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Effect of temperature on the compositions of ladderane lipids in globally surveyed anammox populations

Authors :
Vojtěch Kouba
Kamila Hůrková
Klára Navrátilová
Dana Kok
Andrea Benáková
Michele Laureni
Patricie Vodičková
Tomáš Podzimek
Petra Lipovová
Laura van Niftrik
Jana Hajšlová
Mark C.M. van Loosdrecht
David Gregory Weissbrodt
Jan Bartáček
Source :
Science of The Total Environment, Science of the Total Environment, 830, pp. 1-11, Science of the Total Environment, 830, Science of the Total Environment, 830, 1-11, Sci Total Environ
Publication Year :
2022

Abstract

The adaptation of bacteria involved in anaerobic ammonium oxidation (anammox) to low temperatures will enable more efficient removal of nitrogen from sewage across seasons. At lower temperatures, bacteria typically tune the synthesis of their membrane lipids to promote membrane fluidity. However, such adaptation of anammox bacteria lipids, including unique ladderane phospholipids and especially shorter ladderanes with absent phosphatidyl headgroup, is yet to be described in detail. We investigated the membrane lipids composition (UPLC–HRMS/MS) and dominant anammox populations (16S rRNA gene amplicon sequencing, Fluorescence in situ hybridization) in 14 anammox enrichments cultivated at 10–37 °C. “Candidatus Brocadia” appeared to be the dominant organism in all but two laboratory enrichments of “Ca. Scalindua” and “Ca. Kuenenia”. At lower temperatures, the membranes of all anammox populations were composed of shorter [5]-ladderane ester (reduced chain length demonstrated by decreased fraction of C20/(C18 + C20)). This confirmed the previous preliminary evidence on the prominent role of this ladderane fatty acid in low-temperature adaptation. “Ca. Scalindua” and “Ca. Kuenenia” had distinct profile of ladderane lipids compared to “Ca. Brocadia” biomasses with potential implications for adaptability to low temperatures. “Ca. Brocadia” membranes contained a much lower amount of C18 [5]-ladderane esters than reported in the literature for “Ca. Scalindua” at similar temperature and measured here, suggesting that this could be one of the reasons for the dominance of “Ca. Scalindua” in cold marine environments. Furthermore, we propose additional and yet unreported mechanisms for low-temperature adaptation of anammox bacteria, one of which involves ladderanes with absent phosphatidyl headgroup. In sum, we deepen the understanding of cold anammox physiology by providing for the first time a consistent comparison of anammox-based communities across multiple environments.

Details

ISSN :
00489697
Database :
OpenAIRE
Journal :
Science of The Total Environment
Accession number :
edsair.doi.dedup.....f9e667e13c6c0549cd75a74d504d3ca2
Full Text :
https://doi.org/10.1016/j.scitotenv.2022.154715