Interstrand cross-links (ICLs) are absolute blocks to transcription and replication and can provoke genomic instability and cell death. Studies in bacteria define a two-stage repair scheme, the first involving recognition and incision on either side of the cross-link on one strand (unhooking), followed by recombinational repair or lesion bypass synthesis. The resultant monoadduct is removed in a second stage by nucleotide excision repair. In mammalian cells, there are multiple, but poorly defined, pathways, with much current attention on repair in S phase. However, many questions remain, including the efficiency of repair in the absence of replication, the factors involved in cross-link recognition, and the timing and demarcation of the first and second repair cycles. We have followed the repair of laser-localized lesions formed by psoralen (cross-links/ monoadducts) and angelicin (only monoadducts) in mammalian cells. Both were repaired in G 1 phase by nucleotide excision repair-dependent pathways. Removal of psoralen adducts was blocked in XPC-deficient cells but occurred with wild type kinetics in cells deficient in DDB2 protein (XPE). XPC protein was rapidly recruited to psoralen adducts. However, accumulation of DDB2 was slow and XPC-dependent. Inhibition of repair DNA synthesis did not interfere with DDB2 recruitment to angelicin but eliminated recruitment to psoralen. Our results demonstrate an efficient ICL repair pathway in G 1 phase cells dependent on XPC, with entry of DDB2 only after repair synthesis that completes the first repair cycle. DDB2 accumulation at sites of cross-link repair is a marker for the start of the second repair cycle.
Interstrand cross-links (ICLs)2 are among the most dangerous DNA lesions. They are absolute blocks to replication and transcription and, unlike monoadducts, cannot be carried through a proliferative cycle. Their accumulation over time is believed to contribute to genomic instability and aging in tissues and organs (1, 2). If not removed, they can provoke chromosomal breakage, rearrangements, or cell death (3, 4). Mice and humans deficient in genes associated with ICL repair, such as members of the ERCC1-XPF complex, display severe pathology and greatly reduced life span (2, 5-9). Given the challenge of repairing lesions that engage both strands of the duplex, it is understandable that multiple repair pathways are engaged (10 -12) and that repair is more complex than for monoadducts.In Escherichia coli, the NER apparatus incises one strand on either side of the ICL. This produces an "unhooked" substrate with the excised fragment still attached to the non-incised strand by the cross-linking agent. The immediate product of unhooking is typically depicted as a gapped structure with the cross-linked oligonucleotide flipped out of the duplex (although this structure may not actually form (13)). The incised/gapped strand is repaired by homology-directed repair using information from an undamaged homologous chromosome (14 -17). The gap may also be filled by lesion bypass sy...