MmeI: a minimal Type II restriction-modification system that only modifies one DNA strand for host protection

MmeI is an unusual Type II restriction enzyme that is useful for generating long sequence tags. We have cloned the MmeI restriction-modification (R-M) system and found it to consist of a single protein having both endonuclease and DNA methyltransferase activities. The protein comprises an amino-terminal endonuclease domain, a central DNA methyltransferase domain and C-terminal DNA recognition domain. The endonuclease cuts the two DNA strands at one site simultaneously, with enzyme bound at two sites interacting to accomplish scission. Cleavage occurs more rapidly than methyl transfer on unmodified DNA. MmeI modifies only the adenine in the top strand, 5′-TCCRAC-3′. MmeI endonuclease activity is blocked by this top strand adenine methylation and is unaffected by methylation of the adenine in the complementary strand, 5′-GTYGGA-3′. There is no additional DNA modification associated with the MmeI R-M system, as is required for previously characterized Type IIG R-M systems. The MmeI R-M system thus uses modification on only one of the two DNA strands for host protection. The MmeI architecture represents a minimal approach to assembling a restriction-modification system wherein a single DNA recognition domain targets both the endonuclease and DNA methyltransferase activities.     

Characterization of the Type III restriction endonuclease PstII from Providencia stuartii

A new Type III restriction endonuclease designated PstII has been purified from Providencia stuartii. PstII recognizes the hexanucleotide sequence 5′-CTGATG(N)_25-26/27-28-3′. Endonuclease activity requires a substrate with two copies of the recognition site in head-to-head repeat and is dependent on a low level of ATP hydrolysis (~40 ATP/site/min). Cleavage occurs at just one of the two sites and results in a staggered cut 25–26 nt downstream of the top strand sequence to generate a two base 5′-protruding end. Methylation of the site occurs on one strand only at the first adenine of 5′-CATCAG-3′. Therefore, PstII has characteristic Type III restriction enzyme activity as exemplified by EcoPI or EcoP15I. Moreover, sequence asymmetry of the PstII recognition site in the T7 genome acts as an historical imprint of Type III restriction activity in vivo. In contrast to other Type I and III enzymes, PstII has a more relaxed nucleotide specificity and can cut DNA with GTP and CTP (but not UTP). We also demonstrate that PstII and EcoP15I cannot interact and cleave a DNA substrate suggesting that Type III enzymes must make specific protein–protein contacts to activate endonuclease activity.     

Excision of 8-oxoguanine within clustered damage by the yeast OGG1 protein

Clustered damages are formed in DNA by ionising radiation and radiomimetic anticancer agents and are thought to be biologically severe. 7,8-dihydro-8-oxoguanine (8-oxoG), a major DNA damage resulting from oxidative attack, is highly mutagenic leading to a high level of G·C→T·A transversions if not previously excised by OGG1 DNA glycosylase/AP lyase proteins in eukaryotes. However, 8-oxoG within clustered DNA damage may present a challenge to the repair machinery of the cell. The ability of yeast OGG1 to excise 8-oxoG was determined when another type of damage [dihydrothymine, uracil, 8-oxoG, abasic (AP) site or various types of single-strand breaks (SSBs)] is present on the complementary strand 1, 3 or 5 bases 5′ or 3′ opposite to 8-oxoG. Base damages have little or no influence on the excision of 8-oxoG by yeast OGG1 (yOGG1) whereas an AP site has a strong inhibitory effect. Various types of SSBs, obtained using either oligonucleotides with 3′- and 5′-phosphate termini around a gap or through conversion of an AP site with either endonuclease III or human AP endonuclease 1, strongly inhibit excision of 8-oxoG by yOGG1. Therefore, this large inhibitory effect of an AP site or a SSB may minimise the probability of formation of a double-strand break in the processing of 8-oxoG within clustered damages.     

