Human mismatch repair: reconstitution of a nick-directed bidirectional reaction

Bidirectional mismatch repair directed by a strand break located 3' or 5' to the mispair has been reconstituted using seven purified human activities: MutSalpha, MutLalpha, EXOI, replication protein A (RPA), proliferating cell nuclear antigen (PCNA), replication factor C (RFC) and DNA polymerase delta. In addition to DNA polymerase delta, PCNA, RFC, and RPA, 5'-directed repair depends on MutSalpha and EXOI, whereas 3'-directed mismatch correction also requires MutLalpha. The repair reaction displays specificity for DNA polymerase delta, an effect that presumably reflects interactions with other repair activities. Because previous studies have suggested potential involvement of the editing function of a replicative polymerase in mismatch-provoked excision, we have evaluated possible participation of DNA polymerase delta in the excision step of repair. RFC and PCNA dramatically activate polymerase delta-mediated hydrolysis of a primer-template. Nevertheless, the contribution of the polymerase to mismatch-provoked excision is very limited, both in the purified system and in HeLa extracts, as judged by in vitro assay using nicked circular heteroplex DNAs. Thus, excision and repair in the purified system containing polymerase delta are reduced 10-fold upon omission of EXOI or by substitution of a catalytically dead form of the exonuclease. Furthermore, aphidicolin inhibits both 3'- and 5'-directed excision in HeLa nuclear extracts by only 20-30%. Although this modest inhibition could be because of nonspecific effects, it may indicate limited dependence of bidirectional excision on an aphidicolin-sensitive DNA polymerase.     

A defined human system that supports bidirectional mismatch-provoked excision

Mismatch-provoked excision directed by a strand break located 3' or 5' to the mispair has been reconstituted using purified human proteins. While MutSalpha, EXOI, and RPA are sufficient to support hydrolysis directed by a 5' strand break, 3' directed excision also requires MutLalpha, PCNA, and RFC. EXOI interacts with PCNA. RFC and PCNA suppress EXOI-mediated 5' to 3' hydrolysis when the nick that directs excision is located 3' to the mispair and activate 3' to 5' excision, which is dependent on loaded PCNA and apparently mediated by a cryptic EXOI 3' to 5' hydrolytic function. By contrast, RFC and PCNA have only a limited effect on 5' to 3' excision directed by a 5' strand break.     

Human exonuclease I is required for 5' and 3' mismatch repair.

We have partially purified a human activity that restores mismatch-dependent, bi-directional excision to a human nuclear extract fraction depleted for one or more mismatch repair excision activities. Human EXOI co-purifies with the excision activity, and the purified activity can be replaced by near homogeneous recombinant hEXOI. Despite the reported 5' to 3' hydrolytic polarity of this activity, hEXOI participates in mismatch-provoked excision directed by a strand break located either 5' or 3' to the mispair. When the strand break that directs repair is located 3' to the mispair, hEXOI- and mismatch-dependent gap formation in excision-depleted extracts requires both hMutSalpha and hMutLalpha. However, excision directed by a 5' strand break requires hMutSalpha but can occur in absence of hMutLalpha. In systems comprised of pure components, the 5' to 3' hydrolytic activity of hEXOI is activated by hMutSalpha in a mismatch-dependent manner. These observations indicate a hydrolytic function for hEXOI in 5'-heteroduplex correction. The involvement of hEXOI in 3'-heteroduplex repair suggests that it has a regulatory/structural role in assembly of the 3'-excision complex or that the protein possesses a cryptic 3' to 5' hydrolytic activity.     

Reconstitution of 5'-directed human mismatch repair in a purified system

This paper reports reconstitution of 5'-nick-directed mismatch repair using purified human proteins. The reconstituted system includes MutSalpha or MutSbeta, MutLalpha, RPA, EXO1, HMGB1, PCNA, RFC, polymerase delta, and ligase I. In this system, MutSbeta plays a limited role in repair of base-base mismatches, but it processes insertion/deletion mispairs much more efficiently than MutSalpha, which efficiently corrects both types of heteroduplexes. MutLalpha reduces the processivity of EXO1 and terminates EXO1-catalyzed excision upon mismatch removal. In the absence of MutLalpha, mismatch-provoked excision by EXO1 occurs extensively. RPA and HMGB1 play similar but complementary roles in stimulating MutSalpha-activated, EXO1-catalyzed excision in the presence of a mismatch, but RPA has a distinct role in facilitating MutLalpha-mediated excision termination past mismatch. Evidence is provided that efficient repair of a single mismatch requires multiple molecules of MutSalpha-MutLalpha complex. These data suggest a model for human mismatch repair involving coordinated initiation and termination of mismatch-provoked excision.     

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.     

