scholarly journals The CMG helicase bypasses DNA protein cross-links to facilitate their repair

2018 ◽  
Author(s):  
Justin L. Sparks ◽  
Alan O. Gao ◽  
Markus Räschle ◽  
Nicolai B. Larsen ◽  
Matthias Mann ◽  
...  
Keyword(s):  
Replication Fork ◽  
Dna Helicase ◽  
Genome Integrity ◽  
Cross Link ◽  
Replication Fork Progression ◽  
Egg Extracts ◽  
Cross Links ◽  
Leading Strand ◽  
Nucleoprotein Complexes ◽  
Lagging Strand

SummaryCovalent and non-covalent nucleoprotein complexes impede replication fork progression and thereby threaten genome integrity. UsingXenopus laevisegg extracts, we previously showed that when a replication fork encounters a covalent DNA-protein cross-link (DPC) on the leading strand template, the DPC is degraded to a short peptide, allowing its bypass by translesion synthesis polymerases. Strikingly, we show here that when DPC proteolysis is blocked, the replicative DNA helicase (CMG), which travels on the leading strand template, still bypasses the intact DPC. The DNA helicase RTEL1 facilitates bypass, apparently by translocating along the lagging strand template and generating single-stranded DNA downstream of the DPC. Remarkably, RTEL1 is required for efficient DPC proteolysis, suggesting that CMG bypass of a DPC normally precedes its proteolysis. RTEL1 also promotes fork progression past non-covalent protein-DNA complexes. Our data suggest a unified model for the replisome’s response to nucleoprotein barriers.

scholarly journals Replisome bypass of transcription complexes and R-loops

2020 ◽  
Vol 48 (18) ◽  
pp. 10353-10367
Author(s):  
Jan-Gert Brüning ◽  
Kenneth J Marians
Keyword(s):  
Dna Replication ◽  
Replication Fork ◽  
Genome Instability ◽  
Bacterial Dna ◽  
Template Strand ◽  
Replication Fork Progression ◽  
Leading Strand ◽  
Fork Stalling ◽  
Transcription Complexes ◽  
Lagging Strand

Abstract The vast majority of the genome is transcribed by RNA polymerases. G+C-rich regions of the chromosomes and negative superhelicity can promote the invasion of the DNA by RNA to form R-loops, which have been shown to block DNA replication and promote genome instability. However, it is unclear whether the R-loops themselves are sufficient to cause this instability or if additional factors are required. We have investigated replisome collisions with transcription complexes and R-loops using a reconstituted bacterial DNA replication system. RNA polymerase transcription complexes co-directionally oriented with the replication fork were transient blockages, whereas those oriented head-on were severe, stable blockages. On the other hand, replisomes easily bypassed R-loops on either template strand. Replication encounters with R-loops on the leading-strand template (co-directional) resulted in gaps in the nascent leading strand, whereas lagging-strand template R-loops (head-on) had little impact on replication fork progression. We conclude that whereas R-loops alone can act as transient replication blocks, most genome-destabilizing replication fork stalling likely occurs because of proteins bound to the R-loops.

scholarly journals Single-molecule imaging reveals control of parental histone recycling by free histones during DNA replication

2020 ◽  
Vol 6 (38) ◽  
pp. eabc0330 ◽  
Author(s):  
D. T. Gruszka ◽  
S. Xie ◽  
H. Kimura ◽  
H. Yardimci
Keyword(s):  
Dna Replication ◽  
Real Time ◽  
Single Molecule ◽  
Replication Fork ◽  
Epigenetic Inheritance ◽  
Replication Forks ◽  
Replication Fork Progression ◽  
Egg Extracts ◽  
Fork Stalling ◽  
The Moment

During replication, nucleosomes are disrupted ahead of the replication fork, followed by their reassembly on daughter strands from the pool of recycled parental and new histones. However, because no previous studies have managed to capture the moment that replication forks encounter nucleosomes, the mechanism of recycling has remained unclear. Here, through real-time single-molecule visualization of replication fork progression in Xenopus egg extracts, we determine explicitly the outcome of fork collisions with nucleosomes. Most of the parental histones are evicted from the DNA, with histone recycling, nucleosome sliding, and replication fork stalling also occurring but at lower frequencies. Critically, we find that local histone recycling becomes dominant upon depletion of endogenous histones from extracts, revealing that free histone concentration is a key modulator of parental histone dynamics at the replication fork. The mechanistic details revealed by these studies have major implications for our understanding of epigenetic inheritance.

scholarly journals Basal CHK1 activity safeguards its stability to maintain intrinsic S-phase checkpoint functions

