Activation of the Hippo pathway effector Yap underlies many liver cancers, however no germline or somatic mutations have been identified. Autophagy maintains essential metabolic functions of the liver, and autophagy-deficient murine models develop benign adenomas and hepatomegaly, which have been attributed to activation of the p62/Sqstm1-Nrf2 axis. Here, we show that Yap is an autophagy substrate and mediator of tissue remodeling and hepatocarcinogenesis independent of the p62/Sqstm1-Nrf2 axis. Hepatocyte-specific deletion of Atg7 promotes liver size, fibrosis, progenitor cell expansion, and hepatocarcinogenesis, which is rescued by concurrent deletion of Yap. Our results shed new light on mechanisms of Yap degradation and the sequence of events that follow disruption of autophagy, which is impaired in chronic liver disease.
Hepatocellular carcinoma (HCC) is the third leading cause of cancer-related mortality worldwide1 with a rising incidence attributed to advanced liver disease from multiple etiologies2. HCC develops as a multistep process on a background of chronic liver injury leading to inflammation, stromal activation, fibrosis, and regeneration3. Pathways involved in the malignant transformation of hepatocytes from dysplastic nodules to early stage HCC include oxidative stress responses, deregulation of the protein folding machinery and dedifferentiation with reexpression of fetal genes4,5.
Autophagy, a nexus of metabolic homeostasis in liver is typically impaired during chronic injury, leading to reduced clearance of cellular constituents, and dysregulated mitochondrial and cellular integrity6,7,8. Although reduced autophagy is a feature of chronic liver disease, mechanisms linking autophagy loss to carcinogenesis are not fully clarified1,2,3,4,5,8,9,10,11,12,13.
Autophagy has a dual role in cancer. During tumor initiation autophagy removes damaged organelles and reactive oxygen species to maintain genomic stability and promote oncogene-induced senescence, thereby inhibiting malignant transformation. However, in advanced tumors and metastases autophagy may promote tumor cell survival in low-nutrient conditions and chemotherapy-induced stress14,15.
Autophagy’s role in liver is primarily tumor-suppressive, yet its full activity in hepatocarcinogenesis is unclear. Rodent models with liver-specific deletion of the autophagy-related proteins 5 (Atg5)16 or Atg717,18,19 display hepatic metabolic dysfunction with steatosis, ER stress and marked hepatomegaly and develop benign tumors (adenomas), but not HCCs. Central to this phenotype is signaling by p62/Sqstm1-Keap1-Nrf2, because loss of either p62/Sqstm120 or Nrf2 in autophagy-deficient double knock out mice normalizes liver size16,21 and decreases tumorigenesis in p62/Sqstm1/Atg7 DKO mice18. When autophagy is impaired, the autophagy adaptor protein p62/Sqstm1 accumulates and binds Kelch-like protein 1 (KEAP1), a negative regulator of the oxidative master regulator nuclear factor erythroid 2-related factor 2 (NRF2, NFE2L2). NRF2 stabilization leads to a deleteriously high antioxidative response with induction of downstream targets such as NAD(P)H quinone oxireductase 1 (Nqo1) or gluthathion S-transferase 1 (Gst1) exacerbating liver injury and metabolic reprogramming22. The p62/Sqstm1-Keap1-Nrf2 axis has been thus identified as the pathway linking autophagy inhibition in the liver to hepatomegaly and tumorigenesis. However, the current paradigm does not account for the dramatic tissue remodeling and progenitor cell activation within autophagy deficient livers prior to the onset of cancer.
Yap is the major nuclear effector of the Hippo signaling pathway and mediates organ size control, proliferation, differentiation, and stemness. Yap can be activated by multiple stimuli including DNA damage23, ER stress24, and mechanical/shear stress25, but its inhibition is tightly regulated and includes signaling by the Hippo core kinase cassette26. Yap may also be inhibited by cytoplasmic sequestration by dystrophin–glycoprotein complex27 or Yap/Amot, which can result in the translocation of Yap to the cytoplasm or to cell junctions28,29. Upon its activation, Yap translocates into the nucleus, where it interacts with Tead1–4 as transcriptional co-activators to promote a range of biologic activities, including cell survival, proliferation, polarity, and, most importantly, organ size control30. Liver-specific deletions of Hippo pathway components (e.g., Mst1/2, Sav1, Nf2) or overexpression of Yap, lead to prominent hepatomegaly, progenitor cell expansion and hepatocarcinogenesis31,32,33,34. Ectopic overexpression of Yap in hepatocytes promotes their plasticity, with dedifferentiation to a cholangiocytic phenotype35.
Yap activation is an early event in liver cancer development36. Up to 65% of HCCs harbor dysregulation of the Hippo/Yap pathway, which is associated with a significantly poorer prognosis37,38. Strikingly, despite comprehensive efforts, no germline or somatic mutations have been uncovered39. Thus, mechanisms underlying Yap dysregulation in hepatocarcinogenesis remain obscure.
