A simple and rapid quantitative method of detection of the common achondroplasia mutation: analysis in mismatch repair deficient cells

Achondroplasia is the most common form of dwarfism and has an incidence of approximately 1/7500. In more than 97% of cases, it is caused by a recurrent point mutation, a G to A substitution at nucleotide position 1138 (G1138A) of the fibroblast growth factor receptor 3 gene. Although this is an autosomal dominant condition, more than 90% of all mutations occur sporadically making this one of the most mutagenic sites in the human genome. The reasons for the high spontaneous G1138A mutation rate are not known. This investigation was performed by developing a simple and rapid semi-quantitative allele specific PCR based assay capable of reliably detecting more than 25 mutant G1138A copies in a pool of 300 000 wild type molecules. Using this assay, the G1138A mutation frequency was measured in cell lines deficient in mismatch repair (LoVo, SW48) and comparing it with controls. No differences were found in the frequency of this point mutation between the mismatch repair deficient and wild type cell lines.     

Specific targeted gene repair using single-stranded DNA oligonucleotides at an endogenous locus in mammalian cells uses homologous recombination

The feasibility of introducing point mutations in vivo using single-stranded DNA oligonucleotides (ssON) has been demonstrated but the efficiency and mechanism remain elusive and potential side effects have not been fully evaluated. Understanding the mechanism behind this potential therapy may help its development. Here, we demonstrate the specific repair of an endogenous non-functional hprt gene by a ssON in mammalian cells, and show that the frequency of such an event is enhanced when cells are in S-phase of the cell cycle. A potential barrier in using ssONs as gene therapy could be non-targeted mutations or gene rearrangements triggered by the ssON. Both the non-specific mutation frequencies and the frequency of gene rearrangements were largely unaffected by ssONs. Furthermore, we find that the introduction of a mutation causing the loss of a functional endogenous hprt gene by a ssON occurred at a similarly low but statistically significant frequency in wild type cells and in cells deficient in single strand break repair, nucleotide excision repair and mismatch repair. However, this mutation was not induced in XRCC3 mutant cells deficient in homologous recombination. Thus, our data suggest ssON-mediated targeted gene repair is more efficient in S-phase and involves homologous recombination.     

UV-induced skin carcinogenesis in xeroderma pigmentosum group A (XPA) gene-knockout mice with nucleotide excision repair-deficiency

Nucleotide excision repair (NER) removes a wide variety of lesions from the genome and is deficient in the genetic disorder, xeroderma pigmentosum (XP). In this paper, an in vitro analysis of the XP group A gene product (XPA protein) is reported. Results of an analysis on the pathogenesis of ultraviolet (UV)-B-induced skin cancer in the XPA gene-knockout mouse are also described: (1) contrary to wild type mice, significant bias of p53 mutations to the transcribed strand and no evident p53 mutational hot spots were detected in the skin tumors of XPA-knockout mice. (2) Skin cancer cell lines from UVB-irradiated XPA-knockout mice had a decreased mismatch repair activity and an abnormal cell cycle checkpoint, suggesting that the downregulation of mismatch repair helps cells escape killing by UVB and that mismatch repair-deficient clones are selected for during the tumorigenic transformation of XPA (-/-) cells. (3) The XPA-knockout mice showed a higher frequency of UVB-induced mutation in the rpsL transgene at a low dose of UVB-irradiation than the wild type mice. CC-->TT tandem transition, a hallmark of UV-induced mutation, was detected at higher frequency in the rpsL transgene in the XPA-knockout mice than the wild type mice. This rpsL/XPA mouse system will be useful for further analysing the role of NER in the mutagenesis induced by various carcinogens. (4) The UVB-induced immunosuppression was greatly enhanced in the XPA-knockout mice. It is possible that an enhanced impairment of the immune system by UVB irradiation is involved in the high incidence of skin cancer in XP.     

