Transcription Domain-Associated Repair in Human Cells

Abstract

Nucleotide excision repair (NER), which is arguably the most versatile DNA repair system, is strongly attenuated in human cells of the monocytic lineage when they differentiate into macrophages. Within active genes, however, both DNA strands continue to be proficiently repaired. The proficient repair of the nontranscribed strand cannot be explained by the dedicated subpathway of transcription-coupled repair (TCR), which is targeted to the transcribed strand in expressed genes. We now report that the previously termed differentiation-associated repair (DAR) depends upon transcription, but not simply upon RNA polymerase II (RNAPII) encountering a lesion: proficient repair of both DNA strands can occur in a part of a gene that the polymerase never reaches, and even if the translocation of RNAPII is blocked with transcription inhibitors. This suggests that DAR may be a subset of global NER, restricted to the subnuclear compartments or chromatin domains within which transcription occurs. Downregulation of selected NER genes with small interfering RNA has confirmed that DAR relies upon the same genes as global genome repair, rather than upon TCR-specific genes. Our findings support the general view that the genomic domains within which transcription is active are more accessible than the bulk of the genome to the recognition and repair of lesions through the global pathway and that TCR is superimposed upon that pathway of NER.

We thank Toshio Mori for the gift of anti-CPD and anti-(6-4)PP antibodies, Stephen Lloyd for the gift of T4 endonuclease V, David Mellert for assistance with RT-PCR, and Ann Ganesan for critical reading of the manuscript and helpful suggestions.

This work was supported by a Senior Scholar Award from the Ellison Medical Foundation and grant CA77712 from the National Cancer Institute, U.S. Department of Health and Human Services.