Pyrophosphorolysis by Type II DNA polymerases: implications for pyrophosphorolysis-activated polymerization

We find that Type II DNA polymerases can catalyze pyrophosphorolysis, the reverse reaction of DNA polymerization. This property is applied utilizing pyrophosphorolysis-activated polymerization (PAP), a method of nucleic acid amplification using serial coupling of pyrophosphorolysis and polymerization. PAP can be used for ultrarare allele detection (detection of minimal residual disease and cancer risk assessment through measurement of mutation load) and for microarray-based scanning for unknown mutations. Herein, we show that Type II DNA polymerases efficiently catalyze template-dependent pyrophosphorolysis to activate oligonucleotides blocked at their 3' termini with acyclonucleotides in which a 2-hydroxyethoxymethyl group substitutes for the 2'-deoxyribofuranosyl sugar. Type II archeon DNA polymerases Vent (exo-) and Pfu (exo-) can be utilized for PAP or a bidirectional form of PAP with acyclonucleotide-blocked oligonucleotides, but not with dideoxynucleotide-blocked oligonucleotides. In contrast, a Type I DNA polymerase, TaqFS, can utilize either acyclonucleotide-blocked or dideoxynucleotide-blocked oligonucleotides. These findings expand the potential of nascent PAP technology.     

Pyrophosphorolysis-activatable oligonucleotides may facilitate detection of rare alleles, mutation scanning and analysis of chromatin structures

Pyrophosphorolysis-activated polymerization (PAP) was initially developed to enhance the specificity of allele-specific PCR for detection of known mutations in the presence of a great excess of wild-type allele. The high specificity of PAP derives from the serial coupling of pyrophosphorolysis-mediated activation of a pyrophosphorolysis-activatable oligonucleotide (P*) followed by extension of the activated oligonucleotide. Herein, we demonstrate that genetically engineered DNA polymerases greatly improve the efficiency of PAP, making it a practical technique for detection of rare mutations. We also show that P* oligonucleotides have the novel and unexpected property of high sensitivity to mismatches throughout at least the 16 3′-terminal nucleotides. Thus, PAP constitutes a technology platform of potential utility whenever high specificity is required along the length of an oligonucleotide.     

Multiplex dosage pyrophosphorolysis-activated polymerization: application to the detection of heterozygous deletions

Large heterozygous chromosomal deletions and gene duplications are important classes of mutations that are generally missed by standard PCR amplification and sequencing. Multiplex dosage pyrophosphorolysis-activated polymerization (MD-PAP), a derivative of PAP, was utilized to detect these types of mutations. PAP is a method for nucleic acid amplification in which 3' blocked oligonucleotides (P*) are activated by pyrophosphorolysis when annealed to the target template and subsequently extended. A key advantage to this technology is that PAP reactions produce little or no primer-dimer or false priming. As a result of this enhanced specificity, MD-PAP is easy to optimize. Herein, we utilize MD-PAP to determine gene dosage of each exon of the human factor IX gene by comparison with one endogenous internal control from the ATM gene. Estimated dosage is proportional to the actual template copy number over a minimum dynamic range from 1 to 16 copies. A blinded analysis detected 100% of 43 heterozygous deletions of exons in the human factor IX gene.     

Detection of extremely rare alleles by bidirectional pyrophosphorolysis-activated polymerization allele-specific amplification (Bi-PAP-A): measurement of mutation load in mammalian tissues

Pyrophosphorolysis-activated polymerization (PAP) was developed to detect extremely rare mutations in complex genomes. In theory, PAP can detect a copy of a single base mutation present in 3 x 10(11) copies of the wild-type allele. In practice, the selectivity of detection is limited by a bypass reaction involving a polymerase extension error from the unblocked oligonucleotide annealed to the opposing strand. Bidirectional PAP allele-specific amplification (Bi-PAP-A) is a novel method that uses two opposing 3'-terminal blocked pyrophosphorolysis-activatable oligonucleotides (P*s) with one nucleotide overlap at their 3' termini. This eliminates the problematic bypass reaction. The selectivity of Bi-PAP-A was examined using lambda phage DNA as a model system. Bi-PAP-A selectively detected two copies of a rare mutated allele in the presence of at least 2 x 10(9) copies of the wild-type lambda phage DNA. Bi-PAP-A was then applied to direct detection of spontaneous somatic mutations in the mouse genome at a frequency as low as 3 x 10(-9). A 370-fold variation in the frequency of a specific somatic mutation among different mouse samples was found, suggesting clonal expansion of mutation occurring during early development and a hyper-Poisson variance. Bi-PAP-A is a rapid, general, and automatable method for the detection of rare mutations.     

