Kinetic mechanism of DNA polymerase I (Klenow)

Virtual terminator nucleotides for next-generation DNA sequencing

We synthesized reversible terminators with tethered inhibitors for next generation sequencing. These were efficiently incorporated with high fidelity while preventing incorporation of additional nucleotides and were used to sequence canine bacterial artificial chromosomes in a single-molecule system that provided even coverage for over 99% of the region sequenced. This single-molecule approach generated high quality sequence data without the need for target amplification and thus avoided concomitant biases.

Variations on a theme: eukaryotic Y-family DNA polymerases

Most classical DNA polymerases, which function in normal DNA replication and repair, are unable to synthesize DNA opposite damage in the template strand. Thus in order to replicate through sites of DNA damage, cells are equipped with a variety of nonclassical DNA polymerases. These nonclassical polymerases differ from their classical counterparts in at least two important respects. First, nonclassical polymerases are able to efficiently incorporate nucleotides opposite DNA lesions while classical polymerases are generally not. Second, nonclassical polymerases synthesize DNA with a substantially lower fidelity than do classical polymerases. Many nonclassical polymerases are members of the Y-family of DNA polymerases, and this article focuses on the mechanisms of the four eukaryotic members of this family: polymerase eta, polymerase kappa, polymerase iota, and the Rev1 protein. We discuss the mechanisms of these enzymes at the kinetic and structural levels with a particular emphasis on how they accommodate damaged DNA substrates. Work over the last decade has shown that the mechanisms of these nonclassical polymerases are fascinating variations of the mechanism of the classical polymerases. The mechanisms of polymerases eta and kappa represent rather minor variations, while the mechanisms of polymerase iota and the Rev1 protein represent rather major variations. These minor and major variations all accomplish the same goal: they allow the nonclassical polymerases to circumvent the problems posed by the template DNA lesion.

Chemical synthesis, DNA incorporation and biological study of a new photocleavable 2'-deoxyadenosine mimic

The phototriggered cleavage of chemical bonds has found numerous applications in biology, particularly in the field of gene sequencing through photoinduced DNA strand scission. However, only a small number of modified nucleosides that are able to cleave DNA at selected positions have been reported in the literature. Herein, we show that a new photoactivable deoxyadenosine analogue, 3-nitro-3-deaza-2'-deoxyadenosine (d(3-NiA)), was able to induce DNA backbone breakage upon irradiation (lambda > 320 nm). The d(3-NiA) nucleoside was chemically incorporated at desired positions into 40-mer oligonucleotides as a phosphoramidite monomer and subsequent hybridization studies confirmed that the resulting modified duplexes display a behaviour that is close to that of the related natural sequence. Enzymatic action of the Klenow fragment exonuclease free revealed the preferential incorporation of dAMP opposite the 3-NiA base. On the other hand, incorporation of the analogous 3-NiA triphosphate to a primer revealed high enzyme efficiency and selectivity for insertion opposite thymine. Furthermore, only the enzymatically synthesized base pair 3-NiA:T was a substrate for further extension by the enzyme. All the hybridization and enzymatic data indicate that this new photoactivable 3-NiA triphosphate can be considered as a photochemically cleavable dATP analogue.

Mapping the position of DNA polymerase-bound DNA templates in a nanopore at 5 A resolution

DNA polymerases are molecular motors that catalyze template-dependent DNA replication, advancing along template DNA by one nucleotide with each catalytic cycle. Nanopore-based measurements have emerged as a single molecule technique for the study of these enzymes. Using the alpha-hemolysin nanopore, we determined the position of DNA templates bearing inserts of abasic (1',2'-dideoxy) residues, bound to the Klenow fragment of Escherichia coli DNA polymerase I (KF) or to bacteriophage T7 DNA polymerase. Hundreds of individual polymerase complexes were analyzed at 5 A precision within minutes. We generated a map of current amplitudes for DNA-KF-deoxynucleoside triphosphate (dNTP) ternary complexes, using a series of templates bearing blocks of three abasic residues that were displaced by approximately 5 A in the nanopore lumen. Plotted as a function of the distance of the abasic insert from n = 0 in the active site of the enzyme held atop the pore, this map has a single peak. The map is similar when the primer length, the DNA sequences flanking the abasic insert, and the DNA sequences in the vicinity of the KF active site are varied. Primer extension catalyzed by KF using a three abasic template in the presence of a mixture of dNTPs and 2',3'-dideoxynucleoside triphosphates resulted in a ladder of ternary complexes with discrete amplitudes that closely corresponded to this map. An ionic current map measured in the presence of 0.15 M KCl mirrored the map obtained with 0.3 M KCl, permitting experiments with a broader range of mesophilic DNA and RNA processing enzymes. We used the abasic templates to show that capture of complexes with the KF homologue, T7 DNA polymerase, yields an amplitude map nearly indistinguishable from the KF map.

Specific nucleotide binding and rebinding to individual DNA polymerase complexes captured on a nanopore

Nanoscale pores are a tool for single molecule analysis of DNA or RNA processing enzymes. Monitoring catalytic activity in real time using this technique requires that these enzymes retain function while held atop a nanopore in an applied electric field. Using an alpha-hemolysin nanopore, we measured the dwell time for complexes of DNA with the Klenow fragment of Escherichia coli DNA polymerase I (KF) as a function of the concentration of deoxynucleoside triphosphate (dNTP) substrate. We analyzed these dwell time measurements in the framework of a two-state model for captured complexes (DNA-KF binary and DNA-KF-dNTP ternary states). Average nanopore dwell time increased without saturating as a function of correct dNTP concentration across 4 orders of magnitude. This arises from two factors that are proportional to dNTP concentration: (1) The fraction of complexes that are in the ternary state when initially captured predominantly affects dwell time at low dNTP concentrations. (2) The rate of binding and rebinding of dNTP to captured complexes affects dwell time at higher dNTP concentrations. Thus there are two regimes that display a linear relationship between average dwell time and dNTP concentration. The transition from one linear regime to the other occurs near the equilibrium dissociation constant (K(d)) for dNTP binding to KF-DNA complexes in solution. We conclude from the combination of titration experiments and modeling that DNA-KF complexes captured atop the nanopore retain iterative, sequence-specific dNTP binding, as required for catalysis and fidelity in DNA synthesis.

Identifying the features of purine dNTPs that allow accurate and efficient DNA replication by herpes simplex virus I DNA polymerase

To accurately replicate its viral genome, the Herpes Simplex Virus 1 (HSV-1) DNA polymerase usually polymerizes the correct natural 2'-deoxy-5'-triphosphate (dNTP) opposite the template base being replicated. We employed a series of purine-dNTP analogues to determine the chemical features of the base necessary for the herpes polymerase to avoid polymerizing incorrect dNTPs. The enzyme uses N-3 to prevent misincorporation of purine dNTPs but does not require N-3 for correct polymerization. A free pair of electrons on N-1 also helps prevent misincorporation opposite A, C, and G and strongly drives polymerization opposite T. N6 contributes a small amount both for preventing misincorporation and for correct polymerization. Within the context of guanine in either the incoming dNTP or the template base being replicated, N2 prevents misincorporation opposite adenine but plays at most a minor role for incorporation opposite C. In contrast, adding N2 to the dNTPs of either adenine, purine, 6-chloropurine, or 1-deazapurine greatly enhances incorporation opposite C, likely via the formation of a hydrogen bond between N2 of the purine and O2 of the pyrimidine. Herpes polymerase is very sensitive to the structure of the base pair at the primer 3'-terminus since eliminating N-1, N-3, or N6 from a purine nucleotide at the primer 3'-terminus interfered with polymerization of the next two dNTPs. The biological and evolutionary implications of these data are discussed.

