Reversible immortalization of human hepatocytes mediated by retroviral transfer and site-specific recombination

AIM: To establish a method for the reversible immortalization of human hepatocytes, which may offer a good and safe source of hepatocytes for practical applications.METHODS: We successfully isolated primary human hepatocytes from surgically resected liver tissue taken from a patient with liver hemangiomas. The freshly isolated cells were then immortalized with retroviral vector SSR#69 expressing simian virus 40 large T antigen (SV40T) and hygromycin-resistance genes flanked by paired loxP recombination targets.RESULTS: The freshly isolated hepatocytes with high viability (85%) were successfully immortalized using retroviral gene transfer of SV40T. SV40T in the immortalized cells was then excised by Cre/loxP site-specific recombination. This cell population exhibited the characteristics of differentiated hepatocytes.CONCLUSION: We successfully established reversibly immortalized human hepatocytes, which will provide an unlimited supply of cells for practical applications.     

Which Are the Right Cells to be Used in a Bioartificial Liver?

Anno 2004 freshly isolated or cryopreserved porcine or human hepatocytes have been most frequently used as biocomponent in clinically applied bioartificial livers (BALs). Phase 1 studies of all biocomponent modalities showed safety, feasibility, and improvement of biochemical, neurological, and hemodynamic parameters. However, both the pilot-controlled clinical trial with C3A cells and the randomized larger clinical trial with cryopreserved porcine hepatocytes did not show significant improvement of survival by intention-to-treat analysis. Because of the xenotransplantation-related disadvantages of porcine cells and the shortage of primary human hepatocytes, other sources of biocomponents have to be explored. The future lies in the development of one or more human hepatocyte cell lines, which will have minimal immunogenicity, no risk of xeno-zoonosis, and the requested functionality and availability. Primary sources for the development of such human cell lines are liver-tumor-derived cell lines, immortalized fetal or adult hepatocytes, and stem cells of hepatic, hematopoietic, or embryonic origin. At present the most promising results for BAL application have been obtained by immortalization of human fetal liver cells by reconstitution of telomerase activity. However, in all cell types tested so far, the in vitro differentiation cannot be stimulated to such an extent that their functionality reaches that of primary human hepatocytes. More insight in differentiation-promoting factors and the influence of matrix and co-culture conditions is needed.     

Herpes simplex virus thymidine kinase-mediated suicide gene therapy for hepatocellular carcinoma using HIV-1-derived lentiviral vectors

BACKGROUND/AIMS: Gene therapy is a promising approach for treatment of hepatocellular carcinoma (HCC). However, transduction of non-tumoral hepatocytes may lead to severe hepatitis when using suicide gene therapy approaches. The aim of our study was to evaluate the gene transfer efficiency into HCC cells and normal hepatocytes using human immunodeficiency virus (HIV)-derived lentiviral vectors in vitro and in vivo. METHODS: Lentiviral vectors encoding for the LacZ gene or the fusion gene HSV-Tk/GFP were tested in vitro in human HCC cells and human hepatocytes in primary culture and in vivo in a chemically induced rat model of HCC. RESULTS: We show that HIV-1-derived lentiviral vectors are efficient in transducing HCC cells in vitro and in vivo. No significant transduction of non-tumorous hepatocytes was observed in vivo whatever the route of administration used. Measurement of tumor growth following direct intratumoral injection of a lentiviral vector containing the HSV-Tk gene and GCV treatment showed a strong antitumoral efficacy in the absence of normal liver toxicity. CONCLUSIONS: These observations suggest that lentiviral vectors allow an antitumoral effect with low liver toxicity when using suicide gene therapy approach and could be efficient tools for HCC gene therapy.     

