Optimization of the rate of DNA hybridization and rapid detection of methicillin resistant Staphylococcus aureus DNA using fluorescence polarization

Rapid and multi-cycle smFISH enabled by microfluidic ion concentration polarization for in-situ profiling of tissue-specific gene expression in whole C. elegans

Understanding gene regulation networks in multicellular organisms is crucial to decipher many complex physiological processes ranging from development to aging. One technique to characterize gene expression with tissue-specificity in whole organisms is single-molecule fluorescence in situ hybridization (smFISH). However, this protocol requires lengthy incubation times, and it is challenging to achieve multiplexed smFISH in a whole organism. Multiplexing techniques can yield transcriptome-level information, but they require sequential probing of different genes. The inefficient macromolecule exchange through diffusion-dominant transport across dense tissues is the major bottleneck. In this work, we address this challenge by developing a microfluidic/electrokinetic hybrid platform to enable multicycle smFISH in an intact model organism, Caenorhabditis elegans. We integrate an ion concentration polarization based ion pump with a microfluidic array to rapidly deliver and remove gene-specific probes and stripping reagents on demand in individual animals. Using our platform, we can achieve rapid smFISH, an order of magnitude faster than traditional smFISH protocols. We also demonstrate the capability to perform multicycle smFISH on the same individual samples, which is impossible to do off-chip. Our method hence provides a powerful tool to study individual-specific, spatially resolvable, and large-scale gene expression in whole organisms.

Blocking probe as a potential tool for detection of single nucleotide DNA mutations: design and performance

Developing strategies to detect single nucleotide DNA mutations associated with treatment decisions in cancer patients from liquid biopsies is a rapidly emerging area of personalized medicine that requires high specificity. Here we report how to design an easy enzyme-free approach that could create a platform for detection of L858R mutation of EGFR that is a predictive biomarker of tyrosine kinase treatment in many cancers. This approach includes the addition of blocking probes with the antisense ssDNA at different blocking positions and different concentrations such as to avoid re-annealing with the respective sense ssDNA. The successful blocking strategy was corroborated by fluorescence spectroscopy in solution using two distinct FRET pairs and quartz crystal microbalance with dissipation (QCM-D) measurements under comparable experimental conditions, as the hybridization rate-limiting step in both methods is the nucleation process. The efficiency of hybridization of each blocking probe was strongly dependent on its position particularly when the analyte possesses a secondary hairpin-structure. We tested the performance of blocking probes in combination with gold nanoparticles; the obtained results were in agreement with those of QCM-D. These findings could facilitate the development of better biosensors, especially those using probes containing secondary structure.

A molecularly imprinted nanocavity-based fluorescence polarization assay platform for cortisol sensing

The sensing nano-platform for cortisol detection was developed on the basis of the fluorescence polarization assay involving the competitive binding of dansyl-cortisol and cortisol against molecularly imprinted polymer nanoparticles.

DNA aptamers are functional molecular recognition sensors in protic ionic liquids

The function and structural changes of an AMP molecular aptamer beacon and its molecular recognition capacity for its target, adenosine monophosphate (AMP), was systematically explored in solution with a protic ionic liquid, ethylammonium nitrate (EAN). It could be proven that up to 2 M of EAN in TBS buffer, the AMP molecular aptamer beacon was still capable of recognizing AMP while also maintaining its specificity. The specificity was proven by using the guanosine monophosphate (GMP) as target; GMP is structurally similar to AMP but was not recognized by the aptamer. We also found that in highly concentrated EAN solutions the overall amount of double stranded DNA formed, as well as its respective thermal stability, diminished gradually, but surprisingly the hybridization rate (kh ) of single stranded DNA was significantly accelerated in the presence of EAN. The latter may have important implications in DNA technology for the design of biosensing and DNA-based nanodevices in nonconventional solvents, such as ionic liquids.

