肝卵圆细胞来源分化增殖的研究进展

卵圆细胞为肝内一种祖细胞，在肝细胞严重受损或分裂增生受抑制时可向肝细胞和胆管上皮细胞分化，是一种具有双向分化潜能的祖细胞。卵圆细胞的分化增殖受多种因素调控．新近研究认为SDF-1-CXCR4生物学轴在卵圆细胞增殖过程中起非常重要的作用。肝癌的发生与卵圆细胞的分化异常有一定的关系。卵圆细胞分化为肝细胞和胆管上皮细胞使其可能成为旰脏细胞移植的重要细胞来源，在治疗终末期肝病、生物人工肝及基因治疗的研究领域有着广阔的应用前景。     

Selective proliferation of chemically altered rat liver epithelial cells following hepatic transplantation

Although proliferation of oval cells is often observed during the early stages of chemical hepatocarcinogenesis, the role of these putative hepatic stem cells during the neoplastic process is unknown. In earlier studies our laboratory showed that feeding a choline-deficient (CD) diet containing 0.05% 2-acetylaminofluorene (CD-AAF) to rats produced three subpopulations of oval cells that antigenically resemble biliary duct cells, fetal liver cells, and transitional cells. In the present investigation we have employed a semiallogeneic transplantation protocol in order to study the fate of these nonparenchymal epithelial cells (NPEC) beyond the 4-week endpoint imposed by the lethality of CD-AAF diet. An enriched NPEC suspension containing gamma-glutamyl-transpeptidase (GGT)-positive oval cells (greater than 75%) was isolated from ACI rats maintained on CD-AAF diet for 3 weeks. The donor cells were transplanted via the portal vein into livers of male F1 progeny (LExACI) that had been fed a CD diet for 7 days prior to receiving a partial hepatectomy and the cell suspension. Host rats were then fed either a CD or choline-supplemented (CS) diet for 12 weeks and killed. Colonies of donor-derived cells identified in frozen sections by their lack of reactivity with ACI anti-LE alloantiserum in indirect immunofluorescence (IF) assays were only observed in rats continuously fed the CD diet. Histochemical analysis indicated that the donor-derived colonies expressed GGT, a preneoplastic marker for liver cancer. IF assays using MAbs previously shown to be capable of distinguishing between oval cells and mature hepatocytes indicated that the donor-derived colonies consisted of a mixture of cells with phenotypes resembling those of mature and immature hepatocytes rather than those of oval or ductal cells. Although the cellular origin of the GGT+ donor-derived colonies has not been unequivocally resolved, our results demonstrate that the livers of rats fed a CD-AAF diet contain a chemically altered call population that can be induced to proliferate by a CD diet. In contrast, a CD diet did not promote colonization when normal hepatocytes were employed as the donor cell population, suggesting that the GGT+ oval cells and not the few contaminating GGT- hepatocytes (1%) in the CD-AAF donor cell suspension were the preneoplastic precursors that gave rise to donor-derived colonies. This transplantation protocol will be useful to define the biological potential of chemically altered liver cells during carcinogenesis.     

The origin of biliary ductular cells that appear in the spleen after transplantation of hepatocytes

Transplantation of rat hepatocytes into the syngeneic rat spleen results in the appearance of cytokeration (CK)-19-positive biliary cells that form ductules. The exact origin of CK-19-positive cells is not known and the possibility that they are derived from biliary cells or precursors of oval cells in transplanted hepatocyte preparations has been raised. In the present study, we found that the number of CK-19-positive biliary cells increased rapidly after transplantation of hepatocytes, reached the maximum at 4 weeks, and then gradually decreased. However, a Ki-67 labeling index of CK-19-positive biliary cells was low and showed no significant changes throughout the experimental period. In addition, no or few CK-19-positive cells appeared in the spleen after transplantation of nonparenchymal liver cells enriched with biliary cells. These results showed that biliary cells were not the source of CK-19-positive cells in the spleen. Impairment of precursors of oval cells in the liver by administration of 4,4'-diaminodiphenylmethane 24 h before transplantation of hepatocytes did not prevent the appearance of CK-19-positive biliary cells in the spleen. Moreover, transplantation of nonparenchymal cells carrying an increased number of oval cells by means of treatment with 2-acetylaminofluorene and partial hepatectomy resulted in no appearance of CK-19-positive biliary cells in the spleen. These results ruled out oval cells as the origin of CK-19-positive biliary cells in the spleen. Because CK-19-positive biliary cells appeared in the spleen only when hepatocyte fractions were transplanted, we suggest transdifferentiation of heptocytes may be the mechanism by which CK-19-positive biliary cells are generated.     