Effects of plasma from patients with acute on chronic liver failure on function of cytochrome P450 in immortalized human hepatocytes

BACKGROUND:The bioartificial liver is anticipated to be a promising alternative choice for patients with liver failure. Toxic substances which accumulate in the patients'plasma exert deleterious effects on hepatocytes in the bioreactor,and potentially reduce the efficacy of bioartificial liver devices. This study was designed to investigate the effects of plasma from patients with acute on chronic liver failure(AoCLF)on immortalized human hepatocytes in terms of cytochrome P450 gene expression,drug metabolism activity and detoxification capability. METHODS:Immortalized human hepatocytes(HepLi-2 cells)were cultured in medium containing fetal calf serum or human plasma from three patients with AoCLF.The cytochrome P450(CYP3A5,CYP2E1,CYP3A4)expression, drug metabolism activity and detoxification capability of HepLi-2 cells were assessed by RT-PCR,lidocaine clearance and ammonia elimination assay. RESULTS:After incubation in medium containing AoCLF plasma for 24 hours,the cytochrome P450 mRNA expression of HepLi-2 cells was not significantly decreased compared with control culture.Ammonia elimination and lidocaine clearance assay showed that the ability of ammonia removal and drug metabolism remained stable. CONCLUSIONS:Immortalized human hepatocytes can be exposed to AoCLF plasma for at least 24 hours with no significant reduction in the function of cytochrome P450. HepLi-2 cells appear to be effective in metabolism and detoxification and can be potentially used in the development of bioartificial liver.     

Treatment of liver failure in rats with end-stage cirrhosis by transplantation of immortalized hepatocytes

The shortage of organ donors has impeded the development of human hepatocyte transplantation. Immortalized hepatocytes could provide an unlimited supply of transplantable cells. To determine whether immortalized hepatocytes could provide global metabolic support in end-stage liver disease, 35 immortalized rat hepatocyte clones were developed by transduction with the gene encoding the simian virus 40 T antigen (SV40Tag). The SV40Tag sequence and a suicide gene, herpes simplex virus thymidine kinase (HSV-tk), were flanked by loxP sequences so that they could be excised by Cre/lox recombination. When transplanted into the spleens of portacaval-shunted rats, 3 of the 35 immortalized hepatocyte clones prevented the development of hyperammonemia-induced hepatic encephalopathy. The protection was reversed by treatment with ganciclovir, which kills HSV-tk-expressing cells. Transplantation of alginate-encapsulated, immortalized hepatocytes into the spleens of cirrhotic rats resulted in significant improvement in prothrombin time, serum albumin and bilirubin levels, hepatic encephalopathy score, and duration of survival. The metabolic support provided by the immortalized cells equaled that observed after transplantation of primary rat hepatocytes. In conclusion, immortalized hepatocytes can function as well as primary hepatocytes following transplantation and can be engineered to contain safeguards that could make them clinically useful. Further investigation is warranted regarding the mechanisms of loss of mass or function of the transplanted hepatocytes over time and how the relatively few engrafted hepatocytes can ameliorate liver decompensation in cirrhosis.     

Pluripotent Stem Cell-derived Strategies to Treat Acute Liver Failure: Current Status and Future Directions

Liver disease has long been a heavy health and economic burden worldwide. Once the disease is out of control and progresses to end-stage or acute organ failure, orthotopic liver transplantation (OLT) is the only therapeutic alternative, and it requires appropriate donors and aggressive administration of immunosuppressive drugs. Therefore, hepatocyte transplantation (HT) and bioartificial livers (BALs) have been proposed as effective treatments for acute liver failure (ALF) in clinics. Although human primary hepatocytes (PHs) are an ideal cell source to support these methods, the large demand and superior viability of PH is needed, which restrains its wide usage. Thus, a finding alternative to meet the quantity and quality of hepatocytes is urgent. In this context, human pluripotent stem cells (PSC), which have unlimited proliferative and differential potential, derived hepatocytes are a promising renewable cell source. Recent studies of the differentiation of PSC into hepatocytes has provided evidence that supports their clinical application. In this review, we discuss the recent status and future directions of the potential use of PSC-derived hepatocytes in treating ALF. We also discuss opportunities and challenges of how to promote such strategies in the common applications in clinical treatments.     

