Your search keyword '"Hingorani MM"' showing total 63 results

1. Molecular dynamics of mismatch detection-How MutS uses indirect readout to find errors in DNA.

Author

Jayaraj A, Thayer KM, Beveridge DL, and Hingorani MM

Subjects

Base Pair Mismatch, DNA chemistry, MutS DNA Mismatch-Binding Protein chemistry, MutS DNA Mismatch-Binding Protein genetics, MutS DNA Mismatch-Binding Protein metabolism, Base Pairing, Molecular Dynamics Simulation, Escherichia coli Proteins genetics

Abstract

The mismatch repair protein MutS safeguards genomic integrity by finding and initiating repair of basepairing errors in DNA. Single-molecule studies show MutS diffusing on DNA, presumably scanning for mispaired/unpaired bases, and crystal structures show a characteristic "mismatch-recognition" complex with DNA enclosed within MutS and kinked at the site of error. But how MutS goes from scanning thousands of Watson-Crick basepairs to recognizing rare mismatches remains unanswered, largely because atomic-resolution data on the search process are lacking. Here, 10 μs all-atom molecular dynamics simulations of Thermus aquaticus MutS bound to homoduplex DNA and T-bulge DNA illuminate the structural dynamics underlying the search mechanism. MutS-DNA interactions constitute a multistep mechanism to check DNA over two helical turns for its 1) shape, through contacts with the sugar-phosphate backbone, 2) conformational flexibility, through bending/unbending engineered by large-scale motions of the clamp domain, and 3) local deformability, through basepair destabilizing contacts. Thus, MutS can localize a potential target by indirect readout due to lower energetic costs of bending mismatched DNA and identify a site that distorts easily due to weaker base stacking and pairing as a mismatch. The MutS signature Phe-X-Glu motif can then lock in the mismatch-recognition complex to initiate repair., Competing Interests: Declaration of interests The authors declare no conflict of interest., (Published by Elsevier Inc.)

Published

2023

2. Recurrent mismatch binding by MutS mobile clamps on DNA localizes repair complexes nearby.

Author

Hao P, LeBlanc SJ, Case BC, Elston TC, Hingorani MM, Erie DA, and Weninger KR

Subjects

Adenosine Triphosphatases metabolism, Adenosine Triphosphate metabolism, Base Pair Mismatch, DNA chemistry, DNA genetics, Hydrolysis, Models, Molecular, Multiprotein Complexes metabolism, MutL Proteins chemistry, MutL Proteins metabolism, MutS DNA Mismatch-Binding Protein chemistry, Structure-Activity Relationship, DNA metabolism, DNA Mismatch Repair, MutS DNA Mismatch-Binding Protein metabolism

Abstract

DNA mismatch repair (MMR), the guardian of the genome, commences when MutS identifies a mismatch and recruits MutL to nick the error-containing strand, allowing excision and DNA resynthesis. Dominant MMR models posit that after mismatch recognition, ATP converts MutS to a hydrolysis-independent, diffusive mobile clamp that no longer recognizes the mismatch. Little is known about the postrecognition MutS mobile clamp and its interactions with MutL. Two disparate frameworks have been proposed: One in which MutS-MutL complexes remain mobile on the DNA, and one in which MutL stops MutS movement. Here we use single-molecule FRET to follow the postrecognition states of MutS and the impact of MutL on its properties. In contrast to current thinking, we find that after the initial mobile clamp formation event, MutS undergoes frequent cycles of mismatch rebinding and mobile clamp reformation without releasing DNA. Notably, ATP hydrolysis is required to alter the conformation of MutS such that it can recognize the mismatch again instead of bypassing it; thus, ATP hydrolysis licenses the MutS mobile clamp to rebind the mismatch. Moreover, interaction with MutL can both trap MutS at the mismatch en route to mobile clamp formation and stop movement of the mobile clamp on DNA. MutS's frequent rebinding of the mismatch, which increases its residence time in the vicinity of the mismatch, coupled with MutL's ability to trap MutS, should increase the probability that MutS-MutL MMR initiation complexes localize near the mismatch., Competing Interests: The authors declare no competing interest.

Published

2020

3. Mismatch Recognition by Saccharomyces cerevisiae Msh2-Msh6: Role of Structure and Dynamics.

Author

Li Y, Lombardo Z, Joshi M, Hingorani MM, and Mukerji I

Subjects

Base Pair Mismatch, DNA, Fungal genetics, DNA, Fungal metabolism, DNA-Binding Proteins chemistry, Models, Molecular, MutS Homolog 2 Protein chemistry, Protein Binding, Protein Conformation, Protein Multimerization, Saccharomyces cerevisiae chemistry, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins chemistry, DNA-Binding Proteins metabolism, MutS Homolog 2 Protein metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

The mismatch repair (MMR) pathway maintains genome integrity by correcting errors such as mismatched base pairs formed during DNA replication. In MMR, Msh2-Msh6, a heterodimeric protein, targets single base mismatches and small insertion/deletion loops for repair. By incorporating the fluorescent nucleoside base analog 6-methylisoxanthopterin (6-MI) at or adjacent to a mismatch site to probe the structural and dynamic elements of the mismatch, we address how Msh2-Msh6 recognizes these mismatches for repair within the context of matched DNA. Fluorescence quantum yield and rotational correlation time measurements indicate that local base dynamics linearly correlate with Saccharomyces cerevisiae Msh2-Msh6 binding affinity where the protein exhibits a higher affinity ( K D ≤ 25 nM) for mismatches that have a significant amount of dynamic motion. Energy transfer measurements measuring global DNA bending find that mismatches that are both well and poorly recognized by Msh2-Msh6 experience the same amount of protein-induced bending. Finally, base-specific dynamics coupled with protein-induced blue shifts in peak emission strongly support the crystallographic model of directional binding, in which Phe 432 of Msh6 intercalates 3' of the mismatch. These results imply an important role for local base dynamics in the initial recognition step of MMR.

Published

2019

4. The ATPase mechanism of UvrA2 reveals the distinct roles of proximal and distal ATPase sites in nucleotide excision repair.

Author

Case BC, Hartley S, Osuga M, Jeruzalmi D, and Hingorani MM

Subjects

Adenosine Triphosphate chemistry, Adenosine Triphosphate metabolism, Amino Acid Sequence, Bacterial Proteins genetics, Bacterial Proteins metabolism, Binding Sites, Cloning, Molecular, DNA Damage, DNA, Bacterial genetics, DNA, Bacterial metabolism, Endodeoxyribonucleases genetics, Endodeoxyribonucleases metabolism, Escherichia coli genetics, Escherichia coli metabolism, Escherichia coli Proteins genetics, Escherichia coli Proteins metabolism, Gene Expression, Genetic Vectors chemistry, Genetic Vectors metabolism, Geobacillus stearothermophilus chemistry, Geobacillus stearothermophilus genetics, Kinetics, Models, Molecular, Protein Binding, Protein Interaction Domains and Motifs, Protein Multimerization, Protein Structure, Secondary, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Sequence Alignment, Structural Homology, Protein, Substrate Specificity, Thermodynamics, Thermotoga maritima chemistry, Thermotoga maritima enzymology, Thermotoga maritima genetics, ortho-Aminobenzoates metabolism, Adenosine Triphosphate analogs & derivatives, Bacterial Proteins chemistry, DNA Repair, DNA, Bacterial chemistry, Endodeoxyribonucleases chemistry, Escherichia coli Proteins chemistry, Geobacillus stearothermophilus enzymology, ortho-Aminobenzoates chemistry

Abstract

The UvrA2 dimer finds lesions in DNA and initiates nucleotide excision repair. Each UvrA monomer contains two essential ATPase sites: proximal (P) and distal (D). The manner whereby their activities enable UvrA2 damage sensing and response remains to be clarified. We report three key findings from the first pre-steady state kinetic analysis of each site. Absent DNA, a P2ATP-D2ADP species accumulates when the low-affinity proximal sites bind ATP and enable rapid ATP hydrolysis and phosphate release by the high-affinity distal sites, and ADP release limits catalytic turnover. Native DNA stimulates ATP hydrolysis by all four sites, causing UvrA2 to transition through a different species, P2ADP-D2ADP. Lesion-containing DNA changes the mechanism again, suppressing ATP hydrolysis by the proximal sites while distal sites cycle through hydrolysis and ADP release, to populate proximal ATP-bound species, P2ATP-Dempty and P2ATP-D2ATP. Thus, damaged and native DNA trigger distinct ATPase site activities, which could explain why UvrA2 forms stable complexes with UvrB on damaged DNA compared with weaker, more dynamic complexes on native DNA. Such specific coupling between the DNA substrate and the ATPase mechanism of each site provides new insights into how UvrA2 utilizes ATP for lesion search, recognition and repair., (© The Author(s) 2019. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2019

5. Large conformational changes in MutS during DNA scanning, mismatch recognition and repair signaling.

Author

Qiu R, DeRocco VC, Harris C, Sharma A, Hingorani MM, Erie DA, and Weninger KR

Published

2019

6. MutSγ-Induced DNA Conformational Changes Provide Insights into Its Role in Meiotic Recombination.

Author

Lahiri S, Li Y, Hingorani MM, and Mukerji I

Subjects

Chromosome Segregation, DNA-Binding Proteins chemistry, DNA-Binding Proteins genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins chemistry, Saccharomyces cerevisiae Proteins genetics, Crossing Over, Genetic, DNA, Cruciform chemistry, DNA-Binding Proteins metabolism, Meiosis, Nucleic Acid Conformation, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

In many organisms, MutSγ plays a role in meiotic recombination, facilitating crossover formation between homologous chromosomes. Failure to form crossovers leads to improper segregation of chromosomes and aneuploidy, which in humans result in infertility and birth defects. To improve current understanding of MutSγ function, this study investigates the binding affinities and structures of MutSγ in complex with DNA substrates that model homologous recombination intermediates. For these studies, we overexpressed and isolated from Escherichia coli the yeast MutSγ protein Saccharomyces cerevisiae (Sc) Msh4-Msh5. Sc Msh4-Msh5 binds Holliday junction (HJ)-like substrates, 3' overhangs, single-stranded (ss) forks, and the displacement loop with nanomolar affinity. The weakest binding affinities are detected for an intact duplex and open-junction construct. Similar to the human protein, Sc Msh4-Msh5 exhibits the highest affinity for the HJ with a K d  < 0.4 nM in solution. Energy-transfer experiments further demonstrate that DNA structure is modulated by the binding interaction with the largest changes associated with substrates containing an ss end. Upon binding, Sc Msh4-Msh5 displaces the ss away from the duplex in most of the ss-containing intermediates, potentially enabling the binding of RPA and other proteins. In the case of the junction-like intermediates, Msh4-Msh5 binding either stabilizes the existing stacked structure or induces formation of the stacked X conformation. Significantly, we find that upon binding, Msh4-Msh5 stacks an open-junction construct to the same extent as the standard junction. Stabilization of the junction in the stacked conformation is generally refractory to branch migration, which is consistent with a potential role for MutSγ to stabilize HJs and prevent branch migration until resolution by MutLγ. The different binding modalities observed suggest that Msh4-Msh5 not only binds to and stabilizes stacked junctions but also participates in meiotic recombination before junction formation through the stabilization of single-end invasion intermediates., (Copyright © 2018 Biophysical Society. Published by Elsevier Inc. All rights reserved.)

