UV-induced inhibition of transcription involves repression of transcription initiation and phosphorylation of RNA polymerase II.

Cells from patients with Cockayne syndrome (CS) are hypersensitive to DNA-damaging agents and are unable to restore damage-inhibited RNA synthesis. On the basis of repair kinetics of different types of lesions in transcriptionally active genes, we hypothesized previously that impaired transcription in CS cells is a consequence of defective transcription initiation after DNA damage induction. Here, we investigated the effect of UV irradiation on transcription by using an in vitro transcription system that allowed uncoupling of initiation from elongation events. Nuclear extracts prepared from UV-irradiated or mock-treated normal human and CS cells were assayed for transcription activity on an undamaged beta-globin template. Transcription activity in nuclear extracts closely mimicked kinetics of transcription in intact cells: extracts from normal cells prepared 1 h after UV exposure showed a strongly reduced activity, whereas transcription activity was fully restored in extracts prepared 6 h after treatment. Extracts from CS cells exhibited reduced transcription activity at any time after UV exposure. Reduced transcription activity in extracts coincided with a strong reduction of RNA polymerase II (RNAPII) containing hypophosphorylated C-terminal domain, the form of RNAPII known to be recruited to the initiation complex. These results suggest that inhibition of transcription after UV irradiation is at least partially caused by repression of transcription initiation and not solely by blocked elongation at sites of lesions. Generation of hypophosphorylated RNAPII after DNA damage appears to play a crucial role in restoration of transcription. CS proteins may be required for this process in a yet unknown way.

[1]  L. Mullenders,et al.  Cells from XP-D and XP-D-CS patients exhibit equally inefficient repair of UV-induced damage in transcribed genes but different capacity to recover UV-inhibited transcription. , 1999, Nucleic acids research.

[2]  F. Holstege,et al.  An unusual eukaryotic protein phosphatase required for transcription by RNA polymerase II and CTD dephosphorylation in S. cerevisiae. , 1999, Molecular cell.

[3]  J. Hoeijmakers,et al.  Biochemical and Biological Characterization of Wild-type and ATPase-deficient Cockayne Syndrome B Repair Protein* , 1998, The Journal of Biological Chemistry.

[4]  E. Friedberg,et al.  Yeast RNA Polymerase II Transcription In Vitro Is Inhibited in the Presence of Nucleotide Excision Repair: Complementation of Inhibition by Holo-TFIIH and Requirement for RAD26 , 1998, Molecular and Cellular Biology.

[5]  J. Corden,et al.  Ultraviolet Radiation-induced Ubiquitination and Proteasomal Degradation of the Large Subunit of RNA Polymerase II , 1998, The Journal of Biological Chemistry.

[6]  A. Lehmann Dual functions of DNA repair genes: molecular, cellular, and clinical implications , 1998, BioEssays : news and reviews in molecular, cellular and developmental biology.

[7]  D. Moras,et al.  Cisplatin‐ and UV‐damaged DNA lure the basal transcription factor TFIID/TBP , 1997, The EMBO journal.

[8]  J. Hoeijmakers,et al.  The Cockayne syndrome B protein, involved in transcription‐coupled DNA repair, resides in an RNA polymerase II‐containing complex , 1997, The EMBO journal.

[9]  P. Hanawalt,et al.  TFIIH-mediated nucleotide excision repair and initiation of mRNA transcription in an optimized cell-free DNA repair and RNA transcription assay. , 1996, Nucleic acids research.

[10]  L. Mullenders,et al.  The sensitivity of Cockayne's syndrome cells to DNA-damaging agents is not due to defective transcription-coupled repair of active genes , 1996, Molecular and cellular biology.

[11]  D. Bregman,et al.  Transcription-dependent redistribution of the large subunit of RNA polymerase II to discrete nuclear domains , 1995, The Journal of cell biology.

[12]  D. Bushnell,et al.  Different forms of TFIIH for transcription and DNA repair: Holo-TFIIH and a nucleotide excision repairosome , 1995, Cell.

[13]  P. Hanawalt Transcription-coupled repair and human disease. , 1994, Science.

[14]  M. Dahmus,et al.  Purification and characterization of a phosphatase from HeLa cells which dephosphorylates the C-terminal domain of RNA polymerase II. , 1994, The Journal of biological chemistry.

[15]  M. Dahmus The role of multisite phosphorylation in the regulation of RNA polymerase II activity. , 1994, Progress in nucleic acid research and molecular biology.

[16]  L. Mullenders,et al.  Deficient repair of the transcribed strand of active genes in Cockayne's syndrome cells. , 1993, Nucleic acids research.

[17]  P. Cooper,et al.  Preferential repair of ionizing radiation-induced damage in the transcribed strand of an active human gene is defective in Cockayne syndrome. , 1993, Proceedings of the National Academy of Sciences of the United States of America.

[18]  M. Barton,et al.  The erythroid protein cGATA-1 functions with a stage-specific factor to activate transcription of chromatin-assembled beta-globin genes. , 1993, Genes & development.

[19]  P. Chambon,et al.  DNA repair helicase: a component of BTF2 (TFIIH) basic transcription factor. , 1993, Science.

[20]  J. Hoeijmakers,et al.  Engagement with transcription , 1993, Nature.

[21]  D. Reinberg,et al.  Human general transcription factor IIH phosphorylates the C-terminal domain of RNA polymerase II , 1992, Nature.

[22]  M. Nance,et al.  Cockayne syndrome: review of 140 cases. , 1992, American journal of medical genetics.

[23]  L. Mullenders,et al.  The genetic defect in Cockayne syndrome is associated with a defect in repair of UV-induced DNA damage in transcriptionally active DNA. , 1990, Proceedings of the National Academy of Sciences of the United States of America.

[24]  P. Laybourn,et al.  Transcription-dependent structural changes in the C-terminal domain of mammalian RNA polymerase subunit IIa/o. , 1989, The Journal of biological chemistry.

[25]  P. Hanawalt,et al.  Selective removal of transcription-blocking DNA damage from the transcribed strand of the mammalian DHFR gene , 1987, Cell.

[26]  P. Hanawalt,et al.  DNA repair in an active gene: Removal of pyrimidine dimers from the DHFR gene of CHO cells is much more efficient than in the genome overall , 1985, Cell.

[27]  A. Lehmann,et al.  Failure of RNA synthesis to recover after UV irradiation: an early defect in cells from individuals with Cockayne's syndrome and xeroderma pigmentosum. , 1982, Cancer research.

[28]  S. Takeda,et al.  Effects of Ultra-violet Microbeam Irradiation of Various Sites in HeLa Cells on the Synthesis of RNA, DNA and Protein , 1967, Nature.