Quantitative cytochemical aspects of a combined Feulgen-Naphthol Yellow S staining procedure for the simultaneous determination of nuclear and cytoplasmic proteins and DNA in mammalian cells

The simultaneous cytophotometric determination of nuclear and cytoplasmic proteins and DNA by means of a combined Feulgen-Naphthol Yellow S (NYS) staining procedure was investigated. According to this procedure Feulgen staining is performed prior to NYS staining. The following main results were obtained:

1. 1. After NYS staining alone, the amount of NYS bound to the cell was found to be closely correlated to the cellular dry mass. The correlation coefficient was 0.99 in ethanol-acetone fixed cells and 0.95 in formaldehyde-fixed cells. This close correlation was not significantly altered by the Feulgen staining procedure and was 0.92 in ethanol-acetone and 0.94 in formaldehyde-fixed cells. However, the absolute amount of NYS bound per unit dry mass was affected by the method of fixation and type of Feulgen hydrolysis.

2. 2. The cells lose material during the Feulgen procedure, particularly during the acid hydrolysis stage. The type of hydrolysis most suitable for the Feulgen procedure (5 N HCl, 22 °C, 60 min) resulted in a considerable loss of dry mass in ethanol-acetone fixed cells. This loss was smaller in formaldehyde-fixed cells (15%) and was in addition closely correlated (correlation coefficient 0.99) to the dry mass of the cells prior to hydrolysis. In formaldehyde-fixed cells the dry mass after the Feulgen procedure is thus a good measure of the true cellular dry mass of the fixed cells. This is further demonstrated by the close correlation between NYS binding to Feulgenstained cells and the dry mass of these cells prior to the Feulgen procedure (correlation coefficient 0.95).

3. 3. When using the combined Feulgen-NYS staining procedure under standardized conditions (formaldehyde fixation and acid hydrolysis in 5 N HCl, 22 °C, 60 min) a constant amount of NYS was found to be bound per unit dry weight to nuclear and cytoplasmic proteins in various types of mammalian cells with different proliferative activity.

4. 4. The Feulgen DNA determination was not found to be quantitatively affected by the subsequent NYS staining.

From the results of the present study it seems that, under standardized conditions, the combined Feulgen-NYS staining procedure can be used as a reliable quantitative method for the determination of nuclear and cytoplasmic proteins and DNA in mammalian cells.     

Estimation of residual DNA in Feulgen reaction. A new correction of DNA determination per nucleus.

For the determination of the residual DNA amount after acid hydrolysis of Feulgen's method, a high salt-fluorochrome assay for DNA (5 microM Hoechst 33258 with 1 M NaCl) was effectively applied. At an optimal time length of acid hydrolysis for Feulgen reaction, the ratio of the residual DNA of non-hydrolysis to total DNA is 10% or more in hepatocyte or lymphocyte nuclei. A lot of residual DNA seems not to be negligible in Feulgen's method. A more accurate determination of DNA can be made by correcting the loss ratio of the residual DNA value to Feulgen DNA value. Thus, the combination assay of Feulgen's method with the present fluorometry is enough to measure separately both the amounts of Feulgen DNA and its residual DNA and successfully determines more accurately the total DNA per nucleus by summing both the amounts. The residual DNA, a resistant portion of the chromatin DNA against acid hydrolysis, is a possible constituent as the physiological component of nuclear structures.     

Combined staining procedures for cytophotometry of protein and DNA Feulgen-Naphthol Yellow S and dinitrofluorobenzene-Feulgen

A comparison has been made between dinitrofluorobenzene (DNFB) and Naphthol Yellow S (NYS) as protein stains in combination with the pararosaniline-SO2 Feulgen procedure. Chicken erythrocytes were used as test cells. Cytophotometric measurements were made using a Zeiss scanning stage cytophotometer coupled to a PDP 11/10 minicomputer using the BICOSCAN program to obtain values for protein per cell, protein per "nuclear area' and DNA per nucleus. With 5N HCl as the Feulgen hydrolysis agent, DNFB staining, applied before the Feulgen procedure, was found to be unaffected by hydrolysis conditions required to give optimum Feulgen staining and showed only small losses after longer hydrolysis times. On the other hand measurements of NYS staining, of necessity applied after the Feulgen procedure, seem to be susceptible to the duration of Feulgen hydrolysis. This susceptibility is probably due to the interaction of the DNA phosphates with the basic amino acid residues, potential binding sites for NYS. Since the degree of this interaction may be variable, it is argued that NYS binding will measure the available basicity of proteins at the time of staining but no specific protein fraction. DNFB binding is unaffected by DNA-protein interactions and therefore can give a more reliable measure of "nuclear' protein, particularly in conjunction with Feulgen-DNA measurements.     

