MSH-MLH complexes formed at a DNA mismatch are disrupted by the PCNA sliding clamp

Mitochondrial Transcription Factor A Binds to and Promotes Mutagenic Transcriptional Bypass of O4-Alkylthymidine Lesions

O2- and O4-alkylated thymidine lesions are known to be poorly repaired and persist in mammalian tissues. To understand how mammalian cells sense the presence and regulate the repair of these lesions, we employed a quantitative proteomic method to discover regioisomeric O2- and O4-n-butylthymidine (O2- and O4-nBudT)-binding proteins. We were able to identify 21 and 74 candidate DNA damage recognition proteins for O2-nBudT- and O4-nBudT-bearing DNA probes, respectively. Among these proteins, DDB1 and DDB2 selectively bind to O2-nBudT-containing DNA, whereas three high-mobility group (HMG) proteins (i.e., HMGB1, HMGB2, and mitochondrial transcription factor A (TFAM)) exhibit preferential binding to O4-nBudT-bearing DNA. We further demonstrated that TFAM binds directly and selectively with O4-alkyldT-harboring DNA, and the binding capacity depends mainly on the HMG box-A domain of TFAM. We also found that TFAM promotes transcriptional mutagenesis of O4-nBudT and O4-pyridyloxobutylthymidine, which is a DNA adduct induced by tobacco-specific N-nitrosamines, in vitro and in human cells. Together, we explored, for the first time, the interaction proteomes of O-alkyldT lesions, and our study expanded the functions of TFAM by revealing its capability in the recognition of O4-alkyldT-bearing DNA and uncovering its modulation of transcriptional mutagenesis of these lesions in human cells.

Deoxyribonucleic Acid Damage and Repair: Capitalizing on Our Understanding of the Mechanisms of Maintaining Genomic Integrity for Therapeutic Purposes

Deoxyribonucleic acid (DNA) is the self-replicating hereditary material that provides a blueprint which, in collaboration with environmental influences, produces a structural and functional phenotype. As DNA coordinates and directs differentiation, growth, survival, and reproduction, it is responsible for life and the continuation of our species. Genome integrity requires the maintenance of DNA stability for the correct preservation of genetic information. This is facilitated by accurate DNA replication and precise DNA repair. DNA damage may arise from a wide range of both endogenous and exogenous sources but may be repaired through highly specific mechanisms. The most common mechanisms include mismatch, base excision, nucleotide excision, and double-strand DNA (dsDNA) break repair. Concurrent with regulation of the cell cycle, these mechanisms are precisely executed to ensure full restoration of damaged DNA. Failure or inaccuracy in DNA repair contributes to genome instability and loss of genetic information which may lead to mutations resulting in disease or loss of life. A detailed understanding of the mechanisms of DNA damage and its repair provides insight into disease pathogeneses and may facilitate diagnosis and the development of targeted therapies.

MutSα maintains the mismatch repair capability by inhibiting PCNA unloading

Eukaryotic mismatch repair (MMR) utilizes single-strand breaks as signals to target the strand to be repaired. DNA-bound PCNA is also presumed to direct MMR. The MMR capability must be limited to a post-replicative temporal window during which the signals are available. However, both identity of the signal(s) involved in the retention of this temporal window and the mechanism that maintains the MMR capability after DNA synthesis remain unclear. Using Xenopus egg extracts, we discovered a mechanism that ensures long-term retention of the MMR capability. We show that DNA-bound PCNA induces strand-specific MMR in the absence of strand discontinuities. Strikingly, MutSα inhibited PCNA unloading through its PCNA-interacting motif, thereby extending significantly the temporal window permissive to strand-specific MMR. Our data identify DNA-bound PCNA as the signal that enables strand discrimination after the disappearance of strand discontinuities, and uncover a novel role of MutSα in the retention of the post-replicative MMR capability.

DOI:http://dx.doi.org/10.7554/eLife.15155.001

To pass on genetic information from one generation to the next, the DNA in a cell must be precisely copied. DNA is made of two strands and genetic information is encoded by sequences of molecules called bases in the strands. The bases from one strand form pairs with complementary bases on the other strand. However, errors in the copying process result in unmatched pairs of bases. Such errors are corrected by a repair system called mismatch repair.

When DNA is copied, the two strands are separated and used as templates to make new complementary strands. This means that errors only arise on the new strands. Mismatch repair must therefore target the new strands to maintain the original information encoded by the template DNA. The repair needs to happen before the copying process is complete because the template strands and the new strands become indistinguishable afterwards. However, it is not clear how the two processes communicate with each other.

Previous studies have identified a ring-shaped molecule called the replication clamp – which is essential for the copying process – as a prime candidate for the molecule responsible for this communication. This molecule binds to the DNA to promote the copying process, and afterwards it is removed from the DNA by other molecules. Furthermore, a group of proteins called the MutSα complex, which recognizes unmatched bases in DNA molecules, physically interacts with the replication clamp.

Kawasoe et al. used eggs from African clawed frogs to study how the replication clamp connects the copying process and mismatch repair in more detail. The experiments show that when the replication clamp is bound to the DNA, it is able to direct mismatch repair to a specific DNA strand. When MutSα recognizes unmatched bases, it prevents the replication clamp from being removed from the DNA. By doing so, MutSα prevents the information about the new DNA strand from being lost until mismatch repair has taken place.

These findings reveal new interactions between DNA copying and the correction of errors by mismatch repair. The next steps will be to understand how MutSα is able to keep the replication clamp on the DNA and to clarify its role in protecting DNA from gaining mutations.

DOI:http://dx.doi.org/10.7554/eLife.15155.002

Protein-protein interactions in DNA mismatch repair

The principal DNA mismatch repair proteins MutS and MutL are versatile enzymes that couple DNA mismatch or damage recognition to other cellular processes. Besides interaction with their DNA substrates this involves transient interactions with other proteins which is triggered by the DNA mismatch or damage and controlled by conformational changes. Both MutS and MutL proteins have ATPase activity, which adds another level to control their activity and interactions with DNA substrates and other proteins. Here we focus on the protein-protein interactions, protein interaction sites and the different levels of structural knowledge about the protein complexes formed with MutS and MutL during the mismatch repair reaction.

Different roles of eukaryotic MutS and MutL complexes in repair of small insertion and deletion loops in yeast

DNA mismatch repair greatly increases genome fidelity by recognizing and removing replication errors. In order to understand how this fidelity is maintained, it is important to uncover the relative specificities of the different components of mismatch repair. There are two major mispair recognition complexes in eukaryotes that are homologues of bacterial MutS proteins, MutSα and MutSβ, with MutSα recognizing base-base mismatches and small loop mispairs and MutSβ recognizing larger loop mispairs. Upon recognition of a mispair, the MutS complexes then interact with homologues of the bacterial MutL protein. Loops formed on the primer strand during replication lead to insertion mutations, whereas loops on the template strand lead to deletions. We show here in yeast, using oligonucleotide transformation, that MutSα has a strong bias toward repair of insertion loops, while MutSβ has an even stronger bias toward repair of deletion loops. Our results suggest that this bias in repair is due to the different interactions of the MutS complexes with the MutL complexes. Two mutants of MutLα, pms1-G882E and pms1-H888R, repair deletion mispairs but not insertion mispairs. Moreover, we find that a different MutL complex, MutLγ, is extremely important, but not sufficient, for deletion repair in the presence of either MutLα mutation. MutSβ is present in many eukaryotic organisms, but not in prokaryotes. We suggest that the biased repair of deletion mispairs may reflect a critical eukaryotic function of MutSβ in mismatch repair.

