镉胁迫对紫花苜蓿镉吸收特征及根系形态影响

doi:10.11686/cyxb2015401

摘要/Abstract

摘要： 采用盆栽模拟方法,研究了4种镉(Cd)浓度(0,10,25,50 mg/kg)下紫花苜蓿对Cd吸收特征及根系形态的变化特征。结果发现,随着镉胁迫加剧,紫花苜蓿地上生物量、根系生物量、根系总长度、根平均直径、根表面积、根系体积、根尖数和分枝数均显著下降(P<0.05),地上部生物量分别为对照的87.8%,56.5%,14.3%,根系生物量分别为96.1%,63.3%,16.2%;不同部位镉吸收量表现为细根>地上部>粗根,三者均随着处理浓度增加而显著提高,细根镉含量与地上部镉含量呈显著正相关;地上部最高镉积累量出现在25 mg/kg处理中,达到7.715 μg/株;不同径级根系的总根长、根表面积、根体积随镉浓度增加呈下降趋势,根径<0.5 mm根系占总根系比例呈增加趋势。研究表明,紫花苜蓿可用于低Cd污染场地的植被恢复,其根系对Cd胁迫的响应特征呈现侧根产生—根受损的动态平衡现象。

Abstract: This study used pot experiments to investigate the cadmium (Cd) uptake potential of alfalfa (Medicago sativa) and to explore the possible mechanisms involved in root adaptation under various levels of cadmium stress (0, 10, 25, 50 mg/kg). Alfalfa shoot biomass, root biomass, total root length, root surface-area, root volume, average root diameter and root number were all significantly smaller under the three Cd stress treatments than in the normal Cd condition (P<0.05). Shoot biomass was 87.8%, 56.5% and 14.3%, and root biomass was 96.1%, 63.3% and 16.2% respectively. The highest Cd content was observed in fine roots (root diameter below 1.0 mm) and the Cd content in shoots was higher than that in roots with diameters above 1.0 mm. The Cd content in three parts (shoot, fine root, coarse root) increased significantly with increasing Cd exposure. The highest Cd accumulation was recorded in shoots (7.715 μg/plant) at a concentration of 25 mg/kg Cd. Compared to the control, root length, root surface-area and the root volume of different diameter classes decreased significantly with increases in Cd concentration, except for the proportion of roots with diameters below 0.5 mm, which increased. It can be concluded that alfalfa is suitable for remediation of Cd polluted soil when Cd concentrations are less than 25 mg/kg and the response characteristics of root systems to Cd show dynamic equilibrium.

李希铭, 宋桂龙. 镉胁迫对紫花苜蓿镉吸收特征及根系形态影响[J]. 草业学报, 2016, 25(2): 178-186.

LI Xi-Ming, SONG Gui-Long. Cadmium uptake and root morphological changes in Medicago sativa under cadmium stress[J]. Acta Prataculturae Sinica, 2016, 25(2): 178-186.

