Selective 2'-hydroxyl acylation analyzed by primer extension (SHAPE): quantitative RNA structure analysis at single nucleotide resolution

Selective 2'-hydroxyl acylation analyzed by primer extension (SHAPE) interrogates local backbone flexibility in RNA at single-nucleotide resolution under diverse solution environments. Flexible RNA nucleotides preferentially sample local conformations that enhance the nucleophilic reactivity of 2'-hydroxyl groups toward electrophiles, such as N-methylisatoic anhydride (NMIA). Modified sites are detected as stops in an optimized primer extension reaction, followed by electrophoretic fragment separation. SHAPE chemistry scores local nucleotide flexibility at all four ribonucleotides in a single experiment and discriminates between base-paired versus unconstrained or flexible residues with a dynamic range of 20-fold or greater. Quantitative SHAPE reactivity information can be used to establish the secondary structure of an RNA, to improve the accuracy of structure prediction algorithms, to monitor structural differences between related RNAs or a single RNA in different states, and to detect ligand binding sites. SHAPE chemistry rarely needs significant optimization and requires two days to complete for an RNA of 100-200 nucleotides.     

Mechanics of DNA flexibility visualized by selective 2'-amine acylation at nucleotide bulges

We used selective acylation of 2'-amine-substituted nucleotides to visualize local backbone conformations that occur preferentially at bulged sites in DNA duplexes. 2'-Amine acylation reports local nucleotide flexibility because unconstrained 2'-amino nucleotides more readily reach a reactive conformation in which the amide-forming transition state is stabilized by interactions between the amine nucleophile and the adjacent 3'-phosphodiester group. Bulged 2'-amine-substituted cytidine nucleotides react approximately 20-fold more rapidly than nucleotides constrained by base-pairing at 35 degrees C. In contrast, base-paired 2'-amine-substituted nucleotides flanked by a 5' or 3' bulge react two- or six-fold more rapidly, respectively, than the perfectly paired duplex. The relative lack of 2'-amine reactivity for nucleotides adjacent to a DNA bulge emphasizes, first, that structural perturbations do not extend significantly into the flanking duplex structure. Second, the exquisite sensitivity towards very local perturbations in nucleic acid structure suggests that 2'-amine acylation can be used to chemically interrogate deletion mutations in DNA. Finally, these data support the mechanical interpretation that the reactive ribose conformation for 2'-amine acylation requires that the base lies out of the helix and in the major groove, a mechanistic insight useful for designing 2'-amine-based sensors.     

Synthesis of RNA oligomer using 9-fluorenylmethoxycarbonyl (Fmoc) group for 5'-hydroxyl protection

An approach using a new combination of protecting groups in RNA oligomer synthesis is proposed, in which 5'-hydroxyl group of ribose moiety is temporarily protected with the alkaline labile 9-fluorenylmethoxycarbonyl (Fmoc) group and the 2'-hydroxyl group is protected with the acid labile 1-ethoxyethyl (EE) group. The adoption of this method presented great selectivity in removing the 5'-hydroxyl protecting group and facilitated the RNA oligomer synthesis. A RNA pentamer was synthesized by the phosphotriester method in solution.     

The pre-tRNA nucleotide base and 2'-hydroxyl at N(-1) contribute to fidelity in tRNA processing by RNase P

