Mutagenesis of bacteriophage T7 in vitro by incorporation of O6-methylguanine during DNA synthesis

A high-throughput screening method for evolving a demethylase enzyme with improved and new functionalities

AlkB is a DNA/RNA repair enzyme that removes base alkylations such as N¹-methyladenosine (m¹A) or N³-methylcytosine (m³C) from DNA and RNA. The AlkB enzyme has been used as a critical tool to facilitate tRNA sequencing and identification of mRNA modifications. As a tool, AlkB mutants with better reactivity and new functionalities are highly desired; however, previous identification of such AlkB mutants was based on the classical approach of targeted mutagenesis. Here, we introduce a high-throughput screening method to evaluate libraries of AlkB variants for demethylation activity on RNA and DNA substrates. This method is based on a fluorogenic RNA aptamer with an internal modified RNA/DNA residue which can block reverse transcription or introduce mutations leading to loss of fluorescence inherent in the cDNA product. Demethylation by an AlkB variant eliminates the blockage or mutation thereby restores the fluorescence signals. We applied our screening method to sites D135 and R210 in the Escherichia coli AlkB protein and identified a variant with improved activity beyond a previously known hyperactive mutant toward N¹-methylguanosine (m¹G) in RNA. We also applied our method to O6-methylguanosine (O6mG) modified DNA substrates and identified candidate AlkB variants with demethylating activity. Our study provides a high-throughput screening method for in vitro evolution of any demethylase enzyme.

The Role of Mismatch Repair in Glioblastoma Multiforme Treatment Response and Resistance

Mismatch repair (MMR) is a highly conserved DNA repair pathway that is critical for the maintenance of genomic integrity. This pathway targets base substitution and insertion-deletion mismatches, which primarily arise from replication errors that escape DNA polymerase proof-reading function. Here, the authors review key concepts in the molecular mechanisms of MMR in response to alkylation damage, approaches to detect MMR status in the clinic, and the clinical relevance of this pathway in glioblastoma multiforme treatment response and resistance.

MutT homologue 1 (MTH1) catalyzes the hydrolysis of mutagenic O6-methyl-dGTP

Nucleotides in the free pool are more susceptible to nonenzymatic methylation than those protected in the DNA double helix. Methylated nucleotides like O6-methyl-dGTP can be mutagenic and toxic if incorporated into DNA. Removal of methylated nucleotides from the nucleotide pool may therefore be important to maintain genome integrity. We show that MutT homologue 1 (MTH1) efficiently catalyzes the hydrolysis of O6-methyl-dGTP with a catalytic efficiency similar to that for 8-oxo-dGTP. O6-methyl-dGTP activity is exclusive to MTH1 among human NUDIX proteins and conserved through evolution but not found in bacterial MutT. We present a high resolution crystal structure of human and zebrafish MTH1 in complex with O6-methyl-dGMP. By microinjecting fertilized zebrafish eggs with O6-methyl-dGTP and inhibiting MTH1 we demonstrate that survival is dependent on active MTH1 in vivo. O6-methyl-dG levels are higher in DNA extracted from zebrafish embryos microinjected with O6-methyl-dGTP and inhibition of O6-methylguanine-DNA methyl transferase (MGMT) increases the toxicity of O6-methyl-dGTP demonstrating that O6-methyl-dGTP is incorporated into DNA. MTH1 deficiency sensitizes human cells to the alkylating agent Temozolomide, a sensitization that is more pronounced upon MGMT inhibition. These results expand the cellular MTH1 function and suggests MTH1 also is important for removal of methylated nucleotides from the nucleotide pool.

Modified Nucleotides for Discrimination between Cytosine and the Epigenetic Marker 5-Methylcytosine

5‐Methyl‐2′‐deoxycytosine, the most common epigenetic marker of DNA in eukaryotic cells, plays a key role in gene regulation and affects various cellular processes such as development and carcinogenesis. Therefore, the detection of 5mC can serve as an important biomarker for diagnostics. Here we describe that modified dGTP analogues as well as modified primers are able to sense the presence or absence of a single methylation of C, even though this modification does not interfere directly with Watson–Crick nucleobase pairing. By screening several modified nucleotide scaffolds, O⁶‐modified 2′‐deoxyguanosine analogues were identified as discriminating between C and 5mC. These modified nucleotides might find application in site‐specific 5mC detection, for example, through real‐time PCR approaches.

