Non-Canonical Helical Structure of Nucleic Acids Containing Base-Modified Nucleotides

Chemically modified nucleobases are thought to be important for therapeutic purposes as well as diagnosing genetic diseases and have been widely involved in research fields such as molecular biology and biochemical studies. Many artificially modified nucleobases, such as methyl, halogen, and aryl modifications of purines at the C8 position and pyrimidines at the C5 position, are widely studied for their biological functions. DNA containing these modified nucleobases can form non-canonical helical structures such as Z-DNA, G-quadruplex, i-motif, and triplex. This review summarizes the synthesis of chemically modified nucleotides: (i) methylation, bromination, and arylation of purine at the C8 position and (ii) methylation, bromination, and arylation of pyrimidine at the C5 position. Additionally, we introduce the non-canonical structures of nucleic acids containing these modifications.     

Chemoenzymatic Preparation of Functional Click-Labeled Messenger RNA

Synthetic mRNAs are promising candidates for a new class of transformative drugs that provide genetic information for patients’ cells to develop their own cure. One key advancement to develop so-called druggable mRNAs was the preparation of chemically modified mRNAs, by replacing standard bases with modified bases, such as uridine with pseudouridine, which can ameliorate the immunogenic profile and translation efficiency of the mRNA. Thus the introduction of modified nucleobases was the foundation for the clinical use of such mRNAs. Herein we describe modular and simple methods to chemoenzymatically modify mRNA. Alkyne- and/or azide-modified nucleotides are enzymatically incorporated into mRNA and subsequently conjugated to fluorescent dyes using click chemistry. This allows visualization of the labeled mRNA inside cells. mRNA coding for the enhanced green fluorescent protein (eGFP) was chosen as a model system and the successful expression of eGFP demonstrated that our modified mRNA is accepted by the translation machinery.     

Was a Pyrimidine-Pyrimidine Base Pair the Ancestor of Watson-Crick Base Pairs? Insights from a Systematic Approach to the Origin of RNA

Uncovering the origin of RNA is essential for understanding the origins of life. The persistent inability of chemists to identify a plausible prebiotic route to RNA polymers, along with the seemingly optimal structure of RNA for its functions in extant life, argue in favor of the hypothesis that RNA is a product of chemical or biological evolution. To understand the origin of RNA, we must consider which molecules could have originally acted in place of RNA’s substructures (i.e., nucleobases (the recognition units), ribose (a trifunctional connector), and phosphate (an ionized linker)) in the oldest ancestor of RNA (or proto-RNA). Major challenges to uncovering the chemical structure of proto-RNA include finding molecules that would have spontaneously undergone molecular selection and covalent assembly into an RNA-like polymer, within the complex mixture of the “prebiotic soup” and without the aid of enzymes. In this review, we discuss progress towards identifying the recognition units of proto-RNA and mechanisms by which the ancestral nucleobases might have been originally selected and incorporated into polymers. We consider possible proto-nucleobases within the chemical space of the heterocycles defined by the purines and pyrimidines that have H, NH₂, or O as exocyclic groups (which includes the extant nucleobases). Taking into account the results of numerous experiments that have explored nucleic acids with alternative backbones and noncanonical nucleobases, we are able to remove about half of these 81 molecules from candidacy as ancestral nucleobases. A particularly encouraging result of this approach is the identification of two molecules, 2,4,6-triaminopyrimidine and barbituric acid, which look very promising as possible nucleobases of proto-RNA.     

On the Origin of the Canonical Nucleobases: An Assessment of Selection Pressures across Chemical and Early Biological Evolution

The native bases of RNA and DNA are prominent examples of the narrow selection of organic molecules upon which life is based. How did nature “decide” upon these specific heterocycles? Evidence suggests that many types of heterocycles could have been present on the early Earth. It is therefore likely that the contemporary composition of nucleobases is a result of multiple selection pressures that operated during early chemical and biological evolution. The persistence of the fittest heterocycles in the prebiotic environment towards, for example, hydrolytic and photochemical assaults, may have given some nucleobases a selective advantage for incorporation into the first informational polymers. The prebiotic formation of polymeric nucleic acids employing the native bases remains, however, a challenging problem to reconcile. Hypotheses have proposed that the emerging RNA world may have included many types of nucleobases. This is supported by the extensive utilization of non-canonical nucleobases in extant RNA and the resemblance of many of the modified bases to heterocycles generated in simulated prebiotic chemistry experiments. Selection pressures in the RNA world could have therefore narrowed the composition of the nucleic acid bases. Two such selection pressures may have been related to genetic fidelity and duplex stability. Considering these possible selection criteria, the native bases along with other related heterocycles seem to exhibit a certain level of fitness. We end by discussing the strength of the N-glycosidic bond as a potential fitness parameter in the early DNA world, which may have played a part in the refinement of the alphabetic bases.     