Repair of Single- and Multiple-Substitution Mismatches during Recombination in Streptococcus Pneumoniae

The use as genetic markers, during transformation of Streptococcus pneumoniae, of 19 sequences differing from wild type, located throughout the amiA locus, enabled us to examine the fate of 24 single- and 11 multiple-mismatches during recombination. Tentative mismatch ranking as a function of decreasing repair efficiency by the Hex mismatch repair system is G/T = A/C = G/G (maximum repair: 90-95%) greater than C/T (mostly 75 to 90% repair) greater than A/A (from 50 to 90% repair) greater than T/T (50-65% repair) greater than A/G (from 0 to 20% repair) greater than C/C. No indication of correction of the latter has been obtained. Over the limited number of samples examined, we observed no influence of the base composition of the surrounding sequence on correction efficiency for both transition mismatches and for G/G and C/C. Variations in the surrounding sequence affect repair of A/G and C/T, and, even more strongly, of A/A and T/T. No simple correlation to the G:C content of the surrounding sequence is apparent from our results, in contrast to the conclusion drawn for the Mut mismatch repair system of Escherichia coli. Examination of the fate of multiple mismatches suggests that C/C may sometimes impede recognition of otherwise corrected mismatches.     

Requirement for Phe36 for DNA binding and mismatch repair by Escherichia coli MutS protein

The MutS family of DNA repair proteins recognizes base pair mismatches and insertion/deletion mismatches and targets them for repair in a strand-specific manner. Photocrosslinking and mutational studies previously identified a highly conserved Phe residue at the N-terminus of Thermus aquaticus MutS protein that is critical for mismatch recognition in vitro. Here, a mutant Escherichia coli MutS protein harboring a substitution of Ala for the corresponding Phe36 residue is assessed for proficiency in mismatch repair in vivo and DNA binding and ATP hydrolysis in vitro. The F36A protein is unable to restore mismatch repair proficiency to a mutS strain as judged by mutation to rifampicin or reversion of a specific point mutation in lacZ. The F36A protein is also severely deficient for binding to heteroduplexes containing an unpaired thymidine or a G:T mismatch although its intrinsic ATPase activity and subunit oligomerization are very similar to that of the wild-type MutS protein. Thus, the F36A mutation appears to confer a defect specific for recognition of insertion/deletion and base pair mismatches.     

Escherichia Coli Mutator Mutd5 Is Defective in the Muthls Pathway of DNA Mismatch Repair

We have previously reported that the Escherichia coli mutator strain mutD5 was defective in the correction of bacteriophage M13mp2 heteroduplex DNA containing a T.G mismatch. Here, this defect was further investigated with regard to its interaction with the mutHLS pathway of mismatch repair. A set of 15 different M13mp2 heteroduplexes was used to measure the mismatch-repair capability of wild-type, mutL and mutD5 cells. Throughout the series, the mutD5 strain proved as deficient in mismatch repair as the mutL strain, indicating that the repair defect is similar in the two strains in both extent and specificity. [One exception was noted in the case a T.G mispair that was subject to VSP (Very Short Patch) repair. VSP repair was abolished by mutL but not by mutD.] Variation in the dam-methylation state of the heteroduplex molecules clearly affected repair in the wild-type strain but had no effect on either the mutD or mutL strain. Finally, mutDmutL or mutDmutS double-mutator strains were no more deficient in mismatch repair as were the single mutator strains. The combined results strongly argue that the mismatch-repair deficiency of mutD5 cells resides in the mutH,L,S-dependent pathway of mismatch repair and that the high mutation rate of mutD strains derives in part from this defect.     

Detection of single DNA base mutations with mismatch repair enzymes.

A novel method for identifying DNA point mutations has been developed by using mismatch repair enzymes. The high specificity of the Escherichia coli MutY protein has permitted the development of a reliable and sensitive method for the detection and characterization of point mutations in the human genome. The MutY protein is involved in a repair pathway that can convert A/G or A/C mismatches to C/G or G/C basepairs, respectively. A/G or A/C mismatches formed by hybridization between two amplified genomic DNA samples or between specific DNA probes and target DNA are nicked at the mispaired adenine strand by MutY protein. As little as 1% of the mutant sequence can be detected by the mismatch repair enzyme cleavage (MREC) method in a mixture of normal and mutated DNAs (e.g., mutant cells are only present in 1% of the normal cell background). By using different probes, the assay also can determine the nucleotide sequence of the mutation. We have applied this method to detect single-base substitutions in human oncogenes.     