MGMT: a personal perspective

This review describes the history of studies on alkylation damage of mammalian genomes and its carcinogenic consequences that led to the discovery of a unique DNA repair protein, named MGMT. MGMT repairs O(6)-alkylguanine, a critical mutagenic lesion induced by alkylating agents. The follow-up studies in mammalian cells following the discovery of the ubiquitous repair protein in E. coli are summarized.

Sulfolobus solfataricus DNA Polymerase Dpo4 Is Partially Inhibited by “Wobble” Pairing between O6-Methylguanine and Cytosine, but Accurate Bypass Is Preferred

We examined the effect of a single O6-methylguanine (O6-MeG) template residue on catalysis by a model Y family polymerase, Dpo4 from Sulfolobus solfataricus. Mass spectral analysis of Dpo4-catalyzed extension products revealed that the enzyme accurately bypasses O6-MeG, with C being the major product (approximately 70%) and T or A being the minor species (approximately 20% or approximately 10%, respectively), consistent with steady-state kinetic parameters. Transient-state kinetic experiments revealed that kpol, the maximum forward rate constant describing polymerization, for dCTP incorporation opposite O6-MeG was approximately 6-fold slower than observed for unmodified G, and no measurable product was observed for dTTP incorporation in the pre-steady state. The lack of any structural information regarding how O6-MeG paired in a polymerase active site led us to perform x-ray crystallographic studies, which show that "wobble" pairing occurs between C and O6-MeG. A structure containing T opposite O6-MeG was solved, but much of the ribose and pyrimidine base density was disordered, in accordance with a much higher Km,dTTP that drives the difference in efficiency between C and T incorporation. The more stabilized C:O6-MeG pairing reinforces the importance of hydrogen bonding with respect to nucleotide selection within a geometrically tolerant polymerase active site.

T7 single strand DNA binding protein but not T7 helicase is required for DNA double strand break repair

An in vitro system based on Escherichia coli infected with bacteriophage T7 was used to test for involvement of host and phage recombination proteins in the repair of double strand breaks in the T7 genome. Double strand breaks were placed in a unique XhoI site located approximately 17% from the left end of the T7 genome. In one assay, repair of these breaks was followed by packaging DNA recovered from repair reactions and determining the yield of infective phage. In a second assay, the product of the reactions was visualized after electrophoresis to estimate the extent to which the double strand breaks had been closed. Earlier work demonstrated that in this system double strand break repair takes place via incorporation of a patch of DNA into a gap formed at the break site. In the present study, it was found that extracts prepared from uninfected E. coli were unable to repair broken T7 genomes in this in vitro system, thus implying that phage rather than host enzymes are the primary participants in the predominant repair mechanism. Extracts prepared from an E. coli recA mutant were as capable of double strand break repair as extracts from a wild-type host, arguing that the E. coli recombinase is not essential to the recombinational events required for double strand break repair. In T7 strand exchange during recombination is mediated by the combined action of the helicase encoded by gene 4 and the annealing function of the gene 2.5 single strand binding protein. Although a deficiency in the gene 2.5 protein blocked double strand break repair, a gene 4 deficiency had no effect. This argues that a strand transfer step is not required during recombinational repair of double strand breaks in T7 but that the ability of the gene 2.5 protein to facilitate annealing of complementary single strands of DNA is critical to repair of double strand breaks in T7.

Repair of double-strand breaks by incorporation of a molecule of homologous DNA

An in vitro system based upon extracts of Escherichia coli infected with bacteriophage T7 was used to monitor repair of double-strand breaks in the T7 genome. The efficiency of double-strand break repair was markedly increased by DNA molecules ('donor' DNA) consisting of a 2.1 kb DNA fragment, generated by PCR, that had ends extending approximately 1 kb on either side of the break site. Repair proceeded with greater than 10% efficiency even when T7 DNA replication was inhibited. When the donor DNA molecules were labelled with 32P, repaired genomes incorporated label only near the site of the double-strand break. When repair was carried out with unlabelled donor DNA and [32P]-dCTP provided as precursor for DNA synthesis the small amount of incorporated label was distributed randomly throughout the entire T7 genome. Repair was performed using donor DNA that had adjacent BamHI and PstI sites. When the BamHI site was methylated and the PstI site was left unmethylated, the repaired genomes were sensitive to PstI but not to BamHI endonuclease, showing that the methyl groups at the BamHI recognition site had not been replaced by new DNA synthesis during repair of the double-strand break. These observations are most consistent with a model for double-strand break repair in which the break is widened to a small gap, which is subsequently repaired by physical incorporation of a patch of donor DNA into the gap.