Tuning the Innate Immune Response to Cyclic Dinucleotides by Using Atomic Mutagenesis

Cyclic dinucleotides (CDNs) trigger the innate immune response in eukaryotic cells through the stimulator of interferon genes (STING) signaling pathway. To decipher this complex cellular process, a better correlation between structure and downstream function is required. Herein, we report the design and immunostimulatory effect of a novel group of c-di-GMP analogues. By employing an “atomic mutagenesis” strategy, changing one atom at a time, a class of gradually modified CDNs was prepared. These c-di-GMP analogues induce type-I interferon (IFN) production, with some being more potent than c-di-GMP, their native archetype. This study demonstrates that CDN analogues bearing modified nucleobases are able to tune the innate immune response in eukaryotic cells.     

Copper‐Free Postsynthetic Labeling of Nucleic Acids by Means of Bioorthogonal Reactions

Postsynthetic modification of nucleic acids has the advantage that the chemical development of only a few building blocks is necessary, each bearing a chosen reactive functional group that is applicable to its reactive counterpart for a variety of different labeling types. The reactive group is either linked to phosphoramidites for chemical synthesis on solid phase or attached to nucleoside triphosphates for application in primer extension experiments and PCR. Chemoselectivity is required for this strategy, together with bioorthogonality to perform these labelings in living cells or even organisms. Currently, the copper‐free reactions include strain‐promoted 1,3‐dipolar cycloadditions, “photoclick” reactions, Diels–Alder reactions with inverse electron demand, and nucleophilic additions. The majority of these modification strategies show good to excellent reaction kinetics, an important prerequisite for labeling inside cells and in vivo in order to keep the concentrations of the reacting partners as low as possible.     

Traceless affinity labeling of endogenous proteins for functional analysis in living cells

Protein labeling and imaging techniques have provided tremendous opportunities to study the structure, function, dynamics, and localization of individual proteins in the complex environment of living cells. Molecular biology-based approaches, such as GFP-fusion tags and monoclonal antibodies, have served as important tools for the visualization of individual proteins in cells. Although these techniques continue to be valuable for live cell imaging, they have a number of limitations that have only been addressed by recent progress in chemistry-based approaches. These chemical approaches benefit greatly from the smaller probe sizes that should result in fewer perturbations to proteins and to biological systems as a whole. Despite the research in this area, so far none of these labeling techniques permit labeling and imaging of selected endogenous proteins in living cells. Researchers have widely used affinity labeling, in which the protein of interest is labeled by a reactive group attached to a ligand, to identify and characterize proteins. Since the first report of affinity labeling in the early 1960s, efforts to fine-tune the chemical structures of both the reactive group and ligand have led to protein labeling with excellent target selectivity in the whole proteome of living cells. Although the chemical probes used for affinity labeling generally inactivate target proteins, this strategy holds promise as a valuable tool for the labeling and imaging of endogenous proteins in living cells and by extension in living animals. In this Account, we summarize traceless affinity labeling, a technique explored mainly in our laboratory. In our overview of the different labeling techniques, we emphasize the challenge of designing chemical probes that allow for dissociation of the affinity module (often a ligand) after the labeling reaction so that the labeled protein retains its native function. This feature distinguishes the traceless labeling approach from the traditional affinity labeling method and allows for real-time monitoring of protein activity. With the high target specificity and biocompatibility of this technique, we have achieved individual labeling and imaging of endogenously expressed proteins in samples of high biological complexity. We also highlight applications in which our current approach enabled the monitoring of important biological events, such as ligand binding, in living cells. These novel chemical labeling techniques are expected to provide a molecular toolbox for studying a wide variety of proteins and beyond in living cells.     

N3-Kethoxal-Based Bioorthogonal Intracellular RNA Labeling

There is growing interest in developing intracellular RNA tools. Herein, we describe a strategy for N₃-kethoxal (N₃K)-based bioorthogonal intracellular RNA functionalization. With N₃K labeling followed by an in vivo click reaction with DBCO derivatives, RNA can be modified with fluorescent or phenol groups. This strategy provides a new way of labeling RNA inside cells.     

