Molecular-beacon-based array for sensitive DNA analysis

A DNA biosensors-based microfluidic platform for attomolar real-time detection of unamplified SARS-CoV-2 virus

The emergence of the coronavirus 2019 (COVID-19) arose the need for rapid, accurate and massive virus detection methods to control the spread of infectious diseases. In this work, a device, deployable in non-medical environments, has been developed for the detection of non-amplified SARS-CoV-2 RNA. A SARS-CoV-2 specific probe was designed and covalently immobilized at the surface of glass slides to fabricate a DNA biosensor. The resulting system was integrated in a microfluidic platform, in which viral RNA was extracted from non-treated human saliva, before hybridizing at the surface of the sensor. The formed DNA/RNA duplex was detected in presence of SYBR Green I using an opto-electronic system, based on a high-power LED and a photo multiplier tube, which convert the emitted fluorescence into an electrical signal that can be processed in less than 10 min. The limit of detection of the resulting microfluidic platform reached six copies of viral RNA per microliter of sample (equal to 10 aM) and satisfied the safety margin. The absence of non-specific adsorption and the selectivity for SARS-CoV-2 RNA were established. In addition, the designed device could be applicable for the detection of a variety of viruses by simple modification of the immobilized probe.

Molecular elements: novel approaches for molecular building

Classically, a molecular element (ME) is a pure substance composed of two or more atoms of the same element. However, MEs, in the context of this review, can be any molecules as elements bonded together into the backbone of synthetic oligonucleotides (ONs) with designed sequences and functions, including natural A, T, C, G, U, and unnatural bases. The use of MEs can facilitate the synthesis of designer molecules and smart materials. In particular, we discuss the landmarks associated with DNA structure and related technologies, as well as the extensive application of ONs, the ideal type of molecules for intervention therapy aimed at correcting disease-causing genetic errors (indels). It is herein concluded that the discovery of ON therapeutics and the fabrication of designer molecules or nanostructures depend on the ME concept that we previously published. Accordingly, ME will be our focal point as we discuss related research directions and perspectives in making molecules and materials. This article is part of the theme issue 'Reactivity and mechanism in chemical and synthetic biology'.

Paving the way towards continuous biosensing by implementing affinity-based nanoswitches on state-dependent readout platforms

Combining affinity-based nanoswitches with state-dependent readout platforms allows for continuous biosensing and acquisition of real-time information about biochemical processes occurring in the environment of interest.

Evaluation of Rationally Designed Label-free Stem-loop DNA Probe Opening in the Presence of miR-21 by Circular Dichroism and Fluorescence Techniques

The characteristic features of stem-loop structured probes make them robust tools to detect targets with high sensitivity and selectivity. The basis of the hairpin based sensors operation is a conformational change that occurs upon hybridization of target with stem-loop probe. The design of the stem-loop probe has an important role in target recognition. Therefore, we designed a label-free stem loop probe for targeting miR-21 as a cancer biomarker investigated by web-based tools; its thermodynamic parameters obtained by thermal UV spectroscopy. The efficiency of stem-loop structure opening in the presence of target and non-target sequences was evaluated by fluorescence spectroscopy and circular dichroism spectro-polarimetry. The results showed that the target sequence opens the structure of hairpin efficiently in comparison to non-target sequences. To optimize the stem-loop hybridization to its target, the buffer ionic strength was changed by adding different concentrations of NaCl, KCl and MgCl₂. It was shown that buffering conditions have a significant role in loop structure opening and its optimization, led to an increase in sensitivity detection and have improved LOD from 60 pM to 45 pM.

Supramolecular Microgels with Molecular Beacons at the Interface for Ultrasensitive, Amplification-Free, and SNP-Selective miRNA Fluorescence Detection

