Project description:Replication origins in human cells form clusters ranging from tens to hundreds of kilobases called initiation zones (IZs), typically located in intergenic regions between active genes. On a larger megabase scale, chromosomes replicate in a temporally defined replication timing (RT) pattern, where euchromatic regions replicate early, and heterochromatic regions replicate late. Although the stochastic model of IZ firing with a temporally regulated limiting factor can explain RT formation, this limiting factor in human cells remains unclear. To investigate the relationship between IZ and RT, we mapped the temporal firing pattern of IZs and examined the genome-wide distributions of replication licensing and firing factors in human cells. We identified TRESLIN-MTBP as the key limiting firing factor for replication initiation. Its loading onto phosphorylated MCM2–7 double hexamer (MCM-DH) is controlled by the opposing phosphorylation events on MCM-DH by Dbf4-dependent kinase and RIF1-Protein Phosphatase 1, which ultimately determine IZs and establish RT.

Project description:Replication origins in human cells form clusters ranging from tens to hundreds of kilobases called initiation zones (IZs), typically located in intergenic regions between active genes. On a larger megabase scale, chromosomes replicate in a temporally defined replication timing (RT) pattern, where euchromatic regions replicate early, and heterochromatic regions replicate late. Although the stochastic model of IZ firing with a temporally regulated limiting factor can explain RT formation, this limiting factor in human cells remains unclear. To investigate the relationship between IZ and RT, we mapped the temporal firing pattern of IZs and examined the genome-wide distributions of replication licensing and firing factors in human cells. We identified TRESLIN-MTBP as the key limiting firing factor for replication initiation. Its loading onto phosphorylated MCM2–7 double hexamer (MCM-DH) is controlled by the opposing phosphorylation events on MCM-DH by Dbf4-dependent kinase and RIF1-Protein Phosphatase 1, which ultimately determine IZs and establish RT.

Project description:Replication origins in human cells form clusters ranging from tens to hundreds of kilobases called initiation zones (IZs), typically located in intergenic regions between active genes. On a larger megabase scale, chromosomes replicate in a temporally defined replication timing (RT) pattern, where euchromatic regions replicate early, and heterochromatic regions replicate late. Although the stochastic model of IZ firing with a temporally regulated limiting factor can explain RT formation, this limiting factor in human cells remains unclear. To investigate the relationship between IZ and RT, we mapped the temporal firing pattern of IZs and examined the genome-wide distributions of replication licensing and firing factors in human cells. We identified TRESLIN-MTBP as the key limiting firing factor for replication initiation. Its loading onto phosphorylated MCM2–7 double hexamer (MCM-DH) is controlled by the opposing phosphorylation events on MCM-DH by Dbf4-dependent kinase and RIF1-Protein Phosphatase 1, which ultimately determine IZs and establish RT.

Project description:In eukaryotes, DNA replication initiation requires assembly and activation of the minichromosome maintenance (MCM) 2-7 double hexamer (DH) to melt origin DNA strands. However, the mechanism for this initial melting is unknown. Here, we report a 2.59-Å cryo-electron microscopy structure of the endogenously purified human MCM-DH (hMCM-DH), also known as the pre-replication complex. In this structure, the hMCM-DH shows a constricted central channel with a diameter of only 13 Å at the hexamer interface. This unusual conformation untwists and stretches the DNA strands such that almost a half turn of the bound duplex DNA is distorted with one-base pair completely separated, generating an initial open structure (IOS) at the hexamer junction. This IOS is captured and stabilized by zinc fingers (ZFs) of MCM2 and MCM5 from opposing hexamers. Disturbing the interaction between MCM5-ZF and the IOS demonstrably inhibits DH formation and replication initiation. High-resolution mapping of hMCM-DH footprints indicates that IOSs are distributed across the human genome in large clusters aligning perfectly with initiation zones to safeguard robust stochastic origin firing. This work unravels an intrinsic mechanism that couples DH formation with initial DNA melting to license replication initiation in human cells.

