Ultramicrochemical determination of nucleic acids in individual cells using the Zeiss UMSP-I microspectrophotometer. Application to isolated rat hepatocytes of different ploidy classes

Synopsis Edström's method for the ultramicrochemical determination of RNA and DNA in individual cells was modified for the measurement of extinction in u.v. light with the aid of the Zeiss scanning microspectrophotometer UMSP-I. With this new procedure, nucleic acids down to about 3 pg RNA or about 4 pg DNA can be measured with a very high accuracy.The method was applied to enzymatically isolated rat liver parenchymal cells. A mean DNA content of 6.52 pg was found for diploid cells. The DNA content of mononuclear cells of different ploidy levels and of binuclear cells showed a close proportionality with the nuclear ploidy and the number of nuclei per cell. The RNA content of mononuclear diploid cells amounted to 33.4 pg, yielding an RNA/DNA ratio of 5.12. The RNA/DNA ratio was similar for binuclear and mononuclear cells of the same ploidy level but decreased considerably with increasing nuclear ploidy.     

Immunocytochemical determination of ploidy class-dependent bromodeoxyuridine incorporation in rat liver parenchymal cells after partial hepatectomy

Summary Immunocytochemistry of bromodeoxyuridine (BrdU) incorporated in DNA was performed on cryostat sections of rat liver and on isolated hepatocytes after partial hepatectomy using a two-step labeling technique. The method enabled the detection of S-phase nuclei in both tissue preparations. Quantification of the number of labeled nuclei in sections showed that the number of nuclei in S-phase increased from 0.3% in control liver to about 36% at 24 h after partial hepatectomy. The detection of BrdU in isolated hepatocytes showed the same labeling index of binuclear diploid, mononuclear tetraploid and binuclear tetraploid cells. A special role for mononuclear diploid cells in proliferation did not seem to occur.     

Proliferative quiescence of normal mast cells resembles that of cold-sensitive mutant mastocytoma cells. Dominant expression of the quiescent state in heterokaryons

Normal murine peritoneal mast cells were fused to serum-deprived, non-proliferating cells of a cultured subline (41-SB-4) of the P-815 murine mastocytoma. Upon reincubation in medium containing 10% horse serum for 48 h, mono- and binuclear 41-SB-4 cells reentered S phase of the cell cycle, while mast cell X 41-SB-4 heterokaryons as well as mono- and binuclear mast cells remained in proliferative quiescence, indicating dominant expression of the quiescent state of mast cells. The quiescent state of normal mast cells thus resembles that of cold-sensitive (cs) mutant cells (21-F) of the undifferentiated P-815 mastocytoma: at the non-permissive temperature of 33 degrees C, the 21-F cells were found to enter a state of quiescence which is characterized by its dominant expression in heterokaryons and by morphological differentiation with the formation of metachromatically staining granules similar to those of mast cells. This suggests that the cellular control mechanisms involved in entry into proliferative quiescence and in morphological differentiation of cs 21-F cells may be analogous to those of normal mast cells and/or their precursors.     

Immunocytochemical determination of ploidy class-dependent bromodeoxyuridine incorporation in rat liver parenchymal cells after partial hepatectomy

Immunocytochemistry of bromodeoxyuridine (BrdU) incorporated in DNA was performed on cryostat sections of rat liver and on isolated hepatocytes after partial hepatectomy using a two-step labeling technique. The method enabled the detection of S-phase nuclei in both tissue preparations. Quantification of the number of labeled nuclei in sections showed that the number of nuclei in S-phase increased from 0.3% in control liver to about 36% at 24 h after partial hepatectomy. The detection of BrdU in isolated hepatocytes showed the same labeling index of binuclear diploid, mononuclear tetraploid and binuclear tetraploid cells. A special role for mononuclear diploid cells in proliferation did not seem to occur.     

Binucleation and polyploidization patterns in developmental and regenerative rat liver growth

The hepatocellular binucleation rate, measured as the percentage of binuclear cells amongst newly formed bromodeoxyuridine-labelled and immunostained collage-nase-isolated rat hepatocytes, decreased from 12% to 4% between days 30 and 40 after birth, rose to 20% between days 50 and 60, and then declined again to the adult rate of about 10% at day 80. During regenerative growth following a two-thirds partial hepatectomy, the rate of binucleation declined to about 3%, causing the fraction of binuclear cells to fall from 27% (before hepactectomy) to 5% (at 45 h after hepactectomy) as pre-existing binuclear cells replicated and formed mononuclear daughter cells. Essentially all (97%) hepatocytes replicated at least once, starting their DNA synthesis at around 13 h and reaching a peak at 30 h, irrespective of ploidy and nuclearity. At later time points, the diploid hepatocytes had a higher labelling index than the polyploid cells, suggesting a greater tendency to go through several cell cycles.     

