The sabotage of the bacterial transcription machinery by a small bacteriophage protein

Prophage-encoded small protein YqaH counteracts the activities of the replication initiator DnaA in Bacillus subtilis

Bacterial genomes harbour cryptic prophages that are mostly transcriptionally silent with many unannotated genes. Still, cryptic prophages may contribute to their host fitness and phenotypes. In Bacillus subtilis, the yqaF-yqaN operon belongs to the prophage element skin, and is tightly repressed by the Xre-like repressor SknR. This operon contains several small ORFs (smORFs) potentially encoding small-sized proteins. The smORF-encoded peptide YqaH was previously reported to bind to the replication initiator DnaA. Here, using a yeast two-hybrid assay, we found that YqaH binds to the DNA binding domain IV of DnaA and interacts with Spo0A, a master regulator of sporulation. We isolated single amino acid substitutions in YqaH that abolished the interaction with DnaA but not with Spo0A. Then, using a plasmid-based inducible system to overexpress yqaH WT and mutant derivatives, we studied in B. subtilis the phenotypes associated with the specific loss-of-interaction with DnaA (DnaA_LOI). We found that expression of yqaH carrying DnaA_LOI mutations abolished the deleterious effects of yqaH WT expression on chromosome segregation, replication initiation and DnaA-regulated transcription. When YqaH was induced after vegetative growth, DnaA_LOI mutations abolished the drastic effects of YqaH WT on sporulation and biofilm formation. Thus, YqaH inhibits replication, sporulation and biofilm formation mainly by antagonizing DnaA in a manner that is independent of the cell cycle checkpoint Sda.

Structural basis for transcription antitermination at bacterial intrinsic terminator

Bacteriophages typically hijack the host bacterial transcriptional machinery to regulate their own gene expression and that of the host bacteria. The structural basis for bacteriophage protein-mediated transcription regulation—in particular transcription antitermination—is largely unknown. Here we report the 3.4 Å and 4.0 Å cryo-EM structures of two bacterial transcription elongation complexes (P7-NusA-TEC and P7-TEC) comprising the bacteriophage protein P7, a master host-transcription regulator encoded by bacteriophage Xp10 of the rice pathogen Xanthomonas oryzae pv. Oryzae (Xoo) and discuss the mechanisms by which P7 modulates the host bacterial RNAP. The structures together with biochemical evidence demonstrate that P7 prevents transcription termination by plugging up the RNAP RNA-exit channel and impeding RNA-hairpin formation at the intrinsic terminator. Moreover, P7 inhibits transcription initiation by restraining RNAP-clamp motions. Our study reveals the structural basis for transcription antitermination by phage proteins and provides insights into bacterial transcription regulation.

Bacteriophages reprogram the host transcriptional machinery. Here the authors provide insights into the mechanism of how bacteriophages regulate host transcription by determining the cryo-EM structures of two bacterial transcription elongation complexes bound with the bacteriophage master host-transcription regulator protein P7.

The Xp10 Bacteriophage Protein P7 Inhibits Transcription by the Major and Major Variant Forms of the Host RNA Polymerase via a Common Mechanism

The σ factor is a functionally obligatory subunit of the bacterial transcription machinery, the RNA polymerase. Bacteriophage-encoded small proteins that either modulate or inhibit the bacterial RNAP to allow the temporal regulation of bacteriophage gene expression often target the activity of the major bacterial σ factor, σ⁷⁰. Previously, we showed that during Xanthomonas oryzae phage Xp10 infection, the phage protein P7 inhibits the host RNAP by preventing the productive engagement with the promoter and simultaneously displaces the σ⁷⁰ factor from the RNAP. In this study, we demonstrate that P7 also inhibits the productive engagement of the bacterial RNAP containing the major variant bacterial σ factor, σ⁵⁴, with its cognate promoter. The results suggest for the first time that the major variant form of the host RNAP can also be targeted by bacteriophage-encoded transcription regulatory proteins. Since the major and major variant σ factor interacting surfaces in the RNAP substantially overlap, but different regions of σ⁷⁰ and σ⁵⁴ are used for binding to the RNAP, our results further underscore the importance of the σ–RNAP interface in bacterial RNAP function and regulation and potentially for intervention by antibacterials.

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Xp10 phage transcription regulator P7 inhibits transcription by RNAP containing σ⁵⁴.

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P7 prevents the productive engagement of the σ⁵⁴–RNAP with the promoter DNA.

• P7 disrupts preformed σ⁵⁴–RNAP-promoter complexes.

Global transcriptional response of Clostridium difficile carrying the CD38 prophage

Clostridium difficile is one of the most dangerous pathogens in hospital settings. Most strains of C. difficile carry one or more prophages, and some of them, like CD38-2 and CD119, can influence the expression of toxin genes. However, little is known about the global host response in the presence of a given prophage. In order to fill this knowledge gap, we used high-throughput RNA sequencing (RNA-seq) to conduct a genome-wide transcriptomic analysis of the epidemic C. difficile strain R20291 carrying the CD38-2 prophage. A total of 39 bacterial genes were differentially expressed in the R20291 lysogen, 26 of them being downregulated. Several of the regulated genes encode transcriptional regulators and phosphotransferase system (PTS) subunits involved in glucose, fructose, and glucitol/sorbitol uptake and metabolism. CD38-2 also upregulated the expression of a group of regulatory genes located in phi-027, a resident prophage common to most ribotype 027 isolates. The most differentially expressed gene was that encoding the conserved phase-variable cell wall protein CwpV, which was upregulated 20-fold in the lysogen. Quantitative PCR and immunofluorescence showed that the increased cwpV expression results from a greater proportion of cells actively transcribing the gene. Indeed, 95% of f lysogenic cells express cwpV, as opposed to only 5% of wild-type cells. Furthermore, the higher proportion of cells expressing cwpV results from a higher frequency of recombination of the genetic switch controlling phase variation, which we confirmed to be dependent on the host-encoded recombinase RecV. In summary, CD38-2 interferes with phase variation of the surface protein CwpV and the expression of metabolic genes.