Synthesis and Properties of RNA Modified with Thioamide Internucleoside Linkage.

Recent success of RNA therapeutics has reinvigorated interest in chemical modifications of RNA. As exemplified by the phosphorothioates, modifications of sugar-phosphate backbone have been remarkably impactful but relatively underexplored in therapeutic RNAs. The present study reports synthesis, thermal stability, and RNA interference activity of RNAs modified with thioamide linkages. Compared to the previously studied amide-modified RNA, thioamide linkages strongly destabilized a short self-complementary RNA model duplex. However, in short interfering RNAs amides and thioamides had a similar effect on duplex stability and target RNA cleavage activity and specificity. Hence, the thioamide may be added to the toolbox of chemical biologist as a useful backbone modification well tolerated by the RNA interference machinery.

Synthesis and Properties of RNA Modified with Cationic Amine Internucleoside Linkage.

Chemical modifications of RNA are important tools for the development of RNA therapeutics. The present study reports a novel RNA backbone modification that replaces the negatively charged phosphate with a positively charged amine linkage. Despite being thermally destabilizing in RNA duplexes, the amine linkage caused a relatively modest decrease of activity of a modified short interfering RNA (siRNA). At position 2 of the guide strand, the amine modification strongly enhanced the specificity of siRNA while causing an ∼5-fold drop of on-target activity. These results support the future development of amines as cationic RNA modifications and novel tools to modulate protein-RNA interactions.

Comparison of 2-Aminopyridine and 4-Thiopseudisocytosine PNA Nucleobases for Hoogsteen Recognition of Guanosine in RNA.

Peptide nucleic acid (PNA) is emerging as a promising ligand for triple-helical recognition of folded biologically relevant RNA. Chemical modifications are actively being developed to achieve high affinity and sequence specificity under physiological conditions. In this study, we compared two modified PNA nucleobases, 2-aminopyridine (M) and 4-thiopseudisocytosine (L), as alternatives to protonated cytosine (unfavorable under physiological conditions), to form more stable triplets than C+·G-C. Both nucleobases formed M+·G-C and L·G-C triplets of similar stability; however, the L-modified PNAs showed somewhat reduced sequence specificity. In conclusion, M and L represent two alternative solutions to the problem of cytosine protonation in triple-helical recognition of RNA. In M, the pKa is increased to favor partial protonation, which improves solubility and cellular uptake of M-modified PNAs. In L, the sulfur substitution enhances favorable hydrophobic interactions, which may have advantages in avoiding off-target effects that may be caused by cationic modifications. However, our results showed that substituting Ms with Ls did not restore the sequence specificity of a PNA containing cationic groups.

Triplex-forming peptide nucleic acids as emerging ligands to modulate structure and function of complex RNAs.

Over the last three decades, our view of RNA has changed from a simple intermediate supporting protein synthesis to a major regulator of biological processes. In the expanding area of RNA research, peptide nucleic acid (PNA) is emerging as a promising ligand for triple-helical recognition of complex RNAs. As discussed in this feature article, the key advantages of PNAs are high sequence specificity and affinity for RNA (>10 fold higher than for DNA) that are difficult to achieve with small molecule ligands. Emerging studies demonstrate that triple-helical binding of PNAs can modulate biological function and control dynamic conformational equilibria of complex folded RNAs. These results suggest that PNA has a unique potential as a research tool and therapeutic compound targeting RNA. The remaining problems hampering advances in these directions are limitations of sequences that can be recognized by Hoogsteen triplexes (typically purine rich tracts), poor cellular uptake and bioavailability of PNA, and potential off-target effects in biological systems. Recent exciting studies are discussed that illustrate how synthetic nucleic acid chemistry provides innovative solutions for these problems.

Conformational Morphing by a DNA Analogue Featuring 7-Deazapurines and 5-Halogenpyrimidines and the Origins of Adenine-Tract Geometry.

