Characterization of dye-induced mobility shifts affecting DNA sequencing in poly(ethylene oxide) sieving matrix

The influence of three classes of fluorescence labels including dipyrrometheneboron difluoride (BODIPY), energy transfer (ET) and conventional fluorescein and rhodamine (ABI), on DNA sequencing has been examined with laser-induced fluorescence detection and poly(ethylene oxide)-filled capillary electrophoresis. DNA sequencing fragments were generated by dye-labeled primer cycle-sequencing reactions in a hot-air thermal cycler. A parameter, relative-induced shift, was introduced to quantify the uniformity of electrophoretic mobilities of these fragments. BODIPY was found to have the smallest, but nonzero, effect for dye-induced nonuniformity. Although ET dyes provided the highest sensitivity due to their unique spectroscopic properties, they were found to lack photostability compared to BODIPY and ABI dyes. Characterization also brings out some important tips for selecting the suitable dye set for the two-channel ratio-based DNA base-calling method.     

Near-infrared heavy-atom-modified fluorescent dyes for base-calling in DNA-sequencing applications using temporal discrimination

A series of near-IR fluorescent dyes were prepared which contained an intramolecular heavy atom for altering the fluorescence lifetimes to produce a set of probes appropriate for base-calling in a single-lane DNA sequencing format. The heavy-atom modification consisted of an intramolecular halogen situated on a remote section of the chromophore in order to minimize the perturbation on the lifetimes and fluorescence quantum yields. In addition, the dye series possessed an isothiocyanate functional group to allow facile attachment to sequencing primers. The unconjugated dyes showed similar absorption and emission maxima (lambda abs = 765-768 nm; lambda em = 794-798 nm) as well as fluorescence quantum yields that were invariant, within experimental error, with the heavy atom. However, the lifetimes of these dyes were found to vary with the identity of the halogen substitution (I, tau f = 947 ps; F, tau f = 843 ps, measured in methanol), with an average variation within the dye series of 35 ps. The spectroscopic properties of the free dyes and the dyes conjugated to sequencing primers on the 5'-end of the oligonucleotide were determined in a DNA-sequencing matrix (denaturing gels containing formamide). The results indicated slight differences in the fluorescence properties of the free dyes compared to those of the dye/ primer conjugates in this particular matrix. Inspection of the ground-state absorption spectra showed significant aggregation for the free dyes in this solution, but the conjugated dyes exhibited no sign of aggregation due to the highly anionic nature of the oligonucleotide. The fluorescence lifetimes of the dye/primer conjugates demonstrated lifetimes which ranged from 735 to 889 ps, with an average variation of 51 ps, an adequate difference to allow facile discrimination of these dyes in DNA-sequencing conditions. In addition, the free solution electrophoretic mobilities of the native heavy-atom-modified dyes were found to be very similar. When the dye/primer conjugates were electrophoresed in a cross-linked polyacrylamide gel electrophoresis capillary column, they comigrated, indicating that, in single-lane sequencing applications, when utilizing these dyes, no postrun corrections would be required to correct for dye-dependent mobility shifts.     

Two color hybridization analysis using high density oligonucleotide arrays and energy transfer dyes

High density oligonucleotide arrays (DNA chips) have been used in two color mutational analysis of the 3.43 kb exon 11 of the hereditary breast and ovarian cancer gene BRCA1 . Two color analysis allows competitive hybridization between a reference standard and an unknown sample, improving the performance of the assay. Fluorescein and phycoerythrin dyes werepreviously used due to their compatibility with a single line 488 nm excitation source. Here we show that an alternative dye combination, containing the energy transfer dye system phycoerythrin*cy5 along with phycoerythrin, provides more evenly matched signal intensities and decreased spectral overlap between the two fluorophores, while maintaining compatibility with a 488 nm excitation source.     

Simple miniaturized gel system for DNA sequence analysis

A simple miniaturized gel system suitable for DNA sequencing is described. Small ultrathin polyacrylamide gels are cast, eight or more at a time, using standard microscope slides. Gels, ready to use, can be stored for approximately 2 weeks. Gels are run horizontally in a standard mini-agarose gel apparatus. Typical run times are 6-8 min. A novel sample loading system permits volumes of standard sequencing reactions as small as 0.1 microl to be analyzed. Sequencing ladders were visualized using 35S-labeled DNA by autoradiography and by colorimetric detection. Band resolution compares favorably with that of large gels. The methods introduced here serve as a step toward the miniaturization of DNA sequencing and are amenable to automated sample loading and detection.     