In this study, a supramolecular structure with femtomolar biorecognition properties is proposed for use in analytical devices. It is obtained by an innovative interface between synthetic hydrogel polymers and molecular beacon (mb) probes. Supramolecularly structured microgels are synthetized with a core-shell architecture with specific dyes polymerized in a desired compartment. Mb probes are opportunely conjugated at the microgel interface so that their recognition mechanism is preserved and their spatial distribution is optimized to avoid crowding effects. The miR-21, a microRNA involved in various biological processes and usually used as a biomarker in early cancer diagnosis, has been selected as the target. The results demonstrate that by tuning the spatial distribution of molecular probes immobilized on the microgel and/or the amount of microgels, the assay shows scalable sensitivity reaching a limit of detection down to about 10 fM, without amplification steps and with detection time as short as 1 h. The assay results specific toward single mutated targets, and it is stable in the presence of high-interfering oligonucleotides concentrations. The miRNA target is also detected in human serum with performances similar to those observed in PBS buffer because of microgel antifouling properties without the need of any surface treatment. All tests were performed in a low sample volume (20 μL). As a result, mb-microgel represents an innovative biosensor to precisely quantify microRNAs in a direct (mix&read), scalable, and selective way. Such an approach paves the way for creating innovative biosensing interfaces with other probes, such as hairpins, aptamers, and PNA.

Quantitative Detection of miRNA-21 Expression in Tumor Cells and Tissues Based on Molecular Beacon

As a new tumor marker, the microRNA-21 (miRNA21) level can provide important information for early diagnosis, drug treatment, and prognosis of gastric cancer. With the tool of molecular beacons which can hybridize specifically with target miRNA-21 and generate fluorescence signal change, this paper develops a direct, simple, and rapid method for miRNA-21 detection with detection limit of 0.5 nM. Under the optimal conditions, the method was used to detect the expression of miRNA-21 in tumor cells and tissues. The results showed significant differences of miRNA-21 levels in tumor cells which have different origins and different degree of malignancy. In 8 cases of gastric cancer tissues and adjacent tissues, the level of miRNA-21 in 6 cases was higher than that in adjacent tissues, 1 case had lower expression level than that in adjacent tissues, and 1 case had no significant difference. Furthermore, qRT-PCR method was used to verify the detection results based on the fluorescent probe detection method. The consistent results show that the molecular beacon assay has a good prospect in direct and rapid detection of miRNA-21 expression and will be widely used in the functional research and clinical diagnosis of microRNA.

Design of Gaussia luciferase-based bioluminescent stem-loop probe for sensitive detection of HIV-1 nucleic acids

Here we describe the design of a bioluminescent stem-loop probe for the sensitive detection of HIV-1 spliced RNA. In this study, we employed Gaussia luciferase (GLuc), a bioluminescent protein that has several advantages over other bioluminescent proteins, including smaller size, higher bioluminescent intensity, and chemical and thermal stability. GLuc was chemically conjugated to the DABCYL-modified stem-loop probe (SLP) and was purified with a 2-step process to remove unconjugated GLuc and SLP. The binding of the target RNA to the loop region of the SLP results in the open conformation separating the stem part of SLP. GLuc conjugated to the stem acts as a reporter that produces light by a chemical reaction upon adding its substrate, coelenterazine in the presence of the target, while DABCYL serves as a quencher of bioluminescence in the closed conformation of SLP in the absence of the target. The optimized GLuc based-SLP assay resulted in a signal-to-background ratio of 47, which is the highest reported with bioluminescent SLPs and is significantly higher compared to traditional fluorescence-based SLPs that yield low signal to background ratio. Moreover, the assay showed an excellent selectivity against a single and double mismatched nucleic acid target, low detection limit, and ability to detect spiked HIV-1 RNA in human serum matrix.

Electronic Detection of DNA Hybridization by Coupling Organic Field-Effect Transistor-Based Sensors and Hairpin-Shaped Probes

In this paper, the electronic transduction of DNA hybridization is presented by coupling organic charge-modulated field-effect transistors (OCMFETs) and hairpin-shaped probes. These probes have shown interesting properties in terms of sensitivity and selectivity in other kinds of assays, in the form of molecular beacons (MBs). Their integration with organic-transistor based sensors, never explored before, paves the way to a new class of low-cost, easy-to-use, and portable genetic sensors with enhanced performances. Thanks to the peculiar characteristics of the employed sensor, measurements can be performed at relatively high ionic strengths, thus optimizing the probes’ functionality without affecting the detection ability of the device. A complete electrical characterization of the sensor is reported, including calibration with different target concentrations in the measurement environment and selectivity evaluation. In particular, DNA hybridization detection for target concentration as low as 100 pM is demonstrated.

A sandwich-like strategy for the label-free detection of oligonucleotides by surface plasmon fluorescence spectroscopy (SPFS)

Cutting surface-bound optical molecular beacons results in a sandwich-like detection strategy with lower background fluorescence.

