Nucleotide sequence and copy control function of the extension of the incI region (incI-b) of Rts 1

Strong minor groove base conservation in sequence logos implies DNA distortion or base flipping during replication and transcription initiation

The sequence logo for DNA binding sites of the bacteriophage P1 replication protein RepA shows unusually high sequence conservation ( approximately 2 bits) at a minor groove that faces RepA. However, B-form DNA can support only 1 bit of sequence conservation via contacts into the minor groove. The high conservation in RepA sites therefore implies a distorted DNA helix with direct or indirect contacts to the protein. Here I show that a high minor groove conservation signature also appears in sequence logos of sites for other replication origin binding proteins (Rts1, DnaA, P4 alpha, EBNA1, ORC) and promoter binding proteins (sigma(70), sigma(D) factors). This finding implies that DNA binding proteins generally use non-B-form DNA distortion such as base flipping to initiate replication and transcription.

Analysis of functional domains of Rts1 RepA by means of a series of hybrid proteins with P1 RepA

The RepA protein of the plasmid Rts1, consisting of 288 amino acids, is a trans-acting protein essential for initiation of plasmid replication. To study the functional domains of RepA, hybrid proteins of Rts1 RepA with the RepA initiator protein of plasmid P1 were constructed such that the N-terminal portion was from Rts1 RepA and the C-terminal portion was from P1 RepA. Six hybrid proteins were examined for function. The N-terminal region of Rts1 RepA between amino acid residues 113 and 129 was found to be important for Rts1 ori binding in vitro. For activation of the origin in vivo, an Rts1 RepA subregion between residues 177 and 206 as well as the DNA binding domain was required. None of the hybrid initiator proteins activated the P1 origin. Both in vivo and in vitro studies showed, in addition, that a C-terminal portion of Rts1 RepA was required along with the DNA binding and ori activating domains to achieve autorepression, suggesting that the C-terminal region of Rts1 RepA is involved in dimer formation. A hybrid protein consisting of the N-terminal 145 amino acids of Rts1 and the C-terminal 142 amino acids from P1 showed strong interference with both Rts1 and P1 replication, whereas other hybrid proteins showed no or little effect on P1 replication.

Expression and regulation of the RepA protein of the RepFIB replicon from plasmid P307

The control of RepFIB replication appears to rely on the interaction between an initiator protein (RepA) and two sets of DNA repeat elements located on either side of the repA gene. Limited N-terminal sequence information obtained from a RepA:beta-galactosidase fusion protein indicates that although the first residue of RepA is methionine, the initiation of translation of RepA occurs from a CTG codon rather than from the predicted GTG codon located further downstream. Overexpressed RepA in trans is capable of repressing a repA:lacZ fusion plasmid in which the expression of the fusion protein is under the control of the repA promoter. The repA promoter has been located functionally by testing a series of repA:lacZ fusion plasmids. Both in vivo genetic tests and in vitro DNA-binding studies indicate that repA autoregulation can be achieved by RepA binding to one or more repeat elements which overlap the repA promoter sequence.

Replication properties of mini-Rts1 derivatives deleted for DnaA boxes in the replication origin

Mini-Rts1 was found to be unable to replicate in a dnaA-null mutant. However, a mini-Rts1 derivative lacking entire tandem DnaA boxes in the replication origin retained the replication ability in a dnaA+ host although its copy number was about half that of the mini-Rts1 having complete DnaA boxes. Mini-Rts1cop1 that contains a high copy number mutation in repA was found to replicate more efficiently than mini-Rts1 of wild repA when DnaA boxes were deleted. In addition, the copy number of mini-Rts1cop1 without DnaA boxes increased 1.5-fold upon removal of incI iterons, whereas that of mini-Rts1 without DnaA boxes did not increase after the iterons were deleted. These indicate that the RepAcop1 protein can initiate the replication of mini-Rts1 efficiently even when DnaA boxes are absent from the origin of replication.

Protein-DNA interactions in regulation of P1 plasmid replication

The P1 RepA protein appears to play three roles in P1 plasmid replication: acting at the origin both as a specific initiator and as a repressor of transcription, and interacting with the copy-control locus incA to bring about a negative control of initiation. We have used the DNase I footprinting technique to show that RepA binds specifically to repeat units of a 19-base-pair consensus sequence present in both the origin and incA control regions. RNA polymerase was shown to bind to two specific regions within the origin repeats. One of these constitutes the known promoter sequence for the repA gene. We show evidence that the polymerase can be efficiently displaced from the promoter by subsequent RepA binding, thus providing a direct mechanism for RepA autoregulation. Under the conditions used, there were no obvious differences in the affinities of individual repeat sequences for the purified protein.

Purification of Rts1 RepA protein and binding of the protein to mini-Rts1 DNA

RepA protein, essential for the replication of plasmid Rts1, was purified, and its binding to mini-Rts1 subregions was examined by a DNase I protection assay. RepA protected the incI and incII iterons, a region immediately upstream of the repA promoter, and a 10-base-pair region located between the most external incII iteron and a GATC box. The protection was less efficient when preheated RepA was used.