Rpb9 subunit controls transcription fidelity by delaying NTP sequestration in RNA polymerase II

Rpb9 is a small non-essential subunit of yeast RNA polymerase II located on the surface on the enzyme. Deletion of the RPB9 gene shows synthetic lethality with the low fidelity rpb1-E1103G mutation localized in the trigger loop, a mobile element of the catalytic Rpb1 subunit, which has been shown to control transcription fidelity. Similar to the rpb1-E1103G mutation, the RPB9 deletion substantially enhances NTP misincorporation and increases the rate of mismatch extension with the next cognate NTP in vitro. Using pre-steady state kinetic analysis, we show that RPB9 deletion promotes sequestration of NTPs in the polymerase active center just prior to the phosphodiester bond formation. We propose a model in which the Rpb9 subunit controls transcription fidelity by delaying the closure of the trigger loop on the incoming NTP via interaction between the C-terminal domain of Rpb9 and the trigger loop. Our findings reveal a mechanism for regulation of transcription fidelity by protein factors located at a large distance from the active center of RNA polymerase II.

Contribution of the reverse rate of the conformational step to polymerase beta fidelity

A complete understanding of the kinetic mechanism of fidelity requires comparison of correct and incorrect dNTP incorporation pathways in both the forward and reverse directions. The studies presented here focus on the dNTP-induced conformational step, which has historically been proposed by many to be the major determinant of fidelity. As it was recently highlighted [Tsai, Y. C., and Johnson, K. A. (2006) Biochemistry 45, 9675-9687], chemistry can be the slowest step in the forward direction of the correct dNTP incorporation pathway, yet the corresponding microscopic rate constant would not contribute toward fidelity in the case when the reverse rate of the conformational step is slower than chemistry. Here we use a stopped-flow technique to directly measure the reverse rate of the conformational step in the DNA polymerase beta (Pol beta) kinetic pathway. Extensive pre-steady-state kinetic studies presented include the utilization of 2-aminopurine-labeled DNA substrates, 2-aminopurine nucleotide triphosphate, a nonhydrolyzable nucleotide analogue dAMPCPP, and a rapid sequential mixing reaction scheme. Additionally, the effect of mismatched dNTPs, various metal ions, and the presence of the 3'-terminal hydroxyl group of the primer on the rate of the reverse "opening" conformational step were analyzed. Our analyses indicate that reverse "opening" is drastically facilitated in the presence of mismatched ternary complexes, which is in agreement with the hypothesis that the ternary complex is destabilized by the presence of incorrect dNTP. By analysis of the relative magnitudes of chemistry and reverse "opening" in the presence of both matched and mismatched matched ternary complexes, this work further validates that, for Pol beta, fidelity is dictated by the differences in free energy required to reach the highest energy transition state of the chemical step.

Insights into the high fidelity of a DNA polymerase I mutant

Mutants of DNA polymerase I from Thermus aquaticus (Taq) with higher fidelity compared to the wild type enzyme were identified in an earlier study by Summerer et al. (Angew Chem Int Ed 44:4712-4715, 2005). Here, one of these mutants, PLQ (consensus residues 879-881), was analysed using molecular dynamics simulations. This was done by calculating the structures of the ternary complex comprising the enzyme, the DNA primer and template as well as the incoming nucleotide before the chemical reaction for the Watson-Crick and different mismatched base pairings. The results show that the high fidelity of the mutant can be explained partly by different specific interactions between the amino acids of the enzyme and the DNA primer end as well as, in some mismatches, a displacement of the primer relative to the incoming deoxyribonucleoside triphosphate and the catalytic magnesium ion. This displacement is facilitated by reduced steric interactions between the enzyme and the DNA.

Role of the 2-amino group of purines during dNTP polymerization by human DNA polymerase alpha

We used a series of dNTP analogues in conjunction with templates containing modified bases to elucidate the role that N(2) of a purine plays during dNTP polymerization by human DNA polymerase alpha. Removing N(2) from dGTP had small effects during correct incorporation opposite C but specifically increased misincorporation opposite A. Adding N(2) to dATP and related analogues had small and variable effects on the efficiency of polymerization opposite T. However, the presence of N(2) greatly enhanced polymerization of these dATP analogues opposite a template C. The ability of N(2) to enhance polymerization opposite C likely results from formation of a hydrogen bond between the purine N(2) and pyrimidine O(2). Even in those cases where formation of a wobble base pair, tautomerization, and/or protonation of the base pair between the incoming dNTP and template base cannot occur (e.g., 2-pyridone.purine (or purine analogue) base pairs), N(2) enhanced formation of the base pair. Importantly, N(2) had similar effects on dNTP polymerization both when added to the incoming purine dNTP and when added to the template base being replicated. The mechanistic implications of these results regarding how pol alpha discriminates between right and wrong dNTPs are discussed.

Kinetics of deoxy-CTP incorporation opposite a dG-C8-N-2-aminofluorene adduct by a high-fidelity DNA polymerase

The model carcinogen N-2-acetylaminofluorene covalently binds to the C8 position of guanine to form two adducts, the N-(2'-deoxyguanosine-8-yl)-aminofluorene (G-AF) and the N-2-(2'-deoxyguanosine-8-yl)-acetylaminofluorene (G-AAF). Although they are chemically closely related, their biological effects are strongly different and they are processed by different damage tolerance pathways. G-AF is bypassed by replicative and high-fidelity polymerases, while specialized polymerases ensure synthesis past of G-AAF. We used the DNA polymerase I fragment of a Bacillus stearothermophilus strain as a model for a high-fidelity polymerase to study the kinetics of incorporation of deoxy-CTP (dCTP) opposite a single G-AF. Pre-steady-state kinetic experiments revealed a drastic reduction in dCTP incorporation performed by the G-AF-modified ternary complex. Two populations of these ternary complexes were identified: (i) a minor productive fraction (20%) that readily incorporates dCTP opposite the G-AF adduct with a rate similar to that measured for the adduct-free ternary complexes and (ii) a major fraction of unproductive complexes (80%) that slowly evolve into productive ones. In the light of structural data, we suggest that this slow rate reflects the translocation of the modified base within the active site, from the pre-insertion site into the insertion site. By making this translocation rate limiting, the G-AF lesion reveals a novel kinetic step occurring after dNTP binding and before chemistry.

Versatility of Y-family Sulfolobus solfataricus DNA polymerase Dpo4 in translesion synthesis past bulky N2-alkylguanine adducts

In contrast to replicative DNA polymerases, Sulfolobus solfataricus Dpo4 showed a limited decrease in catalytic efficiency (k(cat)/Km) for insertion of dCTP opposite a series of N2-alkylguanine templates of increasing size from (methyl (Me) to (9-anthracenyl)-Me (Anth)). Fidelity was maintained with increasing size up to (2-naphthyl)-Me (Naph). The catalytic efficiency increased slightly going from the N2-NaphG to the N2-AnthG substrate, at the cost of fidelity. Pre-steady-state kinetic bursts were observed for dCTP incorporation throughout the series (N2-MeG to N2-AnthG), with a decrease in the burst amplitude and k(pol), the rate of single-turnover incorporation. The pre-steady-state kinetic courses with G and all of the six N2-alkyl G adducts could be fit to a general DNA polymerase scheme to which was added an inactive complex in equilibrium with the active ternary Dpo4.DNA.dNTP complex, and only the rates of equilibrium with the inactive complex and phosphodiester bond formation were altered. Two crystal structures of Dpo4 with a template N2-NaphG (in a post-insertion register opposite a 3'-terminal C in the primer) were solved. One showed N2-NaphG in a syn conformation, with the naphthyl group located between the template and the Dpo4 "little finger" domain. The Hoogsteen face was within hydrogen bonding distance of the N4 atoms of the cytosine opposite N2-NaphG and the cytosine at the -2 position. The second structure showed N2-Naph G in an anti conformation with the primer terminus largely disordered. Collectively these results explain the versatility of Dpo4 in bypassing bulky G lesions.

