In single-stranded RNA bacteriophages (ssRNA phages) a single copy of the maturation protein binds the genomic RNA (gRNA) and is required for attachment of the phage to the host pilus. For the canonical Qβ the maturation protein, A, has an additional role as the lysis protein, by its ability to bind and inhibit MurA, which is involved in peptidoglycan biosynthesis. Here, we determined structures of Qβ virions, virus-like particles, and the Qβ-MurA complex using single-particle cryoelectron microscopy, at 4.7-Å, 3.3-Å, and 6.1-Å resolutions, respectively. We identified the outer surface of the β-region in A as the MurA-binding interface. Moreover, the pattern of MurA mutations that block Qβ lysis and the conformational changes of MurA that facilitate A binding were found to be due to the intimate fit between A and the region encompassing the closed catalytic cleft of substrate-liganded MurA. Additionally, by comparing the Qβ virion with Qβ virus-like particles that lack a maturation protein, we observed a structural rearrangement in the capsid coat proteins that is required to package the viral gRNA in its dominant conformation. Unexpectedly, we found a coat protein dimer sequestered in the interior of the virion. This coat protein dimer binds to the gRNA and interacts with the buried α-region of A, suggesting that it is sequestered during the early stage of capsid formation to promote the gRNA condensation required for genome packaging. These internalized coat proteins are the most asymmetrically arranged major capsid proteins yet observed in virus structures.
Summary
The lysis protein A2, present as a single copy on the surface of Qβ virion particles, was previously shown to inhibit the activity of MurA, an enzyme that catalyzes the first committed step of murein biosynthesis. Here we report experiments with a two-hybrid study that indicates A2 and MurA interact directly. Moreover, experiments with a soluble MBP-A2 fusion indicate that the interaction between MurA and A2 is dependent on a substrate-induced conformational change featured in the UDP-NAG-liganded state of MurA but not the tetrahedral intermediate state. Moreover, based on the location of L138Q, the original dominant A2-resistant mutant that identified MurA as the target, a directed mutagenesis strategy has identified a continuous surface required for A2 binding. This surface spans the catalytic loop/cleft and encompasses both the catalytic and C-terminal domains. These data support a model in which A2 preferentially binds MurA liganded with UDP-NAG, thereby preventing catalysis by occluding PEP from accessing the active site.
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