Modified DNA bearing 5(methoxycarbonylmethyl)-2'-deoxyuridine: preparation by PCR with thermophilic DNA polymerase and postsynthetic derivatization

A thymidine analogue bearing a methyl ester at the C5 position was accepted as a substrate by the thermophilic family B DNA polymerases, KOD Dash, Pwo, and Vent(exo-), to form the corresponding PCR product, but not by the thermophilic family A DNA polymerases, Taq, Tth, and T7 thermosequenase. Modified DNA containing this analogue was prepared by PCR on a large scale with KOD Dash DNA polymerase and 5(methoxycarbonylmethyl)-2'-deoxyuridine 5'-triphosphate as a substrate. The methyl ester of the modified DNA was further allowed to react with tris(2-aminoethyl)amine or histamine by an ester-amide exchange reaction to form the corresponding derivatized DNA bearing a tris(2-aminoethyl)amine or histamine moiety. Hydrolysis of the methyl ester of the modified DNA gave a functionalized DNA bearing an anionic carboxyl group. The derivatized DNA could act as a template for the PCR with KOD Dash DNA polymerase and the natural 2'-deoxythymidine 5'-triphosphate or the modified thymidine analogue as a substrate. The postsynthetic derivatization of the modified DNA may expand the variety of structurally modified DNA produced by PCR.     

Intracellular detection of cytosine incorporation in genomic DNA by using 5-ethynyl-2'-deoxycytidine

5-Ethynyl-2'-deoxycytidine triphosphate (EdCTP) was synthesized as a probe to be used in conjunction with fluorescent labeling to facilitate the analysis of the in vivo dynamics of DNA-centered processes (DNA replication, repair and cytosine demethylation). Kinetic analysis showed that EdCTP is accepted as a substrate by Klenow exo(-) and DNA polymerase β. Incorporation of 5-ethynyl-2'-deoxycytidine (EdC) into DNA by these enzymes is, at most, modestly less efficient than native dC. EdC-containing DNA was visualized by using a click reaction with a fluorescent azide, following polymerase incorporation and T4 DNA ligase mediated ligation. Subsequent experiments in mouse male germ cells and zygotes demonstrated that EdC is a specific and reliable reporter of DNA replication, in vivo.     

Cleavage of functionalized DNA containing 5-modified pyrimidines by type II restriction endonucleases

A series of six pyrimidine-modified dNTPs--5-ethynyl-, 5-phenyl-, and 5-(3-nitrophenyl)deoxycitidine and -deoxyuridine triphosphates--were prepared and incorporated by primer extension with Vent (exo-)polymerase to specific DNA sequences within or next to the recognition sequences of selected restriction endonucleases. The cleavage of these pyrimidine-modified DNA sequences by 13 restriction enzymes was then studied. Whereas the presence of any modified C within the target sequence completely prevented any restriction cleavage, most enzymes tolerated the presence of 5-ethynylU and two of them even the presence of 5-phenyl- and 5-(3-nitrophenyl)U. Modifications outside the recognition sequence were tolerated except in the case of phenyl derivatives with the PvuII enzyme. 5-EthynylC was used for protection of the recognition sequence from cleavage in the presence of the second unmodified copy of the same sequence that was cleaved.     

