Repair of DNA lesions in chromosomal DNA impact of chromatin structure and Cockayne syndrome proteins.

Decondensation of chromatin is essential to facilitate access to DNA metabolizing processes such as transcription and DNA repair. Disruption of histone-DNA contacts by histone modification or by ATP dependent chromatin remodelling allows DNA-binding proteins to compete with histones for DNA. The efficiency of global genome nucleotide excision repair (GGR) that removes a variety of helix distorting DNA lesions is known to be affected by chromatin structure most notably demonstrated by the slow repair of heterochromatin. In addition, the efficiency of GGR to repair lesions in transcriptionally active genes requires functional CSA and B proteins. We found that repair of UV-photolesions in both strands of the active adenosine deaminase gene was delayed in CS cells when compared to normal human fibroblasts. We suggest that the lack of transcription recovery characteristic for CS cells exposed to DNA damaging agents, might lead to changes in the chromatin structure of active genes, causing less efficient repair of lesions in these genes when compared to normal cells.

Differential repair of the two major UV-induced photolesions in trichothiodystrophy fibroblasts.

Defects in nucleotide excision repair have been shown to be associated with the photosensitive form of the disorder trichothiodystrophy (TTD). Most repair-deficient TTD patients are mutated in the XPD gene, a subunit of the transcription factor TFIIH. Knowledge of the kinetics and efficiency of repair of the two major UV-induced photolesions in TTD is critical to understand the role of unrepaired lesions in the process of carcinogenesis and explain the absence of enhanced skin cancer incidence in TTD patients contrarily to the xeroderma pigmentosum D patients. In this study, we used different approaches to quantify repair of UV-induced cyclobutane pyrimidine dimers (CPD) and pyrimidine (6-4) pyrimidone photoproducts (6-4PP) at the gene and the genome overall level. In cells of two TTD patients, repair of CPD and 6-4PP was reduced compared with normal human cells, but the reduction was more severe in confluent cells than in exponentially growing cells. Moreover, the impairment of repair was more drastic for CPD than 6-4PP. Most notably, exponentially growing TTD cells displayed complete repair 6-4PP over a broad dose range, albeit at a reduced rate compared with normal cells. Strand-specific analysis of CPD repair in a transcriptional active gene revealed that TTD cells were capable to perform transcription-coupled repair. Taken together, the data suggest that efficient repair of 6-4PP in dividing TTD cells in concert with transcription-coupled repair might account for the absence of increased skin carcinogenesis in TTD patients.

Nucleotide excision repair and its interplay with transcription.

Nucleotide excision repair (NER) is a multistep process capable to remove a variety of DNA distorting lesions from prokaryotic and eukaryotic genomes. In eukaryotic cells, the process requires more than 30 proteins to perform the different steps, i.e. recognition of DNA damage, single strand incisions and excision of the lesion-containing DNA fragment and DNA repair synthesis/ligation. NER can operate via two subpathways: global genome repair (GGR) and a specialized pathway coupled to active transcription (transcription-coupled repair, TCR) and directed to DNA lesions in the transcribed strand of active genes. Both in vivo as well as in cultured cells the fast removal of transcription blocking lesions by TCR is crucial to escape from lethal effects of inhibited transcription inhibition The most delicate step in NER is the recognition of the DNA lesions in their different chromatin context and the mechanism of damage recognition in GGR and TCR is principally different and requires specific proteins. In GGR, the XPC-HR23B is essential for the formation of the incision complex. In TCR the Cockayne syndrome (CS) gene products are key players in the recognition of a stalled RNA polymerase the presumed signaling structure for repair of transcribed strands. In this study, we show that the extent of recovery of UV-inhibited transcription and TCR strictly depends on the amount of CSB protein as well as the amount of DNA damage present in the cell. This indicates that the ratio between DNA damage frequency and CSB protein concentration in the cell is rather critical for acute cellular response, i.e. recovery of inhibited transcription upon DNA damage infliction, and hence cellular survival.