Evaluation of nickel tolerance in Amaranthus paniculatus L. plants by measuring photosynthesis, oxidative status, antioxidative response and metal-binding molecule content

详细信息    查看全文

• 作者：Fabrizio Pietrini (1)
  Valentina Iori (1)
  Alexandra Cheremisina (2)
  Nina I. Shevyakova (2)
  Nataliya Radyukina (2)
  Vladimir V. Kuznetsov (2)
  Massimo Zacchini (1)
  
  1. Institute of Agro-environmental and Forest Biology ; National Research Council of Italy ; Via Salaria Km 29 ; 300 ; 00015 ; Monterotondo Scalo ; RM ; Italy
  2. Timiryazev Institute of Plant Physiology ; Russian Academy of Sciences ; Botanicheskaya ul. ; 35 ; Moscow ; Russia ; 127276
  
• 关键词：Metal tolerance ; Organic acids ; Chlorophyll fluorescence ; Polyamines ; Antioxidative enzymes ; Oxidative stress
• 刊名：Environmental Science and Pollution Research
• 出版年：2015
• 出版时间：January 2015
• 年：2015
• 卷：22
• 期：1
• 页码：482-494
• 全文大小：9,288 KB
• 参考文献：1. Assun莽茫o AGL, Bookum WM, Nelissen HJM, Vooijs R, Schat H, Ernst WHO (2003) Differential metal-specific tolerance and accumulation patterns among / Thlaspi caerulescens populations originating from different soil types. New Phytol 159:411鈥?19 CrossRef
  2. Beauchamp C, Fridovich I (1971) Superoxide dismutase improved assays and an assay applicable to acrylamide gels. Anal Biochem 44:276鈥?87 CrossRef
  3. Bhatia NP, Walsh KB, Baker AJM (2005) Detection and quantification of ligands involved in nickel detoxification in a herbaceous Ni hyperaccumulator / Stackhousia tryonii Bailey. J Exp Bot 56:1343鈥?349 CrossRef
  4. Cabanillas J, Ginebreda A, Guill茅n D, Mart铆nez E, Barcel贸 D, Moragas L, Robust茅 J, Darbra RM (2012) Fuzzy logic based risk assessment of effluents from waste-water treatment plants. Sci Tot Environ 439:202鈥?10 CrossRef
  5. Callahan DL, Baker AJM, Kolev SD, Wedd AG (2006) Metal ion ligands in hyperaccumulating plants. J Biol Inorg Chem 11:2鈥?2 CrossRef
  6. Cerovic ZG, Masdoumier G, Ghozlen NB, Latouche G (2012) A new optical leaf-clip meter for simultaneous non-destructive assessment of leaf chlorophyll and epidermal flavonoids. Physiol Plant 146:251鈥?60 CrossRef
  7. Chance B, Maehly C (1955) Assay of catalase and peroxidases. Meth Enzymol 11:764鈥?75 CrossRef
  8. Clemens S (2006) Toxic metal accumulation, responses to exposure and mechanisms of tolerance in plants. Biochimie 88:1707鈥?719 CrossRef
  9. Cona A, Cenci F, Cervelli M, Federico R, Mariottini P, Moreno S, Angelini R (2003) Polyamine oxidase, a hydrogen peroxide-producing enzyme, is up-regulated by light and down-regulated by auxin in the outer tissues of the maize mesocotyl. Plant Physiol 131:803鈥?13 CrossRef
  10. de Agazio M, Zacchini M (2001) Dimethylthiourea, a hydrogen peroxide trap, partially prevents stress effects and ascorbate peroxidase increase in spermidine-treated maize roots. Plant Cell Environ 24:237鈥?44 CrossRef
  11. Dietz KJ, Baier M, Kr盲mer U (1999) Free radicals and reactive oxygen species as mediators of heavy metal toxicity in plants. In: Prasad MNV, Hagemeyer J (eds) Heavy metal stress in plants: from molecules to ecosystems. Springer Verlag, Berlin, pp 73鈥?7 CrossRef
  12. Dra藕kiewicz M, Baszy艅ski T (2005) Growth parameters and photosynthetic pigments in leaf segments of / Zea mays exposed to cadmium, as related to protection mechanisms. J Plant Physiol 162:1013鈥?021 CrossRef
  13. Gabbrielli R, Pandolfini T, Vergnano O, Palandri MR (1990) Comparison of two serpentine species with different nickel tolerance strategies. Plant Soil 122:271鈥?77 CrossRef
  14. Gajewska E, Sklodowska M (2007) Effect of nickel on ROS content and antioxidative enzyme activities in wheat leaves. Biometals 20:27鈥?6 CrossRef
  15. Gajewska E, Sklodowska M, Slaba M, Mazur J (2006) Effect of nickel on antioxidative enzymes activities, proline and chlorophyll contents in wheat shoots. Biol Plant 50:653鈥?59 CrossRef
  16. Galardi F, Corrales I, Mengoni A, Pucci S, Barletti L, Barzanti R, Arnetoli M, Gabbrielli R, Gonnelli C (2007) Intra-specific differences in nickel tolerance and accumulation in the Ni-hyperaccumulator / Alyssum bertolonii. Environ Exp Bot 60:377鈥?84 CrossRef