The MutSalpha-proliferating cell nuclear antigen interaction in human DNA mismatch repair

We have examined the interaction parameters, conformation, and functional significance of the human MutSalpha(.) proliferating cell nuclear antigen (PCNA) complex in mismatch repair. The two proteins associate with a 1:1 stoichiometry and a K(D) of 0.7 microm in the absence or presence of heteroduplex DNA. PCNA does not influence the affinity of MutSalpha for a mismatch, and mismatch-bound MutSalpha binds PCNA. Small angle x-ray scattering studies have established the molecular parameters of the complex, which are consistent with an elongated conformation in which the two proteins associate in an end-to-end fashion in a manner that does not involve an extended unstructured tether, as has been proposed for yeast MutSalpha and PCNA ( Shell, S. S., Putnam, C. D., and Kolodner, R. D. (2007) Mol. Cell 26, 565-578 ). MutSalpha variants lacking the PCNA interaction motif are functional in 3'- or 5'-directed mismatch-provoked excision, but display a partial defect in 5'-directed mismatch repair. This finding is consistent with the modest mutability conferred by inactivation of the MutSalpha PCNA interaction motif and suggests that interaction of the replication clamp with other repair protein(s) accounts for the essential role of PCNA in MutSalpha-dependent mismatch repair.     

The 3'-->5' exonucleases of DNA polymerases delta and epsilon and the 5'-->3' exonuclease Exo1 have major roles in postreplication mutation avoidance in Saccharomyces cerevisiae

Replication fidelity is controlled by DNA polymerase proofreading and postreplication mismatch repair. We have genetically characterized the roles of the 5'-->3' Exo1 and the 3'-->5' DNA polymerase exonucleases in mismatch repair in the yeast Saccharomyces cerevisiae by using various genetic backgrounds and highly sensitive mutation detection systems that are based on long and short homonucleotide runs. Genetic interactions were examined among DNA polymerase epsilon (pol2-4) and delta (pol3-01) mutants defective in 3'-->5' proofreading exonuclease, mutants defective in the 5'-->3' exonuclease Exo1, and mismatch repair mutants (msh2, msh3, or msh6). These three exonucleases play an important role in mutation avoidance. Surprisingly, the mutation rate in an exo1 pol3-01 mutant was comparable to that in an msh2 pol3-01 mutant, suggesting that they participate directly in postreplication mismatch repair as well as in other DNA metabolic processes.     

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.     

Flavonol and iridoid glycosides of Ajuga remota aerial parts

Six flavonol glycosides characterised as myricetin 3-O-alpha-rhamnosyl-(1'-->2')-alpha-rhamnoside-3'-O-alpha-rhamnoside, 5'-O-methylmyricetin 3-O-[alpha-rhamnosyl (1'-->2')][alpha-rhamnosyl (1'-->4')]-beta -glucoside-3'-O-beta-glucoside, 5'-O-methylmyricetin 3-O-alpha-rhamnosyl (1'-->2')-alpha-rhamnoside 3'-O-beta-galactoside, kaemferol 3-O-rutinoside-7-O-rutinoside, myricetin 3-O-rutinoside-3'-O-alpha-rhamnoside, myricetin 3-O-beta-glucosyl (1'-->2')-beta-glucoside-4'-O-beta-glucoside together with two iridoid glycosides identified as 6,8-diacetylharpagide and 6,8-diacetylharpagide-1-O-beta-(3',4'-di-O-acetylglucoside) have been isolated from extract of Ajuga remota aerial parts. Also isolated from the same extract were known compounds; kaempferol 3-O-alpha-rhamnoside, quercetin 3-O-beta-glucoside, quercetin 3-O-rutinoside, 8-acetylharpagide, ajugarin I and ajugarin II.     

Identification and expression of the TREX1 and TREX2 cDNA sequences encoding mammalian 3'-->5' exonucleases.

The 3'-->5' exonucleases catalyze the excision of nucleoside monophosphates from the 3' termini of DNA. We have identified the cDNA sequences encoding two 3'-->5' exonucleases (TREX1 and TREX2) from mammalian cells. The TREX1 and TREX2 proteins are 304 and 236 amino acids in length, respectively. Analysis of the TREX1 and TREX2 sequences identifies three conserved motifs that likely generate the exonuclease active site in these enzymes. The specific amino acids in these three conserved motifs suggest that these mammalian exonucleases are most closely related to the proofreading exonucleases of the bacterial replicative DNA polymerases and the RNase T enzymes. Expression of TREX1 and TREX2 in Escherichia coli demonstrates that these recombinant proteins are active 3'-->5' exonucleases. The recombinant TREX1 protein was purified, and exonuclease activity was measured using single-stranded, partial duplex, and mispaired oligonucleotide DNA substrates. The greatest activity of the TREX1 protein was detected using a partial duplex DNA containing five mispaired nucleotides at the 3' terminus. No activity was detected using single-stranded RNA or an RNA-DNA partial duplex. Identification of the TREX1 and TREX2 cDNA sequences provides the genetic tools to investigate the physiological roles of these exonucleases in mammalian DNA replication, repair, and recombination pathways.     

