Synthesis of Deoxynucleoside Triphosphates that Include Proline,Urea, or Sulfonamide Groups and Their Polymerase Incorporation into DNA

To expand the chemical array available for DNA sequences in the context of in vitro selection, I present herein the synthesis of five nucleoside triphosphate analogues containing side chains capable of organocatalysis. The synthesis involved the coupling of L ‐proline‐containing residues (dU^tPTP and dU^cPTP), a dipeptide (dU^FPTP), a urea derivative (dU^BpuTP), and a sulfamide residue (dU^BsTP) to a suitably protected common intermediate, followed by triphosphorylation. These modified dNTPs were shown to be excellent substrates for the Vent (exo^?) and Pwo DNA polymerases, as well as the Klenow fragment of E. coli DNA polymerase I, although they were only acceptable substrates for the 9°N_m polymerase. All of the modified dNTPs, with the exception of dU^BpuTP, were readily incorporated into DNA by the polymerase chain reaction (PCR). Modified oligonucleotides efficiently served as templates for PCR for the regeneration of unmodified DNA. Thermal denaturation experiments showed that these modifications are tolerated in the major groove. Overall, these heavily modified dNTPs are excellent candidates for SELEX.     

Enzymatic Synthesis of a DNA Triblock Copolymer that is Composed of Natural and Unnatural Nucleotides

DNA molecules have come under the spotlight as potential templates for the fabrication of nanoscale products, such as molecular‐scale electronic or photonic devices. Herein, we report an enhanced approach for the synthesis of oligoblock copolymer‐type DNA by using the Klenow fragment exonuclease minus of E. coli DNA polymerase I (KF^?) in a multi‐step reaction with natural and unnatural nucleotides. First, we confirmed the applicability of unnatural nucleotides with 7‐deaza‐nucleosides—which was expected because they were non‐metalized nucleotides—on the unique polymerization process known as the “strand‐slippage model”. Because the length of the DNA sequence could be controlled by tuning the reaction time, analogous to a living polymerization reaction on this process, stepwise polymerization provided DNA block copolymers with natural and unnatural bases. AFM images showed that this DNA block copolymer could be metalized sequence‐selectively. This approach could expand the utility of DNA as a template.     

Enzymatic Incorporation of a Coumarin–Guanine Base Pair

Previous expansions beyond nature's preferred base‐pairing interactions have utilized either nonpolar shape‐fitting interactions or classical hydrogen bonding. Reported here is a hybrid of these systems. By replacing a single N?H with C?H at a Watson–Crick interface, the design space for new drug candidates and fluorescent nucleobase analogues is dramatically expanded, as demonstrated here by the new, highly fluorescent deoxycytidine mimic 3‐glycosyl‐5‐fluoro‐7‐methoxy‐coumarin‐2′‐deoxyribose (d C ^C ). dGTP is selectively incorporated across from a template d C ^C during enzymatic DNA synthesis. Likewise, d C ^C is selectively incorporated across from a template guanine when d C ^C is provided as the triphosphate d C ^C TP . DNA polymerase I (Klenow fragment) exhibited about a 10‐fold higher affinity for d C ^C TP than dCTP, allowing selective incorporation of d C ^C in direct competition experiments. These results demonstrate that a single C?H can replace N?H at a Watson–Crick‐type interface with preservation of functional selectivity and enhanced activity.     

Discrimination Between 8‐Oxo‐2′‐Deoxyguanosine and 2′‐Deoxyguanosine in DNA by the Single Nucleotide Primer Extension Reaction with Adap Triphosphate

The adenosine derivative of 2‐oxo‐1,3‐diazaphenoxazine (Adap) exhibits a superb ability to recognize and form base pairs with 8‐oxo‐2′‐deoxyguanosine (8‐oxo‐dG) in duplex DNA. In this study, the triphosphate of Adap (dAdapTP) was synthesized and tested for single nucleotide incorporation into primer strands using the Klenow Fragment. The efficiency of dAdapTP incorporation into 8‐oxo‐dG‐containing templates was more than 36‐fold higher than with dG‐containing templates, and provides better discrimination than does the incorporation of natural 2′‐deoxyadenosine triphosphate (dATP). The selective incorporation of dAdapTP into 8‐oxo‐dG templates was therefore applied to the detection of 8‐oxo‐dG in human telomeric DNA sequences extracted from H₂O₂‐treated HeLa cells. The enzymatic incorporation of dAdapTP into 8‐oxo‐dG‐containing templates may provide a novel basis for sequencing oxidative DNA damage in the genome.     

