Standardization of the post-irradiation method to eliminate primary fluorescence in cytofluorometry.

Thorough irradiation of specimen with the strong excitation light after fluorescent Feulgen staining destroys the primary fluorescence in the background with stabilization of specific fluorescence of pararosaniline (post-irradiation method). An apparatus to perform effective post-irradiation was developed and irradiation condition for DNA cytofluorometry on a pararosaniline Feulgen stained smear was standardized. After 10 h irradiation on this condition, the primary fluorescente in the background is almost completely cleared away. Proportionality between amount of fluorescence and DNA content is perfectly preserved and standard deviation in each class of ploidy becomes to be less than 5% of the mean DNA value. The standardized post-irradiation enables us to obtain reproducibly the same values of fluorescence on Feulgen stained nuclei of the same cell population in different smears even if the staining conditions in Schiff's solution might be different to some extent.     

Irradiation of specimens by excitation light before and after staining with pararosaniline feulgen: A new method to reduce non-specific fluorescence in cytofluorometry

Summary Thorough irradiation on specimens with strong green light before or after pararosaniline Feulgen staining destroys specifically the primary-fluorescent substances in the background. By this treatment of pre- or post-irradiation, accuracy of DNA cytofluorometry is markedly improved and the Feulgen specific fluorescence is stabilized. Selecting proper wavelength, this technique will universally be useful in microfluorometry of any fluorochromes for reducing background fluorescence.     

Fluorescence fading and stabilization in cytofluorometry

The factors affecting fluorescence fading in cytofluorometry were investigated using different kinds of nuclear staining, mounting media, and procedure of specimen preparation. Acceleration of fluorescence fading was observed in smear specimens treated with RNase, trypsin, or hypotonic solution before pararosaniline Feulgen nuclear staining. Similar effect was found for other DNA-stainings such as "33258 Hoechst" and Feulgen reactions with different Schiff-type dyes, such as acriflavine-SO2 and cresyl-violet-SO2, when chemically pure DNA was used. Fluorescence decay was rapid for all fluorochromes examined, when glycerin or buffer solution was used as mounting medium. Marked stabilization of fluorescence emission was induced in specimen mounted in non-fluorescent resin, Entellan (Merck), after post-staining fixation with absolute methanol for all tested fluorochromes. The same treatment induced almost complete fluorescence stabilization of fluorescein isothiocyanate (FITC); no detectable fluorescence fading was observed in a specimen stained with indirect immunofluorescence reaction using anti-UV-DNA antibody, during storage for 2 years at room temperature without special protection against light. These observations suggest that factors which bring about conformational stability of macromolecule-dye complexes generally induce fluorescence stabilization.     

Measurement of DNA content in single cells morphologically identified on smears

A method was developed for measuring the nuclear DNA content in single cells previously identified on a bone marrow smear stained by the Wright-Giemsa method. The smear was first photographed and the location of individual cells, identified by morphology, was recorded on a cell map. The smear was then bleached with 50% acid ethanol and absolute methanol, and re-stained by the Feulgen method in 0.05% pararosaniline Schiff's reagent (pH 2.3) at 7 degrees C for 10 min. Nuclear red fluorescence was observed and the intensity of this fluorescence was proportional to the amount of DNA after prior irradiation of smears with green light for 9 hr. The method is useful for measuring cell DNA content in heterogeneous cell populations when morphological cell identification is required.     

Further observations on the chemistry of pararosaniline-Feulgen staining.

