Detection of C677T mutation of MTHFR in subject with coronary heart disease by hairpin probe with enzymatic color on microarray

Molecular beacon (MB) is especially suited for detection of single nucleotide polymorphism (SNP), and the type of MB immobilized on the surface of microarray in particular, may detect multi-sample and multi-locus. However, the majority of MB needs to be labeled with fluorescence and quenching molecules on the two ends of the probe, and observed the reaction of fluorescence or complicated electrochemical signal produced hybridization of MB and target sequence by complex and expensive instruments. The "molecular beacon" and microarray designed appropriately in our study can produce visible light response signal induced by amplification effect of enzymatic color, and are avoided with the marker of fluorescence and quenching molecules and expensive instruments. The "molecular beacon" without fluorescence and quenching molecules is entitled as "hairpin DNA probe" by us for only the "hairpin" structure of traditional molecular beacon is adopted. The merits of two techniques, molecular beacon and amplification effect of enzymatic color, are successfully combined, and the technique is simple, sensitive and specific, to detect and compare the methylenetetrahydrofolate reductase (MTHFR) Gene C677T mutation of subjects between coronary heart disease (CHD) and control group. The results showed that MTHFR Gene C677T polymorphism is an independent risk factor for CHD.     

Time-resolved detection probe for homogeneous nucleic acid analyses in one-step format

We report here an extension of homogeneous assays based on fluorescence intensity and lifetime measuring on DNA hybridization. A novel decay probe that allows simple one-step nucleic acid detection with subnanomolar sensitivity, and is suitable for closed-tube applications, is introduced. The decay probe uses fluorescence resonance energy transfer (FRET) between a europium chelate donor and an organic fluorophore acceptor. The substantial change in the acceptor emission decay time on hybridization with the target sequence allows the direct separation of the hybridized and unhybridized probe populations in a time-resolved measurement. No additional sample manipulation or self-hybridization of the probes is required. The wavelength and decay time of a decay probe can be adjusted according to the selection of probe length and acceptor fluorophore, thereby making the probes applicable to multiplexed assays. Here we demonstrate the decay probe principle and decay probe-based, one-step, dual DNA assay using celiac disease-related target oligonucleotides (single-nucleotide polymorphisms [SNPs]) as model analytes. Decay probes showed specific response for their complementary DNA target and allowed good signal deconvolution based on simultaneous optical and temporal filtering. This technique potentially could be used to further increase the number of simultaneously detected DNA targets in a simple one-step homogeneous assay.     

DNA bioassays based on the fluorescence ‘turn off’ of silver nanocluster beacon

Recognition and quantification of oligonucleotide sequences play important roles in medical diagnosis. In this study, a new fluorescent oligonucleotide‐stabilized silver nanocluster beacon (NCB) probe was designed for sensitive detection of oligonucleotide sequence targets. This probe contained two tailored DNA strands. One strand was a signal probe strand containing a cytosine‐rich strand template for fluorescent silver nanocluster (Ag NC) synthesis and a detection sections at each end. The other strand was a fluorescence enhancing strand containing a guanine‐rich section for signal enhancement at one end and a linker section complementary to one end of the signal probe strand. After synthesis of the Ag NCs and hybridization of the two strands, the fluorescence intensity of the as‐prepared silver NCB was enhanced 200‐fold compared with the Ag NCs. Two NCBs were designed to detect two disease‐related oligonucleotide sequences, and results indicated that the two target oligonucleotide sequences in the range 50.0–600.0 and 50.0–200.0 nM could be linearly detected with detection limits of 20 and 25 nM, respectively. The developed fluorescence method using NCBs for oligonucleotide sequence detection was sensitive, facile and had potential for use in bioanalysis and diagnosis.     

