UV- and visible-excited fluorescence of nucleic acids separated by capillary electrophoresis

UV- and visible-excited fluorescence detection strategies were compared for nucleic acids separated by capillary electrophoresis (CE). A dual-polymer sieving matrix consisting of hydroxypropylmethylcellulose and poly(vinylpyrrolidone) was used to separate DNA fragments from a 100-base pair ladder and RNA from individual cells. Two nucleic acid dyes, SYBR Gold and SYBR Green I, were evaluated for their performance at both UV (275 nm) and visible (488 nm) excitation wavelengths. While SYBR Gold-bound RNA from single cells yielded a substantially reduced UV-excited signal compared to that with visible excitation (as expected), the sensitivity of SYBR Gold-bound double-stranded DNA was comparable for UV and Vis excitation wavelengths. This study reveals the first demonstration of using SYBR Gold dyes for DNA detection following separation with CE and also the first example of SYBR-based detection of RNA sampled and separated from individual cells.     

Comparison of benzothiazole-based dyes for sensitive DNA detection

For efficient and quantitative DNA detection, fluorescence staining is the most often explored approach, which relies on non-covalent binding of dyes with double stranded DNA (dsDNA). Ethidium bromide (EB) is the most classic DNA stain, but suffers from its high carcinogenicity. A series of less toxic alternatives were developed, many of which contain the core structure of the benzothiazole ring. However, the relationship between the structure and the DNA detection performance was not illustrated. Herein, five benzothiazole dyes, namely thiazole orange, SYBR Green I, PicoGreen, SYBR Safe, and thioflavine-T, were compared for DNA detection through direct fluorescence and gel electrophoresis, with particular focus on the structure-performance relationship. It turned out that SYBR Green I is currently the best choice for DNA detection. The results in this work may be useful for future DNA-staining dye developments.     

Comparison of benzothiazole-based dyes for sensitive DNA detection

For efficient and quantitative DNA detection, fluorescence staining is the most often explored approach, which relies on non-covalent binding of dyes with double stranded DNA (dsDNA). Ethidium bromide (EB) is the most classic DNA stain, but suffers from its high carcinogenicity. A series of less toxic alternatives were developed, many of which contain the core structure of the benzothiazole ring. However, the relationship between the structure and the DNA detection performance was not illustrated. Herein, five benzothiazole dyes, namely thiazole orange, SYBR Green I, PicoGreen, SYBR Safe, and thioflavine-T, were compared for DNA detection through direct fluorescence and gel electrophoresis, with particular focus on the structure-performance relationship. It turned out that SYBR Green I is currently the best choice for DNA detection. The results in this work may be useful for future DNA-staining dye developments.     

Effect of nucleic acid binding dyes on DNA extraction,amplification, and STR typing

We report on the effects of six dyes used in the detection of DNA on the process of DNA extraction, amplification, and detection of STR loci. While dyes can be used to detect the presence of DNA, their use is restricted if they adversely affect subsequent DNA typing processes. Diamond? Nucleic Acid Dye, GelGreen?, GelRed?, RedSafe?, SYBR^® Green I, and EvaGreen? were evaluated in this study. The percentage of dye removed during the extraction process was determined to be: 70.3% for SYBR^® Green I; 99.6% for RedSafe?; 99.4% for EvaGreen?; 52.7% for Diamond? Dye; 50.6% for GelRed?, and; could not be determined for GelGreen?. It was then assumed that the amount of dye in the fluorescent quantification assay had no effect on the DNA signal. The presence of all six dyes was then reviewed for their effect on DNA extraction. The t‐test showed no significant difference between the dyes and the control. These extracts were then STR profiled and all dyes and control produced full DNA profiles. STR loci in the presence of GelGreen^TM at 1X concentration showed increased amplification products in comparison to the control samples. Full STR profiles were detected in the presence of EvaGreen? (1X), although with reduced amplification products. RedSafe? (1X), Diamond? Dye (1X), and SYBR^® Green I (1X) all exhibited varying degrees of locus drop‐out with GelRed? generating no loci at all. We provide recommendations for the best dye to visualize the presence of DNA profile as a biological stain and its subsequent amplification and detection.     

Photophysical properties of fluorescent DNA-dyes bound to single- and double-stranded DNA in aqueous buffered solution.