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

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.

The functions of MutL in mismatch repair: the power of multitasking

DNA mismatch repair enhances genomic stability by correcting errors that have escaped polymerase proofreading. One of the critical steps in DNA mismatch repair is discriminating the new from the parental DNA strand as only the former needs repair. In Escherichia coli, the latent endonuclease MutH carries out this function. However, most prokaryotes and all eukaryotes lack a mutH gene. MutL is a key component of this system that mediates protein-protein interactions during mismatch recognition, strand discrimination, and strand removal. Hence, it had long been thought that the primary function of MutL was coordinating sequential mismatch repair steps. However, recent studies have revealed that most MutL homologs from organisms lacking MutH encode a conserved metal-binding motif associated with a weak endonuclease activity. As MutL homologs bearing this activity are found only in organisms relying on MutH-independent DNA mismatch repair, this finding unveils yet another crucial function of the MutL protein at the strand discrimination step. In this chapter, we review recent functional and structural work aimed at characterizing the multiple functions of MutL and discuss how the endonuclease activity of MutL is regulated by other repair factors.

Functional residues on the surface of the N-terminal domain of yeast Pms1

Saccharomyces cerevisiae MutLalpha is a heterodimer of Mlh1 and Pms1 that participates in DNA mismatch repair (MMR). Both proteins have weakly conserved C-terminal regions (CTDs), with the CTD of Pms1 harboring an essential endonuclease activity. These proteins also have conserved N-terminal domains (NTDs) that bind and hydrolyze ATP and bind to DNA. To better understand Pms1 functions and potential interactions with DNA and/or other proteins, we solved the 2.5A crystal structure of yeast Pms1 (yPms1) NTD. The structure is similar to the homologous NTDs of Escherichia coli MutL and human PMS2, including the site involved in ATP binding and hydrolysis. The structure reveals a number of conserved, positively charged surface residues that do not interact with other residues in the NTD and are therefore candidates for interactions with DNA, with the CTD and/or with other proteins. When these were replaced with glutamate, several replacements resulted in yeast strains with elevated mutation rates. Two replacements also resulted in NTDs with decreased DNA binding affinity in vitro, suggesting that these residues contribute to DNA binding that is important for mismatch repair. Elevated mutation rates also resulted from surface residue replacements that did not affect DNA binding, suggesting that these conserved residues serve other functions, possibly involving interactions with other MMR proteins.

Construction of bacteriophage phi29 DNA packaging motor and its applications in nanotechnology and therapy

Nanobiotechnology involves the creation, characterization, and modification of organized nanomaterials to serve as building blocks for constructing nanoscale devices in technology and medicine. Living systems contain a wide variety of nanomachines and highly ordered structures of macromolecules. The novelty and ingenious design of the bacterial virus phi29 DNA packaging motor and its parts inspired the synthesis of this motor and its components as biomimetics. This 30-nm nanomotor uses six copies of an ATP-binding pRNA to gear the motor. The structural versatility of pRNA has been utilized to construct dimers, trimers, hexamers, and patterned superstructures via the interaction of two interlocking loops. The approach, based on bottom-up assembly, has also been applied to nanomachine fabrication, pathogen detection and the delivery of drugs, siRNA, ribozymes, and genes to specific cells in vitro and in vivo. Another essential component of the motor is the connector, which contains 12 copies of a protein gp10 to form a 3.6-nm central channel as a path for DNA. This article will review current studies of the structure and function of the phi29 DNA packaging motor, as well as the mechanism of motion, the principle of in vitro construction, and its potential nanotechnological and medical applications.

Novel mechanism of hexamer ring assembly in protein/RNA interactions revealed by single molecule imaging

Many nucleic acid-binding proteins and the AAA+ family form hexameric rings, but the mechanism of hexamer assembly is unclear. It is generally believed that the specificity in protein/RNA interaction relies on molecular contact through a surface charge or 3D structure matching via conformational capture or induced fit. The pRNA of bacteriophage phi29 DNA-packaging motor also forms a ring, but whether the pRNA ring is a hexamer or a pentamer is under debate. Here, single molecule studies elucidated a mechanism suggesting the specificity and affinity in protein/RNA interaction relies on pRNA static ring formation. A combined pRNA ring-forming group was very specific for motor binding, but the isolated individual members of the ring-forming group bind to the motor nonspecifically. pRNA did not form a ring prior to motor binding. Only those RNAs that formed a static ring, via the interlocking loops, stayed on the motor. Single interlocking loop interruption resulted in pRNA detachment. Extension or reduction of the ring circumference failed in motor binding. This new mechanism was tested by redesigning two artificial RNAs that formed hexamer and packaged DNA. The results confirmed the stoichiometry of pRNA on the motor was the common multiple of two and three, thus, a hexamer.

DNA mismatch repair: molecular mechanism, cancer, and ageing

DNA mismatch repair (MMR) proteins are ubiquitous players in a diverse array of important cellular functions. In its role in post-replication repair, MMR safeguards the genome correcting base mispairs arising as a result of replication errors. Loss of MMR results in greatly increased rates of spontaneous mutation in organisms ranging from bacteria to humans. Mutations in MMR genes cause hereditary nonpolyposis colorectal cancer, and loss of MMR is associated with a significant fraction of sporadic cancers. Given its prominence in mutation avoidance and its ability to target a range of DNA lesions, MMR has been under investigation in studies of ageing mechanisms. This review summarizes what is known about the molecular details of the MMR pathway and the role of MMR proteins in cancer susceptibility and ageing.

Mechanisms and functions of DNA mismatch repair

DNA mismatch repair (MMR) is a highly conserved biological pathway that plays a key role in maintaining genomic stability. The specificity of MMR is primarily for base-base mismatches and insertion/deletion mispairs generated during DNA replication and recombination. MMR also suppresses homeologous recombination and was recently shown to play a role in DNA damage signaling in eukaryotic cells. Escherichia coli MutS and MutL and their eukaryotic homologs, MutSalpha and MutLalpha, respectively, are key players in MMR-associated genome maintenance. Many other protein components that participate in various DNA metabolic pathways, such as PCNA and RPA, are also essential for MMR. Defects in MMR are associated with genome-wide instability, predisposition to certain types of cancer including hereditary non-polyposis colorectal cancer, resistance to certain chemotherapeutic agents, and abnormalities in meiosis and sterility in mammalian systems.

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

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.

Endonucleolytic function of MutLalpha in human mismatch repair

Half of hereditary nonpolyposis colon cancer kindreds harbor mutations that inactivate MutLalpha (MLH1*PMS2 heterodimer). MutLalpha is required for mismatch repair, but its function in this process is unclear. We show that human MutLalpha is a latent endonuclease that is activated in a mismatch-, MutSalpha-, RFC-, PCNA-, and ATP-dependent manner. Incision of a nicked mismatch-containing DNA heteroduplex by this four-protein system is strongly biased to the nicked strand. A mismatch-containing DNA segment spanned by two strand breaks is removed by the 5'-to-3' activity of MutSalpha-activated exonuclease I. The probable endonuclease active site has been localized to a PMS2 DQHA(X)(2)E(X)(4)E motif. This motif is conserved in eukaryotic PMS2 homologs and in MutL proteins from a number of bacterial species but is lacking in MutL proteins from bacteria that rely on d(GATC) methylation for strand discrimination in mismatch repair. Therefore, the mode of excision initiation may differ in these organisms.