Published

2018

7. Coordinated protein and DNA conformational changes govern mismatch repair initiation by MutS.

Author

LeBlanc SJ, Gauer JW, Hao P, Case BC, Hingorani MM, Weninger KR, and Erie DA

Subjects

Base Pairing physiology, Escherichia coli, Fluorescence Resonance Energy Transfer, Genomic Instability genetics, Models, Molecular, MutS DNA Mismatch-Binding Protein chemistry, MutS DNA Mismatch-Binding Protein genetics, Mutant Proteins chemistry, Mutant Proteins metabolism, Protein Binding physiology, Protein Conformation, Protein Domains genetics, Protein Isoforms chemistry, Protein Isoforms genetics, Protein Isoforms metabolism, Base Pair Mismatch genetics, DNA chemistry, DNA Mismatch Repair genetics, MutS DNA Mismatch-Binding Protein metabolism, Nucleic Acid Conformation

Abstract

MutS homologs identify base-pairing errors made in DNA during replication and initiate their repair. In the presence of adenosine triphosphate, MutS induces DNA bending upon mismatch recognition and subsequently undergoes conformational transitions that promote its interaction with MutL to signal repair. In the absence of MutL, these transitions lead to formation of a MutS mobile clamp that can move along the DNA. Previous single-molecule FRET (smFRET) studies characterized the dynamics of MutS DNA-binding domains during these transitions. Here, we use protein-DNA and DNA-DNA smFRET to monitor DNA conformational changes, and we use kinetic analyses to correlate DNA and protein conformational changes to one another and to the steps on the pathway to mobile clamp formation. The results reveal multiple sequential structural changes in both MutS and DNA, and they suggest that DNA dynamics play a critical role in the formation of the MutS mobile clamp. Taking these findings together with data from our previous studies, we propose a unified model of coordinated MutS and DNA conformational changes wherein initiation of mismatch repair is governed by a balance of DNA bending/unbending energetics and MutS conformational changes coupled to its nucleotide binding properties.

Published

2018

8. Missed cleavage opportunities by FEN1 lead to Okazaki fragment maturation via the long-flap pathway.

Author

Zaher MS, Rashid F, Song B, Joudeh LI, Sobhy MA, Tehseen M, Hingorani MM, and Hamdan SM

Subjects

Acetyltransferases metabolism, DNA Helicases genetics, DNA Helicases metabolism, DNA, Fungal genetics, DNA, Fungal metabolism, Fluorescence Resonance Energy Transfer methods, Kinetics, Membrane Proteins metabolism, Protein Binding, Replication Protein A genetics, Replication Protein A metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism, Signal Transduction genetics, Single Molecule Imaging methods, Substrate Specificity, Acetyltransferases genetics, DNA genetics, DNA Cleavage, DNA Replication genetics, Membrane Proteins genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics

Abstract

RNA-DNA hybrid primers synthesized by low fidelity DNA polymerase α to initiate eukaryotic lagging strand synthesis must be removed efficiently during Okazaki fragment (OF) maturation to complete DNA replication. In this process, each OF primer is displaced and the resulting 5'-single-stranded flap is cleaved by structure-specific 5'-nucleases, mainly Flap Endonuclease 1 (FEN1), to generate a ligatable nick. At least two models have been proposed to describe primer removal, namely short- and long-flap pathways that involve FEN1 or FEN1 along with Replication Protein A (RPA) and Dna2 helicase/nuclease, respectively. We addressed the question of pathway choice by studying the kinetic mechanism of FEN1 action on short- and long-flap DNA substrates. Using single molecule FRET and rapid quench-flow bulk cleavage assays, we showed that unlike short-flap substrates, which are bound, bent and cleaved within the first encounter between FEN1 and DNA, long-flap substrates can escape cleavage even after DNA binding and bending. Notably, FEN1 can access both substrates in the presence of RPA, but bending and cleavage of long-flap DNA is specifically inhibited. We propose that FEN1 attempts to process both short and long flaps, but occasional missed cleavage of the latter allows RPA binding and triggers the long-flap OF maturation pathway.

Published

2018

9. Positioning the 5'-flap junction in the active site controls the rate of flap endonuclease-1-catalyzed DNA cleavage.

Author

Song B, Hamdan SM, and Hingorani MM

Subjects

Calcium metabolism, Catalysis, Catalytic Domain, DNA metabolism, Flap Endonucleases metabolism, Humans, Magnesium metabolism, Calcium chemistry, DNA chemistry, Flap Endonucleases chemistry, Magnesium chemistry

Abstract

Flap endonucleases catalyze cleavage of single-stranded DNA flaps formed during replication, repair, and recombination and are therefore essential for genome processing and stability. Recent crystal structures of DNA-bound human flap endonuclease (hFEN1) offer new insights into how conformational changes in the DNA and hFEN1 may facilitate the reaction mechanism. For example, previous biochemical studies of DNA conformation performed under non-catalytic conditions with Ca 2+ have suggested that base unpairing at the 5'-flap:template junction is an important step in the reaction, but the new structural data suggest otherwise. To clarify the role of DNA changes in the kinetic mechanism, we measured a series of transient steps, from substrate binding to product release, during the hFEN1-catalyzed reaction in the presence of Mg 2+ We found that whereas hFEN1 binds and bends DNA at a fast, diffusion-limited rate, much slower Mg 2+ -dependent conformational changes in DNA around the active site are subsequently necessary and rate-limiting for 5'-flap cleavage. These changes are reported overall by fluorescence of 2-aminopurine at the 5'-flap:template junction, indicating that local DNA distortion ( e.g. disruption of base stacking observed in structures), associated with positioning the 5'-flap scissile phosphodiester bond in the hFEN1 active site, controls catalysis. hFEN1 residues with distinct roles in the catalytic mechanism, including those binding metal ions (Asp-34 and Asp-181), steering the 5'-flap through the active site and binding the scissile phosphate (Lys-93 and Arg-100), and stacking against the base 5' to the scissile phosphate (Tyr-40), all contribute to these rate-limiting conformational changes, ensuring efficient and specific cleavage of 5'-flaps., (© 2018 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2018

10. Linchpin DNA-binding residues serve as go/no-go controls in the replication factor C-catalyzed clamp-loading mechanism.

Author

Liu J, Zhou Y, and Hingorani MM

Subjects

Adenosine Triphosphate metabolism, DNA-Directed DNA Polymerase metabolism, Hydrolysis, Models, Molecular, Proliferating Cell Nuclear Antigen metabolism, Protein Binding, Protein Conformation, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins chemistry, Saccharomyces cerevisiae Proteins metabolism, Structure-Activity Relationship, Biocatalysis, DNA, Fungal chemistry, DNA, Fungal metabolism, Replication Protein C chemistry, Replication Protein C metabolism

Abstract

DNA polymerases depend on circular sliding clamps for processive replication. Clamps must be loaded onto primer-template DNA (ptDNA) by clamp loaders that open and close clamps around ptDNA in an ATP-fueled reaction. All clamp loaders share a core structure in which five subunits form a spiral chamber that binds the clamp at its base in a twisted open form and encloses ptDNA within, while binding and hydrolyzing ATP to topologically link the clamp and ptDNA. To understand how clamp loaders perform this complex task, here we focused on conserved arginines that might play a central coordinating role in the mechanism because they can alternately contact ptDNA or Walker B glutamate in the ATPase site and lie close to the clamp loader-clamp-binding interface. We mutated Arg-84, Arg-88, and Arg-101 in the ATPase-active B, C, and D subunits of Saccharomyces cerevisiae replication factor C (RFC) clamp loader, respectively, and assessed the impact on multiple transient events in the reaction: proliferating cell nuclear antigen (PCNA) clamp binding/opening/closure/release, ptDNA binding/release, and ATP hydrolysis/product release. The results show that these arginines relay critical information between the PCNA-binding, DNA-binding, and ATPase sites at all steps of the reaction, particularly at a checkpoint before RFC commits to ATP hydrolysis. Moreover, their actions are subunit-specific with RFC-C Arg-88 serving as an accelerator that enables rapid ATP hydrolysis upon contact with ptDNA and RFC-D Arg-101 serving as a brake that confers specificity for ptDNA as the correct substrate for loading PCNA., (© 2017 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2017

11. Evolutionary Covariance Combined with Molecular Dynamics Predicts a Framework for Allostery in the MutS DNA Mismatch Repair Protein.

Author

Lakhani B, Thayer KM, Hingorani MM, and Beveridge DL

Subjects

DNA Mismatch Repair, Hydrogen Bonding, Thermus chemistry, Molecular Dynamics Simulation, MutS DNA Mismatch-Binding Protein chemistry

Abstract

Mismatch repair (MMR) is an essential, evolutionarily conserved pathway that maintains genome stability by correcting base-pairing errors in DNA. Here we examine the sequence and structure of MutS MMR protein to decipher the amino acid framework underlying its two key activities-recognizing mismatches in DNA and using ATP to initiate repair. Statistical coupling analysis (SCA) identified a network (sector) of coevolved amino acids in the MutS protein family. The potential functional significance of this SCA sector was assessed by performing molecular dynamics (MD) simulations for alanine mutants of the top 5% of 160 residues in the distribution, and control nonsector residues. The effects on three independent metrics were monitored: (i) MutS domain conformational dynamics, (ii) hydrogen bonding between MutS and DNA/ATP, and (iii) relative ATP binding free energy. Each measure revealed that sector residues contribute more substantively to MutS structure-function than nonsector residues. Notably, sector mutations disrupted MutS contacts with DNA and/or ATP from a distance via contiguous pathways and correlated motions, supporting the idea that SCA can identify amino acid networks underlying allosteric communication. The combined SCA/MD approach yielded novel, experimentally testable hypotheses for unknown roles of many residues distributed across MutS, including some implicated in Lynch cancer syndrome.

Published

2017

12. Mismatch binding, ADP-ATP exchange and intramolecular signaling during mismatch repair.

Author

Hingorani MM

Subjects

Animals, Humans, MutS DNA Mismatch-Binding Protein metabolism, Adenosine Diphosphate metabolism, Adenosine Triphosphate metabolism, Base Pair Mismatch, DNA Mismatch Repair, Signal Transduction

Abstract

The focus of this article is on the DNA binding and ATPase activities of the mismatch repair (MMR) protein, MutS-our current understanding of how this protein uses ATP to fuel its actions on DNA and initiate repair via interactions with MutL, the next protein in the pathway. Structure-function and kinetic studies have yielded detailed views of the MutS mechanism of action in MMR. How MutS and MutL work together after mismatch recognition to enable strand-specific nicking, which leads to strand excision and synthesis, is less clear and remains an active area of investigation., (Copyright © 2015 Elsevier B.V. All rights reserved.)

Published

2016

13. Single-Molecule FRET to Measure Conformational Dynamics of DNA Mismatch Repair Proteins.

Author

Gauer JW, LeBlanc S, Hao P, Qiu R, Case BC, Sakato M, Hingorani MM, Erie DA, and Weninger KR

Subjects

DNA chemistry, Nucleic Acid Conformation, Protein Conformation, DNA Mismatch Repair genetics, Fluorescence Resonance Energy Transfer methods, Proteins chemistry, Single Molecule Imaging methods

Abstract

Single-molecule FRET measurements have a unique sensitivity to protein conformational dynamics. The FRET signals can either be interpreted quantitatively to provide estimates of absolute distance in a molecule configuration or can be qualitatively interpreted as distinct states, from which quantitative kinetic schemes for conformational transitions can be deduced. Here we describe methods utilizing single-molecule FRET to reveal the conformational dynamics of the proteins responsible for DNA mismatch repair. Experimental details about the proteins, DNA substrates, fluorescent labeling, and data analysis are included. The complementarity of single molecule and ensemble kinetic methods is discussed as well., (© 2016 Elsevier Inc. All rights reserved.)

