Your search keyword '"Minichromosome Maintenance Proteins chemistry"' showing total 9 results

1. Stabilisation of half MCM ring by Cdt1 during DNA insertion.

Author

Guerrero-Puigdevall M, Fernandez-Fuentes N, and Frigola J

Subjects

Cell Cycle Proteins chemistry, Cell Cycle Proteins genetics, DNA-Binding Proteins chemistry, DNA-Binding Proteins genetics, Minichromosome Maintenance Complex Component 6 chemistry, Minichromosome Maintenance Complex Component 6 metabolism, Minichromosome Maintenance Proteins chemistry, Minichromosome Maintenance Proteins genetics, Nuclear Proteins metabolism, Origin Recognition Complex chemistry, Origin Recognition Complex metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins chemistry, Saccharomyces cerevisiae Proteins genetics, Cell Cycle Proteins metabolism, DNA Replication physiology, DNA-Binding Proteins metabolism, Minichromosome Maintenance Proteins metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

Origin licensing ensures precise once per cell cycle replication in eukaryotic cells. The Origin Recognition Complex, Cdc6 and Cdt1 load Mcm2-7 helicase (MCM) into a double hexamer, bound around duplex DNA. The complex formed by ORC-Cdc6 bound to duplex DNA (OC) recruits the MCM-Cdt1 complex into the replication origins. Through the stacking of both complexes, the duplex DNA is inserted inside the helicase by an unknown mechanism. In this paper we show that the DNA insertion comes with a topological problem in the stacking of OC with MCM-Cdt1. Unless an essential, conserved C terminal winged helix domain (C-WHD) of Cdt1 is present, the MCM splits into two halves. The binding of this domain with the essential C-WHD of Mcm6, allows the latching between the MCM-Cdt1 and OC, through a conserved Orc5 AAA-lid interaction. Our work provides new insights into how DNA is inserted into the eukaryotic replicative helicase, through a series of synchronized events.

Published

2021

2. The Eukaryotic CMG Helicase at the Replication Fork: Emerging Architecture Reveals an Unexpected Mechanism.

Author

Li H and O'Donnell ME

Subjects

Animals, Binding Sites, DNA genetics, DNA metabolism, DNA-Binding Proteins genetics, DNA-Binding Proteins metabolism, Drosophila melanogaster genetics, Drosophila melanogaster metabolism, Encephalitozoon cuniculi genetics, Encephalitozoon cuniculi metabolism, G1 Phase, Humans, Minichromosome Maintenance Proteins genetics, Minichromosome Maintenance Proteins metabolism, Models, Molecular, Nuclear Proteins genetics, Nuclear Proteins metabolism, Nucleic Acid Conformation, Protein Binding, Protein Multimerization, Protein Structure, Secondary, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism, Xenopus laevis genetics, Xenopus laevis metabolism, DNA chemistry, DNA Replication, DNA-Binding Proteins chemistry, Minichromosome Maintenance Proteins chemistry, Nuclear Proteins chemistry, Saccharomyces cerevisiae Proteins chemistry

Abstract

The eukaryotic helicase is an 11-subunit machine containing an Mcm2-7 motor ring that encircles DNA, Cdc45 and the GINS tetramer, referred to as CMG (Cdc45, Mcm2-7, GINS). CMG is "built" on DNA at origins in two steps. First, two Mcm2-7 rings are assembled around duplex DNA at origins in G1 phase, forming the Mcm2-7 "double hexamer." In a second step, in S phase Cdc45 and GINS are assembled onto each Mcm2-7 ring, hence producing two CMGs that ultimately form two replication forks that travel in opposite directions. Here, we review recent findings about CMG structure and function. The CMG unwinds the parental duplex and is also the organizing center of the replisome: it binds DNA polymerases and other factors. EM studies reveal a 20-subunit core replisome with the leading Pol ϵ and lagging Pol α-primase on opposite faces of CMG, forming a fundamentally asymmetric architecture. Structural studies of CMG at a replication fork reveal unexpected details of how CMG engages the DNA fork. The structures of CMG and the Mcm2-7 double hexamer on DNA suggest a completely unanticipated process for formation of bidirectional replication forks at origins., (© 2018 WILEY Periodicals, Inc.)

