Project description:The N4-methylation of cytidine (m4C and m42C) in RNA plays important roles in both bacterial and eukaryotic cells. In this work, we synthesized a series of m4C and m42C modified RNA oligonucleotides, conducted their base pairing and bioactivity studies, and solved three new crystal structures of the RNA duplexes containing these two modifications. Our thermostability and X-ray crystallography studies, together with the molecular dynamic simulation studies, demonstrated that m4C retains a regular C:G base pairing pattern in RNA duplex and has a relatively small effect on its base pairing stability and specificity. By contrast, the m42C modification disrupts the C:G pair and significantly decreases the duplex stability through a conformational shift of native Watson-Crick pair to a wobble-like pattern with the formation of two hydrogen bonds. This double-methylated m42C also results in the loss of base pairing discrimination between C:G and other mismatched pairs like C:A, C:T and C:C. The biochemical investigation of these two modified residues in the reverse transcription model shows that both mono- or di-methylated cytosine bases could specify the C:T pair and induce the G to T mutation using HIV-1 RT. In the presence of other reverse transcriptases with higher fidelity like AMV-RT, the methylation could either retain the normal nucleotide incorporation or completely inhibit the DNA synthesis. These results indicate the methylation at N4-position of cytidine is a molecular mechanism to fine tune base pairing specificity and affect the coding efficiency and fidelity during gene replication.

Project description:Elucidation of the folded structures that RNA forms in vivo is vital to understanding its functions. Chemical reagents that modify the Watson-Crick (WC) face of unprotected nucleobases are particularly useful in structure elucidation. Dimethyl sulfate penetrates cell membranes and informs on RNA base-pairing and secondary structure but only modifies the WC face of adenines and cytosines. We present glyoxal, methylglyoxal, and phenylglyoxal as potent in vivo reagents that target the WC face of guanines as well as cytosines and adenines. Tests on rice (Oryza sativa) 5.8S rRNA in vitro read out by reverse transcription and gel electrophoresis demonstrate specific modification of almost all guanines in a time- and pH-dependent manner. Subsequent in vivo tests on rice, a eukaryote, and Bacillus subtilis and Escherichia coli, Gram-positive and Gram-negative bacteria, respectively, showed that all three reagents enter living cells without prior membrane permeabilization or pH adjustment of the surrounding media and specifically modify solvent-exposed guanine, cytosine, and adenine residues.

Project description:In the active cytosine demethylation pathway, 5-methylcytosine (5mC) is oxidized sequentially to 5-hydroxymethylcytosine (5hmC), 5-formylcytosine (5fC), and 5-carboxylcytosine (5caC). Thymine DNA glycosylase (TDG) selectively excises 5fC and 5caC but not cytosine (C), 5mC, and 5hmC. We propose that the electron-withdrawing properties of -CHO and -COOH in 5fC and 5caC increase N3 acidity, leading to weakened hydrogen bonding and reduced base pair stability relative to C, 5mC, and 5hmC, thereby facilitating the selective recognition of 5fC and 5caC by TDG. Through (13)C NMR, we measured the pKa at N3 of 5fC as 2.4 and the two pKa's of 5caC as 2.1 and 4.2. We used isotope-edited IR spectroscopy coupled with density functional theory (DFT) calculations to site-specifically assign the more acidic pKa of 5caC to protonation at N3, indicating that N3 acidity is increased in 5fC and 5caC relative to C. IR and UV melting studies of self-complementary DNA oligomers confirm reduced stability for 5fC-G and 5caC-G base pairs. Furthermore, while the 5fC-G base pair stability is insensitive to pH, the 5caC-G stability is reduced as pH decreases and the carboxyl group is increasingly protonated. Despite suggestions that 5fC and 5caC may exist in rare tautomeric structures which form wobble GC base pairs, our two-dimensional infrared (2D IR) spectroscopy of 5fC and 5caC free nucleosides confirms that both bases are predominantly in the canonical amino-keto form. Taken together, these findings support our model that weakened base pairing ability for 5fC and 5caC in dsDNA contributes to their selective recognition by TDG.

