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.     

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.     

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.     

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.     

Ploidy class-dependent metabolic changes in rat hepatocytes after partial hepatectomy

Glucose-6-phosphate dehydrogenase (G6PDH), succinate dehydrogenase (SDH) activity and the single-stranded RNA (ssRNA) content of isolated hepatocytes of different ploidy classes from adult male rats have been studied after partial hepatectomy using quantitative cytochemical means. The SDH activity and ssRNA content in all classes of hepatocytes are decreased during the first hours after operation followed by an increase above control values. The increase of both SDH activity and ssRNA content is significant only in the mononuclear diploid (MD) cells but not in the hepatocytes of higher ploidy classes and is related with the mitotic wave at 32 h after hepatectomy. After the mitotic wave, the values quickly return to normal levels. The G6PDH activity does not show any significant change in hepatocytes other than MD cells. In MD cells the G6PDH activity is elevated on a highly significant level up to a maximum value of 3.5 times the control value at 48 h after operation. The G6PDH activity in MD cells is returned to normal values within 14 days after operation. It is concluded that: 1. The MD cells show a distinct metabolic behaviour due to their function as stem cells of liver parenchyma and retain at least some of their fetal characteristics. 2. G6PDH activity is not a transformation-linked discriminant for neoplastic metabolism.     

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.     

Histochemical determination of histone and non-histone protein content in rat liver nuclei

Summary The purpose of this study is to compare the protein content of parenchymal and non-parenchymal nuclei, as isolated from rat liver. The nucleic have been separated by means of a 1 g-sedimentation technique. The protein content of the separated nuclei has been determined cytophotometrically using the Naphthol Yellow S staining procedure after TCA-extraction (corresponding with the total protein content) and directly (corresponding with the non-histone proteins). The ratio of the total protein content of non-parenchymal, parenchymal diploid and parenchymal tetraploid nuclei respectively was found to be 0.65:1.00:1.90. The ratio of non-histone protein to total protein was the same for all types of nuclei investigated, namely about 55%.     

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.     

The kinetics of the cell population of human liver parenchyma at different periods of life]

Processes of polyploidization in the liver parenchyma were investigated in the course of postnatal organism growth, stabilization of growth and ageing, using cytophotometry on the slides of isolated hepatocytes from normal livers of 140 donors aged from 1 day to 92 years. In addition, livers of human embryos (4, 5, 6 and 7 month old) were investigated. It is concluded that polyploid cells in the human liver appear in individuals aged from 1 to 5 years. However, during the postnatal development their relative number increases insignificantly. At the end of the intensive postnatal growth period the share of polyploid human liver cells is less than 3%. Binuclear cells with diploid nuclei are seen as early as in the embryonic liver. After birth their number increases slowly to reach 7.1% in the 16-20 year age group. The postnatal growth of human liver is due mainly to mitotic divisions of mononuclear diploid hepatocytes whose relative number is more than 90% during the postnatal growth. During the period of maturity (from 21 to 50 years), when the liver practically stops to grow, the levels of hepatocyte ploidy are changed insignificantly: part of 2c-hepatocytes decreases slowly (up to 84.8% by the end of period) and (2c x 2)-hepatocyte number increases slowly too. The number of polyploid cells increases by several times, but is equal only to 6.6% of all the hepatocytes counted. Under ageing, on the background of human liver atrophy, acceleration of hepatocyte polyploidization takes place. In the age group of 86-92 years parts of 2c- and (2c x 2)-hepatocytes reach 60.3 and 14.3%, resp., and the total share of polyploid cells is as much as near 25%, calculated from the cell population of liver parenchyma. The maximum ploidy levels in hepatocytes of normal human liver during ageing is becoming 16c and 8c x 2 for mononuclear and binuclear cells, resp. Transition rates among hepatocytes of different ploidy classes (2c--2c, 2c--2c x 2, 2c x 2--4c, 2c--4c) were calculated in addition to the coefficient of changing of the hepatocyte proliferative activity with the increase in its ploidy and cell death rate in different periods of human life. A rather high hepatocyte proliferative activity in the early postnatal period of human life was seen to lower during the following years of life. In maturity it is the lowermost to make less than 5% of that in newborns. During ageing the hepatocyte DNA-synthesizing activity being almost 1.6-1.7 times as much as in maturity.(ABSTRACT TRUNCATED AT 400 WORDS)     