Bi-stranded, multisite replication of a base pair between difluorotoluene and adenine: confirmation by ‘inverse’ sequencing

Background: The nonpolar nucleoside of difluorotoluene (F) was previously found to behave similarly to thymidine in single-site deoxynucleoside triphosphate (dNTP) insertion experiments with the Klenow fragment (KF) of DNA polymerase I. Further study was needed, first to see whether F-A base pairs could be replicated in more than one sequence context; second to investigate whether specific base pair replication occurs in the presence of four dNTPs; and third to confirm the presence of F in a replicated DNA strand.Results: A primer bound to a template strand containing eight F residues was extended by KF using the four natural dNTPs at 20 μM. Similarly, the complement (containing eight adenines) was extended using dATP, dGTP, dCTP and dFTP. Comparison of the new strands to authentic strands using standard and ‘inverse’ chemical sequencing showed identical composition within ± 5%.Conclusions: The results confirm that F in a template strand encodes the insertion of dATP and that adenine in a template encodes the insertion of dFTP with good specificity in at least six different nearest neighbor contexts. The results confirm that analog F behaves similarly to thymidine despite its poor hydrogen-bonding ability.     

Arrest of Rolling Circle Amplification by Protein‐Binding DNA Aptamers

Certain DNA polymerases, such as ?29 DNA polymerase, can isothermally copy the sequence of a circular template round by round in a process known as rolling circle amplification (RCA), which results in super‐long single‐stranded (ss) DNA molecules made of tandem repeats. The power of RCA reflects the high processivity and the strand‐displacement ability of these polymerases. In this work, the ability of ?29DNAP to carry out RCA over circular templates containing a protein‐binding DNA aptamer sequence was investigated. It was found that protein–aptamer interactions can prevent this DNA polymerase from reading through the aptameric domain. This finding indicates that protein‐binding DNA aptamers can form highly stable complexes with their targets in solution. This novel observation was exploited by translating RCA arrest into a simple and convenient colorimetric assay for the detection of specific protein targets, which continues to showcase the versatility of aptamers as molecular recognition elements for biosensing applications.     

Thermoelectric method for sequencing DNA

This study describes a novel, thermoelectric method for DNA sequencing in a microfluidic device. The method measures the heat released when DNA polymerase inserts a deoxyribonucleoside triphosphate into a primed DNA template. The study describes the principle of operation of a laminar flow microfluidic chip with a reaction zone that contains DNA template/primer complex immobilized to the inner surface of the device's lower channel wall. A thin-film thermopile attached to the external surface of the lower channel wall measures the dynamic change in temperature that results when Klenow polymerase inserts a deoxyribonucleoside triphosphate into the DNA template. The intrinsic rejection of common-mode thermal signals by the thermopile in combination with hydrodynamic focused flow allows for the measurement of temperature changes on the order of 10(-4) K without control of ambient temperature. To demonstrate the method, we report the sequencing of a model oligonucleotide containing 12 bases. Results demonstrate that it is feasible to sequence DNA by measuring the heat released during nucleotide incorporation. This thermoelectric method for sequencing DNA may offer a novel new method of DNA sequencing for personalized medicine applications.     

Fluorous base-pairing effects in a DNA polymerase active site

We describe selective "fluorous" effects in the active site of a DNA polymerase, by using nucleotide analogues whose pairing edges are perfluorinated. The 5'-triphosphate deoxynucleotide derivatives of DNA base analogues 2,3,4,5-tetrafluorobenzene ((F)B) and 4,5,6,7-tetrafluoroindole ((F)I), as well as hydrocarbon controls benzene (B) and indole (I), were synthesized and studied as substrates for the DNA Polymerase I Klenow fragment (KF exo-). Modified nucleotides were present in the DNA template or were supplied as nucleoside triphosphates in studies of the steady-state kinetics of single nucleotide insertion. When supplied opposite the non-natural bases in the template strand, the hydrophobic nucleoside triphosphates were incorporated by up to two orders of magnitude more efficiently than the natural deoxynucleoside triphosphates. The purine-like fluorinated indole nucleotide ((F)I) was the most efficiently inserted of the four hydrophobic analogues, with the most effective incorporation occurring opposite the pyrimidine-like tetrafluorobenzene ((F)B). In all cases, the polyfluorinated base pairs were more efficiently processed than the analogous hydrocarbon pairs. A preliminary test of polymerase extension beyond these pairs showed that only the (F)B base is appreciably extended; the inefficient extension is consistent with recently published data regarding other nonpolar base pairs. These results suggest the importance of hydrophobicity, stacking, and steric interactions in the polymerase-mediated replication of DNA base pairs that lack hydrogen bonds. These findings further suggest that the enhanced hydrophobicity of polyfluoroaromatic bases could be employed in the design of new, selective base pairs that are orthogonal to the natural Watson-Crick pairs used in replication.     

