Age-related alterations in the size of human hepatocytes

Age-related alterations in the size of human hepatocytes (both mononuclear and binucleate forms), were studied in histological sections and in separated cells and nuclei using cytophotometrical and microspectrophotometrical methods. The following results were obtained: 1. The volume of nuclear DNA increased in proportion to nuclear size. The increase occurred in a group pattern reflecting nuclear polyploidization. 2. Cell size increased in proportion to nuclear size. Tetraploid cells (4C) were roughly two times greater than diploid cells (2C). 3. In most of the binucleate cells examined, the ploidy class of the two nuclei in a binucleate cell was observed to be equal. Heterogeneity of the ploidy class among the nuclei of a binucleate cell was present in less than 1% of total binucleate cells examined. The nuclear DNA volume of individual nuclei in binucleate cells appeared to be the same as that of mononuclear cells. 4. The cell size of binucleate cells corresponded with that of mononuclear cells whose ploidy class was the same as the sum of the ploidy classes of two nuclei of a binucleate cell. 5. The incidence of binucleate cells in the lobular periphery was about 4 to 6% in the third decade, and increased slightly with age up to 5 to 7% in the tenth decade. 6. The incidence of binucleate cells in the liver at different ages followed a similar pattern to that observed in mononuclear cells whose ploidy class was half of the sum of ploidy classes of the two nuclei of the binucleate cell.     

Flow cytometric analysis of mouse hepatocyte ploidy

Preparative and mathematical procedures are presented for the investigation of the ploidy pattern of liver cells. The DNA content of enzymatically-isolated liver cells and of nuclei was measured by flow cytometry. The true DNA content could not be measured directly due to super-position of statistical coincidences (demanding "first mode correction") and incomplete separation of the nuclei in binucleate hepatocytes (demanding "second mode correction"). The statistical coincidences (caused by simultaneous measurement of two or more particles or subsequent reaggregation of particles) were corrected by splitting the "unnatural" i.e., aneuploid DNA content, and classifying it with the normal ploidy classes. In addition, the higher normal ploidy classes were reduced by the proportion of the measured coincidences in favour of the lower ones. The second mode correction applied to nuclear distributions only. It is a probability calculation based on counting nuclear pairs on microscope slides, and resulted in a 10% increase of diploid nuclei and a larger standard deviation between the age groups. 8c and 16c values were reduced. The tetraploid values were unchanged.     

Differences in the flow and absorption cytometric DNA distributions of mouse hepatocytes and tumor cells

We have determined the DNA content, the ploidy levels, and the percentages of different cell types present in small and large mouse mammary tumors as well as in young and old mouse livers by using absorption and flow cytometry. Absorption cytometry data indicated a significant increase in the proportion of transformed G0/G1 cells in the tumors as compared to that of the stromal G0/G1 cells with progressive tumor growth. This increase was not detected by flow cytometry. In both young and old mouse livers, a small number of cells of higher ploidy (8C and 16C) were detected by absorption cytometry but were not apparent in histograms obtained by flow cytometry. Furthermore, changes in the proportions of liver cells of different ploidy with age were apparent in absorption cytometry data but not in flow cytometry data. In one mouse liver experiment, a 6C cell peak appeared in the flow cytometry histogram, but a direct measurement of DNA content by absorption cytometry failed to detect cells with such a peak. We therefore believe that some caution may be warranted in the use of flow cytometry alone for evaluation of DNA distributions and of the proportions of different types of cells in complex solid tissues.     

Studies on DNA content of hepatocytes in cirrhosis and hepatoma by means of microspectrophotometry and radioautography

In order to clarify the underlying mechanism of malignant transformation from cirrhosis to hepatoma the cell kinetics of hepatocytes were studied in these two conditions. The content and synthesis of DNA in hepatocyte nuclei were investigated, by means of Feulgen-microspectrophotometry and tritiated thymidine radioautography, in cirrhotic and noncancerous parts of hepatoma with concomitant cirrhosis. The distribution of ploidy patterns was widely spread, from hypodiploid to hyperpolyploid, in the noncancerous parts of a cirrhotic liver containing hepatoma. In normal liver, each paired nuclear DNA content of a binucleate cell recorded almost the same amount, whereas in the noncancerous as well as in hepatoma cells much difference of DNA content was observed between the paired nuclei of the binucleate cells. The ploidy pattern of hepatocytes in patients with liver cirrhosis, who had developed hepatoma during follow-up periods of several months to several years, appeared to resemble that in noncancerous parts of hepatoma cases. On the other hand, the incorporation of tritiated thymidine into hepatocytes was found to be markedly increased in noncancerous parts as well as in cirrhotic liver developing hepatoma during follow-up periods. These results suggest the possibility that the hepatocytes in noncancerous parts of hepatoma have deranged cell-kinetics which might be a driving factor for the development of malignancy.     

