整合生物学期刊网

Plant Diversity >

2018 , Vol. 40 >Issue 01: 19 - 27

DOI: https://doi.org/10.1016/j.pld.2017.12.005

Articles

Physiological and biochemical analysis of mechanisms underlying cadmium tolerance and accumulation in turnip

  • Xiong Li ,
  • Xiaoming Zhang ,
  • Yuansheng Wu ,
  • Boqun Li ,
  • Yongping Yang
展开
  • a Key Laboratory for Plant Diversity and Biogeography of East Asia, Kunming Institute of Botany, Chinese Academy of Sciences, Kunming, China;
    b China Germplasm Bank of Wild Species, Kunming Institute of Botany, Chinese Academy of Sciences, Kunming, China;
    c University of Chinese Academy of Sciences, Beijing, China;
    d College of Plant Protection, Yunnan Agricultural University, Kunming, China

收稿日期: 2017-06-04

  修回日期: 2017-12-27

  网络出版日期: 2021-11-05

基金资助

This work was financially supported by the Western Youth Project B of the "Light of West China" Program of Chinese Academy of Sciences (Y7260411W1) and the National Natural Science Foundation of China (31590823).

收起

Physiological and biochemical analysis of mechanisms underlying cadmium tolerance and accumulation in turnip

  • Xiong Li ,
  • Xiaoming Zhang ,
  • Yuansheng Wu ,
  • Boqun Li ,
  • Yongping Yang
Expand
  • a Key Laboratory for Plant Diversity and Biogeography of East Asia, Kunming Institute of Botany, Chinese Academy of Sciences, Kunming, China;
    b China Germplasm Bank of Wild Species, Kunming Institute of Botany, Chinese Academy of Sciences, Kunming, China;
    c University of Chinese Academy of Sciences, Beijing, China;
    d College of Plant Protection, Yunnan Agricultural University, Kunming, China

Received date: 2017-06-04

  Revised date: 2017-12-27

  Online published: 2021-11-05

Supported by

This work was financially supported by the Western Youth Project B of the "Light of West China" Program of Chinese Academy of Sciences (Y7260411W1) and the National Natural Science Foundation of China (31590823).

Fold

摘要

The capacity of plants to accumulate cadmium (Cd) is significant for phytoremediation of Cd-polluted soils. Turnips cultivated in China include species featuring high Cd accumulation and some of these plants act as Cd hyperaccumulator landraces. These plants can accumulate over 100 mg Cd kg-1 dry weight in leaves without injury. Hence, studies that explore mechanisms underlying Cd detoxification and transport in turnip plants are essential. In the present study, we compared physiological and biochemical changes in turnip leaves treated with two Cd concentrations to controls. We discovered that Cd stress significantly increased the enzymatic activities or compound contents in the antioxidant system, including members of the glutathione-ascorbic acid cycle, whereas oxidation of reactive oxygen species (ROS) remained stable. Cd treatments also increased the contents of phytochelatins as well as a number of amino acids. Based on these results, we conclude that turnips initiate a series of response processes to manage Cd treatment. First, the antioxidant system maintaining ROS homeostasis and osmotic adjustment is excited to maintain stability of cell osmotic potential. Cd is chelated into its stable form to reduce its toxicity. Cd is possibly transported to vacuoles or non-protoplasts for isolation. Amino acid synthesis may directly and indirectly play an important role in these processes. This study partly revealed physiological and biochemical mechanisms underlying turnip response to Cd stress and provides information on artificially increasing or decreasing Cd accumulation in turnips and other plants.

关键词: Turnip; Cadmium; Detoxification; Antioxidant system; Phytochelatin

本文引用格式

Xiong Li , Xiaoming Zhang , Yuansheng Wu , Boqun Li , Yongping Yang . Physiological and biochemical analysis of mechanisms underlying cadmium tolerance and accumulation in turnip[J]. Plant Diversity, 2018 , 40(01) : 19 -27 . DOI: 10.1016/j.pld.2017.12.005