Quantification of nuclear non-histone proteins by Feulgen-Naphthol Yellow S cytophotometry

Summary Owing to the accumulation of nuclear non-histone protein (NHP) (a) in cells entering the cell cycle from the quiescent state and (b) in continuously cycling cells during G₁ phase, a simultaneous determination of DNA and nuclear NHP is of high potential utility in cell kinetic studies. This paper provides guidelines for a Feulgen-Naphthol Yellow S staining technique for this purpose. It discusses details of the preparation and quantification procedures, and reviews the evidence for a quantitative relationship between nuclear Naphthol Yellow S binding and nuclear NHP.     

Development of tetraploidy in V79 spheroids

Summary Chinese hamster V-79-171 cells, when placed in suspension culture, spontaneously form multicell spheroids. As the spheroids enlarge the fraction of polyploid (predominantly tetraploid) cells increases and can approach 100% in very large spheroids. Spheroid size, rather than age, seems to be a major determinant for increased ploidy. When cell separation techniques were used to select enriched populations of diploid and tetraploid cells, the growth rate and plating efficiency of the diploid cells was always marginally higher, and they gradually became predominant in mixed monolayer cultures. Cloned tetraploid cells, however, generally remained quite stable, and no consistent ploidy dependent changes in radiosensitivity were observed relative to normal, diploid cell lines. This research was supported by grants CA 28793 and CA 23511 awarded by the National Cancer Institute, Bethesda, MD.     

Quantitative cytochemistry of nuclear and cytoplasmic proteins using the Naphthol Yellow S and dinitrofluorobenzene staining methods

Summary The total protein staining of biological specimens with the electrostatically binding Naphthol Yellow S or the covalently binding dinitrofluorobenzene must be interpreted as methods which yield data on the specific amino acid pool of the proteins concerned. Both dyes bind to certain free amino-acid side-chains, giving different dye-protein ratios for various proteins. In the presence of DNA, dinitrofluorobenzene stains all proteins present in cell nuclei, whereas Naphthol Yellow S only stains the majority of the non-histone proteins. When protein staining methods are combined with the Feulgen-Pararosaniline (SO₂) procedure for DNA, decreased Feulgen-DNA contents were measured in dinitrofluorobenzene-stained isolated nuclei and lymphocytes.     

Ploidy-Dependent Growth and Binucleation in Cultured Rat Hepatocytes

The proliferative activity of rat hepatocytes, cultured in the presence of epidermal growth factor (EGF) and insulin, was examined by immunostaining of S-phase cells labeled with bromodeoxyuridine (BrdU) in culture. Proliferation rates of the different hepatocellular ploidy and nuclearity classes were measured by fluorescence image cytometry or by microscope counting of immunostained cells. Effects of EGF and insulin were largely additive, the binuclear cells being more growth factor-dependent (showing less growth in the absence of factors) than the mononuclear cells. A serial warm-washing procedure was used to remove excess BrdU from the culture medium, allowing the study of hepatocellular binucleation by a BrdU pulse-chase approach. A high rate of binucleation was detected (50%, possibly suggesting a quantal mechanism), indicating that the hormones induce a binucleating (polyploidizing) type of growth similar to that normally observed in the liver of growing rats. The highest proliferative activity (labeling index) in the hepatocyte cultures was found among the diploid cells, independent of the degree of mitogenic stimulation. The labeling index was inversely correlated with ploidy, suggesting that the ability of hepatocytes to proliferate decreases with increasing polyploidization.     