Pararosaniline-Feulgen staining of cells in suspension produces nucleus- and chromatin-specific fluorescence as well as color. Experiments were designed to test postulated reaction mechanisms responsible for the fluorescent staining with the nonfluorescent pararosaniline. The reduction in fluorescent-staining intensity by pretreatment of cells with 2.2 x 10-2M K2S2O5 tends to rule out the alkysulfonic acid pathway; conditions favoring the formation of this intermediate reduce staining intensity. The fluorescence enhancement, observed when cells stained in pararosaniline without K2S2O5 are post-treated with K2S2O5, suggests that there is an initial Schiff-base linkage between pararosaniline and an aldehyde of hydrolyzed DNA, and that this linkage is stabilized in the presence of K2S2O5. Microspectrofluorometer measurements of cells stained at various pararosaniline concentrations in 2.2x10-2M K2S2O5, show that the fluorescence emission maximum ranges from about 627 nm at 3.1x10-3 M pararosaniline to about 604 nm at 3.1x10-5M. All of the employed staining protocols appear to produce the same fluorescent product, perhaps a heterocyclic pyronin analog formed from pararosaniline. Flow microfluorometric analysis of cells stained in suspension verified that the relative fluorescence intensity represents relative DNA content. Staining at reduced pararosaniline concentration (3.1x10-4M) reduces the coefficient of variation of the flow microfluorometric histograms, showing that maximum quantitation does not necessarily correlate with maximum staining intensity.     

Fluorescence fading and stabilization in cytofluorometry

Summary The factors affecting fluorescence fading in cytofluorometry were investigated using different kinds of nuclear staining, mounting media, and procedure of specimen preparation. Acceleration of fluorescence fading was observed in smear specimens treated with RNase, trypsin, or hypotonic solution before pararosaniline Feulgen nuclear staining. Similar effect was found for other DNA-stainings such as 33258 Hoechst and Feulgen reactions with different Schiff-type dyes, such as acriflavine-SO₂ and cresylviolet-SO₂, when chemically pure DNA was used. Fluorescence decay was rapid for all fluorochromes examined, when glycerin or buffer solution was used as mounting medium. Marked stabilization of fluorescence emission was induced in specimen mounted in non-fluorescent resin, Entellan (Merck), after post-staining fixation with absolute methanol for all tested fluorochromes. The same treatment induced almost complete fluorescence stabilization of fluorescein isothiocyanate (FITC); no detectable fluorescence fading was observed in a specimen stained with indirect immunofluorescence reaction using anti-UV-DNA antibody, during storage for 2 years at room temperature without special protection against light. These observations suggest that factors which bring about conformational stability of macromoleculedye complexes generally induce fluorescence stabilization.     

Standardization of the Papanicolaou stain. I. A comparison of five nuclear stains.

The staining characteristics of five nuclear stains used in a Papanicolaou staining procedure were investigated. Alcohol-fixed cervical smears were stained with a modified Papanicolaou procedure using hematoxylin, alcoholic thionin bromide, alcoholic Victoria blue B, gallocyanin or the thionin Feulgen reagent (thionin-SO2) as the nuclear stain. The same anionic counterstain was used for all slides, and the optical densities of cell nuclei and cytoplasm were measured with the IBAS 2000 image analyzer. Alcoholic thionin gave the most intense nuclear stain, with a very high reproducibility of the staining pattern. Hematoxylin showed the highest coefficient of variation of the staining intensity. Both hematoxylin and gallocyanin gave some nonspecific cytoplasmic staining. Thionin-SO2 allowed a quantitative assessment of DNA, but gave a low staining intensity. Staining with the metal complex dyes interfered with subsequent staining with the pararosaniline Feulgen reagent. Alcoholic thioinin is thus recommended as a nuclear stain for cervical cytology in the Papanicolaou procedure, both for image analysis and for visual microscopy.     

A comparative study of quantitative stains for DNA in image cytometry.

