Arousing sleeping genes: shifts in secondary metabolism of metal tolerant actinobacteria under conditions of heavy metal stress

Haferburg, Götz; Groth, Ingrid; Möllmann, Ute; Kothe, Erika; Sattler, Isabel

doi:10.1007/s10534-008-9157-4

Cited by 44 publications

(35 citation statements)

References 25 publications

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“…Molecular structures and functional groups of many antibiotics and other bacterial secondary metabolites suggest a potential to complex trace elements (Gräfe and Radics, 1986). In trace element tolerant bacteria the addition of trace elements to culture media can trigger synthesis of various secondary metabolites (Haferburg et al., 2009; Sprocati et al., 2006). Haferburg et al.…”

Section: Mechanisms Involved In Trace Element Mobilization By Microbesmentioning

confidence: 99%

The role of plant-associated bacteria in the mobilization and phytoextraction of trace elements in contaminated soils

Sessitsch

Kuffner

Kidd

et al. 2013

Soil Biology and Biochemistry

608

253

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Phytoextraction makes use of trace element-accumulating plants that concentrate the pollutants in their tissues. Pollutants can be then removed by harvesting plants. The success of phytoextraction depends on trace element availability to the roots and the ability of the plant to intercept, take up, and accumulate trace elements in shoots. Current phytoextraction practises either employ hyperaccumulators or fast-growing high biomass plants; the phytoextraction process may be enhanced by soil amendments that increase trace element availability in the soil. This review will focus on the role of plant-associated bacteria to enhance trace element availability in the rhizosphere. We report on the kind of bacteria typically found in association with trace element – tolerating or – accumulating plants and discuss how they can contribute to improve trace element uptake by plants and thus the efficiency and rate of phytoextraction. This enhanced trace element uptake can be attributed to a microbial modification of the absorptive properties of the roots such as increasing the root length and surface area and numbers of root hairs, or by increasing the plant availability of trace elements in the rhizosphere and the subsequent translocation to shoots via beneficial effects on plant growth, trace element complexation and alleviation of phytotoxicity. An analysis of data from literature shows that effects of bacterial inoculation on phytoextraction efficiency are currently inconsistent. Some key processes in plant–bacteria interactions and colonization by inoculated strains still need to be unravelled more in detail to allow full-scale application of bacteria assisted phytoremediation of trace element contaminated soils.

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Section: Mechanisms Involved In Trace Element Mobilization By Microbesmentioning

confidence: 99%

The role of plant-associated bacteria in the mobilization and phytoextraction of trace elements in contaminated soils

Sessitsch

Kuffner

Kidd

et al. 2013

Soil Biology and Biochemistry

608

253

View full text Add to dashboard Cite

show abstract

“…Several studies are being carried out for bioremediation of metals by Actinobacteria, on zinc (Attwa and El Awady, 2011), boron (Amoroso et al, 2013), nickel (Haferburg et al, 2008(Haferburg et al, , 2009, and cadmium (Siñeriz et al, 2009), among others.…”

Section: Bioremediation Of Heavy Metalsmentioning

confidence: 99%

Role of Actinobacteria in Bioremediation

Polti

Aparicio

Benimeli

et al. 2014

Microbial Biodegradation and Bioremediation

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“…Apart from co-cultivation and genomic approaches, challenging microorganisms through culture conditions and external cues have been commonly known as an effective way of triggering ''cryptic'' biosynthetic pathways to yield ''cryptic natural products'' . Heavy metal ions, as one of the most important nutritional and environmental factors, may not only impact the quantity of a certain compound but also the general metabolic profile of an organism (Haferburg et al 2009). Therefore, we hypothesized that Cu 2?…”

Section: Discussionmentioning

confidence: 99%

Cu(II): a “signaling molecule” of the mangrove endophyte Fusarium oxysporum ZZF51?

et al. 2010

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We previously reported the isolation of Cu-fusaric acid (Cu-FA) complex from the mangrove endophyte Fusarium oxysporum ZZF51. In this study, we explored the mechanism of Cu-FA production in the strain ZZF51 by comparing with that of another endophyte Fusarium sp. B2, which produced FA but not Cu-FA in the same culture condition. The results allowed us to hypothesize that Cu(2+) may act as a "signaling molecule" to awaken the silent FA biosynthetic genes in ZZF51, inducing intracellular production of FA followed by chelation with Cu(2+). This signaling network was triggered specifically by Cu(2+) and may be interfered by other metal ions.

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Arousing sleeping genes: shifts in secondary metabolism of metal tolerant actinobacteria under conditions of heavy metal stress

Cited by 44 publications

References 25 publications

The role of plant-associated bacteria in the mobilization and phytoextraction of trace elements in contaminated soils

The role of plant-associated bacteria in the mobilization and phytoextraction of trace elements in contaminated soils

Role of Actinobacteria in Bioremediation

Cu(II): a “signaling molecule” of the mangrove endophyte Fusarium oxysporum ZZF51?

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