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Publications > Journals > Journal of Clinical and Translational Hepatology > Article Full Text

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Stem Cell Strategies to Evaluate Idiosyncratic Drug-induced Liver Injury

  • Winfried Krueger1,
  • Urs A. Boelsterli1 and
  • Theodore P. Rasmussen*,1,2,3
 Author information  Cite
Journal of Clinical and Translational Hepatology   2014;2(3):143-152

doi: 10.14218/JCTH.2014.00012

Abstract

The host-dependent nature of idiosyncratic drug-induced liver injury (iDILI) suggests that rare genetic polymorphisms may contribute to the disease. Indeed, a few mutations in key genes have already been identified using conventional human genetics approaches. Over 50 commonly used drugs can precipitate iDILI, making this a substantial medical problem. Only recently have human induced pluripotent stem cells been used as a research tool to discover novel iDILI genes and to study the mechanisms of iDILI in vitro. Here we review the current state of stem cell use in the investigation of iDILI, with a special focus on genetics. In addition, the concerns and difficulties associated with genetics and animal model research are discussed. We then present the features of patient-specific pluripotent stem cells (which may be derived from iDILI patients themselves), and explain why these cells may be of great utility. A variety of recent approaches to produce hepatocyte-like cells from pluripotent cells and the associated advantages and limitations of such cells are discussed. Future directions for the use of stem cell science to investigate iDILI include novel ways to identify new iDILI genes, a consideration of epigenetic impacts on iDILI, and the development of new and improved strategies for the production of hepatocytes from human pluripotent cells.

Keywords

DILI, Embryonic stem cell, iPS, Toxicity, Genetics

Introduction

Idiosyncratic drug-induced liver injury (iDILI) is a complex disorder that is typified by the onset of severe (even fatal) liver damage after exposure to drugs that are otherwise well tolerated in the human patient population. The host-dependent (idiosyncratic) nature of iDILI suggests that genetic polymorphisms that cause a predisposition to DILI events likely exist in the population. In these cases, iDILI occurs only when an individual with a predisposing genotype is exposed to the precipitating drug. Put another way, iDILI is a type of drug-genotype interaction, and most individuals with a potential underlying iDILI genotype will never know of their underlying genetic susceptibility because they will fail to encounter the interacting drug.

At present, the only way to “find” an iDILI genotype is for an individual with a predisposing genotype to be treated (unintentionally) with an iDIL-precipitating drug. Current medical practice dictates that all patients are assumed to be normal, and they are treated routinely with potentially DILI-causing drugs. Importantly, these patients are monitored for the onset of liver damage only after the onset of drug treatment, usually by monitoring levels of liver enzymes, such as ALT and others in the blood. Currently, there is no effective way to detect potential iDILI responders prior to drug treatment. As more iDILI polymorphisms in the genome become known, it may be possible to devise genetic tests that identify at-risk individuals. Such a goal will require the comprehensive identification of iDILI risk alleles for each of the 50 or more highly problematic drugs, and an expedient way to gather this genetic information is needed. One way that such information could be gathered is via genome-wide association studies (GWAS). However, about 50 commonly used drugs can cause iDILI, often by completely independent mechanisms, and it is likely that 50 complete GWAS studies would be required. Although GWAS, a recently developed and powerful approach, would work in theory, practicalities of scale and relatively low numbers of iDILI patients for specific drugs prohibit the widespread use of GWAS to comprehensively identify iDILI genes and polymorphisms.

Recently, an entirely different and new approach uses human induced pluripotent stem cells (hiPSCs) that are exact genetic matches to iDILI patients (Fig. 1). These are obtained by a cellular reprogramming approach that takes relatively non-invasive biopsies (either blood or a small skin sample) and reprograms them to an early developmental state that is functionally equivalent to embryonic stem cells. This is achieved by expressing key embryonic transcription factors that induce the state of pluripotency (i.e. the potential to differentiate into any desired cell type, including hepatocytes, present in the adult body). To do this, a patient who has suffered iDILI donates blood or skin that can be derived into hiPSCs and then hepatocytes. These induced hepatocyte-like cells (iHLCs) are subjected to functional toxicity studies, and more importantly, iDILI-causing mutations can be identified in such cells using strategies that are described below. Therefore, it may be possible to identify the majority of iDIL-predisposing genes using at most a few hundred patients rather than several hundred thousand, as would be required for GWAS. In addition, disease mechanisms can never be addressed with GWAS, but iHLCs can be easily studied in vitro, thus providing insight into cellular and molecular mechanisms that govern iDILI.

Strategy for using iPS reprogramming to investigate iDILI.
Fig. 1  Strategy for using iPS reprogramming to investigate iDILI.

Somatic cell samples such as skin or blood are collected from iDILI and control patients. These are used to derive hiPSCs that are exact genetic matches to the donor patients. Such hiPSCs can be indefinitely expanded and passaged, so long as they are maintained under pluripotent conditions. hiPSCs can then be differentiated to iHLCs (hepatocyte-like cells). iHLCs from iDILI and control patients can then be compared using functional tests (A., such as exposure to the iDILI-precipitating drug) or using transcriptome comparisons (B.), which may lead to identification of iDILI genes. Subsequently, causative mutations (C.) can be identified, using transcriptome alterations as a guide.

Drug-induced liver injury

Idiosyncratic drug-induced liver injury

iDILI is a rare form of iatrogenic liver injury that manifests itself as a wide spectrum of symptoms, ranging from mild and transient increases in plasma markers of hepatocellular injury to more severe forms that present with abdominal symptoms, cholestasis, and, in rare cases, the development of liver necrosis and fulminant hepatic failure. Despite its relatively low frequency (for individual drugs ranging from 1:100,000, e.g., for amoxicillin/clavulanic acid, to 1:100, e.g., for isoniazid),1 iDILI has become a major clinical concern for a number of reasons. First, an increasing number of drugs (>600), belonging to a variety of therapeutic classes, have been implicated in iDILI, with approximately 50 drugs featuring a strong causality. Therefore, the absolute number of all iDILI cases has become impressive when iDILI cases from over 600 drugs are considered in aggregate. Second, the occurrence of iDILI is unpredictable, both for a new drug on the market and for an individual patient. Third, iDILI has been associated with high morbidity and mortality, particularly when combined with jaundice, that can lead to acute liver failure and the need for liver transplants in the most severe cases.2 Finally, iDILI is one of the major reasons for the withdrawal of successfully launched drugs from the market, which may result in the loss of an otherwise important drug.3 Numerous reviews have addressed causality criteria, clinical hallmarks, underreported incidence, potential mechanisms, and prediction of iDILI.2,4–12

Determinants of susceptibility to iDILI

By definition, iDILI is “idiosyncratic”, i.e., dependent on the specific characteristics of the recipient (patient). Thus, besides the toxicodynamic properties of the drug itself (chemotype) and its potential to cause toxicity to hepatocytes by a number of mechanisms, host-specific factors also greatly contribute to the precipitation of toxicity (Fig. 2). There are two major types of host-specific factors: acquired/environmental factors and genotype. Regarding acquired/environmental factors, the underlying disease (indication) against which the patient is being treated,13 underlying infections, and episodes of inflammatory reactions14 can influence the risk. Coadministration with other potentially hepatotoxic drugs or alcohol is another important factor. Taken together, acquired/environmental and genetic determinants of susceptibility to iDILI are responsible for increasing the penetrance and for modulating the expressivity of drug toxicity.10 For these reasons, it is understandable that, despite many attempts with limited success, it is extremely difficult to develop an animal model for iDILI, using, e.g., inbred, virtually genetically identical mice, that are expected to recapitulate the clinical situation in individual patients.