Published

2016

14. MutL traps MutS at a DNA mismatch.

Author

Qiu R, Sakato M, Sacho EJ, Wilkins H, Zhang X, Modrich P, Hingorani MM, Erie DA, and Weninger KR

Subjects

Genes, Bacterial, Bacterial Proteins genetics, Base Pair Mismatch, Thermus genetics

Abstract

DNA mismatch repair (MMR) identifies and corrects errors made during replication. In all organisms except those expressing MutH, interactions between a DNA mismatch, MutS, MutL, and the replication processivity factor (β-clamp or PCNA) activate the latent MutL endonuclease to nick the error-containing daughter strand. This nick provides an entry point for downstream repair proteins. Despite the well-established significance of strand-specific nicking in MMR, the mechanism(s) by which MutS and MutL assemble on mismatch DNA to allow the subsequent activation of MutL's endonuclease activity by β-clamp/PCNA remains elusive. In both prokaryotes and eukaryotes, MutS homologs undergo conformational changes to a mobile clamp state that can move away from the mismatch. However, the function of this MutS mobile clamp is unknown. Furthermore, whether the interaction with MutL leads to a mobile MutS-MutL complex or a mismatch-localized complex is hotly debated. We used single molecule FRET to determine that Thermus aquaticus MutL traps MutS at a DNA mismatch after recognition but before its conversion to a sliding clamp. Rather than a clamp, a conformationally dynamic protein assembly typically containing more MutL than MutS is formed at the mismatch. This complex provides a local marker where interaction with β-clamp/PCNA could distinguish parent/daughter strand identity. Our finding that MutL fundamentally changes MutS actions following mismatch detection reframes current thinking on MMR signaling processes critical for genomic stability.

Published

2015

15. Slow conformational changes in MutS and DNA direct ordered transitions between mismatch search, recognition and signaling of DNA repair.

Author

Sharma A, Doucette C, Biro FN, and Hingorani MM

Subjects

Adenosine Triphosphate chemistry, Adenosine Triphosphate metabolism, DNA metabolism, Hydrolysis, Kinetics, Models, Biological, Models, Molecular, MutS DNA Mismatch-Binding Protein metabolism, Nucleic Acid Conformation, Protein Binding, Protein Conformation, Signal Transduction, DNA chemistry, DNA Mismatch Repair physiology, MutS DNA Mismatch-Binding Protein chemistry

Abstract

MutS functions in mismatch repair (MMR) to scan DNA for errors, identify a target site and trigger subsequent events in the pathway leading to error removal and DNA re-synthesis. These actions, enabled by the ATPase activity of MutS, are now beginning to be analyzed from the perspective of the protein itself. This study provides the first ensemble transient kinetic data on MutS conformational dynamics as it works with DNA and ATP in MMR. Using a combination of fluorescence probes (on Thermus aquaticus MutS and DNA) and signals (intensity, anisotropy and resonance energy transfer), we have monitored the timing of key conformational changes in MutS that are coupled to mismatch binding and recognition, ATP binding and hydrolysis, as well as sliding clamp formation and signaling of repair. Significant findings include (a) a slow step that follows weak initial interaction between MutS and DNA, in which concerted conformational changes in both macromolecules control mismatch recognition, and (b) rapid, binary switching of MutS conformations that is concerted with ATP binding and hydrolysis and (c) is stalled after mismatch recognition to control formation of the ATP-bound MutS sliding clamp. These rate-limiting pre- and post-mismatch recognition events outline the mechanism of action of MutS on DNA during initiation of MMR., (© 2013.)

Published

2013

16. Distinct structural alterations in proliferating cell nuclear antigen block DNA mismatch repair.

Author

Dieckman LM, Boehm EM, Hingorani MM, and Washington MT

Subjects

Crystallography, X-Ray, DNA Polymerase III metabolism, DNA, Fungal chemistry, DNA, Fungal genetics, DNA, Fungal metabolism, DNA-Binding Proteins metabolism, Electrophoresis, Polyacrylamide Gel, Models, Molecular, Molecular Structure, MutS DNA Mismatch-Binding Protein metabolism, MutS Homolog 2 Protein metabolism, Mutant Proteins chemistry, Mutant Proteins genetics, Mutant Proteins metabolism, Mutation, Missense, Proliferating Cell Nuclear Antigen genetics, Proliferating Cell Nuclear Antigen metabolism, Protein Binding, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism, DNA Mismatch Repair, Proliferating Cell Nuclear Antigen chemistry, Protein Structure, Secondary, Saccharomyces cerevisiae Proteins chemistry

Abstract

During DNA replication, mismatches and small loops in the DNA resulting from insertions or deletions are repaired by the mismatch repair (MMR) machinery. Proliferating cell nuclear antigen (PCNA) plays an important role in both mismatch-recognition and resynthesis stages of MMR. Previously, two mutant forms of PCNA were identified that cause defects in MMR with little, if any, other defects. The C22Y mutant PCNA protein completely blocks MutSα-dependent MMR, and the C81R mutant PCNA protein partially blocks both MutSα-dependent and MutSβ-dependent MMR. In order to understand the structural and mechanistic basis by which these two amino acid substitutions in PCNA proteins block MMR, we solved the X-ray crystal structures of both mutant proteins and carried out further biochemical studies. We found that these amino acid substitutions lead to subtle, distinct structural changes in PCNA. The C22Y substitution alters the positions of the α-helices lining the central hole of the PCNA ring, whereas the C81R substitution creates a distortion in an extended loop near the PCNA subunit interface. We conclude that the structural integrity of the α-helices lining the central hole and this loop are both necessary to form productive complexes with MutSα and mismatch-containing DNA.

Published

2013

17. Escherichia coli heptosyltransferase I: investigation of protein dynamics of a GT-B structural enzyme.

Author

Czyzyk DJ, Sawant SS, Ramirez-Mondragon CA, Hingorani MM, and Taylor EA

Subjects

Crystallization, Escherichia coli chemistry, Escherichia coli genetics, Escherichia coli Proteins genetics, Escherichia coli Proteins metabolism, Glycosyltransferases genetics, Glycosyltransferases metabolism, Kinetics, Protein Binding, Protein Conformation, Substrate Specificity, Escherichia coli enzymology, Escherichia coli Proteins chemistry, Glycosyltransferases chemistry

Abstract

Heptosyltransferase I (HepI), the enzyme responsible for the transfer of l-glycero-d-manno-heptose to a 3-deoxy-α-d-manno-oct-2-ulopyranosonic acid (Kdo) of the growing core region of lipopolysaccharide, is a member of the GT-B structural class of enzymes. Crystal structures have revealed open and closed conformations of apo and ligand-bound GT-B enzymes, implying that large-scale protein conformational dynamics play a role in their reaction mechanism. Here we report transient kinetic analysis of conformational changes in HepI reported by intrinsic tryptophan fluorescence and present the first real-time evidence of a GT-B enzyme undergoing a substrate binding-induced transition from an open to closed state prior to catalysis.

Published

2013

18. DnaN clamp zones provide a platform for spatiotemporal coupling of mismatch detection to DNA replication.

Author

Lenhart JS, Sharma A, Hingorani MM, and Simmons LA

Subjects

Bacillus subtilis genetics, Bacillus subtilis metabolism, MutS DNA Mismatch-Binding Protein metabolism, Bacillus subtilis physiology, Bacterial Proteins metabolism, DNA Mismatch Repair, DNA Replication, DNA-Directed DNA Polymerase metabolism

Abstract

Mismatch repair (MMR) increases the fidelity of DNA replication by identifying and correcting replication errors. Processivity clamps are vital components of DNA replication and MMR, yet the mechanism and extent to which they participate in MMR remains unclear. We investigated the role of the Bacillus subtilis processivity clamp DnaN, and found that it serves as a platform for mismatch detection and coupling of repair to DNA replication. By visualizing functional MutS fluorescent fusions in vivo, we find that MutS forms foci independent of mismatch detection at sites of replication (i.e. the replisome). These MutS foci are directed to the replisome by DnaN clamp zones that aid mismatch detection by targeting the search to nascent DNA. Following mismatch detection, MutS disengages from the replisome, facilitating repair. We tested the functional importance of DnaN-mediated mismatch detection for MMR, and found that it accounts for 90% of repair. This high dependence on DnaN can be bypassed by increasing MutS concentration within the cell, indicating a secondary mode of detection in vivo whereby MutS directly finds mismatches without associating with the replisome. Overall, our results provide new insight into the mechanism by which DnaN couples mismatch recognition to DNA replication in living cells., (© 2012 Blackwell Publishing Ltd.)

Published

2013

19. Impact of individual proliferating cell nuclear antigen-DNA contacts on clamp loading and function on DNA.

Author

Zhou Y and Hingorani MM

Subjects

Amino Acid Substitution, DNA Polymerase III genetics, DNA Polymerase III metabolism, DNA, Fungal genetics, Humans, Mutation, Missense, Proliferating Cell Nuclear Antigen genetics, Protein Structure, Tertiary, Replication Protein C genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics, Structure-Activity Relationship, DNA, Fungal biosynthesis, Proliferating Cell Nuclear Antigen metabolism, Replication Protein C metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

Ring-shaped clamp proteins encircle DNA and affect the work of many proteins, notably processive replication by DNA polymerases. Crystal structures of clamps show several cationic residues inside the ring, and in a co-crystal of Escherichia coli β clamp-DNA, they directly contact the tilted duplex passing through (Georgescu, R. E., Kim, S. S., Yurieva, O., Kuriyan, J., Kong, X. P., and O'Donnell, M. (2008) Structure of a sliding clamp on DNA. Cell 132, 43-54). To investigate the role of these contacts in reactions involving circular clamps, we examined single arginine/lysine mutants of Saccharomyces cerevisiae proliferating cell nuclear antigen (PCNA) in replication factor C (RFC)-catalyzed loading of the clamp onto primer template DNA (ptDNA). Previous kinetic analysis has shown that ptDNA entry inside an ATP-activated RFC-PCNA complex accelerates clamp opening and ATP hydrolysis, which is followed by slow PCNA closure around DNA and product dissociation. Here we directly measured multiple steps in the reaction (PCNA opening, ptDNA binding, PCNA closure, phosphate release, and complex dissociation) to determine whether mutation of PCNA residues Arg-14, Lys-20, Arg-80, Lys-146, Arg-149, or Lys-217 to alanine affects the reaction mechanism. Contrary to earlier steady state analysis of these mutants (McNally, R., Bowman, G. D., Goedken, E. R., O'Donnell, M., and Kuriyan, J. (2010) Analysis of the role of PCNA-DNA contacts during clamp loading. BMC Struct. Biol. 10, 3), our pre-steady state data show that loss of single cationic residues can alter the rates of all DNA-linked steps in the reaction, as well as movement of PCNA on DNA. These results explain an earlier finding that individual arginines and lysines inside human PCNA are essential for polymerase δ processivity (Fukuda, K., Morioka, H., Imajou, S., Ikeda, S., Ohtsuka, E., and Tsurimoto, T. (1995) Structure-function relationship of the eukaryotic DNA replication factor, proliferating cell nuclear antigen. J. Biol. Chem. 270, 22527-22534). Mutations in the N-terminal domain have greater impact than in the C-terminal domain, indicating a positional bias in PCNA-DNA contacts that can influence its functions on DNA.

Published

2012

20. Single-molecule multiparameter fluorescence spectroscopy reveals directional MutS binding to mismatched bases in DNA.