Enzymatic signal amplification of molecular beacons for sensitive DNA detection

Molecular beacons represent a new family of fluorescent probes for nucleic acids, and have found broad applications in recent years due to their unique advantages over traditional probes. Detection of nucleic acids using molecular beacons has been based on hybridization between target molecules and molecular beacons in a 1:1 stoichiometric ratio. The stoichiometric hybridization, however, puts an intrinsic limitation on detection sensitivity, because one target molecule converts only one beacon molecule to its fluorescent form. To increase the detection sensitivity, a conventional strategy has been target amplification through polymerase chain reaction. Instead of target amplification, here we introduce a scheme of signal amplification, nicking enzyme signal amplification, to increase the detection sensitivity of molecular beacons. The mechanism of the signal amplification lies in target-dependent cleavage of molecular beacons by a DNA nicking enzyme, through which one target DNA can open many beacon molecules, giving rise to amplification of fluorescent signal. Our results indicate that one target DNA leads to cleavage of hundreds of beacon molecules, increasing detection sensitivity by nearly three orders of magnitude. We designed two versions of signal amplification. The basic version, though simple, requires that nicking enzyme recognition sequence be present in the target DNA. The extended version allows detection of target of any sequence by incorporating rolling circle amplification. Moreover, the extended version provides one additional level of signal amplification, bringing the detection limit down to tens of femtomolar, nearly five orders of magnitude lower than that of conventional hybridization assay.     

Thermodynamically modulated partially double-stranded linear DNA probe design for homogeneous real-time PCR

Real-time PCR assays have recently been developed for diagnostic and research purposes. Signal generation in real-time PCR is achieved with probe designs that usually depend on exonuclease activity of DNA polymerase (e.g. TaqMan probe) or oligonucleotide hybridization (e.g. molecular beacon). Probe design often needs to be specifically tailored either to tolerate or to differentiate between sequence variations. The conventional probe technologies offer limited flexibility to meet these diverse requirements. Here, we introduce a novel partially double-stranded linear DNA probe design. It consists of a hybridization probe 5'-labeled with a fluorophore and a shorter quencher oligo of complementary sequence 3'-labeled with a quencher. Fluorescent signal is generated when the hybridization probe preferentially binds to amplified targets during PCR. This novel class of probe can be thermodynamically modulated by adjusting (i) the length of hybridization probe, (ii) the length of quencher oligo, (iii) the molar ratio between the two strands and (iv) signal detection temperature. As a result, pre-amplification signal, signal gain and the extent of mismatch discrimination can be reliably controlled and optimized. The applicability of this design strategy was demonstrated in the Abbott RealTime HIV-1 assay.     

Two-color hybridization with high complexity chromosome-specific probes and a degenerate alpha satellite probe DNA allows unambiguous discrimination between symmetrical and asymmetrical translocations

This report describes a fluorescence in situ hybridization approach to chromosome staining that facilitates detection of structural aberrations and allows discrimination between dicentric chromosomes and symmetrically translocated chromosomes. In this approach, selected whole chromosomes are stained in one color by hybridization with composite probes whose elements have DNA sequence homology along the length of the target chromosomes. In addition, all chromosomes are counterstained with a DNA specific dye so that structural aberrations between target and non-target chromosomes are clearly visible. Discrimination between dicentric chromosomes and symmetrical translocations is accomplished by hybridization with a second probe that is homologous to DNA sequences found in the centromeric region of all chromosomes. The centromeric marker is visualized in a different color, so that the number of centromeres per aberrant chromosome can be rapidly determined in the microscope by changing excitation and fluorescence filters.by H.F. Willard     

PNA beacons for duplex DNA

We report here on the hybridization of peptide nucleic acid (PNA)-based molecular beacons (MB) directly to duplex DNA sites locally exposed by PNA openers. Two stemless PNA beacons were tested, both featuring the same recognition sequence and fluorophore-quencher pair (Fluorescein and DABCYL, respectively) but differing in arrangement of these groups and net electrostatic charge. It was found that one PNA beacon rapidly hybridized, with the aid of openers, to its complementary target within duplex DNA at ambient conditions via formation of a PD-like loop. In contrast, the other PNA beacon bound more slowly to preopened duplex DNA target and only at elevated temperatures, although it readily hybridized to single-stranded (ss) DNA target. Besides a higher selectivity of hybridization provided by site-specific PNA openers, we expect this approach to be very useful in those MB applications when denaturation of the duplex DNA analytes is unfavorable or undesirable. Furthermore, we show that PNA beacons are advantageous over DNA beacons for analyzing unpurified/nondeproteinized DNA samples. This feature of PNA beacons and our innovative hybridization strategy may find applications in emerging fluorescent DNA diagnostics.     