Gram (−) microorganisms DNA polymerase inhibition,antibacterial and chemical properties of fruit and leaf extracts of Sorbus acuparia and Sorbus caucasica var. yaltirikii

Investigation of novel plant‐based agents might provide alternative antibiotics and thus fight antibiotic resistance. Here, we measured the ability of fruit and leaf extracts of Sorbus aucuparia (Sauc ) and endemic Sorbus caucasica var. yaltirikii (Scau ) to inhibit nonreplicative (Klenow Fragment‐KF and Bacillus Large Fragment‐BLF) and replicative (DnaE and PolC) bacterial DNA polymerases along with their antimicrobial, DPPH free radical scavenging activity (RSA), and chemical contents by total phenolic content and HPLC‐DAD analysis. We found that leaf extracts had nearly 10‐fold higher RSA and 5‐fold greater TPC than the corresponding fruit extracts. All extracts had large amounts of chlorogenic acid (CGA) and rutin, while fruit extracts had large amounts of quercetin. Hydrolysis of fruit extracts revealed mainly caffeic acid from CGA (caffeoylquinic acid) and quercetin from rutin (quercetin‐3‐O ‐rutinoside), as well as CGA and derivatives of CGA and p ‐coumaric acid. Plant extracts of Sorbus species showed antimicrobial activity against Gram‐negative microorganisms. Scau leaf extracts exhibited strong inhibition of KF activity. Sauc and Scau leaf extracts also strongly inhibited two replicative DNA polymerases. Thus, these species can be considered a potential source of novel antimicrobial agents specific for Gram‐negative bacteria.     

Recording the Reaction Process of Loop‐Mediated Isothermal Amplification (LAMP) by Monitoring the Voltammetric Response of 2′‐Deoxyguanosine 5′‐Triphosphate

We describe here a novel strategy for recording the reaction process of loop‐mediated isothermal amplification (LAMP) by monitoring the voltammetric response of 2′‐deoxyguanosine 5′‐triphosphate (dGTP). Unlike the other three kinds of reactive substrates for DNA synthesis in LAMP reaction, dGTP exhibits sensitive voltammetric response at the carbon nanotube array electrode. When the LAMP reaction occurs, the concentration of dGTP decreases accordingly, bringing forth the decrease of the anodic peak current (i_pa). In inversion, the decrease of the i_pa of dGTP was used to characterize the reaction process of LAMP. The relationships among the LAMP reaction time, the initial quantity of template DNA and the value change of the i_pa were studied. The results indicate that the protocol integrated LAMP and voltammetric techniques can be used for not only qualitative gene discrimination but also quantitative gene assay in a wide range. The malB gene extracted from common strains of Escherichia coli cells was tested as a model. The detecting results of LAMPs obtained by voltammetric method were in good agreement with those by optical‐based methods (gel electrophoresis and fluorescent dye).     

Synthesis and Some Biochemical Properties of a Novel 5,6,7,8‐Tetrahydropyrimido[4,5‐c]pyridazine Nucleoside

A novel nucleoside analogue is described based on the pyridazine ring system. The nucleoside was successfully incorporated into DNA via both its phosphoramidite and 5′‐triphosphate derivatives. Enzymatically, the analogue behaves essentially as thymidine: it is a good substrate for the DNA polymerases Taq and exonuclease‐free Klenow fragment, leading to full‐length products when present in either the primer or template strands. In hybridisation studies, the nucleoside displays ambiguous base‐pairing properties, including universal base properties.     

Chemical Morphing of DNA Containing Four Noncanonical Bases

The ability of alternative nucleic acids, in which all four nucleobases are substituted, to replicate in vitro and to serve as genetic templates in vivo was evaluated. A nucleotide triphosphate set of 5‐chloro‐2′‐deoxyuridine, 7‐deaza‐2′‐deoxyadenosine, 5‐fluoro‐2′‐deoxycytidine, and 7‐deaza‐2′deoxyguanosine successfully underwent polymerase chain reaction (PCR) amplification using templates of different lengths (57 or 525mer) and Taq or Vent (exo‐) DNA polymerases as catalysts. Furthermore, a fully morphed gene encoding a dihydrofolate reductase was generated by PCR using these fully substituted nucleotides and was shown to transform and confer trimethoprim resistance to E. coli. These results demonstrated that fully modified templates were accurately read by the bacterial replication machinery and provide the first example of a long fully modified DNA molecule being functional in vivo.     

