ABSTRACT
The ATP– and CTP-dependent ParA-ParB-parS segrosome is a macromolecular complex that segregates chromosomes/plasmids in most bacterial species. CTP binding and hydrolysis enable ParB to slide on DNA and to bridge and condense DNA, thereby dictating the size and dynamics of the tripartite ParABS complex. Several other evolutionarily distinct systems can also segregate DNA, although the full diversity of bacterial DNA partition systems is not yet known. Here, we identify a CTP-independent ParABS system that maintains a conjugative plasmid SCP2 in the filamentous bacterium Streptomyces coelicolor. We demonstrate that an SCP2 ParB-like protein, ParT, loads onto DNA at an 18-bp parS site and diffuses away to the adjacent DNA despite lacking an apparent CTPase domain and detectable NTPase activity. We further show that parS DNA stimulates ParT transition from loading to a diffusing state to accumulate on DNA, and ParT activates the ATPase activity of its cognate partner protein ParA. We also identify numerous structural homologs of ParT, suggesting that CTP-independent diffusion on DNA might be widespread in bacteria despite being previously unappreciated. Overall, our findings uncover a CTP-independent DNA translocation as an alternative and unanticipated mechanism for the assembly of a bacterial DNA segregation complex and suggest that CTP binding and hydrolysis is not a fundamental feature of ParABS-like systems.
Competing Interest Statement
The authors have declared no competing interest.