Circular bacterial chromosome

Circular bacterial chromosome
A circular bacterial chromosome, showing DNA replication proceeding bidirectionally, with two replication forks generated at the "origin". Each half of the chromosome replicated by one replication fork is called a "replichore". (Graphic computer art by Daniel Yuen)

Circular bacterial chromosome are the bacterial chromosomes contained in a circular DNA molecule. Unlike the linear DNA of vertebrates, typical bacterial chromosomes contain circular DNA.

Most bacterial chromosomes contain a circular DNA molecule - there are no free ends to the DNA. Free ends would otherwise create significant challenges to cells with respect to DNA replication and stability. Cells that do contain chromosomes with DNA ends, or telomeres (most eukaryotes), have acquired elaborate mechanisms to overcome these challenges. However, a circular chromosome can provide other challenges for cells. After replication, the two progeny circular chromosomes can sometimes remain interlinked or tangled, and they must be resolved so that each cell inherits one complete copy of the chromosome during cell division.


Replication of a circular bacterial chromosome

Bacterial chromosome replication is best understood in the well-studied bacteria Escherichia coli and Bacillus subtilis. Chromosome replication proceeds in three major stages: initiation, elongation and termination. The initiation stage starts with the ordered assembly of "initiator" proteins at the origin region of the chromosome, called oriC. These assembly stages are regulated to ensure that chromosome replication occurs only once in each cell cycle. During the elongation phase of replication, the enzymes that were assembled at oriC during initiation proceed along each arm ("replichore") of the chromosome, in opposite directions away from the oriC, replicating the DNA to create two identical copies. This process is known as bidirectional replication. The entire assembly of molecules involved in DNA replication on each arm is called a "replisome." At the forefront of the replisome is a DNA helicase that unwinds the two strands of DNA, creating a moving "replication fork". The two unwound single strands of DNA serve as templates for DNA polymerase, which moves with the helicase (together with other proteins) to synthesise a complementary copy of each strand. In this way, two identical copies of the original DNA are created. Eventually, the two replication forks moving around the circular chromosome meet in a specific zone of the chromosome, approximately opposite oriC, called the terminus region. The elongation enzymes then disassemble, and the two "daughter" chromosomes are resolved before cell division is completed.


The E. coli bacterial replication origin, called oriC consists of DNA sequences that are recognised by the DnaA protein, which is highly conserved amongst different bacterial species. DnaA binding to the origin initiates the regulated recruitment of other enzymes and proteins that will eventually lead to the establishment of two complete replisomes for bidirectional replication.[1]

DNA sequence elements within oriC that are important for its function include DnaA boxes, a 9-mer repeat with a highly conserved consensus sequence 5' - TTATCCACA - 3',[2] that are recognized by the DnaA protein. DnaA protein plays a crucial role in the initiation of chromosomal DNA replication.[3] Bound to ATP, and with the assistance of bacterial histone-like proteins [HU] DnaA then unwinds an AT-rich region near the left boundary of oriC, which carries three 13-mer motifs,[4] and opens up the double-stranded DNA for entrance of other replication proteins.[5]

This region also contains four “GATC” sequences that are recognized by DNA adenine methylase (Dam), an enzyme that modifies the adenine base when this sequence is unmethylated or hemimethylated. The methylation of adenines is important as it alters the conformation of DNA to promote strand separation,[6] and it appears that this region of oriC has a natural tendency to unwind.[7]

DNA sequence motifs in oriC of the E. coli. The gray bars represent GATC sequences recognized by DNA adenine methyltransferase. Small blue arrows are 13-mer sequences near the left border of oriC that become single-stranded when oriC is bound by DnaA in association with ATP. The red boxes are DnaA box sequences recognized by DnaA protein. Smaller green boxes represent I sites bound by DnaA-ATP. The site within oriC to which integration host factor (IHF) binds is shown between DnaA boxes R1 and R5 (M). Dashed lines represent two regions bound by SeqA protein. (after Jon M. Kaguni 2006).[8]

DnaA then recruits the replicative helicase, DnaB, from the DnaB-DnaC complex to the unwound region to form the pre-priming complex.[9] After DnaB translocates to the apex of each replication fork, the helicase both unwinds the parental DNA and interacts momentarily with primase.[10]

In order for DNA replication to continue, single stranded binding proteins are needed to prevent the single strands of DNA from forming secondary structures and to prevent them from re-annealing. In addition, DNA gyrase is needed to relieve the topological stress created by the action of DnaB helicase.