A single engineered point mutation in the adenine glycosylase MutY confers bifunctional glycosylase/AP lyase activity

The E. coli adenine glycosylase MutY is a member of the base excision repair (BER) superfamily of DNA repair enzymes. MutY plays an important role in preventing mutations caused by 7, 8-dihydro-8-oxo-2'-deoxyguanosine (OG) by removing adenine from OG:A base pairs. Some enzymes of the BER superfamily catalyze a strand scission even concomitant with base removal. These bifunctional glycosylase/AP lyases bear a conserved lysine group in the active site region, which is believed to be the species performing the initial nucleophilic attack at C1' in the catalysis of base removal. Monofunctional glycosylases such as MutY are thought to perform this C1' nucleophilic displacement by a base-activated water molecule, and, indeed, the conservation of amine functionality positioning has not been observed in protein sequence alignments. Bifunctional glycosylase/AP lyase activity was successfully engineered into MutY by replacing serine 120 with lysine. MutY S120K is capable of catalyzing DNA strand scission at a rate equivalent to that of adenine excision for both G:A and OG:A mispair substrates. The extent of DNA backbone cleavage is independent of treating reaction aliquots with 0.1 M NaOH. Importantly, the replacement of the serine with lysine results in a catalytic rate that is compromised by at least 20-fold. The reduced efficiency in the glycosylase activity is also reflected in a reduced ability of S120K MutY to prevent DNA mutations in vivo. These results illustrate that the mechanisms of action of the two classes of these enzymes are quite similar, such that a single amino acid change is sufficient, in the case of MutY, to convert a monofunctional glycosylase to a bifunctional glycosylase/AP lyase.     

Novel protein fold discovered in the PabI family of restriction enzymes

Although structures of many DNA-binding proteins have been solved, they fall into a limited number of folds. Here, we describe an approach that led to the finding of a novel DNA-binding fold. Based on the behavior of Type II restriction–modification gene complexes as mobile elements, our earlier work identified a restriction enzyme, R.PabI, and its cognate modification enzyme in Pyrococcus abyssi through comparison of closely related genomes. While the modification methyltransferase was easily recognized, R.PabI was predicted to have a novel 3D structure. We expressed cytotoxic R.PabI in a wheat-germ-based cell-free translation system and determined its crystal structure. R.PabI turned out to adopt a novel protein fold. Homodimeric R.PabI has a curved anti-parallel β-sheet that forms a ‘half pipe’. Mutational and in silico DNA-binding analyses have assigned it as the double-strand DNA-binding site. Unlike most restriction enzymes analyzed, R.PabI is able to cleave DNA in the absence of Mg²⁺. These results demonstrate the value of genome comparison and the wheat-germ-based system in finding a novel DNA-binding motif in mobile DNases and, in general, a novel protein fold in horizontally transferred genes.     

Mechanistic decoupling of exonuclease III multifunctionality into AP endonuclease and exonuclease activities at the single-residue level

Bacterial exonuclease III (ExoIII) is a multifunctional enzyme that uses a single active site to perform two conspicuous activities: (i) apurinic/apyrimidinic (AP)-endonuclease and (ii) 3′→5′ exonuclease activities. The AP endonuclease activity results in AP site incision, while the exonuclease activity results in the continuous excision of 3′ terminal nucleobases to generate a partial duplex for recruiting the downstream DNA polymerase during the base excision repair process (BER). The key determinants of functional selection between the two activities are poorly understood. Here, we use a series of mutational analyses and single-molecule imaging to unravel the pivotal rules governing these endo- and exonuclease activities at the single amino acid level. An aromatic residue, either W212 or F213, recognizes AP sites to allow for the AP endonuclease activity, and the F213 residue also participates in the stabilization of the melted state of the 3′ terminal nucleobases, leading to the catalytically competent state that activates the 3′→5′ exonuclease activity. During exonucleolytic cleavage, the DNA substrate must be maintained as a B-form helix through a series of phosphate-stabilizing residues (R90, Y109, K121 and N153). Our work decouples the AP endonuclease and exonuclease activities of ExoIII and provides insights into how this multifunctional enzyme controls each function at the amino acid level.     

