Land Spreading of Wastewaters from the Fruit-Packaging Industry and Potential Effects on Soil Microbes: Effects of the Antioxidant Ethoxyquin and Its Metabolites on Ammonia Oxidizers

Papadopoulou, Evangelia S.; Tsachidou, Bella; Sułowicz, Sławomir; Menkissoglu‐Spiroudi, Urania; Karpouzas, Dimitrios G.

doi:10.1128/aem.03437-15

Cited by 29 publications

(27 citation statements)

References 55 publications

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“…Considering that in the cultures inhibited by EQ (i) EQNL was formed at concentrations substantially lower than those expected to result in an inhibitory effect on the AO tested, and (ii) QI was formed at concentrations equal or higher than those expected to induce an inhibitory effect on the AO tested, we suggest that QI is the main determinant of the persistent inhibitory effect of EQ on AO and NOB. This is consistent with our previous soil studies where EQ, but mostly QI when applied alone, induced a significant inhibition of potential nitrification and transcription of both bacterial and archaeal amoA genes (32). Unlike our previous soil studies where QI showed equivalent inhibitory effects against AOB and AOA, we observed a difference in the inhibition potential of QI between these two AO groups.…”

Section: Discussionsupporting

confidence: 93%

“…animals, plants, and soils) (46). In this study, EQ was rapidly transformed to QI and EQNL, with the former being the major but least persistent transformation product, while the latter being a minor but more persistent product, in line with previous studies in soil (32, 33). We observed a different inhibition potential for AOB and AOA.…”

Section: Discussionsupporting

confidence: 91%

“…In previous soil microcosm studies we showed that ethoxyquin (EQ) (1,2-dihydro-6-ethoxy-2,2,4-trimethylquinoline), an antioxidant used as preservative in fruit-packaging plants, and its derivative 2,6-dihydro-2,2,4-trimethyl-6-quinone imine (QI), strongly inhibited the activity of AOB and AOA (32). EQ in soil is rapidly transformed to QI and 2,4-dimethyl-6-ethoxyquinoline (EQNL), with the former being the major metabolite (33).…”

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Comparison of thein vitroactivity of novel and established nitrification inhibitors applied in agriculture: challenging the effectiveness of the currently available compounds

Papadopoulou

Bachtsevani

Lampronikou

et al. 2020

Preprint

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Nitrification inhibitors (NIs) applied to soil reduce nitrogen fertilizer losses 19 from agricultural ecosystems. Currently available NIs appear to selectively inhibit 20 ammonia-oxidizing bacteria (ΑΟΒ), while their impact on other groups of nitrifiers is 21 limited. Ethoxyquin (EQ), a preservative shown to inhibit ammonia-oxidizers (AO) in soil, 22 is rapidly transformed to 2,6-dihydro-2,2,4-trimethyl-6-quinone imine (QI) and 2,4-23 dimethyl-6-ethoxy-quinoline (EQNL). We compared the inhibitory potential of EQ and its 24 derivatives in vitro with other established NIs that have been applied in an agricultural 25 setting (dicyandiamide (DCD), nitrapyrin (NP), 3,4-dimethylpyrazole phosphate (DMPP)) 26 by evaluating their impact on the activity and growth of five soil-derived strains (two AOB 27 (Nitrosomonas europaea, Nitrosospira multiformis), two ammonia-oxidizing archaea 28 (AOA) ("Candidatus Nitrosocosmicus franklandus", "Candidatus Nitrosotalea sinensis"), 29 and one nitrite-oxidizing bacterium (NOB) (Nitrobacter sp.)). NIs degradation was also 30 determined. AOA were more sensitive than AOB or NOB to EQ and its derivatives. Despite 31 its transient character, QI was primarily responsible for AO inhibition by EQ, and the most 32 potent NI against AOA. For AOB, QI was more potent than DCD but less than nitrapyrin 33 and DMPP. AOA and NOB showed higher tolerance to the persistent compounds DCD 34 and DMPP. Our findings benchmark the activity range of known and novel NIs with 35 practical implications for their use, and the development of novel NIs with broad or 36 complementary activity against all AO. 37 DMPP: 3,4-dimethylpyrazole phosphate, AOB: ammonia-oxidizing bacteria, AOA: ammonia-oxidizing archaea, AO: ammonia-oxidizers, NOB: nitrite-oxidizing bacteria, comammox: complete ammonia-oxidizing bacteria; AMO: ammonia monooxygenase 3 38 KEYWORDS nitrification inhibitors, ethoxyquin, quinone imine, ammonia-oxidizing 39 bacteria, ammonia-oxidizing archaea, nitrite-oxidizing bacteria, in vitro assays 40 41Modern agricultural systems depend heavily on large inputs of synthetic N fertilizers to 42 maintain crop productivity and alleviate food crisis for the growing global population (1). 43However, approximately 70% of the annual global input of 100 Tg N fertilizer is lost from 44 agricultural ecosystems due to nitrification and subsequent denitrification processes 45 leading to groundwater and atmospheric pollution through nitrate leaching and nitrogen 46 oxides (NxO) emissions, respectively (2). To reduce N losses and improve nitrogen use 47 efficiency, nitrification inhibitors (NIs) are routinely incorporated into N-stabilized 48 fertilizers to reduce the activities of nitrifying prokaryotes and increase N retention time in 49 soil (3, 4). 50Hundreds of compounds have been identified as potential NIs (5), but only three of 51 them have gained importance for practical use on a global scale: 2-chloro-6-52 (trichloromethyl) pyridine (nitrapyrin) (NP) (6), dicyandiamide (DCD) (7), and 3,4-53 dimethylpyraz...

