Structure of NaeI-DNA complex reveals dual-mode DNA recognition and complete dimer rearrangement

NaeI, a novel DNA endonuclease, shows topoisomerase and recombinase activities when a Lys residue is substituted for Leu 43. The NaeI-DNA structure demonstrates that each of the two domains of NaeI recognizes one molecule of DNA duplex. DNA recognition induces dramatic rearrangements: narrowing the binding site of the Topo domain 16 A to grip DNA, widening that of the Endo domain 8 A to encircle and bend DNA 45 degrees for cleavage, and completely rebuilding the homodimer interface. The NaeI-DNA structure presents the first example of novel recognition of two copies of one DNA sequence by two different amino acid sequences and two different structural motifs in one polypeptide.

Evidence for mutations that break communication between the Endo and Topo domains in NaeI endonuclease/topoisomerase

NaeI is a type IIe endonuclease that interacts with two DNA recognition sequences to cleave DNA. One DNA sequence serves as a substrate and the other serves to activate cleavage. NaeI is divided into two domains whose structures parallel the two functionalities recognized in NaeI, endonuclease and topoisomerase. In this study, we report evidence for mutations that break interdomain functional communication in a NaeI-DNA complex. Deletion of the initial 124 amino acids of the N-terminal domain of NaeI converted NaeI to a monomer, consistent with self-association being mediated by the Endo domain. Deletions within a small region of the C-terminal DNA binding domain of NaeI (amino acids 182-192) altered the recognition by NaeI of sequences flanking the NaeI recognition sequence. Substituting Ala for Arg182 within this region had no apparent effect on DNA binding but greatly reduced the extent of DNA cleavage even though it is not part of the catalytic Endo domain. Substituting Ala for Ile185 reduced the extent of DNA binding about 1000-fold. Substituting Ala for Lys189 altered flanking sequence recognition. Residues 182-192 are away from the Endo domain responsible for cleavage and also face away from the modeled DNA binding faces of the apoprotein crystal structure. We propose that residues 182-192 are part of a web that mediates the flow of information between the NaeI Endo and Topo domains.

Crystal structure of NaeI-an evolutionary bridge between DNA endonuclease and topoisomerase

NAE:I is transformed from DNA endonuclease to DNA topoisomerase and recombinase by a single amino acid substitution. The crystal structure of NAE:I was solved at 2.3 A resolution and shows that NAE:I is a dimeric molecule with two domains per monomer. Each domain contains one potential DNA recognition motif corresponding to either endonuclease or topoisomerase activity. The N-terminal domain core folds like the other type II restriction endonucleases as well as lambda-exonuclease and the DNA repair enzymes MutH and Vsr, implying a common evolutionary origin and catalytic mechanism. The C-terminal domain contains a catabolite activator protein (CAP) motif present in many DNA-binding proteins, including the type IA and type II topoisomerases. Thus, the NAE:I structure implies that DNA processing enzymes evolved from a few common ancestors. NAE:I may be an evolutionary bridge between endonuclease and DNA processing enzymes.

Abasic sites induce triplet-repeat expansion during DNA replication in vitro

The occurrence of triplet-repeat expansion (TRE) during transmission of genetic information is involved in many neurological and neuromuscular diseases including Fragile X syndrome and myotonic dystrophy. DNA slippage during replicative synthesis appears to cause TRE. The causes of DNA slippage, however, remain mostly unknown. We investigated the effects of abasic sites on the occurrence of TRE during DNA replication in vitro using Escherichia coli Klenow polymerase I as the model polymerase. Here we show that a single abasic site analog, synthesized in the triplet-repeat tract at the 5' end of the template strand, induced dramatic TRE during DNA synthesis. The amount of TRE induced decreased when the abasic site was moved to the middle of the repeat tract, consistent with effectively decreasing the length of the repeat tract. Placing the abasic site in the primer did not induce TRE. TRE was sequence-dependent. The damage-induced increase in growing strand TRE depended on the sequence of the growing strand repeat as AAT approximately ATT > CAG > CTG. The expansions required replication from a primer complementary to the repeat tract. The expanded tracts were sequenced and contained multiple additions of the original repeat. The results imply that DNA damage can play a significant role in generating TRE in vivo.

Effects of temperature, Mg2+ concentration and mismatches on triplet-repeat expansion during DNA replication in vitro

The human genome contains many simple tandem repeats that are widely dispersed and highly polymorphic. At least one group of simple tandem repeats, the DNA trinucleotide repeats, can dramaticallyexpand in size during transmission from one generation to the next to cause disease by a process known as dynamic mutation. We investigated the ability of trinucleotide repeats AAT and CAG to expand in size during DNA replication using a minimal in vitro system composed of the repeat tract, with and without unique flanking sequences, and DNA polymerase. Varying Mg2+concentration and temperature gave dramatic expansions of repeat size during DNA replication in vitro. Expansions of up to 1000-fold were observed. Mismatches partially stabilized the repeat tracts against expansion. Expansions were only detected when the primer was complementary to the repeat tract rather than the flanking sequence. The results imply that cellular environment and whether the growing strand contains a nick or gap are important factors for the expansion process in vivo.

Step-wise DNA relaxation and decatenation by NaeI-43K

Nae I protein was originally isolated for its restriction endonuclease properties. Nae I was later discovered to either relax or cleave supercoiled DNA, depending upon whether Nae I position 43 contains a lysine (43K) or leucine (43L) respectively. Nae I-43K DNA relaxation activity appears to be the product of coupling separate endonuclease and ligase domains within the same polypeptide. Whereas Nae I relaxes supercoiled DNA like a topoisomerase, even forming a transient covalent intermediate with the substrate DNA, Nae I shows no obvious sequence similarity to the topoisomerases. To further characterize the topoisomerase activity of Nae I, we report here that Nae I-43K changes the linking number of a single negatively supercoiled topoisomer of pBR322 by units of one and therefore is a type I topoisomerase. Positively supercoiled pBR322 was resistant to Nae I-43K. At low salt concentration Nae I-43K was processive; non-saturating amounts of enzyme relaxed a fraction of the DNA. At high salt concentration the same non-saturating amounts of Nae I-43K partially relaxed all the DNA in a step-wise fashion to give a Gaussian distribution of topoisomers, demonstrating a switch from a processive to a distributive mode of action. Nae I-43K decatenated kinetoplast DNA containing nicked circles, implying that Nae I-43K can cleave opposite a nick. The products of the reaction are decatenated nicked circles under both processive and distributive conditions. The behavior of Nae I-43K is consistent with that of a prokaryotic type I topoisomerase.