Rapid sequencing of the p53 gene with a new automated DNA sequencer

p53 is the most commonly mutated gene in human cancers. Approximately 90% of the p53 gene mutations are localized between domains encoding exons 5 to 8. Sequencing methods currently available are tedious and time-consuming and are not suitable for routine laboratory testing. In an effort to identify a simple and rapid sequencing method, we analyzed 16 preselected breast tumors and 18 preselected ovarian tumors, using a newly developed automated DNA sequencer. p53 gene mutations had been previously identified in these tumors, using a conventional automated sequencing procedure. Exons 5 to 8 were amplified by PCR, and the PCR products were subsequently subjected to cycle sequencing with the Sanger chain termination method, using Cy5.5-labeled primers. The sequencing mixture was then resolved on a newly developed automated DNA sequencer that can sequence approximately 300 bases of DNA in 30 min. Of these 16 breast tumors, two had mutations in exon 5, four in exon 6, three in exon 7, and three in exon 8. Of the 18 ovarian tumors, two had mutations in exon 5, five in exon 6, two in exon 7, and three in exon 8. In all cases, we identified the same mutations by both the new and the conventional sequencing procedures. Most mutations affected an arginine codon. These data demonstrate that the new method has the capability to provide accurate sequencing information in a fraction of the time and labor in comparison with current automated sequencing techniques. When such procedures are used, DNA sequencing may become a routine tool for identifying clinically important mutations for diagnosis and prognosis of patients with genetic, malignant, infectious, and other diseases.     

Orphan peak analysis: a novel method for detection of point mutations using an automated fluorescence DNA sequencer

Automated DNA sequencers draw the four-base profiles of a sample with four different colors, but it is also possible to draw the profiles of a base-specific reaction of four different samples with four colors. PCR-amplified DNAs from four individuals were subjected to a single base-specific sequencing reaction and the products were applied to a set of four lanes of an automated DNA sequencer. A base substitution in an individual was clearly identified as an individual-specific peak with a color specific for the individual. In this way, we analyzed more than 50 individuals and identified several polymorphic base substitutions. The sensitivity of this method was high enough to allow detection of the mutation/polymorphism even if samples from several individuals were applied to one lane. Thus, our method is applicable to screening of a large number of samples in an automated manner.     

Fluorescence energy transfer as a probe for tetraplex formation: the i-motif

The secondary structure of cytosine-rich oligodeoxynucleotides has been investigated with fluorescent probes. Intramolecular folding of an oligonucleotide into an i-DNA motif led to fluorescence excitation energy transfer between a donor (fluorescein) and an acceptor (tetramethylrhodamine) covalently attached to the 5' and 3' ends of the DNA, respectively, provided that a suitable linker was chosen. The conjugation of the dyes to the oligonucleotide had an influence on the thermodynamics of i-motif formation as well as on the kinetics of folding. Intramolecular folding was demonstrated from the concentration independence of FRET over a wide concentration range. Folding of the oligonucleotide was confirmed by UV absorption melting experiments. The folding of the i-motif could be followed at concentrations as low as 50 pM. Fluorescence energy transfer can thus be used to reveal the formation of multistranded DNA structures.     

Peak oxygen uptake, muscle volume, and the growth hormone-insulin-like growth factor-I axis in adolescent males

OBJECTIVES: To define the molecular genetic basis of the MELAS phenotype in five patients without any known mutation of mitochondrial DNA. METHODS: Systematic automated mitochondrial DNA sequencing of all mitochondrial transfer RNA and cytochrome c oxidase genes was undertaken in five patients who had the MELAS phenotype. RESULTS: A novel heteroplasmic mitochondrial DNA mutation was identified in the transfer RNA gene for phenylalanine in one case (patient 3). This mutation was not detected in the patient's blood or in her mother's blood. No pathogenic mutations were identified in the other four patients. CONCLUSIONS: This is the first point mutation in the transfer RNA gene for phenylalanine to be associated with MELAS. The absence of mutations in the remaining four patients suggests that there is further genetic heterogeneity associated with this mitochondrial phenotype.     

