Generation of a mono-ubiquitinated PCNA mimic by click chemistry

Genotoxic stress results in more than 50 000 damaged DNA sites per cell per day. During DNA replication, processive high‐fidelity DNA polymerases generally stall at DNA lesions and have to be displaced by translesion synthesis DNA polymerases, which are able to bypass the lesion. This switch is mediated by mono‐ubiquitination of the processivity factor proliferating cell nuclear antigen (PCNA). To further investigate the regulation of the DNA polymerase exchange, we developed an easy and efficient method to synthesize site‐specifically mono‐ubiquitinated PCNA by click chemistry. By incorporating artificial amino acids that carry an azide (Aha) or an alkyne (Plk) in their side chains, into ubiquitin (Ub) and PCNA, respectively, we were able to link the two proteins site‐specifically by the Cu^I‐catalyzed azide–alkyne cycloaddition. Finally, we show that the synthetic PCNA–Ub is able to stimulate DNA synthesis by DNA polymerase δ, and that DNA polymerase η has a higher affinity for PCNA–Ub than to PCNA.     

1,2,4‐Triazine‐Modified 2′‐Deoxyuridine Triphosphate for Efficient Bioorthogonal Fluorescent Labeling of DNA

In order to establish the Diels–Alder reaction with inverse electron demand for postsynthetic DNA modification, a 1,2,4‐triazine‐modified 2′‐deoxyuridine triphosphate was synthesized. The bioorthogonally reactive 1,2,4‐triazine group was attached at the 5‐position of 2′‐deoxyuridine by a flexible alkyl linker to facilitate its acceptance by DNA polymerases. The screening of four DNA polymerases showed successful primer extensions, using a mixture of dATP, dGTP, dCTP, and the modified 2′‐deoxyuridine triphosphate, by using KOD XL or Vent polymerase. The triazine moiety was stable under the conditions of primer extension, which was evidenced by labeling with a BCN‐modified rhodamine at room temperature in yields of up to 82 %. Two or three modified bases could be incorporated in quantitative yields when the modification sites were separated by three base pairs. These results establish the 1,2,4‐triazene group as a bioorthogonally reactive moiety in DNA, thereby replacing the problematic 1,2,4,5‐tetrazine for postsynthetic labeling by the Diels–Alder reaction with inverse electron demand.     

Structure and Replication of yDNA: A Novel Genetic Set Widened by Benzo‐Homologation

In a functioning genetic system, the information‐encoding molecule must form a regular self‐complementary complex (for example, the base‐paired double helix of DNA) and it must be able to encode information and pass it on to new generations. Here we study a benzo‐widened DNA‐like molecule (yDNA) as a candidate for an alternative genetic set, and we explicitly test these two structural and functional requirements. The solution structure of a 10 bp yDNA duplex is measured by using 2D‐NMR methods for a simple sequence composed of T–yA/yA–T pairs. The data confirm an antiparallel, right‐handed, hydrogen‐bonded helix resembling B‐DNA but with a wider diameter and enlarged base‐pair size. In addition to this, the abilities of two different polymerase enzymes (Klenow fragment of DNA pol I (Kf) and the repair enzyme Dpo4) to synthesize and extend the yDNA pairs T–yA, A–yT, and G–yC are measured by steady‐state kinetics studies. Not surprisingly, insertion of complementary bases opposite yDNA bases is inefficient due to the larger base‐pair size. We find that correct pairing occurs in several cases by both enzymes, but that common and relatively efficient mispairing involving T–yT and T–yC pairs interferes with fully correct formation and extension of pairs by these polymerases. Interestingly, the data show that extension of the large pairs is considerably more efficient with the flexible repair enzyme (Dpo4) than with the more rigid Kf enzyme. The results shed light on the properties of yDNA as a candidate for an alternative genetic information‐encoding molecule and as a tool for application in basic science and biomedicine.     