The domain organization of NaeI endonuclease: separation of binding and catalysis

NaeI is a remarkable type II restriction endonuclease. It must bind two recognition sequences to cleave DNA, forms a covalent protein-DNA intermediate, and is only 1 aa change away from topoisomerase and recombinase activity. The latter activities apparently derive from reactivation of a cryptic DNA ligase active site. Here, we demonstrate that NaeI has two protease-resistant domains, involving approximately the N-terminal and C-terminal halves of the protein, linked by a protease-accessible region of 30 aa. The domains were purified by cloning. The C-terminal domain was shown by gel mobility-shift assay to have approximately 8-fold lower DNA-binding ability than intact NaeI. Analytical ultracentrifugation showed this domain to be a monomer in solution. The N-terminal domain, which contains the catalytic region defined by random mutagenesis, did not bind DNA and was a mixture of different-sized complexes in solution implying that it mediates self-association. DNA greatly inhibited proteolysis of the linker region. The results identify the DNA-binding domain, imply that DNA cleavage and recognition are independent and separable, and lead us to speculate about a cleft-like structure for NaeI.

Effects on NaeI-DNA recognition of the leucine to lysine substitution that transforms restriction endonuclease NaeI to a topoisomerase: a model for restriction endonuclease evolution

Substituting lysine for leucine at position 43 (L43K) transforms NaeI from restriction endonuclease to topoisomerase and makes NaeI hypersensitive to intercalative anticancer drugs. Here we investigated DNA recognition by Nael-L43K. Using DNA competition and gel retardation assays, NaeI-L43K showed reduced affinity for DNA substrate and the ability to bind both single- and double-stranded DNA with a definite preference for the former. Sedimentation studies showed that under native conditions NaeI-L43K, like NaeI, is a dimer. Introduction of mismatched bases into double-stranded DNA significantly increased that DNA's ability to inhibit NaeI-L43K. Wild-type NaeI showed no detectable binding of either single-stranded DNA or mismatched DNA over the concentration range studied. These results demonstrate that the L43K substitution caused a significant change in recognition specificity by NaeI and imply that NaeI-L43K's topoisomerase activity is related to its ability to bind single-stranded and distorted regions in DNA. A mechanism is proposed for the evolution of the NaeI restriction-modification system from a topoisomerase/ligase by a mutation that abolished religation activity and provided a needed change in DNA recognition.

Changing a leucine to a lysine residue makes NaeI endonuclease hypersensitive to DNA intercalative drugs

A single amino acid change transforms restriction enzyme NaeI to a topoisomerase and recombinase (NaeI-L43K) that shows no sequence similarity to these protein families. This transformation appears to result from coupled endonuclease and ligase domains. To further elucidate the relationship between NaeI-L43K and the topoisomerase protein family, we studied the effect of the topoisomerase inhibitors on NaeI-L43K activity. The intercalative drugs amsacrine, ellipticine, and daunorubicin inhibited NaeI-L43K, whereas the nonintercalating drugs camptothecin, VP-16, and oxolinic acid did not. Ethidium bromide also inhibited NaeI-L43K, implying that intercalation is responsible for its inhibition. The effects of the intercalative drugs on the DNA cleavage steps of NaeI and NaeI-L43K were compared. The drugs hardly inhibited DNA cleavage by wild type NaeI but completely inhibited DNA cleavage by NaeI-L43K. This difference in inhibition demonstrates that the L43K amino acid change sensitized NaeI to these drugs. Low concentrations of the intercalative drugs, except for ethidium bromide, enhance production of topoisomerase--DNA covalent intermediates but inhibited production of the NaeI-L43K--DNA covalent intermediate. These results imply some unique differences between DNA relaxation by NaeI-L43K and DNA topoisomerase. Concomitant with studying inhibition of the cleavage intermediate, NaeI-L43K was found to covalently bond with the 5' end of the cleaved DNA strand.

O6-methylguanine-induced replication blocks

The ability of Klenow polymerase I, phage T7 polymerase (Sequenase), human polymerase alpha, and human polymerase beta to synthesize past (bypass) O6-methylguanine (O6-meG) lesions was studied in the presence of MgCl2 and MnCl2. An end-labeled 16-mer primer was annealed to the 3' end of gel-purified oligodeoxyribonucleotide templates (45-mers), each containing a single O6-meG in place of one G in the sequence -G1G2CG3G4T-. Extension products were analyzed by denaturing polyacrylamide gel electrophoresis and autoradiography. A fraction of the products extended by Klenow fragment terminated either opposite or one base before O6-meG located at sites 1 and 3. Termination occurred primarily one base before O6-meG located at sites 2 and 4. The remaining fractions that bypassed the lesions represented full-length product. In control reactions, the O6-meG-containing templates were annealed with complementary 45-mers, repaired with O6-alkylguanine DNA-alkyltransferase, annealed with an excess of labeled primer, and extended by Klenow fragment. Full-length extension of > 90% was observed with each template. Primer extension past O6-meG by DNA polymerase alpha and Sequenase was partially blocked in a manner which varied with the site of O6-meG in the template while primer extension by DNA polymerase beta was completely blocked (< 2% full length extension) with O6-meG at sites 1-4. Substitution of MnCl2 for MgCl2 in the reaction mixture greatly increased the bypass of O6-meG by Klenow fragment and DNA polymerase alpha but not Sequenase or DNA polymerase beta. The increased ability of Klenow fragment to bypass O6-meG in the presence of MnCl2 was found to result from an increased incorporation of G (O6-meG at sites 1 and 2) and A (O6-meG at sites 1, 2, and 3) opposite the lesion. The results indicate that O6-meG can block in vitro polymerization by several DNA polymerases and are consistent with the observed cytotoxic effects of methylating agents on mammalian cells.

