Chemical inhibition of cell surface modification sensitizes bacteria to phage infection.

Many bacteriophages that infect Gram-positive bacteria rely on the bacterial cell surface polymer wall teichoic acid (WTA) as a receptor. However, some bacteria modulate their cell wall with d-alanine residues, which can disrupt phage adsorption. The prevalence and significance of WTA alanylation as an anti-phage defense is unknown. A chemical inhibitor of WTA d-alanylation could be employed to efficiently screen phage-host combinations for those that exhibit alanylation-dependent infections. Since the incorporation of d-alanine residues into the cell wall requires the activity of d-alanine:alanyl carrier protein ligase (DltA), a DltA inhibitor was employed as this tool. Herein, we found that a chemical probe inhibiting DltA activity impeded bacterial cell wall alanylation and enhanced infectivity of many phages against Bacillus subtilis, including phages Phi29, SPP1, SPO1, SP50, and Goe2. This finding reveals the breadth of immunity conferred by WTA alanylation in B. subtilis, which was previously known to impact only phages Phi29 and SPP1, but not SPO1, SP50, or Goe2. DltA inhibition selectively promoted infection by several phages that bind WTA, having no impact on the flagellotropic phage PBS1. Unexpectedly, DltA inhibition also had no effect on phage SP10, which binds to WTA. This selective chemical tool has the potential to unravel bacteriophage interactions with bacteria, leading to improved phage therapies in the future.

Bacterium secretes chemical inhibitor that sensitizes competitor to bacteriophage infection.

To overtake competitors, microbes produce and secrete secondary metabolites that kill neighboring cells and sequester nutrients. This natural product-mediated competition likely evolved in complex microbial communities that included viral pathogens. From this ecological context, we hypothesized that microbes secrete metabolites that "weaponize" natural pathogens (i.e., bacteriophages) to lyse their competitors. Indeed, we discovered a bacterial secondary metabolite that sensitizes other bacteria to phage infection. We found that this metabolite provides the producer (a Streptomyces sp.) with a fitness advantage over its competitor (Bacillus subtilis) by promoting phage infection. The phage-promoting metabolite, coelichelin, sensitized B. subtilis to a wide panel of lytic phages, and it did so by preventing the early stages of sporulation through iron sequestration. Beyond coelichelin, other natural products may provide phage-mediated competitive advantages to their producers-either by inhibiting sporulation or through yet-unknown mechanisms.

A Metabolite Produced by Gut Microbes Represses Phage Infections in Vibrio cholerae.

Vibrio cholerae is the causative agent of the severe diarrheal disease cholera. Bacteriophages that prey on V. cholerae may be employed as phage therapy against cholera. However, the influence of the chemical environment on the infectivity of vibriophages has been unexplored. Here, we discovered that a common metabolite produced by gut microbes─linear enterobactin (LinEnt), represses vibriophage proliferation. We found that the antiphage effect by LinEnt is due to iron sequestration and that multiple forms of iron sequestration can protect V. cholerae from phage predation. This discovery emphasizes the significance that the chemical environment can have on natural phage infectivity and phage-based interventions.

Correction: Highly efficient room-temperature phosphorescence achieved by gadolinium complexes.

Correction for 'Highly efficient room-temperature phosphorescence achieved by gadolinium complexes' by Boxun Sun et al., Dalton Trans., 2019, 48, 14958-14961.

Highly efficient room-temperature phosphorescence achieved by gadolinium complexes.

A new family of room temperature phosphorescent materials with emission lifetimes in microseconds has been reported in this work. Phosphorescence of gadolinium complexes with emission color from blue to orange has been obtained at room temperature with a maximum photoluminescence quantum yield of 66%, benefiting from appropriate molecular structures and favorable encapsulation methods.