Regeneration of the liver of Chinese hamster Cricetulus griseus

Using cytofluorimetry and interferometry, hepatocyte DNA, dry mass and distribution of hepatocyte ploidy classes were measured in hamsters Cricetulus griseus in 1 month after partial hepatoctomy. Ploidy of normal liver hepatocyte was 2.35 +/- 0.03 (mean +/- SD) c. Modal ploidy class was presented by mononuclear hepatocytes with diploid nuclei (82.4 +/- 1.3 %). Hepatocyte dry mass was 605.2 +/- 4.8 pg. One month after partial hepatectomy the distribution of ploidy classes and dry mass of hepatocyte did not change. A similar hepatectomy in mice resulted in significant polyploidization of liver parenchyma: the middle level of hepatocyte ploidy increased by 32% and mononuclear octaploid cells, the number of which increased 5-fold, composed modal ploidy class in place of 4cx2-hepatocytes predominated in control mice. The number of 8cx2-hepatocytes in the liver of mice creased by more than 5-fold. Thus, in contrast with mice, in hamsters Cricetulus griseus an increase in the liver mass followed partial hepatectomy depended completely on hepatocyte proliferation.     

Cellular mechanisms of cirrhotic rat liver regeneration. II. Proliferation, polyploidization and hypertrophy after partial hepatectomy

Using cytofluorimetry and absorptional cytophotometry, hepatocyte DNA and total protein contents were measured in intact and cirrhotic rats in 1, 3 and 6 months after partial hepatectomy (PH). It has been found that within one month of intact rat liver regeneration the level of hepatocyte ploidy rised by 25% to remain elevated for the next 6 months. This was due mainly to reducing the number of cells with diploid nuclei (2c 2-fold, 2c x 2 - 6.6-fold) and to rising the number of octaploid hepatocytes. In cirrhotic animals the ploidy level in hepatocytes increased in 3 months after PH, and decreased by 15% in 6 months. The number of hepatocytes with diploid nuclei (2c and 2c x 2) increased within 3-6 months in both control and cirrhotic rats. The protein content per diploid hepatocyte rised by 30% within 3-6 months of liver regeneration after PH. Special calculations have shown that within 3 months after PH the increase in the liver mass of control and cirrhotic rats was due completely to hepatocyte DNA synthesis, i. e. proliferation and polyploidization. Within the next 3 months of liver regeneration after PH, the contribution of polyploidization to liver mass increase was negative because of depolyploidization of liver parenchyma cell population. At this time hypertrophy was the main process determining the liver mass increase.     

A comparative analysis of the karyotypes of Cricetus cricetus and Cricetulus griseus

This study presents a comparison of the mitotic chromosomes of the two species of hamsters Cricetus cricetus (European hamster) and Cricetulus griseus (Chinese hamster), which have the same chromosome number of 2n=22. — G-banding procedure reveals striking similarities in both karyotypes and gives the possibility to analyse structural changes so that two examples for Robertsonian rearrangement can be observed. — A remarkable kind of difference between the two karyotypes becomes obvious after C-banding procedure. While Cricetus cricetus shows a large amount of predominantly centromeric heterochromatin, in Cricetulus griseus C-bands are less conspicuous, and a few chromosomes do not exhibit any centromeric heterochromatin at all.     

Chromosome preparations from hepatocytes and bone marrow of Chinese hamsters: A direct method

This report describes a method for the direct preparation of chromosomes from the hepatocytes and bone marrow of the same Chinese hamster (Cricetulus griseus). The technique is a modification of that described by Becker et al. (J. natl. Ca. Inst. 46: 1261–69, 1971) for rat hepatocytes, with the following significant differences: (1) a less extensive partial hepatectomy is employed to initiate hepatocyte regeneration, (2) the use of a larger initial dose of colchicine (4 mg/K) 46–48 hours after hepatectomy instead of 1 mg/K 24 hours after hepatectomy, (3) the use of 0.075 M KCl as hypotonic solution instead of fetal calf serum diluted 1 : 7 with distilled water and (4) flame or blaze drying of chromosome preparations instead of air drying. The combination of the above modifications gave abundant, clear and well-spread chromosomes.     

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.     

