Abstract
Hereditary tyrosinemia type I (HT1) is caused by a deficiency in the enzyme fumarylacetoacetate hydrolase (Fah). Fah-deficient mice and pigs are phenotypically analogous to human HT1, but do not recapitulate all the chronic features of the human disorder, especially liver fibrosis and cirrhosis. Rats as an important model organism for biomedical research have many advantages over other animal models. Genome engineering in rats is limited till the availability of new gene editing technologies. Using the recently developed CRISPR/Cas9 technique, we generated Fah−/− rats. The Fah−/− rats faithfully represented major phenotypic and biochemical manifestations of human HT1, including hypertyrosinemia, liver failure and renal tubular damage. More importantly, the Fah−/− rats developed remarkable liver fibrosis and cirrhosis, which have not been observed in Fah mutant mice or pigs. Transplantation of wild-type hepatocytes rescued the Fah−/− rats from impending death. Moreover, the highly efficient repopulation of hepatocytes in Fah−/− livers prevented the progression of liver fibrosis to cirrhosis and in turn restored liver architecture. These results indicate that Fah−/− rats may be used as an animal model of HT1 with liver cirrhosis. Furthermore, Fah−/− rats may be used as a tool in studying hepatocyte transplantation and a bioreactor for the expansion of hepatocytes.
Similar content being viewed by others
Introduction
Hereditary tyrosinemia type I (HT1) is an autosomal recessive inborn error of metabolism that is caused by defects in the enzyme, fumarylacetoacetate hydrolase (Fah). Fah is an enzyme required in the last step of the tyrosine catabolic pathway, which hydrolyzes fumarylacetoacetate into fumarate and acetoacetate1. A deficiency in Fah leads to the accumulation of toxic metabolites, including fumarylacetoacetate and maleylacetoacetate2. HT1 affects the liver and kidney, which are organs where Fah is mainly expressed3,4. The acute presentation of HT1 is with fatal liver failure in infancy and its chronic presentation is with cirrhosis and hepatocellular carcinoma (HCC) early in childhood5. Renal tubular damage in HT1 patients generally leads to Fanconi syndrome, developmental hypophosphatemic rickets and growth failure6. When left untreated, most HT1 patients die of acute and severe hepatorenal failure during early infancy5. 2-(2-Nitro-4-trifluoromethylbenzoyl)-1,3-cyclohexanedione (NTBC) as an inhibitor of 4-hydroxyphenylpyruvate dioxygenase acts by blocking the accumulation of toxic metabolites such as fumarylacetoacetate and maleylacetoacetate (Supplementary Fig. 1)7. NTBC treatment is effective in ameliorating liver and kidney damage in HT1 patents. Combined with a low tyrosine diet, it has achieved >90% survival rate8,9. However, some HT1 patients do not respond to NTBC, thereby rendering liver transplantation as the only option to date10.
The Fah gene is conserved in mammals. High homology has been observed among human, pig, rat and mouse cDNAs (80% homology) and proteins (94% homology)4. Fah-deficient mice and pigs have previously been reported as disease models for HT111,12,13,14,15. Fah-deficient mice and pigs are maintained using NTBC treatment and both models develop progressive liver failure and renal tubular dysfunction after NTBC withdrawal12,16. Notably, Fah−/− mice can be rescued by wild-type (WT) hepatocyte transplantation, with almost complete liver repopulation by transplanted cells16,17. This approach makes them also a valuable model for evaluating the in vivo functions of lately identified liver progenitor cells and hepatocyte-like cells, a model for generating to generate humanized liver and a bio-factory for the in vivo expansion of human hepatocytes18,19,20,21,22,23. Interestingly, Fah−/− mice can also be used to assess the therapeutic efficacy of transplanted cells from extrahepatic sources such as bone marrow or adult pancreas24,25. Nevertheless, both mouse and pig models fail to recapitulate key chronic manifestations of HT1 patients, namely, liver fibrosis and cirrhosis13.
Rats, as a medium-sized laboratory model, are at least 10 times larger than mice and thus are capable of providing greater blood volumes and more bile acid, cells and tissues for analyses26. More importantly, rats are more similar to humans than mice in terms of various physiological and pathological aspects. For example, rats recapitulate a more accurate phenotype for inflammatory disorders and neurodegenerative diseases, such as Parkinson’s disease and Huntington’s disease27. Interestingly, rats generally show more liver fibrosis than mice upon toxin-induced liver injury28. Furthermore, rats are routinely employed in testing drug therapeutic efficacy and toxicity before human clinical trials29 and abundant physiological and pharmacological data from rats has been accumulated. However, the absence of genetic modification technologies in rats has largely impeded its application in biomedical studies in the last three decades. While our manuscript was under preparation, a Fah−/−IL2rg−/− rat model was reported for the evaluation of the in vivo functions of rat liver stem cells30. However, detailed characterization of human HT1 manifestations in Fah−/− rats remains unclear. We are one of the first groups to adapt the CRISPR/Cas9 system to generate genetically modified rats31,32,33. In the present study, we generated Fah−/− rats using the CRISPR/Cas9 system. Fah−/− rats were maintained with drinking water supplemented with NTBC. After NTBC withdrawal, the Fah−/− rats developed majority of human HT1 manifestations, including liver fibrosis and cirrhosis. Importantly, WT hepatocyte transplantation improved the survival of Fah−/− rats via efficient liver repopulation as well as prevented the development of liver cirrhosis.
