Project description:In adaptive immunity, transcription-coupled damage is introduced into antibody genes by activation-induced cytidine deaminase (AID) to diversify antibody repertoire. However, the coordination between transcription and DNA damage/repair remains elusive. Here, we find that transcription elongation factor 1 (ELOF1) stabilizes paused RNA polymerase II (RNAPII) at transcription barriers, providing a platform for transcription-coupled DNA damage/repair. Using a genetic screen, we discover that ELOF1 is required for AID targeting and that ELOF1 deficiency results in defective antibody class switch recombination and somatic hypermutation in mice. While downstream transcription-coupled repair factors are dispensable for AID-damage, ELOF1 mechanistically facilitates both transcription-coupled damage and repair by stabilizing chromatin-bound RNAPII. In ELOF1-deficient cells, paused RNAPII tends to detach from chromatin and fails to recruit factors to induce or repair DNA damage. Our study places ELOF1 at the center of transcription-coupled DNA metabolism processes and suggests a transition of RNAPII from elongation to a DNA damage/repair scaffold.

Project description:In adaptive immunity, transcription-coupled damage is introduced into antibody genes by activation-induced cytidine deaminase (AID) to diversify antibody repertoire. However, the coordination between transcription and DNA damage/repair remains elusive. Here, we find that transcription elongation factor 1 (ELOF1) stabilizes paused RNA polymerase II (RNAPII) at transcription barriers, providing a platform for transcription-coupled DNA damage/repair. Using a genetic screen, we discover that ELOF1 is required for AID targeting and that ELOF1 deficiency results in defective antibody class switch recombination and somatic hypermutation in mice. While downstream transcription-coupled repair factors are dispensable for AID-damage, ELOF1 mechanistically facilitates both transcription-coupled damage and repair by stabilizing chromatin-bound RNAPII. In ELOF1-deficient cells, paused RNAPII tends to detach from chromatin and fails to recruit factors to induce or repair DNA damage. Our study places ELOF1 at the center of transcription-coupled DNA metabolism processes and suggests a transition of RNAPII from elongation to a DNA damage/repair scaffold.

Project description:Removal of transcription-blocking DNA lesions requires the binding of transcription-coupled repair (TCR) factors to DNA damage-stalled RNA polymerase II (RNAPII). The full repertoire of factors required for TCR remains to be elucidated. Through genome-wide CRISPR screens and strand-specific ChIP-seq, we identify the RNAPII-associated factor ELOF1 as a new core TCR component. Mechanistically, ELOF1 does not affect the association of TCR components CSB and the CRL4CSA ubiquitin ligase, but instead regulates RNAPII ubiquitylation, and subsequent ubiquitin-dependent recruitment of repair factors. This function requires its constitutive interaction with RNAPII close to the K1268 site, revealing ELOF1 as a specificity factor that positions CRL4CSA for optimal RNAPII ubiquitylation to orchestrate transcription-coupled repair. Finally, ELOF1 operates in a second transcription stress-response pathway, regulated by the deubiquitylating enzyme OTUD5.

Project description:Cells employ transcription-coupled repair (TCR) to eliminate transcription-blocking DNA lesions. DNA damage-induced binding of the TCR-specific repair factor CSB to RNA polymerase II (RNAPII) triggers RNAPII ubiquitylation at a single lysine (K1268) by the CRL4CSA ubiquitin ligase. How CRL4CSA is specifically directed toward the K1268 site is unknown. Here, we identify ELOF1 as the missing link that facilitates RNAPII ubiquitylation, a key signal for the assembly of downstream repair factors. This function requires its constitutive interaction with RNAPII close to the K1268 site, revealing ELOF1 as a specificity factor that interacts with and positions CRL4CSA for optimal RNAPII ubiquitylation. Drug-genetic interaction screening also reveals a CSB-independent compensatory pathway in which ELOF1 protects cells against DNA replication stress by preventing DNA damage-induced R-loops. Our study offers key insights into the molecular mechanisms of TCR and provides a genetic framework of the interplay between the transcriptional stress response and DNA replication.

Project description:Correct transcription is crucial for life. However, DNA damage severely impedes elongating RNA Polymerase II (Pol II), causing transcription inhibition and transcription-replication conflicts. Cells are equipped with intricate mechanisms to counteract the severe consequence of these transcription-blocking lesions (TBLs). However, the exact mechanism and factors involved remain largely unknown. Here, using a genome-wide CRISPR/cas9 screen, we identified elongation factor ELOF1 as an important new factor in the transcription stress response upon DNA damage. We show that ELOF1 has an evolutionary conserved role in Transcription-Coupled Nucleotide Excision Repair (TC-NER), where it promotes recruitment of the TC-NER factors UVSSA and TFIIH to efficiently repair TBLs and resume transcription. Additionally, ELOF1 modulates transcription to protect cells from transcription-mediated replication stress, thereby preserving genome stability. Thus, ELOF1 protects the transcription machinery from DNA damage via two distinct mechanisms.

