Your search keyword '"Replisome"' showing total 78 results

1. 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

2. 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

3. Replisome activity slowdown after exposure to ultraviolet light in Escherichia coli.

Author

Soubry, Nicolas, Andrea Wang, and Reyes-Lamothe, Rodrigo

Subjects

*DNA synthesis, *ESCHERICHIA coli, *DNA repair, *CELL imaging, *DNA damage, *DNA replication, *REPLISOMES, *ULTRAVIOLET radiation

Abstract

The replisome is a multiprotein machine that is responsible for replicating DNA. During active DNA synthesis, the replisome tightly associates with DNA. In contrast, after DNA damage, the replisome may disassemble, exposing DNA to breaks and threatening cell survival. Using live cell imaging, we studied the effect of UV light on the replisome of Escherichia coli. Surprisingly, our results showed an increase in Pol III holoenzyme (Pol III HE) foci post-UV that do not colocalize with the DnaB helicase. Formation of these foci is independent of active replication forks and dependent on the presence of the χ subunit of the clamp loader, suggesting recruitment of Pol III HE at sites of DNA repair. Our results also showed a decrease of DnaB helicase foci per cell after UV, consistent with the disassembly of a fraction of the replisomes. By labeling newly synthesized DNA, we demonstrated that a drop in the rate of synthesis is not explained by replisome disassembly alone. Instead, we show that most replisomes continue synthesizing DNA at a slower rate after UV. We propose that the slowdown in replisome activity is a strategy to prevent clashes with engaged DNA repair proteins and preserve the integrity of the replication fork. [ABSTRACT FROM AUTHOR]

Published

2019

4. Single-molecule visualization of Saccharomyces cerevisiae leading-strand synthesis reveals dynamic interaction between MTC and the replisome.

Author

Lewis, Jacob S., Spenkelink, Lisanne M., Schauer, Grant D., Hill, Flynn R., Georgescu, Roxanna E., O'donnell, Michael E., and Van Oijen, Antoine M.

Subjects

*DNA replication, *REPLISOMES, *EUKARYOTIC genomes, *SACCHAROMYCES cerevisiae, *IN vivo studies

Abstract

The replisome, the multiprotein system responsible for genome duplication, is a highly dynamic complex displaying a large number of different enzyme activities. Recently, the Saccharomyces cerevisiae minimal replication reaction has been successfully reconstituted in vitro. This provided an opportunity to uncover the enzymatic activities of many of the components in a eukaryotic system. Their dynamic behavior and interactions in the context of the replisome, however, remain unclear. We use a tethered-bead assay to provide real-time visualization of leading-strand synthesis by the S. cerevisiae replisome at the single-molecule level. The minimal reconstituted leading-strand replisome requires 24 proteins, forming the CMG helicase, the Pol ε DNA polymerase, the RFC clamp loader, the PCNA sliding clamp, and the RPA single-stranded DNA binding protein. We observe rates and product lengths similar to those obtained from ensemble biochemical experiments. At the single-molecule level, we probe the behavior of two components of the replication progression complex and characterize their interaction with active leading-strand replisomes. The Minichromosome maintenance protein 10 (Mcm10), an important player in CMG activation, increases the number of productive replication events in our assay. Furthermore, we show that the fork protection complex Mrc1-Tof1-Csm3 (MTC) enhances the rate of the leading-strand replisome threefold. The introduction of periods of fast replication by MTC leads to an average rate enhancement of a factor of 2, similar to observations in cellular studies. We observe that the MTC complex acts in a dynamic fashion with the moving replisome, leading to alternating phases of slow and fast replication. [ABSTRACT FROM AUTHOR]

Published

2017

5. Cryo-EM structure of the replisome reveals multiple interactions coordinating DNA synthesis.

Author

Kulczyk, Arkadiusz W., Moeller, Arne, Meyer, Peter, Sliz, Piotr, and Richardson, Charles C.

Subjects

*DNA synthesis, *REPLISOMES, *BACTERIOPHAGES, *DNA replication, *BIOCHEMISTRY

Abstract

We present a structure of the -650-kDa functional replisome of bacteriophage T7 assembled on DNA resembling a replication fork. A structure of the complex consisting of six domains of DNA helicase, five domains of RNA primase, two DNA polymerases, and two thioredoxin (processivity factor) molecules was determined by single-particle cryo-electron microscopy. The two molecules of DNA polymerase adopt a different spatial arrangement at the replication fork, reflecting their roles in leading- and lagging-strand synthesis. The structure, in combination with biochemical data, reveals molecular mechanisms for coordination of leading- and laggingstrand synthesis. Because mechanisms of DNA replication are highly conserved, the observations are relevant to other replication systems. [ABSTRACT FROM AUTHOR]

Published

2017

6. Quality control mechanisms exclude incorrect polymerases from the eukaryotic replication fork.

Author

Schauer, Grant D. and O'Donnell, Michael E.

Subjects

*POLYMERASES, *EUKARYOTIC cells, *EUKARYOTES, *ANTIGENS, *ENZYMES

Abstract

The eukaryotic genome is primarily replicated by two DNA polymerases, Pol ε and Pol δ, that function on the leading and lagging strands, respectively. Previous studies have established recruitment mechanisms whereby Cdc45-Mcm2-7-GINS (CMG) helicase binds Pol e and tethers it to the leading strand, and PCNA (proliferating cell nuclear antigen) binds tightly to Pol δ and recruits it to the lagging strand. The current report identifies quality control mechanisms that exclude the improper polymerase from a particular strand. We find that the replication factor C (RFC) clamp loader specifically inhibits Pol ε on the lagging strand, and CMG protects Pol ε against RFC inhibition on the leading strand. Previous studies show that Pol δ is slow and distributive with CMG on the leading strand. However, Saccharomyces cerevisiae Pol δ-PCNA is a rapid and processive enzyme, suggesting that CMG may bind and alter Pol δ activity or position it on the lagging strand. Measurements of polymerase binding to CMG demonstrate Pol ε binds CMG with a Kd value of 12 nM, but Pol δ binding CMG is undetectable. Pol δ, like bacterial replicases, undergoes collision release upon completing replication, and we propose Pol δ-PCNA collides with the slower CMG, and in the absence of a stabilizing Pol δ-CMG interaction, the collision release process is triggered, ejecting Pol δ on the leading strand. Hence, by eviction of incorrect polymerases at the fork, the clamp machinery directs quality control on the lagging strand and CMG enforces quality control on the leading strand. [ABSTRACT FROM AUTHOR]

Published

2017

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

Author

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

Subjects

Genome instability, DNA Replication, R-loop, Telomere-Binding Proteins, Genome, Biochemistry, Models, Biological, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, CRISPR-Associated Protein 9, Proliferating Cell Nuclear Antigen, Pif1, replication bypass, 030304 developmental biology, Gene Editing, 0303 health sciences, Multidisciplinary, biology, replisome, Cas9, DNA replication, Helicase, DNA, Biological Sciences, Cell biology, Biophysics and Computational Biology, chemistry, Physical Sciences, biology.protein, Replisome, single-molecule, R-Loop Structures, 030217 neurology & neurosurgery, Protein Binding, RNA, Guide, Kinetoplastida

Abstract

Significance The replisome machine that duplicates the DNA genome encounters a variety of blocks to replication, such as DNA bound proteins, R-loops, and DNA lesions. Studies in bacterial systems demonstrate that replisome advance through blocks is facilitated by an accessory monomeric helicase that acts on the opposite strand from the replicative hexameric helicase. This report examines this issue in a eukaryotic system, using Pif1, a monomeric helicase that acts on the opposite strand from the replicative CMG helicase. The report shows that an inactive “dead” Cas9 (dCas9) protein R-loop block arrests the replisome, but Pif1 enables replisome bypass of the dCas9 R-loop block. Hence, use of monomeric helicases may have evolved to aid replisome bypass of protein-DNA and protein-bound R-loop blocks., 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 single-molecule 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.

Published

2020

8. Primer release is the rate-limiting event in laggingstrand synthesis mediated by the T7 replisome.

Author

Hernandez, Alfredo J., Seung-Joo Lee, and Richardson, Charles C.

Subjects

*REPLISOMES, *DNA replication, *DNA synthesis, *DNA polymerases, *CARRIER proteins

Abstract

DNA replication occurs semidiscontinuously due to the antiparallel DNA strands and polarity of enzymatic DNA synthesis. Although the leading strand is synthesized continuously, the lagging strand is synthesized in small segments designated Okazaki fragments. Lagging-strand synthesis is a complex event requiring repeated cycles of RNA primer synthesis, transfer to the lagging-strand polymerase, and extension effected by cooperation between DNA primase and the lagging-strand polymerase. We examined events controlling Okazaki fragment initiation using the bacteriophage T7 replication system. Primer utilization by T7 DNA polymerase is slower than primer formation. Slow primer release from DNA primase allows the polymerase to engage the complex and is followed by a slow primer handoff step. The T7 single-stranded DNA binding protein increases primer formation and extension efficiency but promotes limited rounds of primer extension. We present a model describing Okazaki fragment initiation, the regulation of fragment length, and their implications for coordinated leading- and lagging-strand DNA synthesis. [ABSTRACT FROM AUTHOR]

Published

2016

9. Nonrandom segregation of sister chromosomes by Escherichia coli MukBEF

Author

Stephan Uphoff, Jarno Mäkelä, and David J. Sherratt

Subjects

Chromosomal Proteins, Non-Histone, Biology, DNA replication, Origin of replication, Chromosome segregation, chemistry.chemical_compound, Chromosome Segregation, Escherichia coli, Nucleoid, Genetics, Multidisciplinary, SMC, Escherichia coli Proteins, Inheritance (genetic algorithm), Chromosome, Cell Biology, Gene Expression Regulation, Bacterial, Biological Sciences, MatP, chromosome organization, Repressor Proteins, chemistry, MukBEF, Replisome, DNA, Gene Deletion

