Remarkable acceleration of a DNA/RNA inter-strand functionality transfer reaction to modify a cytosine residue: the proximity effect via complexation with a metal cation

Modified nucleosides in natural RNA molecules are essential for their functions. Non-natural nucleoside analogues have been introduced into RNA to manipulate its structure and function. We have recently developed a new strategy for the in situ modification of RNA based on the functionality transfer reaction between an oligodeoxynucleotide probe and an RNA substrate. 2′-Deoxy-6-thioguanosine (6-thio-dG) was used as the platform to anchor the transfer group. In this study, a pyridinyl vinyl ketone moiety was newly designed as the transfer group with the expectation that a metal cation would form a chelate complex with the pyridinyl-2-keto group. It was demonstrated that the (E)-pyridinyl vinyl keto group was efficiently and specifically transferred to the 4-amino group of the opposing cytosine in RNA in the presence of NiCl₂ with more than 200-fold accelerated rate compared with the previous system with the use of the diketo transfer group. Detailed mechanistic studies suggested that NiCl₂ forms a bridging complex between the pyridinyl keto moiety and the N7 of the purine residue neighboring the cytosine residue of the RNA substrate to bring the groups in close proximity.     

Chemistry enters nucleic acids biology: Enzymatic mechanisms of RNA modification

Modified nucleotides are universally conserved in all living kingdoms and are present in almost all types of cellular RNAs, including tRNA, rRNA, sn(sno)RNA, and mRNA and in recently discovered regulatory RNAs. Altogether, over 110 chemically distinct RNA modifications have been characterized and localized in RNA by various analytical methods. However, this impressive list of known modified nucleotides is certainly incomplete, mainly due to difficulties in identification and characterization of these particular residues in low abundance cellular RNAs. In DNA, modified residues are formed by both enzymatic reactions (like DNA methylations, for example) and by spontaneous chemical reactions resulting from oxidative damage. In contrast, all modified residues characterized in cellular RNA molecules are formed by specific action of dedicated RNA-modification enzymes, which recognize their RNA substrate with high specificity. These RNA-modification enzymes display a great diversity in terms of the chemical reaction and use various low molecular weight cofactors (or co-substrates) in enzymatic catalysis. Depending on the nature of the target base and of the co-substrate, precise chemical mechanisms are used for appropriate activation of the base and the co-substrate in the enzyme active site. In this review, we give an extended summary of the enzymatic mechanisms involved in formation of different methylated nucleotides in RNA, as well as pseudouridine residues, which are almost universally conserved in all living organisms. Other interesting mechanisms include thiolation of uridine residues by ThiI and the reaction of guanine exchange catalyzed by TGT. The latter implies the reversible cleavage of the N-glycosidic bond in order to replace the initially encoded guanine by an aza-guanosine base. Despite the extensive studies of RNA modification and RNA-modification machinery during the last 20 years, our knowledge on the exact chemical steps involved in catalysis of RNA modification remains very limited. Recent discoveries of radical mechanisms involved in base methylation clearly demonstrate that numerous possibilities are used in Nature for these difficult reactions. Future studies are certainly required for better understanding of the enzymatic mechanisms of RNA modification, and this knowledge is crucial not only for basic research, but also for development of new therapeutic molecules.     

The nucleic acids of Drosophila melanogaster

1. Nucleic acids of whole Drosophila adults were prepared in good yield and substantially free from impurities by new modifications of the phenol method. 2. The average molar base compositions of the DNA (41% of guanine+cytosine) and transfer RNA (60% of guanine+cytosine) resemble those of mammalian nucleic acids; the ribosomal RNA has a DNA-like molar base composition (43% of guanine+cytosine), and it is considered that this is reflected in the lower stability of its secondary structure compared with mammalian ribosomal RNA. 3. The two main ribosomal forms were separated and average base compositions and sedimentation values determined.     

Ribozyme mediated trans insertion-splicing of modified oligonucleotides into RNA

The trans insertion-splicing reaction, catalyzed by a group I intron-derived from Pneumocystis carinii, was recently developed for the site-specific insertion of a segment of RNA into a separate RNA substrate. The molecular determinants of this reaction for binding and catalysis are reasonably well understood, making them easily and highly modifiable for altering substrate specificity. To demonstrate proof-of-concept, we now report that the P. carinii ribozyme can except modified oligonucleotides as substrates for catalyzing the trans insertion-splicing reaction. Oligonucleotides that contain one or more sugar modifications (deoxy or methoxy substitution), a backbone modification (phosphorothioate substitution), or a base modification (2-aminopurine or 4-thiouridine) are effective substrates in this reaction. Apparently, trans insertion-splicing is a unique and viable reaction for the site-specific incorporation of modified oligonucleotides into RNAs. This is the first report of a group I intron-derived ribozyme being capable of catalyzing the insertion of a modified oligonucleotide into RNA.     

