High-resolution genomic assays provide insight into the division of labor between TLS and HDR in mammalian replication of damaged DNA.

The multitude of DNA lesions that continuously form in DNA cannot all be detected and removed prior to replication. Thus, encounters of the replication fork with DNA damage become inevitable. Such encounters inhibit fork progression, leading to replication fork arrest or to replication re-priming downstream of the damage site. Either of these events will result in the formation of gap-lesion structures, in which a damaged base is located in a single stranded stretch of DNA, that is vulnerable to subsequent nicking. The double strand break that would ensue if ssDNA becomes nicked constitutes escalation of the damage from nucleotide(s)-specific to chromosomal scale. Cells employ two universal DNA damage tolerance (DDT) strategies to resolve these situations, by converting the gap-lesion structures into dsDNA without repairing the damage. The first is translesion DNA synthesis (TLS), in which a specialized low-fidelity DNA polymerase inserts a nucleotide opposite the damaged one. TLS is inherently mutagenic, due to the miscoding nature of most damaged nucleotides. The second strategy is homology-dependent repair (HDR), which relies on the presence of an identical intact sister chromatid. The molecular mechanisms that regulate the division of labor between these pathways are poorly understood. This review focuses on the balance between TLS and HDR in mammalian cells, discussing recent findings that were made possible thanks to newly developed high resolution genomic assays, and highlighting the role of the DNA lesion's properties in DDT pathway choice.

In vivo evidence for translesion synthesis by the replicative DNA polymerase δ.

The intolerance of DNA polymerase δ (Polδ) to incorrect base pairing contributes to its extremely high accuracy during replication, but is believed to inhibit translesion synthesis (TLS). However, chicken DT40 cells lacking the POLD3 subunit of Polδ are deficient in TLS. Previous genetic and biochemical analysis showed that POLD3 may promote lesion bypass by Polδ itself independently of the translesion polymerase Polζ of which POLD3 is also a subunit. To test this hypothesis, we have inactivated Polδ proofreading in pold3 cells. This significantly restored TLS in pold3 mutants, enhancing dA incorporation opposite abasic sites. Purified proofreading-deficient human Polδ holoenzyme performs TLS of abasic sites in vitro much more efficiently than the wild type enzyme, with over 90% of TLS events resulting in dA incorporation. Furthermore, proofreading deficiency enhances the capability of Polδ to continue DNA synthesis over UV lesions both in vivo and in vitro These data support Polδ contributing to TLS in vivo and suggest that the mutagenesis resulting from loss of Polδ proofreading activity may in part be explained by enhanced lesion bypass.

DNA lesion identity drives choice of damage tolerance pathway in murine cell chromosomes.

DNA-damage tolerance (DDT) via translesion DNA synthesis (TLS) or homology-dependent repair (HDR) functions to bypass DNA lesions encountered during replication, and is critical for maintaining genome stability. Here, we present piggyBlock, a new chromosomal assay that, using piggyBac transposition of DNA containing a known lesion, measures the division of labor between the two DDT pathways. We show that in the absence of DNA damage response, tolerance of the most common sunlight-induced DNA lesion, TT-CPD, is achieved by TLS in mouse embryo fibroblasts. Meanwhile, BP-G, a major smoke-induced DNA lesion, is bypassed primarily by HDR, providing the first evidence for this mechanism being the main tolerance pathway for a biologically important lesion in a mammalian genome. We also show that, far from being a last-resort strategy as it is sometimes portrayed, TLS operates alongside nucleotide excision repair, handling 40% of TT-CPDs in repair-proficient cells. Finally, DDT acts in mouse embryonic stem cells, exhibiting the same pattern­mutagenic TLS included­despite the risk of propagating mutations along all cell lineages. The new method highlights the importance of HDR, and provides an effective tool for studying DDT in mammalian cells.

Genomic assay reveals tolerance of DNA damage by both translesion DNA synthesis and homology-dependent repair in mammalian cells.

DNA lesions can block replication forks and lead to the formation of single-stranded gaps. These replication complications are mitigated by DNA damage tolerance mechanisms, which prevent deleterious outcomes such as cell death, genomic instability, and carcinogenesis. The two main tolerance strategies are translesion DNA synthesis (TLS), in which low-fidelity DNA polymerases bypass the blocking lesion, and homology-dependent repair (HDR; postreplication repair), which is based on the homologous sister chromatid. Here we describe a unique high-resolution method for the simultaneous analysis of TLS and HDR across defined DNA lesions in mammalian genomes. The method is based on insertion of plasmids carrying defined site-specific DNA lesions into mammalian chromosomes, using phage integrase-mediated integration. Using this method we show that mammalian cells use HDR to tolerate DNA damage in their genome. Moreover, analysis of the tolerance of the UV light-induced 6-4 photoproduct, the tobacco smoke-induced benzo[a]pyrene-guanine adduct, and an artificial trimethylene insert shows that each of these three lesions is tolerated by both TLS and HDR. We also determined the specificity of nucleotide insertion opposite these lesions during TLS in human genomes. This unique method will be useful in elucidating the mechanism of DNA damage tolerance in mammalian chromosomes and their connection to pathological processes such as carcinogenesis.