Kinetic mechanism of DNA polymerase I (Klenow)

Influence of 5'-nearest neighbors on the insertion kinetics of the fluorescent nucleotide analog 2-aminopurine by Klenow fragment

The effects of nearest neighbor interactions between a nucleotide base at the primer 3'-terminus and an incoming deoxyribonucleoside triphosphate on DNA polymerase catalyzed insertion were examined. Kinetics of inserting the fluorescent nucleotide analog 2-aminopurine deoxyribonucleotide (dAPMP) and dAMP opposite a template T by 3'-->5' exonuclease-deficient mutants of Klenow fragment (KF-) were measured on primer/templates of identical sequence except for the base pair at the 3'-primer terminus. In addition to its fluorescence properties, 2-aminopurine (AP) is an attractive probe because it is misinserted opposite T by polymerases at much higher frequencies than natural nucleotides. Misinsertion frequencies for AP are on the same order of magnitude as variations in misinsertion frequencies due to changes in local DNA sequence, which makes the statistical significance of these variations easier to document. We have established that changes in the fluorescence of AP can be used to follow the insertion of dAPMP on both steady-state and pre-steady-state time scales. Rates of insertion of dAPMP measured by fluorescence and by a polyacrylamide gel assay were similar and are sensitive to the identity of the base at the 3'-primer twice as fast as insertion following a primer terminus T. The difference in rates arises primarily from differences in kcat values, which were fastest next to G and slowest next to T, while apparent Km values were similar next to each of the 4 different nearest neighbors. The gel assay was used to measure AP misinsertion efficiencies by two methods: (1) by having dAPTP and dATP directly compete for insertion opposite T in the same reaction and (2) by measuring Vmax/Km values for each substrate in separate reactions. The results from the direct competition and separate kinetics measurements are similar. The misinsertion efficiency of dAPMP relative to dAMP opposite a template T was significantly higher next to a 3'-primer terminus G (f(ins) = 0.31 +/- 0.06) than next to T (f(ins) = 0.15 +/- 0.03) for the KF- single mutant (D42A). The corresponding misinsertion efficiencies next to a 3'-primer terminus G and T were 0.20 +/- 0.02 and 0.16, respectively, for the KF- double mutant (D355A, E357A). Relative rates of insertion of dAPMP and dAMP correlate with melting temperatures calculated for nearest neighbor doublets which reflect the relative base-stacking energies. In addition to changes in insertion kinetics, polymerase-DNA dissociation rates varied with the identity of the 3'-primer terminus, differing by as much as 7-20-fold depending on the polymerase and the primer/template.

Multi-stage proofreading in DNA replication

The mechanisms by which DNA polymerases achieve their remarkable fidelity, including base selection and proofreading, are briefly reviewed. Nine proofreading models from the current literature are evaluated in the light of steady-state and transient kinetic studies of E. coli DNA polymerase I, the best-studied DNA polymerase. One model is demonstrated to predict quantitatively the response of DNA polymerase I to three mutagenic probes of proofreading: exogenous pyrophosphate, deoxynucleoside monophosphates, and the next correct deoxynucleoside triphosphate substrate, as well as the response to combinations of these probes. The theoretical analysis allows elimination of many possible proofreading mechanisms based on the kinetic data. A structural hypothesis links the kinetic analysis with crystallographic, NMR and genetic studies. It would appear that DNA polymerase I proofreads each potential error twice, at the same time undergoing two conformational changes within a catalytic cycle. Multi-stage proofreading is more efficient, and may be utilized in other biological systems as well. In fact, recent evidence suggests that fidelity of transfer RNA charging may be ensured by a similar mechanism.

Rapid kinetic analysis of a point mutant of HIV-1 reverse transcriptase lacking ribonuclease H activity

The comparative kinetics of RNA-dependent DNA polymerization catalyzed by wild-type HIV-1 reverse transcriptase and a point mutant specifically lacking RNase H activity were analyzed using a heteropolymeric substrate consisting of a 19-mer primer hybridized to a 345-nucleotide RNA template. The rapid-quench product distributions generated under single-turnover conditions, in which primer extension by the two enzymes was restricted to the incorporation of 5 nucleotides (N+5), were significantly different. Whereas the wild-type enzyme catalyzed synthesis of the N+5 product over the time course of the reaction (20 ms-10 s) with a relatively low degree of processivity, the extent of accumulation of the intermediate N+2 and N+3 products was grossly exaggerated in the parallel mutant-catalyzed time course. The observation of concomitant polymerase-dependent hydrolysis during the course of synthesis catalyzed by the wild-type enzyme suggested that the inability of the RNase H- mutant to hydrolyze the RNA template created blocks to further synthesis by reducing the rates of DNA polymerization at these intermediate positions, and hence impaired the ability of this mutant to complete cDNA synthesis.