Tropolone-Conjugated DNA: Fluorescence Enhancement in the Duplex

Tropolone (2-hydroxycyclohepta-2,4,6-triene-1-one and tautomer) is a non-benzenoid bioactive natural chromophore with pH-dependent fluorescence character and extraordinary metal binding affinities, especially with transition-metal ions Cu²⁺/Zn²⁺/Ni²⁺. This report describes the syntheses and biophysical studies of a new tropolonyl thymidine [(4(5)-hydroxy-5(4)-oxo-5(4)H-cyclohepta-1,3,6-trienyl)thymidine] (tr-T) nucleoside and of corresponding tropolone-conjugated DNA oligonucleotides that form B-form DNA duplex structures with a complementary DNA strand, although their duplex structures are less stable than that of the control. Furthermore, the stabilities of those DNA duplex structures are lowered by the presence of increasing numbers of tr-T residue or by decreasing pH of their environments. Most importantly, these duplex structures are made fluorescent because of the presence of the tropolone moieties conjugated to the thymidine residues. The fluorescence behavior of those duplex structures exhibits pH dependence, with stronger fluorescence at lower pH and weaker fluorescence at high pH. Importantly, the fluorescence characters of tr-DNA oligonucleotides are significantly enhanced by nearly threefold after duplex structure formation with their complementary control DNA oligonucleotide. Further, the fluorescence behavior of these tr-DNA duplex structures is also dependent on the pH conditions. Hence, tropolonyl-conjugated DNA represents a class of new fluorescent analogues that might be be employed for sensing DNA duplex formation and provide opportunities to improve fluorescence properties further.     

Synthesis and Photophysical Characterisation of a Fluorescent Nucleoside Analogue that Signals the Presence of an Abasic Site in RNA

The synthesis and site‐specific incorporation of an environment‐sensitive fluorescent nucleoside analogue ( 2 ), based on a 5‐(benzofuran‐2‐yl)pyrimidine core, into DNA oligonucleotides (ONs), and its photophysical properties within these ONs are described. Interestingly and unlike 2‐aminopurine (a widely used nucleoside analogue probe), when incorporated into an ON and hybridised with a complementary ON, the emissive nucleoside 2 displays significantly higher emission intensity than the free nucleoside. Furthermore, photophysical characterisation shows that the fluorescence properties of the nucleoside analogue within ONs are significantly influenced by flanking bases, especially by guanosine. By utilising the responsiveness of the nucleoside to changes in base environment, a DNA ON reporter labelled with the emissive nucleoside 2 was constructed; this signalled the presence of an abasic site in a model depurinated sarcin/ricin RNA motif of a eukaryotic 28S rRNA.     

A new photoactive building block for investigation of DNA backbone interactions: photoaffinity labeling of human DNA polymerase beta

The cross-linking of target proteins or nucleic acids to light-activatable ligands is an important tool for elucidating molecular interactions. Through the use of photoaffinity-labeling reagents, several new insights into nucleic acid interactions have been obtained, for example in DNA replication and repair. In most known photoprobes, the applied light-sensitive functionalities are placed directly at the nucleobase or are attached via linkers to either the nucleobase or the phosphate backbone. Here we describe the first photoprobe that bears a light-sensitive aryl(trifluoromethyl)diazirine at the sugar moiety of a DNA oligonucleotide. We devised a route for the synthesis of the modified nucleoside and its incorporation into an oligonucleotide. The photoactive species was proven to be stable under the conditions employed in routine automated DNA synthesis. The modified oligonucleotide was shown by subsequent photolabeling studies of human DNA polymerase beta to form a covalent complex to the enzyme upon irradiation with near-UV light.     

Tropolone-Conjugated DNA: A Fluorescent Thymidine Analogue Exhibits Solvatochromism,Enzymatic Incorporation into DNA and HeLa Cell Internalization

Tropolone is a non-benzenoid aromatic scaffold with unique photophysical and metal-chelating properties. Recently, it has been conjugated with DNA, and the photophysical properties of this conjugate have been explored. Tropolonyl-deoxyuridine (tr-dU) is a synthetic fluorescent DNA nucleoside analogue that exhibits pH-dependent emissions. However, its solvent-dependent fluorescence properties are unexplored owing to its poor solubility in most organic solvents. It would be interesting to incorporate it into DNA primer enzymatically. This report describes the solvent-dependent fluorescence properties of the silyl-derivative, and enzymatic incorporation of its triphosphate analogue. For practical use, its cell-internalization and cytotoxicity are also explored. tr-dU nucleoside was found to be a potential analogue to design DNA probes and can be explored for various therapeutic applications in the future.     

