Enhanced phytoremediation of toxic metals by inoculating endophytic Enterobacter sp. CBSB1 expressing bifunctional glutathione synthase

Enhanced phytoremediation of toxic metals by inoculating endophytic Enterobacter sp. CBSB1 expressing bifunctional glutathione synthase

•The glutathione synthase gene was introduced into endophytic Enterobacter sp.•The GSH contents of shoots inoculated with engineered strain increased.•The phytoremediation efficacy of Cd and Pb by B. juncea increased.•Engineered strain showed potentials in remediation for complex contamination. To e...

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Bibliographic Details
Published in:Journal of hazardous materials Vol. 267; pp. 17 - 20
Main Authors: Qiu, Zhiqi, Tan, Hongming, Zhou, Shining, Cao, Lixiang
Format: Journal Article
Language:English
Published: Kidlington Elsevier B.V 28-02-2014
Elsevier
Subjects:
Applied sciences
Bioremediation
Cadmium - analysis
Endophyte
Endophytes - enzymology
Enterobacter - enzymology
Enterobacter - genetics
Environmental Restoration and Remediation - methods
Exact sciences and technology
Glutathione
Glutathione - metabolism
Glutathione Synthase - genetics
Glutathione Synthase - metabolism
Lead - analysis
Metal
Mustard Plant - genetics
Mustard Plant - metabolism
Plants - metabolism
Plasmids
Pollution
Seedlings
Soil Pollutants - analysis
Endophyte
Bioremediation
Metal
Glutathione
Phytoremediation
Pollution
Decontamination
Cruciferae
Dicotyledones
Angiospermae
Lead
Bacteria
Spermatophyta
Brassica juncea
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Summary:•The glutathione synthase gene was introduced into endophytic Enterobacter sp.•The GSH contents of shoots inoculated with engineered strain increased.•The phytoremediation efficacy of Cd and Pb by B. juncea increased.•Engineered strain showed potentials in remediation for complex contamination. To engineer plant–bacteria symbionts for remediating complex sites contaminated with multiple metals, the bifunctional glutathione (GSH) synthase gene gcsgs was introduced into endophytic Enterobacter sp. CBSB1 to improve phytoremediation efficiency of host plant Brassica juncea. The GSH contents of shoots inoculated with CBSB1 is 0.4μMg−1 fresh weight. However, the GSH concentration of shoots with engineered CBSB1-GCSGS increased to 0.7μMg−1 fresh weight. The shoot length, fresh weight and dry weight of seedlings inoculated with CBSB1-GCSGS increased 67%, 123%, and 160%, compared with seedlings without inoculation, respectively. The Cd and Pb concentration in shoots with CBSB1-GCSGS increased 48% and 59% compared with seedlings without inoculation, respectively. The inoculation of CBSB1 and CBSB1-GCSGS could increase the Cd and Pb extraction amounts of seedlings significantly compared with those without inoculation (P<0.05), the seedlings inoculated with CBSB1-GCSGS showed the highest Cd and Pb extraction amounts. It was concluded that the gcsgs gene introduced into Enterobacter sp. CBSB1 upgraded the phytoremediation efficacy of B. juncea. So the engineered Enterobacter sp. CBSB1-GCSGS showed potentials in remediation sites contaminated with complex contaminants by inoculating into remediating plants.
ISSN:0304-3894
1873-3336
DOI:10.1016/j.jhazmat.2013.12.043