Determinants of susceptibility to drug-induced liver injury (DILI).
Fig. 2  Determinants of susceptibility to drug-induced liver injury (DILI).

A number of patient-specific (idiosyncratic) factors greatly modulate the sensitivity to the potential hepatotoxic effects of certain drugs.

Role of the genotype

Mutations and/or rare single nucleotide polymorphisms (SNPs) in critical genes have been implicated in modulating the risk for iDILI.15,16 These specific haplotypes or mutations could be responsible for modulating the degree of toxicity at different levels. For example, they could enhance the pro-toxicant pathways in the liver, they could interfere with mechanisms involved in adaptation to the insult or impair defense mechanisms, or they could weaken immune tolerance. While traditional studies have focused on polymorphisms in cytochrome P450 forms that modulate metabolic bioactivation/hepatic clearance of drugs, more recent approaches have addressed the role of genetic variation in genes involved in the adaptive immune system, in detoxification pathways, or in mitochondrial function. For example, the human leukocyte antigen (HLA)-B*5701 haplotype of the major histocompatibility complex (MHC) has been associated with a >80-fold higher risk for developing liver injury from flucloxacillin treatment than individuals with other MHC haplotypes.17 Similarly, carriers of the HLA-A*3303 haplotype have a 36-fold higher risk for iDILI from ticlopidine treatment than other patients.18 These risk factors are statistically robust and point to a key role of these genes in the susceptibility to liver injury. Another example consists of mutations in certain forms of glutathione-S-transferase (GST), which have been implicated in the conjugation of reactive intermediates of many drugs including isoniazid or troglitazone. Phenotypes from null mutations are also quite frequent; specifically, homozygous null mutations encoding the GSTT1 form and the GSTM1 form of GST are present in 50% and 10–25% of Caucasians, respectively. In a study involving 154 patients with a diagnosis of iDILI, 18.2% of patients had the GSTT1/GSTM1 double-null genotype, while only 7.6% of control patients carried this genotype.19 Finally, other studies have analyzed the role of polymorphisms in the mitochondrial polymerase γ (POLG) gene that is involved in mtDNA replication. It was found that the risk for valproic acid-induced DILI was >20-fold increased in individuals carrying the pQ1236H and pE1143G mutations in the POLG gene as compared to wild-type.20

One important point is that these polymorphic risk alleles are quite common in the general population, which raises the question why iDILI is not more common. Most likely, these haplotypes become dangerous only in specific contexts, e.g., exposure to a particular drug. Furthermore, these analyses showed, at best, only a strong correlation with iDILI episodes, and there must undoubtedly be other risk factors. While the identification of such “risky” mutations does not necessarily explain the underlying mechanism of toxicity, it can be used to identify certain individuals or patient subsets who are predisposed to higher risk of iDILI. For the vast majority of drugs, however, the genetic determinants of susceptibility are not known. More recent approaches to establish a link between iDILI and underlying genetic risk factors have aimed at identifying entire functional pathways rather than single genes.

Lessons from current models and the need for novel patient-specific models

Currently there are no fully validated animal models that recapitulate the clinical features of iDILI. It makes sense that normal healthy inbred animals cannot model a disease that is driven by a variety of underlying patient-specific genotypes.21 While certain environmental factors can be modeled in vitro or in vivo, genetic variations are more difficult to adapt in animal models because in most cases, the most relevant “risk genes” are not known. For example, the lipopolysaccharide (LPS) rat or mouse model22 can mimic the underlying presence of sporadic inflammatory episodes, and the heterozygous Sod2 mouse model23 can emulate increased mitochondrial oxidant stress as it occurs with certain forms of underlying mitochondrial disease. However, applications useful for wide-scale screening platforms have not been possible to date. Hepatic cells can be harvested and cultured from patients who had developed iDILI from a particular drug and compared with cells from unaffected patients. At present, however, it is extremely difficult to obtain viable liver tissue from such patients, and primary hepatocytes cannot be easily cultured for extended periods of time. One promising approach is the use and study of stem cells derived from both diseased and healthy patients.

Stem cell approaches

Pluripotent cells and induced pluripotent stem cells

Pluripotent cells can in theory give rise to any cell type present in the adult mammalian body plan. The first widely-used pluripotent stem cells were mouse embryonic stem cells (mESCs).24,25 These cells were derived from day 3.5 preimplantation embryos at the blastocyst stage. At this stage of development, there are only a small set of cell types in the embryo. These include trophectoderm cells, which are destined to form the embryonic portion of the placenta, and the inner cell mass (ICM), which subsequently gives rise to all the cells of the embryo proper, and eventually, the adult mouse. It is the ICM cells that can be explanted and used to derive mESCs. Although the ICM exists in the embryo for only a few hours at most, mESCs can be cultured indefinitely in vitro, under conditions that maintain their pluripotency.26 Leukemia inhibitory factor (LIF) is a key cell signaling factor necessary for the maintenance of mESCs in a state of protracted pluripotency.27,28 The LIF receptor signals via Stat3 to the nucleus where key pluripotency transcription factors, including octamer-binding transcription factor 4 (Oct4), sry-related HMG box 2 (Sox2), and Nanog, collude to regulate a large set of genes, whose expression has been aptly described as a pluripotency network.29–32 Human ESCs (hESCs) were first derived from human blastocysts that would otherwise have been discarded from human fertility clinics.33 Unlike mESCs, hESCs depend upon the fibroblast growth factor 2 (FGF2) for maintenance of pluripotency,34 but like mESCs, hESCs contain a pluripotency transcriptional network that is mediated by the master transcription factors OCT4, SOX2, and NANOG. Collectively mESCs and hESCs have been used to model many developmental processes in vitro via directed differentiation experiments. Several dozens of differentiated cell types have been produced in this way, and they have been derived from all three of the principle germ layers, ectoderm, endoderm, and mesoderm. In many cases, these differentiated cells are rather similar to cells from primary organ culture as they become post-mitotic and exhibit gene and protein expression patterns similar to analogous cells in vivo. Such differentiated cells derived from pluripotent cells are far more similar to endogenous cells than traditional immortalized cell lines, which are transformed and usually without a normal complement of chromosomes.

