Crystal structures of a ddATP-, ddTTP-, ddCTP, and ddGTP- trapped ternary complex of Klentaq1: insights into nucleotide incorporation and selectivity

Microenvironment-Sensitive Fluorescent Nucleotide Probes from Benzofuran, Benzothiophene, and Selenophene as Substrates for DNA Polymerases

DNA polymerases can process a wide variety of structurally diverse nucleotide substrates, but the molecular basis by which the analogs are processed is not completely understood. Here, we demonstrate the utility of environment-sensitive heterocycle-modified fluorescent nucleotide substrates in probing the incorporation mechanism of DNA polymerases in real time and at the atomic level. The nucleotide analogs containing a selenophene, benzofuran, or benzothiophene moiety at the C5 position of 2'-deoxyuridine are incorporated into oligonucleotides (ONs) with varying efficiency, which depends on the size of the heterocycle modification and the DNA polymerase sequence family used. KlenTaq (A family DNA polymerase) is sensitive to the size of the modification as it incorporates only one heterobicycle-modified nucleotide into the growing polymer, whereas it efficiently incorporates the selenophene-modified nucleotide analog at multiple positions. Notably, in the single nucleotide incorporation assay, irrespective of the heterocycle size, it exclusively adds a single nucleotide at the 3'-end of a primer, which enabled devising a simple two-step site-specific ON labeling technique. KOD and Vent(exo-) DNA polymerases, belonging to the B family, tolerate all the three modified nucleotides and produce ONs with multiple labels. Importantly, the benzofuran-modified nucleotide (BFdUTP) serves as an excellent reporter by providing real-time fluorescence readouts to monitor enzyme activity and estimate the binding events in the catalytic cycle. Further, a direct comparison of the incorporation profiles, fluorescence data, and crystal structure of a ternary complex of KlenTaq DNA polymerase with BFdUTP poised for catalysis provides a detailed understanding of the mechanism of incorporation of heterocycle-modified nucleotides.

Snapshots of a modified nucleotide moving through the confines of a DNA polymerase

Despite being evolved to process the four canonical nucleotides, DNA polymerases are known to incorporate and extend from modified nucleotides, which is the key to numerous core biotechnology applications. The structural basis for postincorporation elongation remained elusive. We successfully crystallized KlenTaq DNA polymerase in six complexes, providing high-resolution snapshots of the modification “moving” from the 3′ terminus upstream to the sixth nucleotide in the primer strand. Combining these data with quantum mechanics/molecular mechanics calculations and biochemical studies elucidates how the enzyme and the modified substrate mutually modulate their conformations without compromising the enzyme’s activity. This highlights the unexpected plasticity of the system as origin of the broad substrate properties of the DNA polymerase and guide for the design of improved systems.

DNA polymerases have evolved to process the four canonical nucleotides accurately. Nevertheless, these enzymes are also known to process modified nucleotides, which is the key to numerous core biotechnology applications. Processing of modified nucleotides includes incorporation of the modified nucleotide and postincorporation elongation to proceed with the synthesis of the nascent DNA strand. The structural basis for postincorporation elongation is currently unknown. We addressed this issue and successfully crystallized KlenTaq DNA polymerase in six closed ternary complexes containing the enzyme, the modified DNA substrate, and the incoming nucleotide. Each structure shows a high-resolution snapshot of the elongation of a modified primer, where the modification “moves” from the 3′-primer terminus upstream to the sixth nucleotide in the primer strand. Combining these data with quantum mechanics/molecular mechanics calculations and biochemical studies elucidates how the enzyme and the modified substrate mutually modulate their conformations without compromising the enzyme’s activity significantly. The study highlights the plasticity of the system as origin of the broad substrate properties of DNA polymerases and facilitates the design of improved systems.

Plant organellar DNA polymerases paralogs exhibit dissimilar nucleotide incorporation fidelity

The coding sequences of plant mitochondrial and chloroplast genomes present a lower mutation rate than the coding sequences of animal mitochondria. However, plant mitochondrial genomes frequently rearrange and present high mutation rates in their noncoding sequences. DNA replication in plant organelles is carried out by two DNA polymerases (DNAP) paralogs. In Arabidopsis thaliana at least one DNAP paralog (AtPolIA or AtPolIB) is necessary for plant viability, suggesting that both genes are partially redundant. To understand how AtPolIs replicate genomes that present low and high mutation rates, we measured their nucleotide incorporation for all 16-base pair combinations in vitro. AtPolIA presents an error rate of 7.26 × 10^-5 , whereas AtPolIB has an error rate of 5.45 × 10^-4 . Thus, AtPolIA and AtPolIB are 3.5 and 26-times less accurate than human mitochondrial DNAP γ. The 8-fold difference in fidelity between both AtPolIs results from a higher catalytic efficiency in AtPolIA. Both AtPolIs extend from mismatches and the fidelity of AtPolIs ranks between high fidelity and lesion bypass DNAPs. The different nucleotide incorporation fidelity between AtPolIs predicts a prevalent role of AtPolIA in DNA replication and AtPolIB in DNA repair. We hypothesize that in plant organelles, DNA mismatches generated during DNA replication are repaired via recombination-mediated or DNA mismatch repair mechanisms that selectively target the coding region and that the mismatches generated by AtPolIs may result in the frequent expansion and rearrangements present in plant mitochondrial genomes.

