Isotope and microbiome data provide complementary information to identify natural nitrate attenuation processes in groundwater

Amo, Elena Hernández-del; Menció, Anna; Gich, Frédéric; Mas‐Pla, Josep; Bañeras, Lluís

doi:10.1016/j.scitotenv.2017.09.018

Cited by 27 publications

(9 citation statements)

References 61 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In Sep 2014 NO 3 - -N < 5.65 was evident for all locations (Fig 5). In terms of N source groundwater NO 3 - -N isotopic composition clustered within the manure/sewage value range and along a 1:1–1:2 slope, suggesting a common organic source for these, and denitrification as the main biotransformation process (Fig 5) [41–43]. The denitrification lines for 2014 and 2017 samples share the same trend, which points to denitrification as the main process leading N attenuation.…”

Section: Resultsmentioning

confidence: 98%

An integrated assessment of nitrogen source, transformation and fate within an intensive dairy system to inform management change

et al. 2019

View full text Add to dashboard Cite

From an environmental perspective optimised dairy systems, which follow current regulations, still have low nitrogen (N) use efficiency, high N surplus (kg N ha -1 ) and enable ad-hoc delivery of direct and indirect reactive N losses to water and the atmosphere. The objective of the present study was to divide an intensive dairy farm into N attenuation capacity areas based on this ad-hoc delivery. Historical and current spatial and temporal multi-level datasets (stable isotope and dissolved gas) were combined and interpreted. Results showed that the farm had four distinct attenuation areas: high N attenuation : characterised by ammonium-N (NH 4 + -N) below 0.23 mg NH 4 + -N l -1 and nitrate (NO 3 - -N) below 5.65 mg NO 3 - -N l -1 in surface, drainage and groundwater, located on imperfectly to moderately-well drained soils with high denitrification potential and low nitrous oxide (N 2 O) emissions (av. 0.0032 mg N 2 O-N l -1 ); moderate N attenuation : characterised by low NO 3 - -N concentration in drainage water but high N 2 O production (0.0317 mg N 2 O-N l -1 ) and denitrification potential lower than group 1 (av. δ 15 N-NO 3 - : 16.4‰, av. δ 18 O-NO 3 - : 9.2‰), on well to moderately drained soils; low N attenuation—area 1 : characterised by high NO 3 - -N (av. 6.90 mg NO 3 - -N l -1 ) in drainage water from well to moderately-well drained soils, with low denitrification potential (av. δ 15 N-NO 3 - : 9.5‰, av. δ 18 O-NO 3 - : 5.9‰) and high N 2 O emissions (0.0319 mg N 2 O l -1 ); and low N attenuation—area 2 : characterised by high NH 4 + -N (av. 3.93 mg NH 4 + -N l -1 and high N 2 O emissions (av. 0.0521 mg N 2 O l -1 ) from well to imperfectly drained soil. N loads on site should be moved away from low attenuation areas and emissions to air and water should be assessed.

show abstract

Section: Resultsmentioning

confidence: 98%

An integrated assessment of nitrogen source, transformation and fate within an intensive dairy system to inform management change

et al. 2019

View full text Add to dashboard Cite

show abstract

“…As the first step (nitrate reduction into nitrite) of the denitrification pathway was shown to be mainly impacted, and in order to determine if the proportion of the denitrifying community changed among the microbial community, the relative abundance of narG and napA genes, both encoding nitrate reductase, was measured using qPCR approaches ( Figure 5 ). Data were normalized by taking into account molecular biomass (total DNA) ( Bru et al, 2007 ; Wakelin et al, 2011 ; Hernández-del Amo et al, 2018 ). The presence of pesticides or metabolites did not significantly modify the relative abundance of both genes even in conditions for which nitrate reduction rate was decreased (in particular ESA-metolachlor at 10 μg/L), suggesting an impact (inhibition) of pesticides and metabolites at the protein level rather than on the nitrate-reducing bacteria abundance within the bacterial community.…”