Visualization of repair of double-strand breaks in the bacteriophage T7 genome without normal DNA replication

An in vitro system based on extracts of Escherichia coli infected with bacteriophage T7 is able to repair double-strand breaks in a T7 genome with efficiencies of 20% or more. To achieve this high repair efficiency it is necessary that the reaction mixtures contain molecules of donor DNA that bracket the double-strand break. Gaps as long as 1,600 nucleotides are repaired almost as efficiently as simple double-strand breaks. DNA synthesis was measured while repair was taking place. It was found that the amount of DNA synthesis associated with repair of a double-strand break was below the level of detection possible with this system. Furthermore, repair efficiencies were the same with or without normal levels of T7 DNA polymerase. However, the repair required the 5'-->3' exonuclease encoded by T7 gene 6. The high efficiency of DNA repair allowed visualization of the repaired product after in vitro repair, thereby assuring that the repair took place in vitro rather than during an in vivo growth step after packaging.

In vitro repair of gaps in bacteriophage T7 DNA

An in vitro system based upon extracts of Escherichia coli infected with bacteriophage T7 was used to study the mechanism of double-strand break repair. Double-strand breaks were placed in T7 genomes by cutting with a restriction endonuclease which recognizes a unique site in the T7 genome. These molecules were allowed to repair under conditions where the double-strand break could be healed by (i) direct joining of the two partial genomes resulting from the break, (ii) annealing of complementary versions of 17-bp sequences repeated on either side of the break, or (iii) recombination with intact T7 DNA molecules. The data show that while direct joining and single-strand annealing contributed to repair of double-strand breaks, these mechanisms made only minor contributions. The efficiency of repair was greatly enhanced when DNA molecules that bridge the region of the double-strand break (referred to as donor DNA) were provided in the reaction mixtures. Moreover, in the presence of the donor DNA most of the repaired molecules acquired genetic markers from the donor DNA, implying that recombination between the DNA molecules was instrumental in repairing the break. Double-strand break repair in this system is highly efficient, with more than 50% of the broken molecules being repaired within 30 min under some experimental conditions. Gaps of 1,600 nucleotides were repaired nearly as well as simple double-strand breaks. Perfect homology between the DNA sequence near the break site and the donor DNA resulted in minor (twofold) improvement in the efficiency of repair. However, double-strand break repair was still highly efficient when there were inhomogeneities between the ends created by the double-strand break and the T7 genome or between the ends of the donor DNA molecules and the genome. The distance between the double-strand break and the ends of the donor DNA molecule was critical to the repair efficiency. The data argue that ends of DNA molecules formed by double-strand breaks are typically digested by between 150 and 500 nucleotides to form a gap that is subsequently repaired by recombination with other DNA molecules present in the same reaction mixture or infected cell.

Site-directed mutagenesis

The development of genetic engineering, whereby a specific gene or cDNA (c is copy or complementary) can be isolated as part of a minichromosome that can replicate and be expressed (by transcription and translation) in a living cell, has made possible in vitro techniques for micromanipulation (i.e. site-directed mutagenesis) of a cloned gene, to make defined changes in the portion of the gene that encodes its protein product. The methods by which this micromanipulation of a structural gene are effected fall under three broad headings: (i) the production of random single base-pair substitutions by chemical or enzymatic means; (ii) the construction of heteroduplex DNA by annealing single-strand target DNA with a chemically synthesized mutagenic oligonucleotide and (iii) the total or partial synthesis of mutant duplex DNA from chemically synthesized oligonucleotides. As a consequence it is now possible to modify a gene so that any amino acid in its product protein can be replaced by any other amino acid.

Deletion between direct repeats in T7 DNA stimulated by double-strand breaks

An in vitro system based on extracts of Escherichia coli infected with bacteriophage T7 was used to study genetic deletions between directly repeated sequences. The frequency of deletion was highest under conditions in which the DNA was actively replicating. Deletion frequency increased markedly with the length of the direct repeat both in vitro and in vivo. When a T7 gene was interrupted by 93 bp of nonsense sequence flanked by 20-bp direct repeats, the region between the repeats was deleted in about 1 out of every 1,600 genomes during each round of replication. Very similar values were found for deletion frequency in vivo and in vitro. The deletion frequency was essentially unaffected by a recA mutation in the host. When a double-strand break was placed between the repeats, repair of this strand break was often accompanied by the deletion of the DNA between the direct repeats, suggesting that break rejoining could contribute to deletion during in vitro DNA replication.