参考文献

[1] Wagner G J. Accumulation of cadmium in crop plants and its consequences to human health. Advances in Agronomy, 1993, 51: 173-212.
[2] Ministry of Environmental Protection of PRC, Ministry of Land and Resources of PRC. National survey of soil pollution[N]. China Land Resources Journal, 2014-04-18(02).
[3] Conesa H M, Evangelou M W H, Robinson B H, et al . A critical view of current state of phytotechnologies to remediate soils: still a promising tool. The Scientific World Journal, 2012, 1: 1-10.
[4] Wu Q, Gao Y J, Li D M, et al . Phytoremediation of heavy metal pollution in river sediment by Medicago sativa L. Journal of Anhui Agricultural Sciences, 2011, 39(28): 17376-17378.
[5] Yang J, Li H J, Zhang N, et al . Effects of three kinds of leguminous plants on remedying heavy metals of soil abandoned coal mine. Hubei Agricultural Sciences, 2014, 53(9): 2025-2028.
[6] Mei L N, Yuan Q H, Yao T, et al . Effects of cadmium stress on some physiological biochemical characters of four alfalfa varieties. Chinese Journal of Grassland, 2010, 32(3): 21-27.
[7] Xu S L, Xing C H, Fang Y. The effect of cadmium stress on growth and Cd content of alfalfa. Guangdong Trace Elements Science, 2008, 15(3): 23-26.
[8] Marques A P, Rangel A O, Castro P M. Remediation of heavy metal contaminated soils: phytoremediation as a potentially promising clean-up technology. Critical Reviews in Environmental Science and Technology, 2009, 39(8): 622-654.
[9] Potters G, Pasternak T P, Guisez Y, et al . Stress-induced morphogenic responses: growing out of trouble. Trends in Plant Science, 2007, 12(3): 98-105.
[10] Lu Z, Zhang Z, Su Y, et al . Cultivar variation in morphological response of peanut roots to cadmium stress and its relation to cadmium accumulation. Ecotoxicology and Environmental Safety, 2013, 91: 147-155.
[11] Shi G, Xia S, Ye J, et al . PEG-simulated drought stress decreases cadmium accumulation in castor bean by altering root morphology. Environmental and Experimental Botany, 2015, 111: 127-134.
[12] Bochicchio R, Sofo A, Terzano R, et al . Root architecture and morphometric analysis of Arabidopsis thaliana grown in Cd/Cu/Zn-gradient agar dishes: A new screening technique for studying plant response to metals. Plant Physiology and Biochemistry, 2015, 91: 20-27.
[13] Najeeb U, Jilani G, Ali S, et al . Insights into cadmium induced physiological and ultra-structural disorders in Juncus effusus L. and its remediation through exogenous citric acid. Journal of Hazardous Materials, 2011, 186(1): 565-574.
[14] Green J J, Baddeley J A, Cortina J, et al . Root development in the mediterranean shrub Pistacia lentiscus as affected by nursery treatments. Journal of Arid Environments, 2005, 61(1): 1-12.
[15] Johnson L D, Marquez-Ortiz J J, Lamb J, et al . Root morphology of alfalfa plant introductions and cultivars. Crop Science, 1998, 38(2): 497-502.
[16] Yang Y H, Zhang C R, Xia L J, et al . Effect of cadmium and zinc pollutions of alfalfa quality and cadmium content. Acta Agriculture Boreali-Sinica, 2008, 23: 363-366.
[17] Yang F, Wang H. Experimental study on phytoremediation of heavy metal contaminated soil. China New Technologies and Products, 2013, 24: 180-181.
[18] Pan C, Teng Y, Luo Y M, et al . Effects of Medicago sativa , Elsholtzia splendens and Sedum plumbizincicola remedying soils contaminated with both polychlorinated biphenyls and heavy metals. Acta Pedologica Sinica, 2012, 49(5): 1062-1067.
[19] Wei S H, Zhou Q X, Wang X, et al . A new discovery of cadmium hyperaccumulator- Solanum nigrum L. Chinese Science Bulletin, 2004, 49(24): 2568-2573.
[20] Liu W, Shu W S, Lan C Y. A new discovery of cadmium hyperaccumulator- Viola baoshanensis . Chinese Science Bulletin, 2003, 48(19): 2046-2049.
[21] Wang S F, Shi X, Sun H J, et al . Metal uptake and root morphological changes for two varieties of Salix integra under cadmium stress. Acta Ecologica Sinica, 2013, 33(19): 6065-6073.
