Yeast-based assay for the measurement of positive and negative influences on microsatellite stability

The evolutionary conservation of mismatch repair and Saccharomyces cerevisiae as a model system have been exploited for monitoring the influence of everyday beverages and the antineoplastic agent, hydroxyurea, on the stability of regions of highly repetitive DNA known as microsatellites. Two different reporter systems are compared for sensitivity and reproducibility by measuring the extent of frame slippage events occurring in microsatellite regions in wild-type and mismatch repair-compromised yeast strains. Increased frame slippage results in increased reporter gene expression and hence represents instability within the repetitive region, whereas a decrease or no significant change indicates the faithful replication of the original assay plasmid, suggesting a beneficial or neutral effect of the test component. A significant outcome of this study was the identification of the protective influence exerted by the green tea catechin (-)-epigallocatechin-3-gallate (EGCG) against microsatellite instability, which is in agreement with the hypothesis that EGCG is the major chemopreventive ingredient of green tea. Immunological detection can also be used in conjunction with the green fluorescent protein (GFP) version of the assay system to identify compounds, such as hydroxyurea, which increased microsatellite instability. The system has the potential for development as a high-throughput assay for wider application.     

The in vitro fidelity of yeast DNA polymerase δ and polymerase ε holoenzymes during dinucleotide microsatellite DNA synthesis

Elucidating the sources of genetic variation within microsatellite alleles has important implications for understanding the etiology of human diseases. Mismatch repair is a well described pathway for the suppression of microsatellite instability. However, the cellular polymerases responsible for generating microsatellite errors have not been fully described. We address this gap in knowledge by measuring the fidelity of recombinant yeast polymerase δ (Pol δ) and ? (Pol ?) holoenzymes during synthesis of a [GT/CA] microsatellite. The in vitro HSV-tk forward assay was used to measure DNA polymerase errors generated during gap-filling of complementary GT(10) and CA(10)-containing substrates and ～90 nucleotides of HSV-tk coding sequence surrounding the microsatellites. The observed mutant frequencies within the microsatellites were 4 to 30-fold higher than the observed mutant frequencies within the coding sequence. More specifically, the rate of Pol δ and Pol ? misalignment-based insertion/deletion errors within the microsatellites was ～1000-fold higher than the rate of insertion/deletion errors within the HSV-tk gene. Although the most common microsatellite error was the deletion of a single repeat unit, ～ 20% of errors were deletions of two or more units for both polymerases. The differences in fidelity for wild type enzymes and their exonuclease-deficient derivatives were ～2-fold for unit-based microsatellite insertion/deletion errors. Interestingly, the exonucleases preferentially removed potentially stabilizing interruption errors within the microsatellites. Since Pol δ and Pol ? perform not only the bulk of DNA replication in eukaryotic cells but also are implicated in performing DNA synthesis associated with repair and recombination, these results indicate that microsatellite errors may be introduced into the genome during multiple DNA metabolic pathways.     

Mitotic crossovers between diverged sequences are regulated by mismatch repair proteins in Saccaromyces cerevisiae.

Mismatch repair systems correct replication- and recombination-associated mispaired bases and influence the stability of simple repeats. These systems thus serve multiple roles in maintaining genetic stability in eukaryotes, and human mismatch repair defects have been associated with hereditary predisposition to cancer. In prokaryotes, mismatch repair systems also have been shown to limit recombination between diverged (homologous) sequences. We have developed a unique intron-based assay system to examine the effects of yeast mismatch repair genes (PMS1, MSH2, and MSH3) on crossovers between homologous sequences. We find that the apparent antirecombination effects of mismatch repair proteins in mitosis are related to the degree of substrate divergence. Defects in mismatch repair can elevate homologous recombination between 91% homologous substrates as much as 100-fold while having only modest effects on recombination between 77% homologous substrates. These observations have implications for genome stability and general mechanisms of recombination in eukaryotes.     

The instability within: problems in current analyses of microsatellite instability

Microsatellite instability is regarded as one of the phenotypes of defective DNA mismatch repair and, consequently, as a marker of high risk for cancer. Despite numerous studies, the reported rates for positive microsatellite instability differ widely in each human malignancy. These discrepancies may relate to problems in the methods used. To establish a methodology for an accurate microsatellite instability analysis, technical requirements for a precise assay and biological conditions required for positive microsatellite instability were discussed. First, to describe microsatellite changes in detail, a sensitive detection system with linear detection characteristics and electrophoresis with standardised migration and minimised migration errors are considered to be necessary. Therefore, systems using fluorescent labelling and laser scanning are recommended. For reproducible polymerase chain reactions, it is essential to control the terminal deoxynucleotidyl transferase activity in Taq polymerase. Second, as a biological condition for positive microsatellite instability, feasible selection and combination of microsatellite markers, mutations in specific DNA mismatch repair genes and existence of monoclonal populations enriched sufficiently in a sample are essential. Finally, one possible diagnostic criterion for positive microsatellite instability is proposed, that is the existence of one of the patterns shown in the panel (see Fig. 6) at one or more loci in a set of more than five microsatellite markers.     