Mechanism of calf thymus DNA primase: slow initiation, rapid polymerization, and intelligent termination

The mechanism by which calf thymus DNA primase synthesizes RNA primers was examined. Primase first binds a single-stranded DNA template (KD << 100 nM) and can then slide along the DNA in order to find a start for initiating primer synthesis. NTP binding appears ordered, such that the NTP which eventually becomes the second nucleotide of the primer binds the E.DNA complex first. The NTP that becomes the second nucleotide of the primer thereby influences where primase initiates. Primer synthesis is remarkably slow (0.0027 s-1 at 20 microM NTP). The rate-limiting step is after formation of the E.DNA.NTP.NTP complex and before or during dinucleotide synthesis. After synthesis of the dinucleotide, additional NTPs are rapidly polymerized. Primase products are 2-10 nucleotides long. If the enzyme fails to synthesize a primer at least 7 nucleotides long, it reinitiates rather than dissociating from the template. Once a primer at least 7 nucleotides long has been generated, however, subsequent primase activity is inhibited. This inhibition is due to the generation of a stable primer-template complex, which likely remains associated with pol alpha.primase. The role of primase is to synthesize primers that pol alpha can elongate. The ability of primase to distinguish between primers at least 7 nucleotides long and shorter products therefore likely reflects the fact that pol alpha only utilizes primers at least 7 nucleotides long.

Biochemical basis of DNA replication fidelity

DNA polymerase is the critical enzyme maintaining genetic integrity during DNA replication. Individual steps in the replication process that contribute to DNA synthesis fidelity include nucleotide insertion, exonucleolytic proofreading, and binding to and elongation of matched and mismatched primer termini. Each process has been investigated using polyacrylamide gel electrophoresis (PAGE) to resolve 32P-labeled primer molecules extended by polymerase. We describe how integrated gel band intensities can be used to obtain site-specific velocities for addition of correct and incorrect nucleotides, extending mismatched compared to correctly matched primer termini and measuring polymerase dissociation rates and equilibrium DNA binding constants. The analysis is based on steady-state "single completed hit conditions", where polymerases encounter many DNA molecules but where each DNA encounters an enzyme at most once. Specific topics addressed include nucleotide misinsertion, mismatch extension, exonucleolytic proofreading, single nucleotide discrimination using PCR, promiscuous mismatch extension by HIV-1 and AMV reverse transcriptases, sequence context effects on fidelity and polymerase dissociation, structural and kinetic properties of mispairs relating to fidelity, error avoidance mechanisms, kinetics of copying template lesions, the "A-rule" for insertion at abasic template lesions, an interesting exception to the "A-rule", thermodynamic and kinetic determinants of base pair discrimination by polymerases.

Inhibitors of HIV-1 reverse transcriptase and fidelity of in vitro DNA replication

Mechanisms of the effects of the dTTP analogues 3'-azido-3'-deoxythymidine 5'-triphosphate (AZTTP) and 3'-amino-3'-deoxythymidine 5'-triphosphate (NH2 TTP) upon the HIV-1 reverse transcriptase (RT) are discussed. These compounds block the RT in vitro and do so by different kinetic mechanisms. Infidelity of replication is a hallmark of the HIV-1 RT, and replication errors by the enzyme on RNA and DNA templates are discussed. The enzyme's infidelity has ramifications for inhibition: On the one hand, the propensity to produce mutations enhances the ability of the virus to escape inhibitors whereas on the other hand, the infidelity of the reverse transcriptase may allow the development of imaginative inhibitor strategies.

