To initiate their life cycle, phages must specifically bind to the surface of their bacterial hosts. Long-tailed phages often interact with the cell surface using fibers, which are elongated intertwined trimeric structures. The folding and assembly of these complex structures generally requires the activity of an intra- or intermolecular chaperone protein. Tail fiber assembly (Tfa) proteins are a very large family of proteins that serve as chaperones for fiber folding in a wide variety of phages infecting diverse species. A recent structural study showed that the Tfa protein from E. coli phage Mu (TfaMu) mediates fiber folding and stays bound to the distal tip of the fiber, becoming a component of the mature phage particle. This finding revealed the potential for TfaMu to also play a role in cell surface binding. To address this issue, here we have shown that TfaMu binds to lipopolysaccharide (LPS), the cell surface receptor of phage Mu with a similar strength as the fiber itself. Furthermore, we have found that TfaMu and the Tfa protein from E. coli phage P2 bind LPS with distinct specificities that mirror the host specificity of these two phages. By comparing the sequences of these two proteins, which are 93% identical, we identified a single residue that is responsible for their distinct LPS-binding behaviours. Although we have not yet found conditions under which Tfa proteins influence host range, the potential for such a role is now evident as we have demonstrated their ability to bind LPS in a strain-specific manner. Importance With the growing interest in using phages to combat antibiotic-resistant infections or manipulate the human microbiome, establishing approaches for the modification of phage host range has become an important research topic. Tfa proteins are a large family of proteins known previously to function as chaperones for the folding of phage fibers, which are crucial determinants of host range for long-tailed phages. Here we reveal that some Tfa proteins are bi-functional with the additional activity of binding to LPS, the surface binding receptor for many phages. This discovery opens up new potential avenues for altering phage host range through engineering of the surface binding specificity of Tfa proteins.
Antibiotic resistance has reached dangerously high levels throughout the world. A growing number of bacteria pose an urgent, serious, and concerning threat to public health. Few new antibiotics are available to clinicians and only few are in development, highlighting the need for new strategies to overcome the antibiotic resistance crisis. Combining existing antibiotics with phages, viruses the infect bacteria, is an attractive and promising alternative to standalone therapies. Phage-antibiotic combinations have been shown to suppress the emergence of resistance in bacteria, and sometimes even reverse it. Here, we discuss the mechanisms by which phage-antibiotic combinations reduce resistance evolution, and the potential limitations these mechanisms have in steering microbial resistance evolution in a desirable direction. We also emphasize the importance of gaining a better understanding of mechanisms behind physiological and evolutionary phage-antibiotic interactions in complex in-patient environments.
Most Pseudomonas aeruginosa strains produce bacteriocins derived from contractile or non-contractile phage tails known as R-type and F-type pyocins, respectively. These bacteriocins possess strain-specific bactericidal activity against P. aeruginosa and likely increase evolutionary fitness through intraspecies competition. R-type pyocins have been studied extensively and show promise as alternatives to antibiotics. Although they have similar therapeutic potential, experimental studies on F-type pyocins are limited. Here, we provide a bioinformatic and experimental investigation of F-type pyocins. We introduce a systematic naming scheme for genes found in R- and F-type pyocin operons and identify 15 genes invariably found in strains producing F-type pyocins. Five proteins encoded at the 3’-end of the F-type pyocin cluster are divergent in sequence, and likely determine bactericidal specificity. We use sequence similarities among these proteins to define 11 distinct F-type pyocin groups, five of which had not been previously described. The five genes encoding the variable proteins associate in two modules that have clearly re-assorted independently during the evolution of these operons. These proteins are considerably more diverse than the specificity-determining tail fibers of R-type pyocins, suggesting that F-type pyocins emerged earlier or have been subject to distinct evolutionary pressures. Experimental studies on six F-type pyocin groups show that each displays a distinct spectrum of bactericidal activity. This activity is strongly influenced by the lipopolysaccharide O-antigen type, but other factors also play a role. F-type pyocins appear to kill as efficiently as R-type pyocins. These studies set the stage for the development of F-type pyocins as anti-bacterial therapeutics.
Pseudomonas aeruginosa is an opportunistic pathogen that causes antibiotic-resistant infections with high mortality rates, particularly in immunocompromised individuals and cystic fibrosis patients. Due to the increasing frequency of multidrug-resistant P. aeruginosa infections, there is great need for the development of alternative therapeutics.
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