DNA mismatch repair,microsatellite instability and cancer

Mismatch (MMR) repair system plays a significant role in restoration of stability in the genome. Mutations in mismatch repair genes hamper their activity thus bring about a defect in mismatch repair (MMR) mechanism thereby conferring instability in the microsatellite sequences of both the coding and non-coding regions of the genome. Mutated mismatch repair genes result in the expansion or contraction of microsatellite sequence and confer microsatellite unstable or replication error positive phenotype. Hypermethylation of promoter regions of some of the MMR genes also causes inactivation of these genes and thus contribute to MSI. Microsatellite instability is an indicator of MMR deficiency and is a prime cause of varied tumorogenesis.     

Microsatellite instability induced by hydrogen peroxide in Escherichia coli

Damage to DNA by reactive oxygen species may be a significant source of endogenous mutagenesis in aerobic organisms. Using a selective assay for microsatellite instability in E. coli, we have asked whether endogenous oxidative mutagenesis can contribute to genetic instability. Instability of repetitive sequences, both in intronic sequences and within coding regions, is a hallmark of genetic instability in human cancers. We demonstrate that exposure of E. coli to low levels of hydrogen peroxide increases the frequency of expansions and deletions within dinucleotide repetitive sequences. Sequencing of the repetitive sequences and flanking non-repetitive regions in mutant clones demonstrated the high specificity for alterations with the repeats. All of the 183 mutants sequenced displayed frameshift alterations within the microsatellite repeats, and no base substitutions or frameshift mutations occurred within the flanking non-repetitive sequences. We hypothesize that endogenous oxidative damage to DNA can increase the frequency of strand slippage intermediates occurring during DNA replication or repair synthesis, and contribute to genomic instability.     

Identification of hMutLbeta, a heterodimer of hMLH1 and hPMS1.

hMLH1 and hPMS2 function in postreplicative mismatch repair in the form of a heterodimer referred to as hMutLalpha. Tumors or cell lines lacking this factor display mutator phenotypes and microsatellite instability, and mutations in the hMLH1 and hPMS2 genes predispose to hereditary non-polyposis colon cancer. A third MutL homologue, hPMS1, has also been reported to be mutated in one cancer-prone kindred, but the protein encoded by this locus has so far remained without function. We now show that hPMS1 is expressed in human cells and that it interacts with hMLH1 with high affinity to form the heterodimer hMutLbeta. Recombinant hMutLalpha and hMutLbeta, expressed in the baculovirus system, were tested for their activity in an in vitro mismatch repair assay. While hMutLalpha could fully complement extracts of mismatch repair-deficient cell lines lacking hMLH1 or hPMS2, hMutLbeta failed to do so with any of the different substrates tested in this assay. The involvement of the latter factor in postreplicative mismatch repair thus remains to be demonstrated.     

Hypermutability at a poly(A/T) tract in the human germline

Poly(A/T) tracts are abundant simple sequence repeats (SSRs) within the human genome. They constitute part of the coding sequence of a variety of genes, encoding polylysine stretches that are important for protein function. Assessment of poly(A/T) tract stability is also used to identify microsatellite unstable colorectal cancers, which are characteristic of tumours defective in DNA mismatch repair. Despite their importance, little is known about the stability of poly(A/T) SSRs in the human germline. We have determined the stability of a paradigm poly(A/T) tract, BAT-40, by study of population allele frequencies, mutation frequency in families and mutation frequency in sperm DNA. We show that the locus is polymorphic, with a level of heterozygosity of 59.7%. Germline mutation was observed in 13 of 187 germline transmissions (7.0%) in 10 families suggesting BAT-40 is unstable in the germline. Further evidence for germline instability at BAT-40 was provided by small pool PCR analysis of matched blood and sperm DNA templates, revealing a significantly elevated frequency of mutation in the germline (P < 0.001). These findings provide insight into poly(A/T) tract stability in the germline. They also have relevance to the study of gene expression and to determination of microsatellite instability in tumours.     