Author

Cristóvão M, Sisamakis E, Hingorani MM, Marx AD, Jung CP, Rothwell PJ, Seidel CA, and Friedhoff P

Subjects

DNA metabolism, Escherichia coli Proteins chemistry, Fluorescence Polarization, Fluorescence Resonance Energy Transfer, Fluorescent Dyes, Models, Molecular, MutS DNA Mismatch-Binding Protein chemistry, Nucleotides chemistry, Protein Binding, Spectrometry, Fluorescence, Base Pair Mismatch, DNA chemistry, DNA Mismatch Repair, Escherichia coli Proteins metabolism, MutS DNA Mismatch-Binding Protein metabolism

Abstract

Mismatch repair (MMR) corrects replication errors such as mismatched bases and loops in DNA. The evolutionarily conserved dimeric MMR protein MutS recognizes mismatches by stacking a phenylalanine of one subunit against one base of the mismatched pair. In all crystal structures of G:T mismatch-bound MutS, phenylalanine is stacked against thymine. To explore whether these structures reflect directional mismatch recognition by MutS, we monitored the orientation of Escherichia coli MutS binding to mismatches by FRET and anisotropy with steady state, pre-steady state and single-molecule multiparameter fluorescence measurements in a solution. The results confirm that specifically bound MutS bends DNA at the mismatch. We found additional MutS-mismatch complexes with distinct conformations that may have functional relevance in MMR. The analysis of individual binding events reveal significant bias in MutS orientation on asymmetric mismatches (G:T versus T:G, A:C versus C:A), but not on symmetric mismatches (G:G). When MutS is blocked from binding a mismatch in the preferred orientation by positioning asymmetric mismatches near the ends of linear DNA substrates, its ability to authorize subsequent steps of MMR, such as MutH endonuclease activation, is almost abolished. These findings shed light on prerequisites for MutS interactions with other MMR proteins for repairing the appropriate DNA strand.

Published

2012

21. Large conformational changes in MutS during DNA scanning, mismatch recognition and repair signalling.

Author

Qiu R, DeRocco VC, Harris C, Sharma A, Hingorani MM, Erie DA, and Weninger KR

Subjects

Adenosine Diphosphate chemistry, Adenosine Triphosphate chemistry, DNA Mismatch Repair genetics, Fluorescence Resonance Energy Transfer, MutS DNA Mismatch-Binding Protein genetics, MutS DNA Mismatch-Binding Protein metabolism, Protein Conformation, DNA Mismatch Repair physiology, MutS DNA Mismatch-Binding Protein chemistry

Abstract

MutS protein recognizes mispaired bases in DNA and targets them for mismatch repair. Little is known about the transient conformations of MutS as it signals initiation of repair. We have used single-molecule fluorescence resonance energy transfer (FRET) measurements to report the conformational dynamics of MutS during this process. We find that the DNA-binding domains of MutS dynamically interconvert among multiple conformations when the protein is free and while it scans homoduplex DNA. Mismatch recognition restricts MutS conformation to a single state. Steady-state measurements in the presence of nucleotides suggest that both ATP and ADP must be bound to MutS during its conversion to a sliding clamp form that signals repair. The transition from mismatch recognition to the sliding clamp occurs via two sequential conformational changes. These intermediate conformations of the MutS:DNA complex persist for seconds, providing ample opportunity for interaction with downstream proteins required for repair.

Published

2012

22. The variable subdomain of Escherichia coli SecA functions to regulate SecA ATPase activity and ADP release.

Author

Das S, Grady LM, Michtavy J, Zhou Y, Cohan FM, Hingorani MM, and Oliver DB

Subjects

Adenosine Triphosphatases genetics, Amino Acid Sequence, Bacterial Proteins genetics, DEAD-box RNA Helicases genetics, DEAD-box RNA Helicases metabolism, Escherichia coli genetics, Escherichia coli Proteins genetics, Escherichia coli Proteins metabolism, Membrane Transport Proteins genetics, Models, Molecular, Molecular Sequence Data, Mutation, Phylogeny, Protein Binding, Protein Conformation, Protein Structure, Tertiary, SEC Translocation Channels, SecA Proteins, Adenosine Diphosphate metabolism, Adenosine Triphosphatases metabolism, Bacterial Proteins metabolism, Escherichia coli metabolism, Gene Expression Regulation, Bacterial physiology, Gene Expression Regulation, Enzymologic physiology, Membrane Transport Proteins metabolism

Abstract

Bacterial SecA proteins can be categorized by the presence or absence of a variable subdomain (VAR) located within nucleotide-binding domain II of the SecA DEAD motor. Here we show that VAR is dispensable for SecA function, since the VAR deletion mutant secAΔ519-547 displayed a wild-type rate of cellular growth and protein export. Loss or gain of VAR is extremely rare in the history of bacterial evolution, indicating that it appears to contribute to secA function within the relevant species in their natural environments. VAR removal also results in additional secA phenotypes: azide resistance (Azi(r)) and suppression of signal sequence defects (PrlD). The SecAΔ(519-547) protein was found to be modestly hyperactive for SecA ATPase activities and displayed an accelerated rate of ADP release, consistent with the biochemical basis of azide resistance. Based on our findings, we discuss models whereby VAR allosterically regulates SecA DEAD motor function at SecYEG.

Published

2012

23. A central swivel point in the RFC clamp loader controls PCNA opening and loading on DNA.

Author

Sakato M, O'Donnell M, and Hingorani MM

Subjects

Adenosine Triphosphatases chemistry, Adenosine Triphosphatases metabolism, Adenosine Triphosphate metabolism, DNA, Fungal chemistry, DNA, Fungal metabolism, Hydrolysis, Kinetics, Models, Molecular, Mutation, Proliferating Cell Nuclear Antigen genetics, Proliferating Cell Nuclear Antigen metabolism, Protein Conformation, Protein Subunits chemistry, Protein Subunits genetics, Protein Subunits metabolism, Replication Protein C genetics, Replication Protein C metabolism, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism, DNA Replication, Proliferating Cell Nuclear Antigen chemistry, Replication Protein C chemistry, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins chemistry

Abstract

Replication factor C (RFC) is a five-subunit complex that loads proliferating cell nuclear antigen (PCNA) clamps onto primer-template DNA (ptDNA) during replication. RFC subunits belong to the AAA(+) superfamily, and their ATPase activity drives interactions between the clamp loader, the clamp, and the ptDNA, leading to topologically linked PCNA·ptDNA. We report the kinetics of transient events in Saccharomyces cerevisiae RFC-catalyzed PCNA loading, including ATP-induced RFC activation, PCNA opening, ptDNA binding, ATP hydrolysis, PCNA closing, and PCNA·ptDNA release. This detailed perspective enables assessment of individual RFC-A, RFC-B, RFC-C, RFC-D, and RFC-E subunit functions in the reaction mechanism. Functions have been ascribed to RFC subunits previously based on a steady-state analysis of 'arginine-finger' ATPase mutants; however, pre-steady-state analysis provides a different view. The central subunit RFC-C serves as a critical swivel point in the clamp loader. ATP binding to this subunit initiates RFC activation, and the clamp loader adopts a spiral conformation that stabilizes PCNA in a corresponding open spiral. The importance of RFC subunit response to ATP binding decreases as RFC-C>RFC-D>RFC-B, with RFC-A being unnecessary. RFC-C-dependent activation of RFC also enables ptDNA binding, leading to the formation of the RFC·ATP·PCNA(open)·ptDNA complex. Subsequent ATP hydrolysis leads to complex dissociation, with RFC-D activity contributing the most to rapid ptDNA release. The pivotal role of the RFC-B/C/D subunit ATPase core in clamp loading is consistent with the similar central location of all three ATPase active subunits of the Escherichia coli clamp loader., (Copyright © 2011 Elsevier Ltd. All rights reserved.)

Published

2012

24. ATP binding and hydrolysis-driven rate-determining events in the RFC-catalyzed PCNA clamp loading reaction.

Author

Sakato M, Zhou Y, and Hingorani MM

Subjects

Adenosine Triphosphate chemistry, Binding Sites, Catalysis, DNA Primers chemistry, DNA Primers metabolism, DNA, Fungal chemistry, DNA, Fungal metabolism, Hydrolysis, Models, Molecular, Proliferating Cell Nuclear Antigen chemistry, Protein Conformation, Replication Protein C chemistry, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins chemistry, Adenosine Triphosphate metabolism, Proliferating Cell Nuclear Antigen metabolism, Replication Protein C metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

The multi-subunit replication factor C (RFC) complex loads circular proliferating cell nuclear antigen (PCNA) clamps onto DNA where they serve as mobile tethers for polymerases and coordinate the functions of many other DNA metabolic proteins. The clamp loading reaction is complex, involving multiple components (RFC, PCNA, DNA, and ATP) and events (minimally: PCNA opening/closing, DNA binding/release, and ATP binding/hydrolysis) that yield a topologically linked clamp·DNA product in less than a second. Here, we report pre-steady-state measurements of several steps in the reaction catalyzed by Saccharomyces cerevisiae RFC and present a comprehensive kinetic model based on global analysis of the data. Highlights of the reaction mechanism are that ATP binding to RFC initiates slow activation of the clamp loader, enabling it to open PCNA (at ~2 s(-1)) and bind primer-template DNA (ptDNA). Rapid binding of ptDNA leads to formation of the RFC·ATP·PCNA(open)·ptDNA complex, which catalyzes a burst of ATP hydrolysis. Another slow step in the reaction follows ATP hydrolysis and is associated with PCNA closure around ptDNA (8 s(-1)). Dissociation of PCNA·ptDNA from RFC leads to catalytic turnover. We propose that these early and late rate-determining events are intramolecular conformational changes in RFC and PCNA that control clamp opening and closure, and that ATP binding and hydrolysis switch RFC between conformations with high and low affinities, respectively, for open PCNA and ptDNA, and thus bookend the clamp loading reaction., (Copyright © 2011 Elsevier Ltd. All rights reserved.)

Published

2012

25. Human MSH2 (hMSH2) protein controls ATP processing by hMSH2-hMSH6.

Author

Heinen CD, Cyr JL, Cook C, Punja N, Sakato M, Forties RA, Lopez JM, Hingorani MM, and Fishel R

Subjects

Adenosine Diphosphate chemistry, Adenosine Diphosphate genetics, Adenosine Diphosphate metabolism, Adenosine Triphosphate genetics, Adenosine Triphosphate metabolism, Colorectal Neoplasms, Hereditary Nonpolyposis enzymology, Colorectal Neoplasms, Hereditary Nonpolyposis genetics, DNA-Binding Proteins genetics, DNA-Binding Proteins metabolism, Humans, Hydrolysis, Kinetics, Multienzyme Complexes genetics, Multienzyme Complexes metabolism, MutS Homolog 2 Protein genetics, MutS Homolog 2 Protein metabolism, Adenosine Triphosphate chemistry, DNA-Binding Proteins chemistry, Multienzyme Complexes chemistry, MutS Homolog 2 Protein chemistry

Abstract

The mechanics of hMSH2-hMSH6 ATP binding and hydrolysis are critical to several proposed mechanisms for mismatch repair (MMR), which in turn rely on the detailed coordination of ATP processing between the individual hMSH2 and hMSH6 subunits. Here we show that hMSH2-hMSH6 is strictly controlled by hMSH2 and magnesium in a complex with ADP (hMSH2(magnesium-ADP)-hMSH6). Destabilization of magnesium results in ADP release from hMSH2 that allows high affinity ATP binding by hMSH6, which then enhances ATP binding by hMSH2. Both subunits must be ATP-bound to efficiently form a stable hMSH2-hMSH6 hydrolysis-independent sliding clamp required for MMR. In the presence of magnesium, the ATP-bound sliding clamps remain on the DNA for ∼8 min. These results suggest a precise stepwise kinetic mechanism for hMSH2-hMSH6 functions that appears to mimic G protein switches, severely constrains models for MMR, and may partially explain the MSH2 allele frequency in Lynch syndrome or hereditary nonpolyposis colorectal cancer.

