E. coli primase and DNA polymerase III holoenzyme are able to bind concurrently to a primed template during DNA replication.

During DNA replication in E. coli, a switch between DnaG primase and DNA polymerase III holoenzyme (pol III) activities has to occur every time when the synthesis of a new Okazaki fragment starts. As both primase and the χ subunit of pol III interact with the highly conserved C-terminus of single-stranded DNA-binding protein (SSB), it had been proposed that the binding of both proteins to SSB is mutually exclusive. Using a replication system containing the origin of replication of the single-stranded DNA phage G4 (G4ori) saturated with SSB, we tested whether DnaG and pol III can bind concurrently to the primed template. We found that the addition of pol III does not lead to a displacement of primase, but to the formation of higher complexes. Even pol III-mediated primer elongation by one or several DNA nucleotides does not result in the dissociation of DnaG. About 10 nucleotides have to be added in order to displace one of the two primase molecules bound to SSB-saturated G4ori. The concurrent binding of primase and pol III is highly plausible, since even the SSB tetramer situated directly next to the 3'-terminus of the primer provides four C-termini for protein-protein interactions.

The helicase-binding domain of Escherichia coli DnaG primase interacts with the highly conserved C-terminal region of single-stranded DNA-binding protein.

During bacterial DNA replication, DnaG primase and the χ subunit of DNA polymerase III compete for binding to single-stranded DNA-binding protein (SSB), thus facilitating the switch between priming and elongation. SSB proteins play an essential role in DNA metabolism by protecting single-stranded DNA and by mediating several important protein-protein interactions. Although an interaction of SSB with primase has been previously reported, it was unclear which domains of the two proteins are involved. This study identifies the C-terminal helicase-binding domain of DnaG primase (DnaG-C) and the highly conserved C-terminal region of SSB as interaction sites. By ConSurf analysis, it can be shown that an array of conserved amino acids on DnaG-C forms a hydrophobic pocket surrounded by basic residues, reminiscent of known SSB-binding sites on other proteins. Using protein-protein cross-linking, site-directed mutagenesis, analytical ultracentrifugation and nuclear magnetic resonance spectroscopy, we demonstrate that these conserved amino acid residues are involved in the interaction with SSB. Even though the C-terminal domain of DnaG primase also participates in the interaction with DnaB helicase, the respective binding sites on the surface of DnaG-C do not overlap, as SSB binds to the N-terminal subdomain, whereas DnaB interacts with the ultimate C-terminus.

Investigation of protein-protein interactions of single-stranded DNA-binding proteins by analytical ultracentrifugation.

Bacterial single-stranded DNA-binding (SSB) proteins are essential for DNA metabolism, since they protect stretches of single-stranded DNA and are required for numerous crucial protein-protein interactions in DNA replication, recombination, and repair. At the lagging strand of the DNA replication fork of Escherichia coli, for example, SSB contacts not only DnaG primase but also the χ subunit of DNA polymerase III, thereby facilitating the switch between primase and polymerase activity. Here, we describe a powerful method that allows the study of interactions between SSB and its binding partners by sedimentation velocity experiments in an analytical ultracentrifuge. Whenever two molecules interact, a complex of a higher mass forms that can usually be distinguished from free binding partners by its different sedimentation behavior. As an example, we show how sedimentation velocity experiments of purified proteins can be employed to determine the binding parameters of the interaction of SSB and the χ subunit of DNA polymerase III from E. coli.

Characterization of the χψ subcomplex of Pseudomonas aeruginosa DNA polymerase III.

BACKGROUND: DNA polymerase III, the main enzyme responsible for bacterial DNA replication, is composed of three sub-assemblies: the polymerase core, the ß-sliding clamp, and the clamp loader. During replication, single-stranded DNA-binding protein (SSB) coats and protects single-stranded DNA (ssDNA) and also interacts with the χψ heterodimer, a sub-complex of the clamp loader. Whereas the χ subunits of Escherichia coli and Pseudomonas aeruginosa are about 40% homologous, P. aeruginosa ψ is twice as large as its E. coli counterpart, and contains additional sequences. It was shown that P. aeruginosa χψ together with SSB increases the activity of its cognate clamp loader 25-fold at low salt. The E. coli clamp loader, however, is insensitive to the addition of its cognate χψ under similar conditions. In order to find out distinguishing properties within P. aeruginosa χψ which account for this higher stimulatory effect, we characterized P. aeruginosa χψ by a detailed structural and functional comparison with its E. coli counterpart. RESULTS: Using small-angle X-ray scattering, analytical ultracentrifugation, and homology-based modeling, we found the N-terminus of P. aeruginosa ψ to be unstructured. Under high salt conditions, the affinity of the χψ complexes from both organisms to their cognate SSB was similar. Under low salt conditions, P. aeruginosa χψ, contrary to E. coli χψ, binds to ssDNA via the N-terminus of ψ. Whereas it is also able to bind to double-stranded DNA, the affinity is somewhat reduced. CONCLUSIONS: The binding to DNA, otherwise never reported for any other ψ protein, enhances the affinity of P. aeruginosa χψ towards the SSB/ssDNA complex and very likely contributes to the higher stimulatory effect of P. aeruginosa χψ on the clamp loader. We also observed DNA-binding activity for P. putida χψ, making this activity most probably a characteristic of the ψ proteins from the Pseudomonadaceae.

Site-directed mutagenesis of the χ subunit of DNA polymerase III and single-stranded DNA-binding protein of E. coli reveals key residues for their interaction.

During DNA replication in Escherichia coli, single-stranded DNA-binding protein (SSB) protects single-stranded DNA from nuclease action and hairpin formation. It is known that the highly conserved C-terminus of SSB contacts the χ subunit of DNA polymerase III. However, there only exists a theoretical model in which the 11 C-terminal amino acids of SSB have been docked onto the surface of χ. In order to refine this model of SSB/χ interaction, we exchanged amino acids in χ and SSB by site-directed mutagenesis that are predicted to be of key importance. Detailed characterization of the interaction of these mutants by analytical ultracentrifugation shows that the interaction area is correctly predicted by the model; however, the SSB C-terminus binds in a different orientation to the χ surface. We show that evolutionary conserved residues of χ form a hydrophobic pocket to accommodate the ultimate two amino acids of SSB, P176 and F177. This pocket is surrounded by conserved basic residues, important for the SSB/χ interaction. Mass spectrometric analysis of χ protein cross-linked to a C-terminal peptide of SSB reveals that K132 of χ and D172 of SSB are in close contact. The proposed SSB-binding site resembles those described for RecQ and exonuclease I.