Accumulation of ornithine lipids in Vibrio cholerae under phosphate deprivation is dependent on VC0489 (OlsF) and PhoBR system

Livia C. Barbosa; Carolina L. Goulart; Marcela M. Avellar; Paulo M. Bisch; Wanda M. A. von Kruger

doi:10.1099/mic.0.000607

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f Accumulation of ornithine lipids in Vibrio cholerae under phosphate deprivation is dependent on VC0489 (OlsF) and PhoBR system

Authors: Livia C. Barbosa^1,† , Carolina L. Goulart^1,† , Marcela M. Avellar¹ , Paulo M. Bisch¹ , Wanda M. A. von Kruger¹
- VIEW AFFILIATIONS
- ¹ Laboratório de Física Biológica, Instituto de Biofísica Carlos Chagas Filho, Universidade Federal do Rio de Janeiro, Rio de Janeiro, Brazil
*Correspondence: Livia C. Barbosa [email protected]
First Published Online: 22 January 2018, Microbiology 164: 395-399, doi: 10.1099/mic.0.000607
Subject: Physiology and Metabolism

Received: 18/11/2017
Accepted: 10/01/2018
Cover date: 01/03/2018

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Ornithine lipids (OLs) are phosphorus-free lipids found in many bacteria grown under phosphate deprivation, a condition that activates the PhoBR system and leads to phosphate uptake and metabolism. Two OL synthesis pathways have already been described. One depends on OlsB and OlsA acyltransferases to add, respectively, the first and second acyl chains to an ornithine molecule. The other pathway is carried out by OlsF, a bifunctional enzyme responsible for both acylation steps. Although Vibrio cholerae lacks olsBA genes, an olsF homologue (vc0489) was identified in its genome. In this work we demonstrated that V. cholerae produces OLs and expresses vc0489 in response to phosphate depletion, in a PhoBR-dependent manner. In Escherichia coli, under similar condition, vc0489 expression leads to OL accumulation. These results indicate a strong connection between OL synthesis and VC0489 from V. cholerae and, for the first time, a direct regulation of an olsF homologue by the PhoBR system.

†
These authors contributed equally to this work.

Keyword(s): membrane lipids, gene regulation, Pho regulon, membrane plasticity, phosphate response, phosphorous-free lipids

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