Project description:Many cancers originate from misregulation of gene expression caused by chromosomal translocations which result from ligation of DNA double-strand breaks (DSBs). Indeed, translocations may be causal in ~20% of human cancer morbidity 1. Although the sources of DSBs are numerous2-5, we have virtually no knowledge of the steps linking DSB formation to DSB ligation. Here, we show that early replication timing of translocation partner loci, mediated by the activity of replication origins, is a critical regulator of lymphomagenic Myc translocations generated by activation-induced deaminase (AID) during antibody maturation in B-cells. Reduced levels of the replicative helicase, the minichromosome maintenance (MCM) complex6, impairs translocation genesis, decreases firing of replication origins at AID target genes and globally abrogates the replication timing program without altering cell proliferation, gene expression or genome architecture. Strikingly, deleting a single origin of replication at Myc induces a switch from early-to-late replication at Myc with concomitantly impaired translocation frequency. This phenotype is reversed by restoring early replication at Myc thereby demonstrating a direct, causal role of replication origin activity and replication timing in translocation genesis. Finally, this replication timing-mediated step acts downstream of DSBs and is independent of DSB frequency, constituting a novel regulatory step in translocation biogenesis.

Project description:Many cancers originate from misregulation of gene expression caused by chromosomal translocations which result from ligation of DNA double-strand breaks (DSBs). Indeed, translocations may be causal in ~20% of human cancer morbidity 1. Although the sources of DSBs are numerous2-5, we have virtually no knowledge of the steps linking DSB formation to DSB ligation. Here, we show that early replication timing of translocation partner loci, mediated by the activity of replication origins, is a critical regulator of lymphomagenic Myc translocations generated by activation-induced deaminase (AID) during antibody maturation in B-cells. Reduced levels of the replicative helicase, the minichromosome maintenance (MCM) complex6, impairs translocation genesis, decreases firing of replication origins at AID target genes and globally abrogates the replication timing program without altering cell proliferation, gene expression or genome architecture. Strikingly, deleting a single origin of replication at Myc induces a switch from early-to-late replication at Myc with concomitantly impaired translocation frequency. This phenotype is reversed by restoring early replication at Myc thereby demonstrating a direct, causal role of replication origin activity and replication timing in translocation genesis. Finally, this replication timing-mediated step acts downstream of DSBs and is independent of DSB frequency, constituting a novel regulatory step in translocation biogenesis.

Project description:Many cancers originate from misregulation of gene expression caused by chromosomal translocations which result from ligation of DNA double-strand breaks (DSBs). Indeed, translocations may be causal in ~20% of human cancer morbidity 1. Although the sources of DSBs are numerous2-5, we have virtually no knowledge of the steps linking DSB formation to DSB ligation. Here, we show that early replication timing of translocation partner loci, mediated by the activity of replication origins, is a critical regulator of lymphomagenic Myc translocations generated by activation-induced deaminase (AID) during antibody maturation in B-cells. Reduced levels of the replicative helicase, the minichromosome maintenance (MCM) complex6, impairs translocation genesis, decreases firing of replication origins at AID target genes and globally abrogates the replication timing program without altering cell proliferation, gene expression or genome architecture. Strikingly, deleting a single origin of replication at Myc induces a switch from early-to-late replication at Myc with concomitantly impaired translocation frequency. This phenotype is reversed by restoring early replication at Myc thereby demonstrating a direct, causal role of replication origin activity and replication timing in translocation genesis. Finally, this replication timing-mediated step acts downstream of DSBs and is independent of DSB frequency, constituting a novel regulatory step in translocation biogenesis.

Project description:Many cancers originate from misregulation of gene expression caused by chromosomal translocations which result from ligation of DNA double-strand breaks (DSBs). Indeed, translocations may be causal in ~20% of human cancer morbidity 1. Although the sources of DSBs are numerous2-5, we have virtually no knowledge of the steps linking DSB formation to DSB ligation. Here, we show that early replication timing of translocation partner loci, mediated by the activity of replication origins, is a critical regulator of lymphomagenic Myc translocations generated by activation-induced deaminase (AID) during antibody maturation in B-cells. Reduced levels of the replicative helicase, the minichromosome maintenance (MCM) complex6, impairs translocation genesis, decreases firing of replication origins at AID target genes and globally abrogates the replication timing program without altering cell proliferation, gene expression or genome architecture. Strikingly, deleting a single origin of replication at Myc induces a switch from early-to-late replication at Myc with concomitantly impaired translocation frequency. This phenotype is reversed by restoring early replication at Myc thereby demonstrating a direct, causal role of replication origin activity and replication timing in translocation genesis. Finally, this replication timing-mediated step acts downstream of DSBs and is independent of DSB frequency, constituting a novel regulatory step in translocation biogenesis.

Project description:Chromosomal translocations result from joining of DNA double-strand breaks (DSBs) and frequently cause cancer. Yet, the steps linking DSB formation to DSB ligation remain undeciphered. We report that DNA replication timing (RT) directly regulates lymphomagenic Myc translocations during antibody maturation in B-cells downstream of DSBs and independently of DSB frequency. Depletion of minichromosome-maintenance (MCM) complexes alters replication origin activity, decreases translocations and abrogates global RT. Ablating a single origin at Myc causes an early-to-late RT switch, loss of translocations and reduced nuclear proximity with a translocation partner locus, phenotypes that were reversed by restoring early RT. Disruption of shared early RT also reduced tumorigenic translocations in human leukemic cells. Thus, RT constitutes a new, unprecedented mechanism in translocation biogenesis linking DSB formation to DSB ligation

Project description:Chromosomal translocations result from the joining of DNA double-strand breaks (DSBs) and frequentlycause cancer. However, the steps linking DSB formation to DSB ligation remain undeciphered. Wereport that DNA replication timing (RT) directly regulates lymphomagenicMyctranslocations duringantibody maturation in B cells downstream of DSBs and independently of DSB frequency. Depletion ofminichromosome maintenance complexes alters replication origin activity, decreases translocations,and deregulates global RT. Ablating a single origin atMyccauses an early-to-late RT switch, loss oftranslocations, and reduced proximity with the immunoglobulin heavy chain (Igh) gene, its majortranslocation partner. These phenotypes were reversed by restoring early RT. Disruption of early RT alsoreduced tumorigenic translocations in human leukemic cells. Thus, RT constitutes a general mechanismin translocation biogenesis linking DSB formation to DSB ligation.

