Project description:Faithful duplication of DNA is essential for the maintenance of genomic stability in all organisms. DNA synthesis proceeds bi-directionally with continuous synthesis of leading strand DNA and discontinuous synthesis of lagging strand DNA. Herein, we describe a method of enriching and Sequencing of Protein-Associated Nascent strand DNA (eSPAN) to detect whether a protein binds the leading- and lagging-strands of DNA replication forks. We show that Pol-epsilon, PCNA, Cdc45, Mcm6 and Mcm10 preferentially associate with leading strands, whereas Pol-alpha, Pol32, Pol-delta, Rfa1 and Rfc1 associate with lagging strands of hydroxyurea (HU)-stalled replication forks. In contrast, PCNA is enriched at lagging strands of normal replication forks in wild type cells and HU-stalled forks in cells lacking Elg1. These studies demonstrate a strategy to reveal proteins at leading and lagging strands of DNA replication forks, and suggest that the unloading of PCNA from lagging strands of HU-stalled replication forks helps maintain genome integrity. We synchronized yeast cells at G1 and released into early S phase in the presence of BrdU, a nucleotide analog that can be incorporated into newly synthesized DNA strand, and hydroxyurea (HU), a ribonucleotide reductase inhibitor. HU has no effect on initiation of DNA replication at early replication origins, but inhibit late replication firing. In addition, replication forks are stalled due to depletion of dNTPs. We then performed chromatin-immunoprecipitation of 12 proteins of interest following a standard procedure. Protein-bound DNAs were then reverse-crosslinked and double strand DNA was denatured. Nascent DNA was enriched by immunoprecipitation using anti-BrdU antibodies. The recovered ssDNA was first marked with ligation to one oligo at 3M-bM-^@M-^Y end before conversion to dsDNA for library preparation and sequencing. In this way, the directionality of ssDNA and therefore strand information of each sequenced DNA were known. The sequencing tag was mapped to both Watson (red) and Crick (blue) strands of the reference genome. In addition to ChIP-eSPAN, we also performed BrdU-IP and single strand DNA sequence (BrdU-ssSeq) and protein ChIP followed by single-strand DNA sequencing (ChIP-ssSeq) for each corresponding ChIP-eSPAN experiment. We also performed Mcm4 and Mcm6 ChIP-seq using cells synchronized at G1 phase of the cell cycle for identification of replication origins in comparison with published dataset. Some protein ChIP-ssSeq and ChIP-eSPAN experiments were repeated and the data fits well each other. Therefore, we did not repeat all protein ChIP-ssSeq and ChIP-eSPAN experiments.

Project description:How parental histone H3-H4 tetramers, the primary carrier of epigenetic modifications, are transferred to leading and lagging strands of DNA replication forks following DNA replication is an important question that remains not well understood. Here we show that DNA polymerase clamp PCNA and its partner involved in lagging strand DNA synthesis, Pol d, regulate parental histone transfer to lagging strands. Mutations at PCNA as well as at subunits of Pol d that impair the PCNA-Pol d interaction affect parental histone transfer to lagging strands, and this defect unlikely arises from their impacts on DNA synthesis. Moreover, Pol d interacts with H3-H4 in vitro. We suggest that the PCNA-Pol d complex, best known for its role in lagging strand DNA synthesis and DNA repair, couples lagging strand DNA synthesis to the transfer of the parental histones H3-H4 for the inheritance of chromatin structures following DNA replication and possibly DNA repair.

Project description:Although essential for epigenetic inheritance, the transfer of parental histone (H3-H4)2 tetramers that contain epigenetic modifications to replicating DNA strands is poorly understood. Here, we show that the Mcm2-Ctf4-Pol axis facilitates the transfer of parental (H3-H4)2 tetramers to lagging strands of DNA replication forks. Mutating the H3-H4 binding domain of Mcm2, a subunit of the CMG (Cdc45-MCM-GINS) replicative helicase that translocates along leading strands, impairs the transfer of parental (H3-H4)2 to lagging strands. Similar effects are observed in Ctf4 and Pol-primase mutants that disrupt the connection of the CMG helicase via Ctf4-Pol to lagging strands. Our results support a model whereby parental (H3-H4)2 displaced from nucleosomes through leading-strand DNA replication are transferred to lagging strands for nucleosome assembly via the CMG-Ctf4-Pol complex.

Project description:The tolerance pathway allows bypassing deleterious lesions that block replicative DNA polymerases. In eukaryotes tolerance is controlled by ubiquitylation of the DNA replication factor PCNA4. Here, we show that PCNAK164-ubiquitin proteases (PCNA-DUBs) Ubp10 and Ubp12 localise to replication forks. In particular, the main PCNA-DUB, Ubp10, associates primarily to nascent lagging strands. We also found that cells deficient for PCNA deubiquitylation show both increased interaction of TLS polymerase ζ-associated Rev1 with lagging strands and Rad52-dependent template switching events. This evidence reveals a fork-coupled layer of DDT regulation allowing strand-specific pathway choices.