When the replication fork moves around the circle, a structure shaped like the Greek letter theta Ө is formed. John Cairns demonstrated the theta structure of E. coli chromosomal replication in 1963, using an innovative method to visualize DNA replication. In his experiment, he radioactively labeled the chromosome by growing his cultures in a medium containing 3H-thymidine. The nucleoside base was incorporated uniformly into the bacterial chromosome. He then isolated the chromosomes by lysing the cells gently and placed them on an electron micrograph (EM) grid which he exposed to X-ray film for two months. This Experiment clearly demonstrates the theta replication model of circular bacterial chromosomes.[11]

  • See Autoradiograph of intact replicating chromosome of E.coli [1]

As described above, bacterial chromosomal replication occurs in a bidirectional manner. This was first demonstrated by specifically labelling replicating bacterial chromosomes with radioactive isotopes. The regions of DNA undergoing replication during the experiment were then visualized by using autoradiography and examining the developed film microscopically. This allowed the researchers to see where replication was taking place. The first conclusive observations of bidirectional replication was from studies of B. subtilis.[12] Sortly after, the E. coli chromosome was also shown to replicate bidirectionally.[13]

  • See Figure 4 of D. M. Prescott, and P. L. Kuempel (1972): A grain track produced by an E. coli chromosome from cells labeled for 19 min with [3H] thymine, followed by labelingfor 2.5 min with [3H]thymine and ['H]thymidine. [2].

The E. coli DNA polymerase III holoenzyme is a 900 kD complex, possessing an essentially a dimeric structure. Each monomeric unit has a catalytic core, a dimerization subunit, and a processivity component .[14] DNA Pol III uses one set of its core subunits to synthesize the leading strand continuously, while the other set of core subunits cycles from one Okazaki fragment to the next on the looped lagging strand. Leading strand synthesis begins with the synthesis of a short RNA primer at the replication origin by the enzyme Primase (DnaG protein).

Deoxynucleotides are then added to this primer by a single DNA polymerase III dimer, in an integrated complex with DnaB helicase. Leading strand synthesis then proceeds continuously, while the DNA is concurrently unwound at the replication fork. In contrast, lagging strand synthesis is accomplished in short Okazaki fragments. First, an RNA primer is synthesized by primase, and, like that in leading strand synthesis, DNA Pol III binds to the RNA primer and adds deoxyribonucleotides.

When the synthesis of an Okazaki fragment has been completed, replication halts and the core subunits of DNA Pol III dissociates from the β sliding clamp [B sliding clap is the processivity subunit of DNA Pol III].[15] The RNA primer is remove and replaced with DNA by DNA polymerase I [which also possesses proofreading exonuclease activity] and the remaining nick is sealed by DNA ligase, which then ligates these fragments to form the lagging strand.


Termination is the process of fusion of replication forks and disassembly of the resplisomes to yield two separate and complete DNA molecules. It occurs in the terminus region, approximately opposite oriC on the chromosome (Fig 5). The terminus region contains several DNA replication terminator sites, or "Ter" sites. A special "replicaiton terminator" protein must be bound at the Ter site for it to pause replication. Each Ter site has polarity of action, that is, it will arrest a replication fork approaching the Ter site from one direction, but will allow unimpeded fork movement through the Ter site from the other direction. The arrangement of the Ter sites forms two opposed groups that forces the two forks to meet each other within the region they span. This arrangement is called the "replication fork trap."[16]

  • See locations and sequences of the replication termini of E. coli.(A) Map showing the ori and the 10 Ter sites. (B) The consensus sequence of Ter. [3]

The Ter sites specifically interact with the replication terminator protein called Tus in E. coli.[17] The Tus-Ter complex impedes the DNA unwinding activity of DnaB in an orientation-dependent manner.[18]

  • The crystal structure of the Ter DNA-Tus protein complex (A) showing the nonblocking and the fork-blocking faces of Tus. (B) A cross-sectional view of the helicase-arresting surface.[4]

Replication of the DNA separating the opposing replication forks, leaves the completed chromosomes joined as ‘catenanes’ or topologically interlinked circles. The circles are not covalently linked, but cannot be separated because they are interwound and each is covalently closed. The catenated circles require the action of topoisomerases to separate the circles [decatanation]. In E.coli, DNA topoisomerase IV plays the major role in the separation of the catenated chromosomes, transiently breaking both DNA strands of one chromosome and allowing the other chromosome to pass through the break.

There has been some confusion about the role DNA gyrase plays in decatenation. To define the nomenclature, there are two types of topoisomerases: type I produces transient single-strand breaks in DNA and types II produces transient double-strand breaks. As a result, the type I enzyme removes supercoils from DNA one at a time, whereas the type II enzyme removes supercoils two at a time. The topo I of both prokaryotes and eukaryotes are the type I topoisomerase. The eukaryotic topo II, bacterial gyrase, and bacterial topo IV belong to the type II.

