So far, there has been no report on molecularly resolved discrimination of single nucleobase mismatches using surface-confined single stranded locked nucleic acid (ssLNA) probes. Herein, it is exemplified using a label-independent force-sensing approach that an optimal coverage of 12-mer ssLNA sensor probes formed onto gold(111) surface allows recognition of ssDNA targets with twice stronger force sensitivity than 12-mer ssDNA sensor probes. The force distributions are reproducible and the molecule-by-molecule force measurements are largely in agreement with ensemble on-surface melting temperature data. Importantly, the molecularly resolved detection is responsive to the presence of single nucleobase mismatches in target sequences. Since the labelling steps can be eliminated from protocol, and each force-based detection event occurs within milliseconds' time scale, the force-sensing assay is potentially capable of rapid detection. The LNA probe performance is indicative of versatility in terms of substrate choice - be it gold (for basic research and array-based applications) or silicon (for ‘lab-on-a-chip’ type devices). The nucleic acid microarray technologies could therefore be generally benefited by adopting the LNA films, in place of DNA. Since LNA is nuclease-resistant, unlike DNA, and the LNA-based assay is sensitive to single nucleobase mismatches, the possibilities for label-free in vitro rapid diagnostics based on the LNA probes may be explored.
Locked nucleic acid (LNA) is a conformationally restricted nucleic acid analogue, which is potentially a better alternative than DNA for application in the nucleic acid based biosensor technologies, due to its efficient and sequence-specific DNA/RNA detection capability and lack of molecule-surface interaction on solid surfaces, compared to DNA. We report, for the first time, a straightforward way (based on simple immersion method) of generating an ordered self-assembled LNA monolayer, which is bioactive, onto a gold(111) surface. This layer is capable of giving rise to a stronger DNA recognition signal (4-4.5 times) than its DNA counterpart, and importantly, it can differentiate between a fully complementary DNA target and that having a single base mismatch, where the mismatch discrimination ratio is almost two times compared to the ratio relevant in case of DNA-based detection. We have presented high-resolution atomic force microscopy (AFM) topographs of the well-defined one-dimensional LNA molecular ordering (few hundred nanometers long) and of the two-dimensional ordered assembly formed over a large area (7 μm × 7 μm) due to parallel positioning of the one-dimensional ordered arrangements. The effects of different parameters such as LNA concentration and incubation time on LNA self-assembly have been investigated. Further, reflection absorption infrared (RAIR) spectroscopy has been applied to obtain information about the orientation of the surface-immobilized LNA molecules for the first time. It has been found that the LNA molecules undergo an orientational transition from the "lying down" to the "upright" configuration in a time scale of few hours.
Several investigations on DNA-based nucleic acid sensors performed in the past few years point toward the requirement of an alternative nucleic acid that can detect target DNA strands more efficiently, i.e., with higher sensitivity and selectivity, and can be more robust compared to the DNA sensor probes. Locked nucleic acid (LNA), a conformationally restricted DNA analogue, is potentially a better alternative than DNA, since it is nuclease-resistant, it can form a more stable duplex with DNA in a sequence-specific manner, and it interacts less with substrate surface due to presence of a rigid backbone. In this work, we probed solid-phase dehybridization of ssDNA targets from densely packed fully modified ssLNA probes immobilized onto a gold(111) surface by fluorescence-based measurement of the "on-surface" melting temperatures. We find that mismatch discrimination can be clearly improved by applying the surface-tethered LNA probes, in comparison to the corresponding DNA probes. We show that concentration as well as type of cation (monovalent and polyvalent) can significantly influence thermal stability of the surface-confined LNA-DNA duplexes, the nature of concentration dependence contradicting the solution phase behavior. Since the ionic setting influenced the fully matched duplexes more strongly than the singly mismatched duplexes, the mismatch discrimination ability of the surface-confined LNA probes could be controlled by ionic modulations. To our knowledge, this is the first report on ionic regulation of melting behavior of surface-confined LNA-DNA duplexes.
Challenges in reliable nucleic acid detection are manifold. The major ones are related to false positive or negative signals due to a lack of target specificity in detection and to low sensitivity, especially when a plethora of background sequences are present that can mask the specific recognition signal. Utilizing designed synthetic nucleic acids that are commonly called xeno nucleic acids could offer potential routes to meeting such challenges. In this article, we present the general framework of nucleic acid detection, especially for nanoscale applications, and discuss how and why the xeno nucleic acids could be truly an alternative to the DNA probes. Two specific cases, locked nucleic acid (LNA) and peptide nucleic acid (PNA), which are nuclease-resistant and can form thermally stable duplexes with DNA, are addressed. It is shown that the relative ease of the conformationally rigid LNA probe to be oriented upright on the substrate surface and of the nonionic PNA probe to result into high probe density assists in their use in nanoscale nucleic acid recognition. It is anticipated that success with these probes may lead to important developments such as PCR-independent approaches where the major aim is to detect a small number of target sequences present in the analyte medium.
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