Characterization of New DNA Aptamers for Anti-HIV-1 Reverse Transcriptase

HIV-1 RT is a necessary enzyme for retroviral replication, which is the main target for antiviral therapy against AIDS. Effective anti-HIV-1 RT drugs are divided into two groups; nucleoside inhibitors (NRTI) and non-nucleoside inhibitors (NNRTI), which inhibit DNA polymerase. In this study, new DNA aptamers were isolated as anti-HIV-1 RT inhibitors. The selected DNA aptamer (WT62) presented with high affinity and inhibition against wild-type (WT) HIV-1 RT and gave a KD value of 75.10±0.29 nM and an IC₅₀ value of 84.81±8.54 nM. Moreover, WT62 decreased the DNA polymerase function of K103 N/Y181 C double mutant (KY) HIV-1 RT by around 80 %. Furthermore, the ITC results showed that this aptamer has small binding enthalpies with both WT and KY HIV-1 RTs through which the complex might form a hydrophobic interaction or noncovalent bonding. The NMR result also suggested that the WT62 aptamer could bind with both WT and KY mutant HIV-1 RTs at the connection domain.     

An Azide‐Modified Nucleoside for Metabolic Labeling of DNA

Metabolic incorporation of azido nucleoside analogues into living cells can enable sensitive detection of DNA replication through copper(I)‐catalyzed azide–alkyne cycloaddition (CuAAC) and strain‐promoted azide–alkyne cycloaddition (SPAAC) “click” reactions. One major limitation to this approach is the poor chemical stability of nucleoside derivatives containing an aryl azide group. For example, 5‐azido‐2′‐deoxyuridine (AdU) exhibits a 4 h half‐life in water, and it gives little or no detectable labeling of cellular DNA. In contrast, the benzylic azide 5‐(azidomethyl)‐2′‐deoxyuridine (AmdU) is stable in solution at 37 °C, and it gives robust labeling of cellular DNA upon addition of fluorescent alkyne derivatives. In addition to providing the first examples of metabolic incorporation into and imaging of azide groups in cellular DNA, these results highlight the general importance of assessing azide group stability in bioorthogonal chemical reporter strategies.     

Structural Basis for The Recognition of Deaminated Nucleobases by An Archaeal DNA Polymerase

With increasing temperature, nucleobases in DNA become increasingly damaged by hydrolysis of exocyclic amines. The most prominent damage includes the conversion of cytosine to uracil and adenine to hypoxanthine. These damages are mutagenic and put the integrity of the genome at risk if not repaired appropriately. Several archaea live at elevated temperatures and thus, are exposed to a higher risk of deamination. Earlier studies have shown that DNA polymerases of archaea have the property of sensing deaminated nucleobases in the DNA template and thereby stalling the DNA synthesis during DNA replication providing another layer of DNA damage recognition and repair. However, the structural basis of uracil and hypoxanthine sensing by archaeal B-family DNA polymerases is sparse. Here we report on three new crystal structures of the archaeal B-family DNA polymerase from Thermococcus kodakarensis (KOD) DNA polymerase in complex with primer and template strands that have extended single stranded DNA template 5’-overhangs. These overhangs contain either the canonical nucleobases as well as uracil or hypoxanthine, respectively, and provide unprecedented structural insights into their recognition by archaeal B-family DNA polymerases.     

An Isocytidine Derivative with a 2‐Amino‐6‐methylpyridine Unit for Selective Recognition of the CG Interrupting Site in an Antiparallel Triplex DNA

Sequence‐specific recognition of duplex DNA mediated by triple helix formation offers a potential basis for oligonucleotide therapy and biotechnology. However, triplex formation is limited mostly to homopurine strands, due to poor stabilization at CG or TA base pairs in the target duplex DNA sequences. Several non‐natural nucleosides have been designed for the recognition of CG or TA base pairs within an antiparallel triplex DNA. Nevertheless, problems including low selectivity and high dependence on the neighboring bases remain unsolved. We thus synthesized N²‐arylmethyl isodC derivatives and incorporated them into triplex‐forming oligonucleotides (TFOs) for the selective recognition of the CG base pair within antiparallel triplex DNA. It was shown that an isodC derivative bearing a 2‐amino‐6‐methylpyridine moiety (AP‐isodC) recognizes the CG base pair with high selectivity in antiparallel triplex DNA irrespective of the flanking base pairs.     

