Activation of the Unfolded Protein Response (UPR) Is Associated with Cholangiocellular Injury, Fibrosis and Carcinogenesis in an Experimental Model of Fibropolycystic Liver Disease.

Fibropolycystic liver disease is characterized by hyperproliferation of the biliary epithelium and the formation of multiple dilated cysts, a process associated with unfolded protein response (UPR). In the present study, we aimed to understand the mechanisms of cyst formation and UPR activation in hepatocytic c-Jun N-terminal kinase 1/2 (Jnk1/2) knockout mice. Floxed JNK1/2 (Jnkf/f) and Jnk∆hepa animals were sacrificed at different time points during progression of liver disease. Histological examination of specimens evidenced the presence of collagen fiber deposition, increased α-smooth muscle actin (αSMA), infiltration of CD45, CD11b and F4/80 cells and proinflammatory cytokines (Tnf, Tgfβ1) and liver injury (e.g., ALT, apoptosis and Ki67-positive cells) in Jnk∆hepa compared with Jnkf/f livers from 32 weeks of age. This was associated with activation of effectors of the UPR, including BiP/GRP78, CHOP and spliced XBP1. Tunicamycin (TM) challenge strongly induced ER stress and fibrosis in Jnk∆hepa animals compared with Jnkf/f littermates. Finally, thioacetamide (TAA) administration to Jnk∆hepa mice induced UPR activation, peribiliary fibrosis, liver injury and markers of biliary proliferation and cholangiocarcinoma (CCA). Orthoallografts of DEN/CCl4-treated Jnk∆hepa liver tissue triggered malignant CCA. Altogether, these results suggest that activation of the UPR in conjunction with fibrogenesis might trigger hepatic cystogenesis and early stages of CCA.

1. Introduction

JNKs are a family of evolutionarily conserved mitogen-activated protein kinases (MAPKs) activated by tumor necrosis factor (TNF) that play an important role in converting extracellular stimuli into a wide range of cellular responses, including inflammatory response, stress response, cell death, cell differentiation and cell proliferation [1,2]. JNKs are encoded by three genes, Jnk1, Jnk2 and Jnk3; the products of two of these genes, JNK1 and JNK2, are expressed in the liver [3]. Importantly, JNK1 and JNK2 elicit redundant but also distinct functions [4,5]. In order to characterize the combined functions of the JNK genes, using cell-type-specific deletion models is essential. By implementing this strategy, we were the first to report that aged hepatocyte-specific Jnk1/2 (Jnk) knockout mice present bile duct hyperplasia. Moreover, the deletion of Jnk1/2 in an experimental model of chronic liver disease was strongly associated with cell death, cholestasis and cholangiocyte proliferation [1]. A few months later, Manieri and colleagues [6] reported that changes in bile acid metabolism in Jnk mice may contribute to cholangiocyte proliferation and hepatoblast maturation, causing bile duct hyperplasia and cholangiocyte injury, which leads to cholangiocarcinoma (CCA) development at late stages. A very recent paper [7] confirmed these findings and identified a molecular link between JNK and RIPK1 as a mechanistic trigger of murine polycystic liver disease (PLD).

PLD is a group of rare disorders that result from structural changes in the biliary tree development [8]. Genetic mechanisms and/or signaling defects are the main cause of ductal structures that become separated from the biliary tree finally resulting in hepatic cystogenesis [9,10]. Cyst formation in the liver may solely affect the intrahepatic bile ducts (i.e., autosomal dominant polycystic liver disease (ADPLD)) or arise associated with renal cysts [(i.e., autosomal dominant polycystic kidney disease (ADPKD), autosomal recessive polycystic kidney disease (ARPKD), Caroli disease (CD) and CD accompanied by congenital hepatic fibrosis (CHF) in infants, known as Caroli syndrome (CS) [11,12]). Among PLDs, CD patients have an increased risk of developing CCA [13].

The majority of PLD-related genes (i.e., PRKCSH, SEC63, ALG8, PKD2, GANAB, SEC61β) encode for endoplasmic reticulum (ER)-resident proteins involved in the biogenesis, synthesis, maturation, folding and transport of nascent proteins [14]. Therefore, mutations in these genes may compromise ER protein homeostasis, thereby activating the unfolded protein response (UPR) signaling cascades, consisting of sensor (IRE1α, PERK and ATF6) and effector (CHOP, BiP/GRP78 and XBP1) proteins, in order to promote protein folding, ER-associated protein degradation (ERAD) and the activation of prosurvival mechanisms [12].

In the present study, we hypothesized that fibropolycystic-related pathogenesis in Jnk mice might be triggered concomitantly with the activation of the UPR in response to abnormal ER protein homeostasis thus contributing to uncontrolled cholangiocyte proliferation and cell death.

2. Materials and Methods

2.1. Experimental Models

The generation of hepatocyte-specific Jnk1/2 knockout mice (Jnk) in a C57BL/6 background was earlier described [5]. Albumin (Alb)-Cre animals were purchased from Charles River (Cerdanyola del Vallés, Barcelona, Spain). By homologous recombination in embryonic stem (ES) cells, mice with a floxed allele of Jnk1/2 were constructed Jnk1/2LoxP/LoxP (Jnk) according to previously published studies, and Alb-Cre mice were crossed with Jnk1/2LoxP/LoxP to generate Jnk mice [5,15,16]. Cre-negative Jnk mice were used as controls.

