Lead is a heavy metal of particular concern with respect to environmental quality and health. The lack of plant species that accumulate and tolerate Pb is a limiting factor to understand the molecular mechanisms involved in Pb tolerance. In this study we identified Hirschfeldia incana, a Brassicaceae collected from metalliferous mine spoils in Morocco, as a Pb accumulator plant. H. incana exhibited high Pb accumulation in mine soils and in hydroponic cultures. Major Pb accumulation occurred in the roots and a part of Pb translocated from the roots to the shoots, even to the siliques. These findings demonstrated that H. incana is a Pb accumulator species. The expression of several candidate genes after Pb-exposure was measured by quantitative PCR and two of them, HiHMA4 and HiMT2a, coding respectively for a P1B-type ATPase and a metallothionein, were particularly induced by Pb-exposure in both roots and leaves. The functional characterization of HiHMA4 and HiMT2a was achieved using Arabidopsis T-DNA insertional mutants. Pb content and primary root growth analysis confirmed the role of these two genes in Pb tolerance and accumulation. H. incana could be considered as a good experimental model to identify genes involved in lead tolerance and accumulation in plants.
References
[1]
Lee M, Lee K, Lee J, Noh EW, Lee Y (2005) AtPDR12 contributes to lead resistance in Arabidopsis. Plant Physiology 138: 827–836.
[2]
Sharma P, Dubey RS (2005) Lead toxicity in plants. Brazilian Journal of Plant Physiology 17: 35–52.
[3]
Van Nevel L, Mertens J, Oorts K, Verheyen K (2007) Phytoextraction of metals from soils: How far from practice? Environmental Pollution 150: 34–40.
[4]
Baker AJM, Reeves RD, Hajar ASM (1994) Heavy metal accumulation and tolerance in British populations of the metallophyte Thlaspi caerulescens J. & C. Presl (Brassicaceae). New Phytologist 127: 61–68.
[5]
Kramer U (2010) Metal hyperaccumulation in plants. Annual Review of Plant Biology 61: 517–534.
[6]
Verbruggen N, Hermans C, Schat H (2009) Molecular mechanisms of metal hyperaccumulation in plants. New Phytolologist 181: 759–776.
[7]
Anderson CWN, Brooks RR, Chiarucci A, LaCoste CJ, Leblanc M, et al. (1999) Phytomining for nickel, thallium and gold. Journal of Geochemical Exploration 67: 407–415.
[8]
Baker AJM, Brooks RR (1989) Terrestrial higher plants which hyper-accumulate metallic elements - A review of their distribution, ecology and phytochemistry. Biorecovery 1: 81–126.
[9]
Reeves RD (2006) Hyperaccumulation of trace elements by plants. In: Morel JL, Echevarria G, Goncharova N, editors. Phytoremediation of Metal-contaminated Soils. NATO Sciences Series 68. Springer, New York. 25–52.
[10]
Sunkar R, Kaplan B, Bouche N, Arazi T, Dolev D, et al. (2000) Expression of a truncated tobacco NtCBP4 channel in transgenic plants and disruption of the homologous Arabidopsis CNGC1 gene confer Pb tolerance. Plant Journal 24: 533–542.
[11]
Gravot A, Lieutaud A, Verret F, Auroy P, Vavasseur A, et al. (2004) AtHMA3, a plant P1B-ATPase, functions as a Cd/Pb transporter in yeast. FEBS Letters 561: 22–28.
[12]
Morel M, Crouzet J, Gravot A, Auroy P, Leonhardt N, et al. (2009) AtHMA3, a P1B-ATPase allowing Cd/Zn/Co/Pb vacuolar storage in Arabidopsis. Plant Physiology 149: 894–904.
[13]
Papoyan A, Kochian V (2004) Identification of Thlaspi caerulescens genes that may be involved in heavy metal hyperaccumulation and tolerance. Characterization of a novel heavy metal transporting ATPase. Plant Physiology 145: 3814–3823.
[14]
Kim DY, Bovet L, Kushnir S, Noh EW, Martinoia E, et al. (2006) AtATM3 is involved in heavy metal resistance in Arabidopsis. Plant Physiology 140: 922–932.
[15]
Kim DY, Bovet L, Maeshima M, Martinoia E, Lee Y (2007) The ABC transporter AtPDR8 is a cadmium extrusion pump conferring heavy metal resistance. Plant Journal 50: 207–218.
