A new system for studying molecular mechanisms of mutation by carcinogens.

A new system for studying the molecular mechanisms of mutation by carcinogens is described. The system involves (a) site-specific modification of the essential gene G in phi X174 replicative form DNA by a combination of chemical and enzymatic steps; (b) production of mutant virus carrying a change at a single preselected site by transfection of spheroplasts with the site modified phi X174 DNA; (c) detection and propagation of mutants using a host carrying the plasmid, p phi XG, that rescues all type of gene G mutants by complementation; (d) identification of the mutation in the progeny virus by isolating and sequencing mutant phi X174 DNA in the region that carried the parental, site-specific change. To demonstrate that this system is operational, we have produced a previously unknown phi X174 gene G mutant carrying a C leads to T base change at position 2401 of the viral (plus) strand. This preplanned, nonsense (amber) mutant was obtained by changing G to A at the appropriate position in a chemically synthesized, octadeoxynucleotide, minus strand primer; elongating this enzymatically with Escherichia coli DNA polymerase I (larger fragment) (lacking 5' leads to 3' exonuclease activity) to a 17-mer; and repriming to obtain the site-modified phi X174 replicative form DNA enzymatically with E. coli DNA polymerase I (large fragment) and T4 DNA ligase. After transfection of spheroplasts with the heteroduplex DNA, the lysate was screened for mutant virus with permissive (carrying p phi XG) and nonpermissive (without p phi XG) host cells. About 1% of the progeny virus were mutants. Out of 15 isolates, 11 were suppressible by an amber Su1+ (serine) or an ochre Su8+ (glutamine) suppressor. The other 4 isolates were not suppressed at all. Replicative form DNA produced from one of the suppressible mutants was shown (by sequencing) to contain the expected C leads to T change at the preselected site in the viral strand. Replicative form DNA from one of the nonsuppressible mutants was partially sequenced. No change was found at or around position 2401. The nature of the mutation(s) in these isolates is still unknown. The occurrence of mutations outside the preselected sites represent a potential problem for our projected studies, but additional data is required before the problem can be fully evaluated. In spite of this, it should be possible to study, in vivo, the biological effects of any site-specific modification (including covalent modifications by carcinogens) that can be introduced into gene G of phi X174 DNA via a synthetic, oligonucleotide primer.     

Replication of phi X174 dna with purified enzymes. I. Conversion of viral DNA to a supercoiled, biologically active duplex

Conversion of phi X174 viral, single-stranded circular DNA to the duplex replicative form (RF), previously observed with partially purified enzymes, has now been demonstrated with the participation of 12 nearly pure Escherichia coli proteins containing approximately 30 polypeptides. To complete the synthesis of a full length complementary strand, E. coli DNA polymerase I was needed to fill the short gap left by DNA polymerase III holoenzyme, and to remove the primer and replace it with DNA. Production of supercoiled RF required the further actions of E. coli DNA ligase and gyrase. Net synthesis of viral circles was obtained by coupling the formation of RF supercoils to the actions of the phi X174-encoded gene A protein and E. coli rep protein. Viral DNA circles produced from enzymatically synthesized supercoiled RF, serving as template-substrate, were indistinguishable from those produced from RF isolated from infected cells; synthetic RF and the viral circles generated from it by replication were as biologically active in transfection of spheroplasts as the forms obtained from infected cells and virions. The conversion of single-stranded circular DNA to RF is suggested here as a model for discontinuous synthesis of the lagging strand of the E. coli chromosome. The primosome, a complex of some of the replication proteins responsible for initiations of DNA chains, will be described elsewhere. Multiplication of RF supercoils, described in the succeeding paper, proceeds by a rolling-circle mechanism in which the synthesis of viral strands may have analogies to the continuous synthesis of the leading strand of the E. coli chromosome.     

The dnaZ protein, the gamma subunit of DNA polymerase III holoenzyme of Escherichia coli