Project description:Here we describe a new class of immunostimulatory short duplex RNAs that potently induce production of type I interferon (IFN-I), and particularly IFN-β, in a wide range ofhuman cell types via end-to-end dimerization, direct binding to RIG-I, and activation of the RIG-I/IRF3 pathway. These RNAs require a minimum of 20 base pairs, lack any sequence or structural characteristics of known immunostimulatory RNAs, and instead require a unique conserved sequence motif (sense strand: 5’-C, antisense strand: 3’-GGG) that mediates the self-assembly of end-to-end RNA dimers by Hoogsteen G-G base-pairing. The presence of terminal hydroxyl or monophosphate groups, blunt or overhanging ends, or terminal RNA or DNA bases also did not affect their ability to induce IFN-I production. Immune stimulation mediated by these duplex RNAs results in broad spectrum inhibition of infections by many respiratory viruses with pandemic potential, including SARS-CoV-2, SARS-CoV, MERS-CoV, and influenza A, as well as the common cold virus HCoV-NL63 in cell lines and in human Lung Chips that mimic organlevel lung pathophysiology. These novel immunostimulatory motifs potentially could be harnessed to create broad-spectrum antiviral therapeutics, but they should be avoided when designing siRNAs to minimize immunological side effects.

Project description:Geranylation is a hydrophobic modification discovered in several bacteria tRNAs with the function of promoting codon bias during translation. However, why nature selects this C10-geranyl group remains a question. We conduct synthesis, UV-thermal denaturation, and molecular simulation studies in RNA duplexes and reveal possible reasons behind this natural selection. Among methyl-(C1), dimethylallyl-(C5), geranyl-(C10), and farnesyl-(C15) modified 2-thiouridines, only geranyl-group promotes U:G over U:A pair. Molecular simulation shows all the modified terpene groups point to the minor groove of RNA duplexes. The discrimination between U:G and U:A pairs derives from the difference in hydrogen bonding and interactions of the chain with the hydrophobic area in the minor groove. Geranyl group has perfect length to discriminate U:G and U:A pairs, whereas the others are either too long or too short to achieve the same behavior. This work indicates that geranyl group cannot be replaced by other terpene groups in promoting codon-specificity.

Project description:Inflammation-mediated reactive molecules can damage DNA by oxidation and chlorination. The biological consequences of this damage are as yet incompletely understood. In this paper, we have constructed oligonucleotides containing 5-chlorouracil (ClU), one of the known inflammation damage products. The thermodynamic stability, base pairing configuration, and duplex conformation of oligonucleotides containing ClU paired opposite adenine have been examined. NMR spectra reveal that the ClU-A base pair adopts a geometry similar to that of the T-A base pair, and the ClU-A base pair-containing duplex adopts a normal B-form conformation. The line width of the imino proton of the ClU residue is substantially greater than that of the corresponding T imino proton; however, this difference is not attributed to a reduced thermal or thermodynamic stability or to an increased level of proton exchange with solvent. While the NMR studies reveal an increased level of chemical exchange for the ClU imino proton of the ClU-A base pair, the ClU residue is not a target for removal by the Escherichia coli mispaired uracil glycosylase, which senses damage-related helix instability. The results of this study are consistent with previous reports indicating that the DNA of replicating cells can tolerate substantial substitution with ClU. The fraudulent, pseudo-Watson-Crick ClU-A base pair is sufficiently stable to avoid glycosylase removal and, therefore, might constitute a persistent form of cellular DNA damage.

