Cooperative responses of DNA-damage-activated protein kinases ATR and ATM and DNA translesion polymerases to replication-blocking DNA damage in a stem-cell niche.

Conserved DNA-damage responses (DDRs) efficiently cope with replication blocks and double-strand breaks (DSBs) in cultured eukaryotic cells; DDRs in tissues remain poorly understood. DDR-inactivating mutations lethal in animals are tolerated in Arabidopsis, whose root meristem provides a powerful stem-cell-niche model. We imaged UVB-induced death of specific meristem cells in single and double Arabidopsis mutants to elucidate cooperation among DNA translesion synthesis (TLS) polymerases (Polη, Polζ) and DNA-damage-activated protein kinases (ATR, ATM). Death was 100-fold higher in stem and progenitor (StPr) cells than in transiently amplifying cells. Quantitative analyses of dose-response plots showed that Polη and Polζ act redundantly to tolerate replication blocks and that Polζ-mediated TLS requires ATR. Deficient TLS resulted in ATM-signaled death, which first appeared 10-14h post-UVB. Although ssDNA downstream of blocks was likely cleaved into DSBs throughout S phase, death pathways appeared to initiate late in S. In atm mutants death appeared much later, likely signaled by a slow ATR-dependent pathway. To bypass replication blocks, tissues may use TLS rather than error-free pathways that could generate genomic aberrations. Dynamic balances among ATR and ATM death-avoidance and death-signaling functions determine how many DSB-burdened StPr cells are killed. Their replacement by less-burdened quiescent-center cells then restores growth homeostasis.

Effects of suppressing the DNA mismatch repair system on homeologous recombination in tomato.

In plant breeding, the ability to manipulate genetic (meiotic) recombination would be beneficial for facilitating gene transfer from wild relatives of crop plants. The DNA mismatch repair (MMR) system helps maintain genetic integrity by correcting base mismatches that arise via DNA synthesis or damage, and antagonizes recombination between homeologous (divergent) DNA sequences. Previous studies have established that the genomes of cultivated tomato (Solanum lycopersicum) and the wild relative S. lycopersicoides are substantially diverged (homeologous) such that recombination between their chromosomes is strongly reduced. Here, we report the effects on homeologous recombination of suppressing endogenous MMR genes in S. lycopersicum via RNAi-induced silencing of SlMSH2 and SlMSH7 or overexpressing dominant negatives of Arabidopsis MSH2 (AtMSH2-DN) in an alien substitution line (SL-8) of S. lycopersicoides in tomato. We show that certain inhibitions of MMR (RNAi of SlMSH7, AtMSH2-DN) are associated with modest increases in homeologous recombination, ranging from 3.8 to 29.2% (average rate of 17.8%) compared to controls. Unexpectedly, only the AtMSH2-DN proteins but not RNAi-induced silencing of MSH2 was found to increase homeologous recombination. The ratio of single to double crossovers (SCO:DCO ratio) decreased by approximately 50% in progeny of the AtMSH2-DN parents. An increase in the frequency of heterozygous SL-8 plants was also observed in the progeny of the SlMSH7-RNAi parents. Our findings may contribute to acceleration of introgression in cultivated tomato.

New analytical methods for genetic dissection of biological responses to DNA lesions.

Two proteins that process damaged DNA may function in the same pathway, or in redundant ("synergistic") pathways that respond to the same lesion(s), or in parallel pathways targeted to different lesions. Previously, extended plots of positive outcomes (such as cell survival) or negative outcomes (such as reduced tissue growth) vs. genotoxic dose yielded empirical estimates of wt and mutant resistances to DNA damage. Recently, wt and mutant outcomes have been compared at one or two doses. The criterion for parallel pathways was "additivity": wt positive outcomes roughly equal to numerical sums of single-mutant positive outcomes or double-mutant negative outcomes equal to sums of single-mutant negative outcomes. For redundant pathways, wt positive outcomes or double-mutant negative outcomes were postulated to be "greater-than-additive" relative to single-mutant sums. Equations derived here to describe parallel and redundant pathways provide no rigorous theoretical justification for these criteria. Furthermore, simulations using these equations generate additive or greater-than-additive outcomes for both parallel and redundant pathways, depending on the values chosen for various parameters. Proposed new methods to compare wt vs. mutant plots of negative outcomes against doses of genotoxic agents yield three different but complementary estimates of resistances to DNA damage: respective plot slopes where mutant and wt outcomes are the same (inversely proportional to instantaneous damage-resistance strengths), respective total doses that cause the same outcomes (total resistance capacities), and respective dose thresholds where negative outcomes are first detected. Analyses of experimental examples suggest that greater-than additive threshold doses provide the most straightforward criteria for pathway redundancy.

