DNA substrate structural requirements for the exonuclease and polymerase activities of procaryotic and phage DNA polymerases

A DNA duplex covalently cross-linked between specific bases has been prepared. This and similar duplexes are substrates for the polymerase and exonuclease activities of the Klenow fragment of Escherichia coli DNA polymerase I and T4 and T7 DNA polymerases. The action of Klenow fragment on these duplexes indicates that the polymerase site does not require that the DNA duplex undergo strand separation for activity, whereas the exonuclease site requires that at least four base pairs of the primer strand must melt out for the exonucleolytic removal of nucleotides from the primer terminus. The exonucleolytic action of T4 and T7 DNA polymerases requires that only two and three bases respectively melt out for excision of nucleotides from the primer terminus. Klenow fragment and T4 DNA polymerase are able to polymerize onto duplexes incapable of strand separation, whereas T7 DNA polymerase seems to require that the primer terminus be at least three bases from the cross-linked base pair. A DNA duplex with a biotin covalently linked to a specific base has been prepared. In the presence of the biotin binding protein avidin, the exonucleolytic activity of Klenow fragment requires that the primer terminus be at least 15 base pairs downstream from the base with the biotin-avidin complex. On the other hand, the polymerase activity of Klenow fragment required that the primer terminus be at least six base pairs downstream from the base with the biotin-avidin complex. These results suggest that the polymerase and exonuclease sites of Klenow are physically separate in solution and exhibit different substrate structural requirements for activity.     

Synthesis of new modified DNAs by hyperthermophilic DNA polymerase: substrate and template specificity of functionalized thymidine analogues bearing an sp3-hybridized carbon at the C5 alpha-position for several DNA polymerases

Novel thymidine analogue triphosphates, which have an sp3-hybridized carbon at the C5 alpha-position with amino-linker arms, a methyl ester, or a carboxyl group at the C5 sidearm, were good substrates for primer-extension reactions by DNA polymerase from Pyrococcus kodakaraensis (KOD Dash DNA polymerase), yielding exclusively full-length products. The resulting modified DNA was further allowed to react with a functional molecule such as fluorescein isothiocyanate. By contrast, only truncated products were formed from the thymidine analogue substrate bearing the amino-linker arm or the negatively charged carboxyl group using Taq, Tth DNA polymerase, or DNA polymerase I from E. coli (Klenow fragment). The results indicate either that the thymidine analogue was not accepted by the enzymes, or that the polymerases could not extend the products, once the analogue had been incorporated, depending on the type of the analogue. A conventional thymidine analogue bearing an aminopropenyl group at the C5-position was accepted by all enzymes, among which KOD Dash DNA polymerase showed the highest activity for the polymerization with this analogue. Templates bearing the thymidine analogues in place of one thymidine residue were read by KOD Dash, Taq, Tth DNA polymerases, and the Klenow fragment giving the full-length product. KOD Dash DNA polymerase could expand structural diversities of substrates that can be used to prepare modified DNAs.     

Role of base stacking and sequence context in the inhibition of yeast DNA polymerase eta by pyrene nucleotide

The Y family DNA polymerase yeast pol eta inserts pyrene deoxyribose monophosphate (dPMP) in preference to A opposite an abasic site, the 3'-T of a thymine dimer, and a normal T with almost equal efficiency. In contrast, pol A family polymerases such as Klenow fragment and T7 DNA polymerase only insert dPMP efficiently opposite an abasic site and the 3'-T of a thymine dimer but not opposite undamaged DNA. Pyrene nucleotide is also an efficient chain-terminating inhibitor of DNA synthesis by pol eta but not by Klenow fragment or T7 DNA polymerase. To better understand the origin of the efficiency and sequence specificity of dPMP insertion by pol eta, the kinetics of dPMP insertion opposite various templates have been determined. In one sequence context, the efficiency of dPMP insertion increases 4.6-fold opposite G < A < T < C, suggesting that the templating nucleotide modulates dPMP insertion efficiency by having to destack prior to dPTP binding. The efficiency of insertion of dPMP opposite T in the same sequence context increases 7-fold for primers terminating in G < A < C < T and is similar to that observed for nontemplated blunt-end extension, suggesting that stacking interactions between the pyrene and the primer terminus are also important. On heterogeneous templates, the average selectivity for dPMP insertion relative to the complementary dNMP decreases in the order of dAMP > dGMP > dTMP > dCMP, from a high of 5.8 when dAMP is to be inserted following a T to a low of 0.5 when dCMP is to be inserted following a C. The relative preference for dPMP insertion at a given site can be largely explained by the energetic cost of destacking the templating base and stacking of pyrene nucleotide relative to that of stacking and base pairing the complementary nucleotide. Thus, pyrene nucleotide represents a novel class of nucleotide-based chain-terminating DNA synthesis inhibitors whose base portion consists of a hydrophobic, non-hydrogen bonding, base-pair mimic.     

