Your search keyword '"Replisome"' showing total 1,903 results

1. Functional and structural investigations of human replisomes assembled from purified proteins

Author

Bariş, Yasemin and Yeeles, Joseph T. P.

Subjects

DNA replication, Replisome, DNA, CMG, biochemical reconstitution

Abstract

DNA replication is a fundamental biological process for the transmission of genetic information from one generation of cells to the next in each cell division. Errors or abnormalities during replication can lead to mutations and genome instability, which is a hallmark of cancer. The complex and highly regulated molecular machinery responsible for an accurate and efficient replication is known as the replisome. At the heart of the eukaryotic replisome is the CMG (CDC45-MCM-GINS) helicase that unwinds the parental DNA duplex to generate single-stranded DNA for initiation of DNA synthesis by Pol α -primase and the replication of both strands by the replicative polymerases Pol ε and Pol δ. Replisomes contain multiple additional proteins including AND-1, CLASPIN and TIMELESS-TIPIN that function in replication and various replication-coupled processes. Biochemical reconstitution of DNA replication is a powerful approach to study the mechanism and structures of replisomes. Reconstitution of functional budding yeast replisomes has uncovered important aspects of the eukaryotic replication machinery including how the replisome achieves rapid DNA replication, how it responds DNA damage and how it navigates chromatin. Despite the significance of biochemical reconstitution and the critical importance of replication in human cells, an *in vitro* DNA replication system that utilises purified human proteins has not been established. Here, by developing the first *in vitro* human DNA replication system, I have investigated the requirements for efficient leading and lagging strand replication. Importantly, this system has enabled me to address the functions of several replisomes components in human DNA replication in isolation. In addition, reconstitution of functional human replisomes resulted in collaborative work that succeeded in determining the cryo-EM structure of a human replisome comprising CMG, TIMELESS-TIPIN, AND-1 and Pol ε bound to replication fork DNA. Here, we showed that how TIMELESS-TIPIN, AND-1 and Pol ε associate with CMG and provided structural insights into human replisome organisation. Finally, I have discussed the applications of the *in vitro* human DNA replication system.

Published

2023

2. DNA Methylation and RNA-DNA Hybrids Regulate the Single-Molecule Localization of a DNA Methyltransferase on the Bacterial Nucleoid.

Author

Fernandez, Nicolas, Chen, Ziyuan, Fuller, David, van Gijtenbeek, Lieke, Nye, Taylor, Biteen, Julie, and Simmons, Lyle

Subjects

Bacillus subtilis, epigenetic, replisome, restriction modification, superresolution microscopy, Methyltransferases, DNA Methylation, RNA, DNA, Bacterial, DNA Restriction-Modification Enzymes, Bacteriophages

Abstract

Bacterial DNA methyltransferases (MTases) function in restriction modification systems, cell cycle control, and the regulation of gene expression. DnmA is a recently described DNA MTase that forms N6-methyladenosine at nonpalindromic 5-GACGAG-3 sites in Bacillus subtilis, yet how DnmA activity is regulated is unknown. To address DnmA regulation, we tested substrate binding in vitro and found that DnmA binds poorly to methylated DNA and to an RNA-DNA hybrid with the DNA recognition sequence. Further, DnmA variants with amino acid substitutions that disrupt cognate sequence recognition or catalysis also bind poorly to DNA. Using superresolution fluorescence microscopy and single-molecule tracking of DnmA-PAmCherry, we characterized the subcellular DnmA diffusion and detected its preferential localization to the replisome region and the nucleoid. Under conditions where the chromosome is highly methylated, upon RNA-DNA hybrid accumulation, or with a DnmA variant with severely limited DNA binding activity, DnmA is excluded from the nucleoid, demonstrating that prior methylation or accumulation of RNA-DNA hybrids regulates the association of DnmA with the chromosome in vivo. Furthermore, despite the high percentage of methylated recognition sites and the proximity to putative endonuclease genes conserved across bacterial species, we find that DnmA fails to protect B. subtilis against phage predation, suggesting that DnmA is functionally an orphan MTase involved in regulating gene expression. Our work explores the regulation of a bacterial DNA MTase and identifies prior methylation and RNA-DNA hybrids as regulators of MTase localization. These MTase regulatory features could be common across biology. IMPORTANCE DNA methyltransferases (MTases) influence gene expression, cell cycle control, and host defense through DNA modification. Predicted MTases are pervasive across bacterial genomes, but the vast majority remain uncharacterized. Here, we show that in the soil microorganism Bacillus subtilis, the DNA MTase dnmA and neighboring genes are remnants of a phage defense system that no longer protects against phage predation. This result suggests that portions of the bacterial methylome may originate from inactive restriction modification systems that have maintained methylation activity. Analysis of DnmA movement in vivo shows that active DnmA localizes in the nucleoid, suggesting that DnmA can search for recognition sequences throughout the nucleoid region with some preference for the replisome. Our results further show that prior DNA methylation and RNA-DNA hybrids regulate DnmA dynamics and nucleoid localization, providing new insight into how DNA methylation is coordinated within the cellular environment.

Published

2023

3. Targeting of essential mycobacterial replication enzyme DnaG primase revealed Mitoxantrone and Vapreotide as novel mycobacterial growth inhibitors**.

Author

Ali, Waseem, Jamal, Salma, Gangwar, Rishabh, Ahmed, Faraz, Sharma, Rahul, Agarwal, Meetu, Sheikh, Javaid Ahmad, Grover, Abhinav, and Grover, Sonam

Subjects

MITOXANTRONE, DEATH rate, TARGETED drug delivery, DYNAMIC simulation

Abstract

Tuberculosis (TB) is the second leading cause of mortality after COVID‐19, with a global death toll of 1.6 million in 2021. The escalating situation of drug‐resistant forms of TB has threatened the current TB management strategies. New therapeutics with novel mechanisms of action are urgently required to address the current global TB crisis. The essential mycobacterial primase DnaG with no structural homology to homo sapiens presents itself as a good candidate for drug targeting. In the present study, Mitoxantrone and Vapreotide, two FDA‐approved drugs, were identified as potential anti‐mycobacterial agents. Both Mitoxantrone and Vapreotide exhibit a strong Minimum Inhibitory Concentration (MIC) of ≤25μg/ml against both the virulent (M.tb‐H37Rv) and avirulent (M.tb‐H37Ra) strains of M.tb. Extending the validations further revealed the inhibitory potential drugs in ex vivo conditions. Leveraging the computational high‐throughput multi‐level docking procedures from the pool of ~2700 FDA‐approved compounds, Mitoxantrone and Vapreotide were screened out as potential inhibitors of DnaG. Extensive 200 ns long all‐atoms molecular dynamic simulation of DnaGDrugs complexes revealed that both drugs bind strongly and stabilize the DnaG during simulations. Reduced solvent exposure and confined motions of the active centre of DnaG upon complexation with drugs indicated that both drugs led to the closure of the active site of DnaG. From this study's findings, we propose Mitoxantrone and Vapreotide as potential anti‐mycobacterial agents, with their novel mechanism of action against mycobacterial DnaG. [ABSTRACT FROM AUTHOR]

Published

2024

4. Direct visualization of translesion DNA synthesis polymerase IV at the replisome

Author

Tuan, Pham Minh, Gilhooly, Neville S, Marians, Kenneth J, and Kowalczykowski, Stephen C

Subjects

Biochemistry and Cell Biology, Physical Sciences, Biological Sciences, Genetics, DNA, DNA Polymerase III, DNA Polymerase beta, DNA-Directed DNA Polymerase, Holoenzymes, DNA repair, DNA replication, replisome, single-molecule visualization, translesion DNA synthesis

Abstract

In bacterial cells, DNA damage tolerance is manifested by the action of translesion DNA polymerases that can synthesize DNA across template lesions that typically block the replicative DNA polymerase III. It has been suggested that one of these translesion DNA synthesis DNA polymerases, DNA polymerase IV, can either act in concert with the replisome, switching places on the β sliding clamp with DNA polymerase III to bypass the template damage, or act subsequent to the replisome skipping over the template lesion in the gap in nascent DNA left behind as the replisome continues downstream. Evidence exists in support of both mechanisms. Using single-molecule analyses, we show that DNA polymerase IV associates with the replisome in a concentration-dependent manner and remains associated over long stretches of replication fork progression under unstressed conditions. This association slows the replisome, requires DNA polymerase IV binding to the β clamp but not its catalytic activity, and is reinforced by the presence of the γ subunit of the β clamp-loading DnaX complex in the DNA polymerase III holoenzyme. Thus, DNA damage is not required for association of DNA polymerase IV with the replisome. We suggest that under stress conditions such as induction of the SOS response, the association of DNA polymerase IV with the replisome provides both a surveillance/bypass mechanism and a means to slow replication fork progression, thereby reducing the frequency of collisions with template damage and the overall mutagenic potential.

Published

2022

5. Deciphering the molecular functionality of Cdc45 in replisomal complex

Author

Arathi Radhakrishnan, Chandresh Sharma, Viveka Nand Malviya, and Rajpal Srivastav

Subjects

DHH superfamily, Cdc45, Replisome, DNA replication, Genomic integrity, Biology (General), QH301-705.5, Biochemistry, QD415-436

Abstract

The members of DHH superfamily have been reported with diverse substrate spectrum and play pivotal roles in replication, repair, and RNA metabolism. This family comprises phosphatases, phosphoesterase and bifunctional enzymes having nanoRNase and phosphatase activities. Cell cycle factor Cdc45, a member of this superfamily, is crucial for movement of the replication fork during DNA replication and an important component of the replisome. The specific protein-protein interactions of Cdc45 with other factors along with helicase moderate the faithful DNA replication process. However, the exact biochemical functions of this factor are still unknown and need further investigation. Here, we studied the biochemical roles of Cdc45 and its molecular interactions within the replisomal complex. The alteration in the level of protein, observed when DNA damage is induced in-vivo, suggests its association with DNA replication stress. We analyzed protein Cdc45, providing new insights about the molecular and biochemical functionality of this replisomal factor.