Fidelity in tRNA processing by the RNase P RNA from Escherichia coli depends, in part, on interactions with the nucleobase and 2' hydroxyl group of N(-1), the nucleotide immediately upstream of the site of RNA strand cleavage. Here, we report a series of biochemical and structure-function studies designed to address how these interactions contribute to cleavage site selection. We find that simultaneous disruption of cleavage site nucleobase and 2' hydroxyl interactions results in parallel reactions leading to correct cleavage and mis-cleavage one nucleotide upstream (5') of the correct site. Changes in Mg(2+) concentration and pH can influence the fraction of product that is incorrectly processed, with pH effects attributable to differences in the rate-limiting steps for the correct and mis-cleavage reaction pathways. Additionally, we provide evidence that interactions with the 2' hydroxyl group adjacent to the reactive phosphate group also contribute to catalysis at the mis-cleavage site. Finally, disruption of the adjacent 2'-hydroxyl contact has a greater effect on catalysis when pairing between the ribozyme and N(-1) is also disrupted, and the effects of simultaneously disrupting these contacts on binding are also non-additive. One implication of these results is that mis-cleavage will result from any combination of active site modifications that decrease the rate of correct cleavage beyond a certain threshold. Indeed, we find that inhibition of correct cleavage and corresponding mis-cleavage also results from disruption of any combination of active site contacts including metal ion interactions and conserved pairing interactions with the 3' RCCA sequence. Such redundancy in interactions needed for maintaining fidelity may reflect the necessity for multiple substrate recognition in vivo. These studies provide a framework for interpreting effects of substrate modifications on RNase P cleavage fidelity and provide evidence for interactions with the nucleobase and 2' hydroxyl group adjacent to the reactive phosphate group in the transition state.     

The formation of covalent adducts between benzo[a]pyrenediol epoxide and RNA: structural analysis by mass spectrometry

Racemic 7-r,8-t-dihydroxy-9-t,10-t-epoxy-7,8,9,10-tetrahydrobenzo[a] pyrene was reacted with yeast RNA. Modified nucleosides were isolated and resolved by high-performance liquid chromatography; nine adduct peaks were collected for analysis. The bases in these adducts were identified by comparing their retention times with those of adducts from poly(G), poly(A), and poly(C). These samples gave two major and two minor Guo adducts, four major Ado adducts, and at least four Cyd adducts. The relative efficiencies of adduct formation with the polyribonucleotides were poly(G) greater than yeast RNA greater than poly(A) greater than poly(C). Fluorescence measurements show that emission from Guo adducts is strongly quenched relative to that from Ado adducts. Liquid secondary ion mass spectrometry (LSIMS) of underivatized samples and electron-impact mass spectrometry (EIMS) of permethyl derivatives were used to confirm the base identities and establish the alkylation sites of the RNA adducts. Unique nitrogen-containing hydrocarbon fragments that were observed with all samples by EIMS establish that in each adduct analyzed the C-10 position of the hydrocarbon is linked to the exocyclic amino group of the base. This suggested that the multiple adducts formed with each base are diastereomers derived from cis/trans epoxide ring opening of the (+) and (-) enantiomers of the carcinogen. Several adducts exhibited molecular ions by both LSIMS and EIMS. Large fragments observed by EIMS usually resulted from the loss of CH3OH, CH3O., CH2O, CH3., and H. from the molecular ion. Major fragmentation pathways also resulted in formation of nucleoside, base, ribose, hydrocarbon, and base-hydrocarbon ions. Each of these major ions in turn resulted in further characteristic fragmentation patterns.     

Evidence of the formation of direct covalent adducts of primaquine, 2-tert-butylprimaquine (NP-96) and monohydroxy metabolite of NP-96 with glutathione and N-acetylcysteine

2-tert-Butylprimaquine (NP-96) is a novel quinoline anti-malarial compound with superior therapeutic profile than primaquine (PQ). Moreover, it is the first 8-aminoquinoline that is established to be devoid of methemoglobin toxicity. The purpose of the present study was to investigate covalent adduct formation tendency of PQ, NP-96 and their phase I metabolites with glutathione (GSH) and N-acetylcysteine (NAc). For the same, the two compounds were incubated in human and rat liver microsomes in the presence of trapping agents and NADPH. In a control set, NADPH was excluded, while a blank was also studied that was devoid of both NADPH and microsomes. The components in the reaction mixtures were initially separated on a C-18 column (250 mm×4.6mm, 5 μm) using a mobile phase composed of acetonitrile and 10 mM ammonium acetate in a gradient mode. The samples were then subjected to LC-MS(n) and LC-HR-MS analyses, and data were collected in full scan MS, data dependent MS/MS, targeted MS/MS, neutral loss scan (NLS) and accurate mass (MS/TOF) modes. In a significant finding, both PQ and NP-96 themselves showed potential to bind covalently with GSH and NAc, as adducts were observed even in the control and blank incubations. Intense peaks corresponding to covalent adduct of mono-hydroxy metabolite of NP-96 with GSH and NAc were also detected in NADPH supplemented reaction solution.     

