Activin A, p15INK4b signaling, and cell competition promote stem/progenitor cell repopulation of livers in aging rats.

BACKGROUND & AIMS: Highly proliferative fetal liver stem/progenitor cells (FLSPCs) repopulate livers of normal recipients by cell competition. We investigated the mechanisms by which FLSPCs repopulate livers of older compared with younger rats. METHODS: Fetal liver cells were transplanted from DPPIV(+) F344 rats into DPPIV(-) rats of different ages (2, 6, 14, or 18 months); liver tissues were analyzed 6 months later. Cultured cells and liver tissues were analyzed by reverse transcription polymerase chain reaction, immunoblot, histochemistry, laser-capture microscopy, and terminal deoxynucleotidyl transferase-mediated deoxyuridine triphosphate nick-end labeling analyses. RESULTS: We observed 4- to 5-fold increases in liver repopulation when FLSPCs were transplanted into older compared with younger rats. Messenger RNA levels of cyclin-dependent kinase inhibitors increased progressively in livers of older rats; hepatocytes from 20-month-old rats had 6.1-fold higher expression of p15INK4b and were less proliferative in vitro than hepatocytes from 2-month-old rats. Expression of p15INK4b in cultured hepatocytes was up-regulated by activin A, which increased in liver during aging. Activin A inhibited proliferation of adult hepatocytes, whereas FLSPCs were unresponsive because they had reduced expression of activin receptors (eg, ALK-4). In vivo, expanding cell clusters derived from transplanted FLSPCs had lower levels of ALK-4 and p15INK4b and increased levels of Ki-67 compared with the host parenchyma. Liver tissue of older rats had 3-fold more apoptotic cells than that of younger rats. CONCLUSIONS: FLSPCs, resistant to activin A signaling, repopulate livers of older rats; hepatocytes in older rats have less proliferation because of increased activin A and p15INK4b levels and increased apoptosis than younger rats. These factors and cell types might be manipulated to improve liver cell transplantation strategies in patients with liver diseases in which activin A levels are increased.

Increased levels of a unique post-translationally modified betaIVb-tubulin isotype in liver cancer.

Identifying changes at the molecular level during the development of hepatocellular carcinoma is important for the detection and treatment of the disease. The characteristic structural reorganization of preneoplastic cells may involve changes in the microtubule cytoskeleton. Microtubules are dynamic protein polymers that play an essential role in cell division, maintenance of cell shape, vesicle transport, and motility. They are comprised of multiple isotypes of alpha- and beta-tubulin. Changes in the levels of these isotypes may affect not only microtubule stability and sensitivity to drugs but also interactions with endogenous proteins. We employed a rat liver cancer model that progresses through stages similar to those of human liver cancer, including metastasis to the lung, to identify changes in the tubulin cytoskeleton during carcinogenesis. Tubulin isotypes in both liver and lung tissue were purified and subsequently separated by isoelectric focusing electrophoresis. The C-terminal isotype-defining region from each tubulin was obtained by cyanogen bromide cleavage and identified by mass spectrometry. A novel post-translational modification of betaIVb-tubulin in which two hydrophobic residues are proteolyzed from the C-terminus, thus exposing a charged glutamic acid residue, was identified. The unique form of betaIVb-tubulin was quantified in the liver tissue of all carcinoma stages and found to be approximately 3-fold more abundant in nodular and tumor tissue than in control tissue. The level of this form was also found to be increased in lung tissue with liver metastasis. This modification alters the C-terminal domain of one of the most abundant beta-tubulin isotypes in the liver and therefore may affect the interactions of microtubules with endogenous proteins.

Purification of fetal liver stem/progenitor cells containing all the repopulation potential for normal adult rat liver.

