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.     

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.     

Temperature and acid concentration in the search for optimum Feulgen hydrolysis conditions.

Exposure and removal of aldehyde groups during Feulgen acid hydrolysis were studied at a wide range of temperature and acid concentrations. Temperatures between 9 and 75degreesC were found to influence only the rate of the hydrolysis reaction over the entire range from high (6 M) to low (0.05 M) HCl concentrations. The temperature dependence was high, and around +5degreesC was sufficient to double the reaction rate. The influence of acid concentrations between 0.02 and 6 M was studied, and the extraction rates that determine the peak values of the Feulgen hydrolysis curve were found to depend in the same way on the (H+) concentration. A diagram is given that makes it possible to determine the time to reach the point during hydrolysis where the maximum amount of aldehyde groups are developed for a wide range of temperatures and acid concentrations. Temperatures slightly above room temperature in combination with high acid concentration is recommended for Feulgen hydrolysis.     

The influence of chromatin compactness on the stoichiometry of the Feulgen-Schiff procedure studied in model films. II. Investigations on films containing condensed or swollen chicken erythrocyte nuclei.

As models for different states of chromatin compactness, nuclei from chicken erythrocytes were isolated and either osmotically swollen or kept as condensed as possible. Both types of nuclei were then fixed and incorporated into polyacrylamide films. Hydrolysis with 5 N HCl and staining with Schiff's reagent of these model films were studied using several parameters. The phosphate content of the films was analyzed as a parameter for the depolymerization losses and the staining with Schiff's reagent as a parameter for the apurinic acid (APA) content. The loss of ultraviolet absorbance from the films and the accumulation of ultraviolet absorbing substances in the hydrolyzing acid were monitored as parameters for the progress of hydrolysis. Conversion of the generated aldehyde groups to APA-Schiff chromophore is shown to take place with the same stoichiometry for both types of nuclei as well as for DNA in model films. It is further shown that the nuclei- and DNA-films are suitable models for investigating the influence of chromatin compactness on the course of the Feulgen-Schiff reaction. For the most compact form of chromatin studied, a very high reduction in staining intensity of up to 40% could be demonstrated after certain normally applied hydrolysis times. This is due primarily to a decrease with a factor of 2.3 of the depurination rate constants of these models (from 0.030/min to 0.013/min). Therefore prolonged hydrolysis periods are required to obtain the same APA concentrations, but then depolymerization processes cause losses of nuclear material. The differences in depurination rates could be explained by a decrease in [H3O]+ in the neighborhood of the purine-sugar linkages, caused by the presence of fixed positive charges form the protein components of the chromatin. These findings may explain the cytophotometrically determined differences in chromophore yield of 10-20% found in the nuclei of cells with different states of compactness of their chromatin. The descending part of the Feulgen hydrolysis curve represents the depolymerization of APA and loss by diffusion of the reaction products. In the Appendix, cytophotometric data of cells have been analyzed to show that this part of the hydrolysis curve may be used to estimate the acid stability of chromatin complexes. The depurination and depolymerization rates found closely correspond with the data obtained from the model films.     

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.     

Some remarks on degeneration granules in the genital sphere

Summary By using different methods of staining the authors have made a closer study of the various stages in the process of cell degeneration that take place in the urogenital tract. In the beginning of this cell degeneration the nuclei remnants are Feulgen positive, becoming later, however, Feulgen negative, and accumulating finally into larger conglomerations possessing the same staining-qualities as the cytoplasm.     

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.     

Diurnal variations in endogenous RNA polymerase activity and amounts of nuclear non-histone protein, DNA and cytoplasmic protein in rat liver.

From rats fed ad libitum and kept under a 12 + 12 h light/dark regimen, the DNA dependent RNA polymerase activity of liver cell nuclei was determined avery four hours. From identical rats, nuclear non-histone protein and DNA, and cytoplasmic protein was determined by Feulgen-Naphthol Yellow S cytophotometry of isolated liver cells. The minimum: maximum ratio of the RNA polymerase activity is 0.77; the min:max ratio of nuclear non-histone protein is 0.84. These two parameters have identical time courses with a gradual decline during the light period and a sharp rise after the onset of the dark period. The variations in nuclear DNA content, estimated as the amount of Feulgen stain bound, closely parallel those of the RNA polymerase activity and nuclear non-histone protein content (min:max = 0.96). The amount of cytoplasmic protein per cell also varies throughout the day, but its time curve lags behind those of nuclear non-histone content and RNA polymerase activity. These results are consistent with the concept of nuclear non-histone proteins as de-repressors of the DNA template in differentiated, non-proliferating cells, and support the validity of using Feulgen-Naphthol Yellow S cytophotometry of nuclear non-histone proteins as an estimate of gene expression in such cells.     