Mitotic polyploidization of mouse heart myocytes during the first postnatal week

Summary Polyploidization of myocytes in the cardiac ventricle of mice occurs predominantly during the first week of the postnatal life. Using isolated cells it was shown that about 70 % of the cardiomyocytes become binuclear at this time (2c×2), while 10 % are mononuclear but contain 4c of DNA, where c was the haploid level of DNA. About 2 % of the cell population were represented by 4c×2 or 8c cells.Cytophotometry of Feulgen-stained DNA in ¹⁴C-thymidine-labeled nuclei has shown that the cells that enter the mitotic cycle are mainly diploid. After mitosis (30 h or more after thymidine application) the label was found predominantly in 2c×2 and 4c cell types. Comparison of the curves presenting dynamics of labeled mitoses and the accumulation of labeled binuclear cells reveals that binuclear 2c×2 cells are formed by acytokinetic mitosis. The formation of 4c mononuclear cells is accomplished via other types of mitotic arrest; this may be due, for example, to a block in the pro-or metaphase.Only very rare cases of cytotomy were detected and the number of newly formed 2c cells was very low. It is concluded that cell multiplication is practically arrested at this period of life, and growth of the ventricular mass is due to polyploidization of virtually all cycling cells, while their number remains unchanged. Mechanisms and functional significance of cardiomyocyte polyploidization are discussed.     

Ploidy class-dependent variations during 24 h of glucose-6-phosphate and succinate dehydrogenase activity and single-stranded RNA content in isolated rat hepatocytes

The time-dependent variations over 24 h of glucose-6-phosphate dehydrogenase (G6PDH) activity, succinate dehydrogenase (SDH) activity and single-stranded RNA (ssRNA) content have been investigated by cytophotometric analysis of cytochemically stained isolated hepatocytes of different ploidy classes from adult male rats. A marked variation of 48 % over the day in G6PDH activity of the mononuclear diploid cells was revealed, but no significant variation in the binuclear tetraploid cells. The cells of the inbetween ploidy classes showed an amplitude of variation of 38 % (binuclear diploid cells) and 24% (mononuclear tetraploid cells), respectively. All cells showed a maximum activity of the enzyme at the middle of the day and a minimum during the night. The relative enzyme activity per mononuclear diploid cell was significantly higher than the relative activity in the other cells, especially at its maximum. The variation of the SDH activity in hepatocytes isolated from the same rats was similar in all cells, irrespective of their ploidy class. The activity was highest at the end of the activity phase of the animals. The SDH activity per cell was directly proportional to the quantity of genome copies. The ssRNA content of the hepatocytes showed a time-dependent variation with a maximum during the resting phase of the animals and a minimum during their activity phase. The variation was larger in the mononuclear diploid cells than in the cells of other ploidy classes and the ssRNA content was also significantly higher in these cells than in the hepatocytes of other ploidy classes when calculated on the basis of genome copies. It is concluded that the large amplitude of variation over the day and the high relative amount of G6PDH activity and ssRNA content in mononuclear diploid cells is related to the function of these cells as stem cells of the liver parenchyma.     

Changes in pancreatic acinar cell nuclear number and DNA content during aging in the rat

Pancreatic acinar cells from rats 5 to 658 days (94 weeks) of age were isolated by enzymatic dissociation and stained with the DNA specific fluorochrome Hoechst 33258. The nuclear DNA content and the incidence of binucleation were estimated in these cells. Total pancreatic weight, RNA, protein and DNA, and the incorporation of 3H-thymidine into pancreatic acinar cell DNA were also estimated in similar animals as measures of pancreatic growth. From 5 to 17 days after birth, 95% of the cells were mononucleate diploid and 5% were binucleate diploid; but during the period of rapid pancreatic growth over the following 39 days, acinar cells became increasingly binucleate. By 56 days after birth, 64% of cells were binucleate with a diploid DNA content per nucleus; and the incidence of binucleation then remained constant. At 28 days of age, 4% of mononucleate cells were tetraploid, increasing to 6% at 658 days of age. At this time 3% of binucleate cells contained dual tetraploid nuclei. There is thus a rapid development towards diploid binucleate acinar cells in the growing, postnatal pancreas; and in the adult pancreas a small proportion of these cells develop tetraploid nuclei.     