Age progression of Jnk mice was followed, and animals were fed until sacrifice at Weeks 8, 32, 52 and 72 of age. Endoplasmic reticulum (ER) stress induction using tunicamycin (TM) liquid solution (Merck, Madrid, Spain) was performed by diluting TM in sterile 150 mM Dextrose with a fixed working concentration. Eight-week-old Jnk and Jnk mice received an IP dosage of 2 mg/Kg TM. Control groups received the same IP injection of dextrose solution. Mice were sacrificed 24 h later. Induction of fibrosis in mice was performed using thioacetamide (TAA; Merck, Madrid, Spain) in drinking water (300 mg/L) for a period of 24 weeks to 8-week-old Jnk and Jnk mice. Another set of Jnk male mice received 25 mg/kg (i.p.) of diethyl-nitrosamine (DEN) at 14 days of age and from Week 8 until Week 22 were treated with CCl4 (0.5 mL/kg, i.p.) twice per week. From Week 18 until Week 22, one group of mice (n = 6) was treated with the dual G9a/DNMT1 inhibitor CM272 [17,18] (5 mg/kg, i.p.) daily, while control mice (n = 6) received the same volume of PBS. For orthotopic implantation, primary tumors from Jnk and Jnk—DEN/CCl4-treated mice were aseptically isolated and placed at room temperature in DMEM supplemented with 10% FBS plus 50 U/mL penicillin and 50 mg/mL streptomycin and implanted in nude mice, as previously reported [19].

Upon sacrifice, serum was collected from the inferior vena cava, and serum alanine aminotransferase (ALT), aspartate aminotransferase (AST), alkaline phosphatase (AP) and lactate dehydrogenase (LDH) were measured in the Institute of Clinical Chemistry at the University Hospital RWTH Aachen (UKA) using automated analyzers. Liver tissue was collected in liquid nitrogen and kept at −80 °C for protein and RNA extraction. A portion was fixed in 4% PFA for immunohistochemistry (IHC) staining and in TissueTek for immunofluorescence (IF) staining.

Both Jnk mice and Jnk mice were bred and maintained in the Animal Facility at the School of Biology at UCM, Madrid, under pathogen-free conditions in a temperature and humidity-controlled room with 12 h light/dark cycles and allowed food and water ad libitum. Animal work was approved by the Consejería de Medio Ambiente, Administración Local y Ordenación del Territorio (PROEX-125.1/20).

2.2. Immunoblot Analysis

According to Bradford’s method, protein concentrations in the whole liver tissue lysate, cytoplasm and mitochondria were measured using Bio-Rad protein analysis reagent following the manufacturer’s instructions [20]. Immunoblotting was performed as described [1] using the following primary antibodies: BIP/GRP78 (CST, Leiden, Netherlands), CHOP (CST), GAPDH (Bio-Rad, Madrid, Spain), sXBP1 (CST), uXBP1 (Abcam, Cambridge, UK), pJNK1 (BIONOVA, Littleton, CO, USA), JNK1 (CST), pJNK2 (BIONOVA), JNK2 (CST), CK19 (Abcam, Cambridge, UK) and αSMA (Merck). GAPDH was used as a loading control. Primary antibodies were detected with anti-mouse (Bio-Rad) or anti-rabbit (Werfen, Barcelona, Spain) IgG antibodies, and signals were developed using Amersham ECL Prime (GE Healthcare, Madrid, Spain). Quantification of immunoblot signals was performed with the Image Lab Software from Bio-Rad Laboratories. Values were normalized to control signals and are provided together with blot images.

2.3. Histological Evaluation of Samples

Paraffin-embedded hepatic tissue was sectioned and stained for H&E, Periodic Acid Schiff (PAS) and Sirius Red (SR). Samples were examined by a pathologist blinded who analyzed the degree of liver injury. Immunohistochemistry on paraffin sections was performed. Briefly, liver sections were deparaffinized with xylene and rehydrated with serially descending percentages of ethanol. The sections were then boiled in 10 mM sodium citrate acid buffer (pH = 6) to enhance the availability of the antigen, followed by incubation with 3% H2O2. Afterward, the sections were transferred to 2.5% horse serum (Palex Medical, Barcelona, Spain) and incubated overnight at 4 °C with CK19 (Abcam), Ki67 (Abcam), SOX9 (Abcam), cleaved caspase-3 (CST), NOTCH1 (Abcam) and MUCIN2 (Santa Cruz, Heidelberg, Germany) antibodies.

The following day, slides were incubated with secondary antibodies (Palex Medical, Madrid, Spain) for 1 h at RT in a humidifying box. The signal was developed with diaminobenzidine (DAB, peroxidase substrate kit) (Palex Medical). The sections were counterstained using hematoxylin and mounted with Roti-Histokit (Quimivita, Barcelona, Spain).

For the immunofluorescence staining, frozen cryosections were incubated with αSMA, Ki67, CD11b (BD Biosciences, Madrid, Spain), CD45 (BD Biosciences) and F4/80 (Bio-Rad) overnight and incubated with fluorescence labeled secondary antibodies (AlexaFluor 488, Fisher Scientific, Madrid, Spain). Slides were then mounted with DAPI (Palex Medical) and imaged using Axio Imager A1 microscope (Carl Zeiss AG, Jena, Germany) and AxioVision software. The cryosections from mouse liver were also incubated with an in situ cell death detection kit (Roche, Madrid, Spain) overnight at 4 °C.