BACKGROUND & AIMS: Previously, we showed high-level, long-term liver replacement after transplantation of unfractionated embryonic day (ED) 14 fetal liver stem/progenitor cells (FLSPC). However, for clinical applications, it will be essential to transplant highly enriched cells, while maintaining high repopulation potential. METHODS: Dlk-1, a member of the delta-like family of cell surface transmembrane proteins, is highly expressed in human and rodent fetal liver. Dlk-1(+) cells, isolated from ED14 fetal liver using immunomagnetic beads, were examined for their hepatic gene expression profile and characteristic properties in vitro and their proliferative and differentiation potential in vivo after transplantation into normal adult rat liver. RESULTS: Rat ED14 FLSPC were purified to 95% homogeneity and exhibited cell culture and gene expression characteristics expected for hepatic stem/progenitor cells. Rat ED14 FLSPC are alpha-fetoprotein(+)/cytokeratin-19(+) or alpha-fetoprotein(+)/cytokeratin-19(-) and contain all of the normal liver repopulation capacity found in fetal liver. Hematopoietic stem cells, a major component in crude fetal liver cell preparations that engraft in other organs, such as bone marrow, spleen, and lung, are totally removed by Dlk-1 selection, and Dlk-1 purified FLSPC repopulate only the liver. CONCLUSIONS: This is the first study reporting purification of hepatic stem/progenitor cells from fetal liver that are fully capable of repopulating the normal adult liver. This represents a major advance toward developing protocols that will be essential for clinical application of liver cell transplantation therapy.

Comparison of hepatic properties and transplantation of Thy-1(+) and Thy-1(-) cells isolated from embryonic day 14 rat fetal liver.

UNLABELLED: Thy-1, a marker of hematopoietic progenitor cells, is also expressed in activated oval cells of rat liver. Thy-1(+) cells are also in rat fetal liver and exhibit properties of bipotent hepatic epithelial progenitor cells in culture. However, no information is available concerning liver repopulation by Thy-1(+) fetal liver cells. Therefore, we isolated Thy-1(+) and Thy-1(-) cells from embryonic day (ED) 14 fetal liver and compared their gene expression characteristics in vitro and proliferative and differentiation potential after transplantation into adult rat liver. Fetal liver cells selected for Thy-1 expression using immunomagnetic microbeads were enriched from 5.2%-87.2% Thy-1(+). The vast majority of alpha fetoprotein(+), albumin(+), cytokine-19(+), and E-cadherin(+) cells were found in cultured Thy-1(-) cells, whereas nearly all CD45(+) cells were in the Thy-1(+) fraction. In normal rat liver, transplanted Thy-1(+) cells produced only rare, small DPPIV(+) cell clusters, very few of which exhibited a hepatocytic phenotype. In retrorsine-treated liver, transplanted Thy-1(+) fetal liver cells achieved a 4.6%-23.5% repopulation. In contrast, Thy-1(-) fetal liver cells substantially repopulated normal adult liver and totally repopulated retrorsine-treated liver. Regarding the stromal cell-derived factor (SDF)-1/chemokine (C-X-C motif) receptor 4 (CXCR4) axis for stem cell homing, Thy-1(+) and Thy-1(-) fetal hepatic epithelial cells equally expressed CXCR4. However, SDF-1alpha expression was augmented in bile ducts and oval cells in retrorsine/partial hepatectomy-treated liver, and this correlated with liver repopulation by Thy-1(+) cells. CONCLUSION: Highly enriched Thy-1(+) ED14 fetal liver cells proliferate and repopulate the liver only after extensive liver injury and represent a fetal hepatic progenitor cell population distinct from Thy-1(-) stem/progenitor cells, which repopulate the normal adult liver.

Properties of cryopreserved fetal liver stem/progenitor cells that exhibit long-term repopulation of the normal rat liver.

We have previously achieved a high level of long-term liver replacement by transplanting freshly isolated embryonic day (ED) 14 rat fetal liver stem/progenitor cells (FLSPCs). However, for most clinical applications, it will be necessary to use cryopreserved cells that can effectively repopulate the host organ. In the present study, we report the growth and gene expression properties in culture of rat FLSPCs cryopreserved for up to 20 months and the ability of cryopreserved FLSPCs to repopulate the normal adult rat liver. After thawing and placement in culture, cryopreserved FLSPCs exhibited a high proliferation rate: 49.7% Ki-67-positive on day 1 and 34.7% Ki-67-positive on day 5. The majority of cells were also positive for both alpha-fetoprotein and cytokeratin-19 (potentially bipotent) on day 5. More than 80% of cultured cells expressed albumin, the asialoglycoprotein receptor, and UDP-glucuronosyltransferase (unique hepatocyte-specific functions). Expression of glucose-6-phosphatase, carbamyl phosphate synthetase 1, hepatocyte nuclear factor 4alpha, tyrosine aminotransferase, and oncostatin M receptor mRNAs was initially negative, but all were expressed on day 5 in culture. After transplantation into the normal adult rat liver, cryopreserved FLSPCs proliferated continuously, regenerated both hepatocytes and bile ducts, and produced up to 15.1% (mean, 12.0% +/- 2.0%) replacement of total liver mass at 6 months after cell transplantation. These results were obtained in a normal liver background under nonselective conditions. This study is the first to show a high level of long-term liver replacement with cryopreserved fetal liver cells, an essential requirement for future clinical applications.