Important 2'-hydroxyl groups in model substrates for M1 RNA, the catalytic RNA subunit of RNase P from Escherichia coli.

The role of 2'-hydroxyl groups in a model substrate for RNase P from Escherichia coli was studied using mixed DNA/RNA derivatives of such a substrate. The presence of the 2'-hydroxyl groups of nucleotides at positions -1 and -2 in the leader sequence and at position 1, as well as at the first C in the 3'-terminal CCA sequence, are important but not absolutely essential for efficient cleavage of the substrate by RNase P or its catalytic RNA subunit, M1 RNA. The 2'-hydroxyl groups in the substrate that are important for efficient cleavage also participate in the binding of Mg2+. An all-DNA external guide sequence (EGS) can efficiently render a potential substrate, derived from the model substrate, susceptible to cleavage by the enzyme or its catalytic RNA subunit. Furthermore, both DNA and RNA EGSs turn over during the reaction with RNase P in vitro. The identity of the nucleotide at position 1 in the substrate, the adjacent Mg(2+)-binding site in the leader sequence, and the junction of the single and double-stranded regions are the important elements in the recognition of model substrates, as well as in the identification of the sites of cleavage in those model substrates.     

Selective RNA binding by a single CCCH zinc-binding domain from Nup475 (Tristetraprolin)

Regulation of gene expression takes place at several different levels and involves specific domains involved in specific protein-nucleic acid interactions. The protein Nup475 (also known as Tristetraprolin and TS11) binds to AU-rich sequence elements in certain mRNA molecules and favors the degradation of these mRNAs. The nucleic acid binding domain of Nup475 consists of two CCCH zinc-binding domains. A 36-amino acid peptide corresponding to the first of these CCCH domains has been synthesized and characterized. This peptide binds metal ions such as zinc(II) and cobalt(II) with affinities comparable to those of other authenticated zinc-binding domains. The zinc(II) complex of this peptide binds the RNA oligonucleotide UUUAUUU labeled with fluorescein on the 3'-end with an affinity of approximately 5 microM and discriminates against other sequences lacking the central A or the flanking U residues. These results demonstrate for the first time that a single CCCH domain is capable of binding single-stranded RNA with considerable affinity and selectivity. The combination of this well-behaved domain and the fluorescence-based binding assay sets the stage for more detailed structure-activity studies.     

Selective adsorption of 2'-O-anthraniloyl-AMP on DEAE-Sephadex: the basis of a direct, fluorescent assay for cyclic nucleotide phosphodiesterase

The fluorescent, 2'-O-anthraniloyl derivative of AMP was selectively absorbed onto DEAE-Sephadex in the presence of zirconyl chloride in citrate buffer. Under these conditions 2'-O-anthraniloyl-cAMP was eluted from the column. The selective adsorption of the AMP derivative onto DEAE-Sephadex, in the presence of zirconyl chloride, was adapted to the direct discontinuous assay of cyclic nucleotide phosphodiesterase. In this assay the enzyme is incubated for 4 min with 2'-O-anthraniloyl-cAMP; after quenching of the reaction by boiling, zirconyl chloride is added and the product (2'-O-anthraniloyl-AMP) is separated from the substrate on a column (0.6 ml) of DEAE-Sephadex. 2'-O-Anthraniloyl-AMP is then eluted with NaCl (2 M) and quantitated spectrofluorometrically. Under the conditions employed, 2'-O-anthraniloyl-AMP concentrations as low as 0.1 nmol can be detected. In the present study, this assay has been used to estimate Km and Vmax values for 2'-O-anthraniloyl-cAMP hydrolysis catalyzed by highly purified, as well as crude, preparations of cyclic nucleotide phosphodiesterase from bovine brain.     

