Improved Hepatocyte Engraftment After Portal Vein Occlusion in LDL Receptor-Deficient WHHL Rabbits and Lentiviral-Mediated Phenotypic Correction In Vitro.

Innovative cell-based therapies are considered as alternatives to liver transplantation. Recent progress in lentivirus-mediated hepatocyte transduction has renewed interest in cell therapy for the treatment of inherited liver diseases. However, hepatocyte transplantation is still hampered by inefficient hepatocyte engraftment. We previously showed that partial portal vein embolization (PVE) improved hepatocyte engraftment in a nonhuman primate model. We developed here an ex vivo approach based on PVE and lentiviral-mediated transduction of hepatocytes from normal (New Zealand White, NZW) and Watanabe heritable hyperlipidemic (WHHL) rabbits: the large animal model of familial hypercholesterolemia type IIa (FH). FH is a life-threatening human inherited autosomal disease caused by a mutation in the low-density lipoprotein receptor (LDLR) gene, which leads to severe hypercholesterolemia and premature coronary heart disease. Rabbit hepatocytes were isolated from the resected left liver lobe, and the portal branches of the median lobes were embolized with Histoacryl® glue under radiologic guidance. NZW and WHHL hepatocytes were each labeled with Hoechst dye or transduced with lentivirus expressing GFP under the control of a liver-specific promoter (mTTR, a modified murine transthyretin promoter) and were then immediately transplanted back into donor animals. In our conditions, 65-70% of the NZW and WHHL hepatocytes were transduced. Liver repopulation after transplantation with the Hoechst-labeled hepatocytes was 3.5 ± 2%. It was 1.4 ± 0.6% after transplantation with either the transduced NZW hepatocytes or the transduced WHHL hepatocytes, which was close to that obtained with Hoechst-labeled cells, given the mean transduction efficacy. Transgene expression persisted for at least 8 weeks posttransplantation. Transduction of WHHL hepatocytes with an LDLR-encoding vector resulted in phenotypic correction in vitro as assessed by internalization of fluorescent LDL ligands. In conclusion, our results have applications for the treatment of inherited metabolic liver diseases, such as FH, by transplantation of lentivirally transduced hepatocytes.

Treatment of fulminant liver failure by transplantation of microencapsulated primary or immortalized xenogeneic hepatocytes.

BACKGROUND: The aim of this study was to evaluate in vitro and in vivo functions of isolated hepatocytes after immortalization, cryopreservation, encapsulation and xenotransplantation into mice with fulminant liver failure (FLF). METHODS: Rat and human hepatocytes were isolated from normal liver tissue by collagenase digestion. Human hepatocytes were immortalized using lentiviral vectors coding for SV 40 large T antigen, Bmi-1 and telomerase. Rat and immortalized human hepatocytes (IHH) were encapsulated in 400 micron alginate-PLL-alginate membranes and cryopreserved using a computerized device. In vitro, encapsulated hepatocytes (cryopreserved or freshly isolated) were cultured in albumin-free medium and albumin production was measured by enzyme-linked immunosorbent assay (ELISA). In vivo, a model of FLF was established in C57/BL6 mice by acetaminophen administration (700 mg/kg i.p.) followed 15 h later by a 30% hepatectomy. Microencapsulated (cryopreserved or freshly isolated) hepatocytes were transplanted intraperitoneally to mice with FLF and the following experimental groups were performed: group 1 (n = 10) Tx of empty capsules; group 2 (n = 12) Tx of free primary rat hepatocytes; group 3 (n = 12) Tx of cryopreserved encapsulated rat hepatocytes; group 4 (n = 10) Tx of fresh encapsulated rat hepatocytes; group 5 (n = 9) Tx of cryopreserved encapsulated IHH; group 6 (n = 10) Tx of fresh encapsulated IHH. Animals were killed at regular intervals and histopathology of microcapsules and liver tissue was obtained. RESULTS: In vitro, cryopreserved or fresh encapsulated rodent hepatocytes showed a progressively decreasing albumin secretion over 1 week in culture. In contrast, cryopreserved or fresh encapsulated IHH showed minimal, but stable albumin secretion. In vivo, FLF was achieved by combination of acetaminophen with 30% hepatectomy, resulting in a reproducible survival of 23% +/- 5%. In groups 1 and 2, survival rates were not improved significantly compared with untreated mice. In groups 3 and 4, Tx of cryopreserved or fresh encapsulated rat hepatocytes significantly increased survival rate to 66% and 80%, respectively (P < 0.01). In groups 5 and 6, Tx of cryopreserved or fresh encapsulated IHH improved survival to 50% and 55%, respectively (P < 0.05). Histopathology revealed that encapsulated hepatocytes were viable up to 2 weeks post-Tx. CONCLUSIONS: Primary rodent hepatocytes maintained synthetic functions after encapsulation and cryopreservation short-term. IHH showed minimal albumin secretion in the absence of encapsulation and cryopreservation, suggesting that hepatocytes loose specific functions after immortalization. After induction of FLF in mice, intraperitoneal Tx of encapsulated (primary or immortalized, fresh or cryopreserved) xenogeneic hepatocytes significantly improved survival. These results indicate that naïve and genetically modified hepatocytes can successfully be encapsulated, stored using cryopreservation, and be transplanted into xenogeneic recipients with liver failure and sustain liver metabolic functions.