Published

2024

6. The Response of the Replication Apparatus to Leading Template Strand Blocks.

Author

Bellani, Marina A., Shaik, Althaf, Majumdar, Ishani, Ling, Chen, and Seidman, Michael M.

Subjects

*DNA adducts, *DNA denaturation, *DNA replication, *DNA polymerases, *REPLISOMES, *DNA helicases

Abstract

Duplication of the genome requires the replication apparatus to overcome a variety of impediments, including covalent DNA adducts, the most challenging of which is on the leading template strand. Replisomes consist of two functional units, a helicase to unwind DNA and polymerases to synthesize it. The helicase is a multi-protein complex that encircles the leading template strand and makes the first contact with a leading strand adduct. The size of the channel in the helicase would appear to preclude transit by large adducts such as DNA: protein complexes (DPC). Here we discuss some of the extensively studied pathways that support replication restart after replisome encounters with leading template strand adducts. We also call attention to recent work that highlights the tolerance of the helicase for adducts ostensibly too large to pass through the central channel. [ABSTRACT FROM AUTHOR]

Published

2023

7. Transcription–Replication Conflicts as a Source of Genome Instability.

Author

Goehring, Liana, Huang, Tony T., and Smith, Duncan J.

Abstract

Transcription and replication both require large macromolecular complexes to act on a DNA template, yet these machineries cannot simultaneously act on the same DNA sequence. Conflicts between the replication and transcription machineries (transcription–replication conflicts, or TRCs) are widespread in both prokaryotes and eukaryotes and have the capacity to both cause DNA damage and compromise complete, faithful replication of the genome. This review will highlight recent studies investigating the genomic locations of TRCs and the mechanisms by which they may be prevented, mitigated, or resolved. We address work from both model organisms and mammalian systems but predominantly focus on multicellular eukaryotes owing to the additional complexities inherent in the coordination of replication and transcription in the context of cell type–specific gene expression and higher-order chromatin organization. [ABSTRACT FROM AUTHOR]

Published

2023

8. Keeping it together and taking it apart : structural investigations of replisome complexes involved in DNA replication fork protection and termination

Author

Jenkyn Bedford, Michael and Yeeles, Joseph T. P.

Subjects

Replisome, DNA, DNA replication, Cryo-EM, Disassembly, Fork protection complex, CMG, Ctf4, SCFDia2

Abstract

DNA replication is an essential cellular process whose dysregulation is implicated in severe human disease, including cancer. Broadly, DNA replication involves the unwinding of the DNA double-helix, allowing DNA polymerases to use each unwound strand as a template for nascent DNA synthesis; the complex molecular machinery responsible for DNA replication is known as the replisome. However, during unwinding and DNA synthesis, the replisome may encounter various obstacles such as DNA damage and tightly-bound proteins, necessitating specific pathways tailored to tolerating and overcoming such hinderances. Upon completion of DNA replication, the replisome is disassembled in a regulated manner. An understanding of DNA replication requires structural knowledge of how the various replisome components assemble to form the replicative machinery. Although significant advances have been made in recent years, facilitated by the development of electron cryo-microscopy (cryo-EM), our understanding of replisome structure remains in its infancy. Here I present high-resolution cryo-EM structures of the most complete replisome complexes to date, which are involved in multiple aspects of DNA replication and replication-coupled processes. First, I describe how four replisome components - the fork protection complex (Csm3-Tof1-Mrc1) plus Ctf4 - associate with the replicative helicase CMG. The fork protection complex is involved in achieving maximal rates of DNA replication, as well as performing roles in protecting replication forks from varied forms of replication stress. Ctf4 acts as a structural hub recruiting factors required for cohesion establishment and epigenetic inheritance. Second, I discuss structural insights into the regulation of replisome disassembly as the final stage of DNA replication, presenting the first structure of a replisome complex which has translocated onto double-stranded DNA and is bound by the termination-specific E3 ubiquitin ligase, SCFDia2.

Published

2021

9. Treslin and its role in the assembly of the replicative DNA helicase

Author

Jatikusumo, Vincentius Aji and Pellegrini, Luca

Subjects

572.8, Treslin, DNA replication, CryoEM, Biochemistry, CMG Helicase, MCM, Cdc45, DNA replication initiation, Replisome

Abstract

DNA replication is an essential biochemical process that underlies genetic inheritance. In eukaryotic cells, this process is carried out by a multi-subunit protein complex called replisome. The core of replisome is made up of six-subunit protein ring Mcm2–7, which contains weak DNA helicase activity. In order to fully activate the helicase activity, protein co-activators of Cdc45 and GINS have to be recruited to assemble a replicative DNA helicase called the CMG (Cdc45-Mcm2–7-GINS) complex. The active CMG subsequently unwinds the parental DNA duplex to provide single-stranded DNA templates for replicative DNA polymerases. The precise mechanism for CMG assembly and activation is still poorly understood. Recent studies using model organisms suggested the importance of protein called Sld3/Treslin for CMG assembly. The aim of the project was to understand in detail how human Treslin participates in the assembly of the CMG helicase. The interactions of Treslin with Cdc45, Mcm2–7, and DNA were characterised by a series of biochemical, biophysical, and structural biology experiments. Cdc45–Treslin interaction was shown to be conserved from budding yeast to human, in which it is mediated by a domain called Sld3/Treslin Homology Domain (SHD). However, human Treslin contains an additional Cdc45-binding site—next to the C-terminus of SHD— in an intrinsically disordered region referred to as Treslin ’extension’ (Treslinext). Treslinext was also demonstrated to interact with Mcm2–7 ring and DNA. S-phase Cyclin-Dependent Kinase (S-CDK) appeared to regulate Treslin’s interaction with Cdc45 and Mcm2–7, in which it targets a number of potential S-CDK phosphorylation sites present in Treslinext. As a part of this project, low-resolution Cdc45–Treslin and medium-resolution of MCM single hexamer 3D maps were obtained through single-particle cryo-electron microscopy (cryo-EM) analyses. The results provide molecular basis for Treslin’s role in the assembly of the CMG complex. Treslin acts as a molecular chaperone for Cdc45 recruitment to the DNA-bound Mcm2-7 ring. Treslin’s role during CMG assembly may involve its binding ability to the Mcm2–7 and DNA. Furthermore, the regulatory role of S-CDK in Treslin’s interactions with Cdc45 and Mcm2–7 suggests a link of the CMG assembly control to the cell cycle in human.

Published

2020

10. The Fork Protection Complex: A Regulatory Hub at the Head of the Replisome

Author

Grabarczyk, Daniel B., Harris, J. Robin, Series Editor, Kundu, Tapas K., Advisory Editor, Korolchuk, Viktor, Advisory Editor, Bolanos-Garcia, Victor, Advisory Editor, and Marles-Wright, Jon, Advisory Editor

Published

2022

11. Inhibition of Replication Fork Formation and Progression: Targeting the Replication Initiation and Primosomal Proteins.

Author

Radford, Holly M., Toft, Casey J., Sorenson, Alanna E., and Schaeffer, Patrick M.

Subjects

*DNA replication, *DRUG target, *PROTEINS, *PROTEIN drugs, *HIGH throughput screening (Drug development), *REPLISOMES, *PEPTIDE antibiotics

Abstract

Over 1.2 million deaths are attributed to multi-drug-resistant (MDR) bacteria each year. Persistence of MDR bacteria is primarily due to the molecular mechanisms that permit fast replication and rapid evolution. As many pathogens continue to build resistance genes, current antibiotic treatments are being rendered useless and the pool of reliable treatments for many MDR-associated diseases is thus shrinking at an alarming rate. In the development of novel antibiotics, DNA replication is still a largely underexplored target. This review summarises critical literature and synthesises our current understanding of DNA replication initiation in bacteria with a particular focus on the utility and applicability of essential initiation proteins as emerging drug targets. A critical evaluation of the specific methods available to examine and screen the most promising replication initiation proteins is provided. [ABSTRACT FROM AUTHOR]

Published

2023

12. The TIMELESS effort for timely DNA replication and protection.

Author

Patel, Jinal A. and Kim, Hyungjin

Abstract

Accurate replication of the genome is fundamental to cellular survival and tumor prevention. The DNA replication fork is vulnerable to DNA lesions and damages that impair replisome progression, and improper control over DNA replication stress inevitably causes fork stalling and collapse, a major source of genome instability that fuels tumorigenesis. The integrity of the DNA replication fork is maintained by the fork protection complex (FPC), in which TIMELESS (TIM) constitutes a key scaffold that couples the CMG helicase and replicative polymerase activities, in conjunction with its interaction with other proteins associated with the replication machinery. Loss of TIM or the FPC in general results in impaired fork progression, elevated fork stalling and breakage, and a defect in replication checkpoint activation, thus underscoring its pivotal role in protecting the integrity of both active and stalled replication forks. TIM is upregulated in multiple cancers, which may represent a replication vulnerability of cancer cells that could be exploited for new therapies. Here, we discuss recent advances on our understanding of the multifaceted roles of TIM in DNA replication and stalled fork protection, and how its complex functions are engaged in collaboration with other genome surveillance and maintenance factors. [ABSTRACT FROM AUTHOR]

Published

2023

13. Impact of Saccharomyces cerevisiae on the Field of Single-Molecule Biophysics.

Author

Ball, David A., Jalloh, Binta, and Karpova, Tatiana S.