Hepatocyte classes during liver atrophy due to starvation in the golden hamster

Summary The total dry masses of normal hepatocytes isolated from adult golden hamsters form a multimodal frequency distribution curve (10–11 cell classes with a period of 132 pg). During starvation the hepatocytes maintain the arrangement in classes, the number of which, however, decreases. The cell percentage of the lightest classes progressively increases, but no change occurs in the class period. A similar behaviour is shown by the aqueo-insoluble dry masses of the hepatocytes. The nuclear dry masses increase until the 4th day of starvation. Later on, they decrease. The nucleo-cytoplasmic ratio progressively increases. The total number of hepatocytes per liver and the binuclear cell percentage do not show any significant changes during starvation. The mitotic index is lower in starved animals. The kinetics of decrement in dry mass of the hepatocytes during starvation and the possibility that the hepatocyte class series are the resultant of a dynamic balance of single hepatocyte mass are discussed.This work was supported by Consiglio Nazionale delle Ricerche, Roma, Italia (Grant No. 70/01811/04).The author is deeply grateful to Prof. Enrico Puccinelli for his encouragement and advice during this work. The skilful technical assistance of Mrs. Lucia Giaccardo and Mr. Emilio Madrigali is gratefully acknowledged.     

Effect of long-term administration of a high protein or low protein diet on rat liver. Morphological and biochemical findings

An increase in relative liver weight, the total liver DNA content, hepatocyte volume and the total surface area of the membranes of mitochondria and the granular and smooth endoplasmic reticulum of hepatocytes, but a decrease in the size of the nuclei, were found in adult male rats fed three weeks on a high protein diet compared with animals given a standard laboratory diet. Serum transaminase (ALT, AST) and alkaline phosphatase activity was practically the same as the control values. Rats fed three weeks on a low protein diet showed a decrease in relative liver weight, in the total liver DNA content, in hepatocyte and nuclear volume and in ploidy, and also in the surface area of the membranes of the mitochondria and the smooth and granular endoplasmic reticulum; conversely, the number of binucleate hepatocytes rose. Serum ALT, AST and alkaline phosphatase activity was mildly, but statistically significantly elevated.     

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     

Fractionation of Rat Hepatocyte Subpopulations with Varying Metabolic Potential, Proliferative Capacity, and Retroviral Gene Transfer Efficiency

The liver contains hepatocytes with varying ploidy and gene expression. To isolate cells on the basis of ploidy for analyzing mechanisms concerning cell proliferation and differentiation, we used Percoll gradients to separate F344 rat hepatocyte subpopulations. Specific fractions were enriched in polyploid (H2 fraction) or diploid (H3 and H4 fractions) hepatocytes containing glycogen and glucose-6-phosphatase. H4 cells were relatively smaller with greater nuclear/cytoplasmic ratios, less complex cytoplasm, and higher serum albumin or ceruloplasmin biosynthetic rates. H2 fraction cells were larger with lesser nuclear/cytoplasmic ratio, more complex cytoplasm, and more cytochrome P450 activity. Phenotypic marking showed that H4 cells originated in zone one and H2 cells in zones two or three of the liver lobule. H4 cells showed much greater mitogenic responsiveness to human hepatocyte growth factor. Retroviral gene transfer, which requires both viral receptors and cellular DNA synthesis, was significantly more efficient in H4 cells. The findings indicated thatsmalldiploid andlargepolyploid hepatocytes show unique biological differences. The ability to isolate hepatocytes of varying maturity is relevant for mechanisms concerning liver growth control and hepatic gene expression.     

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)     

Hepatocyte population dynamics during hydrocortisone and thioacetamide treatment

Summary The orderly organization in a number of discrete classes of weight persists in the hepatocytes during acute and chronic poisoning with thioacetamide and during a prolonged treatment with hydrocortisone, though many striking cytological and structural changes occur in the liver.The number of hepatocyte classes decreases under hydrocortisone treatment and during acute and chronic thioacetamide poisoning, and increases during recovery after acute thioacetamide poisoning and during the late phases of chronic thioacetamide poisoning. This is due to decrements and increments in dry mass of the hepatocytes, which occur by steps, through repeated losses and additions of a constant amount of solids substantially corresponding to the class period.Such a mechanism is similar to that acting in the hepatocyte atrophy due to starvation and in the hepatocyte enlargement occurring during postnatal development. Therefore, the increment and the decrement in dry mass by defined steps takes place in the hepatocytes in both physiological and pathological conditions.This work was supported by a grant of the Consiglio Nazionale delle Ricerche, Rome, Italy.     