Abstract

Significance Circular chromosomes in rod-shaped bacteria exist inside a cell in two distinct configurations, “transverse” and “longitudinal,” relative to the long cell axis, with chromosomal loci occupying specific cellular locations in both cases. Bacteria with longitudinal chromosome organization (e.g., Caulobacter crescentus) typically tether their origins of replication to the cell membrane and do not undergo overlapping rounds of replication. In contrast, bacteria with transverse organization (e.g., Escherichia coli) orient their chromosomes by an unknown mechanism and have lifestyles compatible with overlapping rounds of replication. Here, we address the relative roles of two major players in chromosome organization–segregation and propose a model of how E. coli maintains chromosome conformation and orientation inside cells and how this organization is propagated over generations., Structural maintenance of chromosomes (SMC) complexes contribute to chromosome organization in all domains of life. In Escherichia coli, MukBEF, the functional SMC homolog, promotes spatiotemporal chromosome organization and faithful chromosome segregation. Here, we address the relative contributions of MukBEF and the replication terminus (ter) binding protein, MatP, to chromosome organization–segregation. We show that MukBEF, but not MatP, is required for the normal localization of the origin of replication to midcell and for the establishment of translational symmetry between newly replicated sister chromosomes. Overall, chromosome orientation is normally maintained through division from one generation to the next. Analysis of loci flanking the replication termination region (ter), which demark the ends of the linearly organized portion of the nucleoid, demonstrates that MatP is required for maintenance of chromosome orientation. We show that DNA-bound β2-processivity clamps, which mark the lagging strands at DNA replication forks, localize to the cell center, independent of replisome location but dependent on MukBEF action, and consistent with translational symmetry of sister chromosomes. Finally, we directly show that the older (“immortal”) template DNA strand, propagated from previous generations, is preferentially inherited by the cell forming at the old pole, dependent on MukBEF and MatP. The work further implicates MukBEF and MatP as central players in chromosome organization, segregation, and nonrandom inheritance of genetic material and suggests a general framework for understanding how chromosome conformation and dynamics shape subcellular organization.

Published

2021

10. The circadian clock ensures successful DNA replication in cyanobacteria

Author

Michael J. Rust and Yi Liao

Subjects

DNA Replication, Photoperiod, Circadian clock, ved/biology.organism_classification_rank.species, Biology, Genome, Microbiology, cyanobacteria, Bacterial Proteins, Circadian Clocks, circadian clock, Computer Simulation, Circadian rhythm, Model organism, Synechococcus, Multidisciplinary, Models, Statistical, ved/biology, Cell Cycle, DNA replication, mathematical modeling, Gene Expression Regulation, Bacterial, Cell cycle, Biological Sciences, Replication (computing), Cell biology, Circadian Rhythm, Replisome

Abstract

Significance Cyanobacteria, which are reliant on photosynthesis for growth, face a fundamental challenge. Replicating the genome takes hours, so the decision to initiate replication must be made at time when conditions may be quite different from the future state of the environment when replication is due to complete. We found that cyanobacteria use their circadian clock to ensure that DNA replication finishes efficiently, both by scheduling initiation early in the day and by directing the accumulation of metabolic resources that support ongoing replication after nightfall. When these circadian protections are removed, replication fails to complete. This study connects genome replication to the ability of a circadian clock to anticipate environmental changes., Disruption of circadian rhythms causes decreased health and fitness, and evidence from multiple organisms links clock disruption to dysregulation of the cell cycle. However, the function of circadian regulation for the essential process of DNA replication remains elusive. Here, we demonstrate that in the cyanobacterium Synechococcus elongatus, a model organism with the simplest known circadian oscillator, the clock generates rhythms in DNA replication to minimize the number of open replication forks near dusk that would have to complete after sunset. Metabolic rhythms generated by the clock ensure that resources are available early at night to support any remaining replication forks. Combining mathematical modeling and experiments, we show that metabolic defects caused by clock–environment misalignment result in premature replisome disassembly and replicative abortion in the dark, leaving cells with incomplete chromosomes that persist through the night. Our study thus demonstrates that a major function of this ancient clock in cyanobacteria is to ensure successful completion of genome replication in a cycling environment.

Published

2021

11. Molecular interactions in the priming complex of bacteriophage T7.

Author

Kulczyk, Arkadiusz W. and Richardson, Charles C.

Subjects

*BACTERIOPHAGES, *DNA polymerases, *PROTEIN-protein interactions, *PROTEIN binding, *RIBONUCLEOSIDES, *DNA synthesis, *DNA replication

Abstract

The lagging-strand DNA polymerase requires an oligoribonucleo-tide, synthesized by DNA primase, to initiate the synthesis of an Okazaki fragment. In the replication system of bacteriophage T7 both DNA primase and DNA helicase activities are contained within a single protein, the afunctional gene 4 protein (gp4). Intermole-cular interactions between gp4 and T7 DNA polymerase are crucial for the stabilization of the oligoribonucleotide, its transfer to the polymerase, and its extension by DNA polymerase. We have identified conditions necessary to assemble the T7 priming complex and characterized its biophysical properties using fluorescence aniso-tropy. In order to reveal molecular interactions that occur during delivery of the oligoribonucleotide to DNA polymerase, we have used four genetically altered gp4 to demonstrate that both the RNA polymerase and the zinc-finger domains of DNA primase are involved in the stabilization of the priming complex and in sequence recognition in the DNA template. We find that the helicase domain of gp4 contributes to the stability of the complex by binding to the ssDNA template. The C-terminal tail of gp4 is not required for complex formation. [ABSTRACT FROM AUTHOR]

Published

2012

12. Insights into eukaryotic DNA priming from the structure and functional interactions of the 4Fe-4S cluster domain of human DNA primasea.

Author

VaithiyaIingam, Sivaraja, Warren, Eric M., Eichman, Brandt F., and Chazin, Walter J.

Subjects

*DNA replication, *EUKARYOTIC cells, *DNA primers, *X-ray crystallography, *ANISOTROPY, *NUCLEAR magnetic resonance, *MUTAGENESIS

Abstract

DNA replication requires priming of DNA templates by enzymes known as primases. Although DNA primase structures are available from archaea and bacteria, the mechanism of DNA priming in higher eukaryotes remains poorly understood in large part due to the absence of the structure of the unique, highly conserved C-terminal regulatory domain of the large subunit (p58C). Here, we present the structure of this domain determined to 1.7-A resolution by X-ray crystallography. The p58C structure reveals a novel arrangement of an evolutionarily conserved 4Fe-4S cluster buried deeply within the protein core and is not similar to any known protein structure. Analysis of the binding of DNA to p58C by fluorescence anisotropy measurements revealed a strong preference for ss/ dsDNA junction substrates. This approach was combined with site-directed mutagenesis to confirm that the binding of DNA occurs to a distinctively basic surface on p58C. A specific interaction of p58C with the C-terminal domain of the intermediate subunit of replication protein A (RPA32C) was identified and characterized by isothermal titration calorimetry and NMR. Restraints frorn NMR experiments were used to drive computational docking of the two domains and generate a model of the p58C-RPA32C complex. Together, our results explain functional defects in human DNA primase mutants and provide insights into primosome loading on RPA-coated 55DNA and regulation of primase activity. [ABSTRACT FROM AUTHOR]

Published

2010

13. Real-time observation of bacteriophage T4 gp41 helicase reveals an unwinding mechanism.

Author

Lionnet, Timothée, Spiering, Michelle M., Benkovic, Stephen J., Bensimon, David, and Croquette, Vincent

Subjects

*BACTERIOPHAGE T4, *DNA helicases, *NUCLEIC acids, *DNA replication, *CHROMOSOMAL translocation, *CHROMOSOMES

Abstract

Helicases are enzymes that couple ATP hydrolysis to the unwinding of double-stranded (ds) nucleic acids. The bacteriophage T4 helicase (gp41) is a hexameric helicase that promotes DNA replication within a highly coordinated protein complex termed the replisome. Despite recent progress, the gp41 unwinding mechanism and regulatory interactions within the replisome remain unclear. Here we use a single tethered DNA hairpin as a real-time reporter of gp41-mediated dsDNA unwinding and single-stranded (ss) DNA translocation with 3-base pair (bp) resolution. Although gp41 translocates on ssDNA as fast as the in vivo replication fork (≈400 bp/s). its unwinding rate extrapolated to zero force is much slower (≈30 bp/s). Together, our results have two implications: first, gp41 unwinds DNA through a passive mechanism; second, this weak helicase cannot efficiently unwind the T4 genome alone. Our results suggest that important regulations occur within the replisome to achieve rapid and processive replication. [ABSTRACT FROM AUTHOR]

Published

2007

14. Exchange of DNA polymerases at the replication fork of bacteriophage 17.

Author

Johnson, Donald E., Takahashi, Masateru, Hamdan, Samir M., Seung-Joo Lee, and Richardson, Charles C.

