Your search keyword '"Peptide Nucleic Acids chemistry"' showing total 370 results

1. Recognition of Noncanonical RNA Base Pairs Using Triplex-Forming Peptide Nucleic Acids.

Author

Farshineh Saei S, Baskevics V, Katkevics M, and Rozners E

Subjects

Peptide Nucleic Acids chemistry, Base Pairing, RNA chemistry, Nucleic Acid Conformation, Molecular Dynamics Simulation, Hydrogen Bonding

Abstract

Noncanonical base pairs play an important role in enabling the structural and functional complexity of RNA. Molecular recognition of such motifs is challenging because of their diversity, significant deviation from the Watson-Crick structures, and dynamic behavior, resulting in alternative conformations of similar stability. Triplex-forming peptide nucleic acids (PNAs) have emerged as excellent ligands for the recognition of Watson-Crick base-paired double helical RNA. The present study extends the recognition potential of PNA to RNA helices having noncanonical GoU, AoC, and tandem GoA/AoG base pairs. The purines of the noncanonical base pairs formed M + ·GoU, T·AoC, M + ·GoA, and T·AoG Hoogsteen triples of similar or slightly reduced stability compared to the canonical M + ·G-C and T·A-U triples. Recognition of pyrimidines was more challenging. While the P·CoA triple was only slightly less stable than P·C-G, the E nucleobase did not form a stable triple with U of the UoG wobble pair. Molecular dynamics simulations suggested the formation of expected Hoogsteen hydrogen bonds for all of the stable triples. Collectively, these results expand the scope of triple helical recognition to noncanonical structures and sequence motifs common in biologically relevant RNAs.

Published

2025

2. A Multifunctional Peptide Nucleic Acid/Peptide Copolymer-Based Dual-Mode Biosensor with Macrophage-Hitchhiking for Enhanced Tumor Imaging and Urinalysis.

Author

Wei K, Xu Y, Nie C, Wei Q, Xie P, Chen T, Jiang J, and Chu X

Subjects

Animals, Humans, Mice, Urinalysis, MicroRNAs urine, MicroRNAs analysis, Polymers chemistry, Polymers chemical synthesis, Peptides chemistry, Neoplasms diagnostic imaging, Biosensing Techniques methods, Peptide Nucleic Acids chemistry, Macrophages metabolism

Abstract

Biosensors are capable of diagnosing tumors through imaging in vivo or liquid biopsy, but they face the challenges of inefficient delivery into tumor sites and the lack of reliable tumor-associated biomarkers. Herein, we constructed a dual-mode biosensor based on a multifunctional peptide nucleic acid (PNA)/peptide copolymer and DNA tetrahedron for tumor imaging and urinalysis. The biosensor could enter the cancer cells to initiate a microRNA-21-specific catalytic hairpin assembly reaction after cleavage by matrix-metalloprotease (MMP) in the tumor microenvironment, and the MMP cleavage product was released into the bloodstream and then was filtered out by the kidney. As PNA was a synthetic DNA analogue that could not be degraded by nucleases and proteases, it could serve as a reliable synthetic biomarker and be easily detected by high-performance liquid chromatography in urine. Importantly, the biosensor was hitchhiked on the macrophage membrane to realize efficient delivery in the depth of tumor utilizing the macrophage ability of actively homing to the tumor site and infiltrating into the tumor. The results indicated that the signal output of the biosensor was improved remarkably and mice with a tumor volume as little as 30-40 mm 3 could be reliably discriminated through urine assay. This innovative macrophage-hitchhiking dual-mode biosensor holds a great potential as a non-invasive and convenient tool for tumor diagnosis and tumor progression evaluation.

Published

2024

3. Synthetic Protein-to-DNA Input Exchange for Protease Activity Detection Using CRISPR-Cas12a.

Author

Capelli L, Pedrini F, Di Pede AC, Chamorro-Garcia A, Bagheri N, Fortunati S, Giannetto M, Mattarozzi M, Corradini R, Porchetta A, and Bertucci A

Subjects

Humans, DNA chemistry, DNA metabolism, Peptide Nucleic Acids chemistry, Peptide Nucleic Acids metabolism, CRISPR-Associated Proteins metabolism, CRISPR-Associated Proteins chemistry, Peptides chemistry, Peptides metabolism, DNA, Single-Stranded chemistry, DNA, Single-Stranded metabolism, Biosensing Techniques methods, Fluorescence Resonance Energy Transfer, CRISPR-Cas Systems genetics, Matrix Metalloproteinase 2 metabolism, Matrix Metalloproteinase 2 genetics

Abstract

We present a novel activity-based detection strategy for matrix metalloproteinase 2 (MMP2), a critical cancer protease biomarker, leveraging a mechanism responsive to the proteolytic activity of MMP2 and its integration with CRISPR-Cas12a-assisted signal amplification. We designed a chemical translator comprising two functional units─a peptide and a peptide nucleic acid (PNA), fused together. The peptide presents the substrate of MMP2, while the PNA serves as a nucleic acid output for subsequent processing. This chemical translator was immobilized on micrometer magnetic beads as a physical support for an activity-based assay. We incorporated into our design a single-stranded DNA partially hybridized with the PNA sequence and bearing a region complementary to the RNA guide of CRISPR-Cas12a. The target-induced nuclease activity of Cas12a results in the degradation of FRET-labeled DNA reporters and amplified fluorescence signal, enabling the detection of MMP2 in the low picomolar range, showing a limit of detection of 72 pg/mL. This study provides new design principles for a broader applicability of CRISPR-Cas-based biosensing.

Published

2024

4. Enhanced Recognition of a Herbal Compound Epiberberine by a DNA Quadruplex-Duplex Structure.

Author

Zhan X, Deng L, Lian Y, Shu Z, Xu Y, Mai X, Krishna MS, Lu R, Wang A, Bai S, Zhou F, Xiong C, Xu Y, Ni J, Vandana JJ, Wang Z, Li Y, Sun D, Huang S, Liu J, Cheng GJ, Wu S, Chiang YC, Stjepanovic G, Jiang C, Shao Y, and Chen G

Subjects

Humans, DNA chemistry, Peptide Nucleic Acids chemistry, G-Quadruplexes, Berberine chemistry, Berberine analogs & derivatives, Berberine pharmacology

Abstract

The small molecule epiberberine (EPI) is a natural alkaloid with versatile bioactivities against several diseases including cancer and bacterial infection. EPI can induce the formation of a unique binding pocket at the 5' side of a human telomeric G-quadruplex (HTG) sequence with four telomeric repeats (Q4), resulting in a nanomolar binding affinity ( K D approximately 26 nM) with significant fluorescence enhancement upon binding. It is important to understand (1) how EPI binding affects HTG structural stability and (2) how enhanced EPI binding may be achieved through the engineering of the DNA binding pocket. In this work, the EPI-binding-induced HTG structure stabilization effect was probed by a peptide nucleic acid (PNA) invasion assay in combination with a series of biophysical techniques. We show that the PNA invasion-based method may be useful for the characterization of compounds binding to DNA (and RNA) structures under physiological conditions without the need to vary the solution temperature or buffer components, which are typically needed for structural stability characterization. Importantly, the combination of theoretical modeling and experimental quantification allows us to successfully engineer Q4 derivative Q4-ds-A by a simple extension of a duplex structure to Q4 at the 5' end. Q4-ds-A is an excellent EPI binder with a K D of 8 nM, with the binding enhancement achieved through the preformation of a binding pocket and a reduced dissociation rate. The tight binding of Q4 and Q4-ds-A with EPI allows us to develop a novel magnetic bead-based affinity purification system to effectively extract EPI from Rhizoma coptidis (Huang Lian) extracts.

Published

2024

5. Electrophoretically Snagging Viral Genomes in Wormlike Micelle Networks Using Peptide Nucleic Acid Amphiphiles and dsDNA Oligomers.

Author

Hui K, Yan L, and Schneider JW

Subjects

Electrophoresis, Capillary, DNA, Viral genetics, DNA, Viral chemistry, DNA, Single-Stranded chemistry, Micelles, Genome, Viral, Peptide Nucleic Acids chemistry, DNA chemistry

Abstract

We demonstrate that the attachment of 30-170 bp dsDNA oligomers to ssDNA viral genomes gives a significant additional mobility shift in micelle-tagging electrophoresis (MTE). In MTE, a modified peptide nucleic acid amphiphile is attached to the viral genome to bind drag-inducing micelles present in capillary electrophoresis running buffers. Further attachment of 30-170 bp dsDNA oligomers drastically shifts the mobility of the 5.1 kB ssDNA genome of mouse minute virus (MMV), providing a new mechanism to improve resolution in CE-based analysis of kilobase nucleic acids. A model based on biased-reptation electrophoresis, end-labeled free-solution electrophoresis, and Ferguson gel-filtration theory is presented to describe the observed mobility shifts.

Published

2024

6. Papain-Mediated Conjugation of Peptide Nucleic Acids to Delivery Peptides: A Density Functional Theory/Molecular Mechanics Metadynamics Study in Aqueous and Organic Solvent.

Author

González RD and Carvalho ATP

Subjects

Molecular Dynamics Simulation, Peptide Nucleic Acids chemistry, Papain chemistry, Papain metabolism, Water chemistry, Solvents chemistry, Peptides chemistry, Density Functional Theory

Abstract

Enzymatic peptide synthesis is a powerful alternative to solid-phase methods, as enzymes can have high regio- and stereoselectivity and high yield and require mild reaction conditions. This is beneficial in formulation research due to the rise of nucleic acid therapies. Peptide nucleic acids (PNAs) have a high affinity toward DNA and RNA, and their solubility and cellular delivery can be improved via conjugation to peptides. Here, we designed and assessed the viability of the papain enzyme to conjugate four PNA-peptide models in water and an organic solvent using QM/MM metadynamics. We found that the reactions in water yield better results, where three conjugates could potentially be synthesized by the enzyme, with the first transition state as the rate-limiting step, with an associated energy of 14.53 kcal mol -1 , although with a slight endergonic profile. The results highlight the importance of considering the enzyme pockets and different substrate acceptivities and contribute to developing greener, direct, and precise synthetic routes for nucleic acid-based therapies. By exploring the enzyme's potential in conjunction with chemical synthesis, current protocols can be simplified for the synthesis of longer nucleic acids and peptide sequences (and, by extension, proteins) from smaller oligo or peptide blocks.