Stabilization of Microsatellite Sequences by Variant Repeats in the Yeast Saccharomyces Cerevisiae

We examined the effect of a single variant repeat on the stability of a 51-base pair (bp) microsatellite (poly GT). We found that the insertion stabilizes the microsatellite about fivefold in wild-type strains. The stabilizing effect of the variant base was also observed in strains with mutations in the DNA mismatch repair genes pms1, msh2 and msh3, indicating that this effect does not require a functional DNA mismatch repair system. Most of the microsatellite alterations in the pms1, msh2 and msh3 strains were additions or deletions of single GT repeats, but about half of the alterations in the wild-type and msh6 strains were large (>8 bp) deletions or additions.     

Positive correlation between DNA polymerase alpha-primase pausing and mutagenesis within polypyrimidine/polypurine microsatellite sequences

Microsatellite DNA sequences are ubiquitous in the human genome, and mutation rates of these repetitive sequences vary with respect to DNA sequence as well as length. We have analyzed polymerase-DNA interactions as a function of microsatellite sequence, using polypyrimidine/polypurine di- and tetranucleotide alleles representative of those found in the human genome. Using an in vitro primer extension assay and the mammalian DNA polymerase alpha-primase complex, we have observed a polymerase termination profile for each microsatellite that is unique to that allele. Interestingly, a periodic termination profile with an interval size (9-11 nucleotides) unrelated to microsatellite unit length was observed for the [TC](20) and [TTCC](9) templates. In contrast, a unit-punctuated polymerase termination profile was found for the longer polypurine templates. We detected strong polymerase pauses within the [TC](20) allele at low reaction pH which were eliminated by the addition of deaza-dGTP, consistent with these specific pauses being a consequence of triplex DNA formation during DNA synthesis. Quantitatively, a strand bias was observed in the primer extension assay, in that polymerase synthesis termination is more intense when the polypurine sequence serves as the template, relative to its complementary polypyrimidine sequence. The HSV-tk forward mutation assay was utilized to determine the corresponding polymerase alpha-primase error frequencies and specificities at the microsatellite alleles. A higher microsatellite polymerase error frequency (50x10(-4) to 60x10(-4)) was measured when polypurine sequences serve as templates for DNA synthesis, relative to the polypyrimidine template (18x10(-4)). Thus, a positive correlation exists between polymerase alpha-primase pausing and mutagenesis within microsatellite DNA alleles.     

Relative rates of insertion and deletion mutations in dinucleotide repeats of various lengths in mismatch repair proficient mouse and mismatch repair deficient human cells

Microsatellites are DNA elements composed of short tandem repeats of 1-5bp. These sequences are particularly prone to frameshift mutation by insertion-deletion loop formation during replication. The mismatch repair system is responsible for correcting these replication errors, and microsatellite mutation rates are significantly elevated in the absence of mismatch repair. We have investigated the effect of varying the number of repeats in a (CA)n microsatellite on mutation rates in cultured mammalian cells proficient or deficient in mismatch repair. We have also compared the relative rates of single-repeat insertions and deletions in these cells. Two plasmid vectors were constructed for each repeat unit number (n=8, 17, and 30), such that the microsatellites, placed upstream of a bacterial neomycin resistance gene (neo), disrupted the reading frame of the gene in the (-1) or (+1) direction. Plasmids were introduced separately into the cells, where they integrated into the cellular genome. Mutation rates were determined by selection of clones with frameshift mutations in the microsatellite that restored the reading frame of the neo gene. We found that mutation rates were significantly higher for (CA)17 and (CA)30 tracts than for (CA)8 tracts in both mismatch repair proficient (mouse) and deficient (human) cells. A mutational bias favoring insertions was generally observed. In both (CA)17 and (CA)30 tracts, single-repeat insertion rates were higher than single-repeat deletion rates with or without mismatch repair; deletions of multiple repeat units (> or =8bp) were observed in these tracts, where as deletions this large were not found in the (CA)8 tract. Single-repeat mutations of both types were made at similar rates in (CA)8 tracts in human mismatch repair deficient (MMR-) cells, but single-repeat insertion rates were higher than single-repeat deletion rates in mouse mismatch repair proficient (MMR+) cells. Results of these direct studies on microsatellite mutations in cultured cells should be useful for refinement of mathematical models for microsatellite evolution.     

Limitations of the in vitro repair synthesis assay for probing the role of DNA repair in platinum resistance.