In this study we examined the reproducibility of several stains used to measure nuclear DNA by image cytometry. The specimens were touch preparations of liver and testis from mouse and liver, intestine and brain from rat, fixed in either neutral formalin or Carnoy's solution. The tested stains included four Feulgen methods (pararosaniline, azure-A, thionin and acriflavine), the gallocyanine-chromalum stain and two fluorescent stains (acridine orange and propidium iodide). Absorbance measurements employed a video image analysis system; fluorescence measurements were from a scanning microspectrophotometer. The acriflavine-Feulgen stain was analyzed for both absorbance and fluorescence. All seven stains were quantitative for DNA and gave reproducible results. The absorbance measurements had a lower coefficient of variation (CV) than the fluorescence values. In a nested analysis of variance of the pararosaniline Feulgen stains, cell-to-cell variability accounted for 67% of the total variance; slide-to-slide, 9%; and batch-to-batch, 24%. These values did not change significantly when the staining was performed in an automatic staining machine. For DNA analysis using image cytometry, we conclude that the Feulgen staining technique is the most useful. In particular, acriflavine-Feulgen-stained cells fixed in Carnoy's fluid give the least variation between measurement values and the most accurate ratios between the separate ploidy groups. For fluorescence cytometry we recommend Carnoy's fixation and the acriflavine-Feulgen stain because of its narrow CV as compared to acridine orange and propidium iodide.     

Involvement of sulfhydryl groups of chromosomal proteins in sister chromatid differentiation

The fluorescence of human lymphocyte chromosomes stained with sulfhydryl group-specific fluorochromes is markedly enhanced by a mild near-ultraviolet irradiation pretreatment, indicating breakage of protein disulfide bonds. When metaphase preparations of cells cultured in the presence of BrdU during two cell cycles are irradiated and subsequently stained with the sulfhydryl group-specific fluorescent reagents used in this study, a differential fluorescence of sister chromatids is observed. After staining with the DNA-specific fluorochrome DAPI an opposite pattern of lateral differentiation appears. It can be concluded that the chromatid containing bifilarly BrdU-substituted DNA has a higher content of sulfhydryl groups than the chromatid containing unifilarly BrdU-substituted DNA. This implies a more pronounced effect of breakage of disulfide bonds in the chromatid with the higher degree of BrdU-substitution. BrdU-containing chromosomes pretreated with the mild near-ultraviolet irradiation procedure used by us, do not show any differentiation of sister chromatids after Feulgen staining. Using sulfhydryl group-specific reagents, differential fluorescence of sister chromatids could still be induced by irradiation with near-ultraviolet light after the complete removal of DNA from the chromosomes by incubation with DNase I. Thus, the protein effect of irradiation of BrdU-containing chromosomes takes place independently of what occurs to DNA.Our results indicate that subsequent to the primary alteration of chromatin structure caused by the incorporation of BrdU into DNA, breakage of disulfide bonds of chromosomal proteins might play an important role in bringing about differential staining of sister chromatids, at least for those procedures that use irradiation as a pretreatment or prolonged illumination during microscopic examination.     

Cytofluorometric and cytochemical comparisons of normal and abnormal human cells from the female genital tract.

Acridine orange staining of exfoliated cells from epithelial tissues facilitates discrimination between normal and abnormal cells: abnormal cells develop highly elevated nuclear fluorescence. Comparisons of acridine orange (AO) staining with propidium iodide (PI) or Feulgen staining have shown that: (a) PI staining also provides highly elevated nuclear fluorescence from abnormal cells; (b) the distributions of nuclear fluorescence following AO or PI staining were usually not significantly different as judged by the Kolmogorov-Smirnov test; (c) fluorescence emission spectra from AO and PI stained cells are consistent with the hypothesis that both fluorochromes bind to DNA within cell nuclei; (d) DNAse treatment of AO stained normal cells eliminates the nuclear fluorescence peak from slit-scan contours; RNAse treatment has no effect on nuclear fluorescence; (e) the distribution of abnormal cell nuclear fluorescence after AO staining is usually, but not always, significantly different from the distribution of abnormal cell nuclear absorbance after Feulgen staining, with relative nuclear fluorescence being greater than relative nuclear absorbance. The hypothesis currently most consistent with these results is that elevated Feulgen DNA content can account for only part of the discrimination provided by AO staining, and that the chromatin within abnormal cells is altered so as to increase accessibility of DNA to intercalating dyes.     

Combined protein and DNA measurements by the ninhydrin-Schiff and Feulgen techniques.