Extensive chimerism in liver transplants: Vascular endothelium,bile duct epithelium,and hepatocytes

The transplanted liver has been shown to be particularly capable of inducing tolerance. An explanation may be the presence of chimerism. Cells of donor origin have been found in recipient tissues after transplantation of any solid organ. Evidence for the presence of cells of recipient origin within the transplanted liver is very limited. We investigated whether nonlymphoid cells of recipient origin can be found within human liver allografts. Five male patients who received a liver transplant from a female donor and 11 patients who received an HLA-I mismatched liver transplant were studied. We confirmed our observations with two different techniques in combination with double-staining techniques. To identify male cells in female liver transplants, we used in situ hybridization for sex chromosomes. To identify specific HLA class I antigens of recipient origin, we used immunohistochemistry with HLA class I-specific antibodies. Double staining was performed to discriminate different cell lineages and inflammatory cells. Endothelial cells of recipient origin were found in 14 of 16 donor livers. Bile duct epithelial cells of recipient origin were found in 5 of 16 cases. Hepatocytes of recipient origin were seen in only 1 of the 5 studied sex-mismatched donor livers. Our study provides evidence that cells of recipient origin can replace biliary epithelial cells, endothelial cells, and hepatocytes within the human liver allograft. This is consistent with the concept that circulating pluripotent progenitor cells exist, capable of differentiating into endothelial cells, epithelial cells, and hepatocytes. (Liver Transpl 2003;9:552-556.)     

Liver repopulation after cell transplantation in mice treated with retrorsine and carbon tetrachloride

BACKGROUND: Efficiency of engraftment after liver cell transplantation is less than 1% under conventional conditions. Our aim was to develop a high-efficiency, nonsurgical, no-genetic-advantage mouse model of liver repopulation with transplanted cells. METHODS: Mice were conditioned with nonlethal doses of a cell cycle inhibitor, retrorsine, 70 mg/kg, to irreversibly block proliferation of native hepatocytes. After the drug was eliminated, 2 million freshly isolated beta-galactosidase-labeled liver cells were transplanted into the spleens of C57BL/6J recipient mice. To stimulate donor cell proliferation, three doses of carbon tetrachloride (CCl4), 0.5 ml/kg, were given. Several control groups were studied to evaluate the contribution of each treatment to liver repopulation. RESULTS: Repopulation, as measured by cell isolation from recipient livers 1-7 months after transplantation, was on average 20%. Repopulation was 10% if CCl4 was given only once, between 0.5% and 1% if only retrorsine or CCl4 were used, and 0.05% if no conditioning was used. Phenotypically, whole livers turned blue on exposure to X-gal staining, whereas negative (control) livers remained pale brown. More than 55% of liver repopulation resulted from clusters containing 21 or more cells, some of which contained more than 200 cells, suggesting seven or more rounds of cell division in a subset of transplanted cells. CONCLUSION: This murine study demonstrates high levels of repopulation after liver cell transplantation into nongenetically modified livers, using a cell cycle inhibitor and chemical liver injury to provide transplanted cells a proliferative advantage. Liver repopulation was effected mostly by a small fraction of transplanted cells. Analogous nonsurgical liver cell transplantation strategies, but with clinically applicable drugs, could be devised for the treatment of liver-based metabolic diseases.     

兔肝细胞胆管上皮细胞对射频热效应的敏感性

目的　探讨兔正常肝细胞、胆管上皮细胞对射频热效应的敏感性。方法　将40只新西兰大白兔随机分为射频组和对照组。射频组用Cool tip冷循环超能射频肿瘤治疗系统行肝射频治疗8 min,对照组除不行射频治疗外其余处理均与射频组相同。24 h后切除肝脏,HE染色观察损伤区及正常肝组织,用TUNEL法检测肝细胞、胆管上皮细胞凋亡作为判断热敏性指标。结果　射频组凝固、坏死与正常交界区组织形态学上肝细胞损伤较胆管上皮细胞明显,其肝细胞的凋亡指数显著高于胆管上皮细胞(P<0.05);随着离凝固、坏死边缘距离的增加凋亡指数逐渐降低,1.0 cm以内无显著性差异(P>0.05),距离2.0 cm以内与对照组相比均有非常显著性差异(P<0.01)。结论　正常兔肝细胞对射频热效应的敏感性大于胆管上皮细胞,凋亡与射频热效应相关,是射频引起肝细胞、胆管上皮细胞死亡的形式之一。     

Blocking CTL-based cytotoxic pathways reduces apoptosis of transplanted hepatocytes.

