Investigating the Process of Sheath Maturation in Antifeeding Prophage: a Phage Tail-Like Protein Translocation Structure.

The antifeeding prophage (Afp) produced by the bacterium Serratia entomophila is the archetypical external contractile injection system (eCIS). Afp and its orthologues are characterized by three sheath proteins, while contractile bacteriophages and pyocins encode only one. Using targeted mutagenesis, transmission electron microscopy (TEM), and pulldown studies, we interrogated the roles of the three sheath proteins (Afp2, Afp3, and Afp4) in Afp assembly, in particular the interaction between the two sequence-related helical-sheath-forming proteins Afp2 and Afp3 and their cross talk with the tail termination sheath capping protein (TrP) Afp16 in the sheath maturation process. The expressed assemblies for the -deficient mutant were mostly a mixture of isolated tail fibers, detached baseplates without tail fibers, and sheathless inner tube baseplate complexes (TBCs) with a length similar to that of mature Afp, which were surrounded in many cases by fibrillar polymerized material. In the -deficient mutant, variable-length TBCs with similar but shorter fibrillar polymerized material, largely bereft of tail fibers, were observed, while only detached baseplate assemblies were seen for the -deficient mutant. Furthermore, we found that (i) only complementation of with its mutated counterpart restored mature Afp particles with full biological activity, (ii) purified Afp3 pulled down Afp2 by forming a sodium dodecyl sulfate (SDS)-resistant complex but not vice versa, (iii) Afp16 had a higher affinity for binding Afp2 or Afp3 than Afp4, and (iv) Afp4 is required for the association of the polymerized sheath on the baseplate via Afp2. A proposed model for sheath maturation and assembly in Afp is presented. Members of the contractile bacteriophage-related but evolutionarily divergent eCIS contain not one but three sheath proteins, two of which, namely, Afp2 and Afp3 in the Afp, arranged as alternate hexameric stacks constitute the helical sheath. We revealed that Afp2 and Afp3, even though they are highly similar, possess markedly distinct, crucial roles in Afp assembly. We find that Afp3, by virtue of its interaction with the tail-terminating protein Afp16, regulates tube and sheath length, while Afp2 is critical for proper sheath polymerization and the assembly of the baseplate. The resulting model for the Afp assembly will further guide the manipulation of Afp and its related eCISs as nanodelivery vehicles for pest control and phage therapy.