Is there "Metabolic" DNA in the Mouse Seminal Vesicle?

This study was designed to answer the question: Is H³-thymidine uptake by nuclei of the mouse seminal vesicle evidence for DNA synthesis and mitosis, or does it signify some "metabolic" function of DNA unrelated to chromosome duplication? Mice were given an intraperitoneal injection of H³-thymidine. Six hours later Feulgen squashes of the seminal vesicle epithelium were made and covered with autoradiographic stripping film. The silver grains above labeled nuclei were counted, and the Feulgen dye contents of these same nuclei were determined photometrically after removal of the grains from the emulsion. Unlabeled nuclei were also measured. The dye contents of non-radioactive nuclei form a unimodal distribution, indicating that polyploidy is absent from this tissue. The radioactive nuclei fall into two groups. In the first, the average dye content is the same as that of the cold nuclei (2C). In the second, the values range from 2C to 4C. In the 2C to 4C group the grain count is proportional to the dye content, showing that incorporation is correlated with synthesis. The radioactive 2C nuclei arose by mitosis during the course of the experiment. This is shown by the following facts: (1) They frequently occur in pairs. (2) They average smaller than unlabeled 2C nuclei. (3) Their average grain count is approximately half that of the 4C nuclei. (4) Labeled division figures are found. (5) A mitotic rate estimated from the number of labeled 2C nuclei accords reasonably well with one based on the number of observed mitoses. Since the incorporation of thymidine accompanies DNA synthesis and precedes mitosis, there is no reason to postulate a special "metabolic" DNA in this tissue.     

Feulgen Densitometry: Importance of a Stringent Hydrolysis Regime

Abstract: Feulgen densitometry is still a widely used method for DNA content measurements, but experimental procedures and results are often controversial. The present note is concerned with a recent report in the literature that optimum Feulgen staining required a remarkably longer hydrolysis time with 5 M HCI in Dactylis glomerata L. than in Hordeum vulgare L. (i.e., 62 min versus 20 min at 25 C). As this result is prone to question the usual practice of maintaining unified hydrolysis times for test material and internal standard, we established hydrolysis curves for D. glomerata, H. vulgare, Pisum sativum L. and Allium cepa L. at 20 C and 25C for 0 to 100 min. No striking differences between the species and, in particular, between Doctylis and Hordeum were found. Optimum staining occurred after 60 min with hydrolysis at 20 C and after 25 min at 25 C. It is strongly recommended to conduct the quantitative Feulgen reaction at a precisely controlled temperature instead of an inexact room temperature. The broader plateau of optimum staining at 20 C makes this regime preferable.     

Feulgen hydrolysis and chromosome banding in Chilocorus (Coleoptera: Coccinellidae).

Prolonged Feulgen hydrolysis of chromosomes of Chilocorus orbus Csy. and C. stigma Say produces banding patterns that are the reverse of those revealed with quinacrine; brightly fluorescing regions are unstained, but nonfluorescent regions remain relatively darkly stained. This differential reactivity at hydrolysis times that otherwise yield intense Feulgen staining confirms the need for caution in the determination of DNA values with the Feulgen reaction in material with well-defined quinacrine bands. The coincidence of DNA-specific Feulgen bands with Q-, G-, and C-bands supports the view that, in Chilocorus at least, bands reflect differences in DNA composition along the chromosome.     

