Lead tolerance in Festuca ovina is an inherited characteristic, evolved by the production of compounds within the plants, specifically for protection against the toxic effects of heavy metals. Get unlimited, online access to over 18 million full-text articles from more than 15,000 scientific journals. Interactions between lead (Pb) with different plant species. NIH Lead tolerance in plants: strategies for phytoremediation. Lead tolerance in plants: strategies for phytoremediation. Lead (Pb) is the most common heavy metal contaminant in the environment. 2009 Nov;16(7):795-804. doi: 10.1007/s11356-009-0168-7. What are the why’s, the how’s, and the whereto’s? 2009 Mar;16(2):162-75. doi: 10.1007/s11356-008-0079-z. NLM • Exclusion, uptake, and transportation mechanisms of Pb in different plant systems. PMID: Select data courtesy of the U.S. National Library of Medicine. 2012 May;164:242-7 Do not surround your terms in double-quotes ("") in this field. Epub 2020 Jun 5. Require these words, in this exact order. To limit the detrimental impact of Pb, efficient strategies like phytoremediation are required. Heavy metals are among the most important sorts of contaminant in the environment. Heavy-metal-induced reactive oxygen species: phytotoxicity and physicochemical changes in plants. To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one. Commonly plants may prevent the toxic effect of heavy metals by induction of various celular … But what does it mean? -, Environ Pollut. Implications of metal accumulation mechanisms to phytoremediation. HHS Two independent trials were conducted to examine the involvement of nitric oxide (NO) in MT-mediated tolerance to Cd toxicity in wheat plants. -, Plant Physiol. Unlimited access to over18 million full-text articles. From classic methodologies to application of nanomaterials for soil remediation: an integrated view of methods for decontamination of toxic metal(oid)s. Genome-wide association study (GWAS) reveals genetic loci of lead (Pb) tolerance during seedling establishment in rapeseed (Brassica napus L.). This technology is environmental friendly and potentially cost effective. They were placed on your computer when you launched this website. Enjoy affordable access to Damage to soil texture, i.e., pH of soil, presence of different elements, and accumulation of heavy metals cause direct and/or indirect reduction of plant growth by adversely affecting vari… Environ Sci Pollut Res Int. The negative effects of environmental stresses, such as low temperature, high temperature, salinity, drought, heavy metal stress, and biotic stress significantly decrease crop productivity. from heavy metal-contaminated paddy field soil and its potential in promoting plant growth and heavy metal accumulation in metal-polluted soil, A comprehensive overview of elements in bioremediation, AtATM3 is involved in heavy metal resistance in Arabidopsis, Kim, DY; Bovet, L; Kushnir, S; Noh, EU; Martinoia, E; Lee, Y, Distribution of lead in lead-accumulating pteridophyte Blechnum niponicum, measured by synchrotron radiation micro X-ray fluorescence, Kodera, H; Nishioka, H; Muramatsu, Y; Terada, Y, Characterization of a novel gene family of putative cyclic nucleotide and calmodulin-regulated ion channels in Arabidopsis thaliana, Localization and chemical speciation of Pb in roots of signal grass (Brachiaria decumbens) and Rhodes grass (Chloris gayana), Kopittke, PM; Asher, CJ; Blamey, FP; Auchterlonie, GJ; Guo, YN; Menzies, NW, Alleviation of Cu and Pb rhizotoxicities in Cowpea (Vigna unguiculata) as related to ion activities at root-cell plasma membrane surface, Kopittke, PM; Kinraide, TB; Wang, P; Blarney, FPC; Reichman, SM; Menzies, NW, Nitric oxide stimulates seed germination and counteracts the inhibitory effect of heavy metals and salinity on root growth of Lupinus luteus, Genetically modified plants in phytoremediation of heavy metal and metalloid soil and sediment pollution, Kotrba, P; Najmanova, J; Macek, T; Ruml, T; Mackova, M, Pectinous cell wall thickenings formation–A response of moss protonemata cells to lead, Krzeslowska, M; Lenartowska, M; Mellerowicz, EJ; Samardakiewicz, S; Wozny, A, Lead deposited in the cell wall of Funaria