The effects of mismatch repair and RAD1 genes on interchromosomal crossover recombination in Saccharomyces cerevisiae

We have previously shown that recombination between 400-bp substrates containing only 4-bp differences, when present in an inverted repeat orientation, is suppressed by >20-fold in wild-type strains of S. cerevisiae. Among the genes involved in this suppression were three genes involved in mismatch repair--MSH2, MSH3, and MSH6--and one in nucleotide excision repair, RAD1. We now report the involvement of these genes in interchromosomal recombination occurring via crossovers using these same short substrates. In these experiments, recombination was stimulated by a double-strand break generated by the HO endonuclease and can occur between completely identical (homologous) substrates or between nonidentical (homeologous) substrates. In addition, a unique feature of this system is that recombining DNA strands can be given a choice of either type of substrate. We find that interchromosomal crossover recombination with these short substrates is severely inhibited in the absence of MSH2, MSH3, or RAD1 and is relatively insensitive to the presence of mismatches. We propose that crossover recombination with these short substrates requires the products of MSH2, MSH3, and RAD1 and that these proteins have functions in recombination in addition to the removal of terminal nonhomology. We further propose that the observed insensitivity to homeology is a result of the difference in recombinational mechanism and/or the timing of the observed recombination events. These results are in contrast with those obtained using longer substrates and may be particularly relevant to recombination events between the abundant short repeated sequences that characterize the genomes of higher eukaryotes.

Polymorphisms of the DNA mismatch repair gene HMSH2 in breast cancer occurence and progression

The response of the cell to DNA damage and its ability to maintain genomic stability by DNA repair are crucial in preventing cancer initiation and progression. Therefore, polymorphism of DNA repair genes may affect the process of carcinogenesis. The importance of genetic variability of the components of mismatch repair (MMR) genes is well documented in colorectal cancer, but little is known about its role in breast cancer. hMSH2 is one of the crucial proteins of MMR. We performed a case-control study to test the association between two polymorphisms in the hMSH2 gene: an A --> G transition at 127 position producing an Asn --> Ser substitution at codon 127 (the Asn127Ser polymorphism) and a G --> A transition at 1032 position resulting in a Gly --> Asp change at codon 322 (the Gly322Asp polymorphism) and breast cancer risk and cancer progression. Genotypes were determined in DNA from peripheral blood lymphocytes of 150 breast cancer patients and 150 age-matched women (controls) by restriction fragment length polymorphism and allele-specific PCR. We did not observe any correlation between studied polymorphisms and breast cancer progression evaluated by node-metastasis, tumor size and Bloom-Richardson grading. A strong association between breast cancer occurrence and the Gly/Gly phenotype of the Gly322Asp polymorphism (odds ratio 8.39; 95% confidence interval 1.44-48.8) was found. Therefore, MMR may play a role in the breast carcinogenesis and the Gly322Asp polymorphism of the hMSH2 gene may be considered as a potential marker in breast cancer.

The beta sliding clamp binds to multiple sites within MutL and MutS

The MutL and MutS proteins are the central components of the DNA repair machinery that corrects mismatches generated by DNA polymerases during synthesis. We find that MutL interacts directly with the beta sliding clamp, a ring-shaped dimeric protein that confers processivity to DNA polymerases by tethering them to their substrates. Interestingly, the interaction of MutL with beta only occurs in the presence of single-stranded DNA. We find that the interaction occurs via a loop in MutL near the ATP-binding site. The binding site of MutL on beta locates to the hydrophobic pocket between domains two and three of the clamp. Site-specific replacement of two residues in MutL diminished interaction with beta without disrupting MutL function with helicase II. In vivo studies reveal that this mutant MutL is no longer functional in mismatch repair. In addition, the human MLH1 has a close match to the proliferating cell nuclear antigen clamp binding motif in the region that corresponds to the beta interaction site in Escherichia coli MutL, and a peptide corresponding to this site binds proliferating cell nuclear antigen. The current report also examines in detail the interaction of beta with MutS. We find that two distinct regions of MutS interact with beta. One is located near the C terminus and the other is close to the N terminus, within the mismatch binding domain. Complementation studies using genes encoding different MutS mutants reveal that the N-terminal beta interaction motif on MutS is essential for activity in vivo, but the C-terminal interaction site for beta is not. In light of these results, we propose roles for the beta clamp in orchestrating the sequence of events that lead to mismatch repair in the cell.

Interaction of gp16 with pRNA and DNA for Genome Packaging by the Motor of Bacterial Virus phi29

One striking feature in the assembly of linear double-stranded (ds) DNA viruses is that their genome is translocated into a preformed protein coat via a motor involving two non-structural components with certain characteristics of ATPase. In bacterial virus phi29, these two components include the protein gp16 and a packaging RNA (pRNA). The structure and function of other phi29 motor components have been well elucidated; however, studies on the role of gp16 have been seriously hampered by its hydrophobicity and self-aggregation. Such problems caused by insolubility also occur in the study of other viral DNA-packaging motors. Contradictory data have been published regarding the role and stoichiometry of gp16, which has been reported to bind every motor component, including pRNA, DNA, gp3, DNA-gp3, connector, pRNA-free procapsid, and procapsid/pRNA complex. Such conflicting data from a binding assay could be due to the self-aggregation of gp16. Our recent advance to produce soluble and highly active gp16 has enabled further studies on gp16. It was demonstrated in this report that gp16 bound to DNA non-specifically. gp16 bound to the pRNA-containing procapsid much more strongly than to the pRNA-free procapsid. The domain of pRNA for gp16 interaction was the 5'/3' paired helical region. The C18C19A20 bulge that is essential for DNA packaging was found to be dispensable for gp16 binding. This result confirms the published model that pRNA binds to the procapsid with its central domain and extends its 5'/3' DNA-packaging domain for gp16 binding. It suggests that gp16 serves as a linkage between pRNA and DNA, and as an essential DNA-contacting component during DNA translocation. The data also imply that, with the exception of the C18C19A20 bulge, the main role of the 5'/3' helical double-stranded region of pRNA is not for procapsid binding but for binding to gp16.

Novel PMS1 alleles preferentially affect the repair of primer strand loops during DNA replication

Null mutations in DNA mismatch repair (MMR) genes elevate both base substitutions and insertions/deletions in simple sequence repeats. Data suggest that during replication of simple repeat sequences, polymerase slippage can generate single-strand loops on either the primer or template strand that are subsequently processed by the MMR machinery to prevent insertions and deletions, respectively. In the budding yeast Saccharomyces cerevisiae and mammalian cells, MMR appears to be more efficient at repairing mispairs comprised of loops on the template strand compared to loops on the primer strand. We identified two novel yeast pms1 alleles, pms1-G882E and pms1-H888R, which confer a strong defect in the repair of "primer strand" loops, while maintaining efficient repair of "template strand" loops. Furthermore, these alleles appear to affect equally the repair of 1-nucleotide primer strand loops during both leading- and lagging-strand replication. Interestingly, both pms1 mutants are proficient in the repair of 1-nucleotide loop mispairs in heteroduplex DNA generated during meiotic recombination. Our results suggest that the inherent inefficiency of primer strand loop repair is not simply a mismatch recognition problem but also involves Pms1 and other proteins that are presumed to function downstream of mismatch recognition, such as Mlh1. In addition, the findings reinforce the current view that during mutation avoidance, MMR is associated with the replication apparatus.