The absorption and fluorescence spectra, fluorescence quantum yields, lifetimes and time-resolved fluorescence spectra are reported for nine different fluorescent DNA-dyes. The work was initiated in search of a quantitative method to detect the ratio of single-to-double stranded DNA (ssDNA/dsDNA) in solution based on the photophysics of dye-DNA complexes; the result is a comprehensive study providing a vast amount of information for users of DNA strains. The dyes examined were the bisbenzimide or indole-derived stains (Hoechst 33342, Hoechst 33258 and 4',6-diamidino-2-phenylindole), phenanthridinium stains (ethidium bromide and propidium iodide) and cyanine dyes (PicoGreen, YOYO-1 iodide, SYBR Green I and SYBR Gold). All were evaluated under the same experimental conditions in terms of ionic strength, pH and dye-DNA ratio. Among the photophysical properties evaluated only fluorescence lifetimes for the cyanine stilbene dyes allowed a convenient differentiation between ssDNA and dsDNA. The bisbenzimide dyes showed multiexponential decays when bound to either form of DNA, making lifetime-based analysis cumbersome with inherent errors. These dyes also presented biexponential decay when free in aqueous buffered solutions at different pH. A mechanism for their deactivation is proposed based on two different conformers decaying with different kinetics. The phenanthridinium dyes showed monoexponential decays with ssDNA and dsDNA, but there was no discrimination between them. High dye-DNA ratios (e.g. 1:1) resulted in multiexponential decays for cyanine dyes, resulting from energy transfer or self-quenching deactivation. Shifts in both absorption and fluorescence maxima for both ssDNA and dsDNA DNA-cyanine dye complexes were small. Broadening of dye-ssDNA absorption and fluorescence bands for the cyanine dyes relative to dye-dsDNA bands was detected and attributed to higher degrees of rotational freedom in the former.     

Focusing and stabilization of bis‐intercalating dye–DNA complexes for high‐sensitive CE‐LIF DNA analysis

Multiple labeling of nucleic acids by intercalative dyes is a promising method for ultrasensitive nucleic acid assays. The properties of the fast dissociation and instability of dye–DNA complexes may prevent from their wide applications in CE‐LIF nucleic acid analysis. Here, we describe an optimum CE focusing method by using appropriately paired sample and separation buffers, Tris‐glycine buffer and Tris‐glycine‐acetic acid buffer. The developed method was applied in both uncoated and polyacrylamide coated fused‐silica capillary‐based CE‐LIF analysis while the sample and separation buffers were conversely used. The complexes of intercalative dye benzoxazolium‐4‐pyridinium dimer and dsDNA were greatly focused (separation efficiency: 1.8 million theoretical plates per meter) by transient isotachophoresis mechanism in uncoated capillary, and moderately focused by transient isotachophoresis in combination of field amplified sample stacking and further stabilized by the paired buffer in polyacrylamide coated capillary. Based on the developed focusing strategy, an ultrasensitive DNA assay was developed for quantitation of calf thymus dsDNA (from 0.02 to 2.14 pM). By the use of an excitation laser power as low as 1 mW, the detection limits of calf thymus dsDNA (3.5 kb) are 7.9 fM in concentration and 2.4×10^?22 mol (150 molecules) in mass. We further demonstrate that the non‐gel sieving CE‐LIF analysis of DNA fragments can be enhanced by the same strategy. Since the presented strategy can be applied to uncoated and coated capillaries and does not require special device, it is also reasonable to extend to the applications in chip‐based CE DNA analysis.     

Novel monofunctional and bifunctional boronic acid‐functionalized squarylium dyes as precolumn and on‐column labels for protein analysis by capillary electrophoresis with laser‐induced fluorescence

This article presents a continuous capillary electrophoresis with laser‐induced fluorescence (CE‐LIF) following spectral studies of the noncovalent interactions between novel Squarylium Boronic Acid 4 (SQ‐BA4) & Squarylium Diboronic Acid 2 (SQ‐DBA2) squarylium dyes and human serum albumin (HSA). Two protocols were used wherein the on‐column‐labeling protocol was found to be more sensitive than the precolumn one by showing a better enhancement in the peak area of the HSA–dye complex besides lower limits of detection (LODs) for HSA. Also, stability studies were conducted with or without HSA using precolumn‐labeling mode over one week exhibiting the superiority of SQ‐BA4 to SQ‐DBA2. Then, a mixture containing three model proteins, HSA, β‐lactoglobulin B, and transferrin, was labeled on‐column with both dyes and completely resolved by CE‐LIF after optimization of several parameters. Both dyes provided lower LODs for HSA than those of β‐lactoglobulin B and transferrin with higher sensitivities. In addition, the SQ‐BA4 dye showed again greater sensitivities with all the three proteins than SQ‐DBA2.     