Subjects

*DNA polymerases, *BIOSYNTHESIS, *ESCHERICHIA coli, *AMINO acid synthesis, *POLYMERASE chain reaction, *TYROSINE

Abstract

T7 gene 5 DNA polymerase (gp5) and its processivity factor, Escherichia coli thioredoxin, together with the T7 gene 4 DNA helicase, catalyze strand displacement synthesis on duplex DNA processively (>17,000 nucleotides per binding event). The processive DNA synthesis is resistant to the addition of a DNA trap. However, when the polymerase-thioredoxin complex actively synthesizing DNA is challenged with excess DNA polymerase-thioredoxin exchange occurs readily. The exchange can be monitored by the use of a genetically altered T7 DNA polymerase (gp5-Y526F) in which tyrosine-526 is replaced with phenylalanine. DNA synthesis catalyzed by gp5-Y526F is resistant to inhibition by chain-terminating dideoxynucleotides because gp5-Y526F is deficient in the incorporation of these analogs relative to the wild-type enzyme. The exchange also occurs during coordinated DNA synthesis in which leading- and lagging-strand synthesis occur at the same rate. On 55DNA templates with the T7 DNA polymerase alone, such exchange is not evident, suggesting that free polymerase is first recruited to the replisome by means of T7 gene 4 helicase. The ability to exchange DNA polymerases within the replisome without affecting processivity provides advantages for fidelity as well as the cycling of the polymerase from a completed Okazaki fragment to a new primer on the lagging strand. [ABSTRACT FROM AUTHOR]

Published

2007

15. Replication is required for the RecA localization response to DNA damage in Bacillus subtilis.

Author

Simmons, Lyle A., Grossman, Alan D., and Walker, Graham C.

Subjects

*BACILLUS subtilis, *DNA replication, *PROKARYOTES, *DNA repair, *ENDONUCLEASES, *DNA damage

Abstract

In both prokaryotes and eukaryotes. proteins involved in DNA repair often organize into multicomponent complexes that can be visualized as foci in living cells. We used a RecA-GFP fusion to examine the subcellular cues that direct RecA-GFP to assemble as foci in response to DNA damage. We used two different methods to inhibit initiation of DNA replication and determined that DNA replication is required for the cell to establish RecA-GFP foci after exposure to DNA-damaging agents. Furthermore, use of endonuclease cleavage to generate a site-specific double-strand break demonstrated that the replication machinery (replisome) and DNA synthesis are required for assembly of RecA-GFP foci during repair of a double-strand break. We monitored the cellular levels of RecA and found that focus formation does not require further induction of protein levels, suggesting that foci result from a redistribution of existing protein to sites of damage encountered by the replisome. Taken together, our results support the model that existing RecA protein is recruited to ssDNA generated by the replisome at sites of DNA damage. These results provide insight into the mechanisms that the cell uses to recruit repair proteins to damaged DNA in living cells. [ABSTRACT FROM AUTHOR]

Published

2007

16. Architecture of the bacteriophage T4 primosome: Electron microscopy studies of helicase (gp41) and primase (gp61).

Author

Norcum, Mona T., Warrington, J. Anthony, Spiering, Michelle M., Ishmael, Faoud T., Trakselis, Michael A., and Benkovic, Stephen J.

Subjects

*DNA replication, *BACTERIOPHAGE T4, *ELECTRON microscopy, *DNA helicases, *DNA, *MONOMERS

Abstract

Replication of DNA requires helicase and primase activities as part of a primosome assembly. In bacteriophage T4, helicase and primase are separate polypeptides for which little structural information is available and whose mechanism of association within the primosome is not yet understood. Three-dimensional structural information is provided here by means of reconstructions from electron microscopic images. Structures have been calculated for complexes of each of these proteins with ssDNA in the presence of MgATPyS. Both the helicase (gp41) and primase (gp61) complexes are asymmetric hexagonal rings. The gp41 structure suggests two distinct forms that have been termed "open" and "closed." The gp61 structure is clearly a six-membered ring, which may be a trimer of dimers or a traditional hexamer of monomers. This structure provides conclusive evidence for an oligomeric primase- to-ssDNA stoichiometry of 6:1. [ABSTRACT FROM AUTHOR]

Published

2005

17. Pivotal roles of PCNA loading and unloading in heterochromatin function

Author

Martin Kupiec, Ryan Janke, Grant A King, and Jasper Rine

Subjects

0301 basic medicine, DNA Replication, Saccharomyces cerevisiae Proteins, Nucleosome assembly, Transcription, Genetic, Heterochromatin, 1.1 Normal biological development and functioning, Elg1, Saccharomyces cerevisiae, Biology, nucleosome assembly, S Phase, Histones, 03 medical and health sciences, Open Reading Frames, 0302 clinical medicine, Ribonucleases, Genetic, Underpinning research, Gene Expression Regulation, Fungal, Proliferating Cell Nuclear Antigen, Genetics, PCNA, Gene silencing, Gene Silencing, CAF-1, Genome, Multidisciplinary, fungi, DNA replication, Chromatin, Cell biology, Proliferating cell nuclear antigen, Fungal, 030104 developmental biology, Gene Expression Regulation, PNAS Plus, biology.protein, Replisome, Genome, Fungal, Carrier Proteins, Transcription, 030217 neurology & neurosurgery, Gene Deletion, Plasmids

Abstract

In Saccharomyces cerevisiae, heterochromatin structures required for transcriptional silencing of the HML and HMR loci are duplicated in coordination with passing DNA replication forks. Despite major reorganization of chromatin structure, the heterochromatic, transcriptionally silent states of HML and HMR are successfully maintained throughout S-phase. Mutations of specific components of the replisome diminish the capacity to maintain silencing of HML and HMR through replication. Similarly, mutations in histone chaperones involved in replication-coupled nucleosome assembly reduce gene silencing. Bridging these observations, we determined that the proliferating cell nuclear antigen (PCNA) unloading activity of Elg1 was important for coordinating DNA replication forks with the process of replication-coupled nucleosome assembly to maintain silencing of HML and HMR through S-phase. Collectively, these data identified a mechanism by which chromatin reassembly is coordinated with DNA replication to maintain silencing through S-phase.

Published

2018

18. Structure of eukaryotic CMG helicase at a replication fork and implications to replisome architecture and origin initiation

Author

Huilin Li, Jingchuan Sun, Olga Yurieva, Lin Bai, Ruda de Luna Almeida Santos, Mike O'Donnell, Dan Zhang, Zuanning Yuan, and Roxana E. Georgescu

Subjects

0301 basic medicine, DNA Replication, Models, Molecular, Saccharomyces cerevisiae Proteins, DNA polymerase, Protein Conformation, education, DNA, Single-Stranded, Replication Origin, Fork (software development), 03 medical and health sciences, chemistry.chemical_compound, health services administration, A-DNA, health care economics and organizations, Genetics, Multidisciplinary, biology, Minichromosome Maintenance Proteins, DNA replication, Helicase, Nuclear Proteins, GINS, Cell biology, DNA-Binding Proteins, 030104 developmental biology, chemistry, PNAS Plus, biology.protein, Replisome, DNA

Abstract

The eukaryotic CMG (Cdc45, Mcm2–7, GINS) helicase consists of the Mcm2–7 hexameric ring along with five accessory factors. The Mcm2–7 heterohexamer, like other hexameric helicases, is shaped like a ring with two tiers, an N-tier ring composed of the N-terminal domains, and a C-tier of C-terminal domains; the C-tier contains the motor. In principle, either tier could translocate ahead of the other during movement on DNA. We have used cryo-EM single-particle 3D reconstruction to solve the structure of CMG in complex with a DNA fork. The duplex stem penetrates into the central channel of the N-tier and the unwound leading single-strand DNA traverses the channel through the N-tier into the C-tier motor, 5′-3′ through CMG. Therefore, the N-tier ring is pushed ahead by the C-tier ring during CMG translocation, opposite the currently accepted polarity. The polarity of the N-tier ahead of the C-tier places the leading Pol e below CMG and Pol α-primase at the top of CMG at the replication fork. Surprisingly, the new N-tier to C-tier polarity of translocation reveals an unforeseen quality-control mechanism at the origin. Thus, upon assembly of head-to-head CMGs that encircle double-stranded DNA at the origin, the two CMGs must pass one another to leave the origin and both must remodel onto opposite strands of single-stranded DNA to do so. We propose that head-to-head motors may generate energy that underlies initial melting at the origin.

Published

2017

19. Archaeal orthologs of Cdc45 and GINS form a stable complex that stimulates the helicase activity of MCM

Author

Yuli Xu, Tamzin Gristwood, Jonathan C. Trinidad, Sonja-Verena Albers, Stephen D. Bell, and Ben Hodgson

Subjects

0301 basic medicine, Chromosomal Proteins, Non-Histone, Archaeal Proteins, Cell Cycle Proteins, Evolution, Molecular, 03 medical and health sciences, 0302 clinical medicine, Minichromosome maintenance, parasitic diseases, Helicase activity, Genetics, Multidisciplinary, biology, Manchester Cancer Research Centre, Minichromosome Maintenance Proteins, ResearchInstitutes_Networks_Beacons/mcrc, Helicase, Biological Sciences, Archaea, GINS, 030104 developmental biology, Multiprotein Complexes, biology.protein, Replisome, 030217 neurology & neurosurgery, Function (biology), Protein Binding

Abstract

The regulated recruitment of Cdc45 and GINS is key to activating the eukaryotic MCM(2-7) replicative helicase. We demonstrate that the homohexameric archaeal MCM helicase associates with orthologs of GINS and Cdc45 in vivo and in vitro. Association of these factors with MCM robustly stimulates the MCM helicase activity. In contrast to the situation in eukaryotes, archaeal Cdc45 and GINS form an extremely stable complex before binding MCM. Further, the archaeal GINS•Cdc45 complex contains two copies of Cdc45. Our analyses give insight into the function and evolution of the conserved core of the archaeal/eukaryotic replisome.