Kinetic analysis of correct nucleotide insertion by a Y-family DNA polymerase reveals conformational changes both prior to and following phosphodiester bond formation as detected by tryptophan fluorescence

The Sulfolobus solfataricus Y-family DNA polymerase Dpo4 is a model for translesion replication and has been used in the analysis of individual steps involved in catalysis. The role of conformational changes has not been clear. Introduction of Trp residues into the Trp-devoid wild-type protein provided fluorescence probes of these events, particularly in the case of mutants T239W and N188W. With both mutants, a rapid increase in Trp fluorescence was observed only in the case of normal base pairing (G:C), was saturable with respect to dCTP concentration, and occurred in the absence of phosphodiester bond formation. A subsequent decrease in the Trp fluorescence occurred when phosphodiester bond formation was permitted, and these rates were independent of the dCTP concentration. This step is relatively slow and is attributed to a conformational relaxation step occurring after pyrophosphate release, which was measured and shown to be fast in a separate experiment. The measured rate of release of DNA from Dpo4 was rapid and is not rate-limiting. Overall, the measurements provide a kinetic scheme for Dpo4 different than generally accepted for replicative polymerases or proposed for Dpo4 and other Y-family polymerases: the initial enzyme.DNA.dNTP complex undergoes a rapid (18 s(-1)), reversible (21 s(-1)) conformational change, followed by relatively rapid phosphodiester bond formation (11 s(-1)) and then fast release of pyrophosphate, followed by a rate-limiting relaxation of the active conformation (2 s(-1)) and then rapid DNA release, yielding an overall steady-state kcat of <1 s(-1).

DNA polymerases and aminoacyl-tRNA synthetases: shared mechanisms for ensuring the fidelity of gene expression

DNA polymerases and aminoacyl-tRNA synthetases (ARSs) represent large enzyme families with critical roles in the transformation of genetic information from DNA to RNA to protein. DNA polymerases carry out replication and collaborate in the repair of the genome, while ARSs provide aminoacylated tRNA precursors for protein synthesis. Enzymes of both families face the common challenge of selecting their cognate small molecule substrates from a pool of chemically related molecules, achieving high levels of discrimination with the assistance of proofreading mechanisms. Here, the fidelity preservation mechanisms in these two important systems are reviewed and similar features highlighted. Among the noteworthy features common to both DNA polymerases and ARSs are the use of multidomain architectures that segregate synthetic and proofreading functions into discrete domains; the use of induced fit to enhance binding selectivity; the imposition of fidelity at the level of chemistry; and the use of postchemistry error correction mechanisms to hydrolyze incorrect products in a discrete editing domain. These latter mechanisms further share the common property that error correction involves the translocation of misincorporated products from the synthetic to the editing site and that the accuracy of the process may be influenced by the rates of translocation in either direction. Fidelity control in both families can thus be said to rely on multiple elementary steps, each with its contribution to overall fidelity. The summed contribution of these kinetic checkpoints provides the high observed overall accuracy of DNA replication and aminoacylation.

Varied active-site constraints in the klenow fragment of E. coli DNA polymerase I and the lesion-bypass Dbh DNA polymerase

We report on comparative pre-steady-state kinetic analyses of exonuclease-deficient Escherichia coli DNA polymerase I (Klenow fragment, KF-) and the archaeal Y-family DinB homologue (Dbh) of Sulfolobus solfataricus. We used size-augmented sugar-modified thymidine-5'-triphosphate (T(R)TP) analogues to test the effects of steric constraints in the active sites of the polymerases. These nucleotides serve as models for study of DNA polymerases exhibiting both relatively high and low intrinsic selectivity. Substitution of a hydrogen atom at the 4'-position in the nucleotide analogue by a methyl group reduces the maximum rate of nucleotide incorporation by about 40-fold for KF- and about twelve fold for Dbh. Increasing the size to an ethyl group leads to a further twofold reduction in the rates of incorporation for both enzymes. Interestingly, the affinity of KF- for the modified nucleotides is only marginally affected, which would indicate no discrimination during the binding step. Dbh even has a higher affinity for the modified analogues than it does for the natural substrate. Misincorporation of either TTP or T(Me)TP opposite a G template causes a drastic decline in incorporation rates for both enzymes. At the same time, the binding affinities of KF- for these nucleotides drop by about 16- and fourfold, respectively, whereas Dbh shows only a twofold reduction. Available structural data for ternary complexes of relevant DNA polymerases indicate that both enzymes make close contacts with the sugar moiety of the dNTP. Thus, the varied proficiencies of the two enzymes in processing the size-augmented probes indicate varied flexibility of the enzymes' active sites and support the notion of active site tightness being a criterion for DNA polymerase selectivity.

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.

Opposed steric constraints in human DNA polymerase beta and E. coli DNA polymerase I

DNA polymerase selectivity is crucial for the survival of any living species, yet varies significantly among different DNA polymerases. Errors within DNA polymerase-catalyzed DNA synthesis result from the insertion of noncanonical nucleotides and extension of misaligned DNA substrates. The substrate binding characteristics among DNA polymerases are believed to vary in properties such as shape and tightness of the binding pocket, which might account for the observed differences in fidelity. Here, we employed 4'-alkylated nucleotides and primer strands bearing 4'-alkylated nucleotides at the 3'-terminal position as steric probes to investigate differential active site properties of human DNA polymerase beta (Pol beta) and the 3'-->5'-exonuclease-deficient Klenow fragment of E. coli DNA polymerase I (KF(exo-)). Transient kinetic measurements indicate that both enzymes vary significantly in active site tightness at both positions. While small 4'-methyl and -ethyl modifications of the nucleoside triphosphate perturb Pol beta catalysis, extension of modified primer strands is only marginally affected. Just the opposite was observed for KF(exo-). Here, incorporation of the modified nucleotides is only slightly reduced, whereas size augmentation of the 3'-terminal nucleotide in the primer reduces the catalytic efficiency by more than 7000- and 260,000-fold, respectively. NMR studies support the notion that the observed effects derive from enzyme substrate interactions rather than inherent properties of the modified substrates. These findings are consistent with the observed differential capability of the investigated DNA polymerases in fidelity such as processing misaligned DNA substrates. The results presented provide direct evidence for the involvement of varied steric effects among different DNA polymerases on their fidelity.

