Probing DNA polymerase-DNA interactions: examining the template strand in exonuclease complexes using 2-aminopurine fluorescence and acrylamide quenching

The bacteriophage T4 DNA polymerase forms fluorescent complexes with DNA substrates labeled with 2-aminopurine (2AP) in the template strand; the fluorescence intensity depends on the position of 2AP. When preexonuclease complexes are formed, complexes at the crossroads between polymerase and exonuclease complexes, 2AP in the +1 position in the template strand is fully free of contacts with the adjacent bases as indicated by high fluorescence intensity and a long fluorescence lifetime of about 10.9 ns. Fluorescence intensity decreases for 2AP in the template strand when the primer end is transferred to the exonuclease active center to form exonuclease complexes, which indicates a change in DNA conformation; 2AP can now interact with adjacent bases, which quenches fluorescence emission. Some polymerase-induced base unstacking for 2AP in the template strand in exonuclease complexes is observed but is restricted primarily to the n and +1 positions, which indicates that the DNA polymerase holds the template strand in a way that forces base unstacking only in a small region near the primer terminus. A hold on the template strand will help to maintain the correct alignment of the template and primer strands during proofreading. Acrylamide quenches 2AP fluorescence in preexonuclease and in exonuclease complexes formed with DNA labeled with 2AP in the template strand, which indicates that the template strand remains accessible to solvent in both complexes. These studies provide new information about the conformation of the template strand in exonuclease complexes that is not available from structural studies.     

Fluorescence of 2-aminopurine reveals rapid conformational changes in the RB69 DNA polymerase-primer/template complexes upon binding and incorporation of matched deoxynucleoside triphosphates

We have used 2-aminopurine (2AP) as a fluorescent probe in the template strand of a 13/20mer primer/template (D) to detect deoxynucleoside triphosphates (N)-dependent conformational changes exhibited by RB69 DNA polymerase (ED) complexes. The rates and amplitudes of fluorescence quenching depend hyperbolically on the [dTTP] when a dideoxy-primer/template (ddP/T) with 2AP as the templating base (n position) is used. No detectable fluorescence changes occur when a ddP/T with 2AP positioned 5′ to the templating base (n + 1 position) is used. With a deoxy-primer/template (dP/T) with 2AP in the n position, a rapid fluorescence quenching occurs within 2 ms, followed by a second, slower fluorescence quenching with a rate constant similar to base incorporation as determined by chemical quench. With a dP/T having 2AP in the n + 1 position, there is a [dNTP]-dependent fluorescence enhancement that occurs at a rate comparable to dNMP incorporation. Collectively, the results favor a minimal kinetic scheme in which population of two distinct biochemical states of the ternary EDN complex precedes the nucleotidyl transfer reaction. Observed differences between dP/T and ddP/T ternary complexes indicate that the 3′ hydroxyl group of the primer plays a critical role in determining the rate constants of transitions that lead to strong deoxynucleoside triphosphate binding prior to chemistry.     

Interaction of DNA polymerase I (Klenow fragment) with DNA substrates containing extrahelical bases: implications for proofreading of frameshift errors during DNA synthesis

Frameshift mutagenesis occurs through the misalignment of primer and template strands during DNA synthesis and involves DNA intermediates that contain one or more extrahelical bases in either strand of the DNA substrate. To investigate whether these DNA structures are recognized by the proofreading apparatus of DNA polymerases, time-resolved fluorescence spectroscopy was used to examine the interaction between the Klenow fragment of DNA polymerase I and synthetic DNA primer-templates containing extrahelical bases at defined positions within the template strand. A dansyl probe attached to the DNA was used to measure the fractional occupancies of the polymerase and 3'-5' exonuclease sites of the enzyme for DNA substrates with and without the extrahelical bases. The presence of an extrahelical base at the first position from the primer 3' terminus increased the level of partitioning of the DNA substrates into the 3'-5' exonuclease site by 3-7-fold, relative to the perfectly base-paired primer-template, depending on the identity of the extrahelical base. The ability of different extrahelical bases to promote partitioning of DNA into the 3'-5' exonuclease site decreased in the following order: G > A approximately T > C. The results of partitioning measurements for DNA substrates containing a bulged adenine base at different positions within the template showed that an extrahelical base is recognized up to five bases from the primer 3' terminus. The largest effects were observed for the extrahelical base at the third or fourth positions from the primer terminus, which increased the level of partitioning of DNA into the 3'-5' exonuclease site by 8- and 18-fold, respectively, relative to that of the perfectly base-paired substrate. Steady-state fluorescence measurements of analogous primer-templates containing 2-aminopurine (AP) at the primer 3' terminus indicate that extrahelical bases increase the degree of terminus unwinding, especially when close to the terminus. In addition, steady-state kinetic measurements of removal of AP from the primer-templates indicate that the exonucleolytic cleavage activity of Klenow fragment is correlated with the increased level of partitioning of bulged DNA substrates to the 3'-5' exonuclease site relative to that of properly base-paired DNA. The results of this study indicate that misalignment of primer and template strands to generate an extrahelical base strongly promotes transfer of a DNA substrate to the 3'-5' exonuclease site, suggesting that the premutational intermediates in frameshift mutagenesis are subject to proofreading by the polymerase.     

