G. Scott Gordon scite author profile

We have investigated DNA segregation in E. coli by inserting multiple lac operator sequences into the chromosome near the origin of replication (oriC), in the hisC gene, a terminus marker, and into plasmids P1 and F. Expression of a GFP-LacI fusion protein allowed visualization of lac operator localization. oriC was shown to be specifically localized at or near the cell poles, and when duplicated, one copy moved to the site of new pole formation near the site of cell division. In contrast, P1 and F localized to the cell center and on duplication appeared to move rapidly to the quarter positions in the cell. Our analysis suggests that different active processes are involved in movement and localization of the chromosome and of the two plasmids during segregation.

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DNA Segregation in Bacteria

Gordon

Wright

2000

Annu. Rev. Microbiol.

130

117

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Segregation of DNA in bacterial cells is an efficient process that assures that every daughter cell receives a copy of genomic and plasmid DNA. In this review, we focus primarily on observations in recent years, including the visualization of DNA and proteins at the subcellular level, that have begun to define the events that separate DNA molecules. Unlike the process of chromosome segregation in higher cells, segregation of the bacterial chromosome is a continuous process in which chromosomes are separated as they are replicated. Essential to separation is the initial movement of sister origins to opposite ends of the cell. Subsequent replication and controlled condensation of DNA are the driving forces that move sister chromosomes toward their respective origins, which establishes the polarity required for segregation. Final steps in the resolution and separation of sister chromosomes occur at the replication terminus, which is localized at the cell center. In contrast to the chromosome, segregation of low-copy plasmids, such as Escherichia coli F, P1, and R1, is by mechanisms that resemble those used in eukaryotic cells. Each plasmid has a centromere-like site to which plasmid-specified partition proteins bind to promote segregation. Replication of plasmid DNA, which occurs at the cell center, is followed by rapid partition protein-mediated separation of sister plasmids, which become localized at distinct sites on either side of the division plane. The fundamental similarity between chromosome and plasmid segregation-placement of DNA to specific cell sites-implies an underlying cellular architecture to which both DNA and proteins refer.

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Bacterial conjugative transfer: visualization of successful mating pairs and plasmid establishment in live Escherichia coli

Lawley

Gordon

Wright

et al. 2002

Molecular Microbiology

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Summary We used the LacO/GFP–LacI system to label and visualize the IncPβ plasmid R751 fluorescently during conjugative transfer between live donor and recipient bacteria. Comparisons of R751 in conjugative and non‐conjugative conditions have allowed us to identify key localizations and movements associated with the initiation of conjugative transfer in the donor and the establishment of R751 in the recipient. A survey of successful mating pairs demonstrates that close physical contact between donor and recipient bacteria is required for DNA transfer and that regions of intimate contact can occur at any location on the donor or recipient cell membrane. The transferred DNA is positioned at the characteristic centre or quarter‐cell position after conversion to a double‐stranded molecule in the recipient cell. Initial duplication of plasmids often results in an asymmetric distribution of plasmid foci. Symmetric localization (either at centre or at 1/4 and 3/4 cell lengths) occurs only after a significant lag, presumably reflecting the time required to synthesize the plasmid‐encoded partitioning proteins.

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Polar localization of the Escherichia coli oriC region is independent of the site of replication initiation

Gordon

Shivers

Wright³

2002

Molecular Microbiology

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Summary The location of the origin‐linked region of the Escherichia coli chromosome was analysed in strains lacking the core origin locus, oriC. In these strains, which initiate replication from F factors integrated at different locations around the chromosome, origin‐linked DNA remains localized near the cell poles, as in wild‐type cells. In contrast, minichromosomes containing 7 kb of chromosomal DNA including oriC are generally excluded from the ends of the cell. Thus, we propose that positioning of the wild‐type origins at the poles is not a function of their order of replication but a sequence‐specific phenomenon. It is proposed that there are centromere‐like sequences, bordering the wild‐type origin of replication, which are used by host mechanisms to direct the proper placement of the origin region of the chromosome. This function, combined with other host processes, may assure efficient segregation of the E. coli chromosome.

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DNA segregation: Putting chromosomes in their place

Gordon

Wright

1998

Current Biology

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G. Scott Gordon

Chromosome and Low Copy Plasmid Segregation in E. coli: Visual Evidence for Distinct Mechanisms

DNA Segregation in Bacteria

Bacterial conjugative transfer: visualization of successful mating pairs and plasmid establishment in live Escherichia coli

Polar localization of the Escherichia coli oriC region is independent of the site of replication initiation

DNA segregation: Putting chromosomes in their place

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