Several efforts are currently directed at the creation and cellular implementation of alternative genetic systems composed of pairing components that are orthogonal to the natural dA/dT and dG/dC base pairs. In an alternative approach, Watson-Crick-type pairing is conserved, but one or all of the four letters of the A, C, G, and T alphabet are substituted by modified components. Thus, all four nucleobases were altered to create halogenated deazanucleic acid (DZA): dA was replaced by 7-deaza-2'-deoxyadenosine (dzA), dG by 7-deaza-2'-deoxyguanosine (dzG), dC by 5-fluoro-2'-deoxycytidine (FdC), and dT by 5-chloro-2'-deoxyuridine (CldU). This base-pairing system was previously shown to retain function in Escherichia coli. Here, we analyze the stability, hydration, structure, and dynamics of a DZA Dickerson-Drew Dodecamer (DDD) of sequence 5'-FdC-dzG-FdC-dzG-dzA-dzA-CldU-CldU-FdC-dzG-FdC-dzG-3'. Contrary to similar stabilities of DDD and DZA-DDD, osmotic stressing revealed a dramatic loss of hydration for the DZA-DDD relative to that for the DDD. The parent DDD 5'-d(CGCGAATTCGCG)-3' features an A-tract, a run of adenosines uninterrupted by a TpA step, and exhibits a hallmark narrow minor groove. Crystal structures─in the presence of RNase H─and MD simulations show increased conformational plasticity ("morphing") of DZA-DDD relative to that of the DDD. The narrow dzA-tract minor groove in one structure widens to resemble that in canonical B-DNA in a second structure. These changes reflect an indirect consequence of altered DZA major groove electrostatics (less negatively polarized compared to that in DNA) and hydration (reduced compared to that in DNA). Therefore, chemical modifications outside the minor groove that lead to collapse of major groove electrostatics and hydration can modulate A-tract geometry.

Improved Triplex-Forming Isoorotamide PNA Nucleobases for A-U Recognition of RNA Duplexes.

Four new isoorotamide (Io)-containing PNA nucleobases have been designed for A-U recognition of double helical RNA. New PNA monomers were prepared efficiently and incorporated into PNA nonamers for binding A-U in a PNA:RNA2 triplex. Isothermal titration calorimetry and UV thermal melting experiments revealed slightly improved binding affinity for singly modified PNA compared to known A-binding nucleobases. Molecular dynamics simulations provided further insights into binding of Io bases in the triple helix. Together, the data revealed interesting insights into binding modes including the notion that three Hoogsteen hydrogen bonds are unnecessary for strong selective binding of an extended nucleobase. Cationic monomer Io8 additionally gave the highest affinity observed for an A-binding nucleobase to date. These results will help inform future nucleobase design toward the goal of recognizing any sequence of double helical RNA.

Nucleobase and Linker Modification for Triple-Helical Recognition of Pyrimidines in RNA Using Peptide Nucleic Acids.

Triple-helical recognition of any sequence of double-stranded RNA requires high affinity Hoogsteen hydrogen binding to pyrimidine interruptions of polypurine tracts. Because pyrimidines have only one hydrogen bond donor/acceptor on Hoogsteen face, their triple-helical recognition is a formidable problem. The present study explored various five-membered heterocycles and linkers that connect nucleobases to backbone of peptide nucleic acid (PNA) to optimize formation of X•C-G and Y•U-A triplets. Molecular modeling and biophysical (UV melting and isothermal titration calorimetry) results revealed a complex interplay between the heterocyclic nucleobase and linker to PNA backbone. While the five-membered heterocycles did not improve pyrimidine recognition, increasing the linker length by four atoms provided promising gains in binding affinity and selectivity. The results suggest that further optimization of heterocyclic bases with extended linkers to PNA backbone may be a promising approach to triple-helical recognition of RNA.

Triplex-Forming Peptide Nucleic Acid Controls Dynamic Conformations of RNA Bulges.

RNA folding is driven by the formation of double-helical segments interspaced by loops of unpaired nucleotides. Among the latter, bulges formed by one or several unpaired nucleotides are one of the most common structural motifs that play an important role in stabilizing RNA-RNA, RNA-protein, and RNA-small molecule interactions. Single-nucleotide bulges can fold in alternative structures where the unpaired nucleobase is either looped-out (flexible) in a solvent or stacked-in (intercalated) between the base pairs. In the present study, we discovered that triplex-forming peptide nucleic acids (PNAs) had unusually high affinity for single-purine-nucleotide bulges in double-helical RNA. Depending on the PNA's sequence, the triplex formation shifted the equilibrium between looped-out and stacked-in conformations. The ability to control the dynamic equilibria of RNA's structure will be an important tool for studying structure-function relationships in RNA biology and may have potential in novel therapeutic approaches targeting disease-related RNAs.