Results
Generation of heritable Fah mutant rats using the CRISPR/Cas9 system
To generate a Fah-null allele, two single guide RNAs (sgRNAs) targeting exon 2 of the rat Fah gene (Fig. 1A) were co-injected with Cas9 mRNA into one cell-stage Sprague-Dawley (SD) rat embryos. The manipulated embryos were then transferred into pseudopregnant females. The genomic DNA of the newborns was extracted from tail-tips for PCR amplification using primers flanking the target locus. After T7 endonuclease I (T7EI) digestion, 8 out of 20 pups were identified as founders, bearing mutations in the Fah gene (Fig. 1B). DNA sequencing of the 5 founders confirmed that these were heterozygotes with insertion/deletion (indel) mutations in one allele. 4 out of the 5 indel mutations caused frame-shifting mutations and premature termination (Fig. 1C). Among these, the mutation in founder #15 was predicted to generate the shortest Fah truncation protein. We bred founder #15 with WT rats. Genome PCR (Fig. 1D) and DNA sequencing (Fig. 1E) confirmed that the same Fah mutation was present in the F1 rats, thereby suggesting that this mutated Fah allele is heritable.
One important concern relating to genome editing with CRISPR/Cas9 is the occurrence of potential off-target effects. We predicted the potential off-target sites of Fah sgRNAs in the rat genome based on a published software tool (Supplementary Table 1)34. The three top-ranking off-target sites for each sgRNA were cloned and sequenced. No mutations were observed at these potential off-target sites in founder #15. These results were in line with the findings of previous studies that few off-target effects were induced via embryonic injection of the CRISPR/Cas9 system32,35. To further exclude unknown off-target sites, founder #15 was backcrossed to WT rats for two generations and Fah+/− rats were then bred to homozygotes.
NTBC treatment prevents neonatal death of Fah−/− rats
The Fah+/− rats were healthy and apparently showed no defects. Serum biochemical analyses detected no liver and kidney dysfunction in the Fah+/− rats (Supplementary Fig. 2A). The Fah−/− rats were born from heterozygous Fah+/− rats following the predicted Mendelian ratio. However, none of the Fah−/− newborns survived longer than three days after birth in the absence of NTBC. Upon NTBC addition to the drinking water, the Fah−/− rats underwent normal growth and were indistinguishable from their WT littermates (Fig. 2A). Notably, the complete loss of the Fah protein in Fah−/− rats was confirmed by quantitative PCR(q-PCR) analysis, immunohistochemical staining and Western blotting of Fah (Fig. 2B–D and Supplementary Fig. 2B). The Fah−/− rats on NTBC displayed normal body weight, whereas their liver-body weight ratio was slightly increased (Supplementary Fig. 2C,D). To determine whether NTBC prevented hepatic and renal damage in Fah−/− rats, blood biochemical parameters relative to liver and kidney functions were measured in 8-week-old rats. The serum levels of albumin (ALB), alanine transaminase (ALT), aspartate aminotransferase (AST), total bilirubin (TBIL), blood urea nitrogen (BUN) and creatinine (Cr) were within the normal ranges in both Fah−/− rats on NTBC and WT control rats (Fig. 2E). These biochemical measurements were indicative of normal liver and kidney functions in Fah−/− rats on NTBC. Histological analysis also revealed that the Fah−/− rats maintained normal liver and kidney tissue architectures with NTBC treatment (Fig. 2F). We did not observe apparent sickness in Fah−/− rats after more than one year of NTBC exposure (Supplementary Fig. 3). Taken together, these findings suggest that NTBC protects Fah−/− rats from neonatal death caused by a deficiency in Fah.
Fah−/− rats develop liver failure and cirrhosis after NTBC withdrawal
We next analyzed the manifestations and visceral pathologies of HT1 in Fah−/− rats after NTBC withdrawal. Fah−/− rats were maintained with NTBC in drinking water for 8–10 weeks after birth. NTBC was then discontinued until the Fah−/− rats were moribund and sacrificed (Fig. 3A). Most of the rats (18/22, 81%) died within 4 weeks after NTBC withdrawal, whereas the rest rats (4/22) eventually died within 7 weeks after NTBC withdrawal (Fig. 3B). Compared to WT rats, Fah−/− rats failed to thrive and lost 40% of their body weight at 4 weeks after NTBC withdrawal (Fig. 3C). Elevated serum levels of tyrosine, phenylalanine and methionine caused by the defective metabolism of amino acids are commonly observed in HT1 patients36. Accordingly, the tyrosine level of moribund Fah−/− rats within 3 weeks after NTBC withdrawal was elevated 32-fold compared to that of WT rats, thereby indicating hypertyrosinemia (Fig. 3D). Elevated serum levels for the other amino acids were also observed in the Fah−/− rats after NTBC withdrawal (Fig. 3D). The liver function of these moribund Fah−/− rats was further assessed by blood biochemistry analysis. The serum levels of ALT, AST and TBIL increased to a significantly high level, whereas that of ALB decreased by 25% (Fig. 3E), thereby suggesting severe impaired liver function in these rats. No significant sex differences in NTBC-off Fah−/− rats were observed based on a comparison of survival curve and liver injury (Supplementary Fig. 4A,B). Accumulation of fumarylacetoacetate leads to profound DNA damage in livers of Fah−/− mice, thereby causing the deregulated gene expression37. Indeed, the expression levels of DNA damage response and cell cycle arrest related genes, including CHOP, p53 and p21, were dramatically increased in NTBC-off Fah−/− livers (Supplementary Fig. 4C).
