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Relationship assessment of microbial community and cometabolic consumption of 2-chlorophenol
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Journal Article
Relationship assessment of microbial community and cometabolic consumption of 2-chlorophenol
2025
Overview
The relationship of microbial community and cometabolic consumption of 2-chlorophenol (2-CP) in a nitrifying sequencing batch reactor (SBR) was studied. The assessment of the population dynamics of the nitrifying sludge during the cometabolic 2-CP consumption with increasing ammonium (NH
4
+
) concentrations in the SBR showed the presence of 39 different species of which 10 were always present in all cycles. Fifty-five percent of the species found were grouped as Proteobacteria (45% as β-proteobacteria and 10% as γ-proteobacteria class), 30% as Acidobacteria, and 15% as Deinococcus-Thermus phyla. NH
4
+
and cometabolic 2-CP consumption could be related to the presence and permanence of ammonium-oxidizing bacteria (AOB) species and heterotrophic bacteria, while the complete nitrification to the presence of nitrite-oxidizing bacteria (NOB) species. A correlation analysis showed that the complete and stable nitrifying performance (NH
4
+
consumption efficiencies (ENH
4
+
-N) > 99% and nitrate production yields (YNO
3
−
-N) between 0.93 and 0.99), as well as the increase in specific rates (ammonium (qNH
4
+
-N) and 2-CP (q2-CP-C) consumption and nitrate production (qNO
3
−
-N)), was associated with the homogeneity of the bacterial community (
J
index = 0.99). The increase in the proportion of individuals of AOB species such as
Nitrosomonas oligotropha
and
Nitrosomonas marina
was associated with the increase in qNH
4
+
-N (
r
≥ 0.69) and q2-CP-C (
r
≥ 0.64) and, therefore, with the 2-CP cometabolic consumption in the SBR. Finally, the increase in the proportion of individuals of heterotrophic species such as
Dokdonella ginsengisoli
,
Deinococcus peraridilitoris
,
Truepera radiovictrix
, and
Stenotrophobacter terrae
was associated with the increase in q2-CP-C (
r
≥ 0.59).
Key points
•
Thirty-nine bacterial species were identified in the nitrifying sludge population of the SBR.
•
β-Proteobacteria and Acidobacteria were the prevalent (85%) bacterial groups.
•
AOB and heterotrophic bacteria participate in NH
4
+
and cometabolic 2-CP consumption.
Graphical abstract
Publisher
Springer Berlin Heidelberg,Springer Nature B.V
Subject