Deoxynucleoside Triphosphate Containing Pyridazin-3-one Aglycon as a Thymidine Triphosphate Substitute for Primer Extension and Chain Elongation by Klenow Fragments

Deoxynucleoside 5'-triphosphate was synthesized with 3-oxo-2 H-pyridazin-6-yl (Pz^O)-a uracil analogue lacking a 2-keto group-as the nucleobase. Theoretical analyses and hybridization experiments indicated that Pz^O recognizes adenine (A) for formation of a Watson-Crick base pair. Primer extension reactions using nucleoside 5'-triphosphate and the Klenow fragment revealed that the synthetic nucleoside 5'-triphosphate was incorporated into the 3' end of the primer through recognition of A in the template strand. Moreover, the 3'-nucleotide residue harboring Pz^O as the base was resistant to the 3'-exonuclease activity of Klenow fragment exo+. The primer bearing the Pz^O base at the 3' end could function in subsequent chain elongation. These properties of Pz^O were attributed to the presence of an endocyclic nitrogen atom at the position ortho to the glycosidic bond, which was presumed to form an H-bond with the amino acid residue of DNA polymerase for effective recognition of the 3' end of the primer for primer extension. These results provide a basis for designing new nucleobases by combining a nitrogen atom at the position ortho to the glycosidic bond and base-pairing sites for Watson-Crick hydrogen bonding.

Crystal structures of ternary complexes of archaeal B-family DNA polymerases

Archaeal B-family polymerases drive biotechnology by accepting a wide substrate range of chemically modified nucleotides. By now no structural data for archaeal B-family DNA polymerases in a closed, ternary complex are available, which would be the basis for developing next generation nucleotides. We present the ternary crystal structures of KOD and 9°N DNA polymerases complexed with DNA and the incoming dATP. The structures reveal a third metal ion in the active site, which was so far only observed for the eukaryotic B-family DNA polymerase δ and no other B-family DNA polymerase. The structures reveal a wide inner channel and numerous interactions with the template strand that provide space for modifications within the enzyme and may account for the high processivity, respectively. The crystal structures provide insights into the superiority over other DNA polymerases concerning the acceptance of modified nucleotides.

In Vivo Structure-Activity Relationships and Optimization of an Unnatural Base Pair for Replication in a Semi-Synthetic Organism

In an effort to expand the genetic alphabet and create semi-synthetic organisms (SSOs) that store and retrieve increased information, we have developed the unnatural base pairs (UBPs) dNaM and d5SICS or dTPT3 (dNaM-d5SICS and dNaM-dTPT3). The UBPs form based on hydrophobic and packing forces, as opposed to complementary hydrogen bonding, and while they are both retained within the in vivo environment of an Escherichia coli SSO, their development was based on structure-activity relationship (SAR) data generated in vitro. To address the likely possibility of different requirements of the in vivo environment, we screened 135 candidate UBPs for optimal performance in the SSO. Interestingly, we find that in vivo SARs differ from those collected in vitro, and most importantly, we identify four UBPs whose retention in the DNA of the SSO is higher than that of dNaM-dTPT3, which was previously the most promising UBP identified. The identification of these four UBPs further demonstrates that when optimized, hydrophobic and packing forces may be used to replace the complementary hydrogen bonding used by natural pairs and represents a significant advance in our continuing efforts to develop SSOs that store and retrieve more information than natural organisms.

Mirror-Image Thymidine Discriminates against Incorporation of Deoxyribonucleotide Triphosphate into DNA and Repairs Itself by DNA Polymerases

DNA polymerases are known to recognize preferably d-nucleotides over l-nucleotides during DNA synthesis. Here, we report that several general DNA polymerases catalyze polymerization reactions of nucleotides directed by the DNA template containing an l-thymidine (l-T). The results display that the 5'-3' primer extension of natural nucleotides get to the end at chiral modification site with Taq and Phanta Max DNA polymerases, but the primer extension proceeds to the end of the template catalyzed by Deep Vent (exo^-), Vent (exo^-), and Therminator DNA polymerases. Furthermore, templating l-nucleoside displays a lag in the deoxyribonucleotide triphosphate (dNTP) incorporation rates relative to natural template by kinetics analysis, and polymerase chain reactions were inhibited with the DNA template containing two or three consecutive l-Ts. Most interestingly, no single base mutation or mismatch mixture corresponding to the location of l-T in the template was found, which is physiologically significant because they provide a theoretical basis on the involvement of DNA polymerase in the effective repair of l-T that may lead to cytotoxicity.

Crystal Structure of the Apicoplast DNA Polymerase from Plasmodium falciparum: The First Look at a Plastidic A-Family DNA Polymerase

Plasmodium falciparum, the primary cause of malaria, contains a non-photosynthetic plastid called the apicoplast. The apicoplast exists in most members of the phylum Apicomplexa and has its own genome along with organelle-specific enzymes for its replication. The only DNA polymerase found in the apicoplast (apPOL) was putatively acquired through horizontal gene transfer from a bacteriophage and is classified as an atypical A-family polymerase. Here, we present its crystal structure at a resolution of 2.9Å. P. falciparum apPOL, the first structural representative of a plastidic A-family polymerase, diverges from typical A-family members in two of three previously identified signature motifs and in a region not implicated by sequence. Moreover, apPOL has an additional N-terminal subdomain, the absence of which severely diminishes its 3' to 5' exonuclease activity. A compound known to be toxic to Plasmodium is a potent inhibitor of apPOL, suggesting that apPOL is a viable drug target. The structure provides new insights into the structural diversity of A-family polymerases and may facilitate structurally guided antimalarial drug design.