In human HT1, liver injury is usually associated with diffuse necro-inflammation in the acute form and micro- and macro-nodular cirrhosis in the chronic form6. To further assess liver fibrosis and cirrhosis, we analyzed liver samples from Fah−/− rats after NTBC withdrawal (Fig. 4A). Histopathological analyses of Fah−/− livers at 1 week after NTBC withdrawal demonstrated massive necrosis associated with hepatocyte death and inflammatory cell infiltration (Fig. 4B). The extensive cell death was confirmed using TUNEL assay (Supplementary Fig. 5A). Elevated expression levels of several inflammatory cytokines were coincident with inflammatory cell infiltration (Supplementary Fig. 5B). Steatosis and bile duct hyperplasia were also observed in Fah−/− livers (Supplementary Fig. 5C,D). Immunohistochemical staining of alpha smooth muscle actin (α-SMA), a marker of activated hepatic stellate cells, showed a large number of α-SMA-positive cells in Fah−/− livers (Fig. 4C). Moreover, Sirius red staining revealed an increase in collagen deposition in the Fah−/− livers (Fig. 4D). These findings suggest that the Fah−/− rats rapidly developed liver fibrosis after NTBC withdrawal.
A small percentage of Fah−/− rats survived more than 4 weeks after NTBC withdrawal (Fig. 3B). We then assessed whether fibrosis in Fah−/− livers progressed to cirrhosis after prolonged liver injury. Livers from Fah−/− rats at 4 weeks after NTBC withdrawal showed irregular external surface with nodules showing variable sizes and shapes, which is a typical feature of cirrhotic livers (Fig. 4A). Histopathological analysis showed a disruption of the structural organization of hepatic lobules, accompanied by the formation of pseudo-lobules (Fig. 4B). Furthermore, Sirius red staining demonstrated the formation of nodules by broad fibrous septa, which were not observed in WT rat livers (Fig. 4D), thereby suggesting prominent cirrhosis as assessed by the Scheuer system38. In line with liver cirrhosis, all surviving Fah−/− rats developed ascites and Fah−/− rats showed symptoms of hepatic encephalopathy before dying, including fatigue, unresponsiveness and drowsiness. Moreover, total bilirubin levels remained high in these rats, whereas their serum albumin levels decreased (Fig. 4E). The Fah−/− rats also developed coagulopathy after NTBC withdrawal as revealed by prolonged prothrombin time (PT) and reduced fibrinogen (Fig. 4E). Taken together, the findings indicate that Fah−/− rats develop severe liver injury and fibrosis after NTBC withdrawal and those that survived longer than 4 weeks progressed to liver cirrhosis.
The kidney is another vital organ affected by HT1. Renal damage is generally variable and is mainly reflected in HT1 patients in the form of tubular dilatation, nephrocalcinosis, interstitial fibrosis and involution of epithelial cells 6. The impaired kidney functions in Fah−/− rats were indicated by elevated serum creatinine and blood urea nitrogen levels (Supplementary Fig. 6A). Histological analyses showed glomerulus inflammation, proximal tubule dilation and epithelial cell detachment from tubules (Supplementary Fig. 6B). Moreover, Sirius red staining confirmed the existence of interstitial fibrosis (Supplementary Fig. 6C). These results indicate that Fah−/− rats also develop kidney damage after NTBC withdrawal.
Hepatocyte transplantation improves liver function and survival of Fah−/− rats
Fah−/− mice have been shown as one of best recipient animal models for hepatocyte transplantation39. We next characterized whether Fah−/− rats could serve as a model for liver transplantation. NTBC administration was discontinued in 6–8-week-old Fah−/− rats after receiving intrasplenic infusion of 1 × 107 WT hepatocytes till they were sacrificed. The Fah−/− rats that did not receive transplantation of WT hepatocytes showed a 40% decrease in body weight as expected and died within 7 weeks of NTBC withdrawal (Fig. 5A,B). In contrast, WT hepatocyte transplantation significantly improved the survival of Fah−/− rats (Fig. 5A,B, 14 out of 22 rats survived). The rats transplanted with hepatocytes presented a 15% reduction in body weight during the first two weeks, but regained this later (Fig. 5C). The altered serum levels of tyrosine and other amino acids returned to their normal levels upon transplantation of WT hepatocytes (Fig. 5D). The serum ALT, AST and TBIL levels of these rats also returned to their normal levels and serum ALB levels increased, reaching levels comparable to that of WT rats (Fig. 5E).
To analyze repopulation efficiency, we harvested liver samples from Fah−/− rats at 4 and 8 weeks after transplantation. Immunohistochemical staining with a Fah antibody showed extensive liver repopulation with 70% tissue replacement in recipients at 4 weeks after transplantation (Fig. 6A). Ki67 staining showed a high proliferation index at this time point (Fig. 6B). More than 90% liver repopulation was achieved at 8 weeks (Fig. 6A). Remarkably, Ki67 staining indicated a cessation of proliferation of transplanted cells in livers with near-complete repopulation of transplanted hepatocytes (Fig. 6B). The extensive cell death was induced in Fah−/− livers after NTBC withdrawal (Supplementary Fig. 5A). 4 weeks after transplantation, cell death was reduced and only existed in recipient liver tissues but not in nodules repopulated by transplanted WT hepatocytes (Supplementary Fig. 5A). Therefore, the death of Fah−/− hepatocytes might give repopulation advantage to the transplanted cells. HE staining confirmed that Fah-positive hepatocytes were morphologically normal (Fig. 6C). Together, these findings suggest that WT hepatocytes efficiently repopulated the entire liver and restored liver function in Fah−/− rats, thereby indicating that Fah−/− rats may be utilized as a biofactory for the expansion of transplanted hepatocytes.
