Harnessing Rhizobia to Improve Heavy-Metal Phytoremediation by Legumes
Abstract
:1. Introduction
2. Legumes in Heavy-Metal Contaminated Areas
2.1. The Serpentine Vegetation: A Source of Legumes Evolved on Heavy-Metal Rich Soils
2.2. The Search for Heavy-Metal Tolerant Rhizobia and Their Use as Inoculants
3. Genetics and Genomics of Heavy-Metal Resistance in Symbiotic Rhizobia
4. Genomic Manipulation Strategies for Improving Legume Phytoremediation
5. Conclusions
Author Contributions
Funding
Conflicts of Interest
References
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Legume Species | Heavy-Metals in the Soil | Rhizobium Inoculant | Co-Inoculation with Other PGPR? | Evidence for Stimulation of Rhizosphere Microbiota | Type of Study | Effect | Reference |
---|---|---|---|---|---|---|---|
Glycine max | As | Bradyrhizobium sp. Per 3.61 | No | NA | Lab scale (pot) | Reduce translocation factor | [59] |
Lupinus luteus | Cu, Cd, Pb | Bradyrhizobium sp. 750 | Yes | NA | In situ | Increased metal accumulation in root | [10] |
Medicago lupulina | Cu | Sinorhizobium meliloti CCNWSX0020 | No | NA | In vitro (pot) | Increased plant growth and copper tolerance | [55] |
Medicago sativa | Cu | Sinorhizobium meliloti CCNWSX0020 | No | NA | In vitro | Increased tolerance of seedlings | [60] |
Medicago sativa | Cd | Sinorhizobium meliloti (from contaminated soil [61]) | No | NA | Lab scale (pot) | Increased Cd phytoextraction | [56] |
Medicago sativa | Zn | Sinorhizobium meliloti (from contaminated soil [61]) | No | NA | Lab scale (pot with sterile sand) | Increased Zn accumulation in root | [57] |
Medicago truncatula | Cu | Sinorhizobium medicae MA11 (genetically modified with copAB genes) | No | NA | In vitro | Increased metal accumulation in root | [54] |
Robinia pseudoacacia | Cd, Zn, Pb | Mesorhizobium loti HZ76 | No | Yes | Lab scale (pot) | Increased growth of the plant | [62] |
Sulla conoraria | Cu, Zn, Pb | Rhizobium sullae | Yes | NA | In situ | Increased soil Zn stabilization | [58] |
Vicia faba | Cu, Zn, Pb | Rhizobium sp. CCNWSX0481 | Yes | NA | In situ | Increased soil Cu stabilization | [58] |
Strain | Host Plant | Isolation Site | Method of Identification | Gene(s) | Metal(s) Tolerance | Reference |
---|---|---|---|---|---|---|
Bradhyrhizobium spp. | Serianthes calycina | Serpentine (New Caledonia) | PCR amplification, site-directed mutagenesis | cnr/nre systems | Co, Ni | [42] |
Mesorhizobium spp. | Acmispon wrangelianus | Serpentine (California) | Association mapping | Various | Ni | [79] |
Mesorhizobium metallidurans | Antyllis vulneraria | Zinc mine (France) | Cosmid library | cadA (PIB-2-type ATPase) | Zn, Cd | [82] |
Sinorhizobium meliloti 1021 | Medicago sativa | Laboratory strain | Site-directed gene deletion | nreB (SMa1641) | Ni | [25] |
Sinorhizobium meliloti 1021 | Medicago sativa | Laboratory strain | Tn5 insertion, biochemical characterization | SMa1163 (P1B-5-ATPase) | Ni, Fe | [67] |
Sinorhizobium meliloti CCNWSX0020 | Medicago lupulina | Mine tailings (China) | Site-directed gene deletion and transcriptomics | P1B-type ATPases and others | Cu, Zn | [69,70] |
Rhizobium leguminosarum bv. viciae UPM1137 | Pisum sativum | Serpentine (Italy) | Transposon mutagenesis | 14 loci (gene annotation corresponds to Rlv 3841 genome): RL2862, RL2436, RL2322, pRL110066, RL1351, RL4539, pRL90287, RL4188, RL2793, RL2100, RL0615, RL1589, pRL110071, RL1553 | Ni, Co | [83] |
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Fagorzi, C.; Checcucci, A.; DiCenzo, G.C.; Debiec-Andrzejewska, K.; Dziewit, L.; Pini, F.; Mengoni, A. Harnessing Rhizobia to Improve Heavy-Metal Phytoremediation by Legumes. Genes 2018, 9, 542. https://doi.org/10.3390/genes9110542
Fagorzi C, Checcucci A, DiCenzo GC, Debiec-Andrzejewska K, Dziewit L, Pini F, Mengoni A. Harnessing Rhizobia to Improve Heavy-Metal Phytoremediation by Legumes. Genes. 2018; 9(11):542. https://doi.org/10.3390/genes9110542
Chicago/Turabian StyleFagorzi, Camilla, Alice Checcucci, George C. DiCenzo, Klaudia Debiec-Andrzejewska, Lukasz Dziewit, Francesco Pini, and Alessio Mengoni. 2018. "Harnessing Rhizobia to Improve Heavy-Metal Phytoremediation by Legumes" Genes 9, no. 11: 542. https://doi.org/10.3390/genes9110542
APA StyleFagorzi, C., Checcucci, A., DiCenzo, G. C., Debiec-Andrzejewska, K., Dziewit, L., Pini, F., & Mengoni, A. (2018). Harnessing Rhizobia to Improve Heavy-Metal Phytoremediation by Legumes. Genes, 9(11), 542. https://doi.org/10.3390/genes9110542