Differential helix stabilities and sites pre-organized for tertiary interactions revealed by monitoring local nucleotide flexibility in the bI5 group I intron RNA

The local environment at adenosine residues in the bI5 group I intron RNA was monitored as a function of Mg(2+) using both the traditional method of dimethyl sulfate (DMS) N1 methylation and a new approach, selective acylation of 2'-amine substituted nucleotides. These probes yield complementary structural information because N1 methylation reports accessibility at the base pairing face, whereas 2'-amine acylation scores overall residue flexibility. 2'-Amine acylation robustly detects RNA secondary structure and is sensitive to higher order interactions not monitored by DMS. Disruption of RNA structure due to the 2'-amine substitution is rare and can be compensated by stabilizing folding conditions. Peripheral helices that do not interact with other parts of the RNA are more stable than both base paired helices and tertiary interactions in the conserved catalytic core. The equilibrium state of the bI5 intron RNA, prior to assembly with its protein cofactor, thus features a relatively loosely packed core anchored by more stable external stem-loop structures. Adenosine residues in J4/5 and P9.0 form structures in which the nucleotide is constrained but the N1 position is accessible, consistent with pre-organization to form long-range interactions with the 5' and 3' splice sites.     

4,5-bis(ethoxycarbonyl)-[1,3]dioxolan-2-yl as a new orthoester-type protecting group for the 2'-hydroxyl function in the chemical synthesis of RNA

We wish to report 4,5-bis(ethoxycarbonyl)-[1,3]dioxolan-2-yl as a new protecting for the 2'-hydroxyl function. Our cyclic orthoester-type group is compatible with the DMTr strategy for oligonucleotide synthesis. This group was introduced to the 2'-hydroxyl group of appropriately protected nucleoside derivatives in good yields under mild acidic conditions. Post-synthetic conversion of the moiety of this protecting group with an amine resulted in formation of a new amide moiety that is more stable to acid deprotection in aqueous solution, but it can still be easily removed by treatment with acids in organic solvents. In this article, we also describe the stability of not only the original and modified protecting groups but also internucleotidic phosphate linkages of protected RNA intermediates under deprotection conditions.     

A mechanism for SARS-CoV-2 RNA capping and its inhibition by nucleotide analog inhibitors

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Localized influence of 2'-hydroxyl groups and helix geometry on protein recognition in the RNA major groove

The local geometry of a DNA helix can influence protein recognition, but the sequence-specific features that contribute to helix structure are not fully understood, and even less is known about how RNA helix geometry may affect protein recognition. To begin to understand how local or global helix structure may influence binding in an RNA model system, we generated a series of DNA analogues of HIV and BIV TAR RNAs in which ribose sugars were systematically substituted in and around the known binding sites for argininamide and a BIV Tat arginine-rich peptide, respectively, and measured their corresponding binding affinities. For each TAR interaction, binding occurs in the RNA major groove with high specificity, whereas binding to the all-DNA analogue is weak and nonspecific. Relatively few substitutions are needed to convert either DNA analogue of TAR into a high-affinity binder, with the ribose requirements being restricted largely to regions that directly contact the ligand. Substitutions at individual positions show up to 70-fold differences in binding affinity, even at adjacent base pairs, while two base pairs at the core of the BIV Tat peptide-RNA interface are largely unaffected by deoxyribose substitution. These results suggest that the helix geometries and unique conformational features required for binding are established locally and are relatively insulated from effects more than one base pair away. It seems plausible that arginine-rich peptides are able to adapt to a mosaic helical architecture in which segments as small as single base steps may be considered as modular recognition units.