Progression to liver cirrhosis is prevented by hepatocyte repopulation
Because cirrhosis developed in Fah−/− rats after NTBC withdrawal (Fig. 4), we determined whether repopulation of WT hepatocytes could ameliorate progression to liver cirrhosis. Compared to Fah−/− livers without hepatocyte transplantation, WT hepatocytes that repopulated Fah−/− livers were apparently soft and did not show irregular nodules macroscopically at 4 weeks. These macroscopic changes in Fah−/− livers were more conspicuous at 8 weeks (Fig. 7A). mRNA levels of α-SMA, PDGFRβ, TIMP1, TIMP2, vimentin and desmin were significantly upregulated in the livers of Fah−/− rats at 4 weeks after NTBC withdrawal, which was apparently due to fibrogenesis (Fig. 7D). However, the expression of fibrogenic genes was dramatically reduced after WT hepatocyte transplantation (Fig. 7D). Furthermore, immunohistochemical staining of α-SMA indicated a reduction in the number of activated hepatic stellate cells in recipient livers at 4 and 8 weeks (Fig. 7B). Sirius red staining showed that collagen deposition in Fah−/− rat livers was not significantly reduced [Collagen proportional area (CPA) = 7.8 ± 0.4%] at 4 weeks after hepatocyte transplantation, compared to those without transplantation (CPA = 24 ± 11%). However, collagen deposition was remarkably resolved at 8 weeks (CPA = 1.5 ± 0.3%; Fig. 7C). Histological analysis revealed larger nodules in WT hepatocyte transplanted Fah−/− rat livers at 4 weeks (Fig. 7C). In contrast, Fah−/− rat livers that did not undergo hepatocyte transplantation mainly presented small fragmented nodular cirrhosis (Fig. 7C). The resolution of collagen resulted in near-normal liver architecture in hepatocyte-transplanted Fah−/− rat livers at 8 weeks (Fig. 7C). Taken together, WT hepatocyte repopulation reduced fibrogenic activity and progression to liver cirrhosis was largely prevented after hepatocyte transplantation in Fah−/− rats.
Finally, we analyzed whether repopulation of WT hepatocytes had any effect on kidney damage in Fah−/− rats. Serum creatinine and blood urea nitrogen levels significantly decreased (Supplementary Fig. 7A). HE staining revealed a reduction in the number of dilated proximal tubules (Supplementary Fig. 7B), indicating that kidney function improved after correction of impaired liver function. However, interstitial fibrosis was still detectable by Sirius red staining (Supplementary Fig. 7C), suggesting renal tubular damage appears to be irreversible after hepatocyte transplantation.
Discussion
Fah−/− mice and pigs are invaluable models for mimicking major manifestations of HT1. Nevertheless, both models do not develop cirrhosis, the chronic presentation of HT1. Rats have recently been a research target of interest because of advances in genetic editing technology. We used the CRISPR/Cas9 system to generate Fah knockout rats. The Fah−/− rats showed a reduction in body weight, failed to thrive, died due to progressive liver failure combined with other complications after NTBC withdrawal and recapitulated the common presentation of human HT1. The significantly elevated serum levels of ALT, AST, TBIL and other amino acids in Fah−/− rats were indicative of severe liver damage. Massive hepatocyte death was also confirmed by histological analyses. Remarkably, typical liver cirrhosis was developed as shown by macroscopic changes in the liver, histological analyses and laboratory biochemical examination. Furthermore, renal tubular damage was detected in Fah−/− rats after NTBC withdrawal.
Despite the observed similarities, Fah−/− mice, pigs and rats also have several differences. First, Fah−/− rat embryos developed to term even without NTBC administration, which is similar to Fah-deficient human and mice, whereas Fah knockout pigs are embryonic lethal12. Second, compared to Fah−/− mice and pigs, NTBC withdrawal induced higher serum levels of ALT, AST and TBIL in Fah−/− rats, thereby suggesting more severe liver injury in rats. It has been reported that transplantation of primary mouse hepatocytes to Fah−/− mice leads to a survival rate of 100%17,40. However, around 60% Fah−/− rats transplanted with WT hepatocytes survived. Interestingly, in transplantation to Fah−/− mice, the survival and repopulation of human hepatocytes and iMPC-heps are increased by cycle NTBC off and on18,22. Therefore, it would be worth testing whether cycle NTBC off and on would improve the survival of transplanted Fah−/− rats. Third, cirrhosis and bile duct hyperplasia were evident in Fah−/− rats, which were not observed in Fah−/− mice and pigs. Fourth, Fah−/− mice developed liver cancer at the age of 10 months even on a standard dose of NTBC treatment16. In contrast, liver cancers were not detected in Fah−/− rats at the age of 1 year under NTBC treatment (Supplementary Table 2).