Signal amplification through nucleotide extension and excision on a dendritic DNA platform

Techniques that provide strong signal amplification are useful in diagnostic applications, especially in detecting low concentrations of non-amplifiable target molecules. A versatile and strong signal amplification method based on activities of a DNA polymerase to generate high concentrations of pyrophosphate (PPi) is described. The generation of PPi is catalyzed by nucleotide extension and excision activities of a DNA polymerase on an oligonucleotide cassette. The signal is generated upon enzymatic conversion of PPi to ATP and ATP levels subsequently detected with firefly luciferase. Bioluminesence produced by an oligonucleotide cassette consisting of just two polymerase reaction sites is sufficient to detect them at low attomole levels. The attachment of a large number of these oligonucleotide cassettes to DNA dendrimers enabled the detection of such polyvalent substrate molecules at low zeptomole (10^–21 mol) concentrations. The extent of signal amplification obtained with dendrimer substrates is comparable to exponential target amplifications provided by nucleic acid amplification methods. The attachment of such PPi-generating dendritic DNA platforms to ligands that mediate target recognition would potentially permit detection of extremely low concentrations of analytes in diagnostic assays.     

Kinetic mechanism of DNA polymerase I (Klenow fragment): identification of a second conformational change and evaluation of the internal equilibrium constant.

In a previously determined minimal kinetic scheme for DNA polymerization catalyzed by the Klenow fragment (KF) of Escherichia coli DNA polymerase I, a nonchemical step that interconverted the KF'.DNAn+1.PPi and KF.DNAn+1PPi complexes was not observed in correct incorporation [Kuchta, R. D., Mizrahi, V., Benkovic, P.A., Johnson, K.A., & Benkovic, S.J. (1987) Biochemistry 26, 8410-8417] but was detected in misincorporation [Kuchta, R. D., Benkovic, P.A., & Benkovic, S.J. (1988) Biochemistry 27, 6716-6725]. In a pulse-chase experiment in this study, a burst amplitude of 100% of the enzyme concentration is observed; under pulse-quench conditions, the burst amplitude is 80%, indicative of the accumulation of the KF'.DNA.dNTP species owing to a slow step subsequent to chemical bond formation. This latter step was unequivocally identified by single-turnover pyrophosphorolysis and pyrophosphate-exchange experiments as one interconverting KF'.DNAn+1.PPi and KF.DNAn+1.PPi. The rate constants for this step in both directions were established through the rate constants for processive synthesis and pyrophosphorolysis. Pyrophosphorolysis of a 3'-phosphorothioate DNA duplex confirmed that the large elemental effect observed previously [Mizrahi, V., Henrie, R. N., Marlier, J.F., Johnson, K.A., & Benkovic, S.J. (1985) Biochemistry 24, 4010-4018] in this direction but not in polymerization is due to a marked decrease in the affinity of KF for the phosphorothioate-substituted duplex and not to the chemical step. The combination of the experimentally measured equilibrium constant for the bound KF.DNA species with the collective kinetic measurements further extends previous insights into the dynamics of the polymerization process catalyzed by KF.     

Interaction of dNTP, pyrophosphate and their analogs with the dNTP-binding sites of E. coli DNA polymerase I Klenow fragment and human DNA polymerase alpha

The 3',5'-exonuclease center of the Klenow fragment of E. coli DNA polymerase I (FK) was selectively blocked by NaF. The latter was shown to forbid the binding of nucleotides and their analogs to the enzyme exonuclease center. In the presence of poly(dT).r(pA)10 template.primer complex and NaF, we observed AMP, ADP, ATP, PPi and dATP to be competitive inhibitors of the FK-catalyzed DNA polymerization. The interactions of the nucleotides with FK and human DNA polymerase alpha were compared to reveal similarity of binding to the DNA polymerizing centers. Structural components of dNTP and PPi playing key roles in forming complexes with pro- and eukaryotic DNA polymerases were identified.     