Subjects

*SACCHAROMYCES cerevisiae, *BIOPHYSICS, *SINGLE molecules, *ENZYME kinetics, *MEMBRANE proteins

Abstract

Cellular functions depend on the dynamic assembly of protein regulator complexes at specific cellular locations. Single Molecule Tracking (SMT) is a method of choice for the biochemical characterization of protein dynamics in vitro and in vivo. SMT follows individual molecules in live cells and provides direct information about their behavior. SMT was successfully applied to mammalian models. However, mammalian cells provide a complex environment where protein mobility depends on numerous factors that are difficult to control experimentally. Therefore, yeast cells, which are unicellular and well-studied with a small and completely sequenced genome, provide an attractive alternative for SMT. The simplicity of organization, ease of genetic manipulation, and tolerance to gene fusions all make yeast a great model for quantifying the kinetics of major enzymes, membrane proteins, and nuclear and cellular bodies. However, very few researchers apply SMT techniques to yeast. Our goal is to promote SMT in yeast to a wider research community. Our review serves a dual purpose. We explain how SMT is conducted in yeast cells, and we discuss the latest insights from yeast SMT while putting them in perspective with SMT of higher eukaryotes. [ABSTRACT FROM AUTHOR]

Published

2022

14. The multifaceted roles of the Ctf4 replisome hub in the maintenance of genome integrity.

Author

Branzei, Dana, Bene, Szabolcs, Gangwani, Laxman, and Szakal, Barnabas

Subjects

*REPLICATION factors (Biochemistry), *REPLICATION fork, *DNA structure, *REPLISOMES, *DNA damage, *DNA replication

Abstract

At the core of cellular life lies a carefully orchestrated interplay of DNA replication, recombination, chromatin assembly, sister-chromatid cohesion and transcription. These fundamental processes, while seemingly discrete, are inextricably linked during genome replication. A set of replisome factors integrate various DNA transactions and contribute to the transient formation of sister chromatid junctions involving either the cohesin complex or DNA four-way junctions. The latter structures serve DNA damage bypass and may have additional roles in replication fork stabilization or in marking regions of replication fork blockage. Here, we will discuss these concepts based on the ability of one replisome component, Ctf4, to act as a hub and functionally link these processes during DNA replication to ensure genome maintenance. • Ctf4 is a replisome hub connecting DNA replication with other metabolism processes. • Ctf4 interacting peptides (CIP) and other domains link replication factors to Ctf4. • Ctf4 interactions contribute to cohesion, recombination and chromatin structure. [ABSTRACT FROM AUTHOR]

Published

2024

15. Mechanisms controlling replication fork stalling and collapse at topoisomerase 1 cleavage complexes.

Author

Westhorpe, Rose, Roske, Johann J., and Yeeles, Joseph T.P.

Subjects

*SINGLE-strand DNA breaks, *REPLICATION fork, *REPLISOMES, *PROTEINS, *DNA topoisomerase I, *DNA replication, *YEAST

Abstract

Topoisomerase 1 cleavage complexes (Top1-ccs) comprise a DNA-protein crosslink and a single-stranded DNA break that can significantly impact the DNA replication machinery (replisome). Consequently, inhibitors that trap Top1-ccs are used extensively in research and clinical settings to generate DNA replication stress, yet how the replisome responds upon collision with a Top1-cc remains obscure. By reconstituting collisions between budding yeast replisomes, assembled from purified proteins, and site-specific Top1-ccs, we have uncovered mechanisms underlying replication fork stalling and collapse. We find that stalled replication forks are surprisingly stable and that their stability is influenced by the template strand that Top1 is crosslinked to, the fork protection complex proteins Tof1-Csm3 (human TIMELESS-TIPIN), and the convergence of replication forks. Moreover, nascent-strand mapping and cryoelectron microscopy (cryo-EM) of stalled forks establishes replisome remodeling as a key factor in the initial response to Top1-ccs. These findings have important implications for the use of Top1 inhibitors in research and in the clinic. [Display omitted] • Reconstitution of collisions between in vitro -assembled replisomes and Top1-ccs • The template strand that a Top1-cc is crosslinked to heavily influences collisions • Fork protection factors Tof1-Csm3 mediate fork pausing at a leading-strand Top1-cc • Cryo-EM and biochemical data suggest replisome remodeling upon Top1-cc collision Using biochemical and structural approaches, Westhorpe et al. have characterized the response of the core DNA replication machinery to topoisomerase 1-DNA crosslinks. This work reveals that the context in which replication forks meet these crosslinks is key to the outcome and suggests replisome remodeling as a feature of such collisions. [ABSTRACT FROM AUTHOR]

Published

2024

16. Bulk synthesis and beyond: The roles of eukaryotic replicative DNA polymerases.

Author

Bainbridge, Lewis J. and Daigaku, Yasukazu

Subjects

*DNA denaturation, *DEOXYRIBOZYMES, *DNA synthesis, *DNA replication, *REPLICATION fork, *DNA polymerases

Abstract

An organism's genomic DNA must be accurately duplicated during each cell cycle. DNA synthesis is catalysed by DNA polymerase enzymes, which extend nucleotide polymers in a 5′ to 3′ direction. This inherent directionality necessitates that one strand is synthesised forwards (leading), while the other is synthesised backwards discontinuously (lagging) to couple synthesis to the unwinding of duplex DNA. Eukaryotic cells possess many diverse polymerases that coordinate to replicate DNA, with the three main replicative polymerases being Pol α, Pol δ and Pol ε. Studies conducted in yeasts and human cells utilising mutant polymerases that incorporate molecular signatures into nascent DNA implicate Pol ε in leading strand synthesis and Pol α and Pol δ in lagging strand replication. Recent structural insights have revealed how the spatial organization of these enzymes around the core helicase facilitates their strand-specific roles. However, various challenging situations during replication require flexibility in the usage of these enzymes, such as during replication initiation or encounters with replication-blocking adducts. This review summarises the roles of the replicative polymerases in bulk DNA replication and explores their flexible and dynamic deployment to complete genome replication. We also examine how polymerase usage patterns can inform our understanding of global replication dynamics by revealing replication fork directionality to identify regions of replication initiation and termination. • Canonical polymerase roles were defined by several innovative techniques. • The structure of the replisome, built around the helicase, dictates polymerase use. • Pol δ is used flexibly for different replication stages and DNA damage tolerance. • Mapping polymerase usage reveals global replication dynamics. [ABSTRACT FROM AUTHOR]

Published

2024

17. Accelerated adaptation through stimulated copy number variation in Saccharomyces cerevisiae

Author

Hull, Ryan and Houseley, Jonathan

Subjects

572.8, Copy Number Variation, Adaptation, CUP1, SFA1, Histone H3 Lysine 56, Saccharomyces cerevisiae, Copper, Formaldehyde, Nicotinamide, Rtt109, Rapamycin, Mutation, eccDNA, DNA Damage, Replisome, Break-induced replication

Abstract

Accelerated Adaptation through Stimulated Copy Number Variation in Saccharomyces cerevisiae Ryan Matthew Hull Repetitive regions of the genome, such as the centromeres, telomeres and ribosomal DNA account for a large proportion of the genetic variation between individuals. Differences in the number of repeat sequences between individuals is termed copy number variation (CNV) and is rife across eukaryotic genomes. CNV is of clinical importance as it has been implicated in many human disorders, in particularly cancers where is has been associated with tumour growth and drug resistance. The copper-resistance gene CUP1 in Saccharomyces cerevisiae is one such CNV gene. CUP1 is transcribed from a copper inducible promoter and encodes a protein involved in copper detoxification. In this work I show that yeast can regulate their repeat levels of the CUP1 gene through a transcriptionally stimulated CNV mechanism, as a direct adaptation response to a hostile environment. I characterise the requirement of the epigenetic mark Histone H3 Lysine 56 acetylation (H3K56ac) for stimulated CNV and its limitation of only working at actively transcribed genes. Based upon my findings, I propose a model for how stimulated CNV is regulated in yeast and show how we can pharmacologically manipulate this mechanism using drugs, like nicotinamide and rapamycin, to stimulate and repress a cell's ability to adapt to its environment. I further show that the model is not limited to high-copy CUP1 repeat arrays, but is also applicable to low-copy systems. Finally, I show that the model extends to other genetic loci in response to different challenging environments, such as formaldehyde stimulation of the formaldehyde-resistance gene SFA1. To the best of our knowledge, this is the first example of any eukaryotic cell undergoing genome optimisation as a novel means to accelerate its adaptation in direct response to its environment. If conserved in higher eukaryotes, such a mechanism could have major implications in how we consider and treat disorders associated with changes in CNV.

Published

2018

18. In vitro reconstitution of the ubiquitylation and disassembly of the eukaryotic replisome

Author

Mukherjee, Progya and Labib, Karim

Subjects

572, Disassembly, Ubiquitin, CMG, Replisome, ubiquitylation, Cdc48, p97, segregase, SCF ligase, Cullin ligase

Abstract

Maintenance of genomic integrity is dependent on the duplication of chromosomes, only once per cell cycle. Highly conserved mechanisms for the regulation of chromosome replication exists to ensure that the genome is copied only once. The Cdc45-MCM-GINS (CMG) DNA helicase which is the core of the eukaryotic replication complex, has been shown to be extensively regulated by post translational modifications, during its assembly. Therefore, it is not inconceivable that the process to unload the replication complex would also be a conserved and regulated process. In 2014, our lab discovered that the CMG complex undergoes post-translational modification in the form of ubiquitylation on one of the subunits of CMG, leading to its disassembly from the chromatin. Though the main players in the disassembly of CMG were known, viz the E3 ligase SCFDia2 and segregase Cdc48, very little was known about the mechanism of CMG disassembly. In the process of learning more about the disassembly of the replicative helicase from chromatin, I reconstituted the ubiquitylation of CMG and thereafter the disassembly of CMG helicase in vitro. My work resulting in the reconstitution of CMG disassembly in vitro is the first example of the disassembly of a multi-subunit physiological substrate of Cdc48. Though CMG is ubiquitylated in yeast extracts in vitro, it does not lead to its disassembly and therefore led me to find conditions necessary for the efficient ubiquitylation of CMG. I have further shown that purifying the E3 ligase associated CMG can be efficiently ubiquitylated in a semi-reconstituted system consisting of purified factors, necessary for the ubiquitylation of substrate. I investigated whether this efficiently ubiquitylated CMG can be disassembled by purified Cdc48 and associated co-factor Ufd1/Npl4 in vitro and found that disassembly is dependent on K48 linked poly-ubiquitylation of CMG. I have found that the reconstituted poly-ubiquitylation of CMG is restricted to the Mcm7 subunit of CMG, recapitulating the ubiquitylation of CMG in vivo, and my data points out that there are multiple sites of ubiquitylation on Mcm7. Through this work, I have also found that ubiquitylated Mcm7 no longer associates with the rest of the CMG components after disassembly of CMG. My assays and findings, open the door towards dissecting the molecular mechanism of the disassembly of CMG in greater detail.