2019 ◽  
Vol 218 (9) ◽  
pp. 2865-2875 ◽  
Author(s):  
Jone Michelena ◽  
Marco Gatti ◽  
Federico Teloni ◽  
Ralph Imhof ◽  
Matthias Altmeyer
Keyword(s):  
Cell Proliferation ◽  
Steady State ◽  
Cell Survival ◽  
Replication Fork ◽  
S Phase ◽  
Genome Integrity ◽  
Replication Machinery ◽  
Replication Fork Progression ◽  
Steady State Activity ◽  
S Phase Checkpoint

The DNA replication machinery frequently encounters impediments that slow replication fork progression and threaten timely and error-free replication. The CHK1 protein kinase is essential to deal with replication stress (RS) and ensure genome integrity and cell survival, yet how basal levels and activity of CHK1 are maintained under physiological, unstressed conditions is not well understood. Here, we reveal that CHK1 stability is controlled by its steady-state activity during unchallenged cell proliferation. This autoactivatory mechanism, which depends on ATR and its coactivator ETAA1 and is tightly associated with CHK1 autophosphorylation at S296, counters CHK1 ubiquitylation and proteasomal degradation, thereby preventing attenuation of S-phase checkpoint functions and a compromised capacity to respond to RS. Based on these findings, we propose that steady-state CHK1 activity safeguards its stability to maintain intrinsic checkpoint functions and ensure genome integrity and cell survival.

scholarly journals Chromatin-associated degradation is defined by UBXN-3/FAF1 to safeguard DNA replication fork progression

2016 ◽  
Vol 7 (1) ◽  
Author(s):  
André Franz ◽  
Paul A. Pirson ◽  
Domenic Pilger ◽  
Swagata Halder ◽  
Divya Achuthankutty ◽  
...  
Keyword(s):  
Dna Replication ◽  
Dynamic Process ◽  
Metabolic Pathways ◽  
Replication Fork ◽  
Genome Instability ◽  
Genome Integrity ◽  
Substrate Selection ◽  
Replication Fork Progression ◽  
Replication Factors ◽  
Spatiotemporal Control

Abstract The coordinated activity of DNA replication factors is a highly dynamic process that involves ubiquitin-dependent regulation. In this context, the ubiquitin-directed ATPase CDC-48/p97 recently emerged as a key regulator of chromatin-associated degradation in several of the DNA metabolic pathways that assure genome integrity. However, the spatiotemporal control of distinct CDC-48/p97 substrates in the chromatin environment remained unclear. Here, we report that progression of the DNA replication fork is coordinated by UBXN-3/FAF1. UBXN-3/FAF1 binds to the licensing factor CDT-1 and additional ubiquitylated proteins, thus promoting CDC-48/p97-dependent turnover and disassembly of DNA replication factor complexes. Consequently, inactivation of UBXN-3/FAF1 stabilizes CDT-1 and CDC-45/GINS on chromatin, causing severe defects in replication fork dynamics accompanied by pronounced replication stress and eventually resulting in genome instability. Our work identifies a critical substrate selection module of CDC-48/p97 required for chromatin-associated protein degradation in both Caenorhabditis elegans and humans, which is relevant to oncogenesis and aging.

scholarly journals Mammalian CST averts replication failure by preventing G-quadruplex accumulation

2018 ◽  
Author(s):  
Yang Liu ◽  
Miaomiao Zhang ◽  
Bing Wang ◽  
Yingnan Xiao ◽  
Tingfang Li ◽  
...  
Keyword(s):  
Replication Fork ◽  
Genome Integrity ◽  
G4 Dna ◽  
Genome Wide ◽  
G Quadruplex ◽  
Preferential Loss ◽  
Telomere Replication ◽  
Lagging Strand

AbstractHuman CST (CTC1-STN1-TEN1) is an RPA-like complex that associates with G-rich single-strand DNA and helps resolve replication problems both at telomeres and genome-wide. We previously showed that CST binds and disrupts G-quadruplex (G4) DNA in vitro, suggesting that CST may prevent in vivo blocks to replication by resolving G4 structures. Here, we demonstrate that CST binds and unfolds G4 with similar efficiency to RPA. In cells, CST is recruited to telomeric and non-telomeric chromatin upon G4 stabilization. STN1 depletion increases G4 accumulation and slows bulk genomic DNA replication. At telomeres, combined STN1 depletion and G4 stabilization causes multi-telomere FISH signals and telomere loss, hallmarks of deficient telomere duplex replication. Strand-specific telomere FISH indicates preferential loss of C-strand DNA while analysis of BrdU uptake during leading and lagging-strand telomere replication shows preferential under-replication of lagging telomeres. Together these results indicate a block to Okazaki fragment synthesis. Overall, our findings indicate a novel role for CST in maintaining genome integrity through resolution of G4 structures both ahead of the replication fork and on the lagging strand template.

