Mismatch Discrimination Research Articles

7-Deazapurine and Pyrimidine Nucleoside and Oligonucleotide Cycloadducts Formed by Inverse Diels-Alder Reactions with 3,6-Di(pyrid-2-yl)-1,2,4,5-tetrazine: Ethynylated and Vinylated Nucleobases for Functionalization and Impact of Pyridazine Adducts on DNA Base Pair Stability and Mismatch Discrimination.

The manuscript reports on 7-deazapurine and pyrimidine nucleoside and oligonucleotide cycloadducts formed by the inverse electron demand Diels-Alder (iEDDA) reaction with 3,6-di(pyrid-2-yl)-1,2,4,5-tetrazine. Cycloadducts were constructed from ethynylated and vinylated nucleobases. Oligonucleotides were synthesized containing iEDDA modifications, and the impact on duplex stability was investigated. iEDDA reactions were performed on nucleoside triple bond side chains. Oxidation was not required in these cases as dihydropyridazine intermediates are not formed. In contrast, oxidation is necessary for reactions performed on alkenyl compounds. This was verified on 5-vinyl-2'-deoxyuridine. A diastereomeric mixture of 1,2-dihydropyridazine cycloadduct intermediates was isolated, characterized, and later oxidized. 12-mer oligonucleotides containing 1,2-pyridazine inverse Diels-Alder cycloadducts and their precursors were hybridized to short DNA duplexes. For that, a series of phosphoramidites was prepared. DNA duplexes with 7-functionalized 7-deazaadenines and 5-functionalized pyrimidines display high duplex stability when spacer units are present between nucleobases and pyridazine cycloadducts. A direct connectivity of the pyridazine moiety to nucleobases as reported for metabolic labeling of vinyl nucleosides reduced duplex stability strongly. Oligonucleotides bearing linkers with and without pyridazine cycloadducts attached to the 7-deazaadenine nucleobase significantly reduced mismatch formation with dC and dG.

Rationally Designed Dual Base Pair Mismatch Enables Toehold-Mediated Strand Displacement to Efficiently Recognize Single-Nucleotide Polymorphism without Enzymes.

The efficiency of the enzyme-free toehold-mediated strand displacement (TMSD) technique is often insufficient to detect single-nucleotide polymorphism (SNP) that possesses only single base pair mismatch discrimination. Here, we report a novel dual base pair mismatch strategy enabling TMSD biosensing for SNP detection under enzyme-free conditions when coupled with catalytic hairpin assembly (CHA) and fluorescence resonance energy transfer (FRET). The strategy is based on a competitive strand displacement reaction mechanism, affected by the thermodynamic stability originating from rationally designed dual base pair mismatch, for the specific recognition of mutant-type DNA. In particular, enzyme-free nucleic acid circuits, such as CHA, emerge as a powerful method for signal amplification. Eventually, the signal transduction of this proposed biosensor was determined by FRET between streptavidin-coated 605 nm emission quantum dots (605QDs, donor) and Cy5/biotin hybridization (acceptor, from CHA) when incubated with each other. The proposed biosensor displayed high sensitivity to the mutant target (MT) with a detection concentration down to 4.3 fM and led to high discrimination factors for all types of mismatches in multiple sequence contexts. As such, the application of this proposed biosensor to investigate mechanisms of the competitive strand displacement reaction further illustrates the versatility of our dual base pair mismatch strategy, which can be utilized for the creation of a new class of biosensors.

Watson-Crick Base Pairs with Protecting Groups: The 2-Amino Groups of Purine- and 7-Deazapurine-2,6-Diamine as Target Sites for DNA Functionalization by Selective Nucleobase Acylation.