Published

2018

19. The Response of the Replication Apparatus to Leading Template Strand Blocks

Author

Marina A. Bellani, Althaf Shaik, Ishani Majumdar, Chen Ling, and Michael M. Seidman

Subjects

DNA replication, replisome, CMG structure, DNA replication stress, Cytology, QH573-671

Abstract

Duplication of the genome requires the replication apparatus to overcome a variety of impediments, including covalent DNA adducts, the most challenging of which is on the leading template strand. Replisomes consist of two functional units, a helicase to unwind DNA and polymerases to synthesize it. The helicase is a multi-protein complex that encircles the leading template strand and makes the first contact with a leading strand adduct. The size of the channel in the helicase would appear to preclude transit by large adducts such as DNA: protein complexes (DPC). Here we discuss some of the extensively studied pathways that support replication restart after replisome encounters with leading template strand adducts. We also call attention to recent work that highlights the tolerance of the helicase for adducts ostensibly too large to pass through the central channel.

Published

2023

20. The DNA Replication Machine: Structure and Dynamic Function

Author

Yao, Nina Y., O’Donnell, Michael E., Harris, J. Robin, Series Editor, Kundu, Tapas K., Advisory Editor, Holzenburg, Andreas, Advisory Editor, Korolchuk, Viktor, Advisory Editor, Bolanos-Garcia, Victor, Advisory Editor, and Marles-Wright, Jon, Advisory Editor

Published

2021

21. DNA Methylation and RNA-DNA Hybrids Regulate the Single-Molecule Localization of a DNA Methyltransferase on the Bacterial Nucleoid

Author

Nicolas L. Fernandez, Ziyuan Chen, David E. H. Fuller, Lieke A. van Gijtenbeek, Taylor M. Nye, Julie S. Biteen, and Lyle A. Simmons

Subjects

replisome, epigenetic, superresolution microscopy, Bacillus subtilis, restriction modification, Microbiology, QR1-502

Abstract

ABSTRACT Bacterial DNA methyltransferases (MTases) function in restriction modification systems, cell cycle control, and the regulation of gene expression. DnmA is a recently described DNA MTase that forms N6-methyladenosine at nonpalindromic 5′-GACGAG-3′ sites in Bacillus subtilis, yet how DnmA activity is regulated is unknown. To address DnmA regulation, we tested substrate binding in vitro and found that DnmA binds poorly to methylated DNA and to an RNA-DNA hybrid with the DNA recognition sequence. Further, DnmA variants with amino acid substitutions that disrupt cognate sequence recognition or catalysis also bind poorly to DNA. Using superresolution fluorescence microscopy and single-molecule tracking of DnmA-PAmCherry, we characterized the subcellular DnmA diffusion and detected its preferential localization to the replisome region and the nucleoid. Under conditions where the chromosome is highly methylated, upon RNA-DNA hybrid accumulation, or with a DnmA variant with severely limited DNA binding activity, DnmA is excluded from the nucleoid, demonstrating that prior methylation or accumulation of RNA-DNA hybrids regulates the association of DnmA with the chromosome in vivo. Furthermore, despite the high percentage of methylated recognition sites and the proximity to putative endonuclease genes conserved across bacterial species, we find that DnmA fails to protect B. subtilis against phage predation, suggesting that DnmA is functionally an orphan MTase involved in regulating gene expression. Our work explores the regulation of a bacterial DNA MTase and identifies prior methylation and RNA-DNA hybrids as regulators of MTase localization. These MTase regulatory features could be common across biology. IMPORTANCE DNA methyltransferases (MTases) influence gene expression, cell cycle control, and host defense through DNA modification. Predicted MTases are pervasive across bacterial genomes, but the vast majority remain uncharacterized. Here, we show that in the soil microorganism Bacillus subtilis, the DNA MTase dnmA and neighboring genes are remnants of a phage defense system that no longer protects against phage predation. This result suggests that portions of the bacterial methylome may originate from inactive restriction modification systems that have maintained methylation activity. Analysis of DnmA movement in vivo shows that active DnmA localizes in the nucleoid, suggesting that DnmA can search for recognition sequences throughout the nucleoid region with some preference for the replisome. Our results further show that prior DNA methylation and RNA-DNA hybrids regulate DnmA dynamics and nucleoid localization, providing new insight into how DNA methylation is coordinated within the cellular environment.

Published

2023

22. BRCA1/BARD1 ubiquitinates PCNA in unperturbed conditions to promote continuous DNA synthesis

Author

Universidad de Sevilla. Departamento de Biología Celular, Universidad de Sevilla. Departamento de Genética, Junta de Andalucía, Ministerio de Ciencia, Innovación y Universidades (MICINN). España, Agencia Estatal de Investigación. España, European Union (UE), Salas Lloret, Daniel, García Rodríguez, Néstor, Soto Hidalgo, Emily, González Vinceiro, Lourdes, Espejo Serrano, Carmen, Giebel, Lisanne, Huertas Sánchez, Pablo, González Prieto, Román, Universidad de Sevilla. Departamento de Biología Celular, Universidad de Sevilla. Departamento de Genética, Junta de Andalucía, Ministerio de Ciencia, Innovación y Universidades (MICINN). España, Agencia Estatal de Investigación. España, European Union (UE), Salas Lloret, Daniel, García Rodríguez, Néstor, Soto Hidalgo, Emily, González Vinceiro, Lourdes, Espejo Serrano, Carmen, Giebel, Lisanne, Huertas Sánchez, Pablo, and González Prieto, Román

Abstract

Deficiencies in the BRCA1 tumor suppressor gene are the main cause of hereditary breast and ovarian cancer. BRCA1 is involved in the Homologous Recombination DNA repair pathway and, together with BARD1, forms a heterodimer with ubiquitin E3 activity. The relevance of the BRCA1/BARD1 ubiquitin E3 activity for tumor suppression and DNA repair remains controversial. Here, we observe that the BRCA1/BARD1 ubiquitin E3 activity is not required for Homologous Recombination or resistance to Olaparib. Using TULIP2 methodology, which enables the direct identification of E3-specific ubiquitination substrates, we identify substrates for BRCA1/BARD1. We find that PCNA is ubiquitinated by BRCA1/BARD1 in unperturbed conditions independently of RAD18. PCNA ubiquitination by BRCA1/BARD1 avoids the formation of ssDNA gaps during DNA replication and promotes continuous DNA synthesis. These results provide additional insight about the importance of BRCA1/BARD1 E3 activity in Homologous Recombination.

Published

2024

23. USP37 prevents unscheduled replisome unloading through MCM complex deubiquitination.

Author

Bolhuis DL, Fleifel D, Bonacci T, Wang X, Mouery BL, Cook JG, Brown NG, and Emanuele MJ

Abstract

The CMG helicase (CDC45-MCM2-7-GINS) unwinds DNA as a component of eukaryotic replisomes. Replisome (dis)assembly is tightly coordinated with cell cycle progression to ensure genome stability. However, factors that prevent premature CMG unloading and replisome disassembly are poorly described. Since disassembly is catalyzed by ubiquitination, deubiquitinases (DUBs) represent attractive candidates for safeguarding against untimely and deleterious CMG unloading. We combined a targeted loss-of-function screen with quantitative, single-cell analysis to identify human USP37 as a key DUB preventing replisome disassembly. We demonstrate that USP37 maintains active replisomes on S-phase chromatin and promotes normal cell cycle progression. Proteomics and enzyme assays revealed USP37 interacts with the CMG complex to deubiquitinate MCM7, thus antagonizing replisome disassembly. Significantly, USP37 protects normal epithelial cells from oncoprotein-induced replication stress. Our findings reveal USP37 to be critical to the maintenance of replisomes in S-phase and suggest USP37-targeting as a potential strategy for treating malignancies with defective DNA replication control., Competing Interests: COMPETING INTERESTS The Brown laboratory receives research funding from Amgen. The remaining authors declare no competing interests.

Published

2024

24. DNA replication machinery: Insights from in vitro single-molecule approaches

Author

Rebeca Bocanegra, G.A. Ismael Plaza, Carlos R. Pulido, and Borja Ibarra

Subjects

DNA replication, Single-molecule, Force spectroscopy, Fluorescence spectroscopy, Replisome, Biotechnology, TP248.13-248.65

Abstract

The replisome is the multiprotein molecular machinery that replicates DNA. The replisome components work in precise coordination to unwind the double helix of the DNA and replicate the two strands simultaneously. The study of DNA replication using in vitro single-molecule approaches provides a novel quantitative understanding of the dynamics and mechanical principles that govern the operation of the replisome and its components. ‘Classical’ ensemble-averaging methods cannot obtain this information. Here we describe the main findings obtained with in vitro single-molecule methods on the performance of individual replisome components and reconstituted prokaryotic and eukaryotic replisomes. The emerging picture from these studies is that of stochastic, versatile and highly dynamic replisome machinery in which transient protein-protein and protein-DNA associations are responsible for robust DNA replication.