Mechanism of in vitro expansion of long DNA repeats: effect of temperature, repeat length, repeat sequence, and DNA polymerases.

Studies of sequence repeat expansions from duplexes consisting of DNA repeat sequences greater than three bases are currently lacking. These studies are needed in order to gain a better understanding of DNA expansions in general and as a first step in understanding expansions of longer sequence repeats that have been implicated in human diseases. We have undertaken an in vitro study of tetranucleotide, hexanucleotide, and octanucleotide repeat expansions from short DNA duplexes using Taq DNA polymerase. Expansions of hexanucleotide repeats were also studied with the Klenow fragment of DNA polymerase I and with T4 DNA polymerase. Studies with Taq DNA polymerase show that expansions occur more readily as the length of the repeat sequence decreases but are generally more efficient at reaction temperatures closer to the melting point of the starting duplex. A mechanism for the observed expansions with Taq DNA polymerase is proposed that does not invoke strand slippage or DNA structure. Studies at 37 degrees C with Klenow pol I and T4 DNA polymerase indicate that the template-switching and/or strand-displacement activities of the polymerases used can play a major role in the apparent in vitro expansions of short repetitive DNA duplexes.     

Fapyadenine is a moderately efficient chain terminator for prokaryotic DNA polymerases

Hypoxanthine?xanthine oxidase?Fe3+?ethylenediaminetetraacetate (EDTA) was used to modify ss M13 mp18 phage DNA. The dominant base modifications found by GC/IDMS-SIM were FapyGua, FapyAde, 8-hydroxyguanine, and thymine glycol. Analysis of in vitro DNA synthesis on oxidatively modified template by three DNA polymerases revealed that T7 DNA polymerase and Klenow fragment of polymerase I from Escherichia coli were blocked mainly by oxidized pyrimidines in the template whereas some purines that were easily bypassed by the prokaryotic polymerases constituted a block for DNA polymerase beta from calf thymus. DNA synthesis by T7 polymerase on poly(dA) template, where FapyAde content increased 16-fold on oxidation, yielded a final product with a discrete ladder of premature termination bands. When DNA synthesis was performed on template from which FapyAde, FapyGua, and 8OHGua were excised by the Fpg protein new chain terminations at adenine and guanine sites appeared or existing ones were enhanced. This suggests that FapyAde, when present in DNA, is a moderately toxic lesion. Its ability to arrest DNA synthesis depends on the sequence context and DNA polymerase. FapyGua might possess similar properties.     

Effect of the (+)-CC-1065-(N3-adenine)DNA adduct on in vitro DNA synthesis mediated by Escherichia coli DNA polymerase.

(+)-CC-1065 is a potent antitumor antibiotic produced by Streptomyces zelensis. Previous studies have shown that the potent cytotoxic and antitumor activities of (+)-CC-1065 are due to the ability of this compound to covalently modify DNA. (+)-CC-1065 reacts with duplex DNA to form an N3-adenine DNA adduct which lies in the minor groove of the DNA helix overlapping with a 5-base-pair region. As a consequence of covalent modification with (+)-CC-1065, the DNA helix bends into the minor groove and also undergoes winding and stiffening [Lee, C.-S., Sun, D., Kizu, R., & Hurley, L. H. (1991) Chem. Res. Toxicol. 4, 203-213]. In the studies described here, in which we have constructed site-directed DNA adducts on single-stranded DNA templates, we have shown that (+)-CC-1065 and select synthetic analogues, which have different levels of cytotoxicity, all show strong blocks against progression of Klenow fragment, E. coli DNA polymerase, and T4 DNA polymerase. The inhibition of bypass of drug lesions by polymerase could be partially alleviated by increasing the concentration of dNTPs and, to a small extent, by increasing polymerase levels. Klenow fragment binds equally well to a DNA template adjacent to a drug modification site and to unmodified DNA. These results taken together lead us to suspect that it is primarily inhibition of base pairing around the drug modification site and not prevention of polymerase binding that leads to blockage of DNA synthesis.(ABSTRACT TRUNCATED AT 250 WORDS)     

