Bacterial community and groundwater quality changes in an anaerobic aquifer during groundwater recharge with aerobic recycled water

Ginige, Maneesha P.; Kaksonen, Anna H.; Morris, Christina; Shackelton, Mark; Patterson, Bradley M.

doi:10.1111/1574-6941.12137

Cited by 31 publications

(14 citation statements)

References 59 publications

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“…These results suggest that P8 denitrification processes occur below the basin even when it is empty, indicating that 4 months is not enough time to revert back to natural conditions at this sampling point. This assumption is consistent with nitrate isotopic data presented in Grau-Martínez et al (2018) and is also in agreement with the study of Rodriguez-Escales et al (2016) in which biomass decay acted as an endogenous carbon source for respiration once the input carbon was reduced, maintaining denitrification rates.…”

Section: Matching Groundwater Model Ecological Disturbance Principlesupporting

confidence: 91%

“…Biodegradation of EOCs strongly depends on redox conditions (Barbieri et al, 2011;Maeng et al, 2010). In this regard, it has been shown that MAR is a feasible technique capable of partially degrading some of these contaminants (Hellauer et al, 2017;Massmann et al, 2008), particularly when bioprocesses are enhanced (Grau-Martínez et al, 2018;Schaffer et al, 2015). Infiltration through the soil intrinsically leads to two main consequences in groundwater recharge:…”

Section: Barba Et Al: Microbial Communities In Marmentioning

confidence: 99%

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Microbial community changes induced by Managed Aquifer Recharge activities: linking hydrogeological and biological processes

Barba

Folch

Gaju

et al. 2019

Hydrol. Earth Syst. Sci.

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Abstract. Managed Aquifer Recharge (MAR) is a technique used worldwide to increase the availability of water resources. We study how MAR modifies microbial ecosystems and its implications for enhancing biodegradation processes to eventually improve groundwater quality. We compare soil and groundwater samples taken from a MAR facility located in NE Spain during recharge (with the facility operating continuously for several months) and after 4 months of no recharge. The study demonstrates a strong correlation between soil and water microbial prints with respect to sampling location along the mapped infiltration path. In particular, managed recharge practices disrupt groundwater ecosystems by modifying diversity indices and the composition of microbial communities, indicating that infiltration favors the growth of certain populations. Analysis of the genetic profiles showed the presence of nine different bacterial phyla in the facility, revealing high biological diversity at the highest taxonomic range. In fact, the microbial population patterns under recharge conditions agree with the intermediate disturbance hypothesis (IDH). Moreover, DNA sequence analysis of excised denaturing gradient gel electrophoresis (DGGE) band patterns revealed the existence of indicator species linked to MAR, most notably Dehalogenimonas sp., Nitrospira sp. and Vogesella sp.. Our real facility multidisciplinary study (hydrological, geochemical and microbial), involving soil and groundwater samples, indicates that MAR is a naturally based, passive and efficient technique with broad implications for the biodegradation of pollutants dissolved in water.

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Section: Matching Groundwater Model Ecological Disturbance Principlesupporting

confidence: 91%

Section: Barba Et Al: Microbial Communities In Marmentioning

confidence: 99%

Microbial community changes induced by Managed Aquifer Recharge activities: linking hydrogeological and biological processes

Barba

Folch

Gaju

et al. 2019

Hydrol. Earth Syst. Sci.

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“…As for microbial MAR field studies, most relevant research is limited to well injection systems (Ginige et al, 2013;Reed et al, 2008;Zhang et al, 2016) or riverbank filtration conditions (Huang et al, 2015). Onesios-Barry et al (2014) compared results from a column experiment and soil samples in a MAR site in the US, focusing on the micro-30 bial populations linked to pharmaceutical and personal care products removal, and concluded that microbial composition and structure of both systems were comparable.…”

mentioning

confidence: 99%

Microbial community changes induced by Managed Aquifer Recharge activities: Linking hydrogeological and biological processes

