scholarly journals Uncoupling of the replicative helicase induces nascent strand degradation and replication fork remodeling

2021 ◽  
Vol 35 (S1) ◽  
Author(s):  
James Dewar ◽  
Tamar Kavlashvili
Keyword(s):  
Replication Fork ◽  
Replicative Helicase

scholarly journals Replication fork stalling elicits chromatin compaction for the stability of stalling replication forks

2019 ◽  
Vol 116 (29) ◽  
pp. 14563-14572 ◽  
Author(s):  
Gang Feng ◽  
Yue Yuan ◽  
Zeyang Li ◽  
Lu Wang ◽  
Bo Zhang ◽  
...  
Keyword(s):  
Replication Fork ◽  
Cellular Mechanism ◽  
Eukaryotic Cells ◽  
Replication Forks ◽  
Physical Separation ◽  
Replicative Helicase ◽  
Chromatin Compaction ◽  
Acetylation Site ◽  
Fork Stalling ◽  
The Stability

DNA replication forks in eukaryotic cells stall at a variety of replication barriers. Stalling forks require strict cellular regulations to prevent fork collapse. However, the mechanism underlying these cellular regulations is poorly understood. In this study, a cellular mechanism was uncovered that regulates chromatin structures to stabilize stalling forks. When replication forks stall, H2BK33, a newly identified acetylation site, is deacetylated and H3K9 trimethylated in the nucleosomes surrounding stalling forks, which results in chromatin compaction around forks. Acetylation-mimic H2BK33Q and its deacetylase clr6-1 mutations compromise this fork stalling-induced chromatin compaction, cause physical separation of replicative helicase and DNA polymerases, and significantly increase the frequency of stalling fork collapse. Furthermore, this fork stalling-induced H2BK33 deacetylation is independent of checkpoint. In summary, these results suggest that eukaryotic cells have developed a cellular mechanism that stabilizes stalling forks by targeting nucleosomes and inducing chromatin compaction around stalling forks. This mechanism is named the “Chromsfork” control: Chromatin Compaction Stabilizes Stalling Replication Forks.

scholarly journals Unwinding 20 Years of the Archaeal Minichromosome Maintenance Helicase

2020 ◽  
Vol 202 (6) ◽  
Author(s):  
Lori M. Kelman ◽  
William B. O’Dell ◽  
Zvi Kelman
Keyword(s):  
Dna Replication ◽  
Replication Fork ◽  
Duplex Dna ◽  
Chromosomal Dna ◽  
Minichromosome Maintenance ◽  
Replicative Helicase ◽  
Dna Helicases ◽  
First Report ◽  
20Th Anniversary

ABSTRACT Replicative DNA helicases are essential cellular enzymes that unwind duplex DNA in front of the replication fork during chromosomal DNA replication. Replicative helicases were discovered, beginning in the 1970s, in bacteria, bacteriophages, viruses, and eukarya, and, in the mid-1990s, in archaea. This year marks the 20th anniversary of the first report on the archaeal replicative helicase, the minichromosome maintenance (MCM) protein. This minireview summarizes 2 decades of work on the archaeal MCM.

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

eLife ◽  
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.

scholarly journals Mechanism of RPA-Facilitated Processive DNA Unwinding by the Eukaryotic CMG Helicase

2019 ◽  
Author(s):  
Hazal B. Kose ◽  
Sherry Xie ◽  
George Cameron ◽  
Melania S. Strycharska ◽  
Hasan Yardimci
Keyword(s):  
Single Molecule ◽  
Replication Fork ◽  
Double Helix ◽  
Dna Unwinding ◽  
Helicase Activity ◽  
Replicative Helicase ◽  
Double Stranded Dna ◽  
Order Of Magnitude ◽  
Dna Strand ◽  
Dna Double Helix

AbstractThe DNA double helix is unwound by the Cdc45/Mcm2-7/GINS (CMG) complex at the eukaryotic replication fork. While isolated CMG unwinds duplex DNA very slowly, its fork unwinding rate is stimulated by an order of magnitude by single-stranded DNA binding protein, RPA. However, the molecular mechanism by which RPA enhances CMG helicase activity remained elusive. Here, we demonstrate that engagement of CMG with parental double-stranded DNA (dsDNA) at the replication fork impairs its helicase activity, explaining the slow DNA unwinding by isolated CMG. Using single-molecule and ensemble biochemistry, we show that binding of RPA to the excluded DNA strand prevents duplex engagement by the helicase and speeds up CMG-mediated DNA unwinding. When stalled due to dsDNA interaction, DNA rezipping-induced helicase backtracking re-establishes productive helicase-fork engagement underscoring the significance of plasticity in helicase action. Together, our results elucidate the dynamics of CMG at the replication fork and reveal how other replisome components can mediate proper DNA engagement by the replicative helicase to achieve efficient fork progression.

scholarly journals Replication Fork Uncoupling Causes Nascent Strand Degradation and Fork Reversal