The immune response to soluble D10 TCR: analysis of antibody and T cell responses

Interactions between short single-stranded DNA ligands and fluorescent DNA indicator dyes were used to investigate binding selectivity of the ligands. Conformational differences among four DNA ligands of different sequence and structure, including two that form a G-quartet and two that do not, were confirmed by circular dichroism spectroscopy. Their interactions with indicator dyes YO-pro-1 iodide (YO) and YOYO-1 iodide (YOYO) were probed using measurements of dye absorbance; induced circular dichroism; and fluorescence spectra, anisotropy, and lifetime. Equilibrium binding constants and stoichiometry were determined as well. Results indicate significant differences among the dye interactions and binding stoichiometries of the four ligands. One of the G-quartet forming ligands, a 20-mer of sequence 5'-GGTTTTGGTTTTGGTTTTGG-3', shows distinctly different interactions from the other three ligands, all of which are 15-mers. These studies illustrate the importance of sequence and conformation in determining the binding interactions of short single-stranded DNA.     

Manganese citrate improves base-calling accuracy in DNA sequencing reactions using rhodamine-based fluorescent dye-terminators

While dideoxy-terminators labeled with rhodamine-based fluorescent dyes provide the most versatile method of automated DNA sequencing, variation in peak heights reduces base-calling accuracy. We describe a simple approach that uses additions of a manganese salt and the metal buffer sodium citrate (MnCit) to overcome this limitation. This modification reduces peak height variability >2-fold and significantly increases the number of accurately read bases in DNA sequences.     

Fiber bundle based scanning detection system for automated DNA sequencing

High-throughput DNA sequencing techniques are under rapid development currently, mainly triggered by the Human Genome Project. At the present time, slab gel based automated DNA sequencing is the standard procedure, utilizing fluorophore labeling and laser-induced fluorescence detection with scanning technology. In this paper, a novel, fiber-optic bundle based detection system is introduced, where a central illuminating fiber is used for the excitation of the electrophoretically separated fluorophore-labeled DNA sequencing fragments, along with several collecting fibers disposed around the illuminating fiber to collect the emitted fluorescent signal. As a model system, Cy5-labeled DNA sequencing fragments were separated on an ultrathin polyacrylamide slab gel and detected by the fiber bundle based laser-induced fluorescence detection system. A 640-nm diode laser was used to generate the illumination beam, and the emitted light collected by the fiber bundle was detected by a solid-state avalanche photodiode.     

Tracing of dye molecules in living plants through NaGdF4:Yb3+,Er3+ fluorescent nanoprobes

In this paper, we demonstrated trace of dye molecules in living plants. The NaGdF₄:Yb³⁺,Er³⁺ nanoparticles probe was used to detect the rhodamine B (RhB) in bean sprout. It is found that the fluorescencedye can be efficiently imbibed during the growing process and the absorbance presented a position dependence effect, which was supported by the upconversion spectra and the fluorescent image characterization. In addition, the concentration of the residual RhB in bean sprout can be efficiently traced by the synthesized probe based on the fluorescent resonant energy transfer. Finally, the relation between the excitation power, concentration and the ratio of yellow to green emission are discussed in detail. These results can be helpful in understanding the RhB dye molecules absorbance process in vegetable growth and provide an efficient way to trace the residual dyes in vivo plant.     

Kinetic analysis of pairing and strand exchange catalyzed by RecA. Detection by fluorescence energy transfer

RecA is a 38-kDa protein from Escherichia coli that polymerizes on single-stranded DNA, forming a nucleoprotein filament that pairs with homologous duplex DNA and carries out strand exchange in vitro. In this study, we measured RecA-catalyzed pairing and strand exchange in solution by energy transfer between fluorescent dyes on the ends of deoxyribo-oligonucleotides. By varying the position of the dyes in separate assays, we were able to detect the pairing of single-stranded RecA filament with duplex DNA as an increase in energy transfer, and strand displacement as a decrease in energy transfer. With these assays, the kinetics of pairing and strand displacement were studied by stopped-flow spectrofluorometry. The data revealed a rapid, second order, reversible pairing step that was followed by a slower, reversible, first order strand exchange step. These data indicate that an initial unstable intermediate exists which can readily return to reactants, and that a further, rate-limiting step (or steps) is required to effect or complete strand exchange.     