Published

2024

7. PNA-Functionalized, Silica Nanowires-Filled Glass Microtube for Ultrasensitive and Label-Free Detection of miRNA-21.

Author

Xu S, Wang G, Feng Y, Zheng J, Huang L, Liu J, Jiang Y, Wang Y, and Liu N

Subjects

Humans, Biosensing Techniques methods, Limit of Detection, MicroRNAs analysis, Peptide Nucleic Acids chemistry, Silicon Dioxide chemistry, Nanowires chemistry, Glass chemistry

Abstract

MicroRNAs (miRNAs) are endogenous and noncoding single-stranded RNA molecules with a length of approximately 18-25 nucleotides, which play an undeniable role in early cancer screening. Therefore, it is very important to develop an ultrasensitive and highly specific method for detecting miRNAs. Here, we present a bottom-up assembly approach for modifying glass microtubes with silica nanowires (SiNWs) and develop a label-free sensing platform for miRNA-21 detection. The three-dimensional (3D) networks formed by SiNWs make them abundant and highly accessible sites for binding with peptide nucleic acid (PNA). As a receptor, PNA has no phosphate groups and exhibits an overall electrically neutral state, resulting in a relatively small repulsion between PNA and RNA, which can improve the hybridization efficiency. The SiNWs-filled glass microtube (SiNWs@GMT) sensor enables ultrasensitive, label-free detection of miRNA-21 with a detection limit as low as 1 aM at a detection range of 1 aM-100 nM. Noteworthy, the sensor can still detect miRNA-21 in the range of 10 2 -10 8 fM in complex solutions containing 1000-fold homologous interference of miRNAs. The high anti-interference performance of the sensor enables it to specifically recognize target miRNA-21 in the presence of other miRNAs and distinguish 1-, 3-mismatch nucleotide sequences. Significantly, the sensor platform is able to detect miRNA-21 in the lysate of breast cancer cell lines ( e.g ., MCF-7 cells and MDA-MB-231 cells), indicating that it has good potential in the screening of early breast cancers.

Published

2024

8. Harnessing Peptide Nucleic Acids and the Eukaryotic Resolvase MOC1 for Programmable, Precise Generation of Double-Strand DNA Breaks.

Author

Sivakrishna Rao G, Saleh AH, Melliti F, Muntjeeb S, and Mahfouz M

Subjects

DNA Breaks, Double-Stranded, DNA chemistry, Gene Editing, Temperature, Peptide Nucleic Acids chemistry

Abstract

Programmable site-specific nucleases (SSNs) hold extraordinary promise to unlock myriad gene editing applications in medicine and agriculture. However, developing small and specific SSNs is needed to overcome the delivery and specificity translational challenges of current genome engineering technologies. Structure-guided nucleases have been harnessed to generate double-strand DNA breaks but with limited success and translational potential. Here, we harnessed the power of peptide nucleic acids (PNAs) for site-specific DNA invasion and the generation of localized DNA structures that are recognized and cleaved by the eukaryotic resolvase AtMOC1 from Arabidopsis thaliana . We named this technology PN A-assisted R esolvase-mediated (PNR) editing. We tested the PNR editing concept in vitro and demonstrated its precise target specificity, examined the nucleotide requirement around the PNA invasion for the AtMOC1-mediated cleavage, mapped the AtMOC1-mediated cleavage sites, tested the role of different types and lengths of PNA molecules invasion into dsDNA for the AtMOC1-mediated cleavage, optimized the in vitro PNA invasion and AtMOC1 cleavage conditions such as temperature, buffer conditions, and cleavage time points, and demonstrated the multiplex cleavage for precise fragment release. We discuss the best design parameters for efficient, site-specific in vitro cleavage using PNR editors.

Published

2024

9. Tryptophan-PNA gc Conjugates Self-Assemble to Form Fibers.

Author

Mosseri A, Sancho-Albero M, Mercurio FA, Leone M, De Cola L, and Romanelli A

Subjects

Dipeptides chemistry, Peptides, Models, Molecular, Tryptophan, Peptide Nucleic Acids chemistry

Abstract

Peptide nucleic acids and their conjugates to peptides can self-assemble and generate complex architectures. In this work, we explored the self-assembly of PNA dimers conjugated to the dipeptide WW. Our studies suggest that the indole ring of tryptophan promotes aggregation of the conjugates. The onset of fluorescence is observed upon self-assembly. The structure of self-assembled WWgc is concentration-dependent, being spherical at low concentrations and fibrous at high concentrations. As suggested by molecular modeling studies, fibers are stabilized by stacking interactions between tryptophans and Watson-Crick hydrogen bonds between nucleobases.

Published

2023

10. Parameterization of the miniPEG-Modified γPNA Backbone: Toward Induced γPNA Duplex Dissociation.

Author

Tamez A, Nilsson L, Mihailescu MR, and Evanseck JD

Subjects

Base Pairing, Molecular Conformation, Molecular Dynamics Simulation, Magnetic Resonance Spectroscopy, Nucleic Acid Conformation, Peptide Nucleic Acids chemistry

Abstract

γ-Modified peptide nucleic acids (γPNAs) serve as potential therapeutic agents against genetic diseases. Miniature poly(ethylene glycol) (miniPEG) has been reported to increase solubility and binding affinity toward genetic targets, yet details of γPNA structure and dynamics are not understood. Within our work, we parameterized missing torsional and electrostatic terms for the miniPEG substituent on the γ-carbon atom of the γPNA backbone in the CHARMM force field. Microsecond timescale molecular dynamics simulations were carried out on six miniPEG-modified γPNA duplexes from NMR structures (PDB ID: 2KVJ). Three NMR models for the γPNA duplex (PDB ID: 2KVJ) were simulated as a reference for structural and dynamic changes captured for the miniPEG-modified γPNA duplex. Principal component analysis performed on the γPNA backbone atoms identified a single isotropic conformational substate (CS) for the NMR simulations, whereas four anisotropic CSs were identified for the ensemble of miniPEG-modified γPNA simulations. The NMR structures were found to have a 23° helical bend toward the major groove, consistent with our simulated CS structure of 19.0°. However, a significant difference between simulated methyl- and miniPEG-modified γPNAs involved the opportunistic invasion of miniPEG through the minor and major groves. Specifically, hydrogen bond fractional analysis showed that the invasion was particularly prone to affect the second G-C base pair, reducing the Watson-Crick base pair hydrogen bond by 60% over the six simulations, whereas the A-T base pairs decreased by only 20%. Ultimately, the invasion led to base stack reshuffling, where the well-ordered base stacking was reduced to segmented nucleobase stacking interactions. Our 6 μs timescale simulations indicate that duplex dissociation suggests the onset toward γPNA single strands, consistent with the experimental observation of decreased aggregation. To complement the insight of miniPEG-modified γPNA structure and dynamics, the new miniPEG force field parameters allow for further exploration of such modified γPNA single strands as potential therapeutic agents against genetic diseases.

Published

2023

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

Author

Ryan CA, Rahman MM, Kumar V, and Rozners E

Subjects

Nucleic Acid Conformation, Base Pairing, Nucleotides chemistry, RNA chemistry, Peptide Nucleic Acids chemistry

Abstract

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.

Published

2023

12. Using Peptide Nucleic Acid Hybridization Probes for Qualitative and Quantitative Analysis of Nucleic Acid Therapeutics by Capillary Electrophoresis.

Author

Hutanu A, Signori C, Moritz B, Gregoritza M, Rohde A, and Schwarz MA

Subjects

Nucleic Acid Hybridization, DNA genetics, DNA chemistry, RNA chemistry, Peptides, Electrophoresis, Capillary methods, RNA, Messenger, Peptide Nucleic Acids chemistry

Abstract

The space of advanced therapeutic modalities is currently evolving in rapid pace necessitating continuous improvement of analytical quality control methods. In order to evaluate the identity of nucleic acid species in gene therapy products, we propose a capillary electrophoresis-based gel free hybridization assay in which fluorescently labeled peptide nucleic acids (PNAs) are applied as affinity probes. PNAs are engineered organic polymers that share the base pairing properties with DNA and RNA but have an uncharged peptide backbone. In the present study, we conduct various proof-of-concept studies to identify the potential of PNA probes for advanced analytical characterization of novel therapeutic modalities like oligonucleotides, plasmids, mRNA, and DNA released by recombinant adeno-associated virus. For single-stranded nucleic acids up to 1000 nucleotides, the method is an excellent choice that proved to be highly specific by detecting DNA traces in complex samples, while having a limit of quantification in the picomolar range when multiple probes are used. For double-stranded samples, only fragments that are similar in size to the probe could be quantified. This limitation can be circumvented when target DNA is digested and multiple probes are used opening an alternative to quantitative PCR.

Published

2023

13. Modeling Peptide Nucleic Acid Binding Enthalpies Using MM-GBSA.

Author

Goodman J, Attwood D, Kiely J, Coladas Mato P, and Luxton R

Subjects

DNA chemistry, Thermodynamics, Molecular Dynamics Simulation, Peptides, Nucleic Acid Conformation, Peptide Nucleic Acids chemistry, Nucleic Acids

Abstract

The binding enthalpies of peptide nucleic acid (PNA) homoduplexes were predicted using a molecular mechanics generalized Born surface area approach. Using the nucleic acid nearest-neighbor model, these were decomposed into sequence parameters which could replicate the enthalpies from thermal melting experiments with a mean error of 8.7%. These results present the first systematic computational investigation into the relationship between sequence and binding energy for PNA homoduplexes and identified a stabilizing helix initiation enthalpy not observed for nucleic acids with phosphoribose backbones.

Published

2022

14. Development of the Right- and Left-Handed Gamma Peptide Nucleic Acid Building Blocks for On-Resin Chemical Functionalization.

Author

Dhami I, Thadke SA, and Ly DH

Subjects

DNA chemistry, RNA chemistry, Peptide Nucleic Acids chemistry

Abstract

Gamma peptide nucleic acids (PNAs) are a promising class of nucleic acid mimics that adopt either a right- or left-handed helical motif as individual strands and hybridize to DNA or RNA with high affinity and sequence specificity, or not at all, depending on the helical sense. They are attractive as antisense and antigene reagents, as well as building blocks for molecular self-assembly; however, they have not been widely adopted due to their relatively poor biophysical attributes and the challenge in chemical modifications. Here, we report the development of a set of universal monomers, four each for both the right- and left-handed conformers, that permit rapid and selective on-resin chemical functionalization and diversification. The system is modular, permitting incorporation of different chemical groups in the backbone without causing adverse effects on hybridization. The approach overcomes the need to prepare a new set of monomers each time a different chemical group is introduced in the backbone. The newly added synthetic flexibility, along with superior hybridization property, recognition orthogonality, and helical sense translational capability, significantly expands the scope of gamma PNA in biology, biotechnology, and molecular engineering.