DNA topoisomerase and recombinase activities in Nae I restriction endonuclease

Nae I endonuclease must bind to two DNA sequences for cleavage. Examination of the amino acid sequence of Nae I uncovered similarity to the active site of human DNA ligase I, except for leucine 43 in Nae I instead of the lysine essential for ligase activity. Changing leucine 43 to lysine 43 (L43K) changed Nae I activity: Nae I-L43K relaxed supercoiled DNA to yield DNA topoisomers and recombined DNA to give dimeric molecules. Interruption of the reactions of Nae I and Nae I-L43K with DNA demonstrated transient protein-DNA covalent complexes. These findings imply coupled endonuclease and ligase domains and link Nae I endonuclease to the topoisomerase and recombinase protein families.

DNA cleavage by NaeI: protein purification, rate-limiting step, and accuracy

NaeI endonuclease must bind two DNA sites for cleavage to occur. NaeI was purified to apparent homogeneity and used to determine the rate-limiting step for DNA cleavage and to measure NaeI's specificity for its cognate recognition site. Steady-state cleavage by NaeI in the presence of effector DNA (activated) gave values of 0.045 s-1 and 10 nM for kcat and KM for M13 DNA substrate, respectively, but values of 0.4 s-1 and 170 nM, respectively, for an M13 DNA fragment substrate. Single-turnover cleavage of M13 DNA demonstrated that DNA strand scission is not rate-limiting for turnover of NaeI. Transient kinetic analysis of M13 DNA cleavage by NaeI showed an initial burst of substrate cleavage that was proportional to NaeI concentration, implying that product release is rate-limiting for turnover of NaeI. The NaeI effector and substrate binding sites were found to prefer cognate over noncognate sequences by 10(3)-fold and at least 40-500-fold, respectively. kcat for noncognate recognition sequence was at least 10(6)-fold lower than that for cognate. The specificity of activated NaeI, as measured by kcat/KM, for noncognate recognition sequence was 10(8)-fold lower than that for cognate, and over 10(11)-fold lower when the decreased affinity for noncognate sequence at the effector binding site was taken into account. This specificity is approximately 10(4)-fold larger than for any other restriction enzyme measured.

Location of putative binding and catalytic sites of NaeI by random mutagenesis

Endonuclease NaeI is a prototype for an unusual group of type II restriction endonucleases that must bind two DNA recognition sequences to cleave DNA. The naeIR gene, expressed from a Ptac promotor construct, was toxic to Escherichia coli in the absence of NaeI-sequence specific methylases. The naeIR gene was mutagenized with N-methyl-N'-nitrosoguanidine; four classes of NaeI variants were isolated in the absence of protecting methylase activity. Class I variants (T60I, E70K) lacked detectable cleavage activity, but displayed good sequence-specific DNA binding. Class II variants (D95N, G141D) displayed 1-5% of the wild-type cleavage activity and normal DNA binding. Class III variants (G131E, G131R, G155D, G245E) displayed significantly attenuated cleavage and binding activities. Class IV variants (G197D, G214R/A219T, G236S, L241P, G245E, G245R, G250E, G270E) lacked both cleavage and binding activities. These results imply two amino acids (Thr-60, Glu-70) essential for catalysis. In addition, two domains are indicated in NaeI: one (Thr-60 to Gly-155) mediates substrate binding and catalysis, the other (Gly-197 to Gly-270) may mediate binding of the activating DNA sequence. Our results are compared with the active site residues of EcoRI, EcoRV, and BamHI.

Formation of a cleavasome: enhancer DNA-2 stabilizes an active conformation of NaeI dimer

Cleavage of DNA by NaeI-type restriction enzymes is stimulated by a DNA element with affinity for the activator site of the enzyme: a cleavage-enhancer DNA element. Measurements of the mobility of NaeI activity in comparison with protein standards on gel permeation columns and glycerol gradients demonstrated that NaeI, without enhancer, can form a 70,000 MW dimer. The dimer, however, is inactive: it could not cleave the "resistant" NaeI site in M13mp18 DNA in the absence of enhancer. In cleavage assays, enhancer stimulated either DNA nicking or DNA cleavage, depending upon NaeI concentration, and reduced the NaeI concentration required for the transition from nicking to cleavage activity. A gel mobility-shift assay of the interaction of NaeI with enhancer showed the formation of two complexes. Results using different sized DNAs and different percentage acrylamide gels for gel mobility-shift analysis implied that the two complexes were caused by NaeI monomer and dimer structures rather than one and two DNA binding. Dimer formation increased with the affinity of enhancer for NaeI. UV cross-linking "captured" the NaeI-enhancer complex; electrophoretic analysis of the cross-linked products showed NaeI dimer bound to enhancer. These results imply a model for cleavage enhancement in which enhancer binding stabilizes an active NaeI dimer conformation ("cleavasome") that cleaves both DNA strands before dissociating.