Studies on DNA content of hepatocytes in cirrhosis and hepatoma by means of microspectrophotometry and radioautography

Summary In order to clarify the underlying mechanism of malignant transformation from cirrhosis to hepatoma the cell kinetics of hepatocytes were studied in these two conditions. The content and synthesis of DNA in hepatocyte nuclei were investigated, by means of Feulgen-microspectrophotometry and tritiated thymidine radioautography, in cirrhotic and noncancerous parts of hepatoma with concomitant cirrhosis. The distribution of ploidy patterns was widely spread, from hypodiploid to hyperpolyploid, in the noncancerous parts of a cirrhotic liver containing hepatoma. In normal liver, each paired nuclear DNA content of a binucleate cell recorded almost the same amount, whereas in the noncancerous as well as in hepatoma cells much difference of DNA content was observed between the paired nuclei of the binucleate cells. The ploidy pattern of hepatocytes in patients with liver cirrhosis, who had developed hepatoma during follow-up periods of several months to several years, appeared to resemble that in noncancerous parts of hepatoma cases. On the other hand, the incorporation of tritiated thymidine into hepatocytes was found to be markedly increased in noncancerous parts as well as in cirrhotic liver developing hepatoma during follow-up periods. These results suggest the possibility that the hepatocytes in noncancerous parts of hepatoma have deranged cell-kinetics which might be a driving factor for the development of malignancy.     

A method for determining ploidy distributions in liver tissue by stereological analysis of nuclear size calibrated by flow cytometric DNA analysis

A method is presented for determining ploidy distributions in mouse liver from image analysis with stereological estimations of nuclear size in tissue sections. Nuclear profile distributions obtained from profile measurements were subjected to a mathematical unfolding procedure in order to obtain the nuclear size distributions. Based on the assumption that nuclear size increases monotonically with nuclear DNA content, flow cytometric DNA analysis of suspensions of liver cell nuclei was used to calibrate the method, thus yielding the mean nuclear size of each ploidy class, i.e., diploid, tetraploid, and octaploid nuclei. After the size interval for each of the ploidy classes was determined, the method allowed determination of ploidy distributions in mouse liver by stereological image analysis alone. The method was established from combined stereological and flow cytometric measurements on liver tissue representing two different stages of liver regeneration after two-thirds partial hepatectomy, and it was tested against an independent set of data representing a marked increase in the portion of S-phase cells.     

Flow cytometric analysis of isolated rat liver nuclei during growth

The development of hepatocyte polyploidy in rats aged up to 4 months was analyzed by flow cytometry using both scatter and fluorescent parameters to distinguish DNA diploid and DNA tetraploid populations and to discriminate between parenchymal and non-parenchymal compartments. The precise origin of each class of nuclei was assessed in whole liver homogenate using purified hepatocytes, obtained by liver perfusion followed by separation on Percoll gradient, and identifying the peaks corresponding to parenchymal nuclei. The results indicate that preparative procedures involving homogenization of the rat liver tissue caused loss of the DNA octaploid population. Data on the relative proportion of the different DNA ploidy elements during rat liver development, which are in good agreement with those observed by cell analysis by means of microspectrophotometry, indicate the usefulness of flow cytometry as a choice method for the analysis of ploidy distribution.     

Human hepatocyte polyploidization kinetics in the course of life cycle

The processes of polyploidization in normal human liver parenchyma from 155 individuals aged between 1 day and 92 years were investigated by Feulgen-DNA cytophotometry. It was shown that polyploid hepatocytes appear in individuals from 1 to 5 years old. Up to the age of 50 years the accumulation rate of binucleate and polyploid cells is very slow, but subsequently hepatocyte polyploidization is intensified, and in patients aged 86–92 years the relative number of cells with polyploid nuclei is about 27%. Only a few hepatocytes in the normal human liver reach 16C and 8C×2 ploidy levels for mononucleate and binucleate cells respectively. Using a mathematical modeling method, it was shown that during postnatal liver growth the polyploidization process in human liver is similar to that in the rat, and that polyploid cells are formed mainly from binucleate cells. As in rats, prior to an increase in ploidy level, diploid human hepatocytes can pass several times through the usual mitotic cycles maintaining their initial ploidy level. After birth, only one in ten hepatocytes starting DNA synthesis enters the polyploidization process. At maturity about 60% of 2C-hepatocytes starting DNA synthesis divide by conventional mitosis, the rest dividing by acytokinetic mitosis leading to the formation of binucleate cells. During ageing the probability of hepatocyte polyploidization increases and in this period there are two polyploid or binucleate cells for every diploid dividing by conventional mitosis.     