Project description:High-throughput genome-wide translocation sequencing (HTGTS) is a robust approach to identify genome-wide translocation junctions. We performed HTGTS to study the fate of introduced c-myc DSBs in mouse splenic B cells activated for activation cytidine deaminase (AID)-dependent class switch recombination (CSR). We found frequent translocations of c-myc DSBs to AID-initiated DSBs in IgH switch regions in wild-type (WT) and ATM-deficient B cells. However, c-myc also translocated frequently to newly generated DSBs within a 35-megabase region downstream of IgH in ATM-deficient, but not WT, CSR-activated B cells. Moreover, we found such DSBs and translocations in activated B cells that did not express AID or undergo CSR. These findings indicate that ATM deficiency leads to formation of chromosome 12 dicentrics via RAG-initiated IgH DSBs in progenitor B cells and that these dicentrics can be propagated developmentally into mature B cells where they generate new DSBs downstream of IgH via breakage-fusion-bridge cycles. Preparation of libraries from WT or ATM-deficient activated by a-CD40/IL4 or RP105.

Project description:High-throughput genome-wide translocation sequencing (HTGTS) is a robust approach to identify genome-wide translocation junctions. We performed HTGTS to study the fate of introduced c-myc DSBs in mouse splenic B cells activated for activation cytidine deaminase (AID)-dependent class switch recombination (CSR). We found frequent translocations of c-myc DSBs to AID-initiated DSBs in IgH switch regions in wild-type (WT) and ATM-deficient B cells. However, c-myc also translocated frequently to newly generated DSBs within a 35-megabase region downstream of IgH in ATM-deficient, but not WT, CSR-activated B cells. Moreover, we found such DSBs and translocations in activated B cells that did not express AID or undergo CSR. These findings indicate that ATM deficiency leads to formation of chromosome 12 dicentrics via RAG-initiated IgH DSBs in progenitor B cells and that these dicentrics can be propagated developmentally into mature B cells where they generate new DSBs downstream of IgH via breakage-fusion-bridge cycles.

Project description:DNA duplication is intimately connected to setting up post-replicative chromosome structures and events, but molecular details of this coordination are not well understood. A striking example occurs during yeast meiosis, where replication locally influences timing of the DNA double-strand breaks (DSBs) that initiate recombination. We show here that replication-DSB coordination is eliminated by overexpressing Dbf4-dependent Cdc7 kinase (DDK) or removing Tof1 or Csm3, components of the replication fork protection complex (FPC). DDK physically associates with Tof1, and Tof1 is dispensable for replication-DSB coordination if DDK is artificially tethered to replisomes. Furthermore, DDK phosphorylation of the DSB-promoting factor Mer2 is locally coordinated with replication, dependent on Tof1. These findings indicate that DDK recruited by FPC to replisomes phosphorylates chromatin-bound Mer2 in the wake of the replication fork, thus synchronizing replication with an early prerequisite for DSB formation. This may be a general mechanism to ensure spatial and temporal coordination of replication with other chromosomal processes. Ninety-six samples total: 12 time points (each time points contains ChIP and input samples) from Rec114-myc ARS+, Rec114-myc arsM-bM-^HM-^F strains, Rec114-myc tof1M-bM-^HM-^FARS+ and Rec114-myc tof1M-bM-^HM-^F arsM-bM-^HM-^F strains

Project description:Activation-induced cytidine deaminase (AID) is required for initiation of Ig class switch recombination (CSR) and somatic hypermutation (SHM) of antibody genes during immune responses. AID has also been shown to induce chromosomal translocations, mutations, and DNA double-strand breaks (DSBs) involving non-Ig genes in activated B cells. To determine what makes a DNA site a target for AID-induced DSBs, we identify off-target DSBs induced by AID by performing chromatin immunoprecipitation (ChIP) for Nbs1, a protein that binds DSBs, followed by deep sequencing (ChIP-Seq). We detect and characterize hundreds of off-target AID-dependent DSBs. Two types of tandem repeats are highly enriched within the Nbs1-binding sites: long CA repeats, which can form Z-DNA, and tandem pentamers containing the AID target hotspot WGCW. These tandem repeats are not nearly as enriched at AID-independent DSBs, which we also identified. Msh2, a component of the mismatch repair pathway and important for genome stability, increases off-target DSBs, similar to its effect on Ig switch region DSBs, which are required intermediates during CSR. Most of the off-target DSBs are two-ended, consistent with generation during G1 phase, similar to DSBs in Ig switch regions. However, a minority are one-ended, presumably due to conversion of single-strand breaks to DSBs during replication. One-ended DSBs are repaired by processes involving homologous recombination, including break-induced replication repair, which can lead to genome instability. Off-target DSBs, especially those present during S phase, can lead to chromosomal translocations, deletions and gene amplifications, resulting in the high frequency of B cell lymphomas derived from cells that express or have expressed AID.