Reversion-reporter transgenes to analyze all six base-substitution pathways in Arabidopsis.

To expand the repertoire of Arabidopsis (Arabidopsis thaliana) mutation-reporter transgenes, we constructed six mutant alleles in the same codon of the ß-glucuronidase-encoding GUS transgene. Each allele reverts to GUS+ only via a particular one of the six transition/transversion pathways. AcV5 epitope tags, fused carboxyl terminal to the inactive GUS- proteins, enabled semiquantitative immunoassays in plant protein extracts. Spontaneous G:C→T:A transversions, previously not measured using reporter transgenes, were quite frequent. This may reflect mispairing of adenine with 8-oxoguanine in DNA attacked by endogenous oxyradicals. Spontaneous G:C→A:T was modest and other reversions were relatively low, as reported previously. Frequencies of ultraviolet C-induced TT→TC and TC→TT reversions were both high. With increased transgene copy number, spontaneous G:C→T:A reversions increased but ultraviolet C-induced reversions decreased. Frequencies of some reversion events were reduced among T4 versus T3 generation plants. Based on these and other analyses of sources of experimental variation, we propose guidelines for the employment of these lines to study genotoxic stress in planta.

Reciprocal chromosome translocation associated with TDNA-insertion mutation in Arabidopsis: genetic and cytological analyses of consequences for gametophyte development and for construction of doubly mutant lines.

Chromosomal rearrangements may complicate construction of Arabidopsis with multiple TDNA-insertion mutations. Here, crossing two lines homozygous for insertions in AtREV3 and AtPOLH (chromosomes I and V, respectively) and selfing F1 plants yielded non-Mendelian F2 genotype distributions: frequencies of +/++/+ and 1/1 2/2 progeny were only 0.42 and 0.25%. However, the normal development and fertility of double mutants showed AtPOLH-1 and AtREV3-2 gametes and 1/1 2/2 embryos to be fully viable. F2 distributions could be quantitatively predicted by assuming that F1 selfing produced inviable (1,2) and (+,+) gametophytes 86% of the time. Some defect intrinsic to the F1 selfing process itself thus appeared responsible. In selfing AtREV3 (+/2 ) single mutants, imaging of ovules and pollen showed arrest or abortion, respectively, of half of gametophytes; however, gametogenesis was normal in AtREV3 ( 2/2 ) homozygotes. These findings, taken together, suggested that T-DNA insertion at AtREV3 on chromosome I had caused a reciprocal I-V translocation. Spreads of meiosis I chromosomes in selfing AtREV3 (+/2 ) heterozygotes revealed the predicted cruciform four-chromosome structures, which fluorescence in situ hybridization showed to invariably include both translocated and normal chromosomes I and V. Sequencing of the two junctions of T-DNA with AtREV3 DNA and the two with gene At5g59920 suggested translocation via homologous recombination between independent inverted-repeat T-DNA insertions. Thus, when crosses between TDNA-insertion mutants yield anomalous progeny distributions, TDNA-linked translocations should be considered.

Biochemical evolution of DNA polymerase eta: properties of plant, human, and yeast proteins.