Application of fluorescence resonance energy transfer in the clinical laboratory: routine and research

Fluorescence resonance energy transfer (FRET) phenomenon has been applied to a variety of scientific challenges in the past. The potential utility of this biophysical tool will be revisited in the 21st century. The rapid digital signal processing in conjunction with personal computers and the wide use of multicolor laser technology in clinical flow cytometry opened an opportunity for multiplexed assay systems. The concept is very simple. Color-coded microspheres are used as solid-phase matrix for the detection of fluorescent labeled molecules. It is the homogeneous assay methodology in which solid-phase particles behave similarly to the dynamics of a liquid environment. This approach offers a rapid cost-effective technology that harnesses a wide variety of fluorochromes and lasers. With this microsphere technology, the potential applications for clinical flow cytometry in the future are enormous. This new approach of well-established clinically proven methods sets the stage to briefly review the theoretical and practical aspects of FRET technology. The review shows various applications of FRET in research and clinical laboratories. Combination of FRET with monoclonal antibodies resulted in a boom of structural analysis of proteins in solutions and also in biological membranes. Cell surface mapping of cluster of differentiation molecules on immunocompetent cells has gained more and more interest in the last decade. Several examples for biological applications are discussed in detail. FRET can also be used to improve the spectral characteristics of fluorescent dyes and dye combinations, such as the tandem dyes in flow and image cytometry and the FRET primers in DNA sequencing and polymerase chain reactions. The advantages and disadvantages of donor-acceptor dye combinations are evaluated. In addition, the sensitivity of FRET provides the basis for establishing fast, robust, and accurate enzyme assays and immunoassays. Benefits and limitations of FRET-based assays are thoroughly scrutinized. At the end of the paper we review the future of FRET methodology.     

Pyridyloxobutyl adduct O6-[4-oxo-4-(3-pyridyl)butyl]guanine is present in 4-(acetoxymethylnitrosamino)-1-(3-pyridyl)-1-butanone-treated DNA and is a substrate for O6-alkylguanine-DNA alkyltransferase

The lung carcinogen 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK) is activated to reactive metabolites that methylate or pyridyloxobutylate DNA. Previous studies demonstrated that pyridyloxobutylated DNA interferes with the repair of O6-methylguanine (O6-mG) by O6-alkylguanine-DNA alkyltransferase (AGT). The AGT reactivity of pyridyloxobutylated DNA was attributed to (pyridyloxobutyl)guanine adducts. One potential AGT substrate adduct, 2'-deoxy-O6-[4-oxo-4-(3-pyridyl)butyl]guanosine (O6-pobdG), was prepared. This adduct was stable at pH 7.0 for greater than 13 days and to neutral thermal hydrolysis conditions (pH 7.0, 100 degrees C, 30 min). Under mild acid hydrolysis conditions (0.1 N HCl, 80 degrees C), O6-pobdG was depurinated to yield O6-[4-oxo-4-(3-pyridyl)butyl]guanine (O6-pobG). O6-pobdG was hydrolyzed to 4-hydroxy-1-(3-pyridyl)-1-butanone and guanine under strong acid hydrolysis conditions (0.8 N HCl, 80 degrees C). O6-pobG was detected in 0.1 N HCl hydrolysates of DNA alkylated with the model pyridyloxobutylating agent 4-(acetoxymethylnitrosamino)-1-(3-[5-3H]pyridyl)-1-butanone ([5-3H]NNKOAc). When [5-3H]NNKOAc-treated DNA was incubated with either rat liver or recombinant human AGT, O6-pobG was removed, presumably a result of transfer of the pyridyloxobutyl group from the O6-position of guanine to AGT's active site.     

Peak height pattern in dichloro-rhodamine and energy transfer dye terminator sequencing

Establishing the pattern in peak heights within local sequence contexts improves the accuracy of base calling and the identification of DNA sequence variations in dye-terminator cycle sequencing. We have systematically examined pairs of sequence-tagged sites (STSs) that vary at only a single nucleotide to determine how base changes influence the peak heights of neighboring bases in sequencing traces generated by two recently commercialized dye-terminator chemistries, the dichloro-rhodamine (dRhodamine) and the energy transfer (BigDye) terminators. For sequencing traces generated with the dRhodamine terminators, the peak height of a particular base in 28 of 64 possible 3-base windows (44%) can be predicted by knowing just one or two bases 5' to the base in question. For those generated with the BigDye terminators, the peak height of a particular base in 23 of 64 possible 3-base windows (36%) can be predicted by knowing the local sequence context. When the peak heights are binned slightly differently, 75% (48 out of 64 cases) of the base peaks generated by both dRhodamine and BigDye terminators fall in the middle half, confirming that the peak patterns of these two new dye terminator chemistries are much more even than those found in the original rhodamine dye terminator sequences.     