DNA mismatch repair mediates protection from mutagenesis induced by short-wave ultraviolet light

To investigate involvement of DNA mismatch repair in the response to short-wave ultraviolet (UVC) light, we compared UVC-induced mutant frequencies and mutational spectra at the Hprt gene between wild type and mismatch-repair-deficient mouse embryonic stem (ES) cells. Whereas mismatch repair gene status did not significantly affect survival of these cells after UVC irradiation, UVC induced substantially more mutations in ES cells that lack the MutSalpha mismatch-recognizing heterodimer than in wild type ES cells. The global UVC-induced mutational spectra at Hprt and the distribution of most spectral mutational hotspots were found to be similar in mismatch-repair-deficient and wild type cells. However, at one predominant spectral hot spot for mutagenesis in wild type cells, the UVC-induced mutation frequency was not affected by the mismatch repair status. Together these data reveal a major role of mismatch repair in controlling mutagenesis induced by UVC light and may suggest the sequence context-dependent direct mismatch repair of misincorporations opposite UVC-induced pyrimidine dimers.     

A new assay to quantify in vivo repair of G:T mispairs by base excision repair.

The double mismatch reversion (DMR) assay quantifies the repair of G:T mispairs exclusively by base excision repair in vivo. Synthetic oligonucleotides containing two G:T mispairs on opposite strands were placed into the suppressor tRNA gene supF in the shuttle plasmid pDMR. Placement of two mispairs on opposite strands of supF creates a one to one correspondence between the number of correct repair events prior to replication in which G:T mispairs are converted to G:C base pairs and the number of post-replication progeny plasmids with functional supF. Replication of unrepaired or incorrectly repaired mispairs cannot produce progeny plasmids containing functional supF. Indeed, direct transformation of Escherichia coli strain MBL50, which reports the functional status of supF, with pDMR constructs containing two G:T or G:G mispairs yielded <0.5% wild-type supF-containing colonies. In contrast, passage of G:T mispair-containing pDMR constructs through human 5637 bladder carcinoma cells for 48h prior to plasmid recovery and transformation of the reporter E. coli strain MBL50 produced 47% wild-type supF-containing colonies. This finding was indicative of repair prior to the onset of replication in 5637 cells. However, passage of G:G mispair-containing pDMR constructs through 5637 cells yielded <0.5% wild-type supF-containing colonies. Moreover, no difference was observed in the rate of G:T mispair repair by HCT 116 colorectal carcinoma cells deficient in long-patch mismatch repair and a long-patch mismatch repair proficient HCT 116 subline. These data demonstrate that repair measured by the DMR assay is exclusively attributable to short-patch pathways. The DMR assay proved useful in the analysis of the effect of the base 5' to a mispaired G on the rate of G:T base excision repair by 5637 cells, indicating the sequence preference CpG approximately 5mCpG>TpG>GpG approximately ApG, and in the comparison of G:T base excision repair rates between cell lines.     

Mismatch repair in mammalian cells

A vital process in maintaining a low genetic error rate is the removal of mismatched bases in DNA. The importance of this process in E. coli is demonstrated by the 100–1000 fold increase in mutation frequency observed in cells deficient in this repair system⁽¹⁾. Mismatches can arise as a consequence of recombination, errors in replication and as a result of spontaneous chemical deamination, the latter process resulting in an estimated twelve T:G mismatches per genome per day in mammalian cells⁽²⁾. Recent studies, discussed here, provide evidence for the existence of specific mismatch repair systems in mammalian and human cells.     