Using 2-aminopurine fluorescence to detect bacteriophage T4 DNA polymerase-DNA complexes that are important for primer extension and proofreading reactions

The fluorescence of the base analogue 2-aminopurine (2AP) was used to probe bacteriophage T4 DNA polymerase-induced conformational changes in the template strand produced during the nucleotide incorporation and proofreading reactions. 2AP fluorescence in DNA is quenched by 2AP interactions with neighboring bases, but T4 DNA polymerase binding to DNA substrates labeled with 2AP in the templating position produces large increases in fluorescence intensity. Fluorescence lifetime studies were performed to characterize the fluorescent complexes. Three fluorescence lifetime components were observed for unbound DNA substrates as reported previously, but T4 DNA polymerase binding modulated the amplitudes of these components and created a new, highly fluorescent 10.5 ns component. Experimental evidence for correlation of fluorescence lifetimes with functionally distinct complexes was obtained by forming complexes under different reaction conditions. T4 DNA polymerase complexes were formed with DNA substrates with matched and mismatched primer ends and with A+T- or G+C-rich primer-terminal regions. dTTP was added to binary complexes to form ternary DNA polymerase-DNA-nucleotide complexes. The effect of temperature on complex formation was studied, and complexes were formed with proofreading-defective T4 DNA polymerases. Complexes characterized by the 10.5 ns lifetime were demonstrated to be formed at the crossroads of the primer-extension and proofreading pathways.     

Interaction of Drosophila DNA polymerase alpha holoenzyme with synthetic template-primers containing mismatched primer bases or propanodeoxyguanosine adducts at various positions in template and primer regions.

We studied recognition and binding of synthetic template-primers by Drosophila DNA polymerase alpha (pol alpha) holoenzyme. The template-primers used contained either mismatched base pairs at various positions in the primer region or exocyclic propanodeoxyguanosine (PdG) adducts at various positions in both template and primer.pol alpha requires primer-terminal complementarity of greater than or equal to 4 base pairs for efficient binding and incorporation. When a mismatched base pair is at the -4 position relative to the 3'-primer terminus, minimal but detectable binding occurs. This is consistent with the ability of pol alpha to incorporate a single nucleotide on a template-primer containing a mismatch at this position, but at a rate of only 7% relative to incorporation on a perfectly matched template-primer. No binding or incorporation (less than 1% of incorporation on a perfectly matched template-primer) was evident when a mismatched base pair was at the -3 position or closer, relative to the 3'-primer terminus. Similar results were obtained when PdG was placed at various positions in the primer region. When a PdG residue was located in the template region (+ 3 position relative to the 3'-primer terminus), single-nucleotide incorporation was stimulated 3-4-fold. These observations suggest that there are intrinsic aspects to the mechanism of nucleotide incorporation by pol alpha which ensure the fidelity of DNA synthesis by this enzyme and may provide novel insights into the fundamental mechanism of polymerase translocation along templates.     

Use of 2-aminopurine fluorescence to examine conformational changes during nucleotide incorporation by DNA polymerase I (Klenow fragment)