Spectral measurements of intercalated PCR-amplified short tandem repeat alleles

Short tandem repeat (STR) alleles are popular for use as forensic markers due to their highly polymorphic nature. Commonly they are separated by gel electrophoresis and visualized using intercalation dyes. The purpose of this study was to determine the changes in absorbance and fluorescence of DNA-intercalation dye complexes as a function of base pair (bp)-to-dye ratio. The DNA samples consisted of STR alleles from loci THO1, F13A01, and vWFA31. The alleles were PCR amplified and HPLC purified to ensure that only the desired DNA fragment was present in each sample. Alleles ranged in size from 151 bp for locus vWFA (allele 17) to 199 bp for the locus F13A01 (allele 8). The adenine and thymine (AT) content varied from 48% for the THO1 locus to 69% for F13A01 and vWFA31 loci. The homozygous alleles of each locus were mixed individually with the bis-intercalators TOTO-1 and YOYO-1 and their corresponding monomeric dyes TOPRO-1 and YOPRO-1. The absorbance of the DNA-dye complex at 260 nm increased with addition of each intercalation dye. Subtraction of the dye absorbance rendered the DNA absorbance constant at 260 nm. Fluorescence emission increased dramatically upon intercalation of both the monomeric and dimeric dyes into the DNA helix. A plateau of fluorescence intensity was observed at base pair-to-dye ratios of 10/1 for the bis-intercalator TOTO-1 and 5/1 for YOYO-1 for all three loci. The greatest fluorescence intensity response was obtained with the intercalator YOYO-1 using allele 8 of the F13A01 locus, which had the greatest AT concentration.     

Determinants of risk of invasive cervical cancer in young women

We describe doublex sequencing of human genomic PCR products using two differently labeled primers in a single reaction and analysis on two automated DNA sequencing devices. Feasibility of the methodology is demonstrated by isothermal and cycle sequencing for two different PCR products and by cycle sequencing on both strands of a single product. It was applied to analyze mutations in patient DNAs in routine sample screening. Because it has the advantage of increased throughput and cost reduction while retaining its accuracy and reading length, we found that doublex sequencing is an attractive option for molecular diagnosis of hereditary diseases. This approach would be even more beneficial if it used DNA sequencing devices with several lasers in a single instrument.     

Quantitative analysis of synthetic dyes in lipstick by micellar electrokinetic capillary chromatography

The separation of synthetic dyes, used as color additives in cosmetics, by micellar electrokinetic capillary chromatography (MEKC) is described in this study. The separation of seven dyes, namely eosine, erythrosine, cyanosine, rhodamine B, orange II, chromotrope FB and tartrazine has been achieved in about 3 min in an untreated fused silica capillary containing as background electrolyte a 25 mM tetraborate/phosphate buffer, pH 8.0, and 30 mM sodium dodecyl sulfate. The electrophoretic method exhibits precision and relatively high sensitivity. A detection limit (LOD, signal/noise = 3) in the range of 5-7.5 X 10(-7) M of standard compounds was recorded. Intra-day repeatability of all the studied dye determinations (8 runs) gave the following results (limit values), % standard deviation: 0.24-1.54% for migration time, 0.99-1.24% for corrected peak areas, 0.99-1.24% for corrected peak area ratio (analyte/internal standard) and 1.56-2.74% for peak areas. The optimized method was successfully applied to the analysis of a lipstick sample where eosine and cyanosine were present.     

Simultaneous on-line DNA sequencing on both strands with two fluorescent dyes

We describe an automated DNA-sequencing technique which allows both the simultaneous sequencing from the two strands of double-stranded templates and the subsequent detection of the sequencing products online and in parallel. The technique is based on hardware technology also used in the ALF DNA sequencer (Pharmacia, Uppsala). A helium-neon laser was mounted into the sequencing device additionally to the standard argon laser. Two different primers, labeled with either fluorescein or Texas red, are used in a single sequencing reaction resulting in an output of two sequences. Both sequencing products are then analyzed on-line in the same lanes of a gel. This technique is especially useful for the complete sequencing of DNA fragments up to 1 kb. High accuracy sequencing of PCR products in double-stranded form can now be accomplished in only one sequencing reaction.