Structural Insights into the Processing of Nucleobase-Modified Nucleotides by DNA Polymerases

The DNA polymerase-catalyzed incorporation of modified nucleotides is employed in many biological technologies of prime importance, such as next-generation sequencing, nucleic acid-based diagnostics, transcription analysis, and aptamer selection by systematic enrichment of ligands by exponential amplification (SELEX). Recent studies have shown that 2'-deoxynucleoside triphosphates (dNTPs) that are functionalized with modifications at the nucleobase such as dyes, affinity tags, spin and redox labels, or even oligonucleotides are substrates for DNA polymerases, even if modifications of high steric demand are used. The position at which the modification is introduced in the nucleotide has been identified as crucial for retaining substrate activity for DNA polymerases. Modifications are usually attached at the C5 position of pyrimidines and the C7 position of 7-deazapurines. Furthermore, it has been shown that the nature of the modification may impact the efficiency of incorporation of a modified nucleotide into the nascent DNA strand by a DNA polymerase. This Account places functional data obtained in studies of the incorporation of modified nucleotides by DNA polymerases in the context of recently obtained structural data. Crystal structure analysis of a Thermus aquaticus (Taq) DNA polymerase variant (namely, KlenTaq DNA polymerase) in ternary complex with primer-template DNA and several modified nucleotides provided the first structural insights into how nucleobase-modified triphosphates are tolerated. We found that bulky modifications are processed by KlenTaq DNA polymerase as a result of cavities in the protein that enable the modification to extend outside the active site. In addition, we found that the enzyme is able to adapt to different modifications in a flexible manner and adopts different amino acid side-chain conformations at the active site depending on the nature of the nucleotide modification. Different "strategies" (i.e., hydrogen bonding, cation-π interactions) enable the protein to stabilize the respective protein-substrate complex without significantly changing the overall structure of the complex. Interestingly, it was also discovered that a modified nucleotide may be more efficiently processed by KlenTaq DNA polymerase when the 3'-primer terminus is also a modified nucleotide instead of a nonmodified natural one. Indeed, the modifications of two modified nucleotides at adjacent positions can interact with each other (i.e., by π-π interactions) and thereby stabilize the enzyme-substrate complex, resulting in more efficient transformation. Several studies have indicated that archeal DNA polymerases belonging to sequence family B are better suited for the incorporation of nucleobase-modified nucleotides than enzymes from family A. However, significantly less structural data are available for family B DNA polymerases. In order to gain insights into the preference for modified substrates by members of family B, we succeeded in obtaining binary structures of 9°N and KOD DNA polymerases bound to primer-template DNA. We found that the major groove of the archeal family B DNA polymerases is better accessible than in family A DNA polymerases. This might explain the observed superiority of family B DNA polymerases in polymerizing nucleotides that bear bulky modifications located in the major groove, such as modification at C5 of pyrimidines and C7 of 7-deazapurines. Overall, this Account summarizes our recent findings providing structural insight into the mechanism by which modified nucleotides are processed by DNA polymerases. It provides guidelines for the design of modified nucleotides, thus supporting future efforts based on the acceptance of modified nucleotides by DNA polymerases.

The expanded genetic alphabet

All biological information, since the last common ancestor of all life on Earth, has been encoded by a genetic alphabet consisting of only four nucleotides that form two base pairs. Long-standing efforts to develop two synthetic nucleotides that form a third, unnatural base pair (UBP) have recently yielded three promising candidates, one based on alternative hydrogen bonding, and two based on hydrophobic and packing forces. All three of these UBPs are replicated and transcribed with remarkable efficiency and fidelity, and the latter two thus demonstrate that hydrogen bonding is not unique in its ability to underlie the storage and retrieval of genetic information. This Review highlights these recent developments as well as the applications enabled by the UBPs, including the expansion of the evolution process to include new functionality and the creation of semi-synthetic life that stores increased information.

Taq DNA Polymerase Mutants and 2'-Modified Sugar Recognition

Chemical modifications to DNA, such as 2' modifications, are expected to increase the biotechnological utility of DNA; however, these modified forms of DNA are limited by their inability to be effectively synthesized by DNA polymerase enzymes. Previous efforts have identified mutant Thermus aquaticus DNA polymerase I (Taq) enzymes capable of recognizing 2'-modified DNA nucleotides. While these mutant enzymes recognize these modified nucleotides, they are not capable of synthesizing full length modified DNA; thus, further engineering is required for these enzymes. Here, we describe comparative biochemical studies that identify useful, but previously uncharacterized, properties of these enzymes; one enzyme, SFM19, is able to recognize a range of 2'-modified nucleotides much wider than that previously examined, including fluoro, azido, and amino modifications. To understand the molecular origins of these differences, we also identify specific amino acids and combinations of amino acids that contribute most to the previously evolved unnatural activity. Our data suggest that a negatively charged amino acid at 614 and mutation of the steric gate residue, E615, to glycine make up the optimal combination for modified oligonucleotide synthesis. These studies yield an improved understanding of the mutational origins of 2'-modified substrate recognition as well as identify SFM19 as the best candidate for further engineering, whether via rational design or directed evolution.

Selective transcription of an unnatural naphthyridine:imidazopyridopyrimidine base pair containing four hydrogen bonds with T7 RNA polymerase

The naphthyridine:imidazopyridopyrimidine base pair is the first base pair containing four hydrogen bonds that can be replicated selectively and efficiently by the use of DNA polymerases. Herein we describe the synthesis of naphthyridine-C-ribonucleoside 5'-triphosphate (rNaTP) and transcription reactions catalyzed by T7 RNA polymerase with rNaTP and template DNA containing imidazopyridopyrimidine. The transcription reaction was also applied to a longer transcript containing part of the human c-Ha-Ras gene.

