2026-06-15 マックス・プランク研究所
A dividing ciliate demonstrates that the bacterial symbionts divide together with their host. In blue, the ciliate nuclei are shown; in yellow, the bacterial endosymbionts (scale bar 10 μm). © MPI for Marine Microbiology/ Sina Schorn
<関連情報>
- https://www.mpg.de/26812501/symbiosis-in-swiss-lakes
- https://academic.oup.com/ismej/article/20/1/wrag043/8502596
酸化還元勾配は、無酸素湖水における脱窒共生体を持つ繊毛虫の生態的ニッチを規定する Redox gradients define the ecological niche of ciliates with denitrifying endosymbionts in anoxic lake waters
Linus M Zeller,Sina Schorn,Louison Nicolas-Asselineau,Jakob Zopfi,Soeren Ahmerkamp,Carsten J Schubert,Fabio Lepori,Marcel M M Kuypers,Jon S Graf,Jana Milucka
The ISME Journal Published:01 March 2026
DOI:https://doi.org/10.1093/ismejo/wrag043
Abstract
Bacterial endosymbionts of the family Candidatus Azoamicaceae obligately associate with anaerobic ciliates belonging to the class Plagiopylea. The symbionts’ unique role for their host involves anaerobic respiration of nitrate and generation of adenosine triphosphate (ATP), analogous to the role of mitochondria in aerobic eukaryotes. As this symbiosis remains so far uncultured, insights into its functioning have been mainly inferred from environmental metagenomes. Here, we investigated the distribution and environmental role of this symbiosis in the anoxic basins of two freshwater lakes, Zug and Lugano (Switzerland), over a course of several years. We found that the environmental niche of the ciliate host is defined by the combined effects of sulfide, oxygen, and nitrate, the latter of which is essential for the symbiont’s respiratory function. Moreover, the distribution and abundance of ciliates with denitrifying endosymbionts in the water column suggest that they may substantially contribute to nitrate consumption in Lake Zug. Our microscopic analyses further demonstrated a coordinated division of the Ca. Azoamicus ciliaticola symbionts and their ciliate hosts, implying a vertical inheritance of denitrifying symbionts. These observations offer new insights into the evolution of ciliates with denitrifying endosymbionts and their ecological role in oxygen-depleted lake waters.