2.4. RNA Isolation and Quantitative Real-Time Polymerase Chain Reaction (RT-PCR)

Total cellular RNA was isolated with Trizol (Fisher Scientific). For reverse transcription, 1 µg of total RNA was transcribed using Applied Biosystems™ High-Capacity cDNA Reverse Transcription Kit (Fisher Scientific). Quantitative real-time PCR was carried out by a real-time PCR machine employing Sybr Green PCR Master Mix (Fisher Scientific). The Ct values were extrapolated to a standard curve and data was normalized to the house-keeping gene expression (Gapdh). Primers’ sequences are available upon request.

2.5. Statistical Analysis

All data were expressed as mean ± standard deviation of the mean. The standard error of the mean (SEM) was calculated from the average of at least 3 independent samples per condition. Statistical significance was determined via using GraphPad Prism 8.0 software (GraphPad Software, CA, USA), followed by a Student’s t-test (unpaired, two-tailed test) or via two-way analysis of variance (ANOVA), including Tukey’s multiple comparisons test. Values of p < 0.05 were considered significant.

3. Results

3.1. Hepatocytic Deletion of Jnk1/2 Results in Progressive Fibropolycystic Disease Characterized by Extracellular Matrix Deposition and Inflammation

We first generated knockout animals with conditional deletion of both Jnk1 and Jnk2 in hepatocytes (Jnk) (Supplementary Figure S1A,B). Littermates carrying the respective loxP-flanked alleles but lacking expression of Cre recombinase were used as controls (Jnk) (Supplementary Figure S1A,B). Progression of liver disease was evaluated at 8, 32, 52 and 72 weeks of age (Supplementary Figure S1C).

Interestingly, strong presence of fibrillar collagen networks was identified using Sirius Red (SR) staining in tissue sections from aging Jnk mice, mimicking CS in patients [7] (Figure 1A). No signs of PKD were observed (Supplementary Figure S2A–C). The quantification of type I and III Collagen fibers in the liver parenchyma of these mice showed a clear tendency from 32 weeks of age and significant differences at 52 and 72 weeks of age, compared to Jnk mice (Figure 1B). Alpha-smooth muscle actin (αSMA) protein overexpression was evident at 32 weeks of age in Jnk mice (Figure 1C). Moreover, increased mRNA expression levels of αSma, ColIa1 and Mmp9 was observed in aging Jnk compared with Jnk livers in most of the time points assessed (Figure 1D).

Figure 1

Fibropolycystic disease in aging Jnk mice is characterized by extracellular matrix deposition and inflammation. (A) Fibrosis was evaluated by SR staining in 8- to 72-week-old Jnk and Jnk mice. Scale bars, 500 μm. (B) Quantification of SR areas was performed using ImageJ. Protein and mRNA expression was analyzed for αSma (left panel), ColIA1 (center panel) and Mmp9 (right panel) using Western Blot (C) and qRT-PCR (D), respectively (* p < 0.05; intergroup significance). (E) Quantification of positive cells from IF microphotographs of CD45 (left panel), F4/80 (center panel) and CD11b (right panel) is shown in 8- to 72-week-old Jnk and Jnk mice. Data are shown as the mean ± SEM and graphed, separately (n = 6 mice per group) (* p < 0.05; ** p < 0.01; *** p < 0.001; **** p < 0.0001).

Synthesis of extracellular matrix (ECM) and activation of myofibroblasts and hepatic stellate cells (HSCs) is often accompanied by the recruitment of leukocytes. Thus, we examined by immunofluorescence (IF) the infiltration of inflammatory cells. The numbers of leukocytes (CD45), macrophages (F4/80) and monocytes (CD11b) were significantly increased in the liver of aging Jnk mice from 32 weeks of age, compared with Jnk littermates (Figure 1E and Figure S3A–C). Additionally, the levels of transcripts of proinflammatory cytokines including TNFα and TGFβ1 were significantly elevated in the livers of 32-week-old Jnk compared with Jnk mice (Supplementary Figure S3D,E).

3.2. Hepatocytic Deletion of Jnk1/2 Promotes Hepatomegaly and Liver Damage

Since hepatobiliary pathology manifested by Jnk mimicked CS to a great extent, we next explored the histological and clinical characteristics of Jnk aging mice. Hepatomegaly was observed from 52 weeks of age, when mice showed a significantly increased liver weight to body weight (LW/BW) ratio compared with Jnk animals (Figure 2A and Figure S4A–C). Histologically, from the 52-week-old time point, 100% of Jnk mice exhibited cysts across the hepatic parenchyma, accompanied by necrotic areas and the presence of inflammatory cells (Figure 2B and Figure S4D).

Figure 2

Hepatic deletion of Jnk1/2 promotes hepatomegaly and liver damage. Eight- to 72-week-old male Jnk and Jnk mice were analyzed. (A) Representation of the LW/BW ratio. (B) Liver cysts were counted in the H&E liver tissue staining and represented. Serum ALT (C) and LDH (D) levels were analyzed. (E) Representative microphotographs of TUNEL stainings from Jnk and Jnk mice liver tissues collected from 8 to 72 weeks of age and quantification of TUNEL-positive cells/HPF. Scale bars, 50 µm. (F) Representative microphotographs of Ki67 IF and quantification of Ki67-positive cells/HPF from the same mice. Scale bars, 50 µm. Data are shown as the mean ± SEM and graphed, separately (n = 6–8 mice per group) (* p < 0.05; ** p < 0.01; *** p < 0.001; **** p < 0.0001).