Project description:Here we describe a new class of immunostimulatory short duplex RNAs that potently induce production of type I interferon (IFN-I), and particularly IFN-β, in a wide range of human cell types via end-to-end dimerization, direct binding to RIG-I, and activation of the RIG-I/IRF3 pathway. These RNAs require a minimum of 20 base pairs, lack any sequence or structural characteristics of known immunostimulatory RNAs, and instead require a unique conserved sequence motif (sense strand: 5’-C, antisense strand: 3’-GGG) that mediates the self-assembly of end-to-end RNA dimers by Hoogsteen G-G base-pairing. The presence of terminal hydroxyl or monophosphate groups, blunt or overhanging ends, or terminal RNA or DNA bases also did not affect their ability to induce IFN-I production. Immune stimulation mediated by these duplex RNAs results in broad spectrum inhibition of infections by many respiratory viruses with pandemic potential, including SARS-CoV-2, SARS-CoV, MERS-CoV, and influenza A, as well as the common cold virus HCoV-NL63 in cell lines and in human Lung Chips that mimic organlevel lung pathophysiology. These novel immunostimulatory motifs potentially could be harnessed to create broad-spectrum antiviral therapeutics, but they should be avoided when designing siRNAs to minimize immunological side effects.

Project description:DNA and RNA are known to have different structural properties. In the present study, molecular dynamics (MD) simulations on a series of RNA and DNA duplexes indicate differential structural flexibility for the two classes of oligonucleotides. In duplex RNA, multiple base pairs experienced local opening events into the major groove on the nanosecond time scale, while such events were not observed in the DNA simulations. Three factors are indicated to be responsible for the base opening events in RNA: solvent-base interactions, 2'OH(n)-O4'(n+1) intra-strand hydrogen bonding, and enhanced rigid body motion of RNA at the nucleoside level. Water molecules in the major groove of RNA contribute to initiation of base pair opening. Stabilization of the base pair open state is due to a 'conformational switch' comprised of 2'OH(n)-O4'(n+1) hydrogen bonding and a rigid body motion of the nucleoside moiety in RNA. This rigid body motion is associated with decreased flexibility of the glycosyl linkage and sugar moieties in A-form structures. The observed opening rates in RNA are consistent with the imino proton exchange experiments for AU base pairs, although not for GC base pairs, while structural and flexibility changes associated with the proposed conformational switch are consistent with survey data of RNA and DNA crystal structures. The possible relevance of base pair opening events in RNA to its many biological functions is discussed.

Project description:There are many effective ways to represent a minimum free energy RNA secondary structure that make it easy to locate its helices and loops. It is a greater challenge to visualize the thermal average probabilities of all folds in a partition function sum; dot plot representations are often puzzling. Therefore, we introduce the RNAbows visualization tool for RNA base pair probabilities. RNAbows represent base pair probabilities with line thickness and shading, yielding intuitive diagrams. RNAbows aid in disentangling incompatible structures, allow comparisons between clusters of folds, highlight differences between wild-type and mutant folds, and are also rather beautiful.

Project description:Noncanonical base pairs play important roles in assembling the three-dimensional structures critical to the diverse functions of RNA. These associations contribute to the looped segments that intersperse the canonical double-helical elements within folded, globular RNA molecules. They stitch together various structural elements, serve as recognition elements for other molecules, and act as sites of intrinsic stiffness or deformability. This work takes advantage of new software (DSSR) designed to streamline the analysis and annotation of RNA three-dimensional structures. The multiscale structural information gathered for individual molecules, combined with the growing number of unique, well-resolved RNA structures, makes it possible to examine the collective features deeply and to uncover previously unrecognized patterns of chain organization. Here we focus on a subset of noncanonical base pairs involving guanine and adenine and the links between their modes of association, secondary structural context, and contributions to tertiary folding. The rigorous descriptions of base-pair geometry that we employ facilitate characterization of recurrent geometric motifs and the structural settings in which these arrangements occur. Moreover, the numerical parameters hint at the natural motions of the interacting bases and the pathways likely to connect different spatial forms. We draw attention to higher-order multiplexes involving two or more G·A pairs and the roles these associations appear to play in bridging different secondary structural units. The collective data reveal pairing propensities in base organization, secondary structural context, and deformability and serve as a starting point for further multiscale investigations and/or simulations of RNA folding.