Enzymatic Incorporation of Modified Purine Nucleotides in DNA

A series of nucleotide analogues, with a hypoxanthine base moiety (8‐aminohypoxanthine, 1‐methyl‐8‐aminohypoxanthine, and 8‐oxohypoxanthine), together with 5‐methylisocytosine were tested as potential pairing partners of N⁸‐glycosylated nucleotides with an 8‐azaguanine or 8‐aza‐9‐deazaguanine base moiety by using DNA polymerases (incorporation studies). The best results were obtained with the 5‐methylisocytosine nucleotide followed by the 1‐methyl‐8‐aminohypoxanthine nucleotide. The experiments demonstrated that small differences in the structure (8‐azaguanine versus 8‐aza‐9‐deazaguanine) might lead to significant differences in recognition efficiency and selectivity, base pairing by Hoogsteen recognition at the polymerase level is possible, 8‐aza‐9‐deazaguanine represents a self‐complementary base pair, and a correlation exists between in vitro incorporation studies and in vivo recognition by natural bases in Escherichia coli, but this recognition is not absolute (exceptions were observed).     

Terminal Deoxynucleotidyl Transferase in the Synthesis and Modification of Nucleic Acids

The terminal deoxynucleotidyl transferase (TdT) belongs to the X family of DNA polymerases. This unusual polymerase catalyzes the template-independent addition of random nucleotides on 3′-overhangs during V(D)J recombination. The biological function and intrinsic biochemical properties of the TdT have spurred the development of numerous oligonucleotide-based tools and methods, especially if combined with modified nucleoside triphosphates. Herein, we summarize the different applications stemming from the incorporation of modified nucleotides by the TdT. The structural, mechanistic, and biochemical properties of this polymerase are also discussed.     

Effects of Intermediates between Vitamins K(2) and K(3) on Mammalian DNA Polymerase Inhibition and Anti-Inflammatory Activity

Previously, we reported that vitamin K(3) (VK(3)), but not VK(1) or VK(2) (=MK-4), inhibits the activity of human DNA polymerase γ (pol γ). In this study, we chemically synthesized three intermediate compounds between VK(2) and VK(3), namely MK-3, MK-2 and MK-1, and investigated the inhibitory effects of all five compounds on the activity of mammalian pols. Among these compounds, MK-2 was the strongest inhibitor of mammalian pols α, κ and λ, which belong to the B, Y and X families of pols, respectively; whereas VK(3) was the strongest inhibitor of human pol γ, an A-family pol. MK-2 potently inhibited the activity of all animal species of pol tested, and its inhibitory effect on pol λ activity was the strongest with an IC(50) value of 24.6 μM. However, MK-2 did not affect the activity of plant or prokaryotic pols, or that of other DNA metabolic enzymes such as primase of pol α, RNA polymerase, polynucleotide kinase or deoxyribonuclease I. Because we previously found a positive relationship between pol λ inhibition and anti-inflammatory action, we examined whether these compounds could inhibit inflammatory responses. Among the five compounds tested, MK-2 caused the greatest reduction in 12-O-tetradecanoylphorbol-13-acetate (TPA)-induced acute inflammation in mouse ear. In addition, in a cell culture system using mouse macrophages, MK-2 displayed the strongest suppression of the production of tumor necrosis factor (TNF)-α induced by lipopolysaccharide (LPS). Moreover, MK-2 was found to inhibit the action of nuclear factor (NF)-κB. In an in vivo mouse model of LPS-evoked acute inflammation, intraperitoneal injection of MK-2 in mice led to suppression of TNF-α production in serum. In conclusion, this study has identified VK(2) and VK(3) intermediates, such as MK-2, that are promising anti-inflammatory candidates.     