Interaction of Escherichia coli DNA polymerase I with azidoDNA and fluorescent DNA probes: identification of protein-DNA contacts

The synthesis of an azidoDNA duplex and its use to photolabel DNA polymerases have been previously described (Gibson & Benkovic, 1987). We now present detailed experiments utilizing this azidoDNA photoprobe as a substrate for Escherichia coli DNA polymerase I (Klenow fragment) and the photoaffinity labeling of the protein. The azidoDNA duplex is an efficient substrate for both the polymerase and 3'----5' exonuclease activities of the enzyme. However, the hydrolytic degradation of the azido-bearing base is dramatically impaired. On the basis of the ability of these duplexes to photolabel the enzyme, we have determined that the protein contacts between five and seven bases of duplex DNA. Incubation of azidoDNA with the Klenow fragment in the presence of magnesium results in the in situ formation of a template-primer with the azido-bearing base bound at the polymerase catalytic site of the enzyme. Photolysis of this complex followed by proteolytic digestion and isolation of DNA-labeled peptides results in the identification of a single residue modified by the photoreactive DNA substrate. We identify Tyr766 as the modified amino acid and thus localize the catalytic site for polymerization in the protein. A mansyl-labeled DNA duplex has been prepared as a fluorescent probe of protein structure. This has been utilized to determine the location of the primer terminus when bound to the Klenow fragment. When the duplex contains five unpaired bases in the primer strand of the duplex, the primer terminus resides predominantly at the exonuclease catalytic site of the enzyme. Removal of the mismatched bases by the exonuclease activity of the enzyme yields a binary complex with the primer terminus now bound predominantly at the polymerase active site. Data are presented which suggest that the rate-limiting step in the exonuclease activity of the enzyme is translocation of the primer terminus from polymerase to exonuclease catalytic sites.     

Biochemical behavior of N-oxidized cytosine and adenine bases in DNA polymerase-mediated primer extension reactions

To clarify the biochemical behavior of 2'-deoxyribonucleoside 5'-triphosphates and oligodeoxyribonucleotides (ODNs) containing cytosine N-oxide (C(o)) and adenine N-oxide (A(o)), we examined their base recognition ability in DNA duplex formation using melting temperature (T(m)) experiments and their substrate specificity in DNA polymerase-mediated replication. As the result, it was found that the T(m) values of modified DNA-DNA duplexes incorporating 2'-deoxyribonucleoside N-oxide derivatives significantly decreased compared with those of the unmodified duplexes. However, single insertion reactions by DNA polymerases of Klenow fragment (KF) (exo(-)) and Vent (exo(-)) suggested that C(o) and A(o) selectively recognized G and T, respectively. Meanwhile, the kinetic study showed that the incorporation efficiencies of the modified bases were lower than those of natural bases. Ab initio calculations suggest that these modified bases can form the stable base pairs with the original complementary bases. These results indicate that the modified bases usually recognize the original bases as partners for base pairing, except for misrecognition of dATP by the action of KF (exo(-)) toward A(o) on the template, and the primers could be extended on the template DNA. When they misrecognized wrong bases, the chain could not be elongated so that the modified base served as the chain terminator.     

A multisite-directed mutagenesis using T7 DNA polymerase: application for reconstructing a mammalian gene

A method to introduce multiple mutations and to reconstruct genes, using a single oligodeoxyribonucleotide and DNA polymerase with high processivity, such as modified T7 DNA polymerase [Tabor and Richardson, Proc. Natl. Acad. Sci. USA 84 (1987a) 4767-4771], is described. A eukaryotic cDNA, coding for porcine growth hormone (pGH), was reconstructed in this study to delete 75 bp and to introduce a G----A transition. The deletion removes 75 bp and brings an ATG just upstream from the codon for the first amino acid in the mature protein. Moreover, the G----A substitution creates a new PvuII restriction site to facilitate further manipulation of the gene. Maximum mutation frequency with this multisite-directed mutagenesis is reached within 15 min with an efficiency approaching 50%, when using the modified T7 DNA polymerase. No multisite-directed mutants were obtained when T4 DNA polymerase or Klenow (large) fragment of DNA polymerase I were used. The described method is also applicable to simple single site-directed mutations as well as to more complex gene reconstruction strategies.     

