Characterization of a unique repression system present in arbitrium phages of the SPbeta family

Closely related and yet special - how SPβ family phages control lysis-lysogeny decisions

Soon after the discovery of genetic competence in the Gram-positive bacterium Bacillus subtilis, lytic and temperate phages that infect this organism were isolated. For instance, the lytic phage ϕ29 became a model for studying processes such as viral DNA packaging, replication, and transcription. By contrast, only a handful of temperate B. subtilis phages have been comprehensively characterized. However, the discovery of a peptide-based quorum sensing (QS) system in 2017 has brought temperate B. subtilis phages, particularly those of the SPβ family, back into the focus of research. The QS system is used by these phages to modulate lysis-lysogeny decisions. Meanwhile, many key components of the lysis-lysogeny management system have been identified. It turned out that a complex co-adaptation between the B. subtilis host cell and SPβ-like phages occurred during evolution and that a host-encoded toxin-antitoxin system plays a key role in controlling lysis-lysogeny decisions. There are many similarities and many important differences between the two well-studied model phages. Thus, a further comparative analysis of the lysis-lysogeny systems is essential to uncover the fundamental differences between ϕ3T and SPβ. Moreover, we believe that it would be exciting to revive research on temperate B. subtilis phages that are not related to SPβ-family phages.

Phage small proteins play large roles in phage-bacterial interactions

Phages have wide influence on bacterial physiology, and likewise, bacterial processes impinge on phage biology. Key to these interactions are phage small proteins (<100 aa). Long underappreciated, recent work has revealed millions of phage small proteins, and increasingly, mechanisms by which they function to dictate phage and/or bacterial behavior and evolution. Here, we describe select phage small proteins that mediate phage-bacterial interactions by modulating phage lifestyle decision-making components or by altering host gene expression.

Antagonistic interactions between phage and host factors control arbitrium lysis-lysogeny decision

Phages can use a small-molecule communication arbitrium system to coordinate lysis-lysogeny decisions, but the underlying mechanism remains unknown. Here we determined that the arbitrium system in Bacillus subtilis phage phi3T modulates the bacterial toxin-antitoxin system MazE-MazF to regulate the phage life cycle. We show that phi3T expresses AimX and YosL, which bind to and inactivate MazF. AimX also inhibits the function of phi3T_93, a protein that promotes lysogeny by binding to MazE and releasing MazF. Overall, these mutually exclusive interactions promote the lytic cycle of the phage. After several rounds of infection, the phage-encoded AimP peptide accumulates intracellularly and inactivates the phage antiterminator AimR, a process that eliminates aimX expression from the aimP promoter. Therefore, when AimP increases, MazF activity promotes reversion back to lysogeny, since AimX is absent. Altogether, our study reveals the evolutionary strategy used by arbitrium to control lysis-lysogeny by domesticating and fine-tuning a phage-defence mechanism.