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Microbial communities in slow sand filters for drinking water treatment adapt to organic matter altered by ozonation

Rosenqvist, Tage LU ; Hilding, Johanna ; Suarez, Carolina LU and Paul, Catherine J. LU orcid (2025) In Water Research 270.
Abstract

Changing natural organic matter quality from anthropogenic activity and stricter requirements for micropollutant removal challenges existing systems for drinking water production. Ozonation of water followed by biofiltration, such as passage through a slow sand filter (SSF), is a partial solution. Biofiltration relies on biofilms (microbial communities within extracellular matrices). However, the effects of ozonation on SSF microbial communities are unknown. In this study, genome-resolved and read-based metagenomics were used to compare the microbial communities of two full-scale SSFs employing conventional pre-treatment to a 20 m2 SSF operated in parallel with ozonation as additional pre-treatment. The SSF microbial... (More)

Changing natural organic matter quality from anthropogenic activity and stricter requirements for micropollutant removal challenges existing systems for drinking water production. Ozonation of water followed by biofiltration, such as passage through a slow sand filter (SSF), is a partial solution. Biofiltration relies on biofilms (microbial communities within extracellular matrices). However, the effects of ozonation on SSF microbial communities are unknown. In this study, genome-resolved and read-based metagenomics were used to compare the microbial communities of two full-scale SSFs employing conventional pre-treatment to a 20 m2 SSF operated in parallel with ozonation as additional pre-treatment. The SSF microbial community receiving ozonated water was less diverse than those receiving non-ozonated water. Families Hyphomicrobiaceae, Acetobacteraceae, Sphingomonadaceae and Burkholderiaceae were more abundant when ozone was used, as were genes for metabolism of single-carbon organic compounds. Conversely, genes for metabolism of aromatic compounds and fatty acids were less abundant. Metagenome assembled genomes associated with the non-ozonated SSFs were enriched with several glycoside hydrolases, while those associated with the ozonated SSF were enriched with genes for 1-2 carbon compound metabolism. No indications of increased microbial risk (pathogens or antibiotic resistance genes) were detected as a consequence of ozonation. This study shows how microbial communities of SSFs adapt to changes in organic matter quality, highlighting the key role of biofilters for production of safe and sustainable drinking water in a changing climate.

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author
; ; and
organization
publishing date
type
Contribution to journal
publication status
published
subject
keywords
Biofilm, Drinking water, Metagenome, Ozone, Slow sand filtration
in
Water Research
volume
270
article number
122843
publisher
Elsevier
external identifiers
  • pmid:39612821
  • scopus:85210287076
ISSN
0043-1354
DOI
10.1016/j.watres.2024.122843
language
English
LU publication?
yes
id
039f9608-77ed-4ee5-8cf8-c7baeba520b1
date added to LUP
2025-02-20 15:31:19
date last changed
2025-05-29 23:39:07
@article{039f9608-77ed-4ee5-8cf8-c7baeba520b1,
  abstract     = {{<p>Changing natural organic matter quality from anthropogenic activity and stricter requirements for micropollutant removal challenges existing systems for drinking water production. Ozonation of water followed by biofiltration, such as passage through a slow sand filter (SSF), is a partial solution. Biofiltration relies on biofilms (microbial communities within extracellular matrices). However, the effects of ozonation on SSF microbial communities are unknown. In this study, genome-resolved and read-based metagenomics were used to compare the microbial communities of two full-scale SSFs employing conventional pre-treatment to a 20 m<sup>2</sup> SSF operated in parallel with ozonation as additional pre-treatment. The SSF microbial community receiving ozonated water was less diverse than those receiving non-ozonated water. Families Hyphomicrobiaceae, Acetobacteraceae, Sphingomonadaceae and Burkholderiaceae were more abundant when ozone was used, as were genes for metabolism of single-carbon organic compounds. Conversely, genes for metabolism of aromatic compounds and fatty acids were less abundant. Metagenome assembled genomes associated with the non-ozonated SSFs were enriched with several glycoside hydrolases, while those associated with the ozonated SSF were enriched with genes for 1-2 carbon compound metabolism. No indications of increased microbial risk (pathogens or antibiotic resistance genes) were detected as a consequence of ozonation. This study shows how microbial communities of SSFs adapt to changes in organic matter quality, highlighting the key role of biofilters for production of safe and sustainable drinking water in a changing climate.</p>}},
  author       = {{Rosenqvist, Tage and Hilding, Johanna and Suarez, Carolina and Paul, Catherine J.}},
  issn         = {{0043-1354}},
  keywords     = {{Biofilm; Drinking water; Metagenome; Ozone; Slow sand filtration}},
  language     = {{eng}},
  publisher    = {{Elsevier}},
  series       = {{Water Research}},
  title        = {{Microbial communities in slow sand filters for drinking water treatment adapt to organic matter altered by ozonation}},
  url          = {{http://dx.doi.org/10.1016/j.watres.2024.122843}},
  doi          = {{10.1016/j.watres.2024.122843}},
  volume       = {{270}},
  year         = {{2025}},
}