Feulgen nuclear staining with pararosanilin-SO2 was combined with the ninhydrin-Schiff technique. The aldehyde groups converted from primary amino groups are stained with an acriflavine-Schiff reaction. This results in a red nuclear fluorescence and a bright yellow cytoplasmic and nuclear fluorescence. The combined fluorescence staining facilitates cytofluorometric determination of total protein and DNA in the same cell. The ninhydrin-Schiff reaction is affected by the fixation procedure and the duration of the ninhydrin reaction. Investigations with a model system showed that proportionality between the fluorescence intensity of acriflavine and the amount of protein stained by the procedure was obtained after fixation with a fixation mixture suggested by B?hm et al. (1968) and a reaction with ninhydrin at 37 degrees C for 10 h. The ninhydrin-Schiff reaction has no effect on the fluorescence intensity of cells previously treated with pararosanilin-Feulgen staining and it is not affected itself by this previous procedure. Testing this double fluorescence staining on cytology specimens taken from patients with gastric carcinoma and uterine cervial carcinoma, cancer cells were shown to have markedly increased protein and DNA contents compared with those of normal cells.     

Combined protein and DNA measurements by the ninhydrin-Schiff and Feulgen techniques

Summary Feulgen nuclear staining with pararosanilin-SO₂ was combined with the ninhydrin-Schiff technique. The aldehyde groups converted from primary amino groups are stained with an acriflavine-Schiff reaction. This results in a red nuclear fluorescence and a bright yellow cytoplasmic and nuclear fluorescence. The combined fluorescence staining facilitates cytofluorometric determination of total protein and DNA in the same cell.The ninhydrin-Schiff reaction is affected by the fixation procedure and the duration of the ninhydrin reaction. Investigations with a model system showed that proportionality beween the fluorescence intensity of acriflavine and the amount of protein stained by the procedure was obtained after fixation with a fixation mixture suggested by Böhm et al. (1968) and a reaction with ninhydrin at 37° C for 10 h.The ninhydrin-Schiff reaction has no effect on the fluorescence intensity of cells previously treated with pararosanilin-Feulgen staining and it is not affected itself by this previous procedure.Testing this double fluorescence staining on cytology specimens taken from patients with gastric carcinoma and uterine cervial carcinoma, cancer cells were shown to have markedly increased protein and DNA contents compared with those of normal cells.Partly supported by Deutsche Forschungsgemeinschaft (DFG), grant Nr. Bo 395/4     

Further observations on the chemistry of Pararosaniline-Feulgen staining

Summary Pararosaniline-Feulgen staining of cells in suspension produces nucleus- and chromatin-specific fluorescence as well as color. Experiments were designed to test postulated reaction mechanisms responsible for the fluorescent staining with the nonfluorescent pararosaniline. The reduction in fluorescent-staining intensity by pretreatment of cells with 2.2×10⁻²M K₂S₂O₅ tends to rule out the alkysulfonic acid pathway; conditions favoring the formation of this intermediate reduce staining intensity. The fluorescence enhancement, observed when cells stained in pararosaniline without K₂S₂O₅ are post-treated with K₂S₂O₅, suggests that there is an initial Schiff-base linkage between pararosaniline and an aldehyde of hydrolyzed DNA, and that this linkage is stabilized in the presence of K₂S₂O₅. Microspectrofluorometer measurements of cells stained at various pararosaniline concentrations in 2.2×10⁻²M K₂S₂O₅, show that the fluorescence emission maximum ranges from about 627 nm at 3.1×10⁻³M pararosaniline to about 604 nm at 3.1×10⁻⁵M. All of the employed staining protocols appear to produce the same fluorescent product, perhaps a heterocyclic pyronin analog formed from pararosaniline. Flow microfluorometric analysis of cells stained in suspension verified that the relative fluorescence intensity represents relative DNA content. Staining at reduced pararosaniline concentration (3.1×10⁻⁴M) reduces the coefficient of variation of the flow microfluorometric histograms, showing that maximum quantitation does not necessarily correlate with maximum staining intensity.     