Published

2018

3. Cryo-EM structure of Mcm2-7 double hexamer on DNA suggests a lagging-strand DNA extrusion model.

Author

Noguchi Y, Yuan Z, Bai L, Schneider S, Zhao G, Stillman B, Speck C, and Li H

Subjects

DNA Replication genetics, Oligosaccharides chemistry, Protein Domains genetics, Zinc Fingers genetics, DNA chemistry, DNA Helicases chemistry, DNA-Binding Proteins chemistry, Minichromosome Maintenance Proteins chemistry

Abstract

During replication initiation, the core component of the helicase-the Mcm2-7 hexamer-is loaded on origin DNA as a double hexamer (DH). The two ring-shaped hexamers are staggered, leading to a kinked axial channel. How the origin DNA interacts with the axial channel is not understood, but the interaction could provide key insights into Mcm2-7 function and regulation. Here, we report the cryo-EM structure of the Mcm2-7 DH on dsDNA and show that the DNA is zigzagged inside the central channel. Several of the Mcm subunit DNA-binding loops, such as the oligosaccharide-oligonucleotide loops, helix 2 insertion loops, and presensor 1 (PS1) loops, are well defined, and many of them interact extensively with the DNA. The PS1 loops of Mcm 3, 4, 6, and 7, but not 2 and 5, engage the lagging strand with an approximate step size of one base per subunit. Staggered coupling of the two opposing hexamers positions the DNA right in front of the two Mcm2-Mcm5 gates, with each strand being pressed against one gate. The architecture suggests that lagging-strand extrusion initiates in the middle of the DH that is composed of the zinc finger domains of both hexamers. To convert the Mcm2-7 DH structure into the Mcm2-7 hexamer structure found in the active helicase, the N-tier ring of the Mcm2-7 hexamer in the DH-dsDNA needs to tilt and shift laterally. We suggest that these N-tier ring movements cause the DNA strand separation and lagging-strand extrusion., Competing Interests: The authors declare no conflict of interest., (Copyright © 2017 the Author(s). Published by PNAS.)

Published

2017

4. Structural basis of Mcm2-7 replicative helicase loading by ORC-Cdc6 and Cdt1.

Author

Yuan Z, Riera A, Bai L, Sun J, Nandi S, Spanos C, Chen ZA, Barbon M, Rappsilber J, Stillman B, Speck C, and Li H

Subjects

Binding Sites, Cell Cycle Proteins metabolism, Cell Cycle Proteins ultrastructure, Cryoelectron Microscopy, DNA, Fungal chemistry, DNA, Fungal metabolism, DNA-Binding Proteins metabolism, DNA-Binding Proteins ultrastructure, Mass Spectrometry, Minichromosome Maintenance Proteins metabolism, Minichromosome Maintenance Proteins ultrastructure, Models, Molecular, Nucleotides metabolism, Protein Binding, Protein Domains, Protein Multimerization, Protein Structure, Secondary, Saccharomyces cerevisiae Proteins metabolism, Saccharomyces cerevisiae Proteins ultrastructure, Cell Cycle Proteins chemistry, DNA Replication, DNA-Binding Proteins chemistry, Minichromosome Maintenance Proteins chemistry, Replication Origin, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins chemistry

Abstract

To initiate DNA replication, the origin recognition complex (ORC) and Cdc6 load an Mcm2-7 double hexamer onto DNA. Without ATP hydrolysis, ORC-Cdc6 recruits one Cdt1-bound Mcm2-7 hexamer, thus forming an ORC-Cdc6-Cdt1-Mcm2-7 (OCCM) helicase-loading intermediate. Here we report a 3.9-Å structure of Saccharomyces cerevisiae OCCM on DNA. Flexible Mcm2-7 winged-helix domains (WHDs) engage ORC-Cdc6. A three-domain Cdt1 configuration embraces Mcm2, Mcm4, and Mcm6, thus comprising nearly half of the hexamer. The Cdt1 C-terminal domain extends to the Mcm6 WHD, which binds the Orc4 WHD. DNA passes through the ORC-Cdc6 and Mcm2-7 rings. Origin DNA interaction is mediated by an α-helix within Orc4 and positively charged loops within Orc2 and Cdc6. The Mcm2-7 C-tier AAA+ ring is topologically closed by an Mcm5 loop that embraces Mcm2, but the N-tier-ring Mcm2-Mcm5 interface remains open. This structure suggests a loading mechanism of the first Cdt1-bound Mcm2-7 hexamer by ORC-Cdc6.