Real-time detection of nucleotide incorporation during complementary DNA strand synthesis

Real-time observation of DNA strand synthesis by using a supercritical angle fluorescence detection apparatus for surface-selective fluorescence detection is described. DNA template molecules were immobilized on a glass surface and the synthesis of the complementary strand was observed after addition of enzyme, dTTP, dATP, dGTP, and fluorescently labeled dCTP (d, deoxy; TP, triphosphate; T, A, G, and C, nucleobases). The fluorescence increase during the Klenow-fragment-catalyzed polymerization depends on the number of labeled dCTP nucleotides incorporated. The efficiency of this reaction is of the same order of magnitude as that of a bimolecular hybridization reaction.     

Polymerase Synthesis of DNA Containing Iodinated Pyrimidine or 7-Deazapurine Nucleobases and Their Post-synthetic Modifications through the Suzuki-Miyaura Cross-Coupling Reactions

All four iodinated 2′-deoxyribonucleoside triphosphates (dNTPs) derived from 5-iodouracil, 5-iodocytosine, 7-iodo-7-deazaadenine and 7-iodo-7-deazaguanine were prepared and studied as substrates for KOD XL DNA polymerase. All of the nucleotides were readily incorporated by primer extension and by PCR amplification to form DNA containing iodinated nucleobases. Systematic study of the Suzuki-Miyaura cross-coupling reactions with two bulkier arylboronic acids revealed that the 5-iodopyrimidines were more reactive and gave cross-coupling products both in the terminal or internal position in single-stranded oligonucleotides (ssONs) and in the terminal position of double-stranded DNA (dsDNA), whereas the 7-iodo-7-deazapurines were less reactive and gave cross-coupling products only in the terminal position. None of the four iodinated bases reacted in an internal position of dsDNA. These findings are useful for the use of the iodinated nucleobases for post-synthetic modification of DNA with functional groups for various applications.     

Guanine-rich DNA nanocircles for the synthesis and characterization of long cytosine-rich telomeric DNAs

Short synthetic oligonucleotides derived from the human telomeric repeat have been studied recently for their ability to fold into four-stranded structures that are thought to be important to their biological function. Because telomeric DNAs are several kilobases in length, however, their folding might well be affected by cooperative or high-order interactions in these long sequences. Here, we present a new molecular system that allows for easy synthesis of very long stretches of the cytosine-rich strand of human telomeric DNA. Small circular DNAs composed of the G-rich sequence of human telomeres were prepared and used as templates in a rolling-circle replication mechanism. To facilitate the synthesis of the repetitive G-rich circles, an orthogonal base-protection strategy that made use of dimethylformamidine-protected guanine nucleobases was developed. Nanometer-scale circles ranging in size from 42 to 54 nucleotides were prepared. Subsequently, we tested the action of various DNA polymerases on these circular templates, and identified DNA Pol I (Klenow fragment) and T7 DNA polymerase as enzymes that are able to generate very long, C-rich telomeric DNA strands. Purification and initial structural examination of these C-rich polymeric products revealed evidence of a folded structure in the polymer.     

Direct Synthesis of Partially Modified 2′‐O‐Pivaloyloxymethyl RNAs by a Base‐Labile Protecting Group Strategy and their Potential for Prodrug‐Based Gene‐Silencing Applications

An original and straightforward synthesis of partially modified 2′‐O‐pivaloyloxymethyl‐substituted (PivOM‐substituted) oligoribonucleotides has been achieved. The aim of this 2′‐enzymolabile modification was to enhance nuclease stability of RNA and transmembrane transport. To make these modified RNAs easily available we developed a base‐labile protecting group strategy with standard protections for nucleobases (acyl) and phosphates (cyanoethyl), a Q‐linker and two different acetalester protection groups for 2′‐OH: propionyloxymethyl (PrOM) and PivOM. Interestingly, orthogonal deprotection conditions based on anhydrous butylamine in THF were found to remove propionyloxymethyl groups selectively, while preserving PivOM groups. Duplex stability, circular dichroism studies and nuclease resistance, as well as the ability to inhibit gene expression of modified 2′‐O‐PivOM RNA, were evaluated.     

Transglutaminase-mediated N- and C-terminal fluorescein labeling of a protein can support the native activity of the modified protein

Fluorescein and its analogs are among the best fluorophores to label proteins and the labeling generally involves chemical modification of a translated protein. Using this methodology, labeling at a specific position remains difficult. It is known that the guinea pig liver transglutaminase (TGase)-catalyzed enzymatic modification method can allow terminal-specific fluorophore labeling of a protein by monodansylcadaverine. However, native activity of the fluorescent protein has not been investigated so far, nor has direct comparison between the chemical modification and the TGase-catalyzed modification been attempted. Therefore, we compared the possibility of fluorescein labeling via chemical labeling and via TGase-catalyzed modification. The latter method was found to be very practical and overcame some of the problems associated with the specificity of the former; fluorescein was covalently attached only to the N- or C-terminal site of glutathione S-transferase when the reaction was catalyzed by TGase and the resulting labeled protein completely retained its native activity. The TGase-mediated labeling occurred not only at room temperature but also at 4 degrees C to the same extent, which is more desirable for preventing the inactivation of proteins.     