scholarly journals Replication dynamics of recombination-dependent replication forks

2020 ◽  
Author(s):  
Karel Naiman ◽  
Eduard Campillo-Funollet ◽  
Adam T. Watson ◽  
Alice Budden ◽  
Izumi Miyabe ◽  
...  
Keyword(s):  
Monte Carlo Simulation ◽  
Monte Carlo ◽  
Homologous Recombination ◽  
Replication Fork ◽  
S Phase ◽  
Replication Forks ◽  
Leading Strand ◽  
The Stability ◽  
Lagging Strand

AbstractDNA replication fidelity is essential for maintaining genetic stability. Forks arrested at replication fork barriers can be stabilised by the intra-S phase checkpoint, subsequently being rescued by a converging fork, or resuming when the barrier is removed. However, some arrested forks cannot be stabilised and fork convergence cannot rescue in all situations. Thus, cells have developed homologous recombination-dependent mechanisms to restart persistently inactive forks. To understand HR-restart we use polymerase usage sequencing to visualize in vivo replication dynamics at an S. pombe replication barrier, RTS1, and model replication by Monte Carlo simulation. We show that HR-restarted forks synthesise both strands with Pol δ for up to 30 kb without maturing to a δ/ε configuration and that Pol α is not used significantly on either strand, suggesting the lagging strand template remains as a gap that is filled in by Pol δ later. We further demonstrate that HR-restarted forks progress uninterrupted through a fork barrier that arrests canonical forks. Finally, by manipulating lagging strand resection during HR-restart by deleting pku70, we show that the leading strand initiates replication at the same position, signifying the stability of the 3’ single strand in the context of increased resection.

scholarly journals Structures and operating principles of the replisome

Science ◽  
2019 ◽  
Vol 363 (6429) ◽  
pp. eaav7003 ◽  
Author(s):  
Yang Gao ◽  
Yanxiang Cui ◽  
Tara Fox ◽  
Shiqiang Lin ◽  
Huaibin Wang ◽  
...  
Keyword(s):  
Replication Fork ◽  
Model System ◽  
Molecular Organization ◽  
Cryo Electron Microscopy ◽  
Adenosine Triphosphatases ◽  
Dna Strands ◽  
Leading Strand ◽  
Dna Strand ◽  
Aaa Atpases ◽  
Lagging Strand

Visualization in atomic detail of the replisome that performs concerted leading– and lagging–DNA strand synthesis at a replication fork has not been reported. Using bacteriophage T7 as a model system, we determined cryo–electron microscopy structures up to 3.2-angstroms resolution of helicase translocating along DNA and of helicase-polymerase-primase complexes engaging in synthesis of both DNA strands. Each domain of the spiral-shaped hexameric helicase translocates sequentially hand-over-hand along a single-stranded DNA coil, akin to the way AAA+ ATPases (adenosine triphosphatases) unfold peptides. Two lagging-strand polymerases are attached to the primase, ready for Okazaki fragment synthesis in tandem. A β hairpin from the leading-strand polymerase separates two parental DNA strands into a T-shaped fork, thus enabling the closely coupled helicase to advance perpendicular to the downstream DNA duplex. These structures reveal the molecular organization and operating principles of a replisome.

scholarly journals Yeast Genome Maintenance by the Multifunctional PIF1 DNA Helicase Family

Genes ◽  
2020 ◽  
Vol 11 (2) ◽  
pp. 224 ◽  
Author(s):  
Julius Muellner ◽  
Kristina H. Schmidt
Keyword(s):  
Cellular Response ◽  
Replication Fork ◽  
Strand Break ◽  
Dna Helicase ◽  
Yeast Cells ◽  
Genome Integrity ◽  
Yeast Genome ◽  
Functional Evaluation ◽  
Cellular Functions ◽  
Yeast Homolog

The two PIF1 family helicases in Saccharomyces cerevisiae, Rrm3, and ScPif1, associate with thousands of sites throughout the genome where they perform overlapping and distinct roles in telomere length maintenance, replication through non-histone proteins and G4 structures, lagging strand replication, replication fork convergence, the repair of DNA double-strand break ends, and transposable element mobility. ScPif1 and its fission yeast homolog Pfh1 also localize to mitochondria where they protect mitochondrial genome integrity. In addition to yeast serving as a model system for the rapid functional evaluation of human Pif1 variants, yeast cells lacking Rrm3 have proven useful for elucidating the cellular response to replication fork pausing at endogenous sites. Here, we review the increasingly important cellular functions of the yeast PIF1 helicases in maintaining genome integrity, and highlight recent advances in our understanding of their roles in facilitating fork progression through replisome barriers, their functional interactions with DNA repair, and replication stress response pathways.

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