Published

2016

20. Single-molecule motions and interactions in live cells reveal target search dynamics in mismatch repair

Author

Jeremy W. Schroeder, Burke Gao, Julie S. Biteen, Lyle A. Simmons, and Yi Liao

Subjects

Genetics, DNA Replication, DNA, Bacterial, congenital, hereditary, and neonatal diseases and abnormalities, education.field_of_study, Multidisciplinary, DNA clamp, DNA Repair, MutS DNA Mismatch-Binding Protein, Base Pair Mismatch, Population, DNA replication, Biology, Commentaries, MutS-1, Biophysics, Replisome, DNA mismatch repair, Single-Cell Analysis, education, Bacillus subtilis

Abstract

MutS is responsible for initiating the correction of DNA replication errors. To understand how MutS searches for and identifies rare base-pair mismatches, we characterized the dynamic movement of MutS and the replisome in real time using superresolution microscopy and single-molecule tracking in living cells. We report that MutS dynamics are heterogeneous in cells, with one MutS population exploring the nucleoid rapidly, while another MutS population moves to and transiently dwells at the replisome region, even in the absence of appreciable mismatch formation. Analysis of MutS motion shows that the speed of MutS is correlated with its separation distance from the replisome and that MutS motion slows when it enters the replisome region. We also show that mismatch detection increases MutS speed, supporting the model for MutS sliding clamp formation after mismatch recognition. Using variants of MutS and the replication processivity clamp to impair mismatch repair, we find that MutS dynamically moves to and from the replisome before mismatch binding to scan for errors. Furthermore, a block to DNA synthesis shows that MutS is only capable of binding mismatches near the replisome. It is well-established that MutS engages in an ATPase cycle, which is necessary for signaling downstream events. We show that a variant of MutS with a nucleotide binding defect is no longer capable of dynamic movement to and from the replisome, showing that proper nucleotide binding is critical for MutS to localize to the replisome in vivo. Our results provide mechanistic insight into the trafficking and movement of MutS in live cells as it searches for mismatches.

Published

2015

21. Plasmid replication initiator interactions with origin 13-mers and polymerase subunits contribute to strand-specific replisome assembly

Author

Aleksandra Wawrzycka, Anna Wasaznik, Marta Gross, and Igor Konieczny

Subjects

DNA Replication, Replication Origin, DNA-Directed DNA Polymerase, Biology, Pre-replication complex, Replication factor C, Minichromosome maintenance, Multienzyme Complexes, Escherichia coli, Genetics, Adenosine Triphosphatases, Multidisciplinary, Circular Dichroism, Escherichia coli Proteins, DNA replication, Templates, Genetic, DnaA, Cell biology, Protein Subunits, Nucleoproteins, PNAS Plus, Prokaryotic DNA replication, Origin recognition complex, Replisome, Mutant Proteins, DnaB Helicases, Plasmids, Protein Binding

Abstract

Although the molecular basis for replisome activity has been extensively investigated, it is not clear what the exact mechanism for de novo assembly of the replication complex at the replication origin is, or how the directionality of replication is determined. Here, using the plasmid RK2 replicon, we analyze the protein interactions required for Escherichia coli polymerase III (Pol III) holoenzyme association at the replication origin. Our investigations revealed that in E. coli, replisome formation at the plasmid origin involves interactions of the RK2 plasmid replication initiation protein (TrfA) with both the polymerase β- and α-subunits. In the presence of other replication proteins, including DnaA, helicase, primase and the clamp loader, TrfA interaction with the β-clamp contributes to the formation of the β-clamp nucleoprotein complex on origin DNA. By reconstituting in vitro the replication reaction on ssDNA templates, we demonstrate that TrfA interaction with the β-clamp and sequence-specific TrfA interaction with one strand of the plasmid origin DNA unwinding element (DUE) contribute to strand-specific replisome assembly. Wild-type TrfA, but not the TrfA QLSLF mutant (which does not interact with the β-clamp), in the presence of primase, helicase, Pol III core, clamp loader, and β-clamp initiates DNA synthesis on ssDNA template containing 13-mers of the bottom strand, but not the top strand, of DUE. Results presented in this work uncovered requirements for anchoring polymerase at the plasmid replication origin and bring insights of how the directionality of DNA replication is determined.

Published

2015

22. Archaeal replicative primases can perform translesion DNA synthesis

Author

Aidan J. Doherty, Stanislaw K. Jozwiakowski, and Farimah Borazjani Gholami

Subjects

Genetics, Genome instability, Multidisciplinary, DNA repair, DNA damage, DNA replication, Eukaryotic DNA replication, DNA Primase, Biology, Archaea, Cell biology, Oxidative Stress, DNA, Archaeal, Control of chromosome duplication, PNAS Plus, Biocatalysis, Replisome, Primase, DNA Damage

Abstract

DNA replicases routinely stall at lesions encountered on the template strand, and translesion DNA synthesis (TLS) is used to rescue progression of stalled replisomes. This process requires specialized polymerases that perform translesion DNA synthesis. Although prokaryotes and eukaryotes possess canonical TLS polymerases (Y-family Pols) capable of traversing blocking DNA lesions, most archaea lack these enzymes. Here, we report that archaeal replicative primases (Pri S, primase small subunit) can also perform TLS. Archaeal Pri S can bypass common oxidative DNA lesions, such as 8-Oxo-2'-deoxyguanosines and UV light-induced DNA damage, faithfully bypassing cyclobutane pyrimidine dimers. Although it is well documented that archaeal replicases specifically arrest at deoxyuracils (dUs) due to recognition and binding to the lesions, a replication restart mechanism has not been identified. Here, we report that Pri S efficiently replicates past dUs, even in the presence of stalled replicase complexes, thus providing a mechanism for maintaining replication bypass of these DNA lesions. Together, these findings establish that some replicative primases, previously considered to be solely involved in priming replication, are also TLS proficient and therefore may play important roles in damage tolerance at replication forks.

Published

2015

23. Fate of the replisome following arrest by UV-induced DNA damage in Escherichia coli

Author

H. Arthur Jeiranian, Justin Courcelle, Charmain T. Courcelle, and Brandy J. Schalow

Subjects

DNA, Bacterial, Multidisciplinary, DNA damage, Ultraviolet Rays, DNA replication, Biology, Biological Sciences, Molecular biology, Cell biology, DnaG, chemistry.chemical_compound, chemistry, biology.protein, Biocatalysis, Escherichia coli, Replisome, Replication fork processing, dnaB helicase, DNA, Polymerase, DNA Damage

Abstract

Accurate replication in the presence of DNA damage is essential to genome stability and viability in all cells. In Escherichia coli , DNA replication forks blocked by UV-induced damage undergo a partial resection and RecF-catalyzed regression before synthesis resumes. These processing events generate distinct structural intermediates on the DNA that can be visualized in vivo using 2D agarose gels. However, the fate and behavior of the stalled replisome remains a central uncharacterized question. Here, we use thermosensitive mutants to show that the replisome’s polymerases uncouple and transiently dissociate from the DNA in vivo. Inactivation of α, β, or τ subunits within the replisome is sufficient to signal and induce the RecF-mediated processing events observed following UV damage. By contrast, the helicase–primase complex (DnaB and DnaG) remains critically associated with the fork, leading to a loss of fork integrity, degradation, and aberrant intermediates when disrupted. The results reveal a dynamic replisome, capable of partial disassembly to allow access to the obstruction, while retaining subunits that maintain fork licensing and direct reassembly to the appropriate location after processing has occurred.

Published

2013

24. Properties of the human Cdc45/Mcm2-7/GINS helicase complex and its action with DNA polymerase epsilon in rolling circle DNA synthesis

Author

Wiebke Chemnitz Galal, Young-Hoon Kang, Jerard Hurwitz, Inger Tappin, and Andrea Farina

Subjects

Chromosomal Proteins, Non-Histone, DNA polymerase II, Blotting, Western, Oligonucleotides, Origin Recognition Complex, DNA, Single-Stranded, Cell Cycle Proteins, Electrophoretic Mobility Shift Assay, Biology, Spodoptera, DNA polymerase delta, Cell Line, Substrate Specificity, Adenosine Triphosphate, Animals, Humans, Replication protein A, dnaB helicase, Multidisciplinary, CMG complex, DNA clamp, DNA Helicases, Nuclear Proteins, Minichromosome Maintenance Complex Component 2, DNA, DNA Polymerase II, Biological Sciences, Chromatin, Cell biology, Kinetics, HEK293 Cells, Biochemistry, biology.protein, Replisome, Nucleic Acid Conformation, Primase, HeLa Cells, Protein Binding

Abstract

In eukaryotes, although the Mcm2-7 complex is a key component of the replicative DNA helicase, its association with Cdc45 and GINS (the CMG complex) is required for the activation of the DNA helicase. Here, we show that the CMG complex is localized to chromatin in human cells and describe the biochemical properties of the human CMG complex purified from baculovirus-infected Sf9 cells. The isolated complex binds to ssDNA regions in the presence of magnesium and ATP (or a nonhydrolyzable ATP analog), contains maximal DNA helicase in the presence of forked DNA structures, and translocates along the leading strand (3′ to 5′ direction). The complex hydrolyses ATP in the absence of DNA; unwinds duplex regions up to 500 bp; and either replication protein A or Escherichia coli single stranded binding protein increases the efficiency of displacement of long duplex regions. Using a 200-nt primed circular DNA substrate, the combined action of human DNA polymerase ε and the human CMG complex leads to the formation of products >10 kb in length. These findings suggest that the coordinated action of these replication complexes supports leading strand synthesis.