Transplanted WT hepatocytes efficiently repopulated the livers of Fah−/− mice and restored its functions41. We confirmed this finding in Fah−/− rats. Though spontaneous correction of Fah mutations was reported in HT1 patients, it has been demonstrated that somatic reversion was not found in Fah−/− mice17. A spontaneous reversion in Fah−/− rats is unlikely, because this requires an in-frame insertion of 68 bp nucleotides in exon 2. Moreover, the present study showed that hepatocyte transplantation in Fah−/− rats during the onset of liver injury effectively prevented the progression to liver cirrhosis. Previous studies have shown that hepatocyte transplantation reduces the extent of fibrosis in moderate liver fibrosis models such as lasiocarpine-treated rats, Mdr2−/− mice and the LEC rat model of Wilson’s disease42,43,44. However, it is more challenging to transplant hepatocytes into cirrhotic livers45. In rats with decompensated cirrhosis, hepatocyte transplantation prolonged survival time but transplanted cells appeared to lose function over time46. Another study also showed that transplanted hepatocytes repopulated livers with limited efficiency and did not improve the outcomes in rats with ccl4-induced cirrhosis47. In addition, a recent study characterized the transplantation of fetal liver stem cells (FLSCs) and mature hepatocytes in TAA-induced rat cirrhotic livers48. Transplantation of both types of cells resulted in more than 20% of liver repopulation, but did not significantly reverse the existing cirrhosis. Interestingly, transplantation of mesenchymal stem cells appeared to alleviate chemically induced liver fibrosis in rodents49,50,51. Nevertheless, whether cirrhosis could be fully reverted after extensive repopulation of transplanted hepatocytes remains elusive. Because Fah−/− rats develop cirrhosis after NTBC withdrawal and permit the extensive repopulation of transplanted cells, it would be worth assessing the therapeutic efficacy of different types of cells, including hepatocytes, on liver cirrhosis in Fah−/− rats.
Extensive liver humanization has been achieved by the transplantation of human hepatocytes into immune-deficient Fah−/− mice51,52. Due to their small size, Fah−/− mice only provides a relative low number of human hepatocytes. Immune-deficient Fah−/− pigs are a desirable large animal that may be utilized as bioreactors for the large-scale production of human hepatocytes13; however, severe immune-deficient pigs are difficult to maintain53. Recently, immune-deficient rats have been generated under specific pathogen-free conditions26. Moreover, Fah−/−IL2rg−/− rats have been used to evaluate the in vivo functions of rat liver stem cells30. Fah−/−Rag2−/−IL2rg−/− (FRG) rats could be achieved by crossing Fah−/−IL2rg−/− rats with Rag2−/− rats. FRG rats may be potentially utilized as an alternative choice for the expansion of human hepatocytes. They could also be used as a model for the transplantation of liver progenitor cells and hepatocyte-like cells derived through direct differentiation or transdifferentiation54,55,56. Together, our study provides a novel rat model with the major features of HT1, including cirrhosis. Fah−/− rats may be useful not only for the study of HT1, but also for hepatocyte transplantation.
Methods
Animal
All rats were maintained in specific pathogen-free husbandry. Fah−/− rats were fed with drinking water containing 5.4 mg/L NTBC (Synthesized by Capot Chemical, China). All animal experimental protocols were approved by the Animal Care and Use Committee of Shanghai Institute of Biochemistry and Cell Biology. All animal research was carried out in accordance with the approved guidelines.
Microinjection of sgRNA and Cas9 mRNA
Rat zygotes were obtained by superovulation of female SD rats (SLAC Shanghai) mating with the males. The zygotes were cultured in KSOM embryo culture medium (Millipore) before injection. TE solution containing 12.5 ng/uL of sgRNA and ~25 ng/uL of Cas9 mRNA was injected into the cytoplasm of one-cell stage embryos through the injection needle. Injected zygotes were transferred into pseudopregnant female rats immediately after injection.
Founder identification by T7E1 mismatch sensitive assays
Tail clips were subjected to a standard DNA extraction procedure. The extracted DNA was amplified using the primers listed in Supplementary Table 3 to produce amplifications at a size of 733 bp around the target sites. After amplification was finished, the following program was carried out to generate mismatches into heteroduplexed DNA with PCR products generated from wild-type DNA: 98 °C, 5 min, 60 cycles of 98 °C, 30 sec, with auto-delta of 1 °C per cycle. The products were purified and 500 ng DNA per sample was digested with 0.3 ul of T7 endonuclease (New England Biotech) in a 10 ul reaction volume for 30 min at 45 °C. The mixture was then resolved on a 2% agrose gel.
TA cloning and sequencing
To identify the modifications in founders, PCR products from the founder were cloned using TA cloning kit (Takara) following the manufacturer’s instructions. Four colonies were picked from each transformation and then sequenced with RV-M primer.
Off-target site analysis
The off-target sites for each sgRNA were analyzed using a published prediction tool. A list of these target sites is provided in Supplementary Table 1. PCR primers were designed to flank the off-target sites as shown in Supplementary Table 3. The PCR products were directly sequenced.
Hepatocyte isolation and transplantation
6–8 weeks rat were subjected to standard two-step collagenase perfusion for isolation of primary hepatocytes. Viability of isolated hepatocytes was around 90% as determined by Trypan blue. 1 × 107 hepatocytes from WT littermates were transplanted through the spleen into Fah−/− rats. NTBC was discontinued immediately after transplantation and all through the experiment. They were sacrificed at 4 and 8 weeks after transplantation. Liver and blood samples were collected for further analyses.