Escherichia coli mutator (Delta)polA is defective in base mismatch correction: the nature of in vivo DNA replication errors

We constructed a set of Escherichia coli strains containing deletions in genes encoding three SOS polymerases, and defective in MutS and DNA polymerase I (PolI) mismatch repair, and estimated the rate and specificity of spontaneous endogenous tonB(+)-->tonB- mutations. The rate and specificity of mutations in strains proficient or deficient in three SOS polymerases was compared and found that there was no contribution of SOS polymerases to the chromosomal tonB mutations. MutS-deficient strains displayed elevated spontaneous mutation rates, consisting of dominantly minus frameshifts and transitions. Minus frameshifts are dominated by warm spots at run-bases. Among 57 transitions (both G:C-->A:T and A:T-->G:C), 35 occurred at two hotspot sites. PolI-deficient strains possessed an increased rate of deletions and frameshifts, because of a deficiency in postreplicative deletion and frameshift mismatch corrections. Frameshifts in PolI-deficient strains occurred within the entire tonB gene at non-run and run sequences. MutS and PolI double deficiency indicated a synergistic increase in the rate of deletions, frameshifts and transitions. In this case, mutS-specific hotspots for frameshifts and transitions disappeared. The results suggested that, unlike the case previously known pertaining to postreplicative MutS mismatch repair for frameshifts and transitions and PolI mismatch repair for frameshifts and deletions, PolI can recognize and correct transition mismatches. Possible mechanisms for distinct MutS and PolI mismatch repair are discussed. A strain containing deficiencies in three SOS polymerases, MutS mismatch repair and PolI mismatch repair was also constructed. The spectrum of spontaneous mutations in this strain is considered to represent the spectrum of in vivo DNA polymerase III replication errors. The mutation rate of this strain was 219x10(-8), about a 100-fold increase relative to the wild-type strain. Uncorrected polymerase III replication errors were predominantly frameshifts and base substitutions followed by deletions.     

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.     

Hypermutation in Ig V genes from mice deficient in the MLH1 mismatch repair protein

During somatic hypermutation of Ig V genes, mismatched nucleotide substitutions become candidates for removal by the DNA mismatch repair pathway. Previous studies have shown that V genes from mice deficient for the MSH2 and PMS2 mismatch repair proteins have frequencies of mutation that are comparable with those from wild-type (wt) mice; however, the pattern of mutation is altered. Because the absence of MSH2 and PMS2 produced different mutational spectra, we examined the role of another protein involved in mismatch repair, MLH1, on the frequency and pattern of hypermutation. MLH1-deficient mice were immunized with oxazolone Ag, and splenic B cells were analyzed for mutations in their V kappa Ox1 light chain genes. Although the frequency of mutation in MLH1-deficient mice was twofold lower than in wt mice, the pattern of mutation in Mlh1-/- clones was similar to wt clones. These findings suggest that the MLH1 protein has no direct effect on the mutational spectrum.     

Mismatch repair proteins collaborate with methyltransferases in the repair of O(6)-methylguanine

DNA repair is essential for combatting the adverse effects of damage to the genome. One example of base damage is O(6)-methylguanine (O(6)mG), which stably pairs with thymine during replication and thereby creates a promutagenic O(6)mG:T mismatch. This mismatch has also been linked with cellular toxicity. Therefore, in the absence of repair, O(6)mG:T mismatches can lead to cell death or result in G:C-->A:T transition mutations upon the next round of replication. Cysteine thiolate residues on the Ada and Ogt methyltransferase (MTase) proteins directly reverse the O(6)mG base damage to yield guanine. When a cytosine is opposite the lesion, MTase repair restores a normal G:C pairing. However, if replication past the lesion has produced an O(6)mG:T mismatch, MTase conversion to a G:T mispair must still undergo correction to avoid mutation. Two mismatch repair pathways in E. coli that convert G:T mispairs to native G:C pairings are methyl-directed mismatch repair (MMR) and very short patch repair (VSPR). This work examined the possible roles that proteins in these pathways play in coordination with the canonical MTase repair of O(6)mG:T mismatches. The possibility of this repair network was analyzed by probing the efficiency of MTase repair of a single O(6)mG residue in cells deficient in individual mismatch repair proteins (Dam, MutH, MutS, MutL, or Vsr). We found that MTase repair in cells deficient in Dam or MutH showed wild-type levels of MTase repair. In contrast, cells lacking any of the VSPR proteins MutS, MutL, or Vsr showed a decrease in repair of O(6)mG by the Ada and Ogt MTases. Evidence is presented that the VSPR pathway positively influences MTase repair of O(6)mG:T mismatches, and assists the efficiency of restoring these mismatches to native G:C base pairs.     