Liver stem cells and prospects for liver reconstitution by transplanted cells.

Although it was proposed almost 60 years ago that the adult mammalian liver contains hepatic stem cells, this issue remains controversial. Part of the problem is that no specific marker gene unique to the adult hepatic stem cell has yet been identified, and regeneration of the liver after acute injury is achieved through proliferation of adult hepatocytes and does not require activation or proliferation of stem cells. Also, there are differences in the expected properties of stem versus progenitor cells, and we attempt to use specific criteria to distinguish between these cell types. We review the evidence for each of these cell types in the adult versus embryonic/fetal liver, where tissue-specific stem cells are known to exist and to be involved in organ development. This review is limited to studies directed toward identification of hepatic epithelial stem cells and does not address the controversial issue of whether stem cells derived from the bone marrow have hepatocytic potential, a topic that has been covered extensively in other recent reviews.

Cell competition leads to a high level of normal liver reconstitution by transplanted fetal liver stem/progenitor cells.

BACKGROUND & AIMS: A critical property of stem cells is their ability to repopulate an organ or tissue under nonselective conditions. The aims of this study were to determine whether we could obtain reproducible, high levels of liver repopulation by transplanted fetal liver stem/progenitor cells in normal adult liver and the mechanism by which liver replacement occurred. METHODS: Wild-type (dipeptidyl peptidase IV [DPPIV(+)]) embryonic day (ED) 14 fetal liver cells underwent transplantation into DPPIV(-) mutant F344 rats to follow the fate and differentiation of transplanted cells. To determine the mechanism for repopulation, proliferation and apoptosis of transplanted and host liver cells were also followed. RESULTS: Transplanted ED 14 fetal liver cells proliferated continuously for 6 months, differentiated into mature hepatocytes, and replaced 23.5% of total liver mass. The progeny of transplanted cells were morphologically and functionally indistinguishable from host hepatocytes and expressed unique liver-specific genes commensurate with their location in the hepatic lobule. Repopulation was based on greater proliferative activity of transplanted cells and reduced apoptosis of their progeny compared with host hepatocytes, coupled with increased apoptosis of host hepatocytes immediately adjacent to transplanted cells. This process, referred to as cell-cell competition, has been described previously in Drosophila during wing development. CONCLUSIONS: We show for the first time that cell-cell competition, a developmental paradigm, can be used to replace functional organ tissue in an adult mammalian species under nonselective conditions and may serve as a strategy for tissue reconstitution in a wide variety of metabolic and other disorders involving the liver, as well as other organs.

Bone marrow progenitors are not the source of expanding oval cells in injured liver.

Liver progenitor/oval cells differentiate into hepatocytes and biliary epithelial cells, repopulating the liver when the regenerative capacity of hepatocytes is impaired. Recent studies have shown that hematopoietic bone marrow (BM) stem/progenitor cells can give rise to hepatocytes in diseased/damaged liver. One study has reported that BM cells can transdifferentiate into liver progenitor/oval cells, but it has not been proven that the latter can repopulate the liver. To answer this question, we have lethally irradiated female DPP4(-) mutant F344 rats and transplanted them with 50 million wild-type male F344 BM cells. One month after transplantation, the recipient BM was reconstituted with male hematopoietic cells, determined by quantitative polymerase chain reaction using primers for Y chromosome-specific sry gene. In addition, DPP4(+) cells, single or in clusters and predominantly in the periportal region, were detected in all liver sections of recipient rats. Animals were subjected to the following three different liver injury protocols for activation and expansion of oval cells: D-galactosamine, retrorsine/partial hepatectomy (Rs/PH), and 2-acetylaminofluorene/partial hepatectomy (2-AAF/PH). In all three models, prominent expansion and accumulation of cytokeratin 19-positive (CK-19(+)) oval cells was observed. However, most of the DPP4(+) clusters dispersed over time, and their total number decreased. Very few oval cells (less than 1%) showed double DPP4/CK-19 labeling. None of the small hepatocytic clusters in the Rs/PH or 2-AAF/PH model were comprised of DPP4(+) cells. These data demonstrate that the sources of oval cells and small hepatocytes in the injured liver are endogenous liver progenitors and that they do not arise through transdifferentiation from BM cells.