Zhang J , Dewar JM , Budzowska M , Motnenko A , Cohn MA , Walter JC .

R01 GM062267 NIGMS NIH HHS , R01 HL098316 NHLBI NIH HHS , GM62267 NIGMS NIH HHS , HL098316 NHLBI NIH HHS , Howard Hughes Medical Institute

	Figure 2. CMG is not evicted from a single fork stalled at an ICL(a) Schematic of primers used in chromatin immunoprecipitation (ChIP).(b) MCM7 and CDC45 ChIP anaylsis at different time points during repair. pICL-lacO was replicated with or without LacI, and IPTG was added immediately before the 20 minute time point, as indicated (green arrow). A repetition of this experiment is shown in Supplementary Fig. 5a.
	Figure 3. A single, stalled fork does not undergo incisions(a) Schematic of repair intermediates expected in panel (b).(b) Replication intermediates of pICL-lacO separated on a native agarose gel. pICL-lacO and an internal control plasmid lacking the lacO array (pQuant) were pre-incubated with buffer or LacI and replicated in the presence of [α-32P]dATP. IPTG was added as indicated. Sc: supercoiled. Oc: open circular. Blue arrowhead: “Figure 8” DNA structure. Green arrowhead: “Theta” DNA structure.(c) Schematic of incision assay. Before dual incisions, single cutting with BlpI yields X-shaped products (blue strands, upper cartoon), whereas after dual incisions, BlpI digestion yields linear molecules (blue strands, lower cartoon).(d) Incision assay. pICL-lacO was replicated with or without LacI and IPTG, as indicated. The repair intermediates were digested with BlpI, separated on an alkaline (denaturing) gel, and visualized by Southern blotting to detect parental strands. Unreplicated pICL-lacO was used to generate size markers for the X-shaped structure and linear structure, which came from a small fraction of uncrosslinked background plasmids in the pICL-lacO preparations. Uncropped image of Fig. 3d is presented in Supplementary Data Set 1c.(e) XPF and SLX4 ChIP analysis. pICL-lacO and pQuant were replicated with or without LacI, and IPTG was added immediately before the 20 minute time point where indicated (green arrow). At different times, samples were withdrawn for XPF and SLX4 ChIP using primer pairs for the ICL locus (Fig. 2a) or pQuant (Ctrl). A repetition of this experiment is shown in Supplementary Fig. 5c.
	Figure 4. The order of replisome arrival at an ICL does not determine which leading strand undergoes lesion bypass(a) Scheme to determine whether the order in which the two forks arrive at an ICL dictates which parental strand is used as the lesion bypass template.(b) Schematic depiction of final repair products after AflIII and AseI digestion, depending on which leading strand undergoes lesion bypass. Note that AflIII and AseI generate different sized overhangs, allowing us to differentiate top (178 nt) and bottom (176 nt) strands. Top-AD or Bottom-AD: top or bottom strand containing an adduct.(c, d) Strand-specific Southern blotting to detect the adducts. pCtrl or pICL-lacO was replicated in the presence of buffer or LacI, and IPTG was added at the indicated times. After 6 hours, repair products were digested with AflIII and AseI, separated on a sequencing gel, and analyzed with strand-specific Southern blotting to visualize the bottom (c) or top (d) strands. To generate size markers for the top (178 nt) and bottom (176 nt) strands (lane 1), pCtrl was replicated in the presence of [α-32P]dATP (pCtrl*), and was analyzed on the same sequencing gel as the strand-specific Southern after AflIII and AseI digestion. The fact that no top (c, lane 2) or bottom strand (d, lane 2) was detected in Southern blotting of pCtrl established the strand-specificity of the blotting protocol. Uncropped images of Figs. 4c and 4d are presented in Supplementary Data Set 1d.

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