Involvement of nucleotide-excision repair in msh2 pms1-independent mismatch repair.

Nucleotide-excision repair (NER) and mismatch repair (MMR) are prominent examples of highly conserved DNA repair systems which recognize and replace damaged and/or mispaired nucleotides in DNA. In humans, inheritable defects in components of the NER system are associated with severe diseases such as xeroderma pigmentosum (XP) and Cockayne syndrome (CS), whereas inactivation of MMR is accompanied by predisposition to certain types of cancer. In Schizosaccharomyces pombe, the msh2- and pms1-dependent long-patch MMR system efficiently corrects small insertion/deletion loops and all base-base mismatches, except C/C. Up to 70% of C/C mismatches generated in recombination intermediates, and to a lesser extent also other base-base mismatches, are thought to undergo correction by a minor, short-patch excision repair system. We identify here the NER genes rhpl4, swi10 and rad16 as components of this repair pathway and show that they act independently of msh2 and pms1.

DNA Repair in mammalian cells: Mismatched repair: variations on a theme.

Complementary base pairing underlies the genetic template function of the DNA double helix. Therefore, to assure faithful DNA transactions, cells must adhere to a strict application of the Watson-Crick base pairing principle.Yet, mispairing does arise in DNA, most frequently as a result of DNA polymerase errors or base damage. These mismatches need be rectified to avoid mutation. Sometimes, however, mispairing is actively induced to trigger mutagenesis. This happens in activated B-lymphocytes, where the targeted generation and processing of G.U mismatches contributes to somatic hypermutation and antibody diversification. Non-mutagenic mismatches arise in heteroduplex intermediates of homologous recombination, and their processing helps restrict homeologous recombination. Depending on the type of mismatch and the biological context of its occurrence, cells must apply appropriate strategies of repair to properly control mutagenesis. This review will illustrate conceptual and functional challenges of cellular mismatch correction on typical examples of mutagenic base-base mismatches. (Part of a Multi-author Review).

Molecular cloning and expression of human cDNAs encoding a novel DNA ligase IV and DNA ligase III, an enzyme active in DNA repair and recombination.

Three distinct DNA ligases, I to III, have been found previously in mammalian cells, but a cloned cDNA has been identified only for DNA ligase I, an essential enzyme active in DNA replication. A short peptide sequence conserved close to the C terminus of all known eukaryotic DNA ligases was used to search for additional homologous sequences in human cDNA libraries. Two different incomplete cDNA clones that showed partial homology to the conserved peptide were identified. Full-length cDNAs were obtained and expressed by in vitro transcription and translation. The 103-kDa product of one cDNA clone formed a characteristic complex with the XRCC1 DNA repair protein and was identical with the previously described DNA ligase III. DNA ligase III appears closely related to the smaller DNA ligase II. The 96-kDa in vitro translation product of the second cDNA clone was also shown to be an ATP-dependent DNA ligase. A fourth DNA ligase (DNA ligase IV) has been purified from human cells and shown to be identical to the 96-kDa DNA ligase by unique agreement between mass spectrometry data on tryptic peptides from the purified enzyme and the predicted open reading frame of the cloned cDNA. The amino acid sequences of DNA ligases III and IV share a related active-site motif and several short regions of homology with DNA ligase I, other DNA ligases, and RNA capping enzymes. DNA ligases III and IV are encoded by distinct genes located on human chromosomes 17q11.2-12 and 13q33-34, respectively.

Thymine DNA glycosylase.

More than 50% of colon cancer-associated mutations in the p53 tumor suppressor gene are C-->T transitions. The majority of them locate in CpG dinucleotides and are thought to have arisen through spontaneous hydrolytic deamination of 5-methylcytosine. This deamination process gives rise to G.T mispairs that need to be repaired to G.C in order to avoid C-->T mutation. Similarly, deamination of cytosine generates G.U mispairs that also produce C-->T transitions if not repaired. Restoration of both G.T and G.U mismatches was shown to be mediated by a short-patch excision repair pathway, and one principal player implicated in this process may be thymine DNA glycosylase (TDG). Human TDG was discovered as an enzyme that has the potential to specifically remove thymine and uracil bases mispaired with guanine through hydrolysis of their N-glycosidic bond, thereby generating abasic sites in DNA and initiating a base excision repair reaction. The same protein was later found to interact physically and functionally with the retinoid receptors RAR and RXR, and this implicated an unexpected function of TDG in nuclear receptor-mediated transcriptional activation of gene expression. The objective of this chapter is to put together the results of different lines of experimentation that have explored the thymine DNA glycosylase since its discovery and to critically evaluate their implications for possible physiological roles of this enzyme.