Serum biochemical analysis
The rat blood was collected from the retro-orbital sinus and centrifuged at 12,000 r.p.m. for 5 min. The serum was frozen at −80 °C until biochemical analyses. Total bilirubin, albumin, ALT, AST, blood urea nitrogen and creatinine were measured by 7600-020 clinical analyser (Hitachi). Amino acids were quantified by liquid chromatographymass spectrometry ABI 3200 Q TRAP LC–MS/MS system (Applied Biosystem).
Histology and immunohistochemistry
Liver tissues were collected immediately at the time rats were sacrificed. Liver samples were fixed by paraformaldehyde and embedded in paraffin. Sections were subjected to hematoxylin and eosin (H&E), immunohistochemistry (IHC), Sirius red staining according to the standard protocols. Antibodies used for IHC staining are as follows: Rabbit anti-Fah (AbboMax, San Jose, CA, 1:3000), Rabbit anti-Ki67 (novocastra, 1:1000), Rabbit anti-α-SMA (Abcam, 1:200), Rabbit anti-Ck19 (Abcam, 1:200).
RNA extraction and quantitative PCR
Total RNA was isolated from liver samples by Trizol (Invitrogen). Quantitative PCR (qPCR) was performed with SYBR Premix Ex Taq (TaKaRa) on an ABI StepOne Plus real-time PCR system (Applied Biosystems). A list of the primers is shown in Supplementary Table 3.
Statistics
For most statistic evaluation, an unpaired Student’s t test was applied for calculating statistical probability in this study. P values were calculated by two-tailed test. For survival analysis, the Mantel-Cox log-rank test was applied. Statistic calculation was performed using GraphPad Prism5 (GraphPad).
Additional Information
How to cite this article: Zhang, L. et al. Efficient liver repopulation of transplanted hepatocyte prevents cirrhosis in a rat model of hereditary tyrosinemia type I. Sci. Rep. 6, 31460; doi: 10.1038/srep31460 (2016).
References
Lindblad, B., Lindstedt, S. & Steen, G. On the enzymic defects in hereditary tyrosinemia. Proceedings of the National Academy of Sciences of the United States of America 74, 4641–4645 (1977).
Kvittingen, E. A. Hereditary tyrosinemia type I–an overview. Scandinavian journal of clinical and laboratory investigation. Supplementum 184, 27–34 (1986).
Tanguay, R. M. et al. Different molecular basis for fumarylacetoacetate hydrolase deficiency in the two clinical forms of hereditary tyrosinemia (type I). American journal of human genetics 47, 308–316 (1990).
St-Louis, M. & Tanguay, R. M. Mutations in the fumarylacetoacetate hydrolase gene causing hereditary tyrosinemia type I: overview. Human mutation 9, 291–299, 10.1002/(SICI)1098-1004(1997)9:4<291::AID-HUMU1>3.0.CO;2-9 (1997).
Scriver, C. R. The metabolic & molecular bases of inherited disease. Vol. 4 (New York; Montreal: McGraw-Hill, 2001).
Russo, P. & O’Regan, S. Visceral pathology of hereditary tyrosinemia type I. American journal of human genetics 47, 317–324 (1990).
Lindstedt, S., Holme, E., Lock, E. A., Hjalmarson, O. & Strandvik, B. Treatment of Hereditary Tyrosinemia Type-I by Inhibition of 4-Hydroxyphenylpyruvate Dioxygenase. Lancet 340, 813–817, 10.1016/0140-6736(92)92685-9 (1992).
Masurel-Paulet, A. et al. NTBC treatment in tyrosinaemia type I: Long-term outcome in French patients. J Inherit Metab Dis 31, 81–87, 10.1007/s10545-008-0793-1 (2008).
McKiernan, P. J. Nitisinone in the treatment of hereditary tyrosinaemia type 1. Drugs 66, 743–750, 10.2165/00003495-200666060-00002 (2006).
Mohan, N. et al. Indications and outcome of liver transplantation in tyrosinaemia type 1. European journal of pediatrics 158 Suppl 2, S49–S54 (1999).
Grompe, M. et al. Loss of Fumarylacetoacetate Hydrolase Is Responsible for the Neonatal Hepatic-Dysfunction Phenotype of Lethal Albino Mice. Genes & Development 7, 2298–2307, 10.1101/Gad.7.12a.2298 (1993).
Hickey, R. D. et al. Fumarylacetoacetate hydrolase deficient pigs are a novel large animal model of metabolic liver disease. Stem cell research 13, 144–153, 10.1016/j.scr.2014.05.003 (2014).
Hickey, R. D. et al. Efficient Production of Fah-Null Heterozygote Pigs by Chimeric Adeno-Associated Virus-Mediated Gene Knockout and Somatic Cell Nuclear Transfer. Hepatology 54, 1351–1359, 10.1002/hep.24490 (2011).
Gluecksohnwaelsch, S. Genetic-Control of Morphogenetic and Biochemical Differentiation-Lethal Albino Deletions in the Mouse. Cell 16, 225–237, 10.1016/0092-8674(79)90001-1 (1979).
Aponte, J. L. et al. Point mutations in the murine fumarylacetoacetate hydrolase gene: Animal models for the human genetic disorder hereditary tyrosinemia type 1. Proceedings of the National Academy of Sciences of the United States of America 98, 641–645, 0.1073/Pnas.98.2.641 (2001).
Grompe, M. et al. Pharmacological Correction of Neonatal Lethal Hepatic-Dysfunction in a Murine Model of Hereditary Tyrosinemia Type-I. Nature genetics 10, 453–460, 10.1038/Ng0895-453 (1995).