Inverse-flow derivatization for capillary electrophoresis of DNA fragments with laser-induced fluorescence detection

A novel method is presented to detect DNA fragments separated by capillary electrophoresis (CE) with laser-induced fluorescence (LIF) detection using inverse-flow derivatization. In electrophoresis, the intercalating dye, thiazol orange was only added to the separation buffer at the positive polarity. The negatively charged DNA fragments migrated from the negative polarity to the positive polarity, while the positively charged dye migrated in the opposite direction. When DNA fragments met with dye ions, the DNA–dye complexes were formed. The complexes continued migrating to the positive end, due to their net negative charges. When the complexes passed through the detection window, the fluorescent signals were generated. Importantly, DNA fragments migrated as their native state before DNA–dye complexes were formed. This procedure was used to detect double stranded DNA (dsDNA) and single stranded DNA (ssDNA) fragments, and polymerase chain reaction (PCR) products. The excellent resolution and good reproducibility of DNA fragments were achieved in non-gel sieving medium. This procedure may be useful in genetic mutation/polymorphism detections.     

High-throughput analysis of telomerase by capillary electrophoresis

The enzyme telomerase is expressed in (85-90)% of all human cancers, but not in normal, non-stem cell somatic tissues. Clinical assays for telomerase in easily obtained body fluids would have great utility as noninvasive, cost-effective methods for the early detection of cancer. The most commonly used method for the detection and quantification of telomerase enzyme activity is the polymerase chain reaction (PCR)-based assay known as the telomerase repeat amplification protocol or TRAP assay. Most of the TRAP assay systems use a slab-gel based electrophoresis system to size and quantify the PCR-amplified extension products. We are developing high-throughput capillary electrophoresis (CE) methods for the analysis of TRAP/PCR products. The TRAP assay was conducted on lysates of the human lung cancer cell line A-549 in reactions containing 5-100 cells. TRAP/PCR products were generated using a fluorescent 4,7,2'4'5'7',-hexachloro-6-carboxyfluorescein(HEX)-labeled TS primer and analyzed on the Applied Biosystems Model 310 CE system using POP4 polymer. After analysis with GeneScan and Genotyper software, the total peak areas of the TRAP ladder extension products were computed using Microsoft Excel. Results were compared with unlabeled TRAP/PCR products analyzed on the Bio-Rad BioFocus 3000 CE system using 6% high molecular weight polyvinylpyrrolidone (HMW PVP) polymer and SYBR Green I dye. Both CE systems were able to resolve the TRAP ladder products with high reproducibility and sensitivity (5-15 cells). With the appropriate robotic sample handling system, these CE methods would enable performing the telomerase TRAP assay with increased sensitivity, reproducibility and automation over slab-gel methods.     

New unsymmetrical cyanine dyes for real-time thermal cycling

Asymmetric cyanine dyes bind to the minor groove of double stranded DNA (dsDNA) owing to their crescent configuration; therefore, these dyes are widely used as a dsDNA probes. BOXTO-MEE is derived from BOXTO by adding the polar methoxyethoxyethyl tail in order to increase solubility, dissociation rate kinetics, and stability. As a result, BOXTO-MEE showed significant reduction in nonspecific amplification (primer dimers) without significant effect on target sequence amplification, PCR efficiency, and standard curve correlation coefficient. BETIBO is another example of an asymmetric cyanine dye that can binds to dsDNA but is less efficient than BOXTO-MEE for use in real-time PCR. Statistical analysis of reproducibility results shows that BETIBO is not strong enough to be used for quantifying low nucleic acid quantities. Statistical analysis for BOXTO-MEE results shows that there is no significant difference between the efficiency and correlation coefficient achieved by BOXTO-MEE and SYBR Green I, but a significant difference in the dynamic range is observed because BOXTO-MEE has a wider dynamic range. BOXTO-MEE stock solution was stable at −20 °C for more than 1 year and 40 μM solution was stable for 45 days (at least) at 4 °C.     

