砷抗性细菌的耐金属性及其在 Pb 污染土壤中促进蜈蚣草生长的能力。

Metal tolerance of arsenic-resistant bacteria and their ability to promote plant growth of Pteris vittata in Pb-contaminated soil.

机构信息

Research Center for Soil Contamination and Environmental Remediation, Southwest Forestry University, Kunming 650224, China; Soil and Water Science Department, University of Florida, Gainesville, FL 32611, USA; Institute of Environmental Sciences and Engineering, School of Civil and Environmental Engineering, National University of Sciences and Technology, Islamabad 44000, Pakistan.

Soil and Water Science Department, University of Florida, Gainesville, FL 32611, USA; Institute of Pure and Applied Biology, Bahauddin Zakariya University, Multan 60800, Pakistan.

出版信息

Sci Total Environ. 2019 Apr 10;660:18-24. doi: 10.1016/j.scitotenv.2019.01.013. Epub 2019 Jan 3.

DOI:10.1016/j.scitotenv.2019.01.013

PMID:30639714

Abstract

Soils contaminated with Pb and As are difficult to remediate. In this study, the utility of coupling As-hyperaccumulator Pteris vittata with metal-resistant rhizobacteria was explored. Siderophore-producing and P-solubilizing As-resistant bacteria from the P. vittata rhizosphere were screened for resistance to multiple metals. Results indicated Pseudomonas spp. strain PG-12 was most efficient in resisting multiple metals, i.e., up to 0.6 mM Cd and 10 mM Pb. Amplification of gene fragments encoding various metal efflux transporters (PbrA and CadA2) from genomic DNA of PG-12 suggested that metal efflux might play a role in its metal resistance and detoxification. In addition, PG-12 produced significant levels of plant growth hormones including 17.4 μg mL indole acetic acid and 3.54 μg mL gibberellin. P. vittata sporophytes inoculated with PG-12 were grown in Pb-contaminated medium and exhibited improved growth, increased P uptake, and reduced Pb uptake into plant tissue compared to the control. Results demonstrated that viable PG-12 cells were responsible for Pb immobilization and plant growth enhancement in P. vittata. The ability of PG-12 cells to solubilize P and display resistance to multiple metals combined with the production of plant hormones indole acetic acid and gibberellin make PG-12 a suitable candidate for plant growth promotion in metal-contaminated soil.

摘要

受 Pb 和 As 污染的土壤难以修复。在这项研究中，探索了将 As 超积累植物蜈蚣草与耐金属根际细菌相耦合的应用。从蜈蚣草根际筛选出具有产铁载体和溶磷能力且能耐受多种金属的耐砷细菌。结果表明，假单胞菌（Pseudomonas spp.）PG-12 菌株对多种金属的抗性最强，即能耐受高达 0.6 mM Cd 和 10 mM Pb。PG-12 基因组 DNA 中编码各种金属外排转运蛋白（PbrA 和 CadA2）的基因片段的扩增表明，金属外排可能在其金属抗性和解毒中发挥作用。此外，PG-12 产生了大量的植物生长激素，包括 17.4 μg/mL 的吲哚乙酸和 3.54 μg/mL 的赤霉素。将 PG-12 接种到蜈蚣草的孢子体中，使其在 Pb 污染的培养基中生长，与对照组相比，表现出更好的生长、增加的 P 吸收以及减少的 Pb 向植物组织中的吸收。结果表明，存活的 PG-12 细胞负责 Pb 的固定和蜈蚣草的生长增强。PG-12 细胞溶解 P 的能力和对多种金属的抗性以及产生植物激素吲哚乙酸和赤霉素，使 PG-12 成为受金属污染土壤中植物生长促进的合适候选物。

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砷抗性细菌的耐金属性及其在 Pb 污染土壤中促进蜈蚣草生长的能力。

Metal tolerance of arsenic-resistant bacteria and their ability to promote plant growth of Pteris vittata in Pb-contaminated soil.

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