Formation of purine-purine mispairs by Sulfolobus solfataricus DNA polymerase IV

DNA damage that stalls replicative polymerases can be bypassed with the Y-family polymerases. These polymerases have more open active sites that can accommodate modified nucleotides. The lack of protein-DNA interactions that select for Watson-Crick base pairs correlate with the lowered fidelity of replication. Interstrand hydrogen bonds appear to play a larger role in dNTP selectivity. The mechanism by which purine-purine mispairs are formed and extended was examined with Solfolobus solfataricus DNA polymerase IV, a member of the RAD30A subfamily of the Y-family polymerases, as is pol eta. The structures of the purine-purine mispairs were examined by comparing the kinetics of mispair formation with adenine versus 1-deaza- and 7-deazaadenine and guanine versus 7-deazaguanine at four positions in the DNA, the incoming dNTP, the template base, and both positions of the terminal base pair. The time course of insertion of a single dNTP was examined with a polymerase concentration of 50 nM and a DNA concentration of 25 nM with various concentrations of dNTP. The time courses were fitted to a first-order equation, and the first-order rate constants were plotted against the dNTP concentration to produce k pol and K d (dNTP) values. A decrease in k pol/ K d (dNTP) associated with the deazapurine substitution would indicate that the position is involved in a crucial hydrogen bond. During correct base pair formation, the adenine to 1-deazaadenine substitution in both the incoming dNTP and template base resulted in a >1000-fold decrease in k pol/ K d (dNTP), indicating that interstrand hydrogen bonds are important in correcting base pair formation. During formation of purine-purine mispairs, the k pol/ K d (dNTP) values for the insertion of dATP and dGTP opposite 7-deazaadenine and 7-deazaguanine were decreased >10-fold with respect to those of the unmodified nucleotides. In addition, the rate of incorporation of 1-deaza-dATP opposite guanine was decreased 5-fold. These results suggest that during mispair formation the newly forming base pair is in a Hoogsteen geometry with the incoming dNTP in the anti conformation and the template base in the syn conformation. These results indicate that Dpo4 holds the incoming dNTP in the normal anti conformation while allowing the template nucleotide to change conformations to allow reaction to occur. This result may be functionally relevant in the replication of damaged DNA in that the polymerase may allow the template to adopt multiple configurations.

An intramolecular FRET system monitors fingers subdomain opening in Klentaq1

A major goal of polymerase research is to determine the mechanism through which a nucleotide complementary to a templating DNA base is selected and delivered to the polymerase active site. Structural evidence suggests a large open-to-closed conformational change affecting the fingers subdomain as being crucial to the process. We previously designed a FRET system capable of measuring the rate of fingers subdomain closure in the presence of correct nucleotide. However, this FRET system was limited in that it could not directly measure the rate of fingers subdomain opening by FRET after polymerization or in the absence of DNA. Here we report the development of a new system capable of measuring both fingers subdomain closure and reopening by FRET, and show that the rate of fingers subdomain opening is limited only by the rate of polymerization. We anticipate that this system will scale down to the single molecule level, allowing measurement of fingers subdomain movements in the presence of incorrect nucleotide and in the absence of DNA.

Structural insights into mechanisms of catalysis and inhibition in Norwalk virus polymerase

Crystal structures of Norwalk virus polymerase bound to an RNA primer-template duplex and either the natural substrate CTP or the inhibitor 5-nitrocytidine triphosphate have been determined to 1.8A resolution. These structures reveal a closed conformation of the polymerase that differs significantly from previously determined open structures of calicivirus and picornavirus polymerases. These closed complexes are trapped immediately prior to the nucleotidyl transfer reaction, with the triphosphate group of the nucleotide bound to two manganese ions at the active site, poised for reaction to the 3'-hydroxyl group of the RNA primer. The positioning of the 5-nitrocytidine triphosphate nitro group between the alpha-phosphate and the 3'-hydroxyl group of the primer suggests a novel, general approach for the design of antiviral compounds mimicking natural nucleosides and nucleotides.

Probing nonnucleoside inhibitor-induced active-site distortion in HIV-1 reverse transcriptase by transient kinetic analyses

Nonnucleoside reverse transcriptase inhibitors (NNRTI) are a group of structurally diverse compounds that bind to a single site in HIV-1 reverse transcriptase (RT), termed the NNRTI-binding pocket (NNRTI-BP). NNRTI binding to RT induces conformational changes in the enzyme that affect key elements of the polymerase active site and also the association between the two protein subunits. To determine which conformational changes contribute to the mechanism of inhibition of HIV-1 reverse transcription, we used transient kinetic analyses to probe the catalytic events that occur directly at the enzyme's polymerase active site when the NNRTI-BP was occupied by nevirapine, efavirenz, or delavirdine. Our results demonstrate that all NNRTI-RT-template/primer (NNRTI-RT-T/P) complexes displayed a metal-dependent increase in dNTP binding affinity (K(d) ) and a metal-independent decrease in the maximum rate of dNTP incorporation (k (pol)). The magnitude of the decrease in k (pol) was dependent on the NNRTI used in the assay: Efavirenz caused the largest decrease followed by delavirdine and then nevirapine. Analyses that were designed to probe direct effects on phosphodiester bond formation suggested that the NNRTI mediate their effects on the chemistry step of the DNA polymerization reaction via an indirect manner. Because each of the NNRTI analyzed in this study exerted largely similar phenotypic effects on single nucleotide addition reactions, whereas each of them are known to exert differential effects on RT dimerization, we conclude that the NNRTI effects on subunit association do not directly contribute to the kinetic mechanism of inhibition of DNA polymerization.

Analysis of human telomerase activity and function by two color single molecule coincidence fluorescence spectroscopy

Telomerase is a nonclassical DNA polymerase that uses its integral RNA as a template to synthesize telomeric repeats onto chromosome ends. The molecular mechanism of telomerase is unique and involves a translocation step after the synthesis of each telomeric repeat. To directly measure the enzymatic turnover of substrate and the efficiency of the translocation step we have extended our two-color single molecule fluorescence coincidence method (Anal.Chem. 2003, 75, 1664-1670). The method employs Cy5-dATP incorporation into a DNA primer that has been prelabeled with a reference fluorophore. Measurements are performed in the single molecule regime and products, which necessarily have both fluorophores, are excited by two independent lasers, and give rise to coincident events. By counting the number of coincident events and using the coincidence detection efficiency, it is possible to determine the number of the extended products generated by attomole quantities of telomerase, without separation or the use of PCR or radioactivity. Histograms of the logarithms of the ratios of the Cy5 to the reference fluorophore fluorescence can be used to determine the length distribution of the products and hence the enzyme processivity. The mean processivity obtained from the single molecule fluorescence coincidence assay is 0.32 +/- 0.04, in good agreement with the value of 0.37 +/- 0.05 derived from the direct radioactive assay approach. The function of the alignment domain of human telomerase RNA in sustaining catalytic activity in vitro has been reevaluated using this method. Together with our previous results (Nucleic Acids Res. 2002, 30, 4470-4480) these experiments identify the essential residues in the alignment domain of human telomerase RNA that contribute to the activity and processivity of telomerase.

Single-molecule and ensemble fluorescence assays for a functionally important conformational change in T7 DNA polymerase

We report fluorescence assays for a functionally important conformational change in bacteriophage T7 DNA polymerase (T7 pol) that use the environmental sensitivity of a Cy3 dye attached to a DNA substrate. An increase in fluorescence intensity of Cy3 is observed at the single-molecule level, reflecting a conformational change within the T7 pol ternary complex upon binding of a dNTP substrate. This fluorescence change is believed to reflect the closing of the T7 pol fingers domain, which is crucial for polymerase function. The rate of the conformational change induced by a complementary dNTP substrate was determined by both conventional stopped-flow and high-time-resolution continuous-flow fluorescence measurements at the ensemble-averaged level. The rate of this conformational change is much faster than that of DNA synthesis but is significantly reduced for noncomplementary dNTPs, as revealed by single-molecule measurements. The high level of selectivity of incoming dNTPs pertinent to this conformational change is a major contributor to replicative fidelity.

