Roadblocks & bypasses : protection of genome stability by translesion DNA synthesis in C. elegans

Abstract

DNA encodes the genetic instructions for living organisms. However, damage to the DNA is inevitable, because DNA itself is an unstable molecule and environmental factors such as UV-radiation or X-rays cause damage to the DNA. A certain type of DNA damages can block DNA replication, an essential step before cell can divide. The polymerases that normally replicate DNA are incredibly efficient and virtually flawless on undamaged DNA, but they cannot replicate damaged DNA. In multi-celled organisms, the most important defense mechanism against this is Translesion DNA synthesis (TLS). TLS protects against various negative consequences of damage to the DNA. For this, TLS utilizes specialized TLS polymerases that can replicate damaged DNA.My experiments show that the strong evolutionary conservation of TLS is explained by the dual functions of TLS: guarding replication potential and genome stability. TLS suppresses genomic instability, by preventing conversion of replication blocks to double-stranded DNA breaks (DSBs). Without functional TLS, DSBs arise and result in larger and more harmful mutations. TLS is beneficial for organisms because it supports continuous reproduction and growth. Although DNA damage is always present and unavoidable, TLS guards against the formation of mutations that would otherwise lead to cancer, aging and congenital disease.Financial support for the printing of this thesis was provided by MRC Holland BV.LUMC / Geneeskund