Changing endonuclease EcoRII Tyr308 to Phe abolishes cleavage but not recognition: possible homology with the Int-family of recombinases

Endonuclease EcoRII is one of a group of type II restriction enzymes, including Nael, Narl, BspMI, HpaII, and SacII, that require binding of an enhancer sequence to cleave DNA. Comparison of the EcoRII amino-acid sequence with the amino-acid consensus motifs that differentiate between recombinase families uncovered similarity between a 29 amino-acid sequence in the carboxyl end of EcoRII and the motif defining the integrase family of recombinases. This similarity implied that EcoRII tyrosine 308 should be involved in catalyzing hydrolysis of the scissile bond. Site-directed mutagenesis was used to mutate Tyr308 to Phe. The phenylalanine-substituted enzyme could not cleave T5 DNA under conditions in which wild-type enzyme completely cleaved this DNA. The Tyr308 to Phe mutation abolished cleavage activity but not specific binding to DNA. No evidence was found for the existence during the cleavage reaction of a covalent linkage between Tyr308 and DNA.

Nonidentical DNA-binding sites of endonuclease NaeI recognize different families of sequences flanking the recognition site

NaeI endonuclease uses a two-site binding mechanism to cleave substrate DNA: reaction-rate studies imply that occupancy of the second DNA site causes an allosteric change in the protein that enables DNA cleavage at the first site [Conrad, M., & Topal, M. D. (1989) Proc. Natl. Acad. Sci. U.S.A. 86, 9707-9711]. Measurements of relative binding affinities for 14-base-pair DNA fragments containing the NaeI recognition sequence GCCGGC and various flanking sequences showed that the two DNA-binding sites are not identical. G.C-rich flanking sequences were preferred by the activator binding site, whereas A.T-rich flanking sequences were preferred by the substrate binding site: GGGTGCCGGCAGGG was preferred 8-fold more by the activator site but 14-fold less by the substrate site than TTTCGCCGGCGTTT. Substitution of pyrimidine or 7-deazapurine for purine immediately 3' to GCCGGC reduced DNA affinity for only the activator site by up to 26-fold, implying that the activator DNA-binding site requires N-7 base contacts immediately flanking GCCGGC. The implications of nonidentical DNA-binding sites, one of which binds a specific DNA site to allosterically activate the other, are discussed.

Modified DNA fragments activate NaeI cleavage of refractory DNA sites

Endonuclease NaeI cleaves DNA using a two-site mechanism. The DNA-binding sites are nonidentical: they recognize different families of flanking sequences. A unique NaeI site that is resistant to cleavage resides in M13 double-stranded DNA. NaeI can be activated to cleave this site by small DNA fragments containing one or more NaeI sites. These activators are not practical for genetic engineering because unphosphorylated activators that are consumed during the cleavage of substrate give ends that may interfere with subsequent ligations. We show that a DNA fragment containing phosphorothioate linkages at the NaeI scissile bonds (S-activator) is not cleaved by NaeI, even though this S-activator binds to the substrate site. The S-activator activates NaeI to cleave M13 DNA under conditions that completely exhaust unsubstituted activator. These results demonstrate that activation is not coupled to cleavage of activator, that NaeI reverts to its inactive state soon after dissociation of the EA complex, and that S-activator makes for a nondepletable activator during prolonged incubations.

Ability of DNA and spermidine to affect the activity of restriction endonucleases from several bacterial species

Previous work has described the novel ability to modulate in vitro the activity of restriction endonuclease NaeI from Nocardia aerocoligenes by using cleavable DNA and spermidine [Conrad & Topal (1989) Proc. Natl. Acad. Sci. U.S.A. 86, 9707-9711]. In this paper we report the results of a study of 49 type II restriction enzymes from a variety of bacterial species. On the basis of the rates of cleavage observed, we found that in addition to expected cleavable sites a number of enzymes had slow and resistant cognate recognition sites. Resistant sites were identified for BspMI, NaeI, and NarI; slow sites were identified for HpaII, NaeI, and SacII. Cleavage of these sites was found to be significantly enhanced by the addition of cleavable DNA or spermidine. We demonstrate that for BspMI, as for NaeI, activator DNAs increased Vmax without altering Km, whereas for HpaII, NarI, and SacII activator DNAs decreased Km without changing Vmax. Comparison among the Kms for NaeI cleavage of several different substrates demonstrated that distant DNA sequences can affect DNA recognition by the activated enzyme. Our observations extend DNA activation of the Nocardia NaeI endonuclease to restriction endonucleases from Nocardia argentinensis (NarI), Bacillus species M (BspMI), Haemophilus parainfluenza (HpaII), and Streptomyces achromogenes (SacII). In addition, activation has now been found to affect slow as well as resistant recognition sites.

NaeI endonuclease binding to pBR322 DNA induces looping

Previous work has demonstrated the existence of both resistant and cleavable NaeI sites. Cleavable sites introduced on exogenous DNA can act in trans to increase the catalysis of NaeI endonuclease cleavage at resistant sites without affecting the apparent binding affinity of the enzyme for the resistant site [Conrad, M., & Topal, M. D. (1989) Proc. Natl. Acad. Sci. U.S.A. 86, 9707-9711]. This activation suggests allosteric regulation of NaeI cleavage by distant cis- and trans-acting sites in DNAs containing both resistant and cleavable sites. Plasmid pBR322 contains four NaeI sites, at least one of which is resistant to cleavage. Electron microscopy is used here to demonstrate that NaeI endonuclease simultaneously binds to multiple recognition sites in pBR322 DNA to form loops with NaeI protein bound at the loop's base. The maximum number of loops formed with a common base suggests four binding sites per enzyme molecule. Looping was inhibited by addition of enzyme-saturating amounts of double-stranded oligonucleotide containing an NaeI site, whereas another double-strand oligonucleotide without the NaeI site had no effect. The number of loops seen was not above background when double-stranded M13 DNA, which contains only a single NaeI recognition site, was used as substrate.