Published

2021

25. The Eukaryotic Replisome Goes Under the Microscope

Author

Li, Huilin [Stony Brook Univ., NY (United States); Brookhaven National Lab. (BNL), Upton, NY (United States)]

Published

2016

26. Structure of a human replisome shows the organisation and interactions of a DNA replication machine.

Author

Jones, Morgan L, Baris, Yasemin, Taylor, Martin R G, and Yeeles, Joseph T P

Subjects

*DNA helicases, *DNA replication, *REPLISOMES, *CHROMOSOME replication, *DNA denaturation, *CATALYTIC domains

Abstract

The human replisome is an elaborate arrangement of molecular machines responsible for accurate chromosome replication. At its heart is the CDC45‐MCM‐GINS (CMG) helicase, which, in addition to unwinding the parental DNA duplex, arranges many proteins including the leading‐strand polymerase Pol ε, together with TIMELESS‐TIPIN, CLASPIN and AND‐1 that have key and varied roles in maintaining smooth replisome progression. How these proteins are coordinated in the human replisome is poorly understood. We have determined a 3.2 Å cryo‐EM structure of a human replisome comprising CMG, Pol ε, TIMELESS‐TIPIN, CLASPIN and AND‐1 bound to replication fork DNA. The structure permits a detailed understanding of how AND‐1, TIMELESS‐TIPIN and Pol ε engage CMG, reveals how CLASPIN binds to multiple replisome components and identifies the position of the Pol ε catalytic domain. Furthermore, the intricate network of contacts contributed by MCM subunits and TIMELESS‐TIPIN with replication fork DNA suggests a mechanism for strand separation. SYNOPSIS: Cryo‐EM structures of the core human replisome reveal its complex architecture and show how TIMELESS‐TIPIN, AND‐1, Pol ε and CLASPIN engage the CMG helicase. Contacts between MCM subunits and DNA suggest a mechanism for strand separation. High‐resolution structure of a reconstituted human replisome comprising the CMG helicase, AND‐1, TIMELESS‐TIPIN, Pol ε, CLASPIN and fork DNA.Detailed description of the protein‐protein and protein‐DNA contacts that underpin the organisation of the human replisome.Atomic model for three regions of CLASPIN showing how the protein extends across one side of the replisome contacting TIMELESS, MCM2 and MCM6.Identification of a specific conformation for the catalytic domain of Pol ε, demonstrating that Pol ε can adopt a "linear" configuration in the human replisome. [ABSTRACT FROM AUTHOR]

Published

2021

27. Two conformations of DNA polymerase D-PCNA-DNA, an archaeal replisome complex, revealed by cryo-electron microscopy

Author

Kouta Mayanagi, Keisuke Oki, Naoyuki Miyazaki, Sonoko Ishino, Takeshi Yamagami, Kosuke Morikawa, Kenji Iwasaki, Daisuke Kohda, Tsuyoshi Shirai, and Yoshizumi Ishino

Subjects

Archaea, Replisome, PolD, PCNA, Processive DNA synthesis, Biology (General), QH301-705.5

Abstract

Abstract Background DNA polymerase D (PolD) is the representative member of the D family of DNA polymerases. It is an archaea-specific DNA polymerase required for replication and unrelated to other known DNA polymerases. PolD consists of a heterodimer of two subunits, DP1 and DP2, which contain catalytic sites for 3′-5′ editing exonuclease and DNA polymerase activities, respectively, with both proteins being mutually required for the full activities of each enzyme. However, the processivity of the replicase holoenzyme has additionally been shown to be enhanced by the clamp molecule proliferating cell nuclear antigen (PCNA), making it crucial to elucidate the interaction between PolD and PCNA on a structural level for a full understanding of its functional relevance. We present here the 3D structure of a PolD-PCNA-DNA complex from Thermococcus kodakarensis using single-particle cryo-electron microscopy (EM). Results Two distinct forms of the PolD-PCNA-DNA complex were identified by 3D classification analysis. Fitting the reported crystal structures of truncated forms of DP1 and DP2 from Pyrococcus abyssi onto our EM map showed the 3D atomic structural model of PolD-PCNA-DNA. In addition to the canonical interaction between PCNA and PolD via PIP (PCNA-interacting protein)-box motif, we found a new contact point consisting of a glutamate residue at position 171 in a β-hairpin of PCNA, which mediates interactions with DP1 and DP2. The DNA synthesis activity of a mutant PolD with disruption of the E171-mediated PCNA interaction was not stimulated by PCNA in vitro. Conclusions Based on our analyses, we propose that glutamate residues at position 171 in each subunit of the PCNA homotrimer ring can function as hooks to lock PolD conformation on PCNA for conversion of its activity. This hook function of the clamp molecule may be conserved in the three domains of life.

Published

2020

28. The interplay of RNA:DNA hybrid structure and G-quadruplexes determines the outcome of R-loop-replisome collisions

Author

Charanya Kumar, Sahil Batra, Jack D Griffith, and Dirk Remus

Subjects

DNA replication, R-loop, G-quadruplex, Pif1, RNase H, replisome, Medicine, Science, Biology (General), QH301-705.5

Abstract

R-loops are a major source of genome instability associated with transcription-induced replication stress. However, how R-loops inherently impact replication fork progression is not understood. Here, we characterize R-loop-replisome collisions using a fully reconstituted eukaryotic DNA replication system. We find that RNA:DNA hybrids and G-quadruplexes at both co-directional and head-on R-loops can impact fork progression by inducing fork stalling, uncoupling of leading strand synthesis from replisome progression, and nascent strand gaps. RNase H1 and Pif1 suppress replication defects by resolving RNA:DNA hybrids and G-quadruplexes, respectively. We also identify an intrinsic capacity of replisomes to maintain fork progression at certain R-loops by unwinding RNA:DNA hybrids, repriming leading strand synthesis downstream of G-quadruplexes, or utilizing R-loop transcripts to prime leading strand restart during co-directional R-loop-replisome collisions. Collectively, the data demonstrates that the outcome of R-loop-replisome collisions is modulated by R-loop structure, providing a mechanistic basis for the distinction of deleterious from non-deleterious R-loops.

Published

2021

29. Single-Molecule Insights Into the Dynamics of Replicative Helicases

Author

Richard R. Spinks, Lisanne M. Spenkelink, Nicholas E. Dixon, and Antoine M. van Oijen

Subjects

helicases, dynamics, replisome, DNA replication, single-molecule, fluorescence, Biology (General), QH301-705.5

Abstract

Helicases are molecular motors that translocate along single-stranded DNA and unwind duplex DNA. They rely on the consumption of chemical energy from nucleotide hydrolysis to drive their translocation. Specialized helicases play a critically important role in DNA replication by unwinding DNA at the front of the replication fork. The replicative helicases of the model systems bacteriophages T4 and T7, Escherichia coli and Saccharomyces cerevisiae have been extensively studied and characterized using biochemical methods. While powerful, their averaging over ensembles of molecules and reactions makes it challenging to uncover information related to intermediate states in the unwinding process and the dynamic helicase interactions within the replisome. Here, we describe single-molecule methods that have been developed in the last few decades and discuss the new details that these methods have revealed about replicative helicases. Applying methods such as FRET and optical and magnetic tweezers to individual helicases have made it possible to access the mechanistic aspects of unwinding. It is from these methods that we understand that the replicative helicases studied so far actively translocate and then passively unwind DNA, and that these hexameric enzymes must efficiently coordinate the stepping action of their subunits to achieve unwinding, where the size of each step is prone to variation. Single-molecule fluorescence microscopy methods have made it possible to visualize replicative helicases acting at replication forks and quantify their dynamics using multi-color colocalization, FRAP and FLIP. These fluorescence methods have made it possible to visualize helicases in replication initiation and dissect this intricate protein-assembly process. In a similar manner, single-molecule visualization of fluorescent replicative helicases acting in replication identified that, in contrast to the replicative polymerases, the helicase does not exchange. Instead, the replicative helicase acts as the stable component that serves to anchor the other replication factors to the replisome.

Published

2021

30. Replication of the Mammalian Genome by Replisomes Specific for Euchromatin and Heterochromatin

Author

Jing Zhang, Marina A. Bellani, Jing Huang, Ryan C. James, Durga Pokharel, Julia Gichimu, Himabindu Gali, Grant Stewart, and Michael M. Seidman

Subjects

replication stress, replisome, CMG, FANCM, DONSON, GINS, Biology (General), QH301-705.5

Abstract

Replisomes follow a schedule in which replication of DNA in euchromatin is early in S phase while sequences in heterochromatin replicate late. Impediments to DNA replication, referred to as replication stress, can stall replication forks triggering activation of the ATR kinase and downstream pathways. While there is substantial literature on the local consequences of replisome stalling–double strand breaks, reversed forks, or genomic rearrangements–there is limited understanding of the determinants of replisome stalling vs. continued progression. Although many proteins are recruited to stalled replisomes, current models assume a single species of “stressed” replisome, independent of genomic location. Here we describe our approach to visualizing replication fork encounters with the potent block imposed by a DNA interstrand crosslink (ICL) and our discovery of an unexpected pathway of replication restart (traverse) past an intact ICL. Additionally, we found two biochemically distinct replisomes distinguished by activity in different stages of S phase and chromatin environment. Each contains different proteins that contribute to ICL traverse.

Published

2021

31. Mechanisms for Maintaining Eukaryotic Replisome Progression in the Presence of DNA Damage

Author

Thomas A. Guilliam

Subjects

DNA replication, replisome, DNA damage tolerance, translesion synthesis, repriming, recoupling, Biology (General), QH301-705.5

Abstract

The eukaryotic replisome coordinates template unwinding and nascent-strand synthesis to drive DNA replication fork progression and complete efficient genome duplication. During its advancement along the parental template, each replisome may encounter an array of obstacles including damaged and structured DNA that impede its progression and threaten genome stability. A number of mechanisms exist to permit replisomes to overcome such obstacles, maintain their progression, and prevent fork collapse. A combination of recent advances in structural, biochemical, and single-molecule approaches have illuminated the architecture of the replisome during unperturbed replication, rationalised the impact of impediments to fork progression, and enhanced our understanding of DNA damage tolerance mechanisms and their regulation. This review focusses on these studies to provide an updated overview of the mechanisms that support replisomes to maintain their progression on an imperfect template.

Published

2021

32. Improved detection of DNA replication fork-associated proteins.

Author

Rivard, Rebecca S., Chang, Ya-Chu, Ragland, Ryan L., Thu, Yee-Mon, Kassab, Muzaffer, Mandal, Rahul Shubhra, Van Riper, Susan K., Kulej, Katarzyna, Higgins, LeeAnn, Markowski, Todd M., Shang, David, Hedberg, Jack, Erber, Luke, Garcia, Benjamin, Chen, Yue, Bielinsky, Anja-Katrin, and Brown, Eric J.

