Abstract
To cope with ultraviolet C (UVC)-stalled replication forks and restart DNA synthesis, cells either undergo DNA translesion synthesis (TLS) by specialised DNA polymerases or tolerate the lesions using homologous recombination (HR)-based mechanisms. To gain insight into how cells manage UVC-induced stalled replication forks, we analysed the molecular crosstalk between the TLS DNA polymerases Polη and Rev1, the double-strand break repair (DSB)-associated protein MDC1 and the FANC pathway. We describe three novel functional interactions that occur in response to UVC-induced DNA lesions. First, Polη and Rev1, whose optimal expression and/or relocalisation depend on the FANC core complex, act upstream of FANCD2 and are required for the proper relocalisation of monoubiquitinylated FANCD2 (Ub-FANCD2) to subnuclear foci. Second, during S-phase, Ub-FANCD2 and MDC1 relocalise to UVC-damaged nuclear areas or foci simultaneously but independently of each other. Third, Ub-FANCD2 and MDC1 are independently required for optimal BRCA1 relocalisation. While RPA32 phosphorylation (p-RPA32) and RPA foci formation were reduced in parallel with increasing levels of H2AX phosphorylation and MDC1 foci in UVC-irradiated FANC pathway-depleted cells, MDC1 depletion was associated with increased UVC-induced Ub-FANCD2 and FANCD2 foci as well as p-RPA32 levels and p-RPA32 foci. On the basis of the previous observations, we propose that the FANC pathway participates in the rescue of UVC-stalled replication forks in association with TLS by maintaining the integrity of ssDNA regions and by preserving genome stability and preventing the formation of DSBs, the resolution of which would require the intervention of MDC1.
Highlights
DNA damage is a primary source of cellular stress and a leading cause of cancer [1]
This contrasts with the wellknown response of nucleotide excision repair (NER) proteins, which rapidly relocalise to damaged local irradiated regions (LIR) independently of the cell cycle phase (Figures S1C and S1D)
Our results provide new insights into the protein network involved in rescuing ultraviolet C radiation (UVC)-stalled replication forks (Figure 5D)
Summary
To cope with DNA lesions, cells have developed an integrated and tightly regulated molecular network called the DNA damage response (DDR), in which cell cycle checkpoints and DNA repair pathways collaborate to efficiently restore the integrity of the genetic material [2]. DNA damage induced by ultraviolet C radiation (UVC) is a well-characterised roadblock for ongoing replication forks. UVC induces two major DNA lesions, cyclobutane pyrimidine dimers (CPDs) and 6-4 pyrimidine-pyrimidone photoproducts (6,4-PPs). These lesions are primarily removed through the error-free nucleotide excision repair (NER) pathway [2]. Inactivation of any of these genes is associated with cellular hypersensitivity to UVC, increased UV-induced mutagenesis and inefficient removal of both CPDs and 6,4-PPs [5]
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