Marker effects of G to C transversions on intragenic recombination and mismatch repair in Schizosaccharomyces pombe.

G to C transversion mutations show very strong allele-specific marker effects on the frequency of wild-type recombinants in intragenic two-factor crosses. Here we present a detailed study of the marker effect of one representative, the ade6-M387 mutation of Schizosaccharomyces pombe. Crosses of M387 with other mutations at varying distance reveal highly increased prototroph frequencies in comparison with the C to T transition mutation ade6-51 (control without any known marker effect) located four nucleotides from M387. The marker effect of M387 is strongest (> 40-fold) for crosses with mutations less than 15 nucleotides from M387. It decreases to an intermediate level (5-10-fold) in crosses with mutations located 25-150 base pairs from M387/51 and is very low in crosses with mutations beyond 200 base pairs. On the basis of these results and the quantitation of the low efficiency of C/C mismatch repair presented in the accompanying publication we propose the existence of at least two different types of mechanisms for base mismatch repair in fission yeast. The major system is suggested to recognize all base mismatches except C/C with high efficiency and to generate long excision tracts (approximately 100 nucleotides unidirectionally). The minor system is proposed to recognize all base mismatches including C/C with low and variable efficiency and to have short excision tracts (approximately 10 nucleotides unidirectionally). We estimate from the M387 marker effect that the minor system accounts for approximately 1-8% repair of non-C/C mismatches (depending on the nature of the mutation) in fission yeast meiosis.

Meiotic mismatch repair quantified on the basis of segregation patterns in Schizosaccharomyces pombe.

Hybrid DNA with mismatched base pairs is a central intermediate of meiotic recombination. Mismatch repair leads either to restoration or conversion, while failure of repair results in postmeiotic segregation (PMS). The behavior of three G to C transversions in one-factor crosses with the wild-type alleles is studied in Schizosaccharomyces pombe. They lead to C/C and G/G mismatches and are compared with closely linked mutations yielding other mismatches. A method is presented for the detection of PMS in random spores. The procedure yields accurate PMS frequencies as shown by comparison with tetrad data. A scheme is presented for the calculation of the frequency of hybrid DNA formation and the efficiency of mismatch repair. The efficiency of C/C repair in S. pombe is calculated to be about 70%. Other mismatches are repaired with close to 100% efficiency. These results are compared with data published on mutations in Saccharomyces cerevisiae and Ascobolus immersus. This study forms the basis for the detailed analysis of the marker effects caused by G to C transversions in two-factor crosses.

Mismatch repair in Schizosaccharomyces pombe requires the mutL homologous gene pms1: molecular cloning and functional analysis.

Homologues of the bacterial mutS and mutL genes involved in DNA mismatch repair have been found in organisms from bacteria to humans. Here, we describe the structure and function of a newly identified Schizosaccharomyces pombe that encodes a predicted amino acid sequence of 794 residues with a high degree of homology to MutL related proteins. On the basis of its closer relationship to the eukaryotic "PMS" genes than to the "MLH" genes, we have designated the S. pombe homologue pms1. Disruption of the pms1 gene causes a significant increase of spontaneous mutagenesis as documented by reversion rate measurements. Tetrad analyses of crosses homozygous for the pms1 mutation reveal a reduction of spore viability from > 92% to 80% associated with a low proportion (approximately 50%) of meioses producing four viable spores and a significant, allele-dependent increase of the level of post-meiotic segregation of genetic marker allele pairs. The mutant phenotypes are consistent with a general function of pms1 in correction of mismatched base pairs arising as a consequence of DNA polymerase errors during DNA synthesis, or of hybrid DNA formation between homologous but not perfectly complementary DNA strands during meiotic recombination.

The mutator gene swi8 effects specific mutations in the mating-type region of Schizosaccharomyces pombe.

The swi8+ gene of Schizosaccharomyces pombe appears to be involved in the termination step of copy synthesis during mating-type (MT) switching. Mutations in swi8 confer a general mutator phenotype and, in particular, generate specific mutations in the MT region. Sequencing of the MT cassettes of the h90 swi8-137 mutant revealed three altered sites. One is situated at the switching (smt) signal adjacent to the H1 homology box of the expression locus mat1:1. It reduces the rate of MT switching. The alteration at the smt signal arose frequently in other h90 swi8 strains and is probably caused by gene conversion in which the sequence adjacent to the H1 box of mat2:2 is used as template. This change might be generated during the process of MT switching when hybrid DNA formation is anomalously extended into the more heterologous region flanking the H1 homology box. In addition to the gene conversion at mat1:1, two mutations were found in the H3 homology boxes of the silent cassettes mat2:2 and mat3:3.

