Factors affecting the reproducibility of a spectrofluorimetric assay for the enumeration of human venous endothelium in culture

In an EDTA/Hoechst 33258 assay system, a linear increase in fluorescence with increase in cell number between 2 X 10(3) and 1 X 10(5) was obtained if a dye concentration of 800 ng/ml was used. For a given number of cells, the enhancement of fluorescence was found to be greater than that of a theoretically equivalent of DNA. A standard curve for the assay was derived by plotting enhancement of fluorescence against cell number. The effect of storage on the fluorescence of intact monolayers, cellular or commercial DNA, or dye-DNA complexes made it essential that the assay was carried out on fresh samples.     

Fluorometric assay of DNA in cartilage explants using Hoechst 33258

A simple two-step fluorometric assay of DNA in cartilage explants, utilizing the bisbenzimidazole dye Hoechst 33258, is described. Cartilage explants were prepared for assay by digestion with papain. Aliquots of the digest were mixed with dye solution, and the fluorescence emission measured. The enhancement in fluorescence of dye was specific for DNA, as demonstrated by 97% sensitivity to DNase and resistance to RNase. In addition, little or no interference was caused by non-DNA tissue components, since DNA caused an equal enhancement in fluorescence independent of the presence of papain-digested cartilage. By performing the assay on isolated chondrocytes, the cellular content of DNA was computed to be 7.7 pg per chondrocyte. The assay was stable for at least 2 h and sensitive to as little as 6 ng of DNA or equivalently less than 1000 cells. This procedure offers advantages over other established DNA assays of cartilage and may be especially useful in metabolic studies of cartilage explants.     

Development of a mechanism-based, DNA staining protocol using SYTOX orange nucleic acid stain and DNA fragment sizing flow cytometry

Accurate measurement of single DNA fragments by DNA fragment sizing flow cytometry (FSFC) depends upon precise, stoichiometric DNA staining by the intercalating dye molecules. In this study, we determined the binding characteristics of a commercially available 532 nm wavelength-excitable dye and used this information to develop a universal DNA staining protocol for DNA FSFC using a compact frequency-doubled Nd:YAG laser excitation source. Among twelve 532 nm wavelength-excitable nucleic acid staining dyes tested, SYTOX Orange stain showed the highest fluorescence intensity along with a large fluorescence enhancement upon binding to double-stranded DNA ( approximately 450-fold). Furthermore, using SYTOX Orange stain, accurate fragment-size-distribution histograms were consistently obtained without regard to the staining dye to base pair (dye/bp) ratio. A model describing two binding modes, intercalation (primary, yielding fluorescence) and external binding (secondary, involving fluorescence quenching), was proposed to interpret the performance of the dyes under different dye/bp ratios. The secondary equilibrium dissociation constant was found to be the most critical parameter in determining the sensitivity of each fluorophore to the staining dye/bp ratio. The measurements of both equilibrium dissociation constants provided us with a theoretical framework for developing a universal protocol which was successfully demonstrated over a wide range of DNA concentrations on a compact flow cytometer equipped with a frequency-doubled, diode-pumped, solid-state Nd:YAG laser for rapid and sensitive DNA fragment sizing.     

Bivariate analysis of cellular DNA versus RNA content by laser scanning cytometry using the product of signal subtraction (differential fluorescence) as a separate parameter