Next, we measured serum levels of surrogate markers of liver injury in aging Jnk knockout mice. The biochemical analysis revealed that ALT and LDH levels were significantly increased in Jnk mice from 52 weeks of age (Figure 2C,D), indicating that hepatocellular injury might be associated with cyst formation observed in Jnk livers.

Therefore, we subsequently assessed cell death and proliferation using IF and IHC techniques. The TUNEL assay detects DNA breakage that arises during early and late stages of apoptosis [21]. The amount of TUNEL-positive cells per view field was significantly increased in Jnk livers from 52 weeks of age, compared with Jnk animals, indicating increased apoptotic cell death in the absence of hepatocytic Jnk1/2 (Figure 2E). Interestingly, detection of the cleaved form of Caspase-3 (CC3) by IHC was observable already from 32 weeks of age (Supplementary Figure S5A,B). In accordance, a compensatory proliferative response, measured using Ki67-, was evident in Jnk mice livers, reaching statistical significance from 32 weeks of age when compared with Jnk mice (Figure 2F and Figure S5C).

3.3. Hepatocytic Deletion of Jnk1/2 Triggers Cystic Hyperproliferation and Cholangiocyte Malignancy

Earlier work demonstrated that hepatocellular JNK deficiency is sufficient for the stimulation of cholangiocyte proliferation and the development of malignancy, resulting in the occurrence of CCA [6]. Therefore, we next studied markers of cystic structures and cholangiocyte proliferation such as CK19 in 52-week-old Jnk and Jnk mice. Whereas CK19-positive staining was exclusive of small bile ducts in Jnk mice, Jnk livers showed increased staining in cystic areas as a result of massive cholangiocyte proliferation. This was corroborated by significantly elevated CK19 protein and mRNA expression in these livers (Figure 3A,B). Glutamine synthase (GS) is normally expressed around perivenular areas, as in Jnk livers (Figure 3A, center panel). However, transforming cells express GS. We observed strong positive areas of GS staining are visible in Jnk livers (Figure 3A, center panel). Concomitant with our GS results, Periodic Acid Schiff (PAS) staining, characteristic of mucin-containing tissues, was restricted to cystic areas in Jnk livers (Figure 3A, right panel). Next, we analyzed markers of hepatoblast differentiation. Interestingly, the mRNA expression of Yap1, a marker of hepatoblast differentiation [22] and Jag1 and Hey1, genes involved in the Notch signaling pathway [23], were significantly upregulated in 52-week-old Jnk compared with Jnk mice (Figure 3C–E).

Figure 3

End-stage disease in liver injury of 52-week-old Jnk mice. (A) Expression of CK19 (left panel), Glutamine synthase (GS) and Periodic Acid Schiff (PAS) were performed in paraffin sections from 52-week-old Jnk and Jnk mice livers. Scale bars, 100 μm. (B–E) Expression of Ck19, Yap1, Jag1 and Hey1 was analyzed and graphed. The data were normalized for the amount of Gapdh mRNA in each sample. Data were represented as the mean ± SEM and graphed, separately (n = 6 mice per group, * p < 0.05; ** p < 0.01).

3.4. Activation of the Unfolded Protein Response (UPR) Is Associated with Increased Liver Injury in Jnk∆hepa Mice

Hepatic cystogenesis in PLD patients has been recently associated with abnormalities in protein homeostasis in endoplasmic reticulum (ER) [12]. Moreover, severe or prolonged ER stress in epithelial cells is known to result in myofibroblast activation and fibrosis development in different tissues [24]. Therefore, since we detected αSMA overexpression and ECM deposition, indicative of activated myofibroblasts and HSCs, in the livers of Jnk mice from 32 weeks of age, we analyzed the protein levels of the main UPR components in liver tissue of our experimental groups. Interestingly, while no differences in pIREα protein expression were observed between Jnk and Jnk mice livers (not shown), the UPR effectors BiP/GRP78 and CHOP were strongly overexpressed in 32-week-old Jnk livers (Figure 4A). These findings were associated with increased levels of spliced and total XBP1 protein levels in Jnk compared with Jnk animals (Figure 4A).

Figure 4

Activation of the unfolded protein response (UPR) triggers increased liver injury in Jnk mice. (A) The expression of BiP/GRP78, CHOP, spliced XBP1 (sXBP1) and unspliced XBP1 (uXBP1) was evaluated in 32-week-old Jnk and Jnk mice using Western blot. (B) The expression of the same proteins was measured in Tunicamycin (TM)-challenged Jnk and Jnk mice. Numbers denote molecular weight (KDa) of proteins. GAPDH served as loading control. #/* p < 0.05 intra- and intergroup significance, respectively. (C) Representative Sirius Red (SR) stainings of liver tissue from the indicated mice after TM treatment. Scale bars, 500 μm. (D) TUNEL staining was performed to assess apoptotic cell death in the same samples by IF. Scale bars, 50 μm. (E) Ki67 was used to measure cell proliferation after TM treatment in the experimental groups. Scale bars, 50 μm. Data were represented as the mean ± SEM and graphed (n = 3–6 mice per group;*/# p < 0.05; ## p < 0.01; *** p < 0.001; ****/#### p < 0.0001).

