Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:4.1.99.3 (PRE)
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Yeast and many other organisms use nucleotide excision repair (NER) and photolyase in the presence of light (photoreactivation) to repair cyclobutane pyrimidine dimers (CPDs), a major class of DNA lesions generated by UV light. To study the role of photoreactivation at the chromatin level in vivo, we used yeast strains which contained minichromosomes (YRpTRURAP, YRpCS1) with well-characterized chromatin structures. The strains were either proficient (RAD1) or deficient (rad1 delta) in NER. In contrast to NER, photolyase rapidly repairs CPDs in non-nucleosomal regions, including promoters of active genes (URA3, HIS3, DED1) and in linker DNA between nucleosomes. CPDs in nucleosomes are much more resistant to photoreactivation. These results demonstrate a direct role of chromatin in modulation of a DNA repair process and an important role of photolyase in repair of damaged promoters with presumptive effects on gene regulation. In addition, photoreactivation provides an in vivo test for chromatin structure and stability. In active genes (URA3, HIS3), photolyase repairs the non-transcribed strand faster than the transcribed strand and can match fast removal of lesions from the transcribed strand by NER (transcription-coupled repair). Thus, the combination of both repair pathways ensures efficient repair of active genes.
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PMID:Chromatin structure modulates DNA repair by photolyase in vivo. 915 40

Yeast uses nucleotide excision repair (NER) and photolyase (photoreactivation) to repair cyclobutane pyrimidine dimers (CPDs) generated by ultraviolet light. In active genes, NER preferentially repairs the transcribed strand (TS). In contrast, we recently showed that photolyase preferentially repairs the non-transcribed strands (NTS) of the URA3 and HIS3 genes in minichromosomes. To test whether photoreactivation depends on transcription, repair of CPDs was investigated in the transcriptionally regulated GAL10 gene in a yeast strain deficient in NER [AMY3 (rad1Delta)]. In the active gene (cells grown in galactose), photoreactivation was fast in the NTS and slow in the TS demonstrating preferential repair of the NTS. In the inactive gene (cells grown in glucose), both strands were repaired at similar rates. This suggests that RNA polymerases II blocked at CPDs inhibit accessibility of CPDs to photolyase. In a strain in which both pathways are operational [W303-1a (RAD1)], no strand bias was observed either in the active or inactive gene, demonstrating that photoreactivation of the NTS compensates preferential repair of the TS by NER. Moreover, repair of the NTS was more quickly in the active gene than in the repressed gene indicating that transcription dependent disruption of chromatin facilitates repair of an active gene.
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PMID:RNA polymerase II transcription inhibits DNA repair by photolyase in the transcribed strand of active yeast genes. 938 May

Poly(dA.dT) sequences (T-tracts) are abundant genomic DNA elements with unusual properties in vitro and an established role in transcriptional regulation of yeast genes. In vitro T-tracts are rigid, contribute to DNA bending, affect assembly in nucleosomes and generate a characteristic pattern of CPDs (cyclobutane pyrimidine dimers) upon irradiation with UV light (UV photofootprint). In eukaryotic cells, where DNA is packaged in chromatin, the DNA structure of T-tracts is unknown. Here we have used in vivo UV photofootprinting and DNA repair by photolyase to investigate the structure and accessibility of T-tracts in yeast promoters (HIS3, URA3 and ILV1). The same characteristic photofootprints were obtained in yeast and in naked DNA, demonstrating that the unusual T-tract structure exists in living cells. Rapid repair of CPDs in the T-tracts demonstrates that these T-tracts were not folded in nucleosomes. Moreover, neither datin, a T-tract binding protein, nor Gcn5p, a histone acetyltransferase involved in nucleosome remodelling, showed an influence on the structure and accessibility of T-tracts. The data support a contribution of this unusual DNA structure to transcriptional regulation.
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PMID:Poly(dA.dT) sequences exist as rigid DNA structures in nucleosome-free yeast promoters in vivo. 1105 3