Diurnal variations in endogenous RNA polymerase activity and amounts of nuclear non-histone protein,DNA and cytoplasmic protein in rat liver

Summary From rats fed ad libitum and kept under a 12+12 h light/dark regimen, the DNA dependent RNA polymerase activity of liver cell nuclei was determined every four hours. From identical rats, nuclear non-histone protein and DNA, and cytoplasmic protein was determined by Feulgen-Naphtol Yellow S cytophotometry of isolated liver cells. The minimum: maximum ratio of the RNA polymerase activity is 0.77; the min:max ratio of nuclear non-histone protein is 0.84. These two parameters have identical time courses with a gradual decline during the light period and a sharp rise after the onset of the dark period. The variations in nuclear DNA content, estimated as the amount of Feulgen stain bound, closely parallel those of the RNA polymerase activity and nuclear non-histone protein content (min:max=0.96). The amount of cytoplasmic protein per cell also varies throughout the day, but its time curve lags behind those of nuclear nonhistone content and RNA polymerase activity. These results are consistent with the concept of nuclear non-histone proteins as de-repressors of the DNA template in differentiated, non-proliferating cells, and support the validity of using Feulgen-Naphthol Yellow S cytophotometry of nuclear non-histone proteins as an estimate of gene expression in such cells.     

Hot hydrochloric acid hydrolysis and UV Feulgen staining of rat liver sections fixed in CRAF and CRAF-like fixative.

Sections of rat liver fixed in CRAF III and Nawaschin's fixative in Dutt's modification were subjected to hydrolysis in 1N HCl at 60 degrees C for different periods of time and to Schiff's staining according to the UV Feulgen technique. The study showed that Feulgen reaction intensity depends upon time of hydrolysis, optimum coloration being possible only after 10-15 min of hydrolysis. Prolongation of hydrolysis beyond this time produced decreased staining intensity which is retained for further 35 min of hydrolysis thus forming a plateau. Further prolongation of hydrolysis results in gradual deterioration of the staining intensity which culminates in utterly pale coloration of the nuclei after one hour's hydrolysis. A possible explanation for this phenomena is suggested.     

The influence of chromatin compactness on the stoichiometry of the Feulgen-Schiff procedure studied in model films. I. Theoretical kinetics and experiments with films containing isolated deoxyribonucleic acid.

Theoretical considerations on the expected kinetics of the course of the Feulgen-Schiff reaction show that the leveling off of the first part of the Feulgen hydrolysis curve can be explained by the gradual conversion of deoxyribonucleic acid (DNA) to apurinic acid (APA). In addition, depolymerization of DNA caused by the acid used for hydrolysis can account for the decline after a maximum is reached in this curve. With the aid of polyacrylamide model films containing DNA, a detailed study was made both of the process of purine liberation which results in the formation of APA and of the depolymerization processes which cause losses of stainable material. The liberation of purine bases was analyzed by ultraviolet absorbance measurements and by gel chromatography of the neutralized hydrolysing acid. APA concentration was monitored by following the loss of ultraviolet absorbance associated with the purine losses. The depolymerization process was followed by phosphorus determinations. The experimental results were found to be in accordance with the kinetics expected from the theoretical model.     

Feulgen-DNA response and chromatin condensation in Malpighian tubules of Melipona rufiventris and Melipona quadrifasciata (Hymenoptera, Apoidea)

Melipona quadrifasciata and Melipona rufiventris are stingless bee species which present low and high heterochromatin content, respectively, on their mitotic chromosomes as assessed visually after a C-banding assay. However, these species do not show differences in the C-banding responses of their Malpighian tubule interphase nuclei. In the present study, the Feulgen-DNA response, which could inform on differences in DNA depurination due to differences in chromatin condensation, was compared in the cell nuclei of the Malpighian tubules of these species. It was hypothesized that differences in acid hydrolysis kinetics patterns, as assessed by Feulgen reaction and studied microspectrophotometrically, could discriminate M. quadrifasciata and M. rufiventris interphase nuclei not distinguishable with the C-banding method. Feulgen-DNA values corresponding to more than one ploidy class were found in both species; these values at the hydrolysis time corresponding to the maximal DNA depurination for each ploidy degree were higher in M. quadrifasciata, reflecting a higher DNA content in the Malpighian tubule cell nuclei of this species compared to those of M. rufiventris at the same larval instar. The maximal Feulgen-DNA values of M. quadrifasciata after short (50 min) and long (90 min) hydrolysis times were found to be closer to each other, while those of M. rufiventris occurred sharply at the long hydrolysis time, indicating that DNA depurination in M. quadrifasciata occurred faster. This result is probably related to the involvement of differences in chromatin condensation; it agrees with the idea that M. rufiventris contains more heterochromatin than M. quadrifasciata, which is supported by the analysis of results obtained with the image analysis parameter average absorption ratio. The depurination kinetics studied here with the Feulgen reaction were revealed to be more pertinent than the C-banding technique in establishing differences in levels of chromatin condensation for these cell nuclei.     