Amide Modifications in the Seed Region of the Guide Strand Improve the On-Target Specificity of Short Interfering RNA.

RNA interference (RNAi) is a well-established research tool and is also maturing as a novel therapeutic approach. For the latter, microRNA-like off-target activity of short interfering RNAs (siRNAs) remains as one of the main problems limiting RNAi drug development. In this communication, we report that replacement of a single internucleoside phosphodiester in the seed region (nucleotides 2 to 7) of the guide strand with an amide linkage suppressed the undesired microRNA-like off-target activity by at least an order of magnitude. For the specific siRNA targeting the PIK3CB gene, an amide modification between the third and fourth nucleotides of the guide strand showed the strongest enhancement of specificity (completely eliminated off-target silencing) while maintaining high on-target activity. These results are important because off-target activity is one of the main remaining roadblocks for RNA based drug development.

Enzyme Fragment Complementation Driven by Nucleic Acid Hybridization.

A modified protein fragment complementation assay has been designed and validated as a gain-of-signal biosensor for nucleic acid:nucleic acid interactions. The assay uses fragments of NanoBiT, the split luciferase reporter enzyme, that are esterified at their C-termini to steramers, sterol-modified oligodeoxynucleotides. The Drosophila hedgehog autoprocessing domain, DHhC, served as a self-cleaving catalyst for these bioconjugations. In the presence of ssDNA or RNA with segments complementary to the steramers and adjacent to one another, the two NanoBiT fragments productively associate, reconstituting NanoBiT enzyme activity. NanoBiT luminescence in samples containing nM ssDNA or RNA template exceeded background by 30-fold and as high as 120-fold depending on assay conditions. A unique feature of this detection system is the absence of a self-labeling domain in the NanoBiT bioconjugates. Eliminating that extraneous bulk broadens the detection range from short oligos to full-length mRNA.

Chemical Modifications of CRISPR RNAs to Improve Gene-Editing Activity and Specificity.

CRISPR (clustered, regularly interspaced, short palindromic repeats) has become a cutting-edge research method and holds great potential to revolutionize biotechnology and medicine. However, like other nucleic acid technologies, CRISPR will greatly benefit from chemical innovation to improve activity and specificity for critical in vivo applications. Chemists have started optimizing various components of the CRISPR system; the present Perspective focuses on chemical modifications of CRISPR RNAs (crRNAs). As with other nucleic acid-based technologies, early efforts focused on well-established sugar and backbone modifications (2'-deoxy, 2'-F, 2'-OMe, and phosphorothioates). Some more significant alterations of crRNAs have been done using bicyclic (locked) riboses and phosphate backbone replacements (phosphonoacetates and amides); however, the range of chemical innovation applied to crRNAs remains limited to modifications that have been successful in RNA interference and antisense technologies. The encouraging results given by these tried-and-true modifications suggest that, going forward, chemists should take a bolder approach─research must aim to investigate what chemistry will have the most impact on maturing CRISPR as therapeutic and other in vivo technologies. With an eye to the future, this Perspective argues that the complexity of CRISPR presents rich unprecedented opportunities for chemists to synergize advances in synthetic methodology and structural biochemistry to rationally optimize crRNA-protein interactions.

2-Guanidyl pyridine PNA nucleobase for triple-helical Hoogsteen recognition of cytosine in double-stranded RNA.

In triplex-forming peptide nucleic acid, a novel 2-guanidyl pyridine nucleobase (V) enables recognition of up to two cytosine interruptions in polypurine tracts of dsRNA by engaging the entire Hoogsteen face of C-G base pair. Ab initio and molecular dynamics simulations provided insights into H-bonding interactions that stabilized V·C-G triplets. Our results provided insights for future design of improved nucleobases, which is an important step towards the ultimate goal of recognition of any sequence of dsRNA.

Optimization of Automated Synthesis of Amide-Linked RNA.