Abstract

The capacity of plants to accumulate cadmium (Cd) is significant for phytoremediation of Cd-polluted soils. Turnips cultivated in China include species featuring high Cd accumulation and some of these plants act as Cd hyperaccumulator landraces. These plants can accumulate over 100 mg Cd kg-1 dry weight in leaves without injury. Hence, studies that explore mechanisms underlying Cd detoxification and transport in turnip plants are essential. In the present study, we compared physiological and biochemical changes in turnip leaves treated with two Cd concentrations to controls. We discovered that Cd stress significantly increased the enzymatic activities or compound contents in the antioxidant system, including members of the glutathione-ascorbic acid cycle, whereas oxidation of reactive oxygen species (ROS) remained stable. Cd treatments also increased the contents of phytochelatins as well as a number of amino acids. Based on these results, we conclude that turnips initiate a series of response processes to manage Cd treatment. First, the antioxidant system maintaining ROS homeostasis and osmotic adjustment is excited to maintain stability of cell osmotic potential. Cd is chelated into its stable form to reduce its toxicity. Cd is possibly transported to vacuoles or non-protoplasts for isolation. Amino acid synthesis may directly and indirectly play an important role in these processes. This study partly revealed physiological and biochemical mechanisms underlying turnip response to Cd stress and provides information on artificially increasing or decreasing Cd accumulation in turnips and other plants.

