica, 2004, 28(6): 622-628 [袁燕,生吉萍, 王捍东, 等. 水花生愈伤组织的诱导及根的分化.水生生物学报, 2004, 28(6): 622-628]
[9]	Rajarskarank M K. Endogenous growth regulators in leavesand tissue culture of Pennisetum Purpureum scuum [J]. PlantPhysiology, 1987, 130: 13-25
[10]	Xu Q S, Ji W D, Yang H Y, et al. Cadmium accumulation andphytotoxicity in an aquatic fern, Salvinia natans [J]. ActaEcologica Sinica, 2009, 29(6): 3019-3027 [徐勤松, 计汪栋, 杨海燕, 等. 镉在槐叶苹叶片中的蓄积及其生态毒理学分析. 生态学报, 2009, 29(6): 3019-3027]
[11]	Yang J R, Bao Z P, Zhang S Q. The distribution and solublecombined form of Cadmium, lead in plant cells [J]. ChinaEnvironmental Science, 1993, 13(4): 263-268 [杨居荣, 鲍子平, 张素芹. 镉、铅在植物细胞内的分布及其可溶性结合形态. 中国环境科学, 1993, 13(4): 263-268]
[12]	Jarvis M D, Leung D W M. Chelated lead transport in Pinusradiata: An ultrastructural study [J]. Environmental and ExperimentalBotany, 2002, 48: 21-32
[13]	Xu Q S, Shi G X, Wang X, et al. Subcellular localization ofPb in cells of Eichhornia crassipes Solms by electron microscopy[J]. Journal of Nanjing Normal University (NaturalScience), 2006, 29(3): 18-58 [徐勤松, 施国新, 王学, 等.铅(Pb)在凤眼莲(Eichhornia crassipes Solms)体细胞中分布的电镜观察. 南京师大学报(自然科学版), 2006, 29(3):18-58]
[14]	Allen D L, Jarrell W M. Proton and copper adsorption tomaize and soybean root cell walls [J]. Plant Physiology,1989, 89: 823-832
[15]	Rauserw E. Structure and function of metal chelators producedby plants. Cell [J]. Biochemical and Biophysical, 1999,31: 19-48
[16]	Hayens R J. Ion exchange properties of roots and ionic interactionswithin the root apoplasm: Their role in ion accumulationby plants [J]. Botanical Review, 1980, 46: 75-99
[17]	Salt D E, Princer C, Baker A J. Zinc legends in the metalhyperaccumulator Thlaspi caerulescens as determined usingX-ray absorption spectroscopy [J]. Environmental Scienceand Technology, 1999, 33: 713-717
[18]	Wang J, Shi G X, Zhang L L, et al. Response of callus of Alternanthera philoxeroides to Pb2+ stress [J]. Journal ofLake Science, 2011, 23(2): 281-286 [王娟, 施国新, 张乐乐, 等. 水花生愈伤组织对Pb2+胁迫的响应. 湖泊科学,2011, 23(2): 281-286 ]
[19]	Wang H X. Pollution Ecology [M]. Beijing: Higher EducationPress. 2000, 53-67 [王焕校. 污染生态学. 北京: 高等教育出版社 2000, 53-67]
[20]	Cai C X, Wang H M, Zhang Z M. Studies on beneficiationmechanism and speed rate of removal of five heavy metalicions by water gourd [J]. Journal of Youjiang Teachers CollegeFor Nationalities Guangxi, 2002, 15(6): 48-51 [蔡成翔, 王华敏, 张宗明. 水葫芦对五种重金属离子的去除速率与富集机制研究. 广西右江民族师专学报, 2002, 15(6):48-51]
[21]	Li R C. Effects of cadmium and lead on physiological andultrastructural features in tobacco leaves [J]. Acta PhytoecologicaSinica, 2000, 24(2): 238-242 [李荣春. Cd、Pb及其复合污染对烤烟叶片生理生化及细胞亚显微结构的影响. 植物生态学报, 2000, 24(2): 238-242]
[22]	Morales F, Abadia A, Gomez-Aparis J. Effects of combinedNaCl and CaCl2 salinity on photosynthetic parameters ofbarley grown in nutrient solution [J]. Plant Physiology, 1992,86: 419-426
[23]	Pan R C. Plant Physiology [M]. Beijing: Higher EducationPress. 2004, 30-32 [潘瑞炽. 植物生理学. 北京: 高等教育出版社. 2004, 30-32]
[24]	Xiao X Y, Liao X Y, Chen T B, et al. Subcellular distributionsof phosphorus and calcium in arsenic hyperaccumulatorPteris vittata L. and its tolerance to phytotoxicity of arsenic[J]. Acta Scientiae Circumstantiae, 2006, 26(6): 954-961[肖细元, 廖晓勇, 陈同斌, 等. 砷超富集植物蜈蚣草中磷和钙的亚细胞分布及其与耐砷毒的关系. 环境科学学报,2006, 26(6): 954-961]
[25]	Hepler P K, Wayne R O. Calcium and plant development [J].Annual Review of Plant Physiology, 1985, 36: 397-399
[26]	Wang C, Zhang S H, Wang P F, et al. The effect of excess Znon mineral nutrition and antioxidative response in rapeseedseedlings [J]. Chemosphere, 2009, 75: 1468-1476
[27]	Collier D D, Ackermann F, Somers D J, et al. The effect ofaluminum exposure on root respiration in an aluminumsensitiveand aluminum-tolerant cultivar of Triticum oestirum[J]. Plant Physiology, 1993, 87: 447-452
[28]	Zhang X N, Cui L J, Wang B P, et al. Effect of soil droughtstress on mineral nutrient contents in Larrea tridentate [J].Ecology and Environment, 2008, 17(6): 2387-2390 [张香凝, 崔令军, 王保平, 等. 土壤干旱胁迫对Larrea tridentata叶片矿质营养元素含量的影响. 生态环境, 2008,17(6): 2387-2390]

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ULTRASTRUCTURAL LOCALIZATION AND EFFECT OF LEAD ON MINERAL ELEMENTS IN CALLUS OF ALTERNANTHERA PHILOXEROIDES

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