O6-methylguanine and A.C and G.T mismatches cause asymmetric structural defects in DNA that are affected by DNA sequence

Mismatched and modified base pairs are central to questions of DNA mutation and repair. NMR and X-ray crystallography of mispairs indicate little to no local helical distortion, but these techniques are not sensitive to more global distortions of the DNA molecule. We used polyacrylamide gel electrophoresis and thermal denaturation to examine A.C, G.T, and O6-methylG.T and O6-methylG.C mismatches synthesized in place of either of two adjacent G.C base pairs in synthetic DNA duplexes. Substitution for G.C at either position decreased the stability of the duplex; O6-methylguanine was more destabilizing in place of the 5'G than in place of the 3'G. Comparisons between polymers synthesized so that lesions occurred regularly spaced on the same side of the helix and polymers synthesized so that the lesions alternated from side to side on the helix showed that these lesions introduced helical distortion composed of (i) a symmetric frictional component, probably caused by localized bubble formation, and (ii) an asymmetric component indicative of a more global effect on the DNA molecule. Comparisons between these effects at the two adjacent positions show that the extent of structural perturbation depends on sequence context.

O6-methylguanine in place of guanine causes asymmetric single-strand cleavage of DNA by some restriction enzymes

The interactions of restriction enzymes with their cognate DNA recognition sequences present a model for protein-DNA interactions. We have investigated the effect of O6-methylguanine on restriction enzyme cleavage of DNA; O6-methylguanine is a carcinogenic lesion and a structural analogue of the biological restriction inhibitor N6-methyladenine. O6-Methylguanine was synthesized into oligonucleotides at unique positions. The oligonucleotides were purified and analyzed by high-pressure liquid chromatography to assure that, within the limits of our detection, O6-methylguanine was the only modified base present. These oligonucleotides were annealed with their complement so that cytosine, and in one case thymine, opposed O6-methylguanine. DNA cleavage by restriction enzymes that recognize a unique DNA sequence, HpaII, HhaI, HinPI, NaeI, NarI, PvuII, and XhoI, was inhibited by a single O6-methylguanine in place of guanine (adenine for PvuII) within the appropriate recognition sequences. However, only the modified strand was nicked by HpaII, NaeI, and XhoI with O6-methylguanine at certain positions, indicating asymmetric strand cleavage. For all the restriction enzymes studied but AhaII, BanI, and NarI, lack of double- or single-strand cleavage correlated with inability of the O6-methylguanine-containing recognition sequence to measurably bind enzyme. None of the restriction enzymes studied were inhibited by O6-methylguanine outside their cognate recognition sequences.

DNA and spermidine provide a switch mechanism to regulate the activity of restriction enzyme Nae I

Sequence-specific DNA-protein interactions are basic to DNA function. To better understand these interactions, we studied the effect of position on cleavage of DNA by the type II restriction enzyme (EC 3.1.21.4) Nae I. We discovered two classes of Nae I restriction sites: sites susceptible and sites resistant to cleavage. Kinetic analysis showed that Nae I was activated by DNA containing cleavable Nae I sites to rapidly cleave resistant Nae I sites by a noncompetitive mechanism with a Km for substrate DNA of about 2 nM and a KA for activating DNA of about 6 nM; activation increased catalysis but not substrate binding. Deletion mutagenesis in vitro showed that sequences flanking the Nae I recognition site were responsible for the differences between activating and nonactivating Nae I sites. The polyamine spermidine had a dramatic effect on the interaction of Nae I with DNA; in the presence of 1 mM spermidine, resistant sites were cleaved rapidly and cleavable DNA inhibited cleavage. The direct regulation of enzymatic activity by DNA sequences in trans, and the modulation of this regulation by a polyamine that is sensitive to the cell cycle, provides a regulatory switch mechanism. The implications of this switch for biological control functions are discussed.

Repair of O6-methylguanine by ABC excinuclease of Escherichia coli in vitro

O6-Methylguanine, the major mutagenic product of methylnitroso compounds, was previously thought to be repaired exclusively by alkyltransferases I and II. Using synthetic substrates that contain O6-methyl-guanine at defined positions, we demonstrate that the nucleotide excision repair enzyme of Escherichia coli, ABC excinuclease, also repairs DNA containing this adduct. We show that the ABC excinuclease binds specifically to the modified DNA and produces incisions at the eight phosphodiester bond 5' and at the fifth or sixth phosphodiester bond 3' to the modified guanine.

Excision repair of O6-methylguanine synthesized at the rat H-ras N-methyl-N-nitrosourea activation site and introduced into Escherichia coli

O6-methylguanine (O6-methylG) is believed to be the premutagenic lesion responsible for mutational activation of the H-ras proto-oncogene in rats treated with N-methyl-N-nitrosourea (MNU). Research on the repair of O6-methylG has primarily focused on the methyltransferases. Potentially, other repair proteins may be involved in repair of O6-methylG. We have investigated the effect of Escherichia coli UvrABC excision repair on O6-methylG synthesized at the rat H-ras MNU activation site in a partial rat H-ras sequence constructed in an M13mp vector. An oligonucleotide self-selection technique was used to identify progeny phage containing DNA replicated from the O6-methylG-containing strand. We found that excision repair can help protect against mutation by O6-methylG at the rat H-ras MNU activation site.

Insertion and extension of acyclic, dideoxy, and ara nucleotides by herpesviridae, human alpha and human beta polymerases. A unique inhibition mechanism for 9-(1,3-dihydroxy-2-propoxymethyl)guanine triphosphate