Rapid hepatic fate specification of adipose-derived stem cells and their therapeutic potential for liver failure

Background and Aim:  Multipotential mesenchymal stem cells (MSC), present in many organs and tissues, represent an attractive tool for the establishment of a successful stem cell-based therapy in the field of regeneration medicine. Adipose tissue mesenchymal stem cells (AT-MSC), known as adipose-derived stem cells (ASC) are especially attractive in the context of future clinical applications because of their high accessibility and minimal invasiveness during the procedure to obtain them. The goal of the present study was to induce human ASC into functional hepatocytes in vitro within a very short period of time and to check their therapeutic potential in vivo .
Methods:  In vitro generated ASC-derived hepatocytes were checked for hepatocyte-specific markers and functions. Afterwards, they were transplanted into nude mice with liver injury. Twenty-four hours after transplantation, biochemical parameters were evaluated in blood serum.
Results:  We have shown here that ASC can be differentiated into hepatocytes within 13 days and can reach the functional properties of primary human hepatocytes. After transplantation into mice with acute liver failure, ASC-derived hepatocytes can restore such liver functions as ammonia and purine metabolism. Markers of liver injury, alanine aminotransferase, aspartate aminotransferase, as well as ammonia, were decreased after ASC-derived hepatocyte transplantation.
Conclusions:  Our data highlight the properties of ASC as having a special affinity for hepatocyte differentiation in vitro and liver regeneration in vivo . Thus, ASC may be a superior choice for the establishment of a therapy for injured liver.     

Efficacy and limitation of bone marrow transplantation in the treatment of acute and subacute liver failure in rats

Aim:  Recent reports have shown that bone marrow cells (BMC) retain the potential to differentiate into hepatocytes. Thus, the BMC have been recognized as an attractive source for liver regenerative medicine. However, it has not been clarified whether BMC transplantation can be used to treat liver damage in vivo . In the present study, we explored whether BMC possess therapeutic potential to treat acute and/or subacute liver failure.
Methods:  Fulminant hepatic failure (FHF) was induced by 70% hepatectomy with ligation of the right lobe pedicle (24% liver mass), followed by transplantation of BMC into the spleen. Dipeptidyl peptidase IV-positive (DPPIV⁺) BMC were then transplanted into DPPIV-negative (DPPIV^-) recipients following hepatic irradiation (HIR) in which 70% of the liver was resected and the remnant liver irradiated.
Results:  There was no benefit of BMC transplantation towards survival in the FHF model. DPPIV⁺ hepatocytes appeared in the liver tissues of the DPPIV^- HIR model rats, but DPPIV⁺ hepatocytes replaced less than 13% of the recipient liver.
Conclusion:  BMC transplantation may have limitations in the treatment of fulminant or acute liver failure because they do not have sufficient time to develop into functional hepatocytes. Preparative HIR may be beneficial in help to convert the transplanted BMC into host hepatocytes, and provide a survival benefit. Although, However, the precise mechanism warrants further studies.     

Transplantation of human hepatocytes into tolerized genetically immunocompetent rats

AIM: To determine whether normal genetically immunocompetent rodent hosts could be manipulated to accept human hepatocyte transplants with long term survival without immunosuppression. METHODS: Tolerance towards human hepatocytes was established by injection of primary human hepatocytes or Huh7 human hepatoma cells into the peritoneal cavities of fetal rats. Corresponding cells were subsequently transplanted into newborn rats via intrasplenic injection within 24h after birth. RESULTS: Mixed lymphocyte assays showed that spleen cells from non-tolerized rats were stimulated to proliferate when exposed to human hepatocytes, while cells from tolerized rats were not. Injections made between 15 d and 17 d of gestation produced optimal tolerization. Transplanted human hepatocytes in rat livers were visualized by immunohistochemical staining of human albumin. By dot blotting of genomic DNA in livers of tolerized rats 16 weeks after hepatocyte transplantation, it was found that approximately 2.5 X 10(5) human hepatocytes survived per rat liver. Human albumin mRNA was detected in rat livers by RT-PCR for 15 wk, and human albumin protein was also detectable in rat serum. CONCLUSION: Tolerization of an immuno-competent rat can permit transplantation, and survival of functional human hepatocytes.     