Section: Resultsmentioning

confidence: 99%

Side Effects of Pesticides and Metabolites in Groundwater: Impact on Denitrification

et al. 2021

View full text Add to dashboard Cite

The impact of two pesticides (S-metolachlor and propiconazole) and their respective main metabolites (ESA-metolachlor and 1,2,4-triazole) on bacterial denitrification in groundwater was studied. For this, the denitrification activity and the bacterial diversity of a microbial community sampled from a nitrate-contaminated groundwater were monitored during 20 days in lab experiments in the presence or absence of pesticides or metabolites at 2 or 10 μg/L. The kinetics of nitrate reduction along with nitrite and N2O production all suggested that S-metolachlor had no or only little impact, whereas its metabolite ESA-metolachlor inhibited denitrification by 65% at 10 μg/L. Propiconazole and 1,2,4-triazole also inhibited denitrification at both concentrations, but to a lesser extent (29–38%) than ESA-metolachlor. When inhibition occurred, pesticides affected the reduction of nitrate into nitrite step. However, no significant differences were detected on the abundance of nitrate reductase narG and napA genes, suggesting an impact of pesticides/metabolites at the protein level rather than on denitrifying bacteria abundance. 16S rRNA gene Illumina sequencing indicated no major modification of bacterial diversity in the presence or absence of pesticides/metabolites, except for ESA-metolachlor and propiconazole at 10 μg/L that tended to increase or decrease Shannon and InvSimpson indices, respectively. General growth parameters suggested no impact of pesticides, except for propiconazole at 10 μg/L that partially inhibited acetate uptake and induced a decrease in microbial biomass. In conclusion, pesticides and metabolites can have side effects at environmental concentrations on microbial denitrification in groundwater and may thus affect ecosystem services based on microbial activities.

show abstract

“…The complementation with H 2 injection to stimulate hydrogenotrophic denitrifiers is therefore necessary and the effect of Fe(II)-containing minerals on the physiological characteristics of the underlying bacteria must also be examined. In this regard, Fe(II)-containing minerals may also be used as electron donors by numerous autotrophic denitrifiers (Otero et al, 2009;Jones et al, 2015;Hernández-del Amo et al, 2018;Margalef-Marti et al, 2020). As a result the abiotic reduction of NO 2 − with Fe(II) may occur alongside microbial denitrification, the two processes are even interconnected (Melton et al, 2014) and may catalyze NO 3 − remediation.…”

Section: Fostering Complete Denitrification -Combining Biotic Denitrimentioning

confidence: 99%

Strategies to Overcome Intermediate Accumulation During in situ Nitrate Remediation in Groundwater by Hydrogenotrophic Denitrification

et al. 2021

View full text Add to dashboard Cite

Bioremediation of polluted groundwater is one of the most difficult actions in environmental science. Nonetheless, the clean-up of nitrate polluted groundwater may become increasingly important as nitrate concentrations frequently exceed the EU drinking water limit of 50 mg L–1, largely due to intensification of agriculture and food production. Denitrifiers are natural catalysts that can reduce increasing nitrogen loading of aquatic ecosystems. Porous aquifers with high nitrate loading are largely electron donor limited and additionally, high dissolved oxygen concentrations are known to reduce the efficiency of denitrification. Therefore, denitrification lag times (time prior to commencement of microbial nitrate reduction) up to decades were determined for such groundwater systems. The stimulation of autotrophic denitrifiers by the injection of hydrogen into nitrate polluted regional groundwater systems may represent a promising remediation strategy for such environments. However, besides high costs other drawbacks, such as the transient or lasting accumulation of the cytotoxic intermediate nitrite or the formation of the potent greenhouse gas nitrous oxide, have been described. In this article, we detect causes of incomplete denitrification, which include environmental factors and physiological characteristics of the underlying bacteria and provide possible mitigation approaches.

show abstract

Isotope and microbiome data provide complementary information to identify natural nitrate attenuation processes in groundwater

Cited by 27 publications

References 61 publications

An integrated assessment of nitrogen source, transformation and fate within an intensive dairy system to inform management change

An integrated assessment of nitrogen source, transformation and fate within an intensive dairy system to inform management change

Side Effects of Pesticides and Metabolites in Groundwater: Impact on Denitrification

Strategies to Overcome Intermediate Accumulation During in situ Nitrate Remediation in Groundwater by Hydrogenotrophic Denitrification

Contact Info

Product

Resources

About