Discrimination and versatility in mismatch repair

Evolutionarily-conserved mismatch-repair (MMR) systems correct all or almost all base-mismatch errors from DNA replication via excision-resynthesis pathways, and respond to many different DNA lesions. Consideration of DNA polymerase error rates and possible consequences of excess gratuitous excision of perfectly paired (homoduplex) DNA in vivo suggests that MMR needs to discriminate against homoduplex DNA by three to six orders of magnitude. However, numerous binding studies using MMR base-mispair-recognition proteins, bacterial MutS or eukaryotic MSH2.MSH6 (MutSalpha), have typically shown discrimination factors between mismatched and homoduplex DNA to be 5-30, depending on the binding conditions, the particular mismatches, and the DNA-sequence contexts. Thus, downstream post-binding steps must increase MMR discrimination without interfering with the versatility needed to recognize a large variety of base-mismatches and lesions. We use a complex but highly MMR-active model system, human nuclear extracts mixed with plasmid substrates containing specific mismatches and defined nicks 0.15 kbp away, to measure the earliest quantifiable committed step in mismatch correction, initiation of mismatch-provoked 3'-5' excision at the nicks. We compared these results to binding of purified MutSalpha to synthetic oligoduplexes containing the same mismatches in the same sequence contexts, under conditions very similar to those prevailing in the nuclear extracts. Discrimination against homoduplex DNA, only two-to five-fold in the binding studies, increased to 60- to 230-fold or more for excision initiation, depending on the particular mismatches. Remarkably, the mismatch-preference order for excision initiation was substantially altered from the order for hMutSalpha binding. This suggests that post-binding steps not only strongly discriminate against homoduplex DNA, but do so by mechanisms not tightly constrained by initial binding preferences. Pairs of homoduplexes (40, 50, and 70 bp) prepared from synthetic oligomers or cut out of plasmids showed virtually identical hMutSalpha binding affinities, suggesting that high hMutSalpha binding to homoduplex DNA is not the result of misincorporations or lesions introduced during chemical synthesis. Intrinsic affinities of MutS homologs for perfectly paired DNA may help these proteins efficiently position themselves to carry out subsequent mismatch-specific steps in MMR pathways.

Analysis of interactions between mismatch repair initiation factors and the replication processivity factor PCNA

In eukaryotes, the DNA replication factor PCNA is loaded onto primer-template junctions to act as a processivity factor for DNA polymerases. Genetic and biochemical studies suggest that PCNA also functions in early steps in mismatch repair (MMR) to facilitate the repair of misincorporation errors generated during DNA replication. These studies have shown that PCNA interacts directly with several MMR components, including MSH3, MSH6, MLH1, and EXO1. At present, little is known about how these interactions contribute to the mismatch repair mechanism. The interaction between MLH1 and PCNA is of particular interest because MLH1-PMS1 is thought to act as a matchmaker to signal mismatch recognition to downstream repair events; in addition, PCNA has been hypothesized to act in strand discrimination steps in MMR. Here, we utilized both genetic and surface plasmon resonance techniques to characterize the MLH1-PMS1-PCNA interaction. These analyses enabled us to determine the stability of the complex (K(D) = 300 nM) and to identify residues (572-579) in MLH1 and PCNA (126,128) that appear important to maintain this stability. We favor a model in which PCNA acts as a scaffold for consecutive protein-protein interactions that allow for the coordination of MMR steps.

DNA mismatch repair

DNA mismatch repair (MMR) is an evolutionarily conserved process that corrects mismatches generated during DNA replication and escape proofreading. MMR proteins also participate in many other DNA transactions, such that inactivation of MMR can have wide-ranging biological consequences, which can be either beneficial or detrimental. We begin this review by briefly considering the multiple functions of MMR proteins and the consequences of impaired function. We then focus on the biochemical mechanism of MMR replication errors. Emphasis is on structure-function studies of MMR proteins, on how mismatches are recognized, on the process by which the newly replicated strand is identified, and on excision of the replication error.

Analysis of the interaction between the Saccharomyces cerevisiae MSH2-MSH6 and MLH1-PMS1 complexes with DNA using a reversible DNA end-blocking system

The Lac repressor-operator interaction was used as a reversible DNA end-blocking system in conjunction with an IAsys biosensor instrument (Thermo Affinity Sensors), which detects total internal reflectance and allows monitoring of binding and dissociation in real time, in order to develop a system for studying the ability of mismatch repair proteins to move along the DNA. The MSH2-MSH6 complex bound to a mispaired base was found to be converted by ATP binding to a form that showed rapid sliding along the DNA and dissociation via the DNA ends and also showed slow, direct dissociation from the DNA. In contrast, the MSH2-MSH6 complex bound to a base pair containing DNA only showed direct dissociation from the DNA. The MLH1-PMS1 complex formed both mispair-dependent and mispair-independent ternary complexes with the MSH2-MSH6 complex on DNA. The mispair-independent ternary complexes were formed most efficiently on DNA molecules with free ends under conditions where ATP hydrolysis did not occur, and only exhibited direct dissociation from the DNA. The mispair-dependent ternary complexes were formed in the highest yield on DNA molecules with blocked ends, required ATP and magnesium for formation, and showed both dissociation via the DNA ends and direct dissociation from the DNA.

Meiotic recombination intermediates and mismatch repair proteins

Mismatch repair proteins are a highly diverse group of proteins that interact with numerous DNA structures during DNA repair and replication. Here we review data for the role of Msh4, Msh5, Mlh1, Mlh3 and Exo1 in crossing over. Based on the paradigm of interactions developed from studies of mismatch repair, we propose models for the mechanism of crossover implementation by Msh4/Msh5 and Mlh1/Mlh3.

Mutations in the nucleotide-binding domain of MutS homologs uncouple cell death from cell survival

After genotoxic insult, the decision to repair or undergo cell death is pivotal for undamaged cell survival, and requires a highly controlled coordination of both pathways. Disruption of this regulation results in tumorigenesis and failure of cancer therapy. Mismatch repair (MMR) proteins have a unique role by contributing to both pathways, though direct evidence for their function in the DNA damage response is ambiguous. We report separation of function mutants in the ATPase domains of yeast MutS homologous (MSH) proteins that uncouple MMR-dependent DNA repair from damage response to cisplatin. While mutations in the ATPase domain have devastating effects on the mutation rate of the cell, ATPase processing is mostly dispensable for the cell death phenotype; only limited processing by the MSH6 subunit is required in DNA damage response. Different DNA binding patterns and nucleotide sensitivity of Msh2/Msh6-DNA adduct and protein-mismatch complexes, respectively, suggest that the presence of different DNA lesions influences the requirement for ATP. Limited proteolysis of purified protein gives first indications for differences in nucleotide-induced conformational changes in the presence of platinated DNA. Structural modeling of bacterial MutS proteins reinforces nucleotide-dependent differences in structures that contribute to the distinction between DNA damage response and repair. Our results demonstrate the uncoupling of MMR-dependent damage response from repair and present first indications for the involvement of distinct conformational changes in MSH proteins in this process. These data present evidence for a mechanism of MMR-dependent damage response that differs from MMR; these results have strong implications for the chemotherapeutic treatment of MMR-defective tumors.