  17. Gonnelli C, Galardi F, Gabbrielli R (2001) Nickel and copper tolerance and toxicity in three Tuscan populations of / Silene paradoxa. Physiol Plant 113:507鈥?14 CrossRef
  18. Groppa MD, Tomaro ML, Benavides MP (2007) Polyamines and heavy metal stress: the antioxidant behaviour of spermine in cadmium- and copper-treated wheat leaves. Biometals 20:185鈥?95 CrossRef
  19. Handa AK, Matoo AK (2010) Differential and functional interactions emphasize the multiple roles of polyamines in plants. Plant Physiol Biochem 48:540鈥?46 CrossRef
  20. Havir EA, McHale NA (1987) Biochemical and developmental characterization of multiple forms of catalase in tobacco leaves. Plant Physiol 84:450鈥?55 CrossRef
  21. Heath RL, Packer L (1968) Photoperoxidation in isolated chloroplasts: I. Kinetics and stoichiometry of fatty acid peroxidation. Arch Biochem Biophys 125:189鈥?98 CrossRef
  22. Iori V, Pietrini F, Cheremisina A, Shevyakova NI, Radyukina N, Kuznetsov VLV, Zacchini M (2013) Growth responses, metal accumulation and phytoremoval capability in / Amaranthus plants exposed to nickel under hydroponics. Water Air Soil Poll 224:1450鈥?459 CrossRef
  23. Kov谩膷ik J, Klejdus B, Hedbavny J, Ba膷kor M (2009) Nickel uptake and its effect on some nutrient levels, amino acid contents and oxidative status in / Matricaria chamomilla plants. Water Air Soil Poll 202:199鈥?09 CrossRef
  24. Kr盲mer U (2010) Metal hyperaccumulation in plants. Ann Rev Plant Biol 61:517鈥?34 CrossRef
  25. Kr盲mer U, Smith RD, Wenzel WW, Raskin I, Salt DE (1997) The role of metal transport and tolerance in nickel hyperaccumulation by / Thlaspi goesingense H谩l谩csy. Plant Physiol 115:1641鈥?650
  26. K眉pper H, Kroneck PMH (2007) Nickel in the environment and its role in the metabolism of plants and cyanobacteria. In: Sigel A, Sigel H, Sigel RKO (eds) Metal ions in life sciences, vol 2. Wiley Ltd, pp31鈥?2
  27. Kuznetsov VV, Radyukina NL, Shevyakova NI (2006) Polyamines and stress: biological role, metabolism, and regulation. Russ J Plant Physiol 53:658鈥?83 CrossRef
  28. Llamas A, Ullrich CL, Sanz A (2008) Ni²⁺ toxicity in rice: effect on membrane functionality and plant water content. Plant Physiol Biochem 46:905鈥?10 CrossRef
  29. Lomozik L, Gasowska A, Bregier-Jarzebowska R, Jastrzab R (2005) Coordination chemistry of polyamines and their interactions in ternary systems including metal ions, nucleosides and nucleotides. Coord Chem Rev 249:2335鈥?350 CrossRef
  30. Long SP (1999) Environmental responses. In: Sage RF, Monson RK (eds) C4 Plant biology. Academic, San Diego, pp 215鈥?49 CrossRef
  31. L贸pez-Bucio J, Mart铆nez de la Vega O, Guevara-Garc铆a A, Herrera-Estrella L (2000) Enhanced phosphorus uptake in tobacco transgenic plants that overproduce citrate. Nat Biotech 18:450鈥?53 CrossRef
  32. Madzhugina YG, Kuznetsov VV, Shevyakova NI (2008) Plants inhabiting polygons for megapolis waste as promising species for phytoremediation. Russ J Plant Physiol 55:410鈥?19 CrossRef
  33. Maestri E, Marmiroli M, Visioli G, Marmiroli N (2010) Metal tolerance and hyperaccumulation: cost and trade-offs between traits and environment. Environ Exp Bot 68:1鈥?3 CrossRef
  34. Maheshwary R, Dubey RS (2009) Nickel-induced oxidative stress and the role of antioxidant defence in rice seedlings. Plant Growth Regul 59:37鈥?9 CrossRef
  35. Mellem JJ, Baijnath H, Odhav B (2009) Translocation and accumulation of Cr, Hg, As, Pb, Cu and Ni by / Amaranthus dubius (Amaranthaceae) from contaminated sites. J Environ Sci Health 44:568鈥?75 CrossRef
  36. Memon AR, Schr枚der P (2009) Implications of metal accumulation mechanisms to phytoremediation. Environ Sci Pollut Res 16:162鈥?75 CrossRef
  37. Miller G, Shulaev V, Mittler R (2008) Reactive oxygen signaling and abiotic stress. Physiol Plant 133:481鈥?89 CrossRef
  38. Nakano Y, Asada K (1981) Hydrogen peroxide is scavenged by ascorbate-specific peroxidase in spinach chloroplasts. Plant Cell Physiol 22:867鈥?80
  39. Palacios G, G贸mez I, Carbonell-Barrachina A, Navarro Pedre帽o J, Mataix J (1998) Effect of nickel concentration on tomato plant nutrition and dry matter yield. J Plant Nutr 21:2179鈥?191 CrossRef