Hyperthermophilic DNA Methyltransferase M.PabI from the Archaeon Pyrococcus abyssi

Genome sequence comparisons among multiple species of Pyrococcus, a hyperthermophilic archaeon, revealed a linkage between a putative restriction-modification gene complex and several large genome polymorphisms/rearrangements. From a region apparently inserted into the Pyrococcus abyssi genome, a hyperthermoresistant restriction enzyme [PabI; 5′-(GTA/C)] with a novel structure was discovered. In the present work, the neighboring methyltransferase homologue, M.PabI, was characterized. Its N-terminal half showed high similarities to the M subunit of type I systems and a modification enzyme of an atypical type II system, M.AhdI, while its C-terminal half showed high similarity to the S subunit of type I systems. M.PabI expressed within Escherichia coli protected PabI sites from RsaI, a PabI isoschizomer. M.PabI, purified following overexpression, was shown to generate 5′-GTm6AC, which provides protection against PabI digestion. M.PabI was found to be highly thermophilic; it showed methylation at 95°C and retained at least half the activity after 9 min at 95°C. This hyperthermophilicity allowed us to obtain activation energy and other thermodynamic parameters for the first time for any DNA methyltransferases. We also determined the kinetic parameters of k_cat, K_{m, DNA}, and K_{m, AdoMet}. The activity of M.PabI was optimal at a slightly acidic pH and at an NaCl concentration of 200 to 500 mM and was inhibited by Zn²⁺ but not by Mg²⁺, Ca²⁺, or Mn²⁺. These and previous results suggest that this unique methyltransferase and PabI constitute a type II restriction-modification gene complex that inserted into the P. abyssi genome relatively recently. As the most thermophilic of all the characterized DNA methyltransferases, M.PabI may help in the analysis of DNA methylation and its application to DNA engineering.     

Base excision repair intermediates are mutagenic in mammalian cells

Base excision repair (BER) is the main pathway for repair of DNA damage in mammalian cells. This pathway leads to the formation of DNA repair intermediates which, if still unsolved, cause cell lethality and mutagenesis. To characterize mutations induced by BER intermediates in mammalian cells, an SV-40 derived shuttle vector was constructed carrying a site-specific lesion within the recognition sequence of a restriction endonuclease. The mutation spectra of abasic (AP) sites, 5′-deoxyribose-5-phosphate (5′dRp) and 3′-[2,3-didehydro-2,3-dideoxy-ribose] (3′ddR5p) single-strand breaks (ssb) in mammalian cells was analysed by RFLP/PCR and mutation frequency was estimated by quantitative PCR. Point mutations were the predominant events occurring at all BER intermediates. The AP site-induced mutation spectrum supports evidence for the ‘A-rule’ and is also consistent with the use of the 5′ neighbouring base to instruct nucleotide incorporation (5′-rule). Preferential adenine insertion was also observed after in vivo replication of 5′dRp or 3′ddR5p ssb. We provide original evidence that not only the abasic site but also its derivatives ‘faceless’ BER intermediates are mutagenic, with a similar mutation frequency, in mammalian cells. Our findings support the hypothesis that unattended BER intermediates could be a constant threat for genome integrity as well as a spontaneous source of mutations.     