Signaling from DNA mispairs to mismatch-repair excision sites despite intervening blockades

Mismatch-repair (MMR) systems promote genomic stability by correction of DNA replication errors. Thus, MMR proteins--prokaryotic MutS and MutL homodimers or their MutSalpha and MutLalpha heterodimer homologs, plus accessory proteins--specifically couple mismatch recognition to nascent-DNA excision. In vivo excision-initiation signals--specific nicks in some prokaryotes, perhaps growing 3' ends or Okazaki-fragment 5' ends in eukaryotes--are efficiently mimicked in vitro by nicks or gaps in exogenous DNA substrates. In some models for recognition-excision coupling, MutSalpha bound to mismatches is induced by ATP hydrolysis, or simply by binding of ATP, to slide along DNA to excision-initiation sites, perhaps in association with MutLalpha and accessory proteins. In other models, MutSalpha.MutLalpha complexes remain fixed at mismatches and contact distant excision sites by DNA looping. To challenge the hypothesis that recognition complexes remain fixed, we placed biotin-streptavidin blockades between mismatches and pre-existing nicks. In human nuclear extracts, mismatch efficiently provoked the initiation of excision despite the intervening barriers, as predicted. However, excision progress and therefore mismatch correction were prevented.

Differential Requirement for Proliferating Cell Nuclear Antigen in 5′ and 3′ Nick-directed Excision in Human Mismatch Repair

Proliferating cell nuclear antigen (PCNA) is involved in mammalian mismatch repair at a step prior to or at mismatch excision, but the molecular mechanism of this process is not fully understood. To examine the role of PCNA in mismatch-provoked and nick-directed excision, orientation-specific mismatch removal of heteroduplexes with a pre-existing nick was monitored in human nuclear extracts supplemented with the PCNA inhibitor protein p21. We show here that, whereas 3' nick-directed mismatch excision was completely inhibited by low concentrations of p21 or a p21 C-terminal fusion protein, 5' nick-directed excision was only partially blocked under the same conditions. No further reduction of the 5' excision was detected when a much higher concentration of p21 C-terminal protein was used. These results suggest the following. (i) There is a differential requirement for PCNA in 3' and 5' nick-directed excision; and (ii) 5' nick-directed excision is conducted by a manner either dependent on or independent of PCNA. Our in vitro reconstitution experiments indeed identified a 5' nick-directed excision pathway that is dependent on PCNA, hMutSalpha, and a partially purified fraction from a HeLa nuclear extract.

Evidence for involvement of HMGB1 protein in human DNA mismatch repair

Defects in human DNA mismatch repair predispose to cancer, but many components of the pathway have not been identified. We report here the identification and characterization of a novel component required for mismatch repair in human cells. A 30-kDa protein was purified to homogeneity by virtue of its ability to complement a depleted HeLa extract in repair of mismatched heteroduplexes. The complementing activity was identified as HMGB1 (the high mobility group box 1 protein), a non-histone chromatin protein that facilitates protein-protein interactions and recognizes DNA damage. Evidence is also presented that HMGB1 physically interacts with MutSalpha and is required at a step prior to the excision of mispaired nucleotide in mismatch repair.

DNA mismatch repair: molecular mechanisms and biological function

DNA mismatch repair (MMR) guards the integrity of the genome in virtually all cells. It contributes about 1000-fold to the overall fidelity of replication and targets mispaired bases that arise through replication errors, during homologous recombination, and as a result of DNA damage. Cells deficient in MMR have a mutator phenotype in which the rate of spontaneous mutation is greatly elevated, and they frequently exhibit microsatellite instability at mono- and dinucleotide repeats. The importance of MMR in mutation avoidance is highlighted by the finding that defects in MMR predispose individuals to hereditary nonpolyposis colorectal cancer. In addition to its role in postreplication repair, the MMR machinery serves to police homologous recombination events and acts as a barrier to genetic exchange between species.

Formation of a DNA mismatch repair complex mediated by ATP

The mismatch repair proteins, MutS and MutL, interact in a DNA mismatch and ATP-dependent manner to activate downstream events in repair. Here, we assess the role of ATP binding and hydrolysis in mismatch recognition by MutS and the formation of a ternary complex involving MutS and MutL bound to a mismatched DNA. We show that ATP reduces the affinity of MutS for mismatched DNA and that the modulation of DNA binding affinity by nucleotide is even more pronounced for MutS E694A, a protein that binds ATP but is defective for ATP hydrolysis. Despite the ATP hydrolysis defect, E694A, like WT MutS, undergoes rapid, ATP-dependent dissociation from a DNA mismatch. Furthermore, MutS E694A retains the ability to interact with MutL on mismatched DNA. The recruitment of MutL to a mismatched DNA by MutS is also observed for two mutant MutL proteins, E29A, defective for ATP hydrolysis, and R266A, defective for DNA binding. These results suggest that ATP binding in the absence of hydrolysis is sufficient to trigger formation of a MutS sliding clamp. However, recruitment of MutL results in the formation of a dynamic ternary complex that we propose is the intermediate that signals subsequent repair steps requiring ATP hydrolysis.

The PCNA-RFC families of DNA clamps and clamp loaders

The proliferating cell nuclear antigen PCNA functions at multiple levels in directing DNA metabolic pathways. Unbound to DNA, PCNA promotes localization of replication factors with a consensus PCNA-binding domain to replication factories. When bound to DNA, PCNA organizes various proteins involved in DNA replication, DNA repair, DNA modification, and chromatin modeling. Its modification by ubiquitin directs the cellular response to DNA damage. The ring-like PCNA homotrimer encircles double-stranded DNA and slides spontaneously across it. Loading of PCNA onto DNA at template-primer junctions is performed in an ATP-dependent process by replication factor C (RFC), a heteropentameric AAA+ protein complex consisting of the Rfc1, Rfc2, Rfc3, Rfc4, and Rfc5 subunits. Loading of yeast PCNA (POL30) is mechanistically distinct from analogous processes in E. coli (beta subunit by the gamma complex) and bacteriophage T4 (gp45 by gp44/62). Multiple stepwise ATP-binding events to RFC are required to load PCNA onto primed DNA. This stepwise mechanism should permit editing of this process at individual steps and allow for divergence of the default process into more specialized modes. Indeed, alternative RFC complexes consisting of the small RFC subunits together with an alternative Rfc1-like subunit have been identified. A complex required for the DNA damage checkpoint contains the Rad24 subunit, a complex required for sister chromatid cohesion contains the Ctf18 subunit, and a complex that aids in genome stability contains the Elg1 subunit. Only the RFC-Rad24 complex has a known associated clamp, a heterotrimeric complex consisting of Rad17, Mec3, and Ddc1. The other putative clamp loaders could either act on clamps yet to be identified or act on the two known clamps.