Interactions of Metal Ions with DNA and Some Applications

Nucleic acids play a critical role in life as we know it. It contains the necessary information required for the structure and function of a living organisms. Metal ions play a critical role in stabilizing conformations. In the well-known double helix structure of DNA, metal ions stabilize a particular conformation that ensures storage and propagation of genetic information. Metal ions, however, can interact with various sites on nucleic acids. Moreover, metal coordination can have a tremendous impact on the structure, conformation, stability and the electronic properties of the nucleic acids. The interactions are controlled by the relative affinity of metal ion coordination to the negatively charged phosphodiester backbone versus binding to other donor sites located in the nucleobases. The canonical Watson–Crick base pairs (A-T and G-C) as well as non-canonical base pairs (Hoogsteen and wobble) and mismatched pairs are often sites for metal ion interactions. In this review, an overview will be provided of the structure of different forms of nucleic acids (DNA and RNA) and the impact of different metal ions on their stability and structure. In addition, the recent applications of metal-DNA interactions in nanotechnology, biosensor and bioelectronics will also be discussed along with some therapeutic applications of metal complexes.     

Polymerase Amplification,Cloning, and Gene Expression of Benzo‐Homologous “yDNA” Base Pairs

A widened DNA base‐pair architecture is studied in an effort to explore the possibility of whether new genetic system designs might possess some of the functions of natural DNA. In the “yDNA” system, pairs are homologated by addition of a benzene ring, which yields (in the present study) benzopyrimidines that are correctly paired with purines. Here we report initial tests of ability of the benzopyrimidines yT and yC to store and transfer biochemical and biological information in vitro and in bacterial cells. In vitro primer extension studies with two polymerases showed that the enzymes could insert the correct nucleotides opposite these yDNA bases, but with low selectivity. PCR amplifications with a thermostable polymerase resulted in correct pairings in 15–20 % of the cases, and more successfully when yT or yC were situated within the primers. Segments of DNA containing one or two yDNA bases were then ligated into a plasmid and tested for their ability to successfully lead the expression of an active protein in vivo. Although active at only a fraction of the activity of fully natural DNA, the unnatural bases encoded the correct codon bases in the majority of cases when singly substituted, and yielded functioning green fluorescent protein. Although the activities with native polymerases are modest with these large base pairs, this is the first example of encoding protein in vivo by an unnatural DNA base pair architecture.     

Fluorobenzene Nucleobase Analogues for Triplex-Forming Peptide Nucleic Acids

2,4-Difluorotoluene is a nonpolar isostere of thymidine that has been used as a powerful mechanistic probe to study the role of hydrogen bonding in nucleic acid recognition and interactions with polymerases. In the present study, we evaluated five fluorinated benzenes as nucleobase analogues in peptide nucleic acids designed for triple helical recognition of double helical RNA. We found that analogues having para and ortho fluorine substitution patterns (as in 2,4-difluorotoluene) selectively stabilized Hoogsteen triplets with U−A base pairs. The results were consistent with attractive electrostatic interactions akin to non-canonical F to H−N and C−H to N hydrogen bonding. The fluorinated nucleobases were not able to stabilize Hoogsteen-like triplets with pyrimidines in either G−C or A−U base pairs. Our results illustrate the ability of fluorine to engage in non-canonical base pairing and provide insights into triple helical recognition of RNA.     

Structural Insights into Conformation Differences between DNA/TNA and RNA/TNA Chimeric Duplexes

Threose nucleic acid (TNA) is an artificial genetic polymer capable of heredity and evolution, and is studied in the context of RNA chemical etiology. It has a four‐carbon threose backbone in place of the five‐carbon ribose of natural nucleic acids, yet forms stable antiparallel complementary Watson–Crick homoduplexes and heteroduplexes with DNA and RNA. TNA base‐pairs more favorably with RNA than with DNA but the reason is unknown. Here, we employed NMR, ITC, UV, and CD to probe the structural and dynamic properties of heteroduplexes of RNA/TNA and DNA/TNA. The results indicate that TNA templates the structure of heteroduplexes, thereby forcing an A‐like helical geometry. NMR measurement of kinetic and thermodynamic parameters for individual base pair opening events reveal unexpected asymmetric “breathing” fluctuations of the DNA/TNA helix. The results suggest that DNA is unable to fully adapt to the conformational constraints of the rigid TNA backbone and that nucleic acid breathing dynamics are determined from both backbone and base contributions.     