Published

2022

15. Aza-PNA: Engineering E-Rotamer Selectivity Directed by Intramolecular H-bonding.

Author

Shiraj A, Ramabhadran RO, and Ganesh KN

Subjects

DNA chemistry, Dimethyl Sulfoxide, RNA chemistry, Water, Peptide Nucleic Acids chemistry

Abstract

The replacement of α(CH 2 ) by NH in monomers of standard aeg PNA and its homologue β- ala PNA leads to respective aza -PNA monomers ( 1 and 2 ) in which the N α H can form either an 8-membered H-bonded ring with folding of the backbone (DMSO and water) or a 5-membered N α H─αCO (water) to stabilize E -type rotamers. Such aza -PNA oligomers with exclusive E rotamers and intraresidue backbone H-bonding can modulate its DNA/RNA binding and assembling properties.

Published

2022

16. Tuning the Loading and Release Properties of MicroRNA-Silencing Porous Silicon Nanoparticles by Using Chemically Diverse Peptide Nucleic Acid Payloads.

Author

Neri M, Kang J, Zuidema JM, Gasparello J, Finotti A, Gambari R, Sailor MJ, Bertucci A, and Corradini R

Subjects

Oligonucleotides, Porosity, Silicon chemistry, MicroRNAs genetics, Nanoparticles chemistry, Peptide Nucleic Acids chemistry

Abstract

Peptide nucleic acids (PNAs) are a class of artificial oligonucleotide mimics that have garnered much attention as precision biotherapeutics for their efficient hybridization properties and their exceptional biological and chemical stability. However, the poor cellular uptake of PNA is a limiting factor to its more extensive use in biomedicine; encapsulation in nanoparticle carriers has therefore emerged as a strategy for internalization and delivery of PNA in cells. In this study, we demonstrate that PNA can be readily loaded into porous silicon nanoparticles (pSiNPs) following a simple salt-based trapping procedure thus far employed only for negatively charged synthetic oligonucleotides. We show that the ease and versatility of PNA chemistry also allows for producing PNAs with different net charge, from positive to negative, and that the use of differently charged PNAs enables optimization of loading into pSiNPs. Differently charged PNA payloads determine different release kinetics and allow modulation of the temporal profile of the delivery process. In vitro silencing of a set of specific microRNAs using a pSiNP-PNA delivery platform demonstrates the potential for biomedical applications.

Published

2022

17. A Nanopore Sensor for Multiplexed Detection of Short Polynucleotides Based on Length-Variable, Poly-Arginine-Conjugated Peptide Nucleic Acids.

Author

Mereuta L, Asandei A, Dragomir I, Park J, Park Y, and Luchian T

Subjects

Arginine, DNA, Complementary, DNA, Single-Stranded, Humans, Peptides, Poly A, Polynucleotides, SARS-CoV-2, COVID-19, Nanopores, Peptide Nucleic Acids chemistry

Abstract

Real-time and easy-to-use detection of nucleic acids is crucial for many applications, including medical diagnostics, genetic screening, forensic science, or monitoring the onset and progression of various diseases. Herein, an exploratory single-molecule approach for multiplexed discrimination among similar-sized single-stranded DNAs (ssDNA) is presented. The underlying strategy combined (i) a method based on length-variable, short arginine (poly-Arg) tags appended to peptide nucleic acid (PNA) probes, designed to hybridize with selected regions from complementary ssDNA targets (cDNA) in solution and (ii) formation and subsequent detection with the α-hemolysin nanopore of (poly-Arg)-PNA-cDNA duplexes containing two overhangs associated with the poly-Arg tail and the non-hybridized segment from ssDNA. We discovered that the length-variable poly-Arg tail marked distinctly the molecular processes associated with the nanopore-mediated duplexes capture, trapping and unzipping. This enabled the detection of ssDNA targets via the signatures of (poly-Arg)-PNA-cDNA blockade events, rendered most efficient from the β-barrel entrance of the nanopore, and scaled proportional in efficacy with a larger poly-Arg moiety. We illustrate the approach by sensing synthetic ssDNAs designed to emulate fragments from two regions of SARS-CoV-2 nucleocapsid phosphoprotein N-gene.

Published

2022

18. Thiazole Containing PNA Mimic Regulates c-MYC Gene Expression through DNA G-Quadruplex.

Author

Gorai A, Chaudhuri R, Mukhopadhyay TK, Datta A, and Dash J

Subjects

DNA chemistry, DNA genetics, Gene Expression, HeLa Cells, Humans, Thiazoles, G-Quadruplexes, Peptide Nucleic Acids chemistry

Abstract

Peptide nucleic acids (PNAs), besides hybridizing to complementary DNA and RNAs, bind and stabilize DNA secondary structures. Herein, we illustrate the design and synthesis of PNA-like scaffolds by incorporating five-membered thiazole rings as modified bases instead of nucleobases and their subsequent effects on gene regulation by biophysical and in vitro assays. A thiazole-modified PNA trimer selectively recognizes c-MYC G-quadruplex (G4) DNA over other G4s and duplex DNA. It displays a high stabilization potential for the c-MYC G4 DNA and shows remarkable fluorescence enhancement with the c-MYC G4. It is flexible enough to bind at 5' and 3' ends as well as in the groove region of c-MYC G4. Furthermore, the PNA trimer easily permeates the cellular membrane and suppresses c-MYC mRNA expression in HeLa cells by targeting the promoter G4. This study illuminates modified PNAs as flexible molecular tools for selective targeting of noncanonical nucleic acids and modulating gene function.

Published

2022

19. Fluorescence Sensing of the Panhandle Structure of the Influenza A Virus RNA Promoter by Thiazole Orange Base Surrogate-Carrying Peptide Nucleic Acid Conjugated with Small Molecule.

Author

Sato Y, Miura H, Tanabe T, Okeke CU, Kikuchi A, and Nishizawa S

Subjects

Benzothiazoles, Fluorescence, Nucleic Acid Conformation, Nucleic Acid Probes, Promoter Regions, Genetic, Quinolines, RNA, Influenza A virus genetics, Peptide Nucleic Acids chemistry

Abstract

We have developed a new class of triplex-forming peptide nucleic acid (PNA)-based fluorogenic probes for sensing of the panhandle structure of the influenza A virus (IAV) RNA promoter region. Here, a small molecule (DPQ) capable of selectively binding to the internal loop structure was conjugated with triplex-forming forced intercalation of the thiazole orange (tFIT) probe with natural PNA nucleobases. The resulting conjugate, tFIT-DPQ, showed a significant light-up response (83-fold) upon strong ( K d = 107 nM) and structure-selective binding to the IAV RNA promoter region under physiological conditions (pH 7.0, 100 mM NaCl). We demonstrated the conjugation of these two units through the suitable spacer was key to show useful binding and fluorogenic signaling functions. tFIT-DPQ facilitated the sensitive and selective detection of IAV RNA based on its binding to the promoter region. Furthermore, we found that tFIT-DPQ could work as a sensitive indicator for screening of test compounds targeting the IAV RNA promoter region in the fluorescence indicator displacement assay.

Published

2022

20. Enhanced Triplex Hybridization of DNA and RNA via Syndiotactic Side Chain Presentation in Minimal bPNAs.

Author

Rundell S, Munyaradzi O, and Bong D

Subjects

Nucleic Acid Conformation, Nucleic Acid Hybridization, Thermodynamics, Thymine chemistry, Uracil chemistry, DNA chemistry, Peptide Nucleic Acids chemistry, RNA chemistry

Abstract

General design principles for recognition at noncanonical interfaces of DNA and RNA remain elusive. Triplex hybridization of bifacial peptide nucleic acids (bPNAs) with oligo-T/U DNAs and RNAs is a robust recognition platform that can be used to define structure-function relationships in synthetic triplex formation. To this end, a set of minimal ( m w < 1 kD) bPNA variants was synthesized to probe the impact of amino acid secondary structural propensity, stereochemistry, and backbone cyclization on hybridization with short, unstructured T-rich DNA and U-rich RNAs. Thermodynamic parameters extracted from optical melting analyses of bPNA variant hybrids indicated that there are two bPNA backbone modifications that significantly improve hybridization: alternating (d, l) configuration in open-chain dipeptides and homochiral dipeptide cyclization to diketopiperazine. Further, binding to DNA is preferred over RNA for all bPNA variants. Thymine-uracil substitutions in DNA substrates revealed that the methyl group of thymine accounts for 71% of ΔΔ G DNA-RNA for open-chain bPNAs but only 40% of ΔΔ G DNA-RNA for diketopiperazine bPNA, suggesting a greater sensitivity to RNA conformation and more optimized stacking in the cyclic bPNA. Together, these data reveal pressure points for tuning triplex hybridization at the chiral centers of bPNA, backbone conformation, stacking effects at the base triple, and the nucleic acid substrate itself. A structural blueprint for enhancing bPNA targeting of both DNA and RNA substrates includes syndiotactic base presentation (as found in homochiral diketopiperazines and d, l peptides), expansion of base stacking, and further investigation of bPNA backbone preorganization.

Published

2022

21. Suprastapled Peptides: Hybridization-Enhanced Peptide Ligation and Enforced α-Helical Conformation for Affinity Selection of Combinatorial Libraries.

Author

Sabale PM, Imiołek M, Raia P, Barluenga S, and Winssinger N

Subjects

Humans, Nucleic Acid Hybridization, Peptide Library, Peptide Nucleic Acids chemistry, Protein Binding drug effects, Protein Conformation, alpha-Helical, Proto-Oncogene Proteins c-mdm2 chemistry, Tumor Suppressor Protein p53 chemistry, Peptide Nucleic Acids metabolism, Peptides metabolism, Proto-Oncogene Proteins c-mdm2 metabolism, Tumor Suppressor Protein p53 metabolism

Abstract

Stapled peptides with an enforced α-helical conformation have been shown to overcome major limitations in the development of short peptides targeting protein-protein interactions (PPIs). While the growing arsenal of methodologies to staple peptides facilitates their preparation, stapling methodologies are not broadly embraced in synthetic library screening. Herein, we report a strategy leveraged on hybridization of short PNA-peptide conjugates wherein nucleobase driven assembly facilitates ligation of peptide fragments and constrains the peptide's conformation into an α-helix. Using native chemical ligation, we show that a mixture of peptide fragments can be combinatorially ligated and used directly in affinity selection against a target of interest. This approach was exemplified with a focused library targeting the p-53/MDM2 interaction. One hundred peptides were obtained in a one-pot ligation reaction, selected by affinity against MDM2 immobilized on beads, and the best binders were identified by mass spectrometry.