Project description:The coordinated transcription of genes involves RNA polymerase II enzymes (RNAPII), which pull DNA through their active sites. DNA lesions in transcribed strands block RNAPII elongation and induce a strong transcriptional arrest. The transcription-coupled repair (TCR) pathway ensures the efficient removal of transcription-blocking DNA lesions, but this is not sufficient to overcome this arrest and resume transcription. Through proteomics screens, we find that the TCR-specific CSB protein loads the evolutionary conserved PAF1 complex (PAF1C) onto RNAPII in promoter-proximal regions specifically in response to DNA damage. PAF1C is dispensable for TCR-mediated repair,but is essential to resume RNA synthesis after UV irradiation, suggesting an unexpected uncoupling between DNA repair and transcription restart. Moreover, we find that PAF1C promotes RNAPII pause release in promoter-proximal regions and subsequently acts as a processivity factor that stimulates transcription elongation waves throughout genes. Our findings expose the molecular basis for a non-canonical PAF1C-dependent pathway that restores transcription throughout the human genome after genotoxic stress.

Project description:Correct transcription is crucial for life. However, DNA damage severely impedes elongating RNA Polymerase II (Pol II), causing transcription inhibition and transcription-replication conflicts. Cells have evolved intricate mechanisms to counteract the severe consequence of these transcription-blocking lesions, however the exact mechanism and factors involved remain largely unknown. Here, using a genome-wide CRISPR/cas9 screen, we identified elongation factor ELOF1 as an important new factor in the damage-induced transcription stress response. ELOF1 has an evolutionary-conserved role in TC-NER where it promotes the recruitment of the TC-NER factors UVSSA and TFIIH and facilitates Pol II ubiquitylation to efficiently repair TBLs. Importantly, ELOF1 has an additional role in protecting cells from transcription-mediated replication hindrance, thereby preserving genome stability. Thus, ELOF1 protects the transcription machinery from DNA damage by two distinct mechanisms.

Project description:In response to transcription-blocking DNA damage, cells orchestrate a multi-pronged reaction, involving transcription-coupled DNA repair, degradation of RNAPII and genome-wide transcription shutdown. How these responses are connected has remained unclear. Here we show that damage-induced ubiquitylation of RNAPII itself, at a single lysine (RPB1 K1268), is the focal point for DNA damage response coordination. K1268-ubiquitylation affects DNA repair and signals RNAPII degradation, essential for surviving genotoxic insult. It is also crucial for transcriptional shutdown, in the absence of which cells display dramatic transcriptome alterations. Additionally, regulation of RNAPII stability is central to transcription recovery – indeed, depletion of the RNAPII pool underlies the failure of this process in Cockayne syndrome B cells. These data expose regulation of global RNAPII levels as integral to the cellular DNA damage response, and open the intriguing possibility that RNAPII pool size generally affects cell-specific transcription programmes, in genome instability disorders and even normal cells.

Project description:In response to transcription-blocking DNA damage, cells orchestrate a multi-pronged reaction, involving transcription-coupled DNA repair, degradation of RNAPII and genome-wide transcription shutdown. How these responses are connected has remained unclear. Here we show that damage-induced ubiquitylation of RNAPII itself, at a single lysine (RPB1 K1268), is the focal point for DNA damage response coordination. K1268-ubiquitylation affects DNA repair and signals RNAPII degradation, essential for surviving genotoxic insult. It is also crucial for transcriptional shutdown, in the absence of which cells display dramatic transcriptome alterations. Additionally, regulation of RNAPII stability is central to transcription recovery – indeed, depletion of the RNAPII pool underlies the failure of this process in Cockayne syndrome B cells. These data expose regulation of global RNAPII levels as integral to the cellular DNA damage response, and open the intriguing possibility that RNAPII pool size generally affects cell-specific transcription programmes, in genome instability disorders and even normal cells.

Project description:In response to transcription-blocking DNA damage, cells orchestrate a multi-pronged reaction, involving transcription-coupled DNA repair, degradation of RNAPII and genome-wide transcription shutdown. How these responses are connected has remained unclear. Here we show that damage-induced ubiquitylation of RNAPII itself, at a single lysine (RPB1 K1268), is the focal point for DNA damage response coordination. K1268-ubiquitylation affects DNA repair and signals RNAPII degradation, essential for surviving genotoxic insult. It is also crucial for transcriptional shutdown, in the absence of which cells display dramatic transcriptome alterations. Additionally, regulation of RNAPII stability is central to transcription recovery – indeed, depletion of the RNAPII pool underlies the failure of this process in Cockayne syndrome B cells. These data expose regulation of global RNAPII levels as integral to the cellular DNA damage response, and open the intriguing possibility that RNAPII pool size generally affects cell-specific transcription programmes, in genome instability disorders and even normal cells.