For the detection of oligonucleotides a sandwich-like detection strategy has been developed by which the background fluorescence is significantly lowered in comparison with surface-bound molecular beacons. Surface bound optical molecular beacons are DNA hairpin structures comprising a stem and a loop. The end of the stem is modified with a fluorophore and a thiol anchor for chemisorption on gold surfaces. In the closed state the fluorophore is in close proximity to the gold surface, and most of the fluorescence is quenched. After hybridization with a target the hairpin opens, the fluorophore and surface become separated, and the fluorescence drastically increases. Using this detection method the sensitivity is limited by the difference in the fluorescence intensity in the closed and open state. As the background fluorescence is mainly caused by non-quenched fluorophores, a strategy to reduce the background fluorescence is to cut the beacon in two halves. First a thiolated ssDNA capture probe strand (first half) is chemisorbed to a gold surface together with relatively short thiol spacers. Next the target is hybridized by one end to the surface-anchored capture probe and by the other to a fluorophore-labeled reporter probe DNA (second half). The signal readout is done by surface plasmon fluorescence spectroscopy (SPFS). Using this detection strategy the background fluorescence can be significantly lowered, and the detection limit is lowered by more than one order of magnitude. The detection of a target takes only a few minutes and the sensor chips can be used for multiple detection steps without a significant decrease in performance.

A molecular beacon microarray based on a quantum dot label for detecting single nucleotide polymorphisms

In this work, we report the application of streptavidin-coated quantum dot (strAV-QD) in molecular beacon (MB) microarray assays by using the strAV-QD to label the immobilized MB, avoiding target labeling and meanwhile obviating the use of amplification. The MBs are stem-loop structured oligodeoxynucleotides, modified with a thiol and a biotin at two terminals of the stem. With the strAV-QD labeling an "opened" MB rather than a "closed" MB via streptavidin-biotin reaction, a sensitive and specific detection of label-free target DNA sequence is demonstrated by the MB microarray, with a signal-to-background ratio of 8. The immobilized MBs can be perfectly regenerated, allowing the reuse of the microarray. The MB microarray also is able to detect single nucleotide polymorphisms, exhibiting genotype-dependent fluorescence signals. It is demonstrated that the MB microarray can perform as a 4-to-2 encoder, compressing the genotype information into two outputs.

DNA molecular beacon-based plastic biochip: a versatile and sensitive scanometric detection platform

In this paper, we report a novel DNA molecular beacon (MB)-based plastic biochip platform for scanometric detection of a range of analytical targets. Hairpin DNA strands, which are dually modified with amino and biotin groups at their two ends are immobilized on a disposable plastic (polycarbonate) substrate as recognition element and gold nanoparticle-assisted silver-staining as signal reading protocol. Initially, the immobilized DNA probes are in their folded forms; upon target binding the hairpin secondary structure of the probe strand is "forced" open (i.e., converted to the unfolded state). Nanogold-streptavidin conjugates can then bind the terminal biotin groups and promote the deposition of rather large silver particles which can be either directly visualized or quantified with a standard flatbed scanner. We demonstrate that with properly designed probe sequences and optimized preparation conditions, a range of molecular targets, such as DNA strands, proteins (thrombin) and heavy metal ions (Hg(2+)), can be detected with high sensitivity and excellent selectivity. The detection can be done in both standard physiological buffers and real world samples. This constitutes a platform technology for performing rapid, sensitive, cost-effective, and point-of-care (POC) chemical analysis and medical diagnosis.

Regulating the on-surface LNA probe density for the highest target recognition efficiency

The recent emergence of on-surface LNA-based assays as potentially better alternatives over DNA-based approaches, due to enhanced sensitivity and target specificity, raises the need for the precise identification of the factors that control the performance of these assays. In this work, we investigated whether the probe density of fully modified ssLNA probes on the gold(111) surface could influence the target recognition capacity of the LNA sensing layer and illustrated simple means to control it, primarily by adjusting the salt concentration, nature of the cation, and pH of the immobilization buffer. It was observed that monovalent Na(+) could more effectively control the sensor probe density compared to bivalent Mg(2+), leading to better target recognition. Interestingly, unlike in the case of ssDNA sensor probes, the target recognition efficiency of the LNA layer at the optimum probe density was found to be almost spacer-independent, probably due to the rigidity of the LNA backbone. The optimized LNA sensor layer could discriminate single base mismatches, detect a minimum target DNA concentration of 5 nM, and sense a significant level of hybridization within a time scale of a few minutes. To our knowledge, for the first time, we identify the factors that control the on-surface LNA probe density for maximizing the performance of the LNA sensing layer.