Published

2021

22. Reprogramming Gene Expression by Targeting RNA-Based Interactions: A Novel Pipeline Utilizing RNA Array Technology.

Author

Henderson CA, Vincent HA, and Callaghan AJ

Subjects

RNA, Bacterial genetics, Gene Expression Regulation, Bacterial, Oligodeoxyribonucleotides, Antisense chemistry, Peptide Nucleic Acids chemistry, RNA, Bacterial biosynthesis, Vibrio cholerae genetics, Vibrio cholerae metabolism

Abstract

Regulatory RNA-based interactions are critical for coordinating gene expression and are increasingly being targeted in synthetic biology, antimicrobial, and therapeutic fields. Bacterial trans -encoded small RNAs (sRNAs) regulate the translation and/or stability of mRNA targets through base-pairing interactions. These interactions are often integral to complex gene circuits which coordinate critical bacterial processes. The ability to predictably modulate these gene circuits has potential for reprogramming gene expression for synthetic biology and antibacterial purposes. Here, we present a novel pipeline for targeting such RNA-based interactions with antisense oligonucleotides (ASOs) in order to reprogram gene expression. As proof-of-concept, we selected sRNA-mRNA interactions that are central to the Vibrio cholerae quorum sensing pathway, required for V. cholerae pathogenesis, as a regulatory RNA-based interaction input. We rationally designed anti-sRNA ASOs to target the sRNAs and synthesized them as peptide nucleic acids (PNAs). Next, we devised an RNA array-based interaction assay to allow screening of the anti-sRNA ASOs in vitro . Finally, an Escherichia coli -based gene expression reporter assay was developed and used to validate anti-sRNA ASO regulatory activity in a cellular environment. The output from the pipeline was an anti-sRNA ASO that targets sRNAs to inhibit sRNA-mRNA interactions and modulate gene expression. This anti-sRNA ASO has potential for reprogramming gene expression for synthetic biology and/or antibacterial purposes. We anticipate that this pipeline will find widespread use in fields targeting RNA-based interactions as modulators of gene expression.

Published

2021

23. Triple-Helical Binding of Peptide Nucleic Acid Inhibits Maturation of Endogenous MicroRNA-197.

Author

Endoh T, Brodyagin N, Hnedzko D, Sugimoto N, and Rozners E

Subjects

Cell Line, Tumor, Humans, Inverted Repeat Sequences, MicroRNAs chemistry, Nucleic Acid Conformation, Peptide Nucleic Acids chemistry, Ribonuclease III antagonists & inhibitors, MicroRNAs metabolism, Peptide Nucleic Acids metabolism

Abstract

Sequence specific recognition and functional inhibition of biomedically relevant double-helical RNAs is highly desirable but remains a formidable problem. The present study demonstrates that electroporation of a triplex-forming peptide nucleic acid (PNA), modified with 2-aminopyridine (M) nucleobases, inhibited maturation of endogenous microRNA-197 in SH-SY5Y cells, while having little effect on maturation of microRNA-155 or -27a. In vitro RNA binding and Dicer inhibition assays suggested that the observed biological activity was most likely due to a sequence-specific PNA-RNA triplex formation that inhibited the activity of endonucleases responsible for microRNA maturation. The present study is the first example of modulation of activity of endogenous noncoding RNA using M-modified triplex-forming PNA.

Published

2021

24. Delocalization-Assisted Transport through Nucleic Acids in Molecular Junctions.

Author

Valdiviezo J, Clever C, Beall E, Pearse A, Bae Y, Zhang P, Achim C, Beratan DN, and Waldeck DH

Subjects

Nucleic Acid Conformation, Electron Transport, Electric Conductivity, Peptide Nucleic Acids chemistry, Peptide Nucleic Acids metabolism, DNA chemistry, DNA metabolism

Abstract

The flow of charge through molecules is central to the function of supramolecular machines, and charge transport in nucleic acids is implicated in molecular signaling and DNA repair. We examine the transport of electrons through nucleic acids to understand the interplay of resonant and nonresonant charge carrier transport mechanisms. This study reports STM break junction measurements of peptide nucleic acids (PNAs) with a G-block structure and contrasts the findings with previous results for DNA duplexes. The conductance of G-block PNA duplexes is much higher than that of the corresponding DNA duplexes of the same sequence; however, they do not display the strong even-odd dependence conductance oscillations found in G-block DNA. Theoretical analysis finds that the conductance oscillation magnitude in PNA is suppressed because of the increased level of electronic coupling interaction between G-blocks in PNA and the stronger PNA-electrode interaction compared to that in DNA duplexes. The strong interactions in the G-block PNA duplexes produce molecular conductances as high as 3% G 0 , where G 0 is the quantum of conductance, for 5 nm duplexes.

Published

2021

25. Uptake, Stability, and Activity of Antisense Anti- acpP PNA-Peptide Conjugates in Escherichia coli and the Role of SbmA.

Author

Yavari N, Goltermann L, and Nielsen PE

Subjects

Anti-Bacterial Agents metabolism, Cell Culture Techniques, Cell Membrane Permeability, Drug Discovery, Escherichia coli drug effects, Kinetics, Microbial Sensitivity Tests, Molecular Structure, Oligonucleotides, Antisense metabolism, Peptide Hydrolases metabolism, Peptide Nucleic Acids metabolism, Peptides metabolism, Protein Stability, Anti-Bacterial Agents chemistry, Escherichia coli Proteins metabolism, Membrane Transport Proteins metabolism, Oligonucleotides, Antisense chemistry, Peptide Nucleic Acids chemistry, Peptides chemistry

Abstract

PNA oligomers conjugated to bacteria penetrating peptides (BPPs), such as (KFF) 3 K, targeting essential bacterial genes, such as acp P, can inhibit bacterial growth at one-digit micromolar concentrations. It has been found that the LPS of the outer membrane of Gram-negative bacteria is a barrier for cellular uptake of (KFF) 3 K-eg 1 -PNA and that the SbmA transporter protein is involved in the passage through the inner membrane. We now further elucidate the uptake mechanism of (KFF) 3 K-eg 1 -PNA by showing that the peptide part of (KFF) 3 K-eg 1 -PNA is unstable and is degraded by peptidases in the medium of a bacterial culture ( t 1/2 < 5 min) and inside the bacteria. Analysis of peptide-PNA conjugates present in the periplasmic space and the cytoplasm showed the presence of mainly PNA with only the FFK tripeptide and without a peptide, at a concentration 10-fold that added to the medium. Furthermore, the two main degradation products showed no antibacterial effect when added directly to a bacterial culture and the antibacterial effect decreased with peptide length, thereby demonstrating that an intact peptide is indeed crucial for uptake but not for intracellular antisense activity. Most surprisingly, it was found that although the corresponding series of the proteolytically stable D-form (kff) 3 k-eg 1 -PNAs exhibited an analogous reduction of activity with peptide length, the activity was dependent on the presence of SbmA for the shorter peptides (which is not the case with the full length peptide). Therefore, our results suggest that the BPP is necessary for crossing both the LPS/outer membrane as well as the inner membrane and that full length (KFF) 3 K may spontaneously pass the inner membrane. Thus, SbmA dependence of (KFF) 3 K-eg 1 -PNA is ascribed to peptide degradation in the bacterial medium and in periplasmic space. Finally, the results show that stability and metabolism (by bacterial proteases/peptidases) should be taken into consideration upon design and activity/uptake analysis of BPPs (and antimicrobial peptides).

Published

2021

26. Isothermal Detection of Canine Blood Parasite ( Ehrlichia canis ) Utilizing Recombinase Polymerase Amplification Coupled with Graphene Oxide Quenching-Based Pyrrolidinyl Peptide Nucleic Acid.

Author

Yukhet P, Buddhachat K, Vilaivan T, and Suparpprom C

Subjects

Animals, DNA metabolism, Dogs, Ehrlichia canis genetics, Genes, Bacterial, RNA, Ribosomal, 16S chemistry, Ehrlichia canis isolation & purification, Graphite chemistry, Peptide Nucleic Acids chemistry, Pyrrolidines chemistry, Recombinases metabolism

Abstract

Canine monocytic ehrlichiosis (CME), caused by transmitted Ehrlichia canis infection, is a major disease in dogs with worldwide distribution. Herein, a nucleic acid assay was established for the identification of E. canis infection employing a fluorescently labeled conformationally constrained pyrrolidinyl PNA probe (Flu-acpcPNA) designed to sequence-specifically target the 16S rRNA gene. The sensing principle is based on the excellent quenching ability of graphene oxide (GO) of the free PNA probe, that was diminished upon binding to the DNA target. The addition of DNase I improved the performance of the detection system by eliminating the nonspecific quenching capability of long-chain dsDNA and thus enhancing the fluorescence signaling. The assay was coupled with a recombinase polymerase amplification (RPA) technique, which could be performed under isothermal conditions (37 °C) without DNA denaturation and purification steps. The established method is simple to set up and execute, proving a rapid, specific, and sensitive detection of 16S rRNA gene of E. canis with a limit of detection at least 11.1 pM. This technique shows good potential for the visual detection of double-stranded DNA targets without the need for PCR or complicated instruments, which shows great promise for practical usage in resource limited areas.

Published

2021

27. Peptide/Lipid-Associated Nucleic Acids (PLANAs) as a Multicomponent siRNA Delivery System.

Author

Hall R, Alasmari A, Mozaffari S, Mahdipoor P, Parang K, and Montazeri Aliabadi H

Subjects

Cell Line, Tumor, Gene Silencing physiology, Gene Transfer Techniques, Humans, Lipids chemistry, Nanoparticles chemistry, Peptide Nucleic Acids chemistry, Peptides chemistry, RNA Interference physiology, Lipids genetics, Peptide Nucleic Acids genetics, Peptides genetics, RNA, Small Interfering genetics

Abstract

RNAi is a biological process that utilizes small interfering RNA (siRNA) to prevent the translation of mRNA to protein. This mechanism could be beneficial in preventing the overexpression of proteins in cancer. However, the cellular delivery of siRNA has proven to be challenging due to its inherent negative charge and relative instability. Here, we designed a multicomponent delivery system composed of a specifically designed peptide (linear or cyclic fatty acyl peptide conjugates and hybrid cyclic/linear peptides) and several lipids (DOTAP, DOPE, cholesterol, and phosphatidylcholine) to form a nanoparticle, which we have termed as peptide lipid-associated nucleic acids (PLANAs). Five formulations were prepared (a formulation with no peptide, which was named lipid-associated nucleic acid or LANA, and PLANA formulations A-D) using a mini extruder to form uniform nanoparticles around 100 nm in size with a slightly positive charge (less than +10 mv). Formulations were evaluated for peptide incorporation, siRNA encapsulation efficiency, release profile, toxicity, cellular uptake, and protein silencing. Our experiments showed effective encapsulation of siRNA (>95%), a controlled release profile, and negligible toxicity in formulations that did not contain a positively charged lipid. The results also revealed that PLANAs C and D exhibited optimum cellular uptake (with 80-90% siRNA-positive cells for most of the formulations). PLANA D formulation was selected to silence two model proteins (Src and RPS6KA5) in the triple-negative human breast cancer cell line MDA-MB-231, with promising silencing efficiency, which diminished the expression of RPS6KA5 and Src to approximately 29 and 38% compared to naïve cells, respectively. Many approaches have been investigated for safe and efficient delivery of nucleic acids in the last 20 years; however, many have failed due to the multifaceted challenges to overcome. Our results show a promising potential for a multicomponent design that incorporates different components for a variety of delivery tasks, which warrants further investigation of PLANAs in vivo .