Abstract

Innovative methods to retrieve proteins associated with actively replicating DNA have provided a glimpse into the molecular dynamics of replication fork stalling. We report that a combination of density-based replisome enrichment by isolating proteins on nascent DNA (iPOND2) and label-free quantitative mass spectrometry (iPOND2-DRIPPER) substantially increases both replication factor yields and the dynamic range of protein quantification. Replication protein abundance in retrieved nascent DNA is elevated up to 300-fold over post-replicative controls, and recruitment of replication stress factors upon fork stalling is observed at similar levels. The increased sensitivity of iPOND2-DRIPPER permits direct measurement of ubiquitination events without intervening retrieval of diglycine tryptic fragments of ubiquitin. Using this approach, we find that stalled replisomes stimulate the recruitment of a diverse cohort of DNA repair factors, including those associated with poly-K63-ubiquitination. Finally, we uncover the temporally controlled association of stalled replisomes with nuclear pore complex components and nuclear cytoskeleton networks. [Display omitted] • iPOND2-DRIPPER improves dynamic range for detection of replisome proteins • iPOND2-DRIPPER identifies sites of ubiquitination without di-Gly enrichment • iPOND2-DRIPPER expands upon previously identified replisome components Rivard et al. report that a combination of density-based replisome enrichment and label-free quantitative mass spectrometry (iPOND2-DRIPPER) substantially increases both replication and repair factor yields and the dynamic range of protein quantification. Using this method, the authors identify notable ubiquitination and spatiotemporal changes in replication-fork-associated proteins following replication stress. [ABSTRACT FROM AUTHOR]

Published

2024

33. A rewiring of DNA replication mediated by MRE11 exonuclease underlies primed-to-naive cell de-differentiation.

Author

Ubieto-Capella, Patricia, Ximénez-Embún, Pilar, Giménez-Llorente, Daniel, Losada, Ana, Muñoz, Javier, and Méndez, Juan

Abstract

Mouse embryonic stem cells (mESCs) in the primed pluripotency state, which resembles the post-implantation epiblast, can be de-differentiated in culture to a naive state that resembles the pre-implantation inner cell mass. We report that primed-to-naive mESC transition entails a significant slowdown of DNA replication forks and the compensatory activation of dormant origins. Using isolation of proteins on nascent DNA coupled to mass spectrometry, we identify key changes in replisome composition that are responsible for these effects. Naive mESC forks are enriched in MRE11 nuclease and other DNA repair proteins. MRE11 is recruited to newly synthesized DNA in response to transcription-replication conflicts, and its inhibition or genetic downregulation in naive mESCs is sufficient to restore the fork rate of primed cells. Transcriptomic analyses indicate that MRE11 exonuclease activity is required for the complete primed-to-naive mESC transition, demonstrating a direct link between DNA replication dynamics and the mESC de-differentiation process. [Display omitted] • Primed-to-naive mESC transition triggers replication fork slowdown • iPOND-MS reveals differences in replisome composition of naive and primed mESCs • MRE11 exonuclease mediates fork slowdown in the primed-to-naive mESC transition • Inhibition of MRE11 exonuclease prevents complete primed-to-naive mESC transition Ubieto-Capella et al. report that MRE11 nuclease is enriched at replication forks during primed-to-naive mESC transition and is responsible for replication fork slowdown. Inhibition of MRE11 exonuclease activity prevents the decrease in fork rate and interferes with complete primed-to-naive transition. This study links DNA replication dynamics with mESC reprogramming capacity. [ABSTRACT FROM AUTHOR]

Published

2024

34. Poly(ADP-ribosyl)ation of TIMELESS limits DNA replication stress and promotes stalled fork protection.

Author

Rageul, Julie, Lo, Natalie, Phi, Amy L., Patel, Jinal A., Park, Jennifer J., and Kim, Hyungjin

Abstract

Poly(ADP-ribosyl)ation (PARylation), catalyzed mainly by poly(ADP-ribose) polymerase (PARP)1, is a key posttranslational modification involved in DNA replication and repair. Here, we report that TIMELESS (TIM), an essential scaffold of the replisome, is PARylated, which is linked to its proteolysis. TIM PARylation requires recognition of auto-modified PARP1 via two poly(ADP-ribose)-binding motifs, which primes TIM for proteasome-dependent degradation. Cells expressing the PARylation-refractory TIM mutant or under PARP inhibition accumulate TIM at DNA replication forks, causing replication stress and hyper-resection of stalled forks. Mechanistically, aberrant engagement of TIM with the replicative helicase impedes RAD51 loading and protection of reversed forks. Accordingly, defective TIM degradation hypersensitizes BRCA2-deficient cells to replication damage. Our study defines TIM as a substrate of PARP1 and elucidates how the control of replisome remodeling by PARylation is linked to stalled fork protection. Therefore, we propose a mechanism of PARP inhibition that impinges on the DNA replication fork instability caused by defective TIM turnover. [Display omitted] • TIMELESS (TIM) and PARP1 interact at DNA replication forks • TIM recognizes auto-PARylated PARP1 by two conserved PAR-binding motifs (PBMs) • PBM-dependent TIM PARylation primes TIM for proteasomal degradation • Aberrant TIM accumulation causes replication stress and impairs stalled fork protection Rageul et al. report that TIMELESS harbors poly(ADP-ribose) (PAR)-binding motifs, which are essential for the PARylation of TIMELESS by PARP1. Defects in this modification prevent proteasomal degradation of TIMELESS and cause DNA replication fork instability. The proteotoxic stress caused by dysregulated TIMELESS turnover underlies a mechanism of PARP inhibitor action. [ABSTRACT FROM AUTHOR]

Published

2024

35. Unravelling the potential of Triflusal as an anti-TB repurposed drug by targeting replication protein DciA.

Author

Ali, Waseem, Jamal, Salma, Gangwar, Rishabh, Ahmed, Faraz, Pahuja, Isha, Sharma, Rahul, Prakash Dwivedi, Ved, Agarwal, Meetu, and Grover, Sonam

Subjects

*MOLECULAR dynamics, *MYCOBACTERIUM tuberculosis, *DRUG development, *BACTERIAL proteins, *ZOLEDRONIC acid

Abstract

The increasing prevalence of drug-resistant Tuberculosis (TB) is imposing extreme difficulties in controlling the TB infection rate globally, making treatment critically challenging. To combat the prevailing situation, it is crucial to explore new anti-TB drugs with a novel mechanism of action and high efficacy. The Mycobacterium tuberculosis (M.tb)DciA is an essential protein involved in bacterial replication and regulates its growth. DciA interacts with DNA and provides critical help in binding other replication machinery proteins to the DNA. Moreover, the lack of any structural homology of M.tb DciA with human proteins makes it an appropriate target for drug development. In this study, FDA-approved drugs were virtually screened against M.tb DciA to identify potential inhibitors. Four drugs namely Lanreotide, Risedronate, Triflusal, and Zoledronic acid showed higher molecular docking scores. Further, molecular dynamics simulations analysis of DciA-drugs complexes reported stable interaction, more compactness, and reduced atomic motion. The anti-TB activity of drugs was further evaluated under in vitro and ex vivo conditions where Triflusal was observed to have the best possible activity with the MIC of 25 μg/ml. Our findings present novel DciA inhibitors and anti-TB activity of Triflusal. Further investigations on the use of Triflusal may lead to the discovery of a new anti-TB drug. [ABSTRACT FROM AUTHOR]

Published

2024

36. Allosteric communication in DNA polymerase clamp loaders relies on a critical hydrogen-bonded junction

Author

Subu Subramanian, Kent Gorday, Kendra Marcus, Matthew R Orellana, Peter Ren, Xiao Ran Luo, Michael E O'Donnell, and John Kuriyan

Subjects

bacteriophage T4, AAA+ proteins, allosteric communication, replisome, Medicine, Science, Biology (General), QH301-705.5

Abstract

Clamp loaders are AAA+ ATPases that load sliding clamps onto DNA. We mapped the mutational sensitivity of the T4 bacteriophage sliding clamp and clamp loader by deep mutagenesis, and found that residues not involved in catalysis or binding display remarkable tolerance to mutation. An exception is a glutamine residue in the AAA+ module (Gln 118) that is not located at a catalytic or interfacial site. Gln 118 forms a hydrogen-bonded junction in a helical unit that we term the central coupler, because it connects the catalytic centers to DNA and the sliding clamp. A suppressor mutation indicates that hydrogen bonding in the junction is important, and molecular dynamics simulations reveal that it maintains rigidity in the central coupler. The glutamine-mediated junction is preserved in diverse AAA+ ATPases, suggesting that a connected network of hydrogen bonds that links ATP molecules is an essential aspect of allosteric communication in these proteins.

Published

2021

37. Historical Perspective of Eukaryotic DNA Replication

Author

Kelly, Thomas, COHEN, IRUN R., Series editor, LAJTHA, ABEL, Series editor, LAMBRIS, JOHN D., Series editor, PAOLETTI, RODOLFO, Series editor, REZAEI, NIMA, Series editor, Masai, Hisao, editor, and Foiani, Marco, editor

Published

2017

38. Architecture of the Saccharomyces cerevisiae Replisome

Author

Bai, Lin, Yuan, Zuanning, Sun, Jingchuan, Georgescu, Roxana, O’Donnell, Michael E., Li, Huilin, COHEN, IRUN R., Series editor, LAJTHA, ABEL, Series editor, LAMBRIS, JOHN D., Series editor, PAOLETTI, RODOLFO, Series editor, REZAEI, NIMA, Series editor, Masai, Hisao, editor, and Foiani, Marco, editor

Published

2017

39. Spotlight on the Replisome: Aetiology of DNA Replication-Associated Genetic Diseases.

Author

Bellelli, Roberto and Boulton, Simon J.

