柳枝稷和坚尼草的耐镉性初步研究

doi:10.11686/cyxb2014495

摘要/Abstract

摘要： 为了探究镉污染条件下开发能源植物的可行性,以高生物量黍属能源植物柳枝稷和坚尼草为材料,温室中苗期水培试验,分别对柳枝稷外源施加浓度为0, 0.5, 5, 10, 20, 50, 100 μmol/L镉(Cd),对坚尼草施加浓度为0, 2, 5, 7.5, 10 μmol/L Cd,从形态、生长生理等角度,分析两种能源草对镉的响应。结果表明:随Cd浓度的增加,柳枝稷和坚尼草生物量和根伸长量均下降,Cd浓度为50 μmol/L时,柳枝稷根鲜重减少达显著水平(P<0.05)。而坚尼草则在Cd浓度为2 μmol/L时,根和地上部分总鲜重减少达显著水平。相比于对照,Cd浓度为2 μmol/L时,坚尼草的根伸长量已下降96.3%,而柳枝稷在5 μmol/L Cd时根伸长量才降低55.0%,柳枝稷的耐镉性高于坚尼草。经20 μmol/L镉处理,柳枝稷的地上部镉浓度达40 mg/kg,生物量下降了45%。不同浓度的镉处理下,镉在柳枝稷体内的迁移指数为5.9%14.2%,柳枝稷可以在Cd污染条件下被开发为能源和修复植物种植。此外,实验还发现,在根平均直径为01 mm范围内,柳枝稷的总根长、根表面积和根体积与镉积累呈显著负相关,与迁移指数呈显著正相关(P<0.05),该结果说明,细根在植物的镉吸收积累和转运中可能起着非常重要的作用。

Abstract: It is important to evaluate the capability of heavy metal tolerance of high biomass grasses for developing bioenergy plants suited to heavily polluted environments, particularly metal pollutants, reducing the problem of bioenergy crops competing with staple food crops. Both switchgrass (Panicum virgatum) and guinea grass (P. maximum) are important bioenergy plants because of their high yield potential. These grasses were used to examine the effects of cadmium (Cd) on seedling growth under 0, 0.5, 5, 10, 20, 50, 100 μmol/L Cd for switchgrass, 0, 2, 5, 7.5, 10 μmol/L Cd for guinea grass grown using hydroponic techniques. Root and shoot fresh weights of both grasses were recorded and root morphological data of switchgrass were obtained using an EPSON scanner and WinRHIZO software. ICP-AES was used to examine Cd accumulation in switchgrass. The results showed that the biomass and root elongation of switchgrass and guinea grass were significantly affected by Cd. The root biomass of switchgrass decreased greatly under 50 μmol/L Cd conditions, but root biomass, shoot biomass, total biomass and root elongation in guinea grass were decreased by 86.1%, 83.5%, 84.1% and 96.3% respectively by the 2 μmol/L Cd treatment; root elongation in switchgrass was reduced by 55% in 5 μmol/L Cd solution. The Cd concentration in shoots of switchgrass was 40 mg/kg and the biomass was reduced by 45% in the 20 μmol/L Cd treatment. In addition, the root length and root tip numbers in switchgrass were significantly decreased in Cd treatments in comparison with the control. However, mean root diameter increased in Cd solutions. There was a significant negative correlation between root length, root surface area and root volume, and Cd accumulation and a strong positive correlation between root length, root surface area and root volume and TFs in the 0-1 mm mean root diameter class suggesting that fine roots may play an important role in Cd accumulation.

刘长浩, 娄来清, 郭涛, 骆天鹏, 蔡庆生. 柳枝稷和坚尼草的耐镉性初步研究[J]. 草业学报, 2015, 24(11): 100-117.

LIU Chang-Hao, LOU Lai-Qing, GUO Tao, LUO Tian-Peng, CAI Qing-Sheng. Preliminary research on Cd-tolerance of Panicum virgatum and Panicum maximum[J]. Acta Prataculturae Sinica, 2015, 24(11): 100-117.