The first example of reprogramming a differentiated vertebrate cell to an early embryonic state was achieved with Xenopus frogs, which were successfully cloned in the early 1960s from intestinal epithelial cells transferred into frog oocytes.35,36 The first time differentiated mammalian cells were successfully reprogrammed was over 40 years later with the advent of Dolly the Sheep.37 In this case, the resulting reprogrammed totipotent cell, achieved by nuclear transfer into an enucleated recipient sheep oocyte, was a one cell embryo that was cultured briefly in vitro to the blastocyst stage and then implanted in a surrogate pseudopregnant female to yield the live-born cloned sheep named Dolly. These successes with animal cloning showed that terminally differentiated vertebrate cells could be reversed to a state of pluripotency, albeit with reprogramming activities only found in the oocyte. In 2006, Shinya Yamanaka succeeded in directly reprogramming cultured adult cells to a state of pluripotency by introducing a set of genes encoding key transcription factors (Oct4, Sox2, kruppel-like factor 4 (Klf4), and proto-oncogene myc (c-Myc)) into mouse fibroblasts using retroviruses.38 The resulting pluripotent cells were deemed induced pluripotent stem cells (iPSCs). After initial viral transduction, the somatic cells were shifted to mESC culture conditions. The mechanism of iPS reprogramming depends upon the forced expression of a defined set of transcription factors, which includes members of the master regulatory transcription factors of the pluripotency network. IPSCs are remarkably similar to ESCs, and most importantly, exhibit a full range of pluripotency. Soon after this achievement, human iPSCs (hiPSCs) were developed.38,39 These, like their mouse counterparts, exhibited nearly complete resemblance to their hESC equivalents. It is crucial to point out that hiPSCs contain exactly the same genetic composition as the human fibroblast donor, thus opening the door to their use as a stem cell platform for personalized medicine. Early mouse iPS cells (miPSC) and hiPSC cell lines were made with integrating retroviruses and lentiviruses, and thus had subtly altered genomes. Since then it has become possible to make iPS cell lines that avoid the use of integrating retrovirus or lentivirus, including the use of messenger RNA encoding the reprogramming factors,40 transposon systems that excise with barely a trace,41,42 and episomes that transiently (but efficiently) express reprogramming factors prior to episomal loss by cell division.43 All of these strategies leave the genome nearly or completely untouched by the iPS reprogramming process.

Disease in a dish: Differentiation of iPS cells to hepatocytes

Most strategies to produce hepatocytes from hESCs or hiPSCs attempt to recapitulate liver development in vivo. In addition, strategies to differentiate hESCs and hiPSCs to human hepatocyte-like cells (hereafter termed “iHLCs” if derived from hiPSCs) have been greatly informed by similar (and earlier) successes with mESCs. Because liver is an endoderm-derived organ, all strategies for production of iHLCs begin with a preculture of hiPSCs. In one set of strategies, hiPSCs are shifted from hiPSC culture medium to an endoderm induction medium containing the signaling factor Activin A with insulin, transferrin, and selenium in trace concentration.44,45 Activin A is a potent inducer of endoderm and rapidly leads to cellular expression of the early endoderm marker SOX17. Cells are then shifted to a medium containing FGF2 and bone morphogenic protein 4 (BMP4), both of which are known to play a role in liver organogenesis in vivo.46–48 These cells are then shifted to a medium containing hepatocyte growth factor (HGF), and then finally to a medium containing oncostatin M and dexamethasone. This typical four stage approach yields hepatocyte-like cells that express both albumin (ALB) and α-fetoprotein (AFP), indicating that these iHLCs are similar to hepatocytes of late embryonic or perinatal origin.44 This same protocol yielded hepatocytes that can also secrete cholesterol and respond to statins, as normal hepatocytes should.44 Human ES and iPS cells seem to form hepatocytes with similar efficiency.49 Fully mature iHLCs are quite difficult to produce with entirely in vitro approaches, but subsequent transplantation into immunocompromised mouse liver seems to affect final stages of maturation.50

Similarly, in one seminal study using analogous approaches to that described above, produced hepatocyte-like cells that expressed a spectrum of mature hepatocyte markers with residual AFP expression.45 Alternate designs for the cell culture have also been tested. For example, one approach yielded cells with at least some level of CYP3A4 expression, the ability to take up indocyanine green, and store glycogen.51 In a different strategy, a cDNA encoding the hepatocyte-specific nuclear receptor/transcription factor HNF4α was ectopically expressed in hiPSCs that were otherwise induced to form hepatocyte-like cells.26 These cells exhibited increased cytochrome P450 (CYP) expression, a finding that is consistent with the fact that many CYP genes contain HNF4α response elements near their promoters. Finally, direct reprogramming of fibroblasts to induced hepatocyte-like cells (iHLC) has been achieved by induced transdifferentiation, in most cases using mouse tail tip fibroblasts as a starting material.52–54

Limitations of stem cell models

iHLCs are a tool not only for the discovery of new iDILI genes but also for the elucidation of the cellular and molecular mechanisms of iDILI. However, iHLCs are not without potential problems. First and foremost, it has been exceedingly difficult to produce iHLCs that completely exhibit normal hepatocellular function. Most notably, iHLCs do not exhibit an adult-like range of CYP expression. Improvements in the maturation of iHLCs will be needed in order to fully realize their potential. Another difficulty (though soluble) is rooted in human genetic variation. Hypothetically, one might reprogram somatic cells from three iDILI patients and three control patients and then compare the two sets of iHLCs. Although the iDILI patients may contain polymorphisms relevant to iDILI, there exists a very large amount of extraneous genetic variation between the two groups. Thus, the confounding factor of genetic background may dilute iDILI phenotypes in vitro. A new tool that partially addresses this problem involves the use of new site-specific recombinase systems such as clustered regularly interspaced short palindromic repeats (CRISPR) or transcription activator-like effector nucleases (TALENS) to correct putative SNPs or other polymorphisms suspected of causing iDILI, thus yielding an isogenic pair of cell lines. This is discussed further below.

Finally, a major limitation of stem cell models should be recognized. Any cells derived from stem cells, even sophisticated co-culture models, cannot fully recapitulate the situation in vivo. For instance, it is likely that immune reactions are important for some (though probably not all) cases of iDILI. It is currently not feasible to combine iHLCs with reconstituted immune systems in vitro. Placing iHLCs into mice is also not a reasonable option to assess the contribution of immune functions since the mouse immune system differs in fundamental ways from the human immune system.

In the future, improvements will need to occur if stem cell approaches are to more faithfully model iDILI. Perhaps the area most in need of improvement is the differentiation of stem cells into fully functional hepatocytes that express a normal range of CYP genes.55 Progress is being made in this area through the use of three-dimensional differentiation methods that more closely model cellular positions within organs. Furthermore, new approaches that yield “organoids” (small three-dimensional multicellular structures with organized cells) may lead to better expression of CYP genes.56

Current applications and future directions

iDILI is a disorder that can arise from mutations in at least several key genes, and it likely involves multiple cell types, including hepatocytes and immune cells. It is also possible (though little investigated) that epigenetic alterations in the hepatocyte may lead to changes in gene expression and contribution to the onset of iDILI. The advent of iHLCs constitutes a novel step toward identifying genetic and epigenetic mechanisms leading to predisposition to iDILI and mechanisms involved in the acute phase of iDILI. A number of useful attributes of these cells make them useful for toxicological applications. Foremost, iHLCs are genetically identical to the donor subject who donated somatic cells to produce hiPSCs. In addition, the iPS reprogramming process erases epigenetic modifications that accumulate in primary cells in response to life exposure to toxicants.57–60 Finally, iPSCs and iHLCs, can be produced in unlimited quantities, whereas primary hepatocytes cannot be readily expanded. Hence, the need for repeated liver biopsies from single donors, necessary for conventional experimentation, can be avoided. 61–65

