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Isolation of Allocrenothrix methanica reveals distinct ecophysiologies of filamentous methanotrophs and adaptations to O2 limitation.

Created on 04 Jul 2026

Authors

Kazuhiro Umezawa, Jackson Makoto Tsuji, Yukinori Tani, Seichi Nohara, Rudolf I Amann, Manabu Fukui

Published in

The ISME journal. Jul 03, 2026. Epub Jul 03, 2026.

Abstract

Ferdinand Cohn observed abundant filamentous bacteria in drinking water wells in 1870 that he named Crenothrix polyspora. Subsequent research has revealed the methanotrophic metabolism of Crenothrix bacteria and their disproportionately high activity in stratified lakes compared to unicellular methanotrophs, yet laboratory cultivation has proven elusive, leaving the ecophysiology of Crenothrix bacteria largely unknown. Here we report the isolation of two methanotrophic strains of the "lacustrine Crenothrix" clade from an iron-rich wetland and reveal their unique cell biology and ecology. We demonstrate that the strains are microaerobic and grow as filaments of cells, which are connected by unidirectionally oriented structures. The strains have broad genomic repertoires for addressing O2 limitation that are uniquely associated with lacustrine Crenothrix compared to related clades based on genome data. Aligning with laboratory observations, we identify lacustrine Crenothrix bacteria along potential redox gradients in the wetland at iron-rich snow sites, and we also detect such bacteria in diverse global ecosystems based on public metagenome searches. Together, our data strongly point to an ecophysiology of lacustrine Crenothrix bacteria that is tightly linked to O2 limitation, and we propose that the strains uniquely store or share metabolic intermediates between cells in filaments to thrive under such conditions. Our cultivation-based findings for these strains, which we name Allocrenothrix methanica, provide new insights into the diversity, evolution, and ecology of filamentous methanotrophs, connecting over 150 years of microbiology research and opening vast new opportunities to investigate bacteria contributing to the global methane cycle under O2 limitation.

PMID:
42397959
Bibliographic data and abstract were imported from PubMed on 04 Jul 2026.

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