The recent FDA approval of several antisense and siRNA drugs illustrates the utility of nucleic acid chemical modifications, but numerous challenges remain for generalized nucleic acid therapeutics, urging the exploration of new modification strategies. Replacing backbone phosphates with amides has shown promise for enhancing siRNA activity, specificity, and nuclease resistance; however, amide-linked RNA has not been fully explored due to lengthy and low yielding manual amide coupling procedures. We have addressed this by automating the assembly of amide-linked RNA using an Expedite 8909 nucleic acid synthesizer and optimizing solid-phase synthesis conditions to achieve 91-95% yields in just 5 min of coupling time. The optimized protocol allowed synthesis of a 21-nucleotide-long siRNA guide strand having six consecutive amide linkages at the 3'-end with an overall yield of ∼1%. Our results show that the steric hindrance caused by bulky 2'-O protecting groups and steric hindrance of the solid support are the key optimization variables for improving the amide couplings.

Amide Internucleoside Linkages Are Well Tolerated in Protospacer Adjacent Motif-Distal Region of CRISPR RNAs.

The development of CRISPR-Cas9 mediated gene editing technology is revolutionizing molecular biology, biotechnology, and medicine. However, as with other nucleic acid technologies, CRISPR would greatly benefit from chemical modifications that optimize delivery, activity, and specificity of gene editing. Amide modifications at certain positions of short interfering RNAs have been previously shown to improve their RNAi activity and specificity, which motivated the current study on replacement of selected internucleoside phosphates of CRISPR RNAs with amide linkages. Herein, we show that amide modifications did not interfere with CRISPR-Cas9 activity when placed in the protospacer adjacent motif (PAM) distal region of CRISPR RNAs. In contrast, modification of the seed region led to a loss of DNA cleavage activity at most but not all positions. These results are encouraging for future studies on amides as backbone modifications in CRISPR RNAs.

Cellular uptake of 2-aminopyridine-modified peptide nucleic acids conjugated with cell-penetrating peptides.

Cell-penetrating peptides (CPPs) have been extensively used to deliver peptide nucleic acid (PNA) in cells. We have previously found that replacement of cytosine in triplex-forming PNAs with 2-aminopyridine (M) not only enhanced RNA binding, but also improved cellular uptake of PNAs. In this study, we used confocal fluorescence microscopy to evaluate the ability of CPPs to further improve cellular uptake of M-modified PNAs. We found that PNAs conjugated with Tat and octa-arginine peptides were effectively taken up in MCF7 cells when supplied in cell media at 1 µM. Remarkably, M-modified PNA without any CPP conjugation also showed strong uptake when the concentration was increased to 5 µM. Majority of PNA conjugates remained localized in distinct cytoplasmic vesicles, as judged by dot-like fluorescence patterns. However, M-modified PNAs conjugated with Tat, octa-arginine, and even a simple tri-lysine peptide also showed dispersed fluorescence in cytoplasm and were taken up in nuclei where they localized in larger vesicles, most likely nucleoli. Endosomolytic peptides or chemicals (chloroquine and CaCl2 ) did not release the conjugates from cytosolic vesicles, which suggested that the PNAs were not entrapped in endosomes. We hypothesize that M-modified PNAs escape endosomes and accumulate in cellular compartments rich in RNA, such as nucleoli, stress granules, and P-bodies.

Fluorobenzene Nucleobase Analogues for Triplex-Forming Peptide Nucleic Acids.

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.

Enzymatic Beacons for Specific Sensing of Dilute Nucleic Acid.

Enzymatic beacons, or E-beacons, are 1 : 1 bioconjugates of the nanoluciferase enzyme linked covalently at its C-terminus to hairpin forming ssDNA equipped with a dark quencher. We prepared E-beacons biocatalytically using HhC, the promiscuous Hedgehog C-terminal protein-cholesterol ligase. HhC attached nanoluciferase site-specifically to mono-sterylated hairpin oligonucleotides, called steramers. Three E-beacon dark quenchers were evaluated: Iowa Black, Onyx-A, and dabcyl. Each quencher enabled sensitive, sequence-specific nucleic acid detection through enhanced E-beacon bioluminescence upon target hybridization. We assembled prototype dabcyl-quenched E-beacons specific for SARS-CoV-2. Targeting the E484 codon of the virus Spike protein, E-beacons (80×10-12  M) reported wild-type SARS-CoV-2 nucleic acid at ≥1×10-9  M by increased bioluminescence of 8-fold. E-beacon prepared for the SARS-CoV-2 E484K variant functioned with similar sensitivity. Both E-beacons could discriminate their target from the E484Q mutation of the SARS-CoV-2 Kappa variant. Along with mismatch specificity, E-beacons are two to three orders of magnitude more sensitive than synthetic molecular beacons.