Identification and study of genetic variants causing iDILI

An obvious way to use iPS strategies to investigate iDILI is to collect somatic cell samples (such as skin or nucleated blood cells) and subject them to iPS-mediated reprogramming. The use of iPSCs to investigate iDILI is only now coming to fruition, but here is a reasonable workflow: Cells from at least several subjects who have suffered from iDILI and normal subjects are reprogrammed to yield a set of wild-type and affected (iDILI) iPSCs. Since episodes of DILI affect the liver by definition, it is quite possible that liver biopsies from subjects who have survived (or succumbed) to DILI might be abnormal in terms of their mutational load, gene expression, or even epigenetic content. Since iPSCs are derived from non-liver tissues, these cells are less likely to have undergone drug-induced mutations or other alterations. Sets of iHLCs derived from multiple normal and iDILI patients can then be prepared and investigated to identify changes in gene expression pathways that are potentially involved in iDILI. The iPS approach can yield cells that can be useful to actually test specific mutations in putative iDILI genes such as GSTT1, GSTM1, POLG, and others, as described above.

A notable advantage of the iHLC-based iDILI cell culture model stems from the ability to rescue causative mutations through genome editing.66,67 Using TALENs 68,69 or CRISPR70 homologous recombination genome editing strategies, putative iDILI associated mutations can be repaired in iPSCs. The resulting cells are isogenic with respect to the unedited iPSC cells except for the mutation site. Subsequent differentiation of the repaired and unrepaired iPSCs (which can differ by only a single SNP of interest) to iHLCs yields a powerful pair of experiment and control cell cultures, which may then be interrogated for their response to iDILI-causing drugs. In analogous fashion, using the same recombinase strategies, iDILI associated mutations can also be introduced into the genome of wild-type iPSCs to yield an equivalent pair of wild type and mutant cell lines that are isogenic except for the mutation under investigation. In addition to drug assays, transcriptome and epigenome analyses can be utilized in such paired cell culture approaches to learn more about the role of specific iDILI-promoting mutations and the genes that host such mutations.

Assessment of the contribution of epigenetic regulation to iDILI

Exposure to iDILI-causing drugs may lead to the onset of iDILI in response to epigenetic alterations in hepatocytes. Such alterations could, in theory, be a direct result of exposure to the drug. Alternatively, epigenetic changes might occur over time due to indirect (but consequential) responses71–73 that result in some patients in the deregulation of the expression of proteins that are protective for iDILI. Such genes may be epigenetically silenced more permanently through trimethylation of lysine 27 of histone 3 and methylation of cytosine residues in CpG dinucleotides in gene regulatory regions.74 Similar to perturbed histone acetylation homeostasis in cancer,75 further histone deacetylation may then compact the associated chromatin domains and render the respective genes difficult to transcribe upon exposure to subsequent treatment with an iDILI causing drug. It is likely that candidate genes include not only those encoding proteins but also microRNAs that are protective for iDILI. Certain haplotypes may favor the acquisition of epigenetic marks leading to silencing of iDILI protective genes, adding an additional genetic component that may only be identifiable through whole genome sequencing. In addition, insertion/deletions (indels) and copy number variation for iDILI protective genes may also have a role in the pathogenesis of iDILI by affecting transcription levels and dosage of iDILI protective genes. At present, little is known about an epigenetic influence on iDILI and future research will need to address this issue.

Transcriptome profiling provides a readout that integrates both epigenetic and genetic contributions to gene regulation.76,77 During diagnosis of iDILI in the clinic, it is commonplace to collect a small number of liver cells by needle biopsy.78 From these, it is possible to isolate hepatocytes by laser capture or magnetic bead purification approaches. RNA can be extracted from the iDILI patient hepatocytes and iHLCs are derived from the same individual. Since iPS reprogramming erases only epigenetic information, differences in transcriptome profiles between the patient hepatocytes and iHLCs could be due to either iDILI-caused epigenetic changes in the patient hepatocytes, or incomplete accumulation of proper epigenetic chromatin modification patterns due to infidelities that arise during iHLC differentiation. Future research will be needed to determine if iDILI epigenetic changes can be detected by such strategies. However, such experiments may provide candidate genomic targets for further evaluation using targeted chromatin-immunoprecipitation (ChIP). The alternate approach using ChIP-Seq instead of ChIP based comparisons may currently be quite challenging due to the limited availability of primary cells. In addition, iHLCs are exquisitely well suited for “omics” approaches since their nearly unlimited numbers allow for sufficient transcriptional profiling experiments to achieve a level of experimental replication that is sufficient for the minimization of type one and type two errors.79 Such replication cannot easily be carried out with primary cells. Certain limitations, however, are inherent to this approach. For instance, cell type heterogeneity among collected biopsies confounds the interpretation of large datasets. Laser-capture microscopy based approaches may provide a viable alternative to mixed cell populations normally retrieved via biopsies. However, the limitations in the sample amounts inherent to this technology require amplification based strategies for expression profiling that can introduce a bias sufficient to obscure the contribution of low abundance transcripts to the pathogenesis of iDILI.80–82 Magnetic bead capture of hepatocytes may supply a better alternative as cells could be collected en masse. Alternatively, hepatocytes could be expanded from the initial biopsy but primary hepatocytes have only a limited life span in culture, are difficult to expand, and suffer from drifting gene expression that again can introduce bias sufficient to prohibit the identification of transcripts relevant to iDILI. Clearly, iHLC based transcription surveys, though currently not free from drawbacks, are less prone to these limitations.

Possible xenobiotic-induced predisposition to iDILI

It is possible that prior or concomitant exposure to drugs, other xenobiotics, or even high levels of endogenous metabolites might predispose the onset of iDILI upon treatment with iDILI-causing drugs. Little is known, however, about chemical sensitization to iDILI, so this idea must be considered a working hypothesis. Conventional medical studies typically do not control for prior exposure to compounds that might induce a predisposition to iDILI. Likewise, cell culture models using cell lines such as HepG283 or HepaRG84 are limited since these cell lines cannot capture genotype-based predispositions to the disease. In contrast, iHLCs provide an excellent option to study how prior treatment with predisposing compounds can make cells susceptible to iDILI, since these cells are derived from patients that have already been known to have developed iDILI. For instance, two-staged high throughput screens can be developed where iDILI-iHLCs are treated first with a compound known to elevate oxidative stress in liver cells without causing a disease phenotype. Subsequently, either in the presence or absence of the predisposing compound, the iDILI-inducing drug can be administered and toxicity can be monitored by assays for increased cell death, reduced energy metabolism, or induction of proinflammatory cytokine expression.

Certain types of toxicity, e.g., functional hepatic changes, are difficult to assess in cell culture models. For example, cholestasis, which is a frequent hallmark of DILI, has only recently been modeled in vitro.85,86 Such functional assays have not yet been applied to or validated for iHLCs. Because polymorphisms and rare variants in bile salt transporters have been implicated in the development of drug-induced cholestasis, a genetic analysis of ABCB11 (BSEP), ABCC2 (MRP2), and other genes encoding for canalicular transporters could be analyzed.