A pre-equilibrium before nucleotide binding limits fingers subdomain closure by Klentaq1

Numerous studies have been undertaken to establish the mechanism of dNTP binding and template-directed incorporation by DNA polymerases. It has been established by kinetic experiments that a rate-limiting step, crucial for dNTP selection, occurs before chemical bond formation. Crystallographic studies indicated that this step may be due to a large open-to-closed conformational transition affecting the fingers subdomain. In previous studies, we established a fluorescence resonance energy transfer system to monitor the open-to-closed transition in the fingers subdomain of Klentaq1. By comparing the rates of the fingers subdomain closure with that of the rate-limiting step for Klentaq1, we showed that fingers subdomain motion was significantly faster than the rate-limiting step. We have now used this system to characterize DNA binding as well as to complete a more extensive characterization of incorporation of all four dNTPs. The data indicate that DNA binding occurs by a two-step association and that dissociation of the DNA is significantly slower in the case of the closed ternary complex. The data for nucleotide incorporation indicate a step occurring before dNTP binding, which differs for all four nucleotides. As the only difference between the (E x p/t) complexes is the templating base, it would suggest an important role for the templating base in initial ground state selection.

Kinetic analysis of the entire RNA amplification process by Qbeta replicase

The kinetics of the RNA replication reaction by Qbeta replicase were investigated. Qbeta replicase is an RNA-dependent RNA polymerase responsible for replicating the RNA genome of coliphage Qbeta and plays a key role in the life cycle of the Qbeta phage. Although the RNA replication reaction using this enzyme has long been studied, a kinetic model that can describe the entire RNA amplification process has yet to be determined. In this study, we propose a kinetic model that is able to account for the entire RNA amplification process. The key to our proposed kinetic model is the consideration of nonproductive binding (i.e. binding of an enzyme to the RNA where the enzyme cannot initiate the reaction). By considering nonproductive binding and the notable enzyme inactivation we observed, the previous observations that remained unresolved could also be explained. Moreover, based on the kinetic model and the experimental results, we determined rate and equilibrium constants using template RNAs of various lengths. The proposed model and the obtained constants provide important information both for understanding the basis of Qbeta phage amplification and the applications using Qbeta replicase.

Viscoelastic modeling of template-directed DNA synthesis

In the present study, we have used the QCM-D technology to study the replication of surface attached oligonucleotide template strands using Escherichia coli DNA polymerase I (Klenow fragment, KF). Changes in resonance frequency (F) and energy dissipation (D) for DNA hybridization and polymerization were recorded at multiple harmonics. Formation of the polymerase/DNA complex led to a significant decrease in energy dissipation, which is consistent with a conformational change induced upon enzyme binding. This interpretation was further strengthened by a data analysis using a Voigt-based viscoelastic model. The analysis revealed a significant increase in shear viscosity and shear modulus during KF binding, whereas the viscoelastic properties of single- and double-stranded templates were almost identical. During the actual DNA synthesis, an initial increase in rigidity (shear viscosity) was followed by a gradual decrease that has two components corresponding to the release of enzyme and to the presence of the catalytically active enzyme/substrate complex. The corresponding decrease in surface concentration was found to underestimate the rate of enzyme release due to viscously coupled water that compensates for the loss in enzyme mass. Furthermore, the modeling elucidates that significant changes in both F and D originate from variations in the viscoelastic properties, which means that changes in F alone should be used with care for estimations of coupled mass and kinetics. Therefore, the modeled temporal variation in effective thickness, being proportional to coupled mass and, thus, independent of structural changes, was used to estimate the catalytic constants of the polymerization reaction. The reported work is the first example providing this type of structural information for the catalytic action of an enzyme, thereby demonstrating the potential of the technique for advanced analysis of complex biological reactions, including proper analysis of enzyme kinetics.

Stable complexes formed by HIV-1 reverse transcriptase at distinct positions on the primer-template controlled by binding deoxynucleoside triphosphates or foscarnet

Binding of the next complementary dNTP by the binary complex containing HIV-1 reverse transcriptase (RT) and primer-template induces conformational changes that have been implicated in catalytic function of RT. We have used DNase I footprinting, gel electrophoretic mobility shift, and exonuclease protection assays to characterize the interactions between HIV-1 RT and chain-terminated primer-template in the absence and presence of various ligands. Distinguishable stable complexes were formed in the presence of foscarnet (an analog of pyrophosphate), the dNTP complementary to the first (+1) templating nucleotide or the dNTP complementary to the second (+2) templating nucleotide. The position of HIV-1 RT on the primer-template in each of these complexes is different. RT is located upstream in the foscarnet complex, relative to the +1 complex, and downstream in the +2 complex. These results suggest that HIV-1 RT can translocate along the primer-template in the absence of phosphodiester bond formation. The ability to form a specific foscarnet complex might explain the inhibitory properties of this compound. The ability to recognize the second templating nucleotide has implications for nucleotide misincorporation.

Two proton transfers in the transition state for nucleotidyl transfer catalyzed by RNA- and DNA-dependent RNA and DNA polymerases

The rate-limiting step for nucleotide incorporation in the pre-steady state for most nucleic acid polymerases is thought to be a conformational change. As a result, very little information is available on the role of active-site residues in the chemistry of nucleotidyl transfer. For the poliovirus RNA-dependent RNA polymerase (3D(pol)), chemistry is partially (Mg(2+)) or completely (Mn(2+)) rate limiting. Here we show that nucleotidyl transfer depends on two ionizable groups with pK(a) values of 7.0 or 8.2 and 10.5, depending upon the divalent cation used in the reaction. A solvent deuterium isotope effect of three to seven was observed on the rate constant for nucleotide incorporation in the pre-steady state; none was observed in the steady state. Proton-inventory experiments were consistent with two protons being transferred during the rate-limiting transition state of the reaction, suggesting that both deprotonation of the 3'-hydroxyl nucleophile and protonation of the pyrophosphate leaving group occur in the transition state for phosphodiester bond formation. Importantly, two proton transfers occur in the transition state for nucleotidyl-transfer reactions catalyzed by RB69 DNA-dependent DNA polymerase, T7 DNA-dependent RNA polymerase and HIV reverse transcriptase. Interpretation of these data in the context of known polymerase structures suggests the existence of a general base for deprotonation of the 3'-OH nucleophile, although use of a water molecule cannot be ruled out conclusively, and a general acid for protonation of the pyrophosphate leaving group in all nucleic acid polymerases. These data imply an associative-like transition-state structure.

Human DNA polymerase alpha uses a combination of positive and negative selectivity to polymerize purine dNTPs with high fidelity

DNA polymerases accurately replicate DNA by incorporating mostly correct dNTPs opposite any given template base. We have identified the chemical features of purine dNTPs that human pol alpha uses to discriminate between right and wrong dNTPs. Removing N-3 from guanine and adenine, two high-fidelity bases, significantly lowers fidelity. Analogously, adding the equivalent of N-3 to low-fidelity benzimidazole-derived bases (i.e., bases that pol alpha rapidly incorporates opposite all four natural bases) and to generate 1-deazapurines significantly strengthens the ability of pol alpha to identify the resulting 1-deazapurines as wrong. Adding the equivalent of the purine N-1 to benzimidazole or to 1-deazapurines significantly decreases the rate at which pol alpha polymerizes the resulting bases opposite A, C, and G while simultaneously enhancing polymerization opposite T. Conversely, adding the equivalent of adenine's C-6 exocyclic amine (N-6) to 1- and 3-deazapurines also enhances polymerization opposite T but does not significantly decrease polymerization opposite A, C, and G. Importantly, if the newly inserted bases lack N-1 and N-6, pol alpha does not efficiently polymerize the next correct dNTP, whereas if it lacks N-3, one additional nucleotide is added and then chain termination ensues. These data indicate that pol alpha uses two orthogonal screens to maximize its fidelity. During dNTP polymerization, it uses a combination of negative (N-1 and N-3) and positive (N-1 and N-6) selectivity to differentiate between right and wrong dNTPs, while the shape of the base pair is essentially irrelevant. Then, to determine whether to add further dNTPs onto the just added nucleotide, pol alpha appears to monitor the shape of the base pair at the primer 3'-terminus. The biological implications of these results are discussed.

