Shifts of active microbial community structure and functions in constructed wetlands responded to continuous decreasing temperature in winter

Shaokun Wang; Rumiao Wang; Jan Vyzmal; Yukun Hu; Wei Li; Jinzhi Wang; Yinru Lei; Xiajie Zhai; Xinsheng Zhao; Jing Li; Lijuan Cui

doi:10.1016/j.chemosphere.2023.139080

Shifts of active microbial community structure and functions in constructed wetlands responded to continuous decreasing temperature in winter

Chemosphere. 2023 Sep:335:139080. doi: 10.1016/j.chemosphere.2023.139080. Epub 2023 May 30.

Authors

Shaokun Wang¹, Rumiao Wang¹, Jan Vyzmal², Yukun Hu¹, Wei Li¹, Jinzhi Wang¹, Yinru Lei¹, Xiajie Zhai¹, Xinsheng Zhao¹, Jing Li³, Lijuan Cui⁴

Affiliations

¹ Institute of Wetland Research, Chinese Academy of Forestry, Beijing Key Laboratory of Wetland Ecological Function and Restoration, Beijing, 100091, China; Beijing Hanshiqiao National Wetland Ecosystem Research Station, Beijing, 101399, China.
² Czech University of Life Sciences Prague, Faculty of Environmental Sciences, Kamýcká 129, 165 21 Praha 6, Czech Republic.
³ Institute of Wetland Research, Chinese Academy of Forestry, Beijing Key Laboratory of Wetland Ecological Function and Restoration, Beijing, 100091, China; Beijing Hanshiqiao National Wetland Ecosystem Research Station, Beijing, 101399, China. Electronic address: jingli_2015@caf.ac.cn.
⁴ Institute of Wetland Research, Chinese Academy of Forestry, Beijing Key Laboratory of Wetland Ecological Function and Restoration, Beijing, 100091, China; Beijing Hanshiqiao National Wetland Ecosystem Research Station, Beijing, 101399, China. Electronic address: wetlands108@126.com.

PMID: 37263510
DOI: 10.1016/j.chemosphere.2023.139080

Abstract

Important functions of constructed wetland related to biogeochemical processes are mediated by soil microbes and low-temperature damage is the main limiting factor for microbes in winter. However, the response thresholds for active microbial community and enzyme activities to continuous decreases in temperature remain unclear. In this study, total 90 soil samples were collected every week over a 6-week period to track the dynamics of four enzymes involved in cycles of C, N, P and active bacterial community as field soil temperature decreased continuously from 6.62 °C to 0.55 °C. Enzyme activity changed suddenly when the temperature decreased to 4.83 °C, the nitrite reductase activity reduced by 36.2%, while alkaline phosphatase activity is increased by 396%. The cellulase and urease were only marginally influenced by cold stress. Decreased nitrite reductase activities corresponded with loss of nir-type denitrifiers important for nitrite reduction. For cold stress, N-related bacteria were sensitive species. Whereas increased alkaline phosphatase activity may be due to the fact that P-related bacteria were opportunistic species. Key functional taxa connected with degradation of cellulose promoted species coexistence and microbial network stability. The lower and upper temperature thresholds for community change were 4.85 °C and 6.30 °C, respectively. Collectively, these results revealed that microbial taxa involved in C, N and P cycling respond differently to continuous decreases in temperature and higher than 4.85 °C is an ideal environment to prevent loss of microbial diversity and functions in winter, providing a scientific reference for the targeted isolation and cultivation of key microbial taxa in rhizosphere soil and adjusting temperature range to improve the purification capacity of wetlands during low temperature periods.

Keywords: Active bacterial community; Constructed wetland; Continuous decreases in temperature; Enzyme dynamics; Rhizosphere soil; Winter.

MeSH terms

Alkaline Phosphatase / metabolism
Bacteria / metabolism
Microbiota*
Nitrite Reductases / metabolism
Soil / chemistry
Soil Microbiology
Temperature
Wetlands*

Substances

Alkaline Phosphatase
Soil
Nitrite Reductases