Published

2017

5. Open-ringed structure of the Cdt1-Mcm2-7 complex as a precursor of the MCM double hexamer.

Author

Zhai Y, Cheng E, Wu H, Li N, Yung PY, Gao N, and Tye BK

Subjects

Adenylyl Imidodiphosphate chemistry, Amino Acid Motifs, Cell Cycle Proteins metabolism, Cell Cycle Proteins ultrastructure, Cryoelectron Microscopy, DNA-Binding Proteins metabolism, DNA-Binding Proteins ultrastructure, Minichromosome Maintenance Proteins metabolism, Minichromosome Maintenance Proteins ultrastructure, Models, Molecular, Protein Domains, Protein Structure, Secondary, Protein Subunits chemistry, Protein Subunits metabolism, Saccharomyces cerevisiae Proteins metabolism, Saccharomyces cerevisiae Proteins ultrastructure, Zinc Fingers, Cell Cycle Proteins chemistry, DNA-Binding Proteins chemistry, Minichromosome Maintenance Proteins chemistry, Protein Multimerization, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins chemistry

Abstract

The minichromosome maintenance complex (MCM) hexameric complex (Mcm2-7) forms the core of the eukaryotic replicative helicase. During G1 phase, two Cdt1-Mcm2-7 heptamers are loaded onto each replication origin by the origin-recognition complex (ORC) and Cdc6 to form an inactive MCM double hexamer (DH), but the detailed loading mechanism remains unclear. Here we examine the structures of the yeast MCM hexamer and Cdt1-MCM heptamer from Saccharomyces cerevisiae. Both complexes form left-handed coil structures with a 10-15-Å gap between Mcm5 and Mcm2, and a central channel that is occluded by the C-terminal domain winged-helix motif of Mcm5. Cdt1 wraps around the N-terminal regions of Mcm2, Mcm6 and Mcm4 to stabilize the whole complex. The intrinsic coiled structures of the precursors provide insights into the DH formation, and suggest a spring-action model for the MCM during the initial origin melting and the subsequent DNA unwinding.

Published

2017

6. 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

7. MCM ring hexamerization is a prerequisite for DNA-binding.

Author

Froelich CA, Nourse A, and Enemark EJ

Subjects

Animals, Archaeal Proteins genetics, Archaeal Proteins metabolism, DNA, Single-Stranded chemistry, DNA, Single-Stranded metabolism, DNA-Binding Proteins genetics, DNA-Binding Proteins metabolism, Mice, Minichromosome Maintenance Complex Component 4 genetics, Minichromosome Maintenance Proteins genetics, Minichromosome Maintenance Proteins metabolism, Models, Molecular, Mutation, Protein Binding, Protein Multimerization, Pyrococcus furiosus, Archaeal Proteins chemistry, DNA-Binding Proteins chemistry, Minichromosome Maintenance Proteins chemistry

Abstract

The hexameric Minichromosome Maintenance (MCM) protein complex forms a ring that unwinds DNA at the replication fork in eukaryotes and archaea. Our recent crystal structure of an archaeal MCM N-terminal domain bound to single-stranded DNA (ssDNA) revealed ssDNA associating across tight subunit interfaces but not at the loose interfaces, indicating that DNA-binding is governed not only by the DNA-binding residues of the subunits (MCM ssDNA-binding motif, MSSB) but also by the relative orientation of the subunits. We now extend these findings by showing that DNA-binding by the MCM N-terminal domain of the archaeal organism Pyrococcus furiosus occurs specifically in the hexameric oligomeric form. We show that mutants defective for hexamerization are defective in binding ssDNA despite retaining all the residues observed to interact with ssDNA in the crystal structure. One mutation that exhibits severely defective hexamerization and ssDNA-binding is at a conserved phenylalanine that aligns with the mouse Mcm4(Chaos3) mutation associated with chromosomal instability, cancer, and decreased intersubunit association., (© The Author(s) 2015. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2015

8. DNA binding polarity, dimerization, and ATPase ring remodeling in the CMG helicase of the eukaryotic replisome.

Author

Costa A, Renault L, Swuec P, Petojevic T, Pesavento JJ, Ilves I, MacLellan-Gibson K, Fleck RA, Botchan MR, and Berger JM

Subjects

Adenosine Triphosphatases chemistry, Adenosine Triphosphatases metabolism, Adenosine Triphosphate analogs & derivatives, Adenosine Triphosphate chemistry, Adenosine Triphosphate metabolism, Animals, Cell Cycle Proteins metabolism, Chromosomal Proteins, Non-Histone metabolism, DNA chemistry, DNA metabolism, DNA Replication, DNA, Single-Stranded chemistry, DNA, Single-Stranded metabolism, DNA-Binding Proteins metabolism, Drosophila Proteins metabolism, Drosophila melanogaster metabolism, Eukaryotic Cells metabolism, Microscopy, Electron, Models, Molecular, Multiprotein Complexes metabolism, Multiprotein Complexes ultrastructure, Protein Binding, Protein Multimerization, Protein Structure, Quaternary, Protein Structure, Tertiary, Protein Subunits chemistry, Protein Subunits metabolism, RNA Splicing Factors, RNA-Binding Proteins chemistry, RNA-Binding Proteins metabolism, Repressor Proteins chemistry, Repressor Proteins metabolism, Cell Cycle Proteins chemistry, Chromosomal Proteins, Non-Histone chemistry, DNA-Binding Proteins chemistry, Drosophila Proteins chemistry, Minichromosome Maintenance Proteins chemistry, Minichromosome Maintenance Proteins metabolism, Multiprotein Complexes chemistry