Tunicamycin (TM), a bacterial nucleoside that causes accumulation of unfolded or misfolded proteins in the ER, efficiently induces ER stress and activation of the UPR in the liver in vivo [25,26]. Therefore, we used TM as an experimental tool to directly evaluate the effect of UPR activation as a trigger in the fibrogenic response and hepatocellular injury in Jnk mice. As expected, TM administration resulted in the elevation of UPR effector proteins, including BiP/GRP78, CHOP and XBP1 in Jnk livers (Figure 4B). However, this response was more intense in Jnk animals (Figure 4B), indicating increased UPR activation in hepatocytic Jnk1/2 knockout mice. As indicated by SR staining of liver sections, acute TM dosing triggered a mild fibrogenic response in floxed-control Jnk mice 24 h after administration. In contrast, this response was much more exacerbated in Jnk livers (Figure 4C and Figure S6F). Concomitantly, cell death and compensatory proliferation, measured as TUNEL and Ki-67 staining respectively, were significantly increased in the hepatic parenchyma of Jnk compared with Jnk animals (Figure 4D,E and Figure S6D,E). Altogether these results show that ER stress and UPR activation are increased in hepatocytic Jnk1/2 knockout mice, and these animals are much more sensitive to ER-mediated parenchymal damage, explaining the increased fibrosis and hepatocellular injury observed in these mice.

3.5. Jnk∆hepa Mice Display an Exacerbated Profibrogenic Response

Since Jnk mice are more susceptible to ER stress and UPR activation, resulting in an enhanced acute fibrogenic response, we decided to further explore the response of these mice in the context of chronic liver injury. Chronic supplementation in drinking water with thioacetamide (TAA), a toxin known to induce liver injury and cholangiocarcinogenesis in rodents [27] leads to severe fibrosis/cirrhosis between 16 and 24 weeks in mice [28]. Thus, we treated our experimental groups with TAA for a period of 24 weeks (Supplementary Figure S7A). Interestingly, TAA challenge did not result in further induction of UPR effectors except for CHOP expression in Jnk mice compared with Jnk littermates (Figure 5A). However, fiber deposition was induced in both experimental groups upon TAA administration, as observed by SR staining (Figure 5B,C). Interestingly, a differential pattern of collagen deposition (SR staining), was observed in the livers of Jnk and Jnk mice. While TAA-induced bridging fibrosis in Jnk livers, the hepatic parenchyma of Jnk livers displayed peribiliary-like fibrosis (Figure 5B). αSMA levels were evaluated by IF staining and Western blot (Figure 5D,E). Compared with Jnk mice, activated fibrotic response area was enhanced in Jnk mice (Figure 5C). Consistently, αSMA protein expression was strongly induced in Jnk livers, particularly after TAA challenge (Figure 5E). These results suggest that loss of Jnk1/2 function in hepatocytes promotes exacerbated liver fibrosis.

Figure 5

TAA challenge exacerbates liver fibrogenesis in mice with hepatocytic deletion of Jnk1/2. (A) The expression of BiP/GRP78, CHOP, spliced XBP1 (sXBP1) and unspliced XBP1 (uXBP1) was evaluated in the livers of Jnk and Jnk mice treated or not with TAA using Western blot. Numbers denote molecular weight (KDa) of proteins. GAPDH served as loading control. (B) Representative Sirius Red (SR) stainings of liver paraffin sections from control and TAA-treated Jnk and Jnk mice (n = 6-8 mice per group). Scale bars, 500 μm. (C) Expression of αSMA protein was assessed via IF staining. Scale bars, 50 μm. (D) Positive area of fibrosis was calculated by ImageJ with microphotographs of SR staining. Data were represented as the mean ± SEM and graphed. (E) Expression of αSMA was analyzed by Western blot in the indicated groups of mice. Numbers denote molecular weight (KDa) of proteins. GAPDH served as loading control. (# p < 0.05; ** p < 0.01; ***/### p < 0.001; ****/#### p < 0.0001).

3.6. Jnk∆hepa Mice Display Extensive Hepatocellular Injury in Response to TAA

Given that TAA supplementation caused a strong induction of liver fibrosis in mice with hepatocytic deletion of Jnk1/2, we next sought to evaluate the hepatotoxic response to TAA in our experimental groups. TUNEL staining was performed to detect cell death. Microphotographs and data quantification indicated that TAA significantly induced cytotoxicity in both Jnk and Jnk animals. However, apoptotic cell death was exacerbated in Jnk compared with Jnk livers (Figure 6A,D). Concomitant analysis of cell proliferation using Ki67 indicated that compensatory cell proliferation in response to TAA-induced cell death occurred in both Jnk and Jnk animals. Nevertheless, this response was significantly elevated in Jnk compared with Jnk livers (Figure 6B,E). Moreover, the frequency of mitotic figures was significantly increased in TAA-treated Jnk compared with Jnk livers (Figure 6F).

Figure 6

Jnk mice display extensive hepatocellular and cholangiocellular injury in response to TAA. (A) Cell death was evaluated using TUNEL staining of liver tissue sections from TAA-treated Jnk and Jnk mice. Arrows (→) indicate TUNEL positive cells. Scale bars, 50 μm. (B) Expression of Ki67 was evaluated by IF staining. Scale bars, 50 μm. (C) Liver histopathology was analyzed by H&E staining in each experimental group. Positive TUNEL (D), Ki67 cells (E) and frequency of mitotic figures (F) were analyzed by ImageJ and graphed. (G–J) Analysis of serum levels of ALT, AST, ALP and LDH was assessed. Data were represented as the mean ± SEM and graphed (n = 5–13 mice per group; # p < 0.05; ## p < 0.01; *** p < 0.001; ****/#### p < 0.0001).