  40. Pandey N, Sharma CP (2002) Effect of heavy metals Co²⁺, Ni²⁺ and Cd²⁺ on growth and metabolism of cabbage. Plant Sci 163:753鈥?58 CrossRef
  41. Pietrini F, Iannelli MA, Montanari R, Bianconi D, Massacci A (2005) Cadmium interaction with thiols and photosynthesis in higher plants. In: Hemantaranjan A (ed) Advances in plant physiology. Scientific Publishers (India), Jodhpur, pp 313鈥?26
  42. Pietrini F, Zacchini M, Iori V, Pietrosanti L, Ferretti M, Massacci A (2010) Spatial distribution of cadmium in leaves and its impact on photosynthesis: examples of different strategies in willow and poplar clones. Plant Biol 12:355鈥?63 CrossRef
  43. Robinson BH, Chiarucci A, Brooks RR, Petit D, Kirkman JH, Gregg PEH, De Dominicis V (1997) The nickel hyperaccumulator plant / Alyssum bertolonii as a potential agent for phytoremediation and phytomining of nickel. J Geochem Explor 59:75鈥?6 CrossRef
  44. Sagardoy R, Morales F, Rell谩n-脕lvarez R, Abad铆a A, Abad铆a J, L贸pez-Mill谩n AF (2011) Carboxylate metabolism in sugar beet plants grown with excess Zn. J Plant Physiol 168:730鈥?33 CrossRef
  45. Saito A, Higuchi K, Hirai M, Nakane R, Yoshiba M, Tadano T (2005) Selection and characterization of a nickel-tolerant cell line from tobacco ( / Nicotiana tabacum cv. bright yellow-2) suspension culture. Physiol Plant 125:441鈥?53
  46. Salt DE, Prince RC, Pickering IJ (2002) Chemical speciation of accumulated metals in plants: evidence from X-ray absorption spectroscopy. Microchem J 71:255鈥?59 CrossRef
  47. Schickler H, Caspi H (1999) Response of antioxidative enzymes to nickel and cadmium stress in hyperaccumulator plants of the genus / Alyssum. Physiol Plant 105:39鈥?4 CrossRef
  48. Seregin IV, Kozhevnikova AD (2006) Physiological role of nickel and its toxic effects on higher plants. Russ J Plant Physiol 53:285鈥?08 CrossRef
  49. Shevyakova NI, Cheremisina A, Kuznetsov VV (2011) Phytoremediation potential of / Amaranthus hybrids: antagonism between nickel and iron and chelating role of polyamines. Russ J Plant Physiol 58:634鈥?42 CrossRef
  50. Sreekanth TVM, Nagajyothi PC, Lee KD, Prasad TNVKV (2013) Occurrence, physiological responses and toxicity of nickel in plants. Int J Environ Sci Technol 10:1129鈥?140 CrossRef
  51. Subhan D, Murthy SDS (2001) Senescence retarding effect of metal ions: pigment and protein content and photochemical activities of detached primary leaves of wheat. Photosynthetica 39:53鈥?8 CrossRef
  52. Takao K, Rickhag M, Hegardt C, Oredsson S, Persson L (2006) Induction of apoptotic cell death by putrescine. Int J Biochem Cell Biol 38:621鈥?28 CrossRef
  53. von Caemmerer S, Farquhar GD (1981) Some relationships between the biochemistry of photosynthesis and the gas exchange of leaves. Planta 153:376鈥?87 CrossRef
  54. Yang XE, Baligar VC, Foster JC, Martens DC (1997) Accumulation and transport of nickel in relation to organic acids in ryegrass and maize grown with different nickel levels. Plant Soil 196:271鈥?76 CrossRef
  55. Yusuf M, Fariduddin Q, Varshney P, Ahmad A (2012) Salicylic acid minimizes nickel and/or salinity-induced toxicity in Indian mustard ( / Brassica juncea) through an improved antioxidant system. Environ Sci Pollut Res 19:8鈥?8 CrossRef
  56. Zacchini M, de Agazio M (2004) Spread of oxidative damage and antioxidative response through tobacco callus cell layers after UV-C pulse treatment. Plant Physiol Biochem 42:445鈥?50 CrossRef
  57. Zacchini M, Iori V, Scarascia Mugnozza G, Pietrini F, Massacci A (2011) Cadmium accumulation and tolerance in / Populus nigra and / Salix alba. Biol Plant 55:383鈥?86 CrossRef
  58. Zhang X, Zhang S, Xu X, Li T, Gong G, Jia Y, Li Y, Deng L (2010) Tolerance and accumulation characteristics of cadmium in / Amaranthus hybridus L. J Haz Mat 180:303鈥?08 CrossRef
  59. Zhao J, Shi G, Yuan Q (2008) Polyamines content and physiological and biochemical responses to ladder concentration of nickel stress in / Hydrocharis dubia (Bl.) Backer leaves. Biometals 21:665鈥?74 CrossRef
  
