Delay of rat hepatocyte polyploidization in liver growth inhibition during hypokinesia]

Young rats, weighing 55-59g, after being for 10 days in conditions of limited mobility, show a retardation of body growth as well as that of liver growth. The decrease in the rate of organ growth is accompanied by a reduction of the cell proliferation and by a delay in polyploidization of hepatocytes in the liver of experimental rats.     

Heart and liver as developmental bottlenecks of mammal design: evidence from cell polyploidization

A new concept in physiological evolution in mammals is proposed based on the data of cell and developmental biology. The levels of mammal cardiomyocyte and hepatocyte ploidy were analysed with regards to body mass, growth rate in different periods of ontogenesis, and maximal functional potential of the heart and liver in the adult state. For both organs, cell ploidy and functional potential of the organ correlated inversely. Polyploid cells were shown to have a lower amount of protein per genome and a lower ratio of mitochondrial internal membrane to tissue‐specific cellular machinery (i.e. a lower energy supply) compared with diploid cells. Both cell ploidy and functional potential of the organ correlated with the animal growth rate that controls the organ functional load, but only if measured during the period of ontogenesis when polyploidization of the particular organ proceeds. However, correlation was in opposite directions: negative in the heart and positive in the liver. This is because these organs provide predominantly for the antagonistic tasks that they perform during ontogenesis. The liver provides a gain in body mass, whereas the heart maintains locomotor activity. The balance between these tasks depends on the growth rate constrained by the degree of precocity of development. During ontogenesis, an organ that works intensively in the adult state is subjected to a low workload and is furnished plentifully by resources. On the contrary, an organ with a low functional potential in the adult state starts to work intensively just after birth and experiences a shortage of resources during growth. Our data indicate that somatic polyploidization occurs as a result of tension between growth and function caused by the limitation of resources. The highest levels of mammal cell ploidy occur in the heart and the liver, although in different species which are positioned on the opposite ends of the growth rate range. Thus, the heart and the liver seem to be developmental bottlenecks of mammal design, determining the limits of metabolic capacity of adult animals. Compared with other mammals, the human has a very slow growth rate and a very high ploidy of cardiomyocytes (thus confirming the revealed regularity). This helps explain the well‐known fact that cardiovascular failure is the number one cause of human mortality. © 2004 The Linnean Society of London, Biological Journal of the Linnean Society, 2004, 83 , 175–186.     

Analysis of the polyploidization kinetics of the parenchymal cells in the rat liver

Methodological approaches to kinetics of cell polyploidization in the rat liver parenchyma are discussed. Different ways of hepatocyte polyploidization in the course of postnatal liver growth have been assessed. The intensities of hepatocyte transitions from one ploidy class to another were determined. On the basis of literary experimental data the following is summarized: With the increase in the animal age, there is a decrease in hepatocyte transition from one ploidy class to and ther; in young animals the intensity of formation of tetraploid hepatocytes through the stage of binuclear cells (2c----2c X 2----4c) is 0.39-0.55 within two weeks, the intensity of direct transitions (2c----4c) being 0.00-0.19 within the same time. The intensity of entering to DNA synthesis is reduced with the increase in hepatocyte ploidy levels; in this case the coefficient of the reducing of mitotic activity is calculated as 0.10-0.22, and 0.01-0.05 for 4c- and 8c-hepatocytes, resp. The factors stimulating proliferation in the liver increase the intensity of the direct cell transition (2c----4c) by several times which can exceed the intensity of transition through the binuclear cell stage.     

Mitomycin C-induced acceleration of liver cell polyploidization in adult rat after partial hepatectomy

Mitomycin C, a DNA cross-linking agent, was administered for a week intraperitoneally to a normal 9-week-old rat in which hepatocyte proliferative activity had almost ceased. In the rat treated with mitomycin C, the number of polyploid cells with the DNA amounts more than 4C was not increased in comparison with that in the control rat without any treatment. However, the partial hepatectomy in the rat pretreated with mitomycin C provoked prominent hepatocyte polyploidization much greater in degree than that found in the hepatectomized rat without mitomycin C treatment. These results seem to indicate that the existence of cross-linking DNA damages is a latent factor necessary for the induction of abortive mitosis of a cell after completion of DNA synthesis, which results in the production of a mononuclear polyploid cell in one-step higher DNA class. Cross-linking DNA damages and DNA synthesis are the essential factors for the manifestation of polyploidization.     

Anatomical analysis of growth and developmental patterns in the internode of deepwater rice

Submergence of the stem induces rapid internodal elongation in deepwater rice (Oryza sativa L. cv. Habiganj Aman II). A comparative anatomical study of internodes isolated from airgrown and partially submerged rice plants was undertaken to localize and characterize regions of growth and differentiation in rice stems. Longitudinal sections were examined by light and scanning-electron microscopy. Based on cell-size analysis, three zones of internodal development were recognized: a zone of cell division and elongation at the base of the internode, designated the intercalary meristem (IM); a zone of cell elongation without concomitant cell division; and a zone of cell differentiation where neither cell division nor elongation occur. The primary effects of submergence on internodal development were a threefold increase in the number of cells per cell file resulting from a decrease in the cell-cycle time from 24 to 7 h within the IM; an expansion of the cell-elongation zone from 5 to 15 mm leading to a threefold greater final cell length; and a suppression of tissue differentiation as indicated by reduced chlorophyll content and a lack of secondary wall formation in xylem and cortical sclerenchyma. These data indicate that growth of deepwater-rice internoes involves a balance between elongation and differentiation of the stem. Submergence shifts this balance in favor of growth.Abbreviations GA gibberellin - IM intercalary meristem     

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.     

