Negative regulation of pPS10 plasmid replication: origin pairing by zipping-up DNA-bound RepA monomers.

In many plasmid replicons of gram-negative bacteria, Rep protein dimers are transcriptional self-repressors of their genes, whereas monomers are initiators of DNA replication. Switching between both functions implies conformational remodelling of Rep, and is promoted by Rep binding to the origin DNA repeats (iterons) or chaperones. Rep proteins play another key role: they bridge together two iteron DNA stretches, found either on the same or on different plasmid molecules. These so-called, respectively, 'looped' and 'handcuffed' complexes are thought to be negative regulators of plasmid replication. Although evidence for Rep-dependent plasmid handcuffing has been found in a number of replicons, the structure of these Rep-DNA assemblies is still unknown. Here, by a combination of proteomics, electron microscopy, genetic analysis and modelling, we provide insight on a possible three-dimensional structure for two handcuffed arrays of the iterons found at the origin of pPS10 replicon. These are brought together in parallel register by zipping-up DNA-bound RepA monomers. We also present evidence for a distinct role of RepA dimers in DNA looping. This work defines a new regulatory interface in Rep proteins.

Early events in the binding of the pPS10 replication protein RepA to single iteron and operator DNA sequences.

RepA protein, encoded in the Pseudomonas pPS10 replicon, is a stable dimer in solution (dRepA), acting as a self-repressor of repA transcription through binding to an inverted repeat operator. However, RepA monomers (mRepA) are required to initiate plasmid replication upon binding to four directly repeated DNA sequences (iterons). RepA is composed of two winged-helix (WH) domains: C-terminal WH2 is the main DNA-binding domain (DBD) for both target sequences, whereas N-terminal WH1 acts as dimerization interface in dRepA, but becomes a second DBD in mRepA. On the basis of CD spectroscopy, hydrodynamics, X-ray crystallography and model building studies, we proposed previously that the activation of RepA initiator implies a large structural change in WH1, coupled to protein monomerization and interdomain compaction. Here, we report novel features in the process. Binding curves of RepA to an iteron, followed by fluorescence anisotropy in solution and by surface plasmon resonance on immobilized DNA, exhibit the profiles characteristic of transitions between three states. In contrast, RepA-R93C, a monomeric activated mutant, exhibits a single binding transition. This suggests the presence of an intermediate species in the iteron-induced dissociation and structural transformation of RepA. High concentrations of bovine serum albumin or ovalbumin (macromolecular crowding) enhance RepA affinity for an iteron in solution and, in gel mobility-shift assays, result in the visualization of novel protein-DNA complexes. RepA-induced DNA bending requires the binding of two WH domains: either both WH2 in dimers (operator) or WH1 plus WH2 in monomers (iteron).

Structural changes in RepA, a plasmid replication initiator, upon binding to origin DNA.

RepA protein is the DNA replication initiator of the Pseudomonas plasmid pPS10. RepA dimers bind to an inversely repeated operator sequence in repA promoter, thus repressing its own synthesis, whereas monomers bind to four directly repeated sequences (iterons) to initiate DNA replication. We had proposed previously that RepA is composed of two winged-helix (WH) domains, a structural unit also present in eukaryotic and archaeal initiators. To bind to the whole iteron sequence through both domains, RepA should couple monomerization to a conformational change in the N-terminal WH, which includes a leucine zipper-like sequence motif. We show for the first time that, by itself, binding to iteron DNA in vitro dissociates RepA dimers into monomers and alters RepA conformation, suggesting an allosteric effect. Furthermore, we also show that similar changes in RepA are promoted by mutations that substitute two Leu residues of the putative leucine zipper by Ala, destabilizing the hydrophobic core of the first WH. We propose that this mutant (RepA-2L2A) resembles a transient folding intermediate in the pathway leading to active monomers. These findings, together with the known activation of other Rep-type proteins by chaperones, are relevant to understand the molecular basis of plasmid DNA replication initiation.