Immortalized p19ARF null hepatocytes restore liver injury and generate hepatic progenitors after transplantation

Primary hepatocytes are blocked in mitotic activity and well-defined culture conditions only allow the limited expansion of these cells. Various genetic modifications have therefore been employed to establish immortalized hepatic cell lines, but, unfortunately, proper hepatocyte cultures conducting a faithful hepatic gene expression program and lacking malignancy are hardly available. Here we report the immortalization of primary hepatocytes isolated from p19(ARF) null mice using the rationale that loss of p19(ARF) lowers growth-suppressive functions of p53 and bypasses cellular senescence without losing genetic stability. The established hepatocytes, called MIM, express liver-specific markers, show a nontumorigenic phenotype, and competence to undergo Fas-mediated apoptosis. Intrasplenic transplantation of GFP-expressing parental MIM cells into Fas-injured livers of SCID mice revealed liver-reconstituting activity. In the regenerated liver, MIM cells localized in small-sized clusters and showed presence in structures comparable to canals of Hering, the site of oval cells. Transplantation of MIM-Bcl-X(L) cells, which are protected against apoptosis, and successive Fas-induced liver damage, enhanced donor-derived liver repopulation by showing differentiation into cholangiocytes and cells expressing markers characteristic of both fetal hepatocytes and oval cells. In conclusion, these data indicate that long-term cultivated p19(ARF) null hepatocytes are capable of generating hepatic progenitor cells during liver restoration, and thus represent a highly valuable tool to study the differentiation repertoire of hepatocytes.     

Hepatocyte transplantation: new horizons and challenges

Hepatocyte transplantation represents an alternative strategy for treating liver disease. Liver repopulation following acute liver failure could, potentially, eliminate the requirement for orthotopic liver transplantation. Similarly, the ability to repopulate the liver with disease-resistant hepatocytes offers new opportunities for correcting genetic disorders and treating patients with chronic liver disease. Recent advances concerning the fate of transplanted cells in the recipient liver, the efficacy of cell therapy in outstanding animal models of human disease, and the isolation of progenitor liver cells capable of differentiating into mature hepatocytes have renewed optimism in regard to treating people with hepatocyte transplantation. Recruitment of an increasing number of investigators to the field and the success of recent pilot studies indicate that hepatocyte transplantation will become routine clinical practice in the near future.     

A highly efficient,stable, and rapid approach for ex vivo human liver gene therapy via a FLAP lentiviral vector

Allogenic hepatocyte transplantation or autologous transplantation of genetically modified hepatocytes has been used successfully to correct congenital or acquired liver diseases and can be considered as an alternative to orthotopic liver transplantation. However, hepatocytes are neither easily maintained in culture nor efficiently genetically modified and are very sensitive to dissociation before their reimplantation into the recipient. These difficulties have greatly limited the use of an ex vivo approach in clinical trials. In the present study, we have shown that primary human and rat hepatocytes can be efficiently transduced with a FLAP lentiviral vector without the need for plating and culture. Efficient transduction of nonadherent primary hepatocytes was achieved with a short period of contact with vector particles, without modifying hepatocyte viability, and using reduced amounts of vector. We also showed that the presence of the DNA FLAP in the vector construct was essential to reach high levels of transduction. Moreover, transplanted into uPA/SCID mouse liver, lentivirally transduced primary human hepatocytes extensively repopulated their liver and maintained a differentiated and functional phenotype as assessed by the stable detection of human albumin and antitrypsin in the serum of the animals for months. In conclusion, the use of FLAP lentiviral vectors allows, in a short period of time, a high transduction efficiency of human functional and reimplantable hepatocytes. This work therefore opens new perspectives for the development of human clinical trials based on liver-directed ex vivo gene therapy.     

Concept for Modular Extracorporeal Liver Support for the Treatment of Acute Hepatic Failure

Acute liver failure has a poor prognosis. The introduction of liver transplantation as a therapeutic option reduced mortality to 20–40%. With the growing disparity between the number of organ donations and the number of patients waiting for liver transplantation, efforts have been made to optimize the allocation of organs and to design extracorporeal methods to support the failing liver. The modular extracorporeal liver support is a concept for the treatment of hepatic failure. The CellModule is a multicompartment bioreactor for extracorporeal liver support therapy. The construction provides efficient integrated oxygenator functions and decentralized mass transfer is effected by a woven array of capillary systems. The bioreactor promotes primary human liver cells to spontaneous neo-formation of liver sinusoidal structures in vitro. Small capillary subunits, in which interwoven membrane links represent the liver lobuli, are simultaneously perfused. The used cell mass of 400–600 g enabled the clinical application of a liver lobe equivalent hybrid organ. The DetoxModule enables albumin-dialysis for removal of albumin-bound toxins; a DialysisModule for continuous veno-venous hemofiltration can be added to the system, in the case of hepato-renal failure.     