Here, we identify Yap as an autophagy substrate and as an essential downstream mediator of tissue remodeling, progenitor cell activation and hepatocarcinogenesis in autophagy-deficient livers. Our results shed new light on mechanisms of Yap dysregulation in HCC by implicating impaired autophagy as a potential driver of Yap stabilization and activity. Because autophagy is impaired chronic liver disease, the findings provide a potential basis for enhanced Yap activity associated with hepatocarcinogenesis7,40.
Autophagy maintains hepatic organ size and differentiation
To explore the mechanisms underlying autophagy’s regulation of hepatic growth and tumorigenesis, we generated mice with conditional deletion of Atg7 in hepatocytes (Albumin-CRE:Atg7F/F mice) (Fig. 1a). Consistent with earlier studies18,19,41 mice with liver-specific deletion of the autophagy-related protein 7 (Atg7) displayed massive hepatomegaly with up to 8.5 fold increased relative liver weight compared to CRE negative littermates at 3 months of age (Supplementary Fig. 1A, B, C). By histological analysis, hypertrophic and hyperplastic hepatocytes were prominent with a marked thickening of hepatocyte plates that were composed of at least 2–3 cells instead of single cells based on HE staining and on the pattern of cell membranous staining for β-catenin (Supplementary Fig. 1D, F). Hepatocytes were markedly dedifferentiated based on HNF4α staining (Fig. 1b) and whole liver RNA array analysis in which hepatocyte-specific genes including Albumin, Transthyretin and complement factors (C2, C3) were significantly downregulated (Fig. 1c). Immunostaining showed Epcam+ progenitor cell expansion (Fig. 1d). Blinded histologic scoring demonstrated increased lobular and portal inflammation, steatosis and ballooning (Supplementary Fig. 1E) and significant fibrosis (Supplementary Fig. 1G, H). Hepatocyte proliferative activity was markedly increased as assessed by Ki67 staining and quantification (Supplementary Fig. 1I, J). All Atg7 KO mice developed dysplastic nodules at 8 months, which progressed to HCC at 12 months (Supplementary Fig. 2A, B, C). In contrast to previous reports17, tumors had typical features of HCCs including pseudoglandular transformation, loss of reticulin staining and diffuse Gst1 staining42 (Supplementary Fig. 2D, E).
Autophagy maintains hepatic Hippo tumor suppressor pathway
Yap is a key regulator of hepatocellular fate35, stem cell renewal, and liver size with overexpression or dysregulation of the Hippo/Yap signaling pathway leading to liver outgrowth, progenitor cell expansion and tumorigenesis32,34. We thus analyzed livers of Atg7 KO mice at 3 months and tumors at 12 months of age and found increased cytoplasmic and nuclear Yap (Fig. 1e). consistent with activation of the Hippo pathway effector. Primary hepatocytes isolated from Atg7 KO mice also displayed increased nuclear Yap staining (Supplementary Fig. 3B). Gene set enrichment analysis (GSEA) of the livers’ transcriptome revealed significant enrichment of Yap activation signatures previously identified in Mst1/Mst2 KO mice43 and in human cancer cells44,45 (Fig. 1f). Significant induction of genes associated with Yap activation and Yap target genes was confirmed by gene array (Fig. 1g) and qRT-PCR (Fig. 1h).
To analyze the immediate response to Atg7 deletion, we generated an inducible conditional Atg7 KO mice by crossing Atg7 floxed mice into the tamoxifen-inducible CRE line driven by the Albumin promoter46,47 (Fig. 1i). This model allows for time dependent, hepatocyte-specific gene deletion in adult liver. Immunoblotting of whole liver lysates from tamoxifen-inducible, conditional Atg7 KO mice revealed increased total Yap protein within 7 days post tamoxifen injection, concomitant with effective Atg7 deletion and abrogation of autophagy characterized by reduced conversion of LC3-I to LC3-II (Fig. 1j). In contrast, protein levels of the Yap paralog Taz/Wwtr1 were consistently increased from 14 d (Supplementary Fig. 3D). Immunostaining for Taz/Wwtr1 showed significant staining in non-parenchymal cells rather than hepatocytes (Supplementary Fig. 3E). P62/Sqstm1, a selective autophagy adaptor protein, which accumulates upon inhibition of autophagy7 and which mediates Nrf2 stabilization via Keap121 was increased at 28 days post tamoxifen injection, indicating that the early increase in Yap at d7 is independent of p62/Sqstm1 (Fig. 1j). Quantitative band densitometry showed significantly increased Yap/β-Tubulin and decreased P-Yap/Yap ratios, consistent with Yap activation (Fig. 1k, l).