Fenestration patterns in endothelial cells of rat liver sinusoids

Endothelial fenestrae of both zone 1 and zone 3 acinar liver sinusoids have been studied in rats by an interactive analysis of scanning electron microscopical images. Two fenestration patterns have been recognized in the endothelial cells on the basis of local variation in size, distribution and clustering of pores in each acinar zone. Our data indicate that both the number of fenestrae per square micrometer of endothelial surface and the mean diameter of fenestrae are significantly larger in zone 3 than in zone 1. The number of sieve plates is about 1.74 times larger in zone 3 than in zone 1, and the number of fenestrae per plate in zone 3 is nearly twice that in zone 1. Two different classes of fenestrae have been considered: clustered pores, which prevail in zone 3 and have a mean diameter smaller than the other pores, and free pores, which prevail in zone 1 and are bigger.     

Bioengineering considerations in liver regenerative medicine

Background

Liver disease contributes significantly to global disease burden and is associated with rising incidence and escalating costs. It is likely that innovative approaches, arising from the emerging field of liver regenerative medicine, will counter these trends.

Main body

Liver regenerative medicine is a rapidly expanding field based on a rich history of basic investigations into the nature of liver structure, physiology, development, regeneration, and function. With a bioengineering perspective, we discuss all major subfields within liver regenerative medicine, focusing on the history, seminal publications, recent progress within these fields, and commercialization efforts. The areas reviewed include fundamental aspects of liver transplantation, liver regeneration, primary hepatocyte cell culture, bioartificial liver, hepatocyte transplantation and liver cell therapies, mouse liver repopulation, adult liver stem cell/progenitor cells, pluripotent stem cells, hepatic microdevices, and decellularized liver grafts.

Conclusion

These studies highlight the creative directions of liver regenerative medicine, the collective efforts of scientists, engineers, and doctors, and the bright outlook for a wide range of approaches and applications which will impact patients with liver disease.

     

Immunohistochemical localisation and developmental aspects of epidermal growth factor in the rat

Summary The tissue localisation and time of first appearance of Epidermal Growth Factor (EGF) in the developing rat were investigated by means of immunohistochemistry, radioimmunoassay and radioreceptor assay. In this study we were able to show, that EGF appears prenatally in the lung and the kidney from gestational day 19. Postnatally EGF was found also in the gastrointestinal tract, first in Brunner's glands of the duodenum (at birth), next in the Paneth cells (day 7), and finally in the submandibular glands (day 25). The immunohistochemical and radioreceptor results are consistent, whereas the radioimmunoassay detects EGF later and in smaller quantities, than does the radioreceptor assay. These differences will be discussed.     

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.     

Immunohistochemical localisation and developmental aspects of epidermal growth factor in the rat

The tissue localisation and time of first appearance of Epidermal Growth Factor (EGF) in the developing rat were investigated by means of immunohistochemistry, radioimmunoassay and radioreceptor assay. In this study we were able to show, that EGF appears prenatally in the lung and the kidney from gestational day 19. Postnatally EGF was found also in the gastrointestinal tract, first in Brunner's glands of the duodenum (at birth), next in the Paneth cells (day 7), and finally in the submandibular glands (day 25). The immunohistochemical and radioreceptor results are consistent, whereas the radioimmunoassay detects EGF later and in smaller quantities, than does the radioreceptor assay. These differences will be discussed.     

Comparative study of clonal growth and differentiation of mesenchymal stromal cells from rat fetal liver at different developmental stages

Fetal liver during period of its hematopoietic activity contains mesenchymal stromal cells (MSC) that are known to play a major role in establishing hematopoietic microenvironment. These cells are capable of clonal growing and multilineage differentiation, but only limited data exist about changes in their properties during prenatal development. We compared cloning efficiency of MSC from liver of 14, 16 and 20 day rat fetuses and evaluated their potentials to in vitro osteo- and adipogenesis and in vivo chondrogenesis after whole organ ectopic transplantation. Content of clonogenic MSC in suspension of liver cells was maximal in 16 day fetuses and to a lesser extent in 20 day ones. MSC derived from 16 day fetuses demonstrated maximal potential to estimated lineages. Osteogenic potential of MSC from 14 day fetuses was comparable to whereas their adipogenic and chondrogenic abilities were inferior to that from 16 day fetuses. Cells from 20 day fetuses had only weak adipogenic potency and failed to differentiate into osteogenic of chondrogenic pathways. The results indicate that both number and differentiation potential of MSC in developing rat liver correlate with dynamics of hematopoiesis in this organ. Detected changes may be ascribed to the decline of hematopoiesis in liver and acquisition its definitive functions.