Signal amplification in flow cytometry using biotin tyramine.

BACKGROUND: Catalysed reporter deposition (CARD) has been successfully used as a means of signal amplification in solid-phase immunoassays. The procedure relies on the use of horseradish peroxidase (HRP)-conjugated reagents--normally antibodies-in conjunction with substituted phenolic compounds such as biotin tyramine. The HRP catalyses deposition of biotin tyramine around the site of enzyme activity, and streptavidin-HRP can then be added to generate an amplified HRP signal. The possibility of using this technique for solution-phase amplifications has been suggested but not yet demonstrated. METHODS: This paper describes the application of CARD to signal enhancement in flow cytometry. The specific examples described here are those of anti-human CD4 and anti-human CD36 antibodies binding to either human lymphocytes or mixed mononuclear cells. RESULTS: Optimum biotin tyramine concentrations were evaluated, and a fivefold increase in signal was observed over standard detection of the anti-human CD4 antibody with anti-mouse-fluorescein isothiocyanate (FITC). In the example using the anti-CD36 antibody, the biotin tyramine treatment was repeated, resulting in an additional 2.5-fold signal amplification. CONCLUSIONS: The technique described in this report provides a method of amplifying the signals achieved by standard flow cytometry detection reagents.     

Protein detection enhanced by 3DNA dendrimer signal amplification

DNA dendrimers, conjugated with both anti-biotin antibodies and up to 350 labeling entities, were designed and adapted to protein microarray and enzyme-linked immunosorbent assay (ELISA) to improve the limits of protein detection with no additional steps or equipment. Application of conjugated dendrimers to standard ELISA cytokine detection resulted in up to threefold improvement of the limits of detection with no significant increase in the inter- and intra-assay coefficient of variation (CV) compared to streptavidin horseradish peroxidase (SA-HRP) detection. The adaptation of conjugated dendrimers to protein microarray cytokine detection resulted in up to 10-fold improvement of the limits of detection, but assay conditions would have to be optimized to decrease the intra- and inter-assay %CVs.     

DNA detection by strand displacement amplification and fluorescence polarization with signal enhancement using a DNA binding protein.

Strand displacement amplification (9SDA) is an isothermal in vitro method of amplifying a DNA sequence prior to its detection. We have combined SDA with fluorescence polarization detection. A 5'-fluorescein-labelled oligodeoxynucleotide detector probe hybridizes to the amplification product that rises in concentration during SDA and the single- to double strand conversion is monitored through an increase in fluorescence polarization. Detection sensitivity can be enhanced by using a detector probe containing an EcoRI recognition sequence at its 5'-end that is not homologous to the target sequence. During SDA the probe is converted to a fully double-stranded form that specifically binds a genetically modified form of the endonuclease EcoRI which lacks cleavage activity but retains binding specificity. We have applied this SDA detection system to a target sequence specific for Mycobacterium tuberculosis.     

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.     

Novel signal amplification technology with applications in DNA and protein detection systems.

A non-enzymatic approach to signal amplification has practical advantages over conventional target amplification methods. We have designed a simple, cost-efficient signal amplification system that can be used to enhance the detection of nucleic acids or protein. The signal amplification process requires initial capture of analyte by a specific probe, which, depending on the analyte, can be an oligomer or an antibody. Once the analyte is captured, amplification moieties are applied to significantly enhance the sensitivity of analyte detection. Nucleic acid amplification is typically greater than 1000-fold, increasing the sensitivity of target detection to less than 1 amol/100 microL. This amplification strategy presents a very flexible system with components that are easily altered to accommodate diverse assay requirements.     

Sequence specific detection of DNA using nicking endonuclease signal amplification (NESA)

We have developed a new method for identifying specific single- or double-stranded DNA sequences called nicking endonuclease signal amplification (NESA). A probe and target DNA anneal to create a restriction site that is recognized by a strand-specific endonuclease that cleaves the probe into two pieces leaving the target DNA intact. The target DNA can then act as a template for fresh probe and the process of hybridization, cleavage and dissociation repeats. Laser-induced fluorescence coupled with capillary electrophoresis was used to measure the probe cleavage products. The reaction is rapid; full cleavage of probe occurs within one minute under ideal conditions. The reaction is specific since it requires complete complementarity between the oligonucleotide and the template at the restriction site and sufficient complementarity overall to allow hybridization. We show that both Bacillus subtilis and B. anthracis genomic DNA can be detected and specifically differentiated from DNA of other Bacillus species. When combined with multiple displacement amplification, detection of a single copy target from less than 30 cfu is possible. This method should be applicable whenever there is a requirement to detect a specific DNA sequence. Other applications include SNP analysis and genotyping. The reaction is inherently simple to multiplex and is amenable to automation.     