重组Thermus thermophilus DNA聚合酶表达纯化及其在RT-PCR中的应用

目的研究重组ThermusthermophilusDNA聚合酶的表达、纯化和应用。方法提取Thermusthermophilushb8基因组DNA作为模板,PCR扩增TthDNA聚合酶基因后,克隆至pET28a表达载体上,转化大肠杆菌BL21(DE3),经IPTG诱导表达,用His-BindQuickCartridge300纯化重组TthDNA聚合酶His-tag融合蛋白。提取Thermomonosporafusca总RNA,用一管法RT-PCR扩增E2cd基因,检测重组TthDNA聚合酶RT-PCR活性。结果大肠杆菌表达TthDNA聚合酶,分离出的电泳纯重组TthDNA聚合酶His-tag融合蛋白相对分子质量为94000,表达产量为200000U/L。一管法RT-PCR可扩增出850bp长度的E2cd基因。结论重组TthDNA聚合酶已成功地表达和纯化,并用于RT-PCR。     

2′‐Deoxyribonucleoside Phosphoramidate Triphosphate Analogues as Alternative Substrates for E. coli Polymerase III

Thermostable bacterial polymerases like Taq, Therminator and Vent exo^? are able to perform DNA synthesis by using modified DNA precursors, a property that is exploited in several therapeutic and biotechnological applications. Viral polymerases are also known to accept modified substrates, and this has proven crucial in the development of antiviral therapies. However, non‐thermostable polymerases of bacterial origin, or engineered variants, that have similar substrate tolerance and could be used for synthetic biology purposes remain to be identified. We have identified the α subunit of Escherichia coli polymerase III (Pol III α) as a bacterial polymerase that is able to recognise and process as substrates several pyrophosphate‐modified dATP analogues in place of its natural substrate dATP for template‐directed DNA synthesis. A number of dATP analogues featuring a modified pyrophosphate group were able to serve as substrates during enzymatic DNA synthesis by Pol III α. Features such as the presence of potentially chelating chemical groups and the size and spatial flexibility of the chemical structure seem to be of major importance for the modified leaving group to play its role during the enzymatic reaction. In addition, we could establish that if the pyrophosphate group is altered, deoxynucleotide incorporation proceeds with an efficiency varying with the nature of the nucleobase. Our results represent a great step towards the achievement of a system of artificial DNA synthesis hosted by E. coli and involving the use of altered nucleotide precursors for nucleic acid synthesis.     

Stabilisation of RNA bulges by oligonucleotide complements containing an adenosine analogue

Incorporation of 2'-deoxy-2'-beta-(1-naphthylmethyl)tubercidin into an oligodeoxyribonucleotide mostly has little or a slightly negative effect on the T(m) values of complexes with DNA complements. With the same naphthylmethyl-substituted nucleoside at the 3'-end of a 2'-O-methyloligoribonucleotide, however, a stabilisation of 1-2 degrees C in the corresponding complexes with both DNA and RNA is observed. When the target sequence is an RNA fragment forming a two- or three-nucleotide bulge, complexes with (naphthylmethyl)tubercidin-modified oligodeoxyribonucleotides, as well as with the corresponding 2'-O-methyloligoribonucleotides, give stabilisations of 1-2 degrees C for the three-nucleotide bulge and of almost 4 degrees C for the two-nucleotide bulge. This stabilisation is specific to RNA, since the corresponding complexes with the DNA fragments do not display this effect. Thus, the (naphthylmethyl)tubercidin-containing oligonucleotides are the first reported oligonucleotide modifications that specifically stabilise bulged RNA.     

Making the Bend: DNA Tertiary Structure and Protein-DNA Interactions

DNA structure functions as an overlapping code to the DNA sequence. Rapid progress in understanding the role of DNA structure in gene regulation, DNA damage recognition and genome stability has been made. The three dimensional structure of both proteins and DNA plays a crucial role for their specific interaction, and proteins can recognise the chemical signature of DNA sequence (“base readout”) as well as the intrinsic DNA structure (“shape recognition”). These recognition mechanisms do not exist in isolation but, depending on the individual interaction partners, are combined to various extents. Driving force for the interaction between protein and DNA remain the unique thermodynamics of each individual DNA-protein pair. In this review we focus on the structures and conformations adopted by DNA, both influenced by and influencing the specific interaction with the corresponding protein binding partner, as well as their underlying thermodynamics.     

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.