Mutational specificity of ethyl methanesulfonate in excision-repair-proficient and -deficient strains of Drosophila melanogaster

The vermilion gene was used as a target to determine the mutational specificity of ethyl methanesulfonate (EMS) in germ cells of Drosophila melanogaster. To study the impact of DNA repair on the type of mutations induced, both excision-repair-proficient (exr+) and excision-repair-deficient (exr-) strains were used for the isolation of mutant flies. In all, 28 mutants from the exr+ strain and 24 from the exr- strain, were characterized by sequence analysis. In two mutants obtained from the exr+ strain, small deletions were observed. All other mutations were caused by single base-pair changes. In two mutants double base-pair substitutions had occurred. Of the mutations induced in the exr+ strain, 22 (76%) were GC----AT transitions, 3 (10%) AT----TA transversions, 2 (6%) GC----TA transversions and 2 (6%) were deletions. As in other systems, the mutation spectrum of EMS in Drosophila is dominated by GC----AT transitions. Of the mutations in an exr- background, 12 (48%) were GC----TA transitions, 7 (28%) AT----TA transversions, 5 (20%) GC----TA transversions and 1 (4%) was a AT----GC transition. The significant increase in the contribution of transversion mutations obtained in the absence of an active maternal excision-repair mechanism, clearly indicates efficient repair of N-alkyl adducts (7-ethyl guanine and 3-ethyl adenine) by the excision-repair system in Drosophila germ cells.

N-methyl-N-nitrosourea-induced mutations in a shuttle plasmid replicated in human cells

The supF gene of the recombinant shuttle plasmid pZ190 (modified pZ189) was used as a target to study the nature of mutations induced by N-methyl-N-nitrosourea (MNU) in human cells. Treatment of the intact plasmid with MNU followed by its replication in human lymphoblastoid cells led to extensive inactivation and no detectable mutations of the plasmid. However, exposure of the supF DNA fragment alone, followed by its ligation into the vector, caused a ten-fold increase in mutant frequency when replicated in O6-methylguanine-DNA methyltransferase-deficient cells (from 0.54 x 10(-3) to 5.8 x 10(-3)) and an 80-fold increase when replicated in cells containing normal levels of the enzyme (from 0.047 x 10(-3) to 3.8 x 10(-3)). About 45% of the mutant plasmid molecules recovered from human cells contained deletions and insertions. Sixty to 70% of the mutant molecules of wild-type size contained a single-base substitution. Most of these changes were of the G.C----A.T type, consistent with the hypothesis that O6-methylguanine is the primary mutagenic adduct induced by MNU. However, the distribution of mutation sites was highly nonrandom; more than half of all mutations were localized at the G.C position 123, and the rest were distributed in about a dozen sites. The high yield of mutations induced in the supF DNA in a host cell whose capacity for the removal of O6-methylguanine far exceeded the amount present in the supF suggests that the repair of damages in extrachromosomal DNA may be inefficient. This is supported by the observation that the yield of mutations in supF transfected into lymphoblastoid cells devoid of repair activity for O6-methylguanine was comparable to that observed with repair-proficient host cells. The present data, together with results of mutations induced in pZ189 by other agents, strongly suggest that one major determinant of mutational hot spots is the structure of the target DNA itself.

A single-base change in gene 10 of bacteriophage T7 permits growth on Shigella sonnei

Bacteriophage T7 can extend its host range to include Shigella sonnei D2 371-48 by a mutation called ss found in the T7 major capsid protein, the gene 10 product. We show that a single A-to-C transversion at position 23150 in the T7 genome is responsible for the T7 ss mutant phenotype that allows the phage to avoid DNA degradation and undergo productive infection. The ss mutation causes an amino acid substitution of proline for glutamine at position 61 of the 344-amino-acid T7 major capsid protein.

A second DNA methyltransferase repair enzyme in Escherichia coli

The Escherichia coli ada-alkB operon encodes a 39-kDa protein (Ada) that is a DNA-repair methyltransferase and a 27-kDa protein (AlkB) of unknown function. By DNA blot hybridization analysis we show that the alkylation-sensitive E. coli mutant BS23 [Sedgwick, B. & Lindahl, T. (1982) J. Mol. Biol. 154, 169-175] is a deletion mutant lacking the entire ada-alkB operon. Despite the absence of the ada gene and its product, the cells contain detectable levels of a DNA-repair methyltransferase activity. We conclude that the methyltransferase in BS23 cells is the product of a gene other than ada. A similar activity was detected in extracts of an ada-10::Tn10 insertion mutant of E. coli AB1157. This DNA methyltransferase has a molecular mass of about 19 kDa and transfers the methyl groups from O6-methylguanine and O4-methylthymine in DNA, but not those from methyl phosphotriester lesions. This enzyme was not induced by low doses of alkylating agent and is expressed at low levels in ada+ and a number of ada- E. coli strains.