Another possibility for xenobiotic-induced predisposition to iDILI is immunological in nature. Since major histocompatibility complex (MHC) genes have already been implicated in iDILI, it follows that dysregulation of the immune system is one route to the onset of iDILI. It may be that iDILI has much in common with an allergic response, where the immune system is first sensitized to a cellular antigen, perhaps by an initial exposure to a DILI drug or a chemically-similar compound. This initial exposure could induce the formation of self-directed (hepatocyte-directed) immune cells, which then become activated and amplified upon later exposure to the iDILI-causing drug. Of note, iHLC approaches can readily be used to study cell-autonomous mechanisms of chemical sensitization but not immunological sensitization mechanisms.

Future goals and directions with iHLC cell culture systems

In order to fully leverage the power of the iHLCs as a cell culture model for iDILI, iHLCs must be produced that more accurately resemble the hepatocytes in vivo. In all current differentiation protocols, iHLCs exhibit a phenotype resembling that of late embryonic or early postnatal primary hepatocytes.87 For instance, current state-of-the-art iHLCs express high levels of α-fetoprotein (AFP) and CYP3A7,44,45,88–90 both markers for embryonic hepatocytes.91,92 Consistent with fairly robust AFP expression, ALB, a marker for adult primary hepatocytes, is expressed at significantly lower levels. Similarly, current iHLCs express low CYP3A4 and CYP2E1.44,45,88–90 It therefore appears that, despite demonstrating other typical liver cellular activities such as indocyanin green uptake, urea production, glycogen storage, LDL uptake,93 and cholesterol secretion,44 current iHLCs may express only low levels of drug metabolizing enzymes that have a key role in the pathogenesis in iDILI. The low expression level of CYPs in particular may lead to a significantly attenuated iDILI phenotype in vitro. Future characterization of iHLCs may require the use of global transcriptome comparisons between fresh primary hepatocytes, but this in itself may not guide the design of improved methods to differentiate detoxification-competent iHLCs from pluripotent cells.

A related technical problem is that primary hepatocytes can be maintained in culture for only a short time, prior to loss of detoxification activities typical of the hepatocyte in vivo. For instance, cultured primary hepatocytes rapidly downregulate many CYPs, including CYP3A4, to nearly undetectable levels.94,95 It is possible that cell culture effects lead to transcriptional deregulation of genes essential for the pathogenesis of iDILI. Although significant improvements in primary hepatocyte culture have been made over the last few years64,96,97 permitting the maintenance of some key hepatocyte enzyme expression for up to several weeks, the length of the drug treatment required for eliciting an iDILI response in culture is unknown and drug dependent. Perhaps of even greater concern is that hepatocytes obtained from iDILI patients by needle biopsy may be abnormal after an episode of iDILI, and thus not suitable for experiments designed to uncover the mechanisms whereby naïve hepatocytes are degraded due to a DILI event.

Based on the above, it is clear that there is much room for improvement in the methodologies leading to the production of iHLCs from human pluripotent cells. Three major strategies to improve iHLCs are described here:

Conclusions

In this review article, we have discussed existing knowledge about iDILI, stem cell approaches to find iDILI genes and to study iDILI mechanisms, and also provided a discussion of current applications and future directions for this field of research. Conventional human genetic approaches are unlikely to yield a comprehensive set of iDILI-associated polymorphisms. New approaches using pluripotent stem cells (especially hiPSCs) promise to provide an expedient way to find new iDILI mutations and to offer a way to study iDILI mechanisms in vitro. Finally, future uses of hiPSCs from iDILI patients were discussed, including the use of iHLCs to study epigenetic contributions to iDILI, and xenobiotic-induced sensitivity for iDILI.

Abbreviations

AFP: 

α-fetoprotein

albumin: 

ALB

BMP4: 

bone morphogenic protein 4

ChIP: 

chromatin-immunoprecipitation

CRISPR: 

clustered regularly interspaced short palindromic repeats

c-Myc: 

proto-oncogene myc

CYP: 

cytochrome P450

FGF2: 

fibroblast growth factor 2

GWAS: 

genome-wide association study

GST: 

glutathione-S-transferase

hESC: 

human embryonic stem cell

HGF: 

hepatocyte growth factor

hiPSC: 

human induced pluripotent stem cell

HLA: 

human leukocyte antigen

HNF4α: 

hepatocyte-specific nuclear receptor/transcription factor α

ICM: 

inner cell mass

iDILI: 

idiosyncratic drug-induced liver injury

iHLC: 

induced hepatocyte-like cell

Indels: 

insertion/deletions

iPSCs: 

induced pluripotent stem cells

Klf4: 

kruppel-like factor

LEM: 

liver extracellular matrix

LIF: 

leukemia inhibitory factor

LPS: 

lipopolysaccharide

mESCs: 

mouse embryonic stem cells

MHC: 

major histocompatibility complex

Oct4: 

octamer-binding transcription 4

POLG

mitochondrial polymerase γ

SHH: 

sonic hedgehog

SNP: 

single nucleotide polymorphisms

Sox2: 

sry-related HMG box 2

TALENS: 

transcription activator-like effector nucleases

Declarations

Acknowledgement

This review article was supported by Connecticut Stem Cell Research Grant 11SCDIS02.

Conflict of interest

None

Authors’ contributions

Writing the review (WK, UAB, TPR).

