Mutation in the CSB gene results in the human Cockayne's syndrome (CS). Here, we provide evidence that CSB is found not only in the nucleoplasm but also in the nucleolus within a complex (CSB IP/150) that contains RNA pol I, TFIIH, and XPG and promotes efficient rRNA synthesis. CSB is active in in vitro RNA pol I transcription and restores rRNA synthesis when transfected in CSB-deficient cells. We also show that mutations in CSB, as well as in XPB and XPD genes, all of which confer CS, disturb the RNA pol I/TFIIH interaction within the CSB IP/150. In addition to revealing an unanticipated function for CSB in rRNA synthesis, we show that the fragility of this complex could be one factor contributing to the CS phenotype.
In response to genotoxic attacks, cells activate sophisticated DNA repair pathways such as nucleotide excision repair (NER), which consists of damage removal via dual incision and DNA resynthesis. Using permanganate footprinting as well as highly purified factors, we show that NER is a dynamic process that takes place in a number of successive steps during which the DNA is remodeled around the lesion in response to the various NER factors. XPC/HR23B first recognizes the damaged structure and initiates the opening of the helix from position ؊3 to ؉6. TFIIH is then recruited and, in the presence of ATP, extends the opening from position ؊6 to ؉6; it also displaces XPC downstream from the lesion, thereby providing the topological structure for recruiting XPA and RPA, which will enlarge the opening. Once targeted by XPG, the damaged DNA is further melted from position ؊19 to ؉8. XPG and XPF/ERCC1 endonucleases then cut the damaged DNA at the limit of the opened structure that was previously "labeled" by the positioning of XPC/HR23B and TFIIH.To counteract the detrimental effect of genotoxic attacks, cells activate sophisticated and specific DNA repair pathways. Damage induced by UV radiation, environmental agents, and anticancer drugs are removed by two distinct nucleotide excision repair (NER) 1 subpathways, namely global genome repair (GGR), which eliminates lesions from the entire genome, and transcription-coupled repair (TCR), a specialized pathway that repairs damages on a transcribed strand of active genes (1-3). Human NER involves the ordered action of factors in dual incision and DNA repair resynthesis steps (4). Any mutation that affects either the enzymatic activity or the ordered assembly of the dual incision complex leads to genetic disorders such as xeroderma pigmentosum, trichothiodystrophy, or Cockayne syndrome (5, 6).In global genome repair, the dual incision is a multistep process that results from the coordinated action of XPC/ HR23B, TFIIH, XPA, RPA, XPG, and XPF/ERCC1, resulting in the removal of the damaged oligonucleotide (4, 7, 8). After being recognized by the XPC/HR23B complex, the damaged DNA structure is targeted by TFIIH, which recruits the other factors upon the addition of ATP (9 -11). The unwound DNA is then incised by the two endonucleases XPG and XPF/ERCC1 on the 3Ј and 5Ј side of the lesion, respectively (12-15), leaving a gap structure that is filled up by the DNA polymerase ⑀ or ␦ and the accompanying factors PCNA, RF-C, RPA, and DNA ligase I (16). Whether or not the NER reaction occurs by sequential arrival of the various factors or by a pre-assembled complex referred to as the repairosome or the holoenzyme is still under debate (17)(18)(19). Although the hypothesis of the sequential assembly, which has gained a lot of support from recent biological studies, seems to be more accepted, the order of assembly of the NER factors on the damaged DNA and their contribution to the DNA remodeling to allow the repair are not fully understood (10,20,21). As an example, to further learn abou...
The repair-deficient form of trichothiodystrophy (TTD) most often results from mutations in the genes XPB or XPD, encoding helicases of the transcription/repair factor TFIIH. The genetic defect in a third group, TTD-A, is unknown, but is also caused by dysfunctioning TFIIH. None of the TFIIH subunits carry a mutation and TFIIH from TTD-A cells is active in both transcription and repair. Instead, immunoblot and immunofluorescence analyses reveal a strong reduction in the TFIIH concentration. Thus, the phenotype of TTD-A appears to result from sublimiting amounts of TFIIH, probably due to a mutation in a gene determining the complex stability. The reduction of TFIIH mainly affects its repair function and hardly influences transcription.
Nucleotide excision repair (NER) removes damage from DNA in a tightly regulated multiprotein process. The xeroderma pigmentosum group B (XPB) helicase subunit of TFIIH functions in NER and transcription. The serine 751 (S751) residue of XPB was found to be phosphorylated in vivo. This phosphorylation inhibits NER and the microinjection of a phosphomimicking XPB-S751E mutant is unable to correct the NER defect of XP-B cells. Conversely, XPB-S751 dephosphorylation or its substitution with alanine (S751A) restores NER both in vivo and in vitro. Surprisingly, phospho/dephosphorylation of S751 spares TFIIH-dependent transcription. Finally, the phosphorylation of XPB-S751 does not impair the TFIIH unwinding of the DNA around the lesion, but rather prevents the 5 0 incision triggered by the ERCC1-XPF endonuclease. These data support an additional role for XPB in promoting the incision of the damaged fragment and reveal a point of NER regulation on TFIIH without interference in its transcription activity.
To counteract the deleterious effects of genotoxic injury, cells have set up a sophisticated network of DNA repair pathways. We show that Gal4-VP16 and RAR transcriptional activators stimulate nucleotide excision repair (NER). This DNA repair activation is not coupled to transcription since it occurs in Cockayne syndrome cells (which are transcription-coupled repair deficient) and is observed in vitro in the presence of alpha-amanitin and in the absence of the basal transcription factors. Using a reconstituted dual incision assay, we also show that binding of activators to their cognate sequences induces a local chromatin remodeling mediated by ATP-driven chromatin remodeling and acetyltransferase activities to facilitate DNA repair.
Nucleotide excision repair (NER) removes UV-induced photoproducts and numerous other DNA lesions in a highly conserved 'cut-and-paste' reaction that involves approximately 25 core components. In addition, several other proteins have been identified which are dispensable for NER in vitro but have an undefined role in vivo and may act at the interface of NER and other cellular processes. An intriguing example is the Saccharomyces cerevisiae Mms19 protein that has an unknown dual function in NER and RNA polymerase II transcription. Here we report the cloning and characterization of a human homolog, designated hMMS19, that encodes a 1030 amino acid protein with 26% identity and 51% similarity to S.cerevisiae Mms19p and with a strikingly similar size. The expression profile and nuclear location are consistent with a repair function. Co-immunoprecipitation experiments revealed that hMMS19 directly interacts with the XPB and XPD subunits of NER-transcription factor TFIIH. These findings extend the conservation of the NER apparatus and the link between NER and basal transcription and suggest that hMMS19 exerts its function in repair and transcription by interacting with the XPB and XPD helicases.
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