Cytophotometric analysis of the cell population composition of the the preoptic area of the hypothalamus in the common frog

DNA contents in squashed cells of the adult frog hypothalamic preoptic region (HPR) were measured using the Feulgen and UV cytophotometry techniques. The histone-DNA ratio in the cell nucleus was determined by means of a combined Feulgen-heparin-Alcian blue staining procedure. The nuclei of the vast majority of HPR cells have a diploid DNA content. However, in cells of this group the mean values of DNA amount and the distribution range were always higher than those in hepatocytes used as a diploid standard. Such a heterogeneity in DNA content in the diploid part of HPR cell population could apparently suggest some differences in the nuclear chromatin arrangement to be always higher in spring before the frog spawning, and it seems to be characteristic of this type of cells. About 1 per cent of cells with hyperdiploid surplus of DNA (H2c cells) as well as of tetraploid cells (4c and 2c X 2 cells) is found in HPR in frogs sacrificed both in winter and in summer. The quota of these cells has no reference either to the frog's age or to the annual cycle. The fact that the mean DNA values in H2c and 4c cells are much higher than in the standard cannot be explained by the presence of different amounts of nuclear proteins only. It is suggested that at least some part of the highest DNA values may be due to an actual extra DNA synthesis in a small constantly existing pool of HPR cell population.     

Glucose-6-phosphate dehydrogenase activity in individual rat hepatocytes of different ploidy classes. I. Developments during postnatal growth

The glucose-6-phosphate dehydrogenase (G6PDH) activity of isolated male rat hepatocytes has been investigated in relationship to the ploidy classes of the cells during the first 20 weeks of postnatal growth. The G6PDH activity in the individual cells was measured with an improved quantitative cytochemical method. The data obtained showed that throughout the whole period of postnatal growth there existed a proportional relationship between the genome copies per cell and the amount of G6PDH activity per cell for binuclear diploid (BD), mononuclear tetraploid (MT) and binuclear tetraploid (BT) cells but not for mononuclear diploid (MD) cells. In the MD cells, which are the stem cells of the liver parenchyma, the activity measured was 1.5 times higher than expected. Furthermore, during postnatal growth, the G6PDH activity per hepatocyte was low at the age of 2 weeks, increased somewhat after weaning (5 weeks) and then more dramatically after 8 weeks to reach a maximum between 12 and 16 weeks. This development occurred in MT and BT cells at an earlier age than in MD and BD cells, in which the increase in enzyme activity followed some 3 weeks later. Castration of the rats before puberty did not influence the development of the amount of G6PDH activity per cell of any of the ploidy classes.     

Effect of ploidy on the response of V79 cells to ionizing radiation

The responses of diploid, tetraploid and near-hexaploid V79 cells to X-irradiation or DNA-associated 125I-decay were compared. When cell killing, following X-irradiation, was plotted against the induced level of DNA double-strand breakage (dsb) per unit length of DNA, there was no significant difference between the relationships for each cell line. This suggested that the number of X-ray-induced DNA dsb per cell required to produce a lethal lesion was proportional to ploidy. Consistent with the X-ray results, tetraploid cells required 121 +/- 4 and diploid cells 60 +/- 1 125I-decays to produce a lethal lesion. However, the hexaploid cells deviated from this relationship and required 137 +/- 5 decays. The relationship between relative elution and 125I decays/cell reflected cellular DNA content. It is concluded that current models of radiation action are unable to explain these findings satisfactorily.     

Structural changes of DNA induced by mono- and binuclear cancer drugs

The structural features of the drug-DNA adducts resulted from treatment of DNA with the platinum based mononuclear drug cisplatin and the binuclear drug [{trans-PtCl(NH3)2}2H2N(CH2)4NH2]Cl2 or bis(platin) have been investigated by atomic force microscopy (AFM). Reduction in the contour length of the DNA fragments has been observed after cisplatin treatment while, compaction and aggregation are found to be the primary structural modifications following treatment with the binuclear drug. The intermolecular interaction upon bis(platin) treatment leads to observation of highly condense aggregates without a distinct sight of single isolated DNA molecule. These differences in drug binding indicate that unlike the mononuclear drug cisplatin, bis(platin) causes extensive interhelical/intermolecular cross-linking through its multiple linking sites. To our knowledge, this is the first report of a comparative AFM study to monitor the effects of a mono- and a binuclear platinum anti-cancer drug on DNA structure. These observations should provide clues towards explaining the distinct biological activities of the two drugs.     