To assess how evolution might have biochemically shaped DNA polymerase eta (Poleta) in plants, we expressed in Escherichia coli proteins from Arabidopsis thaliana (At), humans (Hs), and the yeast Saccharomyces cerevisiae (Sc), purified them to near homogeneity, and compared their properties. Consistent with the multiple divergent amino acids within mostly conserved polymerase domains, the polymerases showed modest, appreciable, and marked differences, respectively, in salt and temperature optima for activity and thermostability. We compared abilities to extend synthetic primers past template cyclobutane thymine dimers (T[CPD]T) or undamaged T-T under physiological conditions (80-110 mM salt). Specific activities for "standing-start" extension of synthetic primers ending opposite the second template nucleotide 3' to T-T were roughly similar. During subsequent "running-start" insertions past T-T and the next 5' ( N + 1) nucleotide, AtPoleta and HsPoleta appeared more processive, but DNA sequence contexts strongly affected termination probabilities. Lesion-bypass studies employed four different templates containing T[CPD]Ts, and two containing pyrimidine (6-4')-pyrimidinone photoproducts ([6-4]s). AtPoleta made the three successive insertions [opposite the T[CPD]T and (N + 1) nucleotides] that define bypass nearly as well as HsPoleta and somewhat better than ScPoleta. Again, sequence context effects were profound. Interestingly, the level of insertion opposite the ( N - 1) nucleotide 3' to T[CPD]T by HsPoleta and especially AtPoleta, but not ScPoleta, was reduced (up to 4-fold) relative to the level of insertion opposite the ( N - 1) nucleotide 3' to T-T. Evolutionary conservation of efficient T[CPD]T bypass by HsPoleta and AtPoleta may reflect a high degree of exposure of human skin and plants to solar UV-B radiation. The depressed ( N - 1) insertion upstream of T[CPD]T (but not T-T) may reduce the extent of gratuitous error-prone insertion.

Human DNA mismatch repair: coupling of mismatch recognition to strand-specific excision.

Eukaryotic mismatch-repair (MMR) proteins MutSalpha and MutLalpha couple recognition of base mismatches to strand-specific excision, initiated in vivo at growing 3' ends and 5' Okazaki-fragment ends or, in human nuclear extracts, at nicks in exogenous circular substrates. We addressed five biochemical questions relevant to coupling models. Excision remained fully efficient at DNA:MutSalpha ratios of nearly 1 to 1 at various mismatch-nick distances, suggesting a requirement for only one MutSalpha molecule per substrate. As the mismatch-nick DNA contour distance D in exogenous substrates increased from 0.26 to 0.98 kbp, initiation of excision in extracts decreased as D(-0.43) rather than the D(-1) to D(-2) predicted by some translocation or diffusion models. Virtually all excision was along the shorter (3'-5') nick-mismatch, even when the other (5'-3') path was less than twice as long. These observations argue against stochastically directed translocating/diffusing recognition complexes. The failure of mismatched DNA in trans to provoke excision of separate nicked homoduplexes argues against one-stage (concerted) triggering of excision initiation by recognition complexes acting through space. However, proteins associated with gapped DNA did appear to compete in trans with those in cis to mismatch-associated proteins. Thus, as in Escherichia coli, eukaryotic MMR may involve distinct initial-activation and excision-path-commitment stages.

Tolerance of dividing cells to replication stress in UVB-irradiated Arabidopsis roots: requirements for DNA translesion polymerases eta and zeta.

In tissues of multicellular organisms, DNA lesions that block replication can disrupt division of the transiently amplifying (TA) cells and stem cells that drive growth. To study how tissue growth is maintained despite DNA damage, stem cells and other cell types must be clearly identifiable. In plants, root growth depends directly on cell divisions in the root meristem. In Arabidopsis thaliana, cell identities in root meristems are unambiguously defined by position relative to the quiescent center and are readily visualized by microscopy. We evaluated roles of two DNA translesion polymerases, AtPoleta (Eta) and AtPolzeta (Zeta), in resistance of dividing root cells to a model genotoxin, UVB-radiation. The major UV photoproducts in DNA, cyclobutane pyrimidine dimers (CPDs), were induced to roughly 0.03CPD/kb by a threshold dose (0.28 kJ m(-2)) that minimally affected wild-type roots. In roots lacking AtPoleta and/or AtPolzeta, this dose inhibited cell division and tissue growth and specifically killed stem cells; severities of all three phenotypes increased in the order eta-

Construction of MMR plasmid substrates and analysis of MMR error correction and excision.

