Substrate specificity of DNA polymerases. II. 5-(1-Alkynyl)-dUTPs as substrates of the Klenow DNA polymerase enzyme

A structure-activity relationship study was carried out with a sequence of 5-(1-alkynyl)-dUTPs in Klenow DNA polymerase enzyme-catalyzed reactions. Ability of modified dUTPs examined (up to the octynyl derivative) to serve as a substrate depended on both the length of substituent and the structure of DNA primer-template used.     

Exploration of factors driving incorporation of unnatural dNTPS into DNA by Klenow fragment (DNA polymerase I) and DNA polymerase alpha

In order to further understand how DNA polymerases discriminate against incorrect dNTPs, we synthesized two sets of dNTP analogues and tested them as substrates for DNA polymerase α (pol α) and Klenow fragment (exo⁻) of DNA polymerase I (Escherichia coli). One set of analogues was designed to test the importance of the electronic nature of the base. The bases consisted of a benzimidazole ring with one or two exocyclic substituent(s) that are either electron-donating (methyl and methoxy) or electron-withdrawing (trifluoromethyl and dinitro). Both pol α and Klenow fragment exhibit a remarkable inability to discriminate against these analogues as compared to their ability to discriminate against incorrect natural dNTPs. Neither polymerase shows any distinct electronic or steric preferences for analogue incorporation. The other set of analogues, designed to examine the importance of hydrophobicity in dNTP incorporation, consists of a set of four regioisomers of trifluoromethyl benzimidazole. Whereas pol α and Klenow fragment exhibited minimal discrimination against the 5- and 6-regioisomers, they discriminated much more effectively against the 4- and 7-regioisomers. Since all four of these analogues will have similar hydrophobicity and stacking ability, these data indicate that hydrophobicity and stacking ability alone cannot account for the inability of pol α and Klenow fragment to discriminate against unnatural bases. After incorporation, however, both sets of analogues were not efficiently elongated. These results suggest that factors other than hydrophobicity, sterics and electronics govern the incorporation of dNTPs into DNA by pol α and Klenow fragment.     

Carbocyclic analogues of dTTP and UTP: properties in polymerase enzyme-catalyzed reactions

Racemic carbocyclic analogues of dTTP [(+/-)-C-dTTP] and its ribo counterpart, 5-methyl-UTP [(+/-)-C-m5UTP] were synthesized and examined, in comparison with dTTP and UTP (and m5UTP), as potential substrates of E. coli DNA and RNA polymerases, respectively. Unexpectedly, only a very low (terminal) incorporation of C-dTMP into DNAs of different structure was observed, C-dTTP did not serve as a substrate for chain elongation by the Klenow DNA polymerase. Inhibition of DNA replication was, however, observed in the presence of (+/-)-C-dTTP. The UTP analogue, (+/-)-C-m5UTP proved neither a substrate nor an inhibitor of the RNA polymerase enzyme.     

Inhibition of DNA polymerase reactions by pyrimidine nucleotide analogues lacking the 2-keto group.

To investigate the influence of the pyrimidine 2-keto group on selection of nucleotides for incorporation into DNA by polymerases, we have prepared two C nucleoside triphosphates that are analogues of dCTP and dTTP, namely 2-amino-5-(2'-deoxy-beta-d-ribofuranosyl)pyridine-5'-triphosphate (d*CTP) and 5-(2'-deoxy- beta-d-ribofuranosyl)-3-methyl-2-pyridone-5'-triphosphate (d*TTP) respectively. Both proved strongly inhibitory to PCR catalysed by Taq polymerase; d*TTP rather more so than d*CTP. In primer extension experiments conducted with either Taq polymerase or the Klenow fragment of Escherichia coli DNA polymerase I, both nucleotides failed to substitute for their natural pyrimidine counterparts. Neither derivative was incorporated as a chain terminator. Their capacity to inhibit DNA polymerase activity may well result from incompatibility with the correctly folded form of the polymerase enzyme needed to stabilize the transition state and catalyse phosphodiester bond formation.     

Incorporation of the carbocyclic analogue of (E)-5-(2-bromovinyl)-2'-deoxyuridine 5'-triphosphate into a synthetic DNA

The carbocyclic analogue of (E)-5-(2-bromovinyl)-2'-deoxyuridine, C-BVDU, is a very potent and selective anti-herpes-virus compound. In order to synthesize and study the properties of a DNA that contains C-BVDU, the 5'-triphosphate, C-BVDUTP was prepared and evaluated as a potential substrate of the E. coli Klenow DNA polymerase enzyme. Although C-BVDUTP proved to be a very poor substrate also of this enzyme, it could be incorporated up to 3.6% into the synthetic DNA, poly(dA-dT, C-BVDU). This level of substitution decreased significantly the template activity for DNA and RNA polymerases, as compared to that of poly(dA-dT).     