The dnaZ protein has been purified to near-homogeneity using an in vitro complementation assay that measures the restoration of activity in a crude enzyme fraction from the dnaZ mutant deficient in the replication of phi X174 DNA. Over 70-fold overproduction of the protein was obtained with a bacteriophage lambda lysogen carrying the dnaZ gene. The purified protein, under reducing and denaturing conditions, has a molecular weight of 52,000 and appears to be a dimer in its native form. The dnaZ protein is judged to be th 52,000-dalton gamma subunit of DNA polymerase III holoenzyme (McHenry, C., and Kornberg, A. (1977) J. Biol. Chem. 252, 6478-6484) for the following reasons: (i) highly purified DNA polymerase III holoenzyme contains a 52,000-dalton polypeptide and has dnaZ-complementing activity; (ii) the 52,000-dalton polypeptide is associated tightly with the DNA polymerase III holoenzyme and can be separated from the DNA polymerase III core only with severe measures; (iii) no other purified replication protein, among 14 tested, contains dnaZ protein activity; and (iv) the abundance of dnaZ protein, estimated at about 10 dimer molecules per Escherichia coli cell, is similar to that of the DNA polymerase III core. Among several circular templates tested in vitro (i.e. single stranded phi X174, G4 and M13 DNAs, and duplex phi X174 DNA), all rely on dnaZ protein for elongation by DNA polymerase III holoenzyme. The protein acts catalytically at a stoichiometry of one dimer per template.     

Circular and linear simian virus 40 DNAs differ in recombination.

Linear forms of simian virus 40 (SV40) DNA, when added to transfection mixtures containing circular SV40 and phi X174 RFI DNAs, enhanced the frequency of SV40/phi X174 recombination, as measured by infectious center in situ plaque hybridization in monkey BSC-1 cells. The sequences required for the enhancement of recombination by linear DNA reside within the SV40 replication origin/regulatory region (nucleotides 5,171 to 5,243/0 to 128). Linearization of phi X174 RFI DNA did not increase the recombination frequency. The SV40/phi X174 recombinant structures arising from transfections supplemented with linear forms of origin-containing SV40 DNA contained phi X174 DNA sequences interspersed within tandem head-to-tail repeats derived from the recombination-enhancing linear DNA. Evidence is presented that the tandem repeats are not formed by homologous recombination and that linear forms of SV40 DNA must compete with circular SV40 DNA for the available T antigen to enhance recombination. We propose that the enhancement of recombination by linear SV40 DNA results from the entry of that DNA into a rolling circle type of replication pathway which generates highly recombinogenic intermediates.     

Defined transversion mutations at a specific position in DNA using synthetic oligodeoxyribonucleotides as mutagens.

The oligodeoxyribonucleotides, pCCCAGCCTCAA, which is complementary to nucleotides 5274--4284 of bacteriophage phi X174 viral DNA , and pCCCAGCCTAAA, which corresponds to the same sequence with a C leads to A change at the ninth nucleotide, were synthesized enzymatically. The second of these oligonucleotides was used as a primer for E. coli DNA polymerase I, from which the 5'-exonculease has been removed by proteolysis (Klenow enzyme), on wild-type phi X174 viral DNA template. After ligation, this yielded closed circular heteroduplex DNA with a G, A mismatch at nucleotide 5276. Transfection of E. coli spheroplasts with the heteroduplex DNA produced phage mutated at this nucleotide (G leads to T in the viral DNA) with high efficiency (13%). The mutant DNA, which corresponds to the gene B mutant am16, was reverted (T leads to G) by the wild type oligonucleotide with an efficiency of 19%. The nucleotide changes were established by sequence determination of the mutated viral DNA using the enzymatic terminator method. The production of specific transversion mutations, together with a previous demonstration of specific transition mutations (1), established that short enzymatically synthesized oligodeoxyribonucleotides can be used to induce any class of single nucleotide replacement with high efficiency and thus provide a powerful tool for specific genetic manipulations in circular genomes like that of phi X174.     

On the fidelity of DNA replication. The accuracy of Escherichia coli DNA polymerase I in copying natural DNA in vitro

The accuracy with which Escherichia coli DNA polymerase I (Pol I) copies natural DNA in vitro has been determined. When phi X174 viral DNA containing an amber mutation (am3) is primed with a single restriction endonuclease fragment, copied in vitro with Pol I and then expressed in E. coli spheroplasts (Weymout, L. A., and Loeb, L. A. (1978) Proc. Natl. Acad. Sci. U. S. A. 75, 1924), the reversion frequency of this DNA is greater than that of uncopied DNA. This change in reversion frequency can be increased by selectively increasing the concentration of either dATP or dCTP relative to the other deoxyribonucleotide substrates. DNA sequence analyses of revertants obtained from substrate pool bias experiments demonstrates that the revertants contain the selectively biased nucleotide as an incorrect substitution at position 587 of the am3 codon. We have analyzed the product of the in vitro Pol I reaction using neutral and alkaline sucrose gradients. Fifty per cent of the input phi X174 DNA template molecules are copied past the am3 site. The phenotypic expression of the product (revertant) strand in the spheroplast assay was estimated using a model heteroduplex molecule similar in structure to the product of the reaction and containing a single base mismatch (A:A or A:C) at position 587. Using these data, and by extrapolation from pool bias experiments, we estimate the error rate of Pol I in Mg2+-activated reactions using equimolar concentrations of the four deoxynucleotide substrates is 1/680,000 for an A:C mispair and < 1/6,300,000 for an A:A mispair at position 587 of the am3 codon in phi X174 DNA.     

