Christopher M. Thomas scite author profile

Low copy-number bacterial plasmids F (the classical Escherichia coli sex factor) and prophage P1 encode partitioning functions which may provide fundamental insights into the active processes which ensure that bacterial genomes are segregated to both daughter cells prior to cell division. These partitioning systems involve two proteins: ParA and ParB. We report that incC from the broad host-range plasmid RK2 is a member of the family of ParA partitioning proteins and that these proteins (as well as related proteins encoded by plasmids from Agrobacterium tumefaciens and Chlamydia trachomatis) contain type I nucleotide-binding motifs. Also, we show that the cell division inhibitor MinD is homologous to members of the ParA family. Sequence comparisons of ParB proteins suggest that they may contain sites for phosphorylation. We propose that ATP hydrolysis by the ParA protein may result in phosphorylation of the ParB protein, thereby causing a conformational shift necessary to separate paired plasmid molecules at the cell division plane.

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The bacterial ParA-ParB partitioning proteins

Bignell

Thomas

2001

Journal of Biotechnology

193

174

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The 64 508 bp IncP-1β antibiotic multiresistance plasmid pB10 isolated from a waste-water treatment plant provides evidence for recombination between members of different branches of the IncP-1β group

et al. 2003

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The complete 64 508 bp nucleotide sequence of the IncP-1b antibiotic-resistance plasmid pB10, which was isolated from a waste-water treatment plant in Germany and mediates resistance against the antimicrobial agents amoxicillin, streptomycin, sulfonamides and tetracycline and against mercury ions, was determined and analysed. A typical class 1 integron with completely conserved 59 and 39 segments is inserted between the tra and trb regions. The two mobile gene cassettes of this integron encode a b-lactamase of the oxacillin-hydrolysing type (Oxa-2) and a gene product of unknown function (OrfE-like), respectively. The pB10-specific gene load present between the replication module (trfA1) and the origin of vegetative replication (oriV ) is composed of four class II (Tn3 family) transposable elements: (i) a Tn501-like mercury-resistance (mer) transposon downstream of the trfA1 gene, (ii) a truncated derivative of the widespread streptomycin-resistance transposon Tn5393c, (iii) the insertion sequence element IS1071 and (iv) a Tn1721-like transposon that contains the tetracycline-resistance genes tetA and tetR. A very similar Tn501-like mer transposon is present in the same target site of the IncP-1b degradative plasmid pJP4 and the IncP-1b resistance plasmid R906, suggesting that pB10, R906 and pJP4 are derivatives of a common ancestor. Interestingly, large parts of the predicted pB10 restriction map, except for the tetracycline-resistance determinant, are identical to that of R906. It thus appears that plasmid pB10 acquired as many as five resistance genes via three transposons and one integron, which it may rapidly spread among bacterial populations given its high promiscuity. Comparison of the pB10 backbone DNA sequences with those of other sequenced IncP-1b plasmids reveals a mosaic structure. While the conjugative transfer modules (trb and tra regions) and the replication module are very closely related to the corresponding segments of the IncP-1b resistance plasmid R751 and even more similar to the IncP-1b degradative plasmids pTSA and pADP-1, the stable inheritance operons klcAB-korC and kleAEF are most similar to those of the IncP-1b resistance plasmid pB4, and clearly less similar to the other IncP-1b plasmids. This suggests that IncP-1b plasmids can undergo recombination in the environment, which may enhance plasmid diversity and bacterial adaptability.

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ParB deficiency in Pseudomonas aeruginosa destabilizes the partner protein ParA and affects a variety of physiological parameters

et al. 2009

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Deletions leading to complete or partial removal of ParB were introduced into the Pseudomonas aeruginosa chromosome. Fluorescence microscopy of fixed cells showed that ParB mutants lacking the C-terminal domain or HTH motif formed multiple, less intense foci scattered irregularly, in contrast to the one to four ParB foci per cell symmetrically distributed in wild-type P. aeruginosa. All parB mutations affected both bacterial growth and swarming and swimming motilities, and increased the production of anucleate cells. Similar effects were observed after inactivation of parA of P. aeruginosa. As complete loss of ParA destabilized its partner ParB it was unclear deficiency of which protein is responsible for the mutant phenotypes. Analysis of four parB mutants showed that complete loss of ParB destabilized ParA whereas three mutants that retained the N-terminal 90 aa of ParB did not. As all four parB mutants demonstrate the same defects it can be concluded that either ParB, or ParA and ParB in combination, plays an important role in nucleoid distribution, growth and motility in P. aeruginosa.

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