References

  1. Bell LN, Chalasani N. Epidemiology of idiosyncratic drug-induced liver injury. Semin Liver Dis 2009;29:337-347 View Article
  2. Navarro VJ, Senior JR. Drug-related hepatotoxicity. New Engl J Med 2006;354:731-739 View Article
  3. Sakatis MZ, Reese MJ, Harrell AW, Taylor MA, Baines IA, Chen L. Preclinical strategy to reduce clinical hepatotoxicity using in vitro bioactivation data for >200 compounds. Chem Res Toxicol 2012;25:2067-2082 View Article
  4. Kaplowitz N. Idiosyncratic drug hepatotoxicity. Nature Rev Drug Discov 2005;4:489-499 View Article
  5. Watkins P. Idiosyncratic liver injury: Challenges and approaches. Toxicol Pathol 2005;33:1-5 View Article
  6. Holt MP, Ju C. Mechanisms of drug-induced liver injury. AAPS J 2006;8:E48-54 View Article
  7. Liguori MJ, Waring J F. Investigations toward enhanced understanding of hepatic idiosyncratic drug reactions. Expert Opin Drug Metab Toxicol 2006;2:835-846 View Article
  8. Bleibel W, Kim S, D'Silva K, Lemmer ER. Drug-induced liver injury. Dig Dis Sci 2007;52:2463-2471 View Article
  9. Hussaini SH, Farrington EA. Idiosyncratic drug-induced liver injury: an overview. Expert Opin Drug Saf 2007;6:673-684 View Article
  10. Boelsterli UA, Kashimshetty R. Comprehensive Toxicology. Elsevier; 2010, 383-402 View Article
  11. Bjornsson ES, Bergmann OM, Bjornsson HK, Kvaran RB, Olafsson S. Incidence, presentation, and outcomes in patients with drug-induced liver injury in the general population of Iceland. Gastroenterology 2013;144:1419-1425 View Article
  12. Yuan L, Kaplowitz N. Mechanisms of drug-induced liver injury. Clin Liver Dis 2013;17:507-518 View Article
  13. Boelsterli UA. Disease-related determinants of susceptibility in drug-induced hepatotoxicity. Curr Opin Drug Disc Develop 2013;6:81-91
  14. Deng X, Luyendyk JP, Ganey PE, Roth RA. Inflammatory stress and idiosyncratic hepatotoxicity: Hints from animal models. Pharmacol Rev 2009;61:262-282 View Article
  15. Russmann S, Jetter A, Kullak-Ublik GA. Pharmacogenetics of drug-induced liver injury. Hepatology 2010;52:748-761 View Article
  16. Daly AK, Day CP. Genetic association studies in drug-induced liver injury. Drug Metab Rev 2012;44:116-126 View Article
  17. Daly AK. Molecular basis of polymorphic drug metabolism. J Mol Med (Berl) 1955;73:539-553
  18. Hirata K, Takagi H, Yamamoto M, Matsumoto T, Nishiya T, Mori K. Ticlopidine-induced hepatotoxicity is associated with specific human leukocyte antigen genomic subtypes in Japanese patients: A preliminary case-control study. Pharmacogenom J 2008;8:29-33 View Article
  19. Lucena M, Andrade RJ, Martínez C, Ulzurrun E, García-Martín E, Borraz Y. Glutathione S-transferase M1 and T1 null genotypes increase susceptibility to idiosyncratic drug-induced liver injury. Hepatology 2008;48:588-596 View Article
  20. Stewart JD, Horvath R, Baruffini E, Ferrero I, Bulst S, Watkins PB. Polymerase g gene POLG determines the risk of sodium valproate-induced liver toxicity. Hepatology 2010;52:1791-1796 View Article
  21. Dixit R, Boelsterli UA. Healthy animals and animal models of human disease(s) in safety assessment of human pharmaceuticals, including therapeutic antibodies. Drug Disc Today 2007;12:336-342 View Article
  22. Roth RA, Ganey PE. Animal models of idiosyncratic drug-induced liver injury - Current status. Crit Rev Toxicol 2011;41:723-739 View Article
  23. Boelsterli UA, Hsiao CJ. The heterozygous Sod2+/− mouse: Modeling the mitochondrial role in drug toxicity. Drug Discovery Today 2008;13:982-988 View Article
  24. Evans MJ, Kaufman MH. Establishment in culture of pluripotential cells from mouse embryos. Nature 1981;292:154-156 View Article
  25. Martin GR. Isolation of a pluripotent cell line from early mouse embryos cultured in medium conditioned by teratocarcinoma stem cells. Proc Natl Acad Sci U S A 1981;78:7634-7638 View Article
  26. Evans M. Discovering pluripotency: 30 years of mouse embryonic stem cells. Nat Rev Mol Cell Biol 2011;12:680-686 View Article
  27. Burdon T, Smith A, Savatier P. Signalling, cell cycle and pluripotency in embryonic stem cells. Trends Cell Biol 2002;12:432-438 View Article
  28. Niwa H. Molecular mechanism to maintain stem cell renewal of ES cells. Cell Struct Funct 2001;26:137-148 View Article
  29. Chambers I, Tomlinson SR. The transcriptional foundation of pluripotency. Development 2009;136:2311-2322 View Article
  30. Chia NY, Chan YS, Feng B, Lu X, Orlov YL, Moreau D. A genome-wide RNAi screen reveals determinants of human embryonic stem cell identity. Nature 2010;468:316-320 View Article
  31. Kim J, Chu J, Shen X, Wang J, Orkin SH. An extended transcriptional network for pluripotency of embryonic stem cells. Cell 2008;132:1049-1061 View Article
  32. Orkin SH. Chipping away at the embryonic stem cell network. Cell 2005;122:828-830 View Article
  33. Thomson JA, Itskovitz-Eldor J, Shapiro SS, Waknitz MA, Swiergiel JJ, Marshall VS. Embryonic stem cell lines derived from human blastocysts. Science 1998;282:1145-1147 View Article
  34. Amit M, Carpenter MK, Inokuma MS, Chiu CP, Harris CP, Waknitz MA. Clonally derived human embryonic stem cell lines maintain pluripotency and proliferative potential for prolonged periods of culture. Dev Biol 2000;227:271-278 View Article
  35. Gurdon JB. The developmental capacity of nuclei taken from intestinal epithelium cells of feeding tadpoles. J Embryol Exp Morphol 1962;10:622-640
  36. Gurdon JB, Uehlinger V. “Fertile” intestine nuclei. Nature 1966;210:1240-1241 View Article
  37. Wilmut I, Schnieke AE, McWhir J, Kind AJ, Campbell KH. Viable offspring derived from fetal and adult mammalian cells. Nature 1997;385:810-813 View Article
  38. Takahashi K, Yamanaka S. Induction of pluripotent stem cells from mouse embryonic and adult fibroblast cultures by defined factors. Cell 2006;126:663-676 View Article
  39. Yu J, Vodyanik MA, Smuga-Otto K, Antosiewicz-Bourget J, Frane JL, Tian S. Induced pluripotent stem cell lines derived from human somatic cells. Science 2007;318:1917-1920 View Article
  40. Warren L, Manos PD, Ahfeldt T, Loh YH, Li H, Lau F. Highly efficient reprogramming to pluripotency and directed differentiation of human cells with synthetic modified mRNA. Cell stem cell 2010;7:618-630 View Article
  41. Kaji K, Norrby K, Paca A, Mileikovsky M, Mohseni P, Woltjen K. Virus-free induction of pluripotency and subsequent excision of reprogramming factors. Nature 2009;458:771-775 View Article
  42. Woltjen K, Michael IP, Mohseni P, Desai R, Mileikovsky M, Hämäläinen R. piggyBac transposition reprograms fibroblasts to induced pluripotent stem cells. Nature 2009;458:766-770 View Article