GATC sequences, DNA nicks and the MutH function in Escherichia coli mismatch repair.

Circular heteroduplex DNAs of bacteriophage phi X174 have been constructed carrying either a G:T (Eam+/Eam3) or a G:A (Bam+/Bam16) mismatch and containing either two, one or no GATC sequences. Mismatches were efficiently repaired in wild-type Escherichia coli transfected with phi X174 heteroduplexes only when two unmethylated GATC sequences were present in phi X174 DNA. The requirements for GATC sequences in substrate DNA and for the E. coli MutH function in E. coli mismatch repair can be alleviated by the presence of a persistent nick (transfection with nicked heteroduplex DNA in ligase temperature-sensitive mutant at 40 degrees C). A persistent nick in the GATC sequence is as effective in stimulating mutL- and mutS-dependent mismatch repair as a nick distant from the GATC sequence and from the mismatch. These observations suggest that the MutH protein participates in methyl-directed mismatch repair by recognizing unmethylated DNA GATC sequences and/or stimulating the nicking of unmethylated strands.     

Studies on the role of the phi X174 gene A protein in phi X viral strand synthesis. I. Replication of DNA containing an alteration in position 1 of the 30-nucleotide icosahedral bacteriophage origin

The influence of a C----G transversion at position 1 of the 30-base pair replication origin of bacteriophage phi X174 replicative form I DNA (phi X RFI) was examined in the RF----single-stranded circular DNA replication pathway catalyzed by the combined action of the purified phi X A protein, the Escherichia coli DNA polymerase III holoenzyme, rep helicase, and single-stranded DNA binding protein (Eisenberg, S., Scott, J.F., and Kornberg, A. (1976) Proc. Natl. Acad. Sci. U.S.A. 73, 1594-1597; Reinberg, D., Zipursky, S.L., and Hurwitz, J. (1981) J. Biol. Chem. 256, 13143-13151). RFI DNA containing this transversion was cleaved to RFII by the phi X A protein as effectively as DNA containing the wild-type origin. The altered duplex DNA, however, supported replication at a slower rate (3- to 4-fold) than the wild-type DNA due to a defect in the termination and reinitiation reactions catalyzed by the phi X A protein. This defect resulted in the accumulation of DNA products containing long single strands covalently joined to the mutant DNA. These single strands were susceptible to nuclease S1 and exonuclease VII attack. The defect in the template DNA containing C----G transversion was not corrected when this mutant origin was placed on the same strand with a wild-type origin. This double-origin DNA was also replicated poorly and led to the accumulation of large products, in contrast to the products formed with RFI DNA containing two wild-type 30-base pair replication origins on the same strand.     

Transfer of genome fragments in double infection of E. coli with T5 and phi X174 bacteriophages.

Double infection of Escherichia coli by two DNA phages (phi X174 and T5) resulted in encapsidation into T5 particles of T5 DNA containing linked fragments of phi X174 DNA. The phi X474 sequences in T5 "hybrid" DNA were detected by RNA-DNA hybridization.     

The effect of template secondary structure on vaccinia DNA polymerase.

Vaccinia virus DNA polymerase will utilize a substrate consisting of phi X174 DNA primed with a strand of a unique restriction fragment, but the reaction is inefficient. Examination of the reaction products by alkaline agarose gel electrophoresis revealed a few discrete fragments, each corresponding to an extended primer strand. This result implies that specific barriers exist on the phi X174 template which impede, but do not completely halt, the progress of the enzyme. Only a few per cent of the template molecules were completely copied. Similar findings were reported by Sherman and Gefter using Escherichia coli DNA polymerase II and fd DNA (J. Mol. Biol. (1976) 103, 61-76). Several observations suggest that the barriers are regions of template secondary structure. Some barriers are more effective than others, and they increase in both effectiveness and number as the temperature is decreased. The same barriers are observed with T4 DNA polymerase, but none are detected with E. coli DNA polymerase I. Finally, the major barriers are located in regions of the phi X174 sequence known to contain hairpin structures of relatively high stability. The exact stopping point of one of the major barriers is within the duplex stem of a hairpin structure. These results show that DNA polymerases are a useful probe of the secondary structure of a single-stranded DNA.     