Yap is degraded by autophagy
The Hippo/Yap signaling pathway contains a highly conserved core kinase cassette which, when engaged, phosphorylates and inactivates Yap by βTrCP-mediated proteasomal degradation38,48. Yap may also be inactivated by sequestration in the cytoplasm27,28,32. Since previous data indicated normal proteasomal activity in autophagy-deficient neurons49 we hypothesized that Yap is degraded by autophagy. To test our hypothesis, we stably infected the murine hepatocyte line AML12 with lentiviral shRNAs (scrambled or shAtg750) and verified Atg7 knockdown by qRT-PCR and immunoblotting (Supplementary Fig. 4A, B, C). shAtg7-AML12 cells displayed increased p62/Sqstm1 typical of autophagy inhibition and increased nuclear Yap localization by immunofluorescence (Fig. 2a), which was also verified by immunoblotting Yap in cytoplasmic and nuclear fractions (Fig. 2b). Gapdh and Nucleoprotein p62 (Nup62) (nuclear Nup62 62 kD, cytoplasmic precursor 61 kD protein)51 served as markers for the respective fractions. We observed increased nuclear Nup62 in shAtg7 cells despite loading equal amounts of protein per lane, however, increased expression of Nup62 and other nucleoproteins have been described to be cell cycle-regulated with increases of Nup62 from G1 to G2/M phase52. Indeed, shAtg7 cells exhibited greater proliferative activity as assessed by [3H]-Thymidine incorporation (Fig. 2c) consistent with nuclear Nup62 increase and Yap-mediated proliferation.
Similarly, shAtg7-AML12 cells transfected with a Tead4-Luciferase reporter35 displayed significantly more luciferase activity compared to controls, consistent with increased Yap activation (Fig. 2d). By cycloheximide chase assay Yap half-life was increased in shAtg7-AML12 cells (Fig. 2e, f) while proteasomal activity was maintained (Supplementary Fig. 4D). We thus tested if Yap is degraded by autophagy. Leupeptin/NH4Cl which inhibits lysosomal degradation including autophagy, further increased Yap protein levels in scram-AML12 cells but not in shAtg7-cells (Fig. 2g), confirming that increased Yap levels in shAtg7-cells are a consequence of reduced lysosomal degradation. Furthermore, Tead4-Luciferase activity was significantly increased in AML12 cells incubated with Leupeptin/NH4Cl compared to cells incubated with vehicle alone (Fig. 2h). In the human hepatocyte line THLE5B53, YAP protein was also increased upon inhibition with the lysosomal inhibitor Leupeptin/NH4Cl or by the macroautophagy inhibitor 3-methyladenine (Supplementary Fig. 4E). Increased YAP protein levels and Tead4-Luciferase activity indicative of YAP activation was also observed in shATG5-THLE5B cells (Supplementary Fig. 4J, K). Combined, these result indicate that YAP activation results from a general deficiency in the autophagy pathway rather than from loss of ATG7 alone.
To confirm that YAP colocalized with lysosomes, THLE5B cells were transfected with YAP-DsRed and incubated with Lyso®TrackerGreen, which enabled tracking of Yap and lysosomes. Incubation with Leupeptin increased the appearance of lysosomes and the colocalization of YAP and lysosomes, indicating lysosomal degradation of YAP (Supplementary Fig. 4F, G). Similarly, THLE5B cells transfected with YAP-DsRed and GFP-LC3 also showed colocalization of YAP and autophagosomes upon Leupeptin/NH4Cl incubation (Supplementary Fig. 4H,I). Finally, endogenous YAP colocalized with autophagosomes in cells transfected with GFP-LC3 (Fig. 2i, j) upon Leupeptin/NH4Cl incubation, further confirming that YAP is degraded by autophagy.
Yap deletion attenuates hepatomegaly and hepatocarcinogenesis
To determine if Yap drives hepatomegaly and hepatocarcinogenesis in Atg7 KO mice, we generated conditional Atg7 and Yap54 double-floxed mice (Atg7F/F, YapF/F) crossed into the tamoxifen-inducible Albumin-CRE line46. The use of this system enabled timed and simultaneous hepatocyte-specific knock out of Atg7 and Yap in adult mouse liver. Control (Atg7F/F, YapF/F) mice, Atg7 KO (ERT2-Alb-CRE:Atg7F/F), Atg7 KO/Yap Het double knock out (ERT2-Alb-CRE:Atg7F/F, YapF/wt), and Atg7/Yap DKO (DKO, ERT2-Alb-CRE:Atg7F/F,YapF/F) mice were sacrificed 7, 14, 28 days, and 12 months after tamoxifen injection (Fig. 3a). Deletion of Atg7 led to an immediate liver outgrowth apparent at 2 weeks after tamoxifen injection, which was significantly attenuated by homozygous deletion of Yap in Atg7/Yap DKO (Fig. 3c; Supplementary Fig. 5A-E) and complete normalization at 12 months (Fig. 3b–d; Supplementary Fig. 6B, C). Immunostaining and quantification for BrdU+ cells demonstrated significantly increased proliferative activity in Atg7 KO mice at 2 weeks, which was attenuated in Atg7/Yap DKO mice (Supplementary Fig. 5F-H). The attenuation in hepatomegaly was proportionate to the number of Yap alleles deleted (heterozygous or homozygous deletion) at 4 weeks and 12 months following tamoxifen administration (Fig. 3d, Supplementary Fig. 5D). Moreover, tumor size and number were significantly decreased in Atg7/Yap het DKO mice and Atg7/Yap DKO mice compared to Atg7 KO at 12 months after tamoxifen administration (Fig. 3b, e, f, Supplementary Fig. 6D, E) thereby identifying Yap as a driver of liver growth and hepatocarcinogenesis when autophagy is impaired.