Conformational dynamics of Thermus aquaticus DNA polymerase I during catalysis

Despite the fact that DNA polymerases have been investigated for many years and are commonly used as tools in a number of molecular biology assays, many details of the kinetic mechanism they use to catalyze DNA synthesis remain unclear. Structural and kinetic studies have characterized a rapid, pre-catalytic open-to-close conformational change of the Finger domain during nucleotide binding for many DNA polymerases including Thermus aquaticus DNA polymerase I (Taq Pol), a thermostable enzyme commonly used for DNA amplification in PCR. However, little has been performed to characterize the motions of other structural domains of Taq Pol or any other DNA polymerase during catalysis. Here, we used stopped-flow Förster resonance energy transfer to investigate the conformational dynamics of all five structural domains of the full-length Taq Pol relative to the DNA substrate during nucleotide binding and incorporation. Our study provides evidence for a rapid conformational change step induced by dNTP binding and a subsequent global conformational transition involving all domains of Taq Pol during catalysis. Additionally, our study shows that the rate of the global transition was greatly increased with the truncated form of Taq Pol lacking the N-terminal domain. Finally, we utilized a mutant of Taq Pol containing a de novo disulfide bond to demonstrate that limiting protein conformational flexibility greatly reduced the polymerization activity of Taq Pol.

Prechemistry nucleotide selection checkpoints in the reaction pathway of DNA polymerase I and roles of glu710 and tyr766

The accuracy of high-fidelity DNA polymerases such as DNA polymerase I (Klenow fragment) is governed by conformational changes early in the reaction pathway that serve as fidelity checkpoints, identifying inappropriate template–nucleotide pairings. The fingers-closing transition (detected by a fluorescence resonance energy transfer-based assay) is the unique outcome of binding a correct incoming nucleotide, both complementary to the templating base and with a deoxyribose (rather than ribose) sugar structure. Complexes with mispaired dNTPs or complementary rNTPs are arrested at an earlier stage, corresponding to a partially closed fingers conformation, in which weak binding of DNA and nucleotide promote dissociation and resampling of the substrate pool. A 2-aminopurine fluorescence probe on the DNA template provides further information about the steps preceding fingers closing. A characteristic 2-aminopurine signal is observed on binding a complementary nucleotide, regardless of whether the sugar is deoxyribose or ribose. However, mispaired dNTPs show entirely different behavior. Thus, a fidelity checkpoint ahead of fingers closing is responsible for distinguishing complementary from noncomplementary nucleotides and routing them toward different outcomes. The E710A mutator polymerase has a defect in the early fidelity checkpoint such that some complementary dNTPs are treated as if they were mispaired. In the Y766A mutant, the early checkpoint functions normally, but some correctly paired dNTPs do not efficiently undergo fingers closing. Thus, both mutator alleles cause a blurring of the distinction between correct and incorrect base pairs and result in a larger fraction of errors passing through the prechemistry fidelity checkpoints.

Structures of KOD and 9°N DNA polymerases complexed with primer template duplex

Replicate it: Structures of KOD and 9°N DNA polymerases, two enzymes that are widely used to replicate DNA with highly modified nucleotides, were solved at high resolution in complex with primer/template duplex. The data elucidate substrate interaction of the two enzymes and pave the way for further optimisation of the enzymes and substrates.

dNTP-dependent conformational transitions in the fingers subdomain of Klentaq1 DNA polymerase: insights into the role of the "nucleotide-binding" state

BACKGROUND

Conformational selection plays a key role in the polymerase cycle.

RESULTS

Klentaq1 exists in conformational equilibrium between three states (open, closed, and “nucleotide-binding”) whose level of occupancy is determined by the bound substrate.

CONCLUSION

The “nucleotide-binding” state plays a pivotal role in the reaction pathway.

SIGNIFICANCE

Direct evidence is provided for the role of a conformationally distinct “nucleotide-binding” state during dNTP incorporation. DNA polymerases are responsible for the accurate replication of DNA. Kinetic, single-molecule, and x-ray studies show that multiple conformational states are important for DNA polymerase fidelity. Using high precision FRET measurements, we show that Klentaq1 (the Klenow fragment of Thermus aquaticus DNA polymerase 1) is in equilibrium between three structurally distinct states. In the absence of nucleotide, the enzyme is mostly open, whereas in the presence of DNA and a correctly base-pairing dNTP, it re-equilibrates to a closed state. In the presence of a dNTP alone, with DNA and an incorrect dNTP, or in elevated MgCl2 concentrations, an intermediate state termed the "nucleotide-binding" state predominates. Photon distribution and hidden Markov modeling revealed fast dynamic and slow conformational processes occurring between all three states in a complex energy landscape suggesting a mechanism in which dNTP delivery is mediated by the nucleotide-binding state. After nucleotide binding, correct dNTPs are transported to the closed state, whereas incorrect dNTPs are delivered to the open state.