Surgical treatment of Zenker's diverticulum: transcutaneous diverticulectomy versus microendoscopic myotomy of the cricopharyngeal muscle with CO2 laser.

In a retrospective study, we analyzed 97 patients who were treated by either transcutaneous diverticulectomy (n = 66) or microendoscopic myotomy of the cricopharyngeal muscle with CO(2) laser (n = 31). Two (6.4%) of 31 patients in the microendoscopic myotomy group had complications, compared with 10 (15%) of 66 patients in the diverticulectomy group. In addition, the complications observed in the microendoscopic myotomy group were less severe than those observed in the transcutaneous diverticulectomy group. The average length of hospitalization was shorter in the microendoscopic myotomy group than in the diverticulectomy group (8 days versus 11.4 days). We conclude that microendoscopic CO(2)-laser myotomy is a less invasive, more precise, and safer procedure, which results in a shortened period of hospitalization and complete relief of symptoms in the vast majority of cases.

Advantages and dangers of erbium laser application in stapedotomy.

Among different types of lasers, the erbium laser exhibits particularly favourable characteristics for ear surgery. Experiments with application of erbium laser pulses to the isolated stapes connected to an inner ear model confirmed that there was virtually no thermal effect to the inner ear liquid and that the border damage zone on the stapes footplate perforation did not exceed 5-10 microm. Erbium laser pulses, however, produce pressure waves due to the explosive ablation of tissue. Pulses of 10 to 17 J/cm2 producing pressure waves between 140 and 160 dB appear to be a limit for clinical application. With these criteria, an in-house built erbium YAG laser with a fiberoptic delivery device was used in 15 patients for stapedotomy. A special microhandpiece, where a zirconium fluoride fiber was connected to a quartz tip, was developed. In addition, three patients had stapedotomy with a commercially available Zeiss (Opmi TwinER) microscope equipped with a micromanipulator-operated erbium laser beam. One year after surgery, the air-bone gap was closed in all patients to within 20 dB between 0.5 and 3 kHz with only minor permanent bone conduction threshold losses (< 20 dB). However, we observed an immediate postoperative middle and high frequency loss of up to 75 dB on bone conduction threshold measurements 2 h after surgery, suggesting an acoustic traumatization by the erbium laser. This threshold shift recovered close to preoperative values within 6 h. These observations prompted us to discontinue the clinical use of erbium laser for stapedotomy until the problem of temporary acoustic traumatization is resolved.

Endonasal and transcanalicular Er:YAG laser dacryocystorhinostomy.

In the last 10 years different types of lasers were used for dacryocystorhinostomy (DCR). Between April 1998 and August 1999, a fibreoptic erbium laser DCR was performed on 12 patients. Eight cases were for a presaccal stenosis and 4 cases for a postsaccal stenosis. An erbium laser with a specially designed handpiece was used endonasaly and transcanaliculary. Preoperative epiphora was present in all patients. Double bicanalicular nasal silicone tubes were placed during surgery in all cases. The 3 cases of postoperative failure included 2 cases of presaccal stenosis and 1 case of the postsaccal group; failure manifested with recurrent epiphora/dacryocystitis; the onset of symptom recurrence varied from 9 weeks to 11 weeks postoperatively. Laser-assisted DCR includes the avoidance of a cutaneous incision, excessive tissue injury, the advantage of short operation time and precision. Suitable indications for the erbium laser are stenoses in the canaliculi, in the sac, but also for bone lacrimal bone cutting.

Normal colorectal mucosa exhibits sex- and segment-specific susceptibility to DNA methylation at the hMLH1 and MGMT promoters.