Published

2021

28. Tertiary Base Triple Formation in the SRV-1 Frameshifting Pseudoknot Stabilizes Secondary Structure Components.

Author

Yang L, Toh DK, Krishna MS, Zhong Z, Liu Y, Wang S, Gong Y, and Chen G

Subjects

Native Polyacrylamide Gel Electrophoresis, Nucleic Acid Conformation, Peptide Nucleic Acids chemistry, Peptide Nucleic Acids genetics, Ribosomes genetics, Ribosomes virology, Frameshifting, Ribosomal, Mason-Pfizer monkey virus genetics, RNA, Viral chemistry

Abstract

Minor-groove base triples formed between stem 1 and loop 2 of the simian retrovirus type 1 (SRV-1) mRNA frameshifting pseudoknot are essential in stimulating -1 ribosomal frameshifting. How tertiary base triple formation affects the local stabilities of secondary structures (stem 1 and stem 2) and thus ribosomal frameshifting efficiency is not well understood. We made a short peptide nucleic acid (PNA) that is expected to invade stem 1 of the SRV-1 pseudoknot by PNA-RNA duplex formation to mimic the stem 1 unwinding process by a translating ribosome. In addition, we used a PNA for invading stem 2 in the SRV-1 pseudoknot. Our nondenaturing polyacrylamide gel electrophoresis data for the binding of PNA to the SRV-1 pseudoknot and mutants reveal that mutations in loop 2 disrupting base triple formation between loop 2 and stem 1 in the SRV-1 pseudoknot result in enhanced invasion by both PNAs. Our data suggest that tertiary stem 1-loop 2 base triple interactions in the SRV-1 pseudoknot can stabilize both of the secondary structural components, stem 1 and stem 2. Stem 2 stability is thus coupled to the structural stability of stem 1-loop 2 base triples, mediated through a long-range effect. The apparent dissociation constants of both PNAs are positively correlated with the pseudoknot mechanical stabilities and frameshifting efficiencies. The relatively simple PNA local invasion experiment may be used to characterize the energetic contribution of tertiary interactions and ligand binding in many other RNA and DNA structures.

Published

2020

29. Necessity and Challenges of Sample Preconcentration in Analysis of Multiple MicroRNAs by Capillary Electrophoresis.

Author

Hu L, Krylova SM, Liu SK, Yousef GM, and Krylov SN

Subjects

Humans, Isotachophoresis methods, Limit of Detection, Nucleic Acid Amplification Techniques methods, Nucleic Acid Hybridization, Peptide Nucleic Acids chemistry, Biomarkers, Tumor analysis, Electrophoresis, Capillary methods, MicroRNAs analysis

Abstract

Thousands of putative microRNA (miRNA)-based cancer biomarkers have been reported, but none has been validated for approval by the Food and Drug Administration. One of the reasons for this alarming discrepancy is the lack of a method that is sufficiently robust for carrying out validation studies, which may require analysis of samples from hundreds of patients across multiple institutions and pooling the results together. The capillary electrophoresis (CE)-based hybridization assay proved to be more robust than reversed transcription polymerase chain reaction (the current standard), but its limit of quantification (LOQ) exceeds 10 pM while miRNA concentrations in cell lysates are below 1 pM. Thus, CE-based separation must be preceded by on-column sample preconcentration. Here, we explain the challenges of sample preconcentration for CE-based miRNA analyses and introduce a preconcentration method that can suit CE-based miRNA analysis utilizing peptide nucleic acid (PNA) hybridization probes. The method combines field-amplified sample stacking (FASS) with isotachophoresis (ITP). We proved that FASS-ITP could retain and concentrate both near-neutral PNA with highly negatively charged PNA-miRNA hybrids. We demonstrated that preconcentration by FASS-ITP could be combined with the CE-based separation of the unreacted PNA probes from the PNA-miRNA hybrids and facilitate improvement in LOQ by a factor of 140, down to 0.1 pM. Finally, we applied FASS-ITP-CE for the simultaneous detection of two miRNAs in crude cell lysates and proved that the method was robust when used in complex biological matrices. The 140-fold improvement in LOQ and the robustness to biological matrices will significantly expand the applicability of CE-based miRNA analysis, bringing it closer to becoming a practical tool for validation of miRNA biomarkers.

Published

2020

30. Thermoreversible Control of Nucleic Acid Structure and Function with Glyoxal Caging.

Author

Knutson SD, Sanford AA, Swenson CS, Korn MM, Manuel BA, and Heemstra JM

Subjects

Base Sequence, Catalysis, Catalytic Domain, Methylation, Nucleic Acid Conformation, Oligonucleotides chemistry, Peptide Nucleic Acids chemistry, Structure-Activity Relationship, Synthetic Biology, Tetroses chemistry, Thermodynamics, Glyoxal chemistry, Nucleic Acids chemistry

Abstract

Controlling the structure and activity of nucleic acids dramatically expands their potential for application in therapeutics, biosensing, nanotechnology, and biocomputing. Several methods have been developed to impart responsiveness of DNA and RNA to small-molecule and light-based stimuli. However, heat-triggered control of nucleic acids has remained largely unexplored, leaving a significant gap in responsive nucleic acid technology. Moreover, current technologies have been limited to natural nucleic acids and are often incompatible with polymerase-generated sequences. Here we show that glyoxal, a well-characterized compound that covalently attaches to the Watson-Crick-Franklin face of several nucleobases, addresses these limitations by thermoreversibly modulating the structure and activity of virtually any nucleic acid scaffold. Using a variety of DNA and RNA constructs, we demonstrate that glyoxal modification is easily installed and potently disrupts nucleic acid structure and function. We also characterize the kinetics of decaging and show that activity can be restored via tunable thermal removal of glyoxal adducts under a variety of conditions. We further illustrate the versatility of this approach by reversibly caging a 2'- O -methylated RNA aptamer as well as synthetic threose nucleic acid (TNA) and peptide nucleic acid (PNA) scaffolds. Glyoxal caging can also be used to reversibly disrupt enzyme-nucleic acid interactions, and we show that caging of guide RNA allows for tunable and reversible control over CRISPR-Cas9 activity. We also demonstrate glyoxal caging as an effective method for enhancing PCR specificity, and we cage a biostable antisense oligonucleotide for time-release activation and titration of gene expression in living cells. Together, glyoxalation is a straightforward and scarless method for imparting reversible thermal responsiveness to theoretically any nucleic acid architecture, addressing a significant need in synthetic biology and offering a versatile new tool for constructing programmable nucleic acid components in medicine, nanotechnology, and biocomputing.

Published

2020

31. Caspase-Activated Oligonucleotide Probe.

Author

Yang L, Eberwine JH, and Dmochowski IJ

Subjects

Base Sequence, Caspase 3 metabolism, Enzyme Activation, HeLa Cells, Humans, Oligonucleotide Probes chemistry, Peptide Nucleic Acids chemistry, Peptide Nucleic Acids metabolism, Apoptosis, Caspases metabolism, Oligonucleotide Probes metabolism

Abstract

Light-activated ("caged") oligonucleotides provide a strategy for modulating the activity of antisense oligos, siRNA, miRNA, aptamers, DNAzymes, and mRNA-capturing probes with high spatiotemporal resolution. However, the near-UV and visible wavelengths that promote these bond-breaking reactions poorly penetrate living tissue, which limits some biological applications. To address this issue, we describe the first example of a protease-activated oligonucleotide probe, capable of reporting on caspase-3 during cellular apoptosis. The 2'-F RNA-peptide substrate-peptide nucleic acid (PNA) hairpin structure was generated in 30% yield in a single bioconjugation step.

Published

2020

32. Tuning Composition of Polymer and Porous Silicon Composite Nanoparticles for Early Endosome Escape of Anti-microRNA Peptide Nucleic Acids.

Author

Kelly IB 3rd, Fletcher RB, McBride JR, Weiss SM, and Duvall CL

Subjects

Cell Line, Tumor, Cell Survival drug effects, Endosomes metabolism, Humans, Hydrogen-Ion Concentration, Hydrophobic and Hydrophilic Interactions, MicroRNAs antagonists & inhibitors, MicroRNAs genetics, Nanoparticles toxicity, Peptide Nucleic Acids chemistry, Polymers chemical synthesis, Porosity, RNA Interference, MicroRNAs metabolism, Nanoparticles chemistry, Peptide Nucleic Acids metabolism, Polymers chemistry, Silicon chemistry

Abstract

Porous silicon nanoparticles (PSNPs) offer tunable pore structure and easily modified surface chemistry, enabling high loading capacity for drugs with diverse chemicophysical properties. While PSNPs are also cytocompatible and degradable, PSNP integration into composite structures can be a useful approach to enhance carrier colloidal stability, drug-cargo loading stability, and endosome escape. Here, we explored PSNP polymer composites formed by coating of oxidized PSNPs with a series of poly[ethylene glycol- block -(dimethylaminoethyl methacrylate- co -butyl methacrylate)] (PEG-DB) diblock copolymers with varied molar ratios of dimethylaminoethyl methacrylate (D) and butyl methacrylate (B) in the random copolymer block. We screened and developed PSNP composites specifically toward intracellular delivery of microRNA inhibitory peptide nucleic acids (PNA). While a copolymer with 50 mol % B (50B) is optimal for early endosome escape in free polymer form, its pH switch was suppressed when it was formed into 50B polymer-coated PSNP composites (50BCs). We demonstrate that a lower mol % B (30BC) is the ideal PEG-DB composition for PSNP/PEG-DB nanocomposites based on having both the highest endosome disruption potential and miR-122 inhibitory activity. At a 1 mM PNA dose, 30BCs facilitated more potent inhibition of miR-122 in comparison to 40BC ( p = 0.0095), 50BC ( p < 0.0001), or an anti-miR-122 oligonucleotide delivered with the commercial transfection reagent Fugene 6. Using a live cell galectin 8-based endosome disruption reporter, 30BCs had greater endosomal escape than 40BCs and 50BCs within 2 h after treatment, suggesting that rapid endosome escape correlates with higher intracellular bioactivity. This study provides new insight on the polymer structure-dependent effects on stability, endosome escape, and cargo intracellular bioavailability for endosomolytic polymer-coated PSNPs.