We describe simple and efficient construction of mismatch repair (MMR) substrates, by generation of gapped plasmids using one sequence-specific nicking endonuclease (N.BstNBI), ligation of synthetic oligomers into the gaps, and introduction of defined single nicks for initiation of MMR excision using a second such endonuclease (N.AlwI). We further describe measurement of completed mismatch correction and a sensitive quantitative assay for MMR excision intermediates. These methods can be easily adapted for construction of substrates containing defined DNA lesions, for analysis of MMR responses to DNA damage and for studies of other DNA repair pathways.

Testing excision models for responses of mismatch-repair systems to UV photoproducts in DNA.

Mismatch-repair (MMR) systems correct DNA replication errors and respond to a variety of DNA lesions. Previous observations that MMR antagonizes UV mutagenesis, and that the mismatch-recognition protein heterodimer MSH2*MSH6 (MutSalpha) selectively binds DNA containing "mismatched" photoproducts (T[CPD]T/AG, T[6-4]T/AG) but not "matched" photoproducts (T[CPD]T/AA, T[6-4]T/AA), suggested that mismatched photoproducts would provoke MMR excision similar to mismatched bases. Excision of incorrect nucleotides inserted opposite template photoproducts might then prevent UV-induced mutation. We tested T[CPD]T/AG DNA, in a sequence context in which it is bound substantially by hMutSalpha and in three other contexts, for stimulation of 3' MMR excision in mammalian nuclear extracts. T[CPD]T/AG was inactive in HeLa extracts, or in extracts deficient in the photoproduct-binding proteins DDB or XPC* hHR23B, arguing against interference from the nucleotide excision repair pathway. Prior incubation with hMutSalpha and MLH2.PMS2 (hMutLalpha) did not increase excision relative to homoduplex controls. T[6-4]T/AG also failed to provoke excision. T/G, C/A, and T/T substrates, even though bound by hMutSalpha no better than T[CPD]T/AG substrates, efficiently provoked excision. Even a substrate containing three T[CPD]T/AG photoproducts (in different contexts) did not significantly provoke excision. Thus, MMR may suppress UV mutagenesis by non-excisive mechanisms.

UVB dose-toxicity thresholds and steady-state DNA-photoproduct levels during chronic irradiation of inbred Xenopus laevis tadpoles.

Environmental stressors that severely impact some species more than others can alter ecosystems and threaten biodiversity. Genotoxic stress, such as solar UV-B irradiance, may induce levels of DNA damage at rates that exceed repair capacities in some species but remain below repair capacities in other species. Repair rates would seem to establish toxicity thresholds. We used inbred Xenopus laevis tadpoles in the laboratory to test the hypothesis that balances between rates of induction of cyclobutane pyrimidine dimers (CPDs; the major UV-B photoproduct in DNA) and rates of CPD removal (repair) can determine UV-B toxicity thresholds. As rates of chronic UV-B irradiance were progressively increased by decreased shielding of lamps, survival decreased sharply over a relatively narrow range of dose rates. Apparent toxicity thresholds were associated with large increases in steady-state CPD levels. Induction at twice the measured removal (repair) rate produced sustained high CPDs and 100% mortality. Induction at one-half the removal rate resulted in negligible CPD levels and low mortality. Increased intensity of visible radiation available to drive CPD photoreactivation, mimicking interspecies variation in DNA repair capacity, reduced steady-state CPD levels and increased survival at UV-B dose rates that were previously toxic, resulting in increased thresholds of apparent toxicity. We suggest that threshold effects due to DNA repair should generally be considered in assessments of effects of genotoxic agents on species-specific population decreases and human health risks.

Analysis of mismatch repair in human nuclear extracts.

This unit describes an assay for completed mismatch correction along with a precise and sensitive assay for mismatch-repair excision intermediates and a simple and efficient procedure for construction of mismatch repair substrates. These substrates are derived by ligating synthetic oligomers into a gapped plasmid generated using the sequence-specific N.BstNBI nicking endonuclease, then the sequence-specific nicking endonuclease N.AlwI, to introduce single nicks for initiation of excision. These methods can be easily adapted for construction and analysis of DNA-lesion-containing substrates to study DNA-repair pathways other than mismatch repair.

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.