[16]
Xiao S, Gao W, Chen QF, Ramalingam S, Chye ML (2008) Overexpression of membrane-associated acyl-CoA-binding protein ACBP1 enhances lead tolerance in Arabidopsis. The Plant Journal 54: 141–151.
[17]
Zientara K, Wawrzynska A, Lukomska J, Lopez-Moya JR, Liszewska F, et al. (2009) Activity of the AtMRP3 promoter in transgenic Arabidopsis thaliana and Nicotiana tabacum plants is increased by cadmium, nickel, arsenic, cobalt and lead but not by zinc and iron. Journal of Biotechnology 139: 258–263.
[18]
Cobbett C, Goldsbrough P (2002) Phytochelatins and metallothioneins: roles in heavy metal detoxification and homeostasis. Annual review of Plant Biology 53: 159–182.
[19]
Gupta DK, Huang HG, Yang XE, Razafindrabe BH, Inouhe M (2010) The detoxification of lead in Sedum alfredii H. is not related to phytochelatins but the glutathione. Journal of Hazardous Materials 177: 437–444.
[20]
Murashige T, Skoog F (1962) A revised medium for rapid growth and bio assays with tobacco tissue cultures. Physiologia Plantarum 15: 473–497.
[21]
Broughton WJ, Dilworth MJ (1971) Control of Leghaemoglobin synthesis in snake beans. Biochemical journal 125: 1075–1080.
[22]
Scholl RL, May ST, Ware DH (2000) Seed and molecular resources for Arabidopsis. Plant Physiology 124: 1477–1480.
Smouni A, Ater M, Auguy F, Laplaze L, El Mzibri M, et al.. (2010) Assessment of contamination by metallic trace elements in a mining area of eastern Morocco. Cahiers Agriculture 19:, 26–76.
[25]
Marguí E, Queralt I, Carvalho ML, Hidalgo M (2005) Comparison of EDXRF and ICP-OES after microwave digestion for element determination in plant specimens from an abandoned mining area. Analytica Chimica Acta 549: 197–204.
[26]
White TJ, Bruns T, Lee S, Taylor J (1990) Amplification and direct sequencing of fungal ribosomal RNA genes for phylogenetics. In: Innis MA, Gelfand DH, Sninsky JJ, White TJ, editors. PCR protocols. A guide to methods and applications. Academic Press, San Diego, Calif. 315–322.
[27]
Pourrut B, Shahid M, Dumat C, Winterton P, et al.. (2011) Lead uptake, toxicity, and detoxification in plants. In: Whitacre DM, editor. Reviews of Environmental Contamination and Toxicology 213. Springer, New York. 113–136.
[28]
Xiao S, Chye ML (2008) Arabidopsis ACBP1 overexpressors are Pb(II)-tolerant and accumulate Pb(II). Plant Signaling & Behavior 3: 693–94.
[29]
Poschenrieder P, Bech J, Llugany M, Pace A, Fenés E, et al. (2001) Copper in plant species in a copper gradient in Catalonia (North East Spain) and their potential for phytoremediation. Plant and Soil 2: 247–256.
[30]
Madejón P, Murillo JM, Mara?ón T, Lepp NW (2007) Factors affecting accumulation of thallium and other trace elements in two wild Brassicaceae spontaneously growing on soils contaminated by tailings dam waste. Chemosphere 67: 20–28.
[31]
Gisbert C, Clemente R, Navarro-Avi?ó J, Baixauli C, Ginér A, et al. (2006) Tolerance and accumulation of heavy metals by Brassicaceae species grown in contaminated soils from Mediterranean regions of Spain. Environmental and Experimental Botany 56: 19–27.
[32]
Walker DJ, Bernal MP (2004) The effects of copper and lead on growth and zinc accumulation of Thlaspi caerulescens J. and C. presl: implications for phytoremediation of contaminated soils. Water Air Soil Pollution 151: 361–372.
[33]
Yanqun Z, Yuan L, Schvartz C, Langlade L, Fan L (2004) Accumulation of Pb, Cd, Cu and Zn in plants and hyperaccumulator choice in Lanping lead–zinc mine area, China. Environment International 30: 567–576.
[34]
Deng DM, Deng JC, Li JT, Zhang J, Hu M, et al. (2008) Accumulation of zinc, cadmium, and lead in four populations of Sedum alfredii growing on lead/zinc mine spoils. Journal of Integrative Plant Biology 50: 691–698.
[35]
Kushnir S, Babiychuk E, Storozhenko S, Davey MW, Papenbrock J, et al. (2001) A mutation of the mitochondrial ABC transporter Sta1 leads to dwarfism and chlorosis in the Arabidopsis mutant starik. Plant Cell 13: 89–100.