• 刊物类别：Earth and Environmental Science
• 刊物主题：Environment
  Environment
  Atmospheric Protection, Air Quality Control and Air Pollution
  Waste Water Technology, Water Pollution Control, Water Management and Aquatic Pollution
  Industrial Pollution Prevention
  
• 出版者：Springer Berlin / Heidelberg
• ISSN：1614-7499

文摘

Among metals, Ni has been indicated as one of the most dangerous for the environment, and plants exposed to this metal are frequently reported to undergo a severe stress condition. In this work, the tolerance responses to different Ni concentrations at physiological and biochemical levels were evaluated in Amaranthus paniculatus L., a plant species previously characterised for their ability to phytoremove Ni from metal-spiked water. Results indicated a good metal tolerance of this plant species at environmentally relevant Ni concentrations, while clear symptoms of oxidative damages were detected at higher Ni concentrations, both in roots and leaves, by measuring lipid peroxide content. At the photosynthetic level, pigment content determination, chlorophyll fluorescence image analysis and gas-exchange parameter measurements revealed a progressive impairment of the photosynthetic machinery at increasing Ni concentrations in the solution. Regarding biochemical mechanisms involved in antioxidative defence and metal binding, antioxidative enzyme (ascorbate peroxidase, APX; catalase, CAT; guaiacol peroxidase, GPX; superoxide dismutase, SOD) activity, polyamine (PA) content, polyamine oxidase (PAO) activity and organic acid (OA) content were differently affected by Ni concentration in the growth solution. A role for GPX, SOD, PAs, and oxalic and citric acid in Ni detoxification is suggested. These results can contribute to elucidate the tolerance mechanisms carried out by plants when facing environmentally relevant Ni concentrations and to identify some traits characterising the physiological and biochemical responses of Amaranthus plants to the presence and bioaccumulation of Ni.