Bacteriophage-Encoded Small RNAs: Emerging Tools for Phage Therapy and Antibacterial Intervention

Abstract

Bacteriophages (phages) are viruses that specifically infect bacteria and play a central role in shaping microbial communities and bacterial evolution. Beyond their protein-coding genes, phage genomes were found recently to encode small RNAs (sRNAs) that act post-transcriptionally to regulate host and viral gene expression. These phage-encoded sRNAs can influence infection dynamics, modulate host physiology, and determine the balance between lytic and lysogenic cycles. A prominent example is the phage lambda sRNA PreS, which enhances phage DNA replication by increasing translation of the host dnaN mRNA, linking host replication capacity to phage propagation. This review examines emerging evidence that phage-encoded sRNAs constitute a versatile and underappreciated class of molecular tools. We discuss how such RNAs could be repurposed as precision antibacterial agents in an era of increasing antibiotic resistance and outline key challenges and opportunities for developing RNA-based alternatives to conventional phage therapy.

Keywords

RIL-seq small RNA regulatory RNA phage therapy phage–host interactions post-transcriptional regulation

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References

Abedon

. How simple maths can inform our basic understanding of phage therapy. Clin Infect Dis, 2023; 77(Suppl 5):S401–S406.

Adams

, Storz

. Prevalence of small base-pairing RNAs derived from diverse genomic loci. Biochim Biophys Acta Gene Regul Mech, 2020; 1863(7):194524.

Altuvia

, Storz

, Papenfort

. Cross-regulation between bacteria and phages at a posttranscriptional level. Microbiol Spectr, 2018; 6(4).

Felden

, Augagneur

. Diversity and versatility in small rna-mediated regulation in bacterial pathogens. Front Microbiol, 2021; 12:719977.

Feng

, Rutherford

, Papenfort

, et al. A qrr noncoding RNA deploys four different regulatory mechanisms to optimize quorum-sensing dynamics. Cell, 2015; 160(1–2):228–240.

Gonzalez

, Aranda

. Microbial growth under limiting conditions-future perspectives. Microorganisms, 2023; 11(7):1641.

Hör

, Matera

, Vogel

, et al. Trans-acting small RNAs and their effects on gene expression in Escherichia coli and Salmonella enterica. EcoSal Plus, 2020; 9(1).

Lewandowska

, Bloch

, Łukasiak

, et al. The role of bacteriophage-derived small RNA molecules in bacterial and phage interactions. Viruses, 2025; 17(6):834.

Melamed

, Faigenbaum-Romm

, Peer

, et al. Mapping the small RNA interactome in bacteria using RIL-seq. Nat Protoc, 2018; 13(1):1–33.

10.

Melamed

, Peer

, Faigenbaum-Romm

, et al. Global mapping of small RNA-target interactions in bacteria. Mol Cell, 2016; 63(5):884–897.

11.

Mraheil

, Billion

, Mohamed

, et al. The intracellular sRNA transcriptome of Listeria monocytogenes during growth in macrophages. Nucleic Acids Res, 2011; 39(10):4235–4248.

12.

Novick

, Ross

, Projan

, et al. Synthesis of staphylococcal virulence factors is controlled by a regulatory RNA molecule. Embo J, 1993; 12(10):3967–3975.

13.

Papenfort

, Melamed

. Small RNAs, large networks: Posttranscriptional regulons in gram-negative bacteria. Annu Rev Microbiol, 2023; 77:23–43.

14.

Pichon

, Felden

. Small RNA genes expressed from Staphylococcus aureus genomic and pathogenicity islands with specific expression among pathogenic strains. Proc Natl Acad Sci U S A, 2005; 102(40):14249–14254.

15.

Quereda

, Ortega

ÁD

, Pucciarelli

, et al. The listeria small RNA Rli27 regulates a cell wall protein inside eukaryotic cells by targeting a long 5′-UTR variant. PLoS Genet, 2014; 10(10):e1004765.

16.

Romilly

, Lays

, Tomasini

, et al. A Non-Coding RNA promotes bacterial persistence and decreases virulence by regulating a regulator in staphylococcus aureus. PLoS Pathog, 2014; 10(3):e1003979.

17.

Sawa

, Moriyama

, Kinoshita

. Current status of bacteriophage therapy for severe bacterial infections. J Intensive Care, 2024; 12(1):44.

18.

Silverman

, Melamed

. Biological insights from RNA-RNA interactomes in bacteria, as revealed by RIL-seq. Methods Mol Biol, 2025; 2866:189–206.

19.

Silverman

, Nashef

, Wasserman

, et al. Phage-encoded small RNA hijacks host replication machinery to support the phage lytic cycle. Mol Cell, 2025; 85(24):4678–4697.e12.

20.

Sprenger

, Siemers

, Krautwurst

, et al. Small RNAs direct attack and defense mechanisms in a quorum sensing phage and its host. Cell Host Microbe, 2024; 32(5):727–738.e6.

21.

Strathdee

, Hatfull

, Mutalik

, et al. Phage therapy: From biological mechanisms to future directions. Cell, 2023; 186(1):17–31.

22.

Stukenberg

, Studwell-Vaughan

, O’Donnell

. Mechanism of the sliding beta-clamp of DNA polymerase III holoenzyme. J Biol Chem, 1991; 266(17):11328–11334.

23.

Westermann

, Förstner

, Amman

, et al. Dual RNA-seq unveils noncoding RNA functions in host–pathogen interactions. Nature, 2016; 529(7587):496–501.

24.

Yao

, Zhu

, Duan

, et al. Phage therapy: A novel approach to combat drug-resistant pathogens. Microbiol Res, 2025; 298:128228.