Mechanisms of Regulation of Cryptic Prophage-Encoded Gene Products in Escherichia coli

The operon of Qin cryptic prophage in Escherichia coli K-12 encodes the small RNA (sRNA) DicF and small protein DicB, which regulate host cell division and are toxic when overexpressed. While new functions of DicB and DicF have been identified in recent years, the mechanisms controlling the expressi...

Full description

Saved in:
Bibliographic Details
Published in:Journal of bacteriology 2023-08, Vol.205 (8), p.e0012923-e0012923
Main Authors: Ragunathan, Preethi T, Ng Kwan Lim, Evelyne, Ma, Xiangqian, Massé, Eric, Vanderpool, Carin K
Format: Article
Language:English
Subjects:
Bacteriology
Cell division
Derepression
E coli
Escherichia coli
Filamentation
Gene silencing
Phages
Prophages
Proteins
Ribonuclease E
Ribonuclease III
Stationary phase
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The operon of Qin cryptic prophage in Escherichia coli K-12 encodes the small RNA (sRNA) DicF and small protein DicB, which regulate host cell division and are toxic when overexpressed. While new functions of DicB and DicF have been identified in recent years, the mechanisms controlling the expression of the operon have remained unclear. Transcription from the major promoter of the operon, is repressed by DicA. In this study, we discovered that transcription of the operon and processing of the polycistronic mRNA is regulated by multiple mechanisms. DicF sRNA accumulates during stationary phase and is processed from the polycistronic mRNA by the action of both RNase III and RNase E. DicA-mediated transcriptional repression of can be relieved by an antirepressor protein, Rem, encoded on the Qin prophage. Ectopic production of Rem results in cell filamentation due to strong induction of the operon, and filamentation is mediated by DicF and DicB. Spontaneous derepression of occurs in a subpopulation of cells independent of the antirepressor. This phenomenon is reminiscent of the bistable switch of λ phage with DicA and DicC performing functions similar to those of CI and Cro, respectively. Additional experiments demonstrate stress-dependent induction of the operon. Collectively, our results illustrate that toxic genes carried on cryptic prophages are subject to layered mechanisms of control, some that are derived from the ancestral phage and some that are likely later adaptations. Cryptic or defective prophages have lost genes necessary to excise from the bacterial chromosome and produce phage progeny. In recent years, studies have found that cryptic prophage gene products influence diverse aspects of bacterial host cell physiology. However, to obtain a complete understanding of the relationship between cryptic prophages and the host bacterium, identification of the environmental, host, or prophage-encoded factors that induce the expression of cryptic prophage genes is crucial. In this study, we examined the regulation of a cryptic prophage operon in Escherichia coli encoding a small RNA and a small protein that are involved in inhibiting bacterial cell division, altering host metabolism, and protecting the host bacterium from phage infections.
ISSN:0021-9193
1098-5530
DOI:10.1128/jb.00129-23