Liver repopulation and carcinogenesis: two sides of the same coin?

Liver repopulation by transplanted normal hepatocytes has been described in a number of experimental settings. Extensive repopulation can also occur from the selective proliferation of endogenous normal hepatocytes, both in experimental animals and in the human liver. This review highlights the intriguing association between clinical and experimental conditions related to liver repopulation and an increased risk for development of hepatocellular carcinoma. It is suggested that any microenvironment that is able to sustain the clonal growth of normal transplanted (or endogenous) hepatocytes is also geared to select for the emergence of rare resistant cells with an altered phenotype. Whereas the first pathway leads to liver repopulation with normal histology, the latter results in the growth of focal proliferative lesions and carries an increased risk of neoplastic disease. The implications of this association are discussed, both in terms of pathogenetic significance and possible therapeutic exploitation.

Repopulation by endogenous hepatocytes does not reconstitute liver mass in rats treated with retrorsine.

The retrorsine (RS)-based model for massive liver repopulation was laid on the hypothesis that transplanted cells can proliferate in the recipient liver if the growth capacity of endogenous hepatocytes is persistently impaired. In order to directly test this hypothesis, we examined the long-term response to 2/3 partial hepatectomy (PH) in rats pretreated with RS, according to the protocol for liver repopulation. Rats were given RS or saline and 4 weeks later they underwent PH; they were killed up to 16 weeks thereafter. Liver weights, liver DNA, and protein content were significantly lower in the RS group throughout the experimental time considered (e.g., at 16 weeks post-PH relative liver weight was 1.99 +/- 0.30% in RS group vs. 3.06 +/- 0.5% in controls). Regenerative nodules were present in RS-treated livers; they occupied about 3% of the liver at 2 weeks post-PH and this value increased to nearly 50% at 8 weeks and to > 95% at 16 weeks. In conclusion, RS-treated rat liver is unable to recover its original mass for several months following PH, despite the development of regenerative nodules. This long-lasting effect is likely to contribute to the growth of transplanted hepatocytes, leading to massive liver repopulation.

Liver repopulation by transplanted hepatocytes and risk of hepatocellular carcinoma.

BACKGROUND: Transplantation of isolated hepatocytes in rats treated with retrorsine (RS) results in massive repopulation of the host liver. In this study, the long-term fate of hepatocytes transplanted into RS-treated recipients was followed for up to two years. METHODS: Dipeptidyl-peptidase type IV-deficient (DPPIV) Fischer 344 rats were given two injections of RS (30 mg/kg), followed by transplantation of 2 million hepatocytes, isolated from a syngenic, DPPIV donor. RESULTS: Extensive (91+/-7%) liver replacement by transplanted hepatocytes was observed in animals sacrificed 18 months posttransplantation. Similar levels of repopulation persisted at two years (87+/-5%). No evidence of preneoplastic and/or neoplastic evolution of the transplanted cell population was present in the RS-treated and repopulated livers at any time point considered. Furthermore, serum parameters related to hepatocyte function and integrity were in the normal range. In control groups given cell transplantation in the absence of prior treatment with RS, only small clusters of donor-derived, DPPIV hepatocytes were discerned. CONCLUSIONS: These results indicate that liver repopulation in this model is largely stable, persisting for up to two years and allowing for a normal liver function. In addition, no increased risk of neoplastic transformation appears to be associated with the process of liver repopulation for as long as over two thirds of the life span of the recipient animal.

Aging is associated with increased clonogenic potential in rat liver in vivo.

Cancer increases with age and often arises from the selective clonal growth of altered cells. Thus, any environment favoring clonal growth per se poses a higher risk for cancer development. Using a genetically tagged animal model, we investigated whether aging is associated with increased clonogenic potential. Groups of 4-, 12-, 18-, and 24-month-old Fischer 344 rats were infused (via the portal vein) with 2x10(6) hepatocytes isolated from a normal syngenic 2-month-old donor. Animals deficient in dipeptidyl-peptidase type IV (DPP-IV-) enzyme were used as recipients, allowing for the histochemical detection of injected DPP-IV+ cells. Groups of animals were sacrificed at various times thereafter. No growth of DPP-IV+ transplanted hepatocytes was present after either 2 or 6 months in the liver of rats transplanted at young age, as expected. In striking contrast, significant expansion of donor-derived cells was seen in animals transplanted at the age of 18 months: clusters comprising 7-10 DPP-IV+ hepatocytes/cross-section were present after 2 months and were markedly enlarged after 6 months (mean of 88+/-35 cells/cluster/cross-section). These results indicate that the microenvironment of the aged liver supports the clonal expansion of transplanted normal hepatocytes. Such clonogenic environments can foster the selective growth of pre-existing altered cells, thereby increasing the overall risk for cancer development associated with aging.

Cyclin D1 is up-regulated in hepatocytes in vivo following cell-cycle block induced by retrorsine.

BACKGROUND/AIMS: We reported massive liver repopulation by transplanted hepatocytes in rats given retrorsine (RS), a pyrrolizidine alkaloid which blocks proliferation of resident cells. In these studies, molecular alterations induced by RS on hepatocyte cell cycle were investigated. METHODS: Animals were treated according to the protocol for liver repopulation, i.e. two injections of RS (30 mg/kg) followed by two-thirds partial hepatectomy (PH) and were sacrificed at various time points thereafter. Livers were analyzed for the expression of cell cycle-related genes. RESULTS: Prior to PH, increased cyclin D1 mRNA and protein levels were found in livers of RS-treated rats. Expression of PCNA was also increased; however, DNA synthesis was not significantly changed. Other cyclins, including cyclin B and cyclin E, were not induced. Cyclin D1 expression increased in controls post-PH and then declined by 48 h, as expected. By contrast, no such modulation of cyclin D1 levels was seen in RS group receiving PH and expression remained high at 48 h, without mitotic division. CONCLUSIONS: Exposure to RS is able to block cell cycle progression after cyclin D1 and PCNA induction, but prior to S phase. Such persistent block outside the resting phase may contribute to the selective replacement of resident cells during liver repopulation.