Key words: Turnip; Cadmium; Detoxification; Antioxidant system; Phytochelatin

参考文献

Alia, Mohanty, P., Matysik, J., 2001. Effect of proline on the production of singlet oxygen. Amino Acids 21, 195-200.
Anjum, S.A., Tanveer, M., Hussain, S., Shahzad, B., Ashraf, U., Fahad, S., Hassan, W., Jan, S., Khan, I., Saleem, M.F., Bajwa, A.A., Wang, L.C., Mahmood, A., Samad, R.A., Tung, S.A., 2016. Osmoregulation and antioxidant production in maize under combined cadmium and arsenic stress. Environ. Sci. Pollut. Res. 23, 11864-11875.
Assuncao, A.G.L., Schat, H., Aarts, M.G.M., 2003. Thlaspi caerulescens, an attractive model species to study heavy metal hyperaccumulation in plants. New Phytol. 159, 351-360.
Belcastro, M., Marino, T., Russo, N., Toscano, M., 2009. The role of glutathione in cadmium ion detoxification:coordination modes and binding properties-a density functional study. J. Inorg. Biochem. 103, 50-57.
Bottari, E., Festa, M.R., 1996. Asparagine as a ligand for cadmium (Ⅱ), lead (Ⅱ) and zinc (Ⅱ). Chem. Speciat. Bioavailab. 8, 75-83.
Cai, B.S., Lei, M., Chen, T.B., Zhang, G.P., Chen, Y., 2003. Phytochelatins and their roles in phyto-tolerance to heavy metals:a review. Acta Ecol. Sin. 23, 2125-2132.
Che, J., Yamaji, N., Shao, J.F., Ma, J.F., Shen, R.F., 2016. Silicon decreases both uptake and root-to-shoot translocation of manganese in rice. J. Exp. Bot. 67, 1535-1544.
Chen, H., Jiang, J.G., 2010. Osmotic adjustment and plant adaptation to environmental changes related to drought and salinity. Environ. Rev. 18, 309-319.
Choppala, G., Saifullah, Bolan, N., Bibi, S., Iqbal, M., Rengel, Z., Kunhikrishnan, A., Ashwath, N., Ok, Y.S., 2014. Cellular mechanisms in higher plants governing tolerance to cadmium toxicity. Crit. Rev. Plant Sci. 33, 374-391.
D'alessandro, A., Taamalli, M., Gevi, F., Timperio, A.M., Zolla, L., Ghnaya, T., 2013.Cadmium stress responses in Brassica juncea:hints from proteomics and metabolomics. J. Proteome Res. 12, 4979-4997.
Ehsan, S., Ali, S., Noureen, S., Mahmood, K., Farid, M., Ishaque, W., Shakoor, M.B., Rizwan, M., 2014. Citric acid assisted phytoremediation of cadmium by Brassica napus L. Ecotoxicol. Environ. Saf 106, 164-172.
Ellman, G.L., 1959. Tissue sulfhydryl groups. Arch. Biochem. Biophys. 82, 70-77.
Fang, X.Z., Zhu, Z.J., Sun, G.W., 2004. Effects of different concentrations of cadmium on growth and antioxidant system in Brassica campestris ssp. Chinese. J. Agro Environ. Sci. 23, 877-880.
Fediuc, E., Erdei, L., 2002. Physiological and biochemical aspects of cadmium toxicity and protective mechanisms induced in Phragmites australis and Typha latifolia. J. Plant Physiol. 159, 265-271.
Gao, C.Q., Wang, C., Zheng, L., Wang, L.Q., Wang, Y.C., 2012. A LEA gene regulates cadmium tolerance by mediating physiological responses. Int. J. Mol. Sci. 13, 5468-5481.
Grill, E., Winnacker, E.L., Zenk, M.H., 1985. Phytochelatins-the principal heavymetal complexing peptides of higher-plants. Science 230, 674-676.
Grill, E., Loffler, S., Winnacker, E.L., Zenk, M.H., 1989. Phytochelatins, the heavymetal-binding peptides of plants, are synthesized from glutathione by a specific gamma-glutamylcysteine dipeptidyl transpeptidase (phytochelatin synthase). Proc. Natl. Acad. Sci. U.S.A. 86, 6838-6842.
Gulli, M., Rampino, P., Lupotto, E., Marmiroli, N., Perrotta, C., 2005. The effect of heat stress and cadmium ions on the expression of a small hsp gene in barley and maize. J. Cereal. Sci. 42, 25-31.
Hasanuzzaman, M., Nahar, K., Gill, S.S., Alharby, H.F., Razafindrabe, B.H.N., Fujita, M., 2017. Hydrogen peroxide pretreatment mitigates cadmium-induced oxidative stress in Brassica napus L.:an intrinsic study on antioxidant defense and glyoxalase systems. Front. Plant Sci. 8, 115. https://doi.org/10.3389/fpls.2017.00115.
He, Q.X., 2013. Research progress of screening cadmium hyperaccumulators. Environ. Protect. Circular Econ. 33, 46-49.
Hu, Y.L., Zhang, C.H., Ju, T., Ge, Y., 2009. Differential responses of GSH and GST in two rice cultivars under Cd stress. J. Agro-Environ. Sci. 28, 305-310.
Jiang, D.L., Cai, H., Duanmu, H.Z., Zhu, Y.M., 2013. Genome-wide filter, classification and expression analysis of GST gene family in soybean. Mol. Plant Breed. 11, 465-475.
Kerkeb, L., Kramer, U., 2003. The role of free histidine in xylem loading of nickel in Alyssum lesbiacum and Brassica juncea. Plant Physiol. 131, 716-724.
Kneer, R., Zenk, M.H., 1992. Phytochelatins protect plant enzymes from heavy-metal poisoning. Phytochemistry 31, 2663-2667.
Kostaropoulos, I., Kalmanti, D., Theodoropoulou, B., Loumbourdis, N., 2005. Effects of exposure to a mixture of cadmium and chromium on detoxification enzyme(GST, P450-MO) activities in the frog Rana ridibunda. Ecotoxicology 14, 439-447.