Nonspecific ("pseudo-plasmal") dye-binding in the Feulgen nuclear stain and its blocking by azocarmin G

In Feulgen nuclear staining nonspecific dye-binding due to the "pseudo-plasmal reaction" is intensified in isolated cells with intact cytoplasm, and cannot be eliminated by the post-irradiation method. Fluorescence intensity in the cytoplasm sometimes exceeds that of specific nuclear fluorescence, especially in brain and heart muscle cells, and it was almost impossible to perform cytofluorometric DNA quantification on such specimens. Various kinds of aldehyde-blocking agents such as sodium borohydride, 2,4-dinitrophenylhydrazine, aniline, and sodium pyrosulfite were effective in reducing the "pseudo-plasmal reaction". But the blocking effects were not complete because of additional release of reactive aldehyde groups during subsequent Feulgen hydrolysis. Acidic azocarmin G produced a complete block of all "pseudo-plasmal reaction" in acriflavine-Feulgen nuclear staining, allowing accurate DNA-cytofluorometry to be carried out.     

The mechanism of differential sister chromatid fluorescence as studied with the GC-specific DNA-ligand mithramycin

Chromosomes of human blood cells exposed to BUdR for two cell cycles showed an R-band pattern of fluorescence without lateral differentiation after staining with the GC-specific DNA-fluorochrome mithramycin. Differential sister chromatid fluorescence could be induced by a mild near-ultraviolet irradiation pretreatment which was without effect in Feulgen staining. Thus, besides the primary alteration of DNA structure caused by incorporation of BUdR, secondary structural alterations, probably mediated via chromosomal proteins, are required in order to obtain differential mithramycin-fluorescence of sister chromatids. The differential staining pattern was similar to that achieved with the AT-specific DNA-fluorochrome DAPI. Therefore, it may be concluded that the base specificity of fluorochromes does not play any part in the production of differential fluorescence of sister chromatids by this method.     

Feulgen DNA stainability of bone tumors after demineralization

Microspectrophotometric DNA analysis of archival bone tumor tissue is often impeded by previous acid demineralization, which destroys Feulgen DNA stainability. To find an alternative to acid for prospective DNA studies of bone tumors in tissue sections, Feulgen stainability of fresh osteosarcoma specimens after demineralization in neutral EDTA was investigated. The reliability of DNA analysis of weakly Feulgen-stained sections from archival tissue was also studied. Demineralization of four fresh specimens in EDTA slightly reduced Feulgen DNA stainability compared to nondemineralized preparations but did not affect the determination of ploidy level. Hydrolysis tests of one diploid and one hyperploid osteosarcoma showed that the staining relationship between control and tumor cells was not altered by EDTA pretreatment. For DNA studies of bone tumors requiring demineralization, EDTA offers a means of retaining nuclear Feulgen stainability. In 22 archival osteosarcoma specimens of varying Feulgen stainability, three different upper limits of light transmission (75, 85, and 95%) were applied to test the significance of background disturbances in relation to nuclear stain intensity. The relationship between the median total extinction of the control and tumor cell populations was not significantly affected by altering the upper transmission limit except in four poorly stained lesions. The control cells of these four specimens exhibited a median total extinction less than one-third of the maximum encountered. The results suggest that weakly stained archival specimens can be tested for selecting those appropriate for ploidy determination.     

Simultaneous quantification of DNA and RNA in tissue sections. A comparative analysis of the Methyl Green-Pyronin technique with the Gallocyanin chromalum and Feulgen procedures using image cytometry