A real-time characterization method to rapidly optimize molecular beacon signal for sensitive nucleic acids analysis

This research demonstrates an integrated microfluidic titration assay to characterize the cation concentrations in working buffer to rapidly optimize the signal-to-noise ratio (SNR) of molecular beacons (MBs). The "Microfluidic Droplet Array Titration Assay" (MiDATA) integrated the functions of sample dilution, sample loading, sample mixing, fluorescence analysis, and re-confirmation functions all together in a one-step process. It allows experimentalists to arbitrarily change sample concentration and acquire SNR measurements instantaneously. MiDATA greatly reduces sample dilution time, number of samples needed, sample consumption, and the total titration time. The maximum SNR of molecular beacons is achieved by optimizing the concentrations of the monovalent and divalent cation (i.e., Mg(2+) and K(+)) of the working buffer. MiDATA platform is able to reduce the total consumed reagents to less than 50 μL, and decrease the assay time to less than 30 min. The SNR of the designated MB is increased from 20 to 126 (i.e., enhanced the signal 630 %) using the optimal concentration of MgCl2 and KCl determined by MiDATA. This novel microfluidics-based titration method is not only useful for SNR optimization of molecular beacons but it also can be a general method for a wide range of fluorescence resonance energy transfer (FRET)-based molecular probes.

Dip-pen microarraying of molecular beacon probes on microgel thin-film substrates

Micron-sized spots of molecular beacon probes are patterned on PEG microgel thin films using dip-pen nanolithography.

A reusable sensor for the label-free detection of specific oligonucleotides by surface plasmon fluorescence spectroscopy

The development of a reusable molecular beacon (MB)-based sensor for the label-free detection of specific oligonucleotides using surface plasmon fluorescence spectroscopy (SPFS) as the readout method is described. The MBs are chemisorbed at planar gold surfaces serving as fluorescence quenching units. Target oligonucleotides of 24 bases can be detected within a few minutes at high single-mismatch discrimination rates.

Nanoscale spatial distribution of thiolated DNA on model nucleic acid sensor surfaces

The nanoscale arrangement of the DNA probe molecules on sensor surfaces has a profound impact on molecular recognition and signaling reactions on DNA biosensors and microarrays. Using electrochemical atomic force microscopy, we have directly determined the nanoscale spatial distribution of thiolated DNA that are attached to gold via different methods. We discovered significant heterogeneity in the probe density and limited stability for DNA monolayers prepared by the backfilling method, that is, first exposing the surface to thiolated DNA then "backfilling" with a passivating alkanethiol. On the other hand, the monolayers prepared by "inserting" thiolated DNA into a preformed alkanethiol monolayer lead to a more uniformly distributed layer of DNA. With high-resolution images of single DNA molecules on the surface, we have introduced spatial statistics to characterize the nanoscale arrangement of DNA probes. The randomness of the spatial distribution has been characterized. By determining the local densities surrounding individual molecules, we observed subpopulations of probes with dramatically different levels of "probe crowding". We anticipate that the novel application of spatial statistics to DNA monolayers can enable a framework to understand heterogeneity in probe spatial distributions, interprobe interactions, and ultimately probe activity on sensor surfaces.

A droplet-based, optofluidic device for high-throughput, quantitative bioanalysis

Analysis of chemical or biomolecular contents in a tiny amount of specimen presents a significant challenge in many biochemical studies and diagnostic applications. In this work, we present a single-layer, optofluidic device for real-time, high-throughput, quantitative analysis of droplet contents. Our device integrates an optical fiber-based, on-chip detection unit with a droplet-based microfluidic unit. It can quantitatively analyze the contents of individual droplets in real-time. It also achieves a detection throughput of 2000 droplets per second, a detection limit of 20 nM, and an excellent reproducibility in its detection results. In a proof-of-concept study, we demonstrate that our device can be used to perform detection of DNA and its mutations by monitoring the fluorescent signal changes of the target DNA/molecular beacon complex in single droplets. Our approach can be immediately extended to a real-time, high-throughput detection of other biomolecules (such as proteins and viruses) in droplets. With its advantages in throughput, functionality, cost, size, and reliability, the droplet-based optofluidic device presented here can be a valuable tool for many medical diagnostic applications.