Deletion of Yap in Atg7/Yap DKO mice reduced hepatocyte size (Fig. 3g–i) and significantly improved portal and lobular inflammation, ductular reaction, steatosis, and fibrosis in Atg7/Yap DKO mice (Supplementary Fig. 6F-H). Restored hepatic differentiation was demonstrated by increased immunostaining for HNF4α and qRT-PCR of whole liver RNA for Albumin (Fig. 3g, j) in agreement with previous findings linking Yap overexpression to hepatic dedifferentiation35,55. In addition, progenitor cell expansion, which is observed with Yap overexpression35 was significantly decreased in Atg7/Yap DKO mice as assessed by immunostaining and qRT-PCR for Cd133, Cd44, and Epcam (Fig. 3g, j).
The p62/Sqstm1-Nrf2 axis is maintained in Atg7/Yap DKO livers
In previous studies the impairment of hepatic autophagy leads to accumulation of p62/Sqstm1, which then stabilizes the transcription factor Nrf2 (NFE2L2, nuclear factor erythroid-2 related factor 2) via Keap1 (Kelch-like ECH associated protein 1) an adaptor of the ubiquitin-ligase complex21. Consequently, liver-specific double knockout of either Atg7 or Atg5 and p62/Sqstm1 or Nrf2 abrogates hepatomegaly and attenuates tumorigenesis in p62/Atg7 DKO mice16,18. Moreover, p62/Sqstm1 has been recently identified as an independent oncogene in liver56. Therefore, we analyzed if p62/Sqstm1-Nrf2-mediated signaling is maintained in Atg7/Yap DKO mice and conversely, if Yap is activated in Atg7/Nrf2 DKO and Nrf2 KO mice. Immunoblotting of whole liver lysates from Atg7 KO mice, Atg7/Yap KO mice, Atg7/Nrf2 DKO, and Nrf2 KO mice57 demonstrated increased Nrf2 and p62/Sqstm1 protein in Atg7 KO and Atg7/Yap DKO, but not in Atg7/Nrf2 DKO or Nrf2 KO (Fig. 4a, b). By qRT-PCR analysis of whole liver RNA, Nrf2 downstream targets (Nqo1, Srxn1) were increased in both Atg7 KO and Atg7/Yap DKO mice consistent with preserved Nrf2 activation (Fig. 4c). These results indicate intact p62/Sqstm1-Nrf2 mediated signaling in Atg7/Yap DKO and establish Yap as a separate driver of HCC in autophagy-impaired livers. Our results point to an important role of Nrf2 in p62/Sqstm1 homeostasis and Yap activation as Atg7/Nrf2 DKO mice exhibited Yap levels comparable to control mice and did not have evidence of p62/Sqstm1 increase. On mRNA level, Yap target genes Cyr61 and Areg were significantly decreased in Atg7/Yap DKO compared to Atg7 KO mice, indicating that loss of Yap is sufficient to decrease Hippo pathway target gene expression despite Taz/Wwtr1. This finding is consistent with reports that Yap inactivation likely has a greater impact on cellular physiology than Taz/Wwtr158.
Yap is a potentially druggable driver of HCC in Atg7 KO
To assess if Yap-dependent proliferation in autophagy-impaired livers (Supplementary Fig. 5G, H) is targetable, we tested the effect of verteporfin, a small molecule Yap-Tead4-inhibitor59 in culture and in vivo. Verteporfin has also been shown to be safe in phase I/phase II clinical trials60. In vivo, treatment of Atg7 KO mice with verteporfin for 21 days significantly decreased the number of Ki67+ nuclei in Atg7KO mice (Fig. 5b, c), which was also associated with reduced expression of the Yap target gene Cyr61 (Fig. 5d). In cultured scram- and shAtg7-AML12 cells, verteporfin significantly decreased proliferative activity (Fig. 5e). Similarly, verteporfin significantly diminished Tead4-Luciferase activity in scram- and shAtg7-AML12 cells (Fig. 5f).
Atg7-KO gene signature aligns with human NASH and HCC profiles
To analyze the relevance of our findings to human liver disease and hepatocarcinogenesis, we defined a Atg7-KO gene signature (differentially expressed genes in liver tissues from Atg7-KO mice compared to control mice) and compared it to the transcriptome profile of 72 human non-alcoholic fatty liver disease (NAFLD) liver tissues with known disease severity. GSEA analysis showed significant enrichment of the Atg7-KO gene signature in NAFLD samples that were comprised primarily of samples from advanced NAFLD (F3 or F4), along with enrichment for YAP target genes (Fig. 6a). Similarly, analysis of 374 human HCC transcriptome profiles indicated simultaneous enrichment of the Atg7-KO gene signature and YAP activation in 42.2% (158/374) of HCCs as well (Fig. 6b). Integrative transcriptomic analysis of HCCs has indicated that these tumors may be classified according to three molecular subclasses, S1, S2, and S361. Interestingly, HCC subclass S1, which is characterized by steatohepatitic HCCs, a histological subtype which arises in NAFLD/NASH62 and immune cell infiltration63, was significantly enriched for the Atg7-KO gene signature, whereas subclass S3 had no such alignment with the autophagy-deficient signature. Immunofluorescence analysis of human HCCs with known molecular subclass showed nuclear YAP staining and enhanced cytoplasmic staining for p62/SQSTM1 within the same cells (Fig. 6c), indicating that impaired autophagy flux and concomitant YAP activation occur in human disease.