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Section: Discussionsupporting

confidence: 93%

Section: Discussionsupporting

confidence: 91%

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confidence: 99%

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Comparison of thein vitroactivity of novel and established nitrification inhibitors applied in agriculture: challenging the effectiveness of the currently available compounds

Papadopoulou

Bachtsevani

Lampronikou

et al. 2020

Preprint

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“…Recently, Karas et al (9) demonstrated the major role of TPs of chlorpyrifos and isoproturon on the inhibition of soil microbial functions. Similarly, Papadopoulou et al (10) showed that quinone imine, the oxidized TP of ethoxyquin (an antioxidant used in the fruit-packaging industry) was equally as toxic as, or more toxic than, the parent compound to ammonia-oxidizing microorganisms (AOM). This group has been shown to be particularly sensitive to environmental perturbations (11) including pesticide exposure (6,9).…”

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confidence: 99%

Blame It on the Metabolite: 3,5-Dichloroaniline Rather than the Parent Compound Is Responsible for the Decreasing Diversity and Function of Soil Microorganisms

Vasileiadis

Puglisi

Papadopoulou

et al. 2018

Appl Environ Microbiol

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Pesticides are key stressors of soil microorganisms with reciprocal effects on ecosystem functioning. These effects have been mainly attributed to the parent compounds, while the impact of their transformation products (TPs) has been largely overlooked. We assessed, in a meadow soil (A),the transformation of iprodione and its toxicity on the (i) abundance of functional microbial groups, (ii) activity of key microbial enzymes and (iii) diversity of bacteria, fungi and ammonia-oxidizing microorganisms (AOM) using amplicon sequencing. 3,5-Dichloroaniline (3,5-DCA), the main iprodione TP, was identified as key explanatory factor for the persistent reduction in enzymatic activities and potential nitrification (PN), and for the observed structural changes in the bacterial and fungal community. The abundance of certain bacterial (, , and ) and fungal () groups were negatively correlated with 3,5-DCA. A subsequent study in a fallow agricultural soil (B) showed a limited formation of 3,5-DCA which concurred with the lack of effects on nitrification. Direct 3,5-DCA application in soil B induced a dose-dependent reduction of PN and NO-N, which recovered with time. assays with terrestrial AOM verified the greater toxicity of 3,5-DCA over iprodione. Nitrosotalea sinensis Nd2 was the most sensitive AOM to both compounds. Our findings build on previous evidence on the sensitivity of AOM to pesticides reinforcing their potential utilization as indicators of the soil microbial toxicity of pesticides in pesticide environmental risk analysis and stressing the need to consider the contribution of TPs in the toxicity of pesticides on the soil microbial community. Pesticide toxicity on soil microorganisms is an emerging issue in pesticide risk assessment, dictated by the pivotal role of soil microorganisms on ecosystem services. However, the focus has traditionally been on parent compounds, while transformation products (TPs) are largely overlooked. We tested the hypothesis that TPs can be major contributors on the soil microbial toxicity of pesticides, using, iprodione, and its main TP, 3,5-dichloroaniline, as model compounds. We demonstrated, by measuring functional and structural endpoints, that 3,5-dichloraniline and not iprodione was associated with adverse effects on soil microorganisms, with nitrification being mostly affected. Pioneering assays with relevant ammonia-oxidizing bacteria and archaea verified the greater toxicity of 3,5-dichloraniline. Our findings are expected to advance environmental risk assessment highlighting the potential of ammonia-oxidizing microorganisms as indicators of the soil microbial toxicity of pesticides and stressing the need to consider the contribution of TPs on pesticides soil microbial toxicity.