Published

2011

26. Dynamical allosterism in the mechanism of action of DNA mismatch repair protein MutS.

Author

Pieniazek SN, Hingorani MM, and Beveridge DL

Subjects

Adenosine Triphosphate metabolism, Allosteric Regulation, Protein Structure, Tertiary, Thermus enzymology, DNA Mismatch Repair, Molecular Dynamics Simulation, MutS DNA Mismatch-Binding Protein chemistry, MutS DNA Mismatch-Binding Protein metabolism

Abstract

The multidomain protein Thermus aquaticus MutS and its prokaryotic and eukaryotic homologs recognize DNA replication errors and initiate mismatch repair. MutS actions are fueled by ATP binding and hydrolysis, which modulate its interactions with DNA and other proteins in the mismatch-repair pathway. The DNA binding and ATPase activities are allosterically coupled over a distance of ∼70 Å, and the molecular mechanism of coupling has not been clarified. To address this problem, all-atom molecular dynamics simulations of ∼150 ns including explicit solvent were performed on two key complexes--ATP-bound and ATP-free MutS⋅DNA(+T bulge). We used principal component analysis in fluctuation space to assess ATP ligand-induced changes in MutS structure and dynamics. The molecular dynamics-calculated ensembles of thermally accessible structures showed markedly small differences between the two complexes. However, analysis of the covariance of dynamical fluctuations revealed a number of potentially significant interresidue and interdomain couplings. Moreover, principal component analysis revealed clusters of correlated atomic fluctuations linking the DNA and nucleotide binding sites, especially in the ATP-bound MutS⋅DNA(+T) complex. These results support the idea that allosterism between the nucleotide and DNA binding sites in MutS can occur via ligand-induced changes in motion, i.e., dynamical allosterism., (Copyright © 2011 Biophysical Society. Published by Elsevier Inc. All rights reserved.)

Published

2011

27. Application of stopped-flow kinetics methods to investigate the mechanism of action of a DNA repair protein.

Author

Biro FN, Zhai J, Doucette CW, and Hingorani MM

Subjects

Base Pair Mismatch, Kinetics, DNA Repair, DNA-Binding Proteins metabolism, Fluorometry methods, MutS Homolog 2 Protein metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

Transient kinetic analysis is indispensable for understanding the workings of biological macromolecules, since this approach yields mechanistic information including active site concentrations and intrinsic rate constants that govern macromolecular function. In case of enzymes, for example, transient or pre-steady state measurements identify and characterize individual events in the reaction pathway, whereas steady state measurements only yield overall catalytic efficiency and specificity. Individual events such as protein-protein or protein-ligand interactions and rate-limiting conformational changes often occur in the millisecond timescale, and can be measured directly by stopped-flow and chemical-quench flow methods. Given an optical signal such as fluorescence, stopped-flow serves as a powerful and accessible tool for monitoring reaction progress from substrate binding to product release and catalytic turnover(1,2). Here, we report application of stopped-flow kinetics to probe the mechanism of action of Msh2-Msh6, a eukaryotic DNA repair protein that recognizes base-pair mismatches and insertion/deletion loops in DNA and signals mismatch repair (MMR)(3-5). In doing so, Msh2-Msh6 increases the accuracy of DNA replication by three orders of magnitude (error frequency decreases from approximately 10(-6) to 10(-9) bases), and thus helps preserve genomic integrity. Not surprisingly, defective human Msh2-Msh6 function is associated with hereditary non-polyposis colon cancer and other sporadic cancers(6-8). In order to understand the mechanism of action of this critical DNA metabolic protein, we are probing the dynamics of Msh2-Msh6 interaction with mismatched DNA as well as the ATPase activity that fuels its actions in MMR. DNA binding is measured by rapidly mixing Msh2-Msh6 with DNA containing a 2-aminopurine (2-Ap) fluorophore adjacent to a G:T mismatch and monitoring the resulting increase in 2-aminopurine fluorescence in real time. DNA dissociation is measured by mixing pre-formed Msh2-Msh6 G:T(2-Ap) mismatch complex with unlabeled trap DNA and monitoring decrease in fluorescence over time(9). Pre-steady state ATPase kinetics are measured by the change in fluorescence of 7-diethylamino-3-((((2-maleimidyl)ethyl)amino)carbonyl) coumarin)-labeled Phosphate Binding Protein (MDCC-PBP) on binding phosphate (Pi) released by Msh2-Msh6 following ATP hydrolysis(9,10). The data reveal rapid binding of Msh2-Msh6 to a G:T mismatch and formation of a long-lived Msh2-Msh6 G:T complex, which in turn results in suppression of ATP hydrolysis and stabilization of the protein in an ATP-bound form. The reaction kinetics provide clear support for the hypothesis that ATP-bound Msh2-Msh6 signals DNA repair on binding a mismatched base pair in the double helix. F

Published

2010

28. Saccharomyces cerevisiae Msh2-Msh6 DNA binding kinetics reveal a mechanism of targeting sites for DNA mismatch repair.

Author

Zhai J and Hingorani MM

Subjects

2-Aminopurine metabolism, Adenosine Triphosphatases metabolism, Binding Sites, DNA-Binding Proteins genetics, Kinetics, MutS Homolog 2 Protein genetics, Protein Binding, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics, DNA Mismatch Repair genetics, DNA-Binding Proteins metabolism, MutS Homolog 2 Protein metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

The DNA mismatch repair system (MMR) identifies replication errors and damaged bases in DNA and functions to preserve genomic integrity. MutS performs the task of locating mismatched base pairs, loops and lesions and initiating MMR, and the fundamental question of how this protein targets specific sites in DNA is unresolved. To address this question, we examined the interactions between Saccharomyces cerevisiae Msh2-Msh6, a eukaryotic MutS homolog, and DNA in real time. The reaction kinetics reveal that Msh2-Msh6 binds a variety of sites at similarly fast rates (k (ON) approximately 10(7) M(-1) s(-1)), and its selectivity manifests in differential dissociation rates; e.g., the protein releases a 2-Aminopurine:T base pair approximately 90-fold faster than a G:T mismatch. On releasing the 2-Ap:T site, Msh2-Msh6 is able to move laterally on DNA to locate a nearby G:T site. The long-lived Msh2-Msh6.G:T complex triggers the next step in MMR--formation of an ATP-bound clamp--more effectively than the short-lived Msh2-Msh6.2-Ap:T complex. Mutation of Glu in the conserved Phe-X-Glu DNA binding motif stabilizes Msh2-Msh6(E339A).2-Ap:T complex, and the mutant can signal 2-Ap:T repair as effectively as wild-type Msh2-Msh6 signals G:T repair. These findings suggest a targeting mechanism whereby Msh2-Msh6 scans DNA, interrogating base pairs by transient contacts and pausing at potential target sites, and the longer the pause the greater the likelihood of MMR.

Published

2010

29. Mechanism of cadmium-mediated inhibition of Msh2-Msh6 function in DNA mismatch repair.

Author

Wieland M, Levin MK, Hingorani KS, Biro FN, and Hingorani MM

Subjects

Adenosine Triphosphate metabolism, Binding Sites, Cadmium physiology, Cadmium Chloride chemistry, DNA-Binding Proteins chemistry, DNA-Binding Proteins metabolism, Hydrolysis, MutS Homolog 2 Protein chemistry, Protein Binding, Saccharomyces cerevisiae chemistry, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae physiology, Saccharomyces cerevisiae Proteins chemistry, Base Pair Mismatch, Cadmium chemistry, DNA Repair, DNA-Binding Proteins antagonists & inhibitors, DNA-Binding Proteins physiology, MutS Homolog 2 Protein antagonists & inhibitors, MutS Homolog 2 Protein physiology, Saccharomyces cerevisiae Proteins antagonists & inhibitors, Saccharomyces cerevisiae Proteins physiology

Abstract

The observation that Cadmium (Cd(2+)) inhibits Msh2-Msh6, which is responsible for identifying base pair mismatches and other discrepancies in DNA, has led to the proposal that selective targeting of this protein and consequent suppression of DNA repair or apoptosis promote the carcinogenic effects of the heavy metal toxin. It has been suggested that Cd(2+) binding to specific sites on Msh2-Msh6 blocks its DNA binding and ATPase activities. To investigate the mechanism of inhibition, we measured Cd(2+) binding to Msh2-Msh6, directly and by monitoring changes in protein structure and enzymatic activity. Global fitting of the data to a multiligand binding model revealed that binding of about 100 Cd(2+) ions per Msh2-Msh6 results in its inactivation. This finding indicates that the inhibitory effect of Cd(2+) occurs via a nonspecific mechanism. Cd(2+) and Msh2-Msh6 interactions involve cysteine sulfhydryl groups, and the high Cd(2+):Msh2-Msh6 ratio implicates other ligands such as histidine, aspartate, glutamate, and the peptide backbone as well. Our study also shows that cadmium inactivates several unrelated enzymes similarly, consistent with a nonspecific mechanism of inhibition. Targeting of a variety of proteins, including Msh2-Msh6, in this generic manner would explain the marked broad-spectrum impact of Cd(2+) on biological processes. We propose that the presence of multiple nonspecific Cd(2+) binding sites on proteins and their propensity to change conformation on interaction with Cd(2+) are critical determinants of the susceptibility of corresponding biological systems to cadmium toxicity.

Published

2009

30. Mechanism of ATP-driven PCNA clamp loading by S. cerevisiae RFC.

Author

Chen S, Levin MK, Sakato M, Zhou Y, and Hingorani MM

Subjects

Allosteric Regulation, DNA, Fungal metabolism, Kinetics, Models, Biological, Protein Binding, Protein Conformation, Adenosine Triphosphate metabolism, Proliferating Cell Nuclear Antigen metabolism, Replication Protein C metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

Circular clamps tether polymerases to DNA, serving as essential processivity factors in genome replication, and function in other critical cellular processes as well. Clamp loaders catalyze clamp assembly onto DNA, and the question of how these proteins construct a topological link between a clamp and DNA, especially the mechanism by which ATP is utilized for the task, remains open. Here we describe pre-steady-state analysis of ATP hydrolysis, proliferating cell nuclear antigen (PCNA) clamp opening, and DNA binding by Saccharomyces cerevisiae replication factor C (RFC), and present the first kinetic model of a eukaryotic clamp-loading reaction validated by global data analysis. ATP binding to multiple RFC subunits initiates a slow conformational change in the clamp loader, enabling it to bind and open PCNA and to bind DNA as well. PCNA opening locks RFC into an active state, and the resulting RFC.ATP.PCNA((open)) intermediate is ready for the entry of DNA into the clamp. DNA binding commits RFC to ATP hydrolysis, which is followed by PCNA closure and PCNA.DNA release. This model enables quantitative understanding of the multistep mechanism of a eukaryotic clamp loader and furthermore facilitates comparative analysis of loaders from diverse organisms.

Published

2009

31. Model-based global analysis of heterogeneous experimental data using gfit.

Author

Levin MK, Hingorani MM, Holmes RM, Patel SS, and Carson JH

Subjects

Animals, Humans, Computer Simulation, Models, Biological, Software, Statistics as Topic methods, Systems Biology methods

Abstract

Regression analysis is indispensible for quantitative understanding of biological systems and for developing accurate computational models. By applying regression analysis, one can validate models and quantify components of the system, including ones that cannot be observed directly. Global (simultaneous) analysis of all experimental data available for the system produces the most informative results. To quantify components of a complex system, the dataset needs to contain experiments of different types performed under a broad range of conditions. However, heterogeneity of such datasets complicates implementation of the global analysis. Computational models continuously evolve to include new knowledge and to account for novel experimental data, creating the demand for flexible and efficient analysis procedures. To address these problems, we have developed gfit software to globally analyze many types of experiments, to validate computational models, and to extract maximum information from the available experimental data.

