Abstract
Genetic and biochemical evidence suggests that λ Orf is a recombination mediator, promoting nucleation of either bacterial RecA or phage Redβ recombinases onto single-stranded DNA (ssDNA) bound by SSB protein. We have identified a diverse family of Orf proteins that includes representatives implicated in DNA base flipping and those fused to an HNH endonuclease domain. To confirm a functional relationship with the Orf family, a distantly-related homolog, YbcN, from Escherichia coli cryptic prophage DLP12 was purified and characterized. As with its λ relative, YbcN showed a preference for binding ssDNA over duplex. Neither Orf nor YbcN displayed a significant preference for duplex DNA containing mismatches or 1-3 nucleotide bulges. YbcN also bound E. coli SSB, although unlike Orf, it failed to associate with an SSB mutant lacking the flexible C-terminal tail involved in coordinating heterologous protein-protein interactions. Residues conserved in the Orf family that flank the central cavity in the λ Orf crystal structure were targeted for mutagenesis to help determine the mode of DNA binding. Several of these mutant proteins showed significant defects in DNA binding consistent with the central aperture being important for substrate recognition. The widespread conservation of Orf-like proteins highlights the importance of targeting SSB coated ssDNA during lambdoid phage recombination.
Highlights
Recombination in bacteriophages salvages genomes for packaging by restoring damaged or broken molecules via exonuclease processing and annealing
At the first PSI-BLAST iteration additional sequences with an expectation value of less than 461029 were identified, including a highly diverged Orf-like protein (YbcN) from the DLP12 cryptic prophage of E. coli belonging to the PRK09741 conserved domain [17], currently classified as distinct from the PF05772 NinB (l Orf) family
Further searches initiated with DLP12 YbcN recovered typical Orf proteins including those from Aaw23, Stx2 and l at the second PSI-BLAST iteration confirming the relationship
Summary
Recombination in bacteriophages salvages genomes for packaging by restoring damaged or broken molecules via exonuclease processing and annealing. Illegitimate exchanges promote rapid evolution as new gene combinations or acquisitions can be generated during joint formation. L exonuclease (Reda) degrades the DNA duplex to generate 39 ssDNA tails, which are bound by Redb protein, a strand annealing protein that searches for homologous ssDNA sequences [1,4]. The combined action of Reda and Redb would be expected to favor splice-type recombinants, there is evidence to indicate that annealing events occur regularly in the context of exposed ssDNA at a replication fork [5,6,7]. DNA synthesis primed by the 39 annealed strand or by template switching can provide a means of generating intact genomes suitable for incorporation into capsids
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