Cycling of the E. coli lagging strand polymerase is triggered exclusively by the availability of a new primer at the replication fork

In vitro, purified replisomes drive model replication forks to synthesize continuous leading strands, even without ligase, supporting the semidiscontinuous model of DNA replication. However, nascent replication intermediates isolated from ligase-deficientEscherichia colicomprise only short (on average 1.2-kb) Okazaki fragments. It was long suspected that cells replicate their chromosomal DNA by the semidiscontinuous mode observed in vitro but that, in vivo, the nascent leading strand was artifactually fragmented postsynthesis by excision repair. Here, using high-resolution separation of pulse-labeled replication intermediates coupled with strand-specific hybridization, we show that excision-proficientE. coligenerates leading-strand intermediates >10-fold longer than lagging-strand Okazaki fragments. Inactivation of DNA-repair activities, including ribonucleotide excision, further increased nascent leading-strand size to ∼80 kb, while lagging-strand Okazaki fragments remained unaffected. We conclude that in vivo, repriming occurs ∼70× less frequently on the leading versus lagging strands, and that DNA replication inE. coliis effectively semidiscontinuous.

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Oligodeoxynucleotide Binding to (CTG) · (CAG) Microsatellite Repeats Inhibits Replication Fork Stalling, Hairpin Formation, and Genome Instability

Molecular and Cellular Biology ◽

10.1128/mcb.01265-12 ◽

2012 ◽

Vol 33 (3) ◽

pp. 571-581 ◽

Cited By ~ 13

Author(s):

Guoqi Liu ◽

Xiaomi Chen ◽

Michael Leffak

Keyword(s):

Replication Fork ◽

Trinucleotide Repeat ◽

Cell Model ◽

Replication Stress ◽

Dna Hairpin ◽

Replication Fork Stalling ◽

Fork Stalling ◽

Hairpin Formation ◽

Lagging Strand

ABSTRACT(CTG)n· (CAG)ntrinucleotide repeat (TNR) expansion in the 3′ untranslated region of the dystrophia myotonica protein kinase (DMPK) gene causes myotonic dystrophy type 1. However, a direct link between TNR instability, the formation of noncanonical (CTG)n· (CAG)nstructures, and replication stress has not been demonstrated. In a human cell model, we found that (CTG)45· (CAG)45causes local replication fork stalling, DNA hairpin formation, and TNR instability. Oligodeoxynucleotides (ODNs) complementary to the (CTG)45· (CAG)45lagging-strand template eliminated DNA hairpin formation on leading- and lagging-strand templates and relieved fork stalling. Prolonged cell culture, emetine inhibition of lagging-strand synthesis, or slowing of DNA synthesis by low-dose aphidicolin induced (CTG)45· (CAG)45expansions and contractions. ODNs targeting the lagging-strand template blocked the time-dependent or emetine-induced instability but did not eliminate aphidicolin-induced instability. These results show directly that TNR replication stalling, replication stress, hairpin formation, and instability are mechanistically linkedin vivo.

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Lagging Strand DNA Synthesis at the Eukaryotic Replication Fork Involves Binding and Stimulation of FEN-1 by Proliferating Cell Nuclear Antigen

Journal of Biological Chemistry ◽

10.1074/jbc.270.38.22109 ◽

1995 ◽

Vol 270 (38) ◽

pp. 22109-22112 ◽

Cited By ~ 184

Author(s):

Xiangyang Li ◽

Jun Li ◽

John Harrington ◽

Michael R. Lieber ◽

Peter M. J. Burgers

Keyword(s):

Dna Synthesis ◽

Proliferating Cell Nuclear Antigen ◽

Replication Fork ◽

Nuclear Antigen ◽

Proliferating Cell ◽

Lagging Strand ◽

Stimulation Of

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Mammalian CST averts replication failure by preventing G-quadruplex accumulation

10.1101/354050 ◽

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.

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The molecular coupling between substrate recognition and ATP turnover in a AAA+ hexameric helicase loader

eLife ◽

10.7554/elife.64232 ◽

2021 ◽

Vol 10 ◽

Author(s):

Neha Puri ◽

Amy J Fernandez ◽

Valerie L O'Shea Murray ◽

Sarah McMillan ◽

James L Keck ◽

...

Keyword(s):

Replication Fork ◽

Substrate Recognition ◽

Dna Unwinding ◽

Replicative Helicase ◽

E Coli ◽

Helicase Loading ◽

Dnab Helicase ◽

Replication Restart ◽

Clamp Loading ◽

Aaa Atpases

In many bacteria and in eukaryotes, replication fork establishment requires the controlled loading of hexameric, ring-shaped helicases around DNA by AAA+ ATPases. How loading factors use ATP to control helicase deposition is poorly understood. Here, we dissect how specific ATPase elements of E. coli DnaC, an archetypal loader for the bacterial DnaB helicase, play distinct roles in helicase loading and the activation of DNA unwinding. We identify a new element, the arginine-coupler, which regulates the switch-like behavior of DnaC to prevent futile ATPase cycling and maintains loader responsiveness to replication restart systems. Our data help explain how the ATPase cycle of a AAA+-family helicase loader is channeled into productive action on its target; comparative studies indicate elements analogous to the Arg-coupler are present in related, switch-like AAA+ proteins that control replicative helicase loading in eukaryotes, as well as polymerase clamp loading and certain classes of DNA transposases.

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

10.1101/381582 ◽

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.

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Replication dynamics of recombination-dependent replication forks

10.1101/2020.07.03.186676 ◽

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.

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