Role of polymeric forms of the bacteriophage phi X174 coded gene A protein in phi XRFI DNA cleavage.

Gene A of the phi X174 genome codes for two proteins, A and A* (Linney, E.A., and Hayashi, M.N. (1973) Nature New Biol. 245, 6-8) of molecular weights 60,000 and 35,000, respectively. The phi X A* protein is formed from a natural internal initiator site within the A gene cistron while the phi X A protein is the product of the entire A gene. These two proteins have been purified to homogeneity as judged by sodium dodecyl sulfate polyacrylamide gel electrophoresis. Previous studies have shown that the phi X A protein is an endonuclease which specifically introduces a discontinuity in the A cistron of the viral strand of supertwisted phi XRFI DNA. In addition to this activity, the phi X A protein also causes relaxation of supertwisted phi XRFI DNA and formation of a phi XRFH DNA . phi X A protein complex which has a discontinuity in the A cistron of the viral strand. This isolatable complex supports DNA synthesis when supplemented with extracts of uninfected Escherichia coli which lack phi X A protein and phi XRFI DNA. The phi XRFII DNA . phi X A protein complex can be attacked by exonuclease III but is not susceptible to attack by E. coli DNA polymerase I, indicating that the 5'-end of the complex is blocked. Attempts to seal the RFII structure generated from the phi XRFII DNA . phi X A protein complex with T4 DNA ligase in the presence or absence of DNA polymerase were unsuccessful. The phi X A protein does not act catalytically in the cleavage of phi XRFI DNA. Under conditions leading to the quantitative cleavage of phi XRFI DNA, the molar ratio of phi XRFI DNA to added phi X A protein was approximately 1:10. At this molar ratio, cross-linking experiments with dimethyl suberimidate yielded 10 distinct protein bands which were multiples of the monomeric phi X A protein. In the absence of DNA or in the presence of inactive DNA (phi XRFII DNA) no distinct protein bands above a trimer were detected. We found it possible in vitro to form a phi XRFII DNA . phi X A protein complex with wild-type phi XRFI DNA (phi X A gene+) and with phi XRFI DNA isolated from E. coli (su+) infected with phage phi X H90 (an am mutant in the phi X A gene). Thus, in vitro, in contrast to in vivo studies, phi X A protein is not a cis acting protein. The purified phi X A* protein does not substitute for the phi X A protein in in vitro replication of phi XRFI DNA nor does it interfere with the action of the phi X A protein which binds only to supertwisted phi XRFI DNA. In contrast, the phi X A* protein binds to all duplex DNA preparations tested. This property prevents nucleases of E. coli from hydrolyzing duplex DNAs to small molecular weight products.     

Absence of a role for DNA polymerase II in SOS-induced translesion bypass of phi X174.

In order to examine the possible role of Escherichia coli DNA polymerase II in SOS-induced translesion bypass, Weigle reactivation and mutation induction were measured with single-stranded phi X174 transfecting DNA containing individual lesions. No decrease in bypass of thymine glycol or cyclobutane pyrimidine dimers in the absence of DNA polymerase II was observed. Furthermore, DNA polymerase II did not affect bypass of abasic sites when either survival or mutagenesis was the endpoint. Lastly, repair of gapped DNA molecules, intermediates in methyl-directed mismatch repair, was also unaffected by the presence or absence of DNA polymerase II.     

Processing of mispaired and unpaired bases in heteroduplex DNA in E. coli

Bacteriophage lambda and phi X 174 DNAs, carrying sequenced mutations, have been used to construct in vitro defined species of heteroduplex DNA. Such heteroduplex DNAs were introduced by transfection, as single copies, into E. coli host cells. The progeny of individual heteroduplex molecules from each infective center was analyzed. The effect of the presence of GATC sequences (phi X 174 system) and of their methylation (lambda system) was tested. The following conclusions can be drawn: some mismatched base pairs trigger the process of mismatch repair, causing a localized strand-to-strand information transfer in heteroduplex DNA: transition mismatches G:T and A:C are efficiently repaired, whereas the six transversion mismatches are not always readily recognized and/or repaired. The recognition of transversion mismatches appears to depend on the neighbouring nucleotide sequence; single unpaired bases (frameshift mutation "mismatches") are recognized and repaired, some equally efficiently on both strands (longer and shorter), some more efficiently on the shorter (-1) strand; large non-homologies (about 800 bases) are not repaired by the Mut H, L, S, U system, but some other process repairs the non-homology with a relatively low efficiency; full methylation of GATC sequences inhibits mismatch repair on the methylated strand: this is the chemical basis of strand discrimination (old/new) in mismatch correction; unmethylated GATC sequences appear to improve mismatch repair of a G:T mismatch in phi X 174 DNA, but there may be some residual mismatch repair in GATC-free phi X 174, at least for some mismatches.(ABSTRACT TRUNCATED AT 250 WORDS)     

Restriction enzyme digestion of hemimethylated DNA.