Project description:The spatio-temporal program of genome replication across eukaryotes is thought to be driven both by the uneven loading of pre-replication complexes (pre-RCs) across the genome at the onset of S-phase, and by differences in the timing of activation of these complexes during S-phase. To determine the degree to which distribution of pre-RC loading alone could account for chromosomal replication patterns, we mapped the binding sites of the Mcm2-7 helicase complex (MCM) in budding yeast, fission yeast, mouse and humans. We observed identical individual MCM double-hexamer (DH) footprints across the species, but notable differences in their distribution. Nonetheless, most fluctuations in replication timing in all four organisms could be accounted for by differences in chromosomal MCM distribution. We conclude that, although certain genomic regions, most notably the inactive X-chromosome, are subject to post-licensing regulation, most differences in replication timing along the chromosome reflect uneven chromosomal distribution of stochastically firing pre-replication complexes.

Project description:The mammalian DNA replication timing (RT) program is crucial for the proper functioning and integrity of the genome. The best-known mechanism for controlling RT is the suppression of late origins of replication in heterochromatin by RIF1. Here, we report that in antigen-activated, hypermutating B lymphocytes, RIF1 binds predominantly to early-replicating active chromatin, regulates early origin firing and promotes early replication. However, RIF1 has a minor role in gene expression and genome organization in B cells. Furthermore, we find that RIF1 functions in a complementary and non-epistatic manner with minichromosome maintenance (MCM) proteins to establish early RT signatures genome-wide and, specifically, to ensure the early replication of highly transcribed genes. These findings reveal a new layer of regulation within the B cell RT program, driven by the coordinated activity of RIF1 and MCM proteins.

Project description:The mammalian DNA replication timing (RT) program is crucial for the proper functioning and integrity of the genome. The best-known mechanism for controlling RT is the suppression of late origins of replication in heterochromatin by RIF1. Here, we report that in antigen-activated, hypermutating B lymphocytes, RIF1 binds predominantly to early-replicating active chromatin, regulates early origin firing and promotes early replication. However, RIF1 has a minor role in gene expression and genome organization in B cells. Furthermore, we find that RIF1 functions in a complementary and non-epistatic manner with minichromosome maintenance (MCM) proteins to establish early RT signatures genome-wide and, specifically, to ensure the early replication of highly transcribed genes. These findings reveal a new layer of regulation within the B cell RT program, driven by the coordinated activity of RIF1 and MCM proteins.

Project description:The mammalian DNA replication timing (RT) program is crucial for the proper functioning and integrity of the genome. The best-known mechanism for controlling RT is the suppression of late origins of replication in heterochromatin by RIF1. Here, we report that in antigen-activated, hypermutating B lymphocytes, RIF1 binds predominantly to early-replicating active chromatin, regulates early origin firing and promotes early replication. However, RIF1 has a minor role in gene expression and genome organization in B cells. Furthermore, we find that RIF1 functions in a complementary and non-epistatic manner with minichromosome maintenance (MCM) proteins to establish early RT signatures genome-wide and, specifically, to ensure the early replication of highly transcribed genes. These findings reveal a new layer of regulation within the B cell RT program, driven by the coordinated activity of RIF1 and MCM proteins.

Project description:The mammalian DNA replication timing (RT) program is crucial for the proper functioning and integrity of the genome. The best-known mechanism for controlling RT is the suppression of late origins of replication in heterochromatin by RIF1. Here, we report that in antigen-activated, hypermutating B lymphocytes, RIF1 binds predominantly to early-replicating active chromatin, regulates early origin firing and promotes early replication. However, RIF1 has a minor role in gene expression and genome organization in B cells. Furthermore, we find that RIF1 functions in a complementary and non-epistatic manner with minichromosome maintenance (MCM) proteins to establish early RT signatures genome-wide and, specifically, to ensure the early replication of highly transcribed genes. These findings reveal a new layer of regulation within the B cell RT program, driven by the coordinated activity of RIF1 and MCM proteins.

Project description:The mammalian DNA replication timing (RT) program is crucial for the proper functioning and integrity of the genome. The best-known mechanism for controlling RT is the suppression of late origins of replication in heterochromatin by RIF1. Here, we report that in antigen-activated, hypermutating B lymphocytes, RIF1 binds predominantly to early-replicating active chromatin, regulates early origin firing and promotes early replication. However, RIF1 has a minor role in gene expression and genome organization in B cells. Furthermore, we find that RIF1 functions in a complementary and non-epistatic manner with minichromosome maintenance (MCM) proteins to establish early RT signatures genome-wide and, specifically, to ensure the early replication of highly transcribed genes. These findings reveal a new layer of regulation within the B cell RT program, driven by the coordinated activity of RIF1 and MCM proteins.