Simultaneous detection of six human diarrheal pathogens by using DNA microarray combined with tyramide signal amplification

Multiplex PCR and DNA microarray were combined with tyramide signal amplification (TSA) to develop a reliable method suitable for simultaneous detection of six species of human diarrheal pathogens (Yersinia enterocolitica, Shigella spp, Salmonella typhi, Brucella spp, Vibrio cholera and Escherichia coli O157:H7). Meanwhile, our method could distinguish V. cholera serotype O1 from O139, and O157:H7 from O157: non-H7. This assay conferred a specificity of 100% for target pathogens. The limit of detection was 103 degrees CFU/mL approximately. The results of 98.6% (357/362) clinical specimens and 100% (5/5) mocked double-blind samples were the same to that from conventional assay. Consequently this assay is sensitive and a specific tool suitable for diagnostic detection and surveillance of multiple human pathogens.     

Exonuclease III-based and gold nanoparticle-assisted DNA detection with dual signal amplification

Herein we report a sensitive electrochemical biosensor for DNA detection by making use of exonuclease III and probe DNA functionalized gold nanoparticles. While probe DNA P1 modified on a gold electrode surface can self-hybridize into a stem-loop structure with an exonuclease III-resistant 3' overhang end, in the presence of target DNA, P1 may also hybridize with the target DNA to form a duplex region. Therefore, exonuclease III may selectively digest P1 from its 3'-hydroxyl termini until the duplex is fully consumed. Since a single target DNA can trigger exonuclease III digestion of numerous P1 strands, the first signal amplification is achieved. On the other hand, since the digested P1, exposing its complementary sequence to probe DNA P2, can further hybridize with P2 that has been previously modified on the surface of gold nanoparticles, many nanoparticles loaded with numerous DNA strands are immobilized onto the electrode surface. Consequently, large amount of electroactive molecules [Ru(NH(3))(6)](3+) can bind with the DNA strands to produce an intense electrochemical response as the second signal amplification. Based on the studies with cyclic voltammetry (CV) and chronocoulometry (CC) techniques, the proposed biosensor can sensitively detect specific target DNA at a picomolar level with high specificity.     

Multiparameter DNA flow cytometry of keratoacanthoma.

Keratoacanthomas (KAs) are rapidly growing cutaneous lesions that frequently look much like well-differentiated squamous cell carcinomas (SCCs) but spontaneously regress. It is uncertain whether KA is a reactive hyperplastic lesion that mimics a neoplasm or a true (but defective) neoplasm that cannot sustain progressive growth. To address this question, we performed DNA flow cytometric analysis on 14 KAs and 10 cutaneous SCCs for comparison. By multiparameter DNA flow cytometry using forward scatter and orthogonal scatter, 10 KAs and 4 SCCs had peridiploid DNA aneuploid populations (DNA indices of 1.03-1.14), and 2 SCCs had grossly aneuploid populations (DNA index, 1.69 and 2.33). Our data thus support aneuploidy in KAs. It is argued that KA is a true neoplasm.     

A signal amplification assay for HSV type 1 viral DNA detection using nanoparticles and direct acoustic profiling

Background  

Nucleic acid based recognition of viral sequences can be used together with label-free biosensors to provide rapid, accurate confirmation of viral infection. To enhance detection sensitivity, gold nanoparticles can be employed with mass-sensitive acoustic biosensors (such as a quartz crystal microbalance) by either hybridising nanoparticle-oligonucleotide conjugates to complimentary surface-immobilised ssDNA probes on the sensor, or by using biotin-tagged target oligonucleotides bound to avidin-modified nanoparticles on the sensor. We have evaluated and refined these signal amplification assays for the detection from specific DNA sequences of Herpes Simplex Virus (HSV) type 1 and defined detection limits with a 16.5 MHz fundamental frequency thickness shear mode acoustic biosensor.     

Multiplexed detection of pathogen DNA with DNA-based fluorescence nanobarcodes

Rapid, multiplexed, sensitive and specific molecular detection is of great demand in gene profiling, drug screening, clinical diagnostics and environmental analysis. One of the major challenges in multiplexed analysis is to identify each specific reaction with a distinct label or 'code'. Two encoding strategies are currently used: positional encoding, in which every potential reaction is preassigned a particular position on a solid-phase support such as a DNA microarray, and reaction encoding, where every possible reaction is uniquely tagged with a code that is most often optical or particle based. The micrometer size, polydispersity, complex fabrication process and nonbiocompatibility of current codes limit their usability. Here we demonstrate the synthesis of dendrimer-like DNA-based, fluorescence-intensity-coded nanobarcodes, which contain a built-in code and a probe for molecular recognition. Their application to multiplexed detection of the DNA of several pathogens is first shown using fluorescence microscopy and dot blotting, and further demonstrated using flow cytometry that resulted in detection that was sensitive (attomole) and rapid.     

HPV DNA detection by in situ hybridization with catalyzed signal amplification on thin-layer cervical smears.

Thin layer-based technology in cervical cancer screening now allows both Papanicolaou staining and HPV testing on the same sample. Here, we show that in situ hybridization with catalyzed reporter deposition is a powerful HPV detection method when applied on thin-layer cervical smears, allowing distinction between two staining patterns suggestive of two different physical states of HPV DNA, where diffuse signals are suggestive of episomes and punctate signals are suggestive of viral DNA integration.     