Hemimethylated duplex DNA of the bacteriophage phi X 174 was synthesized using primed repair synthesis is in vitro with E. coli DNA polymerase I followed by ligation to produce the covalently closed circular duplex (RFI). Single-stranded phi X DNA was used as a template, a synthetic oligonucleotide as primer and 5-methyldeoxycytidine-5'-triphosphate (5mdCTP) was used in place of dCTP. The hemimethylated product was used as substrate for cleavage by various restriction enzymes. Out of the 17 enzymes tested, only 5 (BstN I, Taq I, Hinc II, Hinf I and Hpa I) cleaved the hemimethylated DNA. Two enzymes (Msp I and Hae III) were able to produce nicks on the unmethylated strand of the cleavage site. Msp I, which is known to cleave at CCGG when the internal cytosine residue is methylated, does not cleave when both cytosines are methylated. Another enzyme, Apy I, cleaves at the sequence CCTAGG when the internal cytosine is methylated, but is inactive on hemimethylated DNA in which both cytosines are methylated. Hemimethylated molecules should be useful for studying DNA methylation both in vivo and in vitro.     

Growth and DNA synthesis of bacteriophage phi x174 in a dnaP mutant of Escherichia coli.

phi X174am3trD, a temperature-resistant mutant of bacteriophage phi X174am3, exhibited a reduced ability to grow in a dnaP mutant, Escherichia coli KM107, at the restrictive temperature (43 degrees C). Under conditions at which the dnaP gene function was inactivated, the amount and the rate of phi X174am3trD DNA synthesis were reduced. The efficiency of phage attachment to E. coli KM107 at 43 degrees C was the same as to the parental strain, E. coli KD4301, but phage eclipse and phage DNA penetration were inhibited in E. coli KM107 at 43 degrees C. It is suggested that the dnaP gene product, which is necessary for the initiation of host DNA replication, participates in the conversion of attached phages to eclipsed particles and in phage DNA penetration in vivo in normal infection.     

The enzymatic replication of DNA.

Enzymatic mechanisms of DNA replication have been investigated using small bacteriophages as probes to illuminate the cellular systems upon which they must rely during infection. Conversion of the circular, single-stranded DNAs of phages M13, G4, and phi X174 to their duplex forms has revealed the participation of diverse ways to start a new chain and a complex DNA polymerase III holoenzyme upon which all these systems depend for chain elongation. The phi X174 system, which is the most exacting and revealing of the host chromosomal replication pattern, includes at least twenty polypeptides for making the viral DNA into a duplex and multiplying the duplex. Resolution and purification of these numerous proteins is in train and their reconstitution into a "replisome"-like structure is envisioned.     

Suppression of polarity in the gal operon by ultraviolet irradiation.

The polarity of nonsense mutations in the galE gene of Escherichia coli can be suppressed by rho mutations (O. Reyes et al., J. Bacteriol. 126:1108-1112, 1976). We show here that this polarity can also be suppressed by ultraviolet irradiation. The effect is analogous to that already observed for polar nonsense mutations in phi X174 and S13 and suggests that ultraviolet irradiation suppression of polarity may be a general phenomenon.     

Regions of incompatibility in single-stranded DNA bacteriophages phi X174 and G4.