Continuous flow multi-stage microfluidic reactors via hydrodynamic microparticle railing

"Multi-stage" fluidic reactions are integral to diverse biochemical assays; however, such processes typically require laborious and time-intensive fluidic mixing procedures in which distinct reagents and/or washes must be loaded sequentially and separately (i.e., one-at-a-time). Microfluidic processors that enable multi-stage fluidic reactions with suspended microparticles (e.g., microbeads and cells) to be performed autonomously could greatly extend the efficacy of lab-on-a-chip technologies. Here we present a single-layer microfluidic reactor that utilizes a microfluidic railing methodology to passively transport suspended microbeads and cells into distinct, adjacent laminar flow streams for rapid fluidic mixing and assaying. Four distinct molecular synthesis processes (i.e., consisting of 48 discrete fluidic mixing stages in total) were accomplished on polystyrene microbead substrates (15 μm in diameter) in parallel, without the need for external observation or regulation during device operation. Experimental results also revealed successful railing of suspended bovine aortic endothelial cells (approximately 13 to 17 μm in diameter). The presented railing system provides an effective continuous flow methodology to achieve bead-based and cell-based microfluidic reactors for applications including point-of-care (POC) molecular diagnostics, pharmacological screening, and quantitative cell biology.

Design, synthesis, and characterization of nucleic-acid-functionalized gold surfaces for biomarker detection

Nucleic-acid-functionalized gold surfaces have been used extensively for the development of biological sensors. The development of an effective biomarker detection assay requires careful design, synthesis, and characterization of probe components. In this Feature Article, we describe fundamental probe development constraints and provide a critical appraisal of the current methodologies and applications in the field. We discuss critical issues and obstacles that impede the sensitivity and reliability of the sensors to underscore the challenges that must be met to advance the field of biomarker detection.

Label-free genosensor based on immobilized DNA hairpins on gold surface

In this report, we demonstrate a label-free genosensor based on DNA hairpins coupled to gold coated sensor surfaces. The hairpin probes were labeled with a thiolated moiety for immobilization at the 5' end and with a fluorophore for signal transduction at the 3' end. In the absence of the complement, the fluorophore is quenched by energy transfer to the gold surface. Addition of the target sequence leads to the hairpin unfolding, and releases the fluorescent signal. This built-in property, using a gold film as both the immobilizing substrate and quenching agent, has the advantage of simplicity in design and ease of further integration. Our results showed that lengths of both the stem and the loop structures have significant effects on the sensor performance. Hybridization kinetics was investigated for various probe/target lengths and concentrations. An optimized hairpin probe gave a fluorescent signal increase of 39 folds after hybridization, which is much higher than the earlier reported results. A limit of detection (LOD) down to 0.3 nM for the complementary target DNA detection has been achieved. The developed sensor was further successfully applied for the detection of single-base mismatch targets, as well as for the direct detection of PCR products.

Hybridization efficiency of molecular beacons bound to gold nanowires: effect of surface coverage and target length

Surface-bound nucleic acid probes designed to adopt specific secondary structures are becoming increasingly important in a range of biosensing applications but remain less well characterized than traditional single-stranded probes, which are typically designed to avoid secondary structure. We report the hybridization efficiency for surface-immobilized hairpin DNA probes. Our probes are molecular beacons, carrying a 3' dye moiety and a 5' thiol for attachment to gold nanowires, which serve as both scaffolds for probe attachment and quenchers. Hybridization efficiency was dependent on probe surface coverage, reaching a maximum of ∼90% at intermediate coverages of (1-2) × 10(12) probes/cm(2) and dropping to ≤20% at higher or lower coverages. Fluorescence intensity did not track with the number of target molecules bound, and was highest for high probe coverage despite the lower bound targets per square centimeter. Backfilling with short thiolated oligoethylene glycol spacers increased hybridization efficiency at low hairpin probe coverages (∼(3-4) × 10(11) probes/cm(2)), but not at higher probe coverages (1 × 10(12)/cm(2)). We also evaluated the effect of target length by adding up to 50 nonhybridizing nucleotides to the 3' or 5' end of the complementary target sequence. Additional nucleotides on the 3' end of the complementary target sequence (i.e., the end near the nanowire surface) had a much greater impact on hybridization efficiency as compared to nucleotides added to the 5' end. This work provides guidance in designing sensors in which surface-bound probes designed to adopt secondary structures are used to detect target sequences from solution.