Published

2012

25. Architecture of the DNA polymerase B-proliferating cell nuclear antigen (PCNA)-DNA ternary complex

Author

Daisuke Kohda, Shinichi Kiyonari, Hirokazu Nishida, Tsuyoshi Shirai, Kosuke Morikawa, Yoshizumi Ishino, Kouta Mayanagi, and Mihoko Saito

Subjects

Models, Molecular, Multidisciplinary, DNA clamp, Pyrococcus, biology, DNA polymerase, DNA polymerase II, DNA replication, Glutamic Acid, Eukaryotic DNA replication, DNA, Biological Sciences, DNA polymerase delta, Cell biology, Microscopy, Electron, Replication factor C, Biochemistry, Proliferating Cell Nuclear Antigen, biology.protein, Replisome, Streptavidin, DNA Polymerase beta

Abstract

DNA replication in archaea and eukaryotes is executed by family B DNA polymerases, which exhibit full activity when complexed with the DNA clamp, proliferating cell nuclear antigen (PCNA). This replication enzyme consists of the polymerase and exonuclease moieties responsible for DNA synthesis and editing (proofreading), respectively. Because of the editing activity, this enzyme ensures the high fidelity of DNA replication. However, it remains unclear how the PCNA-complexed enzyme temporally switches between the polymerizing and editing modes. Here, we present the three-dimensional structure of the Pyrococcus furiosus DNA polymerase B-PCNA-DNA ternary complex, which is the core component of the replisome, determined by single particle electron microscopy of negatively stained samples. This structural view, representing the complex in the editing mode, revealed the whole domain configuration of the trimeric PCNA ring and the DNA polymerase, including protein–protein and protein–DNA contacts. Notably, besides the authentic DNA polymerase-PCNA interaction through a PCNA-interacting protein (PIP) box, a novel contact was found between DNA polymerase and the PCNA subunit adjacent to that with the PIP contact. This contact appears to be responsible for the configuration of the complex specific for the editing mode. The DNA was located almost at the center of PCNA and exhibited a substantial and particular tilt angle against the PCNA ring plane. The obtained molecular architecture of the complex, including the new contact found in this work, provides clearer insights into the switching mechanism between the two distinct modes, thus highlighting the functional significance of PCNA in the replication process.

Published

2011

26. The DNA-gate of Bacillus subtilis gyrase is predominantly in the closed conformation during the DNA supercoiling reaction

Author

Airat Gubaev, Manuel Hilbert, and Dagmar Klostermeier

Subjects

DNA, Bacterial, Models, Molecular, HMG-box, Biology, DNA gyrase, Phosphates, Substrate Specificity, chemistry.chemical_compound, Topoisomerase II Inhibitors, Enzyme Inhibitors, Multidisciplinary, DNA, Superhelical, Circular bacterial chromosome, Biological Sciences, chemistry, Biochemistry, DNA Gyrase, Biophysics, DNA supercoil, Replisome, Nucleic Acid Conformation, Topoisomerase-II Inhibitor, Type II topoisomerase, DNA, Bacillus subtilis, Plasmids, Protein Binding

Abstract

Gyrase is the only type II topoisomerase that introduces negative supercoils into DNA. Supercoiling is catalyzed via a strand-passage mechanism, in which the gate DNA (gDNA) is transiently cleaved, and a second DNA segment, the transfer DNA (tDNA), is passed through the gap before the gDNA is religated. Strand passage requires an opening of the so-called DNA-gate by ≈2 nm. A single-molecule FRET study reported equal populations of open and closed DNA-gate in topoisomerase II. We present here single-molecule FRET experiments that monitor the conformation of DNA bound to the DNA-gate of Bacillus subtilis gyrase and the conformation of the DNA-gate itself. DNA bound to gyrase adopts two different conformations, one slightly, one severely distorted. DNA distortion requires cleavage, but neither ATP nor the presence of a tDNA. At the same time, the DNA-gate of gyrase is predominantly in the closed conformation. In agreement with the single molecule data and with the danger of dsDNA breaks for genome integrity, B. subtilis gyrase, but disfavor DNA distortion, and the DNA-gate remains in the closed conformation. Our results demonstrate that DNA binding, distortion and cleavage, and gate-opening are mechanistically distinct events. During the relaxation and supercoiling reactions, gyrase with an open DNA-gate is not significantly populated, consistent with gate-opening as a very rare event that only occurs briefly to allow for strand passage.

Published

2009

27. Single-molecule analysis reveals that the lagging strand increases replisome processivity but slows replication fork progression

Author

Jeff Finkelstein, Roxana E. Georgescu, Mike O'Donnell, and Nina Y. Yao

Subjects

Genetics, DNA Replication, Multidisciplinary, DNA clamp, Okazaki fragments, DNA polymerase II, Lipid Bilayers, Processivity, DNA-Directed DNA Polymerase, Biology, Biological Sciences, DNA polymerase delta, DnaG, Diffusion, Prokaryotic DNA replication, Multienzyme Complexes, biology.protein, Biophysics, Escherichia coli, Replisome, DNA, Circular, DnaB Helicases, DNA Polymerase III

Abstract

Single-molecule techniques are developed to examine mechanistic features of individual E. coli replisomes during synthesis of long DNA molecules. We find that single replisomes exhibit constant rates of fork movement, but the rates of different replisomes vary over a surprisingly wide range. Interestingly, lagging strand synthesis decreases the rate of the leading strand, suggesting that lagging strand operations exert a drag on replication fork progression. The opposite is true for processivity. The lagging strand significantly increases the processivity of the replisome, possibly reflecting the increased grip to DNA provided by 2 DNA polymerases anchored to sliding clamps on both the leading and lagging strands.

Published

2009

28. Mrc1 phosphorylation in response to DNA replication stress is required for Mec1 accumulation at the stalled fork

Author

Ju-mei Li, Alexander J. Osborn, Maria L. Naylor, and Stephen J. Elledge

Subjects

DNA Replication, Multidisciplinary, Saccharomyces cerevisiae Proteins, DNA replication, Intracellular Signaling Peptides and Proteins, Nuclear Proteins, Eukaryotic DNA replication, Cell Cycle Proteins, Biology, Protein Serine-Threonine Kinases, Biological Sciences, Pre-replication complex, Cell biology, S Phase, DNA-Binding Proteins, Checkpoint Kinase 2, Replication factor C, Control of chromosome duplication, Stress, Physiological, Replisome, Origin recognition complex, Phosphorylation, S phase

Abstract

DNA replication stress activates a response pathway that stabilizes stalled forks and promotes the completion of replication. The budding yeast Mec1 sensor kinase, Mrc1 mediator, and Rad53 effector kinase are central to this signal transduction cascade in S phase. We report that Mec1-dependent, Rad53-independent phosphorylation of Mrc1 is required to establish a positive feedback loop that stabilizes Mec1 and the replisome at stalled forks. A structure–function analysis of Mrc1 also uncovered a central region required for proper mediator function and association with replisome components. Together these results reveal new insight into how Mrc1 facilitates checkpoint signal amplification at stalled replication forks.

Published

2009

29. Structure of PolC reveals unique DNA binding and fidelity determinants

Author

Thale C. Jarvis, Douglas R. Davies, Louis S. Green, Janice D. Pata, Wendy Ribble, Nebojsa Janjic, Jeffrey Christensen, James M. Bullard, Joseph Guiles, and Ronald J. Evans

Subjects

DNA polymerase, Base pair, Amino Acid Motifs, DNA-Directed DNA Polymerase, Crystallography, X-Ray, chemistry.chemical_compound, Structure-Activity Relationship, Bacterial Proteins, Catalytic Domain, Protein Structure, Quaternary, Ternary complex, Bacillaceae, Polymerase, Genetics, Multidisciplinary, biology, DNA replication, Biological Sciences, Protein Structure, Tertiary, chemistry, biology.protein, Commentary, Replisome, Proofreading, DNA, Genome, Bacterial

Abstract

PolC is the polymerase responsible for genome duplication in many Gram-positive bacteria and represents an attractive target for antibacterial development. We have determined the 2.4-Å resolution crystal structure of Geobacillus kaustophilus PolC in a ternary complex with DNA and dGTP. The structure reveals nascent base pair interactions that lead to highly accurate nucleotide incorporation. A unique β-strand motif in the PolC thumb domain contacts the minor groove, allowing replication errors to be sensed up to 8 nt upstream of the active site. PolC exhibits the potential for large-scale conformational flexibility, which could encompass the catalytic residues. The structure suggests a mechanism by which the active site can communicate with the rest of the replisome to trigger proofreading after nucleotide misincorporation, leading to an integrated model for controlling the dynamic switch between replicative and repair polymerases. This ternary complex of a cellular replicative polymerase affords insights into polymerase fidelity, evolution, and structural diversity.

Published

2008

30. Real-time observation of bacteriophage T4 gp41 helicase reveals an unwinding mechanism

Author

Stephen J. Benkovic, Timothée Lionnet, David Bensimon, Vincent Croquette, and Michelle M. Spiering

Subjects

Multidisciplinary, biology, Circular bacterial chromosome, viruses, DNA replication, Helicase, DNA, Single-Stranded, Biological Sciences, biology.organism_classification, Molecular biology, Cell biology, Substrate Specificity, Bacteriophage, chemistry.chemical_compound, Viral Proteins, Control of chromosome duplication, chemistry, ATP hydrolysis, DNA, Viral, biology.protein, Replisome, Bacteriophage T4, Nucleic Acid Conformation, DNA

Abstract

Helicases are enzymes that couple ATP hydrolysis to the unwinding of double-stranded (ds) nucleic acids. The bacteriophage T4 helicase (gp41) is a hexameric helicase that promotes DNA replication within a highly coordinated protein complex termed the replisome. Despite recent progress, the gp41 unwinding mechanism and regulatory interactions within the replisome remain unclear. Here we use a single tethered DNA hairpin as a real-time reporter of gp41-mediated dsDNA unwinding and single-stranded (ss) DNA translocation with 3-base pair (bp) resolution. Although gp41 translocates on ssDNA as fast as the in vivo replication fork (≈400 bp/s), its unwinding rate extrapolated to zero force is much slower (≈30 bp/s). Together, our results have two implications: first, gp41 unwinds DNA through a passive mechanism; second, this weak helicase cannot efficiently unwind the T4 genome alone. Our results suggest that important regulations occur within the replisome to achieve rapid and processive replication.

