DNA replication
DNA replication or DNA synthesis refers to the process of copying a double-stranded DNA strand, prior to cell division (in eukaryotes, during the S phase (see also mitosis and meiosis)). The two resulting double strands are identical (if the replication went well), and each of them consists of one original and one newly synthesized strand. This is called semiconservative replication. The process of replication consists of three steps, initiation, replication and termination.
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In the initiation step, several key factors are recruited to an origin of replication. This is a sequence that is rich in adenine-thymine base pairs, which are more easily separated than cytosine-guanine base pairs. Once the strands are initially unwound, several factors come into play. The partially unwound strands form a "replication bubble", with one "replication fork" on either end. Each group of enzymes at the replication fork proceeds away from the origin, unwinding and replicating the DNA strands as they move.
The factors involved are:
Steps
Initiation
Replication
After the helicase unwinds the DNA, single-strand binding protein is used to hold the DNA strands in place. RNA primase is then binded to the starting DNA site.
At the beginning of replication, an enzyme called DNA polymerase binds to the RNA primase, which indicates the starting point for the replication. DNA polymerase can only synthesize new DNA from the 5ÃÂÃÂ to 3ÃÂÃÂ (of the new DNA). Because of this, the DNA polymerase can only travel on one side of the original strand without any interruption. This original strand, which goes from 3ÃÂÃÂ to 5ÃÂÃÂ, is called a leading strand. The opposite original strand, from 5ÃÂÃÂ to 3ÃÂÃÂ, is a lagging strand.
Since the DNA replication on the lagging strand is not continuous, a new DNA polymerase has to be added each time as the helicase unwinds more DNA. As a result, the replicated DNA is fragmented, called Okazaki fragments. Another enzyme, DNA ligase, is used to connect the fragments.
Coupled leading strand and lagging strand synthesis is achieved by the action of the polIII holoenzyme.
When the polymerase reaches the end of replication, there is another problem due to the antiparallel structure. The RNA primer on the leading strand occupies a small portion of the DNA, which is not exposed to polymerase and therefore is not copied.
As a result, there would be a gap on the newly duplicated DNA at the original leading strand on the 5ÃÂÃÂ end. The solution is quite simple. The sticking out 3ÃÂÃÂ end consists of noncoding DNA called the telomere, which can be simply cut off.
Before the DNA replication is finally complete, enzymes are used to proofread the sequences to make sure the nucleotides are paired up correctly. If mistake or damage occurs, an enzyme called nuclease will remove the incorrect DNA. DNA polymerase will then fill in the gap.
Mutants that grow at 30°C but not at 42°C are collected. These mutants should incorporate nucleotides into DNA at 30° but not at 42°C. Protein synthesis should not be affected.
There are two outcomes for a graph of incorporation of labelled nucleotides into DNA vs time:
Termination
Equation
(DNA)n + dNTP ↔ (DNA)n+1 + PPiMeasurement
Conditional mutants
Measurement of DNA replication can be done using conditional mutants.Assay
The assay can measure the imcorporation of deoxyribonucleotides into acid or ethanol insoluble forms.