We have investigated conformational transitions in the Klenow fragment polymerase reaction by stopped-flow fluorescence using DNA substrates containing the fluorescent reporter 2-aminopurine (2-AP) on the template strand, either at the templating position opposite the incoming nucleotide (designated the 0 position) or 5' to the templating base (the +1 position). By using both deoxy- and dideoxy-terminated primers, we were able to distinguish steps that accompany ternary complex formation from those that occur during nucleotide incorporation. The fluorescence changes revealed two extremely rapid steps that occur early in the pathway for correct nucleotide incorporation. The first, detectable with the 2-AP reporter at the 0 position, occurs within the first few milliseconds and is associated with dNTP binding. This is followed by a rapid step involving relative movement of the +1 base, detectable when the 2-AP reporter is at the +1 position. Finally, when the primer had a 3'-OH, a fluorescence decrease with a rate equal to the rate of nucleotide incorporation was observed with both 0 and +1 position reporters. When the primer was dideoxy-terminated, the only change observed at the rate expected for nucleotide incorporation had a very small amplitude, suggesting that the rate-limiting conformational change does not produce a large fluorescence change, and is therefore unlikely to involve a significant change in the environment of the fluorophore. Fluorescence changes observed during misincorporation were substantially different from those observed during correct nucleotide incorporation, implying that the conformations adopted during correct and incorrect nucleotide incorporation are distinct.     

Influence of DNA structure on DNA polymerase beta active site function: extension of mutagenic DNA intermediates

In the ternary substrate complex of DNA polymerase (pol) beta, the nascent base pair (templating and incoming nucleotides) is sandwiched between the duplex DNA terminus and polymerase. To probe molecular interactions in the dNTP-binding pocket, we analyzed the kinetic behavior of wild-type pol beta on modified DNA substrates that alter the structure of the DNA terminus and represent mutagenic intermediates. The DNA substrates were modified to 1) alter the sequence of the duplex terminus (matched and mismatched), 2) introduce abasic sites near the nascent base pair, and 3) insert extra bases in the primer or template strands to mimic frameshift intermediates. The results indicate that the nucleotide insertion efficiency (k(cat)/K(m), dGTP-dC) is highly dependent on the sequence identity of the matched (i.e. Watson-Crick base pair) DNA terminus (template/primer, G/C approximately A/T > T/A approximately C/G). Mismatches at the primer terminus strongly diminish correct nucleotide insertion efficiency but do not affect DNA binding affinity. Transition intermediates are generally extended more easily than transversions. Most mismatched primer termini decrease the rate of insertion and binding affinity of the incoming nucleotide. In contrast, the loss of catalytic efficiency with homopurine mismatches at the duplex DNA terminus is entirely due to the inability to insert the incoming nucleotide, since K(d)((dGTP)) is not affected. Abasic sites and extra nucleotides in and around the duplex terminus decrease catalytic efficiency and are more detrimental to the nascent base pair binding pocket when situated in the primer strand than the equivalent position in the template strand.     

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.     

Recognition and binding of template-primers containing defined abasic sites by Drosophila DNA polymerase alpha holoenzyme

Human DNA polymerase alpha holoenzyme follows an ordered sequential terreactant mechanism of substrate recognition and binding (Wong, S. W., Paborsky, L. R., Fisher, P. A., Wang, T. S.-F., and Korn, D. (1986) J. Biol. Chem. 261, 7958-7968). We confirmed this mechanism for the DNA polymerase alpha holoenzyme purified from Drosophila melanogaster embryos and studied the interaction of Drosophila pol alpha with synthetic oligonucleotide template-primers containing modified tetrahydrofuran moieties as model abasic lesions chemically engineered at a number of defined sites. Abasic lesions in the template had relatively little effect on the polymerase incorporation reaction at sites proximal to the lesion. However, incorporation opposite an abasic site was undetectable relative to that which occurred opposite a normal template nucleotide. Moreover, abasic residues in the primer region of the template-primer construct as far as 4 base pairs removed from the 3'-primer terminus prevented detectable nucleotide incorporation relative to that seen on an unmodified template-primer. Primer-region lesions had qualitatively similar effects whether they were located on the primer strand itself or on the complementary template strand. Data from polymerase incorporation experiments were corroborated by competitive binding assays performed under steady state reaction conditions. Results of these experiments suggested that polymerase binding to synthetic oligonucleotide template-primers was essentially unaffected by lesions located at sites that did not block incorporation. Lesions that did block incorporation apparently did so by abrogating template-primer binding. These observations have implications for understanding the mechanisms whereby DNA polymerase alpha recognizes noninformational template sites in vivo and prevents DNA synthesis from proceeding past these points.     