2021 ◽  
Author(s):  
Tamar Kavlashvili ◽  
James M Dewar
Keyword(s):  
Dna Replication ◽  
Replication Fork ◽  
Genome Stability ◽  
Replicative Helicase ◽  
Before And After ◽  
Egg Extracts ◽  
Xenopus Egg ◽  
Biochemical Approach ◽  
Key Steps ◽  
Xenopus Egg Extracts

Genotoxins cause nascent strand degradation (NSD) and fork reversal during DNA replication. NSD and fork reversal are crucial for genome stability and exploited by chemotherapeutic approaches. However, it is unclear how NSD and fork reversal are triggered. Additionally, the fate of the replicative helicase during these processes is unknown. We developed a biochemical approach to study synchronous, localized NSD and fork reversal using Xenopus egg extracts. We show that replication fork uncoupling stimulates NSD of both nascent strands and progressive conversion of uncoupled forks to reversed forks. The replicative helicase remains bound during NSD and fork reversal, indicating that both processes take place behind the helicase. Unexpectedly, NSD occurs before and after fork reversal, indicating that multiple degradation steps take place. Overall, our data show that uncoupling causes NSD and fork reversal and identify key steps involved in these processes.

Structure and function of the GINS complex, a key component of the eukaryotic replisome

2010 ◽  
Vol 425 (3) ◽  
pp. 489-500 ◽  
Author(s):  
Stuart A. MacNeill
Keyword(s):  
Replication Fork ◽  
Biochemical Analysis ◽  
Current Knowledge ◽  
Chromosomal Dna ◽  
Minichromosome Maintenance ◽  
Replication Process ◽  
Replicative Helicase ◽  
Cellular Life ◽  
Mcm Helicase ◽  
And Function

High-fidelity chromosomal DNA replication is fundamental to all forms of cellular life and requires the complex interplay of a wide variety of essential and non-essential protein factors in a spatially and temporally co-ordinated manner. In eukaryotes, the GINS complex (from the Japanese go-ichi-ni-san meaning 5-1-2-3, after the four related subunits of the complex Sld5, Psf1, Psf2 and Psf3) was recently identified as a novel factor essential for both the initiation and elongation stages of the replication process. Biochemical analysis has placed GINS at the heart of the eukaryotic replication apparatus as a component of the CMG [Cdc45–MCM (minichromosome maintenance) helicase–GINS] complex that most likely serves as the replicative helicase, unwinding duplex DNA ahead of the moving replication fork. GINS homologues are found in the archaea and have been shown to interact directly with the MCM helicase and with primase, suggesting a central role for the complex in archaeal chromosome replication also. The present review summarizes current knowledge of the structure, function and evolution of the GINS complex in eukaryotes and archaea, discusses possible functions of the GINS complex and highlights recent results that point to possible regulation of GINS function in response to DNA damage.

Strand Specificity in the Interactions ofEscherichia coliPrimary Replicative Helicase DnaB Protein with a Replication Fork†

Biochemistry ◽  
1997 ◽  
Vol 36 (33) ◽  
pp. 10320-10326 ◽  
Author(s):  
Maria J. Jezewska ◽  
Surendran Rajendran ◽  
Wlodzimierz Bujalowski
Keyword(s):  
Replication Fork ◽  
Replicative Helicase ◽  
Helicase Dnab

scholarly journals p97 Promotes a Conserved Mechanism of Helicase Unloading during DNA Cross-Link Repair

2016 ◽  
Vol 36 (23) ◽  
pp. 2983-2994 ◽  
Author(s):  
George Fullbright ◽  
Halley B. Rycenga ◽  
Jordon D. Gruber ◽  
David T. Long
Keyword(s):  
Replication Fork ◽  
Critical Role ◽  
Dna Lesions ◽  
Cross Link ◽  
Replicative Helicase ◽  
Cellular Events ◽  
Damage Response ◽  
Independent Mechanism ◽  
Interstrand Cross Links ◽  
Cross Links

Interstrand cross-links (ICLs) are extremely toxic DNA lesions that create an impassable roadblock to DNA replication. When a replication fork collides with an ICL, it triggers a damage response that promotes multiple DNA processing events required to excise the cross-link from chromatin and resolve the stalled replication fork. One of the first steps in this process involves displacement of the CMG replicative helicase (comprised of Cdc45, MCM2-7, and GINS), which obstructs the underlying cross-link. Here we report that the p97/Cdc48/VCP segregase plays a critical role in ICL repair by unloading the CMG complex from chromatin. Eviction of the stalled helicase involves K48-linked polyubiquitylation of MCM7, p97-mediated extraction of CMG, and a largely degradation-independent mechanism of MCM7 deubiquitylation. Our results show that ICL repair and replication termination both utilize a similar mechanism to displace the CMG complex from chromatin. However, unlike termination, repair-mediated helicase unloading involves the tumor suppressor protein BRCA1, which acts upstream of MCM7 ubiquitylation and p97 recruitment. Together, these findings indicate that p97 plays a conserved role in dismantling the CMG helicase complex during different cellular events, but that distinct regulatory signals ultimately control when and where unloading takes place.

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