Faculty Bibliography

In understanding mechanisms of liver repopulation with transplanted hepatocytes, we studied the consequences of hepatic polyploidization in the two-thirds partial hepatectomy model of liver regeneration. Liver repopulation studies using genetically marked rodent hepatocytes showed that the number of previously transplanted hepatocytes did not increase in the liver with subsequential partial hepatectomy. In contrast, recipients undergoing partial hepatectomy before cells were transplanted showed proliferation in transplanted hepatocytes, with kinetics of DNA synthesis differing in transplanted and host hepatocytes. Also, partial hepatectomy caused multiple changes in the rat liver, including accumulation of polyploid hepatocytes along with prolonged depletion of diploid hepatocytes, as well as increased senescence-associated beta-galactosidase and p21 expression. Remnant hepatocytes in the partially hepatectomized liver showed increased autofluorescence and cytoplasmic complexity on flow cytometry, which are associated with lipofuscin accumulation during cell aging, and underwent apoptosis more frequently. Moreover, hepatocytes from the partially hepatectomized liver showed attenuated proliferative capacity in cell culture. These findings were compatible with decreased proliferative potential of hepatocytes experiencing partial hepatectomy compared with hepatocytes from the unperturbed liver. Attenuation of proliferative capacity and other changes in hepatocytes experiencing partial hepatectomy offer novel perspectives concerning liver regeneration in the context of cell ploidy.

In rapidly renewing epithelia, such as skin and gut, as well as hemopoietic cells and stromal fibroblasts, the process of progenitor cell maturation, terminal differentiation and senescence from cells of a fetal phenotype is strikingly similar. To examine hepatocellular maturation, we studied embryonic, suckling and young adult rat liver cells with multiparametric fluorescence activated cell sorting (FACS), after exclusion of hemopoietic, endothelial, Kupffer, and nonviable cells. With maturation, cell granularity and autofluorescence exponentially increased from fetal liver to suckling and adult liver as the proportion of S phase cells progressively declined from 33.8% +/- 1.3% to 4.9% +/- 2.8% and 1.1% +/- 0.6% (P < 0.05), respectively. In liver from fetal and suckling rats, all hepatocytes were mononuclear and contained diploid DNA whereas 21.2% +/- 5.9% hepatocytes in adult liver were binucleated. Analysis of nuclear DNA content in adult hepatocytes demonstrated that 53.3% +/- 3.9% of the nuclei were diploid, 43.6% +/- 3.5% tetraploid and 0.5 +/- 0.6% octaploid. However, in the adult liver, small, mononuclear cells were also present with granularity and autofluorescence comparable to fetal hepatoblasts, as well as glucose-6-phosphatase activity, diploid DNA in 89.0% +/- 2.1% of the nuclei, and with increased granularity in culture. Since general features of terminal cellularity differentiation and senescence include cessation of mitotic activity, polyploidy and accumulation of autofluorescent secondary lysosomes, our data suggest that liver cells too undergo a process of terminal differentiation.

The presence of progenitor or stem cells in the adult liver and their potential roles in oncogenesis are unresolved issues. The study of hepatocyte progenitor cells has been limited by a lack of convenient in vivo systems allowing unequivocal cell localization and demonstration of differentiation into hepatocytes. To develop an in vivo progenitor bioassay, early (E14) fetal Fischer 344 rat hepatoblasts were transplanted into the spleen of syngeneic, weaning rats deficient in dipeptidyl peptidase IV (DPPIV) activity. The donor status of transplanted hepatoblasts was demonstrated by DPPIV expression. Localization of hepatoblasts was facilitated by the use of an ectopic site, as well as weanling recipients, which readily allowed identification of very small numbers of transplanted cells. Fetal rat hepatoblasts were demonstrated to undergo cellular differentiation along the hepatocyte lineage by acquiring glucose-6-phosphatase activity within 5 d of transplantation. A critical review of previous transplantation studies of hepatocyte progenitor cells and the role of the local microenvironment at inducing differentiation indicates that this novel bioassay should facilitate analysis of progenitor cells.

We developed methods for enriching fetal hepatoblasts by combining panning and multiparametric fluorescence-activated cell sorting. In unpurified, dissociated fetal liver cell suspensions of embryonic age day 15, 3.2% +/- 1.3% and 2.5% +/- 0.7% cells expressed albumin and alpha-fetoprotein, respectively. The remainder exhibited a hemopoietic, endothelial or stromal cell phenotype. Cells were panned first with an antibody to red blood cells to remove erythroid cells and then with monoclonal antibodies OX-43/OX-44 to remove hemopoietic and endothelial cells. This procedure eliminated 84% of fetal hepatic cells, with enrichment of the remainder for albumin or alpha-fetoprotein expression (up to sixfold increase). Flow cytometric analysis of unlabeled cells revealed two populations, which differed in granularity and autofluorescence. After panning, fluorescence-activated cell sorting for agranular cells yielded OX-43/44-positive cells that were essentially all hemopoietic precursor cells or OX-43/44-negative cells that were mostly hemopoietic precursor cells, along with 3.0% +/- 0.7% alpha-fetoprotein-positive cells. In contrast, sorting for granular, OX-43/44-negative cells enriched for predominantly alpha-fetoprotein-positive, parenchymal precursor cells (75.1% +/- 4.7%). Multiparametric flow cytometric analysis of the expression of an oval cell antigen, OC.3, which is a bile duct and putative liver stem cell marker, showed that most OC.3-positive cells coexpressed OX-43/OX-44 and morphologically were hemopoietic precursor cells. However, approximately 30% of the OX-43/44-negative, granular cells expressed OC.3. Although the physiological significance of OC.3-positive hepatoblasts remains to be determined, the ability to isolate distinct liver cell populations by means of fluorescence-activated cell sorting should facilitate further studies.(ABSTRACT TRUNCATED AT 250 WORDS)