Binding of MutS mismatch repair protein to DNA containing UV photoproducts, "mismatched" opposite Watson--Crick and novel nucleotides, in different DNA sequence contexts.

Mismatch-repair (MMR) systems suppress mutation via correction of DNA replication errors (base-mispairs) and responses to mutagenic DNA lesions. Selective binding of mismatched or damaged DNA by MutS-homolog proteins-bacterial MutS, eukaryotic MSH2.MSH6 (MutSalpha) and MSH2.MSH3-initiates mismatch-correction pathways and responses to lesions, and may cumulatively increase discrimination at downstream steps. MutS-homolog binding selectivity and the well-known but poorly understood effects of DNA-sequence contexts on recognition may thus be primary determinants of MMR specificity and efficiency. MMR processes that modulate UV mutagenesis might begin with selective binding by MutS homologs of "mismatched" T[CPD]T/AG and T[6--4]T/AG photoproducts, reported previously for hMutSalpha and described here for E. coli MutS protein. If MMR suppresses UV mutagenesis by acting directly on pre-mutagenic products of replicative bypass, mismatched photoproducts should be recognized in most DNA-sequence contexts. In three of four contexts tested here (three substantially different), T[CPD]T/AG was bound only slightly better by MutS than was T[CPD]T/AA or homoduplex DNA; only one of two contexts tested promoted selective binding of T[6--4]T/AG. Although the T:G pairs in T[CPD]T/AG and T/G both adopt wobble conformations, MutS bound T/G well in all contexts (K(1/2) 2.1--2.9 nM). Thus, MutS appears to select the two mismatches by different mechanisms. NMR analyses elsewhere suggest that in the (highly distorted) T[6--4]T/AG a forked H-bond between O2 of the 3' thymine and the ring 1-imino and exocyclic 2-amino guanine protons stabilizes a novel planar structure not possible in T[6--4]T/AA. Replacement of G by purines lacking one (inosine, 2-aminopurine) or both (nebularine) protons markedly reduced or eliminated selective MutS binding, as predicted. Previous studies and the work here, taken together, suggest that in only about half of DNA sequence contexts could MutS (and presumably MutSalpha) selectively bind mismatched UV photoproducts and directly suppress UV mutagenesis.

Fluoroimaging-based immunoassay of DNA photoproducts in ultraviolet-B-irradiated tadpoles.

Sensitive and accurate measurement of photoproducts induced in DNA by natural or artificial ultraviolet-B (UVB; and UVC) light is essential to evaluate the toxic and mutagenic effects of this radiation. Monoclonal antibodies specific for the two major classes of photoproducts-cyclobutane pyrimidine dimers (CPDs) and pyrimidine-[6-4]-pyrimidinone photoproducts ([6-4]PPs)-have made possible highly specific and sensitive assays. Described here is the use of these primary antibodies with fluorescent secondary antibodies to generate 96-spot arrays. Stable fluorescence signals are rapidly and sensitively scored by fluoroimaging and computer analysis of peak-and-valley traces. CPD levels in a series of calibration standards are determined by acid hydrolysis/thin-layer chromatography analyses of radiolabeled bacterial DNA, UV-irradiated to known high fluences, and linear extrapolation to known lower fluences. The nonlinear fluorescence vs CPD curve reflects the effect of photoproduct concentration on single vs double binding by divalent antibody proteins. This technique is applied to photoproducts in whole inbred Xenopus laevis tadpoles, chronically irradiated at a series of UVB fluences that reach a lethality threshold when in vivo steady-state photoproduct levels are still quite low. As few as 0.01-0.02 CPDs per DNA kbp can be reliably detected, at signal/noise ratios of roughly 3:1.

Rapid accumulation of mutations during seed-to-seed propagation of mismatch-repair-defective Arabidopsis.