We often forget that DNA gyrase does in fact have topoisomerase type II activity; thus, with it being a homologue of topoisomerase IV (also having topoisomerase II activity) we expect similarity in the two proteins' functions. DNA gyrase preliminary role is to introduce negative super coils into DNA, thereby relaxing positive supercoils that come into play during DNA replication. Topoisomerase IV also relaxes positive supercoils, therefore, DNA Gyrase and topoisomerase IV play an almost identical role in removing the positive supercoils ahead of a translocating DNA polymerase, allowing DNA replication to continue unhindered by topological strain.[19]

Confusion arises when some scientific literature state that DNA gyrase is the sole enzyme responsible for decatanation. In an experiment conducted by Zechiedrich, Khodursky and Cozzarelli in 1997, it was found that topoisomerase IV is the only important decatenase of DNA replication intermediates in bacteria.[20] In this particular experiment, when DNA gyrase alone were inhibited, most of the catenanes were unlinked. However, when Topoisomerase IV alone was inhibited, decatenation was almost completely blocked. The results obtained suggest that Topoisomerase IV is the primary decatenase in vivo, and although DNA gyrase does play a role in decatenation, its function is not as essential as topoisomerase IV in the decatentation of interlinked chromosomes.


This is based on an article by Imalda Devaparanam and David Tribe made available under CC by SA licensing conditions from a University course activity at the Department of Microbiology and Immunology, University of Melbourne, 2007.


This article incorporates material from the Citizendium article "Replication of a circular bacterial chromosome", which is licensed under the Creative Commons Attribution-ShareAlike 3.0 Unported License but not under the GFDL.

  1. ^ Jon M. Kaguni DnaA: Controlling the Initiation of Bacterial DNA Replication and More. Annu. Rev. Microbiol. 2006. 60:351–71
  2. ^ C Weigel, A Schmidt, B Rückert, R Lurz, and W Messer. DnaA protein binding to individual DnaA boxes in the Escherichia coli replication origin, oriC. EMBO J. 1997 November 3; 16(21): 6574–6583.
  3. ^ Hirota Y, Mordoh J and Jacob F (1970) On the process of cellular division in Escherichia coli III. Thermosensitive mutants of Escherichia coli altered in the process of DNA initiation. J Mol Biol, 53, 369–387.
  4. ^ Bramhill D, Kornberg A. 1988. Duplex opening by dnaA protein at novel sequences in initiation of replication at the origin of the E. coli chromosome. Cell 52:743–55
  5. ^ Sekimizu K, Bramhill D and Kornberg A (1987) ATP activates dnaA protein in initiating replication of plasmids bearing the origin of the E.coli chromosome. Cell, 50, 259–265
  6. ^ Gotoh O, Tagashira Y. 1981. Locations of frequently opening regions on natural DNAs and their relation to functional loci. Biopolymers 20:1043–58
  7. ^ Kowalski D, Eddy MJ. 1989. The DNA unwinding element: a novel, cis-acting component that facilitates opening of the Escherichia coli replication origin. EMBO J. 8:4335–44
  8. ^ Jon M. Kaguni DnaA: Controlling the Initiation of Bacterial DNA Replication and More. Annu. Rev. Microbiol. 2006. 60:351–71
  9. ^ Carr KM, Kaguni JM. 2001. Stoichiometry of DnaA and DnaB protein in initiation at the Escherichia coli chromosomal origin. J. Biol. Chem. 276:44919–25
  10. ^ Tougu K, Marians KJ. 1996. The interaction between helicase and primase sets the replication fork clock. J. Biol. Chem. 271:21398–405
  11. ^ Cairns, J.P.: Cold Spring Harbor Symposia on Quantitative Biology 28:44, 1963.
  12. ^ Wake, R.G. 1972. Visualization of reinitiated chromosomes in Bacillus subtilis. J Mol Biol. Jul 28;68(3):501-9.
  13. ^ Prescott D.M., Kuempel P.L. 1972. Bidirectional replication of the chromosome in Escherichia coli. Proc Natl Acad Sci U S A. Oct;69(10):2842-5.
  14. ^ O'Donnell M. , Jeruzalmi D. , Kuriyan J. Clamp loader structure predicts the architecture of DNA polymerase III holoenzyme and RFC. Curr. Biol. 11 R935-R946 2001
  15. ^ Indiani C, O'Donnell M. Mechanism of the delta wrench in opening the beta sliding clamp. J Biol Chem. 2003 Oct 10;278(41):40272-81. Epub 2003 Jul 8.
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  17. ^ Kamada K, Horiuchi T, Ohsumi K, Shimamoto N, Morikawa K. 1996. Structure of a replication-terminator protein complexed with DNA. Nature, 17;383(6601):598-603.
  18. ^ Kaplan DL, Bastia D. 2009. Mechanisms of polar arrest of a replication fork. Mol Microbiol. 72(2):279-85.
  19. ^ Chris Ullsperger and Nicholas R. Cozzarelli. Contrasting Enzymatic Activities of Topoisomerase IV and DNA Gyrase from Escherichia coli. Volume 271, Number 49, Issue of December 6, 1996 pp. 31549-31555
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