Serum from patients with fulminant hepatic failure causes hepatocyte detachment and apoptosis by a beta(1)-integrin pathway

Hepatocyte transplantation is restricted by the impaired ability of hepatocytes to engraft and survive in the damaged liver. Understanding the mechanisms that control this process will permit the development of strategies to improve engraftment. We studied changes in liver matrix during acute injury and delineated the mechanisms that perturb the successful adhesion and engraftment of hepatocytes. Collagen IV expression was increased in sinusoidal endothelium and portal tracts of fulminant hepatic failure explants, whereas there were minimal changes in the expression of fibronectin, tenascin, and laminin. Using an in vitro model of cellular adhesion, hepatocytes were cultured on collagen-coated plates and exposed to serum from patients with liver injury to ascertain their subsequent adhesion and survival. There was a rapid, temporally progressive decrease in the adhesive properties of hepatocytes exposed to such serum that occurred within 4 hours of exposure. Loss of activity of the beta1-integrin receptor, which controls adhesion to collagen, was seen to precede this loss of adhesive ability. Addition of the beta1-integrin activating antibody (TS2/16) to cells cultured with liver injury serum significantly increased their adhesion to collagen, and prevented significant apoptosis. In conclusion, we have identified an important mechanism that underpins the failure of infused hepatocytes to engraft and survive in liver injury. Pretreating cells with an activating antibody can improve their engraftment and survival, indicating that serum from patients with liver injury exerts a defined nontoxic biological effect. This finding has important implications in the future of cellular transplantation for liver and other organ diseases.     

永生化人肝细胞系的建立及其鉴定

目的 建立永生化的人肝细胞系,为生物人工肝、肝细胞移植、体外药物代谢等提供细胞模型.方法 应用胶原酶等四步灌流法分离获得原代人肝细胞,以含有SV40大T抗原(SV40LT)的重组反转录病毒对原代人肝细胞进行永生化,并对永生化人肝细胞进行生物学特性鉴定.结果原代人肝细胞经含有SV40 LT的重组反转录病毒感染3～4周后,获得2株永生化人肝细胞系,分别命名为HepLi2和HepLi3,永生化人肝细胞在相差显微镜下具有典型的肝细胞形态.Western印迹显示有SV40 LT基因的蛋白表达;RT-PCR显示永生化人肝细胞有Alb、谷胱甘肽S转移酶(GSTp)、人凝血因子X(HBCF-X)和β-actin mRNA表达,有细胞色素(CY)P450亚型(CYP3A5、CYP2E1、CYP2C8-19、CYP3A4)mRNA的表达;在HepILi2和HepLi3永生化人肝细胞的培养上清液中可检测到ALT、乳酸脱氢酶(LDH)和Alb.结论 新建立的永生化人肝细胞系具有正常人肝细胞的生物学特性以及完善的肝细胞CYP450酶功能,可进一步用于肝细胞药物代谢研究.     

Hepatocyte transplantation: state of the art and strategies for overcoming existing hurdles

Over three decades of research in experimental animals and several clinical trials have brought us to the threshold of hepatocyte transplantation for the treatment of acute and chronic liver failure, and inherited metabolic disorders. However, more extensive clinical studies and routine clinical application are hampered by the shortage of good quality of donor cells. To overcome these hurdles, current research has focused on the search for alternatives to adult primary hepatocytes, such as liver cell progenitors, fetal hepatoblasts, embryonic, bone marrow or umbilical cord blood stem cells and conditionally immortalized hepatocytes. Cross-species hepatocyte transplantation is also being explored. It is hoped that ongoing research will permit the application of hepatocyte transplantation to the treatment of a wide array of liver diseases.