Structures of KlenTaq DNA polymerase caught while incorporating C5-modified pyrimidine and C7-modified 7-deazapurine nucleoside triphosphates

The capability of DNA polymerases to accept chemically modified nucleotides is of paramount importance for many biotechnological applications. Although these analogues are widely used, the structural basis for the acceptance of the unnatural nucleotide surrogates has been only sparsely explored. Here we present in total six crystal structures of modified 2'-deoxynucleoside-5'-O-triphosphates (dNTPs) carrying modifications at the C5 positions of pyrimidines or C7 positions of 7-deazapurines in complex with a DNA polymerase and a primer/template complex. The modified dNTPs are in positions poised for catalysis leading to incorporation. These structural data provide insight into the mechanism of incorporation and acceptance of modified dNTPs. Our results open the door for rational design of modified nucleotides, which should offer great opportunities for future applications.

Amino acid templating mechanisms in selection of nucleotides opposite abasic sites by a family a DNA polymerase

Cleavage of the N-glycosidic bond that connects the nucleobase to the backbone in DNA leads to abasic sites, the most frequent lesion under physiological conditions. Several DNA polymerases preferentially incorporate an A opposite this lesion, a phenomenon termed "A-rule." Accordingly, KlenTaq, the large fragment of Thermus aquaticus DNA polymerase I, incorporates a nucleotide opposite an abasic site with efficiencies of A > G > T > C. Here we provide structural insights into constraints of the active site during nucleotide selection opposite an abasic site. It appears that these confines govern the nucleotide selection mainly by interaction of the incoming nucleotide with Tyr-671. Depending on the nucleobase, the nucleotides are differently positioned opposite Tyr-671 resulting in different alignments of the functional groups that are required for bond formation. The distances between the α-phosphate and the 3'-primer terminus increases in the order A < G < T, which follows the order of incorporation efficiency. Additionally, a binary KlenTaq structure bound to DNA containing an abasic site indicates that binding of the nucleotide triggers a remarkable rearrangement of enzyme and DNA template. The ability to resolve the stacking arrangement might be dependent on the intrinsic properties of the respective nucleotide contributing to nucleotide selection. Furthermore, we studied the incorporation of a non-natural nucleotide opposite an abasic site. The nucleotide was often used in studying stacking effects in DNA polymerization. Here, no interaction with Tyr-761 as found for the natural nucleotides is observed, indicating a different reaction path for this non-natural nucleotide.

Solution structure, mechanism of replication, and optimization of an unnatural base pair

As part of an ongoing effort to expand the genetic alphabet for in vitro and eventual in vivo applications, we have synthesized a wide variety of predominantly hydrophobic unnatural base pairs and evaluated their replication in DNA. Collectively, the results have led us to propose that these base pairs, which lack stabilizing edge-on interactions, are replicated by means of a unique intercalative mechanism. Here, we report the synthesis and characterization of three novel derivatives of the nucleotide analogue dMMO2, which forms an unnatural base pair with the nucleotide analogue d5SICS. Replacing the para-methyl substituent of dMMO2 with an annulated furan ring (yielding dFMO) has a dramatically negative effect on replication, while replacing it with a methoxy (dDMO) or with a thiomethyl group (dTMO) improves replication in both steady-state assays and during PCR amplification. Thus, dTMO-d5SICS, and especially dDMO-d5SICS, represent significant progress toward the expansion of the genetic alphabet. To elucidate the structure-activity relationships governing unnatural base pair replication, we determined the solution structure of duplex DNA containing the parental dMMO2-d5SICS pair, and also used this structure to generate models of the derivative base pairs. The results strongly support the intercalative mechanism of replication, reveal a surprisingly high level of specificity that may be achieved by optimizing packing interactions, and should prove invaluable for the further optimization of the unnatural base pair.

Synthesis and evaluation of new spacers for use as dsDNA end-caps

A series of aliphatic and aromatic spacer molecules designed to cap the ends of DNA duplexes have been synthesized. The spacers were converted into dimethoxytrityl-protected phosphoramidites as synthons for oligonucleotides synthesis. The effect of the spacers on the stability of short DNA duplexes was assessed by melting temperature studies. End-caps containing amide groups were found to be less stabilizing than the hexaethylene glycol spacer. End-caps containing either a terthiophene or a naphthalene tetracarboxylic acid diimide were found to be significantly more stabilizing. The former showed a preference for stacking above an A*T base pair. Spacers containing only methylene (-CH(2)-) and amide (-CONH-) groups interact weakly with DNA and consequently may be optimal for applications that require minimal influence on DNA structure but require a way to hold the ends of double-stranded DNA together.

Structural basis for the synthesis of nucleobase modified DNA by Thermus aquaticus DNA polymerase

Numerous 2'-deoxynucleoside triphosphates (dNTPs) that are functionalized with spacious modifications such as dyes and affinity tags like biotin are substrates for DNA polymerases. They are widely employed in many cutting-edge technologies like advanced DNA sequencing approaches, microarrays, and single molecule techniques. Modifications attached to the nucleobase are accepted by many DNA polymerases, and thus, dNTPs bearing nucleobase modifications are predominantly employed. When pyrimidines are used the modifications are almost exclusively at the C5 position to avoid disturbing of Watson-Crick base pairing ability. However, the detailed molecular mechanism by which C5 modifications are processed by a DNA polymerase is poorly understood. Here, we present the first crystal structures of a DNA polymerase from Thermus aquaticus processing two C5 modified substrates that are accepted by the enzyme with different efficiencies. The structures were obtained as ternary complex of the enzyme bound to primer/template duplex with the respective modified dNTP in position poised for catalysis leading to incorporation. Thus, the study provides insights into the incorporation mechanism of the modified nucleotides elucidating how bulky modifications are accepted by the enzyme. The structures show a varied degree of perturbation of the enzyme substrate complexes depending on the nature of the modifications suggesting design principles for future developments of modified substrates for DNA polymerases.