参考文献

[1] Johnson P G, Riordan T P, Johnson-Cicalese J. Low-mowing tolerance in buffalograss. Crop Science, 2000, 40(5): 1339-1343.
[2] Sun G, Stewart C N J, Xiao P, et al . MicroRNA expression analysis in the cellulosic biofuel crop switchgrass ( Panicum virgatum ) under abiotic stress. Plos One, 2012, 7(3): e32017.
[3] Liu J L, Zhu W B, Xie G H, et al . The development of Panicum virgatum as an energy crop. Acta Prataculturae Sinica, 2009, 18(3): 232-240.
[4] Calles Torrez V, Johnson P J, Boe A. Infestation rates and tiller morphology effects by the switchgrass moth on six cultivars of switchgrass. BioEnergy Research, 2013, 6(2): 808-812.
[5] Lemus R, Brummer E C, Moore K J, et al . Biomass yield and quality of 20 switchgrass populations in southern Iowa, USA. Biomass and Bioenergy, 2002, 23(6): 433-442.
[6] Gunter L E, Tuskan G A, Wullschleger S D. Diversity among populations of switchgrass based on RAPD markers. Crop Science, 1996, 36(4): 1017-1022.
[7] Xu B, Sathitsuksanoh N, Tang Y, et al . Overexpression of AtLOV 1 in switchgrass alters plant architecture, lignin content, and flowering time. Plos one, 2012, 7(12): e47399.
[8] Berti M T, Johnson B L. Switchgrass establishment as affected by seeding depth and soil type. Industrial Crops and Products, 2013, 41: 289-293. doi:10.1016/j.indcrop.2012.04.023
[9] Foster J L, Guretzky J A, Huo C, et al . Effects of row spacing, seeding rate, and planting date on establishment of switchgrass. Crop Science, 2012, 53(1): 309-314.
[10] Yang J, Worley E, Wang M, et al . Natural variation for nutrient use and remobilization efficiencies in switchgrass. BioEnergy Research, 2009, 2(4): 257-266.
[11] Parrish D J, Fike J H. Selecting, establishing, and managing switchgrass ( Panicum virgatum ) for biofuels. Methods in Molecular Biology, 2009, 581: 27-40. doi:10.1007/978-1-60761-214-8_2.
[12] Missaoui A M, Fasoula V A, Bouton J H. The effect of low plant density on response to selection for biomass production in switchgrass. Euphytica, 2005, 142(1-2): 1-12.
[13] Burris Jason N, Mann David G J, Joyce Blake L, et al . An improved tissue culture system for embryogenic callus production and plant regeneration in switchgrass ( Panicum virgatum L.). BioEnergy Research, 2009, 2(4): 267-274.
[14] Ghimire S R, Charlton N D, Craven K D. The mycorrhizal fungus, Sebacina vermifera , enhances seed germination and biomass production in switchgrass ( Panicum virgatum L). BioEnergy Research, 2009, 2(1-2): 51-58.
[15] Samuel R, Pu Y, Raman B, et al . Structural characterization and comparison of switchgrass ball-milled lignin before and after dilute acid pretreatment. Applied Biochemistry and Biotechnology, 2010, 162(1): 62-74.
[16] Hong C O, Owens V N, Lee D K, et al . Switchgrass, big bluestem, and indiangrass monocultures and their two- and three-way mixtures for bioenergy in the northern great plains. BioEnergy Research, 2012, 6(1): 229-239.
[17] Lewandowski I, Scurlock J M O, Lindvall E, et al . The development and current status of perennial rhizomatous grasses as energy crops in the US and Europe. Biomass and Bioenergy, 2003, 25(4): 335-361.
[18] Hu Z H, Wang Y C, Wen Z Y. Alkali (NaOH) pretreatment of switchgrass by radio frequency-based dielectric heating. Applied Biochemistry and Biotechnology, 2008, 148(1-3): 71-81.
[19] Liu G D. Forage Floras of Hainan[M]. Beijing: Chinese Agricultural Press, 2000.
[20] Huo W, Zhuang C H, Cao Y, et al . Paclobutrazol and plant-growth promoting bacterial endophyte Pantoea sp. enhance copper tolerance of guinea grass ( Panicum maximum ) in hydroponic culture. Acta Physiologiae Plantarum, 2012, 34(1): 139-150.