Histological examination of the livers by H&E staining was performed in both Jnk and Jnk livers. Hepatocellular damage and infiltration of inflammatory cells were prominent in TAA-treated Jnk mice, compared with vehicle-treated animals. Lesion areas in TAA-treated Jnk mice presented a prominent acinar pattern, combined with cytologic atypia (Figure 6C). However, in Jnk mice, cells in the lesion area were characterized by strong mitosis accompanied by multiple ductular dilations. At the same time, the ductular dilations and mitotic figures in the lesion areas of TAA-challenged Jnk mice were significantly different, compared with the structural characteristics of spontaneous cystic dilatations of the ductular tracts in the vehicle-treated group (Figure 6C). Consistently with the enhanced apoptotic and proregenerative (Ki67 labeling) responses found in TAA-treated Jnk mice, increased circulating levels of ALT, AST, AP and LDH, markers of hepatocellular and biliary injury were detected in these animals (Figure 6G–J).

3.7. Chronic TAA Administration Triggers Cellular Atypia and Markers of Cholangiocarcinogenesis in Jnk∆hepa Mice

As shown above, loss of Jnk1/2 in hepatocytes gradually triggers the formation of biliary hamartomas accompanied by the development of ER stress, activation of the UPR, and fibrosis and hepatocellular injury responses, which were enhanced by TAA administration. Since CHF patients have increased risk for CCA [29], we sought to investigate whether carcinogenesis was also enhanced by TAA in our experimental setting. After 24 weeks of TAA administration (Supplementary Figure S7A), no significant differences were observed in the LW/BW ratio between TAA-treated Jnk and Jnk animals (Supplementary Figure S7B–E). However, the number and diameter of nodules observed in the liver surface was significantly higher in Jnk mice (Supplementary Figure S7F,G).

In view of this, we next evaluated by IHC analysis the expression of typical markers of oval cells and biliary epithelium, including CK19, SOX9, and MUCIN2. While CK19, SOX9 and MUCIN2 were prominent in untreated Jnk livers, TAA strongly induced their expression compared with Jnk animals. Analysis of the mRNA expression of Yap1 and Ck19 confirmed the enhanced upregulation of biliary proliferation markers [30] induced in the TAA-treated Jnk mice (Figure 7D,E). Moreover, the percentage of SOX9 and MUCIN2-positive cells per HPF20X were significantly increased in TAA-treated Jnk compared with Jnk mice (Figure 7F,G). Moreover, immunoblotting for CK19 validated the previous observations (Figure 7H). Altogether, markers of cholangiocyte/BECs were strongly activated after treatment with TAA in Jnk livers.

Figure 7

Figure 7. Markers of cholangiocarcinogenesis in Jnk mice livers upon chronic TAA challenge. (A–C) Representative IHC staining for CK19, SOX9 and MUCIN2. Scale bars, 100 μm. (D,E) mRNA expression of Yap1 and Ck19, was evaluated by qRT-PCR. Quantification of Sox9 and Mucin2 positive cells/HPF (20X) was performed in the same livers. Percentage of SOX9 (F) and MUCIN2 (G) positive cells was performed in HPF (20X) in liver paraffin sections and graphed. (H) Expression of CK19 protein was assessed via Western blot. Numbers denote the molecular weight (KDa) of proteins. GAPDH served as loading control. (n = 6; */# p < 0.05; **/## p < 0.01; *** p < 0.001; ****/#### p < 0.0001).

3.8. Hepatotoxin-Challenged Jnk∆hepa Mice Develop Fibrocystic Liver Disease and CCA in Association with a Strong UPR Activation: Therapeutic Potential of an Innovative Epigenetic Inhibitor

So far, our findings reveal that Jnk mice spontaneously develop hepatic histological and molecular traits indicative of liver injury, fibrosis and a remarkable cystogenesis accompanied by early activation of the UPR. This sequence of events can be accelerated and enhanced by the chronic administration of the hepatotoxin and carcinogen TAA, which also hastens the emergence of markers of CCA development, as seen above. We recently described that when Jnk mice are treated with a single dose of the carcinogen diethylnitrosamine (DEN), and then chronically challenged with CCl4 (DEN/CCl4 model), instead of hepatocellular carcinomas, these animals develop cyst-like structures with molecular features compatible with cholangioma and malignant CCA [1,17], including upregulated expression of NOTCH1, GS and markers of oval cells (Ck19, Sox9, Yap1 mRNA), as well as increased proliferation measured as Pcna mRNA levels (Supplementary Figure S8A–I), similar to those observed now in response to TAA. In view of this, and of the recognized risk of CCA development in patients with fibrocystic liver diseases, including CD [13,31,32], it was important to provide conclusive evidence of the malignant nature of the lesions developed in these mice. To this end, liver tissue lesions that emerged in Jnk mice after DEN/CCl4 treatment (Supplementary Figure S8A) were resected and orthotopically implanted in nude mice, as previously described [19] (Figure 8A). Mice were followed up and sacrificed 28 weeks after orthoallografts implantation. As shown in Figure 8B, all mice harbored tumoral lesions. Moreover, the engrafted implants displayed histological features resembling those found in TAA and DEN/CCl4 treated Jnk mice livers, compatible with malignant CCA. Histopathological examination revealed that lesions were constituted as glandular and canalicular with cuboidal epithelium and moderate cytologic atypia. All tumors show expansive margins of growth (Figure 8C).