Fast-in Situ hybridization and immunoenzymatic color pigment detection of mouse bone marrow micronucleus

The development of a whole mouse genomic DNA probe coupled to color pigment painting detection methodology can accurately verify mouse micronuclei induced by chemicals or drugs leading to a lower probability of potential artifacts. Using color pigment painting detection of probes in conjunction with Wright's Giemsa counterstain instead of the current fluorescence detection technology ensures low cost, high resolution permanent documentation of slides for a particular test compound. The permanent color pigment-detected micronuclei and adjoining counterstain allows slides to be stored for future analysis without enhancing the signal or adding antifading agents that are associated with fluorescence detection. Combining innovative technology such as fast-in situ hybridization of DNA probes with immunoenzymatic color pigment detection provides rapid verification of true micronuclei (DNA containing) within 2-3 hr.     

Molecular beacons for isothermal fluorescence enhancement by the cleavage of RNase HII from Chlamydia pneumoniae

This article describes a new assay for isothermal enhancement of fluorescence intensity. The assay is based on the cleavage of duplexes formed by the chimeric DNA-rN(1)-DNA molecular beacon (cMB) and target DNA with Chlamydia pneumoniae RNase HII (CpRNase HII). The loop sequence of the cMB, which was designed according to the target sequence, contains a single ribonucleotide. The combination of CpRNase HII cleavage and cMB (RHMB) permitted a 90-fold increase in fluorescence intensity change compared with the hybridization reaction in the presence of the same amount of target DNA. These results indicate that the RHMB assay can enhance the fluorescence signal in real-time monitoring of the target DNA.     

Efficient detection of secondary structure folded nucleic acids related to Alzheimer's disease based on junction probes

Single stranded DNA often forms stable secondary structures under physiological conditions. These DNA secondary structures play important physiological roles. However, the analysis of such secondary structure folded DNA is often complicated because of its high thermodynamic stability and slow hybridization kinetics. In this article, we demonstrate that Y-shaped junction probes could be used for rapid and highly efficient detection of secondary structure folded DNA. Our approach contained a molecular beacon (MB) probe and an assistant probe. In the absence of target, the MB probe failed to hybridize with the assistant probe. Whereas, the MB probe and the assistant probe could cooperatively unwind the secondary structure folded DNA target to form a ternary Y-shaped junction structure. In this condition, the MB probe was also opened, resulting in separating the fluorophores from the quenching moiety and emitting the fluorescence signal. This approach allowed for the highly sensitive detection of secondary structure folded DNA target, such as a tau specific DNA fragment related to Alzheimer's disease in this case. Additionally, this approach showed strong SNPs identifying capability. Furthermore, it was noteworthy that this newly proposed approach was capable of detecting secondary structure folded DNA target in cell lysate samples.     

Label-free electrical detection of DNA hybridization for the example of influenza virus gene sequences

Microarrays based on DNA-DNA hybridization are potentially useful for detecting and subtyping viruses but require fluorescence labeling and imaging equipment. We investigated a label-free electrical detection system using electrochemical impedance spectroscopy that is able to detect hybridization of DNA target sequences derived from avian H5N1 influenza virus to gold surface-attached single-stranded DNA oligonucleotide probes. A 23-nt probe is able to detect a 120-nt base fragment of the influenza A hemagglutinin gene sequence. We describe a novel method of data analysis that is compatible with automatic measurement without operator input, contrary to curve fitting used in conventional electrochemical impedance spectroscopy (EIS) data analysis. A systematic investigation of the detection signal for various spacer molecules between the oligonucleotide probe and the gold surface revealed that the signal/background ratio improves as the length of the spacer increases, with a 12- to 18-atom spacer element being optimal. The optimal spacer molecule allows a detection limit between 30 and 100 fmol DNA with a macroscopic gold disc electrode of 1 mm radius. The dependence of the detection signal on the concentration of a 23-nt target follows a binding curve with an approximate 1:1 stoichiometry and a dissociation constant of KD=13+/-4 nM at 295 K.     