BACKGROUND: The cytometric methods of bivariate analysis of cellular RNA versus DNA content have limitations. The method based on the use of metachromatic fluorochrome acridine orange (AO) requires rigorous conditions of the equilibrium staining whereas pyronin Y and Hoechst 33342 necessitate the use of an instrument that provides two-laser excitation, including the ultraviolet (UV) light wavelength. METHODS: Phytohemagglutinin (PHA)-stimulated human lymphocytes were deposited on microscope slides and fixed. DNA and double-stranded (ds) RNA were stained with propidium iodide (PI) and protein was stained with BODIPY 630/650-X or fluorescein isothiocyanate (FITC). Cellular fluorescence was measured with a laser scanning cytometer (LSC). The cells were treated with RNase A and their fluorescence was measured again. The file-merge feature of the LSC was used to record the cell PI fluorescence measurements prior to and after the RNase treatment in list mode, as a single file. The integrated PI fluorescence intensity of each cell after RNase treatment was subtracted from the fluorescence intensity of the same cell measured prior to RNase treatment. This RNase-specific differential value of fluorescence (differential fluorescence [DF]) was plotted against the cell fluorescence measured after RNase treatment or against the protein-associated BODIPY 630/650-X or FITC fluorescence. RESULTS: The scattergrams were characteristic of the RNA versus DNA bivariate distributions where DF represented cellular ds RNA content and fluorescence intensity of the RNase-treated cells, their DNA content. The distributions were used to correlate cellular ds RNA content with the cell cycle position or with protein content. CONCLUSIONS: One advantage of this novel approach based on the recording and plotting of DF is that only the RNase -specific fraction of cell fluorescence is measured with no contribution of nonspecific components (e.g., due to the emission spectrum overlap or stainability of other than RNA cell constituents). Another advantage is the method's simplicity, which ensues from the use of a single dye, the same illumination, and the same emission wavelength detection sensor for measurement of both DNA and ds RNA. The method can be extended for multiparameter analysis of cell populations stained with other fluorochromes of the same-wavelength emission but targeted (e.g., immunocytochemically) for different cell constituents.     

DNA fluorometric assay in 96-well tissue culture plates using Hoechst 33258 after cell lysis by freezing in distilled water.

A simple assay is described using bisbenzimidazole (Hoechst 33258) to determine cellular DNA content in 96-well tissue cultures plates. At time points of interest, the plates are emptied of media and stored frozen. When the assay is to be performed, cultures are briefly incubated in distilled water and frozen again. This process lyses the cells and allows rapid and thorough mixing of the fluorochrome and cellular DNA. Freezing permits convenient storage of cultures until the time of assay. Experiments can be batched, further reducing processing time and giving better intra- and interexperimental standardization. The assay generates a linear standard curve for DNA fluorescence versus cell number, the range of which is appropriate for microculture wells. This enables the rapid and accurate measurement of cell number involving minimal processing time, making this assay well suited for cell proliferation studies.     

Quantitative determination of deoxyribonucleic acid from cells collected on filters

A method is described for the quantitation of cellular deoxyribonucleic acid from mammalian cells collected on cellulose triacetate membrane filters. DNA released from cells by sonication is fluorescently quantitated based on the DNA-dependent fluorescence enhancement of the anti-tumor antibiotic mithramycin. Pretreatment of filters with bovine serum albumin prior to sonication is necessary to prevent the loss of DNA-mithramycin fluorescence. The cellular DNA content in isolated capillary endothelium is 7.1 pg per cell and in isolated hepatocytes, 17.7 pg per cell.     

Characteristics of a novel deep red/infrared fluorescent cell-permeant DNA probe, DRAQ5, in intact human cells analyzed by flow cytometry, confocal and multiphoton microscopy

BACKGROUND: The multiparameter fluorometric analysis of intact and fixed cells often requires the use of a nuclear DNA discrimination signal with spectral separation from visible range fluorochromes. We have developed a novel deep red fluorescing bisalkylaminoanthraquinone, DRAQ5 (Ex(lambdamax) 646 nm; Em(lambdamax) 681 nm; Em(lambdarange) 665->800 nm), with high affinity for DNA and a high capacity to enter living cells. We describe here the spectral characteristics and applications of this synthetic compound, particularly in relation to cytometric analysis of the cell cycle. METHODS: Cultured human tumor cells were examined for the ability to nuclear locate DRAQ5 using single and multiphoton laser scanning microscopy (LSM) and multiparameter flow cytometry. RESULTS: Multiparameter flow cytometry shows that the dye can rapidly report the cellular DNA content of live and fixed cells at a resolution level adequate for cell cycle analysis and the cycle-specific expression of cellular proteins (e.g., cyclin B1). The preferential excitation of DRAQ5 by laser red lines (633/647 nm) was found to offer a means of fluorescence signal discrimination by selective excitation, with greatly reduced emission overlap with UV-excitable and visible range fluophors as compared with propidium iodide. LSM reveals nuclear architecture and clearly defines chromosomal elements in live cells. DRAQ5 was found to permit multiphoton imaging of nuclei using a 1,047-nm emitting mode-locked YLF laser. The unusual spectral properties of DRAQ5 also permit live cell DNA analysis using conventional 488 nm excitation and the single-photon imaging of nuclear fluorescence using laser excitation between 488 nm and low infrared (IR; 780 nm) wavelengths. Single and multiphoton microscopy studies revealed the ability of DRAQ5 to report three-dimensional nuclear structure and location in live cells expressing endoplasmic reticulum targeted-GFP, MitoTracker-stained mitochondria, or a vital cell probe for free zinc (Zinquin). CONCLUSION: The fluorescence excitation and emission characteristics of DRAQ5 in living and fixed cells permit the incorporation of the measurement of cellular DNA content into a variety of multiparameter cytometric analyses.     