The recognition of Watson-Crick base pairs carrying nucleobase protecting groups is reported as a new approach for DNA functionalization. The 2-amino groups of purine- and 7-deazapurine-2,6-diamine 2'-deoxyribonucleosides served as molecular targets for this functionalization. The 2-amino group withstands oligonucleotide deprotection with ammonia, whereas all other protecting groups are released after chemical DNA synthesis. On this basis, a method was developed for the selective functionalization of oligonucleotides at the 2-position of purines and 7-deazapurines. Melting experiments and Tm values obtained from hybridization studies revealed that duplexes with protected (2-amino-dA) and (2-amino-7-deaza-dA)-dT base pairs are as stable as their nonprotected counterparts. Mismatch discrimination of protected purine- and 7-deazapurine-2,6-diamine DNA was superior to that of nonprotected DNA. Click functionalization in the minor groove of the DNA double helix became accessible via introduction of heptynoyl protecting groups bearing a terminal triple bond. Click reactions with pyrene azide validated the usability. DNA conjugates with bulky pyrene residues at the 2-position (minor groove) developed the same high stability as those functionalized at the 7-position (major groove). This demonstrates the potential of our new method using protected base pairs for DNA functionalization and paves the way for new DNA labeling strategies.

Fabrication of on-bead functional nucleic acid nanowires based on cyclic ligation reaction-driven rolling circle amplification for label-free detection of long noncoding RNAs in breast and lung tissues

Long noncoding RNAs (lncRNAs) act as the essential regulators in various biological processes, and are becoming potential diagnostic and prognostic biomarkers. Herein, we demonstrate the fabrication of on-bead functional nucleic acid nanowires based on cyclic ligation reaction-driven rolling circle amplification for label-free detection of long noncoding RNAs in breast and lung tissues. The presence of lncRNA activates the cyclic ligation reaction, converting low-abundance target to numerous biotinylated ligation products through repetitive denaturation-hybridization-ligation. The resulting ligation products immobilize on the magnetic bead to initiate the downstream rolling circle amplification (RCA), facilitating the synthesis of long G-quadruplex nanowires. The resultant nanowires can light up Thioflavin T (ThT) to generate a high fluorescence signal. This method displays ultrahigh sensitivity with a limit of detection of 9.97 aM, and it possesses excellent single-base mismatch discrimination capability. Moreover, it can accurately quantify cellular Homeobox (HOX) gene antisense intergenic RNA (HOTAIR) at single-cell level and distinguish the HOTAIR expression level in healthy person and lung/breast cancer patient tissues, holding great promise in clinical diagnosis.

Skill Mismatch, Nepotism, Job Satisfaction, and Young Females in the MENA Region

Skills utilization is an important factor affecting labor productivity and job satisfaction. This paper examines the effects of skills mismatch, nepotism, and gender discrimination on wages and job satisfaction in MENA workplaces. Gender discrimination implies social costs for firms due to higher turnover rates and lower retention levels. Young females suffer disproportionality from this than their male counterparts, resulting in a wider gender gap in the labor market at multiple levels. Therefore, we find that the skill mismatch problem appears to be more significant among specific demographic groups, such as females, immigrants, and ethnic minorities; it is also negatively correlated with job satisfaction and wages. We bridge the literature gap on youth skill mismatch’s main determinants, including nepotism, by showing evidence from some developing countries. Given the implied social costs associated with these practices and their impact on the labor market, we have compiled a list of policy recommendations that the government and relevant stakeholders should take to reduce these problems in the workplace. Therefore, we provide a guide to address MENA’s skill mismatch and improve overall job satisfaction.

Revealing an initiation inhibition of RCA and its application in nucleic acid detection.

Rolling circle amplification is a widely used biosensing technique. Although various secondary structures have been employed in RCA, their effects on RCA efficiency have seldom been reported. Here, we find that stems in circular templates can strongly inhibit RCA, and the primer-stem distance is responsible for the inhibition. Based on the results, we propose an initiation inhibition mechanism and present a design principle for a general RCA assay. Inspired by this mechanism, we further propose a new nucleic acid detection method. The results verify that this method can increase RCA detection sensitivity according to the target recycling principle. Besides DNA detection, it can also achieve single mismatch discrimination of miRNA detection after optimization. This method also shows convenient visualization detection. The initiation inhibition of RCA could be helpful for RCA applications as promising detection techniques.