DNA-programmed mesoscopic architecture

We study the problem of the self-assembly of nanoparticles (NPs) into finite mesoscopic structures with a programmed local morphology and complex overall shape. Our proposed building blocks are NPs that are directionally functionalized with DNA. The combination of directionality and selectivity of interactions allows one to avoid unwanted metastable configurations, which have been shown to lead to slow self-assembly kinetics even in much simpler systems. With numerical simulations, we show that a variety of target mesoscopic objects can be designed and self-assembled in near perfect yield. They include cubes, pyramids, boxes, and even an Empire State Building model. We summarize our findings with a set of design strategies that leads to the successful self-assembly of a wide range of mesostructures.

Enhanced annealing of mismatched oligonucleotides using a novel melting curve assay allows efficient in vitro discrimination and restriction of a single nucleotide polymorphism

Background

Many SNP discrimination strategies employ natural restriction endonucleases to discriminate between allelic states. However, SNPs are often not associated with a restriction site and therefore, a number of attempts have been made to generate sequence-adaptable restriction endonucleases. In this study, a simple, sequence-adaptable SNP discrimination mechanism between a 'wild-type' and 'mutant' template is demonstrated. This model differs from other artificial restriction endonuclease models as cis- rather than trans-orientated regions of single stranded DNA were generated and cleaved, and therefore, overcomes potential issues of either inefficient or non-specific binding when only a single variant is targeted.

Results

A series of mismatch 'bubbles' that spanned 0-5-bp surrounding a point mutation was generated and analysed for sensitivity to S1 nuclease. In this model, generation of oligonucleotide-mediated ssDNA mismatch 'bubbles' in the presence of S1 nuclease resulted in the selective degradation of the mutant template while maintaining wild-type template integrity. Increasing the size of the mismatch increased the rate of mutant sequence degradation, until a threshold above which discrimination was lost and the wild-type sequence was degraded. This level of fine discrimination was possible due to the development of a novel high-resolution melting curve assay to empirically determine changes in Tm (~5.0°C per base-pair mismatch) and to optimise annealing conditions (~18.38°C below Tm) of the mismatched oligonucleotide sets.

Conclusions

The in vitro 'cleavage bubble' model presented is sequence-adaptable as determined by the binding oligonucleotide, and hence, has the potential to be tailored to discriminate between any two or more SNPs. Furthermore, the demonstrated fluorometric assay has broad application potential, offering a rapid, sensitive and high-throughput means to determine Tm and annealing rates as an alternative to conventional hybridisation detection strategies.

Hybridization kinetics of double-stranded DNA probes for rapid molecular analysis

This study reports the hybridization kinetics of double-stranded DNA probes for rapid molecular analysis. Molecular binding schemes based on double-stranded DNA probes have been developed for quantitative detection of various biomolecules, such as nucleic acids and DNA binding proteins recently. The thermodynamic competition between the target and the competitor in binding to the probe provides a highly specific mechanism for molecular detection. The kinetics of the double-stranded DNA probe, on the other hand, represent another key aspect toward its general applicability for a wide set of biomedical applications. Herein we report a systematic investigation of the kinetics of double-stranded DNA probes. The signal-to-background ratio and assay time of the double-stranded DNA probes are optimized at a high ionic strength (over 100 mM NaCl). Both the donor probe and the quencher probe sequences are shown to be important in the hybridization kinetics. A long sticky end of the probe is able to dramatically accelerate the kinetics of the assay. To provide a quantitative description of the kinetics, a two-stage binding model is developed to describe the major features of the kinetics of the assay. The sensitivity of the kinetic model and the dominant affinity constants are studied. The study provides a general guideline for the design of the probes for reducing the total assay time. With an appropriate design of the probes, the assay can be finished within minutes at room temperature.