Reestablishment of the heterogeneous distribution of hepatic glutamine synthetase during regeneration after CCl4-intoxication

Intoxication of rats with CCl4 (1 ml/kg) resulted in the almost complete loss of glutamine synthetase (GS) specific activity and immunologically detectable enzyme protein known to be expressed exclusively in some hepatocytes of the perivenous zone of the liver acinus. During regeneration the specific activity as well as the original number of GS-positive (GS+) hepatocytes were reestablished. However, while the GS+ hepatocytes in control livers were arranged in up to 3 cell layers surrounding the central veins the same number of GS+ hepatocytes in regenerated livers formed a single cell layer only, most likely because the central veins were enlarged in diameter. Investigation of the nuclear pattern of GS+ and GS- hepatocytes of control animals in primary cultures revealed striking differences characterized by significantly more mononuclear diploid, binuclear diploid, and binuclear tetraploid cells among the GS+ hepatocytes and predominantly mononuclear tetraploid cells (70%) among the GS- hepatocytes. Immediately after liver damage by CCl4 and during regeneration small but significant changes in the nuclear pattern were noted for GS- hepatocytes. However, the first GS+ cells appearing during early regeneration showed a pattern of ploidy classes close to the original one found for GS- hepatocytes. These results indicate that new GS+ hepatocytes may be derived from formerly GS- cells which are induced to express GS if they have reached the border of the central veins.     

Polyploidizing mitoses and the biological meaning of polyploidy in liver cells]

The ontogenetic polyploidization of hepatocytes is regarded, within which normal mitoses are changed to polyploidizing mitoses, and diploid hepatocytes transform into polyploid mono- and binuclear cells. A new hypothesis is put forward of the biological significance of the liver cell polyploidy. The hypothesis takes into account a high level of spontaneous chromosomal aberrations in mitotic hepatocytes. The chromosome structural changes interfere with mitosis resulting in the chromosomal imbalance. Polyploidy bestows for hepatocytes a tolerance towards a chromosomal imbalance. Some implications of the hypothesis are discussed: unbalanced genome of hepatocytes after the treatment with mutagens and mitotic stimulators; the reasons of liver cell polyploidy differences in mammalian species; mechanisms of radioresistance of hepatocytes. Chromosomal imbalance of polyploid hepatocytes is assumed to be the basis for wome chronic liver diseases in man.     

Effects of Polyploidy on Photosynthetic Rates, Photosynthetic Enzymes, Contents of DNA, Chlorophyll, and Sizes and Numbers of Photosynthetic Cells in the C(4) Dicot Atriplex confertifolia

Photosynthetic rates, chlorophyll content, and activities of several photosynthetic enzymes were determined per cell, per unit DNA, and per unit leaf area in five ploidal levels of the C₄ dicot Atriplex confertifolia. Volumes of bundle sheath and mesophyll protoplasts were measured in enzymatic digestions of leaf tissue. Photosynthetic rates per cell, contents of DNA per cell, and activities of the bundle sheath enzymes ribulose 1,5-bisphosphate carboxylase (RuBPC) and NAD-malic enzyme per cell were correlated with ploidal level at 99% or 95% confidence levels, and the results suggested a near proportional relationship between gene dosage and gene products. There was also a high correlation between volume of mesophyll and bundle sheath cells and the ploidal level. Contents of DNA per cell, activity of RuBPC per cell, and volumes of cells were correlated with photosynthetic rate per cell at the 95% confidence level. The mesophyll cells did not respond to changes in ploidy like the bundle sheath cells. In the mesophyll cells the chlorophyll content per cell was constant at different ploidal levels, there was less increase in cell volume than in bundle sheath cells with an increase in ploidy, and there was not a significant correlation (at 95% level) of phosphoenolpyruvate carboxylase activity or content and pyruvate,Pi dikinase activity with increase in ploidy. The number of photosynthetic cells per unit leaf area progressively decreased with increasing ploidy from diploid to hexaploid, but thereafter remained constant in octaploid and decaploid plants. Numbers of cells per leaf area were not correlated with cell volumes. The mean photosynthetic rates per unit leaf area were lowest in the diploid, similar in 4×, 6×, and 8×, and highest in the decaploid. The photosynthetic rate per leaf area was highly correlated with the DNA content per leaf area.     