A novel random mutagenesis approach using human mutagenic DNA polymerases to generate enzyme variant libraries

The in vitro MutaGen procedure is a new random mutagenesis method based on the use of low-fidelity DNA polymerases. In the present study, this technique was applied on a 2 kb gene encoding amylosucrase, an attractive enzyme for the industrial synthesis of amylose-like polymers. Mutations were first introduced during a single replicating step performed by mutagenic polymerases pol beta and pol eta. Three large libraries (>10(5) independent clones) were generated (one with pol beta and two with pol eta). The sequence analysis of randomly chosen clones confirmed the potential of this strategy for the generation of diversity. Variants generated by pol beta were 4-7-fold less mutated than those created with pol eta, indicating that our approach enables mutation rate control following the DNA polymerase employed for mutagenesis. Moreover, pol beta and pol eta provide different and complementary mutation spectra, allowing a wider sequence space exploration than error-prone PCR protocols employing Taq polymerase. Interestingly, some of the variants generated by pol eta displayed unusual modifications, including combinations of base substitutions and codon deletions which are rarely generated using other methods. By taking advantage of the mutation bias of naturally highly error-prone DNA polymerases, MutaGen thus appears as a very useful tool for gene and protein randomisation.     

Incorporation of 2'-deoxy-2'-isonucleoside 5'-triphosphates (iNTPs) into DNA by A- and B-family DNA polymerases with different recognition mechanisms

Recently, α-L-threofuranosyl nucleoside 3'-triphosphates (tNTPs) have been reported to be incorporated into DNA by DNA polymerases. Isonucleosides especially the 2'-deoxy-2'-isonucleosides, would be considered regioisomers of α-L-threofuranosyl nucleosides. Therefore, we investigated the synthesis of 2'-deoxy-2'-isonucleoside 5'-triphosphates (iNTPs) having the four natural nucleobases and their incorporation into primer-template duplexes consisting of oligonucleotides containing natural 2'-deoxyribonucleosides and 2'-deoxy-2'-isonucleosides by using primer-extension reactions. We found that Klenow fragment (exo-; an A-family DNA polymerase) has strict recognition of the shape of nucleoside 5'-triphosphates and Therminator (a B-family DNA polymerase) has strict recognition of the shape of primer-template complexes, especially two base pairs upstream of the primer 3' terminus.     

Silver(I)-Ion-Mediated Cytosine-Containing Base Pairs: Metal Ion Specificity for Duplex Stabilization and Susceptibility toward DNA Polymerases

Spectroscopic characterization of Ag^I-ion-mediated C-Ag^I-A and C-Ag^I-T base pairs found in primer extension reactions catalyzed by DNA polymerases was conducted. UV melting experiments revealed that C-A and C-T mismatched base pairs in oligodeoxynucleotide duplexes are specifically stabilized by Ag^I ions in 1:1 stoichiometry in the same manner as a C-C mismatched base pair. Although the stability of the mismatched base pairs in the absence of Ag^I ions is in the order C-A≈C-T>C-C, the stabilizing effect of Ag^I ions follows the order C-C>C-A≈C-T. However, the comparative susceptibility of dNTPs to Ag^I-mediated enzymatic incorporation into the site opposite templating C is dATP>dTTP≫dCTP, as reported. The net charge, as well as the size and/or shape complementarity of the metal-mediated base pairs, or the stabilities of mismatched base pairs in the absence of metal ions, would be more important than the stability of the metallo-base pairs in the replicating reaction catalyzed by DNA polymerases.