Author summary and claims are plotted/visualized first (figures), then explained and critically evaluated with specific, inline evidence citations.
Source: authors' DIA phosphoproteomics: ~8.7% of phosphopeptides increased β₯2-fold with okadaic acid (MSstatsPTM; FDR-adjusted p<0.05)
Rationale: Authors report that okadaic acid causes rapid disappearance of reversed-fork species and accumulation of fork-cleavage and end-joining products, while ATM inhibition stabilizes reversed forks and reduces fork-cleavage signals; the bar-values are qualitative visual encoding of those conclusions (not raw counts) β see source experiments (native agarose gels, nascent-strand mapping)
The authors propose: fork reversal during FA-mediated ICL repair produces a regressed arm (a one-ended DSB-like structure) that activates ATM; ATM (directly or via phosphorylation of downstream effectors) activates long-range resection machineries β EXO1 initiates 5'β3' resection near the regressed arm terminus, and DNA2 with WRN further processes recessed 5' ends β collectively producing ssDNA to support fork restoration and downstream repair (TLS and HR). PP2A (via PTPA) restrains ATM signaling; pharmacological PP2A inhibition hyperactivates ATM and triggers over-resection and error-prone repair.
Support: Strong direct biochemical evidence from Xenopus extracts (well-established ICL cell-free system) plus orthogonal CRISPR genetic data supporting PP2A involvement. Proteomics and inhibitor phenotypes converge on DNA2/EXO1/WRN as effectors
Other supporting literature (context):
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