Target accessibility and signal specificity in live-cell detection of BMP-4 mRNA using molecular beacons

The ability to visualize mRNA in single living cells and monitor in real-time the changes of mRNA level and localization can provide unprecedented opportunities for biological and disease studies. However, the mRNA detection specificity and sensitivity are critically dependent on the selection of target sequences and their accessibility. We carried out an extensive study of the target accessibility of BMP-4 mRNA using 10 different designs of molecular beacons (MBs), and identified the optimal beacon design. Specifically, for MB design 1 and 8 (MB1 and MB8), the fluorescent intensities from BMP-4 mRNA correlated well with the GFP signal after upregulating BMP-4 and co-expressing GFP using adenovirus, and the knockdown of BMP-4 mRNA using siRNA significantly reduced the beacon signals, demonstrating detection specificity. The beacon specificity was further confirmed using blocking RNA and in situ hybridization. We found that fluorescence signal from MBs depends critically on target sequences; the target sequences corresponding to siRNA sites may not be good sites for beacon-based mRNA detection, and vice versa. Possible beacon design rules are identified and approaches for enhancing target accessibility are discussed. This has significant implications to MB design for live cell mRNA detection.     

Light-up probes: thiazole orange-conjugated peptide nucleic acid for detection of target nucleic acid in homogeneous solution

We have constructed light-up probes for nucleic acid detection. The light-up probe is a peptide nucleic acid (PNA) oligonucleotide to which the asymmetric cyanine dye thiazole orange (TO) is tethered. It combines the excellent hybridization properties of PNA and the large fluorescence enhancement of TO upon binding to DNA. When the PNA hybridizes to target DNA, the dye binds and becomes fluorescent. Free probes have low fluorescence, which may increase almost 50-fold upon hybridization to complementary nucleic acid. This makes the light-up probes particularly suitable for homogeneous hybridization assays, where separation of the bound and free probe is not necessary. We find that the fluorescence enhancement upon hybridization varies among different probes, which is mainly due to variations in free probe fluorescence. For eight probes studied the fluorescence quantum yield at 25 degrees C in the unbound state ranged from 0.0015 to 0.08 and seemed to depend mainly on the PNA sequence. The binding of the light-up probes to target DNA is highly sequence specific and a single mismatch in a 10-mer target sequence was readily identified.     

Bis-pyrene-labeled molecular beacon: a monomer-excimer switching probe for the detection of DNA base alteration

A new bis-pyrene-labeled oligonucleotide probe (BP-probe) has been designed for the detection of a single base mismatch in single strand (ss) DNA as a target. The sequence of BP-probe was chosen to form stem-loop structure similar to a molecular beacon (MB-probe), yielding bis-pyrene-labeled molecular beacon (BP-MB-probe). Partially double stranded (ds) BP-MB-probes were prepared by complexation with oligonucleotides whose sequences are complementary to the loop segment but not to the stem and exchangeable with the target DNA. The partially ds BP-MB-probes were shown to exhibit monomer fluorescence as major fluorescence, while the ss BP-MB-probe in the stem-loop form displays strong excimer fluorescence. The strand exchange reactions between partially ds BP-MB-probe and target ss DNA in the presence of cationic comb-type copolymer as a catalyst were monitored by the excimer fluorescence changes. The existence of a mismatched base can be determined by the slower PASE rates compared with fully matched DNA.     

A versatile graphene-based fluorescence "on/off" switch for multiplex detection of various targets

We have designed a versatile molecular beacon (MB)-like probe for the multiplex sensing of targets such as sequence-specific DNA, protein, metal ions and small molecule compounds based on the self-assembled ssDNA-graphene oxide (ssDNA-GO) architecture. The probe employs fluorescence "on/off" switching strategy in a single step in homogeneous solution. Compared to traditional molecular beacons, the proposed design is simple to prepare and manipulate and has little background interference, but still gives superior sensitivity and rapid response. More importantly, this ssDNA-GO architecture can serve as a universal beacon platform by simply changing the types of ssDNA sequences for the different targets. In this work, the ssDNA-GO architecture probe has been successfully applied in the multiplex detection of sequence-specific DNA, thrombin, Ag(+), Hg(2+) and cysteine, and the limit of detection was 1 nM, 5 nM, 20 nM, 5.7 nM and 60 nM, respectively. The results demonstrate that the ssDNA-GO architecture can be an excellent and versatile platform for sensing multiplex analytes, easily replacing the universal molecular beacon.     