Several studies have implicated enhanced DNA repair in acquired platinum resistance. To better understand the mechanism of increased repair we have employed an in vitro assay using cell-free extracts from platinum sensitive and resistant murine and human cell lines. Since the platinum resistant murine cell lines used in our previous studies had shown increased repair of diaminocyclohexane(dach)-Pt-DNA adducts while one of the resistant human cell lines did not, we have measured in vitro repair synthesis on DNA damaged by (d,l)-trans-1,2-diaminocyclohexanedichloroplatinum(II) (PtCl2(dach)). The results of this assay were strongly dependent on the method used to calculate repair synthesis activity and appeared to disagree with previous estimates of repair activity in these cell lines. By one method of calculation the in vitro repair synthesis assay underestimated the ratio of repair activities in the resistant versus the sensitive murine cell lines, while by the other method the in vitro assay overestimated the ratio of repair activities in the resistant versus the sensitive human cell lines.     

A novel fluorometric oligonucleotide assay to measure O 6-methylguanine DNA methyltransferase, methylpurine DNA glycosylase, 8-oxoguanine DNA glycosylase and abasic endonuclease activities: DNA repair status in human breast carcinoma cells overexpressing methylpurine DNA glycosylase

DNA repair status plays a major role in mutagenesis, carcinogenesis and resistance to genotoxic agents. Because DNA repair processes involve multiple enzymatic steps, understanding cellular DNA repair status has required several assay procedures. We have developed a novel in vitro assay that allows quantitative measurement of alkylation repair via O⁶-methylguanine DNA methyltransferase (MGMT) and base excision repair (BER) involving methylpurine DNA glycosylase (MPG), human 8-oxoguanine DNA glycosylase (hOGG1) and yeast and human abasic endonuclease (APN1 and APE/ref-1, respectively) from a single cell extract. This approach involves preparation of cell extracts in a common buffer in which all of the DNA repair proteins are active and the use of fluorometrically labeled oligonucleotide substrates containing DNA lesions specific to each repair protein. This method enables methylation and BER capacities to be determined rapidly from a small amount of starting sample. In addition, the stability of the fluorometric oligonucleotides precludes the substrate variability caused by continual radiolabeling. In this report this technique was applied to human breast carcinoma MDA-MB231 cells overexpressing human MPG in order to assess whether up-regulation of the initial step in BER alters the activity of selected other BER (hOGG1 and APE/ref-1) or direct reversal (MGMT) repair activities.     

Capture of extranuclear DNA at fission yeast double-strand breaks

Proper repair of DNA double-strand breaks (DSBs) is necessary for the maintenance of genomic integrity. Here, a new simple assay was used to study extrachromosomal DSB repair in Schizosaccharomyces pombe. Strikingly, DSB repair was associated with the capture of fission yeast mitochondrial DNA (mtDNA) at high frequency. Capture of mtDNA fragments required the Lig4p/Pku70p nonhomologous end-joining (NHEJ) machinery and its frequency was highly increased in fission yeast cells grown to stationary phase. The fission yeast Mre11 complex Rad32p/Rad50p/Nbs1p was also required for efficient capture of mtDNA at DSBs, supporting a role for the complex in promoting intermolecular ligation. Competition assays further revealed that microsatellite DNA from higher eukaryotes was preferentially captured at yeast DSBs. Finally, cotransformation experiments indicated that, in NHEJ-deficient cells, capture of extranuclear DNA at DSBs was observed if homologies--as short as 8 bp--were present between DNA substrate and DSB ends. Hence, whether driven by NHEJ, microhomology-mediated end-joining, or homologous recombination, DNA capture associated with DSB repair is a mutagenic process threatening genomic stability.     

Epstein–Barr Virus DNase (BGLF5) induces genomic instability in human epithelial cells

Epstein–Barr Virus (EBV) DNase (BGLF5) is an alkaline nuclease and has been suggested to be important in the viral life cycle. However, its effect on host cells remains unknown. Serological and histopathological studies implied that EBV DNase seems to be correlated with carcinogenesis. Therefore, we investigate the effect of EBV DNase on epithelial cells. Here, we report that expression of EBV DNase induces increased formation of micronucleus, an indicator of genomic instability, in human epithelial cells. We also demonstrate, using γH2AX formation and comet assay, that EBV DNase induces DNA damage. Furthermore, using host cell reactivation assay, we find that EBV DNase expression repressed damaged DNA repair in various epithelial cells. Western blot and quantitative PCR analyses reveal that expression of repair-related genes is reduced significantly in cells expressing EBV DNase. Host shut-off mutants eliminate shut-off expression of repair genes and repress damaged DNA repair, suggesting that shut-off function of BGLF5 contributes to repression of DNA repair. In addition, EBV DNase caused chromosomal aberrations and increased the microsatellite instability (MSI) and frequency of genetic mutation in human epithelial cells. Together, we propose that EBV DNase induces genomic instability in epithelial cells, which may be through induction of DNA damage and also repression of DNA repair, subsequently increases MSI and genetic mutations, and may contribute consequently to the carcinogenesis of human epithelial cells.     