Interplay between primase and replication factor C in the hyperthermophilic archaeon Sulfolobus solfataricus

The heterodimeric primase from the hyperthermophilic archaeon Sulfolobus solfataricus synthesizes long RNA and DNA products in vitro. How primer synthesis by primase is coupled to primer extension by DNA polymerase in this organism is unclear. Here we show that the small subunit of the clamp loader replication factor C (RFC) of S. solfataricus interacted with both the catalytic and non-catalytic subunits of the primase by yeast two-hybrid and co-immunoprecipitation assays. Further, the primase-RFC interaction was also identified in the cell extract of S. solfataricus. Deletion analysis indicated that the small subunit of RFC interacted strongly with the N-terminal domain of the catalytic subunit of the primase. RFC stimulated dinucleotide formation but decreased the amount of primers synthesized by the primase. The inhibition of primer synthesis is consistent with the observation that RFC reduced the affinity of the primase for DNA templates. On the other hand, primase stimulated the ATPase activity of RFC. These findings suggest that the primase-RFC interaction modulates the activities of both enzymes and therefore may be involved in the regulation of primer synthesis and the transfer of primers to DNA polymerase in Archaea.

A unique error signature for human DNA polymerase nu

Human DNA polymerase nu (pol nu) is one of three A family polymerases conserved in vertebrates. Although its biological functions are unknown, pol nu has been implicated in DNA repair and in translesion DNA synthesis (TLS). Pol nu lacks intrinsic exonucleolytic proofreading activity and discriminates poorly against misinsertion of dNTP opposite template thymine or guanine, implying that it should copy DNA with low base substitution fidelity. To test this prediction and to comprehensively examine pol nu DNA synthesis fidelity as a clue to its function, here we describe human pol nu error rates for all 12 single base-base mismatches and for insertion and deletion errors during synthesis to copy the lacZ alpha-complementation sequence in M13mp2 DNA. Pol nu copies this DNA with average single-base insertion and deletion error rates of 7 x 10(-5) and 17 x 10(-5), respectively. This accuracy is comparable to that of replicative polymerases in the B family, lower than that of its A family homolog, human pol gamma, and much higher than that of Y family TLS polymerases. In contrast, the average single-base substitution error rate of human pol nu is 3.5 x 10(-3), which is inaccurate compared to the replicative polymerases and comparable to Y family polymerases. Interestingly, the vast majority of errors made by pol nu reflect stable misincorporation of dTMP opposite template G, at average rates that are much higher than for homologous A family members. This pol nu error is especially prevalent in sequence contexts wherein the template G is preceded by a C-G or G-C base pair, where error rates can exceed 10%. Amino acid sequence alignments based on the structures of more accurate A family polymerases suggest substantial differences in the O-helix of pol nu that could contribute to this unique error signature.

Sequential side-chain residue motions transform the binary into the ternary state of DNA polymerase lambda

The nature of conformational transitions in DNA polymerase lambda (pol lambda), a low-fidelity DNA repair enzyme in the X-family that fills short nucleotide gaps, is investigated. Specifically, to determine whether pol lambda has an induced-fit mechanism and open-to-closed transition before chemistry, we analyze a series of molecular dynamics simulations from both the binary and ternary states before chemistry, with and without the incoming nucleotide, with and without the catalytic Mg(2+) ion in the active site, and with alterations in active site residues Ile(492) and Arg(517). Though flips occurred for several side-chain residues (Ile(492), Tyr(505), Phe(506)) in the active site toward the binary (inactive) conformation and partial DNA motion toward the binary position occurred without the incoming nucleotide, large-scale subdomain motions were not observed in any trajectory from the ternary complex regardless of the presence of the catalytic ion. Simulations from the binary state with incoming nucleotide exhibit more thumb subdomain motion, particularly in the loop containing beta-strand 8 in the thumb, but closing occurred only in the Ile(492)Ala mutant trajectory started from the binary state with incoming nucleotide and both ions. Further connections between active site residues and the DNA position are also revealed through our Ile(492)Ala and Arg(517)Ala mutant studies. Our combined studies suggest that while pol lambda does not demonstrate large-scale subdomain movements as DNA polymerase beta (pol beta), significant DNA motion exists, and there are sequential subtle side chain and other motions-associated with Arg(514), Arg(517), Ile(492), Phe(506), Tyr(505), the DNA, and again Arg(514) and Arg(517)-all coupled to active site divalent ions and the DNA motion. Collectively, these motions transform pol lambda to the chemistry-competent state. Significantly, analogs of these residues in pol beta (Lys(280), Arg(283), Arg(258), Phe(272), and Tyr(271), respectively) have demonstrated roles in determining enzyme efficiency and fidelity. As proposed for pol beta, motions of these residues may serve as gate-keepers by controlling the evolution of the reaction pathway before the chemical reaction.

Wanderings of a DNA enzymologist: from DNA polymerase to viral latency

I am a member of what has been called, perhaps too grandiosely, "The Greatest Generation." I grew up during the Great Depression and served in the U.S. Army during World War II. Because of my military service and the benefits of the GI Bill, I was able to attend college and, later, graduate school. Early in my graduate studies, I became fascinated with enzymes and the biochemical reactions that they catalyze. This fascination has never left me during the 50 years I have been a "DNA enzymologist." I was fortunate to have had as a mentor Arthur Kornberg, one of the great biochemists of the twentieth century, and a splendid group of postdocs and graduate students. I have studied DNA polymerases, DNA nucleases, DNA ligases, and DNA recombinases, enzymes that are critical to our understanding of DNA replication, repair, and recombination. Most recently, I have been studying herpes virus replication and inadvertently wandered into an entirely new area-viral latency.

Translesion synthesis across bulky N2-alkyl guanine DNA adducts by human DNA polymerase kappa

DNA polymerase (pol) kappa is one of the so-called translesion polymerases involved in replication past DNA lesions. Bypass events have been studied with a number of chemical modifications with human pol kappa, and the conclusion has been presented, based on limited quantitative data, that the enzyme is ineffective at incorporating opposite DNA damage but proficient at extending beyond bases paired with the damage. Purified recombinant full-length human pol kappa was studied with a series of eight N(2)-guanyl adducts (in oligonucleotides) ranging in size from methyl- to -CH(2)(6-benzo[a]pyrenyl) (BP). Steady-state kinetic parameters (catalytic specificity, k(cat)/K(m)) were similar for insertion of dCTP opposite the lesions and for extension beyond the N(2)-adduct G:C pairs. Mispairing of dGTP and dTTP was similar and occurred with k(cat)/K(m) values approximately 10(-3) less than for dCTP with all adducts; a similar differential was found for extension beyond a paired adduct. Pre-steady-state kinetic analysis showed moderately rapid burst kinetics for dCTP incorporations, even opposite the bulky methyl(9-anthracenyl)- and BPG adducts (k(p) 5.9-10.3 s(-1)). The rapid bursts were abolished opposite BPG when alpha-thio-dCTP was used instead of dCTP, implying rate-limiting phosphodiester bond formation. Comparisons are made with similar studies done with human pols eta and iota; pol kappa is the most resistant to N(2)-bulk and the most quantitatively efficient of these in catalyzing dCTP incorporation opposite bulky guanine N(2)-adducts, particularly the largest (N(2)-BPG).