Replication through an abasic DNA lesion: structural basis for adenine selectivity

Abasic sites represent the most frequent DNA lesions in the genome that have high mutagenic potential and lead to mutations commonly found in human cancers. Although these lesions are devoid of the genetic information, adenine is most efficiently inserted when abasic sites are bypassed by DNA polymerases, a phenomenon termed A-rule. In this study, we present X-ray structures of a DNA polymerase caught while incorporating a nucleotide opposite an abasic site. We found that a functionally important tyrosine side chain directs for nucleotide incorporation rather than DNA. It fills the vacant space of the absent template nucleobase and thereby mimics a pyrimidine nucleobase directing for preferential purine incorporation opposite abasic residues because of enhanced geometric fit to the active site. This amino acid templating mechanism was corroborated by switching to pyrimidine specificity because of mutation of the templating tyrosine into tryptophan. The tyrosine is located in motif B and highly conserved throughout evolution from bacteria to humans indicating a general amino acid templating mechanism for bypass of non-instructive lesions by DNA polymerases at least from this sequence family.

Discrimination between right and wrong purine dNTPs by DNA polymerase I from Bacillus stearothermophilus

We used a series of dATP and dGTP analogues to determine how DNA polymerase I from Bacillus stearothermophilus (BF), a prototypical A family polymerase, uses N-1, N(2), N-3, and N(6) of purine dNTPs to differentiate between right and wrong nucleotide incorporation. Altering any of these nitrogens had two effects. First, it decreased the efficiency of correct incorporation of the resulting dNTP analogue, with the loss of N-1 and N-3 having the most severe effects. Second, it dramatically increased the rate of misincorporation of the resulting dNTP analogues, with alterations in either N-1 or N(6) having the most severe impacts. Adding N(2) to dNTPs containing the bases adenine and purine increased the degree of polymerization opposite T but also tremendously increased the degree of misincorporation opposite A, C, and G. Thus, BF uses N-1, N(2), N-3, and N(6) of purine dNTPs both as negative selectors to prevent misincorporation and as positive selectors to enhance correct incorporation. Comparing how BF discriminates between right and wrong dNTPs with both B family polymerases and low-fidelity polymerases indicates that BF has chosen a unique solution vis-a-vis these other enzymes and, therefore, that nature has evolved at least three mechanistically distinct solutions.

Polymerase-catalysed incorporation of glucose nucleotides into a DNA duplex

The enzymatic recognition of six-membered ring nucleoside triphosphates--in particular the 6'-triphosphates of (beta-D-glucopyranosyl)thymine, (2',3'-dideoxy-beta-D-glucopyranosyl)thymine, (3',4'-dideoxy-beta-D-glucopyranosyl)thymine and (2',3'-dideoxy-beta-D-glucopyranosyl)adenine--was investigated. Despite the facts that the pyranose nucleic acids obtained by polymerisation of these monomers do not hybridise in solution with DNA and that the geometry of a DNA strand in a natural duplex differs from that of a pyranose nucleic acid, elongation of the DNA duplex with all four nucleotide analogues by Vent (exo(-)) polymerase was observed. Modelling experiments showed that hydrogen bonds are formed when 2',3'-dideoxy-beta-homo-T building blocks or beta-D-gluco-T building blocks are incorporated opposite adenosine residues in the template but not when they are incorporated opposite thymine residues in the template. The model shows a near perfect alignment of a secondary hydroxy group at the end of the primer and the alpha-phosphate group of the incoming triphosphate. The results of these experiments provide new information on the role of the active site of the enzyme in the polymerisation reaction.

Optimization of an unnatural base pair toward natural-like replication

Predominantly hydrophobic unnatural nucleotides that selectively pair within duplex DNA as well as during polymerase-mediated replication have recently received much attention as the cornerstone of efforts to expand the genetic alphabet. We recently reported the results of a screen and subsequent lead hit optimization that led to identification of the unnatural base pair formed between the nucleotides dMMO2 and d5SICS. This unnatural base pair is replicated by the Klenow fragment of Escherichia coli DNA polymerase I with better efficiency and fidelity than other candidates reported in the literature. However, its replication remains significantly less efficient than a natural base pair, and further optimization is necessary for its practical use. To better understand and optimize the slowest step of replication of the unnatural base pair, the insertion of dMMO2 opposite d5SICS, we synthesized two dMMO2 derivatives, d5FM and dNaM, which differ from the parent nucleobase in terms of shape, hydrophobicity, and polarizability. We find that both derivatives are inserted opposite d5SICS more efficiently than dMMO2 and that overall the corresponding unnatural base pairs are generally replicated with higher efficiency and fidelity than the pair between dMMO2 and d5SICS. In fact, in the case of the dNaM:d5SICS heteropair, the efficiency of each individual step of replication approaches that of a natural base pair, and the minimum overall fidelity ranges from 10(3) to 10(4). In addition, the data allow us to propose a generalized model of unnatural base pair replication, which should aid in further optimization of the unnatural base pair and possibly in the design of additional unnatural base pairs that are replicated with truly natural-like efficiency and fidelity.

