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.     

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.     

Evidence that cyclin D1 mediates both growth and proliferation downstream of TOR in hepatocytes

Signaling through the target of rapamycin is required for increased protein synthesis, cell growth, and proliferation in response to growth factors. However, the downstream mediators of these responses, and the elements linking growth and proliferation, have not been fully elucidated. Rapamycin inhibits hepatocyte proliferation in culture and liver regeneration in vivo. In cultured rat hepatocytes, rapamycin prevented the up-regulation of cyclin D1 as well as proteins acting downstream in the cell cycle. Transfection with cyclin D1 or E2F2, but not cyclin E or activated Akt, overcame the rapamycin-mediated cell cycle arrest. Rapamycin also inhibited the induction of global protein synthesis after growth factor stimulation, and cyclin D1 overcame this inhibition. Rapamycin inhibited hepatocyte proliferation and cyclin D1 expression in the mouse liver after 70% partial hepatectomy. In rapamycin-treated mice, transfection with cyclin D1 induced hepatocyte proliferation, increased hepatocyte cell size, and promoted growth of the liver. These results suggest that cyclin D1 is a key mediator of increased protein synthesis, cell growth, and proliferation downstream of target of rapamycin in mitogen-stimulated hepatocytes.     

Peculiarities of liver regeneration in Chinese hamster <Emphasis Type="Italic">Cricetulus griseus</Emphasis>

With the aid of cytofluorimetry and interference microscopy, the ploidy level and the hepatocyte ploidy class distribution were studied and the dry mass of hepatocytes was measured in hepatocytes in liver of Chinese hamsters Cricetulus griseus and of Balb/c mice before and one month after partial hepatectomy. The mean ploidy level in hepatocytes of the Chinese hamster normal liver amounted to 2.35 ± 0.03 c. The modal class was mononuclear hepatocytes with diploid nuclei (82.4 ± 1.3%). The mean dry mass of hepatocytes amounted to 605.2 ± 4.8 pg. In the process of liver regeneration in the Chinese hamsters, the ratio of ploidy classes and the hepatocyte dry mass did not change. After a similar liver resection in the mice, a significant polyploidization of liver parenchyma occurred. The mean ploidy level in hepatocytes rose by 32%. Instead of 4cx2-hepatocytes, the modal class became mononuclear octaploid cells the relative portion of which increased, on average, by five times. The portion of binuclear hepatocytes with octaploid nuclei in mouse liver rose by more than five times. Thus, in the Chinese hamsters Cricetulus griseus, unlike mice, regeneration of liver occurred exclusively at the expense of proliferation of hepatocytes.     

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.     

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.