Published

2007

31. Unlocking and opening a DNA gate

Author

James C. Wang

Subjects

Base pair, DNA polymerase, Molecular Sequence Data, Substrate Specificity, Fluorescence Resonance Energy Transfer, Animals, Fluorescent Dyes, chemistry.chemical_classification, DNA ligase, Multidisciplinary, DNA clamp, biology, Base Sequence, Circular bacterial chromosome, DNA replication, DNA, Biological Sciences, Kinetics, Eukaryotic Cells, DNA Topoisomerases, Type II, Drosophila melanogaster, chemistry, Biochemistry, biology.protein, Biophysics, Commentary, DNA supercoil, Replisome, Nucleic Acid Conformation

Abstract

The DNA topoisomerases are enzymes that solve various entanglement problems of intracellular DNA. In their presence, DNA strands or double helices can pass through one another as if there were no physical boundaries in between. Manipulations of DNA by a DNA topoisomerase often require displacements between different parts of the enzyme–DNA complex, over distances of tens of angstroms. Such a requirement is particularly evident in reactions catalyzed by the type II DNA topoisomerases. A type II DNA topoisomerase catalyzes the ATP-dependent transport of one DNA double helix through another (1, 2). Each enzyme is made of two identical halves and possesses two protein gates, an ATP-operated entrance gate that admits the DNA segment to be transported (the T segment), and a second gate for the exit of the admitted T segment after its passage through an enzyme-bound DNA segment termed the G segment (reviewed in refs. 3 and 4; see figure 4B in ref. 4 for a sketch of the type II DNA topoisomerase catalyzed reaction). Slicing a DNA double helix through the entire interface between the two enzyme halves and the enzyme-bound DNA double helix clearly requires large movements within the enzyme–DNA complex. However, there have been few direct studies of such movements before the elegant experiments described in this issue of PNAS by Smiley et al. (5), in which single-molecule fluorescence resonance energy transfer (FRET) is used to monitor the opening and closing of the DNA gate by Drosophila DNA topoisomerase II.

Published

2007

32. Architecture of the bacteriophage T4 primosome: electron microscopy studies of helicase (gp41) and primase (gp61)

Author

Faoud T. Ishmael, Michael A. Trakselis, J. Anthony Warrington, Mona T. Norcum, Stephen J. Benkovic, and Michelle M. Spiering

Subjects

DNA Replication, Multidisciplinary, biology, DNA replication, DNA Helicases, Helicase, DNA, Single-Stranded, Trimer, DNA Primase, Random hexamer, Biological Sciences, biology.organism_classification, Primosome, Bacteriophage, Crystallography, Microscopy, Electron, Imaging, Three-Dimensional, biology.protein, Biophysics, Image Processing, Computer-Assisted, Replisome, Bacteriophage T4, Primase

Abstract

Replication of DNA requires helicase and primase activities as part of a primosome assembly. In bacteriophage T4, helicase and primase are separate polypeptides for which little structural information is available and whose mechanism of association within the primosome is not yet understood. Three-dimensional structural information is provided here by means of reconstructions from electron microscopic images. Structures have been calculated for complexes of each of these proteins with ssDNA in the presence of MgATPγS. Both the helicase (gp41) and primase (gp61) complexes are asymmetric hexagonal rings. The gp41 structure suggests two distinct forms that have been termed “open” and “closed.” The gp61 structure is clearly a six-membered ring, which may be a trimer of dimers or a traditional hexamer of monomers. This structure provides conclusive evidence for an oligomeric primase-to-ssDNA stoichiometry of 6:1.

Published

2005

33. T4 replication: what does 'processivity' really mean?

Author

Catherine M. Joyce

Subjects

Models, Molecular, DNA Replication, DNA polymerase, Macromolecular Substances, DNA-Directed DNA Polymerase, Virus Replication, Viral Proteins, Bacteriophage T4, Polymerase, Genetics, Multidisciplinary, biology, Okazaki fragments, DNA replication, Helicase, Processivity, DNA, Templates, Genetic, Biological Sciences, Cell biology, Protein Subunits, DNA, Viral, biology.protein, Commentary, Replisome, Primase, DNA, Circular

Abstract

DNA polymerases are full of surprises. It is widely accepted that replicative polymerases are highly processive, thanks, in large part, to accessory subunits that act as sliding clamps and tether the polymerase to its DNA template. The bacteriophage T4 replication system is typical in that processivity measurements indicate that a substantial fraction of replication complexes should remain associated with DNA for the ≈15 min required to copy an entire genome length (1). However, an elegant study by Yang et al . (2) in this issue of PNAS challenges our notion of processivity by showing that, within the highly processive T4 replisome, individual DNA polymerase molecules are exchanging rapidly, maybe 90 times per genome length under the conditions prevailing in vivo . Thus, if the replisome is visualized as a molecular factory, the workers are making frequent shift changes. The bacteriophage T4 replisome, on which these studies were carried out, serves as a simple model incorporating the essential features of multisubunit replication systems. The components of the T4 system are illustrated in cartoon form in Fig. 1. The high overall processivity of the replisome does not necessarily mean that all subunits are equally processive, and two approaches have been informative in measuring the life-times of individual components within an actively synthesizing replisome. The simplest is to determine the sensitivity of DNA synthesis to dilution of individual components. This approach has demonstrated that the helicase (gp41) is very stably associated with the replication fork (1). By contrast, lagging strand synthesis was sensitive to dilution of the clamp (gp45), clamp loader (gp44/62 complex), and primase (gp61) (5, 6), reflecting the remodeling of the lagging strand machinery that must take place as each new Okazaki fragment is started. Significantly, dilution of the polymerase (gp43) did not affect lagging strand synthesis, implying that …

Published

2004

34. The DNA-unwinding mechanism of the ring helicase of bacteriophage T7

Author

Mikhail K. Levin, Yong-Joo Jeong, and Smita S. Patel

Subjects

Multidisciplinary, biology, Base Sequence, Circular bacterial chromosome, viruses, DNA Helicases, Helicase, DNA, Biological Sciences, RNA Helicase A, Molecular biology, DnaA, enzymes and coenzymes (carbohydrates), Kinetics, Control of chromosome duplication, DNA Topoisomerases, Type I, Models, Chemical, Bacteriophage T7, biology.protein, Biophysics, health occupations, Replisome, Primase, dnaB helicase

Abstract

Helicases are motor proteins that use the chemical energy of NTP hydrolysis to drive mechanical processes such as translocation and nucleic acid strand separation. Bacteriophage T7 helicase functions as a hexameric ring to drive the replication complex by separating the DNA strands during genome replication. Our studies show that T7 helicase unwinds DNA with a low processivity, and the results indicate that the low processivity is due to ring opening and helicase dissociating from the DNA during unwinding. We have measured the single-turnover kinetics of DNA unwinding and globally fit the data to a modified stepping model to obtain the unwinding parameters. The comparison of the unwinding properties of T7 helicase with its translocation properties on single-stranded (ss)DNA has provided insights into the mechanism of strand separation that is likely to be general for ring helicases. T7 helicase unwinds DNA with a rate of 15 bp/s, which is 9-fold slower than the translocation speed along ssDNA. T7 helicase is therefore primarily an ssDNA translocase that does not directly destabilize duplex DNA. We propose that T7 helicase achieves DNA unwinding by its ability to bind ssDNA because it translocates unidirectionally, excluding the complementary strand from its central channel. The results also imply that T7 helicase by itself is not an efficient helicase and most likely becomes proficient at unwinding when it is engaged in a replication complex.

Published

2004

35. RecA protein promotes the regression of stalled replication forks in vitro

Author

Ross B. Inman, Michael M. Cox, and Mara E. Robu

Subjects

Replication fork reversal, DNA Replication, Multidisciplinary, DNA repair, Ter protein, DNA replication, DNA, Single-Stranded, Biology, Molecular biology, Cell biology, Rec A Recombinases, Control of chromosome duplication, Minichromosome maintenance, Colloquium Paper, DNA, Viral, Escherichia coli, Replisome, DNA, Circular, Replication protein A

Abstract

Replication forks are halted by many types of DNA damage. At the site of a leading-strand DNA lesion, forks may stall and leave the lesion in a single-strand gap. Fork regression is the first step in several proposed pathways that permit repair without generating a double-strand break. Using model DNA substrates designed to mimic one of the known structures of a fork stalled at a leading-strand lesion, we show here that RecA protein of Escherichia coli will promote a fork regression reaction in vitro . The regression process exhibits an absolute requirement for ATP hydrolysis and is enhanced when dATP replaces ATP. The reaction is not affected by the inclusion of the RecO and R proteins. We present this reaction as one of several potential RecA protein roles in the repair of stalled and/or collapsed replication forks in bacteria.