Multiplexed DNA sizing by capillary electrophoresis using entangled polymer solutions and diode array detection

We developed a method for the analysis of multiplexed double-stranded DNA (dsDNA) samples complexed to various intercalating dyes using entangled polymer solution. A commercial single-column capillary electrophoresis (CE) instrument with diode array detection was used for multiplexed detection of DNA samples by addition of intercalating fluorescent molecules. A Phi X174HinfI and a pGEM DNA ladder (1 mg/mL) were used for the electrophoretic separation of dsDNA fragments ranging in size from 24 to 726 and 36 to 2645 bp, respectively. The results suggested that simultaneous electrophoretic separation of different DNA ladders multiplexed with different dyes could be performed in the same capillary yielding fast DNA sizing separations. CE analysis, which is often overpowered by slab gel in sample throughput, could now overcome this disadvantage by allowing multiplexed sample analysis in a fraction of the time needed for slab gel analysis. The separation efficiency of stained DNA molecules with both dyes were dramatically improved with buffers containing a large cation such as tetrapentylammonium ion (Npe(4) (+)) as the only cation in the buffer.     

Label-free fluorescent sensor for mercury(II) ion by using carbon nanotubes to reduce background signal

A simple, selective and sensitive turn-on fluorescent sensor for the detection of mercury(II) ion was developed using Sybr Green I as the signal reporter and SWCNTs as the quencher. Due to the affinity of SWCNTs towards ssDNA and organic dye, Sybr Green I, thymine-rich ssDNA and SWCNTs could form a self-assembly of three components, resulting in fluorescence quenching. Upon addition of another thymine-rich ssDNA and mercury(II) ion, formation of dsDNA via T-Hg(2+)-T base pairs enabled Sybr Green I to intercalate into the dsDNA, resulting in the restoration of fluorescence. SWCNTs were found to reduce the background signal and improve the analytical sensitivity. A linear relationship between the fluorescence intensity and the concentration of mercury(II) ion was observed in the range of 20-1250 nM (R = 0.9985) with a detection limit of 7.9 nM. The proposed method was applied to detect mercury(II) ion in tap water samples with good results.     

Proteinase assay by capillary electrophoresis employing fluorescence-quenched protein-dye conjugates

Determination of proteinases--enzymes that catalyze the hydrolysis of peptide bonds--is often difficult due to the presence of interferences in complex biological media and limited sample size. Capillary electrophoresis (CE), with laser-induced fluorescence (LIF) can serve as a useful tool for such determinations. LIF detection offers the advantages of increased sensitivity and increased selectivity. However, direct LIF detection requires the proteinase analyte to be fluorescently derivatized prior to analysis. A viable alternative is offered by the present work, in which protein substrates are first labeled with BODIPY dye, a relatively pH-insensitive, high-fluorescence quantum yield dye. Upon binding of some 4-10 molecules of dye to a single protein, the dye is effectively fluorescence-quenched. Digestion of the BODIPY--labeled and quenched protein by an unlabeled enzyme yields smaller peptide fragments in which the fluorescence of associated BODIPY tags is restored. We will present how the fragmentation pattern of BODIPY-labeled casein changes as a function of incubation time with trypsin, as well as the effect of varying concentrations of trypsin on the BODIPY-casein digest.     

Yoctomole analysis of ganglioside metabolism in PC12 cellular homogenates

We report an ultrasensitive method for the analysis of glycosphingolipid catabolism. The substrate G(M1) and the set of seven metabolites into which it can be degraded (G(A1), G(M2), G(A2), G(M3), LacCer, GlcCer, and Cer) were labeled with the highly fluorescent dye tetramethylrhodamine. CE with LIF detection was used to assay these compounds with 150 +/- 80 yoctomole mass (1 ymol = 10(-24) mol = 0.6 copies) detection limits and 5 +/- 3 pM concentration detection limits. An alignment algorithm based on migration of two components was employed to correct for drift in the separation. The within-day and between-day precision in peak height was 20%, in peak width 15%, and in adjusted migration time 0.03%. After normalization to total sample injected, the RSD in peak height reduced to 2-6%, which approaches the limit set by molecular shot noise in the number of molecules taken for analysis. PC12 cells were incubated with the labeled G(M1). Fluorescent microscopy demonstrated uptake by the cells. CE was used to separate a cellular homogenate prepared from these cells. A set of peaks was observed, which were tentatively identified based on comigration with the standards. Roughly 120 pL of homogenate was injected, which contained a total of 150 zmol of labeled substrate and products. Metabolite that preserves the fluorescent label can be detected at the yoctomole level, which should allow characterization of this metabolic pathway in single cells.     