By utilizing a regulable hepatocyte-specific promoter to analyze Atg7−/− mice, we have uncovered autophagy as the gatekeeper of hepatic differentiation, growth regulation and carcinogenesis by controlling degradation of Yap. Hepatocyte-specific Atg7−/− mice display enhanced Yap target gene expression and increased Yap protein that drives hepatocyte proliferation, leading to gross hepatomegaly. These abnormalities are significantly attenuated by heterozygous and homozygous loss of Yap allele(s) in Atg7/Yap Het and Atg7/Yap DKO double knockout mice. Thus, Yap is a driver of tissue remodeling and carcinogenesis when autophagy is impaired.
Dysregulation of liver growth regulation in Atg7 KO mice is due to increased cell size (hypertrophy) and Yap-dependent increase in cell number (hyperplasia). Hepatomegaly in Atg7 KO mice was previously attributed to accumulation of non-degraded cell components including proteins, lipids and damaged organelles17,18,41. However, our data demonstrate that inhibiting Yap-mediated hepatocyte proliferation and hyperplasia in Atg7/Yap DKO mice can significantly attenuate the increased liver size and significantly decrease tumorigenesis.
Unlike previous studies20,21 the dramatic phenotype consequences of autophagy loss in liver occurs independent of p62/Sqstm1-KEAP1-NRF2 signaling in our study. p62/Sqstm1 stabilizes Nrf2 by negatively regulating Keap1, thereby abrogating polyubiquitination and proteasomal degradation of Nrf221; this stabilizes Nrf2 and allows its nuclear translocation. In previous studies, Atg7/p62 (Alb-CRE:Atg7F/F, p62−/−) and Atg7/Nrf2 (Mx1-CRE:Atg7 Atg7F/F, Nrf2−/−) double knock-out mice reportedly rescue the dramatic liver phenotype, associated with a significant decrease in ubiquitinated proteins consistent with improved proteostasis despite inhibition of autophagy18,21. In Atg7/p62 double knock-out mice there is decreased tumorigenesis in aged Atg7/p62 DKO animals. Thus, the contribution and relationship of p62/Sqstm1, Nrf2, and Yap in the context of autophagy impairment to liver injury, liver growth regulation and hepatocarcinogenesis remains to be clarified. p62/Sqstm1 is an independent oncogenic driver in AAV-p62/Sqstm1-infected hepatocytes through oncogenic effects of mTOR and Nrf2 signaling. In contrast, Atg7/Yap double knock-out significantly attenuates hepatocarcinogenesis despite increased expression of p62/Sqstm1 and Nrf2, and Nrf2 downstream targets. Thus, Yap is a significant driver of hepatocarcinogenesis when autophagy is impaired. However, tumorigenesis was not completely abrogated in Yap/Atg7 double knock-out mice and the remaining tumorigenesis could be due to p62/Sqstm1-Nrf2 signaling. A contribution of the Yap paralog Taz/Wwtr1 cannot be excluded, however immunostaining demonstrates an increase in Taz/Wwtr1 in non-parenchymal cells, and qPCR analysis showed significant decrease in Hippo downstream targets Cyr61 and Areg, indicating efficient suppression of Yap/Taz targets in Atg7/Yap DKO mice.
Autophagy is clearly a tumor-suppressive pathway in our models. In previous studies autophagy has been ascribed a bifunctional role in tumorigenesis—tumor suppressive in the initial phase and tumor promoting in advanced stages8. Previously, tumors in hepatic Atg7 KO mice have been described as benign adenomas17; however, tumors in ERT2-Alb-CRE:Atg7F/F and Alb-CRE:Atg7F/F mice fulfill characteristics of HCCs. Differences in the genetic background and microbial environment might contribute to the observed phenotypic differences between ours and previous studies, as the microbiome can affect hepatocarcinogenesis, but future studies will need to clarify the underlying mechanisms.
