target="_blank" rel="nofollow" href="#fb3_img_img_ef06bb9b-8c19-51e1-a5c2-7277bfc14c55.jpg" alt="Schematic illustration of the physical blocks on template DNAs. (A) When DNA polymerase III stalls on the lagging-strand template strand, a new Okazaki fragment can be initiated and the stalled polymerase can be moved to the new RNA primer.; Schematic illustration of the physical blocks on template DNAs. (B) When DNA polymerase III stalls on the leading strand, primase can restart DNA replication, leaving a gap that must be repaired by other means.; Schematic illustration of the physical blocks on template DNAs. (C) The translation polymerases have low processivity and fall off the template after a short distance, allowing the accurate DNA polymerase III replication to resume high-fidelity DNA replication."/>
Figure 1.13 Physical blocks on template DNAs. (A) When DNA polymerase III stalls on the lagging-strand template strand, a new Okazaki fragment can be initiated and the stalled polymerase can be moved to the new RNA primer. The process leaves a gap that must be repaired by other means, probably involving RecFOR (see chapter 9). (B) When DNA polymerase III stalls on the leading strand, primase can restart DNA replication, leaving a gap that must be repaired by other means. (C) In some cases where DNA polymerase III stalls at damaged DNA, translesion polymerase can utilize the same sliding clamp to replicate through the lesion, often by error-prone DNA replication. The translesion polymerases have low processivity and fall off the template after a short distance, allowing the accurate DNA polymerase III replication to resume high-fidelity DNA replication.
The replication of the bacterial DNA occurs during the cell division cycle, which is the time during which a cell is born, grows larger, and divides into two progeny cells. Cell division is the process by which the larger cell splits into the two new cells. The division time, or generation time, is the time that elapses from the point when a cell is born until it divides. This time is usually approximately the same for all the individuals in the population under a given set of growth conditions. The original cell before cell division is called the mother cell, and the two progeny cells after division are called the daughter cells.
Structure of Bacterial Chromosomes
The DNA molecule of a bacterium that carries most of its normal genes is commonly referred to as its chromosome, by analogy to the chromosomes of higher organisms. This name distinguishes the molecule from plasmid DNA, which in some cases can be almost as large as chromosomal DNA but usually carries genes that are not always required for growth of the bacterium (see chapter 4). Most bacteria have only one chromosome; in other words, there is only one unique DNA molecule per cell that carries most of the normal genes. There are exceptions, and it is estimated that 10% of bacteria have more than one chromosome, including Vibrio cholerae, the bacterium responsible for the disease cholera. Even in bacteria that contain multiple chromosomes, the second chromosome shows more characteristics of a plasmid than of a chromosome, particularly in how it initiates replication. There appear to be special molecular systems for managing multiple chromosomes (see Fournes et al., Suggested Reading).
As discussed below, when bacteria, such as E. coli, are reproducing very rapidly, new rounds of replication initiate before others are completed, temporally increasing the DNA content of the cells until cellular division returns the number of copies to one unit chromosome per cell. It is important to note, however, that these individual chromosomal DNAs are not unique since they are directly derived from each other by replication.
The structure of bacterial DNA differs significantly from that of the chromosomes of higher organisms. One difference is that the DNA in the chromosomes of most bacteria is circular in the sense that the ends are joined to each other (for exceptions, see Box 4.1). In contrast, eukaryotic chromosomes are usually linear with free ends. As discussed in chapter 4, the circularity of bacterial chromosomal DNA allows it to replicate in its entirety without using telomeres, as eukaryotic chromosomes do, or terminally redundant ends, as some bacteriophages do (see chapter 7). Even in cases where bacterial chromosomes are linear, they do not use the same mechanism, involving telomerases to replicate their ends, that is used by eukaryotic chromosomes. Another difference between the DNA of bacteria and eukaryotes is that the DNA in eukaryotes is wrapped around proteins called histones to form nucleosomes. Bacteria have the proteins HU, HN-S, Fis, and IHF, around which DNA is often wrapped, and archaea do have rudimentary histones related to those of eukaryotes. However, in general, DNA is much less structured in bacteria than in eukaryotes.
Replication of the Bacterial Chromosome
Replication of a circular bacterial chromosome initiates at a unique origin of chromosomal replication, or oriC, and proceeds in both directions around the circle. On the E. coli chromosome, oriC is located at 84.3 min. As mentioned above, the place in DNA at which replication occurs is known as the replication fork. Two replication forks start at oriC and proceed around the circle until they meet and terminate chromosomal replication. The DNA polymerases responsible for replicating the leading and lagging strands associate as a single holoenzyme. However, there is no association between the DNA polymerases at the two DNA replication forks to help drive the separation of chromosomes, and therefore, other force-generating mechanisms must be at play. As discussed in “Termination of Chromosome Replication” below, some bacteria actively terminate replication at a unique site in the DNA; however, these systems are not widespread, and most bacteria terminate replication using an unknown mechanism or simply terminate DNA replication where the two replication forks meet. Each time the two replication forks proceed around the circle and meet, a round of replication has been completed, and two new DNAs, called the daughter DNAs, are generated.
Initiation of Chromosome Replication
Much has been learned about the molecular events occurring during the initiation of replication. Some of this information has a bearing on how the initiation of chromosome replication is regulated and serves as a model for the interaction of proteins and DNA.
Two types of functions are involved in the initiation of chromosome replication. One consists of the sites or sequences on DNA at which proteins act to initiate replication. These are called cis-acting sites. The prefix cis means “on this side of,” and these sites act only on the same DNA. The proteins involved in initiation of replication are examples of trans-acting functions. The prefix trans means “on the other side of,” and these functions can act on any DNA in the same cell, not just the DNA from which they were made. The concepts of cis- and trans-acting properties are common in molecular genetics, and these references are used throughout this book.
ORIGIN OF CHROMOSOMAL REPLICATION
One cis-acting site involved in DNA replication is the oriC site, at which replication initiates. The sequence of oriC is well defined in E. coli, and the basic components that make up oriC are broadly similar in most bacteria. Figure 1.14 shows the structure of the origin of replication of E. coli. Less than 260 base pairs (bp) of DNA is required for initiation at this site. Within oriC are a series of binding sites for various proteins; the most important of these binding proteins is the master initiator protein in bacteria, called DnaA (see below). The canonical DnaAbinding sequences are 9 bp in length, and these sites are termed DnaA boxes. While five DnaA boxes exist within oriC, three of these sites bind DnaA particularly strongly, i.e., are of particularly high affinity, and are always bound by DnaA (