Conformational changes during normal and error-prone incorporation of nucleotides by a Y-family DNA polymerase detected by 2-aminopurine fluorescence

Y-family polymerases are specialized to carry out DNA synthesis past sites of DNA damage. Their active sites make fewer contacts to their substrates, consistent with the remarkably low fidelity of these DNA polymerases when copying undamaged DNA. We have used DNA containing the fluorescent reporter 2-aminopurine (2-AP) to study the reaction pathway of the Y-family polymerase Dbh. We detected 3 rapid noncovalent steps between binding of a correctly paired dNTP and the rate-limiting step for dNTP incorporation. These early steps resemble those seen with high-fidelity DNA polymerases, such as Klenow fragment, and include a step that may be related to the unstacking of the 5' neighbor of the templating base that is seen in polymerase ternary complex crystal structures. A significant difference between Dbh and high-fidelity polymerases is that Dbh generates no fluorescence changes subsequent to dNTP binding if the primer lacks a 3'OH, suggesting that the looser active site of Y-family polymerases may enforce reliance on the correct substrate structure in order to assemble the catalytic center. Dbh, like other bypass polymerases of the DinB subgroup, generates single-base deletion errors at an extremely high frequency by skipping over a template base that is part of a repetitive sequence. Using 2-AP as a reporter to study the base-skipping process, we determined that Dbh uses a mechanism in which the templating base slips back to pair with the primer terminus while the base that was originally paired with the primer terminus becomes unpaired.     

DNA Polymerase �� Substrate Specificity: SIDE CHAIN MODULATION OF THE ��A-RULE��*

Apurinic/apyrimidinic (AP) sites are continuously generated in genomic DNA. Left unrepaired, AP sites represent noninstructional premutagenic lesions that are impediments to DNA synthesis. When DNA polymerases encounter an AP site, they generally insert dAMP. This preferential insertion is referred to as the A-rule. Crystallographic structures of DNA polymerase (pol) β, a family X polymerase, with active site mismatched nascent base pairs indicate that the templating (i.e. coding) base is repositioned outside of the template binding pocket thereby diminishing interactions with the incorrect incoming nucleotide. This effectively produces an abasic site because the template pocket is devoid of an instructional base. However, the template pocket is not empty; an arginine residue (Arg-283) occupies the space vacated by the templating nucleotide. In this study, we analyze the kinetics of pol β insertion opposite an AP site and show that the preferential incorporation of dAMP is lost with the R283A mutant. The crystallographic structures of pol β bound to gapped DNA with an AP site analog (tertrahydrofuran) in the gap (binary complex) and with an incoming nonhydrolyzable dATP analog (ternary complex) were solved. These structures reveal that binding of the dATP analog induces a closed polymerase conformation, an unstable primer terminus, and an upstream shift of the templating residue even in the absence of a template base. Thus, dATP insertion opposite an abasic site and dATP misinsertions have common features.     

Discrimination against the cytosine analog tC by Escherichia coli DNA polymerase IV DinB

The cytosine analog 1,3-diaza-2-oxophenothiazine (tC) is a fluorescent nucleotide that forms Watson-Crick base pairs with dG. The Klenow fragment of DNA polymerase I (an A-family polymerase) can efficiently bypass tC on the template strand and incorporate deoxyribose-triphosphate-tC into the growing primer terminus. Y-family DNA polymerases are known for their ability to accommodate bulky lesions and modified bases and to replicate beyond such nonstandard DNA structures in a process known as translesion synthesis. We probed the ability of the Escherichia coli Y-family DNA polymerase DinB (Pol IV) to copy DNA containing tC and to incorporate tC into a growing DNA strand. DinB selectively adds dGTP across from tC in template DNA but cannot extend beyond the newly formed G:tC base pair. However, we find that DinB incorporates the tC deoxyribonucleotide triphosphate opposite template G and extends from tC. Therefore, DinB displays asymmetry in terms of its ability to discriminate against the modification of the DNA template compared to the incoming nucleotide. In addition, our finding that DinB (a lesion-bypass DNA polymerase) specifically discriminates against tC in the template strand may suggest that DinB discriminates against template modifications in the major groove of DNA.     

Using 2-aminopurine fluorescence to measure incorporation of incorrect nucleotides by wild type and mutant bacteriophage T4 DNA polymerases

The ability of wild type and mutant T4 DNA polymerases to discriminate in the utilization of the base analog 2-aminopurine (2AP) and the fluorescence of 2AP were used to determine how DNA polymerases distinguish between correct and incorrect nucleotides. Because T4 DNA polymerase incorporates dTMP opposite 2AP under single-turnover conditions, it was possible to compare directly the kinetic parameters for incorporation of dTMP opposite template 2AP to the parameters for incorporation of dTMP opposite template A without the complication of enzyme dissociation. The most significant difference detected was in the K(d) for dTTP, which was 10-fold higher for incorporation of dTMP opposite template 2AP (approximately 367 microm) than for incorporation of dTMP opposite template A (approximately 31 microm). In contrast, the dTMP incorporation rate was reduced only about 2-fold from about 318 s(-1) with template A to about 165 s(-1) for template 2AP. Discrimination is due to the high selectivity in the initial nucleotide-binding step. T4 DNA polymerase binding to DNA with 2AP in the template position induces formation of a nucleotide binding pocket that is preshaped to bind dTTP and to exclude other nucleotides. If nucleotide binding is hindered, initiation of the proofreading pathway acts as an error avoidance mechanism to prevent incorporation of incorrect nucleotides.     