The staining efficiency of cyanine dyes for single‐stranded DNA is enormously dependent on nucleotide composition

The staining of nucleic acids with fluorescent dyes is one of the most fundamental technologies in relevant areas of science. For reliable and quantitative analysis, the staining efficiency of the dyes should not be very dependent on the sequences of the specimens. However, this assumption has not necessarily been confirmed by experimental results, especially in the staining of ssDNA (and RNA). In this study, we found that both SYBR Green II and SYBR Gold did not stain either homopyrimidines or ssDNA composed of only adenine (A) and cytosine (C). However, these two dyes emit strong fluorescence when the ssDNA contains both guanine (G) and C (and/or both A and thymine (T)) and form potential Watson‐Crick base pairs. Interestingly, SYBR Gold, but not SYBR Green II, strongly stains ssDNA consisting of G and A (or G and T). Additionally, we found that the secondary structure of ssDNA may play an important role in DNA staining. To obtain reliable results for practical applications, sufficient care must be paid to the composition and sequence of ssDNA.     

Multiplexing N‐glycan analysis by DNA analyzer

Analysis of N‐glycan structures has been gaining attentions over the years due to their critical importance to biopharma‐based applications and growing roles in biological research. Glycan profiling is also critical to the development of biosimilar drugs. The detailed characterization of N‐glycosylation is mandatory because it is a nontemplate driven process and that significantly influences critical properties such as bio‐safety and bio‐activity. The ability to comprehensively characterize highly complex mixtures of N‐glycans has been analytically challenging and stimulating because of the difficulties in both the structure complexity and time‐consuming sample pretreatment procedures. CE‐LIF is one of the typical techniques for N‐glycan analysis due to its high separation efficiency. In this paper, a 16‐capillary DNA analyzer was coupled with a magnetic bead glycan purification method to accelerate the sample preparation procedure and therefore increase N‐glycan assay throughput. Routinely, the labeling dye used for CE‐LIF is 8‐aminopyrene‐1,3,6‐trisulfonic acid, while the typical identification method involves matching migration times with database entries. Two new fluorescent dyes were used to either cross‐validate and increase the glycan identification precision or simplify sample preparation steps. Exoglycosidase studies were carried out using neuramididase, galactosidase, and fucosidase to confirm the results of three dye cross‐validation. The optimized method combines the parallel separation capacity of multiple‐capillary separation with three labeling dyes, magnetic bead assisted preparation, and exoglycosidase treatment to allow rapid and accurate analysis of N‐glycans. These new methods provided enough useful structural information to permit N‐glycan structure elucidation with only one sample injection.     

Separation and determination of basic dyes formulated in hair care products by capillary electrophoresis

A capillary electrophoretic (CE) method for analyzing five basic dyes (Basic Red 76, Basic Brown 16, Basic Yellow 57, Basic Brown 17 and Basic Blue 99) sold under the trade name Arianor, which are commonly used in hair care products, has been established. A buffer of 100 mM acetic acid-ammonium acetate (50:50) containing 90% (v/v) methanol was employed in a fused-silica capillary of 40.0 cm x 50 microm I.D. with a bubble cell arrangement. Washing the capillary end immediately after injection was effective in preventing peak tailing of the basic dyes, which was due to their adsorption onto the outer wall of the capillary during the injection. Under these optimized conditions, acceptable results for reproducibility, limit of detection and quantitation, and linearity were obtained for the five authentic dyes tested. The recoveries of five authentic basic dyes spiked to three commercial hair care products also provided with acceptable results. This optimized CE method is useful for the analysis of mixed basic dyes in hair care products.     

Capillary electrophoresis with dual laser detection in separation of amplified fragment length polymorphism fragments

We are presenting the application of CE technique with dual‐channel LIF detection for the simultaneous separation of DNA fragments labeled with two different fluorescence dyes. The optimal conditions of the analysis were determined for the separation of amplified fragment length polymorphism (AFLP) fragments labeled with 5′‐6‐carboxyfluorescein (6‐FAM) and the DNA size standard labeled with sulfoindocyanine succinimidyl ester (Cy‐5). CE equipped with both argon ion and diode lasers is a good alternative for sequencers and might be applied in analyses of PCR products generated by various fingerprinting methods.