Roles of Watson-Crick and minor groove hydrogen bonds in DNA replication

Orthogonality in organic, polymer, and supramolecular chemistry: from Merrifield to click chemistry

The concept of orthogonality has been applied to many areas of chemistry, ranging from wave functions to chromatography. But it was Barany and Merrifield's orthogonal protecting group strategy that paved the way for solid phase peptide syntheses, other important classes of biomaterials such as oligosaccharides and oligonucleotides, and ultimately to a term in widespread usage that is focused on chemical reactivity and binding selectivity. The orthogonal protection strategy has been extended to the development of orthogonal activation, and recently the click reaction, for streamlining organic synthesis. The click reaction and its variants are considered orthogonal as the components react together in high yield and in the presence of many other functional groups. Likewise, supramolecular building blocks can also be orthogonal, thereby enabling programmed self-assembly, a superb strategy to create complex architectures. Overall, orthogonal reactions and supramolecular interactions have dramatically improved the syntheses, the preparation of functional materials, and the self-assembly of nanoscale structures.

Synthetic biology: mapping the scientific landscape

This article uses data from Thomson Reuters Web of Science to map and analyse the scientific landscape for synthetic biology. The article draws on recent advances in data visualisation and analytics with the aim of informing upcoming international policy debates on the governance of synthetic biology by the Subsidiary Body on Scientific, Technical and Technological Advice (SBSTTA) of the United Nations Convention on Biological Diversity. We use mapping techniques to identify how synthetic biology can best be understood and the range of institutions, researchers and funding agencies involved. Debates under the Convention are likely to focus on a possible moratorium on the field release of synthetic organisms, cells or genomes. Based on the empirical evidence we propose that guidance could be provided to funding agencies to respect the letter and spirit of the Convention on Biological Diversity in making research investments. Building on the recommendations of the United States Presidential Commission for the Study of Bioethical Issues we demonstrate that it is possible to promote independent and transparent monitoring of developments in synthetic biology using modern information tools. In particular, public and policy understanding and engagement with synthetic biology can be enhanced through the use of online interactive tools. As a step forward in this process we make existing data on the scientific literature on synthetic biology available in an online interactive workbook so that researchers, policy makers and civil society can explore the data and draw conclusions for themselves.

Mechanistic studies in the synthesis of a series of thieno-expanded xanthosine and guanosine nucleosides

During the synthetic pursuit of guanosine (triG) and xanthosine (triX) tricyclic nucleosides analogues, an interesting side product was discovered. In an effort to uncover the mechanistic factors leading to this result, a series of reaction conditions were investigated. It was found that by varying the conditions, the appearance of the side product could be controlled. In addition, the yield of the desired products could be manipulated to afford either a 50:50 mix of both triG and triX, or a majority of one or the other. To demonstrate the broad utility of the method, it was also adapted to the synthesis of guanosine and xanthosine from 5-amino-1-beta-D-ribofuranosyl-4-imidazolecarboxyamide (AICAR). The mechanistic details surrounding the synthetic efforts are reported herein.

Identification of recognition residues for ligation-based detection and quantitation of pseudouridine and N6-methyladenosine

Over 100 chemical types of RNA modifications have been identified in thousands of sites in all three domains of life. Recent data suggest that modifications function synergistically to mediate biological function, and that cells may coordinately modulate modification levels for regulatory purposes. However, this area of RNA biology remains largely unexplored due to the lack of robust, high-throughput methods to quantify the extent of modification at specific sites. Recently, we developed a facile enzymatic ligation-based method for detection and quantitation of methylated 2′-hydroxyl groups within RNA. Here we exploit the principles of molecular recognition and nucleic acid chemistry to establish the experimental parameters for ligation-based detection and quantitation of pseudouridine (Ψ) and N⁶-methyladenosine (m⁶A), two abundant modifications in eukaryotic rRNA/tRNA and mRNA, respectively. Detection of pseudouridylation at several sites in the large subunit rRNA derived from yeast demonstrates the feasibility of the approach for analysis of pseudouridylation in biological RNA samples.

Reiterative template switching: the effect of single-strand homopolymeric DNA on non-template-directed nucleotide addition by DNA polymerase

Template switching occurs when DNA polymerase juxtaposes two discontinuous DNA molecules with 3'-terminally complementary ends generated through non-template-directed nucleotide addition. We examined whether juxtaposition of homopolymeric single-stranded oligonucleotides affects non-templated addition. We hypothesized that if DNA polymerase first juxtaposed the two substrates, then the non-template-directed nucleotide addition of any deoxynucleotide would decrease in the presence of its non-complementary template. For dATP, product formation was unaffected by non-complementary substrates. In contrast, dCTP and dGTP incorporation decreased to varying degrees while dTTP incorporation increased in the presence of oligodeoxythymidine but decreased for other non-complementary homopolymers. Interestingly, the presence of complementary templates strongly influenced the formation of highly periodic products indicative of reiterative template switching. Transient template synapsis was observed and found to be dependent on the non-templated sequence added: 3-4 A:T or 1-2 G:C base pairs were needed for stable synapsis, suggesting that base pairing plays a more important role in the active site of the enzyme than previously thought.

Probing minor groove recognition contacts by DNA polymerases and reverse transcriptases using 3-deaza-2'-deoxyadenosine

Standard nucleobases all present electron density as an unshared pair of electrons to the minor groove of the double helix. Many heterocycles supporting artificial genetic systems lack this electron pair. To determine how different DNA polymerases use the pair as a substrate specificity determinant, three Family A polymerases, three Family B polymerases and three reverse transcriptases were examined for their ability to handle 3-deaza-2'-deoxyadenosine (c3dA), an analog of 2'-deoxyadenosine lacking the minor groove electron pair. Different polymerases differed widely in their interaction with c3dA. Most notably, Family A and Family B polymerases differed in their use of this interaction to exploit their exonuclease activities. Significant differences were also found within polymerase families. This plasticity in polymerase behavior is encouraging to those wishing to develop a synthetic biology based on artificial genetic systems. The differences also suggest either that Family A and Family B polymerases do not share a common ancestor, that minor groove contact was not used by that ancestor functionally or that this contact was not sufficiently critical to fitness to have been conserved as the polymerase families diverged. Each interpretation is significant for understanding the planetary biology of polymerases.

Active site tightness and substrate fit in DNA replication

Various physicochemical factors influence DNA replication fidelity. Since it is now known that Watson-Crick hydrogen bonds are not necessary for efficient and selective replication of a base pair by DNA polymerase enzymes, a number of alternative physical factors have been examined to explain the efficiency of these enzymes. Among these factors are minor groove hydrogen bonding, base stacking, solvation, and steric effects. We discuss the concept of active site tightness in DNA polymerases, and consider how it might influence steric (size and shape) effects of nucleotide selection in synthesis of a base pair. A high level of active site tightness is expected to lead to higher fidelity relative to proteins with looser active sites. We review the current data on what parts and dimensions of active sites are most affected by size and shape, based on data with modified nucleotides that have been examined as polymerase substrates. We also discuss recent data on nucleotide analogs displaying higher fidelity than the natural ones. The published data are discussed with a view toward testing this sterically based hypothesis and unifying existing observations into a narrowly defined range of effects.