Fluorophore-quencher pair for monitoring protein motion

A fluorophore/quencher pair capable of detecting conformational changes of DNA-protein complexes is described. The system employs a fluorescent nucleoside analog 1,3-diaza-2-oxophenothiazine (tC) within duplex DNA and a non-fluorescent quencher (TEMPO) attached to an engineered cysteine residue of the protein. The straightforward labeling methodology allows for the placement of the fluorophore and quencher moieties at specific positions suited to studying the conformational change of interest. To illustrate the utility of the tC-TEMPO pair, we have monitored nucleotide-induced conformational changes of the Klenow fragment (KF) polymerase bound to duplex DNA. In this system, tC was incorporated in the primer strand of the duplex, adjacent to the 3' end, while TEMPO was positioned at the end of the O-helix within the fingers domain of KF. Using steady-state fluorescence spectroscopy, we measured the quenching efficiency in a binary complex of tC-modified DNA and TEMPO-labeled KF and in ternary complexes containing cognate or non-cognate dNTP substrates. The quenching efficiency is significantly enhanced in the presence of a cognate dNTP, indicating that the O-helix has moved closer towards the DNA. In contrast, no significant tC quenching is observed in the presence of a non-cognate dNTP, indicating that the O-helix remains in a position that is beyond the distance reporting range of the tC-TEMPO pair. These results demonstrate that a cognate dNTP substrate induces a large conformational change of the O-helix, which can be sensitively detected using the tC-TEMPO pair. This fluorophore/quencher pair may be useful to study conformational changes associated with other DNA-enzyme complexes.

Enzymatic polymerization of phosphonate nucleosides

5'-O-phosphonomethyl-2'-deoxyadenosine (PMdA) proved to be a good substrate of the Therminator polymerase. In this article, we investigated whether the A, C, T and U analogues of this phosphonate nucleoside (PMdN) series can function as substrates of natural DNA polymerases. PMdT and PMdU could only be polymerized enzymatically to a limited extent. Nevertheless, PMdA and PMdC could be incorporated into a DNA duplex with complete chain elongation by all the DNA polymerases tested. A mixed sequence of four nucleotides containing modified C, T and A residues could be obtained with the Vent(exo(-)) and Therminator polymerases. The kinetic values for the incorporation of PMdA by Vent(exo(-)) polymerase were determined; a reduced K(M) value was found for the incorporation of PMdA compared to the natural substrate. Future polymerase directed evolution studies will allow us to select an enzyme with a heightened capacity to process these modified DNA building blocks into modified strands.

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.

Unnatural substrate repertoire of A, B, and X family DNA polymerases

As part of an effort to develop unnatural base pairs that are stable and replicable in DNA, we examined the ability of five different polymerases to replicate DNA containing four different unnatural nucleotides bearing predominantly hydrophobic nucleobase analogs. The unnatural pairs were developed based on intensive studies using the Klenow fragment of DNA polymerase I from E. coli (Kf) and found to be recognized to varying degrees. The five additional polymerases characterized here include family A polymerases from bacteriophage T7 and Thermus aquaticus, family B polymerases from Thermococcus litoralis and Thermococcus 9(o)N-7, and the family X polymerase, human polymerase beta. While we find that some aspects of unnatural base pair recognition are conserved among the polymerases, for example, the pair formed between two d3FB nucleotides is typically well recognized, the detailed recognition of most of the unnatural base pairs is generally polymerase dependent. In contrast, we find that the pair formed between d5SICS and dMMO2 is generally well recognized by all of the polymerases examined, suggesting that the determinants of efficient and general recognition are contained within the geometric and electronic structure of these unnatural nucleobases themselves. The data suggest that while the d3FB:d3FB pair is sufficiently well recognized by several of the polymerases for in vitro applications, the d5SICS:dMMO2 heteropair is likely uniquely promising for in vivo use. T7-mediated replication is especially noteworthy due to strong mispair discrimination.

Discovery, characterization, and optimization of an unnatural base pair for expansion of the genetic alphabet

DNA is inherently limited by its four natural nucleotides. Efforts to expand the genetic alphabet, by addition of an unnatural base pair, promise to expand the biotechnological applications available for DNA as well as to be an essential first step toward expansion of the genetic code. We have conducted two independent screens of hydrophobic unnatural nucleotides to identify novel candidate base pairs that are well recognized by a natural DNA polymerase. From a pool of 3600 candidate base pairs, both screens identified the same base pair, dSICS:dMMO2, which we report here. Using a series of related analogues, we performed a detailed structure-activity relationship analysis, which allowed us to identify the essential functional groups on each nucleobase. From the results of these studies, we designed an optimized base pair, d5SICS:dMMO2, which is efficiently and selectively synthesized by Kf within the context of natural DNA.

Polymerase recognition and stability of fluoro-substituted pyridone nucleobase analogues

Recently much effort has been focused on designing unnatural base pairs that are stable and replicated by DNA polymerases with high efficiency and fidelity. This work has helped to identify a variety of nucleobase properties that are capable of mediating the required interbase interactions in the absence of Watson-Crick hydrogen-bonding complementarity. These properties include shape complementarity, the presence of a suitably positioned hydrogen-bond donor in the developing minor groove, and fluorine substitution. In order to help characterize how each factor contributes to base pairing stability and replication, we synthesized and characterized three fluoro-substituted pyridone nucleoside analogues, 3 FP, 4 FP, and 5 FP. Generally, we found that the specific fluorine substitution pattern of the analogues had little impact on unnatural pair or mispair stability, with the exception of mispairs with dG, which were also the most stable. The mispair between dG and 3 FP was less stable than that with 4 FP or 5 FP, which likely resulted from specific interbase interactions. While fluorine substitution had little impact on the synthesis of the unnatural base pairs, it significantly enhanced mispairing with dG. Remarkably, the mispair between dG and 3 FP was the most efficiently synthesized, due to a favorable entropy of activation, which possibly resulted from the displacement of water molecules from dG in the phosphoryl transfer transition state. The more efficient synthesis of the 3 FP-dG mispair, despite its being the least stable of the three, suggests that the determinants of synthesis and stability are distinct. Finally, we found that fluorine substitution significantly increased the rate at which the pyridone-based unnatural base pairs were extended; this suggests that both minor groove hydrogen-bond acceptors and fluorine substituents could be used to simultaneously optimize unnatural base pairs.