Polyploidy‐associated genomic instability in Arabidopsis thaliana

Formation of polyploid organisms by fertilization of unreduced gametes in meiotic mutants is believed to be a common phenomenon in species evolution. However, not well understood is how species in nature generally exist as haploid and diploid organisms in a long evolutionary time while polyploidization must have repeatedly occurred via meiotic mutations. Here, we show that the ploidy increased for two consecutive generations due to unreduced but viable gametes in the Arabidopsis cyclin a1;2‐2 (also named tardy asynchronous meiosis‐2) mutant, but the resultant octaploid plants produced progeny of either the same or reduced ploidy via genomic reductions during meiosis and pollen mitosis. Ploidy reductions through sexual reproduction were also observed in independently generated artificial octaploid and hexaploid Arabidopsis plants. These results demonstrate that octaploid is likely the maximal ploidy produced through sexual reproduction in Arabidopsis. The polyploidy‐associated genomic instability may be a general phenomenon that constrains ploidy levels in species evolution. genesis 48:254–263, 2010. © 2010 Wiley‐Liss, Inc.     

A method for investigating hepatocyte polyploidization kinetics during postnatal development in mammals.

A method for investigating weakly-proliferating cell populations of liver parenchyma on the basis of a quantitative analysis of hepatocyte polyploidization during postnatal development is described. The method uses a mathematical model which characterizes the hepatocyte polyploidization process, and incorporates data concerning the time course for relative frequencies of hepatocytes in different ploidy classes. As a result of these measurements and calculations for rat liver, transition rates of hepatocytes (the relative number of cells during a given time unit) from one ploidy class to another, and a coefficient for the reduction of hepatocyte mitotic activity with an increase in its ploidy class were obtained. Calculated curves show a good correspondence with the real process of hepatocyte frequency changes as they relate to changes in the age of the animals. To check this method, experiments investigating time changes of autoradiographic label content in the different ploidy classes of hepatocytes were carried out. By mathematically modeling the label diluting process resulting from cell proliferation and polyploidization, transition rates of hepatocytes were calculated, and they reflect values calculated from the model according to changes in occurrence frequencies.     

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.     

Effects of various cyclophosphamide concentrations in vivo on sister chromatid exchanges (SCE) and chromosome aberrations of Chinese hamster bone marrow cells

Summary The in vivo SCE formation and the induction of chromosome aberrations in the bone marrow of Chinese hamsters (Cricetulus griseus) were studied after various concentrations of cyclophosphamide, and the sensitivity of the two test methods was compared. The administration of 1.0, 5.0, 13.3, 25.0, and 40.0 mg/kg body weight induced a dose-dependent increase in SCE. The frequency of chromosome aberration, however, was not increased significantly with doses of 1.0 and 5.0 mg/kg body weight. Only with doses of more than 13.3 mg is a significant induction of chromosome aberrations seen. Therefore the SCE test system seems to be 10 times more sensitive than the induction of chromosome aberrations in the same cell type.This work is a part of the M.D. thesis of G. Roszinsky-Köcher, to whom offprint requests should be sent     

Growth patterns of rat hepatocytes during postnatal development.

During postnatal growth in the liver of the rat, a characteristic shift towards binuclear cells and cells of higher ploidy class occurs. When the protein content of individual isolated hepatocytes of different ploidy classes is analysed cytophotometrically using the specific protein stain Naphthol Yellow S, it appears that the growth in mass in the period 30-99 days is due mainly to increase of protein content of binuclear diploid (BD) and mononuclear tetraploid (MT) cells. The mononuclear diploid (MD) cells play a quickly diminishing role in the parenchymal population after the initial growth phase and cells of highest ploidy degree remain unimportant quantitatively. The quickly growing BD and MT cells only reach a Naphthol Yellow S protein value twice that of MD cells after a certain period of growth, whereas changes in protein content are slight or absent from 99 days onwards in all cell types investigated.     

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.     