A model for the recA-dependent repair of excision gaps in UV-irradiated Escherichia coli

DNA isolated from lambda phage was treated with bleomycin A2 plus Fe2+. The bleomycin-damaged DNA was added to lambda packaging extracts and the resulting phage were grown in SOS-induced E. coli. Under these conditions, treatment of the DNA with 0.8 microM bleomycin reduced the viability of the repackaged phage to 3% and increased the frequency of clear-plaque mutants in the progeny by a factor of 16. Bleomycin-induced mutations which mapped to the DNA-binding domain of the cI gene were subjected to DNA-sequence analysis. The most frequent events were single-base substitutions at G:C base pairs, nearly all of which occurred at cytosines in the sequence Py-G-C. Cytosines in the third position of the sequence C-G-C-C were particularly susceptible to mutation. At A:T base pairs, mutations were less frequent and were a mixture of single-base substitutions and -1 frameshifts, occurring primarily at G-T and A-T sequences. Thus, the overall specificity of bleomycin-induced mutations matches that of bleomycin-induced DNA lesions (strand breaks and apyrimidinic sites), which are formed at G-C (particularly Py-G-C), G-T and, to a lesser extent, A-T sequences. Furthermore, the frequency of various types of substitutions was consistent with selective incorporation of A and T residues opposite apyrimidinic sites at these sequences. The highly selective nature of bleomycin-induced mutations may explain the lack of mutagenesis by this compound in a number of reversion assays.     

Spectroscopic analysis of the interaction of Escherichia coli DNA-dependent RNA polymerase with T7 DNA and synthetic polynucleotides.

We have studied the circular dichroism and ultraviolet difference spectra of T7 bacteriophage DNA and various synthetic polynucleotides upon addition of Escherichia coli RNA polymerase. When RNA polymerase binds nonspecifically to T7 DNA, the CD spectrum shows a decrease in the maximum at 272 but no detectable changes in other regions of the spectrum. This CD change can be compared with those associated with known conformational changes in DNA. Nonspecific binding to RNA polymerase leads to an increase in the winding angle, theta, in T7 DNA. The CD and UV difference spectra for poly[d(A-T)] at 4 degrees C show similar effects. At 25 degrees C, binding of RNA polymerase to poly[d(A-T)] leads to hyperchromicity at 263 nm and to significant changes in CD. These effects are consistent with an opening of the double helix, i.e. melting of a short region of the DNA. The hyperchromicity observed at 263 nm for poly[d(A-T)] is used to determine the number of base pairs disrupted in the binding of RNA polymerase holoenzyme. The melting effect involves about 10 base pairs/RNA polymerase molecule. Changes in the CD of poly(dT) and poly(dA) on binding to RNA polymerase suggest an unstacking of the bases with a change in the backbone conformation. This is further confirmed by the UV difference spectra. We also show direct evidence for differences in the template binding site between holo- and core enzyme, presumably induced by the sigma subunit. By titration of the enzyme with poly(dT) the physical site size of RNA polymerase on single-stranded DNA is approximately equal to 30 bases for both holo- and core enzyme. Titration of poly[d(A-T)] with polymerase places the figure at approximately equal to 28 base pairs for double-stranded DNA.     

Interactions of the dimethyldiazaperopyrenium dication with nucleic acids. 2. Binding to double-stranded polynucleotides

The interactions of dimethyldiazaperopyrenium dication (1) with DNA have been studied by spectroscopic methods: absorption, static and dynamic fluorescence, and linear dichroism. 1 binds strongly to DNA at 250 mM NaCl, with a higher affinity for G-C pairs as compared to A-T pairs. The dye fluorescence is enhanced when it is bound to A-T pairs, whereas the emission is quenched in the vicinity of G-C pairs. Evidence for intercalation has been obtained via energy transfer and linear dichroism measurements.