Abstract

The Cdc45/Mcm2-7/GINS (CMG) helicase separates DNA strands during replication in eukaryotes. How the CMG is assembled and engages DNA substrates remains unclear. Using electron microscopy, we have determined the structure of the CMG in the presence of ATPγS and a DNA duplex bearing a 3' single-stranded tail. The structure shows that the MCM subunits of the CMG bind preferentially to single-stranded DNA, establishes the polarity by which DNA enters into the Mcm2-7 pore, and explains how Cdc45 helps prevent DNA from dissociating from the helicase. The Mcm2-7 subcomplex forms a cracked-ring, right-handed spiral when DNA and nucleotide are bound, revealing unexpected congruencies between the CMG and both bacterial DnaB helicases and the AAA+ motor of the eukaryotic proteasome. The existence of a subpopulation of dimeric CMGs establishes the subunit register of Mcm2-7 double hexamers and together with the spiral form highlights how Mcm2-7 transitions through different conformational and assembly states as it matures into a functional helicase., (Copyright © 2014, Costa et al.)

Published

2014

9. A Ctf4 trimer couples the CMG helicase to DNA polymerase α in the eukaryotic replisome.

Author

Simon AC, Zhou JC, Perera RL, van Deursen F, Evrin C, Ivanova ME, Kilkenny ML, Renault L, Kjaer S, Matak-Vinković D, Labib K, Costa A, and Pellegrini L

Subjects

Amino Acid Motifs, Amino Acid Sequence, Catalytic Domain, Conserved Sequence, Crystallography, X-Ray, DNA Helicases chemistry, DNA Helicases ultrastructure, DNA Polymerase I chemistry, DNA Polymerase I ultrastructure, DNA-Binding Proteins ultrastructure, Microscopy, Electron, Minichromosome Maintenance Proteins chemistry, Minichromosome Maintenance Proteins metabolism, Models, Molecular, Molecular Sequence Data, Nuclear Proteins chemistry, Nuclear Proteins metabolism, Protein Binding, Protein Structure, Quaternary, Protein Subunits chemistry, Protein Subunits metabolism, Saccharomyces cerevisiae ultrastructure, Saccharomyces cerevisiae Proteins ultrastructure, DNA Helicases metabolism, DNA Polymerase I metabolism, DNA Replication, DNA-Binding Proteins chemistry, DNA-Binding Proteins metabolism, DNA-Directed DNA Polymerase chemistry, DNA-Directed DNA Polymerase metabolism, Multienzyme Complexes chemistry, Multienzyme Complexes metabolism, Protein Multimerization, Saccharomyces cerevisiae chemistry, Saccharomyces cerevisiae Proteins chemistry, Saccharomyces cerevisiae Proteins metabolism

Abstract

Efficient duplication of the genome requires the concerted action of helicase and DNA polymerases at replication forks to avoid stalling of the replication machinery and consequent genomic instability. In eukaryotes, the physical coupling between helicase and DNA polymerases remains poorly understood. Here we define the molecular mechanism by which the yeast Ctf4 protein links the Cdc45-MCM-GINS (CMG) DNA helicase to DNA polymerase α (Pol α) within the replisome. We use X-ray crystallography and electron microscopy to show that Ctf4 self-associates in a constitutive disk-shaped trimer. Trimerization depends on a β-propeller domain in the carboxy-terminal half of the protein, which is fused to a helical extension that protrudes from one face of the trimeric disk. Critically, Pol α and the CMG helicase share a common mechanism of interaction with Ctf4. We show that the amino-terminal tails of the catalytic subunit of Pol α and the Sld5 subunit of GINS contain a conserved Ctf4-binding motif that docks onto the exposed helical extension of a Ctf4 protomer within the trimer. Accordingly, we demonstrate that one Ctf4 trimer can support binding of up to three partner proteins, including the simultaneous association with both Pol α and GINS. Our findings indicate that Ctf4 can couple two molecules of Pol α to one CMG helicase within the replisome, providing a new model for lagging-strand synthesis in eukaryotes that resembles the emerging model for the simpler replisome of Escherichia coli. The ability of Ctf4 to act as a platform for multivalent interactions illustrates a mechanism for the concurrent recruitment of factors that act together at the fork.

Published

2014