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“…NOEC fish = 12 μg L −1 ) [8]. We recently reported TBZ concentration levels in soils adjacent to fruit packaging plants of up to 12,000 mg kg −1 resulting in a depleted bacterial diversity [9]. The extensive environmental contamination by TBZ is the result of its high persistence (DT50 (soil - aerobic)> 365 days) [10] and the lack of implemented methods for the treatment of TBZ-contaminated agro-industrial effluents (despite the implementation of relevant EC legislation) [11].…”

Section: Introductionmentioning

confidence: 99%

Nutritional inter-dependencies and a carbazole-dioxygenase are key elements of a bacterial consortium relying on aSphingomonasfor the degradation of the fungicide thiabendazole

Vasileiadis

Perruchon

Scheer

et al. 2020

Preprint

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22Background: Thiabendazole (TBZ), is a benzimidazole fungicide and anthelminthic whose high 23 persistence and toxicity pose a serious environmental threat. In our quest for environmental mitigation 24 we previously isolated the first TBZ-degrading bacterial consortium and provided preliminary evidence 25 for its composition and the degrading role of a Sphingomonas. Here, we employed a multi-omic 26 approach combined with DNA-stable isotope probing (SIP) to determine the genetic make-up of the 27 key consortium members, to disentangle nutritional and metabolic interdependencies, to identify the 28 transformation pathway of TBZ and to understand the genetic network driving its transformation. 29Results: Time-series SIP in combination with amplicon sequencing analysis verified the key role of 30 Sphingomonas in TBZ degradation by assimilating over 80% of the 13 C-labelled phenyl moiety of TBZ. 31Non-target mass spectroscopy (MS) analysis showed the accumulation of thiazole-4-carboxamidine as 32 a single dead-end transformation product and no phenyl-containing derivative, in line with the phenyl 33 moiety assimilation in the SIP analysis. Time series metagenomic analysis of the consortium 34 supplemented with TBZ or succinate led to the assembly of 18 metagenome-assembled genomes 35 (MAGs) with >80% completeness, six (Sphingomonas 3X21F, γ-Proteobacterium 34A, 36Bradyrhizobiaceae 9B and Hydrogenophaga 19A, 13A, and 23F) being dominant. Meta-transcriptomic 37 and -proteomic analysis suggested that Sphingomonas mobilize a carbazole dioxygenase (car) operon 38 during the initial cleavage of TBZ to thiazole-4-carboxamidine and catechol, the latter is further 39 transformed by enzymes encoded in a catechol ortho-cleavage (cat) operon; both operons being up-40 regulated during TBZ degradation. Computational docking analysis of the terminal oxygenase 41 component of car, CarAa, showed high affinity to TBZ, comparable to carbazole, reinforcing its high 42 potency for TBZ transformation. These results suggest no interactions between consortium members in 43 TBZ transformation, performed solely by Sphingomonas. In contrast, gene expression network analysis 44 revealed strong interactions between Sphingomonas MAG 3X12F and Hydrogenophaga MAG 23F, 45with Hydrogenophaga activating its cobalamin biosynthetic pathway and Sphingomonas its cobalamin 46 salvage pathway along TBZ degradation. 47 Conclusions:Our findings suggest interactions between consortium members which align with the 48 "black queen hypothesis": Sphingomonas detoxifies TBZ, releasing consortium members by a toxicant; 49 in return for this, Hydrogenophaga 23F provides cobalamin to the auxotrophic Sphingomonas. 50 Background 54 Thiabendazole (TBZ) is a benzimidazole compound which is used as a post-harvest fungicide to control 55 fungal infestations on fruits during storage [1] and as a broad spectrum anthelminthic to control 56 endoparasites in livestock farming [2]. It acts by binding to tubulin monomers inhibiting the 57 polymerization of microtubules and, thus,...

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Land Spreading of Wastewaters from the Fruit-Packaging Industry and Potential Effects on Soil Microbes: Effects of the Antioxidant Ethoxyquin and Its Metabolites on Ammonia Oxidizers

Cited by 29 publications

References 55 publications

Comparison of thein vitroactivity of novel and established nitrification inhibitors applied in agriculture: challenging the effectiveness of the currently available compounds

Comparison of thein vitroactivity of novel and established nitrification inhibitors applied in agriculture: challenging the effectiveness of the currently available compounds

Blame It on the Metabolite: 3,5-Dichloroaniline Rather than the Parent Compound Is Responsible for the Decreasing Diversity and Function of Soil Microorganisms

Nutritional inter-dependencies and a carbazole-dioxygenase are key elements of a bacterial consortium relying on aSphingomonasfor the degradation of the fungicide thiabendazole

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