The ability of human alpha and beta DNA polymerases and herpes simplex virus type 2 (HSV-2) and human cytomegalovirus (HCMV) DNA polymerases to insert and extend several nucleotide analogs has been investigated using a variation of Sanger-Coulson DNA sequencing technology. The analogs included the triphosphates of two antiviral nucleosides with incomplete sugar rings: 9-(1,3-dihydroxy-2-propoxymethyl)guanine (dhpG) and 9-(2-hydroxyethoxymethyl)guanine (acyG or acyclovir), as well as dideoxy and arabinosyl nucleoside triphosphates. Three pairs of contrasting behaviors were found, each pair distinguishing the two human polymerases from the two viral ones: first, extension behavior with araNTPs; second, insertion/extension behavior with dhpGTP; and third, the relative preference for insertion of ddGTP versus acyGTP. The relative level of insertion of the nucleotide analogs by HCMV and HSV-2 DNA polymerases was dhpGTP greater than (acyGTP and araNTP) greater than ddGTP, whereas by human alpha polymerase it was araATP greater than ddGTP much greater than (acyGTP and dhpGTP) and by human beta polymerase it was (araATP and ddGTP) much greater than (acyGTP and dhpGTP). Evidence is presented for three mechanisms of inhibition by extendible nucleotides (of dhp and ara types) exhibiting frequent internalization: araATP acted as a simple pseudoterminator of alpha and beta polymerases, but was easily extended past singlet sites by Herpesviridae polymerases and only stalled at sites requiring two or more araATP insertions in a row. Herpesviridae polymerases stalled after adding dhpGMP and one additional nucleotide, suggesting that polymerase translocation problems may be a factor in polymerase inhibition by modified sugar nucleotide analogs. The amino acid sequence of the human alpha DNA polymerase, which is acyGTP resistant, was found to vary by one amino acid from the amino sequences of the Herpesviridae polymerases in a region of significant similarity and probable functional homology. Amino acid differences at that same site differentiate acyclovir-resistant HSV-1 mutants from the acyclovir-sensitive HSV-1 wild type.

DNA damage at thymine N-3 abolishes base-pairing capacity during DNA synthesis

3-Methylthymine was synthesized into DNA copolymers and deoxynucleoside triphosphate to study its effect on DNA synthesis by the Klenow fragment of Escherichia coli polymerase I and avian myeloblastosis virus reverse transcriptase. Both polymerases were greatly inhibited by template 3-methylthymine. In response to 3-methylthymine, misincorporation of dTTP increased slightly, but occurred only at low levels consistent with spontaneous misincorporation in vitro. Surprisingly, template 3-methylthymine resulted in a striking decrease in background misincorporation, relative to normal incorporation by the Klenow fragment, of dGTP and, to a lesser extent, of dATP and dCTP. The incorporation of 3-methyl-dTTP into DNA was studied using DNA sequencing technology. The Klenow fragment failed to incorporate 3-methyl-dTTP even at 1 mM. Reverse transcriptase incorporated 3-methyl-dTTP opposite adenine, cytosine, and thymine, but at only about 1/40,000th the efficiency of complementary deoxynucleoside triphosphate incorporation. Furthermore, synthesis generally stalled at sites of 3-methyl-thymine incorporation. From these results, we conclude that damage at the central hydrogen-bonding position of thymine abolishes its base-pairing capabilities during DNA synthesis.

Induction of deletion and insertion mutations by 9-aminoacridine. An in vitro model

The ability of 9-aminoacridine to induce mutagenic lesions during DNA replication in vitro was investigated. The ampicillinase gene of pBR322 was replicated in vitro in the presence of 9-aminoacridine. Transfection of the replicated DNA into Escherichia coli gave Amps mutants. Determination of the base changes in 76 of these mutants indicated that the spectrum of mutations induced by 9-aminoacridine was consistent with its action in vivo. Both large (407-base) and small (1- and 2-base) deletions were induced at repetitive sequences. The frequency of deletion mutations depended on the identity of the base deleted and sequences surrounding the deletions. The characteristics of the frameshift mutations induced were consistent with the interactions of 9-aminoacridine with DNA. These results establish that 9-aminoacridine can induce frameshift mutations during the replication process and provide an in vitro model of frameshift induction for mechanistic studies.

O6-methylguanine mutation and repair is nonuniform. Selection for DNA most interactive with O6-methylguanine

Mutations were induced in the ampicillinase gene of a bacteriophage f1/pBR322 chimera both by incorporation of O6-methyl-dGTP opposite T during DNA replication in vitro and by site-directed mutagenesis using O6-methylguanine-containing oligonucleotides. After passage of the DNA through Escherichia coli, analysis of 151 O6-methyl-dGTP-induced mutations indicated a significantly greater number of unmutated mutation sites than expected, whereas the mutated sites generally fit a Poisson distribution. The unmutated sites are assumed to be caused by the inability of some sequences to tolerate the presence of a tetrahedral methyl group within the confines of a Watson-Crick helix (Toorchen, D., and Topal, M.D. (1983) Carcinogenesis 4, 1591-1597). A consensus of the DNA sequences surrounding unmutated mutation sites was derived. The consensus sequence had significant similarity to the region of the rat Harvey ras oncogene containing the N-methyl-N-nitrosourea activated site for transformation (Zarbl, H., Sukumar, S., Arthur, A. V., Dionisio, M.-Z., and Barbacid, M. (1985) Nature 315, 382-385). We propose that direct alkylation at O6 of a guanine present within the consensus sequence may produce a DNA conformation less subject to repair. Mutation by O6-methylguanine-containing oligonucleotides demonstrated that repair of the O6-methylguanine lesions varied at least 3-4-fold with position of the lesion.

Mutagenesis by incorporation of alkylated nucleotides

The cellular DNA precursor pool was shown to be a target for N-methyl-N-nitrosourea, a potent mutagen and carcinogen. O6medGTP, a product of this interaction, was chemically synthesized and shown to be incorporated into DNA in vitro by Klenow E. coli pol I and phage T4 DNA polymerases. O6medGTP incorporated predominantly opposite T template residues and to a lower extent opposite C. At some loci incorporation of O6medGTP caused DNA synthesis arrest. The significance of the behavior of O6medGTP for mutagenesis in vivo is discussed.

O6-Methylguanine-DNA transmethylase converts O6-methylguanine thymine base pairs to guanine thymine base pairs in DNA

O6-Methylguanine lesions in natural and synthetic DNAs were studied as substrates for the O6-methylguanine-DNA methyltransferase in vitro. The results indicate that O6-methylguanine is repaired by this protein when base paired to T as well as to C in double-stranded DNA. The results also indicate that O6-methylguanine is less subject to repair than previously reported when it is in single-stranded DNA and suggest that O6-methylguanine may not be repaired when it is at the 3' terminus.