Subjects

*REPLISOMES, *GENETIC disorders, *MOLECULAR genetics, *DNA, *ETIOLOGY of diseases

Abstract

Human development and tissue homeostasis depend on the regulated control of cellular proliferation and differentiation. DNA replication is essential to couple genome duplication and cell division with the establishment and maintenance of cellular differentiation programs. In eukaryotes, DNA replication is performed by a large machine known as the 'replisome,' which is strictly regulated in a cell cycle-dependent manner. Inherited mutations of replisome components have been identified in a range of genetic conditions characterised by developmental abnormalities and reduced organismal growth in addition to an involvement of the immune and endocrine systems and/or heightened tumour predisposition. Here, we review the current knowledge of the molecular genetics of replisome dysfunction disorders and discuss recent mechanistic insights into their pathogenesis, with a focus on the specific steps of DNA replication affected in these human diseases. DNA replication is performed by a multiprotein complex known as the 'replisome,' which is assembled and regulated in a cell cycle–dependent manner. Hypomorphic mutations of components of the replisome lead to defective development, reduced growth, and altered tissue homeostasis. Whole-genome sequencing studies significantly expanded the repertoire of mendelian diseases caused by mutation of the replication machinery. Phenotypic analysis and mechanistic studies support defective replication origin assembly and activation and perturbation of replication fork stability as the pathogenetic mechanisms of replication-linked human genetic diseases. [ABSTRACT FROM AUTHOR]

Published

2021

40. The eukaryotic replisome tolerates leading‐strand base damage by replicase switching.

Author

Guilliam, Thomas A and Yeeles, Joseph TP

Subjects

*DNA polymerases, *REPLISOMES, *DNA replication, *POLYMERASES, *THYMINE, *ETHYLENE glycol

Abstract

The high‐fidelity replicative DNA polymerases, Pol ε and Pol δ, are generally thought to be poorly equipped to replicate damaged DNA. Direct and complete replication of a damaged template therefore typically requires the activity of low‐fidelity translesion synthesis (TLS) polymerases. Here we show that a yeast replisome, reconstituted with purified proteins, is inherently tolerant of the common oxidative lesion thymine glycol (Tg). Surprisingly, leading‐strand Tg was bypassed efficiently in the presence and absence of the TLS machinery. Our data reveal that following helicase–polymerase uncoupling a switch from Pol ε, the canonical leading‐strand replicase, to the lagging‐strand replicase Pol δ, facilitates rapid, efficient and error‐free lesion bypass at physiological nucleotide levels. This replicase switch mechanism also promotes bypass of the unrelated oxidative lesion, 8‐oxoguanine. We propose that replicase switching may promote continued leading‐strand synthesis whenever the replisome encounters leading‐strand damage that is bypassed more efficiently by Pol δ than by Pol ε. Synopsis: Complete replication of damaged DNA usually requires dedicated low‐fidelity translesion synthesis polymerases. Here, studies with in vitro‐reconstituted pure yeast replisomes show their inherent ability to bypass the common lesion, thymine glycol, through internal replicase switching. The eukaryotic replisome is tolerant of oxidative base damage in the leading‐strand template.This tolerance does not require canonical translesion synthesis machinery.Base damage causes disengagement of the catalytic subunit of Pol ε from the nascent strand, resulting in uncoupled fork progression.Upon uncoupling, a switch to the lagging strand replicase Pol δ on the nascent leading strand promotes lesion bypass and recoupling.Replicase switching promotes rapid and error‐free lesion bypass at physiological nucleotide levels. [ABSTRACT FROM AUTHOR]

Published

2021

41. Replisome bypass of a protein-based R-loop block by Pif1.

Author

Schauer, Grant D., Spenkelink, Lisanne M., Lewis, Jacob S., Yurieva, Olga, Mueller, Stefan H., van Oijen, Antoine M., and O'Donnell, Michael E.

Subjects

*REPLISOMES, *SINGLE-stranded DNA, *ANTIGEN presenting cells, *PROTEINS, *SACCHAROMYCES cerevisiae, *SINGLE molecules, *GENOMES, *HELICASES

Abstract

Efficient and faithful replication of the genome is essential to maintain genome stability. Replication is carried out by a multiprotein complex called the replisome, which encounters numerous obstacles to its progression. Failure to bypass these obstacles results in genome instability and may facilitate errors leading to disease. Cells use accessory helicases that help the replisome bypass difficult barriers. All eukaryotes contain the accessory helicase Pif1, which tracks in a 5'-3' direction on single-stranded DNA and plays a role in genome maintenance processes. Here, we reveal a previously unknown role for Pif1 in replication barrier bypass. We use an in vitro reconstituted Saccharomyces cerevisiae replisome to demonstrate that Pif1 enables the replisome to bypass an inactive (i.e., dead) Cas9 (dCas9) R-loop barrier. Interestingly, dCas9 R-loops targeted to either strand are bypassed with similar efficiency. Furthermore, we employed a singlemolecule fluorescence visualization technique to show that Pif1 facilitates this bypass by enabling the simultaneous removal of the dCas9 protein and the R-loop. We propose that Pif1 is a general displacement helicase for replication bypass of both R-loops and protein blocks. [ABSTRACT FROM AUTHOR]

Published

2020

42. Recruitment and Spread of Heterochromatin in the Budding Yeast Saccharomyces cerevisiae

Author

Brothers, Molly Elizabeth

Subjects

Biology, Genetics, Molecular biology, histone deacetylation, replisome, sirtuins, transcriptional silencing

Abstract

Transcriptional silencing in the budding yeast Saccharomyces cerevisiae occurs at the cryptic mating-type loci HML and HMR on chromosome III and at all 32 telomeres. Transcriptional silencing occurs through the formation of a repressive chromatin structure, featuring nucleosome compaction and removal of active chromatin marks. These features are the result of the activity of the Silent Information Regulator (SIR) complex, made up of Sir2, Sir3, and Sir4. Sir2, founding member of the wide spread class of protein deacetylases known as sirtuins, deacetylates histone tails, whereas Sir3 and Sir4 serve structural roles, binding to histones and compacting chromatin.The formation of silent chromatin by the SIR complex conceptually involves two steps: recruitment and spreading. Recruitment, also referred to as nucleation, occurs at DNA sequence elements called silencers that are present at telomeres and flank HML and HMR. The E and I silencers that flank both HML and HMR contain different combinations of binding sites for the Origin Recognition Complex (ORC) and the general transcription factors Rap1 and Abf1. Silencers at telomeres are less well characterized, but include an array of Rap1 binding sites in telomere repeats and possibly ORC/Abf1 sites further into the chromosome. Fully silent chromatin displays SIR complex binding beyond recruitment sites for multiple kilobases. The difference in SIR complex occupancy between nucleation and full silencing occurs through an ill-defined process referred to as ‘spreading’.To date, most studies on spreading of the SIR complex have focused on telomeres, sometimes only one, and relied on low-resolution ChIP-PCR, inducible systems that resulted in massive overexpression of Sir3, or both. These studies defined to a limited resolution positions of SIR complex binding and occupancy, and provided a foundation for genome-wide studies with higher temporal and spatial resolution. My work further characterized and distinguished the two processes of recruitment and spread at telomeres as well as HML and HMR. I accomplished this by developing a new method for tracing the history and trajectory of SIR complex binding: measuring DNA methylation by long-read nanopore sequencing of DNA from cells expressing a fusion protein between Sir3 and an N6-methyladenosine methyltransferase, M.EcoGII.The fusion protein Sir3-M.EcoGII strongly and specifically methylated HML, HMR, and telomeres and was able to detect transient or low-affinity Sir3-chromatin interactions better than ChIP-seq. This new method allowed me to characterize the occupancy of a SIR3 allele encoding a protein deficient in binding to nucleosomes, sir3-bah∆. The sir3-bah∆-M.EcoGII fusion protein methylated DNA only at recruitment sites, clearly providing evidence that recruitment and spread of Sir3 were separable processes and that the interaction between Sir3 and nucleosomes was not required for recruitment but was required for spread. I also tested prior claims that overexpression of SIR3 results in binding of the protein at even longer distances from recruitment sites. The overexpression of SIR3-M.ECOGII, with few exceptions, did not extend regions of DNA methylation.I also defined the dynamics of Sir3 spreading during silencing establishment and how its occupancy related to transcriptional silencing of HML and HMR. A fusion between sir3-8–a temperature sensitive allele of SIR3–and M.ECOGII allowed for regulated induction of DNA methylation without straying above the endogenous level of SIR3 expression. Over the course of about one cell cycle, methylation appeared only at the E and I silencers and the promoters of HML and HMR, demonstrating recruitment. Despite a lack of Sir3 occupancy between these recruitment sites, repression of transcription occurred early in the time course, suggesting that the early stages of silencing did not require Sir3 occupancy across the entire locus.Once silent chromatin is established, it must be faithfully inherited through the disruptive process of DNA replication. Certain point mutations in PCNA (POL30), the processivity clamp for DNA polymerase at replication forks, result in loss of transcriptional silencing at HML and HMR. I used classical genetics to study three of these alleles, pol30-6, pol30-8, and pol30-79, in more detail. All three alleles disrupted silencing only in actively-cycling cells, and the disruption in silencing was only transient, suggesting that the inheritance of silent chromatin through cell division was not as robust as in wild-type cells. All three alleles of POL30 destabilized silencing through disrupting the function of histone chaperones, highlighting the importance of histone trafficking at the replication fork for the stability of transcriptional silencing.

Published

2021

43. Cohesion is established during DNA replication utilising chromosome associated cohesin rings as well as those loaded de novo onto nascent DNAs

Author

Madhusudhan Srinivasan, Marco Fumasoni, Naomi J Petela, Andrew Murray, and Kim A Nasmyth

Subjects

cohesin, shister chromatid cohesion, SMC, replication, replisome, Medicine, Science, Biology (General), QH301-705.5

Abstract

Sister chromatid cohesion essential for mitotic chromosome segregation is thought to involve the co-entrapment of sister DNAs within cohesin rings. Although cohesin can load onto chromosomes throughout the cell cycle, it only builds cohesion during S phase. A key question is whether cohesion is generated by conversion of cohesin complexes associated with un-replicated DNAs ahead of replication forks into cohesive structures behind them, or from nucleoplasmic cohesin that is loaded de novo onto nascent DNAs associated with forks, a process that would be dependent on cohesin’s Scc2 subunit. We show here that in S. cerevisiae, both mechanisms exist and that each requires a different set of replisome-associated proteins. Cohesion produced by cohesin conversion requires Tof1/Csm3, Ctf4 and Chl1 but not Scc2 while that created by Scc2-dependent de novo loading at replication forks requires the Ctf18-RFC complex. The association of specific replisome proteins with different types of cohesion establishment opens the way to a mechanistic understanding of an aspect of DNA replication unique to eukaryotic cells.

