Stochastic Activation of a Family of TetR Type Transcriptional Regulators Controls Phenotypic Heterogeneity in

Overview

Journal PNAS Nexus

Specialty General Medicine

Date 2023 Jan 27

PMID 36704122

Authors

Maria Perez-Varela

Aimee R P Tierney

Emma Dawson

Anna R Hutcheson

Kyle A Tipton

Sarah E Anderson

Marina E Haldopoulos

Shaina Song

Brooke R Tomlinson

Lindsey N Shaw

David S Weiss

Minsu Kim

Philip N Rather

Affiliations

Soon will be listed here.

Abstract

Phenotypic heterogeneity is an important mechanism for regulating bacterial virulence, where a single regulatory switch is typically activated to generate virulent and avirulent subpopulations. The opportunistic pathogen can transition at high frequency between virulent opaque (VIR-O) and avirulent translucent subpopulations, distinguished by cells that form opaque or translucent colonies. We demonstrate that expression of 11 TetR-type transcriptional regulators (TTTRs) can drive cells from the VIR-O opaque subpopulation to cells that form translucent colonies. Remarkably, in a subpopulation of VIR-O cells, four of these TTTRs were stochastically activated in different combinations to drive cells to the translucent state. The resulting translucent subvariants exhibited unique phenotypic differences and the majority were avirulent. Due to their functional redundancy, a quadruple mutant with all four of these TTTRs inactivated was required to observe a loss of switching from the VIR-O state. Further, we demonstrate a small RNA, SrvS, acts as a "rheostat," where the levels of SrvS expression influences both the VIR-O to translucent switching frequency, and which TTTR is activated when VIR-O cells switch. In summary, this work has revealed a new paradigm for phenotypic switching in bacteria, where an unprecedented number of related transcriptional regulators are activated in different combinations to control virulence and generate unique translucent subvariants with distinct phenotypic properties.

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