Mineralization of atrazine in agricultural soil: Inhibition by nitrogen

Garcés, Rosa Angélica Guillén; Hansen, Anne M.; Afferden, Manfred van

doi:10.1897/06-328r.1

Cited by 22 publications

(7 citation statements)

References 27 publications

(36 reference statements)

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“…The influence of nitrogen compounds on the efficiency of atrazine elimination has been a focus of research, since most degrading strains use atrazine as a nitrogen source and agricultural soils are often rich in nitrogen due to routine fertilization. Numerous studies have established that nitrogen amendments have a negative effect on atrazine biodegradation by indigenous microbial populations in soils (Entry et al, 1993;Alvey and Crowley, 1995;Abdelhafid et al, 2000a,b;Guillén Garcés et al, 2007). The effect of nitrogen sources on atrazine degradation has also been tested in pure cultures of several degrading strains (Bichat et al, 1999;Gebendinger and Radosevich, 1999;García-González et al, 2003).…”

Section: Effect Of Environmental Nitrogen On Atrazine Degradationmentioning

confidence: 99%

Atrazine biodegradation in the lab and in the field: enzymatic activities and gene regulation

Govantes

Porrúa

García-González

et al. 2009

Microbial Biotechnology

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SummaryAtrazine is an herbicide of the s‐triazine family that is used primarily as a nitrogen source by degrading microorganisms. While many catabolic pathways for xenobiotics are subjected to catabolic repression by preferential carbon sources, atrazine utilization is repressed in the presence of preferential nitrogen sources. This phenomenon appears to restrict atrazine elimination in nitrogen‐fertilized soils by indigenous organisms or in bioaugmentation approaches. The mechanisms of nitrogen control have been investigated in the model strain Pseudomonas sp. ADP. Expression of atzA, atzB ad atzC, involved in the conversion of atrazine in cyanuric acid, is constitutive. The atzDEF operon, encoding the enzymes responsible for cyanuric acid mineralization, is a target for general nitrogen control. Regulation of atzDEF involves a complex interplay between the global regulatory elements of general nitrogen control and the pathway‐specific LysR‐type regulator AtzR. In addition, indirect evidence suggests that atrazine transport may also be a target for nitrogen regulation in this strain. The knowledge about regulatory mechanisms may allow the design of rational bioremediation strategies such as biostimulation using carbon sources or the use of mutant strains impaired in the assimilation of nitrogen sources for bioaugmentation.

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Section: Effect Of Environmental Nitrogen On Atrazine Degradationmentioning

confidence: 99%

Atrazine biodegradation in the lab and in the field: enzymatic activities and gene regulation

Govantes

Porrúa

García-González

et al. 2009

Microbial Biotechnology

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“…It was postulated that this relationship could be exploited to alter s ‐triazine persistence in adapted soils. For example, under laboratory conditions, the addition of exogenous N to pure culture and native s ‐triazine‐adapted soils transiently suppressed s ‐triazine degradation by adapted microbial populations, with the suppression level depending primarily on the bacterial population responsible for degradation and the N source applied 82, 89, 114, 125–130. Additionally, atrazine‐catabolizing genes, particularly atzDEF , are subject to a complex regulatory circuit that is modulated by N availability and the presence of degradation products, e.g.…”

Section: Resultsmentioning

confidence: 99%

Agronomic and environmental implications of enhanceds-triazine degradation

et al. 2010

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environmental implications of enhanced s-triazine degradation" (2010 AbstractNovel catabolic pathways enabling rapid detoxification of s-triazine herbicides have been elucidated and detected at a growing number of locations. The genes responsible for s-triazine mineralization, i.e. atzABCDEF and trzNDF, occur in at least four bacterial phyla and are implicated in the development of enhanced degradation in agricultural soils from all continents except Antarctica. Enhanced degradation occurs in at least nine crops and six crop rotation systems that rely on s-triazine herbicides for weed control, and, with the exception of acidic soil conditions and s-triazine application frequency, adaptation of the microbial population is independent of soil physiochemical properties and cultural management practices. From an agronomic perspective, residual weed control could be reduced tenfold in s-triazine-adapted relative to non-adapted soils. From an environmental standpoint, the off-site loss of total s-triazine residues could be overestimated 13-fold in adapted soils if altered persistence estimates and metabolic pathways are not reflected in fate and transport models. Empirical models requiring soil pH and s-triazine use history as input parameters predict atrazine persistence more accurately than historical estimates, thereby allowing practitioners to adjust weed control strategies and model input values when warranted. Published

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“…Sus resultados indicaron una mayor degradabilidad de clorpirifos (83 %) y su producto metabólico 3,5,6-tricloro-2-piridinol (TCP) (30 %), en suelos suplementados con B. thuringiensis. En el caso de atrazina, Guillén-Garcés et al (2007) caracterizaron la mineralización microbiana en suelos y líquidos en presencia de fertilizante nitrogenado, sus resultados mostraron que únicamente un 20 % de atrazina se mineralizó después de 18 días en presencia de nitrógeno, mientras que más del 90 % de mineralización ocurrió después de un día, sin la presencia de nitrógeno.…”

Section: Bioplaguicidas Y Biorremediaciónunclassified

Estado Actual De La Investigación Sobre Plaguicidas en México

Hernández

Leyva-Morales

Rodríguez

et al. 2018

Rev. Int. Contam. Ambie.

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Palabras Clave: patrón de uso, exposición laboral, ecosistemas, contaminación, agricultura RESUMENEl presente trabajo analiza la investigación que se ha llevado a cabo en México con relación al uso y efecto de los plaguicidas en el ambiente y salud humana. Se revisaron 394 artículos publicados en los últimos 20 años en revistas indizadas o arbitradas. Las publicaciones se agruparon en 7 temas principales: 1) patrón de uso de plaguicidas, 2) efectos en el ambiente; 3) estudios ecotoxicológicos; 4) exposición en población humana; 5) residuos en alimentos; 6) toxicología de plaguicidas (estudios in vitro e in vivo); y 7) bioplaguicidas y biorremediación. El análisis de estas investigaciones indican que actualmente se utilizan Plaguicidas Altamente Peligrosos (PAPs) en las zonas agrícolas del país, su uso histórico y actual se relaciona con efectos negativos en ecosistemas terrestres y costeros, se han reportado efectos en la salud de los trabajadores agrícolas y sus familias, tales como alteraciones hematológicas, hormonales, daños genéticos, alteraciones del comportamiento y daños celulares; los niños constituyen el grupo más vulnerable a la exposición, además se han documentado daños genéticos, reproductivos y neuronales en modelos celulares y en organismos de laboratorio y se reportan residuos en alimentos como leche, hortalizas y granos. Como medidas de mitigación, se documentan procesos de biorremediación de suelos y agua contaminada,

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Mineralization of atrazine in agricultural soil: Inhibition by nitrogen

Cited by 22 publications

References 27 publications

Atrazine biodegradation in the lab and in the field: enzymatic activities and gene regulation

Atrazine biodegradation in the lab and in the field: enzymatic activities and gene regulation

Agronomic and environmental implications of enhanceds-triazine degradation

Estado Actual De La Investigación Sobre Plaguicidas en México

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