Different instability of nuclear DNA at acid hydrolysis in cancerous and noncancerous cells as revealed by fluorescent staining with acridine orange

Ehrlich cancer cells and inflammatory cells in mouse ascitic fluid were hydrolyzed and stained with acridine orange (AO). The AO hydrolysis curves for G1/G2 + M phase cancer cells and inflammatory cells were differentially determined using flow cytometry by monitoring the metachromatic red-shifted fluorescence of the fluorochrome bound to the single-stranded DNA produced by acid hydrolysis. By computer fitting of the Bateman function to the hydrolysis curves, the kinetic parameters k1 (rate constant for the production of single-stranded DNA), k2 (rate constant for the degradation of the produced single-stranded DNA), and y0 (theoretical value of the single-stranded DNA present initially) were determined. It was found that the k2 value, which reflects the degree of DNA instability, was much higher for cancer cells in both the G1 and G2 + M phases than for inflammatory cells. This finding led us to develop a method for the differential AO staining of cancer cells and non-cancerous cells utilizing the different degree of DNA instability at acid hydrolysis. AO staining after hydrolysis with 2N HCl at 30 degrees C for 8.5 min was found to be the optimal method. In the 60 cases of human malignant epithelial and nonepithelial tumors tested, all of the malignant tumor cells emitted metachromatic red fluorescence, while all of the nonmalignant tumor cells (5 cases of benign tumor) and normal cells emitted orthochromatic green fluorescence when observed with a violet excitation light under a fluorescence microscope. This new technique can be a useful tool for the screening of malignancy in exfoliative cytology and also for basic cancer research.     

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.     

Quantitative microdetermination of DNA by two-dimensional electron capture gas chromatography of the thymine constituent

A highly sensitive and specific two-dimensional electron-capture gas chromatographic method has been developed for determining small amounts of DNA by measuring its thymine content. The method can also be used to measure RNA based on uracil content. The nucleic acids were hydrolyzed and released constituents were separated and detected as their chloromethyldimethylsilyl ethers. The minimal amount detected was 5 pg of each base. Standard curves were linear from 5 to 200 pg. This method allowed quantitative determination of 2 ng of DNA (routinely detectable quantity) after hydrolysis of biological material in formic acid, even in the presence of large amounts of RNA and/or protein. For example, this method has been shown to be successful in determination of the DNA contents of manually isolated nucleic such as from amphibian oocytes. Besides being accurate, the procedure was rapid: after maximal hydrolysis (usually about 45 min) the derivatization and gas chromatographic analysis was completed in another 15 min. The procedure described represents a direct biochemical alternative to cytophotometric estimation of nuclear contents and has the advantage of providing values for absolute DNA content per nucleus.     

Degradation of DNA by silicic acid

S1 nuclease hydrolysis and hydroxyapatite chromatography were used to study the effect of silicic acid on DNA. Native calf thymus DNA was incubated with increasing concentrations of silicic acid (DNA nucleotide/silicic acid molar ratios of 1:0.25, 1:0.5 and 1:1) and subjected to S1 nuclease hydrolysis. An increasing degree of DNA degradation was seen suggesting a destabilization of the secondary structure. A decrease in melting temperature was also observed. Hydroxyapatite chromatography indicated that incubation at the molar ratio of 1:1 resulted in denaturation and degradation of DNA.     

Factors affecting the course of DNA acid hydrolysis in carrying out the Feulgen reaction]

Literature data concerning acid hydrolysis of DNA during the Feulgen procedure are reviewed, with emphasis being made on the dependence of Schiff-apurinic acid binding on the fixation technique, the temperature of hydrolysis and acid concentration, the rate of extraction of depolymerized DNA fragments, the nucleotide composition of DNA, the chromatin state, and on the composition of nucleoprotein. Some practical considerations for optimization of the Feulgen procedure for a precise quantitative determination of DNA amount are given.     