Molecular mechanisms of chemical mutagenesis: 9-aminoacridine inhibits DNA replication in vitro by destabilizing the DNA growing point and interacting with the DNA polymerase

9-Aminoacridine was found to inhibit dNTP incorporation into DNA homopolymer duplexes by phage T4 DNA polymerase in vitro. Systematic variation of the molar ratio of 9-aminoacridine to DNA, to DNA polymerase, and to DNA precursors demonstrated that this inhibition at 9-aminoacridine concentrations below 10 microM was mainly due to interaction of 9-aminoacridine with the DNA and suggested that the basis for the preferential inhibition of incorrect precursor incorporation was destabilization of the DNA growing point. Consistent with destabilization, 9-aminoacridine stimulated the hydrolysis of correctly base paired DNA by the 3'-5' exonuclease activity of phage T4 DNA polymerase. This is the first indication to my knowledge that an intercalating dye destabilizes the DNA growing point, whereas it raises the overall Tm of the DNA. At 9-aminoacridine concentrations above 10 microM overall incorporation of dNTPs was inhibited by 9-aminoacridine interaction with the DNA polymerase. A possible explanation for the induction of both deletion and addition frameshift mutations by 9-aminoacridine during DNA biosynthesis is discussed in light of growing-point destabilization.

Mechanism of mutagenesis by O6-methylguanine

O6-methylguanine (O6meG) lesions of double-stranded DNA have been associated with mutation and neoplastic transformation. These lesions can, in principle, be produced by at least three different mechanisms: direct alkylation of G X C base pairs in double-stranded DNA; alkylation of guanine residues in single-stranded regions of DNA associated with replication forks; and alkylation of the DNA precursor pool followed by incorporation of O6-methyl deoxyguanosine triphosphate (O6-medGTP) during DNA replication. DNA biosynthesis subsequent to all three events will generate predominantly O6-meG X T base pairs as O6meG preferentially pairs with T. We show here that O6meG X T base pairs are mutagenic; that transalkylase repair has a direct role in the generation of mutations induced by alkylated pool nucleotides; and that the Escherichia coli mismatch repair system is capable of repairing mutagenic G X T intermediates.

Mechanisms of chemical mutagenesis and carcinogenesis: effects on DNA replication of methylation at the O6-guanine position of dGTP

The incorporation of O6-methyl-dGTP during DNA replication in vitro by 'Klenow' E. coli pol I was determined. O6-Methyl-dGTP was found to: (i) incorporate opposite T and C template residues, with a greater than 20-fold preference for T, and (ii) arrest DNA synthesis when incorporated in place of dATP at all but pyrimidine-rich growing-strand sequences. The significance of O6-methyl-dGTP incorporation during DNA biosynthesis in vivo for mutagenesis and carcinogenesis is discussed.

Products of bacteriophage T4 genes 32 and 45 improve the accuracy of DNA replication in vitro

The six "accessory" proteins of the bacteriophage T4 specified by replication genes 32, 41, 44, 45, 61, and 62 were studied for their ability to enhance the accuracy with which phage T4 DNA polymerase (product of gene 43) replicates synthetic homopolymer duplexes in vitro. Two of these proteins, gene 32-protein (helix-destabilizing protein) and gene 45-protein, inhibited the selection of incorrect, but not correct, precursors, at the growing strand end. Gene 32-protein is shown to enhance replication fidelity by interacting with the DNA, whereas gene 45-protein exerts its fidelity-enhancing effect by interacting with the DNA polymerase. This is the first example to our knowledge of a DNA polymerase's accuracy being altered through interaction with another protein. Possible mechanisms by which gene 32- and gene 45-protein act to enhance replication fidelity are discussed.

Reaction of dATP with N-methyl-N-nitrosourea in vitro

Extensive methylation was found upon reaction of N-methyl-N-nitrosourea with dATP. The products of this reaction were purified by repeated anion exchange column chromatography and were found to consist of adenine deoxyribonucleotides methylated on the base moiety, terminal phosphate, or both. Products methylated on the adenine ring were identified by co-migration of acid-hydrolyzed samples with authentic standards on reverse phase high pressure liquid chromatography. Products methylated on the sugar phosphate moiety were identified by digestion with snake venom phosphodiesterase, alkaline phosphatase, or both followed by polyethyleneimine cellulose thin layer chromatography. The results demonstrate production of gamma-phosphate-methyldATP, beta-phosphate-methyl-dADP, 1-methyldATP, and gamma-phosphate-methyl-1-methyldATP as well as the relatively unstable products 3-methyldATP and gamma-phosphate-methyl-3-methyl-dATP. The identities and amounts of products formed during this reaction in vitro are consistent with our finding that cellular deoxyribonucleotide pools are a significant target for N-methyl-N-nitrosourea (Topal, M. D., and Baker, M. S. (1982) Proc. Natl. Acad. Sci. U.S.A. 79, 2211-2215).

DNA precursors in chemical mutagenesis: a novel application of DNA sequencing

Recently, we have shown that deoxyribonucleoside residues in the cellular DNA precursor pool are generally more susceptible to methylation than are residues within the DNA duplex. The N-1 position of adenosine, for example, was found to be at least 13,000 times more susceptible to methylation by N-methyl-N-nitrosourea (MNU) than the same site in the DNA. These results suggest that potential sites for alkylation in the double-strand duplex are relatively inaccessible to direct alkylation in vivo. Many of these sites are probably protected from alkylation not only by their position in the interstices of the DNA helix, but also by further in vivo 'packaging' of the DNA in chromatin. We have now used DNA sequencing to demonstrate the incorporation properties of products of the reaction of MNU with dATP and of deoxy-N4-hydroxycytidine triphosphate during DNA replication in vitro by phage T4 DNA polymerase and the 'Klenow' fragment of Escherichia coli pol I. The results suggest that DNA precursor nucleotides due to their greater availability for alkylation, may offer routes for the introduction of alkylated residues into double-stranded DNA.