A cytophotometric and karyometric study of the cardiac muscle cells of young rats exposed to intermittent high altitude hypoxia

Thirty-day-old rats were exposed to intermittent high altitude in barochamber (7000 m, 4 h per day, 4 exposures) and number of mono- and binucleated myocytes as well as DNA content per nucleus were determined in the right ventricular myocardium. The data indicate enhancement of mitotic division of mono- and binuclear diploid cells in hypoxic animals. Simultaneously, an increase in mononuclear and binuclear tetraploid cells occurred; the latter is probably due to DNA synthesis not followed by mitosis of some binuclear diploid cells.     

DNA ploidy and autophagic protein degradation as determinants of hepatocellular growth and survival

Hepatocytes have the ability to go through specialized cell cycles, which, during normal developmental liver growth, result in the formation of binuclear and polyploid cells. In the adult rat liver, the majority of the hepatocytes (about 70%) are tetraploid, 15-20% are octoploid, and only 10-15% are diploid (about 50% in humans). One-third of the hepatocytes in either rats or humans are binuclear (with two diploid or two tetraploid nuclei). Among cultured rat hepatocytes stimulated with growth factors (EGF and insulin), one-half of the mitoses are of the binucleating type (suggesting a "quantal" mechanism), causing one-third of the postmitotic cells to become binuclear. In contrast, regenerative liver growth, induced by partial hepatectomy, is predominantly nonbinucleating. During rat liver carcinogenesis, the early populations of phenotypically altered cells (foci) are predominantly diploid, as are the later neoplastic nodules and carcinomas, which can be shown to have a regeneration-like, largely nonbinucleating growth pattern. A negative correlation between growth capacity and ploidy can be demonstrated in cultured hepatocytes, regenerating livers, neoplastic nodules, and hepatocellular carcinomas, suggesting that suppression of binucleation and polyploidization may carry a growth advantage, in addition to helping to maintain a large population of diploid, potential stem cells. Since a diploid genome is less protected against mutagenic change than a polyploid genome, diploid tumor cells may, furthermore, be more prone than polyploid cells to undergo mutation-based progression toward increasing malignancy. The ability of liver tumor promoters like 2-acetylaminofluorene, cyproterone acetate, -hexachlorocyclohexane and methylclofenapate to induce nonbinucleating hepatocyte growth may, therefore, cooperate with the selective growth stimulation of cancer cells and cancer cell precursors to promote liver carcinogenesis.Autophagy, a mechanism for the bulk degradation of cytoplasm, contributes to intracellular protein turnover and serves to restrict cellular growth. Rat liver carcinogenesis is accompanied by a progressive reduction of autophagic capacity, preneoplastic livers having 50% and hepatocellular carcinoma cells only 20% as much autophagy as normal hepatocytes. The ascites hepatoma cell line AH-130 has virtually no autophagy during logarithmic growth, but some autophagy is turned on when the cells become growth-arrested at high cell density. Ascitic fluid from AH-130 cells is able to completely inhibit autophagy in normal hepatocytes, suggesting that the cancer cells may improve their growth ability through an autocrine, autophagy-suppressive mechanism. Hepatocytes from preneoplastic livers similarly maintain a low autophagic activity under restrictive culture conditions, thereby surviving much better than normal hepatocytes, which switch on their autophagy. In the presence of an autophagy inhibitor (3-methyladenine), normal and preneoplastic hepatocytes survive equally well, testifying to the importance of autophagy as a determinant of cell survival and growth.     

Analytical methods for the study of liver cell proliferation.