Vicinal Diol-Tethered Nucleobases as Targets for DNA Redox Labeling with Osmate Complexes

Six-valent osmium (osmate) complexes with nitrogenous ligands have previously been used for the modification and redox labeling of biomolecules involving vicinal diol moieties (typically, saccharides or RNA). In this work, aliphatic (3,4-dihydroxybutyl and 3,4-dihydroxybut-1-ynyl) or cyclic (6-oxo-6-(cis-3,4-dihydroxypyrrolidin-1-yl)hex-2-yn-1-yl, PDI) vicinal diols are attached to nucleobases to functionalize DNA for subsequent redox labeling with osmium(VI) complexes. The diol-linked 2′-deoxyribonucleoside triphosphates were used for the polymerase synthesis of diol-linked DNA, which, upon treatment with K₂OsO₃ and bidentate nitrogen ligands, gave the desired Os-labeled DNA, which were characterized by means of the gel-shift assay and ESI-MS. Through ex situ square-wave voltammetry at a basal plane pyrolytic graphite electrode, the efficiency of modification/labeling of individual diols was evaluated. The results show that the cyclic cis-diol (PDI) was a better target for osmylation than that of the flexible aliphatic ones (alkyl- or alkynyl-linked). The osmate adduct-specific voltammetric signal obtained for Os^VI-treated DNA decorated with PDI showed good proportionality to the number of PDI per DNA molecule. The Os^VI reagents (unlike OsO₄) do not attack nucleobases; thus offering specificity of modification on the introduced glycol targets.     

Metabolic Remodeling of Cell‐Surface Sialic Acids: Principles,Applications, and Recent Advances

Cell‐surface sialic acids are essential in mediating a variety of physiological and pathological processes. Sialic acid chemistry and biology remain challenging to investigate, demanding new tools for probing sialylation in living systems. The metabolic glycan labeling (MGL) strategy has emerged as an invaluable chemical biology tool that enables metabolic installation of useful functionalities into cell‐surface sialoglycans by “hijacking” the sialic acid biosynthetic pathway. Here we review the principles of MGL and its applications in study and manipulation of sialic acid function, with an emphasis on recent advances.     

Two‐Step Protein Labeling by Using Lipoic Acid Ligase with Norbornene Substrates and Subsequent Inverse‐Electron Demand Diels–Alder Reaction

Inverse‐electron‐demand Diels–Alder cycloaddition (DA_inv) between strained alkenes and tetrazines is a highly bio‐orthogonal reaction that has been applied in the specific labeling of biomolecules. In this work we present a two‐step labeling protocol for the site‐specific labeling of proteins based on attachment of a highly stable norbornene derivative to a specific peptide sequence by using a mutant of the enzyme lipoic acid ligase A (LplA^W37V), followed by the covalent attachment of tetrazine‐modified fluorophores to the norbornene moiety through the bio‐orthogonal DA_inv . We investigated 15 different norbornene derivatives for their selective enzymatic attachment to a 13‐residue lipoic acid acceptor peptide (LAP) by using a standardized HPLC protocol. Finally, we used this two‐step labeling strategy to label proteins in cell lysates in a site‐specific manner and performed cell‐surface labeling on living cells.     

Origin of informational polymers: The concurrent roles of formamide and phosphates

Formamide chemistry provides a unitary system by gathering all of the precursors needed to synthesise pregenetic informational polymers in a single milieu. This is not observed with HCN chemistry. With common catalysts, formamide affords all of the precursor nucleobases, photochemically condenses into acyclonucleosides, favours transphosphorylation and enhances micellar aggregation of surfactants. Also, formamide provides a set of physicochemical conditions that thermodynamically favour the polymeric state of nucleotides over the monomers. In the origin-of-informational-polymers scenario, formamide acts in every step, the least characterised being the set of its reactions with phosphates. On this matter, we report two complementary sets of results: 1) the synthesis of prebiotic precursors from formamide, which are catalysed by soluble and mineral phosphates-we observed the formation of rich mixtures that include uracil, 9H-purine, cytosine, dihydrouracil, hypoxanthine, adenosine, urea, parabanic acid, the amino acid N-formylglycine and the peptide-condensing agent carbodiimide; and 2) the protection of ribo- and deoxyribophosphoester bonds by phosphates. The relevance of these effects with respect to the origin of informational polymers is discussed.