Summary For simultaneous cytophotometric measurement of DNA and RNA, the standardized Methyl Green-Pyronin Y technique is an obvious choice. It is, however, first necessary to correlate the uptake of Pyronin Y to the staining intensity of RNA.The material consisted of paraffin sections of formalin- or Carnoy-fixed rat liver. The sections were pretreated with water, buffer, deoxyribonuclease, ribonuclease, or both enzymes in sequence, and stained with the standardized Methyl Green-Pyronin Y procedure, Gallocyanin chromalum, or the Feulgen analtion. Sections stained directly without pretreatment served as controls. Staining intensities were measured with an image analyser for cell nuclei, nucleoli and cytoplasm.After deoxyribonuclease treatment, nuclear staining intensity with Methyl Green, Gallocyanin chromalum, and Schiff's reagent dropped nearly to zero. The same was seen for both nucleoli and cytoplasm with Pyronin Y and Gallocyanin chromalum after ribonuclease treatment. Staining intensity of Pyronin Y correlated directly with that of Gallocyanin chromalum for nucleoli and cytoplasm. After ribonuclease treatment, a direct correlation was found between the nuclear staining intensity of Methyl Green and nuclear absorption of Gallocyanin chromalum.We conclude that the standardized Methyl Green-Pyronin Y stain is reliable for the simultaneous quantitative assessment of both RNA and DNA. The simplicity of this technique makes it a valuable tool even for daily routine.     

Quantification of nuclear DNA and intracellular glycogen in a single cell by fluorescent double-staining.

It was found that intracellular glycogen is stabilized against acid treatment when it is stored under dry conditions for three months after methanol fixation. This stabilization allowed quantitative double fluorescence staining for nuclear DNA and intracellular glycogen, in a single cell. A Feulgen nucleal reaction, with acriflavine-Schiff's reagent following 5 N HCl hydrolysis at 25 degrees C for 4 min, was followed by a pararosanilin-Schiff PAS reaction for glycogen. This short term hydrolysis was found to be sufficient for the performance of a acriflavine-Schiff's Feulgen nucleal reaction and to provide good preservation of intracellular glycogen. Quantification of nuclear DNA and intracellular glycogen were consecutively carried out with a digital microfluorometer on a single ascites cancer cell of the AH-13 line stained by this method. It was found that there is a positive linear correlation between the amount of DNA and glycogen in this cell line.     

QFH banding and DNA distribution in the macrochromosomes of the chicken Gallus domesticus

Chromosomes of Gallus domesticus were stained with rivanolum-SO2 (fluorescence Feulgen reaction) and by Hoechst 33258. Fluorescence photography was performed on a 35 mm film KN-3(KN-3) "Svema". The negatives were analyzed with the microdensitometer. The Feulgen (Fr--) and the Hoechst 3358 (H--) densitometric profiles of chromosomes showed light and dark segments along the metaphase chromosomes. The amount of DNA, as determined by the fluorescence Feulgen reaction, is not constant along the chromosome arms. Consequently, the base composition is not the only factor influencing the fluorescence of Hoechst 33258 along the chromosomes. The comparative analysis of densitometric profiles of the Hoechst 33258 and rivanolum-SO2 stained chromosomes shows that the Iq telomere band consists of GC-rich DNA (about 70% GC). The variation of DNA contents along the metaphase chromosome arms can be realized at both chromoneme and/or subchromoneme levels.     

Standardization of the Feulgen reaction: the influence of chromatin condensation on the kinetics of acid hydrolysis.

The purpose of the present study was to investigate the influence of chromatin compactness on the kinetics of acid hydrolysis in the Feulgen reaction in cytology. Tissue imprints of rabbit liver, of human bronchial carcinoma and of human blood smears, fixed with alcohol, formaldehyde or with B?hm's solution with and without prior air drying, were stained with a standardized pararosanilin-Feulgen reagent. The time for hydrolysis varied between 7.5 and 120 min. The integrated optical density (IOD) of the cell nuclei was measured with an image analyzer (IBAS 2000). Cells with condensed chromatin (lymphocytes, small cell carcinoma, formaldehyde fixed cells) showed a slow increase of staining intensity and late plateau phase as compared with cells with decondensed chromatin. DNA in condensed nuclei was less susceptible to acid hydrolysis. The degree of chromatin compactness which determines the sensitivity of DNA to hydrolysis is influenced by the type of fixation, cell type and by the functional status of the cell. The conclusion is that Feulgen staining intensities of cells with different degrees of chromatin compactness cannot be compared unless measured in the respective plateau phases of the relevant hydrolysis curves which must be determined individually for each cell type.