The simple and rapid detection of specific PCR products from bacterial genomes using Zn finger proteins

A novel method of rapid and specific detection of polymerase chain reaction (PCR) products from bacterial genomes using Zn finger proteins was developed. Zn finger proteins are DNA-binding proteins that can sequence specifically recognize PCR products. Since Zn finger proteins can directly detect PCR products without undergoing dehybridization, unlike probe DNA, and can double check the specific PCR amplification and sequence specificity of the PCR products, this novel method would be quick and highly accurate. In this study, we tried to detect Legionella pneumophila using Sp1. It was found that a 49 bp L. pneumophila-specific region containing the Sp1 recognition site is located on the flhA gene of the L. pneumophila genome. We succeeded in specifically detecting PCR products amplified from L. pneumophila in the presence of other bacterial genomes by ELISA, and demonstrated that Sp1 enables the discrimination of L. pneumophila-specific PCR products from others. By fluorescence depolarization measurement, these specific PCR products could be detected within 1 min. These results indicate that the rapid and simple detection of PCR products specific to L. pneumophila using a Zn finger protein was achieved. This methodology can be applied to the detection of other bacteria using various Zn finger proteins that have already been reported.

Controlling the surface density of DNA on gold by electrically induced desorption

We report on a method to control the packing density of sulfur-bound oligonucleotide layers on metal electrodes by electrical means. In a first step, a dense nucleic acid layer is deposited by self-assembly from solution; in a second step, defined fractions of DNA molecules are released from the surface by applying a series of negative voltage cycles. Systematic investigations of the influence of the applied electrode potentials and oligonucleotide length allow us to identify a sharp desorption onset at -0.65 V versus Ag/AgCl, which is independent of the DNA length. Moreover, our results clearly show the pronounced influence of competitive adsorbents in solution on the desorption behavior, which can prevent the re-adsorption of released DNA molecules, thereby enhancing the desorption efficiency. The method is fully bio-compatible and can be employed to improve the functionality of DNA layers. This is demonstrated in hybridization experiments revealing almost perfect yields for electrically "diluted" DNA layers. The proposed control method is extremely beneficial to the field of DNA-based sensors.

An introduction to electrochemical DNA biosensors

Electrochemical DNA biosensors exploit the affinity of single-stranded DNA for complementary strands of DNA and are used in the detection of specific sequences of DNA with a view towards developing portable analytical devices. Great progress has been made in this field but there are still numerous challenges to overcome. This review for researchers new to the field describes the components of electrochemical DNA biosensors and the important issues in their design. Methods of transducing DNA binding events are discussed along with future directions for DNA biosensors.

Guidelines for the laboratory diagnosis and susceptibility testing of methicillin-resistant Staphylococcus aureus (MRSA)

These evidence-based guidelines have been produced after a literature review of the laboratory diagnosis and susceptibility testing of methicillin-resistant Staphylococcus aureus (MRSA). We have considered the detection of MRSA in screening samples and the detection of reduced susceptibility to glycopeptides in S. aureus. Recommendations are given for the identification of S. aureus and for suitable methods of susceptibility testing and screening for MRSA and for S. aureus with reduced susceptibility to glycopeptides. These guidelines indicate what tests should be used but not when the tests are applicable, as aspects of this are dealt with in guidelines on control of MRSA. There are currently several developments in screening media and molecular methods. It is likely that some of our recommendations will require modification as the new methods become available.

The extremely rapid oligonucleotide hybridization and high throughput detection of microbial gene sequences using fluorescence polarization

The hybridization of oligonucleotide sequences complementary to the genes of Shiga toxins (verotoxins) types 1 and 2 of enterohaemorrhagic Escherichia coli (EHEC) and human hepatitis C virus (HCV) was monitored using fluorescence polarization under the reaction condition of high salt concentration (0.8 M NaCl), which was optimized to obtain a higher rate of hybridization. The time courses of hybridization of fluorescently labeled oligomers (probe DNAs) with the amplified DNA or RNA of the genes were recorded. Two methods, the asymmetric PCR and NASBA, were used to amplify the genetic DNA of Shiga toxins and that of RNA in HCV, respectively. Probe DNA sequences were designed which hybridized extremely rapidly with amplicons of the genes of Shiga toxins types 1 and 2 and that of HCV. In the cases using the three different DNA probes, the hybridization was 90% complete in about 1 min, considerably faster than that of the 3 min reported previously. The rapidity of this hybridization could not be explained by the melting temperature or the G+C content of the probe sequences but its relationship with high order structure of the single stranded DNA or RNA of the amplicons in the solution was strongly suggested.