During the many cell divisions that precede formation of plant gametes, their apical-meristem and floral antecedents are continually exposed to endogenous and environmental mutagenic threats. Although some deleterious recessive mutations may be eliminated during growth of haploid gametophytes and functionally haploid early embryos ("haplosufficiency quality-checking"), the multiplicity of plant genome-maintenance systems suggests aggressive quality control during prior diploid growth. To test in Arabidopsis a hypothesis that prior mismatch repair (MMR) is paramount in defense of plant genetic fidelity, we propagated in parallel 36 MMR-defective (Atmsh2-1) and 36 wild-type lines. The Atmsh2-1 lines rapidly accumulated a wide variety of mutations: fifth-generation (G5) plants showed abnormalities in morphology and development, fertility, germination efficiency, seed/silique development, and seed set. Only two Atmsh2-1, but all 36 wild-type lines, appeared normal at G5. Analyses of insertion/deletion mutation at six repeat-sequence (microsatellite) loci showed each Atmsh2-1 line to have evolved its own "fingerprint," the results of as many as 10 microsatellite mutations in a single line. Thus, MMR during diploid growth is essential for plant genomic integrity.

Arabidopsis thaliana AtPOLK encodes a DinB-like DNA polymerase that extends mispaired primer termini and is highly expressed in a variety of tissues.

Cell survival after DNA damage depends on specialized DNA polymerases able to perform DNA synthesis on imperfect templates. Most of these enzymes belong to the recently discovered Y-family of DNA polymerases, none of which has been previously described in plants. We report here the isolation, functional characterization and expression analysis of a plant representative of the Y-family. This polymerase, which we have termed AtPolkappa, is a homolog of Escherichia coli pol IV and human pol kappa, and thus belongs to the DinB subfamily. We purified AtPolkappa and found a template-directed DNA polymerase, endowed with limited processivity that is able to extend primer-terminal mispairs. The activity and processivity of AtPolkappa are enhanced markedly upon deletion of 193 amino acids (aa) from its carboxy (C)-terminal domain. Loss of this region also affects the nucleotide selectivity of the enzyme, leading to the incorporation of both dCTP and dTTP opposite A in the template. We detected three cDNA forms, which result from the alternative splicing of AtPOLK mRNA and have distinct patterns of expression in different plant organs. Histochemical localization of beta-glucuronidase (GUS) activity in transgenic plants revealed that the AtPOLK promoter is active in endoreduplicating cells, suggesting a possible role during consecutive DNA replication cycles in the absence of mitosis.

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.

Reduction of stability of arabidopsis genomic and transgenic DNA-repeat sequences (microsatellites) by inactivation of AtMSH2 mismatch-repair function.

Highly conserved mismatch repair (MMR) systems promote genomic stability by correcting DNA replication errors, antagonizing homeologous recombination, and responding to various DNA lesions. Arabidopsis and other plants encode a suite of MMR protein orthologs, including MSH2, the constant component of various specialized eukaryotic mismatch recognition heterodimers. To study MMR roles in plant genomic stability, we used Arabidopsis AtMSH2::TDNA mutant SALK_002708 and AtMSH2 RNA-interference (RNAi) lines. AtMSH2::TDNA and RNAi lines show normal growth, development, and fertility. To analyze AtMSH2 effects on germ line DNA fidelity, we measured insertion-deletion mutation of dinucleotide-repeat sequences (microsatellite instability) at nine loci in 16 or more progeny of two to four different wild-type or AtMSH2-deficient plants. Scoring 992 total alleles revealed 23 (2.3%) unique and 51 (5.1%) total repeat length shifts ([+2], [-2], [+4], or [-4] bp). For the six longest repeat loci, the corresponding frequencies were 22/608 and 50/608. Two of four AtMSH2-RNAi plants showed similar microsatellite instability. In wild-type progeny, only one unique repeat length allele was found in 576 alleles tested. This endogenous microsatellite instability, shown for the first time in MMR-defective plants, is similar to that seen in MMR-defective yeast and mice, indicating that plants also use MMR to promote germ line fidelity. We used a frameshifted reporter transgene, (G)(7)GUS, to measure insertion-deletion reversion as blue-staining beta-glucuronidase-positive leaf spots. Reversion rates increased only 5-fold in AtMSH2::TDNA plants, considerably less than increases in MSH2-deficient yeast or mammalian cells for similar mononucleotide repeats. Thus, MMR-dependent error correction may be less stringent in differentiated leaf cells than in plant equivalents of germ line tissue.