Tina M. Henkin

Snyder and Champness Molecular Genetics of Bacteria


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terA and terB in only one direction, opposite that indicated by the black arrows. (B) When they meet, between or at one of the two clusters, chromosome replication terminates. fL is the fork that initiated to the left and moved in a counterclockwise direction. fR is the fork that initiated to the right and moved in a clockwise direction. Adapted from Camara JE, Crooke E, in Higgins MP, ed, The Bacterial Chromosome (ASM Press, Washington, DC, 2005), with permission.

      Structural Features of Bacterial Genomes

      It is widely appreciated that the chromosomes are the information storehouse for an organism. What is less appreciated is that the chromosome as a structure has evolved sequence motifs that allow it to be efficiently replicated, repaired, and segregated into daughter cells. The distribution and orientation of these motifs are discussed here; the molecular biology of the systems that recognize these sequences is explained in greater detail in the text. The placement of these sequence motifs in the context of the chromosome is important for their function, as is the orientation of many of these sequences. Many of the motifs are oriented in one direction, which follows the direction of the DNA replication fork. DNA replication in E. coli and B. subtilis (and all bacteria studied to date) is initiated within a single oriC region and continues bidirectionally to a position on the chromosome equidistant from the origin (indicated by the long arrow-headed line in the figure). The dif site where the resolution of dimer chromosomes occurs is found near to where DNA replication normally terminates.

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      Other polar sequence biases in the chromosome include an overrepresentation of the 5′-CTG-3′ sequence that primes lagging-strand DNA synthesis (not shown). Interestingly, the most common triplet codon is the CUG (5′-CTG-3′ in DNA) that codes for leucine, comprising almost 5% of all codons in E. coli. The 5′-CTG-3′ sequence is found in the chi sequence and all of the most frequent 8-bp sequences in the chromosome. It would be difficult to argue which came first, the use of this sequence by the primase or its frequency of use as a codon. Another type of sequence bias, but one that is not polar in nature, is a general sequence bias called the G/C skew, where G and C are overrepresented in the leading strand. The trend toward A and T in the lagging strand is believed not to have an adaptive value but to be a result of the way in which repair differs on the two strands.

      There are other DNA sequences that are not polar but that show biases for regions of the chromosome. Around the origin of B. subtilis, an area recognized by the Spo0J protein for segregation of the origin region to daughter cells, the parS sequence, is found 8 times (the orange rectangular boxes in the figure). Also around the origin of B. subtilis, there is an enrichment of ram sites (short yellow dashes), a sequence recognized by the RacA protein for maintaining segregation during sporulation. Binding sites for the nucleoid occlusion proteins which prevent septum formation until division is nearly complete reside across the chromosome but are absent from the terminus region. SlmA-binding sites (SBS) in E. coli and Noc-binding sites (NBS) in B. subtilis (long brown dashes) are recognized by SlmA and Noc, respectively. The GATC sites (not shown), which are important for regulating the initiation of DNA replication at oriC in E. coli, also show enrichment in the oriC region, with a spacing that is important for SeqA binding. The organization of the large domain comprising the terminus region of the chromosome appears to be important in E. coli, where the MatP protein recognizes matS sites (red dashes in the E. coli diagram) found across this region.

      References

      Blattner FR, Plunkett G III, Bloch CA, Perna NT, Burland V, Riley M, Collado-Vides J, Glasner JD, Rode CK, Mayhew GF, Gregor J, Davis NW, Kirkpatrick HA, Goeden MA, Rose DJ, Mau B, Shao Y. 1997. The complete genome sequence of Escherichia coli K-12. Science 277:1453–1462.

      Touzain F, Petit M-A, Schbath S, El Karoui M. 2011. DNA motifs that sculpt the bacterial chromosome. Nat Rev Microbiol 9:15–26.

      While bacteria do not contain a special membrane compartment for chromosomal DNA like the nucleus of eukaryotes, even in bacteria the chromosome does not freely diffuse within the cytoplasm. In fact, as we learn more about bacterial chromosomes, we are realizing that they are maintained with an incredible amount of organization.