Profiling DNA Ligase Substrate Specificity with a Pacific Biosciences Single-Molecule Real-Time Sequencing Assay.

DNA ligases catalyze the joining of breaks in nucleic acid backbones and are essential enzymes for in vivo genome replication and repair across all domains of life. These enzymes are also critically important to in vitro manipulation of DNA in applications such as cloning, sequencing, and molecular diagnostics. DNA ligases generally catalyze the formation of a phosphodiester bond between an adjacent 5'-phosphate and 3'-hydroxyl in DNA, but they exhibit different substrate structure preferences, sequence-dependent biases in reaction kinetics, and variable tolerance for mismatched base pairs. Information on substrate structure and sequence specificity can inform both biological roles and molecular biology applications of these enzymes. Given the high complexity of DNA sequence space, testing DNA ligase substrate specificity on individual nucleic acid sequences in parallel rapidly becomes impractical when a large sequence space is investigated. Here, we describe methods for investigating DNA ligase sequence bias and mismatch discrimination using Pacific Biosciences Single-Molecule Real-Time (PacBio SMRT) sequencing technology. Through its rolling-circle amplification methodology, SMRT sequencing can give multiple reads of the same insert. This feature permits high-quality top- and bottom-strand consensus sequences to be determined while preserving information on top-bottom strand mismatches that can be obfuscated or lost when using other sequencing methods. Thus, PacBio SMRT sequencing is uniquely suited to measuring substrate bias and enzyme fidelity through multiplexing a diverse set of sequences in a single reaction. The protocols describe substrate synthesis, library preparation, and data analysis methods suitable for measuring fidelity and bias of DNA ligases. The methods are easily adapted to different nucleic acid substrate structures and can be used to characterize many enzymes under a variety of reaction conditions and sequence contexts in a rapid and high-throughput manner. © 2023 New England Biolabs and The Authors. Current Protocols published by Wiley Periodicals LLC. Basic Protocol 1: Preparation of overhang DNA substrates for ligation Basic Protocol 2: Preparation of ligation fidelity libraries Support Protocol 1: Preparation of ligation libraries for PacBio Sequel II sequencing Support Protocol 2: Loading and sequencing of a prepared library on the Sequel II instrument Basic Protocol 3: Computational processing of ligase fidelity sequencing data.

A programmable CRISPR/Cas12a-mediated hyperbranched hybridization chain reaction for ultrasensitive sensing of Mycobacterium bovis

Mycobacterium bovis results in a serious threat to domestic animal species, wildlife, and humans. Therefore, a novel colorimetric sensor with high sensitivity and specificity was developed for diagnosing Mycobacterium bovis by combining CRISPR/Cas12a with hyperbranched hybridization chain reaction (HB-HCR). In the presence of target DNA, the active Cas12a protein endowed with trans-cleavage activity showed its role in scgRNA. Thus, an auto-catalytic circuit was formed after the released gRNA molecules were converted to form additional active Cas12a effectors. Simultaneously, the released RNA initiator was used to trigger a cascade of HB-HCR events integrated G-quadruplex. Further, the rather low abundance of target could be observed with naked eyes when Hemin, H2O2 and ABTS were added. The results revealed that the limit of detecting Mycobacterium bovis target was 8.9 aM with single-nucleotide mismatch discrimination. Furthermore, the practical application of our designed colorimetric sensor for detecting Mycobacterium bovis performed by the standard addition method, the recovery ranged from 95.7% and 108.9% and the relative standard deviations (RSD) ranged from 1.2% and 2.8%, opened up a new avenue for highly sensitive and specific diagnosis of Mycobacterium bovis in real biological samples.