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.

Minor groove hydrogen bonds and the replication of unnatural base pairs

As part of an effort to expand the genetic alphabet, we examined the synthesis of DNA with six different unnatural nucleotides bearing methoxy-derivatized nucleobase analogues. Different nucleobase substitution patterns were used to systematically alter the nucleobase electronics, sterics, and hydrogen-bonding potential. We determined the ability of the Klenow fragment of E. coli DNA polymerase I to synthesize and extend the different unnatural base pairs and mispairs under steady-state conditions. Unlike other hydrogen-bond acceptors examined in the past, the methoxy groups do not facilitate mispairing, implying that they are not recognized by any of the hydrogen-bond donors of the natural nucleobases; however, they do facilitate replication. The more efficient replication results largely from an increase in the rate of extension of primers terminating at the unnatural base pair and, interestingly, requires that the methoxy group be at the ortho position where it is positioned in the developing minor groove and can form a functionally important hydrogen bond with the polymerase. Thus, ortho methoxy groups should be generally useful for the effort to expand the genetic alphabet.

Mechanism for de novo RNA synthesis and initiating nucleotide specificity by t7 RNA polymerase

DNA-directed RNA polymerases are capable of initiating synthesis of RNA without primers, the first catalytic stage of initiation is referred to as de novo RNA synthesis. De novo synthesis is a unique phase in the transcription cycle where the RNA polymerase binds two nucleotides rather than a nascent RNA polymer and a single nucleotide. For bacteriophage T7 RNA polymerase, transcription begins with a marked preference for GTP at the +1 and +2 positions. We determined the crystal structures of T7 RNA polymerase complexes captured during the de novo RNA synthesis. The DNA substrates in the structures in the complexes contain a common Phi 10 duplex promoter followed by a unique five base single-stranded extension of template DNA whose sequences varied at positions +1 and +2, thereby allowing for different pairs of initiating nucleotides GTP, ATP, CTP or UTP to bind. The structures show that the initiating nucleotides bind RNA polymerase in locations distinct from those described previously for elongation complexes. Selection bias in favor of GTP as an initiating nucleotide is accomplished by shape complementarity, extensive protein side-chain and strong base-stacking interactions for the guanine moiety in the enzyme active site. Consequently, an initiating GTP provides the largest stabilization force for the open promoter conformation.

Hydrophobic Amino Acid and Single-Atom Substitutions Increase DNA Polymerase Selectivity

DNA polymerase fidelity is of immense biological importance due to the fundamental requirement for accurate DNA synthesis in both replicative and repair processes. Subtle hydrogen-bonding networks between DNA polymerases and their primer/template substrates are believed to have impact on DNA polymerase selectivity. We show that deleting defined interactions of that kind by rationally designed hydrophobic substitution mutations can result in a more selective enzyme. Furthermore, a single-atom replacement within the DNA substrate through chemical modification, which leads to an altered acceptor potential and steric demand of the DNA substrate, further increased the selectivity of the developed systems. Accordingly, this study about the impact of hydrophobic alterations on DNA polymerase selectivity--enzyme and substrate wise--further highlights the relevance of shape complementary and polar interactions on DNA polymerase selectivity.

A mechanism of nucleotide misincorporation during transcription due to template-strand misalignment

Transcription errors by T7 RNA polymerase (RNAP) may occur as the result of a mechanism in which the template base two positions downstream of the 3' end of the RNA (the TSn+1 base) is utilized during two consecutive nucleotide-addition cycles. In the first cycle, misalignment of the template strand leads to incorporation of a nucleotide that is complementary to the TSn+1 base. In the second cycle, the template is realigned and the mismatched primer is efficiently extended, resulting in a substitution error. Proper organization of the transcription bubble is required for maintaining the correct register of the DNA template, as the presence of a complementary nontemplate strand opposite the TSn+1 base suppresses template misalignment. Our findings for T7 RNAP are in contrast to related DNA polymerases of the Pol I type, which fail to extend mismatches efficiently and generate predominantly deletion errors as a result of template-strand misalignment.

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.

Molecular flexibility in protein–DNA interactions

In living cells protein-DNA interactions are fundamental processes. Here, we compare the 3D structures of several DNA-binding proteins frequently determined with and without attached DNA. We studied the global structure (backbone-traces) as well as the local structure (binding sites) by comparing pair-wise the related atoms. The DNA-interaction sites of uncomplexed proteins show conspicuously high local structural flexibility. Binding to DNA results in specific local conformations, which are clearly distinct from the unbound states. The adaptation of the protein's binding site to DNA can never be described by the lock and key model but in all cases by the induced fit model. Conformational changes in the seven protein backbone traces take place in different ways. Two of them dock onto DNA without a significant change, while the other five proteins are characterized by a backbone conformation change caused by DNA docking. In the case of three proteins of the latter group the DNA-complexed conformation also occurs in a few uncomplexed structures. This behavior can be described by a conformational ensemble, which is narrowed down by DNA docking until only one single DNA-complexed conformation occurs. Different docking models are discussed and each of the seven proteins is assigned to one of them.