Structure and Function of the Bacterial Genome. Charles J. Dorman

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Structure and Function of the Bacterial Genome - Charles J. Dorman

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rel="nofollow" href="#ulink_384988a7-a838-508a-b443-06c34f95feee">Figure 1.9 The choreography of chromosome movement in E. coli during the cell cycle. (a) In slow‐growing E. coli cells, chromosome replication is initiated at the origin (Ori, green/yellow lozenge) located at mid‐cell, and proceeds bidirectionally, copying the left (LR, light blue) and right (RR, dark blue) replichores and ending in the terminus (red), where the products of replication are decatenated prior to segregation into the daughter cells. Arrows drawn alongside the chromosome are used to indicate the direction of replication fork movement. (b) Rapidly growing E. coli cells have multiple rounds of chromosome replication underway simultaneously. Instead of the mid‐cell position seen in slow‐growing E. coli cells, the Ori is at the cell pole in the rapidly growing bacteria. The newly born cell has its Ter region displaced towards one pole of the cell and this undergoes a transition to the mid‐cell. A second round of chromosome replication starts before the previous one is complete and multiple replication forks can be observed. The final separation of the daughter chromosomes is thought to exert a force at the terminus that moves this part of the chromosome to an eccentric position that is maintained in the daughter cell immediately after its birth (Youngren et al. 2014).

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      The presence or absence of a ParAB‐parS system is a major determinant of the pattern of chromosome segregation seen in a bacterium. E. coli does not possess such a system and forces of mutual repulsion acting on the chromosome copies as they emerge in the confined space of the rod‐shaped cell may drive them to segregate, perhaps aided by the imprinted structural and super‐structural features of the chromosomes (Jun and Mulder 2006; Jun and Wright 2010; Junier et al. 2014; Pelletier et al. 2012; Wiggins et al. 2010).

      ParAB‐parS systems may be useful rather than essential in bacteria that have just one chromosome, unless the bacterium is sporulating (Ireton et al. 1994) or going through a growth phase transition (Godfrin‐Estevenon et al. 2002). If the microbe has more than one chromosome, then the partitioning system is essential if the segregation of its different chromosomes is to be properly coordinated, as, for example, in the case of V. cholerae (Yamaichi et al. 2007) or members of the Burkholderias (Passot et al. 2012). The roles of chromosome‐encoded ParAB‐parS systems as functioning partitioning machines was confirmed in early work where it was demonstrated that they could replace the native plasmid par systems on single copy episomes (Godfrin‐Estevenon et al. 2002; Lin and Grossman 1998; Yamaichi and Niki 2000).

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      The ParA protein drives bidirectional segregation of the parS‐ParB complexes in an ATP‐dependent manner. It can form filaments, and these have been proposed to be a factor in chromosome segregation (Bouet et al. 2007; Hui et al. 2010; Ptacin et al. 2010). However, it is also possible that ParA‐driven chromosome segregation works by a diffusion‐ratchet‐type mechanism that has been described for its plasmid‐encoded counterparts (Hwang et al. 2013; Vecchiarelli et al. 2014) or a trans‐nucleoid relay mechanism (Lim et al. 2014).

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