An oligonucleotide inhibits oligomerization of a rolling circle initiator protein at the pT181 origin of replication.

A large number of plasmids have been shown to replicate by a rolling circle (RC) mechanism. The initiators encoded by these plasmids have origin-specific, nicking-closing activity that is required for the initiation and termination of RC replication. Since the initiators of many RC plasmids are rate-limiting for replication, these proteins are usually inactivated after supporting one round of replication. In the case of the pT181 plasmid, inactivation of the initiator RepC protein occurs by the attachment of an oligonucleotide to its active tyrosine residue. We have generated the inactivated form of RepC, termed RepC*, in vitro and investigated the effects of attachment of the oligonucleotide on its various biochemical activities. Our results demonstrate that while RepC* is inactive in nicking-closing and replication activities due to the blockage of its active tyrosine residue, it is competent in origin DNA binding and DNA religation activities. We have investigated the oligomeric state of RepC and RepC* and found that RepC exists as a dimer in solution and can oligomerize on the DNA. We have generated heterodimers in vitro between the wild-type and epitope-tagged RepC proteins. In electrophoretic mobility shift experiments, the initiator heterodimers generated a novel DNA-protein complex, demonstrating that it binds to DNA as a dimer. We have shown that a DNA binding mutant of RepC can be targeted to the origin in the presence of the wild-type protein primarily through a protein-protein interaction. Interestingly, RepC* is defective in its ability to oligomerize on the DNA. RepC* inhibited the DNA binding and replication activity of wild-type RepC to only a very limited extent, suggesting that it may play only a minor regulatory role in replication in vivo. Based on these and earlier results, we propose a model for the role of RepC during the initiation and termination of pT181 RC replication.

Sequence requirements for the termination of rolling-circle replication of plasmid pT181.

Most small multicopy plasmids of Gram-positive bacteria and many in Gram-negative bacteria replicate by a rolling-circle (RC) mechanism. The replication initiator proteins encoded by the RC plasmids and single-stranded bacteriophages of Escherichia coli have origin-specific nicking-closing activities that are required for the initiation and termination of RC replication. We have investigated the sequence requirements for termination of RC replication of plasmid pT181. The initiator nick site is located in the loop of a hairpin region (IRII) within the pT181 origin of replication. By mutational analysis, we have found that several nucleotides within the stem of IRII which are critical for the initiation activity are dispensable for termination of replication. We also demonstrate that nucleotides in the right arm of IRII, but not the left arm, are absolutely required for termination of RC replication. We have also identified specific nucleotides in IRII that are critical for its termination activity. The sequence of the right arm of the hairpin must be located downstream of the initiator nick site for termination, suggesting that termination requires a specific orientation of the initiator protein at the origin.

An 18-base-pair sequence is sufficient for termination of rolling-circle replication of plasmid pT181.

pT181 and related plasmids of gram-positive bacteria replicate by a rolling-circle mechanism. The replication initiator protein of pT181, RepC, has origin-specific nicking-closing activities. Replication of the plasmid pT181 leading strand initiates by covalent extension of the RepC-generated nick, and the origin of replication contains signals for both initiation and termination of DNA replication. We have investigated the sequence requirements for the initiation and termination steps by using plasmids containing two pT181 origins. In vitro replication experiments showed that 18- and 24-bp synthetic oligonucleotides containing the RepC nick site were active in the termination of replication. However, initiation of replication required a larger region which also includes the RepC binding site. Plasmids containing the 18- and 24-bp region were also found to be nicked by the RepC protein. Our results demonstrate that sequence requirements for initiation and termination of pT181 replication overlap, but while the RepC binding site is required for initiation, it is dispensable for termination.

Structural and functional analysis of the single-strand origin of replication from the lactococcal plasmid pWV01.

The single-strand origin (SSO) of the rolling-circle (RC), broad-host-range lactococcal plasmid pWVO1 was functionally characterized. The activity of this SSO in the conversion of single-stranded DNA to double-stranded DNA was tested both in vivo and in vitro. In addition, the effect of this SSO on plasmid maintenance was determined. The functional pWVO1 SSO comprises a 250 bp region, containing two inverted repeats (IRs). The activity of each IR was tested, separately and in combination, in a plasmid derivative that was otherwise completely devoid of structures that might function as SSO. One of the IRs (IR I) showed some homology with other previously described SSOs of the SSOA type, as well as with the conversion signal of the Escherichia coli phage phi X174. This IR was shown to have a partial, RNA polymerase-independent activity in complementary strand synthesis, both in vivo and in vitro. The second IR, which had no activity of its own, was required for full SSO activity, both in vivo and in vitro. The conversion of single-stranded DNA to the double-stranded form by the complete SSO was only partly sensitive to inhibition by rifampicin, indicating the existence of an RNA polymerase-independent pathway for this event. The results suggest that the pWVO1 SSO can be activated by two different routes: an RNA polymerase-dependent one (requiring the entire SSO), and an RNA polymerase-independent one (requiring only IR I).

Localization of the start sites of lagging-strand replication of rolling-circle plasmids from gram-positive bacteria.

A number of small, multicopy plasmids from Gram-positive bacteria replicate by an asymmetric rolling-circle mechanism. Previous studies with several of these plasmids have identified a palindromic sequence, SSOA, that acts as the single-strand origin (SSO) for the replication of the lagging-strand DNA. Although not all the SSOA sequences share DNA sequence homology, they are structurally very similar. We have used an in vitro system to study the lagging-strand replication of several plasmids from Gram-positive bacteria using the SSOA sequences of pT181, pE194 and pSN2 as representative of three different groups of Staphylococcus aureus plasmids. In addition, we have investigated the lagging-strand replication of the pUB110 plasmid that contains an alternative single-strand origin, SSOU. Our results confirm that RNA polymerase is involved in lagging-strand synthesis from both SSOA and SSOU-type lagging-strand origins. Interestingly, while initiation of lagging-strand DNA synthesis of pUB110 occurred predominantly at a single position within SSOU, replication of pT181, pSN2 and pE194 plasmids initiated at multiple positions from SSOA.