Mechanisms to cope with arsenic or cadmium excess in plants

被引:677
|
作者
Verbruggen, Nathalie [1 ]
Hermans, Christian [1 ]
Schat, Henk [2 ]
机构
[1] Univ Libre Bruxelles, Lab Physiol & Genet Mol Plantes, Fac Sci, B-1050 Brussels, Belgium
[2] Vrije Univ Amsterdam, Inst Mol & Cellular Biol, Fac Earth & Life Sci, NL-1081 HV Amsterdam, Netherlands
来源
CURRENT OPINION IN PLANT BIOLOGY | 2009年 / 12卷 / 03期
关键词
METAL HYPERACCUMULATION; PHYTOCHELATIN SYNTHASE; ARABIDOPSIS-THALIANA; ENGINEERING TOLERANCE; ABC TRANSPORTER; ACCUMULATION; OVEREXPRESSION; METABOLISM; REDUCTION; GENES;
D O I
10.1016/j.pbi.2009.05.001
中图分类号
Q94 [植物学];
学科分类号
071001 ;
摘要
The metalloid arsenic and the heavy metal cadmium have no demonstrated biological function in plants. Both elements are highly toxic and of major concern with respect to their accumulation in soils, in the food-chain or in drinking water. Arsenate is taken up by phosphate transporters and rapidly reduced to arsenite, As(III). In reducing environments, As(III) is taken up by aquaporin nodulin 26-like intrinsic proteins. Cd2+ enters the root via essential metal uptake systems. As(III) and Cd2+ share some similarity between their toxicology and sequestration machineries. Recent progress in understanding the mechanisms of As and Cd uptake and detoxification is presented, including the elucidation of why rice takes up so much arsenic from soil and of mechanisms of As and Cd hypertolerance.
引用
收藏
页码:364 / 372
页数:9
相关论文
共 50 条
  • [41] Toxic Effect of Cadmium, Lead, and Arsenic on the Sertoli Cell: Mechanisms of Damage Involved
    Ramos-Trevino, Juan
    Bassol-Mayagoitia, Susana
    Anselmo Hernandez-Ibarra, Jose
    Ruiz-Flores, Pablo
    Nava-Hernandez, Martha P.
    DNA AND CELL BIOLOGY, 2018, 37 (07) : 600 - 608
  • [42] Mixed bacteria passivation for the remediation of arsenic, lead, and cadmium: Medium optimization and mechanisms
    Peng, Cheng
    Zhao, Xuan
    Ji, Xiaowen
    Wu, Jinhong
    Liang, Weiyu
    Song, Huihui
    Zhang, Wei
    Wang, Xuedong
    PROCESS SAFETY AND ENVIRONMENTAL PROTECTION, 2023, 170 : 720 - 727
  • [43] Global Fitness Profiling Identifies Arsenic and Cadmium Tolerance Mechanisms in Fission Yeast
    Guo, Lan
    Ganguly, Abantika
    Sun, Lingling
    Suo, Fang
    Du, Li-Lin
    Russell, Paul
    G3-GENES GENOMES GENETICS, 2016, 6 (10): : 3317 - 3333
  • [44] Anatomical and Physiological Mechanisms of Water Hyacinth Plants to Arsenic Contamination Tolerance
    Pereira, F. J.
    Castro, E. M.
    Oliveira, C.
    Pires, M. F.
    Pasqual, M.
    PLANTA DANINHA, 2011, 29 (02) : 259 - 267
  • [45] Arsenic toxicity in plants: Cellular and molecular mechanisms of its transport and metabolism
    Farooq, Muhammad A.
    Islam, Faisal
    Ali, Basharat
    Najeeb, Ullah
    Mao, Bizeng
    Gill, Rafaqat A.
    Yan, Guijun
    Siddique, Kadambot H. M.
    Zhou, Weijun
    ENVIRONMENTAL AND EXPERIMENTAL BOTANY, 2016, 132 : 42 - 52
  • [46] Engineering plants to cope with metals
    Moffat, AS
    SCIENCE, 1999, 285 (5426) : 369 - 370
  • [47] HOW PLANTS COPE WITH STRESS
    MOFFAT, AS
    SCIENCE, 1991, 254 (5032) : 655 - 655
  • [48] Arsenic and mercury tolerance and cadmium sensitivity in Arabidopsis plants expressing bacterial γ-glutamylcysteine synthetase
    Li, YJ
    Dhankher, OP
    Carreira, L
    Balish, RS
    Meagher, RB
    ENVIRONMENTAL TOXICOLOGY AND CHEMISTRY, 2005, 24 (06) : 1376 - 1386
  • [49] Strategies in a metallophyte species to cope with manganese excess
    Sabina Rossini-Oliva
    Maria Manuela Abreu
    Eduardo Oscar Leidi
    Environmental Geochemistry and Health, 2021, 43 : 1523 - 1535
  • [50] Strategies in a metallophyte species to cope with manganese excess
    Rossini-Oliva, Sabina
    Abreu, Maria Manuela
    Leidi, Eduardo Oscar
    ENVIRONMENTAL GEOCHEMISTRY AND HEALTH, 2021, 43 (04) : 1523 - 1535
12345