Litcius/Paper detail

<scp>Oxic–anoxic</scp> cycling promotes coupling between complex carbon metabolism and denitrification in woodchip bioreactors

Philip M. McGuire, Natalie Butkevich, Aryaman Saksena, M. Todd Walter, James P. Shapleigh, Matthew C. Reid

2023Environmental Microbiology20 citationsDOIOpen Access PDF

Abstract

Abstract Denitrifying woodchip bioreactors (WBRs) are increasingly used to manage the release of non‐point source nitrogen (N) by stimulating microbial denitrification. Woodchips serve as a renewable organic carbon (C) source, yet the recalcitrance of organic C in lignocellulosic biomass causes many WBRs to be C‐limited. Prior studies have observed that oxic–anoxic cycling increased the mobilization of organic C, increased nitrate (NO 3 − ) removal rates, and attenuated production of nitrous oxide (N 2 O). Here, we use multi‐omics approaches and amplicon sequencing of fungal 5.8S‐ITS2 and prokaryotic 16S rRNA genes to elucidate the microbial drivers for enhanced NO 3 − removal and attenuated N 2 O production under redox‐dynamic conditions. Transient oxic periods stimulated the expression of fungal ligninolytic enzymes, increasing the bioavailability of woodchip‐derived C and stimulating the expression of denitrification genes. Nitrous oxide reductase ( nosZ ) genes were primarily clade II, and the ratio of clade II/clade I nosZ transcripts during the oxic–anoxic transition was strongly correlated with the N 2 O yield. Analysis of metagenome‐assembled genomes revealed that many of the denitrifying microorganisms also have a genotypic ability to degrade complex polysaccharides like cellulose and hemicellulose, highlighting the adaptation of the WBR microbiome to the ecophysiological niche of the woodchip matrix.

Topics & Concepts

Denitrifying bacteriaDenitrificationAnoxic watersBiologyNitrous-oxide reductaseEnvironmental chemistryChemistryEcologyNitrogenOrganic chemistryWastewater Treatment and Nitrogen RemovalEnzyme-mediated dye degradationBiofuel production and bioconversion