Pyrophosphorolysis of CCA addition: implication for fidelity

In nucleic acid polymerization reaction, pyrophosphorolysis is the reversal of nucleotide addition, in which the terminal nucleotide is excised in the presence of inorganic pyrophosphate (PPi). The CCA enzymes are unusual RNA polymerases, which catalyze CCA addition to positions 74-76 at the tRNA 3′ end without using a nucleic acid template. To better understand the reaction mechanism of CCA addition, we tested pyrophosphorolysis of CCA enzymes, which are divided into two structurally distinct classes. Here, we show that only class II CCA enzymes catalyze pyrophosphorolysis and that the reaction can initiate from all three CCA positions and proceed processively until the removal of nucleotide C74. Pyrophosphorolysis of class II enzymes establishes a fundamental difference from class I enzymes, and it is achieved only with the tRNA structure and with specific divalent metal ions. Importantly, pyrophosphorolysis enables class II enzymes to efficiently remove an incorrect A75 nucleotide from the 3′ end, at a rate much faster than the rate of A75 incorporation, suggesting the ability to perform a previously unexpected quality control mechanism for CCA synthesis. Measurement of kinetic parameters of the class II Escherichia coli CCA enzyme reveals that the enzyme catalyzes pyrophosphorolysis slowly relative to the forward nucleotide addition and that it exhibits weak binding affinity to PPi relative to NTP, suggesting a mechanism in which PPi is rapidly released after each nucleotide addition as a driving force to promote the forward synthesis of CCA.     

Factors influencing the pulse character of RNA elongation in vitro by E. coli RNA polymerase

Pause location along primary structure of two RNA fragments each 200 nucleotide residues in the length synthesized from A1 promoters of T7 phage DNA and delta D111 T7 phage DNA was analyzed. No correlation between the location of pauses and GC-rich or self complementary regions of RNA were found. The location of pauses does not change upon the variation of the temperature or ionic strength. Concurrent variation of all four NTP concentrations also did not influence pausing pattern. However the distribution of pauses depends highly on the ratio of the individual substrate concentrations. Substitution of GTP by ITP changes the pausing pattern completely. Inorganic pyrophosphate (PPi) of inhibits RNA elongation preferentially in the regions: NAUN, CGUAG. The study of PPi action on RNA terminated with 3' OCH3-NMP suggest that the sequence-specific inhibition of RNA elongation may be a result of pyrophosphorolysis of terminal nucleotide residues of RNA. It was proposed that the pulse character of RNA elongation stems rather from differences in the kinetic constants of nucleotides attachment and pyrophosphorolysis from the 3'-termini of RNA than by termination signals encoded in the primary structure of DNA. The stable location of pauses in certain short oligonucleotides: AUG, AUU, AAU and some others is in favour of the hypothesis.     

Biochemistry of terminal deoxynucleotidyltransferase: identification, characterization, requirements, and active-site involvement in the catalysis of associated pyrophosphate exchange and pyrophosphorolytic activity

Terminal deoxynucleotidyltransferase (TdT) has been found to catalyze both pyrophosphate exchange and pyrophosphorolysis reactions. Both reactions are strongly inhibited by antiserum to TdT. The reactions require the presence of a divalent cation, a single- or double-stranded oligomeric or polymeric DNA or RNA, and deoxyribonucleoside triphosphates (for PPi exchange only). Of the three divalent cations tested, Mg2+ and Co2+ are equally effective, while Mn2+ neither is used for catalysis nor inhibits the Mg2+-catalyzed reactions. Ribonucleoside triphosphates have been found to support the PPi exchange reaction to a minor extent and have no inhibitory effect on the catalysis mediated by dNTPs. Inhibition studies, using SH group inhibitors, Zn chelator, and a substrate binding site specific reagent, revealed that PPi exchange and pyrophosphorolysis reactions may be distinguished by differences in their sensitivity to inhibition by various reagents. While the PPi exchange reaction is strongly inhibited by sulfhydryl reagents, o-phenanthroline, and pyridoxal phosphate, the pyrophosphorolysis reaction is insensitive to these reagents. In addition, the pyrophosphorolysis reaction is also found not to require a free 3'-OH terminus of a primer. This difference in the susceptibility of the two reactions indicates that discrete active-site structures exist in TdT which catalyze PPi exchange and pyrophosphorolysis reactions.     