RNA aptamers selected against DNA polymerase beta inhibit the polymerase activities of DNA polymerases beta and kappa

DNA polymerase β (polβ), a member of the X family of DNA polymerases, is the major polymerase in the base excision repair pathway. Using in vitro selection, we obtained RNA aptamers for polβ from a variable pool of 8 × 10¹² individual RNA sequences containing 30 random nucleotides. A total of 60 individual clones selected after seven rounds were screened for the ability to inhibit polβ activity. All of the inhibitory aptamers analyzed have a predicted tri-lobed structure. Gel mobility shift assays demonstrate that the aptamers can displace the DNA substrate from the polβ active site. Inhibition by the aptamers is not polymerase specific; inhibitors of polβ also inhibited DNA polymerase κ, a Y-family DNA polymerase. However, the RNA aptamers did not inhibit the Klenow fragment of DNA polymerase I and only had a minor effect on RB69 DNA polymerase activity. Polβ and κ, despite sharing little sequence similarity and belonging to different DNA polymerase families, have similarly open active sites and relatively few interactions with their DNA substrates. This may allow the aptamers to bind and inhibit polymerase activity. RNA aptamers with inhibitory properties may be useful in modulating DNA polymerase actvity in cells.

Concentration of dye-labeled nucleotides incorporated into DNA determined by surface plasmon resonance-surface plasmon fluorescence spectroscopy

A method for the accurate determination of the fraction of surface-attached DNA duplexes exhibiting a single-fluorophore-labeled nucleobase is introduced. The fluorescence signals obtained from surface plasmon field-enhanced fluorescence spectroscopy along with the optical properties of the sensor architecture determined by surface plasmon resonance were employed for the calculation. A Cy5-labeled nucleotide was incorporated into DNA at a well-defined position via template-directed DNA synthesis performed by a DNA polymerase. The sample-to-sample variations associated with the optical properties of the employed metal films caused a small variation in the strength of the evanescent field. This variation was accounted for by evanescent field integration over the DNA layers. The exponential-type relationship between the fraction of DNA with Cy5-dCTP incorporation at the surface and the mole fraction of the Cy5-dCTP in solution indicates the preferential incorporation of nonlabeled nucleotides by the DNA polymerase.

Temperature dependence and thermodynamics of Klenow polymerase binding to primed-template DNA

DNA binding of Klenow polymerase has been characterized with respect to temperature to delineate the thermodynamic driving forces involved in the interaction of this polymerase with primed-template DNA. The temperature dependence of the binding affinity exhibits distinct curvature, with tightest binding at 25-30 degrees C. Nonlinear temperature dependence indicates Klenow binds different primed-template constructs with large heat capacity (DeltaCp) values (-870 to -1220 cal/mole K) and thus exhibits large temperature dependent changes in enthalpy and entropy. Binding is entropy driven at lower temperatures and enthalpy driven at physiological temperatures. Large negative DeltaCp values have been proposed to be a 'signature' of site-specific DNA binding, but type I DNA polymerases do not exhibit significant DNA sequence specificity. We suggest that the binding of Klenow to a specific DNA structure, the primed-template junction, results in a correlated thermodynamic profile that mirrors what is commonly seen for DNA sequence-specific binding proteins. Klenow joins a small number of other DNA-sequence independent DNA binding proteins which exhibit unexpectedly large negative DeltaCp values. Spectroscopic measurements show small conformational rearrangements of both the DNA and Klenow upon binding, and small angle x-ray scattering shows a global induced fit conformational compaction of the protein upon binding. Calculations from both crystal structure and solution structural data indicate that Klenow DNA binding is an exception to the often observed correlation between DeltaCp and changes in accessible surface area. In the case of Klenow, surface area burial can account for only about half of the DeltaCp of binding.

In situ monitoring of polymerase extension rate and adaptive feedback control of PCR by using fluorescence measurements

Real time PCR detection systems based on fluorescence detection from intercalating dyes (such as SYBR Green I) typically take only single point measurements during every cycle to quantify the amplification. In this process key information about enzymatic kinetics is lost. In this work we measure SYBR Green I fluorescence intensity every 0.5 s within a cycle during PCR in polypropylene tubes. We observe that the intensity during the extension cycle increases while the template is being extended. Results obtained for different lengths are used to estimate an in vitro polymerase activity rate of Thermus aquaticus and Thermus brockianus. An important practical consequence of this result is that the extension time of each PCR cycle can be individually optimized while the reaction is in progress. We demonstrate this idea of adaptive feedback control and show that the total number of cycles and total time required to reach maximum fluorescence is reduced as compared to conventional PCR.

Motions of the fingers subdomain of klentaq1 are fast and not rate limiting: implications for the molecular basis of fidelity in DNA polymerases

Various kinetic studies on nucleotide incorporation by DNA polymerases have established that a rate-limiting step occurs that is crucial in the mechanism of discrimination between correct versus incorrect nucleotide. Crystallographic studies have indicated that this step may be due to a large open-to-closed conformational transition affecting the fingers subdomain. However, there is no direct evidence to support this hypothesis. In order to investigate whether or not the open-to-closed conformational transition affecting the fingers subdomain is rate limiting, we have developed a fluorescence resonance energy transfer (FRET) system, which monitors motions of the fingers subdomain. We establish that the closing of the fingers subdomain is significantly faster than the kinetically determined rate-limiting step. We propose that the rate-limiting step occurs after the closing of the fingers subdomain and is caused by local reorganization events in the active site.

Eukaryotic translesion synthesis DNA polymerases: specificity of structure and function

This review focuses on eukaryotic translesion synthesis (TLS) DNA polymerases, and the emphasis is on Saccharomyces cerevisiae and human Y-family polymerases (Pols) eta, iota, kappa, and Rev1, as well as on Polzeta, which is a member of the B-family polymerases. The fidelity, mismatch extension ability, and lesion bypass efficiencies of these different polymerases are examined and evaluated in the context of their structures. One major conclusion is that, despite the overall similarity of basic structural features among the Y-family polymerases, there is a high degree of specificity in their lesion bypass properties. Some are able to bypass a particular DNA lesion, whereas others are efficient at only the insertion step or the extension step of lesion bypass. This functional divergence is related to the differences in their structures. Polzeta is a highly specialized polymerase specifically adapted for extending primer termini opposite from a diverse array of DNA lesions, and depending upon the DNA lesion, it contributes to lesion bypass in a mutagenic or in an error-free manner. Proliferating cell nuclear antigen (PCNA) provides the central scaffold to which TLS polymerases bind for access to the replication ensemble stalled at a lesion site, and Rad6-Rad18-dependent protein ubiquitination is important for polymerase exchange.

Fidelity discrimination in DNA polymerase beta: differing closing profiles for a mismatched (G:A) versus matched (G:C) base pair

Understanding fidelity-the faithful replication or repair of DNA by polymerases-requires tracking of the structural and energetic changes involved, including the elusive transient intermediates, for nucleotide incorporation at the template/primer DNA junction. We report, using path sampling simulations and a reaction network model, strikingly different transition states in DNA polymerase beta's conformational closing for correct dCTP versus incorrect dATP incoming nucleotide opposite a template G. The cascade of transition states leads to differing active-site assembly processes toward the "two-metal-ion catalysis" geometry. We demonstrate that these context-specific pathways imply different selection processes: while active-site assembly occurs more rapidly with the correct nucleotide and leads to primer extension, the enzyme remains open longer, has a more transient closed state, and forms product more slowly when an incorrect nucleotide is present. Our results also suggest that the rate-limiting step in pol beta's conformational closing is not identical to that for overall nucleotide insertion and that the rate-limiting step in the overall nucleotide incorporation process for matched as well as mismatched systems occurs after the closing conformational change.