Energetics of 3-oxo-delta 5-steroid isomerase: source of the catalytic power of the enzyme

Knowledge of the partitioning of the putative dienol intermediate (2) by steroid isomerase (KSI) (Hawkinson et al. 1991), in conjunction with various steady-state kinetic parameters, allows elucidation of the detailed free energy profile for the KSI-catalyzed conversion of 5-androstene-3,17-dione (1) to 4-androstene-3,17-dione (3). This free energy profile shows four kinetically significant energy barriers (substrate binding, the two chemical steps, and dissociation of product) that must be traversed upon conversion of 1 to 3. Thus, no single step of the catalytic cycle is cleanly rate-limiting. The source of the catalytic power of KSI is discussed via comparison of the free energy profile for the KSI-catalyzed isomerization with those for the acetate-catalyzed isomerization and the aqueous reaction at pH 7. Similarities between the energetics of the KSI-catalyzed and triosephosphate isomerase catalyzed reactions are also noted.

The role of RNA polymerase in transcriptional fidelity

The overall transcription of DNA has previously been demonstrated to proceed at extremely high levels of accuracy. We review the evidence that the process of transcription is subject to proof-reading in the Hopfield sense. In addition, we speculate that the proof-reading activity associated with transcription is subject to cyclical phase transitions. That is, during periods of low processivity associated with initiation, RNA synthesis is relatively imprecise. The transition to the elongation phase of RNA synthesis, characterized by a shift to high processivity, is accompanied by enhanced proof-reading. A model for the damping of transcriptional errors, based on a PPi-mediated processive pyrophosphorolysis reaction, is discussed in terms of pausing during transcription.

Chemical, molecular biology, and genetic techniques for correlating DNA base damage induced by ionizing radiation with biological end points

The types of DNA base damage induced by ionizing radiation, and also relevant model system investigations on replication and mutagenesis, are reviewed in this paper. Recent advances in DNA synthesis technology and site-directed mutagenesis suggest that these methods can be profitably utilized to correlate specific types of DNA base damage with selected biological end points. A deeper insight can be obtained into the molecular origins of mutations, and the effects of base sequence surrounding the lesions on the nature and types of mutations.

cis-syn thymine dimers are not absolute blocks to replication by DNA polymerase I of Escherichia coli in vitro

Both Escherichia coli DNA polymerase I (pol I) and the large fragment of pol I (Klenow) were found to bypass a site-specific cis-syn thymine dimer, in vitro, under standard conditions. A template was constructed by ligating d(pCGTAT[c,s]TATGC), synthesized via a cis-syn thymine dimer phosphoramidite building block, to a 12-mer and 19-mer. The site and integrity of the dimer were verified by use of T4 denV endonuclease V. Extension of a 15-mer on the dimer-containing template by either pol I or Klenow led to dNTP and polymerase concentration dependent formation of termination and bypass products. At approximately 0.15 unit/microL and 1-10 microM in each dNTP, termination one prior to the 3'-T of the dimer predominated. At 100 microM in each dNTP termination opposite the 3'-T of the dimer predominated and bypass occurred. Bypass at 100 microM in each dNTP depended on polymerase concentration, reaching a maximum of 20% in 1 h at approximately 0.2 unit/microL, underscoring the importance of polymerase binding affinity for damaged primer-templates on bypass. Seven percent bypass in 1 h occurred under conditions of 100:10 microM dATP:dNTP bias, 1% under dTTP bias, and an undetectable amount under either dGTP or dCTP bias. At 100 microM in each dNTP, the ratio of pdA:pdG:pdC:pdT terminating opposite the 3'-T of the dimer was estimated to be 37:25:10:28. Sequencing of the bypass product produced under these conditions demonstrated that greater than 95% pdA was incorporated opposite both Ts of the dimer and that little or no frame shifting took place.(ABSTRACT TRUNCATED AT 250 WORDS)

Metal ion dependence of phosphorothioate ATP analogues in the Bacillus stearothermophilus tyrosyl-tRNA synthetase reaction