Kozhevnikova, A.D., Seregin, I.V., Erlikh, N.T., Shevyreva, T.A., Andreev, I.M., Verweij, R., Schat, H., 2014. Histidine-mediated xylem loading of zinc is a species-wide character in Noccaea caerulescens. New Phytol. 203, 508-519.
Kramer, U., 2005. Phytoremediation:novel approaches to cleaning up polluted soils. Curr. Opin. Biotechnol. 16, 133-141.
Kramer, U., Cotterhowells, J.D., Charnock, J.M., Baker, A.J.M., Smith, J.A.C., 1996. Free histidine as a metal chelator in plants that accumulate nickel. Nature 379, 635-638.
Li, Y., 1994. The relationship between osmotic adjustment and other physiological processes in plants and its application in crop improvement. Plant Physiol. Commun. 30, 377-385.
Li, W., 2010. Effect of Cd on Nutrient Elements and Free Amino Acids of Kandelia candel Seedlings. Master's thesis. Sun Yat-sen University, Guangzhou.
Li, Y.L., Liu, Y.F., Zhang, J.G., 2010. Advances in the research on the AsA-GSH cycle in horticultural crops. Front. Agric. China 4, 84-90.
Li, X., Yang, Y.Q., Ma, L., Sun, X.D., Yang, S.H., Kong, X.X., Hu, X.Y., Yang, Y.P., 2014a. Comparative proteomics analyses of Kobresia pygmaea adaptation to environment along an elevational gradient on the central Tibetan Plateau. PLoS One 9, e98410. https://doi.org/10.1371/journal.pone.0098410.
Li, X., Yang, Y.Q., Sun, X.D., Lin, H.M., Chen, J.H., Ren, J., Hu, X.Y., Yang, Y.P., 2014b. Comparative physiological and proteomic analyses of poplar (Populus yunnanensis) plantlets exposed to high temperature and drought. PLoS One 9, e107605. https://doi.org/10.1371/journal.pone.0107605.
Li, X., Zhou, Y.L., Yang, Y.Q., Yang, S.H., Sun, X.D., Yang, Y.P., 2015. Physiological and proteomics analyses reveal the mechanism of Eichhornia crassipes tolerance to high-concentration cadmium stress compared with Pistia stratiotes. PLoS One 10, e0124304. https://doi.org/10.1371/journal.pone.0124304.
Li, X., Zhang, X.M., Yang, Y., Li, B.Q., Wu, Y.S., Sun, H., Yang, Y.P., 2016. Cadmium accumulation characteristics in turnip landraces from China and assessment of their phytoremediation potential for contaminated soils. Front. Plant Sci. 7, 1862. https://doi.org/10.3389/fpls.2016.01862.
Liu, J.X., Wang, A.X., Li, B.P., 2010. Effects of exogenous nitric oxide donor on the ascorbate-glutathione in Peganum multisectum seedling leaves under NaCl stress. Bull. Bot. Res. 30, 37-41.
Luo, Q., Sun, L.N., Hu, X.M., Zhou, R.R., 2014. The variation of root exudates from the hyperaccumulator Sedum alfredii under cadmium stress:metabonomics analysis. PLoS One 9, e115581. https://doi.org/10.1371/journal.pone.0115581.
Luo, Q., Sun, L.N., Hu, X.M., 2015. Metabonomics study on root exudates of cadmium hyperaccumulator Sedum alfredii. Chin. J. Anal. Chem. 43, 7-11.
May, M.J., Vernoux, T., Leaver, C., Van Montagu, M., Inze, D., 1998. Glutathione homeostasis in plants:implications for environmental sensing and plant development. J. Exp. Bot. 49, 649-667.
Moller, I.M., 2001. Plant mitochondria and oxidative stress:electron transport, NADPH turnover, and metabolism of reactive oxygen species. Annu. Rev. Plant Physiol. 52, 561-591.
Moreno-Caselles, J., Moral, R., Perez-Espinosa, A., Perez-Murcia, M.D., 2000. Cadmium accumulation and distribution in cucumber plant. J. Plant Nutr. 23, 243-250.
Morikawa, C.K., 2017. Reducing cadmium accumulation in fresh pepper fruits by grafting. Hortic. J. 86, 45-51.
Nahar, K., Rahman, M., Hasanuzzaman, M., Alam, M.M., Rahman, A., Suzuki, T., Fujita, M., 2016. Physiological and biochemical mechanisms of spermineinduced cadmium stress tolerance in mung bean (Vigna radiata L.) seedlings. Environ. Sci. Pollut. Res. 23, 21206-21218.
Ogawa, K., 2005. Glutathione-associated regulation of plant growth and stress responses. Antioxidants Redox Signal. 7, 973-981.
Pan, F.S., Meng, Q., Wang, Q., Luo, S., Chen, B., Khan, K.Y., Yang, X.E., Feng, Y., 2016. Endophytic bacterium Sphingomonas SaMR12 promotes cadmium accumulation by increasing glutathione biosynthesis in Sedum alfredii Hance. Chemosphere 154, 358-366.
Raseetha, S., Leong, S.Y., Burritt, D.J., Oey, I., 2013. Understanding the degradation of ascorbic acid and glutathione in relation to the levels of oxidative stress biomarkers in broccoli (Brassica oleracea L. italica cv. Bellstar) during storage and mechanical processing. Food Chem. 138, 1360-1369.
Repetto, O., Bestel-Corre, G., Dumas-Gaudot, E., Berta, G., Gianinazzi-Pearson, V., Gianinazzi, S., 2003. Targeted proteomics to identify cadmium-induced protein modifications in Glomus mosseae-inoculated pea roots. New Phytol. 157, 555-567.