  43. Okita K, Matsumura Y, Sato Y, Okada A, Morizane A, Okamoto S. A more efficient method to generate integration-free human iPS cells. Nat Methods 2011;8:409-412 View Article
  44. Krueger WH, Tanasijevic B, Barber V, Flamier A, Gu X, Manautou J. Cholesterol-secreting and statin-responsive hepatocytes from human ES and iPS cells to model hepatic involvement in cardiovascular health. PLoS One 2013;8:67296 View Article
  45. Si-Tayeb K, Noto FK, Nagaoka M, Li J, Battle MA, Duris C. Highly efficient generation of human hepatocyte-like cells from induced pluripotent stem cells. Hepatology 2010;51:297-305 View Article
  46. Chu J, Sadler KC. New school in liver development: lessons from zebrafish. Hepatology 2009;50:1656-1663 View Article
  47. Mueller KM, Themanns M, Friedbichler K, Kornfeld JW, Esterbauer H, Tuckermann JP. Hepatic growth hormone and glucocorticoid receptor signaling in body growth, steatosis and metabolic liver cancer development. Mol Cell Endocrinol 2012;361:1-11 View Article
  48. Si-Tayeb K, Lemaigre FP, Duncan SA. Organogenesis and development of the liver. Dev Cell 2010;18:175-189 View Article
  49. Song Z, Cai J, Liu Y, Zhao D, Yong J, Duo S. Efficient generation of hepatocyte-like cells from human induced pluripotent stem cells. Cell research 2009;19:1233-1242 View Article
  50. Azuma H, Paulk N, Ranade A, Dorrell C, Al-Dhalimy M, Ellis E. Robust expansion of human hepatocytes in Fah-/-/Rag2-/-/Il2rg-/- mice. Nat Biotechnol 2007;25:903-910 View Article
  51. Nakamura N, Saeki K, Mitsumoto M, Matsuyama S, Nishio M, Saeki K. Feeder-free and serum-free production of hepatocytes, cholangiocytes, and their proliferating progenitors from human pluripotent stem cells: application to liver-specific functional and cytotoxic assays. Cell Reprogram 2012;14:171-185 View Article
  52. Khurana S, Jaiswal AK, Mukhopadhyay A. Hepatocyte nuclear factor-4alpha induces transdifferentiation of hematopoietic cells into hepatocytes. J Biol Chem 2010;285:4725-4731 View Article
  53. Huang P, He Z, Ji S, Sun H, Xiang D, Liu C. Induction of functional hepatocyte-like cells from mouse fibroblasts by defined factors. Nature 2011;475:386-389 View Article
  54. Ji S, Zhang L, Hui L. Cell fate conversion: direct induction of hepatocyte-like cells from fibroblasts. J Cell Biochem 2013;114:256-265 View Article
  55. Jozefczuk J, Prigione A, Chavez L, Adjaye J. Comparative analysis of human embryonic stem cell and induced pluripotent stem cell-derived hepatocyte-like cells reveals current drawbacks and possible strategies for improved differentiation. Stem Cells Dev 2011;20:1259-1275 View Article
  56. Willenbring H, Soto-Gutierrez A. Transplantable liver organoids made from only three ingredients. Cell stem cell 2013;13:139-140 View Article
  57. Feng Y, Xue WJ, Li P, Sha ZY, Huang H, Rui L. RASSF1A hypermethylation is associated with aflatoxin B1 and polycyclic aromatic hydrocarbon exposure in hepatocellular carcinoma. Hepatogastroenterology 2012;59:1883-1888 View Article
  58. Clarke JD, Cherrington NJ. Genetics or environment in drug transport: the case of organic anion transporting polypeptides and adverse drug reactions. Expert Opin Drug Metab Toxicol 2012;8:349-360 View Article
  59. Castillo P, Ibáñez F, Guajardo A, Llanos MN, Ronco AM. Impact of cadmium exposure during pregnancy on hepatic glucocorticoid receptor methylation and expression in rat fetus. PLoS One 2012;7:44139 View Article
  60. Zeybel M, Mann DA, Mann J. Epigenetic modifications as new targets for liver disease therapies. J Hepatol 2013;59:1349-1353 View Article
  61. Leite SB, Teixeira AP, Miranda JP, Tostões RM, Clemente JJ, Sousa MF. Merging bioreactor technology with 3D hepatocyte-fibroblast culturing approaches: Improved in vitro models for toxicological applications. Toxicol In Vitro 2011;25:825-832 View Article
  62. Janorkar AV, Harris LM, Murphey BS, Sowell BL. Use of three-dimensional spheroids of hepatocyte-derived reporter cells to study the effects of intracellular fat accumulation and subsequent cytokine exposure. Biotechnol Bioeng 2011;108:1171-1180 View Article
  63. Goral VN, Hsieh YC, Petzold ON, Clark JS, Yuen PK, Faris RA. Perfusion-based microfluidic device for three-dimensional dynamic primary human hepatocyte cell culture in the absence of biological or synthetic matrices or coagulants. Lab Chip 2010;10:3380-3386 View Article
  64. Miranda JP, Leite SB, Muller-Vieira U, Rodrigues A, Carrondo MJ, Alves PM. Towards an extended functional hepatocyte in vitro culture. Tissue Eng Part C Methods 2009;15:157-167 View Article
  65. Guillouzo A, Guguen-Guillouzo C. Evolving concepts in liver tissue modeling and implications for in vitro toxicology. Expert Opin Drug Metab Toxicol 2008;4:1279-1294 View Article
  66. Musunuru K. Genome editing of human pluripotent stem cells to generate human cellular disease models. Dis Model Mech 2013;6:896-904 View Article
  67. Cheng LT, Sun LT, Tada T. Genome editing in induced pluripotent stem cells. Genes Cells 2012;17:431-438 View Article
  68. Sun N, Zhao H. Transcription activator-like effector nucleases (TALENs): a highly efficient and versatile tool for genome editing. Biotechnol Bioeng 2013;110:1811-1821 View Article
  69. Joung JK, Sander JD. TALENs: a widely applicable technology for targeted genome editing. Nat Rev Mol Cell Bio 2013;14:49-55 View Article
  70. Horvath P, Barrangou R. CRISPR/Cas, the immune system of bacteria and archaea. Science 2010;327:167-170 View Article
  71. Avan A, Crea F, Paolicchi E, Funel N, Galvani E, Marquez VE. Molecular mechanisms involved in the synergistic interaction of the EZH2 inhibitor 3-deazaneplanocin A with gemcitabine in pancreatic cancer cells. Mol Cancer Ther 2012;11:1735-1746 View Article
  72. D'Addario C, Caputi FF, Ekström TJ, Di Benedetto M, Maccarrone M, Romualdi P. Ethanol induces epigenetic modulation of prodynorphin and pronociceptin gene expression in the rat amygdala complex. J Mol Neurosci 2013;49:312-319 View Article
  73. Dimri M, Bommi PV, Sahasrabuddhe AA, Khandekar JD, Dimri GP. Dietary omega-3 polyunsaturated fatty acids suppress expression of EZH2 in breast cancer cells. Carcinogenesis 2010;31:489-495 View Article
  74. Binder H, Steiner L, Przybilla J, Rohlf T, Prohaska S, Galle J. Transcriptional regulation by histone modifications: towards a theory of chromatin re-organization during stem cell differentiation. Phys Biol 2013;10:026006 View Article
  75. Parbin S, Kar S, Shilpi A, Sengupta D, Deb M, Rath SK. Histone deacetylases: a saga of perturbed acetylation homeostasis in cancer. J Histochem Cytochem 2014;62:11-33 View Article
