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. 1997 Jan;179(1):141–147. doi: 10.1128/jb.179.1.141-147.1997

In vitro inhibitory activity of RepC/C*, the inactivated form of the pT181 plasmid initiation protein, RepC.

R Jin 1, A Rasooly 1, R P Novick 1
PMCID: PMC178672  PMID: 8981991

Abstract

pT181 is a Staphylococcus aureus rolling circle plasmid that regulates its replication by controlling the synthesis of its dimeric initiator protein RepC/C and by inactivating the protein following its use in replication (A. Rasooly and R. P. Novick, Science 262:1048-1050, 1993). This inactivation consists of the addition of an oligonucleotide, representing several nucleotides immediately 3' to the initiation nick site, to the active site tyrosine of one of the two subunits, generating a heterodimer, RepC/C*. Previous results suggested that the inactive form was metabolically stable and was present at a much higher level than the active form (A. Rasooly and R. P. Novick, Science 262:1048-1050, 1993). In the present study we have measured total RepC antigen as a function of plasmid copy number and have analyzed the interaction of the two forms. We find that pT181-containing staphylococci contain approximately one RepC dimer per plasmid copy over a 50-fold range of copy numbers. This is consistent with previous measurements of the rate of RepC synthesis, which suggested that one RepC dimer is synthesized per replication event (J. Bargonetti, P.-Z. Wang and R. P. Novick, EMBO J. 12:3659-3667, 1993). The RepC/C* heterodimer, which is inactive for replication, is a competitive inhibitor of the replication and the topoisomerase-like and cruciform-enhancing activities of the native protein. These results suggest that the inactive form may have a specific regulatory role in vivo. Since the known plasmid-determined controls, which maintain a constant plasmid copy number, are designed to ensure the synthesis of one RepC/C dimer per plasmid replication event, it is difficult to envision any role for yet another negative regulator of replication. Conceivably, under conditions where the initiator is overproduced, such as in the absence of the normal antisense regulation of initiator production, RepC/C* could serve as a fail-safe means of preventing autocatalytic replication.

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Selected References

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