Displacement of SSB Protein from Single Stranded DNA by λ Phage Beta Protein

Abstract

Genetic engineering in vivo by homologous recombination, also known as recombineering, is a well-established method allowing DNA alterations on any replicon in E. coli. Recombineering uses the bacteriophage λ Red recombination functions, Exo (a 5’ to 3’ double strand (ds)DNA exonuclease) and Beta (a single strand (ss)DNA binding and annealing protein). Recombineering with ss-oligonucleotides is more efficient than with dsDNA and requires only Beta activity. One of the two possible complementary oligonucleotides that can be used for any recombination gives a much higher frequency. The oligonucleotide of the same sequence as Okazaki fragments at the replication fork lagging strand shows the higher recombination frequency. This suggests a mechanism by which the oligonucleotide bound Beta is annealed directly to the complementary single strand region at the replication fork. For this to happen, single-strand DNA binding protein (SSB) would need to be displaced during annealing of the Beta-oligonucleotide complex. Recently Roy and colleagues (Nature (2009) 461, 1092-97) proposed that diffusion of SSB along a single-strand DNA allows its displacement by RecA. A 99 base oligo should be long enough to allow SSB to diffuse along it. We have investigated the binding of SSB to a 99 base oligonucleotide by surface plasmon resonance (SPR) spectroscopy in the presence of complementary or non-complementary oligos and without or with Beta. Beta only in the presence of complementary oligo is able to facilitate the displacement of SSB. We have evaluated the role of potassium glutamate and spermidine on Beta's ability to displace SSB.