A graphene-enhanced molecular beacon for homogeneous DNA detection

In this work, we report the design of a novel graphene-based molecular beacon (MB) that could sensitively and selectively detect specific DNA sequences. The ability of water-soluble graphene oxide (GO) to differentiated hairpin and dsDNA offered a new approach to detect DNA. We found that the background fluorescence of MB was significantly suppressed in the presence of GO, which increased the signal-to-background ratio, hence the sensitivity. Moreover, the single-mismatch differentiation ability of hairpin DNA was maintained, leading to high selectivity of this new method.

Protein analysis based on molecular beacon probes and biofunctionalized nanoparticles

With the completion of the human genome-sequencing project, there has been a resulting change in the focus of studies from genomics to proteomics. By utilizing the inherent advantages of molecular beacon probes and biofunctionalized nanoparticles, a series of novel principles, methods and techniques have been exploited for bioanalytical and biomedical studies. This review mainly discusses the applications of molecular beacon probes and biofunctionalized nanoparticles-based technologies for real-time, in-situ, highly sensitive and highly selective protein analysis, including the nonspecific or specific protein detection and separation, protein/DNA interaction studies, cell surface protein recognition, and antigen-antibody binding process-based bacteria assays. The introduction of molecular beacon probes and biofunctionalized nanoparticles into the protein analysis area would necessarily advance the proteomics research.

Addressable bipartite molecular hook (ABMH): immobilized hairpin probes with sensitivity below 50 fM

Sensitivity and specificity of nucleic acid binding probes immobilized on solid supports are essential features of microarrays. Whereas conventional biochips apply nonquenched linear probes (cDNA, oligonucleotides), hairpin structures containing a fluorophore-quencher system comprise important prerequisites required for ideal transcriptional probes. We describe here the generation of addressable bipartite molecular hook (ABMH) probes and the characterization of their performance analyzing biological and clinical samples, also in comparison to linear oligonucleotide arrays. ABMH can be immobilized subsequent to reaction with the target sequence or the reaction carried out directly with the immobilized probe; target sequences are recognized with excellent sensitivity, specificity, and a detection limit below 50 fM. Due to excellent sensitivity and specificity, ABMH represent ideal candidates for the nonamplified microarray-based detection of low abundance nucleic acids, e.g., required in diagnostic assays.

Label-free microarray imaging for direct detection of DNA hybridization and single-nucleotide mismatches

A novel method is proposed for direct detection of DNA hybridization on microarrays. Optical interferometry is used for label-free sensing of biomolecular accumulation on glass surfaces, enabling dynamic detection of interactions. Capabilities of the presented method are demonstrated by high-throughput sensing of solid-phase hybridization of oligonucleotides. Hybridization of surface immobilized probes with 20 base pair-long target oligonucleotides was detected by comparing the label-free microarray images taken before and after hybridization. Through dynamic data acquisition during denaturation by washing the sample with low ionic concentration buffer, melting of duplexes with a single-nucleotide mismatch was distinguished from perfectly matching duplexes with high confidence interval (>97%). The presented technique is simple, robust, and accurate, and eliminates the need of using labels or secondary reagents to monitor the oligonucleotide hybridization.

Locked nucleic acid based beacons for surface interaction studies and biosensor development

DNA sensors and microarrays permit fast, simple, and real-time detection of nucleic acids through the design and use of increasingly sensitive, selective, and robust molecular probes. Specifically, molecular beacons (MBs) have been employed for this purpose; however, their potential in the development of solid-surface-based biosensors has not been fully realized. This is mainly a consequence of the beacon's poor stability because of the hairpin structure once immobilized onto a solid surface, commonly resulting in a low signal enhancement. Here, we report the design of a new MB that overcomes some of the limitations of MBs for surface immobilization. Essentially, this new design adds locked nucleic acid bases (LNAs) to the beacon structure, resulting in a LNA molecular beacon (LMB) with robust stability after surface immobilization. To test the efficacy of LMBs against that of regular molecular beacons (RMBs), the properties of selectivity, sensitivity, thermal stability, hybridization kinetics, and robustness for the detection of target sequences were compared and evaluated. A 25-fold enhancement was achieved for the LMB on surface with detection limits reaching the low nanomolar range. In addition, the LMB-based biosensor was shown to possess better stability, reproducibility, selectivity, and robustness when compared to the RMB. Therefore, as an alternative to conventional DNA and as a prospective tool for use in both DNA microarrays and biosensors, these results demonstrate the potential of the locked nucleic acid bases for nucleic acid design for surface immobilization.