The intracellular presence of a recombinant plasmid containing the intercistronic region between the genes H and A of bacteriophage phi X174 strongly inhibits the conversion of infecting single-stranded phi X DNA to parental replicative-form DNA. Also, transfection with single-stranded or double-stranded phi X174 DNA of spheroplasts from a strain containing such a "reduction" plasmid shows a strong decrease in phage yield. This phenomenon, the phi X reduction effect, was studied in more detail by using the phi X174 packaging system, by which plasmid DNA strands that contain the phi X(+) origin of replication were packaged as single-stranded DNA into phi X phage coats. These "plasmid particles" can transduce phi X-sensitive host cells to the antibiotic resistance coded for by the vector part of the plasmid. The phi X reduction sequence in the resident plasmid strongly affected the efficiency of the transduction process, but only when the transducing plasmid depended on primosome-mediated initiation of DNA synthesis for its conversion to double-stranded DNA. The combination of these results led to a model for the reduction effect in which the phi X reduction sequence interacted with an intracellular component that was present in limiting amounts and that specified the site at which phi X174 replicative-form DNA replication takes place. The phi X reduction sequence functioned as a viral incompatibility element in a way similar to the membrane attachment site model for plasmid incompatibility. In the DNA of bacteriophage G4, a sequence with a similar biological effect on infecting phages was identified. This reduction sequence not only inhibited phage G4 propagation, but also phi X174 infection.     

The complete 30-base-pair origin region of bacteriophage phi X174 in a plasmid is both required and sufficient for in vivo rolling-circle DNA replication and packaging

The origin of replication of the isometric single-stranded DNA bacteriophages is located in a specific sequence of 30 nucleotides, the origin region, which is highly conserved in these phage genomes. Plasmids harboring this origin region are subject to rolling-circle DNA replication and packaging of single-stranded (ss) plasmid DNA into phage coats in phi X174 or G4-phage-infected cells. This system was used to study the nucleotide sequence requirements for rolling-circle DNA replication and DNA packaging employing plasmids which contain the first 24, 25, 26, 27, 28 and the complete 30-base-pair (bp) origin region of phi X174. No difference in plasmid ss DNA packaging was observed for plasmids carrying only the 30-bp origin region and plasmids carrying the 30-bp origin region plus surrounding sequences (i.e. plasmids carrying the HaeIII restriction fragment Z6B of phi X174 replicative-form DNA). This indicates that all signals for DNA replication and phage morphogenesis are contained in the 30-bp origin region and that no contribution is made by sequences which immediately surround the origin region in the phi X174 genome. The efficiency of packaging of plasmid ssDNA for plasmids containing deletions in the right part of the origin region decreases drastically when compared with the plasmid containing the complete 30-bp origin region (for a plasmid carrying the first 28 bp of the origin region to approximately 5% and 0.5% in the phi X174 and G4 systems respectively). Previous studies [Fluit, A.C., Baas, P.D., van Boom, J.H., Veeneman, G.H. and Jansz, H.S. (1984) Nucleic Acids Res. 12, 6443--6454] have shown that the presence of the first 27 bp of the origin region is necessary as well as sufficient for cleavage of the viral strand in the origin region by phi X174 gene A protein. Moreover, Brown et al. [Brown, D.R., Schmidt-Glenewinkel, T., Reinberg, D. and Hurwitz, J. (1983) J. Biol. Chem. 258, 8402--8412] have shown that omission of the last 2 bp of the origin region does not interfere with phi X174 rolling-circle DNA replication in vitro. Our results therefore suggest that for optimal phage development in vivo, signals in the origin region are utilized which have not yet been noticed by the in vitro systems for phi X174 phage DNA replication and morphogenesis.     

Depurination-induced infidelity of deoxyribonucleic acid synthesis with purified deoxyribonucleic acid replication proteins in vitro

Removal of purine bases from phi X174 single-stranded DNA leads to increased reversion frequency of amber mutations when this DNA is copied in vitro with purified DNA polymerases. This depurination-induced mutagenesis is observed at three different genetic loci and with several different purified enzymes, including Escherichia coli DNA polymerases I and III, avian myeloblastosis virus DNA polymerase, and eukaryotic DNA polymerases alpha, beta, and gamma. The extent of mutagenesis correlates with the estimated frequency of bypass of the lesion and is greatest with inherently inaccurate DNA polymerases which lack proofreading capacity. With E. coli DNA polymerase I, conditions which diminish proofreading result in a 3-5-fold increase in depurination-induced mutagenesis, suggesting a role for proofreading in determining the frequency of bypass of apurinic sites. The addition of E. coli single-stranded DNA-binding protein to polymerase I catalyzed reactions with depurinated DNA had no effect on the extent of mutagenesis. Analysis of wild-type revertants produced during in vitro DNA synthesis by polymerase I or avian myeloblastosis virus DNA polymerase on depurinated phi X174 amber 3 DNA indicates a preference for insertion of dAMP opposite the putative apurinic site at position 587. These results are discussed in relation both to the mutagenic potential of apurinic sites in higher organisms and to studies on error-prone DNA synthesis.