Two modes of microsatellite instability in human cancer: differential connection of defective DNA mismatch repair to dinucleotide repeat instability

Microsatellite instability (MSI) is associated with defective DNA mismatch repair in various human malignancies. Using a unique fluorescent technique, we have observed two distinct modes of dinucleotide microsatellite alterations in human colorectal cancer. Type A alterations are defined as length changes of ≤6 bp. Type B changes are more drastic and involve modifications of ≥8 bp. We show here that defective mismatch repair is necessary and sufficient for Type A changes. These changes were observed in cell lines and in tumours from mismatch repair gene-knockout mice. No Type B instability was seen in these cells or tumours. In a panel of human colorectal tumours, both Type A MSI and Type B instability were observed. Both types of MSI were associated with hMSH2 or hMLH1 mismatch repair gene alterations. Intriguingly, p53 mutations, which are generally regarded as uncommon in human tumours of the MSI⁺ phenotype, were frequently associated with Type A instability, whereas none was found in tumours with Type B instability, reflecting the prevailing viewpoint. Inspection of published data reveals that the microsatellite instability that has been observed in various malignancies, including those associated with Hereditary Non-Polyposis Colorectal Cancer (HNPCC), is predominantly Type B. Our findings indicate that Type B instability is not a simple reflection of a repair defect. We suggest that there are at least two qualitatively distinct modes of dinucleotide MSI in human colorectal cancer, and that different molecular mechanisms may underlie these modes of MSI. The relationship between MSI and defective mismatch repair may be more complex than hitherto suspected.     

XRCC1 phosphorylation by CK2 is required for its stability and efficient DNA repair

XRCC1 is a scaffold protein that interacts with several DNA repair proteins and plays a critical role in DNA base excision repair (BER). XRCC1 protein is in a tight complex with DNA ligase IIIα (Lig III) and this complex is involved in the ligation step of both BER and repair of DNA single strand breaks. The majority of XRCC1 has previously been demonstrated to exist in a phosphorylated form and cells containing mutant XRCC1, that is unable to be phosphorylated, display a reduced rate of single strand break repair. Here, in an unbiased assay, we demonstrate that the cytoplasmic form of the casein kinase 2 (CK2) protein is the major protein kinase activity involved in phosphorylation of XRCC1 in human cell extracts and that XRCC1 phosphorylation is required for XRCC1-Lig III complex stability. We demonstrate that XRCC1-Lig III complex containing mutant XRCC1, in which CK2 phosphorylation sites have been mutated, is unstable. We also find that a knockdown of CK2 by siRNA results in both reduced XRCC1 phosphorylation and stability, which also leads to a reduced amount of Lig III and accumulation of DNA strand breaks. We therefore propose that CK2 plays an important role in DNA repair by contributing to the stability of XRCC1-Lig III complex.     

Analysis of genomic damage in the mutagen-sensitive mus-201 mutant of Drosophila melanogaster by arbitrarily primed PCR (AP-PCR) fingerprinting.

DNA repair mechanisms are important to maintain the stability of the genome. In Drosophila melanogaster, the mus-201 gene is required in the excision repair process. To study the contribution of the mus-201 gene in the stability of the Drosophila genome, we have used the arbitrarily primed PCR fingerprinting method (AP-PCR). We have analysed the changes in the genomic DNA fingerprints from the progeny of wild-type males crossed with mus-201 repair-deficient or repair-proficient females. After induction of DNA damage with 2-acetylaminofluorene (2-AAF) in the wild-type parental males, quantitative and qualitative differences in the AP-PCR fingerprints were detected between the two crosses, and the estimate of the genomic damage detected by AP-PCR has clearly shown that the mus-201 repair deficiency is associated with an increase of genomic damage. The predominant type of alterations detected by AP-PCR under the mus-201 repair-deficient conditions agree with the results obtained in microsatellite PCR analysis, suggesting that the role of the mus-201 gene, necessary in excision repair, is not associated to the mismatch repair process. The work reported here demonstrates that the AP-PCR is a suitable technique to analyse genetic alterations in D. melanogaster and, consequently, can be used to compare the susceptibility to genomic damage of different DNA repair mutants.