Cell Division Cycle Fluctuation of Pal Concentration in Escherichia Coli

Overview

Journal Access Microbiol

Specialty Microbiology

Date 2024 Nov 14

PMID 39539348

Authors

Laureen M Y Mertens

Xinwei Liu

Jolanda Verheul

Alexander J F Egan

Waldemar Vollmer

Tanneke den Blaauwen

Affiliations

Soon will be listed here.

Abstract

The Tol-Pal proteins stabilize the outer membrane during cell division in many Gram-negative bacteria, including . Pal is an outer membrane lipoprotein that can bind peptidoglycan. It accumulates at the septum during division by a mobilization-and-capture mechanism. This work further substantiates and extends knowledge of Pal's localization in using immunolabelling; this method enables the detection of endogenous proteins. The midcell localization of Pal and TolB, as seen with fluorescent protein fusions, during cell division, was confirmed. The retention of Pal in newly formed cell poles seemed to persist longer than observed with fluorescent Pal fusions. The concentration of endogenous Pal during the cell division cycle fluctuated: it decreased initially (to half the fluorescence concentration (32.1 au µm) of the maximum (64.1 au µm) reached during the cell cycle) and then increased during the second half of the cell division cycle. We probed for possible regulators and proposed two new putative regulators of Pal. By deleting the periplasmic protease, Prc decreased the total Pal abundance (to ~65% of the fluorescence concentration in WT cells) and affected its concentration fluctuation during the cell cycle. This suggests that Prc controls a cell division stage-specific regulator of Pal. Immunolabelling also supported the prediction that the small RNA MicA suppresses Pal expression (the fluorescence concentration of Pal in cells without MicA is double that of Pal in WT cells). However, the regulation by MicA occurred in a cell cycle-independent manner. All these findings urge further research on the tight regulation of the dividing cell envelope stability.

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