Project description:Profound synthetic lethality between SMARCAL1 and FANCM (CRISPR screen)

Project description:Profound synthetic lethality between SMARCAL1 and FANCM (END-Seq)

Project description:DNA replication stress is a threat to genome integrity. The large SNF2-family of ATPases participates in preventing and mitigating DNA replication stress by employing their ATP-driven motor to remodel DNA or DNA-bound proteins. To understand the contribution of these ATPases in genome maintenance, we undertook CRISPR-based synthetic lethality screens with three SNF2-type ATPases: SMARCAL1, ZRANB3 and HLTF. Here we show that SMARCAL1 displays a profound synthetic lethal interaction with FANCM, another ATP-dependent translocase involved in DNA replication and genome stability. Their combined loss causes severe genome instability that we link to chromosome breakage at loci enriched in simple repeats, which are known to challenge replication fork progression. Our findings illuminate a critical genetic buffering mechanism that provides an essential function for maintaining genome integrity.

Project description:DNA replication stress is a threat to genome integrity. The large SNF2-family of ATPases participates in preventing and mitigating DNA replication stress by employing their ATP-driven motor to remodel DNA or DNA-bound proteins. To understand the contribution of these ATPases in genome maintenance, we undertook CRISPR-based synthetic lethality screens with three SNF2-type ATPases: SMARCAL1, ZRANB3 and HLTF. Here we show that SMARCAL1 displays a profound synthetic lethal interaction with FANCM, another ATP-dependent translocase involved in DNA replication and genome stability. Their combined loss causes severe genome instability that we link to chromosome breakage at loci enriched in simple repeats, which are known to challenge replication fork progression. Our findings illuminate a critical genetic buffering mechanism that provides an essential function for maintaining genome integrity.

Project description:DNA replication stress is a threat to genome integrity. The large SNF2-family of ATPases participates in preventing and mitigating DNA replication stress by employing their ATP-driven motor to remodel DNA or DNA-bound proteins. To understand the contribution of these ATPases in genome maintenance, we undertook CRISPR-based synthetic lethality screens with three SNF2-type ATPases: SMARCAL1, ZRANB3 and HLTF. Here we show that SMARCAL1 displays a profound synthetic lethal interaction with FANCM, another ATP-dependent translocase involved in DNA replication and genome stability. Their combined loss causes severe genome instability that we link to chromosome breakage at loci enriched in simple repeats, which are known to challenge replication fork progression. Our findings illuminate a critical genetic buffering mechanism that provides an essential function for maintaining genome integrity.

Project description:The DNA damage response (DDR) is a multi-faceted network of pathways that preserves genome stability. Unraveling the complementary interplay between these pathways remains a challenge. Here, we comprehensively mapped genetic interactions for all core DDR genes using combinatorial CRISPRi screening. We discovered myriad new connections, including interactions between cancer genes and small molecule targets. We focused on two of the strongest interactions: FEN1/LIG1:WDR48 and FANCM:SMARCAL1. First, we found that WDR48 works with USP1 to restrain overactive translesion synthesis in FEN1/LIG1-deficient cells, and that a preclinical inhibitor of USP1 specifically kills FEN1-deficient cells. Second, we found that SMARCAL1 and FANCM suppress DNA double-strand break (DSB) formation at TA-rich repeats in late-replicating regions that otherwise escape into mitosis and cause nuclear fragmentation. Our dataset provides a springboard for further mechanistic investigations into connections between DDR factors and suggests multiple interactions that could be exploited in cancer therapy.

Project description:Assessment of synthetic lethality between an sml1 null mutation and Yeast Deletion mutations Keywords = SML1 Keywords = yeast Keywords = deletion Keywords = synthetic lethality Keywords = tag Keywords = barcode Keywords: repeat sample

Project description:Assessment of synthetic lethality between an sgs1 null mutation and Yeast Deletion mutations Keywords = SGS1 Keywords = yeast Keywords = deletion Keywords = synthetic lethality Keywords = tag Keywords = barcode Keywords: repeat sample

Project description:Assessment of synthetic lethality between a bim1 null mutation and Yeast Deletion mutations Keywords = BIM1 Keywords = yeast Keywords = deletion Keywords = synthetic lethality Keywords = tag Keywords = barcode Keywords: repeat sample

Project description:Assessment of synthetic lethality between a cin8 deletion mutation and Yeast Deletion mutations. Keywords = CIN8 Keywords = yeast Keywords = deletion Keywords = synthetic lethality Keywords = tag Keywords = barcode Keywords: repeat sample