Pyrosequencing: history, biochemistry and future

BACKGROUND

Pyrosequencing is a DNA sequencing technology based on the sequencing-by-synthesis principle.

METHODS

The technique is built on a 4-enzyme real-time monitoring of DNA synthesis by bioluminescence using a cascade that upon nucleotide incorporation ends in a detectable light signal (bioluminescence). The detection system is based on the pyrophosphate released when a nucleotide is introduced in the DNA-strand. Thereby, the signal can be quantitatively connected to the number of bases added. Currently, the technique is limited to analysis of short DNA sequences exemplified by single-nucleotide polymorphism analysis and genotyping. Mutation detection and single-nucleotide polymorphism genotyping require screening of large samples of materials and therefore the importance of high-throughput DNA analysis techniques is significant. In order to expand the field for pyrosequencing, the read length needs to be improved.

CONCLUSIONS

Th pyrosequencing system is based on an enzymatic system. There are different current and future applications of this technique.

A mathematical model of the Pyrosequencing reaction system

The Pyrosequencing technology is a newly developed DNA sequencing method that monitors DNA nucleotide incorporation in real-time. A set of coupled enzymatic reactions, together with bioluminescence, detects incorporated nucleotides in the form of light pulses, yielding a characteristic light profile. In this study, a biochemical model of the Pyrosequencing reaction system is suggested and implemented. The model is constructed utilizing an assumption of irreversible Michaelis-Menten rate equations and a constant incorporation efficiency. The kinetic parameters are studied and values are chosen to obtain as reliable simulation results as possible. The results presented here show strong resemblance with real experiments. The model is able to capture the dynamics of a single light pulse with great accuracy, as well as the overall characteristics of a whole pyrogram trade mark. The plus- and minus-shift effects observed in experiments are successfully reconstructed by two constant efficiency factors. Furthermore, pulse broadening can partly be explained by apyrase inhibition and successive dilution.

Stereo-selectivity of HIV-1 reverse transcriptase toward isomers of thymidine-5'-O-1-thiotriphosphate

The first pre-steady-state kinetic analysis of the stereo-selective incorporation of Rp- and Sp-isomers of thymidine-5'-O-1-thiotriphosphate (TTPalphaS) by HIV-1 reverse transcriptase (RT) is reported. Rates of polymerization (k(pol)), apparent dissociation constants (K(d)), and substrate specificities (k(pol)/K(d)) were measured for TTP, Rp-TTPalphaS, and Sp-TTPalphaS in the presence of Mg(2+), Mn(2+), and Co(2+). HIV-1 RT exhibits a strong preference to incorporate Sp-TTPalphaS over Rp-TTPalphaS in the presence of Mg(2+); however, this stereo-selective preference was decreased when Mg(2+) was replaced with Mn(2+) and Co(2+). Furthermore, HIV-1 RT exhibited no phosphorothioate elemental effects for the incorporation of Sp-TTPalphaS, but large elemental effects were calculated for Rp-TTPalphaS for each of the metals tested. These results are discussed in relation to our current understanding of the RT active-site structure and the mechanism of DNA synthesis.

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 alpha (pol alpha) 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 alpha 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 alpha 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 alpha 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 alpha and Klenow fragment.

Remote site control of an active site fidelity checkpoint in a viral RNA-dependent RNA polymerase

The kinetic, thermodynamic, and structural basis for fidelity of nucleic acid polymerases remains controversial. An understanding of viral RNA-dependent RNA polymerase (RdRp) fidelity has become a topic of considerable interest as a result of recent experiments that show that a 2-fold increase in fidelity attenuates viral pathogenesis and a 2-fold decrease in fidelity reduces viral fitness. Here we show that a conformational change step preceding phosphoryl transfer is a key fidelity checkpoint for the poliovirus RdRp (3Dpol). We provide evidence that this conformational change step is orientation of the triphosphate into a conformation suitable for catalysis, suggesting a kinetic and structural model for RdRp fidelity that can be extrapolated to other classes of nucleic acid polymerases. Finally, we show that a site remote from the catalytic center can control this checkpoint, which occurs at the active site. Importantly, similar connections between a remote site and the active site exist in a wide variety of viral RdRps. The capacity for sites remote from the catalytic center to alter fidelity suggests new possibilities for targeting the viral RdRp for antiviral drug development.

Mechanism of efficient and accurate nucleotide incorporation opposite 7,8-dihydro-8-oxoguanine by Saccharomyces cerevisiae DNA polymerase eta

Most DNA polymerases incorporate nucleotides opposite template 7,8-dihydro-8-oxoguanine (8-oxoG) lesions with reduced efficiency and accuracy. DNA polymerase (Pol) eta, which catalyzes the error-free replication of template thymine-thymine (TT) dimers, has the unique ability to accurately and efficiently incorporate nucleotides opposite 8-oxoG templates. Here we have used pre-steady-state kinetics to examine the mechanisms of correct and incorrect nucleotide incorporation opposite G and 8-oxoG by Saccharomyces cerevisiae Pol eta. We found that Pol eta binds the incoming correct dCTP opposite both G and 8-oxoG with similar affinities, and it incorporates the correct nucleotide bound opposite both G and 8-oxoG with similar rates. While Pol eta incorporates an incorrect A opposite 8-oxoG with lower efficiency than it incorporates a correct C, it does incorporate A more efficiently opposite 8-oxoG than opposite G. This is mainly due to greater binding affinity for the incorrect incoming dATP opposite 8-oxoG. Overall, these results show that Pol eta replicates through 8-oxoG without any barriers introduced by the presence of the lesion.

Conformational Transition Pathway of Polymerase β/DNA upon Binding Correct Incoming Substrate

The closing conformational transition of wild-type polymerase beta bound to DNA template/primer before the chemical step (nucleotidyl transfer reaction) is simulated using the stochastic difference equation (in length version, "SDEL") algorithm that approximates long-time dynamics. The order of the events and the intermediate states during pol beta's closing pathway are identified and compared to a separate study of pol beta using transition path sampling (TPS) (Radhakrishnan, R.; Schlick, T. Proc. Natl. Acad. Sci. USA 2004, 101, 5970-5975). Results highlight the cooperative and subtle conformational changes in the pol beta active site upon binding the correct substrate that may help explain DNA replication and repair fidelity. These changes involve key residues that differentiate the open from the closed conformation (Asp192, Arg258, Phe272), as well as residues contacting the DNA template/primer strand near the active site (Tyr271, Arg283, Thr292, Tyr296) and residues contacting the beta and gamma phosphates of the incoming nucleotide (Ser180, Arg183, Gly189). This study compliments experimental observations by providing detailed atomistic views of the intermediates along the polymerase closing pathway and by suggesting additional key residues that regulate events prior to or during the chemical reaction. We also show general agreement between two sampling methods (the stochastic difference equation and transition path sampling) and identify methodological challenges involved in the former method relevant to large-scale biomolecular applications. Specifically, SDEL is very quick relative to TPS for obtaining an approximate path of medium resolution and providing qualitative information on the sequence of events; however, associated free energies are likely very costly to obtain because this will require both successful further refinement of the path segments close to the bottlenecks and large computational time.

Structure and mechanism of DNA polymerases

DNA polymerases are molecular motors directing the synthesis of DNA from nucleotides. All polymerases have a common architectural framework consisting of three canonical subdomains termed the fingers, palm, and thumb subdomains. Kinetically, they cycle through various states corresponding to conformational transitions, which may or may not generate force. In this review, we present and discuss the kinetic, structural, and single-molecule works that have contributed to our understanding of DNA polymerase function.