New fluorochromes, compatible with high wavelength excitation, for flow cytometric analysis of cellular nucleic acids

The spectroscopic properties of three new dyes, EK4, VL772, and LL585, free and bound to nucleic acids, are presented, with particular emphasis on their potential use in flow cytometry. Two of these dyes, EK4 and LL585, exhibit red fluorescence, while dye VL772 exhibits yellow fluorescence. Dye LL585 exhibits specificity for DNA, relative to RNA, and a marked enhancement of fluorescence efficiency upon binding to DNA, needed for a red fluorescent DNA-specific stain for flow cytometry. The dye penetrates live cells, although uniformity of nuclear fluorescence, as evidenced by DNA flow histograms, is better if the cells are first permeabilized with Triton X-100. Dye VL772 exhibits yellow fluorescence and little DNA-RNA discrimination, but may prove useful in conjunction with dye LL585 when simultaneous assay of cellular RNA and DNA is desired. Dye EK4 shares properties of the other two dyes but fluoresces with much less efficiency. Dyes LL585 and VL772, used singly, as a pair, or in combination with blue-fluorescing DNA specific dyes, such as bisbenzimidazole derivatives, should permit new, convenient analyses of the content and organization of cellular nucleic acids.     

Enhanced sensitivity and precision in an enzyme-linked immunosorbent assay with fluorogenic substrates compared with commonly used chromogenic substrates

Quantitative enzyme-linked immunosorbent assay (ELISA) is a widely used tool for analyzing biopharmaceutical and vaccine products. The superior sensitivity of the ELISA format is conferred by signal amplification through the enzymatic oxidation or hydrolysis of substrates to products with enhanced color or fluorescence. The extinction coefficient for a colored product or the quantum yield of a fluorescent product, coupled with the efficiency of the immobilized enzyme, is the determining factor for the sensitivity and precision of a given ELISA. The enhancement of precision and sensitivity using fluorogenic substrates was demonstrated in a direct-binding ELISA in a low-analyte concentration range compared with commonly used chromogenic substrates. The enhancement in precision was demonstrated quantitatively with lower coefficients of variation in measurements of signal intensities, approximately a five- to six-fold enhancement in signal-to-noise ratio at a given analyte concentration with fluorogenic substrates. Similarly, the amplitude of the enhancement in sensitivity, as reflected by relative limits of detection or quantitation, is approximately two- to five-fold when compared with commonly used chromogenic substrates. Additional advantages of a fluorescence-based ELISA format include the continuous monitoring of initial rates of enzymatic reactions, the measurement of fluorescence changes in the presence of particulate materials, the absence of a quench step, and a larger quantifiable analyte range.     

Metal-enhanced PicoGreen fluorescence: Application for double-stranded DNA quantification

PicoGreen (PG) is a fluorescent probe for both double-stranded DNA (dsDNA) detection and quantification based on its ability to form a luminescent complex with dsDNA as compared with the free dye in solution. To expand the sensitivity of PG detection, we have studied the spectral properties of PG, both free and in complex with DNA in solution, when the fluorophore is in proximity to silver nanoparticles. We show that for a broad range of PG concentrations (20 pM-3.5 μM), it does not form dimers/oligomers and it exists in a monomeric state. On binding to DNA in the absence of silver, PG fluorescence increases approximately 1100-fold. Deposition of PG/DNA complex onto silver island films (SiFs) increases fluorescence approximately 7-fold due to the metal-enhanced fluorescence (MEF) effect, yielding fluorescence enhancement of 7700-fold as compared with the free dye on glass. In contrast to PG in complex with DNA, the free dye on SiFs demonstrates a decrease in brightness approximately 5-fold. Therefore, the total enhancement of PG on binding to DNA on silver reaches a value of approximately 38,000 as compared with free PG on SiFs. Consequently, the metal-enhanced detection of PG fluorescence is likely to find important utility for amplified dsDNA quantification.     