Overturf, K. et al. Hepatocytes corrected by gene therapy are selected in vivo in a murine model of hereditary tyrosinaemia type I. Nature genetics 12, 266–273, 10.1038/Ng0396-266 (1996).
Azuma, H. et al. Robust expansion of human hepatocytes in Fah−/−/Rag2−/−/Il2rg−/− mice. Nature biotechnology 25, 903–910, 10.1038/nbt1326 (2007).
Huch, M. et al. In vitro expansion of single Lgr5 + liver stem cells induced by Wnt-driven regeneration. Nature 494, 247–250, 10.1038/nature11826 (2013).
Tarlow, B. D. et al. Bipotential adult liver progenitors are derived from chronically injured mature hepatocytes. Cell stem cell 15, 605–618, 10.1016/j.stem.2014.09.008 (2014).
Huang, P. et al. Direct reprogramming of human fibroblasts to functional and expandable hepatocytes. Cell stem cell 14, 370–384, 10.1016/j.stem.2014.01.003 (2014).
Zhu, S. Y. et al. Mouse liver repopulation with hepatocytes generated from human fibroblasts. Nature 508, 93–97, 10.1038/nature13020 (2014).
Bissig, K. D. et al. Human liver chimeric mice provide a model for hepatitis B and C virus infection and treatment. Journal of Clinical Investigation 120, 924–930, 10.1172/JCI40094 (2010).
Lagasse, E. et al. Purified hematopoietic stem cells can differentiate into hepatocytes in vivo. Nature medicine 6, 1229–1234, 10.1038/81326 (2000).
Wang, X., Al-Dhalimy, M., Lagasse, E., Finegold, M. & Grompe, M. Liver repopulation and correction of metabolic liver disease by transplanted adult mouse pancreatic cells. American Journal of Pathology 158, 571–579, 10.1016/S0002-9440(10)63999-5 (2001).
Mashimo, T. et al. Generation and Characterization of Severe Combined Immunodeficiency Rats. Cell reports 2, 685–694, 10.1016/j.celrep.2012.08.009 (2012).
Zheng, S., Geghman, K., Shenoy, S. & Li, C. Retake the center stage–new development of rat genetics. Journal of genetics and genomics = Yi chuan xue bao 39, 261–268, 10.1016/j.jgg.2012.05.003 (2012).
Popov, Y. & Schuppan, D. Targeting Liver Fibrosis: Strategies for Development and Validation of Antifibrotic Therapies. Hepatology 50, 1294–1306, 10.1002/hep.23123 (2009).
Jacob, H. J. & Kwitek, A. E. Rat genetics: Attaching physiology and pharmacology to the genome. Nat Rev Genet 3, 33–42, 10.1038/Nrg702 (2002).
Kuijk, E. W. et al. Generation and characterization of rat liver stem cell lines and their engraftment in a rat model of liver failure. Scientific reports 6, 22154, 10.1038/srep22154 (2016).
Li, W., Teng, F., Li, T. D. & Zhou, Q. Simultaneous generation and germline transmission of multiple gene mutations in rat using CRISPR-Cas systems. Nature biotechnology 31, 684–686, 10.1038/nbt.2652 (2013).
Li, D. L. et al. Heritable gene targeting in the mouse and rat using a CRISPR-Cas system. Nature biotechnology 31, 681–683, 10.1038/nbt.2661 (2013).
Shao, Y. J. et al. CRISPR/Cas-mediated genome editing in the rat via direct injection of one-cell embryos. Nature protocols 9, 2493–2512, 10.1038/nprot.2014.171 (2014).
Hsu, P. D. et al. DNA targeting specificity of RNA-guided Cas9 nucleases. Nature biotechnology 31, 827-+, 10.1038/nbt.2647 (2013).
Iyer, V. et al. Off-target mutations are rare in Cas9-modified mice. Nature methods 12, 479, 10.1038/nmeth.3408 (2015).
Scott, C. R. The genetic tyrosinemias. American journal of medical genetics. Part C, Seminars in medical genetics 142C, 121–126, 10.1002/ajmg.c.30092 (2006).
Willenbring, H. et al. Loss of p21 permits carcinogenesis from chronically damaged liver and kidney epithelial cells despite unchecked apoptosis. Cancer cell 14, 59–67, 10.1016/j.ccr.2008.05.004 (2008).
Scheuer, P. J. Classification of chronic viral hepatitis: a need for reassessment. Journal of hepatology 13, 372–374 (1991).
Grompe, M. & Strom, S. Mice with human livers. Gastroenterology 145, 1209–1214, 10.1053/j.gastro.2013.09.009 (2013).
Huang, P. Y. et al. Induction of functional hepatocyte-like cells from mouse fibroblasts by defined factors. Nature 475, 386–U142, 10.1038/nature10116 (2011).
Overturf, K. et al. Hepatocytes corrected by gene therapy are selected in vivo in a murine model of hereditary tyrosinaemia type I (vol 12, pg 266, 1996). Nature genetics 12, 458–458 (1996).
De Vree, J. M. L. et al. Correction of liver disease by hepatocyte transplantation in a mouse model of progressive familial intrahepatic cholestasis. Gastroenterology 119, 1720–1730, 10.1053/Gast.2000.20222 (2000).