Family A and family B DNA polymerases are structurally related: evolutionary implications.

In order to establish the evolutionary relationship between the family A and B DNA polymerases, we have closely compared the 3'-->5' exonuclease domains between the Klenow fragment of E.coli DNA polymerase I (a family A DNA polymerase) and the bacteriophage PRD1 DNA polymerase, the smallest member of the DNA polymerase family B. Although the PRD1 DNA polymerase has a smaller 3'-->5' exonuclease domain, its active sites appear to be very similar to those of the Klenow fragment. Site-directed mutagenesis studies revealed that the residues important for the 3'-->5' exonuclease activity, particularly metal binding ligands for the Klenow fragment, are all conserved in the PRD1 DNA polymerase as well. The metal binding ligands are also essential for the strand-displacement activity of the PRD1 DNA polymerase. Based on these results and the studies by others in various systems, we conclude that family A and B DNA polymerases, at least in the 3'-->5' exonuclease domain, are structurally as well as evolutionarily related.     

T7 DNA polymerase in automated dideoxy sequencing.

T7 DNA polymerase with chemically inactivated 3'-5' exo-nuclease activity, as well as unmodified T7 DNA polymerase, were used for sequencing by the dideoxy method in an automated system with fluorescence labelled primer and on-line detection of laser-excited reaction products. An analysis of signal intensity variations in the C track revealed that low C signals were usually preceded by a T in the sequence. This effect was modified by surrounding nucleotides. Signal intensities were more uniform with T7 polymerase than with the Klenow fragment of DNA polymerase I. Some sequences ambiguous with the Klenow enzyme could easily be evaluated with the T7 enzyme. One sequence could only be read by the unmodified T7 polymerase, while both the Klenow fragment and the chemically modified T7 enzyme gave uninterpretable data.     

DNA synthesis on discontinuous templates by human DNA polymerases: implications for non-homologous DNA recombination.

DNA polymerases catalyze the synthesis of DNA using a continuous uninterrupted template strand. However, it has been shown that a 3'-->5' exonuclease-deficient form of the Klenow fragment of Escherichia coli DNA polymerase I as well as DNA polymerase of Thermus aquaticus can synthesize DNA across two unlinked DNA templates. In this study, we used an oligonucleotide-based assay to show that discontinuous DNA synthesis was present in HeLa cell extracts. DNA synthesis inhibitor studies as well as fractionation of the extracts revealed that most of the discontinuous DNA synthesis was attributable to DNA polymerase alpha. Additionally, discontinuous DNA synthesis could be eliminated by incubation with an antibody that specifically neutralized DNA polymerase alpha activity. To test the relative efficiency of each nuclear DNA polymerase for discontinuous synthesis, equal amounts (as measured by DNA polymerase activity) of DNA polymerases alpha, beta, delta (+/- PCNA) and straightepsilon (+/- PCNA) were used in the discontinuous DNA synthesis assay. DNA polymerase alpha showed the most discontinuous DNA synthesis activity, although small but detectable levels were seen for DNA polymerases delta (+PCNA) and straightepsilon (- PCNA). Klenow fragment and DNA polymerase beta showed no discontinuous DNA synthesis, although at much higher amounts of each enzyme, discontinuous synthesis was seen for both. Discontinuous DNA synthesis by DNA polymerase alpha was seen with substrates containing 3 and 4 bp single-strand stretches of complementarity; however, little synthesis was seen with blunt substrates or with 1 bp stretches. The products formed from these experiments are structurally similar to that seen in vivo for non-homologous end joining in eukaryotic cells. These data suggest that DNA polymerase alpha may be able to rejoin double-strand breaks in vivo during replication.     

(E)-5-(2-bromovinyl)-2'-deoxyuridine-5'-triphosphate as a DNA polymerase substrate.

Time course of incorporation and the effect of 5'-triphosphate of the selective antiherpetic agent (E)-5-(2-bromovinyl)-2'-deoxyuridine (bv5dUTP) on the incorporation of dTTP and dATP into template-primers of different structure were studied in E. coli DNA polymerase I Klenow fragment enzyme-catalyzed reactions. bv5dUTP could substitute for dTTP depending on the structure of template-primer. E.g. into calf thymus DNA incorporation of bv5dUMP was around 80% of that of dTMP at 30 minutes of incubation. The analog has also inhibited dTMP incorporation, net DNA synthesis, however, was hardly affected. The substrate properties of the analog were studied with [2-14C]-labelled bv5dUTP.     