Fluorometric determination of DNA and RNA in Chlamydomonas using ethidium bromide

By using the fluorescence enhancement of ethidium bromide bound to nuclei acid, a very rapid, simple and sensitive assay of DNA in the green alga Chlamydomonas has been devised. Total fluorescence (DNA + RNA) was determined by complex formation with ethidium bromide in a cell lysate made by mixing cell samples with lauroyl sarcosinate, EDTA and NaOH and incubating the mixture for 5 min at room temperature followed by neutralization. For determination of DNA the RNA was digested by incubating the cell sample in te alkaline lysis solution for 45 min at 60 degrees C followed by neutralization, and complex formation with ethidium bromide. Quenching of the fluorescence due to cellular pigments was corrected for using an internal DNA standard.     

A fluorometric method of determining DNA in cells

A convenient express method is proposed for cell lysis and DNA solubilization in the presence of sarcosyl and sodium citrate. The DNA content was determined in cell lysates by registration of fluorescence enhancement with Hoechst No 33258 ("Serva", FRG). In 0.5 M NaCl solution the Hoechst-RNA fluorescence is negligible. An optimal molar ratio of DNA and Hoechst is in the range from 0.2 to 2.0. Beyond the range the accuracy of DNA quantification become poor. An optimal range of DNA quantification in cells is 200-2000 ng/ml.     

Environment-induced changes in DNA conformation as probed by ethidium bromide fluorescence

The interaction of the ethidium cation with calf thymus DNA is investigated in solutions of different ionic strength and temperature by observation of the enhancement of fluorescence of ethidium upon intercalation in the duplex structure. The quantum yield of the fluorescence of the intercalated dye is found to increase either upon lowering the Na+ concentration or upon increasing the temperature. The existence of a correlation between the geometry of the intercalation complex and the features of the secondary structure of DNA is suggested. Binding isotherms under corresponding environmental conditions are also quantitated by fluorescence enhancement and interpreted in terms of the neighbor exclusion model. Large contributions from change in hydration to the thermodynamics of binding are demonstrated by the temperature dependences of the equilibrium constants. The neighbor exclusion range is found to be practically independent of the salt concentration but its value increases from an average of 2.4 around room temperature to 4-5 at 80 degrees C, as inferred from the binding curves in 0.15 and 0.5 M [Na+] or from the DNA hypochromism vs temperature profiles of complexes at 10(-3) M [Na+]. All the data point to a possible sequence-conformation specificity in the intercalation of ethidium which in heterogeneous DNA is mediated by environmental changes.     

Microfluorometric analysis of cellular DNA following incorporation of bromodeoxyuridine.

Bromodeoxyuridine (BrdU) incorporation into cellular DNA has a differential effect on the cell-associated fluorescence of several DNA-specific dyes. After cells were treated with BrdU, flow microfluorometry was used to study the relative increase or decrease influorescence of stained cells. Bromodeoxyuridine incorporation into CHO cells increased the fluorescence of mithramycin-, olivomycin-, or chromomycin-stained cells, decreased that of propidium iodide-stained cells, and had little, if any, effect on the fluorescence of acriflavine Feulgen-stained cells. Changes in relative fluorescence of cell associated dyes are due to changes in the amounts of dye bound to cells with BrdU-substituted DNA. Colorimetric and absorbance measurement of DNA content showed that BrdU does not alter the diploid DNA content of CHO cells; however, BrdU induces perturbations in the distribution of cells about the cell cycle which cause an increase in average DNA content.     

DNA fluorescence induced by polymethine cation pyrvinium binding.

Pyrvinium is a polymethine cation which shows interesting fluorescence emission and DNA binding properties. In diluted aqueous solution, pyrvinium pamoate induced a bright yellow fluorescence in kinetoplast DNA from Trypanosoma cruzi epimastigotes as well as in chicken erythrocyte nuclei under a wide range of excitations. No fading was observed after mounting in suitable media. Spectroscopic studies on pyrvinium solutions revealed bathochromic and hypochromic shifts in the absorption spectrum of its complex with DNA. A striking enhancement of pyrvinium fluorescence was found in solvents of high viscosity or after binding to DNA. Experimental results and the chemical structure of pyrvinium allow us to suggest that the minor groove of adenine-thymine DNA regions could be the specific binding site for this new DNA fluorochrome.     