Mechanisms of RNA catalysis

Ribozymes are RNA molecules that act as chemical catalysts. In contemporary cells, most known ribozymes carry out phosphoryl transfer reactions. The nucleolytic ribozymes comprise a class of five structurally-distinct species that bring about site-specific cleavage by nucleophilic attack of the 2'-O on the adjacent 3'-P to form a cyclic 2',3'-phosphate. In general, they will also catalyse the reverse reaction. As a class, all these ribozymes appear to use general acid-base catalysis to accelerate these reactions by about a million-fold. In the Varkud satellite ribozyme, we have shown that the cleavage reaction is catalysed by guanine and adenine nucleobases acting as general base and acid, respectively. The hairpin ribozyme most probably uses a closely similar mechanism. Guanine nucleobases appear to be a common choice of general base, but the general acid is more variable. By contrast, the larger ribozymes such as the self-splicing introns and RNase P act as metalloenzymes.     

Triplex targeting of a native gene in permeabilized intact cells: covalent modification of the gene for the chemokine receptor CCR5.

A 12 nucleotide oligodeoxyribopurine tract in the gene for the chemokine receptor CCR5 has been targeted and covalently modified in intact cells by a 12mer triplex forming oligonucleotide (TFO) bearing a reactive group. A nitrogen mustard placed on the 5'-end of the purine motif TFO modified a guanine on the DNA target with high efficiency and selectivity. A new use of a guanine analog in these TFOs significantly enhanced triplex formation and efficiency of modification, as did the use of the triplex-stabilizing intercalator coralyne. This site-directed modification of a native chromosomal gene in intact human cells under conditions where many limitations of triplex formation have been partially addressed underscores the potential of this approach for gene control via site-directed mutagenesis.     

Single nucleotide specific detection of DNA by native chemical ligation of fluorescence labeled PNA-probes

DNA-directed chemical ligations provide the opportunity to diagnose DNA sequences with very high sequence specificity. Fluorescent labels have been attached to reactive probes to enable the homogeneous detection of DNA and RNA. However, it has frequently been found that the attachment of fluorescent labels results in decreases of ligation fidelity. Herein we describe the development of a fluorogenic ligation reaction that provides for 10(2)-fold to perfect sequence selectivity. The reaction is based on the isocysteine-mediated native chemical PNA ligation. It is shown that DNA-induced rate accelerations of approximately 43.000-fold can be obtained through subtle variations of the ligation conditions. PNA-thioesters and isocysteine-PNA conjugates were labeled with FAM and TMR fluorophores, respectively. For gaining rapid synthetic access, a convenient on-resin labeling approach was developed. A new PNA monomer featuring an Alloc-protected lysine side chain was synthesized and coupled in solid-phase PNA synthesis. In the event of a ligation reaction the two fluorophores are brought into proximity. It is shown that fluorescence resonance energy transfer provides a positive fluorescence signal which is specific for product formation rather than for loss of starting materials. Single base mutations can be detected within minutes and with very high sequence selectivity at optimized conditions.     

Caged RNA: photo-control of a ribozyme reaction.

We report here the first photo-chemical control of a ribozyme reaction by the site-specific modification of the 2'-hydroxyl nucleophile in the hammerhead system with a caging functionality. Rapid laser photolysis of the O-(2-nitrobenzyl) caging group initiates an efficient and accurate hammerhead-catalyzed cleavage of substrate RNA under native conditions. RNAs in which reactive functionalities or recognition elements are caged in this manner will be useful tools to probe RNA reactivity and dynamics.     

A dimeric form of N-methoxycarbonyl-2-amino-1,8-naphthyridine bound to the A–A mismatch in the CAG/CAG base triad in dsRNA

A dimeric form of N-methoxycarbonyl-2-amino-1,8-naphthyridine (MCND) connected at the C2 position with a three-atom linker was examined for the binding to mismatches in double stranded RNA. Despite the fully complementary hydrogen bonding groups to guanine, MCND did not bind to guanine–guanine mismatch but did to adenine–adenine mismatch. The base pairs flanking the mismatch had weak effect on the binding, with showing the strongest binding to the A–A mismatch in the CAG/CAG sequence. The A–A mismatch in the GAC/GAC sequence was a poor substrate for the MCND binding. A monomeric derivative of MCND and another derivative lacking a methylcarbamate group showed negligilble binding to the A–A mismatch and the sequence selectivity. These results are important clues for the better molecular design of RNA binding small molecules.     

Raman spectra of ten aqueous transfer RNAs and 5S RNA. Conformational comparison with yeast phenylalanine transfer RNA.