Malhi, H., Irani, A. N., Volenberg, I., Schilsky, M. L. & Gupta, S. Early cell transplantation in LEC rats modeling Wilson’s disease eliminates hepatic copper with reversal of liver disease. Gastroenterology 122, 438–447, 10.1053/gast.2002.31086 (2002).
Laconi, E., Sarma, D. S. R. & Pani, P. Transplantation of Normal Hepatocytes Modulates the Development of Chronic Liver-Lesions Induced by a Pyrrolizidine Alkaloid, Lasiocarpine. Carcinogenesis 16, 139–142, 10.1093/Carcin/16.1.139 (1995).
Forbes, S. J., Gupta, S. & Dhawan, A. Cell therapy for liver disease: From liver transplantation to cell factory. Journal of hepatology 62, S157–S169 (2015).
Kobayashi, N. et al. Hepatocyte transplantation in rats with decompensated cirrhosis. Hepatology 31, 851–857, 10.1053/he.2000.5636 (2000).
Gagandeep, S. et al. Transplanted hepatocytes engraft, survive and proliferate in the liver of rats with carbon tetrachloride-induced cirrhosis. J Pathol 191, 78–85, Doi 10.1002/(Sici)1096-9896(200005)191:1<78::Aid-Path587>3.0.Co;2-P (2000).
Yovchev, M. I., Xue, Y. H., Shafritz, D. A., Locker, J. & Oertel, M. Repopulation of the Fibrotic/Cirrhotic Rat Liver by Transplanted Hepatic Stem/Progenitor Cells and Mature Hepatocytes. Hepatology 59, 284–295, 10.1002/hep.26615 (2014).
Manuelpillai, U. et al. Transplantation of Human Amnion Epithelial Cells Reduces Hepatic Fibrosis in Immunocompetent CCl4-Treated Mice. Cell transplantation 19, 1157–1168, 10.3727/096368910X504496 (2010).
Harn, H. J. et al. Adipose-Derived Stem Cells Can Abrogate Chemical-Induced Liver Fibrosis and Facilitate Recovery of Liver Function. Cell transplantation 21, 2753–2764, 10.3727/096368912X652959 (2012).
Lin, S. Z. et al. Transplantation of Human Wharton’s Jelly-Derived Stem Cells Alleviates Chemically Induced Liver Fibrosis in Rats. Cell transplantation 19, 1451–1463, 10.3727/096368910X514198 (2010).
He, Z. et al. Liver xeno-repopulation with human hepatocytes in Fah−/−Rag2−/− mice after pharmacological immunosuppression. The American journal of pathology 177, 1311–1319, 10.2353/ajpath.2010.091154 (2010).
Huang, J. et al. RAG1/2 Knockout Pigs with Severe Combined Immunodeficiency. J Immunol 193, 1496–1503, 10.4049/jimmuno1.1400915 (2014).
Ji, S. Y., Zhang, L. D. & Hui, L. J. Cell fate conversion: Direct induction of hepatocyte-like cells from fibroblasts. Journal of cellular biochemistry 114, 256–265, 10.1002/jcb.24380 (2013).
Cameron, K., Lucendo-Villarin, B., Szkolnicka, D. & Hay, D. C. Serum-Free Directed Differentiation of Human Embryonic Stem Cells to Hepatocytes. Methods in molecular biology 1250, 105–111, 10.1007/978-1-4939-2074-7_7 (2015).
Mallanna, S. K. & Duncan, S. A. Differentiation of hepatocytes from pluripotent stem cells. Current protocols in stem cell biology 26, Unit 1G 4, 10.1002/9780470151808.sc01g04s26 (2013).
Acknowledgements
We are thankful to Dr. Stephen Strom, Dr. Michael Oertel and Dr. Zhiying He for critical reading and correction of the manuscript and to Wei Kang for technical support. This study is funded by the Ministry of Science and Technology (MOST) of China (2013CB967103, 2012CB945001), the National Science Foundation of China (NSFC) (31225016, 91319307, 31401263 and 81471948), Shanghai Science and Technology Committee (14XD1404200, 14YF1406900 and 15JC1400200).
Author information
Authors and Affiliations
Contributions
L.H. conceived and supervised the project. L.Z. designed and performed most of the experiments and analyzed data. D.L., M.L. and Y.S. generated Fah−/− rats using CRISPR/Cas9. L.L., J.C. and X.C. assisted the experiments. Y.J. and F.T. performed histological analyses. Y. Zhou and D.H. performed the analyses of serum amino acid. D.L., Y.J., Y. Zheng and W.X. contributed to experimental design and manuscript preparation. L.Z. and L.H. wrote the manuscript.
Ethics declarations
Competing interests
The authors declare no competing financial interests.
Electronic supplementary material
Rights and permissions
This work is licensed under a Creative Commons Attribution 4.0 International License. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in the credit line; if the material is not included under the Creative Commons license, users will need to obtain permission from the license holder to reproduce the material. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/
About this article
Cite this article
Zhang, L., Shao, Y., Li, L. et al. Efficient liver repopulation of transplanted hepatocyte prevents cirrhosis in a rat model of hereditary tyrosinemia type I. Sci Rep 6, 31460 (2016). https://doi.org/10.1038/srep31460
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/srep31460
This article is cited by
-
Efficient engraftment and viral transduction of human hepatocytes in an FRG rat liver humanization model
Scientific Reports (2022)
-
Rat models of human diseases and related phenotypes: a systematic inventory of the causative genes
Journal of Biomedical Science (2020)
Comments
By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.