Project description:Transcription is a major obstacle for replication fork (RF) progression and a cause of genome instability. Part of this instability is mediated by cotranscriptional R loops, which are believed to increase by suboptimal assembly of the nascent messenger ribonucleoprotein particle (mRNP). However, no clear evidence exists that heterogeneous nuclear RNPs (hnRNPs), the basic mRNP components, prevent R-loop stabilization. Here we show that yeast Npl3, the most abundant RNA-binding hnRNP, prevents R-loop-mediated genome instability. npl3? cells show transcription-dependent and R-loop-dependent hyperrecombination and genome-wide replication obstacles as determined by accumulation of the Rrm3 helicase. Such obstacles preferentially occur at long and highly expressed genes, to which Npl3 is preferentially bound in wild-type cells, and are reduced by RNase H1 overexpression. The resulting replication stress confers hypersensitivity to double-strand break-inducing agents. Therefore, our work demonstrates that mRNP factors are critical for genome integrity and opens the option of using them as therapeutic targets in anti-cancer treatment.

Project description:Actively dividing cells perform robust and accurate DNA replication during fluctuating nutrient availability, yet factors that prevent disruption of replication remain largely unknown. Here we report that DksA, a nutrient-responsive transcription factor, ensures replication completion in Escherichia coli by removing transcription roadblocks. In the absence of DksA, replication is rapidly arrested upon amino acid starvation. This arrest requires active transcription and is alleviated by RNA polymerase mutants that compensate for DksA activity. This replication arrest occurs independently of exogenous DNA damage, yet it induces the DNA-damage response and recruits the main recombination protein RecA. This function of DksA is independent of its transcription initiation activity but requires its less-studied transcription elongation activity. Finally, GreA/B elongation factors also prevent replication arrest during nutrient stress. We conclude that transcription elongation factors alleviate fundamental conflicts between replication and transcription, thereby protecting replication fork progression and DNA integrity.

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:The identification of genes involved in replicative stress is key to understanding cancer evolution and to identify therapeutic targets. Here, we show that CDK12 prevents transcription-replication conflicts (TRCs) and the activation of cytotoxic replicative stress upon deregulation of the MYC oncogene. CDK12 was recruited at damaged genes by PARP-dependent DDR-signaling and elongation-competent RNAPII, to repress transcription. Either loss or chemical inhibition of CDK12 led to DDR-resistant transcription of damaged genes. Loss of CDK12 exacerbated TRCs in MYC-overexpressing cells and led to the accumulation of double-strand DNA breaks, occurring between co-directional early-replicating regions and transcribed genes. Overall, our data demonstrate that CDK12 protects genome integrity by repressing transcription of damaged genes, which is required for proper resolution of DSBs at oncogene-induced TRCs. This provides a rationale that explains both how CDK12 deficiency can promote tandem duplications of early-replicated regions during tumor evolution, and how CDK12 targeting can exacerbate replicative-stress in tumors.

Project description:In order to identify genes and pathways necessary to preserve genome integrity upon Myc over-expression, we conducted a large siRNA-based screen in isogenic lines. We discovered several genes that suppressed the Myc-induced DNA-damage response and that were essential for the cell survival upon Myc activation. We idntified CDK12, a cyclin dependent kinase involved in transcriptional control and genome stability. We uncovered a novel and unexpected role of CDK12 in controlling transcription at loci proximal to DNA damaged sites and dissected its upstream regulatory pathways and downstream effectors. Mechanistic studies and genome-wide mapping of replication dynamics and DSBs revealed how CDK12 is essential to suppress intrinsic transcription-replication conflicts, thus avoiding cytotoxic DNA damage in cancer cells. Overall, this study uncovers a novel role for CDK12 and a new liability of Myc-driven cancers, which could be exploited for therapeutic purposes.