Enzymatic Beacons for Specific Sensing of Dilute Nucleic Acid and Potential Utility for SARS-CoV-2 Detection.

Enzymatic beacons, or E-beacons, are 1:1 bioconjugates of the nanoluciferase enzyme linked covalently at its C-terminus to hairpin forming DNA oligonucleotides equipped with a dark quencher. We prepared E-beacons biocatalytically using the promiscuous "hedgehog" protein-cholesterol ligase, HhC. Instead of cholesterol, HhC attached nanoluciferase site-specifically to mono-sterylated hairpin DNA, prepared in high yield by solid phase synthesis. We tested three potential E-beacon dark quenchers: Iowa Black, Onyx-A, and dabcyl. Prototype E-beacon carrying each of those quenchers provided sequence-specific nucleic acid sensing through turn-on bioluminescence. For practical application, we prepared dabcyl-quenched E-beacons for potential use in detecting the COVID-19 virus, SARS-CoV-2. Targeting the E484 codon of the SARS-CoV-2 Spike protein, E-beacons (80 × 10 -12 M) reported wild-type SARS-CoV-2 nucleic acid at ≥1 × 10 -9 M with increased bioluminescence of 8-fold. E-beacon prepared for the E484K variant of SARS-CoV-2 functioned with similar sensitivity. These E-beacons could discriminate their complementary target from nucleic acid encoding the E484Q mutation of the SARS-CoV-2 Kappa variant. Along with specificity, detection sensitivity with E-beacons is two to three orders of magnitude better than synthetic molecular beacons, rivaling the most sensitive nucleic acid detection agents reported to date.

Chemical approaches to discover the full potential of peptide nucleic acids in biomedical applications.

Peptide nucleic acid (PNA) is arguably one of the most successful DNA mimics, despite a most dramatic departure from the native structure of DNA. The present review summarizes 30 years of research on PNA's chemistry, optimization of structure and function, applications as probes and diagnostics, and attempts to develop new PNA therapeutics. The discussion starts with a brief review of PNA's binding modes and structural features, followed by the most impactful chemical modifications, PNA enabled assays and diagnostics, and discussion of the current state of development of PNA therapeutics. While many modifications have improved on PNA's binding affinity and specificity, solubility and other biophysical properties, the original PNA is still most frequently used in diagnostic and other in vitro applications. Development of therapeutics and other in vivo applications of PNA has notably lagged behind and is still limited by insufficient bioavailability and difficulties with tissue specific delivery. Relatively high doses are required to overcome poor cellular uptake and endosomal entrapment, which increases the risk of toxicity. These limitations remain unsolved problems waiting for innovative chemistry and biology to unlock the full potential of PNA in biomedical applications.

The 2-Aminopyridine Nucleobase Improves Triple-Helical Recognition of RNA and DNA When Used Instead of Pseudoisocytosine in Peptide Nucleic Acids.

Pseudoisocytosine (J), a neutral analogue of protonated cytosine, is currently the gold standard modified nucleobase in peptide nucleic acids (PNAs) for the formation of J·G-C triplets that are stable at physiological pH. This study shows that triple-helical recognition of RNA and DNA is significantly improved by using 2-aminopyridine (M) instead of J. The positively charged M forms 3-fold stronger M+·G-C triplets than J with uncompromised sequence selectivity. Replacement of six Js with Ms in a PNA 9-mer increased its binding affinity by ∼2 orders of magnitude. M-modified PNAs prefer binding double-stranded RNA over DNA and disfavor off-target binding to single-stranded nucleic acids. Taken together, the results show that M is a promising modified nucleobase that significantly improves triplex-forming PNAs and may provide breakthrough developments for therapeutic and biotechnology applications.