Project description:In eukaryotic cells, inheritable changes in gene expression in response to environmental and developmental stimuli is associated with changes in histone modifications and relies on the passage of these changes into daughter cells during cell division, a process that remains elusive. Here, we show that parental histone (H3-H4)2 tetramers, the primary carrier of epigenetic modifications, are assembled into nucleosomes onto both replicating leading and lagging strands, with a preference for lagging strands of DNA replication forks. This asymmetric distribution of parental (H3-H4)2 is exacerbated in cells lacking Dpb3 and Dpb4, two subunits of DNA polymerase Pol ε. Dpb3-Dpb4 binds (H3-H4)2 and participates in the transfer of parental (H3-H4)2 tetramers onto leading strands of DNA replication forks. Cells lacking Dpb3 and Dpb4 exhibits defects in epigenetic inheritance. These results reveal a previously undocumented mechanism of histone segregation and a direct role for Pol ε in this poorly understood process.

Project description:During every cell cycle, both the genome and the associated chromatin must be accurately replicated. Chromatin Assembly Factor-1 (CAF-1) is a key regulator of chromatin replication, but how CAF-1 functions in relation to the DNA replication machinery is unknown. Here, we reveal that this crosstalk differs between the leading and lagging strand at replication forks. Using biochemical reconstitution, we show that DNA and histones promote CAF-1 recruitment to its binding partner PCNA and reveal that two CAF-1 complexes are required for efficient nucleosome assembly under these conditions. Remarkably, in the context of the replisome, CAF-1 competes with the leading strand DNA polymerase epsilon (Pole) for PCNA binding. However, CAF-1 does not affect the activity of the lagging strand DNA polymerase Delta (Pold). Yet, in cells, CAF-1 deposits newly synthesized histones equally on both daughter strands. Thus, on the leading strand, chromatin assembly by CAF-1 cannot occur simultaneously to DNA synthesis, while on the lagging strand these processes may be coupled. We propose that these differences may facilitate distinct parental histone recycling mechanisms and accommodate the inherent asymmetry of DNA replication.

Project description:ATP-dependent chromatin remodeling complexes have been shown to participate in DNA replication in addition to transcription and DNA repair. However, the mechanisms of their involvement in DNA replication remain unclear. Here, we reveal a specific function of the yeast INO80 chromatin remodeling complex in the DNA damage tolerance pathways. Whereas INO80 is necessary for the resumption of replication at forks stalled by methyl methane sulfonate (MMS), it is not required for replication fork collapse after treatment with hydroxyurea (HU). Mechanistically, INO80 regulates DNA damage tolerance during replication through modulation of PCNA (proliferating cell nuclear antigen) ubiquitination and Rad51-mediated processing of recombination intermediates at impeded replication forks. Our findings establish a mechanistic link between INO80 and DNA damage tolerance pathways, indicating that chromatin remodeling is important for accurate DNA replication. INO80 distribution in WT cells was measured.

Project description:Analysis of PCNA levels at stalled Saccharomyces cerevisiae replication forks upon Replication Factor C (RFC) Removal Analysis of nascent DNA incorporation at progressing Saccharomyces cerevisiae replication forks upon Rfc1 depletion

Project description:In response to DNA replication stress, DNA replication checkpoint is activated to maintain fork stability, a process critical for maintenance of genome stability. However, how DNA replication checkpoint regulates replication forks remain elusive. Here we show that Rad53, a highly conserved replication checkpoint kinase, functions to couple leading and lagging strand DNA synthesis. In wild type cells under HU induced replication stress, synthesis of lagging strand, which contains ssDNA gaps, is comparable to leading strand DNA. In contrast, synthesis of lagging strand is much more than leading strand, and consequently, leading template ssDNA coated with ssDNA binding protein RPA was detected in rad53-1 mutant cells, suggesting that synthesis of leading strand and lagging strand DNA is uncoupled. Mechanistically, we show that replicative helicase MCM and leading strand DNA polymerase Pole move beyond actual DNA synthesis and that an increase in dNTP pools largely suppresses the uncoupled leading and lagging strand DNA synthesis. Our studies reveal an unexpected mechanism whereby Rad53 regulates replication fork stability.

Project description:During DNA replication, histones in nucleosomes ahead of DNA replication forks are evicted and then distributed equally onto leading and lagging strands. Mcm2, a subunit of the replicative MCM helicase, participates in the transfer of parental H3-H4 marked by H3K4me3 to lagging strands. Mutations in Mcm2 (Mcm2-3A) result in enrichment of H3K4me3 at leading strands following DNA replication. Here, we show that mcm2-3A mutant cells partially recover the H3K4me3 lost at lagging strands, with a faster recovery at highly transcribed genes than lowly ones, before mitosis. Furthermore, the H3K4 methyltransferase complex COMPASS is essential in the recovery of H3K4me3, irrespective of transcription status. Finally, H3K4me3 recognition (read) by COMPASS is also important for the restoration (write) of this mark. We suggest that both gene transcription and the “read and write” mechanism contribute to the restoration of H3K4me3, with the later mechanism more important for lowly transcribed chromatin.