Arsenic toxicity in Acacia mangium willd. and mimosa Caesalpiniaefolia benth. seedlings

Cipriani, H. N.; Dias, Luiz Eduardo; Costa, Maurício Dutra; Campos, Naiara Viana; Azevedo, Aristéa Alves; Gomes, Roberto Junio; Fialho, Izabela Ferreira; Amezquita, Sandra Patricia Montealegre

doi:10.1590/s0100-06832013000500031

Cited by 8 publications

(9 citation statements)

References 27 publications

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“…However, no leaves were seen on plants grown on 1,000 and 1,500 mg kg −1 of arsenic indicating the phytotoxicity effect of high arsenic concentrations toward Acacia mangium . Previous work by Cipriani et al (2013) observed a phytotoxicity effect as the soil concentration of arsenic increased to 400 mg kg −1 . The difference could be due to the arsenic compound used in that work, which was arsenic trioxide (As 2 O 3 ) instead of sodium arsenate (Na 3 AsO 4 ) used in this study.…”

Section: Resultsmentioning

confidence: 87%

“…Acacia has a relatively high biomass production which also allows Acacia to be used for bioenergy production (Gasol et al, 2010), thus adding an economical option for this species to be used post‐phytoremediation. Previous work by Cipriani et al (2013) found that Acacia mangium could survive on soil dosed with up to 400 mg kg −1 of arsenic with higher concentrations of arsenic found in the roots compared with shoots. However, to date, no work has been done to investigate the uptake and survivability of Acacia mangium grown on mine wastes containing high concentrations of arsenic.…”

Section: Introductionmentioning

confidence: 91%

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Phytoremediation of Arsenic in Mine Wastes by Acacia mangium

Rosli

Harumain

Zulkalam

et al. 2021

Remediation Journal

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This study explored the potential of Acacia mangium to remediate arsenic present in mine wastes and to determine the remediation mechanism of this plant for removing arsenic. A preliminary test using soil spiked with various arsenic concentrations showed that Acacia mangium was able to survive on arsenic‐contaminated soil with concentrations up to 500 mg kg−1 arsenic. Ex situ phytoremediation studies using mine wastes containing approximately 790 mg kg−1 arsenic also showed no toxicity effect on Acacia mangium throughout 5 months of treatment. Bioconcentration and translocation factors indicate that Acacia mangium utilizes phytostabilization as its main mechanism to uptake arsenic into the plant tissues. The use of the chemical lixiviants monoammonium phosphate and citric acid was also found to increase the translocation of arsenic from roots to stems of Acacia mangium with a 12‐ and six‐fold increase, respectively, compared with the un‐dosed plants. Further speciation analysis revealed that arsenic in the form of arsenate was the only arsenic species detected in the stems after being amended with monoammonium phosphate; thereby, suggesting a sensible strategy for more efficient targeted arsenic phytoremediation by Acacia mangium.

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Section: Resultsmentioning

confidence: 87%

Section: Introductionmentioning

confidence: 91%

Phytoremediation of Arsenic in Mine Wastes by Acacia mangium

Rosli

Harumain

Zulkalam

et al. 2021

Remediation Journal

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“…types and quantities of organic acids into the rhizosphere, which may enhance the mobility of metals and their uptake by roots, explaining the immobilization of Cr, Ni and Pb in plant biomass. In addition, the higher content of Cr and Pb in RS and Ni in DS than in plant biomass could be related to the physiological character of Acacia spp., which here seems to exclude a metal in its shoot tissue (Kabas et al, 2017;Majid et al, 2012;Mohd et al, 2013;Cipriani et al, 2013).…”

Section: P Corethrurus Earthworm and A Mangium Interaction On Phytomentioning

confidence: 72%

“…This emphasizes that Acacia may possess metal exclusion strategy, which probably depend to the nature of the metal. The bioconcentration factors (BCF) ([metal]plant biomass/[metal]soil) were BCF <0.1 under CNi and CI treatments (Table 2), which were indicated that Acacia are not hyperaccumulator plant as demonstrated by Cipriani et al (2013). The findings did not differ from those of various studies indicating that Acacia is able to tolerate and uptake heavy metal in its tissues and therefore could be suitable for phytostabilization of metalcontaminated sites (Majid et al, 2012;Mohd et al, 2013).…”

Section: Phytoremediation Potential Of a Mangium In Contaminated Soilmentioning

confidence: 94%

Enhancement of phytoremediation efficiency of Acacia mangium using earthworms in metal-contaminated soil in Bonoua, Ivory Coast

Jeanne¹,

Faustin²,

Thierry³

et al. 2019

Afr. J. Biotechnol.

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In this paper, the impact of Pontoscolex corethrurus on Acacia mangium growth and its phytoremediation efficiency in metal-contaminated soils were studied in a greenhouse pot culture under four treatments: non contaminated soil-non inoculated, control (C); non contaminated soilinoculated (NcI); contaminated soil-non inoculated (CNi); contaminated soil-inoculated (CI). The results showed that A. mangium growth performance and its Pb, Ni and Cr uptake were significantly (P<0.05) increased under CI treatment. Under CNi treatment, A. mangium uptake more Ni and Cr content in root tissue than in shoot tissue. But for Pb, the greater content was noted in shoot tissue. A. mangium noninoculated preferentially promoted the phytoimmobilization process for Cr and Ni and the phytoextraction process for Pb. However, under CI treatment, the greater content of potential toxic elements (Cr, Ni and Pb) was observed in roots tissue and A. mangium inoculated promoted the phytoimmobilization process for Cr, Ni and Pb. In addition, the phytoextraction efficiency (PEE) of A. mangium increase (ranged 0.1% under CNi to 14% under CI treatment. This study indicates that earthworms can be used to enhance the phytoremediation efficiency of metal-tolerant plant species in contaminated soil.

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“…Although the contaminants are not removed from the site, phytostabilization allows reducing the risk of erosion and the leaching of pollutants, preventing groundwater phytotoxicity Ma, 2013;De Oliveira et al, 2014). On the other hand, species unable to tolerate or hyperaccumulate As, such as Acácia mangium and Mimosa caesalpiniaefolia (Cipriani et al, 2013), may experience phytotoxicity, affecting their development and causing death. In rice, As uptake occurs in the form of arsenite as well as arsenate, depending on the cultivation conditions: arsenite prevails in rice crops grown in flooded areas, while arsenate prevails under aerobic conditions.…”

Section: Phytoremediation Of Soils Contaminated With Arsenicmentioning

confidence: 99%

Arsenic: behavior in the environment, plant uptake mechanisms and human health risks

Oliveira¹,

Massahud²,

Souza³

et al. 2014

RCA

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Negative impacts caused by arsenic (As) in soils and waters have attracted public interest due to contamination of ecosystems and human populations dwelling in the vicinity of its generating sources. The main anthropogenic sources of such contamination result from the oxidation of sulfide residues containing arsenopyrite in piles of mining tailings and the leaching of soils with high background of As. This contamination presents serious consequences to the functional components of ecosystems. Through plant uptake, this element can enter the food chain and cause several health problems, even at low exposure (<10 mgL

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Arsenic toxicity in Acacia mangium willd. and mimosa Caesalpiniaefolia benth. seedlings

Cited by 8 publications

References 27 publications

Phytoremediation of Arsenic in Mine Wastes by Acacia mangium

Phytoremediation of Arsenic in Mine Wastes by Acacia mangium

Enhancement of phytoremediation efficiency of Acacia mangium using earthworms in metal-contaminated soil in Bonoua, Ivory Coast

Arsenic: behavior in the environment, plant uptake mechanisms and human health risks

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