Abstract

UV light causes the formation of pyrimidine dimers (PDs). Transcription-coupled (TC) nucleotide excision repair (NER) and global genome (GG) NER remove PDs from the transcribed strand (TS) of active genes and the inactive genome, respectively. TC-NER is triggered by elongating RNA polymerases that are blocked at PDs. The yeast rRNA genes are densely loaded with RNA polymerase-I. After UV irradiation, their density increases at the 5'-end of the gene, which results from continuous transcription initiation, followed by elongation and pausing/release at the first encountered PD, from the transcription start site. RNA polymerase-I posed at downstream PDs are released from the TS and are replaced by nucleosomes. Consequently, discrete chromatin structures are formed in the damaged transcribed rRNA genes. Singular assignation of the two NER sub-pathways could therefore be required to eliminate PDs from the TS. To advance our understanding of NER in the dynamic structure of transcribed chromatin, we investigated the repair of PDs at nucleotide resolution in separate rRNA gene coding regions. In the TS, the TC-NER efficiency reflected the density of RNA polymerase-I, and PDs were removed faster in the 5'-end than in the 3'-end of the gene. GG-NER removed PDs from the TS where RNA polymerase-I was transiently replaced by a nucleosome. The two NER sub-pathways inversely participated to remove PDs from the TS. In the non-TS of both nucleosome and non-nucleosome rRNA gene coding regions, GG-NER was solely responsible to remove UV-induced DNA lesions.

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