hygrometrica protonemata is not stable-A remobilization can occur, Krzeslowska, M; Lenartowska, M; Samardakiewicz, S; Bilski, H; Wozny, A, Nitric oxide protects sunflower leaves against Cd-induced oxidative stress, Laspina, NV; Groppa, MD; Tomaro, ML; Benavides, MP, AtPDR12 contributes to lead resistance in Arabidopsis, Arsenic triggers the nitric oxide (NO) and S-nitrosoglutathione (GSNO) metabolism in Arabidopsis, Leterrier, M; Airaki, M; Palma, JM; Chaki, M; Barroso, JB; Corpas, FJ, Soil amendment application frequency contributes to phytoextraction of lead by sunflower at different nutrient levels, Lin, CC; Liu, J; Liu, L; Zhu, TC; Sheng, LX; Wang, DL, Comparison of synthetic chelators and low molecular weight organic acids in enhancing phytoextraction of heavy metals by two ecotypes of Sedum alfredii Hance, Liu, D; Islam, E; Li, TQ; Yang, X; Jin, XF; Mahmood, Q, Transcriptional profiling of Arabidopsis seedlings in response to heavy metal lead (Pb), Liu, T; Liu, S; Guan, H; Ma, L; Chen, Z; Gu, H, Synchrotron-based techniques for plant and soil science: Opportunities, challenges and future perspectives, Gibberellic acid, kinetin, and the mixture indole-3-acetic acid-kinetin assisted with EDTA-induced lead hyperaccumulation in alfalfa plants, Lopez, ML; Peralta-Videa, JR; Parsons, JG; Benitez, T; Gardea-Torresdey, JL, Hydrogen peroxide induces a rapid production of nitric oxide in mung vean (Phaseolus aureus), Metal tolerance and hyperaccumulation: costs and trade-offs between traits and environment, Maestri, E; Marmiroli, M; Visioli, G; Marmiroli, N, Accumulation of lead in root cells of Pisum sativum, Małecka, A; Piechalak, A; Morkunas, I; Tomaszewska, B, Phytoremediation of metals, metalloids, and radionuclides, Chemically assisted phytoextraction: a review of potential soil amendments for increasing plant uptake of heavy metals, Meers, E; Tack, FMG; Slycken, S; Ruttens, A; Laing, GD; Vangronsveld, J; Verloo, MG, Uptake and localisation of lead in the root system of Brassica juncea, Meyers, DER; Auchterlonie, GJ; Webb, RI; Wood, B, Hyperaccumulators, arbuscular mycorrhizal fungi and stress of heavy metals, Lead detoxification by coontail (Ceratophyllum demersum L.) involves induction of phytochelatins and antioxidant system in response to its accumulation, Mishra, S; Srivastava, S; Tripathi, RD; Kumar, R; Seth, CS; Gupta, DK, AtHMA3, a P(1B)-ATPase allowing Cd/Zn/Co/Pb vacuolar storage in Arabidopsis, Morel, M; Crouzet, J; Gravot, A; Auroy, P; Leonhardt, N; Vavasseur, A; Richaud, P, Bacteria and phytoremediation: new uses for endophytic bacteria in plants, Correlation of growth inhibition with accumulation of Pb in cell wall and changes in response to oxidative stress in Arabidopsis thaliana seedlings, Phang, IC; Leung, DWM; Taylor, HH; Burritt, DJ, The protective effect of sodium nitroprusside (SNP) treatment on Arabidopsis thaliana seedlings exposed to toxic level of Pb is not linked to avoidance of Pb uptake, Phang, IC; Leung, DW; Taylor, HH; Burritt, DJ, Investigation of Pb(II) binding to pectin in Arabidopsis thaliana, Polec-Pawlak, K; Ruzik, R; Lipiec, E; Ciurzynska, M; Gawronska, H, Potential role of NADPH-oxidase in early steps of lead-induced oxidative burst in Vicia faba roots, Pourrut, B; Perchet, G; Silvestre, J; Cecchi, M; Guiresse, M; Pinelli, E, Lead uptake, toxicity, and detoxificaion in plants, Pourrut, B; Shahid, M; Dumat, C; Winterton, P; Pinelli, E, Symbiotic role of Glomus mosseae in phytoextraction of lead in vetiver grass [Chrysopogon zizanioides (L.)], Punamiya, P; Datta, R; Sarkar, D; Barber, S; Patel, M; Das, P. Heavy metal hyperaccumulating plants: how and why do they do it? Pb is quite common especially in the soil of roadside fields as a result of emission from the automotive exhaust. 