  76. Choi JK. Systems biology and epigenetic gene regulation. IET Syst Biol 2010;4:289-295 View Article
  77. Hoheisel JD. Microarray technology: beyond transcript profiling and genotype analysis. Nat Rev Genet 2006;7:200-210 View Article
  78. Kleiner DE, Chalasani NP, Lee WM, Fontana RJ, Bonkovsky HL, Watkins PB. Hepatic histological findings in suspected drug-induced liver injury: systematic evaluation and clinical associations. Hepatology 2014;59:661-670 View Article
  79. Martin LJ, Woo JG, Avery CL, Chen HS, North KE, Au K. Multiple testing in the genomics era: findings from Genetic Analysis Workshop 15, Group 15. Genet Epidemiol 2007;31:S124-131 View Article
  80. Adjaye J. Generation of amplified RNAs and cDNA libraries from single mammalian cells. Methods Mol Med 2007;132:117-124 View Article
  81. Singh R, Maganti RJ, Jabba SV, Wang M, Deng G, Heath JD. Microarray-based comparison of three amplification methods for nanogram amounts of total RNA. Am J Physiol Cell Physiol 2005;288:C1179-1189 View Article
  82. Neira M, Azen E. Gene discovery with laser capture microscopy. Methods Enzymol 2002;356:282-289 View Article
  83. Knowles BB, Howe CC, Aden DP. Human hepatocellular carcinoma cell lines secrete the major plasma proteins and hepatitis B surface antigen. Science 1980;209:497-499 View Article
  84. Gripon P, Rumin S, Urban S, Le Seyec J, Glaise D, Cannie I. Infection of a human hepatoma cell line by hepatitis B virus. Proc Natl Acad Sci U S A 2002;99:15655-15660 View Article
  85. Ansede JH, Smith WR, Perry CH, St Claire RL, Brouwer KR. An in vitro assay to assess transporter-based cholestatic hepatotoxicity using sandwich-cultured rat hepatocytes. Drug Metab Dispos 2010;38:276-280 View Article
  86. Greer ML, Barber J, Eakins J, Kenna JG. Cell based approaches for evaluation of drug-induced liver injury. Toxicology 2010;268:125-131 View Article
  87. Gerbal-Chaloin S, Funakoshi N, Caillaud A, Gondeau C, Champon B, Si-Tayeb K. Human induced pluripotent stem cells in hepatology: beyond the proof of concept. Am J Pathol 2014;184:332-347 View Article
  88. Kawabata K, Inamura M, Mizuguchi H. Efficient hepatic differentiation from human iPS cells by gene transfer. Methods Mol Biol 2012;826:115-124 View Article
  89. Takata A, Otsuka M, Kogiso T, Kojima K, Yoshikawa T, Tateishi R. Direct differentiation of hepatic cells from human induced pluripotent stem cells using a limited number of cytokines. Hepatol Int 2011;5:890-898 View Article
  90. Shiraki N, Yamazoe T, Qin Z, Ohgomori K, Mochitate K, Kume K. Efficient differentiation of embryonic stem cells into hepatic cells in vitro using a feeder-free basement membrane substratum. PLoS One 2011;6:24228 View Article
  91. Nayak NC, Mital I. The dynamics of alpha-fetoprotein and albumin synthesis in human and rat liver during normal ontogeny. Am J Pathol 1977;86:359-374
  92. Greuet J, Pichard L, Bonfils C, Domergue J, Maurel P. The fetal specific gene CYP3A7 is inducible by rifampicin in adult human hepatocytes in primary culture. Biochem Biophys Res Commun 1996;225:689-694 View Article
  93. Baharvand H, Hashemi SM, Shahsavani M. Differentiation of human embryonic stem cells into functional hepatocyte-like cells in a serum-free adherent culture condition. Differentiation 2008;76:465-477 View Article
  94. LeCluyse E, Madan A, Hamilton G, Carroll K, DeHaan R, Parkinson A. Expression and regulation of cytochrome P450 enzymes in primary cultures of human hepatocytes. J Biochem Mol Toxicol 2000;14:177-188 View Article
  95. Pascussi JM, Drocourt L, Gerbal-Chaloin S, Fabre JM, Maurel P, Vilarem MJ. Dual effect of dexamethasone on CYP3A4 gene expression in human hepatocytes. Sequential role of glucocorticoid receptor and pregnane X receptor. Eur J Biochem 2001;268:6346-6358 View Article
  96. Xia L, Sakban RB, Qu Y, Hong X, Zhang W, Nugraha B. Tethered spheroids as an in vitro hepatocyte model for drug safety screening. Biomaterials 2012;33:2165-2176 View Article
  97. Tostões RM, Leite SB, Serra M, Jensen J, Björquist P, Carrondo MJ. Human liver cell spheroids in extended perfusion bioreactor culture for repeated-dose drug testing. Hepatology 2012;55:1227-1236 View Article
  98. Lee JS, Shin J, Park HM, Kim YG, Kim BG, Oh JW. Liver extracellular matrix providing dual functions of two-dimensional substrate coating and three-dimensional injectable hydrogel platform for liver tissue engineering. Biomacromolecules 2014;15:206-218 View Article
  99. Cooper O, Hargus G, Deleidi M, Blak A, Osborn T, Marlow E. Differentiation of human ES and Parkinson's disease iPS cells into ventral midbrain dopaminergic neurons requires a high activity form of SHH, FGF8a and specific regionalization by retinoic acid. Mol Cell Neurosci 2010;45:258-266 View Article
  100. Sivertsson L, Synnergren J, Jensen J, Björquist P, Ingelman-Sundberg M. Hepatic differentiation and maturation of human embryonic stem cells cultured in a perfused three-dimensional bioreactor. Stem Cells Dev 2013;22:581-594 View Article
  101. Wang S, Nagrath D, Chen PC, Berthiaume F, Yarmush ML. Three-dimensional primary hepatocyte culture in synthetic self-assembling peptide hydrogel. Tissue Eng Part A 2008;14:227-236 View Article
  102. Chen HL, Wu HL, Fon CC, Chen PJ, Lai MY, Chen DS. Long-term culture of hepatocytes from human adults. J Biomed Sci 1998;5:435-440 View Article
  103. Ferrini JB, Pichard L, Domergue J, Maurel P. Long-term primary cultures of adult human hepatocytes. Chem Biol Interact 1997;107:31-45 View Article
  104. Chua KN, Lim WS, Zhang P, Lu H, Wen J, Ramakrishna S. Stable immobilization of rat hepatocyte spheroids on galactosylated nanofiber scaffold. Biomaterials 2005;26:2537-2547 View Article
  105. Lau TT, Ho LW, Wang DA. Hepatogenesis of murine induced pluripotent stem cells in 3D micro-cavitary hydrogel system for liver regeneration. Biomaterials 2013;34:6659-6669 View Article
  106. Fang S, Qiu YD, Mao L, Shi XL, Yu DC, Ding YT. Differentiation of embryoid-body cells derived from embryonic stem cells into hepatocytes in alginate microbeads in vitro. Acta Pharmacol Sin 2007;28:1924-1930 View Article
  107. Takebe T, Sekine K, Enomura M, Koike H, Kimura M, Ogaeri T. Vascularized and functional human liver from an iPSC-derived organ bud transplant. Nature 2013;499:481-484 View Article
  108. Zhang Y, Huang SZ, Zeng YT. The effect of HSV-tk/GCV on hepatic specific damage driven by murine ALB promoter/enhancer. Yi Chuan Xue Bao 2004;31:1053-1060
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Stem Cell Strategies to Evaluate Idiosyncratic Drug-induced Liver Injury

Winfried Krueger, Urs A. Boelsterli, Theodore P. Rasmussen
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