Figure 8

Lesions developed in DEN/CCl4 treated Jnk∆hepa mice are malignant and display CCA histological features. (A) Lesions developed in DEN/CCl4 treated Jnk∆hepa mice were excised and orthotopically implanted in nude mice (n = 9), which were sacrificed and analyzed 28 weeks later. (B) Macroscopic aspect of livers from recipient mice after orthotopic implantation of lesions from DEN/CCl4 treated Jnk∆hepa animals. (C) H&E stainings of representative tissue sections of orthoallografts growing in the livers of recipient animals. Scale bars, 50 (left panels) and 200 (right panels) µm, respectively.

We previously showed that by 32 weeks of age, Jnk mice develop spontaneous liver injury and an UPR (Figure 1, Figure 2 and Figure 4). These features were still not evident in 22-week-old mice (Figure 9A). However, when subjected to the DEN/CCl4 challenge (as described in Supplementary Figure S8A), 22-week-old Jnk mice developed strong activation of the UPR (Figure 9B) and a potent cystogenic and fibrogenic response (Figure 9C). We recently described that the malignant progression of CCA-like lesions in DEN/CCl4 treated Jnk mice can be inhibited by the administration of CM272, a novel epigenetic drug that simultaneously targets the histone methyltransferase G9a and DNA-methyltransferase 1 (DNMT1) [17]. Interestingly, CM272 administration, as described in Supplementary Figure S9A, markedly reduced the expression of UPR effectors (Figure 9B) and significantly attenuated the fibrogenic and cystogenic responses (Figure 9C). Most interestingly, CM272 treatment also reduced the levels of NOTCH1 and MUCIN2 and downregulated Yap1, Jag1 and Hey1 mRNA transcripts, which were induced in the livers of DEN/CCl4-treated Jnk mice (Supplementary Figure S9B,C).

Figure 9

DEN/CCl4 challenge in Jnk mice results in the activation of the unfolded protein response (UPR), cystogenesis and fibrosis in the liver: inhibitory effect of targeting the epigenetic G9a/DNMT1 complex. (A) mRNA expression levels of sXbp1, uXbp1, Bip/Grp78 and Chop evaluated by qRT-PCR in the livers of 22-week-old Jnk and Jnk mice. (B) Expression of CHOP, BIP/GRP78 and sXBP1 proteins as assessed by Western blot in Jnk control mice (Vehicle), DEN/CCl4-challenged mice and DEN/CCl4-challenged mice treated with the G9a/DNMT1 inhibitor CM272. Numbers denote the molecular weight (KDa) of proteins. GAPDH served as loading control. Representative images are shown. Bands were quantitated and Vehicle vs. DEN/CCl4 samples, and DEN/CCl4 vs. DEN/CCl4 + CM272 groups were respectively compared. (C) Fibrosis was evaluated by Sirius Red (SR) staining in Jnk mice treated as indicated. Scale bars, 500 μm. Quantification of SR areas using ImageJ was performed. Data are represented as the mean ± SEM (n = 5–7 mice per group, ** p < 0.01; *** p < 0.00,**** p < 0.0001).

4. Discussion

Fibropolycystic disease is an umbrella term that comprises a spectrum of conditions of the intrahepatic bile ducts, characterized by different histological and clinical findings within the liver and other organs.

We were the first to report that mice with disruption of JNK1/2, hepatocyte specific for JNK1, and systemic JNK2 deletion exhibited bile duct hyperplasia at late stages of age progression. Moreover, combined genetic JNK1- and siRNA-JNK2-mediated hepatocyte-specific deletion also caused hepatic cystogenesis [1]. In the present study, we generated Jnk mice by combining Alb-Cre with Jnk1Jnk2LoxP mice. The cyst phenotype has been also observed with the Alfp-Cre promoter, revealing that progressive biliary cysts development is independent of the Cre line [7].

Interestingly, our results indicated that the observed phenotype was strongly associated with elevated collagen synthesis and extracellular matrix deposition with activation of HSCs. This is a relevant observation, since patients with Caroli syndrome (CS) present hepatic fibrosis, and therefore, the Jnk model might be relevant for this relatively understudied disease.

CS is usually diagnosed in early infancy or during childhood, with an estimated incidence rate of 1 in 10,000 to 20,000 live births [33]. Apart from biliary changes, patients with CS exhibit portal fibrosis and inflammation. Jnk mice from 32 weeks of age and after showed prominent periportal and/or bridging fibrosis, as well as infiltration of immune cells. The phenotype of JNK-hepatocyte knockout mice was characterized by spontaneous liver injury in all 52- and 72-week-old mice. At one year of age, Jnk animals had significantly increased serum transaminases, LW/BW ratio and exhibited prominent cystogenesis. Moreover, cell death and compensatory proliferation were remarkable in Jnk mice. However, the nature of cell death remains unclear. In order to understand whether apoptosis or necrosis contributed to biliary proliferation of Jnk mice, Muller and colleagues [7] additionally deleted Caspase-8, Mlkl and Ripk1 by creating triple knockout mice. Only deletion of Ripk1 prevented cyst formation. Unfortunately, the interaction and functional relevance of Ripk1 and Jnk in this process need to be further studied. However, in the same study, the authors detected RIPK1 expression in biliary epithelial cells of cystically dilated bile ducts of patients with Caroli disease/syndrome (with additional congenital hepatic fibrosis) [7], suggesting that the regulation of JNK1/RIPK1 signaling could be a potential therapeutic avenue for PLD patients.

