Isolation of cold-adapted nitrate-reducing fungi that have potential to increase nitrate removal in woodchip bioreactors

Aims The aim of this study was to obtain cold-adapted denitrifying fungi that could be used for bioaugmentation in woodchip bioreactors to remove nitrate from agricultural subsurface drainage water. Methods and results We isolated a total of 91 nitrate-reducing fungal strains belonging to Ascomycota and Mucoromycota from agricultural soil and a woodchip bioreactor under relatively cold conditions (5 and 15 degrees C). When these strains were incubated with N-15-labelled nitrate, N-29(2) was frequently produced, suggesting the occurrence of co-denitrification (microbially mediated nitrosation). Two strains also produced N-30(2), indicating their ability to reduce N2O. Of the 91 nitrate-reducing fungal strains, fungal nitrite reductase gene (nirK) and cytochrome P450 nitric oxide reductase gene (p450nor) were detected by PCR in 34 (37%) and 11 (12%) strains, respectively. Eight strains possessed both nirK and p450nor, further verifying their denitrification capability. In addition, most strains degraded cellulose under denitrification condition. Conclusions Diverse nitrate-reducing fungi were isolated from soil and a woodchip bioreactor. These fungi reduced nitrate to gaseous N forms at relatively low temperatures. These cold-adapted, cellulose-degrading and nitrate-reducing fungi could support themselves and other denitrifiers in woodchip bioreactors. Significance and Impact of the Study The cold-adapted, cellulose-degrading and nitrate-reducing fungi isolated in this study could be useful to enhance nitrate removal in woodchip bioreactors under low-temperature conditions.

Automated summary

This study isolated a variety of cold-adapted, cellulose-degrading, and nitrate-reducing fungi that could assist in nitrate removal in woodchip bioreactors under low-temperature conditions. These fungi showed the ability to reduce nitrate to gaseous forms and had denitrification genes, potentially enhancing denitrification capability in bioreactors.