Orotate phosphoribosyltransferase and hypoxanthine/guanine phosphoribosyltransferase from yeast: kinetic analysis with chromium (III) pyrophosphate

The reactions catalyzed by orotate phosphoribosyltransferase (OPRTase) and hypoxanthine/guanine phosphoribosyltransferase (HGPRTase) from yeast differ in the kinetic mechanisms by which they are activated by divalent metal ions. Moreover, whereas OPRTase is activated specifically by Mg(II) or Mn(II), the reactions catalyzed by HGPRTase can utilize a wider range of divalent metal ions, including Mg(II), Mn(II), Co(II), and Zn(II). In this report we describe the results of a kinetic analysis of the effects of the addition of Cr(III) pyrophosphate (Cr-PPi) to the OPRTase and HGPRTase assay solutions, which delineates further the differences between these enzyme activations by metal ions. (1) Cr-PPi is an effective competitive inhibitor of the OPRTase catalysis, when the steady-state forward velocity of orotidine monophosphate (OMP) formation is examined over a range of phosphoribosyl alpha-pyrophosphate (PRibPP) concentrations, whereas pyrophosphate (PPi) has been reaffirmed to be a noncompetitive product inhibitor under the same conditions. (2) Cr-PPi itself serves as a substrate for the OPRTase-catalyzed reverse pyrophosphorolysis of OMP and does not inhibit the utilization of PPi as substrate during this reaction. (3) In contrast, Cr-PPi, at concentrations as high as 6 mM, has no effect on the HGPRTase-catalyzed formation of inosine monophosphate, whereas the inhibition exhibited by PPi during this reaction is noncompetitive but defined by two sets of lines in the double reciprocal plot of the initial velocity versus 1/PRibPP. (4) Cr-PPi is not a substrate for the HGPRTase-catalyzed pyrophosphorolysis of IMP under the conditions of these assay procedures.     

Selective inhibition of 3'-5'-exonuclease activity of DNA-polymerase I from Escherichia coli by a fluoride ion

The effect of NaF on the enzymatic activities of the large fragment of E. coli DNA polymerase I (Klenow enzyme-KE) with different DNA-substrates was studied. It was shown that fluoride ion at concentrations of 5-10 mM efficiently inhibits the 3'----5' exonuclease activity of KE but does not affect the polymerase activity of the enzyme. Selective inhibition of the 3'----5' exonuclease activity of KE is Mg-dependent and is observed with double- or single-stranded DNAs. In reaction with the 14-mer oligonucleotide annealed with single-stranded phage M13 DNA the enzyme was found not only to perform the exonucleolytic hydrolysis of the primers but to catalyse also a limited elongation of some primers, adding a few nucleotide residues in the absence of exogenous dNTP. The primer elongation is inhibited by inorganic pyrophosphatase and is stimulated by micromolar concentrations of exogenous pyrophosphate thus suggesting a possible role of PPi contamination in dNTP generation via pyrophosphorolysis. Traces of precursors in DNA preparations obtained by generally employed methods may serve as another source of nucleotides for the primer elongation.     

Flow cytometric platform for high-throughput single nucleotide polymorphism analysis

We have developed a rapid, cost-effective, high-throughput readout for single nucleotide polymorphism (SNP) genotyping using flow cytometric analysis performed on a Luminex 100 flow cytometer. This robust technique employs a PCR-derived target DNA containing the SNP, a synthetic SNP-complementary ZipCode-bearing capture probe, a fluorescent reporter molecule, and a thermophilic DNA polymerase. An array of fluorescent microspheres, covalently coupled with complementary ZipCode sequences (cZipCodes), was hybridized to the reaction products and sequestered them for flow cytometric analysis. The single base chain extension (SBCE) reaction was used to assay 20 multiplexed SNPs for 633 patients in 96-well format. Comparison of the microsphere-based SBCE assay results to gel-based oligonucleotide ligation assay (OLA) results showed 99.3% agreement in genotype assignments. Substitution of direct-labeled R6G dideoxynucleotide with indirect-labeled phycoerythrin dideoxynucleotide enhanced signal five- to tenfold while maintaining low noise levels. A new assay based on allele-specific primer extension (ASPE) was validated on a set of 15 multiplexed SNPs for 96 patients. ASPE offers both the advantage of streamlining the SNP analysis protocol and the ability to perform multiplex SNP analysis on any mixture of allelic variants.     

