Project description:Double-helical RNA has become an attractive target for molecular recognition because many noncoding RNAs play important roles in the control of gene expression. Recently, we discovered that short peptide nucleic acids (PNA) bind strongly and sequence selectively to a homopurine tract of double-helical RNA via formation of a triple helix. Herein, we tested if the molecular recognition of RNA could be enhanced by α-guanidine modification of PNA. Our study was motivated by the discovery of Ly and co-workers that the guanidine modification greatly enhances the cellular delivery of PNA. Isothermal titration calorimetry showed that the guanidine-modified PNA (GPNA) had reduced affinity and sequence selectivity for triple-helical recognition of RNA. The data suggested that in contrast to unmodified PNA, which formed a 1:1 PNA-RNA triple helix, GPNA preferred a 2:1 GPNA-RNA triplex invasion complex. Nevertheless, promising results were obtained for recognition of biologically relevant double-helical RNA. Consistent with enhanced strand invasion ability, GPNA derived from d-arginine recognized the transactivation response element of HIV-1 with high affinity and sequence selectivity, presumably via Watson-Crick duplex formation. On the other hand, strong and sequence selective triple helices were formed by unmodified and nucelobase-modified PNA and the purine-rich strand of the bacterial A-site. These results suggest that appropriate chemical modifications of PNA may enhance molecular recognition of complex noncoding RNAs.

Project description:Risdiplam is the first approved small-molecule splicing modulator for the treatment of spinal muscular atrophy (SMA). Previous studies demonstrated that risdiplam analogues have two separate binding sites in exon 7 of the SMN2 pre-mRNA: (i) the 5'-splice site and (ii) an upstream purine (GA)-rich binding site. Importantly, the sequence of this GA-rich binding site significantly enhanced the potency of risdiplam analogues. In this report, we unambiguously determined that a known risdiplam analogue, SMN-C2, binds to single-stranded GA-rich RNA in a sequence-specific manner. The minimum required binding sequence for SMN-C2 was identified as GAAGGAAGG. We performed all-atom simulations using a robust Gaussian accelerated molecular dynamics (GaMD) method, which captured spontaneous binding of a risdiplam analogue to the target nucleic acids. We uncovered, for the first time, a ligand-binding pocket formed by two sequential GAAG loop-like structures. The simulation findings were highly consistent with experimental data obtained from saturation transfer difference (STD) NMR and structure-affinity-relationship studies of the risdiplam analogues. Together, these studies illuminate us to understand the molecular basis of single-stranded purine-rich RNA recognition by small-molecule splicing modulators with an unprecedented binding mode.

Project description:Peptide nucleic acid (PNA) forms a triple helix with double-stranded RNA (dsRNA) stabilized by a hydrogen-bonding zipper formed by PNA's backbone amides (N-H) interacting with RNA phosphate oxygens. This hydrogen-bonding pattern is enabled by the matching ∼5.7 Å spacing (typical for A-form dsRNA) between PNA's backbone amides and RNA phosphate oxygens. We hypothesized that extending the PNA's backbone by one -CH2 - group might bring the distance between PNA amide groups closer to 7 Å, which is favourable for hydrogen bonding to the B-form dsDNA phosphate oxygens. Extension of the PNA backbone was expected to selectively stabilize PNA-DNA triplexes compared to PNA-RNA. To test this hypothesis, we synthesized triplex-forming PNAs that had the pseudopeptide backbones extended by an additional -CH2 - group in three different positions. Isothermal titration calorimetry measurements of the binding affinity of these extended PNA analogues for the matched dsDNA and dsRNA showed that, contrary to our structural reasoning, extending the PNA backbone at any position had a strong negative effect on triplex stability. Our results suggest that PNAs might have an inherent preference for A-form-like conformations when binding double-stranded nucleic acids. It appears that the original six-atom-long PNA backbone is an almost perfect fit for binding to A-form nucleic acids.

Project description:Peptide nucleic acids (PNAs) have been developed for applications in biotechnology and therapeutics. There is great potential in the development of chemically modified PNAs or other triplex-forming ligands that selectively bind to RNA duplexes, but not single-stranded regions, at near-physiological conditions. Here, we report on a convenient synthesis route to a modified PNA monomer, thio-pseudoisocytosine (L), and binding studies of PNAs incorporating the monomer L. Thermal melting and gel electrophoresis studies reveal that L-incorporated 8-mer PNAs have superior affinity and specificity in recognizing the duplex region of a model RNA hairpin to form a pyrimidine motif major-groove RNA2-PNA triplex, without appreciable binding to single-stranded regions to form an RNA-PNA duplex or, via strand invasion, forming an RNA-PNA2 triplex at near-physiological buffer condition. In addition, an L-incorporated 8-mer PNA shows essentially no binding to single-stranded or double-stranded DNA. Furthermore, an L-modified 6-mer PNA, but not pseudoisocytosine (J) modified or unmodified PNA, binds to the HIV-1 programmed -1 ribosomal frameshift stimulatory RNA hairpin at near-physiological buffer conditions. The stabilization of an RNA2-PNA triplex by L modification is facilitated by enhanced van der Waals contacts, base stacking, hydrogen bonding and reduced dehydration energy. The destabilization of RNA-PNA and DNA-PNA duplexes by L modification is due to the steric clash and loss of two hydrogen bonds in a Watson-Crick-like G-L pair. An RNA2-PNA triplex is significantly more stable than a DNA2-PNA triplex, probably because the RNA duplex major groove provides geometry compatibility and favorable backbone-backbone interactions with PNA. Thus, L-modified triplex-forming PNAs may be utilized for sequence-specifically targeting duplex regions in RNAs for biological and therapeutic applications.