Our results provide an important link between metabolic alterations and mechanisms for Yap activation in hepatocarcinogenesis. With the epidemic of obesity and metabolic syndrome, hyperlipidemia and insulin resistance are frequently observed concomitant to chronic viral hepatitis and NASH2 and have been shown to decrease hepatic autophagic and lysosomal degradation40. Comprehensive integrative molecular analyses (transcriptomic, genomic and epigenomic data) as well as immunological analyses have provided a molecular and immunological classification of HCCs which can be differentiated into a proliferative (S1 and S2) and non-proliferative class39,64,65,66. Of these, S1 subclass is associated with poor prognosis, chromosomal instability and activation of pathways associated with cell proliferation and survival and immune exhaustion66. Enrichment and alignment of the Atg7 KO gene signature in HCCs of the S1 subclass indicates that metabolic pathways of Yap activation might contribute to this subclass.
Our results have uncovered a mechanism of autophagy-dependent degradation of Yap which, when impaired, promotes dedifferentiation, inflammation, fibrosis, and hepatocarcinogenesis. Because Yap activity is strongly implicated in human hepatocarcinogenesis, our studies provide a rationale for chemopreventive or anti-tumorigenic strategies through inhibition of Yap or enhancement of autophagy by drugs such as verteporfin60 or carbamazepine, which is currently in phase II trial for α1-antitrypsin deficiency (NCT01379469) and has anti-fibrotic effects in murine disease models67.
Alb-CRE mice (Jax 003574) were purchased from Jackson Laboratory and crossbred with conditional Atg719. Nrf2−/−21 were crossed with Alb-CRE:Atg7F/F to generate Atg7/Nrf2 DKO mice. ERT2-Alb-CRE mice46 crossed with conditional Atg719 and/or, conditional Yap mice54,21mice were utilized in this study. Age-matched, male and female mice were used and did not show sex-bias differences. ERT2-Alb-CRE mice (6–8 weeks) and respective controls were given 0.1 mg tamoxifen (Sigma) (diluted in corn oil) for 5 consequential days. Verteporfin (Sigma) diluted in DMSO and injected i.p. (50 mg kg−1) every other day for 21 days. All animal studies and procedures were approved by the Animal Care and Use Committee of Icahn School of Medicine at Mount Sinai.
For immunohistochemistry, liver samples were fixed in 10% formalin overnight, transferred to 70% ethanol and processed for paraffin embedding. For immunostaining, samples were deparaffinized and heat induced antigen retrieval performed with either 10 mM sodium-citrate, pH 6 or Tris-EDTA, pH 9 or DAKO target retrieval solution (Dako, S2375) depending on the antigen. Chromogen development after incubation with primary and secondary antibodies was performed using the Dako Envision Kit (Dako). For immunofluorescence studies, AML12 cells, THLE5b cells or primary murine hepatocytes were grown on coverslips, fixed with acetone or 50% acetone/50% methanol for 10 min and rehydrated in PBS. Liver sections from either 4% PFA-perfused livers and sequential sucrose-cryopreservation were analyzed, fixed with acetone, or 50% acetone/50% methanol or 4% PFA depending on the antigen, washed and incubated with primary antibodies overnight. After washing, cells were incubated with secondary antibodies, embedded and imaged. Primary antibodies and secondary antibodies with dilutions are indicated in Supplementary Table 1. Reticulin staining was performed with the Hito Biotek Kit (HTKCS0102) according to the manufacturer’s instructions. For Sirius Red staining, FFPE-slides were deparaffinized, incubated for 15 min in 0.01% fast green in picric acid, washed and then incubated in 0.04% fast green 0.1% Sirius red in picric acid for 45 min. After washing and dehydration, slides were embedded, dried, and imaged. For quantification of Ki67+ hepatocytes, ten fields per mouse were imaged and analyzed. For histological scoring, slides were analyzed by a liver pathologist (MIF) in a blinded manner and graded (0–3 points) analyzing five 200x fields per mouse. Images were analyzed with a Zeiss Axiovision microscope. For confocal live imaging, cells were grown on a glass bottom plate, transfected with Yap-DsRed (addgene 19057) by Lipofectamine 2000 (Roche) and incubated with 100 nM LysoTracker®Green DND-26 (ThermoFisher L7256) in complete medium with 100 µM Leupeptin or vehicle for 2 h prior to imaging. For coimmunofluorescence, cells were transfected with GFP-LC3 via Lipofectamine 2000 (Roche) and incubated with 100 µM Leupeptin/20 mM NH4Cl or vehicle for 2 h prior to imaging. Microscope was performed at the Microscope CoRE at the Icahn School of Medicine at Mount Sinai.
Morphometric quantitative analysis of cell size and nucleus size from liver sections was performed by ImageJ analysis. Two hundred ten to 270 cells per genotype (n = 3) were analyzed and plotted by frequency distribution analysis (Prism 7). Colocalization analysis was performed by ImageJ analysis software (plugin JACoP v2).