Eleven native transfer RNAs have been prepared so as to maintain their Mg2+ content. Their aqueous Raman spectra show a high, relatively constant amount of order in the ribophosphate backbone, as indicated by the ratio 1.73 +/- 0.05 for I814/I1100 in all samples. Variation in the effectiveness of stacking of guanine and adenine bases is seen, though most of the transfer RNAs studied have a comparable degree of stacking to that found in phenylalanine transfer RNA from yeast, whose tertiary structure has been determined by X-ray crystallography. The spectrum of Escherichia coli 5S RNA indicates that the stacking efficiency of the guanine bases is much higher in 5S RNA than in yeast in phenylalanine transfer RNA, while that of the adenine bases is lower.     

Principles of selective inactivation of a viral genome. Comparative kinetic study of modification of the viral RNA and model protein with oligoaziridines

Comparative kinetic analysis of inactivation of bacteriophage MS2 infectivity and aminoalkylation of a model protein (trypsin inhibitor) with oligoaziridines was performed in order to evaluate the selectivity of viral RNA modification with oligocationic reagents. The transition from ethyleneimine monomer to di-, tri-, and tetramer leads to a sharp increase in the rate constant of infectivity inactivation, whereas the rate constant of protein modification changes insignificantly. The selectivity coefficient of the phage RNA aminoalkylation relative to trypsin inhibitor modification increases in this series by more than an order of magnitude. This effect is probably associated with the strengthening of the reagent binding to the nucleic acid, which implies a reaction mechanism that involves the formation of a reactive intermediate. The latter might be an electrostatic complex of the oligocationic reagent and RNA, the only polyanion in the virion. A pronounced decrease in the rate constant of infectivity inactivation in the presence of multiply charged anions (in phosphate buffer) and a biogenic polyamine (spermine) favors this hypothesis. Increasing the reaction temperature increases the rate constant of infectivity inactivation and decreases selectivity of the viral RNA modification.     

G‐rich sequence‐functionalized polystyrene microsphere‐based instantaneous derivatization for the chemiluminescent amplified detection of DNA

Herein, we develop a novel chemiluminescence (CL) approach with high sensitivity and excellent selectivity, by taking advantage of magnetic beads as preconcentration carriers and polystyrene microspheres as an amplification platform. Briefly, a ‘sandwich‐type’ detection strategy is employed in our design, which involves capture probe DNA immobilized on the surface of carboxyl‐terminated magnetic beads and multiple biotinylated reporter DNA self‐assembled on the surface of streptavidin‐modified polystyrene microspheres. The reporter DNA includes a guanine nucleobase‐rich (G‐rich) sequence domain for the generation of light and an additional tethered nucleic acid domain complementary with the target DNA. The CL signal is obtained via a novel instantaneous derivatization reaction between a specific CL reagent and the guanine nucleo­bases rich in the target and reporter DNA. As a result, we demonstrate that this DNA assay is reproducible, stable, easy to use, and can sensitively detect femtomolar target DNA related to anthrax lethal factors with excellent differentiation ability for single‐base mismatched sequences. Overall, this new CL protocol couples the high sensitivity of CL analysis with effective magnetic separation for discriminating against unwanted constituents such as mismatched sequences, and hence, offers great promise for DNA hybridization analysis. Copyright © 2009 John Wiley & Sons, Ltd.     

4-vinyl-substituted pyrimidine nucleosides exhibit the efficient and selective formation of interstrand cross-links with RNA and duplex DNA

The formation of interstrand cross-links in nucleic acids can have a strong impact on biological function of nucleic acids; therefore, many cross-linking agents have been developed for biological applications. Despite numerous studies, there remains a need for cross-linking agents that exhibit both efficiency and selectivity. In this study, a 4-vinyl-substituted analog of thymidine (T-vinyl derivative) was designed as a new cross-linking agent, in which the vinyl group is oriented towards the Watson–Crick face to react with the amino group of an adenine base. The interstrand cross-link formed rapidly and selectively with a uridine on the RNA substrate at the site opposite to the T-vinyl derivative. A detailed analysis of cross-link formation while varying the flanking bases of the RNA substrates indicated that interstrand cross-link formation is preferential for the adenine base on the 5′-side of the opposing uridine. In the absence of a 5′-adenine, a uridine at the opposite position underwent cross-linking. The oligodeoxynucleotides probe incorporating the T-vinyl derivative efficiently formed interstrand cross-links in parallel-type triplex DNA with high selectivity for dA in the homopurine strand. The efficiency and selectivity of the T-vinyl derivative illustrate its potential use as a unique tool in biological and materials research.     

