Regulation of Hierarchical Carbon Substrate Utilization, Nitrogen Fixation, and Root Colonization by the Hfq/Crc/CrcZY Genes in

Overview

Journal iScience

Publisher Cell Press

Date 2022 Dec 12

PMID 36505936

Authors

Fanyang Lv

Yuhua Zhan

Wei Lu

Xiubin Ke

Yahui Shao

Yiyuan Ma

Juan Zheng

Zhimin Yang

Shanshan Jiang

Liguo Shang

Yao Ma

Lei Cheng

Claudine Elmerich

Yongliang Yan

Min Lin

Affiliations

Soon will be listed here.

Abstract

Bacteria of the genus consume preferred carbon substrates in nearly reverse order to that of enterobacteria, and this process is controlled by RNA-binding translational repressors and regulatory ncRNA antagonists. However, their roles in microbe-plant interactions and the underlying mechanisms remain uncertain. Here we show that root-associated diazotrophic A1501 preferentially catabolizes succinate, followed by the less favorable substrate citrate, and ultimately glucose. Furthermore, the Hfq/Crc/CrcZY regulatory system orchestrates this preference and contributes to optimal nitrogenase activity and efficient root colonization. Hfq has a central role in this regulatory network through different mechanisms of action, including repressing the translation of substrate-specific catabolic genes, activating the nitrogenase gene posttranscriptionally, and exerting a positive effect on the transcription of an exopolysaccharide gene cluster. Our results illustrate an Hfq-mediated mechanism linking carbon metabolism to nitrogen fixation and root colonization, which may confer rhizobacteria competitive advantages in rhizosphere environments.

Citing Articles

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Integrated Hfq-interacting RNAome and transcriptomic analysis reveals complex regulatory networks of nitrogen fixation in root-associated A1501.

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