Msh2 separation of function mutations confer defects in the initiation steps of mismatch repair

In eukaryotes the MSH2-MSH3 and MSH2-MSH6 heterodimers initiate mismatch repair (MMR) by recognizing and binding to DNA mismatches. The MLH1-PMS1 heterodimer then interacts with the MSH proteins at or near the mismatch site and is thought to act as a mediator to recruit downstream repair proteins. Here we analyzed five msh2 mutants that are functional in removing 3' non-homologous tails during double-strand break repair but are completely defective in MMR. Because non-homologous tail removal does not require MSH6, MLH1, or PMS1 functions, a characterization of the msh2 separation of function alleles should provide insights into early steps in MMR. Using the Taq MutS crystal structure as a model, three of the msh2 mutations, msh2-S561P, msh2-K564E, msh2-G566D, were found to map to a domain in MutS involved in stabilizing mismatch binding. Gel mobility shift and DNase I footprinting assays showed that two of these mutations conferred strong defects on MSH2-MSH6 mismatch binding. The other two mutations, msh2-S656P and msh2-R730W, mapped to the ATPase domain. DNase I footprinting, ATP hydrolysis, ATP binding, and MLH1-PMS1 interaction assays indicated that the msh2-S656P mutation caused defects in ATP-dependent dissociation of MSH2-MSH6 from mismatch DNA and in interactions between MSH2-MSH6 and MLH1-PMS1. In contrast, the msh2-R730W mutation disrupted MSH2-MSH6 ATPase activity but did not strongly affect ATP binding or interactions with MLH1-PMS1. These results support a model in which MMR can be dissected into discrete steps: stable mismatch binding and sensing, MLH1-PMS1 recruitment, and recycling of MMR components.

Mismatch repair in human nuclear extracts: effects of internal DNA-hairpin structures between mismatches and excision-initiation nicks on mismatch correction and mismatch-provoked excision

DNA mismatch repair (MMR) couples recognition of base mispairs by MSH2.MSH6 heterodimers to initiation, hundreds of nucleotides away, of nascent strand 3'-5' or 5'-3' excision through the mispair. Mismatch-recognition complexes have been hypothesized to move along DNA to excision-initiation signals, in eukaryotes, perhaps ends of nascent DNA, or to remain at mismatches and search through space for initiation signals. Subsequent MMR excision, whether simple processive digestion of the targeted strand or tracking of an excision complex, remains poorly understood. In human cell-free extracts, we analyzed correction of a mismatch in a 2.2-kilobase pair (kbp) circular plasmid containing a pre-existing excision-initiation nick for initiation, and measured MMR excision (in the absence of exogenous dNTPs) at specific locations. Excision specificities were approximately 100:1 for nicked versus continuous strands, 80:1 for mismatched versus homoduplex DNA, and 30:1 for shorter (0.3-kbp) versus longer (1.9-kbp) nick-mispair paths. To test models for recognition-excision coupling and excision progress, we inserted potential blockades, 20-bp hairpins, into nick-mispair paths, using a novel technique to first generate gapped plasmid. Continuous strand longer-path hairpins did not affect mismatch correction, but shorter-path hairpins reduced correction 4-fold, and both together eliminated it. Shorter-path hairpins had little effect on initiation of (3'-5') excision, measured 30-60 nucleotides 5' to the nick, but blocked subsequent progress of excision to the mismatch; longer-path hairpins blocked the (lower level) 5'-3' excision to the mismatch. Thus, (a) MMR excision protein(s) cannot move past DNA hairpins. Hairpins at both ends of substrate-derived 0.5-kbp DNA fragments did not prevent ATP-induced dissociation of mismatch-bound human MSH2.MSH6, so recognition complexes at mismatches might provoke excision at nicks beyond hairpins, or loosely sliding MSH2.MSH6 dimers might move to the nicks.

N-terminus of hMLH1 confers interaction of hMutLalpha and hMutLbeta with hMutSalpha

Mismatch repair is a highly conserved system that ensures replication fidelity by repairing mispairs after DNA synthesis. In humans, the two protein heterodimers hMutSalpha (hMSH2-hMSH6) and hMutLalpha (hMLH1-hPMS2) constitute the centre of the repair reaction. After recognising a DNA replication error, hMutSalpha recruits hMutLalpha, which then is thought to transduce the repair signal to the excision machinery. We have expressed an ATPase mutant of hMutLalpha as well as its individual subunits hMLH1 and hPMS2 and fragments of hMLH1, followed by examination of their interaction properties with hMutSalpha using a novel interaction assay. We show that, although the interaction requires ATP, hMutLalpha does not need to hydrolyse this nucleotide to join hMutSalpha on DNA, suggesting that ATP hydrolysis by hMutLalpha happens downstream of complex formation. The analysis of the individual subunits of hMutLalpha demonstrated that the hMutSalpha-hMutLalpha interaction is predominantly conferred by hMLH1. Further experiments revealed that only the N-terminus of hMLH1 confers this interaction. In contrast, only the C-terminus stabilised and co-immunoprecipitated hPMS2 when both proteins were co-expressed in 293T cells, indicating that dimerisation and stabilisation are mediated by the C-terminal part of hMLH1. We also examined another human homologue of bacterial MutL, hMutLbeta (hMLH1-hPMS1). We show that hMutLbeta interacts as efficiently with hMutSalpha as hMutLalpha, and that it predominantly binds to hMutSalpha via hMLH1 as well.

Crystal structure and biochemical analysis of the MutS.ADP.beryllium fluoride complex suggests a conserved mechanism for ATP interactions in mismatch repair

During mismatch repair ATP binding and hydrolysis activities by the MutS family proteins are important for both mismatch recognition and for transducing mismatch recognition signals to downstream repair factors. Despite intensive efforts, a MutS.ATP.DNA complex has eluded crystallographic analysis. Searching for ATP analogs that strongly bound to Thermus aquaticus (Taq) MutS, we found that ADP.beryllium fluoride (ABF), acted as a strong inhibitor of several MutS family ATPases. Furthermore, ABF promoted the formation of a ternary complex containing the Saccharomyces cerevisiae MSH2.MSH6 and MLH1.PMS1 proteins bound to mismatch DNA but did not promote dissociation of MSH2.MSH6 from mismatch DNA. Crystallographic analysis of the Taq MutS.DNA.ABF complex indicated that although this complex was very similar to that of MutS.DNA.ADP, both ADP.Mg(2+) moieties in the MutS. DNA.ADP structure were replaced by ABF. Furthermore, a disordered region near the ATP-binding pocket in the MutS B subunit became traceable, whereas the equivalent region in the A subunit that interacts with the mismatched nucleotide remained disordered. Finally, the DNA binding domains of MutS together with the mismatched DNA were shifted upon binding of ABF. We hypothesize that the presence of ABF is communicated between the two MutS subunits through the contact between the ordered loop and Domain III in addition to the intra-subunit helical lever arm that links the ATPase and DNA binding domains.

CTG repeat instability and size variation timing in DNA repair-deficient mice

Type 1 myotonic dystrophy is caused by the expansion of an unstable CTG repeat in the DMPK gene. We have investigated the molecular mechanisms underlying the CTG repeat instability by crossing transgenic mice carrying >300 unstable CTG repeats in their human chromatin environment with mice knockout for genes involved in various DNA repair pathways: Msh2 (mismatch repair), Rad52 and Rad54 (homologous recombination) and DNA-PKcs (non-homologous end-joining). Genes of the non-homologous end-joining and homologous recombination pathways did not seem to affect repeat instability. Only lack of Rad52 led to a slight decrease in expansion range. Unexpectedly, the absence of Msh2 did not result in stabilization of the CTG repeats in our model. Instead, it shifted the instability towards contractions rather than expansions, both in tissues and through generations. Furthermore, we carefully analyzed repeat transmissions with different Msh2 genotypes to determine the timing of intergenerational instability. We found that instability over generations depends not only on parental germinal instability, but also on a second event taking place after fertilization.

