The parA and parB genes of Pseudomonas aeruginosa are located approximately 8 kb anticlockwise from oriC. ParA is a cytosolic protein present at a level of around 600 molecules per cell in exponential phase, but the level drops about fivefold in stationary phase. Overproduction of full-length ParA or the N-terminal 85 amino acids severely inhibits growth of P. aeruginosa and P. putida. Both inactivation of parA and overexpression of parA in trans in P. aeruginosa also lead to accumulation of anucleate cells and changes in motility. Inactivation of parA also increases the turnover rate (degradation) of ParB. This may provide a mechanism for controlling the level of ParB in response to the growth rate and expression of the parAB operon.The ubiquitous superfamily of Walker-type ATPases is involved in many bacterial processes (7,34,45). One subfamily of these proteins, the ParA proteins, normally functions with a second protein, ParB, and in plasmid systems the combination of ParA and ParB has been associated with better-than-random segregation of low-copy-number plasmids (6,19,23). Although the plasmid partitioning systems fall into two groups on the basis of the ATPase type of component A (type I with Walker-type ATPase and type II with actin-like ATPase), the two groups seem to be unified in the general mechanism of plasmid pairing and directional separation of plasmid molecules prior to cell division. The ParB-like protein binds a centromere-like sequence and is proposed to form pairs of the plasmid molecules (12,17,30,54). The separation of replicons and their transfer towards opposite poles of the dividing cell correlate with the ability of the ParA-like protein to form a dynamic scaffold in the cells (1,3,11,41), its ATPase activity, and its ability to interact with the ParB-parS complex.Duplication of bacterial chromosomes is part of the cell cycle events leading to cell division. Data gathered during the last decade have revealed the role of many different proteins involved in replication and segregation, as well as the spatial and temporal sequence of these processes (4, 14). However, there are still many questions concerning the directional separation of chromosomes to the progeny cells and the regulation of this process. The discovery of highly conserved homologues of ParA (Walker-type ATPase) and ParB encoded by bacterial chromosomes in close vicinity to oriC (5, 18, 36, 44, 47) suggested a role for these proteins in chromosome segregation. To date, the potential roles of both the ParA and ParB proteins in cell biology have been related to regulatory cell cycle check points (8,16,37,44,48,49), positioning of oriC domains (38, 50), separation of replicated origins (37), and the translocation of the proteins to fixed cell locations (55, 61). Studies on chromosomal ParA and ParB also revealed a lack of uniformity in their action in different organisms despite the high degree of conservation at the levels of sequence and genetic organization (5,20,21,26,32,40,44,55,56,60).The aim of the work described in th...