Human DNA polymerase N (POLN) is a low fidelity enzyme capable of error-free bypass of 5S-thymine glycol

Human DNA polymerase N (POLN or pol nu) is the most recently discovered nuclear DNA polymerase in the human genome. It is an A-family DNA polymerase related to Escherichia coli pol I, human POLQ, and Drosophila Mus308. We report the first purification of the recombinant enzyme and examination of its biochemical properties, as a step toward understanding the functions of POLN. Unusual for an A-family DNA polymerase, POLN is a low fidelity enzyme incorporating T opposite template G with a frequency of 0.45 and G opposite template T with a frequency of 0.021. The frequency of misincorporation of T opposite template G is higher than any other known DNA polymerase. POLN has a processivity of DNA synthesis (1-100 nucleotides) similar to the exonuclease-deficient Klenow fragment of E. coli pol I, is inhibited by dideoxynucleotides, and resistant to aphidicolin. The strand displacement activity of POLN was higher than exonuclease-deficient Klenow fragment. Furthermore, POLN can perform translesion synthesis past thymine glycol, a common endogenous and radiation-induced product of reactive oxygen species damage to DNA. Thymine glycol blocks DNA synthesis by most DNA polymerases, but POLN was particularly adept at efficient and accurate translesion synthesis past a 5S-thymine glycol.     

8-Hydroxyadenine (7,8-dihydro-8-oxoadenine) induces misincorporation in in vitro DNA synthesis and mutations in NIH 3T3 cells.

An oligodeoxyribonucleotide containing 8-hydroxyadenine (OH8Ade) was chemically synthesized and single- and double-stranded c-Ha-ras gene fragments with OH8Ade at the second position of codon 61 were prepared. The single-stranded ras gene fragment was used as a template for in vitro DNA synthesis with the Klenow fragment of Escherichia coli DNA polymerase I, Taq DNA polymerase, rat DNA polymerase beta and mouse DNA polymerase alpha. The former two enzymes exclusively incorporated dTMP opposite OH8Ade. The DNA polymerases alpha and beta misinserted dGMP, and dAMP and dGMP, respectively. The c-Ha-ras gene was constructed using the double-stranded ras gene fragment containing OH8Ade and was transfected into NIH 3T3 cells. The gene with OH8Ade induced focus formation, indicating that OH8Ade elicited point mutations in cells. When c-Ha-ras genes present in transformed cells were analyzed, an A-->G transition and an A-->C transversion were detected. These results indicate that OH8Ade induced misincorporation in in vitro DNA synthesis and mutations in mammalian cells.     

Two DNA polymerases of Escherichia coli display distinct misinsertion specificities for 2-hydroxy-dATP during DNA synthesis

The insertion specificities of an oxidized dATP analogue, 2-hydroxydeoxyadenosine 5'-triphosphate (2-OH-dATP), were determined using the alpha (catalytic) subunit of Escherichia coli DNA polymerase III and the exonuclease-deficient Klenow fragment of DNA polymerase I. In contrast to our previous observation that mammalian DNA polymerase alpha incorporated the oxidized nucleotide opposite T and C, these two E. coli DNA polymerases incorporated 2-OH-dATP opposite T and G on the DNA template. Steady-state kinetic studies indicated that the alpha subunit incorporated 2-OH-dATP 10 times more frequently opposite T than opposite G. On the other hand, the incorporation of 2-OH-dATP opposite T by the exonuclease-deficient Klenow fragment was 2 orders of magnitude more efficient than that opposite G. These results indicate that the misinsertion specificity of 2-OH-dATP differs between replicative and repair-type DNA polymerases, and provide a biochemical basis for the mutations induced by 2-OH-dATP in E. coli.     