DNA precursor pool: a significant target for N-methyl-N-nitrosourea in C3H/10T1/2 clone 8 cells

Synchronized C3H/10T1/2 clone 8 cells were treated in vitro with a nontoxic dose of N-methyl-N-nitrosourea during their S phase. Chromatographic isolation of the deoxyribonucleotide DNA precursor pool and measurement of the precursor content per cell showed that a nucleic acid residue in the precursor pool is 190-13,000 times more susceptible to methylation than a residue in the DNA duplex, depending on the site of methylation. This conclusion comes from measurements indicating that, for example, the N-1 position of adenine in dATP is 6.3 times more methylated than the same position in the DNA, even though the adenine content of the pool is only a fraction (0.0005) of the adenine content of the DNA helix. The comparative susceptibility between pool and DNA was found to vary with the site of methylation in the order the N-1 position of adenine greater than phosphate greater than the N-3 position of adenine greater than the O6 position of guanine greater than the N-7 position of guanine. The significance of these results for chemical mutagenesis and carcinogenesis is discussed.

DNA in proximity to the site of replication is preferentially alkylated in S phase 10T1/2 cells treated with N-methyl-N-nitroso-urea

Replicating DNA is more susceptible to modification by N-methyl-N-nitrosourea (MNU), a spontaneously active methylating agent, than bulk DNA. This conclusion is supported by results from two different experimental approaches. First, synchronized C3H 10T1/2 clone 8 cells were treated in S phase with MNU and DNA replicated during the period of treatment was separated from bulk DNA. This was done by digesting the purified DNA with restriction enzymes and retaining the replication fork-associated DNA in nitro-cellulose filters. Second, synchronized C3H 10T1/2 clone 8 cells were exposed to 5-bromodeoxyuridine and [3H]MNU and the density-labelled, replicated DNA was separated in CsCl gradients. Both methods show 2.6 to 5.0 times more [3H]methyl adducts per nucleotide residue associated with replicating DNA than that expected from random methylation. These experiments were done at low MNU concentrations (0.018-0.115 mM) that did not cause any detectable inhibition of DNA synthesis or stimulation of repair replication in 10T1/2 cells.

Molecular basis for substitution mutations. Effect of primer terminal and template residues on nucleotide selection by phage T4 DNA polymerase in vitro

The DNA-dependent conversion of incorrect deoxynucleoside triphosphate precursors to monophosphates (turnover) by bacteriophage T4 DNA polymerase was determined using either poly(dA) x (dT) or poly(dG) x (dC) homopolymer templates. Competition between correct and incorrect triphosphates for incorporation into DNA, and the use of chain-terminating dideoxynucleoside triphosphates enabled us to determine the amount of turnover occurring at the end of each strand of the homopolymer duplex (e.g. amount of turnover of dATP occurring at the 3'-OH of poly(dG) and the 3'-OH of poly(dC)). These determinations suggest that nearest neighbor interactions between incoming dNTPs and the growing strand terminal residue play a major role in the occurrence of substitution errors during DNA synthesis in vitro byDNA polymerase. When considered together with existing evidence from studies of turnover (Gillin, F. D., and Nossal, N. G. (1976) J. Biol. Chem. 251, 5225-5232) and direct incorporation (Hall, Z. W., and Lehman, I. R. (1968) J. Mol. Biol. 36, 321-333) these results demonstrate that pyrimidine-pyrimidine and purine-purine as well as purine-pyrimidine oppositions have a role in error production at least during DNA replication in vitro. The implications of these results for the role of the "accessory" replication proteins in maintaining accuracy during the DNA biosynthetic process are discussed.

Fluorescence of terbium ion-nucleic acid complexes: a sensitive specific probe for unpaired residues in nucleic acids

The interaction of the lanthanide cation Tb3+ with the phosphate moieties of non-hydrogen-bonded residues of nucleic acids has been shown to result in substantial enhancement of the fluorescence of this cation. The excitation spectrum for this fluorescence is characteristic of the base moiety of the residue to which the Tb3+ is bound, while the emission spectrum is characteristic of the cation itself. The intensity of the fluorescence enhancement, however, is dependent upon the base of the ligand moiety, with G inducing the strongest enhancement, C and T rather less, and A very little. Base-paired residues of nucleic acids induce no such fluorescence enhancement, even though the cation is more tightly bound to double helical regions than to residues in single strands. The enhancement of Tb3+ fluorescence upon binding to non-hydrogen-bonded residues therefore provides a highly specific conformational probe for such residues. This probe has been exploited successfully for the purpose of analyzing the kinetics of reassociation of DNAs (C0t analysis) and as a specific stain for single-strand DNA bands on polyacrylamide gels.

Base pairing and fidelity in codon-anticodon interaction

Base pairing in codon-anticodon interaction has been investigated in order to understand the basis on which particular base pairs have been selected for or against participation at the wobble position and the basis for codon-anticodon infidelity.

Complementary base pairing and the origin of substitution mutations

On the basis of chemical considerations and model building, the Watson-Crick concept of complementary base pairing is extended to a wider range of DNA pairs that A-T and G-C (including A-C, G-T, A-A, G-G and G-A) by invoking imino or enol tautomers (or protonated species) and synisomers. The virtual absence of these additional base pairs from DNA is explained in terms of the low frequency with which these unfavoured forms occur and the two-step mechanism of DNA synthesis, whereby residues are first incorporated by the DNA polymerase and then checked. This base-pairing hypothesis is used to explain the origin, nature and level of spontaneous substitution mutations, their enhancement by base analogues, and the unique effects of certain mutator alleles.