Published

2009

32. Mechanism of MutS searching for DNA mismatches and signaling repair.

Author

Tessmer I, Yang Y, Zhai J, Du C, Hsieh P, Hingorani MM, and Erie DA

Subjects

Adenosine Triphosphate chemistry, Amino Acid Motifs, Base Sequence, DNA chemistry, Hydrolysis, Microscopy, Atomic Force, Models, Biological, Models, Genetic, Molecular Sequence Data, MutS DNA Mismatch-Binding Protein genetics, Phenotype, Protein Conformation, Thermus metabolism, Base Pair Mismatch, DNA Repair, MutS DNA Mismatch-Binding Protein physiology

Abstract

DNA mismatch repair is initiated by the recognition of mismatches by MutS proteins. The mechanism by which MutS searches for and recognizes mismatches and subsequently signals repair remains poorly understood. We used single-molecule analyses of atomic force microscopy images of MutS-DNA complexes, coupled with biochemical assays, to determine the distributions of conformational states, the DNA binding affinities, and the ATPase activities of wild type and two mutants of MutS, with alanine substitutions in the conserved Phe-Xaa-Glu mismatch recognition motif. We find that on homoduplex DNA, the conserved Glu, but not the Phe, facilitates MutS-induced DNA bending, whereas at mismatches, both Phe and Glu promote the formation of an unbent conformation. The data reveal an unusual role for the Phe residue in that it promotes the unbending, not bending, of DNA at mismatch sites. In addition, formation of the specific unbent MutS-DNA conformation at mismatches appears to be required for the inhibition of ATP hydrolysis by MutS that signals initiation of repair. These results provide a structural explanation for the mechanism by which MutS searches for and recognizes mismatches and for the observed phenotypes of mutants with substitutions in the Phe-Xaa-Glu motif.

Published

2008

33. Structure of a mutant form of proliferating cell nuclear antigen that blocks translesion DNA synthesis.

Author

Freudenthal BD, Ramaswamy S, Hingorani MM, and Washington MT

Subjects

Crystallography, X-Ray, DNA-Directed DNA Polymerase biosynthesis, DNA-Directed DNA Polymerase genetics, Nucleic Acid Synthesis Inhibitors metabolism, Proliferating Cell Nuclear Antigen physiology, Protein Conformation, Protein Structure, Secondary genetics, DNA Damage genetics, DNA Replication genetics, Mutation, Nucleic Acid Synthesis Inhibitors chemistry, Proliferating Cell Nuclear Antigen chemistry, Proliferating Cell Nuclear Antigen genetics

Abstract

Proliferating cell nuclear antigen (PCNA) is a homotrimeric protein that functions as a sliding clamp during DNA replication. Several mutant forms of PCNA that block translesion DNA synthesis have been identified in genetic studies in yeast. One such mutant protein (encoded by the rev6-1 allele) is a glycine to serine substitution at residue 178, located at the subunit interface of PCNA. To improve our understanding of how this substitution interferes with translesion synthesis, we have determined the X-ray crystal structure of the PCNA G178S mutant protein. This substitution has little effect on the structure of the domain in which the substitution occurs. Instead, significant, local structural changes are observed in the adjacent subunit. The most notable difference between mutant and wild-type structures is in a single, extended loop (comprising amino acid residues 105-110), which we call loop J. In the mutant protein structure, loop J adopts a very different conformation in which the atoms of the protein backbone have moved by as much as 6.5 A from their positions in the wild-type structure. To improve our understanding of the functional consequences of this structural change, we have examined the ability of this mutant protein to stimulate nucleotide incorporation by DNA polymerase eta (pol eta). Steady state kinetic studies show that while wild-type PCNA stimulates incorporation by pol eta opposite an abasic site, the mutant PCNA protein actually inhibits incorporation opposite this DNA lesion. These results show that the position of loop J in PCNA plays an essential role in facilitating translesion synthesis.

Published

2008

34. Conserved residues in the delta subunit help the E. coli clamp loader, gamma complex, target primer-template DNA for clamp assembly.

Author

Chen S, Coman MM, Sakato M, O'Donnell M, and Hingorani MM

Subjects

Adenosine Triphosphatases metabolism, Adenosine Triphosphate metabolism, Amino Acid Motifs, Conserved Sequence, DNA Polymerase III genetics, DNA Polymerase III metabolism, DNA Primers metabolism, Escherichia coli Proteins genetics, Escherichia coli Proteins metabolism, Mutagenesis, Site-Directed, Protein Binding, Templates, Genetic, Tryptophan chemistry, Tryptophan genetics, DNA metabolism, DNA Polymerase III chemistry, DNA Replication, Escherichia coli Proteins chemistry

Abstract

The Escherichia coli clamp loader, gamma complex (gamma(3)deltadelta'lambdapsi), catalyzes ATP-driven assembly of beta clamps onto primer-template DNA (p/tDNA), enabling processive replication. The mechanism by which gamma complex targets p/tDNA for clamp assembly is not resolved. According to previous studies, charged/polar amino acids inside the clamp loader chamber interact with the double-stranded (ds) portion of p/tDNA. We find that dsDNA, not ssDNA, can trigger a burst of ATP hydrolysis by gamma complex and clamp assembly, but only at far higher concentrations than p/tDNA. Thus, contact between gamma complex and dsDNA is necessary and sufficient, but not optimal, for the reaction, and additional contacts with p/tDNA likely facilitate its selection as the optimal substrate for clamp assembly. We investigated whether a conserved sequence-HRVW(279)QNRR--in delta subunit contributes to such interactions, since Tryptophan-279 specifically cross-links to the primer-template junction. Mutation of delta-W279 weakens gamma complex binding to p/tDNA, hampering its ability to load clamps and promote proccessive DNA replication, and additional mutations in the sequence (delta-R277, delta-R283) worsen the interaction. These data reveal a novel location in the C-terminal domain of the E. coli clamp loader that contributes to DNA binding and helps define p/tDNA as the preferred substrate for the reaction.

Published

2008

35. TIRF(ing) reveals Msh2-Msh6 surfing on DNA.

Author

Hingorani MM

Subjects

Base Pair Mismatch, Dimerization, DNA, Fungal chemistry, DNA-Binding Proteins chemistry, Fungal Proteins chemistry, Microscopy, Fluorescence methods, MutS Homolog 2 Protein chemistry, Saccharomyces cerevisiae Proteins chemistry

Published

2007

36. The effects of nucleotides on MutS-DNA binding kinetics clarify the role of MutS ATPase activity in mismatch repair.

Author

Jacobs-Palmer E and Hingorani MM

Subjects

Adenosine Diphosphate metabolism, Adenosine Triphosphate metabolism, Base Sequence, Dose-Response Relationship, Drug, Models, Genetic, Molecular Sequence Data, Molecular Structure, MutS DNA Mismatch-Binding Protein genetics, Nucleotides chemistry, 2-Aminopurine chemistry, Adenosine Triphosphatases metabolism, Base Pair Mismatch, DNA Mismatch Repair, DNA-Binding Proteins metabolism, MutS DNA Mismatch-Binding Protein metabolism

Abstract

MutS protein initiates mismatch repair with recognition of a non-Watson-Crick base-pair or base insertion/deletion site in DNA, and its interactions with DNA are modulated by ATPase activity. Here, we present a kinetic analysis of these interactions, including the effects of ATP binding and hydrolysis, reported directly from the mismatch site by 2-aminopurine fluorescence. When free of nucleotides, the Thermus aquaticus MutS dimer binds a mismatch rapidly (k(ON)=3 x 10(6) M(-1) s(-1)) and forms a stable complex with a half-life of 10 s (k(OFF)=0.07 s(-1)). When one or both nucleotide-binding sites on the MutS*mismatch complex are occupied by ATP, the complex remains fairly stable, with a half-life of 5-7 s (k(OFF)=0.1-0.14 s(-1)), although MutS(ATP) becomes incapable of (re-)binding the mismatch. When one or both nucleotide-binding sites on the MutS dimer are occupied by ADP, the MutS*mismatch complex forms rapidly (k(ON)=7.3 x 10(6) M(-1) s(-1)) and also dissociates rapidly, with a half-life of 0.4 s (k(OFF)=1.7 s(-1)). Integration of these MutS DNA-binding kinetics with previously described ATPase kinetics reveals that: (a) in the absence of a mismatch, MutS in the ADP-bound form engages in highly dynamic interactions with DNA, perhaps probing base-pairs for errors; (b) in the presence of a mismatch, MutS stabilized in the ATP-bound form releases the mismatch slowly, perhaps allowing for onsite interactions with downstream repair proteins; (c) ATP-bound MutS then moves off the mismatch, perhaps as a mobile clamp facilitating repair reactions at distant sites on DNA, until ATP is hydrolyzed (or dissociates) and the protein turns over.

Published

2007

37. Contribution of Msh2 and Msh6 subunits to the asymmetric ATPase and DNA mismatch binding activities of Saccharomyces cerevisiae Msh2-Msh6 mismatch repair protein.

Author

Antony E, Khubchandani S, Chen S, and Hingorani MM

Subjects

Adenosine Triphosphate chemistry, Amino Acid Motifs, Amino Acid Sequence, DNA chemistry, DNA metabolism, DNA Repair, Dimerization, Dose-Response Relationship, Drug, Fungal Proteins chemistry, Genes, Fungal, Hydrolysis, Kinetics, Models, Biological, Models, Chemical, Models, Molecular, Molecular Sequence Data, MutS DNA Mismatch-Binding Protein metabolism, Mutation, Nucleotides chemistry, Point Mutation, Protein Binding, Protein Structure, Tertiary, Proteins chemistry, Time Factors, Adenosine Triphosphatases chemistry, Base Pair Mismatch, DNA-Binding Proteins metabolism, MutS Homolog 2 Protein metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

Previous analyses of both Thermus aquaticus MutS homodimer and Saccharomyces cerevisiae Msh2-Msh6 heterodimer have revealed that the subunits in these protein complexes bind and hydrolyze ATP asymmetrically, emulating their asymmetric DNA binding properties. In the MutS homodimer, one subunit (S1) binds ATP with high affinity and hydrolyzes it rapidly, while the other subunit (S2) binds ATP with lower affinity and hydrolyzes it at an apparently slower rate. Interaction of MutS with mismatched DNA results in suppression of ATP hydrolysis at S1-but which of these subunits, S1 or S2, makes specific contact with the mismatch (e.g., base stacking by a conserved phenylalanine residue) remains unknown. In order to answer this question and to clarify the links between the DNA binding and ATPase activities of each subunit in the dimer, we made mutations in the ATPase sites of Msh2 and Msh6 and assessed their impact on the activity of the Msh2-Msh6 heterodimer (in Msh2-Msh6, only Msh6 makes base specific contact with the mismatch). The key findings are: (a) Msh6 hydrolyzes ATP rapidly, and thus resembles the S1 subunit of the MutS homodimer, (b) Msh2 hydrolyzes ATP at a slower rate, and thus resembles the S2 subunit of MutS, (c) though itself an apparently weak ATPase, Msh2 has a strong influence on the ATPase activity of Msh6, (d) Msh6 binding to mismatched DNA results in suppression of rapid ATP hydrolysis, revealing a "cis" linkage between its mismatch recognition and ATPase activities, (e) the resultant Msh2-Msh6 complex, with both subunits in the ATP-bound state, exhibits altered interactions with the mismatch.

Published

2006

38. Role of a conserved glutamate residue in the Escherichia coli SecA ATPase mechanism.

Author

Zito CR, Antony E, Hunt JF, Oliver DB, and Hingorani MM

Subjects

Adenosine Triphosphate chemistry, Amino Acid Sequence, Aspartic Acid chemistry, Bacillus subtilis metabolism, Binding Sites, Catalysis, Cell Membrane metabolism, Dimerization, Escherichia coli metabolism, Hydrolysis, Kinetics, Magnesium chemistry, Molecular Sequence Data, Mutation, Phosphates chemistry, Protein Structure, Tertiary, Protein Transport, SEC Translocation Channels, SecA Proteins, Sequence Homology, Amino Acid, Time Factors, Adenosine Triphosphatases chemistry, Bacterial Proteins chemistry, Escherichia coli enzymology, Glutamic Acid chemistry, Membrane Transport Proteins chemistry

Abstract

Escherichia coli SecA uses ATP to drive the transport of proteins across cell membranes. Glutamate 210 in the "DEVD" Walker B motif of the SecA ATP-binding site has been proposed as the catalytic base for ATP hydrolysis (Hunt, J. F., Weinkauf, S., Henry, L., Fak, J. J., McNicholas, P., Oliver, D. B., and Deisenhofer, J. (2002) Science 297, 2018-2026). Consistent with this hypothesis, we find that mutation of glutamate 210 to aspartate results in a 90-fold reduction of the ATP hydrolysis rate compared with wild type SecA, 0.3 s(-1) versus 27 s(-1), respectively. SecA-E210D also releases ADP at a slower rate compared with wild type SecA, suggesting that in addition to serving as the catalytic base, glutamate 210 might aid turnover as well. Our results contradict an earlier report that proposed aspartate 133 as the catalytic base (Sato, K., Mori, H., Yoshida, M., and Mizushima, S. (1996) J. Biol. Chem. 271, 17439-17444). Re-evaluation of the SecA-D133N mutant used in that study confirms its loss of ATPase and membrane translocation activities, but surprisingly, the analogous SecA-D133A mutant retains full activity, revealing that this residue does not play a key role in catalysis.