Initiation of DNA replication by DNA polymerases from primers forming a triple helix

Despite extensive studies on oligonucleotide-forming triple helices, which were discovered in 1957, their possible relevance in the initiation of DNA replication remains unknown. Using sequences forming triple helices, we have developed a DNA polymerisation assay by using hairpin DNA templates with a 3′ dideoxynucleotide end and an unpaired 5′-end extension to be replicated. The T7 DNA polymerase successfully elongated nucleotides to the expected size of the template from the primers forming triple helices composed of 9–14 deoxyguanosine-rich residues. The triple helix-forming primer required for this reaction has to be oriented parallel to the homologous sequence of the hairpin DNA template. Substitution of the deoxyguanosine residues by N7 deazadeoxyguanosines in the hairpin of the template prevented primer elongation, suggesting that the formation of a triple helix is a prerequisite for primer elongation. Furthermore, DNA sequencing could be achieved with the hairpin template through partial elongation of the third DNA strand forming primer. The T4 DNA polymerase and the Klenow fragment of DNA polymerase I provided similar DNA elongation to the T7 polymerase–thioredoxin complex. On the basis of published crystallographic data, we show that the third DNA strand primer fits within the catalytic centre of the T7 DNA polymerase, thus underlying this new property of several DNA polymerases which may be relevant to genome rearrangements and to the evolution of the genetic apparatus, namely the DNA structure and replication processes.     

Klenow fragment of DNA-polymerase I from E. coli. III. The role of internucleotide phosphate groups of the matrix in its binding with the enzyme

The modification of Klenow fragment of DNA polymerase I E. coli was investigated by the affinity reagents d(Tp)2C[Pt2+(NH3)2OH](pT)7 and d(pT)2pC[Pt2+(NH3)2OH](pT)7. The template binding site of the enzyme was modified by these reagents in the presence of NaF (5 mM), which inhibits selectively the 3'----5'-exonuclease activity of the enzyme and therefore prevents the reagent from degradation. NaCN destroyed covalent bonds between reagents and enzyme, restoring activity of the Klenow fragment. The affinity of different ligands (inorganic phosphate, nucleoside monophosphates, oligonucleotides) to the template binding site of Klenow fragment was estimated. Minimal ligands capable to bind with the template site were shown to be triethylphosphate (Kd 290 microM) and phosphate (Kd 26 microM). Ligand affinity increases by the factor 1.76 per an added (monomer unit from phosphate to d(pT) and then for oligonucleotides d(Tp)nT (n 1 to 19-20). At n greater than 19-20, the ligand affinity remained constant. The complete ethylation of phosphodiester groups lowers affinity of the oligothymidylates to the enzyme by approximately 10 times, and comparable decrease of Pt2+-oligonucleotide affinity to polymerase is caused by the absence of Mn2+-ions. The data obtained led to suggestion that one Me2+-dependent electrostatic contact of the template phosphodiester group with the enzyme takes place (delta G = -1.45...-1.75 kcal/mole). Formation of a hydrogen bond with the oxygen atom of P = O group of the same template phosphate is also assumed (delta G = -4.8...-4.9 kcal/mole). Other template internucleotide phosphates do not interact with the enzyme but the bases of oligonucleotides take part in hydrophobic interactions with the template binding site. Gibbs energy changes by -0.34 kcal/mole when the template is lengthened by one unit.     

Substrate and mispairing properties of 5-formyl-2'-deoxyuridine 5'-triphosphate assessed by in vitro DNA polymerase reactions.

5-Formyluracil (fU) is one of the thymine lesions produced by reactive oxygen radicals in DNA and its constituents. In this work, 5-formyl-2'-deoxyuridine 5'-triphosphate (fdUTP) was chemically synthesized and extensively purified by HPLC. The electron withdrawing 5-formyl group facilitated ionization of fU. Thus, p K a of the base unit of fdUTP was 8.6, significantly lower than that of parent thymine (p K a = 10.0 as dTMP). fdUTP efficiently replaced dTTP during DNA replication catalyzed by Escherichia coli DNA polymerase I (Klenow fragment), T7 DNA polymerase (3'-5'exonuclease free) and Taq DNA polymerase. fU-specific cleavage of the replication products by piperidine revealed that when incorporated as T, incorporation of fU was virtually uniform, suggesting minor sequence context effects on the incorporation frequency of fdUTP. fdUTP also replaced dCTP, but with much lower efficiency than that for dTTP. The substitution efficiency for dCTP increased with increasing pH from 7.2 to 9.0. The parallel correlation between ionization of the base unit of fdUTP (p K a = 8.6) and the substitution efficiency for dCTP strongly suggests that the base-ionized form of fdUTP is involved in mispairing with template G. These data indicate that fU can be specifically introduced into DNA as unique lesions by in vitro DNA polymerase reactions. In addition, fU is potentially mutagenic since this lesion is much more prone to form mispairing with G than parent thymine.