Laser flow cytometry and cancer chemotherapy: detection of intracellular anthracyclines by flow cytometry.

The intracellular distribution of important chemotherapeutic antibiotics belonging to the anthracycline group (e.g. adriamycin) can be detected by laser flow cytometry. The indirect method is based on the interference of these compounds with the binding of propidium iodide to the nuclear DNA. While in the direct method, the intracellular fluorescence of these antibiotics is excited and detected with a laser beam in a flow system. The present report demonstrates the use of these two methods for intracellular detection and quantitation of a number of important anthracyclines.     

Measurement of DNA damage in mammalian cells using flow cytometry

A technique for the detection of DNA damage induced by radiation insult has been developed. Cells were lysed with a buffer containing 2 M sodium chloride to release the DNA in a supercoiled form, the nucleoid. These were stained with the DNA intercalating dye, ethidium bromide, and exposed to laser light within a flow cytometer. Scattered and fluorescent light was analyzed from the laser/nucleoid interaction following irradiation of viable cells with gamma rays. The addition of ethidium bromide to prepared nucleoids caused a reduction in scattered light due to condensation of the nucleoid. Irradiation of cells prior to nucleoid production and ethidium bromide treatment restricted this condensation and produced a dose-dependent increase in laser scatter. Nucleoids derived from human lymphocytes showed enhanced light scatter from 5 Gy, compared to Chinese hamster ovary (CHO) fibroblasts where doses above 10 Gy were required. Up to 30 Gy CHO nucleoids showed a dose-dependent reduction in the ethidium bromide fluorescence. This technique allows detection of altered light scattering and fluorescent behavior of nucleoids after cellular irradiation; these may be related to structural changes within the nucleus induced by the radiation. The use of flow cytometry compared to other methods allows a rapid analysis of nuclear damage within individual cells.     

Fluorescent DNA probes for flow cytometry. Considerations and prospects.

Techniques employing base specific deoxyribonucleic acid (DNA)-binding fluorochromes and flow cytometry (FCM) are potentially useful for obtaining information of the compositional features of chromatin or chromosomes of mammalian cells. Fluorescent compounds which form complexes preferentially at the A-T rich regions (i.e., DNA-reactive Hoechst dyes) or the G-C rich regions (i.e., mithramycin, chromomycin, olivomycin) in DNA are available and compatible with current FCM technology as are other compounds (i.e., ethidium bromide, propidium iodide) which show little or no base specificity and bind by intercalation in the double stranded regions of helical DNA. Energy transfer between appropriate DNA-bound dyes is a reflection of the quantity and proximity of regions containing the respective base pair segments. Since extrinsic fluorescent probes provide only a measure of available binding sites or regions unobstructed by chromatin-associated or chromosomal-associated proteins, interpretations of fluorescence measurements need to be substantiated by adequate control measures.     

A DNA intercalation-based electrochemical method for detection of Chlamydia trachomatis utilizing peroxidase-catalyzed signal amplification

A sensitive electrochemical DNA detection method for the diagnosis of sexually transmitted disease (STD) caused by Chlamydia trachomatis was developed. The method utilizes a DNA-intercalating agent and a peroxidase promoted enzymatic precipitation reaction and involves the following steps. After hybridization of the target C. trachomatis gene with an immobilized DNA capture probe on a gold electrode surface, the biotin-tagged DNA intercalator (anthraquinone) was inserted into the resulting DNA duplex. Subsequently, the polymeric streptavidin/peroxidase complex was applied to the biotin-decorated electrode. Peroxidase catalyzed 4-chloronaphthol to produce insoluble product, which is precipitated on the electrode surface in the presence of hydrogen peroxide. Cyclic voltammograms with the gold electrode exhibited a peak current of ferrocenemethanol in electrolyte, which decreased in a proportional way to increasing concentration of target DNA owing to insulation of electrode surface by the growing insoluble precipitate. Using this strategy, we were able to detect picomolar concentrations of C. trachomatis gene in a sample taken from a real patient.     

Sub-femtomolar electrochemical detection of DNA using surface circular strand-replacement polymerization and gold nanoparticle catalyzed silver deposition for signal amplification

A highly sensitive method was developed for detection of target DNA. This method combined circular strand-displacement polymerization (CSRP) with silver enhancement to achieve dual signal amplification. After molecular beacon (MB) hybridized with target DNA, the reporter gold nanoparticle (Au NPs) was attached to an electrode surface by hybridization between Au NP labeled primer and stem part of the MB to initiate a polymerization of DNA strand, which led to the release of target and another polymerization cycle. Thus the CSRP produced the multiplication of target-related reporter Au NPs on the surface. The Au NPs then catalyzed silver deposition for subsequent stripping analysis of silver. The dual signal amplification offered a dramatic enhancement of the stripping response. This signal could discriminate perfect matched target DNA from 1-base mismatch DNA. The dynamic range of the sequence-specific DNA detection was from 10(-16) to 10(-12)molL(-1) with a detection limit down to sub-femtomolar level. This proposed method exhibited an efficient amplification performance, and would open new opportunities for sensitive detection of other biorecognition events.