15,000 peer-reviewed journals. In this review, it will discuss recent advancement and potential application of plants for lead removal from the environment. In plants, Pb uptake and translocation occurs, causing toxic effects resulting in decrease of biomass production. Those are the interesting questions. Read and print from thousands of top scholarly journals. Google Classroom Facebook Twitter. Clipboard, Search History, and several other advanced features are temporarily unavailable. Epub 2019 Nov 19. [Research advances in plant lead tolerance and detoxification mechanism]. Would you like email updates of new search results? The lead tolerance of these species correlated with their water requirements. Plant defense strategies play important roles in the survival of plants as they are fed upon by many different types of herbivores, especially insects, …  |  A small number of genes are probably producing the major Wetland plants such as Typha latifolia and Phragmites australis have been indicated to show a lack of evolution of metal tolerance in metal-contaminated populations. Many houses today were once painted with paints that contained lead ‑ unless the paint was removed, that paint will still be there under layers of newer paint. Lead tolerance in plants: strategies for phytoremediation Lead tolerance in plants: strategies for phytoremediation Gupta, D.; Huang, H.; Corpas, F. 2013-01-22 00:00:00 Environ Sci Pollut Res (2013) 20:2150–2161 DOI 10.1007/s11356-013-1485-4 REVIEW ARTICLE D. K. Gupta & H. G. Huang & F. J. Corpas Received: 22 October 2012 /Accepted: 9 January 2013 /Published online: 22 … Phytoextraction of lead by plants Phytoremediation has been suggested as an inexpensive and Its tolerance and accumulation of zinc, lead, copper, iron, manganese and magnesium as well as sulphur have been studied and compared with similar phenomena in two other local metal-tolerant grasses, Cynodon dactylon and Trachypogon spicatus, as well as Author information: (1)Biology Department and Croucher Institute for Environmental Sciences, Hong Kong Baptist University, Kowloon, Hong Kong SAR, PR China. Plant disease resistance protects plants from pathogens in two ways: by pre-formed structures and chemicals, and by infection-induced responses of the immune system. Analysis of transgenic Arabidopsis thaliana plants overexpressing YCF1 showed that YCF1 is functionally active and that the plants have enhanced tolerance of Pb(II) and Cd(II) and accumulated greater amounts of these metals. -. OH), which are necessary for the correct functioning of plants; however, in excess they caused damage to biomolecules, such as membrane lipids, proteins, and nucleic acids among others. over 18 million articles from more than Snowden and Wheeler (1993) have indicated that Fe 2+ tolerance in wetland plants is significantly related to root porosity, root oxidizing ability and flood tolerance. Lead (Pb) is naturally occurring element whose distribution in the environment occurs because of its extensive use in paints, petrol, explosives, sludge, and industrial wastes. Environ Sci Pollut Res Int. National Center for Biotechnology Information, Unable to load your collection due to an error, Unable to load your delegates due to an error. 2020 Feb 10;21(1):139. doi: 10.1186/s12864-020-6558-4. DeepDyve's default query mode: search by keyword or DOI. Uptake and accumulation of lead by plants from the Bo Ngam lead mine area in Thailand, Rotkittikhun, P; Kruatrachue, M; Chaiyarat, R; Ngernsansaruay, C; Pokethitiyook, P; Paijitprapaporn, A; Baker, AJM, Characterization of a lead hyperaccumulator shrub, Sesbania drummondii, Sahi, SV; Bryant, NL; Sharma, NC; Singh, SR, Saifullah, ME; Qadir, M; Caritat, P; Tack, FMG; Laing, G; Zia, MH, Chelant-aided enhancement of lead mobilization in residential soils, Sarkar, D; Andra, SS; Saminathan, SKM; Datta, R, Distribution and toxic effects of cadmium and lead on maize roots, Characterization of plant growth-promoting Bacillus edaphicus NBT and its effect on lead uptake by Indian mustard in a lead-amended soil, Characterization of heavy metal-resistant endophytic bacteria from rape (Brassica napus) roots and their potential in promoting the growth and lead accumulation of rape, Sheng, XF; Xia, JJ; Jiang, CY; He, LY; Qian, M, Use of vetiver and three other grasses for revegetation of Pb/Zn mine tailings: Field experiment, Shu, WS; Xia, HP; Zhang, ZQ; Lan, CY; Wong, MH, Role of nitric oxide in tolerance of plants to abiotic stress, Engineering tolerance and accumulation of lead and cadmium in transgenic plants, Song, WY; Sohn, EJ; Martinoia, E; Lee, YJ; Yang, YY; Jasinski, M; Forestier, C; Hwang, I; Lee, Y, Pb