Silencing of gene expression by aberrant cytosine methylation is a prominent feature of human tumors, including colorectal cancers. Epigenetic changes of this type play undisputed roles in cell transformation when they involve genes that safeguard genome stability, and they can also be detected in precancerous lesions and seemingly normal peritumoral tissues. We explored physiological conditions associated with aberrant promoter methylation involving two DNA-repair genes in normal colorectal mucosa. Samples of cecal, transverse colon, sigmoid and rectal mucosa collected from 100 healthy individuals undergoing screening colonoscopy were analysed for hMLH1 and MGMT promoter methylation with a quantitative PCR assay. Positivity in at least one colon segment was common in both sexes, with methylation involving 0.1-18.8% of the alleles (median=0.49%). Samples from males showed no consistent patterns for either promoter, but there were striking age- and colon segment-specific differences in the female subgroup. Here, the prevalence of hMLH1 and MGMT methylation increased significantly with age, particularly in the right colon, where there was also an age-related increase in the percentage of alleles showing hMLH1 methylation. Concomitant methylation of both promoters was also significantly more common in the right colon of women. These findings paralleled immunohistochemical patterns of hMLH1 and MGMT protein loss in an independent series of 231 colorectal cancers and were consistent with current epigenetic profiles of colorectal cancer subsets. They suggest the intriguing possibility that the epigenetic signatures of cancers may have early-stage, normal-tissue counterparts that reflect potentially important aspects of the initial carcinogenetic process.

Preferential strand transfer and hybrid DNA formation at the recombination hotspot ade6-M26 of Schizosaccharomyces pombe.

The ade6-M26 mutation of Schizosaccharomyces pombe stimulates intragenic and intergenic meiotic recombination. M26 is a single base pair change creating a specific heptanucleotide sequence that is crucial for recombination hotspot activity. This sequence is recognized by proteins that may facilitate rate-limiting steps of recombination at the ade6 locus. To start the elucidation of the intermediate DNA structures formed during M26 recombination, we have analyzed the aberrant segregation patterns of two G to C transversion mutations flanking the heptanucleotide sequence in crosses homozygous for M26. At both sites the level of post-meiotic segregation is typical for G to C transversion mutations in S. pombe in general. Quantitative treatment of the data provides strong evidence for heteroduplex DNA being the major recombination intermediate at the M26 site. We can now exclude a double-strand gap repair mechanism to account for gene conversion across the recombination hotspot. Furthermore, the vast majority (> 95%) of the heteroduplexes covering either of the G to C transversion sites are produced by transfer of the transcribed DNA strand. These results are consistent with ade6-M26 creating an initiation site for gene conversion by the introduction of a single-strand or a double-strand break in its vicinity, followed by transfer of the transcribed DNA strands for heteroduplex DNA formation.

Recognition of DNA alterations by the mismatch repair system.

Misincorporation of non-complementary bases by DNA polymerases is a major source of the occurrence of promutagenic base-pairing errors during DNA replication or repair. Base-base mismatches or loops of extra bases can arise which, if left unrepaired, will generate point or frameshift mutations respectively. To counteract this mutagenic potential, organisms have developed a number of elaborate surveillance and repair strategies which co-operate to maintain the integrity of their genomes. An important replication-associated correction function is provided by the post-replicative mismatch repair system. This system is highly conserved among species and appears to be the major pathway for strand-specific elimination of base-base mispairs and short insertion/deletion loops (IDLs), not only during DNA replication, but also in intermediates of homologous recombination. The efficiency of repair of different base-pairing errors in the DNA varies, and appears to depend on multiple factors, such as the physical structure of the mismatch and sequence context effects. These structural aspects of mismatch repair are poorly understood. In contrast, remarkable progress in understanding the biochemical role of error-recognition proteins has been made in the recent past. In eukaryotes, two heterodimers consisting of MutS-homologous proteins have been shown to share the function of mismatch recognition in vivo and in vitro. A first MutS homologue, MSH2, is present in both heterodimers, and the specificity for mismatch recognition is dictated by its association with either of two other MutS homologues: MSH6 for recognition of base-base mismatches and small IDLs, or MSH3 for recognition of IDLs only. Mismatch repair deficiency in cells can arise through mutation, transcriptional silencing or as a result of imbalanced expression of these genes.

Identification of two mismatch-binding activities in protein extracts of Schizosaccharomyces pombe.

We have performed band-shift assays to identify mismatch-binding proteins in cell extracts of Schizosaccharomyces pombe. By testing heteroduplex DNA containing either a T/G or a C/C mismatch, two distinct band shifts were produced in the gels. A low mobility complex was observed with the T/G substrate, while a high mobility complex was present with C/C. Further analysis of the mismatch-binding specificities revealed that the T/G binding activity also binds to T/C, C/T, T/T, T/-, A/-, C/-, G/-, G/G, A/A, A/C, A/G, G/T, G/A, and C/A substrates with varying efficiencies, but not binds to C/C. The C/C binding activity efficiently binds to C/C, T/C, C/T, C/A, A/C, C/-, and weakly also to T/T, while all other mispairs are not recognized. Protein extracts of a mutant strain, defective in the mutS homologue swi4, displayed both mismatch-binding activities. Thus, swi4 does not encode for either one of the mismatch-binding proteins.

