Cell transplantation after oxidative hepatic preconditioning with radiation and ischemia-reperfusion leads to extensive liver repopulation.

The inability of transplanted cells to proliferate in the normal liver hampers cell therapy. We considered that oxidative hepatic DNA damage would impair the survival of native cells and promote proliferation in transplanted cells. Dipeptidyl peptidase-deficient F344 rats were preconditioned with whole liver radiation and warm ischemia-reperfusion followed by intrasplenic transplantation of syngeneic F344 rat hepatocytes. The preconditioning was well tolerated, although serum aminotransferase levels rose transiently and hepatic injury was observed histologically, along with decreased catalase activity and 8-hydroxy adducts of guanine, indicating oxidative DNA damage. Transplanted cells did not proliferate in the liver over 3 months in control animals and animals preconditioned with ischemia-reperfusion alone. Animals treated with radiation alone showed some transplanted cell proliferation. In contrast, the liver of animals preconditioned with radiation plus ischemia-reperfusion was replaced virtually completely over 3 months. Transplanted cells integrated in the liver parenchyma and liver architecture were preserved normally. These findings offer a paradigm for repopulating the liver with transplanted cells. Progressive loss of cells experiencing oxidative DNA damage after radiation and ischemia-reperfusion injury could be of significance for epithelial renewal in additional organs.

Isolation of human progenitor liver epithelial cells with extensive replication capacity and differentiation into mature hepatocytes.

The liver can regenerate itself through the progenitor cells it harbors. Here we demonstrate isolation of epithelial progenitor/stem cells from the fetal human liver, which contains a large number of hepatoblasts. Progenitor liver cells displayed clonogenic capacity, expressed genes observed in hepatocytes, bile duct cells and oval cells, and incorporated genes transferred by adenoviral or lentiviral vectors. Under culture conditions, progenitor cells proliferated for several months, with each cell undergoing more than forty divisions, but they retained normal karyotypes. Progenitor cells differentiated into mature hepatocytes in mice with severe combined immunodeficiency, both when in an ectopic location and when in the liver itself. Cells integrated in the liver parenchyma and proliferated following liver injury. An abundance of progenitor cells in the fetal human liver is consistent with models indicating depletion of progenitor/stem cells during aging and maturation of organs. The studies indicate that isolation of progenitor cells from fetal organs will be appropriate for establishing novel systems to investigate basic mechanisms and for cell and gene therapy.

Early cell transplantation in LEC rats modeling Wilson's disease eliminates hepatic copper with reversal of liver disease.

BACKGROUND & AIMS: The Long-Evans Cinnamon (LEC) rat is an excellent model of Wilson's disease with impaired copper excretion, hypoceruloplasminemia, and copper toxicosis. We hypothesized that early hepatocyte transplantation would improve copper excretion and liver disease in Wilson's disease. METHODS: Normal syngeneic Long-Evans Agouti rat hepatocytes were transplanted intrasplenically into 2-week-old LEC rats. Untreated LEC pups were controls. Liver repopulation was shown by changes in serum ceruloplasmin, hepatic atp7b messenger RNA, and bile and liver copper levels. Histologic analysis of the liver was performed. RESULTS: Significant copper accumulation and liver disease were observed in 5-month-old LEC rats, with occasional treated rats showing increased bile copper excretion. The liver was repopulated extensively in 10 of 14 treated LEC rats (71%) 20 months after cell transplantation. In these 10 rats, hepatic copper content was virtually normal in 6 rats (53 +/- 12 microg/g liver) and substantially less in 4 others (270 +/- 35 microg/g) compared with elevated liver copper levels in untreated LEC rats (1090 +/- 253 microg/g) (P < 0.001). Changes in serum ceruloplasmin levels, bile copper excretion capacity, and liver histology were in concordance with decreases in liver copper levels. CONCLUSIONS: Transplanted cells proliferated subsequent to the onset of liver injury, and the liver was repopulated over an extended period. Cell transplantation eventually restored copper homeostasis and reversed liver disease without hepatic preconditioning in LEC rats.