Mechanism of ploidy shift from diploidy to tetraploidy in MSPC-1 mouse myeloma

In order to elucidate the cytological mechanism of ploidy shift from diploidy to tetraploidy in MSPC-1 mouse myeloma, the process of cell division was observed in living cells under phase contrast microscope. It was suggested that loss of cytokinesis and subsequent formation of binucleate cells are the major causes of such a ploidy shift. Elevated frequencies of binucleate cells during the transition phase of ploidy shift from diploidy to tetraploidy also supported the above notion. The possibility of cell fusion as a cause of the ploidy change could be eliminated by analyses of marker chromosomes and incorporation pattern of [³H]thymidine into binuclei.     

Excessive reversible phenobarbital induced nuclear DNA-polyploidization in the growing mouse liver

Summary Phenobarbital was injected intraperitoneally into male white NMRI mice aged 0.5, 1, 1.5, 3, 6 and 12 months at a dose of 120 mg/kg body weight for 10 consecutive days. The 0.5 month-old mice did not tolerate the phenobarbital dose and died. The experimental animals and one of the controls were sacrificed 1, 3, 5, 10, 15 and 20 days after phenobarbital administration was started. Liver weights were recorded and liver cells were isolated. The number of nuclei per cell was determined and the DNA-content of each single nucleus was measured by Feulgen fluorescence cytophotometry. Liver weights showed an increase of 25–30% during phenobarbital treatment and returned slowly to lower values after cessation of drug application. The hepatic enlargement was accompanied by an excessive and likewise reversible nuclear and whole cell DNA-polyploidization, i.e. polyploidization beyond the physiological age-dependent ploidy level; for example, mean values of 7.7 c per nucleus (versus 4.2 c in the controls) and 14.3 c for whole liver cells (versus 7.5 c in the controls) were found in 3 months-old animals after 5 days of treatment. As with the induction of microsomal enzymes, the augmentation of smooth endoplasmic reticulum, and the increase of RNA- and protein-synthesis, excessive DNA-polyploidization of liver cell nuclei appears to be an expression of hepatocellular hypertrophy due to the functional or metabolic stress imposed upon the liver by large quantities of phenobarbital. After cessation of drug administration the abnormally high ploidy cells are eliminated-probably by necrobiosis — and the liver cells return to their normal age-dependent DNA-ploidy level. The liver cells of the one-month-old animals revealed the physiological polyploidization to be slightly inhibited. This is probably due to some toxic effect of phenobarbital. Phenobarbital did not alter the number of nuclei per liver cell.Supported by Deutsche Forschungsgemeinschaft, Grant No. Bo 395/5     

Development of binuclearity and DNA-polyploidization in the growing mouse liver

Summary Suspensions of intact liver cells were prepared from 36 male NMRI mice of different age after perfusion of the liver with ice-cold calcium- and magnesium-free phosphate buffer (CMF). The suspensions of the isolated hepatocytes were smeared on slides, fixed, hydrolized and stained by fluorescent acriflavine-Schiff-Feulgen reaction. The number of nuclei per cell was determined in a phase-contrast microscope. Quantitative fluorescent cytophotometric measurements of nuclear Feulgen-DNA were performed on individual nuclei. At the age of 0.5 month, 55% of the hepatocytes were found to be mononuclear, 45% binuclear. In the animal groups aged 1 month, 1.5 months, 3 months, 6 months and 12 months, the percentage of binuclear hepatocytes remained constant at about 80%. Very few liver cells with 3 or 4 nuclei were detected. Feulgen-DNA-measurements revealed a predominance of 2c and 4c nuclei at ages 1 month and 1.5 months with logarithmic increase of 8c nuclei and a decrease of the 2c nuclei. From 1.5 months on 16c nuclei were found, which never exceeded 8%. When total DNA-ploidy of the hepatocytes was calculated similar kinetics at a higher ploidy level were observed. 2c hepatocytes existed in small percentages at very young ages up to 1.5 months, but were also occasionally found in older animals. With increasing age the number of 16c hepatocytes increased logarithmically with a concomitant decrease of the 4c hepatocytes. The percentage of 8c liver cells remained more or less constant. Few hepatocytes with a 32c total DNA content were found in mice aged 3 months and older. In one-year-old mice the mean DNA-ploidy was calculated to be 5.8c per liver nucleus and 10.0c per whole hepatocyte.Supported by Deutsche Forschungsgemeinschaft, Grant No Bo 395/5     