DNA-induced distamycin A fluorescence

The fluorescent properties of the antibiotic distamycin A were investigated in a range of materials including Trypanosoma cruzi epimastigotes, chicken erythrocytes, calf thymus DNA and synthetic polynucleotides using both microscopic and spectroscopic techniques. A bright blue-white fluorescence was observed from kinetoplast DNA and chromatin after treatment with distamycin A under ultraviolet (365 nm) excitation. Considerable enhancement of distamycin A fluorescence (emission peak at 455 nm under 320-340 nm excitation) was found in the presence of DNA and poly(dA-dT).poly(dA-dT). We discuss a possible explanation for this unexpected fluorescent emission, as well as its implications for microscopic and fluorimetric studies.     

Fluorescence Polarization Studies of the Binding of BMS 181176 to DNA

Abstract

The DNA binding of BMS 181176, an antitumor antibiotic derivative of rebeccamycin was characterized by DNA unwinding assays, as well as by fluorescence emission and polarization spectroscopic techniques. Unwinding and rewinding of supercoiled DNA was interpreted in terms of intercalation of BMS 181176 into DNA BMS 181176 shows an enhanced fluorescence emission upon binding to the AT sequence and no enhancement upon binding to the GC sequence. BMS 181176 appears to be a weaker binder to poly(dAdT).poly(dAdT) compared to doxorubicin and ethidium bromide. When bound to DNA, the rotational motion of BMS 181176 is substantially decreased as evident from the increase in fluorescence polarization. BMS 181176 exhibits a range of binding strengths depending on the DNA This is demonstrated by the Acridine Orange displacement assay using fluorescence polarization.     

DNA binding properties of a new class of linked anthramycin analogs.

We have investigated the DNA binding properties of the anthramycin analogues 4, 5, and 6 using fluorescence spectroscopy. A considerable fluorescence enhancement occurs when pyrrolo [1,4] benzodiazepines (P[1,4]Bs) are covalently attached to duplex DNA, which was used to show that neither the presence of RNA, single-stranded DNA, or protein had any effect on the degree of fluorescence enhancement resulting from the incubation of 5 and 6 with DNA. The enhancement was found to be dependent on the presence of the imine functionality in each of the compounds. A wavelength of 320 nm was used to excite the chromophore and its emission wavelength maximum was 420 nm. Additionally, we have discovered that the P[1,4]B ring system exhibits exceptionally favorable fluorescence polarization anisotropy (FPA) decay characteristics. For these more detailed fluorescence measurements, we used the structurally simpler analogue 4,. The time resolved maximum FPA for 4 in glycerol at 25 degrees C is 0.28. This result indicates that the P[1,4]B family of antibiotics could serve as sensitive probes of DNA dynamics in the 0.1 to 35 ns time scale.     

A novel deep red/low infrared fluorescent flow cytometric probe, DRAQ5NO, for the discrimination of intact nucleated cells in apoptotic cell populations

BACKGROUND: The linking of intracellular metabolism of anticancer drugs with cellular response is problematic. We describe a new probe for cellular integrity, based upon a structure which has the additional potential to act as a substrate for cytochrome P450-dependent bioreductive metabolism. DRAQ5NO is an N-oxide modified anthraquinone with optimal fluorescence excitation maxima compatible with He-Ne (633 nm) and Kr-Ar (647 nm) lasers. METHODS: DRAQ5NO-loading and Annexin V binding was monitored using dual-laser flow cytometry (488 nm/633 nm wavelengths) in human lymphoma cultures undergoing anticancer drug- (etoposide; VP-16) induced apoptosis. RESULTS: DRAQ5NO gave an Em(lambdamax) of 700.5 nm but retains DNA binding potential with an emission wavelength red-shift of approximately 12 nm. The agent showed reduced cytotoxicity and a limited capacity to accumulate within cells compared with the non-N-oxide form that shows a high nuclear targeting capacity in intact cells. DRAQ5NO/Annexin V provides for a positive discrimination between intact cells, membrane-compromised cells, cellular debris, and early stage apoptotic cells. CONCLUSIONS: The spectral properties of DRAQ5NO allow for the use of visible range fluorochromes and differential excitation in multilaser systems for tracking apoptotic populations with implications for the measurement of bioreductive potential in complex tumour populations simultaneously undergoing physiologically or drug-induced apoptosis.