Pre-steady-state kinetic analyses on the formation of tyrosyl adenylate from tyrosine and each of the four diastereomers of alpha- and beta-phosphorothioate adenosine triphosphates [ATP alpha S and ATP beta S; Eckstein, F., & Goody, R. (1976) Biochemistry 15, 1685-1691; Yee, D., Armstrong, V. W., & Eckstein, F. (1979) Biochemistry 18, 4116-4123] were performed in the presence of Mg2+, Co2+, and Cd2+ as the divalent metal ion cofactor. A modest preference of 5.5-fold in kappa 3/KA' (where kappa 3 is the rate constant for tyrosyl adenylate formation and KA' is the dissociation constant for ATP, or phosphorothioate ATP, from the E.Tyr.metal.ATP complex) for the Sp ATP alpha S diastereomer and the absence of an inversion of preference when the metal ion is changed suggest that there is a stereospecific enzyme-alpha-phosphate interaction and that there is no direct metal ion interaction with the alpha-phosphate. The extent of reaction of the ATP alpha S diastereomers (30-50%) implies that these analogues are more susceptible to the hydrolytic site reaction previously reported for this enzyme [Wells, T. N. C., & Fersht, A. R. (1986) Biochemistry 25, 1881-1886]. The strong preference in kappa 3/KA' for the RP ATP beta S diastereomer (16-fold for Mg2+ and 50-fold for Co2+) is indicative of a stereospecific interaction with the pro SP beta oxygen of ATP.(ABSTRACT TRUNCATED AT 250 WORDS)

The efficiency of interaction of deoxyribonucleoside-5'-mono-, di- and triphosphates with the active centre of E. coli DNA polymerase I Klenow fragment

The interaction of deoxyribonucleoside-5'-mono-, di- and triphosphates with E. coli DNA polymerase I Klenow fragments was examined. Dissociation constants of the enzyme complex with nucleotides were determined from the data on the enzyme inactivation by adenosine 2',3'-riboepoxide 5'-triphosphate. The role of nucleotide bases, phosphate groups and sugar moieties in the complex formation of nucleotides with the enzyme was elucidated. The necessity of complementary interaction of nucleotides with templates for template-controlled 'adjusting' of complementary dNTP to its reactive state was found. The crucial role of the interaction of dNTP gamma-phosphate with the enzyme in this process is discussed.

Effect of Sarkosyl and heparin on single-step addition reactions catalysed by wheat-germ RNA polymerase II--poly[d(A-T)]transcription complexes

Incubation of purified wheat-germ RNA polymerase II with poly[d(A-T)] template, Mn2+, U-A dinucleoside monophosphate primer and UTP substrate resulted in catalytic formation of the trinucleoside diphosphate U-A-U, in accordance with the results of previous studies. Both Sarkosyl and heparin inhibited completely and immediately (within less than 1 min) U-A-U synthesis, if either of these compounds was added to the assays during the progress of the reaction. This behaviour is in marked contrast to that reported for single-step addition reactions catalysed by Escherichia coli RNA polymerase on the same template [Sylvester & Cashel (1980) Biochemistry 19, 1069-1074]. However, treatment of the transcription complexes with Sarkosyl or heparin for periods sufficient to abolish U-A-U formation completely did not suppress completely the ability of such complexes to elongate RNA chains. Hence, the effect of Sarkosyl or heparin on the rate of U-A-U synthesis was predominantly due to change in the rate (or in the mechanism) of trinucleotide product release by the transcription complexes. Furthermore, once U-A-U synthesis has begun on the poly[d(A-T)] template, the transcription complexes became resistant to the action of a competitor DNA such as poly[d(G-C)]. The results are consistent with a model where at least a sizeable fraction of the enzyme molecules remains associated with the DNA template upon formation of a single phosphodiester bond.

Fluorescent oligonucleotides and deoxynucleotide triphosphates: preparation and their interaction with the large (Klenow) fragment of Escherichia coli DNA polymerase I

Fluorescent derivatives of short oligonucleotides of defined sequence were prepared by the incorporation of 5-(propylamino)uridine via current phosphoramidite chemistry, followed by derivatization of the propylamine function with mansyl chloride. These oligomers, annealed to complementary oligomers, yielded short duplex DNA fluorescently labeled at a specific base. The fluorescence emission from this labeled duplex increases upon binding to the Klenow fragment of DNA polymerase I (KF) at specific positions within the duplex DNA. By varying the position of the label within the duplex DNA and observing the emission, points of strong enzyme-DNA interactions were elucidated. A similar fluorescent derivative of a deoxynucleoside triphosphate (dNTP), 5-[[[[[[(5- sulfonaphthalenyl)amino]ethyl]amino]carbonyl]- methyl]thio]-2'-deoxyuridine 5'-triphosphate (AEDANS-S-dUTP), was synthesized, whose emission also was increased upon binding to KF. The change in emission intensities between unbound and bound substrates enabled the measurements of KDs for the DNA and dNTP derivative, which were found to be 0.15 nM and 2.9 microM, respectively. Stopped-flow measurements on these species yielded association and dissociation rates for each. Anisotropy measurements of the labeled base at various positions in the duplex yielded values that support the measurements made by observing the emission intensities.