Hepatocytes proteomic alteration and seroproteome analysis of HBV‐transgenic mice

Hepatitis B is the most common and serious liver disease, especially in developing countries. Although HBV pathogenesis has been extensively investigated, the proteomic alteration of hepatocytes during HBV chronic infection is still unclear. Using the purified hepatocytes, we compared the protein profiles by 2‐DE and LC‐MS between HBV‐transgenic (Tg) and corresponding background mice. Twenty‐seven altered proteins were identified in hepatocytes from HBV‐Tg mice, among which 13 proteins were involved in mitochondrion metabolism pathway including tricarboxylic acid (TCA) cycle and oxidative response; four proteins (SELENBP, SCP2, RGN and PRDX1) were also dramatically changed in liver samples from HBV‐infected patients. Important genes (gpx, sod, ogg et al.) correlated to oxidative damage were up‐regulated in the liver of HBV‐Tg mice. Reactive oxygen species production was significantly increased while ATP production was decreased in liver mitochondria from HBV‐Tg mice. Moreover, hepatocytes of HBV‐Tg mice were more sensitive to hydrogen peroxide‐induced cell death than that of wild‐type control. Using 2‐D Western blotting analysis, eight hepatocyte proteins were found to react with sera of HBV‐Tg mice but not with that of background mice. Interestingly, two (Etfa and Dmgdh) of the eight reactive proteins were overexpressed in HBV‐Tg mice. We believe this study is the first proteomic and seroproteome analysis of HBV‐infected mammalian hepatocyte and provides insightful links between HBV infection and HBV‐induced liver diseases.     

Comparative genetics of hamster amylases

Syrian (Mesocricetus auratus) and Chinese (Cricetulus griseus) hamsters were phenotyped by electrophoresis for salivary and pancreatic amylases. Syrian hamsters possess two salivary amylase electromorphs, the more anodal (fast) being invariant in 250 outbred and 17 representatives of 5 highly inbred lines. The slow electromorph had activity equal to that of the fast amylase (heavy), or had distinctly less activity (light), or was absent (null). The slow electromorph is inherited as an autosomal semidominant trait with two alleles, Amy ^s and Amy ^o . Amy ^s homozygotes produce heavy, Amy ^o homozygotes null, and heterozygotes light phenotypes, respectively. Five inbred strains of hamsters were homozygous Amy ^o . Pancreatic amylase was monomorphic. Eight outbred Chinese hamsters showed no salivary amylase activity with electrophoresis, but slight activity with long incubation on starch-agar plates. However, pancreatic amylase activity in the Chinese hamster exceeded that in Syrian hamsters. Site duplication and apparent null alleles for amylase genes occur in muroid rodents. The evolutionary implications are discussed.George H. Bunch Chair Professor of Biology     

Morphometry of hepatocyte mitochondrial apparatus in normal and cirrhotic rat liver

Morphometric electron microscopy study of the hepatocyte mitochondrial apparatus and morphofunctional analysis of the degree of pathological alterations were carried out on the liver of rats with CCL4-cirrhosis (experimental group). Chronic poisoning of rats with CCL4 for 6 months led to a 4.2-fold increase in proportion of connective tissue and to a decrease in the number of hepatocytes in the liver by 21.8 %. Dry mass and ploidy of hepatocytes in the cirrhotis liver rose as compared with norm by 20.6 and 9.3%, respectively. Activities of alanine and aspartate aminotransferases in blood of rats of experimental group exceeded normal ones 2.0 and 1.4 times, respectively. Concentration of total bilirubin in blood of the cirrhotic animals increased 1.7 times, while concentration of total protein decreased by 22%. Concentration of diene conjugates in the liver of rats of experimental group increased 2.1 times as compared with normal one, while the level of malonic dialdehyde - by 34%. Activities of superoxide dismutase and catalase in the cirrhotic liver were lower than in the normal liver were lower than in the normal liver by 16 and 23 %, respectively. Morphometry of the hepatocyte mitochondrial apparatus has shown that in spite of an increase in the voluminous density of mitochondria in hepatocytes of the cirrhotic liver (by 28 %), concentration of internal mitochondrial membranes in the cells was reduced almost 1.5 times, while the total length of internal membrane in a single mitochondrion was reduced about twice as compared with norm. Thus, despite compensation of the partial loss of hepatocytes because of their polyploidization and hypertrophy, the specific synthetic activity of cells in the case of cirrhosis is decreased due to deterioration of the antioxidant system and electron transport chain of the mitochondrial apparatus.