Published

2020

33. Simultaneous Targeting of Two Master Regulators of Apoptosis with Dual-Action PNA- and DNA-Peptide Conjugates.

Author

Altrichter Y and Seitz O

Subjects

A549 Cells, Antineoplastic Agents chemistry, Antineoplastic Agents pharmacology, Cell-Penetrating Peptides, Down-Regulation, Humans, Inhibitor of Apoptosis Proteins, Molecular Structure, Neoplasms genetics, Neoplasms metabolism, Oligonucleotides, Apoptosis, DNA chemistry, Drug Delivery Systems, Peptide Nucleic Acids chemistry

Abstract

Conjugation of peptides with oligonucleotides offers opportunities for combining the strengths of both biopolymer classes. Herein, we show that the combination of a peptide-based module with an antisense oligonucleotide module provides for enhancements of potency and a widened scope of cell delivery options. The peptide unit comprises a Smac mimetic compound (SMCs) which antagonizes the action of inhibitor of apoptosis proteins (IAPs) frequently overexpressed in cancer cells. To counteract SMC resistance, the antisense module downregulates the cellular FLICE-like protein (c-FLIP), a master regulator of the extrinsic apoptosis pathway. We compared c-FLIP antisense units based on oligophosphorothioate (PSO) and peptide nucleic acid (PNA) architectures. Owing to the ease of synthesis, PNA conjugates combined with a cell penetrating peptide (CPP) offer a seemingly ideal solution for cell delivery of dual activity agents. However, our investigations revealed that such congeners have to be handled with care to avoid off-target effects. By contrast, PSO conjugates provided a more robust and specific activity for inducing death of SMC-resistant A549 cells due to a simultaneous activation of caspases and c-FLIP knockdown. We show that lipofection is a convenient approach for delivery of peptide-PSO conjugates into cells. The results highlight that the combination of the peptide and the DNA world confers properties inaccessible by the unconjugated components.

Published

2020

34. Context-Sensitive Cleavage of Folded DNAs by Loop-Targeting bPNAs.

Author

Liang Y, Miao S, Mao J, DeSantis C, and Bong D

Subjects

DNA chemistry, Humans, PC-3 Cells, Peptide Nucleic Acids chemistry, Telomere chemistry, Copper chemistry, DNA metabolism, G-Quadruplexes, Peptide Nucleic Acids pharmacology, Telomere metabolism, Telomere Shortening drug effects

Abstract

Herein, we demonstrate context-dependent molecular recognition of DNA by synthetic bPNA iron and copper complexes, using oxidative backbone cleavage as a chemical readout for binding. Oligoethylenimine bPNAs displaying iron·EDTA or copper·phenanthroline sites were found to be efficient chemical nucleases for designed and native structured DNAs with T-rich single-stranded domains. Cleavage reactivity depends strongly on structural context, as strikingly demonstrated with DNA substrates of the form (GGGTTA) n . This repeat sequence from the human telomere is known to switch between parallel and antiparallel G-quadruplex (G4) topologies with a change from potassium to sodium buffer: notably, bPNA-copper complexes efficiently cleave long repeat sequences into ∼22-nucleotide portions in sodium, but not potassium, buffer. We hypothesize preferential cleavage of the antiparallel topology (Na + ) over the parallel topology (K + ) due to the greater accessibility of the TTA loop to bPNA in the antiparallel (Na + ) form. Similar ion-sensitive telomere shortening upon treatment with bPNA nucleases can be observed in both isolated and intracellular DNA from PC3 cells by quantitative polymerase chain reaction. Live cell treatment was accompanied by accelerated cellular senescence, as expected for significant telomere shortening. Taken together, the loop-targeting approach of bPNA chemical nucleases complements prior intercalation strategies targeting duplex and quadruplex DNA. Structurally sensitive loop targeting enables discrimination between similar target sequences, thus expanding bPNA targeting beyond simple oligo-T sequences. In addition, bPNA nucleases are cell membrane permeable and therefore may be used to target native intracellular substrates. In addition, these data indicate that bPNA scaffolds can be a platform for new synthetic binders to particular nucleic acid structural motifs.

Published

2020

35. Structural Design and Synthesis of Bimodal PNA That Simultaneously Binds Two Complementary DNAs To Form Fused Double Duplexes.

Author

Gupta MK, Madhanagopal BR, Datta D, and Ganesh KN

Subjects

Chemistry Techniques, Synthetic, Click Chemistry, Solid Phase Extraction, Triazoles chemistry, DNA chemistry, Drug Design, Peptide Nucleic Acids chemical synthesis, Peptide Nucleic Acids chemistry

Abstract

Bimodal PNAs are new PNA constructs designed to bind two different cDNA sequences synchronously to form double duplexes. They are synthesized on solid phase using sequential coupling and click reaction to introduce a second base in each monomer at C α via alkyltriazole linker. The ternary bimodal PNA:DNA complexes show stability higher than that of individual duplexes. Bimodal PNAs are appropriate to create higher-order fused nucleic acid assemblies.

Published

2020

36. Unzipping Mechanism of Free and Polyarginine-Conjugated DNA-PNA Duplexes, Preconfined Inside the α-Hemolysin Nanopore.

Author

Dragomir IS, Bucataru IC, Schiopu I, and Luchian T

Subjects

Kinetics, DNA chemistry, Hemolysin Proteins analysis, Nanopores, Peptide Nucleic Acids chemistry, Peptides chemistry

Abstract

In this work, comparative studies on DNA-PNA and polyarginine-conjugated DNA-PNA duplexes unzipping inside the α-hemolysin nanopore (α-HL) are presented. We identified significant differences in the blockade currents, as the applied voltage across the nanopore facilitated the duplex capture inside the nanopore's vestibule against the constriction region, subsequent cDNA strand insertion inside the nanopore's β-barrel past the constriction site, its complete unzip from the duplex, and translocation. We observed that inside the voltage-biased nanopore, polyarginine-conjugated DNA-PNA duplexes dehybridize faster than their DNA-PNA counterparts and proposed a model to describe the duplex unzipping. This study identifies key particularities of DNA-PNA duplex unzipping as it takes place inside the nanopore and being preceded by entrapment in the vestibule domain of the α-HL. Our results are a crucial step toward understanding the nucleic acids duplexes unzipping kinetics variability, in confined, variable geometries.

Published

2020

37. Increasing the Sensitivity of Electrochemical DNA Detection by a Micropillar-Structured Biosensing Surface.

Author

Movilli J, Kolkman RW, Rozzi A, Corradini R, Segerink LI, and Huskens J

Subjects

Biosensing Techniques instrumentation, Biosensing Techniques methods, DNA genetics, Electrochemical Techniques instrumentation, Electrochemical Techniques methods, Electrodes, Gold chemistry, Immobilized Nucleic Acids genetics, Nucleic Acid Hybridization, Peptide Nucleic Acids genetics, Polylysine chemistry, Silicon chemistry, DNA analysis, Immobilized Nucleic Acids chemistry, Peptide Nucleic Acids chemistry

Abstract

The available active surface area and the density of probes immobilized on this surface are responsible for achieving high specificity and sensitivity in electrochemical biosensors that detect biologically relevant molecules, including DNA. Here, we report the design of gold-coated, silicon micropillar-structured electrodes functionalized with modified poly-l-lysine (PLL) as an adhesion layer to concomitantly assess the increase in sensitivity with the increase of the electrochemical area and control over the probe density. By systematically reducing the center-to-center distance between the pillars (pitch), denser micropillar arrays were formed at the electrode, resulting in a larger sensing area. Azido-modified peptide nucleic acid (PNA) probes were click-reacted onto the electrode interface, exploiting PLL with appended oligo(ethylene glycol) (OEG) and dibenzocyclooctyne (DBCO) moieties (PLL-OEG-DBCO) for antifouling and probe binding properties, respectively. The selective electrochemical sandwich assay formation, composed of consecutive hybridization steps of the target complementary DNA (cDNA) and reporter DNA modified with the electroactive ferrocene functionality (rDNA-Fc), was monitored by quartz crystal microbalance. The DNA detection performance of micropillared electrodes with different pitches was evaluated by quantifying the cyclic voltammetric response of the surface-confined rDNA-Fc. By decrease of the pitch of the pillar array, the area of the electrode was enhanced by up to a factor 10.6. A comparison of the electrochemical data with the geometrical area of the pillared electrodes confirmed the validity of the increased sensitivity of the DNA detection by the design of the micropillar array.

Published

2020

38. Peptide Nucleic Acid Conjugates of Quinone Methide Precursors Alkylate Ribonucleic Acid after Activation with Light.

Author

Hornung JE, Hellwig N, and Göbel MW

Subjects

Alkylation, Base Sequence, Peptide Nucleic Acids genetics, Purines chemistry, RNA genetics, Indolequinones chemistry, Peptide Nucleic Acids chemistry, Photochemical Processes, RNA chemistry

Abstract

Quinone methide precursors 2 and 3 were protected with a photoreactive 2-nitrobenzyl group and conjugated to peptide nucleic acids (PNA) using a Huisgen click reaction. After brief irradiation at 365 nm, cross-linking with complementary RNA strands started and was analyzed with an ALFexpress sequencer. When this method was used, the gel temperature had a major influence on apparent rates. Quinone methides are known to form transient as well as stable bonds with nucleotides. Although both were detected at 25 °C, analysis at 57 °C only recorded the stable types of cross-links, suggesting much slower alkylation kinetics. Linker 11 allowed us to attach quinone methides to internal positions of the PNA/RNA duplex and to capture a model of miR-20a with good efficiency.

Published

2020

39. Cell-Penetrating Streptavidin: A General Tool for Bifunctional Delivery with Spatiotemporal Control, Mediated by Transport Systems Such as Adaptive Benzopolysulfane Networks.