Stereochemistry of RNA cleavage by the Tetrahymena ribozyme and evidence that the chemical step is not rate-limiting

The intervening sequence of the ribosomal RNA precursor of Tetrahymena is a catalytic RNA molecule, or ribozyme. Acting as a sequence-specific endoribonuclease, it cleaves single-stranded RNA substrates with concomitant addition of guanosine. The chemistry of the reaction has now been studied by introduction of a single phosphorothioate in the substrate RNA at the cleavage site. Kinetic studies show no significant effect of this substitution on kcat (rate constant) or Km (Michaelis constant), providing evidence that some step other than the chemical step is rate-limiting. Product analysis reveals that the reaction proceeds with inversion of configuration at phosphorus, consistent with an in-line, SN2 (P) mechanism. Thus, the ribozyme reaction is in the same mechanistic category as the individual displacement reactions catalyzed by protein nucleotidyltransferases, phosphotransferases, and nucleases.

Reversibility of nucleotide incorporation by Escherichia coli RNA polymerase, and its effect on fidelity

During transcription, Escherichia coli RNA polymerase is capable of removing the nucleotide that it has just added to a growing RNA chain, and this removal depends on the presence of small concentrations of pyrophosphate. Chemically, the removal reaction is simply the reversal of the incorporation reaction, and we have observed the generation of free triphosphate as a result. After the removal the enzyme can continue synthesis. To test whether this reaction can provide an error correction mechanism, misincorporation rates were measured at a single position in an RNA transcript by withholding the correct nucleotide for that position, measuring the amount of readthrough transcript, and analyzing the readthrough transcripts with nearest-neighbor analysis and enzymatic RNA sequencing. The removal of pyrophosphate increases the rate of misincorporation. We present a theory that explains how reversible incorporation can increase the available discrimination free energy between correct and incorrect nucleotides and therefore may increase the fidelity of transcription. The formation of a covalent phosphodiester bond allows discrimination on the basis of helical structure as well as base-pairing. We propose that the important discrimination step is the translocation of the enzyme from one site on the DNA template to the next, and that reversible incorporation is necessary in order to take full advantage of the maximum discrimination free energy.

The fidelity of base selection by the polymerase subunit of DNA polymerase III holoenzyme

In common with other DNA polymerases, DNA polymerase III holoenzyme of E. coli selects the biologically correct base pair with remarkable accuracy. DNA polymerase III is particularly useful for mechanistic studies because the polymerase and editing activities reside on separate subunits. To investigate the biochemical mechanism for base insertion fidelity, we have used a gel electrophoresis assay to measure kinetic parameters for the incorporation of correct and incorrect nucleotides by the polymerase (alpha) subunit of DNA polymerase III. As judged by this assay, base selection contributes a factor of roughly 10(4)-10(5) to the overall fidelity of genome duplication. The accuracy of base selection is determined mainly by the differential KM of the enzyme for correct vs. incorrect deoxynucleoside triphosphate. The misinsertion of G opposite template A is relatively efficient, comparable to that found for G opposite T. Based on a variety of other work, the G:A pair may require a special correction mechanism, possibly because of a syn-anti pairing approximating Watson-Crick geometry. We suggest that precise recognition of the equivalent geometry of the Watson-Crick base pairs may be the most critical feature for base selection.

A slow kinetic transient in RNA synthesis catalysed by wheat-germ RNA polymerase II

Progress curves of U-A-primed RNA synthesis catalysed by wheat-germ RNA polymerase II on a poly[d(A-T)] template exhibit a slow burst of activity. In contrast, the progress curves of single-step addition of UMP to U-A primer in the abortive elongation reaction do not exhibit the slow burst of activity. The correlation between the kinetic transient in the productive pathway of RNA synthesis and the rate of abortive elongation is suggestive of the occurrence of a slow conformational change of the transcription complex during the transition from abortive to productive elongation. The exceptional duration of the transient burst (in the region of 4 min) may suggest a transition of a hysteretic type.