Specificity of the dRP/AP lyase of Ku promotes nonhomologous end joining (NHEJ) fidelity at damaged ends

Nonhomologous end joining (NHEJ) is essential for efficient repair of chromosome breaks. However, the NHEJ ligation step is often obstructed by break-associated nucleotide damage, including base loss (abasic site or 5'-dRP/AP sites). Ku, a 5'-dRP/AP lyase, can excise such damage at ends in preparation for the ligation step. We show here that this activity is greatest if the abasic site is within a short 5' overhang, when this activity is necessary and sufficient to prepare such termini for ligation. In contrast, Ku is less active near 3' strand termini, where excision would leave a ligation-blocking α,β-unsaturated aldehyde. The Ku AP lyase activity is also strongly suppressed by as little as two paired bases 5' of the abasic site. Importantly, in vitro end joining experiments show that abasic sites significantly embedded in double-stranded DNA do not block the NHEJ ligation step. Suppression of the excision activity of Ku in this context therefore is not essential for ligation and further helps NHEJ retain terminal sequence in junctions. We show that the DNA between the 5' terminus and the abasic site can also be retained in junctions formed by cellular NHEJ, indicating that these sites are at least partly resistant to other abasic site-cleaving activities as well. High levels of the 5'-dRP/AP lyase activity of Ku are thus restricted to substrates where excision of an abasic site is required for ligation, a degree of specificity that promotes more accurate joining.     

AP lyase activity of the human ribosomal protein uS3: The DNA cleavage sequence specificity and the location of the enzyme active center

The human protein uS3, a component of the small ribosomal subunit, has a long-known extra-ribosomal activity as an enzyme of base excision DNA repair displayed in its ability to cleave DNA at abasic (AP) sites. It has been found that the efficacy of DNA cleavage by uS3 in vitro depends on the DNA sequence. To clarify the issue on the sequence specificity of uS3 as an AP lyase in general, we applied a combinatorial approach based on the use of a model single-stranded circular DNA with an AP site flanked with random trinucleotides at both sides. The cleavage of this DNA by uS3 under conditions when only its minor portion undergoes the reaction resulted in the formation of the linear DNA with random triplets at the 5′ and 3′ termini. NGS sequencing of the DNA library derived from this DNA allowed identifying the contexts within which uS3 cleaves DNA the most and the least effectively. Given that the AP lyase reaction occurs via the formation of a covalent intermediate (Schiff base), we determined the region comprising the active center of the uS3 protein. By digesting of uS3 cross-linked to a radiolabeled AP site-containing model DNA with specific proteolytic agents followed by analysis of the resulting modified oligopeptides, the cross-link was mapped to the region 155–192 (likely, to R173/R178). Thus, our results clarified two previously unstudied features of the uS3 AP lyase activity, one related to the recognition of sequences in DNA surrounding the AP site, and the other to the protein region directly contacting this site.     

Thymine-methyl/pi interaction implicated in the sequence-dependent deformability of DNA

The crystal structures of deoxy-oligonucleotides were retrieved from the Nucleic Acid Database and analyzed with the use of our program CHPI. The structure of 5′-ApTpApT-3′ has been shown to be stabilized by the 5-methyl group in the thymidine moiety that favorably interacts with the adenine π-ring preceding it. H2′ of the deoxyribose in adenine also interacts with the thymine ring next to it. Since a 5′-ApT-3′ sequence is accompanied by another 5′-ApT-3′ in the complementary strand, the interaction is duplicated, thus forming a ‘twin A/T-Me interaction’. Coordinates of oligonucleotides with A-T rich sequences were retrieved and analyzed. In almost every case, the thymidine 5-methyl group favorably interacts with an adenine ring in the same strand. The structure of duplexes incorporating A-tracts was also analyzed. The 5-methyl group in the thymidine moiety has been found to interact favorably with the base π-ring before it. Since an A-tract is lined with an oligo-T sequence in the complementary strand, a successive N/T-Me stacking may contribute in making the A-tracts robust and straight. The possible involvement of the  N/T-Me and the twin  A/T-Me motif in the deformability of DNA has been suggested. The role of methyl groups in modified DNA has been discussed on a similar basis.     