The Feulgen banded karyotype of the mouse: analysis of the mechanisms of banding

The chromosomes of the mouse have been identified by specific banding patterns revealed by the Feulgen stain. Comparison of the patterns of the Feulgen-stained karyotype with those of acetic-saline-Giemsa stain and quinacrinemustard-fluorescence demonstrates a high order of similarity among the three, with the localization of Feulgen dense bands and regions closely paralleling that of Giemsa dark and fluorescence bright bands. Since the stained substrate of the Feulgen reaction is known to be DNA, it is suggested that all three banding methods reveal the distribution of DNA or of some moiety that closely follows DNA distribution in metaphase chromosomes. The preparative procedure of the Feulgen banding method consists of a 15 to 20 minute exposure to PO₄ buffer at pH 10 and a prolonged (60–72 hrs) exposure to 12xSSC. Omission or curtailment of either step results in preparations with chromosome sets that are not karyotypable, although some stain differentiation is produced. HCl extraction prior to the preparative treatment blocks banding, but acid extraction following the preparative treatment, either that of the HCl hydrolysis of the Feulgen reaction of that of an almost fourfold extension of the standard hydrolysis time, does not obliterate bands already formed. By extrapolation from biochemical studies of chromatin, it is postulated that the localization of Feulgen dark and light stain, representing relative DNA densities, reflects the regional protein association of the DNA; the Feulgen dense regions may result from aggregation of a specific class of histones by the alkaline buffer with consequent condensation of the DNA bound to those histones; the Feulgen pale or negative regions may represent those in which non-aggregated proteins, histone and non-histone, have been solubilized in the saline incubation, rendering the DNA of those regions subject to diffusion or vulnerable to fragmentation in the Feulgen hydrolysis.     

Exposure and removal of stainable groups during Feulgen acid hydrolysis of fixed chromatin at different temperatures

Summary Hyperdiploid Ehrlioh's ascites tumour cells grown in male mice (strain NMRI) were labeled with radioactive nucleotides. The nucleic acids were extracted from fixed, air-dried smears by fractionated hydrolysis and their radioactivity measured by liquid scintillation. The experiments showed that the exposure of aldehydes through removal of purine bases and the elimination of these aldehydes through depolymerisation of DNA were the two main processes responsible for the Feulgen hydrolysis curve. They were shown to be independent and overlapping. The depurination can be described as a simple hydrolytic reaction, while the extraction of DNA depends on a number of different factors. This entails that, in the Feulgen acid hydrolysis procedure, the part of DNA measured is dependent upon the stability of the chromatin. It was found that it is possible accurately to determine the depolymerisation process and thereby roughly correct the measured amount of Feulgen DNA.     

Tritium labelling and cytochemistry of extra DNA in Acheta

Females of Acheta domesticus were injected with H³-thymidine and H³-uridine at various stages of development in order to study DNA and RNA synthesis in the DNA body present in the oocytes. Staining with alkaline fast green, azure B and the Feulgen reaction were employed as cytochemical tests. The following main results were obtained.

1. The DNA body appears in the oogonia at interphase as a Feulgen positive spherical structure 2 microns in diameter and is seen in subsequent mitotic divisions as a slightly smaller structure of variable shape. H³-thymidine autoradiography discloses that the DNA present in this body is synthesised at a different time from the chromosomal DNA.
2. At interphase and during the early prophase of meiosis the DNA body increases in size becoming a large Feulgen positive sphere 6 microns in diameter. Small nucleoli are present within this body. The DNA of the body is complexed with histone as revealed by alkaline fast green staining. H³-thymidine labelling discloses that it is at these stages that the bulk of the DNA synthesis takes place in the body.
3. Every oocyte contains a DNA body, and no body of comparable size or shape seems to be present in the male meiotic prophase.
4. At pachytene and diplotene the DNA body acquires the appearance of a “puff”. Two zones can be distinguished inside the DNA body: (1) an inner core of DNA and an outer shell of RNA. The inner core is Feulgen positive and stains light green with azure B, the outer shell is Feulgen negative and stains purple-violet with azure B, as does the cytoplasm. From the inner DNA core many Feulgen positive fibrils radiate into the outer RNA shell. These fibrils appear unstained or slightly greenish with Azure B, forming a transparent network in a purple-violet background. This gives the body the typical appearance of a “puff”. H³-uridine incorporation reveals that the RNA synthesis occurs in the outer RNA shell of the body and in the chromosomes. RNase treatment removes the H³-uridine incorporated into these regions.
5. At the end of diplotene the DNA body starts to disintegrate. The DNA core breaks up into minor components and the outer RNA zone also begins to disintegrate. By late diplotene the whole body has vanished, releasing DNA, histone and RNA into the nucleus. Subsequently the nuclear envelope disintegrates as it regularly does at the end of prophase of meiosis.
6. The simplest interpretation of the above results is that the DNA body represents hundreds of copies of the genes of the nucleolar organizing region.