Salt, D.E., Prince, R.C., Pickering, I.J., Raskin, I., 1995. Mechanisms of cadmium mobility and accumulation in Indian mustard. Plant Physiol. 109, 1427-1433.
Salt, D.E., Prince, R.C., Baker, A.J.M., Raskin, I., Pickering, I.J., 1999. Zinc ligands in the metal hyperaccumulator Thlaspi caerulescens as determined using X-ray absorption spectroscopy. Environ. Sci. Technol. 33, 713-717.
Secenji, M., Hideg, E., Bebes, A., Gyorgyey, J., 2010. Transcriptional differences in gene families of the ascorbate-glutathione cycle in wheat during mild water deficit. Plant Cell Rep. 29, 37-50.
Sharma, S.S., Dietz, K.J., 2006. The significance of amino acids and amino acidderived molecules in plant responses and adaptation to heavy metal stress. J. Exp. Bot. 57, 711-726.
Sharma, S.S., Schat, H., Vooijs, R., 1998. In vitro alleviation of heavy metal-induced enzyme inhibition by proline. Phytochemistry 49, 1531-1535.
Shekhawat, G.S., Verma, K., Jana, S., Singh, K., Teotia, P., Prasad, A., 2010. In vitro biochemical evaluation of cadmium tolerance mechanism in callus and seedlings of Brassica juncea. Protoplasma 239, 31-38.
Smirnoff, N., Cumbes, Q.J., 1989. Hydroxyl radical scavenging activity of compatible solutes. Phytochemistry 28, 1057-1060.
Song, X.D., Lv, J.Y., Di, L.J., Liu, X.T., Ye, Q.F., 2011. Effects of chromium stress on the content of phytochelatins and antioxidative characteristics in Brassica chinensis L. J. Agro-Environ. Sci. 30, 843-848.
Song, L.L., Wang, J.H., Shafi, M., Liu, Y., Wang, J., Wu, J.S., Wu, A.M., 2016. Hypobaric treatment effects on chilling injury, mitochondrial dysfunction, and the ascorbate-glutathione (AsA-GSH) cycle in postharvest peach fruit. J. Agric. Food Chem. 64, 4665-4674.
Song, Y., Jin, L., Wang, X.J., 2017. Cadmium absorption and transportation pathways in plants. Int. J. Phytoremediation 19, 133-141.
Sreenivasulu, N., Grimm, B., Wobus, U., Weschke, W., 2000. Differential response of antioxidant compounds to salinity stress in salt-tolerant and salt-sensitive seedlings of foxtail millet (Setaria italica). Physiol. Plantarum 109, 435-442.
Srivastava, S., Tripathi, R.D., Dwivedi, U.N., 2004. Synthesis of phytochelatins and modulation of antioxidants in response to cadmium stress in Cuscuta reflexa -an angiospermic parasite. J. Plant Physiol. 161, 665-674.
Tao, D.L., Oquist, G., Wingsle, G., 1998. Active oxygen scavengers during cold acclimation of Scots pine seedlings in relation to freezing tolerance. Cryobiology 37, 38-45.
Tarhan, L., Kavakcioglu, B., 2016. Glutathione metabolism in Urtica dioica in response to cadmium based oxidative stress. Biol. Plantarum 60, 163-172.
Tauqeer, H.M., Ali, S., Rizwan, M., Ali, Q., Saeed, R., Iftikhar, U., Ahmad, R., Farid, M., Abbasi, G.H., 2016. Phytoremediation of heavy metals by Alternanthera bettzickiana:growth and physiological response. Ecotoxicol. Environ. Saf 126, 138-146.
Wang, L.N., Yang, L.M., Yang, F.J., Li, X.G., Song, Y.P., Wang, X.F., Hu, X.Y., 2010. Involvements of H2O2 and metallothionein in NO-mediated tomato tolerance to copper toxicity. J. Plant Physiol. 167, 1298-1306.
Wei, S.H., Zhou, Q.X., Koval, P.V., 2006. Flowering stage characteristics of cadmium hyperaccumulator Solanum nigrum L. and their significance to phytoremediation. Sci. Total Environ. 369, 441-446.
Wilce, M.C.J., Parker, M.W., 1994. Structure and function of glutathione S-transferases. Bba-Protein. Struct. Mater. 1205, 1-18.
Xiao, C.W., Luo, X.Y., Tian, Y., Lu, X.Y., 2013. Research progress of bioremediation of heavy metal cadmium pollution. Chem. Bioeng. 30, 1-4.
Yang, D.G., Liu, Y.X., Zhang, Q., Jiang, Z.Z., Song, B.G., 2015. Progress on crops osmotic adjustment and genetic engineering of osmotic stress resistance. Crops 1, 6-13.
Ye, S.F., Zhou, Y.H., Sun, Y., Zou, L.Y., Yu, J.Q., 2006. Cinnamic acid causes oxidative stress in cucumber roots, and promotes incidence of Fusarium wilt. Environ. Exp. Bot. 56, 255-262.
Zhang, B.J., Zhang, X.X., Luo, L.G., 2013. The major gene families related to cadmium absorption and transportation in plants. Genom. Appl. Biol. 32, 127-134.
Zhang, Z.S., Li, R.Q., Wang, J.B., 2001. Effects of oxalate treatment on the membrane permeability and calcium distribution in pepper leaves under heat stress. Acta Phytophys. Sin. 27, 109-113.
Zhang, W., Cai, Y., Downum, K.R., Ma, L.Q., 2004. Thiol synthesis and arsenic hyperaccumulation in Pteris vittata (Chinese brake fern). Environ. Pollut. 131, 337-345.
Zheng, S.Y., Shang, X.F., 2006. Research progress of cadmium pollution in soil. Anhui Agri. Sci. Bull. 12, 43-44.
Options
文章导航

/

版权所有 © 《Plant Diversity》编辑部
技术支持:北京玛格泰克科技发展有限公司