SummaryThe mechanism of bacteriophage DNA injection is poorly understood, often considered a simple process, driven merely by the packing pressure inside the capsid. In contrast to the well-established DNA packaging mechanism of Bacillus subtilis phage Ø29, that involves a molecular motor formed by the connector and a viral ATPase, nothing is known about its DNA injection into the cell. We have studied this process measuring DNA binding of p6, a viral genome organization protein. The linear DNA penetrates with a right-left polarity, in a two-step process. In the first step ~ 65% of the genome is pushed into the cell most probably by the pressure built inside the viral capsid. Thus, synthesis of viral proteins from the right early operon is allowed. This step is controlled, probably by bacterial protein(s) that slow down DNA entry. In the second step at least one of the viral early proteins, p17, participates in the molecular machinery that pulls the remaining DNA inside the cell. Both steps are energy-dependent, as treatment of cells with azide overrides the whole mechanism, leading to a deregulated, passive entry of DNA.
The viral protein p6, required for the protein-primed initiation of replication of Bacillus subtilis phage phi 29, forms a nucleoprotein complex at the viral replication origins that shows novel features. Deoxyribonuclease I and hydroxyl radical footprinting data, as well as the induction of positive supercoiling, support a model in which a DNA right-handed superhelix tightly wraps around a multimeric p6 core. The interaction occurs through the DNA minor groove. The activity of p6 not only requires the formation of the complex but also its correct positioning, indicating that the other proteins involved in the initiation of replication recognize, at a precise position, either the p6 core or the DNA conformational change induced by p6.
Protein p6 of Bacillus subtilis phage phi 29 binds specifically to the ends of the viral DNA that contain the replication origins, giving rise to a nucleoprotein structure. DNA regions recognized by protein p6 have been mapped by deletion analysis and DNase I footprinting. Main protein p6‐recognition signals have been located between nucleotides 62 and 125 at the right phi 29 DNA end and between nucleotides 46 and 68 at the left end. In addition, recognition signals are also present at other sites within 200‐300 bp at each phi 29 DNA end. Protein p6 does not seem to recognize a specific sequence in the DNA, but rather a structural feature, which could be bendability. The formation of the protein p6‐DNA nucleoprotein complex is likely to be the structural basis for the protein p6 activity in the initiation of replication.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.