Project description:In order to identify genes and pathways necessary to preserve genome integrity upon Myc over-expression, we conducted a large siRNA-based screen in isogenic lines. We discovered several genes that suppressed the Myc-induced DNA-damage response and that were essential for the cell survival upon Myc activation. We idntified CDK12, a cyclin dependent kinase involved in transcriptional control and genome stability. We uncovered a novel and unexpected role of CDK12 in controlling transcription at loci proximal to DNA damaged sites and dissected its upstream regulatory pathways and downstream effectors. Mechanistic studies and genome-wide mapping of replication dynamics and DSBs revealed how CDK12 is essential to suppress intrinsic transcription-replication conflicts, thus avoiding cytotoxic DNA damage in cancer cells. Overall, this study uncovers a novel role for CDK12 and a new liability of Myc-driven cancers, which could be exploited for therapeutic purposes.

Project description:In order to identify genes and pathways necessary to preserve genome integrity upon Myc over-expression, we conducted a large siRNA-based screen in isogenic lines. We discovered several genes that suppressed the Myc-induced DNA-damage response and that were essential for the cell survival upon Myc activation. We idntified CDK12, a cyclin dependent kinase involved in transcriptional control and genome stability. We uncovered a novel and unexpected role of CDK12 in controlling transcription at loci proximal to DNA damaged sites and dissected its upstream regulatory pathways and downstream effectors. Mechanistic studies and genome-wide mapping of replication dynamics and DSBs revealed how CDK12 is essential to suppress intrinsic transcription-replication conflicts, thus avoiding cytotoxic DNA damage in cancer cells. Overall, this study uncovers a novel role for CDK12 and a new liability of Myc-driven cancers, which could be exploited for therapeutic purposes.

Project description:In order to identify genes and pathways necessary to preserve genome integrity upon Myc over-expression, we conducted a large siRNA-based screen in isogenic lines. We discovered several genes that suppressed the Myc-induced DNA-damage response and that were essential for the cell survival upon Myc activation. We idntified CDK12, a cyclin dependent kinase involved in transcriptional control and genome stability. We uncovered a novel and unexpected role of CDK12 in controlling transcription at loci proximal to DNA damaged sites and dissected its upstream regulatory pathways and downstream effectors. Mechanistic studies and genome-wide mapping of replication dynamics and DSBs revealed how CDK12 is essential to suppress intrinsic transcription-replication conflicts, thus avoiding cytotoxic DNA damage in cancer cells. Overall, this study uncovers a novel role for CDK12 and a new liability of Myc-driven cancers, which could be exploited for therapeutic purposes.

Project description:In order to identify genes and pathways necessary to preserve genome integrity upon Myc over-expression, we conducted a large siRNA-based screen in isogenic lines. We discovered several genes that suppressed the Myc-induced DNA-damage response and that were essential for the cell survival upon Myc activation. We idntified CDK12, a cyclin dependent kinase involved in transcriptional control and genome stability. We uncovered a novel and unexpected role of CDK12 in controlling transcription at loci proximal to DNA damaged sites and dissected its upstream regulatory pathways and downstream effectors. Mechanistic studies and genome-wide mapping of replication dynamics and DSBs revealed how CDK12 is essential to suppress intrinsic transcription-replication conflicts, thus avoiding cytotoxic DNA damage in cancer cells. Overall, this study uncovers a novel role for CDK12 and a new liability of Myc-driven cancers, which could be exploited for therapeutic purposes.

Project description:Ectopic R-loop accumulation causes DNA replication stress and genome instability. To avoid these outcomes, cells possess a range of anti-R-loop mechanisms, including RNaseH that degrades the RNA moiety in R-loops. To comprehensively identify anti-R-loop mechanisms, we performed a genome-wide trigenic interaction screen in yeast lacking RNH1 and RNH201. We identified?>100 genes critical for fitness in the absence of RNaseH, which were enriched for DNA replication fork maintenance factors including the MRE11-RAD50-NBS1 (MRN) complex. While MRN has been shown to promote R-loops at DNA double-strand breaks, we show that it suppresses R-loops and associated DNA damage at transcription-replication conflicts. This occurs through a non-nucleolytic function of MRE11 that is important for R-loop suppression by the Fanconi Anemia pathway. This work establishes a novel role for MRE11-RAD50-NBS1 in directing tolerance mechanisms at transcription-replication conflicts.