[21] Xu K. Effects of light and temperature on the seed germination of Panicum maximum Jacq. and Paspalum plicatulum . Seed, 1989, (3): 43-47.
[22] Du F, Chen X, Yang C H, et al . Effect of NaCl stress on seed germination and seedling growth of different switchgrass materials. Acta Agrestia Sinica, 2011, 19(6): 1018-1024.
[23] Su Y, Liu J, Lu Z, et al . Effects of iron deficiency on subcellular distribution and chemical forms of cadmium in peanut roots in relation to its translocation. Environmental and Experimental Botany, 2014, 97: 40-48. doi:10.1016/j.envexpbot.2013.10.001
[24] Ren A Z, Gao Y B. Effects of single and combinative pollutions of lead, cadmium, chromium on the germination of Brassica chinensis L. Chinese Journal of Ecology, 2000, 19(1): 19-22.
[25] Wang K R, Gong H Q. Effects of cadmium exposures in different stages on plant growth, Cd uptake and Cd concentrations in brown rice of a hybrid and conventional rice variety. Ecology and Environment, 2006, 15(6): 1197-1203.
[26] Lux A, Martinka M, Vaculik M, et al . Root responses to cadmium in the rhizosphere: a review. Journal of Experimental Botany, 2011, 62(1): 21-37.
[27] 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.
[28] Zhang Z, Liu C, Wang X, et al . Cadmium-induced alterations in morpho-physiology of two peanut cultivars differing in cadmium accumulation. Acta Physiologiae Plantarum, 2013, 35(7): 2105-2112.
[29] Shi G R. Screening of Heavy Metal-tolerant Energy Plants and Their Adaptability to Metal Stress[D]. Nanjing: Nanjing Agricultural University, 2009.
[30] Malamy J E. Intrinsic and environmental response pathways that regulate root system architecture. Plant, Cell & Environment, 2005, 28(1): 67-77.
[31] Ding Y, Feng R, Wang R, et al . A dual effect of Se on Cd toxicity: evidence from plant growth, root morphology and responses of the antioxidative systems of paddy rice. Plant and Soil, 2014, 375(1-2): 289-301.
[32] Chen W, Zhang M M, Song Y Y, et al . Impacts of heavy metals on the fluorescence characteristics and root morphology of 2 turfgrass species. Acta Prataculturae Sinica, 2014, 23(3): 333-342.
[33] Huang B, Xin J, Dai H, et al . Root morphological responses of three hot pepper cultivars to Cd exposure and their correlations with Cd accumulation. Environmental Science and Pollution Research, 2014: 1-9. doi:10.1007/s11356-014-3405-7
[34] Potters G, Pasternak T P, Guisez Y, et al . Different stresses, similar morphogenic responses: integrating a plethora of pathways. Plant, Cell & Environment, 2009, 32(2): 158-169.
[35] Berkelaar E, Hale B. The relationship between root morphology and cadmium accumulation in seedlings of two durum wheat cultivars. Canadian Journal of Botany, 2000, 78(3): 381-387.
[36] Li T, Yang X, Lu L, et al . Effects of zinc and cadmium interactions on root morphology and metal translocation in a hyperaccumulating species under hydroponic conditions. Journal of Hazardous Materials, 2009, 169(1-3): 734-741.
[3] 刘吉利, 朱万斌, 谢光辉, 等. 能源作物柳枝稷研究进展. 草业学报, 2009, 18(3): 232-240.
[19] 刘国道. 海南饲用植物志[M]. 北京:中国农业大学出版社, 2000.
[21] 许堃. 光温对坚尼草、棕籽雀稗种子发芽的影响. 种子, 1989, (3): 43-47.
[22] 杜菲, 陈新, 杨春华, 等. NaCl胁迫对不同柳枝稷材料种子萌发与幼苗生长的影响. 草地学报, 2011, 19(6): 1018-1024.
[24] 任安芝, 高玉葆. 铅、镉、铬单一和复合污染对青菜种子萌发的生物学效应. 生态学杂志, 2000, 19(1): 19-22.
[25] 王凯荣, 龚惠群. 不同生育期镉胁迫对两种水稻的生长、镉吸收及糙米镉含量的影响. 生态环境, 2006, 15(6): 1197-1203.
[29] 史刚荣. 耐重金属胁迫的能源植物筛选及其适应性研究[D]. 南京: 南京农业大学, 2009.
[32] 陈伟, 张苗苗, 宋阳阳, 等. 重金属离子对2种草坪草荧光特性及根系形态的影响. 草业学报, 2014, 23(3): 333-342.