Use of PEG to acquire highly soluble DNA-packaging enzyme gp16 of bacterial virus phi29 for stoichiometry quantification

All linear dsDNA viruses package their genome into a preformed procapsid via a ATP-driving motor involving two nonstructural enzymes or ATPase. This essential viral replication step has been investigated in the quest for new antiviral drugs. These DNA-packaging motors could be potential parts in nanotechnology. But both the low solubility and self-aggregation of all nonstructural enzymes have seriously hampered studies on these motors. Bacterial virus phi29 DNA-packaging motor has been well characterized. But the role of the nonstructural ATPase gp16 has not been well defined due to its hydrophobicity, low solubility, and self-aggregation. Here we report a novel approach to obtain affinity-purified, soluble, and highly active native gp16 with the aid of polyethylene glycol (PEG) or acetone. With several thousand-fold increase in specific activity in comparison to the traditional method, this unique approach has made the quantification of gp16 feasible. The basic functional unit of gp16 in solution was found to be a monomer, as determined by sedimentation and size exclusion chromatography. This result leads to a subsequent finding that the stoichiometry of gp16 for phi29 DNA-packaging was about 11+/-2. These findings will facilitate the study on this novel motor that involves three pRNA dimers and a 12-subunit connector.

Interactions of the DNA mismatch repair proteins MLH1 and MSH2 with c-MYC and MAX

MSH2 and MLH1 have a central role in correcting mismatches in DNA occurring during DNA replication and have been implicated in the engagement of apoptosis induced by a number of cytotoxic anticancer agents. The function of MLH1 is not clearly defined, although it is required for mismatch repair (MMR) and engagement of apoptosis after certain types of DNA damage. In order to identify other partners of MLH1 that may be involved in signalling MMR or apoptosis, we used human MLH1 in yeast two-hybrid screens of normal human breast and ovarian cDNA libraries. As well as known partners of MLH1 such as PMS1, MLH3 and MBD4, we identified the carboxy terminus of the human c-MYC proto-oncogene as an interacting sequence. We demonstrate, both in vitro by yeast two-hybrid and GST-fusion pull-down experiments, as well as in vivo by coimmunoprecipitation from human tumour cell extracts, that MLH1 interacts with the c-MYC protein. We further demonstrate that the heterodimeric partner of c-MYC, MAX, interacts with a different MMR protein, MSH2, both in vitro and in vivo. Using an inducible c-MYC-ER fusion gene, we show that elevated c-MYC expression leads to an increased HGPRT mutation rate of Rat1 cells and an increase in the number of frameshift mutants at the HGPRT locus. The effect on HGPRT mutation rate is small (2-3-fold), but is consistent with deregulated c-MYC expression partially inhibiting MMR activity.

The alternating ATPase domains of MutS control DNA mismatch repair

DNA mismatch repair is an essential safeguard of genomic integrity by removing base mispairings that may arise from DNA polymerase errors or from homologous recombination between DNA strands. In Escherichia coli, the MutS enzyme recognizes mismatches and initiates repair. MutS has an intrinsic ATPase activity crucial for its function, but which is poorly understood. We show here that within the MutS homodimer, the two chemically identical ATPase sites have different affinities for ADP, and the two sites alternate in ATP hydrolysis. A single residue, Arg697, located at the interface of the two ATPase domains, controls the asymmetry. When mutated, the asymmetry is lost and mismatch repair in vivo is impaired. We propose that asymmetry of the ATPase domains is an essential feature of mismatch repair that controls the timing of the different steps in the repair cascade.

Systematic mutagenesis of the Saccharomyces cerevisiae MLH1 gene reveals distinct roles for Mlh1p in meiotic crossing over and in vegetative and meiotic mismatch repair

In eukaryotic cells, DNA mismatch repair is initiated by a conserved family of MutS (Msh) and MutL (Mlh) homolog proteins. Mlh1 is unique among Mlh proteins because it is required in mismatch repair and for wild-type levels of crossing over during meiosis. In this study, 60 new alleles of MLH1 were examined for defects in vegetative and meiotic mismatch repair as well as in meiotic crossing over. Four alleles predicted to disrupt the Mlh1p ATPase activity conferred defects in all functions assayed. Three mutations, mlh1-2, -29, and -31, caused defects in mismatch repair during vegetative growth but allowed nearly wild-type levels of meiotic crossing over and spore viability. Surprisingly, these mutants did not accumulate high levels of postmeiotic segregation at the ARG4 recombination hotspot. In biochemical assays, Pms1p failed to copurify with mlh1-2, and two-hybrid studies indicated that this allele did not interact with Pms1p and Mlh3p but maintained wild-type interactions with Exo1p and Sgs1p. mlh1-29 and mlh1-31 did not alter the ability of Mlh1p-Pms1p to form a ternary complex with a mismatch substrate and Msh2p-Msh6p, suggesting that the region mutated in these alleles could be responsible for signaling events that take place after ternary complex formation. These results indicate that mismatches formed during genetic recombination are processed differently than during replication and that, compared to mismatch repair functions, the meiotic crossing-over role of MLH1 appears to be more resistant to mutagenesis, perhaps indicating a structural role for Mlh1p during crossing over.

Transfer of the MSH2.MSH6 complex from proliferating cell nuclear antigen to mispaired bases in DNA

Proliferating cell nuclear antigen (PCNA) is thought to play a role in DNA mismatch repair at the DNA synthesis step as well as in an earlier step. Studies showing that PCNA interacts with mispair-binding protein complexes, MSH2.MSH3 and MSH2.MSH6, and that PCNA enhances MSH2.MSH6 mispair binding specificity suggest PCNA may be involved in mispair recognition. Here we show that PCNA and MSH2.MSH6 form a stable ternary complex with a homoduplex (G/C) DNA, but MSH2.MSH6 binding to a heteroduplex (G/T) DNA disrupts MSH2.MSH6 binding to PCNA. We also found that the addition of ATP or adenosine 5'-O-(thiotriphosphate) restores MSH2.MSH6 binding to PCNA, presumably by disrupting MSH2.MSH6 binding to the heteroduplex (G/T) DNA. These results support a model in which MSH2.MSH6 binds to PCNA loaded on newly replicated DNA and is transferred from PCNA to mispaired bases in DNA.

Characterization of nuclease-dependent functions of Exo1p in Saccharomyces cerevisiae

Exo1p is a member of the Rad2p family of structure-specific nucleases that contain conserved N and I nuclease domains. Exo1p has been implicated in numerous DNA metabolic processes, such as recombination, double-strand break repair and DNA mismatch repair (MMR). In this report, we describe in vitro and in vivo characterization of full-length wild-type and mutant forms of Exo1p. Herein, we demonstrate that full-length yeast Exo1p possesses an intrinsic 5'-3' exonuclease activity as reported previously, but also possesses a flap-endonuclease activity. Our study indicates that Exo1p shares similar, but not identical structure-function relationships to other characterized members of the Rad2p family in the N and I nuclease domains. The two exo1p mutants we examined, showed deficiencies for both double-stranded DNA (dsDNA) 5'-3' exonuclease and flap-endonuclease activities. Examining the genetic interaction of these two exo1 mutations with rad27Delta suggest that the Exo1p flap-endonuclease activity and not the dsDNA 5'-3' exonuclease is redundant to Rad27p for viability. In addition, our in vivo results also indicate that many exo1Delta phenotypes are dependent on the complete catalytic activities of Exo1p. Finally, our findings plus those of other investigators suggest that Exo1p functions both in a catalytic and a structural capacity during DNA MMR.