BACKGROUND: A major obstacle in allogenic hepatocyte transplantation is increased apoptosis of grafted cells due to CTL-based cytotoxicity. However, whether blockade of Fas- and granzyme-mediated pathways of CTL-based cytotoxicity may provide immune protection to transplanted hepatocytes is poorly defined. Our study aimed to reduce apoptosis of allogenic transplanted hepatocytes by inhibiting granzyme B (GraB) activity and blocking Fas-FasL interaction. MATERIALS AND METHODS: Hepatocyte transplantation was performed by inoculating isolated liver cells from ACI rats (allogenic) or Lewis rats (syngenic) into the spleens of Lewis rats. Recipients were treated with FLIM58, an inhibitory anti-FasL mAb, and GraB inhibitor I alone or a combination of the two drugs for 5 days after transplantation, and were sacrificed at Day 7. Apoptosis of transplanted hepatocytes was detected in situ by TUNEL assay and M30 immunostaining. Glutamate dehydrogenase (GLDH) activity in recipient spleens was examined to evaluate survival of transplanted cells. Recipient spleens were assayed for FasL level with Western blotting and for GraB activity by hydrolysis of GraB substrate. RESULTS: FLIM58 or GraB inhibitor I significantly reduced the percentage of TUNEL-positive and M30-positive hepatocytes and markedly increased GLDH levels in allogenic, but not syngenic, recipient spleens. These effects were more pronounced when the two drugs were used in combination (P < 0.05). Additionally, elevation of FasL and GraB levels in allogenic recipient spleens can be significantly reduced by FLIM58 and GraB inhibitor I, respectively. CONCLUSIONS: Inhibition of GraB activity and blockade of Fas-FasL interaction reduce the apoptosis of allogenic transplanted hepatocytes, and thus improve their survival.     

Albumin-Producing Hepatocytes Derived from Cryopreserved F344 Rat Bone Marrow Cells Transplanted in the Livers of Congenic Nagase's Analbuminemic Rats

Purpose Hematopoietic stem cells (SCs) are thought to have the potential to differentiate into hepatocytes; however, this potential has not been reported for cryopreserved SCs. We investigated whether cryopreserved bone marrow cells (BMCs) from F344 rats (F344) can induce the growth of albumin-producing hepatocytes in the livers of congenic Nagase's analbuminemic rats (F344alb). Methods F344 BMCs were cryopreserved in University of Wisconsin (UW) solution containing 10% fetal bovine serum and 12% dimethylsulfoxide, at −80°C. After thawing, 20 × 10⁶ cells were infused via the portal vein into the livers of F344alb immediately after 70% hepatectomy (PH). We examined the recipient livers for albumin-positive (alb+) hepatocytes and albumin mRNA, and measured the serum albumin levels 4 weeks later. Results Single and double alb+ hepatocytes were occasionally seen in the F344alb livers without the BMC transplantation. However, clusters consisting of more than three alb+ hepatocytes were seen in the livers of recipients transplanted with the cryopreserved BMCs after PH, the same as in the livers transplanted with freshly isolated BMCs. Normal albumin mRNA was detected in the recipient livers and the serum albumin levels were increased. Conclusion Cryopreserved F344 BMCs can induce the growth of alb+ hepatocytes after transplantion in the F344alb liver after PH.     

Adenovirus-Mediated CTLA4Ig Gene Transfer Improves the Survival of Grafted Human Hepatic Progenitors in Mouse Liver

The invasive nature of surgery and limited numbers of donor livers for end-stage patients has prompted the search for alternative cell therapies for intractable hepatic disease. Hepatocyte ransplantations have been performed for a variety of indications, but sustained benefits have not been observed in most cases. Rat fetal liver epithelial cells (liver stem cells) have demonstrated self-renewal in vivo and functional repopulation of the liver. We have previously isolated and expanded epithelial progenitor cells (EPC) from the human fetal liver to investigate their differentiation potential. In this study, we applied suppression of immunorejection by adenoviral CTLA4Ig gene delivery mediated to examine the survival and differentiation of human fetal EPC transplanted into normal mouse liver. The grafted EPC showed extensive proliferation at both 1 and 2 months after transplantation compared with controls. Moreover, most EPC differentiated into hepatocytes, while a small fraction became bile ductular cells. This finding suggested that human fetal EPC may be a ideal source of cell-based therapy for various liver diseases.     