Hepatocyte ploidy in normal young rat

The aim of the present study was to examine the relation between hepatocyte size and ploidy in Sprague-Dawley rat liver. Therefore, subpopulations of hepatocytes of various sizes were separated from the isolated crude hepatocyte population either mechanically or by using centrifugal elutriation. Hepatocyte size was determined on scanning electron microscopy photographs. Ploidy of hepatocytes was assessed by flow cytometry. The crude hepatocyte population was very heterogeneous in sizes, with diameters ranging from 8 to 39 microm. Hepatocyte ultrastructure was well preserved as demonstrated by transmission electron microscopy. The distribution of hepatocytes within the ploidy classes was the following: 19.6+/-3.6% diploid, 56.2+/-3.2% tetraploid and 3.4+/-0.6% octoploid mononucleated cells. Thus approximately 79% of hepatocytes appeared mononucleated. The binucleated hepatocytes (21%) had two diploid nuclei (18.7+/-2.9%) or two tetraploid nuclei (2.1+/-0.6%). A similar distribution of hepatocytes into ploidy classes was obtained in subpopulations of hepatocytes of various sizes. Our findings suggest that distribution into ploidy classes is not strictly correlated with hepatocyte size. In accordance with previous observations, our results on hepatocyte ploidy from periportal or perivenous origin using digitonin perfusion, is in favour of the existence of ploidy zonation within the rat hepatic lobule.     

Characterization and cell cycle kinetics of hepatocyte populations isolated from adult liver tissue by a nonenzymatic procedure

Suspensions of liver cells enriched in lobular parenchymal hepatocytes were isolated from adult mouse hepatic tissue by nonenzymatic dispersion in chelating buffer and sedimentation of the released cells at unit g. Single cell suspensions so obtained were suitable for flow cytometric measurements of hepatic ploidy class distributions. The more quickly sedimenting cell population consisted of 88% albumin/transferrin-positive epithelial hepatocytes, the nuclei of which were bimodally distributed with respect to RNA content. This dual G1 population was observed in 2C DNA content liver nuclei prepared by several methods and appears to be a general cytochemical characteristic of adult liver parenchymal cells.     

The fractionation of nuclei from mammalian cells by zonal centrifugation

1. Purified liver nuclei from adult rats separate into two main zones when centrifuged in the slow-speed zonal rotor. One zone contains diploid nuclei, the other tetraploid. 2. The effect of age on the pattern of rat liver ploidy was examined. Tetraploid nuclei are virtually absent from young animals. They increase in proportion steadily with age. Partial hepatectomy disturbs the pattern of ploidy. 3. The zonal centrifuge permits the separation of diploid, tetraploid, octaploid and hexadecaploid nuclei from mouse liver. 4. Rat liver nuclei are isopycnic with sucrose solutions of density 1.35 at 5 degrees .     

Flow cytometric analysis of polysomaty and in vitro genetic instability in potato

The analysis of nuclear DNA contents in various tissues of potato genotypes showed that flow cytometry is a rapid method to characterize large populations of cells for polysomaty, that is, the occurrence of cells with normal DNA levels together with cells containing endoreduplicated nuclei. The proportion of endoreduplicated nuclei varied in different tissues and genotypes of potato. The analysis of callus and cell cultures showed that the temporal changes in nuclear DNA contents during in vitro growth can be followed and the degree of polyploidization quantified. It is concluded that flow cytometry is a highly suitable method to detect ploidy changes in differentiated plant tissues and calli which are often not amenable for chromosome number determination.     

Flow cytometry analysis of DNA ploidy levels and protein profiles distinguish between populations of Lumbriculus (Annelida: Clitellata)

Variations in DNA ploidy have been observed in Lumbriculus, a freshwater annelid, as well as in other clitellates. Interpretation and application of experimental results using these animals may be impacted as ploidy levels affect the protein expression, reproductive behavior, and response to stressors. Ploidy is typically determined by chromosome spreads, a time‐consuming and inefficient method. We adapted flow cytometry protocols used on vertebrates and plants to determine the ploidy levels in different populations of Lumbriculus, including a laboratory strain (Environmental Protection Agency), a commercial strain (Aquatic Foods), and worms collected from natural habitats. To isolate nuclei, worms were homogenized, filtered to remove cell debris, and centrifuged through Optiprep? density gradients. Nuclei were recovered, treated with RNAse, and stained with propidium iodide. Flow cytometry of the labeled nuclei showed that Lumbriculus from natural habitats in Minnesota and Iowa were diploid, with an estimated genome size of 2.7 pg. Populations from natural habitats in California and Oregon were highly polyploid, as were the laboratory and commercial strains. Chromosome spreads verified the high ploidy levels indicated by flow cytometry results, but also suggested that flow cytometry may be underestimating the DNA content levels. Staining of nuclei with diamidino‐2‐phenylindole indicated that this may be due to high levels of heterochromatin in nuclei from polyploid forms of Lumbriculus. To further compare the populations, proteins in worm homogenates were subjected to isoelectrofocusing gel electrophoresis. Distinct protein profiles were seen; one was shared in common by the diploid worms, the other was characteristic of polyploid populations. Diploid worms could also be distinguished from polyploid worms based on differences in hemoglobin linker proteins. The results further support taxonomic classification of the diploid and polyploid forms of Lumbriculus as distinct species.     