[22] Zhou M M, Pan Z H, Chen D D, et al . The influences of different vegetation ecosystems on heavy metals in soil in semi-arid region. Spectroscopy and Spectral Analysis, 2010, 30(10): 2789-2792.
[23] Arduini I, Masoni A, Mariotti M, et al . Low cadmium application increase Miscanthus growth and cadmium translocation. Environmental and Experimental Botany, 2004, 52(2): 89-100.
[24] Kubo K, Watanabe Y, Matsunaka H, et al . Differences in cadmium accumulation and root morphology in seedlings of Japanese wheat varieties with distinctive grain cadmium concentration. Plant Production Science, 2011, 14(2): 148-155.
[25] Xiong J, Lu H, Lu K, et al . Cadmium decreases crown root number by decreasing endogenous nitric oxide, which is indispensable for crown root primordia initiation in rice seedlings. Planta, 2009, 230(4): 599-610.
[26] Luná C ˙ ková L, Aottníková A, Masarovi C ˙ ová E, et al . Comparison of cadmium effect on willow and poplar in response to different cultivation conditions. Biologia Plantarum, 2003, 47(3): 403-411.
[27] Maksimoviĉ I, Kastori R, Krstiĉ L, et al . Steady presence of cadmium and nickel affects root anatomy, accumulation and distribution of essential ions in maize seedlings. Biologia Plantarum, 2007, 51(3): 589-592.
[28] Lu Z W. Physiological Mechanisms of the Absorption and Translocation of Cadmium in Peanut Plants[D]. Huaibei: Huaibei Normal University, 2014.
[29] Cai L P, Wu P F, Hou X L, et al . Morphological response to different drought stress in the roots of Neyraudia reynaudiana . Chinese Agriculture Science Bulletin, 2012, 28(28): 44-48.
[30] Tian X F, Wei H, Jia Z M, et al . Effects of cadmium on growth and root’s forms of Firmia naplatanifolia seedlings. Journal of Southwest China Normal University (Natural Science Edition), 2008, 33(2): 93-98.
[31] Li J G, Zhu E, Li T Q, et al . Effects of nitrogen fertilizer on biomass, root morphology and Cd accumulation of Cd-stressed Sedumalfredii hance species. Environmental Pollution and Control, 2007, 29: 271-275.
[32] Bayuelo-Jiménez J S, Gallardo-Valdéz M, Pérez-Decelis V A, et al . Genotypic variation for root traits of maize ( Zea mays L.) from the Purhepecha plateau under contrasting phosphorus availability. Field Crops Research, 2011, 121(3): 350-362.
[33] Li Z Y, Fan X Y, Tang S R, et al . Effects of elevated CO 2 on the Cd uptake and root morphology of different rice varieties under cadmium stress. Chinese Journal of Applied Ecology, 2012, 4: 1063-1069.
[34] Ren A T, Lu W H, Yang J J, et al . Seasonal change patterns in the production and mortality of fine roots in cotton and alfalfa. Acta Prataculturae Sinica, 2015, 24(6): 213-219.
[35] Dr?zkiewicz M, Tukendorf A, Baszyński T. Age-dependent response of maize leaf segments to cadmium treatment: effect on chlorophyll fluorescence and phytochelatin accumulation. Journal of Plant Physiology, 2003, 160: 247-254.
[2] 环境保护部, 国土资源部. 全国土壤污染状况调查公报[N]. 中国国土资源报, 2014-04-18(02).
[4] 吴卿, 高亚洁, 李东梅, 等. 紫花苜蓿对重金属污染河道底泥的修复能力研究. 安徽农业科学, 2011, 39(28): 17376-17378.
[5] 汤洁, 李华娟, 张楠, 等. 三种牧草对煤矿废弃地土壤重金属的修复效应. 湖北农业科学, 2014, 53(9): 2025-2028.
[6] 梅丽娜, 袁庆华, 姚拓, 等. 镉胁迫对四个苜蓿品种生理特性的影响. 中国草地学报, 2010, 32(3): 21-27.
[7] 徐苏凌, 邢承华, 方勇. 镉胁迫对紫花苜蓿生长及植株镉含量的影响. 广东微量元素科学, 2008, 15(3): 23-26.
[16] 杨玉惠, 张春荣, 夏立江, 等. 镉锌污染对紫花苜蓿体内镉含量及品质的影响. 华北农学报, 2008, 23: 363-366.
[17] 杨帆, 王辉. 重金属污染土壤植物修复效果试验研究. 中国新技术新产品, 2013, 24: 180-181.
[18] 潘澄, 滕应, 骆永明, 等. 紫花苜蓿、海州香薷及伴矿景天对多氯联苯与重金属复合污染土壤的修复作用. 土壤学报, 2012, 49(5): 1062-1067.
[19] 魏树和, 周启星, 王新, 等. 一种新发现的镉超积累植物龙葵. 科学通报, 2004, 49(24): 2568-2573.
[20] 刘威, 束文圣, 蓝崇钰. 宝山堇菜——一种新的镉超富集植物. 科学通报, 2003, 48(19): 2046-2049.
[21] 王树凤, 施翔, 孙海菁, 等. 镉胁迫下杞柳对金属元素的吸收及其根系形态构型特征. 生态学报, 2013, 33(19): 6065-6073.
[22] 周蒙蒙, 潘志华, 陈东东, 等. 半干旱地区不同植被生态体系对土壤重金属含量的影响. 光谱学与光谱分析, 2010, 30(10): 2789-2792.
[28] 陆紫微. 花生吸收和转运镉的生理机制[D]. 淮北: 淮北师范大学, 2014.
[29] 蔡丽平, 吴鹏飞, 侯晓龙, 等. 类芦根系对不同强度干旱胁迫的形态学响应. 中国农学通报, 2012, 28(28): 44-48.
[30] 田晓锋, 魏虹, 贾中民, 等. 重金属镉(Cd 2+ )对梧桐幼苗根生长及根系形态的影响. 西南师范大学学报(自然科学版), 2008, 33(2): 93-98.
[33] 李中阳, 樊向阳, 唐世荣, 等. CO 2 浓度升高对不同品种水稻镉吸收和根形态的影响. 应用生态学报, 2012, 4: 1063-1069.
[34] 任爱天, 鲁为华, 杨洁晶, 等. 棉花、苜蓿根生长和死亡的季节变化. 草业学报, 2015, 24(6): 213-219.