Hepatocyte transplantation in the Long Evans Cinnamon rat model of Wilson's disease

Wilson's disease (WD), caused by a mutation in the P-type copper transporting ATPase (Atp7b) gene, results in excessive accumulation of copper in the liver. Long Evans Cinnamon rats (LEC) bear a mutation in the atp7b gene and share clinical characteristics of human WD. To explore hepatocyte transplantation (HT) as therapy for metabolic liver diseases, 8-week-old LEC rats (n = 12) were transplanted by intrasplenic injection of hepatocytes from donor Long Evans (LE) rats. Immunosuppression was maintained with intraperitoneal tacrolimus. The success of HT was monitored at 24 weeks of life. Serum aminotransferases and bilirubin peaked at 14-21 weeks in both HT rats and nontransplanted controls, but at 24 weeks, survival was 97% in LEC-HT versus 63% in controls. All transplanted rats showed restored biliary copper excretion and reduced liver iron concentration associated with increased ceruloplasmin oxidase activity. Liver tissue expressed atp7b mRNA (11.9 +/- 13.6%) indicative of engraftment of normal cells in 7 of 12 HT rats, associated with a reduced liver copper concentration compared to untreated LEC rats. Periportal islets of normal appearing hepatocytes, recognized by atp7b antibody, were observed in transplanted livers while lobular host cells showed persistent pleomorphic changes and inflammatory infiltrates. In conclusion, transplantation of normal hepatocytes prevented fulminant hepatitis, reduces chronic inflammation, and improved 6-month survival in LEC rats. Engraftment of transplanted cells, which express atp7b mRNA, repopulated the recipient liver with normal functional capacity.     

Enhanced proliferation of hepatic progenitor cells in rats after portal branch occlusion.

It is known that hepatic progenitor cells increase in number after liver injury caused by carcinogens, but this injury cannot be reproduced in humans. In order to create a practical source of hepatic progenitor cells, changes in the number of liver epithelial cells (LECs), a type of hepatic progenitor cell, were examined following partial interruption of the portal flow. Efficiency in this isolation procedure was investigated, and isolated LECs were transplanted into livers to demonstrate their differentiation into hepatocytes in vivo.A volume of 70% of Sprague-Dawley rat's livers was exposed to portal vein ligation. LECs, identified as alpha-fetoprotein (AFP)-positive and albumin-negative cells, were counted and LECs isolated from the portal vein ligated-lobe were characterized by immunostaining and Western blotting. Isolated cells were subjected to a 1-week-culture, and the number of colonies formed on dishes was counted. The cells were then transplanted to the livers of genetic analbuminemic rats and identified by immunohistochemistry. The number of LECs in the portal ligated-lobes on day 7 was 14.7 +/- 6.5 cells/1,000 hepatocytes: 18 times higher than numbers in a normal liver. A significant increase was noted from day 3 until day 28. Isolated LECs were AFP-positive, albumin-negative, and cytokeratin-19-positive cells. The number of colonies on the 7th day following portal vein ligation was 42 times higher than in a normal liver. After transplantation of the LECs to the analbuminemic rat, a cluster of albumin-producing cells was present until day 56, suggesting that they differentiate into hepatocytes. We conclude that after portal vein occlusion, the liver can be a good source of hepatic progenitor cell. These results open up the possibility of cellular transplantation for liver functional support in clinical settings.     

Transplantation of Embryonic Small Hepatocytes Induces Regeneration of Injured Liver in Adult Rat

Small hepatocytes as hepatic stem cells or progenitors may be transplanted to treat several end-stage liver diseases. To identify the characteristics of epithelial cells enriched from fetal liver, we used immunocytochemistry and electron micrography. All cells in the colonies were immunocytochemically positive for alpha fetoprotein and cytokeratins (CK) 7, CK8, and CK18, which are markers of hepatic progenitor. Under transmission electron microscopy, we observed the cultured cells to show naive characteristics of stem cells and to be significantly distinct from mature hepatocytes. To identity whether these small hepatocytes were able to proliferate and differentiate into mature hepatocytes, we cultured them in vitro, and, through the portal vein, and transplanted elements whose membrane were stained with red fluorescence using PKH26 linker dye, into the livers of CCl₄-treated rats that had been subjected to two-thirds partial hepatectomy. Significant liver regeneration was observed 30 days later in rats that did or did not receive the cells. The livers of hepatocytes recipients showed sharper edges and smoother surfaces than the control group. Diffused cells labeled with red fluorescence were observed in the portal area, with branch-like red fluorescence in regions near portal areas of some lobules, suggesting that these elements were involved in the repair of liver lobules and differentiation into mature hepatocytes. Our results revealed that small hepatocytes not only have characteristics of hepatic stem cells, but also may be a source of cellular transplantation to treat liver diseases.     