Affinity alkylation of E. coli RNA-dependent DNA polymerase with TTP gamma-amidate derivatives]

TTP gamma-benzylamidates are shown to act as competitive inhibitors of poly(dT) synthesis catalyzed by E. coli RNA-dependent DNA polymerase. The KM value for TTP as well as KI values for the gamma-analogues have been determined. TTP gamma-4-(N-2-chloroethyl-N-methyl-amino)benzylamidate is shown to be an effective affinity reagent for this enzyme.     

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)     

Mechanism and dynamics of translesion DNA synthesis catalyzed by the Escherichia coli Klenow fragment

Translesion DNA synthesis represents the ability of a DNA polymerase to incorporate and extend beyond damaged DNA. In this report, the mechanism and dynamics by which the Escherichia coli Klenow fragment performs translesion DNA synthesis during the misreplication of an abasic site were investigated using a series of natural and non-natural nucleotides. Like most other high-fidelity DNA polymerases, the Klenow fragment follows the "A-rule" of translesion DNA synthesis by preferentially incorporating dATP opposite the noninstructional lesion. However, several 5-substituted indolyl nucleotides lacking classical hydrogen-bonding groups are incorporated approximately 100-fold more efficiently than the natural nucleotide. In general, analogues that contain large substituent groups in conjunction with significant pi-electron density display the highest catalytic efficiencies ( k cat/ K m) for incorporation. While the measured K m values depend upon the size and pi-electron density of the incoming nucleotide, k cat values are surprisingly independent of both biophysical features. As expected, the efficiency by which these non-natural nucleotides are incorporated opposite templating nucleobases is significantly reduced. This reduction reflects minimal increases in K m values coupled with large decreases in k cat values. The kinetic data obtained with the Klenow fragment are compared to that of the high-fidelity bacteriophage T4 DNA polymerase and reveal distinct differences in the dynamics by which these non-natural nucleotides are incorporated opposite an abasic site. These biophysical differences argue against a unified mechanism of translesion DNA synthesis and suggest that polymerases employ different catalytic strategies during the misreplication of damaged DNA.     

Inhibitory effects of 5-alkyl- and 5-alkenyl-1-beta-D-arabinofuranosyluracil 5'-triphosphates on herpes virus-induced DNA polymerases

Various 5-substituted 1-beta-D-arabinofuranosyluracil 5'-triphosphates (H, methyl, ethyl, n-propyl, n-butyl, (E)-bromovinyl, styryl, and beta-phenylethyl derivatives) were prepared and their inhibitory effects on two different herpes virus-induced DNA polymerases (OMV and HCMV) were studied. These dTTP analogues inhibited the incorporation of [3H]dTMP into DNA in vitro. Among them, analogues having a vinyl group at the 5-position were strongly active against DNA polymerases induced on herpes virus infection. Kinetic analysis showed that the inhibition by the analogues was essentially competitive with respect to the substrate, dTTP. The K1 values (microM) for AraUTP (2.4), AraTTP (1.0), BVAUTP (0.8), and StUAUTP (0.8) were smaller than the Km value (microM) for dTTP (3.4), but those for AraEtUTP, AraPrUTP, and AraBuUTP (5-14) were larger than the Km for dTTP in the case of HCMV-induced DNA polymerase. In contrast to these results, OMV-induced DNA polymerase seemed to be more resistant to these inhibitors than HCMV-induced DNA polymerase. However, the mode of the structure of substituent groups at the 5-position of base moieties is almost the same for the two DNA polymerases, except for in the case of AraUTP itself.     

Inactivation of DNA polymerase I (Klenow fragment) by adenosine 2',3'-epoxide 5'-triphosphate: evidence for the formation of a tight-binding inhibitor

The suicidal inactivation of Escherichia coli DNA polymerase I by epoxy-ATP has been previously reported (Abboud et al., 1978). We have examined in detail the mechanism of this inactivation utilizing a synthetic DNA template-primer of defined sequence. Epoxy-ATP inactivates the large fragment of DNA polymerase I (the Klenow fragment) in a time- and concentration-dependent manner (KI = 21 microM; kinact = 0.021 s-1). Concomitant with inactivation is the incorporation of epoxy-AMP into the primer strand. The elongated DNA duplex directly inhibits the polymerase activity of the enzyme (no time dependence) and is resistant to degradation by the 3'----5' exonuclease and pyrophosphorylase activities of the enzyme. Inactivation of the enzyme results from slow (4 X 10(-4) s-1) dissociation of the intact epoxy-terminated template-primer from the enzyme and is thus characterized as a tight-binding inhibition. Surprisingly, while the polymerase activity of the enzyme is completely suppressed by epoxy-ATP, the 3'----5' exonuclease activity remains intact. The data presented demonstrate that even though the polymerase site is occupied with duplex DNA, the enzyme can bind a second DNA duplex and carry out exonucleolytic cleavage.     

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.