Isolation of mesotrione-degrading bacteria from aquatic environments in Brazil

Pileggi, Marcos; Pileggi, Sônia Alvim Veiga; Olchanheski, Luiz Ricardo; Silva, Paulo Augusto Garbugio da; Gonzalez, Ana M. Munoz; Koskinen, W.C.; Barber, Brian L.; Sadowsky, Michael J.

doi:10.1016/j.chemosphere.2011.12.041

Cited by 45 publications

(56 citation statements)

References 27 publications

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“…Since mesotrione was marketed in 2003, few microorganisms have been reported to catabolize it (Durand et al, 2006;Batisson et al, 2009;Pileggi et al, 2012;Olchanheski et al, 2014). The detailed biodegradative pathway of mesotrione was only established with some of these microorganisms (Durand et al, 2010;Pileggi et al, 2012). Bacillus megaterium strain Mes11, isolated from soil, was able to completely and rapidly biotransform mesotrione leading to the accumulation of 2-amino-4-methylsulfonylbenzoic acid (AMBA) in the culture medium as the final product (Batisson et al, 2009).…”

Section: Introductionmentioning

confidence: 97%

“…Mesotrione, chemically derived from a natural phytotoxin produced by the bottlebrush plant Callistemon citrinus (Mitchell et al, 2001), was developed to minimize adverse effects on the environment. Since mesotrione was marketed in 2003, few microorganisms have been reported to catabolize it (Durand et al, 2006;Batisson et al, 2009;Pileggi et al, 2012;Olchanheski et al, 2014). The detailed biodegradative pathway of mesotrione was only established with some of these microorganisms (Durand et al, 2010;Pileggi et al, 2012).…”

Section: Introductionmentioning

confidence: 97%

See 1 more Smart Citation

How the edaphic Bacillus megaterium strain Mes11 adapts its metabolism to the herbicide mesotrione pressure

Bardot

Besse-Hoggan

Carles

et al. 2015

Environmental Pollution

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Section: Introductionmentioning

confidence: 97%

Section: Introductionmentioning

confidence: 97%

How the edaphic Bacillus megaterium strain Mes11 adapts its metabolism to the herbicide mesotrione pressure

Bardot

Besse-Hoggan

Carles

et al. 2015

Environmental Pollution

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“…23 The herbicide mesotrione is an agrochemical that inhibits the HPPD enzyme in plants. 20 The conventional methods for detecting and quantifying mesotrione are usually liquid chromatography coupled with UV spectroscopy, 24 mass spectrometry, 25 tandem mass spectrometry, 26 or°uorescence spectroscopy. 27 The high sensitivity of such methods, with detection limits at the level of nanograms per liter, 28 can be compared to the sensitivity of the cantilever described in this study, which detected target molecules at the level of nanograms per mL.…”

Section: Introductionmentioning

confidence: 99%

Nanomechanical Cantilever-Based Sensor: An Efficient Tool to Measure the Binding Between the Herbicide Mesotrione and 4-Hydroxyphenylpyruvate Dioxygenase

Rodrigues

Ierich

Andrade

et al. 2017

NANO

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Nanomechanical biosensors based on atomic force microscopy (AFM) cantilevers have garnered considerable attention. AFM cantilevers are devices that can detect a target either via a surface functionalization process based on immobilization through molecular adsorption, or through the selective chemical binding of a speci¯c molecule, transforming the device into a speci¯c biosensor. In this study, we demonstrate that functionalized AFM cantilevers could be used, in a process involving self-assembling layers, to create a homogeneous surface layer of the widely used herbicide mesotrione. Controlled experiments to evaluate its detection were performed, and binding between mesotrione and its target molecule, 4-hydroxyphenylpyruvate dioxygenase (HPPD), was evaluated using de°ection curves of functionalized cantilevers interacting with mesotrione. The cantilevers worked as nanomechanical sensors inside a°uid cell device, under di®erent ¶ Corresponding author. 1750079-1NANO: Brief Reports and Reviews Vol. 12, No. 7 (2017) concentrations of HPPD diluted in PBS. After evaluating increasing concentrations of HPPD, the de°ection curves showed a clear, dose-dependent pattern. The homogeneous dispersion of mesotrione on the cantilevers was assessed by confocal microscopy, and this corroborated the functionalization method. Thus, the results obtained by this functionalized cantilever presented a high e±ciency in detecting binding between HPPD and mesotrione molecules at concentrations as low as 17 ng mL À1 . In this way, as a preliminary step for a future environmental contaminants nanosensor development, the described detection method showed a suitable capability for molecular recognition at the nanoscale.

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“…125) A similar reduction was reported for the degradation of dichloran (5) 59) and mesotrione (58). 86) Although metabolites were not identified, (42) and disulfoton (48) were biodegraded by many kinds of bacteria isolated from ponds. 43) Amides, ureas and carbamates are either hydrolyzed 62,126,127) or oxidized 128,129) during their microbial degradation.…”

Section: Transformation By Enriched Community or Isolated Microbesmentioning

confidence: 83%

“…84) Novick and Alexander 85) reported a doubled yield of products through the incubation of propachlor (33) in eutrophic lake water by addition of glucose, but no microbes using (33) as carbon and energy sources could be isolated. Recently, Pileggi et al 86) isolated Pantoea ananatis from Brazilian freshwater and showed its co-metabolic activity on mesotrione (58) by varying the nutrient composition of the medium. The mineralization of propham (20) in lake water was enhanced by ca.…”

Section: Co-metabolismmentioning

confidence: 99%

Aerobic microbial transformation of pesticides in surface water

Katagi

2013

J. Pestic. Sci.

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Aerobic transformation by microbial organisms is a dissipation process of pesticides in surface water, but the corresponding information is much less available as compared with their microbial degradation in soil. Bacteria freely floating in water or associated with suspended particles are the key microorganisms degrading pesticides; their species and populations, however, depend on sites and seasons. The various factors related to pesticide properties, experimental conditions and characteristics of surface water are involved in the complex control of microbial processes. Bottom sediment and macrophytes with associated biofilms not only act as sink for pesticides but also provide the habitat for both bacteria and fungi that degrade pesticides. More understanding of each factor is necessary to utilize laboratory biodegradation data for the refined assessment of pesticide behavior in surface water.

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Isolation of mesotrione-degrading bacteria from aquatic environments in Brazil

Cited by 45 publications

References 27 publications

How the edaphic Bacillus megaterium strain Mes11 adapts its metabolism to the herbicide mesotrione pressure

How the edaphic Bacillus megaterium strain Mes11 adapts its metabolism to the herbicide mesotrione pressure

Nanomechanical Cantilever-Based Sensor: An Efficient Tool to Measure the Binding Between the Herbicide Mesotrione and 4-Hydroxyphenylpyruvate Dioxygenase

Aerobic microbial transformation of pesticides in surface water

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