Published

2001

36. Processive DNA helicase activity of the minichromosome maintenance proteins 4, 6, and 7 complex requires forked DNA structures

Author

Joon-Kyu Lee and Jerard Hurwitz

Subjects

Saccharomyces cerevisiae Proteins, Chromosomal Proteins, Non-Histone, Macromolecular Substances, Cell Cycle Proteins, Biology, Substrate Specificity, Control of chromosome duplication, Minichromosome maintenance, Schizosaccharomyces, MCM complex, Centrifugation, Density Gradient, dnaB helicase, Electrophoresis, Agar Gel, Multidisciplinary, DNA Helicases, Nuclear Proteins, DNA, Biological Sciences, Minichromosome Maintenance Complex Component 7, Minichromosome Maintenance Complex Component 6, MCM Protein, Recombinant Proteins, Cell biology, Minichromosome Maintenance Complex Component 4, DNA-Binding Proteins, Enzyme Activation, DNA helicase activity, Cross-Linking Reagents, Biochemistry, Replisome, Nucleic Acid Conformation, Primase, Protein Binding

Abstract

The minichromosome maintenance (Mcm) proteins 2–7 are required for both the initiation and elongation steps of chromosomal DNA replication. Previous studies have shown that the Mcm complex consisting of the Mcm 4, 6, and 7 proteins contains 3′ to 5′ DNA helicase activity with limited processivity (displacing duplex DNA regions up to 30 nt). In this report, we show that the presence of both 5′ and 3′ single-stranded tails in DNA helicase substrates is essential for the processive helicase activity of the Mcm complex. The presence of both 5′ and 3′ tails facilitated the formation of double heterohexameric complexes of Mcm4/6/7 on substrate DNA, which appeared to be essential for the processive helicase activity. The double heterohexameric complex of Mcm4/6/7, in the presence of a single-strand DNA binding protein, is capable of unwinding duplex DNA region of about 600 bp in length. These results support the hypothesis that the Mcm4/6/7 complex can function as a replication helicase.

Published

2001

37. A model for the mechanism of strand passage by DNA gyrase

Author

Andrew D. Bates, Sotirios C. Kampranis, and Anthony Maxwell

Subjects

Models, Molecular, Protein Conformation, DNA polymerase II, DNA gyrase, Adenosine Triphosphate, Escherichia coli, Transcription bubble, Adenosine Triphosphatases, Multidisciplinary, DNA clamp, Binding Sites, biology, DNA, Superhelical, Circular bacterial chromosome, DNA, Biological Sciences, DNA Topoisomerases, Type II, Biochemistry, DNA Topoisomerases, Type I, Mutation, biology.protein, Biophysics, DNA supercoil, Replisome, Nucleic Acid Conformation, Type II topoisomerase

Abstract

The mechanism of type II DNA topoisomerases involves the formation of an enzyme-operated gate in one double-stranded DNA segment and the passage of another segment through this gate. DNA gyrase is the only type II topoisomerase able to introduce negative supercoils into DNA, a feature that requires the enzyme to dictate the directionality of strand passage. Although it is known that this is a consequence of the characteristic wrapping of DNA by gyrase, the detailed mechanism by which the transported DNA segment is captured and directed through the DNA gate is largely unknown. We have addressed this mechanism by probing the topology of the bound DNA segment at distinct steps of the catalytic cycle. We propose a model in which gyrase captures a contiguous DNA segment with high probability, irrespective of the superhelical density of the DNA substrate, setting up an equilibrium of the transported segment across the DNA gate. The overall efficiency of strand passage is determined by the position of this equilibrium, which depends on the superhelical density of the DNA substrate. This mechanism is concerted, in that capture of the transported segment by the ATP-operated clamp induces opening of the DNA gate, which in turn stimulates ATP hydrolysis.

Published

1999

38. Unequal fidelity of leading strand and lagging strand DNA replication on the Escherichia coli chromosome

Author

Magdalena Maliszewska Tkaczyk, Iwona J. Fijalkowska, Piotr Jonczyk, Malgorzata Bialoskorska, and Roel M. Schaaper

Subjects

Genetics, DNA Replication, DNA, Bacterial, Multidisciplinary, Okazaki fragments, DNA Repair, GC skew, Drug Resistance, Microbial, Biology, Chromosomes, Bacterial, Biological Sciences, DnaA, DnaG, Evolution, Molecular, Heavy strand, Lac Operon, Prokaryotic DNA replication, Genes, Bacterial, Coding strand, Escherichia coli, Replisome, Point Mutation, Rifampin, Alleles

Abstract

We have investigated the question whether during chromosomal DNA replication in Escherichia coli the two DNA strands may be replicated with differential accuracy. This possibility of differential replication fidelity arises from the distinct modes of replication in the two strands, one strand (the leading strand) being synthesized continuously, the other (the lagging strand) discontinuously in the form of short Okazaki fragments. We have constructed a series of lacZ strains in which the lac operon is inserted into the bacterial chromosome in the two possible orientations with regard to the chromosomal replication origin oriC . Measurement of lac reversion frequencies for the two orientations, under conditions in which mutations reflect replication errors, revealed distinct differences in mutability between the two orientations. As gene inversion causes a switching of leading and lagging strands, these findings indicate that leading and lagging strand replication have differential fidelity. Analysis of the possible mispairs underlying each specific base pair substitution suggests that the lagging strand replication on the E. coli chromosome may be more accurate than leading strand replication.

Published

1998

39. Conversion of DNA gyrase into a conventional type II topoisomerase

Author

Anthony Maxwell and Sotirios C. Kampranis

Subjects

Multidisciplinary, DNA clamp, biology, DNA polymerase, Protein Conformation, DNA polymerase II, Circular bacterial chromosome, DNA, Biological Sciences, DNA gyrase, Enzyme Activation, DNA Topoisomerases, Type II, Biochemistry, biology.protein, Replisome, DNA supercoil, Animals, Nucleic Acid Conformation, Type II topoisomerase

Abstract

DNA gyrase is unique among topoisomerases in its ability to introduce negative supercoils into closed-circular DNA. We have demonstrated that deletion of the C-terminal DNA-binding domain of the A subunit of gyrase gives rise to an enzyme that cannot supercoil DNA but relaxes DNA in an ATP-dependent manner. Novobiocin, a competitive inhibitor of ATP binding by gyrase, inhibits this reaction. The truncated enzyme, unlike gyrase, does not introduce a right-handed wrap when bound to DNA and stabilizes DNA crossovers; characteristics reminiscent of conventional type II topoisomerases. This new enzyme form can decatenate DNA circles with increased efficiency compared with intact gyrase and, as a result, can complement the temperature-sensitive phenotype of a parC ts mutant. Thus these results suggest that the unique properties of DNA gyrase are attributable to the wrapping of DNA around the C-terminal DNA-binding domains of the A subunits and provide an insight into the mechanism of type II topoisomerases.

Published

1996

40. Fork-like DNA templates support bypass replication of lesions that block DNA synthesis on single-stranded templates

Author

Jean-Sébastien Hoffmann, Marie-Jeanne Pillaire, Robert P. Fuchs, Martine Defais, Giuseppe Villani, Dominique Burnouf, and Claire Lesca

Subjects

DNA Replication, DNA polymerase, DNA polymerase II, Molecular Sequence Data, DNA, Single-Stranded, Eukaryotic DNA replication, Antineoplastic Agents, CHO Cells, DNA polymerase delta, DNA Adducts, Cricetinae, Animals, Multidisciplinary, DNA clamp, biology, Base Sequence, DNA replication, Templates, Genetic, 2-Acetylaminofluorene, Biological Sciences, Biochemistry, biology.protein, Carcinogens, Replisome, DNA supercoil, Nucleic Acid Conformation, Cisplatin, DNA Damage

Abstract

DNA replication is an asymmetric process involving concurrent DNA synthesis on leading and lagging strands. Leading strand synthesis proceeds concomitantly with fork opening, whereas synthesis of the lagging strand essentially takes place on a single-stranded template. The effect of this duality on DNA damage processing by the cellular replication machinery was tested using eukaryotic cell extracts and model DNA substrates containing site-specific DNA adducts formed by the anticancer drug cisplatin or by the carcinogen N -2-acetylaminofluorene. Bypass of both lesions was observed only with fork-like substrates, whereas complete inhibition of DNA synthesis occurred on damaged single-stranded DNA substrates. These results suggest a role for additional accessory factors that permit DNA polymerases to bypass lesions when present in fork-like DNA.

Published

1996

41. Structure of eukaryotic CMG helicase at a replication fork and implications to replisome architecture and origin initiation.

Author

Georgescu R, Yuan Z, Bai L, de Luna Almeida Santos R, Sun J, Zhang D, Yurieva O, Li H, and O'Donnell ME

Subjects

DNA Replication, DNA, Single-Stranded chemistry, Models, Molecular, Protein Conformation, Replication Origin, DNA-Binding Proteins chemistry, Minichromosome Maintenance Proteins chemistry, Nuclear Proteins chemistry, Saccharomyces cerevisiae Proteins chemistry

Abstract

The eukaryotic CMG (Cdc45, Mcm2-7, GINS) helicase consists of the Mcm2-7 hexameric ring along with five accessory factors. The Mcm2-7 heterohexamer, like other hexameric helicases, is shaped like a ring with two tiers, an N-tier ring composed of the N-terminal domains, and a C-tier of C-terminal domains; the C-tier contains the motor. In principle, either tier could translocate ahead of the other during movement on DNA. We have used cryo-EM single-particle 3D reconstruction to solve the structure of CMG in complex with a DNA fork. The duplex stem penetrates into the central channel of the N-tier and the unwound leading single-strand DNA traverses the channel through the N-tier into the C-tier motor, 5'-3' through CMG. Therefore, the N-tier ring is pushed ahead by the C-tier ring during CMG translocation, opposite the currently accepted polarity. The polarity of the N-tier ahead of the C-tier places the leading Pol ε below CMG and Pol α-primase at the top of CMG at the replication fork. Surprisingly, the new N-tier to C-tier polarity of translocation reveals an unforeseen quality-control mechanism at the origin. Thus, upon assembly of head-to-head CMGs that encircle double-stranded DNA at the origin, the two CMGs must pass one another to leave the origin and both must remodel onto opposite strands of single-stranded DNA to do so. We propose that head-to-head motors may generate energy that underlies initial melting at the origin., Competing Interests: The authors declare no conflict of interest.