Saccharomyces cerevisiae LIF1: a function involved in DNA double-strand break repair related to mammalian XRCC4.

Saccharomyces cerevisiae DNA ligase IV (LIG4) has been shown previously to be involved in non-homologous DNA end joining and meiosis. The homologous mammalian DNA ligase IV interacts with XRCC4, a protein implicated in V(D)J recombination and double-strand break repair. Here, we report the discovery of LIF1, a S.cerevisiae protein that strongly interacts with the C-terminal BRCT domain of yeast LIG4. LIG4 and LIF1 apparently occur as a heterodimer in vivo. LIF1 shares limited sequence homology with mammalian XRCC4. Disruption of the LIF1 gene abolishes the capacity of cells to recircularize transformed linearized plasmids correctly by non-homologous DNA end joining. Loss of LIF1 is also associated with conditional hypersensitivity of cells to ionizing irradiation and with reduced sporulation efficiency. Thus, with respect to their phenotype, lif1 strains are similar to the previously described lig4 mutants. One function of LIF1 is the stabilization of the LIG4 enzyme. The finding of a XRCC4 homologue in S.cerevisiae now allows for mutational analyses of structure-function relationships in XRCC4-like proteins to define their role in DNA double-strand break repair.

A newly identified DNA ligase of Saccharomyces cerevisiae involved in RAD52-independent repair of DNA double-strand breaks.

Eukaryotic DNA ligases are ATP-dependent DNA strand-joining enzymes that participate in DNA replication, repair, and recombination. Whereas mammalian cells contain several different DNA ligases, encoded by at least three distinct genes, only one DNA ligase has been detected previously in either budding yeast or fission yeast. Here, we describe a newly identified nonessential Saccharomyces cerevisiae gene that encodes a DNA ligase distinct from the CDC9 gene product. This DNA ligase shares significant amino acid sequence homology with human DNA ligase IV; accordingly, we designate the yeast gene LIG4. Recombinant LIG4 protein forms a covalent enzyme-AMP complex and can join a DNA single-strand break in a DNA/RNA hybrid duplex, the preferred substrate in vitro. Disruption of the LIG4 gene causes only marginally increased cellular sensitivity to several DNA damaging agents, and does not further sensitize cdc9 or rad52 mutant cells. In contrast, lig4 mutant cells have a 1000-fold reduced capacity for correct recircularization of linearized plasmids by illegitimate end-joining after transformation. Moreover, homozygous lig4 mutant diploids sporulate less efficiently than isogenic wild-type cells, and show retarded progression through meiotic prophase I. Spore viability is normal, but lig4 mutants appear to produce a higher proportion of tetrads with only three viable spores. The mutant phenotypes are consistent with functions of LIG4 in an illegitimate DNA end-joining pathway and ensuring efficient meiosis.

Separating substrate recognition from base hydrolysis in human thymine DNA glycosylase by mutational analysis.

Human thymine DNA glycosylase (TDG) was discovered as an enzyme that can initiate base excision repair at sites of 5-methylcytosine- or cytosine deamination in DNA by its ability to release thymine or uracil from G.T and G.U mismatches. Crystal structure analysis of an Escherichia coli homologue identified conserved amino acid residues that are critical for its substrate recognition/interaction and base hydrolysis functions. Guided by this revelation, we performed a mutational study of structure function relationships with the human TDG. Substitution of the postulated catalytic site asparagine with alanine (N140A) resulted in an enzyme that bound mismatched substrates but was unable to catalyze base removal. Mutation of Met-269 in a motif with a postulated role in protein-substrate interaction selectively inactivated stable binding of the enzyme to mismatched substrates but not so its glycosylase activity. These results establish that the structure function model postulated for the E. coli enzyme is largely applicable to the human TDG. We further provide evidence for G.U being the preferred substrate of TDG, not only at the mismatch recognition step of the reaction but also in base hydrolysis, and for the importance of stable complementary strand interactions by TDG to compensate for its comparably poor hydrolytic potential.

Repair and processing events at DNA ends.

Cell nuclei contain several abundant enzymes that bind rapidly and avidly to exposed termini of DNA. The properties and physiological roles of such factors are described; they include poly (ADP-ribose) polymerase, DNA-dependent protein kinase, several DNA ligases and excision-repair enzymes. Telomeres normally seem shielded from these activities by telomere-binding proteins. If incomplete protection of telomeres occurred, the functions of the DNA end-specific enzymes would be relevant for processing of telomeres. This could include alternative pathways for telomere propagation in telomerase-negative cells.