Emerging evidence implicates ER stress and UPR signaling in a variety of profibrotic mechanisms in individual cell types. For instance, in epithelial cells, ER stress can induce a profibrotic microenvironment by promoting cell death and activating inflammatory signaling pathways and inducing production of profibrotic mediators that promote fibroblast proliferation and myofibroblast differentiation [24].

The ER is a major intracellular organelle that performs multiple physiological functions including protein folding, post-translational modifications, biosynthesis of fatty acids and sterols, detoxification of xenobiotics, and the storage of intracellular Ca2+ [34]. Upon exposure to potential stressors such as drugs, the ER initiates the UPR to restore homeostasis [35]. Specifically important is the ER protein homeostasis, also called proteostasis. A recent publication reported that mutations in genes related to PLD compromise ER proteostasis [12]. While we did not observe changes in sensor proteins of the UPR, including IRE1 or PERK, we observed overexpression of BiP/GRP78 and XBP1 proteins, indicating activation of the UPR effectors in the absence of hepatocytic JNK1/2.

A standard experimental dose of TM (2 mg/kg) induced substantial ER stress in wildtype mice, while robust and exacerbated UPR activation was observed in Jnk mice after TM challenge, as revealed by overexpression of BiP, CHOP and spliced XBP1, and triggered a fibrogenic response related to cellular injury and compensatory proliferation. To further relate the profibrogenic response to UPR activation and spontaneous liver injury in the absence of hepatocytic JNK1/2, we next challenged Jnk mice with the profibrotic drug TAA, which causes peribiliary fibrosis [36]. Interestingly TAA administration triggered a more robust UPR activation in Jnk animals associated with increased activation of αSMA expression. Moreover, TAA triggered cellular atypia and mitotic figures, as well as centrilobular necrosis in floxed mice. Jnk animals exhibited strong cholangiocellular injury, as well as significantly altered makers of liver injury.

CS and other ductular plate malformations are known to be risk factors for hepatobiliary neoplasms and more frequently for CCA [37]. Indeed, a recent multicenter study confirmed a CCA rate of 7.3% in a large series of CD and CS patients [32]. Previous work by the group of Sabio [6] reported that changes in bile acid metabolism of Jnk mice may contribute to cholangiocyte proliferation and hepatoblast maturation, causing bile duct hyperplasia and cholangiocyte injury, which leads to CCA development at late stages. Others did not detect CCA-neoplastic or -dysplastic areas at least at 52 weeks of age [7]. In our hands, progressive expression of markers of hepatoblast differentiation and Notch signaling, which, together with Yap, is a key pathway in cholangiocarcinogenesis [38,39], were detected already in 52-week-old Jnk mice in the absence of neoplastic lesions on their liver surface. Importantly, nodules were visible in the surface of TAA- and DEN/CCl4 Jnk-treated mice livers, as well as the presence of markers of biliary epithelium atypia and cholangiocarcinogenesis, such as the activation of Notch1 and Yap pathways. Malignancy of these tissues was confirmed by orthotopic implantation in athymic NGS mice, also supporting the metastatic potential of the lesions found in chronically injured Jnk mice livers. These results are in agreement with our previous publication using NEMO mice [1], altogether indicating that Jnk livers are sensitive toward CCA development. Interestingly, we also observed that specific inhibition of the epigenetic enzymes G9a and DNMT1, upregulated in human CCA [17] in DEN/CCl4-challenged Jnk mice, markedly reduced the activation of the UPR, indicating the attenuation of the ER stress response. Mechanistically, it is unlikely that G9a inhibition directly results in the abolition of ER stress, as the level of H3K9me3, the chromatin repressive mark to which G9a contributes, is reduced on the promoters of Chop and BiP/Grp78 genes concomitant with their upregulation during ethanol-induced chronic liver injury and ER stress in mice [40]. Inflammatory mediators play a central role in triggering ER stress and the UPR in liver injury and chronic liver diseases [41]. The strong anti-nflammatory effect mediated by G9a/DNMT1 inhibition that we previously described in DEN/CCl4 Jnk mice and other mouse models of chronic liver injury [17,42] might contribute to explain the attenuation of the UPR by CM272 treatment found in the present study. Noteworthy, here, we also observed that CM272 treatment concomitantly reduced the activation of the Notch pathway. This response is consistent with the stimulatory effect of G9a on Notch signaling previously described in endothelial precursor cells [43]. Notch inhibition, together with a potent TGFβ antagonism as we reported [42], may underlie the therapeutic effects of CM272 on liver fibrocystic disease and carcinogenic progression [31,44]. Nevertheless, the detailed mechanisms of CM272-mediated inhibition of the Notch pathway need to be further explored.

5. Conclusions

Our study links ER stress and fibrosis with cholangiocellular injury and cell death in Jnk mice, which are sensitive to CCA development. Therefore, the Jnk model can be a relevant experimental tool for the study of fibropolycystic liver diseases including CS. Our work also identifies potential therapeutic strategies for a group of diseases lacking effective medical treatments.