Various cytometric methods for analysis of regenerating rat liver growth (DNA ploidy distributions, binucleation, and DNA synthesis by in vivo BrdUrd incorporation) were evaluated. The overall hepatocellular growth rate (labeling index), the binucleation rate, and separate indices for mononuclear and binuclear cells could be measured simply by microscope counting of collagenase-isolated hepatocytes immunostained for BrdUrd. Flow cytometry of cells stained for BrdUrd and DNA provided labeling indices for the various hepatocellular DNA ploidy classes as well as for nonparenchymal cells (identified by their size-dependent light scatter), but could not distinguish between mononuclear and binuclear hepatocytes. Image cytometry, using fluorescence or Feulgen staining, was inferior to flow cytometry in terms of speed and DNA resolution, but allowed a complete analysis of all hepatocellular DNA ploidy and nuclearity classes. It may therefore be the method of choice, particularly for analysis of liver cell cultures from which single cells are not easily obtained. Fluorescence staining would seem to be preferable to Feulgen staining, since the latter could not be used simultaneously with BrdUrd staining and therefore required a two-step analysis. A non-immunological method, based on the ability of incorporated BrdUrd to quench DNA staining by a Hoechst dye, could only be applied to isolated nuclei, thus giving no information about binucleation. The latter method may be useful for analysis of tumors which are difficult to dissociate to intact whole cells.     

Changes in the ultrastructure and DNA and protein content in human atrial myocytes in cardiac hyperfunction due to mitral valve defects

Biopsies from human right auricles were obtained during open heart surgery, prior to valve replacement, from six patients (aged from 20 to 49 years) with rheumatic heart disease. DNA and the total protein contents were measured in isolated myocytes by means of the two wave-length scanning cytophotometry after the double Feulgen and Naphthol yellow S staining procedure. In all the biopsies polyploid hypertrophied myocytes predominate. The hypertrophic, nondegenerated cells and the cells with degenerative changes of varying severity (in the first place, changes of contractile apparatus and membranes) are present. The highest degree of cell ploidy occurs in patients of functional class IV according to the New York Heart Association classification, 72 to 98% of cells displaying octaploid and higher DNA values. With the increase in ploidy of myocytes in series 2c----4c----8c----16c----32c----64c the protein content increases only as 2.0----3.0----5.8----7.8----13.0----16.8. Neither direct correlation between the ploidy level and the degree of cell degeneration, no inverse correlation between the degree of degeneration and the value of ejection fraction was observed.     

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

Summary 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.     

Effects of an acridine half-mustard (ICR 191) on growth and ploidy of frog cells in culture

The effects of an acridine half-mustard, ICR 191, on the growth rate and ploidy of four haploid and two diploid lines of Rana pipiens cells in culture were studied. Growth curves indicate that the haploid and diploid cell lines were equally resistant to a 4-hour exposure of this drug (0.1 micrometer to 10 micrometer. ICR 191 treatment induced the haploid cell cultures to become diploid. The proportion of diploid cells increased progressively with respect to time after the 4-hour exposure period. The greater the concentration of ICR 191 applied, the more rapid the rate of conversion. Autoradiographic determinations of percent labelled nuclei indicate that DNA synthesis was not inhibited in haploid or in diploid cells. Therefore, the increased proportion of diploid cells did not originate from the small percentage of diploid cells in the initial population. Instead the haploid cells were converted to diploid cells. Time lapse cinematography indicated that the conversion mechanism was other than cell fusion. Conversion to higher ploidy did not occur when diploid cell cultures were exposed to ICR 191.     

不同倍性罗汉果果实的生长与甙类含量动态变化规律的研究

对不同倍性罗汉果果实的生长动态、甙类含量动态及其变化规律的研究。结果表明:多倍体与二倍体果实的生长和甙类动态变化规律基本一致。果实的生长动态均可分为3个时期:迅速生长期(1～20 d)、缓慢生长期(20～30 d)、停止生长期(30～90 d),80 d时果实的形态达到最大值,4x>2x>3x,多倍体表现出巨大性。而甙类含量的动态随日龄的增长均表现为:苦味的甙ⅡE转化为甙Ⅲ,两者依次出现和消失;最终都转化为高甜度的甙Ⅴ,即成熟罗汉果以甙Ⅴ为主;80 d时甙Ⅴ的含量达到最大,4x>3x>2x:多倍体的甜甙含量显著提高,特别是三倍体还具有无籽的特性。