TY - JOUR
T1 - Engineering a biofilters microbiome with activated carbon and bioaugmentation to improve stormwater micropollutant removal
AU - LeviRam, Inbar
AU - Gross, Amit
AU - Lintern, Anna
AU - Obayomi, Olabiyi
AU - Chalifa-Caspi, Vered
AU - Gillor, Osnat
AU - Henry, Rebekah
AU - Schang, Christelle
AU - Herzberg, Moshe
AU - McCarthy, David T.
N1 - Publisher Copyright:
© 2023 The Authors
PY - 2023/11/1
Y1 - 2023/11/1
N2 - Harnessing prokaryotes’ metabolic capacity and adaptive potential is of interest for environmental bioremediation and biological treatment of domestic and industrial waste. Bioaugmentation is commonly implicated in the cleanup of high-dosed environmental pollution. In this study, Arthrobacter aurescens TC1 was used to augment biofiltration systems for bioremediation of stormwater micropollutant. Bioaugmentation was tested on non-vegetated and vegetated system designs, with or without an adsorbent biocarrier [granulated activated carbon (GAC)]. This study investigated how system design affects microbial function and structure. It focused on long-term metabolic responses of the biofilter's microbiome to low chronic exposure to the herbicide atrazine and fluctuations in atrazine load. Shotgun metagenomics analyses demonstrated that the major contributor to microbiome structure was the supplementation of GAC. Vegetation affected microbiome structure mainly in sand biofilter-media. GAC showed a significant shift in atrazine-degrading genes over time compared to sand. Diversity and richness increased with time in all system designs, regardless of atrazine load fluctuations. To conclude, incorporating GAC in stormwater-biofiltration systems effectively enhances the micropollutant-biodegradation capacity in stormwater with negligible effects on the biofilter's microbiome diversity and function.
AB - Harnessing prokaryotes’ metabolic capacity and adaptive potential is of interest for environmental bioremediation and biological treatment of domestic and industrial waste. Bioaugmentation is commonly implicated in the cleanup of high-dosed environmental pollution. In this study, Arthrobacter aurescens TC1 was used to augment biofiltration systems for bioremediation of stormwater micropollutant. Bioaugmentation was tested on non-vegetated and vegetated system designs, with or without an adsorbent biocarrier [granulated activated carbon (GAC)]. This study investigated how system design affects microbial function and structure. It focused on long-term metabolic responses of the biofilter's microbiome to low chronic exposure to the herbicide atrazine and fluctuations in atrazine load. Shotgun metagenomics analyses demonstrated that the major contributor to microbiome structure was the supplementation of GAC. Vegetation affected microbiome structure mainly in sand biofilter-media. GAC showed a significant shift in atrazine-degrading genes over time compared to sand. Diversity and richness increased with time in all system designs, regardless of atrazine load fluctuations. To conclude, incorporating GAC in stormwater-biofiltration systems effectively enhances the micropollutant-biodegradation capacity in stormwater with negligible effects on the biofilter's microbiome diversity and function.
KW - Atrazine degradation
KW - Bioaugmentation
KW - Micropollutant removal
KW - Shotgun metagenomics
KW - Stormwater bioremediation
KW - Waterway preservation
UR - http://www.scopus.com/inward/record.url?scp=85169503681&partnerID=8YFLogxK
U2 - 10.1016/j.eti.2023.103338
DO - 10.1016/j.eti.2023.103338
M3 - Article
AN - SCOPUS:85169503681
SN - 2352-1864
VL - 32
JO - Environmental Technology and Innovation
JF - Environmental Technology and Innovation
M1 - 103338
ER -