Alteration of target cleavage patterns and off-target reduction of antisense oligonucleotides incorporating 2-N-carbamoyl- or (2-pyridyl)guanine.

Antisense oligonucleotides (ASOs) are therapeutic modalities that are successfully used as pharmaceuticals. However, there remains a concern that treatment with ASOs may cleave mismatched RNAs other than the target gene, leading to numerous alterations in gene expression. Therefore, improving the selectivity of ASOs is of paramount importance. Our group has focused on the fact that guanine forms stable mismatched base pairs and has developed guanine derivatives with modifications at the 2-amino group, which potentially change the mismatch recognition ability of guanine and the interaction between ASO and RNase H. In this study, we evaluated the properties of ASOs containing two guanine derivatives, 2-N-carbamoyl-guanine and 2-N-(2-pyridyl)guanine. We conducted ultraviolet (UV) melting experiments, RNase H cleavage assays, in vitro knockdown assays, and off-target transcriptome analyses using DNA microarrays. Our results indicate that the target cleavage pattern of RNase H was altered by the modification with guanine. Furthermore, global transcript alteration was suppressed in ASO incorporating 2-N-(2-pyridyl)guanine, despite a decrease in the thermal mismatch discrimination ability. These findings suggest that chemical modifications of the guanine 2-amino group have the potential to suppress hybridization-dependent off-target effects and improve ASO selectivity.

Sensitive microRNA detection based on bimetallic label photothermal lateral flow locked nucleic acid biosensor with smartphone readout

Fast, convenient, and highly sensitive detection of microRNA (miRNA) is vital for the early diagnosis of diseases. Lateral flow biosensor (LFB) as microdevice has been used in rapid detection, however, the sensitivity is not satisfied for low-abundant miRNA detection, and short length of the miRNA requires high affinity detection probe. To address these issues, herein, we synthesized palladium-gold (Pd-Au) bimetallic nanoplates with high photothermal effect combined locked nucleic acid (LNA) detection probe to develop a photothermal lateral flow locked nucleic acid biosensor (P-LFLNAB) for miRNA detection. The P-LFLNAB enables sensitive and selective miRNA-21 detection with detection limit down to 0.094 pM using a smartphone with external thermal imager, which is 639.5 times lower than that of the conventional gold nanoparticles based colorimetric LFB and the most sensitive enzyme-free LFB for miRNA detection. Besides, the P-LFLNAB achieved single-base mismatch discrimination and can quantify signals in various cell lysates. This highly sensitive, selective and portable P-LFLNAB with smartphone readout has great potential in point-of-care test of miRNAs-related biomedical application.

A Programmable, DNA-Exclusively-Guided Argonaute DNase and Its Higher Cleavage Specificity Achieved by 5'-Hydroxylated Guide.

Argonaute proteins exist widely in eukaryotes and prokaryotes, and they are of great potential for molecular cloning, nucleic acid detection, DNA assembly, and gene editing. However, their overall properties are not satisfactory and hinder their broad applications. Herein, we investigated a prokaryotic Argonaute nuclease from a mesophilic bacterium Clostridium disporicum (CdAgo) and explored its overall properties, especially with 5′-hydroxylated (5′-OH) guides. We found that CdAgo can exclusively use single-stranded DNA (ssDNA) as guide to cleave ssDNA and plasmid targets. Further, we found the length of the efficient guide is narrower for the 5′-OH guide (17–20 nt) than for the 5′-phosphorylated guide (5′-P, 14–21 nt). Furthermore, we discovered that the 5′-OH guides can generally offer stronger mismatch discrimination than the 5′-P ones. The 5′-OH guides offer the narrower length range, higher mismatch discrimination and more accurate cleavage than the 5′-P guides. Therefore, 5′-OH-guide-directed CdAgo has great potential in biological and biomedical applications.