Author

López-Andarias J, Saarbach J, Moreau D, Cheng Y, Derivery E, Laurent Q, González-Gaitán M, Winssinger N, Sakai N, and Matile S

Subjects

Biotin chemistry, Cell-Penetrating Peptides chemical synthesis, Fluorescent Dyes chemistry, HeLa Cells, Humans, Microscopy, Fluorescence, Peptide Nucleic Acids chemistry, Single-Domain Antibodies chemistry, Streptavidin chemistry, Sulfides chemical synthesis, Biotin metabolism, Cell-Penetrating Peptides metabolism, Drug Delivery Systems, Streptavidin metabolism, Sulfides metabolism

Abstract

In this report, cell-penetrating streptavidin (CPS) is introduced to exploit the full power of streptavidin-biotin biotechnology in cellular uptake. For this purpose, transporters, here cyclic oligochalcogenides (COCs), are covalently attached to lysines of wild-type streptavidin. This leaves all four biotin binding sites free for at least bifunctional delivery. To maximize the standards of the quantitative evaluation of cytosolic delivery, the recent chloroalkane penetration assay (CAPA) is coupled with automated high content (HC) imaging, a technique that combines the advantages of fluorescence microscopy and flow cytometry. According to the resulting HC-CAPA, cytosolic delivery of CPS equipped with four benzopolysulfanes was the best among all tested CPSs, also better than the much smaller TAT peptide, the original cell-penetrating peptide from HIV. HaloTag-GFP fusion proteins expressed on mitochondria were successfully targeted using CPS carrying two different biotinylated ligands, HaloTag substrates or anti-GFP nanobodies, interfaced with peptide nucleic acids, flipper force probes, or fluorescent substrates. The delivered substrates could be released from CPS into the cytosol through desthiobiotin-biotin exchange. These results validate CPS as a general tool which enables unrestricted use of streptavidin-biotin biotechnology in cellular uptake.

Published

2020

40. Spontaneous Emergence of Self-Replicating Molecules Containing Nucleobases and Amino Acids.

Author

Liu B, Pappas CG, Ottelé J, Schaeffer G, Jurissek C, Pieters PF, Altay M, Marić I, Stuart MCA, and Otto S

Subjects

Dipeptides chemistry, Macromolecular Substances chemical synthesis, Peptide Nucleic Acids chemistry, Purines chemistry, Pyrimidines chemistry

Abstract

The conditions that led to the formation of the first organisms and the ways that life originates from a lifeless chemical soup are poorly understood. The recent hypothesis of "RNA-peptide coevolution" suggests that the current close relationship between amino acids and nucleobases may well have extended to the origin of life. We now show how the interplay between these compound classes can give rise to new self-replicating molecules using a dynamic combinatorial approach. We report two strategies for the fabrication of chimeric amino acid/nucleobase self-replicating macrocycles capable of exponential growth. The first one relies on mixing nucleobase- and peptide-based building blocks, where the ligation of these two gives rise to highly specific chimeric ring structures. The second one starts from peptide nucleic acid (PNA) building blocks in which nucleobases are already linked to amino acids from the start. While previously reported nucleic acid-based self-replicating systems rely on presynthesis of (short) oligonucleotide sequences, self-replication in the present systems start from units containing only a single nucleobase. Self-replication is accompanied by self-assembly, spontaneously giving rise to an ordered one-dimensional arrangement of nucleobase nanostructures.

Published

2020

41. Effective Cellular Delivery of Antisense Peptide Nucleic Acid by Conjugation to Guanidinylated Diaminobutanoic Acid-Based Peptide Dendrons.

Author

Gabas IM and Nielsen PE

Subjects

Aminobutyrates chemistry, Cell-Penetrating Peptides administration & dosage, HeLa Cells, Humans, Luciferases genetics, Oligonucleotides, Antisense administration & dosage, Oligonucleotides, Antisense chemistry, Oligonucleotides, Antisense pharmacology, Peptide Nucleic Acids pharmacology, Solid-Phase Synthesis Techniques methods, Structure-Activity Relationship, Dendrimers chemistry, Peptide Nucleic Acids administration & dosage, Peptide Nucleic Acids chemistry

Abstract

A series of amino- and guanidino-terminating 3- and 4-generation 2,4-diaminobutanoic acid (Dab) dendrons have been robustly synthesized on a solid phase and characterized as cellular delivery agents in antisense peptide nucleic acid (PNA) conjugates in the pLuc705 HeLa cell splice switching system. The dendron-PNA conjugates exhibited splice correction activity at one digit micromolar concentrations, and guanidino-terminating dendrons were significantly more effective than analogous amine terminating ones. Furthermore, introduction of lipophilic groups such as phenyl, alkyl, or fatty acids increased efficacy, but also increased cellular toxicity. Fluorescence microscopy analyses supported an endosomal uptake mechanism and furthermore predominantly showed colocalization with late endosomes and lysosomes. The robust solid phase synthesis should make such Dab-dendrons a useful platform for further in vitro as well as in vivo optimization.

Published

2020

42. Heterochiral DNA Strand-Displacement Based on Chimeric d/l-Oligonucleotides.

Author

Young BE and Sczepanski JT

Subjects

Peptide Nucleic Acids chemistry, DNA chemistry, Oligonucleotides chemistry

Abstract

Heterochiral DNA strand-displacement reactions enable sequence-specific interfacing of oligonucleotide enantiomers, making it possible to interface native d-nucleic acids with molecular circuits built using nuclease-resistant l-DNA. To date, all heterochiral reactions have relied on peptide nucleic acid (PNA), which places potential limits on the scope and utility of this approach. Herein, we now report heterochiral strand-displacement in the absence of PNA, instead utilizing chimeric d/l-DNA complexes to interface oligonucleotides of the opposite chirality. We show that these strand-displacement reactions can be easily integrated into multicomponent heterochiral circuits, are compatible with both DNA and RNA inputs, and can be engineered to function in serum-supplemented medium. We anticipate that these new reactions will lead to a wider application of heterochiral strand-displacement, especially in the design of biocompatible nucleic acid circuits that can reliably operate within living systems.

Published

2019

43. Bilingual Peptide Nucleic Acids: Encoding the Languages of Nucleic Acids and Proteins in a Single Self-Assembling Biopolymer.

Author

Swenson CS, Velusamy A, Argueta-Gonzalez HS, and Heemstra JM

Subjects

Base Sequence, Genetic Code, Nucleic Acid Conformation, Nucleic Acid Hybridization, Nucleic Acids chemical synthesis, Nucleic Acids chemistry, Peptide Nucleic Acids chemical synthesis, Peptide Nucleic Acids chemistry, Surface-Active Agents chemical synthesis, Surface-Active Agents chemistry, Nucleic Acids genetics, Peptide Nucleic Acids genetics, Proteins genetics

Abstract

Nucleic acids and proteins are the fundamental biopolymers that support all life on Earth. Nucleic acids store large amounts of information in nucleobase sequences while peptides and proteins utilize diverse amino acid functional groups to adopt complex structures and perform wide-ranging activities. Although nature has evolved machinery to read the nucleic acid code and translate it into amino acid code, the extant biopolymers are restricted to encoding amino acid or nucleotide sequences separately, limiting their potential applications in medicine and biotechnology. Here we describe the design, synthesis, and stimuli-responsive assembly behavior of a bilingual biopolymer that integrates both amino acid and nucleobase sequences into a single peptide nucleic acid (PNA) scaffold to enable tunable storage and retrieval of tertiary structural behavior and programmable molecular recognition capabilities. Incorporation of a defined sequence of amino acid side-chains along the PNA backbone yields amphiphiles having a "protein code" that directs self-assembly into micellar architectures in aqueous conditions. However, these amphiphiles also carry a "nucleotide code" such that subsequent introduction of a complementary RNA strand induces a sequence-specific disruption of assemblies through hybridization. Together, these properties establish bilingual PNA as a powerful biopolymer that combines two information systems to harness structural responsiveness and sequence recognition. The PNA scaffold and our synthetic system are highly generalizable, enabling fabrication of a wide array of user-defined peptide and nucleotide sequence combinations for diverse future biomedical and nanotechnology applications.

Published

2019

44. Deep-Red Light-up Signaling of Benzo[ c , d ]indole-Quinoline Monomethine Cyanine for Imaging of Nucleolar RNA in Living Cells and for Sequence-Selective RNA Analysis.

Author

Yoshino Y, Sato Y, and Nishizawa S

Subjects

Cell Nucleus chemistry, Cell Survival, Humans, MCF-7 Cells, Optical Imaging methods, Peptide Nucleic Acids chemistry, Sequence Analysis, RNA, Carbocyanines chemistry, Fluorescent Dyes chemistry, Indoles chemistry, Quinolines chemistry, RNA analysis

Abstract

RNA-binding small probes with deep-red emission are promising for RNA analysis in biological media without suffering from background fluorescence. Here benzo[ c , d ]indole-quinoline (BIQ), an asymmetric monomethine cyanine analogue, was newly developed as a novel RNA-selective probe with light-up signaling ability in the deep-red spectral range. BIQ features a significant light-up response (105-fold) with an emission maximum at 657 nm as well as improved photostability over the commercially available RNA-selective probe, SYTO RNA select. BIQ was successfully applied to the fluorescence imaging of nucleolar RNAs in living cells with negligible cytotoxicity. Furthermore, we found the useful ability of BIQ as a base surrogate integrated in peptide nucleic acid (PNA) oligonucleotides for RNA sequence analysis. BIQ base surrogate functioned as a deep-red light-up base surrogate in forced intercalation (FIT) and triplex-forming FIT (tFIT) systems for the sequence-selective detection of single-stranded and double-stranded RNAs, respectively.

Published

2019

45. Molecular Dynamics Study of the Hybridization between RNA and Modified Oligonucleotides.

Author

Jing Z, Qi R, Thibonnier M, and Ren P

Subjects

MicroRNAs chemistry, MicroRNAs metabolism, Nucleic Acid Conformation, Nucleic Acid Hybridization, Oligonucleotides metabolism, Peptide Nucleic Acids chemistry, Peptide Nucleic Acids metabolism, Quantum Theory, RNA metabolism, Thermodynamics, Molecular Dynamics Simulation, Oligonucleotides chemistry, RNA chemistry

Abstract

MicroRNAs (miRNAs) are attractive drug candidates for many diseases as they can modulate the expression of gene networks. Recently, we discovered that DNAs targeting microRNA-22-3p (miR-22-3p) hold the potential for treating obesity and related metabolic disorders (type 2 diabetes mellitus, hyperlipidemia, and nonalcoholic fatty liver disease (NAFLD)) by turning fat-storing white adipocytes into fat-burning adipocytes. In this work, we explored the effects of chemical modifications, including phosphorothioate (PS), locked nucleic acid (LNA), and peptide nucleic acid (PNA), on the structure and energy of DNA analogs by using molecular dynamics (MD) simulations. To achieve a reliable prediction of the hybridization free energy, the AMOEBA polarizable force field and the free energy perturbation technique were employed. The calculated hybridization free energies are generally compatible with previous experiments. For LNA and PNA, the enhanced duplex stability can be explained by the preorganization mechanism, i.e., the single strands adopt stable helical structures similar to those in the duplex. For PS, the S and R isomers (Sp and Rp) have preferences for C2'-endo and C3'-endo sugar puckering conformations, respectively, and therefore Sp is less stable than Rp in DNA/RNA hybrids. In addition, the solvation penalty of Rp accounts for its destabilization effect. PS-LNA is similar to LNA as the sugar puckering is dominated by the locked sugar ring. This work demonstrated that MD simulations with polarizable force fields are useful for the understanding and design of modified nucleic acids.