     

Quantitative cytochemical determination of desoxyribonucleic acid with the Feulgen nucleal reaction

The possibility of using the Feulgen nucleal reaction for a quantitative cytochemical estimation of desoxyribonucleic acid (DNA) was investigated. The intensity of the reaction in nuclei was determined by absorption measurements with the microscope. The accuracy of such measurements was tested by comparison with measurements on the same material with a Beckman spectrophotometer. The values obtained with the microscope agreed within a few per cent with those obtained with the Beckman spectrophotometer. Furthermore, the errors introduced by uneven distribution of absorbing material, by variations in the numerical aperture of the system, and by variation in the area used on the phototube were investigated empirically. The following variables were studied with regard to their effect on the intensity of the Feulgen reaction: type of fixation, time of hydrolysis after acetic acid-alcohol and formalin fixation, time of staining in leucobasic fuchsin, method of preparation of leucobasic fuchsin. The intensity of the Feulgen reaction in liver and erythrocyte nuclei of various vertebrates, fixed in acetic acid-alcohol, was then compared with the DNA content of these nuclei as determined by chemical analysis on a known number of nuclei. The intensity of the reaction was found to be proportional to the DNA content of the nuclei, if nuclei of similar structure and DNA concentration were compared. In nuclei of different structure and DNA concentration (i.e. liver and erythrocyte nuclei), fixed in acetic acid-alcohol, the intensity of the Feulgen reaction was, however, not proportional to the DNA content. This difficulty was overcome by isolating nuclei in sucrose and by fixing them in formalin. Uniform distribution of DNA and therefore uniform coloring after the Feulgen reaction were thus obtained. In such nuclei with uniform distribution of absorbing material the Feulgen reaction was found to be proportional to the DNA content of nuclei, even if they differed greatly in their DNA concentration. The Feulgen nucleal reaction is not quantitative in an absolute sense. For absolute determinations nuclei of known DNA content must be treated together with the unknown material to serve as standard. From these data it therefore appears possible to determine cytochemically relative amounts of DNA in cellular structures by measuring their absorption after treatment with the Feulgen nucleal reaction.     

FEULGEN HYDROLYSIS OF NORMAL CELLS AND MOUSE ASCITES TUMOR CELLS

The effect of HCl hydrolysis on the dye content (Feulgen reaction) of normal cells and mouse ascites tumor cells was examined by means of cytophotometric measurements. After 11 min of hydrolysis, 16-day-old tumor cells showed a hypotetraploid DNA line with doubling peaks. The DNA values were in the ratios of 1:2:4:8 during all the tested hydrolysis times (3 to 21 min). The size of the nucleus and the DNA concentration did not influence the hydrolysis and the dye content. However, the time of the hydrolysis considerably influenced the dye content of normal and tumor cells. The course of the curves obtained by plotting dye absorption against hydrolysis time showed an inflection of the curve at 9 min' hydrolysis time in tumor cells, whereas the inflection occurred at 8 min in mitotic cells. These inflections were statistically significant. The DNA stem-line¹ for tumor cells shifted during different hydrolysis times when compared to normal cells. The possibility is discussed of two types of DNA which differed in their acid sensitivity and which yielded atypical hydrolysis curves.     

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.     