Enrichment of cancer cells using aptamers immobilized on a microfluidic channel

This work describes the development and investigation of an aptamer modified microfluidic device that captures rare cells to achieve a rapid assay without pretreatment of cells. To accomplish this, aptamers are first immobilized on the surface of a poly(dimethylsiloxane) microchannel, followed by pumping a mixture of cells through the device. This process permits the use of optical microscopy to measure the cell-surface density from which we calculate the percentage of cells captured as a function of cell and aptamer concentration, flow velocity, and incubation time. This aptamer-based device was demonstrated to capture target cells with >97% purity and >80% efficiency. Since the cell capture assay is completed within minutes and requires no pretreatment of cells, the device promises to play a key role in the early detection and diagnosis of cancer where rare diseased cells can first be enriched and then captured for detection.

Molecular engineering of DNA: molecular beacons

Molecular beacons (MBs) are specifically designed DNA hairpin structures that are widely used as fluorescent probes. Applications of MBs range from genetic screening, biosensor development, biochip construction, and the detection of single-nucleotide polymorphisms to mRNA monitoring in living cells. The inherent signal-transduction mechanism of MBs enables the analysis of target oligonucleotides without the separation of unbound probes. The MB stem-loop structure holds the fluorescence-donor and fluorescence-acceptor moieties in close proximity to one another, which results in resonant energy transfer. A spontaneous conformation change occurs upon hybridization to separate the two moieties and restore the fluorescence of the donor. Recent research has focused on the improvement of probe composition, intracellular gene quantitation, protein-DNA interaction studies, and protein recognition.

Quantitative rRNA-targeted solution-based hybridization assay using peptide nucleic acid molecular beacons

The potential of a solution-based hybridization assay using peptide nucleic acid (PNA) molecular beacon (MB) probes to quantify 16S rRNA of specific populations in RNA extracts of environmental samples was evaluated by designing PNA MB probes for the genera Dechloromonas and Dechlorosoma. In a kinetic study with 16S rRNA from pure cultures, the hybridization of PNA MB to target 16S rRNA exhibited a higher final hybridization signal and a lower apparent rate constant than the hybridizations to nontarget 16S rRNAs. A concentration of 10 mM NaCl in the hybridization buffer was found to be optimal for maximizing the difference between final hybridization signals from target and nontarget 16S rRNAs. Hybridization temperatures and formamide concentrations in hybridization buffers were optimized to minimize signals from hybridizations of PNA MB to nontarget 16S rRNAs. The detection limit of the PNA MB hybridization assay was determined to be 1.6 nM of 16S rRNA. To establish proof for the application of PNA MB hybridization assays in complex systems, target 16S rRNA from Dechlorosoma suillum was spiked at different levels to RNA isolated from an environmental (bioreactor) sample, and the PNA MB assay enabled effective quantification of the D. suillum RNA in this complex mixture. For another environmental sample, the quantitative results from the PNA MB hybridization assay were compared with those from clone libraries.

BeadCons: detection of nucleic acid sequences by flow cytometry

Molecular beacons are single-stranded nucleic acid structures with a terminal fluorophore and a distal, terminal quencher. These molecules are typically used in real-time PCR assays, but have also been conjugated with solid matrices. This unit describes protocols related to molecular beacon-conjugated beads (BeadCons), whose specific hybridization with complementary target sequences can be resolved by cytometry. Assay sensitivity is achieved through the concentration of fluorescence signal on discrete particles. By using molecular beacons with different fluorophores and microspheres of different sizes, it is possible to construct a fluid array system with each bead corresponding to a specific target nucleic acid. Methods are presented for the design, construction, and use of BeadCons for the specific, multiplexed detection of unlabeled nucleic acids in solution. The use of bead-based detection methods will likely lead to the design of new multiplex molecular diagnostic tools.

