TY - JOUR
T1 - Bacterial bioaugmentation of woodchip bioreactors to increase nitrate removal in cold agricultural drainage water
AU - Jéglot, Arnaud
AU - Sanchez-Cid, Concepcion
AU - Sørensen, Sebastian Reinhold
AU - Schnorr, Kirk Matthew
AU - Plauborg, Finn
AU - Vogel, Timothy M.
AU - Elsgaard, Lars
N1 - Publisher Copyright:
© 2024 Informa UK Limited, trading as Taylor & Francis Group.
PY - 2024
Y1 - 2024
N2 - Woodchip bioreactors (WBRs) are biological systems designed to prevent excess nitrate (NO3−) leaching from agricultural fields to aquatic ecosystems. Nitrate is removed by microbial denitrification, but the enzyme-mediated process slows down at cold temperatures (<10°C), where NO3− removal in WBRs can be less than 20%. We studied the use of bacterial bioaugmentation in replicated test-scale WBRs (∼0.1 m3) as an environmental technology to increase NO3− removal at cold temperatures. Nitrate removal rates increased following injection of a nitrate-reducing inoculum (Pseudomonas proteolytica and Klebsiella sp.), but the effect disappeared within a week and was reproduced in control WBRs by injection of sterile medium (phosphate buffer saline). Metagenome analyses showed a shift in the bacterial community composition after bioaugmentation in the planktonic phase of the woodchip reactors, but not in the solid phase (woodchip matrix). Only in the planktonic phase, Pseudomonas and Klebsiella increased their relative abundance as monitored by 16S rRNA gene sequences. In addition, an increased abundance of genes related to NO3− transformation after bacterial inoculation was observed in the metagenomic sequences. After one week, bacterial community composition became similar to its initial state, indicating resilience of the WBR microbial communities. We conclude that improved inoculation methods are needed to unlock the potential of bioaugmentation to increase NO3− removal at cold temperatures and make it a relevant technology for practical use at field-scale.
AB - Woodchip bioreactors (WBRs) are biological systems designed to prevent excess nitrate (NO3−) leaching from agricultural fields to aquatic ecosystems. Nitrate is removed by microbial denitrification, but the enzyme-mediated process slows down at cold temperatures (<10°C), where NO3− removal in WBRs can be less than 20%. We studied the use of bacterial bioaugmentation in replicated test-scale WBRs (∼0.1 m3) as an environmental technology to increase NO3− removal at cold temperatures. Nitrate removal rates increased following injection of a nitrate-reducing inoculum (Pseudomonas proteolytica and Klebsiella sp.), but the effect disappeared within a week and was reproduced in control WBRs by injection of sterile medium (phosphate buffer saline). Metagenome analyses showed a shift in the bacterial community composition after bioaugmentation in the planktonic phase of the woodchip reactors, but not in the solid phase (woodchip matrix). Only in the planktonic phase, Pseudomonas and Klebsiella increased their relative abundance as monitored by 16S rRNA gene sequences. In addition, an increased abundance of genes related to NO3− transformation after bacterial inoculation was observed in the metagenomic sequences. After one week, bacterial community composition became similar to its initial state, indicating resilience of the WBR microbial communities. We conclude that improved inoculation methods are needed to unlock the potential of bioaugmentation to increase NO3− removal at cold temperatures and make it a relevant technology for practical use at field-scale.
KW - bioaugmentation
KW - Denitrification
KW - microbiome
KW - nitrate
KW - temperature
UR - http://www.scopus.com/inward/record.url?scp=85210947673&partnerID=8YFLogxK
U2 - 10.1080/09593330.2024.2432483
DO - 10.1080/09593330.2024.2432483
M3 - Journal article
C2 - 39626197
AN - SCOPUS:85210947673
SN - 0959-3330
JO - Environmental Technology (United Kingdom)
JF - Environmental Technology (United Kingdom)
ER -