Published

2017

42. Bacteriophage T7 helicase/primase proteins form rings around single-stranded DNA that suggest a general structure for hexameric helicases

Author

Xiong Yu, Manju M. Hingorani, Robert A. Wild, Edward H. Egelman, and Smita S. Patel

Subjects

Models, Molecular, Multidisciplinary, Binding Sites, biology, Macromolecular Substances, Circular bacterial chromosome, DNA replication, DNA Helicases, Helicase, DNA, Single-Stranded, Eukaryotic DNA replication, RNA Nucleotidyltransferases, DNA Primase, Random hexamer, Crystallography, Microscopy, Electron, Bacteriophage T7, biology.protein, Biophysics, Replisome, Primase, Neural Networks, Computer, T7 DNA helicase, Research Article

Abstract

Most helicases studied to date have been characterized as oligomeric, but the relation between their structure and function has not been understood. The bacteriophage T7 gene 4 helicase/primase proteins act in T7 DNA replication. We have used electron microscopy, three-dimensional reconstruction, and protein crosslinking to demonstrate that both proteins form hexameric rings around single-stranded DNA. Each subunit has two lobes, so the hexamer appears to be two-tiered, with a small ring stacked on a large ring. The single-stranded DNA passes through the central hole of the hexamer, and the data exclude substantial wrapping of the DNA about or within the protein ring. Further, the hexamer binds DNA with a defined polarity as the smaller ring of the hexamer points toward the 5' end of the DNA. The similarity in three-dimensional structure of the T7 gene 4 proteins to that of the Escherichia coli RuvB helicase suggests that polar rings assembled around DNA may be a general feature of numerous hexameric helicases involved in DNA replication, transcription, recombination, and repair.

Published

1995

43. Overreplication of the origin region in the dnaB37 mutant of Bacillus subtilis: postinitiation control of chromosomal replication

Author

Gilles Henckes, Francis Harper, Alain Levine, Françoise Vannier, and Simone J. Séror

Subjects

DNA Replication, DNA, Bacterial, Multidisciplinary, biology, Mutant, DNA replication, Chromosome, Bacillus subtilis, Chromosomes, Bacterial, biology.organism_classification, Molecular biology, chemistry.chemical_compound, Kinetics, Plasmid, chemistry, Bacterial Proteins, Replication Initiation, Protein Biosynthesis, Mutation, Replisome, DNA, Plasmids, Research Article

Abstract

When the Bacillus subtilis dnaB37 mutant, defective in initiation, is returned to permissive temperature after accumulation of initiation proteins at 45 degrees C, we have shown, by extensive DNA.DNA hybridization analysis, that the origin region is replicated in excess (approximately 2-fold). However, this replication is limited to a region of about 120-175 kilobases on either side of the origin. This has been confirmed by autoradiographic analysis of the overreplicated region. During the second round of synchronized replication at 30 degrees C, replication in fact appears to resume from the stalled forks on either side of the origin. We propose that in B. subtilis, in addition to a first level of control at the origin, a second level of control exists downstream of the origin in order to limit overreplication of the chromosome. These two controls might normally be tightly coupled. We suggest that the second level of control is exerted through the reversible inhibition of replisome movement at specific regions on either side of the origin.

Published

1989

44. Conservation of the primosome in successive stages of phi X174 DNA replication

Author

Robert L. Low, Arthur Kornberg, and Ken-Ichi Arai

Subjects

DNA Replication, Multidisciplinary, DNA clamp, Okazaki fragments, dnaI, DNA replication, DNA, Single-Stranded, Biology, Virus Replication, Molecular biology, Primosome, Kinetics, DNA Topoisomerases, Type II, Control of chromosome duplication, DNA, Viral, Replisome, Primase, DNA, Circular, Bacteriophage phi X 174, Research Article

Abstract

Synthesis of a complementary strand to match the single-stranded, circular, viral (+) DNA strand of phage phi X174 creates a parental duplex circle (replicative form, RF). This synthesis is initiated by the assembly and action of a priming system, called the primosome [Arai, K. & Kornberg, A (1981) Proc. Natl. Acad. Sci. USA 78, 69-73; Arai, K., Low, R. L. & Kornberg, A. (1981) Proc. Natl. Acad. Sci. USA 78, 707-711]. Of the seven proteins that participate in the assembly and function of the primosome, most all of the components remain even after the DNA duplex is completed and covalently sealed. Remarkably, the primosome in the isolated RF obviates the need for supercoiling of RF by DNA gyrase, an action previously considered essential for the site-specific cleavage by gene A protein that starts viral strand synthesis in the second stage of phi X174 DNA replication. Finally, priming of the synthesis of complementary strands on the nascent viral strands to produce many copies of progeny RF utilizes the same primosome, requiring the addition only of prepriming protein i. thus a single primosome, which becomes associated with the incoming viral DNA in the initial stage of replication, may function repeatedly in the initiation of complementary strands at the subsequent stage of RF multiplication. These patterns of phi X174 DNA replication suggest that a conserved primosome also functions in the progress of the replicating fork of the Escherichia coli chromosome, particularly in initiating the synthesis of nascent (Okazaki) fragments.

Published

1981

45. Contacts between DNA gyrase and its binding site on DNA: features of symmetry and asymmetry revealed by protection from nucleases

Author

Alan Morrison and Nicholas R. Cozzarelli

Subjects

DNA, Bacterial, Exonucleases, Base pair, Macromolecular Substances, DNA gyrase, Substrate Specificity, chemistry.chemical_compound, Escherichia coli, Deoxyribonuclease I, Exonuclease III, Multidisciplinary, Binding Sites, Deoxyribonucleases, biology, DNA, Superhelical, Circular bacterial chromosome, Endonucleases, Molecular biology, DNA Topoisomerases, Type II, Exodeoxyribonucleases, Biochemistry, chemistry, biology.protein, Replisome, DNA supercoil, DNA, Protein Binding, Research Article

Abstract

DNA gyrase supercoils DNA by passing one DNA segment through another by means of a reversible double-strand break at specific DNA sites. We determined the nucleotide sequence of two highly preferred gyrase binding sites and analyzed the grip of gyrase on the DNA by using protection from nuclease attack. The DNA-breakage site of gyrase was centered in about 50 base pairs (bp) of DNA that was completely protected from DNase I and flanked by DNA regions cut at average intervals of 9.9 bases. The same pattern of protection from DNase I was observed with topoisomerase II', an enzyme that shares structural homology with gyrase. The gyrase site of DNA breakage was off-center in the 140 bp of DNA protected from exonuclease III digestion. ATP or inhibitors of gyrase had little specific effect on DNase I protection. On addition of a nonhydrolyzable analogue of ATP, previously stable barriers to exonuclease III were invaded and new barriers appeared. We discuss a detailed model uniting these results with previous data on gyrase structure and mechanism.

Published

1981

46. DNA gyrase: purification and catalytic properties of a fragment of gyrase B protein

Author

L M Fisher, M H O'Dea, and M Gellert

Subjects

Macromolecular Substances, DNA Gyrase B Subunit, Biology, DNA gyrase, Catalysis, chemistry.chemical_compound, Oxolinic acid, medicine, Escherichia coli, Topoisomerase II Inhibitors, Multidisciplinary, DNA, Superhelical, Oxolinic Acid, Circular bacterial chromosome, Endonucleases, Molecular biology, Molecular Weight, DNA Topoisomerases, Type II, Biochemistry, chemistry, Replisome, DNA supercoil, Topoisomerase-II Inhibitor, DNA, medicine.drug, Research Article

Abstract

A protein isolated from Escherichia coli complements the DNA gyrase A (NalA) protein to generate an activity that relaxes supercoiled DNA. Oxolinic acid, a known inhibitor of DNA gyrase, blocks this activity and causes double-strand cleavage of DNA at the same sites as are attacked by DNA gyrase. The protein, of molecular weight 50,000, appears to be fragment of the DNA gyrase B (Cou) protein (molecular weight, 90,000) as judged by the identical sizes of numerous peptides produced by partial proteolytic digestion. The complex of this fragment and the gyrase A protein lacks both the DNA-supercoiling and DNA-dependent ATPase activities of DNA gyrase.

Published

1979

47. A Unique Loop in T7 DNA Polymerase Mediates the Binding of Helicase-Primase, DNA Binding Protein, and Processivity Factor

Author

Hamdan, Samir M., Marintcheva, Boriana, Cook, Timothy, Lee, Seung-Joo, Tabor, Stanley, and Richardson, Charles C.

Published

2005

48. Primer release is the rate-limiting event in lagging-strand synthesis mediated by the T7 replisome

Author

Hernandez, Alfredo J., Lee, Seung-Joo, and Richardson, Charles C.

Published

2016

49. Spatial Organization of a Replicating Bacterial Chromosome

Author

Berlatzky, Idit Anna, Rouvinski, Alex, and Ben-Yehuda, Sigal

Published

2008

50. CDC7-Dependent Protein Kinase Activity in Yeast Replicative-Complex Preparations

Author

Jazwinski, S. Michal

Published

1988