Loss of Rna and Protein, And Changes in Dna During A 30-Hour Cold Perchloric Acid Extraction of Cultured Cells

KB cells derived from human carcinoma were fixed in acetic-alcohol (1:3) and extracted with 10% perchloric acid (PCA) at 4 C for 1, 3, 6, 9, 12, 24 and 30 hr. Cells were then washed in water and stained for nucleic acids, proteins, polysaccharides, and lipids. Control cells were kept in water for 30 hr prior to staining. Acridine orange (AO) fluorochroming revealed color changes in residual cytoplasmic and nucleolar RNA as well as DNA during extraction--interpreted as indicative of molecular alterations. All nucleic acid stains (AO, gallocyanin chromalum, and azure B bromide) demonstrated a differential extraction of RNA, with cytoplasmic RNA being removed in about 6 hr and nucleolar RNA requiring 6 more hours for complete extraction. Large granules appeared early in nuclei. These were positive for DNA by azure B, gallocyanin chromalum, Feulgen, and fluorescent-Feulgen. These same granules stained for protein by mercuric bromphenol blue and alkaline Biebrich scarlet. At 24 hr, there was visual and Feulgen-cytophotometric evidence for a slight loss of DNA, which may amount to 10-20%. There was a progressive loss of cytoplasmic and nuclear but not nucleolar protein during PCA treatment. Concurrently, large protein-positive granules appeared in the cytoplasm. Apparently, PCA treatment in combination with an aqueous wash was responsible for some protein loss. Glycogen was gradually lost (fluorescent PAS) and redistributed in cells. Lipids were unaffected (Sudan black B).     

Rearrangement of nuclear calmodulin during proliferative liver cell activation

Calmodulin increases about three-fold in rat liver nuclei after partial hepatectomy. The increase is maximal after 24 hours, when DNA synthesis is also maximal. During the same time re-distribution of calmodulin within the nuclear structure takes place, leading to its association with the nuclear matrix. Incubation of normal rat liver nuclei with Ca2+ induces association of calmodulin with the matrix, indicating that the re-distribution of calmodulin during the replicative period is related to the increase in nuclear Ca2+. The nuclear matrix contains several calmodulin binding proteins of which one, having Mr of 130 kDa, has been identified as myosin light chain kinase (MLCK). Three acceptor proteins, having Mr of 120, 65, and 60 kDa decrease 24 hours after partial hepatectomy, MLCK and a protein of Mr 150 kDa instead increase.     

The effect of sodium chloride on the extraction of DNA fragments during Feulgen acid hydrolysis

Synopsis Feulgen acid hydrolysis was performed on ascites tumour cells labelled with radioactive DNA-precursors. The development of fragments of apurinic acid and the extraction of purines were studied by monitoring the variations in the extraction rate during the hydrolysis when sodium chloride was either present or absent from the hydrolysis solution. The changes in the rate of extraction of purines and the alterations in the initial retardation of the apurinic acid extracting process followed approximately the same pattern. The extractability of apurinic acid fragments during hydrolysis in 0.3m HCl was found to be a maximum when the sodium chloride concentration was about 1m. Sudden exchange experiments, in which acid was substituted for sodium chloride after various times of hydrolysis, revealed a successive shortening of the extractable fragments during the low acid concentration hydrolysis. The results strengthen the view that, during hydrolysis, apurinic acid is lost from the cells through a reaction whose form is determined, first, by an initial retardation of the depolymerization, second, by the maximum length at which fragments developed through the depolymerization become soluble and are lost by diffusion, and last, at low acid concentrations, by a mechanism whose influence is equivalent to the presence of bonds between the fragments and an unextractable stable structure.     

Proportionalitätsfehler bei der Feulgen-Hydrolyse

Zusammenfassung Beim Vergleich des Feulgen-Farbgehaltes verschiedener Zellkerne (Leberzellen, Lymphozyten, Granulozyten und Spermien) traten nach Alkoholfixierung Abweichungen der gemessenen Feulgen-Werte von den nach dem Gesetz von der DNS- Konstanz zu erwartenden DNS-Gehalt dieser Kerne auf. Verglichen mit den Feulgen-Werten der diploiden Leberzellkerne ergaben Lympho- und Granulozyten bei allen Hydrolysezeiten zu niedrige (bis zu minus 20%), haploide Spermien im postmaximalen Hydrolysebereich zu hohe Feulgen-Werte (z. T. sogar höhere Werte als die diploiden Zellkerne). Innerhalb desselben Zelltypes wurden dagegen, auch beim Vergleich der verschiedenen Ploidiestufen der Leberkerne, keine Differenzen festgestellt.Da die an Leukozyten und Spermien beobachteten Abweichungen nach Methanol-Formalin-Eisessig-Fixierung nicht mehr auftraten und auch durch UV-absorptionscytophotometrische Messungen nicht bestätigt werden konnten, muß man annehmen, daß es sich um Proportionalitätsfehler handelt, die auf Hydrolyseunterschieden beruhen.Für die quantitative Feulgen-Cytophotometrie scheint daher die Methanol-Formalin-Eisessig-Fixierung besser geeignet zu sein als die Alkoholfixierung, bei deren Verwendung es leicht zu Proportionalitätsfehlern während der Feulgen-Hydrolyse kommen kann.