The effect of HCl hydrolysis on the retention of thymidine in DNA

Allium roots grown in C(14)-thymidine and H(3)-thymidine media were treated with N hydrochloric acid at 60 degrees C. as in standard Feulgen hydrolysis. The retention of the radioactive thymidine in DNA as a function of hydrolysis time was studied autoradiographically. No significant loss of label was detected until hydrolysis was extended beyond the optimal time for Feulgen staining. The data are consistent with the assumption that there is no significant loss of DNA during normal Feulgen hydrolysis in the material used.     

Different instability of nuclear DNA at acid hydrolysis in cancerous and noncancerous cells as revealed by fluorescent staining with acridine orange

Summary Ehrlich cancer cells and inflammatory cells in mouse ascitic fluid were hydrolyzed and stained with acridine orange (AO). The AO hydrolysis curves for G₁/G₂+M phase cancer cells and inflammatory cells were differentially determined using flow cytometry by monitoring the metachromatic red-shifted fluorescence of the fluorochrome bound to the single-stranded DNA produced by acid hydrolysis. By computer fitting of the Bateman function to the hydrolysis curves, the kinetic parameters k ₁ (rate constant for the degradation of the produced single-stranded DNA), and y ₀ (theoretical value of the single-stranded DNA present initially) were determined. It was found that the k ₂ value, which reflects the degree of DNA instability, was much higher for cancer cells in both the G₁ and G₂+M phases than for inflammatory cells. This finding led us to develop a method for the differential AO staining of cancer cells and non-cancerous cells utilizing the different degree of DNA instability at acid hydrolysis. AO staining after hydrolysis with 2N HCl at 30°C for 8.5 min was found to be the optimal method. In the 60 cases of human malignant epithelial and nonepithelial tumors tested, all of the malignant tumor cells emitted metachromatic red fluorescence, while all of the nonmalignant tumor cells (5 cases of benign tumor) and normal cells emitted orthochromatic green fluorescence when observed with a violet excitation light under a fluorescence microscope. This new technique can be a useful tool for the screening of malignancy in exfoliative cytology and also for basic cancer research.In honour of Prof. P. van Duijn     

Quantitative detection of DNA damage in the neuronal cells of the cerebellum and cerebrum by the analysis of Feulgen hydrolysis curves

Touch smears of the cerebellum and cerebrum of ageing rats were fixed with methanol, hydrolyzed with 2 N HCl at various temperatures and for various periods, and stained with pararosaniline-Schiff reagent. The hydrolysis curves were determined by fluorescence cytophotometry and were computer fitted to the Bateman function to determine the kinetic parameters, the initial yield of apurinic acid or single-stranded DNA (y0), and the rate constants for depurination or denaturation (k1) and depolymerization (k2). The values for k1 (1/k1 is correlated with the degree of chromatin condensation) and k2 (which reflects the degree of DNA instability) steadily increased with age. The values for y0, which may indicate the degree of DNA denaturation or damage present before acid hydrolysis, also increased with age in both the cerebellum and cerebrum; however, this value was lower in the cerebellum until 15 weeks, with the situation being reversed after 35 weeks, the cross-over time being at about 25 weeks. The values of lnk1 and lnk2 were plotted as the function of the reciprocal of the absolute temperature (T) (Arrhenius plot) for both the cerebellum and cerebrum of 15- and 74-week-old rats, and the activation energies (E) for depurination and depolymerization were calculated from the slopes. In particular, the values of E for k2 decreased much more quickly with age and were smaller in cerebellum. In conclusion, the degree of DNA damage and DNA instability steadily increases in both the cerebellum and cerebrum of ageing rats, and this process is much faster in the cerebellum.     

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.     

