The genetic code of life is stored in DNA molecules that consist of two parallel strands of coupled nucleotides that form a DNA double helix. One of the most deleterious forms of DNA damage is a... Show moreThe genetic code of life is stored in DNA molecules that consist of two parallel strands of coupled nucleotides that form a DNA double helix. One of the most deleterious forms of DNA damage is a DNA double-strand break (DSB) in which both strands of the helix are broken. When not repaired adequately DSBs can lead to extensive loss of genetic information and/or genomic rearrangements, ultimately fueling genome instability, cellular dysfunction and malignant transformation. This thesis describes several studies conducted to examine how living organisms preserve their genetic material and how different DNA repair pathways influence genome stability. To study these questions the nematode C. elegans was used as a model organism, as it allows efficient genetic manipulation as well as in-depth genetic analysis of mutagenic processes. We exploited these unique attributes to i) convert these animals into in vivo sensors of DNA damage ii) identify factors not implicated in genome stability before, iii) unveil mechanisms that dictate DNA repair pathway choice, and iv) determine the biological consequences of endogenous barriers that impede DNA replication. Show less
In this thesis I describe the developmental role of the Y-family polymerases Pol Eta, Pol Kappa and Rev1 in protection against exogenous and endogenous damage in C. elegans. Furthermore I identify... Show moreIn this thesis I describe the developmental role of the Y-family polymerases Pol Eta, Pol Kappa and Rev1 in protection against exogenous and endogenous damage in C. elegans. Furthermore I identify a new role for the A-family Polymerase Pol Theta in repair of replication-associated breaks. Show less