Barba¹,

Folch²,

Gaju³

et al. 2018

Preprint

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Abstract. Managed Aquifer Recharge (MAR) is a worldwide used technique to increase the availability of water resources.We study how MAR modifies microbial ecosystems, and its implications for enhancing biodegradation processes to eventually improve groundwater quality. We compare soil and groundwater samples taken from a MAR facility located in NE Spain during recharge (with the facility operating continuously for several months) and after four months of no recharge. The study demonstrates a strong correlation between soil and water microbial prints with respect to sampling location along the mapped 5 infiltration path. In particular, managed recharge practices disrupt groundwater ecosystems by modifying diversity indices and the composition of microbial communities, indicating that infiltration favors the growth of certain populations. Analysis of the genetic profiles showed the presence of nine different bacterial phyla in the facility, revealing high biological diversity at the highest taxonomic range. In fact, the microbial population patterns under recharge conditions agree with the Intermediate Disturbance Hypothesis. Moreover, DNA sequence analysis of excised DGGE band patterns revealed the existence of indicator 10 species linked to MAR, most notably Dehalogenimonas sp, Nitrospira sp and Vogesella sp. Our real facility multidisciplinary study (hydrological, geochemical and microbial), involving soil and groundwater samples, support that MAR is a naturallybased, passive, and efficient technique with broad implications for the biodegradation of pollutants dissolved in water.

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“…Aquifers harbour diverse microbial communities which can facilitate the natural attenuation of nutrients through microbial metabolic processes [63,64]. Microbial processes that facilitate nitrogen removal include aerobic ammonia oxidation, denitrification and anaerobic ammonia oxidation (Anammox) [65,66].…”

Section: Total Organic Carbon (Toc) and Other Nutrientsmentioning

confidence: 99%

“…As part of Perth's Groundwater Replenishment Scheme, Ginige et al [64] characterised the bacterial community within the anaerobic Leederville aquifer being recharged with aerobic reclaimed water using culture-independent molecular methods (clone library and QPCR of 16S rRNA genes) and flow cytometry. The study revealed that bacterial numbers increased and diversity decreased as a result of the aquifer recharge.…”

Section: Changes To Subsurface Microbial Ecologymentioning

confidence: 99%

Water Recycling via Aquifers for Sustainable Urban Water Quality Management: Current Status, Challenges and Opportunities

Bekele

Page

Vanderzalm

et al. 2018

Water

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Managed aquifer recharge (MAR) is used worldwide in urban environments to replenish groundwater to provide a secure and sustainable supply of potable and non-potable water. It relies on natural treatment processes within aquifers (i.e., filtration, sorption, and degradation), and in some cases involves infiltration through the unsaturated zone to polish the given source water, e.g., treated wastewater, stormwater, or rainwater, to the desired quality prior to reuse. Whilst MAR in its early forms has occurred for millennia, large-scale schemes to replenish groundwater with advanced treated reclaimed water have come to the fore in cities such as Perth, Western Australia, Monterey, California, and Changwon, South Korea, as water managers consider provision for projected population growth in a drying climate. An additional bonus for implementing MAR in coastal aquifers is assisting in the prevention of seawater intrusion. This review begins with the rationale for large-scale MAR schemes in an Australian urban context, reflecting on the current status; describes the unique benefits of several common MAR types; and provides examples from around the world. It then explores several scientific challenges, ranging from quantifying aquifer removal for various groundwater contaminants to assessing risks to human health and the environment, and avoiding adverse outcomes from biogeochemical changes induced by aquifer storage. Scientific developments in the areas of water quality assessments, which include molecular detection methods for microbial pathogens and high resolution analytical chemistry methods for detecting trace chemicals, give unprecedented insight into the "polishing" offered by natural treatment. This provides opportunities for setting of compliance targets for mitigating risks to human health and maintaining high performance MAR schemes.

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Bacterial community and groundwater quality changes in an anaerobic aquifer during groundwater recharge with aerobic recycled water

Cited by 31 publications

References 59 publications

Microbial community changes induced by Managed Aquifer Recharge activities: linking hydrogeological and biological processes

Microbial community changes induced by Managed Aquifer Recharge activities: linking hydrogeological and biological processes

Microbial community changes induced by Managed Aquifer Recharge activities: Linking hydrogeological and biological processes

Water Recycling via Aquifers for Sustainable Urban Water Quality Management: Current Status, Challenges and Opportunities

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