Potential artifacts in the measurement of DNA deamination

Attack on DNA by some reactive nitrogen species results in deamination of adenine and guanine, leading to the formation of hypoxanthine and xanthine, respectively. Published levels of these products in cellular DNA have varied widely. Although these two deamination products are often measured by GC-MS analysis, the procedure of acid hydrolysis to release DNA bases for derivatization poses a risk of artifactual deamination of the DNA. In this study, we demonstrated the artifactual formation of these two deamination products during acid hydrolysis and hence developed a method for detecting and measuring 2'-deoxyinosine, the nucleoside of hypoxanthine. Our assay for 2'-deoxyinosine employs nuclease P1 and alkaline phosphatase to achieve release of the nucleosides from DNA, followed by HPLC prepurification with subsequent GC-MS analysis of the nucleosides. This assay detected an increase in the levels of 2'-deoxyinosine in DNA when commercial salmon testis DNA was treated with nitrous acid. We also used it to measure levels in various rat tissues of both normal and endotoxin-treated rats, but could not find increased 2'-deoxyinosine formation in tissues even though *NO production was substantially increased.     

A study of DNA depolymerisation during feulgen acid hydrolysis

Summary The binding of Schiff dye molecules after acid hydrolysis (1 M HCl) for varying lengths of time was studied in ascites tumour cells. The amount of dye bound to the tumour cells closely followed the number of aldehyde groups, calculated from the extraction of radioactive nucleotides. This constant dye to aldehyde ratio did not change when the hydrolysis was performed at a lower acid concentration (0.3 M HCl). The conclusion drawn is that Feulgen dye measurements represent, in a constant way, the number of aldehydes on DNA at any given time during hydrolysis. The alteration of the hydrolysis pattern of chromatin fixed in formalin was found to be due to a slower extraction of DNA depolymerisation products, the purine liberation being unaffected. A similar explanation is offered for the extreme pattern obtained from hydrolysis of bull spermatozoa chromatin.     

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.     

Probing the MVAI methyltransferase region that interacts with DNA: affinity labeling with the dialdehyde-containing DNA duplexes

Affinity labeling of methyltransferase MvaI by DNA duplexes containing oxidized 2'-O-beta-D-ribofuranosylcytidine or 1-beta-D-galactopyranosyl)thymine residues was performed. Partial chemical hydrolysis of the covalently bound methylase in the conjugates with the dialdehyde-containing DNA allowed us to determine the amino acid region in the C terminus of methylase MvaI that interacts with DNA.     

Effects of pH and salt concentration on the hydrolysis of a benzo[alpha]pyrene 7,8-diol-9,10-epoxide catalyzed by DNA and polyadenylic acid

The time-dependent absorbance change that occurs when benzo[alpha]pyrene 7,8-diol-9,10-epoxide is added to solutions of calf thymus DNA has been shown, by an unequivocal chromatographic method, to correspond to DNA-catalyzed hydrolysis of the diol-epoxide. At 25 degrees C and mu = 0.10, the kinetics of the reaction of the diol-epoxide with polyadenylic acid or DNA are consistent with preequilibrium formation of a non-covalent complex between the diol-epoxide and the polynucleotide or DNA, followed by hydrolysis of the bound epoxide by a process that is first-order in hydronium ions. Cacodylic acid also catalyzes the hydrolysis of the epoxide bound to polyadenylic acid. The rate of the DNA-catalyzed hydrolysis exhibits little or no enantiomeric selectivity for the diol-epoxide. DNA catalyzed hydrolysis of the diol-epoxide is extraordinarily sensitive to the salt concentration in the reaction medium: the rate of hydrolysis of the bound epoxide at pH 7 is retarded by a factor of approximately 45 in the presence of 0.1 M sodium chloride compared to a 1 mM buffer containing no added salt. Thus, studies of the interactions of DNA with carcinogenic diol-epoxides must take into account the ionic environment of DNA within the cell.     

A study of DNA depolymerisation during Feulgen acid hydrolysis.

The binding of Schiff dye molecules after acid hydrolysis (1 M HCl) for varying lengths of time was studied in ascites tumour cells. The amount of dye bound to the tumour cells closely followed the number of aldehyde groups, calculated from the extraction of radioactive nucleotides. This constant dye to aldehyde ratio did not change when the hydrolysis was performed at a lower acid concentration (0.3 M HCl). The conclusion drawn is that Feulgen dye measurements represent, in a constant way, the number of aldehydes on DNA at any given time during hydrolysis. The alteration of the hydrolysis pattern of chromatin fixed in formalin was found to be due to a slower extraction of DNA depolymerisation products, the purine liberation being unaffected. A similar explanation is offered for the extreme pattern obtained from hydrolysis of bull spermatozoa chromatin.     