Structure and function of phi29 hexameric RNA that drives the viral DNA packaging motor: review

One notable feature of linear dsDNA viruses is that, during replication, their lengthy genome is squeezed with remarkable velocity into a preformed procapsid and packed into near crystalline density. A molecular motor using ATP as energy accomplishes this energetically unfavorable motion tack. In bacterial virus phi29, an RNA (pRNA) molecule is a vital component of this motor. This 120-base RNA has many novel and distinctive features. It contains strong secondary structure, is tightly folded, and unusually stable. Upon interaction with ion and proteins, it has a knack to adapt numerous conformations to perform versatile function. It can be easily manipulated to form stable homologous monomers, dimers, trimers and hexamers. As a result, many unknown properties of RNA have been and will be unfolded by the study of this extraordinary molecule. This article reviews the structure and function of this pRNA and focuses on novel methods and unique approaches that lead to the illumination of its structure and function.

DNA template requirements for human mismatch repair in vitro

The human mismatch repair pathway is competent to correct DNA mismatches in a strand-specific manner. At present, only nicks are known to support strand discrimination, although the DNA end within the active site of replication is often proposed to serve this role. We therefore tested the competence of DNA ends or gaps to direct mismatch correction. Eight G.T templates were constructed which contained a nick or gap of 4, 28, or approximately 200 nucleotides situated approximately 330 bp away in either orientation. A competition was established in which the mismatch repair machinery had to compete with gap-filling replication and ligation activities for access to the strand discontinuity. Gaps of 4 or 28 nucleotides were the most effective strand discrimination signals for mismatch repair, whereas double strand breaks did not direct repair to either strand. To define the minimal spatial requirements for access to either the strand signal or mismatch site, the nicked templates were linearized close to either site and assayed. As few as 14 bp beyond the nick supported mismatch excision, although repair synthesis failed using 5'-nicked templates. Finally, asymmetric G.T templates with a remote nick and a nearby DNA end were repaired efficiently.

Mismatch repair in human nuclear extracts. Time courses and ATP requirements for kinetically distinguishable steps leading to tightly controlled 5' to 3' and aphidicolin-sensitive 3' to 5' mispair-provoked excision

Mismatch repair (MMR) systems enhance genomic stability by correcting DNA replication errors. The events in mammalian MMR pathways remain poorly understood. Using HeLa cell nuclear extracts, we analyzed correction of mispairs in circular DNA substrates with single defined nicks and measured excision in the absence of exogenous dNTPs by annealing specific oligonucleotide probes. In reactions initiated by concomitant temperature shift and addition of ATP or Mg(2+) to otherwise complete mixtures on ice, ATP-initiated excision and final error correction lagged behind Mg(2+)-initiated reactions, suggesting a very early requirement for ATP but not its hydrolysis. Subsequent stable commitment (resistance to added excess competitor substrate) began within 30 s, required hydrolyzable ATP, and plateaued after 60-70 s. This may reflect formation of hydrolysis-dependent translocating and/or pre-excision complexes. Excision along shorter nick-mispair paths began 15 s later than commitment. Both 3' to 5' and 5' to 3' excision gaps appeared at rates of approximately 0.0055 of final yields per second, respectively, 30 or 2.5 times the nonspecific excision rates. The lag between 3' to 5' excision gaps at two different positions yielded an excision progress rate of 5.2 nucleotides/s. In both substrates, corrected products appeared at fractional rates of 0.0027 of final yield per second. Aphidicolin, known to inhibit both the DNA synthesis and 3' to 5' exonuclease activities of polymerases delta and epsilon, reduced appearance of 3' to 5' excision tracts roughly 4-fold at 90 microm but had no effect on 5' to 3' excision.

Contribution of human mlh1 and pms2 ATPase activities to DNA mismatch repair

MutLalpha, a heterodimer composed of Mlh1 and Pms2, is the major MutL activity in mammalian DNA mismatch repair. Highly conserved motifs in the N termini of both subunits predict that the protein is an ATPase. To study the significance of these motifs to mismatch repair, we have expressed in insect cells wild type human MutLalpha and forms altered in conserved glutamic acid residues, predicted to catalyze ATP hydrolysis of Mlh1, Pms2, or both. Using an in vitro assay, we showed that MutLalpha proteins altered in either glutamic acid residue were each partially defective in mismatch repair, whereas the double mutant showed no detectable mismatch repair. Neither strand specificity nor directionality of repair was affected in the single mutant proteins. Limited proteolysis studies of MutLalpha demonstrated that both Mlh1 and Pms2 N-terminal domains undergo ATP-induced conformational changes, but the extent of the conformational change for Mlh1 was more apparent than for Pms2. Furthermore, Mlh1 was protected at lower ATP concentrations than Pms2, suggesting Mlh1 binds ATP with higher affinity. These findings imply that ATP hydrolysis is required for MutLalpha activity in mismatch repair and that this activity is associated with differential conformational changes in Mlh1 and Pms2.

Mutations within the hMLH1 and hPMS2 subunits of the human MutLalpha mismatch repair factor affect its ATPase activity, but not its ability to interact with hMutSalpha

The MutL family of mismatch repair proteins belongs to the GHKL class of ATPases, which contains also type II topoisomerases, HSP90, and histidine kinases. The nucleotide binding domains of these polypeptides are highly conserved, but this similarity has failed to help us understand the biological role of the ATPase activity of the MutL proteins in mismatch repair. hMutLalpha is a heterodimer of the human MutL homologues hMLH1 and hPMS2, and we decided to exploit its asymmetry to study this function. We now show that although the two subunits contribute differently to the ATPase activity of the heterodimer, hMutLalpha variants in which one subunit was able to bind but not hydrolyze ATP displayed similarly reduced mismatch repair activities in vitro. In contrast, variants in which either subunit was unable to bind the nucleotide were inactive. Mutation of the catalytic sites of both subunits abolished repair without altering the ability of these peptides to interact with one another. Since the binding of the nucleotide in hMutLalpha was not required for the formation of ternary complexes with the mismatch recognition factor hMutSalpha bound to a heteroduplex substrate, we propose that the ATPase activity of hMutLalpha is required downstream from this process.

HNPCC mutations in hMSH2 result in reduced hMSH2-hMSH6 molecular switch functions

Mutations in the human mismatch repair (MMR) gene hMSH2 have been linked to approximately 40% of hereditary nonpolyposis colorectal cancers (HNPCC). While the consequences of deletion or truncating mutations of hMSH2 would appear clear, the detailed functional defects associated with missense alterations are unknown. We have examined the effect of seven single amino acid substitutions associated with HNPCC that cover the structural subdomains of the hMSH2 protein. We show that alterations which produced a known cancer-causing phenotype affected the mismatch-dependent molecular switch function of the biologically relevant hMSH2-hMSH6 heterodimer. Our observations demonstrate that amino acid substitutions within hMSH2 that are distant from known functional regions significantly alter biochemical activity and the ability of hMSH2-hMSH6 to form a sliding clamp.