Rapid and simple detection of PCR product DNA: a comparison between Southern hybridization and fluorescence polarization analysis

The essential aim of this study was to compare two different methods, Southern hybridization and fluorescence polarization (FP) assay. They both detect specific hybridization and were examined using common asymmetric PCR products and probes. FP assay clearly showed the hybridization of probe DNAs with the asymmetric PCR products of their target genes. Southern blot patterns presented excellent consistency with the results of FP assay. In both methods, two types of Shiga toxin (vero toxin) genes held in enterohaemorrhagic Escherichia coli (EHEC) were used as target genes. For detection of the two genes, stx1 and stx2, two respective DNA probes were synthesized. Both in FP assay and in Southern hybridization, the probe for stx1 hybridized only with the product of stx1 and vice versa. The results of the DNA detection using different methods were completely in agreement. Moreover, FP assay makes it possible to detect the hybridization rapidly. In our high NaCl concentration condition, hybridization between the probes and the asymmetric PCR products could be monitored within about 15min.

A fluorescence polarization assay using oligonucleotide probes for the rapid detection of verotoxin-producing Escherichia coli

A hybridization assay using fluorescence polarization was combined with the asymmetric polymerase chain reaction (PCR) in a method for the detection of the verotoxin type 2 gene of verotoxin-producing Escherichia coli. Six oligonucleotide probes labeled with FITC were designed and evaluated. One of these gave a detection limit of 10(3) colony forming units per assay, and assay results could be obtained within 5 min after PCR. It appears that the detection limit was restricted mainly by the extent and fidelity of PCR amplification, rather than by the sensitivity of the fluorescence polarization technique, indicating that good probe design facilitates the rapid detection of the PCR product. The fluorescence polarization assay, in conjunction with DNA amplification by PCR, is a powerful and widely applicable method for the rapid and sensitive detection of oligonucleotide sequences.

Detection of hybrid formation between peptide nucleic acids and DNA by fluorescence polarization in the presence of polylysine

A new method for the detection of PNA/DNA hybrids is presented. In this method, short PNA probes (9-13 mer) are labeled with a fluorescent dye and allowed to hybridize to target DNA molecules. A cationic polyamino acid, such as polylysine, is then added to the reaction mixture, whereupon the DNA molecules bind electrostatically to this polycation. The PNA probes, which are uncharged or may carry only a small charge due to the fluorescent dye, do not bind to polylysine unless hybridized to the negatively charged DNA target. The binding of the labeled PNA/DNA hybrid to the high-molecular-weight polymer leads to a significant change in the rotational correlation time of the fluorophore attached to the PNA. This can be conveniently detected by measuring the fluorescence polarization of the latter. The method is completely homogeneous because no separation of free from bound PNA probe is required. The hybridization and dehybridization reactions can be followed in real time. The method has been applied to the typing of single-nucleotide polymorphisms in PCR products.

Electrochemical quantitation of DNA immobilized on gold

We have developed an electrochemical method to quantify the surface density of DNA immobilized on gold. The surface density of DNA, more specifically the number of nucleotide phosphate residues, is calculated from the amount of cationic redox marker measured at the electrode surface. DNA was immobilized on gold by forming mixed monolayers of thiol-derivitized, single-stranded oligonucleotide and 6-mercapto-1-hexanol. The saturated amount of charge-compensation redox marker in the DNA monolayer, determined using chronocoulometry, is directly proportional to the number of phosphate residues and thereby the surface density of DNA. This method permits quantitative determination of both single- and double-stranded DNA at electrodes. Surface densities of single-stranded DNA were precisely varied in the range of (1-10) x 10(12) molecules/cm2, as determined by the electrochemical method, using mixed monolayers. We measured the hybridization efficiency of immobilized single-stranded DNA to complementary strands as a function of the immobilized DNA surface density and found that it exhibits a maximum with increasing surface density.