hyperaccumulation and tolerance in common buckwheat (Fagopyrum esculentum Moench), Lead, zinc, cadmium hyperaccumulation and growth stimulation in Arabis paniculata Franch, Tang, YT; Qiu, RL; Zeng, XW; Ying, RR; Yu, FM; Zhou, XY, Effects of soil amendments and EDTA on lead uptake by Chromolaena odorata: Greenhouse and field trial experiments, Tanhan, P; Pokethitiyook, P; Kruatrachue, M; Chaiyarat, R; Upatham, S, Spatial imaging and speciation of lead in the accumulator plant Sedum alfredii by microscopically focused synchrotron X-ray investigation, Tian, SK; Lu, LL; Yang, XE; Webb, SM; Du, YH; Brown, PH, The impact of EDTA on lead distribution and speciation in the accumulator Sedum alfredii by synchrotron X-ray investigation, Tian, SK; Lu, LL; Yang, XE; Huang, HG; Brown, P; Labavitch, J; Liao, HB; He, ZL, Uptake and localization of lead in corn (Zea mays L.) seedlings: a study by histochemical and electron microscopy, Study of lead phytoavailability for atmospheric industrial micronic and sub-micronic particles in relation with lead speciation, Uzu, G; Sobanska, S; Aliouane, Y; Pradere, P; Dumat, C, Zn, Cd and Pb accumulation and arbuscular mycorrhizal colonisation of pennycress Thlaspi praecox Wulf. – Springer Journals. Environ Sci Pollut Res Int. (Brassicaceae) from the vicinity of a lead mine and smelter in Slovenia, Nitric oxide reduces aluminum toxicity by preventing oxidative stress in the roots of Cassia tora L, Effect of indole-3-acetic acid on lead accumulation in maize (Zea mays L.) seedlings and the relevant antioxidant response, Wang, H; Shan, X; Wen, B; Owens, G; Fang, J; Zhang, S, The effect of EDDS addition on the phytoextraction efficiency from Pb contaminated soil by Sedum alfredii Hance, Wang, X; Wang, Y; Mahmood, Q; Islam, E; Jin, XF; Li, TQ; Yang, XE; Liu, D, Lead-contaminated soil induced oxidative stress, defense response and its indicative biomarkers in roots of Vicia faba seedlings, Wang, C; Tian, Y; Wang, X; Geng, J; Jiang, J; Yu, H; Wang, C, Evaluation of Pb phytoremediation potential in Buddleja asiatica and B-paniculata, Waranusantigul, P; Kruatrachue, M; Pokethitiyook, P; Auesukaree, C, Isolation and characterization of lead-tolerant Ochrobactrum intermedium and its role in enhancing lead accumulation by Eucalyptus camaldulensis, Waranusantigul, P; Lee, H; Kruatrachue, M; Pokethitiyook, P; Auesukaree, C, Phytoremediation: plant-endophyte partnerships take the challenge, Weyens, N; Lelie, D; Taghavi, S; Vangronsveld, J, Ca2+-dependent plant response to Pb2+ is regulated by LCT1, Wojas, S; Ruszczynska, A; Bulska, E; Wojciechowski, M; Antosiewicz, DM, Sorghum roots are inefficient in uptake of EDTA-chelated lead, Signal interaction between nitric oxide and hydrogen peroxide in heat shock induced hypericin production of Hypericum perforatum suspension cells, Sedum alfredii H: a new Zn hyperaccumulating plant first found in China, Lead-induced nitric oxide generation plays a critical role in lead uptake by Pogonatherum crinitum root cells, Yu, Q; Sun, L; Jin, H; Chen, Q; Chen, Z; Xu, M, Effects of EDTA on phytoextraction of heavy metals (Zn, Mn and Pb) from sludge-amended soil with Brassica napus, Zaier, H; Ghnaya, T; Ben Rejeb, K; Lakhdar, A; Rejeb, S; Jemal, F, Comparative study of Pb-phytoextraction potential in Sesuvium portulacastrum and Brassica juncea: Tolerance and accumulation, Zaier, H; Ghnaya, T; Lakhdar, A; Baioui, R; Ghabriche, R; Mnasri, M; Sghair, S; Lutts, S; Abdelly, C, Characterization of lead-resistant and ACC deaminase-producing endophytic bacteria and their potential in promoting lead accumulation of rape, Zhang, YF; He, LY; Chen, ZJ; Zhang, WH; Wang, QY; Qian, M; Sheng, XF, Effects of lead and EDTA-assisted lead on biomass, lead uptake and mineral nutrients in Lespedeza chinensis and Lespedeza davidii, Zheng, LJ; Liu, XM; Lutz-Meindl, U; Peer, T, Lead tolerance in plants: strategies for phytoremediation, http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png, Environmental Science and Pollution Research, http://www.deepdyve.com/lp/springer-journals/lead-tolerance-in-plants-strategies-for-phytoremediation-upKdUaJMys. 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