Published

2020

44. The Interplay of Cohesin and the Replisome at Processive and Stressed DNA Replication Forks

Author

Janne J. M. van Schie and Job de Lange

Subjects

sister chromatid cohesion, DNA replication, replisome, cohesin complex, DNA entrapment, cohesion establishment, Cytology, QH573-671

Abstract

The cohesin complex facilitates faithful chromosome segregation by pairing the sister chromatids after DNA replication until mitosis. In addition, cohesin contributes to proficient and error-free DNA replication. Replisome progression and establishment of sister chromatid cohesion are intimately intertwined processes. Here, we review how the key factors in DNA replication and cohesion establishment cooperate in unperturbed conditions and during DNA replication stress. We discuss the detailed molecular mechanisms of cohesin recruitment and the entrapment of replicated sister chromatids at the replisome, the subsequent stabilization of sister chromatid cohesion via SMC3 acetylation, as well as the role and regulation of cohesin in the response to DNA replication stress.

Published

2021

45. An updated perspective on the polymerase division of labor during eukaryotic DNA replication.

Author

Guilliam, Thomas A. and Yeeles, Joseph T. P.

Subjects

*DIVISION of labor, *DNA replication, *GENETIC techniques, *DNA polymerases, *DNA synthesis

Abstract

In eukaryotes three DNA polymerases (Pols), α, δ, and ε, are tasked with bulk DNA synthesis of nascent strands during genome duplication. Most evidence supports a model where Pol α initiates DNA synthesis before Pol ε and Pol δ replicate the leading and lagging strands, respectively. However, a number of recent reports, enabled by advances in biochemical and genetic techniques, have highlighted emerging roles for Pol δ in all stages of leading-strand synthesis; initiation, elongation, and termination, as well as fork restart. By focusing on these studies, this review provides an updated perspective on the division of labor between the replicative polymerases during DNA replication. [ABSTRACT FROM AUTHOR]

Published

2020

46. Timeless couples G‐quadruplex detection with processing by DDX11 helicase during DNA replication.

Author

Lerner, Leticia K, Holzer, Sandro, Kilkenny, Mairi L, Šviković, Saša, Murat, Pierre, Schiavone, Davide, Eldridge, Cara B, Bittleston, Alice, Maman, Joseph D, Branzei, Dana, Stott, Katherine, Pellegrini, Luca, and Sale, Julian E

Subjects

*DNA replication, *DNA structure, *DNA synthesis, *NUCLEOTIDE sequence, *REPLISOMES, *DNA damage, *DNA helicases

Abstract

Regions of the genome with the potential to form secondary DNA structures pose a frequent and significant impediment to DNA replication and must be actively managed in order to preserve genetic and epigenetic integrity. How the replisome detects and responds to secondary structures is poorly understood. Here, we show that a core component of the fork protection complex in the eukaryotic replisome, Timeless, harbours in its C‐terminal region a previously unappreciated DNA‐binding domain that exhibits specific binding to G‐quadruplex (G4) DNA structures. We show that this domain contributes to maintaining processive replication through G4‐forming sequences, and exhibits partial redundancy with an adjacent PARP‐binding domain. Further, this function of Timeless requires interaction with and activity of the helicase DDX11. Loss of both Timeless and DDX11 causes epigenetic instability at G4‐forming sequences and DNA damage. Our findings indicate that Timeless contributes to the ability of the replisome to sense replication‐hindering G4 formation and ensures the prompt resolution of these structures by DDX11 to maintain processive DNA synthesis. Synopsis: How eukaryotic replisomes detect and respond to DNA secondary structures is poorly understood. Here, cooperation of the fork protection complex subunit Timeless and the helicase DDX11 is found to bind and resolve G‐quadruplex (G4) DNA during replication. Timeless, a core component of the replisome, contains a C‐terminal DNA binding domain with specificity for G4 secondary structures.The DNA‐binding domain acts in partial redundancy with an adjacent PARP‐binding domain to maintain processive replication through G4s.The ability of Timeless to maintain replication through G4s requires interaction with the DDX11 helicase.Loss of Timeless or DDX11 leads to G4‐associated epigenetic instability and DNA damage [ABSTRACT FROM AUTHOR]

Published

2020

47. OZF is a Claspin‐interacting protein essential to maintain the replication fork progression rate under replication stress.

Author

Feu, Sonia, Unzueta, Fernando, Llopis, Alba, Semple, Jennifer I., Ercilla, Amaia, Guaita‐Esteruelas, Sandra, Jaumot, Montserrat, Freire, Raimundo, and Agell, Neus

Abstract

DNA replication is essential for cell proliferation and is one of the cell cycle stages where DNA is more vulnerable. Replication stress is a prominent property of tumor cells and an emerging target for cancer therapy. Although it is not directly involved in nucleotide incorporation, Claspin is a protein with relevant functions in DNA replication. It harbors a DNA‐binding domain that interacts preferentially with branched or forked DNA molecules. It also acts as a platform for the interaction of proteins related to DNA damage checkpoint activation, DNA repair, DNA replication origin firing, and fork progression. In order to find new proteins potentially involved in the regulation of DNA replication, we performed a two‐hybrid screen to discover new Claspin‐binding proteins. This system allowed us to identify the zinc‐finger protein OZF (ZNF146) as a new Claspin‐interacting protein. OZF is also present at replication forks and co‐immunoprecipitates not only with Claspin but also with other replisome components. Interestingly, OZF depletion does not affect DNA replication in a normal cell cycle, but its depletion induces a reduction in the fork progression rate under replication stress conditions. Our results suggest that OZF is a Claspin‐binding protein with a specific function in fork progression under replication stress. [ABSTRACT FROM AUTHOR]

Published

2020

48. Replisome genes regulation by antitumor miR‐101‐5p in clear cell renal cell carcinoma.

Author

Yamada, Yasutaka, Nohata, Nijiro, Uchida, Akifumi, Kato, Mayuko, Arai, Takayuki, Moriya, Shogo, Mizuno, Keiko, Kojima, Satoko, Yamazaki, Kazuto, Naya, Yukio, Ichikawa, Tomohiko, and Seki, Naohiko

Abstract

Analysis of microRNA (miRNA) regulatory networks is useful for exploring novel biomarkers and therapeutic targets in cancer cells. The Cancer Genome Atlas dataset shows that low expression of both strands of pre‐miR‐101 (miR‐101‐5p and miR‐101‐3p) significantly predicted poor prognosis in clear cell renal cell carcinoma (ccRCC). The functional significance of miR‐101‐5p in cancer cells is poorly understood. Here, we focused on miR‐101‐5p to investigate the antitumor function and its regulatory networks in ccRCC cells. Ectopic expression of mature miRNAs or siRNAs was investigated in cancer cell lines to characterize cell function, ie, proliferation, apoptosis, migration, and invasion. Genome‐wide gene expression and in silico database analyses were undertaken to predict miRNA regulatory networks. Expression of miR‐101‐5p caused cell cycle arrest and apoptosis in ccRCC cells. Downstream neighbor of son (DONSON) was directly regulated by miR‐101‐5p, and its aberrant expression was significantly associated with shorter survival in propensity score‐matched analysis (P =.0001). Knockdown of DONSON attenuated ccRCC cell aggressiveness. Several replisome genes controlled by DONSON and their expression were closely associated with ccRCC pathogenesis. The antitumor miR‐101‐5p/DONSON axis and its modulated replisome genes might be a novel diagnostic and therapeutic target for ccRCC. [ABSTRACT FROM AUTHOR]

Published

2020

49. Ufd1-Npl4 Recruit Cdc48 for Disassembly of Ubiquitylated CMG Helicase at the End of Chromosome Replication

Author

Marija Maric, Progya Mukherjee, Michael H. Tatham, Ronald Hay, and Karim Labib

Subjects

CMG helicase, DNA replication termination, Cdc48, Ufd1-Npl4, ubiquitylation, ubiquitin, replisome, disassembly, Biology (General), QH301-705.5

Abstract

Disassembly of the Cdc45-MCM-GINS (CMG) DNA helicase is the key regulated step during DNA replication termination in eukaryotes, involving ubiquitylation of the Mcm7 helicase subunit, leading to a disassembly process that requires the Cdc48 “segregase”. Here, we employ a screen to identify partners of budding yeast Cdc48 that are important for disassembly of ubiquitylated CMG helicase at the end of chromosome replication. We demonstrate that the ubiquitin-binding Ufd1-Npl4 complex recruits Cdc48 to ubiquitylated CMG. Ubiquitylation of CMG in yeast cell extracts is dependent upon lysine 29 of Mcm7, which is the only detectable site of ubiquitylation both in vitro and in vivo (though in vivo other sites can be modified when K29 is mutated). Mutation of K29 abrogates in vitro recruitment of Ufd1-Npl4-Cdc48 to the CMG helicase, supporting a model whereby Ufd1-Npl4 recruits Cdc48 to ubiquitylated CMG at the end of chromosome replication, thereby driving the disassembly reaction.

Published

2017

50. Deciphering the molecular functionality of Cdc45 in replisomal complex.

Author

Radhakrishnan A, Sharma C, Malviya VN, and Srivastav R

Abstract

The members of DHH superfamily have been reported with diverse substrate spectrum and play pivotal roles in replication, repair, and RNA metabolism. This family comprises phosphatases, phosphoesterase and bifunctional enzymes having nanoRNase and phosphatase activities. Cell cycle factor Cdc45, a member of this superfamily, is crucial for movement of the replication fork during DNA replication and an important component of the replisome. The specific protein-protein interactions of Cdc45 with other factors along with helicase moderate the faithful DNA replication process. However, the exact biochemical functions of this factor are still unknown and need further investigation. Here, we studied the biochemical roles of Cdc45 and its molecular interactions within the replisomal complex. The alteration in the level of protein, observed when DNA damage is induced in-vivo , suggests its association with DNA replication stress. We analyzed protein Cdc45, providing new insights about the molecular and biochemical functionality of this replisomal factor., Competing Interests: No competing interest to declare., (© 2024 The Authors.)

Published

2024