Sorting the consequences of ionizing radiation: processing of 8-oxoguanine/abasic site lesions

Clustered DNA damage is a hallmark of ionizing radiation. These complex lesions, composed of any combination of oxidized bases, abasic sites, or strand breaks within one helical turn, create a tremendous challenge for the base excision repair system, which must process the damage without generating cytotoxic double strand breaks (DSB). Clustered lesions affect the DNA incision activity of DNA glycosylases and AP endonucleases. Different levels of enzyme inhibition are dependent on lesion identity, orientation and separation. Very little is known about the simultaneous action of both classes of enzymes, which may lead to the creation of DSB. We have developed a novel substrate system of double-labeled hairpin duplexes, which allows the simultaneous determination of enzyme incision and formation of DBS. We use this system to study the processing of four clustered 8-oxoguanine/abasic site lesions by purified mouse Ogg1, human Ape1 and mouse embryonic stem cell nuclear extracts. Ape1 activity is least affected by the presence of a nearby oxidized base. In contrast, an abasic site inhibits the glycosylase and lyase activities of Ogg1 in an orientation-dependent manner. The combined action of both enzymes leads to the preferential formation of DSB with 5'-overhang ends. Processing of clusters by nuclear extracts displayed similar patter of enzyme inhibition and the same preference for avoiding double strand breaks with 3'-overhang ends.     

AP endonucleases process 5-methylcytosine excision intermediates during active DNA demethylation in Arabidopsis

DNA methylation is a primary epigenetic modification regulating gene expression and chromatin structure in many eukaryotes. Plants have a unique DNA demethylation system in that 5-methylcytosine (5mC) is directly removed by DNA demethylases, such as DME/ROS1 family proteins, but little is known about the downstream events. During 5mC excision, DME produces 3′-phosphor-α, β-unsaturated aldehyde and 3′-phosphate by successive β- and δ-eliminations, respectively. The kinetic studies revealed that these 3′-blocking lesions persist for a significant amount of time and at least two different enzyme activities are required to immediately process them. We demonstrate that Arabidopsis AP endonucleases APE1L, APE2 and ARP have distinct functions to process such harmful lesions to allow nucleotide extension. DME expression is toxic to E. coli due to excessive 5mC excision, but expression of APE1L or ARP significantly reduces DME-induced cytotoxicity. Finally, we propose a model of base excision repair and DNA demethylation pathway unique to plants.     

Processing of model single-strand breaks in phi X-174 RF transfecting DNA by Escherichia coli

The inactivation efficiency and repair of single-strand breaks was investigated using model strand breaks created by endonucleolytic incision of damaged DNA. Phi X-174 duplex transfecting DNA containing either thymine glycols, urea residues, or abasic (AP) sites was incubated with AP endonucleases that produce breaks on the 3' side, the 5' side, or both sides of the lesion. For each lesion, incubation with Escherichia coli endonuclease III results in a single-strand break containing a 3' alpha, beta-unsaturated aldehyde (4-hydroxy-2-pentenal), while treatment of AP- or urea-containing DNA with E. coli endonuclease IV results in a single-strand break containing a 5' deoxyribose or a 5' deoxyribosylurea moiety, respectively. Incubation of lesion-containing DNA with both enzymes results in a base gap. Ligatable nicks containing 3' hydroxyl and 5' phosphate moieties were produced by subjecting undamaged DNA to DNase I. When the biological activity of these DNAs was assessed in wild-type cells, ligatable nicks were not lethal, but each of the other strand breaks tested was lethal, having inactivation efficiencies between 0.12 and 0.14. These inactivation efficiencies are similar to those of the base lesions from which the strand breaks were derived. In keeping with the current model of base excision repair, when phi X duplex DNA containing strand breaks with a blocked 3' terminus was transfected into an E. coli double mutant lacking the major 5' cellular AP endonucleases, a greater than twofold decrease in survival was observed. Moreover, when this DNA was treated with a 5' AP endonuclease prior to transfection, the survival returned to that of wild type. As expected, when DNA containing strand breaks with a 5' blocked terminus or DNA containing base gaps was transfected into the double mutant lacking 5' AP endonucleases, the survival was the same as in wild-type cells. The decreased survival of transfecting DNA containing thymine glycols, urea, or AP sites observed in appropriate base excision repair-defective mutants was also obviated if the DNA was incubated with the homologous enzyme prior to transfection. Thus, in every case, with both base lesions and single-strand breaks, the lesion was repaired in the cell by the enzyme that recognizes it in vitro. Furthermore, the repair step in the cell could be eliminated if the appropriate enzyme was added in vitro prior to transfection.(ABSTRACT TRUNCATED AT 400 WORDS)     