The multiple biological roles of the 3'-->5' exonuclease of Saccharomyces cerevisiae DNA polymerase delta require switching between the polymerase and exonuclease domains

Until recently, the only biological function attributed to the 3'-->5' exonuclease activity of DNA polymerases was proofreading of replication errors. Based on genetic and biochemical analysis of the 3'-->5' exonuclease of yeast DNA polymerase delta (Pol delta) we have discerned additional biological roles for this exonuclease in Okazaki fragment maturation and mismatch repair. We asked whether Pol delta exonuclease performs all these biological functions in association with the replicative complex or as an exonuclease separate from the replicating holoenzyme. We have identified yeast Pol delta mutants at Leu523 that are defective in processive DNA synthesis when the rate of misincorporation is high because of a deoxynucleoside triphosphate (dNTP) imbalance. Yet the mutants retain robust 3'-->5' exonuclease activity. Based on biochemical studies, the mutant enzymes appear to be impaired in switching of the nascent 3' end between the polymerase and the exonuclease sites, resulting in severely impaired biological functions. Mutation rates and spectra and synergistic interactions of the pol3-L523X mutations with msh2, exo1, and rad27/fen1 defects were indistinguishable from those observed with previously studied exonuclease-defective mutants of the Pol delta. We conclude that the three biological functions of the 3'-->5' exonuclease addressed in this study are performed intramolecularly within the replicating holoenzyme.     

Bacillus subtilis bacteriophage SPP1 G40P helicase lacking the n-terminal domain unwinds DNA bidirectionally

Bacillus subtilis bacteriophage SPP1 G40P hexameric replicative DNA helicase unidirectionally translocates with a 5'-->3' polarity while separating the DNA strands. A G40P mutant derivative lacking the N-terminal domain (containing amino acid residues 110-442 from G40P, G40PDeltaN109) was purified and characterized. G40PDeltaN109 showed an ATPase activity that was dependent on the presence of single-stranded (ss) DNA. Unlike G40P, G40PDeltaN109 was shown to bind with similar affinity both ssDNA arms of forked structures by nuclease protection assays. In a pH-dependent manner, G40PDeltaN109 unwound a branched double-arm substrate preferentially with a 3'-->5' polarity. Our results show that the linker region and the C-terminal domain of G40P are sufficient to render an enzyme capable of encircling the ssDNA tails of the forked DNA and to unwind DNA with both 5'-->3' and 3'-->5' polarity. The presence of the N-terminal domain, which does not play an essential role in helicase action, might be required indirectly for strand discrimination and polarity of translocation.     

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.     

Syntheses of DNA duplexes containing a C-C interstrand cross-link

Short DNA duplexes that contain a N4C-ethyl-N4C interstrand cross-link were prepared on controlled pore glass supports using a DNA synthesizer. The C-C cross-link was introduced via a convertible nucleoside on the support or by using a protected C-C cross-link phosphoramidite. An orthogonal protection scheme allowed selective chain growth in either a 3'-->5' or 5'-->3' direction. The cross-linked duplexes were purified by HPLC and characterized by MALDI-TOF mass spectrometry and/or by enzymatic digestion.     

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.     

PARP-1 enhances the mismatch-dependence of 5'-directed excision in human mismatch repair in vitro

End-directed mismatch-provoked excision has been reconstituted in several purified systems. While 3'-directed excision displays a mismatch dependence similar to that observed in nuclear extracts (≈20-fold), the mismatch dependence of 5'-directed excision is only 3-4-fold, significantly less than that in extracts (8-10-fold). Utilizing a fractionation-based approach, we have isolated a single polypeptide that enhances mismatch dependence of reconstituted 5'-directed excision and have shown it to be identical to poly[ADP-ribose] polymerase 1 (PARP-1). Titration of reconstituted excision reactions or PARP-1-depleted HeLa nuclear extract with purified PARP-1 showed that the protein specifically enhances mismatch dependence of 5'-directed excision. Analysis of a set of PARP-1 mutants revealed that the DNA binding domain and BRCT fold contribute to the regulation of excision specificity. Involvement of the catalytic domain is restricted to its ability to poly(ADP-ribosyl)ate PARP-1 in the presence of NAD(+), likely through interference with DNA binding. Analysis of protein-protein interactions demonstrated that PARP-1 interacts with mismatch repair proteins MutSα, exonuclease 1, replication protein A (RPA), and as previously shown by others, replication factor C (RFC) and proliferating cell nuclear antigen (PCNA) as well. The BRCT fold plays an important role in the interaction of PARP-1 with the former three proteins.