Modified Taq DNA Polymerase for Allele-Specific Ultra-Sensitive Detection of Genetic Variants

Allele-specific PCR (AS-PCR) has been used as a simple, cost-effective method for genotyping and gene mapping in research and clinical settings. AS-PCR permits the detection of single nucleotide variants and insertion or deletion variants owing to the selective extension of a perfectly matched primer (to the template DNA) over a mismatched primer. Thus, the mismatch discrimination power of the DNA polymerase is critical. Unfortunately, currently available polymerases often amplify some mismatched primer-template complexes as well as matched ones, obscuring AS detection. To increase mismatch discrimination, mutations were generated in the Thermus aquaticus (Taq) DNA polymerase, the most efficient variant was selected, and its performance evaluated in single nucleotide polymorphism and cancer mutation genotyping. In addition, the primer design and reaction buffer conditions were optimized for AS amplification. Our highly selective AS-PCR, which is based on an allele-discriminating priming system that leverages a Taq DNA polymerase variant with optimized primers and reaction buffer, can detect mutations with a mutant allele frequency as low as 0.01% in genomic DNA and 0.0001% in plasmid DNA. This method serves as a simple, fast, cost-effective, and ultra-sensitive way to detect single nucleotide variants and insertion or deletion mutations with low abundance.

Flexible Terahertz Metamaterial Biosensor for Ultra-Sensitive Detection of Hepatitis B Viral DNA Based on the Metal-Enhanced Sandwich Assay.

The high sensitivity and specificity of terahertz (THz) biosensing are both promising and challenging in DNA sample detection. This study produced and refined a flexible THz MM biosensor for ultrasensitive detection of HBV in clinical serum samples based on a gold magnetic nanoparticle-mediated rolling circle amplification (GMNPs@RCA) sandwich assay under isothermal conditions. Typically, solid-phase RCA reactions mediated by circular padlock probes (PLPs) are triggered under isothermal conditions in the presence of HBV DNA, resulting in long single-stranded DNA (ssDNA) with high fidelity and specificity. Then, the resultant ssDNA was conjugated with detection probes (DPs) immobilized on gold nanoparticles (DP@AuNPs) to form GMNPs-RCA-AuNPs sandwich complexes. The HBV DNA concentrations were quantified by introducing GMNPs-RCA-AuNPs complexes into the metasurface of a flexible THz metamaterial-based biosensor chip and resulting in a red shift of the resonance peak of the THz metamaterials. This biosensor can lead to highly specific and sensitive detection with one-base mismatch discrimination and a limit of detection (LOD) down to 1.27E + 02 IU/ml of HBV DNA from clinical serum samples. The HBV DNA concentration was linearly correlated with the frequency shift of the THz metamaterials within the range of 1.27E + 02∼1.27E + 07 IU/ml, illustrating the applicability and accuracy of our assay in real clinical samples. This strategy constitutes a promising THz sensing method to identify virus DNA. In the future, it is hoped it can assist with pathogen identification and clinical diagnosis.

Programming a DNA tetrahedral nanomachine as an integrative tool for intracellular microRNA biosensing and stimulus-unlocked target regulation.

The synchronous detection and regulation of microRNAs (miRNAs) are essential for the early tumor diagnosis and treatment but remains a challenge. An integrative DNA tetrahedral nanomachine was self-assembled for sensitive detection and negative feedback regulation of intracellular miRNAs. This nanomachine comprised a DNA tetrahedron nanostructure as the framework, and a miRNA inhibitor-controlled allosteric DNAzyme as the core. The DNA tetrahedron brought the DNAzyme and the substrate in spatial proximity and facilitated the cellular uptake of DNAzyme. In allosteric regulation of DNAzyme, the locked tetrahedral DNAzyme (L-tetra-D) and active tetrahedral DNAzyme (A-Tetra-D) were controlled by miRNA inhibitor. The combination of miRNA inhibitor and target could trigger the conformational change from L-tetra-D to A-Tetra-D. A-Tetra-D cleaved the substrate and released fluorescence for intracellular miRNA biosensing. The DNA tetrahedral nanomachine showed excellent sensitivity (with detection limit down to 0.77 pM), specificity (with one-base mismatch discrimination), biocompatibility and stability. Simultaneously, miRNA stimulus-unlocked inhibitor introduced by our nanomachine exhibited the synchronous regulation of target cells, of which regulatory performance has been verified by the upregulated levels of downstream genes/proteins and the increased cellular apoptosis. Our study demonstrated that the DNA tetrahedral nanomachine is a promising biosense-and-treat tool for the synchronous detection and regulation of intracellular miRNA, and is expected to be applied in the early diagnosis and tailored management of cancers.

