Hashimoto Y , Ray Chaudhuri A , Lopes M , Costanzo V .

Cancer Research UK, 206281 European Research Council, A15668 Cancer Research UK, A7124 Cancer Research UK, CRUK_A15668 Cancer Research UK, CRUK_A7124 Cancer Research UK, ERC_206281 European Research Council

	Figure 2. Rad51 and PCNA modifications in DNA replication and ssDNA gap accumulation. (A) Rad51 and PCNA requirement for replication of untreated and MMS-treated DNA. Sperm nuclei were incubated in 10 μl egg extract with α32P-dATP for the indicated times in the presence or absence of 0.7 mg ml−1 GST or GST-BRC4 and MMS (− or +), and 0.2 mg ml−1 of recombinant wild type PCNA (WT) or mutated PCNA (K164R). Replication products were resolved on 1% (w/v) alkaline agarose gel and subjected to autoradiography. (B) The signal intensities obtained in (A) were quantified and reported on the graph. The experiments shown represent a typical result. (C) Gap labelling procedure using T4 DNA polymerase. Replicating genomic DNA was isolated and used as a template for gap-filling assay using T4 DNA polymerase. The labelled nascent molecules extended by T4 were then resolved on alkaline agarose gel. (D) Untreated (−MMS) and MMS treated (+MMS) sperm nuclei were incubated in 10 μl of egg extract in the presence of GST or GST-BRC4 for 60 min (1–4). Untreated sperm nuclei were incubated for 40, 60 or 80 min in the presence of PCNA-WT or PCNA-K164R (5–10). Genomic DNA was isolated and subjected to the gap labelling reaction followed by autoradiography. Exposure times are equivalent for the 2 gels although kinetic profile starts at 40 minutes in 5–10. The graph shows the relative fold increase in optical density measured for each lane taking as reference untreated chromatin recovered at 60 minutes. The experiment shows a typical result.
	Figure 3. Rad51 is required to prevent replication fork uncoupling and ssDNA accumulation on damaged and undamaged templates. (A) and (C) Electron micrographs (and schematic drawings) of representative RIs isolated from sperm nuclei, incubated in GST-BRC4 treated extracts. Black arrows point to ssDNA regions at the replication fork. White arrows point to ssDNA gaps along the replicated duplexes (internal gaps). (B) Statistical distribution of internal gaps in the analyzed population of molecules. The total number of molecules analyzed is indicated in brackets. (D) Statistical distribution of ssDNA length at replication forks isolated in the indicated conditions. The total number of forks analyzed is indicated in brackets.
	Figure 4. Accumulation of ssDNA gaps in the absence of Rad52 and Rad51 in S. cerevisiae.Upper panels: Electron micrographs of a representative RIs isolated from rad52 mutant S. cerevisiae growing cells. The black arrow points to an extended ssDNA regions at the replication fork. White arrows show ssDNA gap behind the fork. Lower panels: Statistical distribution of ssDNA gap length (left) and of the number of ssDNA gaps (right) observed on RIs isolated from wild type, Rad52 and Rad51 mutant S. cerevisiae growing cells.
	Figure 5. Rad51 protects nascent strand DNA from Mre11-dependent degradation. (A) Statistical distribution of internal gaps in the analyzed population of molecules isolated from extracts that were supplemented with buffer (Control) or 100 μM Mirin and treated as indicated. The total number of molecules analyzed is indicated in brackets. (B) Statistical distribution of ssDNA length at replication forks isolated from extracts that were supplemented with buffer (Control) or 100 μM Mirin and treated as indicated. The total number of molecules analyzed is indicated in brackets. in the indicated conditions.
	Figure 6. A model for possible roles of Rad51 during DNA replication. See text for explanation.

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