Deamination
Explore the process of deamination and its role in DNA replication, focusing on how single-stranded DNA regions experience higher mutation rates. Understand the nucleotide imbalances caused by deamination and how this affects genome integrity during replication.
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In the last section, we saw that as the replication fork expands, DNA polymerase synthesizes DNA quickly on the reverse half-strand but suffers delays on the forward half-strand. Notice that since the replication of a reverse half-strand proceeds quickly, it lives double-stranded for most of its life. Conversely, a forward half-strand spends a much larger amount of its life single-stranded, waiting to be used as a template for replication. This discrepancy between the forward and reverse half-strands is important because single-stranded DNA has a much higher mutation rate than double-stranded DNA. In particular, if one of the four nucleotides in single-stranded DNA has a greater tendency than other nucleotides to mutate in single-stranded DNA, then we should observe a shortage of this nucleotide on the forward half-strand.