Sensitivity comparison of real-time PCR probe designs on a model DNA plasmid

We investigated three probe design strategies used in quantitative polymerase chain reaction (PCR) for sensitivity in detection of the PCR amplicon. A plasmid with a 120-bp insert served as the DNA template. The probes were TaqMan, conventional molecular beacon (MB), and shared-stem molecular beacon (ATssMB and GCssMB). A shared-stem beacon probe combines the properties of a TaqMan probe and a conventional molecular beacon. It was found that the overall sensitivities for the four PCR probes are in the order of MB>ATssMB>GCssMB>TaqMan. The fluorescence quantum yield measurements indicate that incomplete or partial enzymatic cleavage catalyzed by Taq polymerase is the likely cause of the low sensitivities of two shared-stem beacons when compared with the conventional beacon probe. A high-fluorescence background associated with the current TaqMan probe sequence contributes to the relatively low detection sensitivity and signal-to-background ratio. The study points out that the nucleotide environment surrounding the reporting fluorophore can strongly affect the probe performance in real-time PCR.     

Characterization and applications of CataCleave probe in real-time detection assays

Cycling probe technology (CPT), which utilizes a chimeric DNA-RNA-DNA probe and RNase H, is a rapid, isothermal probe amplification system for the detection of target DNA. Upon hybridization of the probe to its target DNA, RNase H cleaves the RNA portion of the DNA/RNA hybrid. Utilizing CPT, we designed a catalytically cleavable fluorescence probe (CataCleave probe) containing two internal fluorophores. Fluorescence intensity of the probe itself was weak due to F?rster resonance energy transfer. Cleavage of the probe by RNase H in the presence of its target DNA caused enhancement of donor fluorescence, but this was not observed with nonspecific target DNA. Further, RNase H reactions with CataCleave probe exhibit a catalytic dose-dependent response to target DNA. This confirms the capability for the direct detection of specific target DNA through a signal amplification process. Moreover, CataCleave probe is also ideal for detecting DNA amplification processes, such as polymerase chain reaction (PCR) and isothermal rolling circle amplification (RCA). In fact, we observed signal enhancement proportional to the amount of RCA product formed. We were also able to monitor real-time PCR by measuring enhancement of donor fluorescence. Hence, CataCleave probe is useful for real-time monitoring of both isothermal and temperature-cycling nucleic acid amplification methods.     

Label-free quantitative DNA detection using the liquid core optical ring resonator

We demonstrated quantitative real-time label-free detection of DNA sequences using the liquid core optical ring resonator (LCORR) sensor. The LCORR is a recently developed sensing platform that integrates microfluidics and photonic sensing technology with low detection limit and sub-nanoliter detection volume. We analyzed experimentally and theoretically the LCORR response to a variety of DNA samples that had different strand lengths (25-100 bases), number of base- mismatches (1-5), and concentrations (10 pM to 10 microM) to evaluate the LCORR sequence detection capability. In particular, we established the linear correlation between the LCORR sensing signal and the molecule density, which allows us to accurately calculate the molecule density on the surface. It is found that the probe surface coverage was 26-51% and the extent of hybridization was 40-50%. The titration curve for 25-base probe and 25-base target DNA yields a dissociation constant of 2.9 nM. With a 37.1 nm/RIU LCORR, detection of 10 pM bulk DNA concentration was demonstrated. The mass detection limit was estimated to be 4 pg/mm(2), corresponding to a density of 10(10) molecules/cm(2) on the surface. We also showed that the LCORR was sensitive enough to differentiate DNA with only a few base-mismatches based on the raw sensing signal and kinetic analysis. Our work will provide important insight into the light-DNA interaction at the ring resonator surface and lay a foundation for future LCORR-based DNA label-free microarray development.     

Nonenzymatic autoligation in direct three-color detection of RNA and DNA point mutations

Enzymatic ligation methods are useful in diagnostic detection of DNA sequences. Here we describe the investigation of nonenzymatic phosphorothioate-iodide DNA autoligation chemistry as a method for detection and identification of both RNA and DNA sequences. Combining ligation specificity with the hybridization specificity of the ligated product is shown to yield discrimination of a point mutation as high as >10(4)-fold. Unlike enzymatic ligations, this reaction is found to be equally efficient on RNA or DNA templates. The reaction is also shown to exhibit a significant level of self-amplification, with the template acting in catalytic fashion to ligate multiple pairs of probes. A strategy for fluorescence labeling of three autoligating energy transfer (ALET) probes and directly competing them for autoligation on a target sequence is described. The method is tested in several formats, including solution phase, gel, and blot assays. The ALET probe design offers direct RNA detection, combining high sequence specificity with an easily detectable color change by fluorescence resonance energy transfer (FRET).