Cytoplasmic and nuclear fractionation
For cytoplasmic and nuclear fractionation, AML12 cells were grown to 100% confluency, washed twice with ice-cold PBS and incubated with buffer A (10 mM HEPES, 10 mM KCl, 0.1 mM EDTA, 0.1 mM EGTA, pH 7.9, PMSF 50 µg ml−1, Na-Orthovanadate 1 mM, DTT 1 mM, NP-40 (0.6%), HALT-Phosphatase inhibitor (Thermoscientific) 1:1000, complete Protease-inhibitor tablet (Thermoscientific)) on ice for 15 min. Cells were collected and centrifuged for 5 min at 14,000 × g. Supernatant (cytoplasmic fraction) was collected and saved. The pellet was processed further for nuclear extraction by washing with buffer A without NP-40, followed by resuspension in buffer C (10 mM HEPES, 0.4 mM NaCl, 1 mM EDTA, 1 mM EGTA, pH 7.9, PMSF 50 µg ml−1, Na-Orthovanadate 1 mM, DTT 1 mM, NP-40 (0.6%), HALT-Phosphatase inhibitor (Thermoscientific) 1:1000, complete Protease-inhibitor tablet (Thermoscientific)) and incubation on ice for 15 min, vortexing every minute. Fraction was centrifuged at 14,000 × g for 8 min and supernatant (nuclear fraction) collected.
Fifty micrograms of snap frozen liver were homogenized by Qiagen TissueLyser in RIPA buffer containing proteinase inhibitors (Roche complete Mini proteinase inhibitor, 2 tab/10 ml buffer) and 1x HALT phosphatase inhibitors (Thermoscientific, #78428). Lysates were sonicated and then centrifuged for 10 min at 18,800 × g. THLE5B and AML12 cells were lysed directly in RIPA buffer containing inhibitors, sonicated and centrifuged. Protein concentration of supernatants were determined by BioRad protein assay (BioRad). For immunoblot analysis, 30–50 µg of protein were analyzed per SDS-PAGE and tank blotting. Antibodies and dilutions used are indicated in Supplementary Table 1. Semi-quantitative band densitometry was performed using ImageJ software. Uncropped scans of blots are provided in the Supplementary Information.
Hepatocyte isolation and cell culture
The AML12 cell line was obtained from ATCC (CRL2254) and the THLE5b cells had been obtained from Dr. Yujin Hoshida. The THLE5b cells have been authenticated by short-tandem repeat (STR) profiling. Cell lines were tested for mycoplasma with the Venor GeM Mycoplasma Detection Kit (Sigma, MP0025-1KT) according to the manufacturer’s instructions. AML12 cells were cultured in DMEM/F12 medium supplemented with insulin/transferrin/selenium (Invitrogen 51300-044), 40 µg ml−1 Dexamethasone (Sigma D2915) and 10% FBS. AML12 cells were infected with lentiviral shAtg7 or scrambled-shRNA50 and stable clones selected with puromycin (1.25 µg ml−1). Upon establishing stable clones, cells were maintained without puromycin and stable knock down of Atg7 verified over several passages. THLE5B68 cells were cultured in DMEM medium supplemented with 10% FBS and infected with shATG5 or scrambled-shRNA (Santa Cruz, sc-41445 and sc-108080, respectively) according to the manufacturer’s instructions. Stable clones were selected with puromycin. Primary hepatocytes were isolated by in situ perfusion with Liver Perfusion Medium (Thermo Scientific, 17701038) followed by collagenase B perfusion (Roche, 11088831001, 0.05%) and low grade centrifugation (50 × g). Hepatocytes were plated on collagen-coated plates (BD Biosciences, 354249) at 1 mio cells/6-well and cultured in Williams E medium (10% FBS, 1% L-glutamine, 1% penicillin/streptomycin, hydrocortisone (50 µM), insulin (5 µg ml−1)). Cells were incubated in verteporfin (Sigma SML0534, 10 µg ml−1 final concentration), cycloheximide (Enzo Life Sciences, 50 µM final concentration) or the respective vehicles (polyethylene glycol 300 (PEG 300) or DMSO respectively).
AML12 and THLE5B cells were transfected at 70% confluency using Mirus TransIT-LT1 transfection reagent and analyzed at 100% confluency to control for cell-contact mediated inhibition of Hippo pathway by Dual-Glo Luciferase Assay (Promega). pRL-Tead4-Luciferase and Renilla control plasmid were gifts of Yimlamai and Camargo35. Incubation with verteporfin (10 µg ml−1) or vehicle (PEG300) were carried out for 24 h.
Cycloheximide chase assay
AML12 cells were incubated at 90% confluency in complete growth media containing the protein synthesis inhibitor cycloheximide (Enzo Life Sciences) (50 µM final concentration) or vehicle (DMSO). Cells were collected in RIPA buffer (50 mM Tris/HCl, pH 7.4, 150 mM NaCl, 1% Igepal, 0.5% Na-Deoxycholate, 0.1% SDS) containing proteinase inhibitors (ThermoScientific Protease-Inhibitor tablets, 2 tablet/10 ml buffer) at 0, 2, 4, 6, 8, and 24 h after incubation. The lysate was sonicated, centrifuged for 10 min at 18,800 × g and the resulting supernatants analyzed by immunoblotting.