Vertical heterogeneity of DNA ploidy level assessed by flow cytometry in calli of Passiflora Cincinnata

During in vitro culture conditions, callus tissue is exposed to different intensities of environmental stress, which may induce somaclonal variation. Among the possible resulting abnormalities, callus cells can exhibit distinct DNA ploidy levels, a type of somaclonal variation associated with euploidy and/or aneuploidy. As somaclonal variation has been regarded as both a positive and negative phenomenon, the development of strategies to carefully assess the stability of DNA ploidy level within callus tissue is highly valuable. To this end, the present work aimed to evaluate the presence of intra- and inter-calli heterogeneity in relation to DNA ploidy level and nuclei density by flow cytometry. Calli were induced from cotyledonary leaves of Passiflora cincinnata, a wild passion fruit species. Embryogenic friable calli cultivated for 2, 6, and 9 mo were classified as young, intermediary, and old, respectively. These calli were horizontally sliced from the bottom-up at approximately the same thickness, and a total of 160 layers were evaluated by flow cytometry. Inter- and intra-calli heterogeneities were detected in relation to nuclei density and DNA ploidy level. Additional analysis was performed to identify the most proliferative layer. We conclude that care must be taken when using callus as source material for flow cytometry, since one portion cannot represent the whole cell mass. Moreover, in order to prevent the emergence of undesired ploidies during clonal propagation, callus culture time should not be prolonged.     

Genome size and ploidy level: new insights for elucidating relationships in Zygosaccharomyces species

Ploidy is a fundamental genetic trait with important physiological and genomic implications. We applied complementary molecular tools to highlight differences in genome size and ploidy between Zygosaccharomyces rouxii strain CBS 732T and other related wild strains (ATCC 42981, ABT 301, and ABT 601). The cell cycle analysis by flow cytometry revealed a genome size of 12.7+/-0.2 Mb for strain CBS 732T, 21.9+/-0.2 Mb for ATCC 42981, 28.1+/-1.3 Mb for ABT 301, and 39.00+/-0.3 Mb for ABT 601. Moreover, karyotyping analysis showed a high variability, with wild strains having a higher number of chromosomal bands than CBS 732T. The ploidy level was assessed comparing genome size from flow cytometry with the average haploid size from electrophoretic karyotyping. Strain CBS 732T showed an haploid DNA content, whereas the wild strains a diploid DNA content. In addition gene probe-chromosome hybridization targeted to ZSOD genes showed that wild strains with a diploid DNA content have two ZSOD copies located on different chromosomes.     

Cytological Analysis of Anastomoses and Vegetative Incompatibility Reactions in <Emphasis Type="Italic">Helicobasidium monpa</Emphasis>

Our examination of the cytological characteristics of the vegetative incompatibility reaction in a filamentous basidiomycete, Helicobasidium monpa, by analyzing the fluorescence emitted by ethidium bromide and acridine orange stained nuclei is described. Hyphal anastomoses between strains belonging to different mycelium compatibility groups (MCG) were observed with cell death in fused hyphae, whose nuclei were intensified by ethidium bromide. In contrast, the nuclei in a living cell were not intensified by staining with ethidium bromide, but were intensified by staining with acridine orange. These results indicate that in H. monpa, ethidium bromide staining is a useful method for detecting dead cells. We also examined the relationships between the alternation of ploidy and hyphal anastomosis formation using the newly developed method on filamentous fungi. The tetraploid monokaryon strain derived from the original dikaryon strain by continuous subculture could not be fused to any wild type strains, but the original dikaryon strain could be fused without cell death to only the same MCG strain. In contrast, the haploid dikaryon strain derived from the original monokaryon strain fuses to several strains belonging to different MCGs without cell death. These results suggested that the cellular ploidy of this fungus is closely related to its mating system and, H. monpa may be a self-fertilizing fungus. Received: 13 June 2001 / Accepted: 8 August 2001