[36]
Verret F, Gravot A, Auroy P, Leonhardt N, David P, et al. (2004) Overexpression of AtHMA4 enhances root-to-shoot translocation of zinc and cadmium and plant metal tolerance. FEBS Letters 576: 306–312.
[37]
Mills RF, Francini A, Ferreira da Rocha PS, Baccarini PJ, Aylett M, et al. (2005) The plant P1B-type ATPase AtHMA4 transports Zn and Cd and plays a role in detoxification of transition metals supplied at elevated levels. FEBS Letters 579: 783–791.
[38]
Hanikenne M, Talke IN, Haydon MJ, Lanz C, Nolte A, et al. (2008) Evolution of metal hyperaccumulation required cis-regulatory changes and triplication of HMA4. Nature 453: 391–395.
[39]
Roosens NH, Bernard C, Leplae R (2004) Evidence for copper homeostasis function of metallothionein (MT3) in the hyperaccumulator Thlaspi caerulescens. FEBS Letters 577: 9–16.
[40]
Lee J, Shim D, Song WY, Hwang I, Lee Y (2004) Arabidopsis metallothioneins 2a and 3 enhance resistance to cadmium when expressed in Vicia faba guard cells. Plant Molecular Biology 54: 805–815.
[41]
Guo WJ, Meetam M, Goldsbrough PB (2008) Examining the specific contributions of individual Arabidopsis Metallothioneins to copper distribution and metal tolerance. Plant Physiology 146: 1697–1706.
[42]
Yu LH, Umeda M, Liu JY, Zhao NM, Uchimiya H (1998) A novel MT gene of rice plants is strongly expressed in the node portion of the stem. Gene 206: 29–35.
[43]
Xu YF, Zhou GK, Zhou L, Li YQ, Liu JY (2007) Expression patterns of the rice class I metallothionein gene family in response to lead stress in rice seedlings and functional complementation of its members in lead-sensitive yeast cells. Chinese Science Bulletin 52: 2203–2209.
[44]
Dong CJ, Wang Y, Yu SS, Liu JY (2010) Characterization of a novel rice metallothionein gene promoter: its tissue specificity and heavy metal responsiveness. Journal of Integrative Plant Biology 52: 914–924.
[45]
Mills RF, Krijger GC, Baccarini PJ, Hall JL, Williams LE (2003) Functional expression of AtHMA4, a P-1B-type ATPase of the Zn/Co/Cd/Pb subclass. Plant Journal 35: 164–176.
[46]
Bernard C, Roosens N, Czernic P, Lebrun M, Verbruggen N (2004) A novel CPx-ATPase from the cadmium accumulator Thlaspi caerulescens. FEBS letters 569: 140–148.
[47]
Hussain D, Haydon MJ, Wang Y, Wong E, Sherson SM, et al. (2004) P-type ATPase heavy metal transporters with roles in essential zinc homeostasis in Arabidopsis. Plant Cell 16: 1327–1339.
[48]
Wong CKE, Cobbett C (2009) HMA P-type ATPases are the major mechanism for root-to-shoot Cd translocation in Arabidopsis. New Phytologist 181: 71–78.
[49]
Murphy A, Taiz L 1(995) Comparison of metallothionein gene expression and nonprotein thiols in ten Arabidopsis ecotypes (correlation with copper tolerance). Plant Physiology 109: 945–954.
[50]
Jin S, Cheng Y, Guan Q, Liu D, Takano T, et al. (2006) A metallothionein-like protein of rice (rgMT) functions in E. coli and its gene expression is induced by abiotic stresses. Biotechnology Letters 28: 1749–1753.
[51]
Huang GY, Wang YS (2009) Expression analysis of type 2 metallothionein gene in mangrove species (Bruguiera gymnorrhiza) under heavy metal stress. Chemosphere 77: 1026–1029.
[52]
Ma M, Lau PS, Jia YT, Tsang WK, Lam SKS, et al. (2003) The isolation and characterization of Type 1 metallothionein (MT) DNA from a heavy-metal-tolerant plant, Festuca rubra cv. Merlin. Plant Science 164: 51–60.
[53]
Zhu W, Zhao D-X, Miao Q, Xue T-T, Li X-Z, et al. (2009) Arabidopsis thaliana metallothionein, AtMT2a, mediates ROS balance during oxidative stress. Journal of Plant Biology 52: 585–592.