The Carboxy-Terminal Domain of ROS1 Is Essential for 5-Methylcytosine DNA Glycosylase Activity

Arabidopsis thaliana repressor of silencing 1 (ROS1) is a multi-domain bifunctional DNA glycosylase/lyase, which excises 5-methylcytosine (5mC) and 5-hydroxymethylcytosine (5hmC) as well as thymine and 5-hydroxymethyluracil (i.e., the deamination products of 5mC and 5hmC) when paired with a guanine, leaving an apyrimidinic (AP) site that is subsequently incised by the lyase activity. ROS1 is slow in base excision and fast in AP lyase activity, indicating that the recognition of pyrimidine modifications might be a rate-limiting step. In the C-terminal half, the enzyme harbors a helix–hairpin–helix DNA glycosylase domain followed by a unique C-terminal domain. We show that the isolated glycosylase domain is inactive for base excision but retains partial AP lyase activity. Addition of the C-terminal domain restores the base excision activity and increases the AP lyase activity as well. Furthermore, the two domains remain tightly associated and can be co-purified by chromatography. We suggest that the C-terminal domain of ROS1 is indispensable for the 5mC DNA glycosylase activity of ROS1.     

Futile short-patch DNA base excision repair of adenine:8-oxoguanine mispair

8-Oxo-7, 8-dihydrodeoxyguanosine (8-oxo-dG), one of the representative oxidative DNA lesions, frequently mispairs with the incoming dAMP during mammalian DNA replication. Mispaired dA is removed by post-replicative base excision repair (BER) initiated by adenine DNA glycosylase, MYH, creating an apurinic (AP) site. The subsequent mechanism ensuring a dC:8-oxo-dG pair, a substrate for 8-oxoguanine DNA glycosylase (OGG1), remains to be elucidated. At the nucleotide insertion step, none of the mammalian DNA polymerases examined exclusively inserted dC opposite 8-oxo-dG that was located in a gap. AP endonuclease 1, which possesses 3′→5′ exonuclease activity and potentially serves as a proofreader, did not discriminate dA from dC that was located opposite 8-oxo-dG. However, human DNA ligases I and III joined 3′-dA terminus much more efficiently than 3′-dC terminus when paired to 8-oxo-dG. In reconstituted short-patch BER, repair products contained only dA opposite 8-oxo-dG. These results indicate that human DNA ligases discriminate dC from dA and that MYH-initiated short-patch BER is futile and hence this BER must proceed to long-patch repair, even if it is initiated as short-patch repair, through strand displacement synthesis from the ligation-resistant dC terminus to generate the OGG1 substrate, dC:8-oxo-dG pair.     

Characterization of BseMII, a new type IV restriction-modification system, which recognizes the pentanucleotide sequence 5'-CTCAG(N)(10/8)/