Determination of 5-methylcytosine by acid hydrolysis of DNA with hydrofluoric acid

Quantitation of 5-methylcytosine in DNA after acid hydrolysis has been inaccurate because deamination of cytosine and 5-methylcytosine occurs during the hydrolysis procedure. There is little information in the literature regarding the use of hydrofluoric acid (HF) for DNA hydrolysis and we have therefore undertaken a systematic study of this process. The deoxyribonucleotides of cytosine and 5-methylcytosine were shown not to undergo detectable levels of deamination during prolonged periods (up to 24 h) at 80 degrees C in 48% HF. Kinetic studies show that the release of purine and pyrimidine bases was complete by 4 h under these conditions. Analysis of the 5-methylcytosine content of DNA from various tissues gave levels that were very close to the values reported in the literature. This method is ideally suited for the determination of the overall cytosine methylation levels in DNA.     

The study of interactions between DNA and PcrA DNA helicase by using targeted molecular dynamic simulations

DNA helicases are important enzymes involved in all aspects of nucleic acid metabolism, ranging from DNA replication and repair to recombination, rescue of stalled replication and translation. DNA helicases are molecular motors. Through conformational changes caused by ATP hydrolysis and binding, they move along the template double helix, break the hydrogen bonds between the two strands and separate the template chains, so that the genetic information can be accessed. In this paper, targeted molecular dynamic simulations were performed to study the important interactions between DNA and PcrA DNA helicase, which can not be observed from the crystal structures. The key residues on PcrA DNA helicase that have strong interactions with both double stranded DNA (ds-DNA) and single stranded DNA (ss-DNA) have been identified, and it was found that such interactions mostly exist between the protein and DNA backbone, which indicates that the translocation of PcrA is independent of the DNA sequence. The simulations indicate that the ds-DNA is separated upon ATP rebinding, rather than ATP hydrolysis, which suggests that the two strokes in the mechanism have two different major roles. Firstly, in the power stroke (ATP hydrolysis), most of the translocations of the bases from one pocket to the next occur. In the relaxation stroke (ATP binding), most of the ‘work’ is being done to ‘melt’ the DNA at the separation fork. Therefore, we propose a mechanism whereby the translocation of the ss-DNA is powered by ATP hydrolysis and the separation of the ds-DNA is powered by ATP binding.     

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.     

Alkylation of calf thymus DNA with reductively activated mitomycin C

Mitomycin C (MMC) was catalytically reduced in the presence of a nucleotide or calf thymus DNA. Reaction with 5'-guanylic acid (5'-GMP) gave 1,2-cis-2, 7-diamino-1-(5'-guanylyl) mitosene. Reaction with calf thymus DNA gave modified DNA, which on enzymatic hydrolysis gave two alkylated 5'-deoxyguanylic acid (MG-1 and MG-2) and an alkylated 5'-deoxyadenylic acid (MA). This is the first example of isolation of nucleotides from DNA modified by MMC.     

Histochemical properties of spermatozoa and somatic cells. III. Depolymerization and extraction of DNA during Feulgen acid.

The Feulgen acid hydrolysis patterns of chromatin of different biochemical composition and compactness were analyzed. It was found that the purine extraction rate during acid hydrolysis was affected by the addition of NaCl or 2-mercaptoethanol to the hydrolysis bath. The maximum DNA depolymerization rate was directly correlated to the depurination rate but the extraction rate of hydrolysed DNA was in addition dependent on the stability of the surrounding protein matrix. The results indicate that the diffusion of DNA fragments is partially obstructed in extremely stabilized chromatins (e.g. bull spermatozoa). It is assumed that the extraction pattern of DNA is mainly dependent on the size of the fragments which leave the chromatin by diffusion. It appears that basic proteins do not influence the depolymerization of DNA but there are indications that during certain experimental conditions the purine liberation is dependent upon the chromatin structure.