In vitro packaging of heteroduplex bacteriophage T7 DNA: evidence for repair of mismatched bases

Heteroduplex DNA molecules that were wild type or contained combinations of amber, missense, and temperature-sensitive mutations were prepared from bacteriophage T7. These DNA molecules were then encapsulated in in vitro packaging reactions so as to produce infective T7 phage. The genotypes of the phage were examined to determine the degree to which mismatched base pairs in the heteroduplex had been corrected. The data show that conversion of the mismatches took place either during in vitro packaging or immediately after infection of either an Escherichia coli or Shigella sonnei host. The mode of mismatch conversion observed in these experiments was independent of the host mutH, mutL, mutS, and uvrD genes. There was no significant amount of discrimination between markers on either of the two complementary strands. The observed frequency of conversion of a mismatch depended on the genetic marker being monitored and on experimental conditions but was generally in the range between 5 and 30%.

The in vivo mutagenic frequency and specificity of O6-methylguanine in phi X174 replicative form DNA

A bacteriophage phi X174-based site-specific mutagenesis system for the study of the in vivo mutagenic frequency and specificity of carcinogen-induced modification in DNA is presented. A (-)-strand primer containing O6-methylguanine in a specific site was hybridized to a single-stranded region in gene G of phi X gapped duplex DNA. The hybrid was enzymatically converted to replicative form DNA and was used to transform Escherichia coli cells. All gene G mutants generated by the modification were rescued by genetic complementation. An amber mutation in lysis gene E of the (+) strand of the replicative form DNA prevented lytic growth of wild-type phage derived from this strand. In each mutant-containing infective center produced from the transformed cells, gene G mutant phage were present in a 3:1 ratio compared to wild type. Thus, in vivo, O6-methylguanine in replicating phi X DNA has a mutagenic frequency of 75%. When repair of O6 methylguanine occurred, it was prereplicative. The mutations were due exclusively to the misincorporation of thymine.

The incorporation of O6-methyldeoxyguanosine monophosphate and O4-methyldeoxythymidine monophosphate into polynucleotide templates leads to errors during subsequent in vitro DNA synthesis

O4-MedTMP and O6-MedGMP may be incorporated from their 5'-triphosphates into polynucleotides by DNA polymerases. Once incorporated O6-MedGMP leads to errors during further cycles of DNA synthesis with a mutagenic efficiency of 0.3-0.7, the value depending upon the relative dNTP concentrations in the assay. In contrast O4-MedTMP leads to very few errors following its incorporation into DNA. The results demonstrate that O6-MedGMP, once incorporated into DNA, should be destined to give rise to DNA base changes during the second round of DNA synthesis.

Mutagenesis of bacteriophage T7 and T7 DNA by alkylation damage

We have developed a new assay for in vitro mutagenesis of bacteriophage T7 DNA that measures the generation of mutations in the specific T7 gene that codes for the phage ligase. This assay was used to examine mutagenesis caused by in vitro DNA synthesis in the presence of O6-methylguanosine triphosphate. Reversion of one of the newly generated ligase mutants by ethyl methanesulfonate was also tested.

Construction and characterization of extrachromosomal probes for mutagenesis by carcinogens: site-specific incorporation of O6-methylguanine into viral and plasmid genomes

Organic synthesis and recombinant DNA technology were used to situate a putatively premutagenic DNA lesion, O6-methylguanine (O6MeGua), at a specific location in the genomes of two bacterial viruses, M13mp8 and phi X174, and of the bacterial plasmid pBR322. In each genome the first guanine residue in the unique recognition sequence for restriction endonuclease Pst I (5'-C-T-G-C-A-G-3') was replaced with O6MeGua. This was accomplished by ligating a chemically synthesized tetranucleotide, 5'-pTpm6GpCpA-3', into a circular, genome-length heteroduplex in which the four internal nucleotides of the Pst I recognition site had been removed from one strand of the DNA double helix (ligation yield, approximately equal to 50%). It was established that the tetranucleotide was located specifically at the Pst I site and that the presence of O6MeGua rendered the ligation product resistant to cleavage by Pst I. Sensitivity of the genome to Pst I was restored upon treatment with purified Escherichia coli O6MeGua DNA-methyltransferase, a repair protein that removes the methyl group from DNA-bound O6MeGua. This result, in combination with other data, showed unambiguously that O6MeGua was incorporated with high yield into the Pst I recognition sequence.