Published

2005

39. Asymmetric ATP binding and hydrolysis activity of the Thermus aquaticus MutS dimer is key to modulation of its interactions with mismatched DNA.

Author

Antony E and Hingorani MM

Subjects

Adenosine Diphosphate chemistry, Adenosine Triphosphatases antagonists & inhibitors, Adenosine Triphosphatases genetics, Bacterial Proteins antagonists & inhibitors, Bacterial Proteins genetics, DNA, Bacterial genetics, DNA-Binding Proteins antagonists & inhibitors, DNA-Binding Proteins genetics, Dimerization, Enzyme Repression genetics, Escherichia coli Proteins, Hydrolysis, Kinetics, MutS DNA Mismatch-Binding Protein, Mutagenesis, Insertional, Protein Binding genetics, Protein Subunits chemistry, Protein Subunits genetics, Thermus genetics, Adenosine Triphosphatases chemistry, Adenosine Triphosphate analogs & derivatives, Adenosine Triphosphate chemistry, Bacterial Proteins chemistry, Base Pair Mismatch genetics, DNA, Bacterial chemistry, DNA-Binding Proteins chemistry, Thermus enzymology

Abstract

Prokaryotic MutS and eukaryotic Msh proteins recognize base pair mismatches and insertions or deletions in DNA and initiate mismatch repair. These proteins function as dimers (and perhaps higher order oligomers) and possess an ATPase activity that is essential for DNA repair. Previous studies of Escherichia coli MutS and eukaryotic Msh2-Msh6 proteins have revealed asymmetry within the dimer with respect to both DNA binding and ATPase activities. We have found the Thermus aquaticus MutS protein amenable to detailed investigation of the nature and role of this asymmetry. Here, we show that (a) in a MutS dimer one subunit (S1) binds nucleotide with high affinity and the other (S2) with 10-fold weaker affinity, (b) S1 hydrolyzes ATP rapidly while S2 hydrolyzes ATP at a 30-50-fold slower rate, (c) mismatched DNA binding to MutS inhibits ATP hydrolysis at S1 but slow hydrolysis continues at S2, and (d) interaction between mismatched DNA and MutS is weakened when both subunits are occupied by ATP but remains stable when S1 is occupied by ATP and S2 by ADP. These results reveal key MutS species in the ATPase pathway; S1(ADP)-S2(ATP) is formed preferentially in the absence of DNA or in the presence of fully matched DNA, while S1(ATP)-S2(ATP) and S1(ATP)-S2(ADP) are formed preferentially in the presence of mismatched DNA. These MutS species exhibit differences in interaction with mismatched DNA that are likely important for the mechanism of MutS action in DNA repair.

Published

2004

40. Dual functions, clamp opening and primer-template recognition, define a key clamp loader subunit.

Author

Magdalena Coman M, Jin M, Ceapa R, Finkelstein J, O'Donnell M, Chait BT, and Hingorani MM

Subjects

Adenosine Triphosphate metabolism, Binding Sites, Bromodeoxyuridine metabolism, Cross-Linking Reagents, Electrophoresis, Polyacrylamide Gel, Escherichia coli genetics, Mass Spectrometry, Protein Conformation, Protein Subunits, Saccharomyces cerevisiae enzymology, Saccharomyces cerevisiae genetics, Templates, Genetic, Tryptophan chemistry, Ultraviolet Rays, DNA Polymerase III metabolism, DNA Replication, DNA, Bacterial metabolism, Escherichia coli enzymology

Abstract

Clamp loader proteins catalyze assembly of circular sliding clamps on DNA to enable processive DNA replication. During the reaction, the clamp loader binds primer-template DNA and positions it in the center of a clamp to form a topological link between the two. Clamp loaders are multi-protein complexes, such as the five protein Escherichia coli, Saccharomyces cerevisiae, and human clamp loaders, and the two protein Pyrococcus furiosus and Methanobacterium thermoautotrophicum clamp loaders, and thus far the site(s) responsible for binding and selecting primer-template DNA as the target for clamp assembly remain unknown. To address this issue, we analyzed the interaction between the E.coli gamma complex clamp loader and DNA using UV-induced protein-DNA cross-linking and mass spectrometry. The results show that the delta subunit in the gamma complex makes close contact with the primer-template junction. Tryptophan 279 in the delta C-terminal domain lies near the 3'-OH primer end and may play a key role in primer-template recognition. Previous studies have shown that delta also binds and opens the beta clamp (hydrophobic residues in the N-terminal domain of delta contact beta. The clamp-binding and DNA-binding sites on delta appear positioned for facile entry of primer-template into the center of the clamp and exit of the template strand from the complex. A similar analysis of the S.cerevisiae RFC complex suggests that the dual functionality observed for delta in the gamma complex may be true also for clamp loaders from other organisms.

Published

2004

41. Replication factor C clamp loader subunit arrangement within the circular pentamer and its attachment points to proliferating cell nuclear antigen.

Author

Yao N, Coryell L, Zhang D, Georgescu RE, Finkelstein J, Coman MM, Hingorani MM, and O'Donnell M

Subjects

Adenosine Triphosphatases metabolism, Adenosine Triphosphate chemistry, Arginine chemistry, Cell Division, Chromatography, Gel, Crystallography, X-Ray, DNA-Binding Proteins metabolism, Dose-Response Relationship, Drug, Escherichia coli metabolism, Hydrolysis, Models, Molecular, Plasmids metabolism, Proliferating Cell Nuclear Antigen metabolism, Protein Binding, Protein Conformation, Protein Structure, Tertiary, Replication Protein C, Saccharomyces cerevisiae metabolism, Time Factors, DNA-Binding Proteins chemistry, Proliferating Cell Nuclear Antigen chemistry

Abstract

Replication factor C (RFC) is a heteropentameric AAA+ protein clamp loader of the proliferating cell nuclear antigen (PCNA) processivity factor. The prokaryotic homologue, gamma complex, is also a heteropentamer, and structural studies show the subunits are arranged in a circle. In this report, Saccharomyces cerevisiae RFC protomers are examined for their interaction with each other and PCNA. The data lead to a model of subunit order around the circle. A characteristic of AAA+ oligomers is the use of bipartite ATP sites in which one subunit supplies a catalytic arginine residue for hydrolysis of ATP bound to the neighboring subunit. We find that the RFC(3/4) complex is a DNA-dependent ATPase, and we use this activity to determine that RFC3 supplies a catalytic arginine to the ATP site of RFC4. This information, combined with the subunit arrangement, defines the composition of the remaining ATP sites. Furthermore, the RFC(2/3) and RFC(3/4) subassemblies bind stably to PCNA, yet neither RFC2 nor RFC4 bind tightly to PCNA, indicating that RFC3 forms a strong contact point to PCNA. The RFC1 subunit also binds PCNA tightly, and we identify two hydrophobic residues in RFC1 that are important for this interaction. Therefore, at least two subunits in RFC make strong contacts with PCNA, unlike the Escherichia coli gamma complex in which only one subunit makes strong contact with the beta clamp. Multiple strong contact points to PCNA may reflect the extra demands of loading the PCNA trimeric ring onto DNA compared with the dimeric beta ring.

Published

2003

42. Overproduction and analysis of eukaryotic multiprotein complexes in Escherichia coli using a dual-vector strategy.

Author

Finkelstein J, Antony E, Hingorani MM, and O'Donnell M

Subjects

DNA-Binding Proteins genetics, DNA-Binding Proteins metabolism, Fungal Proteins genetics, Fungal Proteins metabolism, Genetic Vectors genetics, Macromolecular Substances, Models, Biological, MutS Homolog 2 Protein, Protein Structure, Quaternary, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics, Escherichia coli genetics, Gene Expression, Saccharomyces cerevisiae Proteins chemistry, Saccharomyces cerevisiae Proteins metabolism

Abstract

Biochemical studies of eukaryotic proteins are often constrained by low availability of these typically large, multicomponent protein complexes in pure form. Escherichia coli is a commonly used host for large-scale protein production; however, its utility for eukaryotic protein production is limited because of problems associated with transcription, translation, and proper folding of proteins. Here we describe the development and testing of pLANT, a vector that addresses many of these problems simultaneously. The pLANT vector contains a T7 promoter-controlled expression unit, a p15A origin of replication, and genes for rare transfer RNAs and kanamycin resistance. Thus, the pLANT vector can be used in combination with the pET vector to coexpress multiple proteins in E. coli. Using this approach, we have successfully produced high-milligram quantities of two different Saccharomyces cerevisiae complexes in E. coli: the heterodimeric Msh2-Msh6 mismatch repair protein (248kDa) and the five-subunit replication factor C clamp loader (250 kDa). Quantitative analyses indicate that these proteins are fully active, affirming the utility of pLANT+pET-based production of eukaryotic proteins in E. coli for in vitro studies of their structure and function.

Published

2003

43. Mismatch recognition-coupled stabilization of Msh2-Msh6 in an ATP-bound state at the initiation of DNA repair.

Author

Antony E and Hingorani MM

Subjects

Adenosine Triphosphatases, Base Pair Mismatch, DNA metabolism, Escherichia coli, MutS Homolog 2 Protein, Recombinant Proteins metabolism, Saccharomyces cerevisiae metabolism, Adenosine Triphosphate metabolism, DNA Repair physiology, DNA-Binding Proteins metabolism, Fungal Proteins metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

Mismatch repair proteins correct errors in DNA via an ATP-driven process. In eukaryotes, the Msh2-Msh6 complex recognizes base pair mismatches and small insertion/deletions in DNA and initiates repair. Both Msh2 and Msh6 proteins contain Walker ATP-binding motifs that are necessary for repair activity. To understand how these proteins couple ATP binding and hydrolysis to DNA binding/mismatch recognition, the ATPase activity of Saccharomyces cerevisiae Msh2-Msh6 was examined under pre-steady-state conditions. Acid-quench experiments revealed that in the absence of DNA, Msh2-Msh6 hydrolyzes ATP rapidly (burst rate = 3 s(-1) at 20 degrees C) and then undergoes a slow step in the pathway that limits catalytic turnover (k(cat) = 0.1 s(-1)). ATP is hydrolyzed similarly in the presence of fully matched duplex DNA; however, in the presence of a G:T mismatch or +T insertion-containing DNA, ATP hydrolysis is severely suppressed (rate = 0.1 s(-1)). Pulse-chase experiments revealed that Msh2-Msh6 binds ATP rapidly in the absence or in the presence of DNA (rate = 0.1 microM(-1) s(-1)), indicating that for the Msh2-Msh6.mismatched DNA complex, a step after ATP binding but before or at ATP hydrolysis is the rate-limiting step in the pathway. Thus, mismatch recognition is coupled to a dramatic increase in the residence time of ATP on Msh2-Msh6. This mismatch-induced, stable ATP-bound state of Msh2-Msh6 likely signals downstream events in the repair pathway.