Published

2019

46. Synthesis and RNA-Binding Properties of Extended Nucleobases for Triplex-Forming Peptide Nucleic Acids.

Author

Kumpina I, Brodyagin N, MacKay JA, Kennedy SD, Katkevics M, and Rozners E

Subjects

Chemistry Techniques, Synthetic, Hydrogen Bonding, Models, Molecular, Nucleic Acid Conformation, Peptide Nucleic Acids metabolism, Peptide Nucleic Acids chemical synthesis, Peptide Nucleic Acids chemistry, RNA metabolism

Abstract

Triple-helix formation, using Hoogsteen hydrogen bonding of triplex-forming oligonucleotides, represents an attractive method for sequence-specific recognition of double-stranded nucleic acids. However, practical applications using triple-helix-forming oligonucleotides and their analogues are limited to long homopurine sequences. The key problem for recognition of pyrimidines is that they present only one hydrogen-bond acceptor or donor group in the major groove. Herein, we report our first attempt to overcome this problem by using peptide nucleic acids (PNAs) modified with extended nucleobases that form three hydrogen bonds along the entire Hoogsteen edge of the Watson-Crick base pair. New nucleobase triples (five) were designed, and their hydrogen bonding feasibility was confirmed by ab initio calculations. PNA monomers carrying the modified nucleobases were synthesized and incorporated in short model PNA sequences. Isothermal titration calorimetry showed that these nucleobases had a modest binding affinity for their double-stranded RNA (dsRNA) targets. Finally, molecular modeling of the modified triples in PNA-dsRNA helix suggested that the modest binding affinity was caused by subtle structural deviations from ideal hydrogen-bonding arrangements or disrupted π-stacking of the extended nucleobase scaffolds.

Published

2019

47. Synergy of Peptide-Nucleic Acid and Spherical Nucleic Acid Enabled Quantitative and Specific Detection of Tumor Exosomal MicroRNA.

Author

Liu L, Lu H, Shi R, Peng XX, Xiang Q, Wang B, Wan QQ, Sun Y, Yang F, and Zhang GJ

Subjects

Cell Line, Tumor, Gold chemistry, Humans, Limit of Detection, Metal Nanoparticles chemistry, MicroRNAs genetics, Nucleic Acid Hybridization, Peptide Nucleic Acids genetics, Electrochemical Techniques methods, Exosomes chemistry, MicroRNAs blood, Peptide Nucleic Acids chemistry

Abstract

Exosomal microRNAs are essential in intercellular communications and disease progression, yet it remains challenging to quantify the expression level due to their small size and low abundance in blood. Here, we report a "sandwich" electrochemical exosomal microRNA sensor (SEEmiR) to detect target microRNA with high sensitivity and specificity. In SEEmiR, neutrally charged peptide nucleic acid (PNA) enables kinetically favorable hybridization with the microRNA target relative to negatively charged DNA, particularly in a short sequence (10 nt). More importantly, this property allows PNA to cooperate with a spherical nucleic acid (SNA) nanoprobe that heavily loads with oligonucleotide-adsorbed electroactive tags to enhance detection sensitivity and specificity. Such a PNA-microRNA-SNA sandwich construct is able to minimize the background noise via PNA, thereby maximizing the SNA-mediated signal amplification in electrostatic adsorption-based SEEmiR. The synergy between PNA and SNA makes the SEEmiR sensor able to achieve a broad dynamic range (from 100 aM to 1 nM) with a detection limit down to 49 aM (2 orders of magnitude lower than that without SNA) and capable of distinguishing a single-base mismatch. This ultrasensitive sensor provides label-free and enzyme-independent microRNA detection in cell lysates, unpurified tumor exosomal lysates, cancer patients' blood, and accurately differentiates the patients with breast cancer from the healthy ones, suggesting its potential as a promising tool in cancer diagnostics.

Published

2019

48. Thermal Stability of Peptide Nucleic Acid Complexes.

Author

Jasiński M, Miszkiewicz J, Feig M, and Trylska J

Subjects

Base Pairing, Base Sequence, Peptide Nucleic Acids genetics, Molecular Dynamics Simulation, Peptide Nucleic Acids chemistry, Temperature

Abstract

Peptide nucleic acid (PNA) is a neutral nucleic acid analogue that base pairs with itself and natural nucleic acids. PNA-nucleic acid complexes are more thermally stable than the corresponding complexes of natural nucleic acids. In addition, PNA is biostable and thus used in many antisense and antigene applications to block functional RNA or DNA via sequence-specific interactions. We have recently developed force field parameters for molecular dynamics (MD) simulations of PNA and PNA-involving duplexes with natural nucleic acids. In this work, we provide the first application of this force field to biologically relevant PNA sequences and their complexes with RNA. We investigated thermal stabilities of short PNA-PNA, PNA-RNA, and RNA-RNA duplexes using UV-monitored thermal denaturation experiments and MD simulations at ambient and elevated temperatures. The simulations show a two-state melting transition and reproduce the thermal stability from melting experiments, with PNA-PNA being the most and RNA-RNA the least stable. The PNA-PNA duplex also displays the highest activation energy for melting. The atomistic details of unfolding of PNA duplexes suggest that all PNA-PNA bases melt concomitantly, whereas the RNA-RNA and PNA-RNA are destabilized from the termini toward the central part of the duplexes.

Published

2019

49. Incorporating G-C Pair-Recognizing Guanidinium into PNAs for Sequence and Structure Specific Recognition of dsRNAs over dsDNAs and ssRNAs.

Author

Krishna MS, Wang Z, Zheng L, Bowry J, Ong AAL, Mu Y, Prabakaran M, and Chen G

Subjects

Animals, Base Pairing, Biological Transport, DNA genetics, HIV-1 chemistry, Hydrogen Bonding, Hydrogen-Ion Concentration, Models, Molecular, Nucleic Acid Conformation, Orthomyxoviridae chemistry, Peptide Nucleic Acids chemistry, Peptide Nucleic Acids genetics, RNA, Double-Stranded genetics, RNA, Viral genetics, RNA, Viral metabolism, Spodoptera chemistry, DNA metabolism, Guanidines chemistry, Peptide Nucleic Acids metabolism, RNA, Double-Stranded metabolism

Abstract

Recognition of RNAs under physiological conditions is important for the development of chemical probes and therapeutic ligands. Nucleobase-modified dsRNA-binding PNAs (dbPNAs) are promising for the recognition of dsRNAs in a sequence and structure specific manner under near-physiological conditions. Guanidinium is often present in proteins and small molecules for the recognition of G bases in nucleic acids, in cell-penetrating carriers, and in bioactive drug molecules, which might be due to the fact that guanidinium is amphiphilic and has unique hydrogen bonding and stacking properties. We hypothesized that a simple guanidinium moiety can be directly incorporated into PNAs to facilitate enhanced molecular recognition of G-C pairs in dsRNAs and improved bioactivity. We grafted a guanidinium moiety directly into a PNA monomer (designated as R) using a two-carbon linker as guided by computational modeling studies. The synthetic scheme of the PNA R monomer is relatively simple compared to that of the previously reported L monomer. We incorporated the R residue into various dbPNAs for binding studies. dbPNAs incorporated with R residues are excellent in sequence specifically recognizing G-C pairs in dsRNAs over dsDNA and ssRNAs. We demonstrated that the R residue is compatible with unmodified T and C and previously developed modified L and Q residues in dbPNAs for targeting model dsRNAs, the influenza A viral panhandle duplex structure, and the HIV-1 frameshift site RNA hairpin. Furthermore, R residues enhance the cellular uptake of PNAs.

Published

2019

50. Incorporating 2-Thiouracil into Short Double-Stranded RNA-Binding Peptide Nucleic Acids for Enhanced Recognition of A-U Pairs and for Targeting a MicroRNA Hairpin Precursor.

Author

Ong AAL, Toh DK, Krishna MS, Patil KM, Okamura K, and Chen G

Subjects

Base Sequence, Peptide Nucleic Acids chemistry, Uric Acid metabolism, Inverted Repeat Sequences, MicroRNAs genetics, Peptide Nucleic Acids metabolism, Uric Acid analogs & derivatives

Abstract

Chemically modified short peptide nucleic acids (PNAs) recognize RNA duplexes under near physiological conditions by major-groove PNA·RNA-RNA triplex formation and show great promise for the development of RNA-targeting probes and therapeutics. Thymine (T) and uracil (U) are often incorporated into PNAs to recognize A-U pairs through major-groove T·A-U and U·A-U base triple formation. Incorporation of a modified nucleobase, 2-thiouracil (s 2 U), into triplex-forming oligonucleotides stabilizes both DNA and RNA triplexes. Thiolation of uracil causes a decrease in the dehydration energy penalty for triplex formation as well as a decrease in the p K a of the N3 atom, which may result in improved hydrogen bonding in addition to enhanced base stacking interactions, similar to the previously reported thiolation effect of pseudoisocytosine (J to L substitution). Here, we incorporated s 2 U into short PNAs, followed by binding studies of a series of s 2 U-modified PNAs. We demonstrated by nondenaturing polyacrylamide gel electrophoresis and thermal melting experiments that s 2 U and L incorporated into dsRNA-binding PNAs (dbPNAs) enhance the recognition of A-U and G-C pairs, respectively, in RNA duplexes in a position-independent manner, with no appreciable binding to the DNA duplex. Combining s 2 U and L modifications in dbPNAs facilitates enhanced recognition of dsRNAs and maintains selective binding to dsRNAs over ssRNAs. We further demonstrated through a cell-free assay the application of the s 2 U- and L-modified dbPNAs (8-mer, with a molecular mass of ∼2.3 kDa) in the inhibition of the pre-microRNA-198 maturation in a substrate-specific manner. Thus, s 2 U-modified dbPNAs may be generally useful for the enhanced and selective recognition of RNA duplexes and for the regulation of RNA functions.

Published

2019