TLR8 activation and inhibition by guanosine analogs in RNA: Importance of functional groups and chain length

Toll-like receptor 8 (TLR8) is an important component of the human innate immune system that recognizes single stranded RNA (ssRNA). Recent X-ray crystal structures of TLR8 bound to ssRNA revealed a previously unrecognized binding site for a 5′-UpG-3′ dinucleotide. Here we use an atomic mutagenesis strategy coupled with a cellular TLR8 activation assay to probe the importance of specific functional groups present on the guanine base in RNA-mediated receptor agonism and antagonism. Results from RNA analogs containing 7-deazaguanosine, 2-aminopurine and inosine confirm the importance of guanine N7, O6 and N2, respectively, in TLR8 activation. Nevertheless, these RNAs each retained TLR8 antagonism activity. RNA containing 7-deaza-8-azainosine (7d8aI) was prepared from a novel phosphoramidite and found to be a weaker TLR8 activator than guanosine-containing RNA. However, 7d8aI-containing RNA also retained TLR8 antagonism activity indicating that removal of multiple TLR8 H-bonding sites on guanine is insufficient for blocking TLR8 antagonism by guanine-containing RNA. We also identified an oligoribonucleotide length dependence on both TLR8 activation and antagonism. These studies extend our understanding of the effects of nucleobase modification on immune stimulation and will inform the design of novel RNA-based therapeutics.     

Structure of the Tetrahymena ribozyme: base triple sandwich and metal ion at the active site

The Tetrahymena intron is an RNA catalyst, or ribozyme. As part of its self-splicing reaction, this ribozyme catalyzes phosphoryl transfer between guanosine and a substrate RNA strand. Here we report the refined crystal structure of an active Tetrahymena ribozyme in the absence of its RNA substrate at 3.8 A resolution. The 3'-terminal guanosine (omegaG), which serves as the attacking group for RNA cleavage, forms a coplanar base triple with the G264-C311 base pair, and this base triple is sandwiched by three other base triples. In addition, a metal ion is present in the active site, contacting or positioned close to the ribose of the omegaG and five phosphates. All of these phosphates have been shown to be important for catalysis. Therefore, we provide a picture of how the ribozyme active site positions both a catalytic metal ion and the nucleophilic guanosine for catalysis prior to binding its RNA substrate.     

Mechanism of free radical nitric oxide-mediated Ras guanine nucleotide dissociation

Ras proteins cycle between GDP-bound and GTP-bound states to modulate a diverse array of cellular growth processes. In this study, we have elucidated a mechanism by which nitric oxide, in the presence of oxygen (NO/O2), regulates Ras activity. We show that treatment of Ras with NO/O2 causes conversion of Ras-bound GDP into a free 463.3 Da nucleotide-nitration product. Mass and UV/visible spectroscopic analyses suggest that this nitration product is 5-guanidino-4-nitroimidazole diphosphate (NIm-DP), a degradation product of 5-nitro-GDP. These results indicate that NO/O2 mediates Ras guanine nucleotide exchange (GNE) by conversion of Ras-bound GDP into an unstable 5-nitro-GDP. 5-Nitro-GDP can be produced by radical-based reaction of the GDP guanine base with nitrogen dioxide (*NO2). We also provide evidence that the Ras Phe28 side-chain plays a key role in the formation of a NO/O2-induced Ras 5-nitro-GDP product. We previously proposed a mechanism of NO/O2-mediated Ras GNE, in which *NO2, formed by the reaction of NO with O2, generates a Ras Cys118 thiyl radical (Ras-S118) intermediate. In the present study, we provide evidence for a radical-based mechanism of NO/O2-mediated Ras GNE. According to this mechanism, reaction of NO with O2 produces *NO2. *NO2 then reacts with Ras to produce Ras-S118, which withdraws an electron from the Ras-bound guanine nucleotide base to produce a guanine nucleotide diphosphate cation radical (G(+)-DP) via the Phe28 side-chain. G(+)-DP is subsequently converted to a neutral radical, and can react with another *NO2 to produce 5-nitro-GDP. This radical-based reaction process disrupts key binding interactions between Ras and the guanine base, resulting in release of GDP from Ras and its conversion to free 5-nitro-GDP. This mechanism is likely to be common to other NKCD motif-containing Ras superfamily GTPases, as NO/O2 also facilitates GNE on the redox-active Rap1A and Rab3A GTPases.     

Chemical synthesis and properties of modified oligonucleotides containing 5′-amino-5′-deoxy-5′-hydroxymethylthymidine residues

In this study, we designed 5′-amino-5′-deoxy-5′-hydroxymethylthymidine as a new oligonucleotide modification with an amino group directly attached to the 5′-carbon atom. We successfully synthesized two isomers of 5′-amino-5′-deoxy-5′-hydroxymethylthymidine via dihydroxylation of the 5′-vinyl group incorporated into 5′-deoxy-5′-C-methenylthymidine derivative. Moreover, it was found that the nuclease resistance, binding selectivity to single-stranded RNA, and triplex-forming ability of an oligonucleotide containing _RT residues of the new compound were higher than those of the unmodified oligonucleotide.