Structure and Function of the Bacterial Genome. Charles J. Dorman. Читать онлайн. Newlib. NEWLIB.NET

Автор: Charles J. Dorman
Издательство: John Wiley & Sons Limited
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Жанр произведения: Биология
Год издания: 0
isbn: 9781119309680
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the 5′‐GATC‐3′ sites at the promoter that become hemimethylated following DNA replication (Bogan and Helmstetter 1997). The process of transcribing gidA and mioC is important for the initiation of chromosome replication at oriC (Bramhill and Kornberg 1988b; Theisen et al. 1993), at least under some circumstances (Asai et al. 1998; Bates et al. 1997; Lies et al. 2015).

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      The primase, DnaG, possesses a central RNA polymerase domain where the RNA primers used in DNA synthesis are manufactured (Corn et al. 2008). The primer emerges from the DnaG‐DnaB complex and is transferred to DNA polymerase and SSB (Corn et al. 2008). DNA Polymerase III works with the beta‐clamp protein (DnaN) to extend the primer, creating a new DNA strand at a rate of 1000 bases per second (Beattie and Reyes‐Lamothe 2015). It is advantageous to have DnaN as a component of the replisome because a beta‐clamp must be reloaded for the synthesis of each lagging strand Okazaki fragment (Beattie and Reyes‐Lamothe 2015). If the replication fork stalls or breaks, replication can be restarted through a DnaA‐independent mechanism. Here, the PriA helicase, in association with accessory proteins such as PriB, PriC, and DnaT, binds to the gapped replication fork and loads DnaBC. In some cases, the restart may be associated with a strong transcription promoter that generates an R‐loop where PriA can introduce DnaBC on the displaced DNA strand (Heller and Marians 2006; Kogoma 1997). Of the approximately 300 copies of DNA gyrase that are bound to the E. coli chromosome at any one time, about 12 accompany each moving replication fork to manage the DNA topological disturbance that is associated with fork migration (Stracy et al. 2019).

      

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      The newly synthesised DNA strand is unmethylated and forms one part of a hemimethylated duplex. For this reason, the products of chromosome replication are chemically distinct from the template duplex until a full methylation of the newly synthesised strand has taken place. DNA adenine methyltransferase, Dam, methylates DNA at 5′‐GATC‐3′ sites and there are 11 of these sites in oriC (Figure 1.2). The SeqA protein binds to these sites while they are still in their hemimethylated form, sequestering the origin and excluding DnaA (Han et al. 2003; Slater et al. 1995; von Freiesleben et al. 1994). The sequestered state persists for about one third of the cell cycle when it is relieved by dissociation of SeqA and methylation of the 5′‐GATC‐3′ sites by Dam (Kang, S. et al. 1999; Lu et al. 1994). SeqA also interferes with expression of the dnaA gene, reducing the levels of the DnaA protein available for binding to oriC (Campbell and Kleckner 1990). In addition, SeqA contributes to processes that ensure proper segregation of the chromosome copies at cell division (Helgesen et al. 2015; Waldminghaus and Skarstad 2009). It is interesting to note that both hemimethylated oriC and SeqA have been shown to associate with the cell envelope (Ogden et al. 1988; Slater et al. 1995), perhaps indicating a role for the complex in the positioning of oriC in the cell.

      The converging replication forks moving along the chromosome will create a topological problem as they approach one another in the Ter region. As chromosome replication comes to an end, the products that it generates will emerge as intertwined DNA duplexes. This physical linkage must be resolved if it is not to impede