Kinetic mechanism of DNA polymerase I (Klenow)

The minimal kinetic scheme for DNA polymerization catalyzed by the Klenow fragment of DNA polymerase I (KF) from Escherichia coli has been determined with short DNA oligomers of defined sequence. A key feature of this scheme is a minimal two-step sequence that interconverts the ternary KF.DNAn.dNTP and KF.DNAn+1.PPi complexes. The rate is not limited by the actual polymerization but by a separate step, possibly important in ensuring fidelity [Mizrahi, V., Henrie, R. N., Marlier, J. F., Johnson, K. A., & Benkovic, S. J. (1985) Biochemistry 24, 4010-4018]. Evidence for this sequence is supplied by the observation of biphasic kinetics in single-turnover pyrophosphorolysis experiments (the microscopic reverse of polymerization). Data analysis then provides an estimate of the internal equilibrium constant. The dissociations of DNA, dNTP, and PPi from the various binary and ternary complexes were measured by partitioning (isotope-trapping) experiments. The rate constant for DNA dissociation from KF is sequence dependent and is rate limiting during nonprocessive DNA synthesis. The combination of single-turnover (both directions) and isotope-trapping experiments provides sufficient information to permit a quantitative evaluation of the kinetic scheme for specific DNA sequences.     

Characterization and mapping of the pyrophosphorolytic activity of the phage phi 29 DNA polymerase. Involvement of amino acid motifs highly conserved in alpha-like DNA polymerases.

The phi 29 DNA polymerase, an alpha-like DNA polymerase, shows an inorganic pyrophosphate-dependent degradative activity with similar requirements to the corresponding one of Escherichia coli DNA polymerase I: (a) it requires a high concentration of inorganic pyrophosphate and is reversed by polymerization; (b) like DNA polymerization, it needs a duplex DNA with protruding 5' single-strand; (c) it acts in the 3' to 5' direction releasing free dNTPs, thus, it can be considered as the reversal of polymerization; (d) although a correctly base-paired 3' primer terminus is the preferred substrate, the pyrophosphorolytic activity is able to remove mismatched 3' ends. In agreement with the structural and functional model previously proposed for the phi 29 DNA polymerase, the analysis of point mutations has revealed that the pyrophosphorolytic activity, like the polymerization activity, is located at the C-terminal portion of the molecule, involving the amino acid motif YCDTD, highly conserved in alpha-like DNA polymerases. Furthermore, the analysis of phi 29 DNA polymerase mutants indicates that pyrophosphorolysis, like DNA polymerization, also requires an efficient translocation of the enzyme along the template.     

Proofreading genotyping assays mediated by high fidelity exo+ DNA polymerases

DNA polymerases with 3'-5' proofreading function mediate high fidelity DNA replication but their application for mutation detection was almost completely neglected before 1998. The obstacle facing the use of exo(+) polymerases for mutation detection could be overcome by primer-3'-termini modification, which has been tested using allele-specific primers with 3' labeling, 3' exonuclease-resistance and 3' dehydroxylation modifications. Accordingly, three new types of single nucleotide polymorphism (SNP) assays have been developed to carry out genome-wide genotyping making use of the fidelity advantage of exo(+) polymerases. Such SNP assays might also provide a novel approach for re-sequencing and de novo sequencing. These new mutation detection assays are widely adaptable to a variety of platforms, including real-time PCR, multi-well plate and microarray technologies. Application of exo(+) polymerases to genetic analysis could accelerate the pace of personalized medicine.     

Calcium is a cofactor of polymerization but inhibits pyrophosphorolysis by the Sulfolobus solfataricus DNA polymerase Dpo4

Y-Family DNA polymerase IV (Dpo4) from Sulfolobus solfataricus serves as a model system for eukaryotic translesion polymerases, and three-dimensional structures of its complexes with native and adducted DNA have been analyzed in considerable detail. Dpo4 lacks a proofreading exonuclease activity common in replicative polymerases but uses pyrophosphorolysis to reduce the likelihood of incorporation of an incorrect base. Mg(2+) is a cofactor for both the polymerase and pyrophosphorolysis activities. Despite the fact that all crystal structures of Dpo4 have been obtained in the presence of Ca(2+), the consequences of replacing Mg(2+) with Ca(2+) for Dpo4 activity have not been investigated to date. We show here that Ca(2+) (but not Ba(2+), Co(2+), Cu(2+), Ni(2+), or Zn(2+)) is a cofactor for Dpo4-catalyzed polymerization with both native and 8-oxoG-containing DNA templates. Both dNTP and ddNTP are substrates of the polymerase in the presence of either Mg(2+) or Ca(2+). Conversely, no pyrophosphorolysis occurs in the presence of Ca(2+), although the positions of the two catalytic metal ions at the active site appear to be very similar in mixed Mg(2+)/Ca(2+)- and Ca(2+)-form Dpo4 crystals.