Inducible reactivation of bacteriophage T7 damaged by methyl methanesulfonate or UV light

We examined the effects of host mutations affecting "SOS"-mediated UV light reactivation on the survival of bacteriophage T7 damaged by UV light or methyl methanesulfonate (MMS). Survival of T7 alkylated with MMS was not affected by the presence of plasmid pKM101 or by a umuC mutation in the host. The survival of UV light-irradiated T7 was similar in umuC+ and umuC strains but was slightly enhanced by the presence of pKM101. When phage survival was determined on host cells preirradiated with a single inducing dose of UV light, these same strains permitted higher survival than that seen with noninduced cells for both UV light- and MMS-damaged phage. The extent of T7 reactivation was approximately proportional to the UV light inducing dose inflicted upon each bacterial strain and was dependent upon phage DNA damage. Enhanced survival of T7 after exposure to UV light or MMS was also observed after thermal induction of a dnaB mutant. Thus, lethal lesions introduced by UV light or MMS are apparently repaired more efficiently when host cells are induced for the SOS cascade, and this inducible reactivation of T7 is umuC+ independent.

Escherichia coli polymerase I can use O2-methyldeoxythymidine or O4-methyldeoxythymidine in place of deoxythymidine in primed poly(dA-dT).poly(dA-dT) synthesis

O2-and O4-alkyldeoxythymidine are among the four O-alkyl base-modified derivatives produced by the reaction of N-nitroso alkylating agents with nucleic acids in vitro and in vivo. We find that both O2- and O4-methyl-dTTP can substitute for dTTP in alternating poly(dA-dT)-primed DNA synthesis. Up to 22% of the pyrimidines in the newly synthesized polymer were found by HPLC analysis to be O-methyldeoxythymidine. Little polymer synthesis was observed in the absence of dTTP. However, the O-methyl-dTTPs did not inhibit polymerization of dATP and dTTP. Polymers containing O2- or O4-methyldeoxythymidine were obtained in good yield, retaining the secondary structure of alternating poly(dA-dT). This was shown by the data for thermal transition under different conditions. In contrast, poly(dA-dT).poly(dA-dT) methylated or ethylated to less than 4% total modification by alkylnitrosoureas had a distinctly less stable structure. Neither O2- nor O4-methyldeoxythymidine can form more than one hydrogen bond with adenosine. The unchanged secondary structure of polymers containing these modified thymidines indicates that stacking interactions must play a major role in helix stabilization. O-Alkyldeoxythymidine may be formed by N-nitroso carcinogens that react intracellularly. We have shown that the triphosphates can be utilized by Escherichia coli DNA polymerase I as dTTP. The incorporated O4-methyl-dT causes misincorporation of G, both in transcription and synthesis. When O2-methyl-dT is present, less, but definite, misincorporation results.

Persistence of methylated purines in the DNA of various rat fetal and maternal tissues and carcinogenesis in the offspring following a single transplacental dose of N-methyl-N-nitrosourea

Formation and loss of methylated purines in DNA of various fetal and maternal tissues were measured up to 7 days following intravenous administration of N-[14C]methyl-N-nitrosourea to rats on the 21st day of gestation. Methylation products were detected in all tissues examined, the level in maternal liver being higher than in other tissues. The concentrations of 7-methylguanine and 3-methyladenine decreased faster in fetal than in corresponding maternal tissues, due to a higher rate of DNA synthesis in fetal tissues, as determined by incorporation of labelled thymidine. Removal of the promutagenic DNA lesion O6-methylguanine was most efficient in maternal and fetal liver; but it was very poorly repaired in kidney and brain. The persistence of O6-methylguanine relative to 7-methylguanine was highest in the DNA of fetal brain. The principal targets for the transplacental carcinogenic effect of N-methyl-N-nitrosourea under these experimental conditions were fetal neurogenic tissue and kidney; and malignant tumors developed at these sites in 31-34% and 15-16% of male and female descendants, respectively. These results support the concept that a complex interaction between DNA alkylation, repair and replication is the molecular basis of initiation of carcinogenesis by alkylating agents.