XNAs: A Troubleshooter for Nucleic Acid Sensing.

The strategies for nucleic acid sensing based on nucleic acid hybridization between the target sequence and the capture probe sequence are considered to be largely successful as far as detection of a specific target of known sequence is concerned. However, when compared with other complementary methods, like direct sequencing, a number of results are still found to be either “false positives” or “false negatives”. This suggests that modifications in these strategies are necessary to make them more accurate. In this minireview, we propose that one way toward improvement could be replacement of the DNA capture probes with the xeno nucleic acid or XNA capture probes. This is because the XNAs, especially the locked nucleic acid, the peptide nucleic acid, and the morpholino, have shown better single nucleobase mismatch discrimination capacity than the DNA capture probes, indicating their capacity for more precise detection of nucleic acid sequences, which is beneficial for detection of gene stretches having point mutations. Keeping the current trend in mind, this minireview will include the recent developments in nanoscale, fluorescent label-free applications, and present the cases where the XNA probes show clear advantages over the DNA probes.

Mismatch discrimination and sequence bias during end-joining by DNA ligases.

DNA ligases, critical enzymes for in vivo genome maintenance and modern molecular biology, catalyze the joining of adjacent 3′-OH and 5′-phosphorylated ends in DNA. To determine whether DNA annealing equilibria or properties intrinsic to the DNA ligase enzyme impact end-joining ligation outcomes, we used a highly multiplexed, sequencing-based assay to profile mismatch discrimination and sequence bias for several ligases capable of efficient end-joining. Our data reveal a spectrum of fidelity and bias, influenced by both the strength of overhang annealing as well as sequence preferences and mismatch tolerances that vary both in degree and kind between ligases. For example, while T7 DNA ligase shows a strong preference for ligating high GC sequences, other ligases show little GC-dependent bias, with human DNA Ligase 3 showing almost none. Similarly, mismatch tolerance varies widely among ligases, and while all ligases tested were most permissive of G:T mismatches, some ligases also tolerated bulkier purine:purine mismatches. These comprehensive fidelity and bias profiles provide insight into the biology of end-joining reactions and highlight the importance of ligase choice in application design.

Site-Specific Synthesis of N4-Acetylcytidine in RNA Reveals Physiological Duplex Stabilization.

N4-Acetylcytidine (ac4C) is a post-transcriptional modification of RNA that is conserved across all domains of life. All characterized sites of ac4C in eukaryotic RNA occur in the central nucleotide of a 5'-CCG-3' consensus sequence. However, the thermodynamic consequences of cytidine acetylation in this context have never been assessed due to its challenging synthesis. Here, we report the synthesis and biophysical characterization of ac4C in its endogenous eukaryotic sequence context. First, we develop a synthetic route to homogeneous RNAs containing electrophilic acetyl groups. Next, we use thermal denaturation to interrogate the biochemical effects of ac4C on duplex stability and mismatch discrimination in a native sequence found in human rRNA. Finally, we demonstrate the ability of this chemistry to incorporate ac4C into the complex modification landscape of human tRNA and use duplex melting to highlight an enforcing role for ac4C in this unique sequence context. By enabling ex vivo biophysical analyses of nucleic acid acetylation in its physiological sequence context, these studies establish a chemical foundation for understanding the function of a universally conserved nucleobase in biology and disease.