Molecular beacon-metal nanowire interface: effect of probe sequence and surface coverage on sensor performance

We report the effect of surface coverage and sequence on the performance of 5' thiolated, 3' fluorophore-labeled DNA hairpin probes bound to Au/Ag striped ("barcoded") metal nanowires. Coverage was controlled by varying probe concentration, buffer ionic strength, and by addition of short hydroxy-terminated alkanethiol diluent molecules during probe assembly onto the nanowire surface. Surface dilution of the surface-bound probes with a omega-hydroxyl alkanethiol, a commonly accepted practice in the surface-bound DNA literature, did not appreciably improve sensor performance as compared to similar probe coverages without hydroxyalkanethiol diluents; this finding underscores the differences between the molecular beacon probes used here and more traditional nonfluorescent, random coil probes. We found that intermediate probe coverage of approximately 10 (12) molecules/cm (2) gave the best discrimination between presence and absence of a target sequence. Because we are interested in multiplexed assays, we also compared several beacon probe sequences having different stabilities for secondary structure formation in solution; we found that both probe surface coverage and sensor performance varied for different probe sequences. When five different molecular beacon probes, each bound to barcoded nanowires, were used in a multiplexed, wash-free assay for target oligonucleotides corresponding to viral nucleic acid sequences, these differences in probe performance did not prevent accurate target identification. We anticipate that the findings described here will also be relevant to other applications involving molecular beacons or other structured nucleic acid probes immobilized on metal surfaces.

Towards a target label-free suboptimum oligonucleotide displacement-based detection system

A novel method for the future development of label-free DNA sensors is proposed here. The approach is based on the displacement of a labelled suboptimum mutated oligonucleotide hybridised with the immobilised biotin-capture probe. The target fully complementary to the biotin-capture probe can displace the labelled oligonucleotide causing a subsequent decrease of the signal that verifies the presence of the target. The decrease of signal was demonstrated to be proportional to the target concentration. A study of the hybridisation of mutated and complementary labelled oligonucleotides with an immobilised biotin-capture probe was carried out. Different kinetic and thermodynamic behaviour was observed for heterogeneous hybridisation of biotin-capture probe with complementary or suboptimum oligonucleotides. The displacement method evaluated colourimetrically achieved the objective of decreasing the response time from 1 h for direct hybridisation of 19-mer oligonucleotides in the direct enzyme-linked oligonucleotide assay (ELONA) to 5 min in the case of displacement detection in the micromolar concentration range.

Transport and detection of unlabeled nucleotide targets by microtubules functionalized with molecular beacons

Shrinking biosensors down to microscale dimensions enables increases in sensitivity and the ability to analyze minute samples such as the contents of individual cells. The goal of the present study is to create mobile microscale biosensors by attaching molecular beacons to microtubules and using kinesin molecular motors to transport these functionalized microtubules across two-dimensional surfaces. Previous work has shown that microfluidic channels can be functionalized with kinesin motors such that microtubules can be transported and directed through these channels without the need for external power or pressure-driven pumping. In this work, we show that molecular beacons can be attached to microtubules such that both the fluorescence reporting capability of the beacon and the motility of the microtubules are retained. These molecular beacon-functionalized microtubules were able to bind ssDNA target sequences, transport them across surfaces, and report their presence by an increase in fluorescence that was detected by fluorescence microscopy. This work is an important step toward creating hybrid microdevices for sensitive virus detection or analyzing mRNA profiles of individual cells.

Determination of the optimized conditions for coupling oligonucleotides with 16-mercaptohexadecanoic acid chemically adsorbed upon Au

A specific 5'-modified amino group oligonucleotide (Primer 1), 15-mers in length, is selectively coupled with the carboxyl terminated 16-mercaptohexadecanoic acid (MHDA) chemically adsorbed on Au and subsequently hybridized with Antisense Primer. The amide-coupling process is of significance to create an intermediate structure for the purpose of adding Primer 1, while the hybridization reaction is relevant to various diagnostic purposes to determine the presence in nucleic acids for a target sequence. In this work, the coupling setting was particularly emphasized by varying commonly used temperatures and pH values with a definite concentration of coupling agents (i.e., 10 mM). The recombination with analogous hybridization treatment was investigated using high resolution X-ray photoelectron spectroscopy and a 75 degrees grazing angle Fourier transform infrared spectrometer. On the basis of the spectroscopic studies, the optimized conditions for the coupling process that is also correlated with the molecular density of subsequent hybridization process on MHDA/Au have been proposed at 37 degrees C and a pH value of 4.5. Therefore, it is pertinent to intensify the joining of short-chain DNA strands by complementary base pairing in diagnostic applications such as the identification of single nucleotide polymorphisms.