A CHROMATOGRAPHIC STUDY OF HYDROLYSIS IN THE FEULGEN NUCLEAL REACTION

In a study on Feulgen hydrolysis of frozen-dried alcohol-fixed lily anthers, a chromatographic technique was developed to analyze the acid hydrolysate for some of the degradation products of nucleic acid. Hydrolysis was accomplished by 10 per cent perchloric acid at 20°C., and a typical hydrolysis time-Feulgen intensity curve was obtained, with maximum staining occurring at 19 hours. Microphotometric measurements indicated that the amount of stain per nucleus was no different from amount in nuclei fixed and hydrolyzed by more conventional procedures. Uracil-containing material (from ribonucleic acid) was almost completely separated from thymine-containing material (deoxyribonucleic acid) of tissue sections by acid treatment for 1½ hours. Adenine (purines), as the base, was effectively all removed from the deoxyribonucleic acid at the time of optimum hydrolysis. Detectable amounts of thymine-containing material appeared in the hydrolysate shortly after the onset of hydrolysis; and the amount increased rapidly with increased hydrolysis time. At the time of optimum hydrolysis approximately two-thirds of the total deoxyribonucleic acid thymine was lost. The removal of these thymine-containing fragments was linear with respect to time during the first 24 hours and occurred at a relatively high rate. Removal after 24 hours was also linear but was at a markedly lower rate. These results would suggest that two kinds of deoxyribonucleic acid exist in lily anthers; an acid-labile fraction amounting to approximately three-fourths of the total, and an acid-resistant fraction making up the remainder. In the Feulgen procedure much of the labile fraction is lost by the time of optimum hydrolysis and is not stained; most of the stable fraction remains in the tissue and is stained. In light of these findings the use of the Feulgen method as a means of determining cytochemically relative amounts of deoxyribonucleic acid in nuclei by measuring their Feulgen dye content was discussed.     

Feulgen staining of rat liver fixed in different fixatives.

In the present study rat liver pieces fixed in 1) 10 per cent buffered neutral formalin, 2) 4 per cent glutaraldehyde, 3) Heidenhain's-Susa fixative and 4) Flemming's fluid, and following hydrolysis in 1-0 N HC1 at 60degreesC for varying time periods have been stained with the UV Feulgen procedure. The results of this study reveal that following hydrolysis for different time periods the tissue material fixed in formalin show the same staining pattern as those fixed in glutaraldehyde. The material fixed in Heidenhain's-Susa displays an intense Feulgen staining after two different times of hydrolysis, and that fixed in Flemming's fluid shows particular staining intensity for a prolonged time period thus indicating better preservation of DNA than in the materials fixed in the other three fixtatives.     

Influence of acid concentration and temperature on fixed chromatin during feulgen hydrolysis

Summary Labelled nucleic acid were extracted from fixed, air-dried smears of Ehrlich's ascites tumour cells by fractionated hydrolysis and measured by liquid scintillation. It was found that the rates of RNA and DNA depolymerisation and of DNA depurination depended on temperature in the same way. The DNA extraction patterns retained their form when the temperature was varied. When the hydrolysis was performed in decreasing acid concentrations, however, there was a concomitant change in the form of the depolymerisation pattern. This change affects the amount of aldehyde groups available for dye-binding with the Feulgen method after the optimal hydrolysis time. The alteration in shape of the Feulgen curve is discussed and supposed to be due to an increased interaction between DNA and other macromolecules. It is suggested that this interaction may be useful in detecting differences in chromatin stability between cells which differ in gene activity.     

Computer analysis of sub-parameters of depurination and depolymerization rate constants in Feulgen DNA hydrolysis

Feulgen DNA hydrolysis curves derived from cytofluorometry at various temperatures and HCl concentrations were computer analyzed with least squares fit to Bateman function. By comparing the depurination (k1) and depolymerization (k2) rate constants at different hydrolysis conditions, it was found that the two parameters of temperature and HCl concentration can be expressed as k = AN2 X exp (-B/T), where A and B are constants, N is the HCl concentrations, and T is the absolute temperature. From the analysis of Feulgen hydrolysis curves with 2N HCl at various temperatures, it was calculated that A = 5.3590 X 10(14) and B = 12133.543, for k1, and A = 6.2401 X 10(14) and B = 12181.660, for k2 for mouse 4C hepatocytes fixed with absolute methanol. Computer generated theoretical hydrolysis curves using the above k1 and k2 values were compared with experimental curves at various temperatures and HCl-concentrations. The two types of hydrolysis curves coincided with each other when 1-3 N HCl was used at temperatures between 30-40 degrees C. The peak times of hydrolysis curves at different conditions determined by experimental analysis and theoretical estimations also coincided reasonably well with each other. The physico-chemical phenomena underlying the equation designating k1 and k2 values are discussed.     

