A purified DDB2 protein complex can be used to detect UV-induced DNA damage.

<p>(<b>A</b>) Experimental strategy to prepare the DDB2 proteo-probe. (<b>B</b>) Signal obtained by hybridization of the DDB2 proteo-probe onto fibroblasts with or without damaging treatments. Hybridized DDB2 proteo-probe is revealed by anti-HA immunofluorescence. Nuclei are visualized by DAPI staining. Nuclei are delineated based on DAPI staining and using CellProfiler <a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0085896#pone.0085896-Carpenter1" target="_blank">[26]</a>.</p

The decrease of DDB2 proteo-probe and 6-4 PP signals over time are nearly identical.

<p>(<b>A</b>) Typical signals after UV damage observed <i>in situ</i> with the DDB2 proteo-probe, an anti-CPD antibody, or an anti-(6-4)PP antibody. Nuclei are delineated based on DAPI staining and using CellProfiler. (<b>B</b>) The DDB2 proteo-probe signal decreases exponentially with time. Average signal per nucleus normalized to signal at 5 minutes. Red dashed curve: one phase exponential decay fit calculated with a non-linear least square method (R² = 0.86). (<b>C</b>) The anti-(6-4)PP signal decreases exponentially with time. Average signal per nucleus normalized to signal at 5 minutes. Blue dashed curve: one phase exponential decay fit calculated with a non-linear least square method (R² = 0.83). (<b>D</b>) The anti-CPD signal remains constant over a two hour period. Average signal per nucleus normalized to signal at 5 minutes. Black dashed line: linear fit on the α-CPD signal (R² = 0.18). (<b>B</b>), (<b>C</b>), and (<b>D</b>): cells were irradiated with UV-C (10 J/m²). The average of three replicas is shown. Each replica represents an average of at least 60 cells. Error bars: s.e.m. (<b>E</b>) A single one phase exponential decay model summarizes the kinetic of (6-4)PPs removal <i>in situ</i>. The single model is based on the decay fits obtained with DDB2 proteo-probe and anti-(6-4)PP data. The grey band represents the area enclosing the true decay curve with 99% confidence. The dotted line indicates the predicted half-life (<i>t</i>_1/2) of (6-4)PPs <i>in situ</i> after UV irradiation.</p

The DDB2 proteo-probe recognizes 6-4-photoproducts <i>in vitro</i>.

<p>(<b>A</b>) The DDB2 proteo-probe signal increases linearly with fluence (J/m²). Fibroblasts were irradiated with different doses of UV-C. Each point is an average of three replicas. Each replica represents an average of at least 60 cells. Dashed line: linear fit (R² = 0.94). Error bars: s.e.m. (<b>B</b>) The DDB2 proteo-probe signal is DNA-dependent. Fibroblasts were irradiated with UV-C (10 J/m²), and untreated or treated with DNase. Nuclei are visualized by DAPI staining. (<b>C</b>) The DDB2 proteo-probe signal can be competed with UV-treated plasmid DNA. Fibroblasts and plasmid DNA were irradiated with UV-C (10 J/m² and 300 J/m², respectively). The DDB2 proteo-probe was incubated with plasmid DNA prior to hybridization onto irradiated fibroblasts. Dashed line: no plasmid control proteo-probe signal level. Each point is an average of three replicas. Each replica represents an average of at least 400 cells. Error bars: s.e.m. (<b>D</b>) The DDB2 proteo-probe binds preferentially to 6-4-photoproducts [(6-4)PP] over cyclobutane pyrimidine dimers (CPD). The DDB2 proteo-probe was immobilized on agarose beads, and incubated with the DNA restriction fragments of a plasmid containing, or not, a unique lesion [(6-4)PP or CPD]. The average ratio of the amount of lesion-containing over lesion-free DNA fragments bound to the proteo-probe is shown (<i>n</i> = 3). Error bars: s.e.m.</p