Liver cell polyploidization: a pivotal role for binuclear hepatocytes

Polyploidy is a general physiological process indicative of terminal differentiation. During liver growth, this process generates the appearance of tetraploid (4n) and octoploid (8n) hepatocytes with one or two nuclei. The onset of polyploidy in the liver has been recognized for quite some time; however, the cellular mechanisms that govern it remain unknown. In this report, we observed the sequential appearance during liver growth of binuclear diploid (2 x 2n) and mononuclear 4n hepatocytes from a diploid hepatocyte population. To identify the cell cycle modifications involved in hepatocyte polyploidization, mitosis was then monitored in primary cultures of rat hepatocytes. Twenty percent of mononuclear 2n hepatocytes failed to undergo cytokinesis with no observable contractile movement of the ring. This process led to the formation of binuclear 2 x 2n hepatocytes. This tetraploid condition following cleavage failure did not activate the p53-dependent checkpoint in G1. In fact, binuclear hepatocytes were able to proceed through S phase, and the formation of a bipolar spindle during mitosis constituted the key step leading to the genesis of two mononuclear 4n hepatocytes. Finally, we studied the duplication and clustering of centrosomes in the binuclear hepatocyte. These cells exhibited two centrosomes in G1 that were duplicated during S phase and then clustered by pairs at opposite poles of the cell during metaphase. This event led only to mononuclear 4n progeny and maintained the tetraploidy status of hepatocytes.     

Discrimination between precancerous and cancerous lesions of the uterine cervix by DNA measurements on tissue sections

Morphologically typical uterine cervical biopsies were separated into normal cervices, condylomas and cervical intraepithelial neoplasias (CIN) grades I, II and III. At least 100 nuclei per lesion were measured on 4 micron Feulgen-stained sections using a Zeiss microspectrophotometer, with a variant of the plug method used to compute the nuclear DNA content. DNA distribution histograms were then decomposed into subsets of diploid, tetraploid, octoploid and aneuploid cells. The decomposition, which assumed a log-normal model of polydiploidy distribution, led to the identification of six indices: (1) the percentage of diploid cells, (2) the percentage of tetraploid cells, (3) the percentage of octoploid cells, (4) the percentage of aneuploid cells with DNA contents less than tetraploidy, (5) the percentage of aneuploid cells with DNA contents between tetraploidy and octaploidy and (6) the percentage of aneuploid cells with DNA contents greater than octoploidy. These indices, along with the mean nuclear radius, the 5c exceeding rate and the 2c deviation index, generated a nine-dimensional space. Two methods of discriminant analysis on this space showed discriminating powers of 78.22% and 87.13%, respectively, as compared to the original diagnoses. The most discriminating variable in both analyses appeared to be the percentage of octoploid cells.     

Induction of mating type interconversion in a heterothallic strain of Saccharomyces cerevisiae by DNA damaging agents

Mating type interconversion of the yeast, Saccharomyces cerevisiae, is an example of a directed genome rearrangement leading to a change in gene expression and in the differentiation state of a cell. In heterothallic haploid cells this switching of the mating type from a to alpha or vice versa, which is accomplished by an intrachromosomal gene conversion mechanism, is a rare event, happening about once per 10(6) cells per generation. Those cells that have changed their mating type can be trapped as diploid colonies by making them mate with tester cells possessing complementary markers. We found that treating haploids with UV light or with chemical carcinogens before they could mate resulted in a significant and dose-dependent enhancement of the numbers of diploid colonies. By genetic as well as by DNA hybridization analyses, these diploid clones were proved to be descendants of haploids which had changed their mating type by the bona fide gene conversion process. Thus, the DNA damaging agents had caused the induction of a directed gene rearrangement. It is suggested that induction of genome rearrangements might be part of a general response to DNA damage, at least in yeast cells. If similar responses also took place in cell populations constituting multicellular organisms, induced gene rearrangements and a generally enhanced mobility of the genome as a consequence of DNA damage might play a determining role in chemical and radiation-induced carcinogenesis.     

Cytophotometric identification of tetraploid purkinje cells in young and aged rats

DNA content of cerebellar basket and Purkinje cells of four month, one year, and two year old albino rats was determined by Feulgen cytophotometry. DNA content per nucleus remained essentially constant during aging although there was a slight shift to lower Feulgen-DNA values occurring in the one year age group. Purkinje cells of all three age groups were found to contain tetraploid amounts of DNA as compared to diploid basket cells.     

Cytophotometric identification of tetraploid Purkinje cells in young and aged rats.

DNA content of cerebellar basket and Purkinje cells of four month, one year, and two year old albino rats was determined by Feulgen cytophotometry. DNA content per nucleus remained essentially constant during aging although there was a slight shift to lower Feulgen-DNA values occurring in the one year age group. Purkinje cells of all three age groups were found to contain tetraploid amounts of DNA as compared to diploid basket cells.