Repair of specific base pair mismatches formed during meiotic recombination in the yeast Saccharomyces cerevisiae.

Heteroduplexes formed between DNA strands derived from different homologous chromosomes are an intermediate in meiotic crossing over in the yeast Saccharomyces cerevisiae and other eucaryotes. A heteroduplex formed between wild-type and mutant genes will contain a base pair mismatch; failure to repair this mismatch will lead to postmeiotic segregation (PMS). By analyzing the frequency of PMS for various mutant alleles in the yeast HIS4 gene, we showed that C/C mismatches were inefficiently repaired relative to all other point mismatches. These other mismatches (G/G, G/A, T/T, A/A, T/C, C/A, A/A, and T/G) were repaired with approximately the same efficiency. We found that in spores with unrepaired mismatches in heteroduplexes, the nontranscribed strand of the HIS4 gene was more frequently donated than the transcribed strand. In addition, the direction of repair for certain mismatches was nonrandom.     

Role of uracil-DNA glycosylase in mutation avoidance by Streptococcus pneumoniae.

Uracil-DNA glycosylase activity was found in Streptococcus pneumoniae, and the enzyme was partially purified. An ung mutant lacking the activity was obtained by positive selection of cells transformed with a plasmid containing uracil in its DNA. The effects of the ung mutation on mutagenic processes in S. pneumoniae were examined. The sequence of several malM mutations revertible by nitrous acid showed them to correspond to A.T----G.C transitions. This confirmed a prior deduction that nitrous acid action on transforming DNA gave only G.C----A.T mutations. Examination of malM mutant reversion frequencies in ung strains indicated that G.C----A.T mutation rates generally were 10-fold higher than in wild-type strains, presumably owing to lack of repair of deaminated cytosine residues in DNA. No effect of ung on mutation avoidance by the Hex mismatch repair system was observed, which means that uracil incorporation and removal from nascent DNA cannot be solely responsible for producing strand breaks that target nascent DNA for correction after replication. One malM mutation corresponding to an A.T----G.C transition showed a 10-fold-higher spontaneous reversion frequency than other such transitions in a wild-type background. This "hot spot" was located in a directly repeated DNA sequence; it is proposed that transient slippage to the wild-type repeat during replication accounts for the higher reversion frequency.     

Mutational specificity of mice defective in the MTH1 and/or the MSH2 genes

Oxidative damage of nucleotides within DNA or precursor pools caused by oxygen radicals is thought to play an important role in spontaneous mutagenesis, as well as carcinogenesis and aging. In particular, 8-oxodGTP and 2-OHdATP are potent mutagenic substrate for DNA synthesis. Mammalian MTH1 catalyzes hydrolysis of these mutagenic substrates, suggesting that it functions to prevent mutagenesis caused by these oxidized nucleotides. We have established MTH1(-/-) mice lacking the 8-oxodGTPase activity, which were shown to be susceptible to lung, liver and stomach cancers. To examine in vivo mutation events due to the MTH1-deficiency, a reporter gene, rpsL of Escherichia coli, was introduced into MTH1(-/-) mice. Interestingly, the net frequency of rpsL(-) forward mutants showed no apparent increase in MTH1(-/-) mice as compared to MTH1(+/+) mice. However, we found differences between these two genotypes in the class- and site-distributions of the rpsL(-) mutations recovered from the mice. Unlike MutT-deficient E. coli showing 1000-fold higher frequency of A:T-->C:G transversion than the wild type cells, an increase in frequency of A:T-->C:G transversion was not evident in MTH1 nullizygous mice. Nevertheless, the frequency of single-base frameshifts at mononucleotide runs was 5.7-fold higher in spleens of MTH1(-/-) mice than in those of wild type mice. Since the elevated incidence of single-base frameshifts at mononucleotide runs is a hallmark of the defect in MSH2-dependent mismatch repair system, this weak site-specific mutator effect of MTH1(-/-) mice could be attributed to a partial sequestration of the mismatch repair function that may act to correct mispairs with the oxidized nucleotides. Consistent with this hypothesis, a significant increase in the frequency of G:C-->T:A transversions was observed with MTH1(-/-) MSH2(-/-) mice over MSH2(-/-) mice alone. These results suggest a possible involvement of multiple anti-mutagenic pathways, including the MTH1 protein and other repair system(s), in mutagenesis caused by the oxidized nucleotides.     