Published

2003

44. Mechanism of loading the Escherichia coli DNA polymerase III beta sliding clamp on DNA. Bona fide primer/templates preferentially trigger the gamma complex to hydrolyze ATP and load the clamp.

Author

Ason B, Handayani R, Williams CR, Bertram JG, Hingorani MM, O'Donnell M, Goodman MF, and Bloom LB

Subjects

Binding Sites, DNA Polymerase III chemistry, DNA Primers, Hydrolysis, Kinetics, Templates, Genetic, Adenosine Triphosphate metabolism, DNA metabolism, DNA Polymerase III metabolism, Escherichia coli enzymology, Escherichia coli Proteins metabolism, Holoenzymes chemistry

Abstract

The Escherichia coli DNA polymerase III gamma complex clamp loader assembles the ring-shaped beta sliding clamp onto DNA. The core polymerase is tethered to the template by beta, enabling processive replication of the genome. Here we investigate the DNA substrate specificity of the clamp-loading reaction by measuring the pre-steady-state kinetics of DNA binding and ATP hydrolysis using elongation-proficient and deficient primer/template DNA. The ATP-bound clamp loader binds both elongation-proficient and deficient DNA substrates either in the presence or absence of beta. However, elongation-proficient DNA preferentially triggers gamma complex to release beta onto DNA with concomitant hydrolysis of ATP. Binding to elongation-proficient DNA converts the gamma complex from a high affinity ATP-bound state to an ADP-bound state having a 10(5)-fold lower affinity for DNA. Steady-state binding assays are misleading, suggesting that gamma complex binds much more avidly to non-extendable primer/template DNA because recycling to the high affinity binding state is rate-limiting. Pre-steady-state rotational anisotropy data reveal a dynamic association-dissociation of gamma complex with extendable primer/templates leading to the diametrically opposite conclusion. The strongly favored dynamic recognition of extendable DNA does not require the presence of beta. Thus, the gamma complex uses ATP binding and hydrolysis as a mechanism for modulating its interaction with DNA in which the ATP-bound form binds with high affinity to DNA but elongation-proficient DNA substrates preferentially trigger hydrolysis of ATP and conversion to a low affinity state.

Published

2003

45. On the specificity of interaction between the Saccharomyces cerevisiae clamp loader replication factor C and primed DNA templates during DNA replication.

Author

Hingorani MM and Coman MM

Subjects

Binding Sites, Binding, Competitive, DNA metabolism, DNA, Single-Stranded ultrastructure, Dose-Response Relationship, Drug, Electrophoresis, Polyacrylamide Gel, Escherichia coli metabolism, Escherichia coli ultrastructure, Kinetics, Models, Biological, Protein Binding, Replication Protein C, Substrate Specificity, Trypsin pharmacology, DNA biosynthesis, DNA Replication, DNA-Binding Proteins chemistry, DNA-Binding Proteins metabolism, Saccharomyces cerevisiae metabolism

Abstract

Replication factor C (RFC) catalyzes assembly of circular proliferating cell nuclear antigen clamps around primed DNA, enabling processive synthesis by DNA polymerase during DNA replication and repair. In order to perform this function efficiently, RFC must rapidly recognize primed DNA as the substrate for clamp assembly, particularly during lagging strand synthesis. Earlier reports as well as quantitative DNA binding experiments from this study indicate, however, that RFC interacts with primer-template as well as single- and double-stranded DNA (ssDNA and dsDNA, respectively) with similar high affinity (apparent K(d) approximately 10 nm). How then can RFC distinguish primed DNA sites from excess ssDNA and dsDNA at the replication fork? Further analysis reveals that despite its high affinity for various DNA structures, RFC selects primer-template DNA even in the presence of a 50-fold excess of ssDNA and dsDNA. The interaction between ssDNA or dsDNA and RFC is far less stable than between primed DNA and RFC (k(off) > 0.2 s(-1) versus 0.025 s(-1), respectively). We propose that the ability to rapidly bind and release single- and double-stranded DNA coupled with selective, stable binding to primer-template DNA allows RFC to scan DNA efficiently for primed sites where it can pause to initiate clamp assembly.

Published

2002

46. Mechanism of beta clamp opening by the delta subunit of Escherichia coli DNA polymerase III holoenzyme.

Author

Stewart J, Hingorani MM, Kelman Z, and O'Donnell M

Subjects

Adenosine Triphosphate metabolism, Amino Acid Sequence, Chromatography, Gel, DNA metabolism, DNA Polymerase III genetics, Dimerization, Kinetics, Models, Biological, Models, Molecular, Molecular Sequence Data, Mutation, Nickel metabolism, Promoter Regions, Genetic, Protein Binding, Protein Conformation, Surface Plasmon Resonance, Time Factors, DNA Polymerase III chemistry, DNA Polymerase III metabolism, Escherichia coli enzymology

Abstract

The beta sliding clamp encircles the primer-template and tethers DNA polymerase III holoenzyme to DNA for processive replication of the Escherichia coli genome. The clamp is formed via hydrophobic and ionic interactions between two semicircular beta monomers. This report demonstrates that the beta dimer is a stable closed ring and is not monomerized when the gamma complex clamp loader (gamma(3)delta(1)delta(1)chi(1)psi(1)) assembles the beta ring around DNA. delta is the subunit of the gamma complex that binds beta and opens the ring; it also does not appear to monomerize beta. Point mutations were introduced at the beta dimer interface to test its structural integrity and gain insight into its interaction with delta. Mutation of two residues at the dimer interface of beta, I272A/L273A, yields a stable beta monomer. We find that delta binds the beta monomer mutant at least 50-fold tighter than the beta dimer. These findings suggest that when delta interacts with the beta clamp, it binds one beta subunit with high affinity and utilizes some of that binding energy to perform work on the dimeric clamp, probably cracking one dimer interface open.

Published

2001

47. The delta subunit of DNA polymerase III holoenzyme serves as a sliding clamp unloader in Escherichia coli.

Author

Leu FP, Hingorani MM, Turner J, and O'Donnell M

Subjects

Blotting, Western, DNA Replication, DNA, Bacterial biosynthesis, DNA, Bacterial metabolism, DNA Polymerase III metabolism, Escherichia coli enzymology

Abstract

In Escherichia coli, the circular beta sliding clamp facilitates processive DNA replication by tethering the polymerase to primer-template DNA. When synthesis is complete, polymerase dissociates from beta and DNA and cycles to a new start site, a primed template loaded with beta. DNA polymerase cycles frequently during lagging strand replication while synthesizing 1-2-kilobase Okazaki fragments. The clamps left behind remain stable on DNA (t(12) approximately 115 min) and must be removed rapidly for reuse at numerous primed sites on the lagging strand. Here we show that delta, a single subunit of DNA polymerase III holoenzyme, opens beta and slips it off DNA (k(unloading) = 0.011 s(-)(1)) at a rate similar to that of the multisubunit gamma complex clamp loader by itself (0.015 s(-)(1)) or within polymerase (pol) III* (0.0065 s(-)(1)). Moreover, unlike gamma complex and pol III*, delta does not require ATP to catalyze clamp unloading. Quantitation of gamma complex subunits (gamma, delta, delta', chi, psi) in E. coli cells reveals an excess of delta, free from gamma complex and pol III*. Since pol III* and gamma complex occur in much lower quantities and perform several DNA metabolic functions in replication and repair, the delta subunit probably aids beta clamp recycling during DNA replication.

Published

2000

48. A tale of toroids in DNA metabolism.

Author

Hingorani MM and O'Donnell M

Subjects

Animals, DNA Helicases chemistry, DNA Helicases metabolism, DNA Topoisomerases, Type I chemistry, DNA Topoisomerases, Type I metabolism, DNA-Binding Proteins metabolism, Humans, Models, Molecular, Proteins metabolism, Recombination, Genetic, DNA metabolism, DNA-Binding Proteins chemistry, Protein Structure, Quaternary, Proteins chemistry

Abstract

A strikingly large number of the proteins involved in DNA metabolism adopt a toroidal -- or ring-shaped -- quaternary structure, even though they have completely unrelated functions. Given that these proteins all use DNA as a substrate, their convergence to one shape is probably not a coincidence. Ring-forming proteins may have been selected during evolution for advantages conferred by the toroidal shape on their interactions with DNA.

Published

2000

49. Molecular mechanism and energetics of clamp assembly in Escherichia coli. The role of ATP hydrolysis when gamma complex loads beta on DNA.

Author

Bertram JG, Bloom LB, Hingorani MM, Beechem JM, O'Donnell M, and Goodman MF

Subjects

Hydrolysis, Adenosine Triphosphate metabolism, DNA chemistry, DNA Polymerase III chemistry, Escherichia coli metabolism, Holoenzymes chemistry

Abstract

Escherichia coli DNA polymerase III holoenzyme is a multisubunit composite containing the beta sliding clamp and clamp loading gamma complex. The gamma complex requires ATP to load beta onto DNA. A two-color fluorescence spectroscopic approach was utilized to study this system, wherein both assembly (red fluorescence; X-rhodamine labeled DNA anisotropy assay) and ATP hydrolysis (green fluorescence; phosphate binding protein assay) were simultaneously measured with millisecond timing resolution. The two temporally correlated stopped-flow signals revealed that a preassembled beta. gamma complex composite rapidly binds primer/template DNA in an ATP hydrolysis independent step. Once bound, two molecules of ATP are rapidly hydrolyzed (approximately 34 s(-1)). Following hydrolysis, gamma complex dissociates from the DNA ( approximately 22 s(-1)). Once dissociated, the next cycle of loading is severely compromised, resulting in steady-state ATP hydrolysis rates with a maximum of only approximately 3 s(-1). Two single-site beta dimer interface mutants were examined which had impaired steady-state rates of ATP hydrolysis. The pre-steady-state correlated kinetics of these mutants revealed a pattern essentially identical to wild type. The anisotropy data showed that these mutants decrease the steady-state rates of ATP hydrolysis by causing a buildup of "stuck" binary-ternary complexes on the primer/template DNA.

Published

2000

50. A model for Escherichia coli DNA polymerase III holoenzyme assembly at primer/template ends. DNA triggers a change in binding specificity of the gamma complex clamp loader.

Author

Ason B, Bertram JG, Hingorani MM, Beechem JM, O'Donnell M, Goodman MF, and Bloom LB

Subjects

Adenosine Triphosphate analogs & derivatives, Adenosine Triphosphate metabolism, Base Sequence, Binding, Competitive, DNA Primers, Kinetics, Substrate Specificity, Templates, Genetic, DNA Polymerase III metabolism, Escherichia coli enzymology

Abstract

The gamma complex of the Escherichia coli DNA polymerase III holoenzyme assembles the beta sliding clamp onto DNA in an ATP hydrolysis-driven reaction. Interactions between gamma complex and primer/template DNA are investigated using fluorescence depolarization to measure binding of gamma complex to different DNA substrates under steady-state and presteady-state conditions. Surprisingly, gamma complex has a much higher affinity for single-stranded DNA (K(d) in the nM range) than for a primed template (K(d) in the microM range) under steady-state conditions. However, when examined on a millisecond time scale, we find that gamma complex initially binds very rapidly and with high affinity to primer/template DNA but is converted subsequently to a much lower affinity DNA binding state. Presteady-state data reveals an effective dissociation constant of 1.5 nM for the initial binding of gamma complex to DNA and a dissociation constant of 5.7 microM for the low affinity DNA binding state. Experiments using nonhydrolyzable ATPgammaS show that ATP binding converts gamma complex from a low affinity "inactive" to high affinity "active" DNA binding state while ATP hydrolysis has the reverse effect, thus allowing cycling between active and inactive DNA binding forms at steady-state. We propose that a DNA-triggered switch between active and inactive states of gamma complex provides a two-tiered mechanism enabling gamma complex to recognize primed template sites and load beta, while preventing gamma complex from competing with DNA polymerase III core for binding a newly loaded beta.DNA complex.

Published

2000