Cloning and characterization of liver progenitor cells from the scattered cell clusters in primary culture of porcine livers

The scattered cell clusters that can differentiate into hepatocytes or biliary epithelial cells have been isolated from primary cultures of adult porcine livers. We have generated 11 clonal cell lines from this system and identified liver progenitor cells (LPCs) among the clonal lines. These clonal lines expressed c-kit, HNF-1, HNF-6, and/or CK19 mRNA. An immunocytochemical study of the clonal lines indicated that clonal line CL-11 expressed liver epithelial cell markers CK14, vimentin, CK18, and BD-1. The expression of albumin and alpha1-antitrypsin (alpha1-AT) mRNA was only upregulated in CL-11 among the clonal lines when they were grown as aggregates. Under these conditions, CL-11 also exhibited ammonia metabolic activity and several indicators that suggest hepatocytic differentiation, including the upregulation of liver-specific genes such as dipeptidyl peptidase IV, CYP1A1, and CYP3A4 mRNA, and the downregulation of biliary cell markers such as gamma-glutamyltrans-peptidase (GGT), CK19, and HNF6 mRNA. After culturing CL-11 in Matrigel, the expression of GGT and HNF6 mRNA was upregulated. These results indicate that CL-11 has dual potential: the ability to differentiate as hepatocytes or as bile duct cells. The isolation of scattered cells could provide a simple method to generate LPC lines from adult livers.     

Connective tissue growth factor expression is increased in biliary epithelial cells in biliary atresia

Background/Purpose

Connective tissue growth factor (CTGF) has been implicated in the pathogenesis of hepatic fibrosis and is elevated in the serum of children with biliary atresia (BA). The objective of this study was to evaluate hepatic CTGF messenger RNA (mRNA) expression and its relationship to hepatic histology in children with BA.

Methods

Connective tissue growth factor mRNA expression was evaluated by in situ hybridization in 26 liver biopsies from 11 patients with BA, 11 with other diseases, and 4 autopsy controls. Serial sections were immunostained with cell-specific markers to characterize the cells expressing CTGF. Biopsies were scored for CTGF expression (0-4) and inflammation and fibrosis (1-4).

Results

High levels of CTGF expression were observed in 9 of 11 BA with localization to biliary epithelial cells and vascular endothelial cells. Connective tissue growth factor mRNA expression was correlated with fibrosis in BA and all livers. In the 11 patients with other liver diseases, 7 had CTGF expression limited to hepatic stellate cells and vascular endothelial cells. None of the 4 livers in children without liver disease had significant levels of CTGF.

Conclusions

In BA livers, novel biliary epithelia CTGF mRNA expression is high and correlates with severity of fibrosis. These data support a role for biliary epithelial cell signaling in fibrogenesis.     

Growth ability and repopulation efficiency of transplanted hepatic stem cells, progenitor cells, and mature hepatocytes in retrorsine-treated rat livers

Cell-based therapies as an alternative to liver transplantation have been anticipated for the treatment of potentially fatal liver diseases. Not only mature hepatocytes (MHs) but also hepatic stem/progenitor cells are considered as candidate cell sources. However, whether the stem/progenitor cells have an advantage to engraft and repopulate the recipient liver compared with MHs has not been comprehensively assessed. Therefore, we used Thy1(+) (oval) and CD44(+) (small hepatocytes) cells isolated from GalN-treated rat livers as hepatic stem and progenitor cells, respectively. Cells from dipeptidylpeptidase IV (DPPIV)(+) rat livers were transplanted into DPPIV(-) livers treated with retrorsine following partial hepatectomy. Both stem and progenitor cells could differentiate into hepatocytes in host livers. In addition, the growth of the progenitor cells was faster than that of MHs until days 14. However, their repopulation efficiency in the long term was very low, since the survival period of the progenitor cells was much shorter than that of MHs. Most foci derived from Thy1(+) cells disappeared within 2 months. Many cells expressed senescence-associated β-galactosidase in 33% of CD44-derived foci at day 60, whereas the expression was observed in 13% of MH-derived ones. The short life of the cells may be due to their cellular senescence. On the other hand, the incorporation of sinusoidal endothelial cells into foci and sinusoid formation, which might be correlated to hepatic maturation, was completed faster in MH-derived foci than in CD44-derived ones. The survival of donor cells may have a close relation to not only early integration into hepatic plates but also the differentiated state of the cells at the time of transplantation.     

