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Application of Enzyme Activity Probes to Characterize Aerobic Microorganisms PDF

25 Pages·2007·0.73 MB·English
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Preview Application of Enzyme Activity Probes to Characterize Aerobic Microorganisms

Application of Enzyme Activity Probes to Characterize Aerobic Microorganisms in Groundwater at PGDP, INL, & elsewhere M. Hope Lee Biodegradation / Bioremediation of TCE TCE can be degraded by bacteria • Several different mechanisms, including two primary ones: • 1. Anaerobic reductive dechlorination (ARD) 2. Aerobic cometabolic oxidation Bioremediation technology can be based on microbial • degradation capacity Tools are needed to detect appropriate enzyme systems and • assess their activity in the environment Molecular Data: What do they tell you? Do any bacteria in the sample carry the genes for contaminant (TCE) degradation? (DNA Probe, e.g. QPCR) YES NO Are the degradative genes expressed? No (mRNA Probe) On-going TCE degradation YES NO Are the TCE-degrading enzymes active? No (Enzyme Activity Probe) On-going TCE degradation YES NO No TCE On-going TCE degradation degradation Microbial metabolism, cometabolism, and enzyme activity probes fluorogenic TCE methane O 2 substrate Methane Monooxygenase * * * Cometa- Energy e- Aerobic bolism production respiration fluorescent oxidized TCE product epoxide product H O 2 * Other enzymes include propane, ammonium, toluene oxygenases, etc. What is an Enzyme Activity Probe? Methane Toluene Probe TCE Cell Labeled cell Other natural substrates that support TCE oxidation: benzene, ammonia, phenol Representative Enzyme Probes and Target Systems: N CH CH C 3 C toluene phenylacetylene trans-cinnamonitrile (natural (2,3-TDO) (2,3-TDO) substrate) (2-TMO, 3-TMO) O O O CH OH C coumarin (sMMO) OH C CH 3-hydroxy-phenylacetylene 3-ethynyl-benzoate (2-TMO) (side chain MO) ( 3-TMO) Results of applying Enzyme Activity Probes to groundwater Negative probe response Total bacterial cell count Positive probe response Control Assays Purpose: To ensure that the measured degradation is attributable to the organisms of interest; verify that either the sMMO or toluene enzymes are responsible for any observed positive response to the assay. Acetylene: irreversible inhibitor of sMMO (a) Methane: competitive reversible inhibitor (b) 1-pentyne (3.5%): irreversible inhibitor for the 2-monooxygenase pathways (c) 3-hexyne (2%): irreversible inhibitor for the 3-and (d) 4-monooxygenases Phenylacetylene (10-15%): dioxygenase (e) DNA… (f) Additional Control Assays To offer supporting evidence for the enzyme activity probes. PCR characterize the potential of the microbial community TOD: toluene 2,3-dioxygenase TOL: xylene monooxygenase RMO: toluene-3,-4-monooxygenase PHE: toluene-2, -3, -4-monooxygenase sMMO: mmoX (f882 & r1403) Universal: (8F and 907R). FISH characterize the activity of the microbial community Eubacteria Cytophaga-Flavobacterium (most common toluene degrading organisms), type I and type II methanotrophs component B of the sMMO … Common Myths, dismissed Early studies (1980-mid-90s) Recent studies have shown that under determined that: natural conditions: (a) Cometabolism requires a natural (a) Non-aromatic substrates can induce substrate induction (methane, activity (naturally occurring phenol, other aromatic) phenolic compounds e.g. humics); TCE itself can induce cometabolic (b) Cometabolic degradation of TCE activity results in TCE epoxides and/or oxygen radicals which inactivate (b) Studies have shown that TCE the active site of the oxygenase epoxides do not cause significant decreases in TCE cometabolizing (c) Growth on non-inducing abilities or rates substrates will result in an enzyme that will not cometabolize (c) Growth on non-inducing substrates chlorinated solvents (TCE) results in TCE degradation Heald and Jenkins, 1994; McClay et al., 1995; Leahy et al., 1996; Shingleton et al., 1998; Ryoo et al., 2000, 2001; Lee et al., 2002; Yeager et al., 2004

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Aerobic cometabolic oxidation. • Bioremediation technology can be based on microbial degradation capacity. • Tools are needed to detect appropriate
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