We report the properties of the new BseMII restriction and modification enzymes from Bacillus stearothermophilus Isl 15-111, which recognize the 5'-CTCAG sequence, and the nucleotide sequence of the genes encoding them. The restriction endonuclease R.BseMII makes a staggered cut at the tenth base pair downstream of the recognition sequence on the upper strand, producing a two base 3'-protruding end. Magnesium ions and S:-adenosyl-L-methionine (AdoMet) are required for cleavage. S:-adenosylhomocysteine and sinefungin can replace AdoMet in the cleavage reaction. The BseMII methyltransferase modifies unique adenine residues in both strands of the target sequence 5'-CTCAG-3'/5'-CTGAG-3'. Monomeric R.BseMII in addition to endonucleolytic activity also possesses methyltransferase activity that modifies the A base only within the 5'-CTCAG strand of the target duplex. The deduced amino acid sequence of the restriction endonuclease contains conserved motifs of DNA N6-adenine methylases involved in S-adenosyl-L-methionine binding and catalysis. According to its structure and enzymatic properties, R.BseMII may be regarded as a representative of the type IV restriction endonucleases.     

Evidence that MutY is a monofunctional glycosylase capable of forming a covalent Schiff base intermediate with substrate DNA.

The Escherichia coli adenine glycosylase MutY is involved in the repair of 7,8-dihydro-8-oxo-2'-deoxyguanosine (OG):A and G:A mispairs in DNA. DNA strand cleavage via beta-elimination (beta-lyase) activity coupled with MutY's removal of misincorporated adenine bases was sought using both qualitative and quantitative methods. The qualitative assays demonstrate formation of a Schiff base intermediate which is characteristic of DNA glycosylases catalyzing a concomitant beta-lyase reaction. Borohydride reduction of the Schiff base results in the formation of a covalent DNA-MutY adduct which is easily detected in SDS-PAGE experiments. However, quantitative activity assays which monitor DNA strand scission accompanying base release suggest MutY behaves as a simple monofunctional glycosylase. Treatment with base effects DNA strand cleavage at apurinic/apyrimidinic (AP) sites arising via simple glycosylase activity. The amount of cleaved DNA in MutY reactions treated with base is much greater than that in non-base treated reactions, indicating that AP site generation by MutY is not associated with a concomitant beta-lyase step. As standards, identical assays were performed with a known monofunctional enzyme (uracil DNA glycosylase) and a known bifunctional glycosylase/lyase (FPG), the results of which were used in comparison with those of the MutY experiments. The apparent inconsistency between the data obtained for MutY by the qualitative and quantitative methods underscores the current debate surrounding the catalytic activity of this enzyme, and a detailed explanation of this controversy is proposed. The work presented here lays ground for the identification of specific active site residues responsible for the chemical mechanism of MutY enzyme catalysis.     

A new Schizosaccharomyces pombe base excision repair mutant,nth1, reveals overlapping pathways for repair of DNA base damage

Endonuclease III (Nth) enzyme from Escherichia coli is involved in base excision repair of oxidised pyrimidine residues in DNA. The Schizosaccharomyces pombe Nth1 protein is a sequence and functional homologue of E. coli Nth, possessing both DNA glycosylase and apurinic/apyrimidinic (AP) lyase activity. Here, we report the construction and characterization of the S. pombe nth1 mutant. The nth1 mutant exhibited no enhanced sensitivity to oxidising agents, UV or gamma-irradiation, but was hypersensitive to the alkylating agent methyl methanesulphonate (MMS). Analysis of base excision from DNA exposed to [3H]methyl-N-nitrosourea showed that the purified Nth1 enzyme did not remove alkylated bases such as 3-methyladenine and 7-methylguanine whereas methyl-formamidopyrimidine was excised efficiently. The repair of AP sites in S. pombe has previously been shown to be independent of Apn1-like AP endonuclease activity, and the main reason for the MMS sensitivity of nth1 cells appears to be their lack of AP lyase activity. The nth1 mutant also exhibited elevated frequencies of spontaneous mitotic intrachromosomal recombination, which is a phenotype shared by the MMS-hypersensitive DNA repair mutants rad2, rhp55 and NER repair mutants rad16, rhp14, rad13 and swi10. Epistasis analyses of nth1 and these DNA repair mutants suggest that several DNA damage repair/tolerance pathways participate in the processing of alkylation and spontaneous DNA damage in S. pombe.