HVEGF165 increases survival of transplanted hepatocytes within portal radicles: suggested mechanism for early cell engraftment

VEGF is a potent angiogenic factor that promotes hepatocyte growth, increases permeability of blood vessels, and induces vasodilatation, and may accelerate engraftment and function of transplanted hepatocytes. The aim was to study the effect of VEGF on early hepatocyte engraftment. Thirty-two Lewis syngeneic female rats underwent 70% partial hepatectomy. Eighteen received 240 ng VEGF165 and 14 received saline for control. Thereafter, intrasplenic transplantation of 10(7) male hepatocytes was done. Semiquantitative analysis of PCR product of the SRY region of the Y-chromosome was performed. Paraffin-embedded sections were stained for H&E and for PCNA immunostaining. By PCR, male hepatocytes were identified in 8 livers out of 14 VEGF-treated rats at 24-48 h, compared with only 1 liver out of 8 controls. Transplanted cells were seen within portal vessels radicles in 7 out of 14 VEGF-treated rats for as long as 48 h posttransplantation, compared with only one control liver at 24 h. There was no histological sign of cell injury to transplanted or adjacent cells. Two weeks after transplantation male transplanted cells were identified in two out of four rats treated with hVEGF165 and in one out of six rats treated with saline. No transplanted cells were detected within portal tracts 14 days after transplantation. hVEGF165 enhances the presence of transplanted hepatocytes within portal vessels after transplantation. We suggest an additional mechanism for cell engraftment, whereby transplanted hepatocytes first stick to each other in the portal radicles. Later they become included in the liver parenchyma as groups of organized cells in a process stimulated by VEGF.     

Amplification of engrafted hepatocytes by preparative manipulation of the host liver

Scarcity of donor livers is a major obstacle to the general application of hepatocytes for the development of bioartificial liver assist devices as well as intracorporeal engraftment of hepatocytes for the treatment of inherited metabolic diseases. The number of hepatocytes that can be transplanted into the liver safely in a single sitting also limits the utility of this procedure. These limitations could be addressed by providing preferential proliferative advantage to the transplanted cells. Studies using transgenic mouse recipients or donors have indicated that massive repopulation of the host liver by engrafted hepatocytes requires that the transplanted cells are subjected to a proliferative stimulus to which the host hepatocytes cannot respond. Prevention of host hepatocyte proliferation has been achieved by treatment with a plant alkaloid, retrorsine. Because retrorsine is carcinogenic, we have evaluated preparative irradiation for this purpose. The proliferative stimulus may consist of the loss of hepatic mass (e.g., partial hepatectomy, reperfusion injury or induction of Fas-mediated apoptosis by gene transfer) or administration of stimulants of hepatocellular mitosis (e.g., growth factors or thyroid hormone). Potential applications of these preparative manipulations of the host liver include the treatment of inherited metabolic disorders by transplantation of allogeneic hepatocytes, hepatocyte-mediated ex vivo gene therapy, rescuing liver cancer patients from radiation-induced liver damage, and expansion of human hepatocytes in animal livers.     

Heterotopically transplanted hepatocyte survival depends on extracellular matrix components

The novel approach of tissue engineering to treat many forms of liver diseases using hepatocytes requires sufficient numbers and sustained survival of the transplanted cells. It has been shown that providing extracellular matrix components extracted from Engelbreth-Holm-Swarm cells (EHS-ECMs) to heterotopically transplanted hepatocytes allows significantly greater hepatocyte survival. We investigated the survival and morphology of hepatocytes and EHS-ECMs transplanted under the kidney capsule compared with hepatocytes with growth factor-reduced EHS-ECMs in mice. Both the EHS-ECMs and growth factor-reduced EHS-ECMs showed a large number of surviving hepatocytes under the kidney capsule without any intergroup differences. Histologically, transplanted hepatocytes in both groups retained their characteristic morphologies and formed small liver tissues. These data indicate that extracellular matrix components are the predominant factor in EHS-ECMs required to maintain hepatocytes at heterotopic sites.