High-fidelity KKH variant of Staphylococcus aureus Cas9 nucleases with improved base mismatch discrimination.

The Cas9 nuclease from Staphylococcus aureus (SaCas9) holds great potential for use in gene therapy, and variants with increased fidelity have been engineered. However, we find that existing variants have not reached the greatest accuracy to discriminate base mismatches and exhibited much reduced activity when their mutations were grafted onto the KKH mutant of SaCas9 for editing an expanded set of DNA targets. We performed structure-guided combinatorial mutagenesis to re-engineer KKH-SaCas9 with enhanced accuracy. We uncover that introducing a Y239H mutation on KKH-SaCas9’s REC domain substantially reduces off-target edits while retaining high on-target activity when added to a set of mutations on REC and RuvC domains that lessen its interactions with the target DNA strand. The Y239H mutation is modelled to have removed an interaction from the REC domain with the guide RNA backbone in the guide RNA-DNA heteroduplex structure. We further confirmed the greatly improved genome-wide editing accuracy and single-base mismatch discrimination of our engineered variants, named KKH-SaCas9-SAV1 and SAV2, in human cells. In addition to generating broadly useful KKH-SaCas9 variants with unprecedented accuracy, our findings demonstrate the feasibility for multi-domain combinatorial mutagenesis on SaCas9’s DNA- and guide RNA- interacting residues to optimize its editing fidelity.

Comparative structural and dynamics study of free and gRNA-bound FnCas9 and SpCas9 proteins

The introduction of CRISPR/Cas9 based gene editing has greatly accelerated therapeutic genome editing. However, the off-target DNA cleavage by CRISPR/Cas9 protein hampers its clinical translation, hindering its widespread use as a programmable genome editing tool. Although Cas9 variants with better mismatch discrimination have been developed, they have significantly lower rates of on-target DNA cleavage. Here, we have compared the dynamics of a more specific naturally occurring Cas9 from Francisella novicida (FnCas9) to the most widely used, SpCas9 protein. Long-scale atomistic MD simulation of free and gRNA bound forms of both the Cas9 proteins was performed, and their domain rearrangements and binding affinity with gRNA were compared to decipher the possible reason behind the enhanced specificity of FnCas9 protein. The greater binding affinity with gRNA, high domain electrostatics, and more volatility of FnCas9 than SpCas9 may explain its increased specificity and lower tolerance for mismatches.

Molecularly resolved, label-free nucleic acid sensing at solid-liquid interface using non-ionic DNA analogues.

Nucleic acid-based biosensors, where the capture probe is a nucleic acid, e.g., DNA or its synthetic analogue xeno nucleic acid (XNA), offer interesting ways of eliciting clinically relevant information from hybridization/dehybridization signals. In this respect, the application of XNA probes is attractive since the drawbacks of DNA probes might be overcome. Within the XNA probe repertoire, peptide nucleic acid (PNA) and morpholino (MO) are promising since their backbones are non-ionic. Therefore, in the absence of electrostatic charge repulsion between the capture probe and the target nucleic acid, a stable duplex can be formed. In addition, these are nuclease-resistant probes. Herein, we have tested the molecularly resolved nucleic acid sensing capacity of PNA and MO capture probes using a fluorescent label-free single molecule force spectroscopy approach. As far as single nucleobase mismatch discrimination is concerned, both PNA and MO performed better than DNA, while the performance of the MO probe was the best. We propose that the conformationally more rigid backbone of MO, compared to the conformationally flexible PNA, is an advantage for MO, since the probe orientation can be made more upright on the surface and therefore MO can be more effectively accessed by the target sequences. The performance of the XNA probes has been compared to that of the DNA probe, using fixed nucleobase sequences, so that the effect of backbone variation could be investigated. To our knowledge, this is the first report on molecularly resolved nucleic acid sensing by non-ionic capture probes, here, MO and PNA.