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Proportionality errors during feulgen hydrolysis

Summary Comparing the Feulgen dye-content of different nuclei (liver cells, lymphocytes, granulocytes and sperms) after alcohol-fixation deviations were found between the measured Feulgen values and the DNA-content to be expected from the DNA-constancy law. The Feulgen values of lymphocytes and granulocytes proved to be lower (up to minus 20%) than those of diploid liver nuclei at all hydrolysis times, while in the postmaximal range of hydrolysis the values of the haploid sperms were too high (even higher than those of the diploid nuclei). Such differences did not appear when nuclei of the same cell type in different DNA- ploidy classes (liver nuclei) were compared.Those deviations of leucocytes and sperms were no longer found after fixation in methanol-formalin-glacial acetic acid and, in addition, could not be confirmed by UV-absorption measurements. For that reason we suppose them to be due to proportionality errors caused by variations in the hydrolytic behaviour of the different nucleoproteins.Thus fixation in methanol-formalin-glacial acetic acid seems to be more suitable for quantitative Feulgen measurements than alcohol-fixation, which may easily give rise to proportionality errors during Feulgen hydrolysis.Moreover, to avoid any false interpretation of Feulgen data we should suggest controll measurements using another independent method (f. e. UV-absorption), or — if this is impossible — to check the Feulgen values after different fixations and variant hydrolysis times (premaximal, maximal, postmaximal).

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Mit Unterstützung durch die Deutsche Forschungsgemeinschaft.     

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.     

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.     

Immunocytochemical detection of sulphonylated DNA in tissue sections. An alternative to Feulgen staining of DNA

We report here on a new sensitive and highly specific DNA staining technique which we have called sulpho-DNA staining. DNA staining is based on a sulphonylation reaction of 2'-deoxycytidine or cytidine that takes place in the 6th position of cytosine with ensuing immunodetection of the sulphonylated DNA. The specificity of DNA staining is introduced by the use of an antibody recognizing only modified DNA but not modified RNA, by recourse to an additional acid hydrolysis step which destroys RNA but not DNA. We describe here the optimal conditions for the sulphonylation of DNA using O-methylhydroxylamine and metabisulphite as reactants. The new DNA stain labels all nuclei in either normal human tissue or in tumor cells. For nuclear DNA the staining signal is higher for the sulpho-DNA staining than for the Feulgen staining for nuclear DNA. This new DNA staining technique is suitable for use on tissue sections as well as on cytosmears.     

Differentiation-related death of an established keratinocyte line in suspension culture

An established keratinocyte line (XB), derived from a mouse teratoma, terminally differentiates in suspension culture in a manner similar to human epidermal keratinocytes. When surface-grown XB cells are placed in suspension culture, they lose colony forming ability very rapidly; within three days the loss is virtually complete. Measurement of the ability of the suspended cells to synthesize protein and RNA show that they begin to lose both after 12 hours, the rate of uridine and glycine incorporation falling nearly to zero in about 36 hours. The cells then become insoluble in ionic detergents, owing to the formation of disulfide-stabilized keratin filaments, and digest their nuclei. The total RNA content of the cells (a measure of ribosomes) begins to drop sharply about 12 hours after the cells are placed in suspension culture, and most RNA is eliminated by 24 hours. This process is independent of the presence of serum in the medium. DNA also begins to disappear from the cells, but this process is slower than ribosomal destruction and is strongly affected by the presence of serum. After seven days in the absence of serum, half the DNA still remains, and nearly all the nuclei are still visible, whereas during the same period in the presence of serum all visible nuclei and all DNA disappear. In contrast to the destructive process that takes place in the keratinocytes, 3T3 cells are much more stable in suspension culture. They show a reversible decline in their rate of amino acid incorporation, but no decline in their rate of uridine incorporation, and they undergo little loss in colony forming efficiency for several days. They retain most of their RNA and nuclei with full DNA content. The destructive process in suspended XB cells seems to be a model for the cell death that takes place in terminal differentiation of the keratinocyte.