Project description:2,4-Difluorotoluene is a nonpolar isostere of thymidine that has been used as a powerful mechanistic probe to study the role of hydrogen bonding in nucleic acid recognition and interactions with polymerases. In the present study, we evaluated five fluorinated benzenes as nucleobase analogues in peptide nucleic acids designed for triple helical recognition of double helical RNA. We found that analogues having para and ortho fluorine substitution patterns (as in 2,4-difluorotoluene) selectively stabilized Hoogsteen triplets with U-A base pairs. The results were consistent with attractive electrostatic interactions akin to non-canonical F to H-N and C-H to N hydrogen bonding. The fluorinated nucleobases were not able to stabilize Hoogsteen-like triplets with pyrimidines in either G-C or A-U base pairs. Our results illustrate the ability of fluorine to engage in non-canonical base pairing and provide insights into triple helical recognition of RNA.

Project description:Triplex-forming oligonucleotides (TFOs) are powerful tools to interfere sequence-specifically with DNA-associated biological functions. (A/T,G)-containing TFOs are more commonly used in cells than (T,C)-containing TFOs, especially C-rich sequences; indeed the low intracellular stability of the non-covalent pyrimidine triplexes make the latter less active. In this work we studied the possibility to enhance DNA binding of (T,C)-containing TFOs, aiming to reach cellular activities; to this end, we used locked nucleic acid-modified TFOs (TFO/LNAs) in association with 5'-conjugation of an intercalating agent, an acridine derivative. In vitro a stable triplex was formed with the TFO-acridine conjugate: by SPR measurements at 37 degrees C and neutral pH, the dissociation equilibrium constant was found in the nanomolar range and the triplex half-life approximately 10 h (50-fold longer compared with the unconjugated TFO/LNA). Moreover to further understand DNA binding of (T,C)-containing TFO/LNAs, hybridization studies were performed at different pH values: triplex stabilization associated with pH decrease was mainly due to a slower dissociation process. Finally, biological activity of pyrimidine TFO/LNAs was evaluated in a cellular context: it occurred at concentrations approximately 0.1 microM for acridine-conjugated TFO/LNA (or approximately 2 microM for the unconjugated TFO/LNA) whereas the corresponding phosphodiester TFO was inactive, and it was demonstrated to be triplex-mediated.

Project description:Two single-stranded nucleic acid binding proteins mCBP and mCTBP were identified by means of their binding to a potential recombination hotspot in LTRs of mouse retro-transposons. Both are nuclear proteins of 35 and 55 kDa respectively. mCBP binds preferentially to oligo dC, mCTBP to oligo dCdT. mCBP was purified and its cDNA was isolated and sequenced.

Project description:Single-stranded nucleic acids (ssNAs) are ubiquitous in many key cellular functions. Their flexibility limits both the number of high-resolution structures available, leaving only a small number of protein-ssNA crystal structures, while forcing solution investigations to report ensemble averages. A description of the conformational distributions of ssNAs is essential to more fully characterize biologically relevant interactions. We combine small angle X-ray scattering (SAXS) with ensemble-optimization methods (EOM) to dynamically build and refine sets of ssNA structures. By constructing candidate chains in representative dinucleotide steps and refining the models against SAXS data, a broad array of structures can be obtained to match varying solution conditions and strand sequences. In addition to the distribution of large scale structural parameters, this approach reveals, for the first time, intricate details of the phosphate backbone and underlying strand conformations. Such information on unperturbed strands will critically inform a detailed understanding of an array of problems including protein-ssNA binding, RNA folding and the polymer nature of NAs. In addition, this scheme, which couples EOM selection with an iteratively refining pool to give confidence in the underlying structures, is likely extendable to the study of other flexible systems.

Project description:Molecular knots represent one of the most extraordinary topological structures in biological polymers. Creating highly knotted nanostructures with well-defined and sophisticated geometries and topologies remains challenging. Here, we demonstrate a general strategy to design and construct highly knotted nucleic acid nanostructures, each weaved from a single-stranded DNA or RNA chain by hierarchical folding in a prescribed order. Sets of DNA and RNA knots of two- or three-dimensional shapes have been designed and constructed (ranging from 1700 to 7500 nucleotides), and they exhibit complex topological features, with high crossing numbers (from 9 up to 57). These single-stranded DNA/RNA knots can be replicated and amplified enzymatically in vitro and in vivo. This work establishes a general platform for constructing nucleic acid nanostructures with complex molecular topologies.

Project description:Ubiquitination typically involves covalent linking of ubiquitin (Ub) to a lysine residue on a protein substrate. Recently, new facets of this process have emerged, including Ub modification of non-proteinaceous substrates like ADP-ribose by the DELTEX E3 ligase family. Here, we show that the DELTEX family member DTX3L expands this non-proteinaceous substrate repertoire to include single-stranded DNA and RNA. Although the N-terminal region of DTX3L contains single-stranded nucleic acid binding domains and motifs, the minimal catalytically competent fragment comprises the C-terminal RING and DTC domains (RD). DTX3L-RD catalyses ubiquitination of the 3'-end of single-stranded DNA and RNA, as well as double-stranded DNA with a 3' overhang of two or more nucleotides. This modification is reversibly cleaved by deubiquitinases. NMR and biochemical analyses reveal that the DTC domain binds single-stranded DNA and facilitates the catalysis of Ub transfer from RING-bound E2-conjugated Ub. Our study unveils the direct ubiquitination of nucleic acids by DTX3L, laying the groundwork for understanding its functional implications.