Transport and survival of GFP-tagged root-colonizing microbes: Implications for rhizodegradation

Transport and survival of GFP-tagged root-colonizing microbes: Implications for rhizodegradation

Many recalcitrant organic contaminants pose unique and vast environmental challenges, potentially addressed through phytoremediation. Using molecular engineering to enhance enzymatic capabilities of root-colonizing microbes, additional contaminants can be targeted and contaminant fate can be altered...

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Bibliographic Details
Published in:European journal of soil biology Vol. 43; no. 4; pp. 224 - 232
Main Authors: Gilbertson, Amanda W., Fitch, Mark W., Burken, Joel G., Wood, Thomas K.
Format: Journal Article Conference Proceeding
Language:English
Published: Paris Elsevier Masson SAS 01-07-2007
Editions scientifiques et médicales Elsevier
Subjects:
Agronomy. Soil science and plant productions
Biochemistry and biology
Biological and medical sciences
Chemical, physicochemical, biochemical and biological properties
Fundamental and applied biological sciences. Psychology
GFP
GMM
Physics, chemistry, biochemistry and biology of agricultural and forest soils
Phytoremediation
Recombinant bacteria
Rhizoremediation
Rhizosphere
Soil science
GFP
Rhizosphere
Rhizoremediation
Recombinant bacteria
GMM
Phytoremediation
Fluorescent tracer
Root
Survival
Bacteria
Soil science
Microorganism
Transport
Colonization
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Summary:Many recalcitrant organic contaminants pose unique and vast environmental challenges, potentially addressed through phytoremediation. Using molecular engineering to enhance enzymatic capabilities of root-colonizing microbes, additional contaminants can be targeted and contaminant fate can be altered to promote rhizosphere degradation of contaminants, which is desired among phytoremediation mechanisms. In this paper, rhizosphere bacteria were tagged with the green fluorescent protein genes ( gfp) in order to monitor colonization, survival, and transport within the root zone and to evaluate the effectiveness of visual identification using GFP. Transport of the gfp-tagged root colonizers was observed to a one meter depth against a hydraulic gradient in less than 180 days revealing that plant's roots clearly enhanced movement of the recombinant strains through the rhizosphere although proliferation of the recombinant bacteria was not substantial. Over a 49-day plant growth period survival and colonization by the recombinant bacteria was monitored in soil and on roots, revealing a decreasing trend. Overall, this study showed that enhanced rhizosphere degradation is mechanistically promising, but that the specific plant-microbe pairing studied herein was not ideal. Using GFP for visual identification is not 100% efficient but provides a quick and simple marker to detect tagged microorganisms. Selection of root colonizing organisms to be engineered in enhanced rhizoremediation is a critical step in advancing the technology.
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ISSN:1164-5563
DOI:10.1016/j.ejsobi.2007.02.005