A Small Molecule Affecting the Replication of Trinucleotide Repeat d(GAA)n

A newly designed ligand, methylcarbamoylnaphthyridine dimer (MCND), was synthesized and characterized. Ligand binding to d(GAA)₁₀ was investigated by UV thermal denaturation, circular dichroism spectroscopy, surface plasmon resonance, and cold‐spray‐ionization time‐of‐flight mass spectrometry. The results indicated that MCND bound to the d(GAA)_n repeat to form a stable hairpin structure with a major binding stoichiometry of 3:1. The most likely binding site was identified as the G? G mismatch in the AGA/AGA triad. The polymerase stop assay showed that MCND binding to the d(GAA)_n repeat effectively interfered with the extension of the primer at the first two GAA sites on the template with both prokaryotic Taq DNA polymerase and human DNA polymerase α.     

Template-Dependent Incorporation of Spin-Labeled Thymidine Analogs into Viral DNA

The synthesis of novel pppU_d analogs substituted at position C(5) with tethered nitroxide radicals is reported. It is shown that these analogs can serve as good substrates for E. coli DNA polymerase (Pol I) and T-4 DNA polymerase using lambda-phage DNA as template. The template-dependent incorporation of the substrates was established by radio-labeling and ESR experiments.     

Detection of LAMP Products Using CNT Array Electrode

We described here a novel strategy for discriminating target gene by integrating loop‐mediated isothermal amplification (LAMP) and differential pulse voltammetry (DPV). After a successful LAMP reaction, the anodic peak current (i_pa) of the free 2′‐deoxyguanosine 5′‐triphosphate (dGTP) decreased remarkably at a carbon nanotubes array working electrode, owing to the consumption of free dGTP as one of reactive substrates. Thus, the change of current response was used to characterize the result of LAMP reaction. And hence the presence of the target gene in template DNA could be discriminated easily. The malB gene extracted from Escherichia coli cells was tested as a model. After the reaction for 30 min, the LAMP mix was scanned directly. Then the information of the target gene in 0.8 picogram template DNA was obtained accurately. The result was in good accordance with that obtained with optical‐based methods (gel electrophoresis and fluorescent dye). The new strategy has the advantages of being very simple to perform, rapid response, elimination of post‐amplification processing, avoidance of auxiliary reagents and low cost (there was almost no cost for the detection step). Therefore, it was quite promising for use in miniaturized devices and in the development of point‐of‐care applications.     

Absence of repair replication following ultraviolet irradiation of an excision-deficient mutant of Escherichia coli

The excision -repair of damaged DNA in bacteria and other systems probably requires at least three enzymes to carry out the following steps in sequence: (1) Recognition of a structural distortion in the DNA and the production of an endonucleolytic cleavage of the damaged strand near the lesion. (2) The simultaneous peeling back of the damaged strand and resynthesis of the excised region, with eventual cleavage of the damaged segment from the DNA. (3) The rejoining of the newly synthesized strand to contiguous parental DNA. Evidence for all three steps has been obtained from in vivo studies. The E. coli DNA polymerase has been shown to carry out step # 2 in vitro [1] and the polynucleotide ligase has the required specificity for step # 3[2–4]. An enzyme responsible for step # 1 has been purified from Micrococcus lysodeikticus [5,6] but not from E. coli, although a class of u.v. sensitive mutants in E. coli has been shown to be defective in this step in the repair sequence. In such mutants the release of pyrimidine dimers from the damaged DNA is not observed during post-irradiation growth of u.v. irradiated cultures [7]. It would be predicted, as a consequence, that the next step, non-conservative repair replication, would not be seen in these mutants. Hanawalt and Petti-john showed this to be true for the double mutant E. coli B_8-1 that includes a deficiency in dimer excision [8]. In the present study we have looked more closely at an E. coli K-12 strain that has only the uvrA6 deficiency that results in inability to excise pyrimidine dimers.     

Regulated Incorporation of Two Different Metal Ions into Programmed Sites in a Duplex by DNA Polymerase Catalyzed Primer Extension

Metal‐mediated base pairs formed by the coordination of metal ions to natural or artificial bases impart unique chemical and physical properties to nucleic acids and have attracted considerable interest in the field of nanodevices. Ag^I ions were found to mediate DNA polymerase catalyzed primer extension through the formation of a C–Ag^I–T base pair, as well as the previously reported C–Ag^I–A base pair. The comparative susceptibility of dNTPs to Ag^I‐mediated enzymatic incorporation into the site opposite cytosine in the template was shown to be dATP>dTTP?dCTP. Furthermore, two kinds of metal ions, Ag^I and Hg^II, selectively mediate the incorporation of thymidine 5′‐triphosphate into sites opposite cytosine and thymine in the template, respectively. In other words, the regulated incorporation of different metal ions into programmed sites in the duplex by DNA polymerase was successfully achieved.