Functional mutation of DNA polymerase beta found in human gastric cancer--inability of the base excision repair in vitro.

DNA polymerase beta (polbeta) is one of mammalian DNA polymerases and is known to be involved in a G:T/G:U mismatch repair. In order to investigate an involvement of this enzyme in a base excision repair, we searched a mutation of human polbeta in human gastric cancer and studied a function of the mutation. We observed cancer-specific missense mutations in 6 of 20 samples. All of these mutations were, however, heterozygous. We further analyzed the base excision repair activity of these mutants to know whether these mutants cause an error of mismatch repair. One of these mutants, which resulted in an amino acid substitution of Glu for Lys at codon 295, showed an inhibitory effect by in vitro base excision repair assay, suggesting that this mutation might play some role in carcinogenesis of the gastric mucosa.     

Deletion of dnaN1 generates a mutator phenotype in Bacillus anthracis

The dnaN gene in eubacteria is an essential gene that encodes the beta subunit of replicative DNA polymerase. Nearly all eubacterial genomes sequenced to date predict a single copy of the dnaN gene in a well-conserved neighboring gene context. However, 19 genomes out of 348 scanned, including Bacillus anthracis, Bacillus cereus, Bacillus thuringiensis, and Bacillus weihenstephanensis, predict more than one dnaN gene. In most cases, these genomes appear to maintain a copy of the dnaN homolog in its usual neighboring gene context (designated as dnaN1) in addition to a second copy (designated as dnaN2) in an entirely different gene context. We used B. anthracis as our model system to investigate the role of these DnaNs. We constructed a single knockout mutant of dnaN1 and of dnaN2; however, we could not make a viable double knockout mutant of dnaN1 and dnaN2. The dnaN1 knockout mutant displays a markedly reduced colony size. It also displays a significantly increased mutation rate, which is similar to that of a mismatch repair deficient strain and to a strain deficient both in dnaN1 and mismatch repair. The dnaN2 knockout mutant, however, has a similar growth rate and a comparable mutation rate to that of the wild type. This is the first study demonstrating the existence of two functional DnaN homologs in the B. anthracis genome, with DnaN1 appearing to be more crucial than DnaN2. Our results also suggest the direct involvement of DnaN1 in the DNA mismatch repair process, which is consistent with previous findings.     

The cellular mismatch repair system is able to repair mismatches within MLV retroviral double-stranded DNA at a low frequency

Eukaryotic cells possess several distinct mismatch repair pathways. A mismatch can be introduced in retroviral double-stranded DNA by a pre-existing mutation within the primer binding site (PBS) of the viral RNA genome. In order to evaluate mismatch repair of retroviral double-stranded DNA, Moloney leukemia virus (MLV)-based vectors with a mutation in their PBS were used to infect mismatch repair-competent as well as mismatch repair-deficient cell lines. If the target cells were capable of repairing the mismatch before an infected cell divided, the mismatch within the PBS could be repaired to the wild-type or mutant PBS. If the target cells were unable to repair the mismatch, half the cells in the colony should contain the mutant PBS while the other half should contain the wild-type PBS. To evaluate these predictions, individual colonies were isolated and analyzed by PCR. Almost all mismatch-deficient cell colonies analyzed (cell lines HCT 116 and PMS2–/–) contained both the wild-type and mutated PBS, therefore, mismatches within retroviral double-strand DNA could not be repaired by the mismatch-deficient cells. In contrast, mismatches in ~25% of the mismatch repair-competent cell clones analyzed (cell lines HeLa and PMS2+/+) were repaired, while 75% were not. Therefore, the cellular mismatch repair system is able to repair mismatches within viral double-stranded DNA, but at a low frequency.