Combined staining of protein-bound sulphydryl groups and DNA in polyacrylamide model systems.

A model system of polyacrylamide films containing protein and DNA has been used to examine the feasibility of combining the dihydroxydinaphthyldisulphide (DDD)-diazonium salt procedure for localizing protein-bound sulphydryl groups with the Feulgen technique for DNA to make possible the direct measurement of both these parameters simultaneously. Optimun conditions for the sulphydryl group reaction require reduction of the protein-containing films in 10% aqueous ammonium sulphide for 3 hr at 50 degree C followed by treatment with a DDD solution at 50 degree C for 4 hr. The final coloured product was developed in a solution of the diazonium salt, Fast Red TR, for 15 min. The azo compound thus produced was completely resistant to hydrochloric acid hydrolysis in the manner of the Feulgen reaction. Calculation of protein-bound sulphydryl groups and DNA from measurements made on doubly-stained films showed excellent agreement between the measured and the expected values.     

Feulgen Hydrolysis with Perchloric Acid

In tissue fixed with Carnoy's acetic alcohol (1:3), the hydrochloric acid hydrolysis performed as part of the Feulgen reaction is optimal for only a very short period of time. When 10% perchloric acid is used as the hydrolytic agent, the same color maximum is obtained, and the optimal hydrolysis time at 25°C. extends from 12 hours to 24 hours. During this time the intensity of color does not change. The events which take place during the period of suboptimal hydrolysis are the same as diose which take place during the corresponding period of hydrochloric acid hydrolysis. Part of the decrease in ultraviolet extinction of nuclei during the first 12 hours is due to the splitting off of purine bases from the desoxyribose nucleic acid. This is consistent with the increase in the amount of Feulgen dye bound by nuclei during this period of time. Between 12 hours and 24 hours no ultraviolet absorbing material is lost from nuclei, which is consistent with the fact that during this time the Feulgen color produced remains at a maximum.     

Combined staining procedures for cytophotometry of protein and DNA Feulgen-Naphthol Yellow S and dinitrofluorobenzene-Feulgen

Summary A comparison has been made between dinitrofluorobenzene (DNFB) and Naphthol Yellow S (NYS) as protein stains in combination with the pararosaniline-SO₂ Feulgen procedure. Chicken erythrocytes were used as test cells. Cytophotometric measurements were made using a Zeiss scanning stage cytophotometer coupled to a PDP 11/10 minicomputer using the BICOSCAN program to obtain values for protein per cell, protein per nuclear area and DNA per nucleus. With 5N HCl as the Feulgen hydrolysis agent, DNFB staining, applied before the Feulgen procedure, was found to be unaffected by hydrolysis conditions required to give optimum Feulgen staining and showed only small losses after longer hydrolysis times. On the other hand measurements of NYS staining, of necessity applied after the Feulgen procedure, seem to be susceptible to the duration of Feulgen hydrolysis. This susceptibility is probably due to the interaction of the DNA phosphates with the basic amino acid residues, potential binding sites for NYS. Since the degree of this interaction may be variable, it is argued that NYS binding will measure the available basicity of proteins at the time of staining but no specific protein fraction. DNFB binding is unaffected by DNA-protein interactions and therefore can give a more reliable measure of nuclear protein, particularly in conjunction with Feulgen-DNA measurements.     

Optimization of the histochemical demonstration of DNA using 3-hydroxy-2-naphthoic acid hydrazide and Fast Blue B

Summary Previous methods for the histochemical demonstration of DNA were optimized. p-Toluene sulfonic acid as catalyst for hydrazone formation between the aldehydes generated after Feulgen hydrolysis and 3-hydroxy-2-naphthoic acid hydrazide (NAH) was used instead of acetic acid. Modifications of the conditions of the coupling reaction with Fast Blue B reduced the background staining. The optimized histochemical staining method for DNA (NAH-FB-DNA staining) can be performed easily and reproducibly. Without prior Feulgen hydrolysis the optimized method can also be used for the histochemical demonstration of reactive carbonyls undissolved under the given histochemical conditions.Dedicated to Prof. Dr. E. Schauenstein on the occasion of his 70th birthday