Proteasomal activity assay
AML12 cells were incubated in cell lysis buffer (50 mM HEPES, pH 7.5; 5 mM EDTA, 150 mM NaCl and 1% Triton X-100) for 30 min on ice, vortexing every 10 min. Lysates were centrifuged at 20,600 × g for 15 min. Protein concentration of the supernatant was determined via Biorad Protein Assay. Protein lysates (10 µg) were diluted with 10x assay buffer (250 mM HEPES (pH 7.5), 5 mM EDTA, 0.5% NP-40, 0.01% SDS) and samples incubated with proteasome substrate at 37˚C for 90 min. Concentration of proteasome substrates were 100 µM for caspase-like activity (Ac-Gly-Pro-Leu-Asp-AMC, Biomol, AW9560), 10 µM for chymotrypsin-like activity (Proteasome substrate III, Calbiochem, #539142) and 100 µM for trypsin-like activity (Biomol, AW 9785). Release of free hydrolyzed 7-amino-4-methylcoumarin (AMC) groups was measured using an ISS Counter with an excitation filter of 380 nm and an emission filter of 460 nm.
qRT-PCR and primer sequences
For qRT-PCR analysis, RNA was extracted from snap frozen liver or cells by Trizol (Ambion) followed by purification using the RNeasy Kit (Qiagen). One to 5 µg RNA were transcribed to cDNA using the RNA to cDNA EcoDry Premix (Clontech). IQ SYBR Green Supermix (Biorad) was used for quantitative PCR on the LightCycler480 System (Roche Diagnostics). Samples were analyzed in triplicates. Data are represented as the relative expression after normalizing to housekeeping genes (Gapdh, β-actin, 18S, Tbp) expression, respectively. Primer sequences are listed in Supplementary Table 2.
Gene expression analysis
Liver tissue was incubated in RNAlater (Ambion) and RNA extracted by Trizol (Ambion) according to the manufacturer’s instructions, and further purified by the RNeasy Kit (Qiagen). RNA from 2 month old, female and male, age-matched Alb-CRE:Atg7F/F and CRE-negative littermates (n = 4 per group) were analyzed on a MouseWG-6 v2.0 Expression BeadChip according to the manufacturer’s protocol. Raw scanned data were normalized by using cubic spine algorithm implemented in the GenePattern genomic analysis toolkit (www.broadinstitute.org/genepattern). Probe-level expression data were collapsed into gene-level by calculating the median of multiple probes, and converted to human genes based on an orthologous mapping table provided by the Jackson laboratory (www.informatics.jax.org). Gene expression analysis was determined by R software and expressed as row z-score.
Bioinformatics and statistical data
Molecular pathway deregulations were determined in the genome-wide transcriptome dataset by surveying a comprehensive collection of pathway gene sets in Molecular Signature Database (MSigDB, www.broadinstitute.org/mdigdb) and a collection of liver cancer-related gene signatures in literature using Gene Set Enrichment Analysis (GSEA, www.broadinstitute.org/gsea).
Transcriptome profiles of 72 NAFLD-affected liver tissues were obtained from NCBI Gene Expression Omnibus database (www.ncbi.nlm.nih.gov/geo, accession number GSE49541). Genome-wide transcriptome profiles of 374 human HCC tissues were obtained from The Cancer Genome Atlas data portal (https://gdc.cancer.gov). Transcriptomic molecular HCC subtypes we were determined using Nearest Template Prediction (NTP) algorithm as previously described61,69. Atg7-KO gene signature was defined as differentially expressed genes in liver tissues from the Atg7-KO mice compared to control mice by t-test-based LOOCV validation (four biological replicates for Atg7-ko and control group, respectively). Transcriptional target genes of Hippo pathway (REACTOME_SIGNALING_BY_HIPPO), transcriptional target genes of Yap1 (CORDENONSI_YAP_CONSERVED_SIGNATURE) were obtained from Molecular Signature Database (MSigDB) (www.broadinstitute.org/msigdb). Modulation of the gene sets in each individual sample was determined by modified gene set enrichment analysis70.
Human HCC samples
Formalin-fixed, paraffin-embedded (FFPE) HCC tissues (n = 8) were analyzed by immunohistochemistry. The de-identified human HCC samples were obtained from Mount Sinai Biorepository with IRB-approved written informed consents from patients. The study had been approved by the Institutional Review Board of Icahn School of Medicine at Mount Sinai.
The Gene Expression Omnibus accession number for the transcriptome profiles reported in this paper is GSE67676. The Gene Expression Omnibus accession number for 72 NAFLD-affected livers is GSE49541. Genome-wide transcriptome profiles of 374 human HCC tissues were obtained from The Cancer Genome Atlas data portal (https://gdc.cancer.gov).
GBD, M. A. C. O. D. C. Global, regional, and national age-sex specific all-cause and cause-specific mortality for 240 causes of death, 1990-2013: a systematic analysis for the Global Burden of Disease Study 2013. Lancet 385, 117–171 (2015).
Mittal, S. et al. Temporal trends of nonalcoholic fatty liver disease-related hepatocellular carcinoma in the veteran affairs population. Clin. Gastroenterol. Hepatol. 13, 594–601.e1 (2015).
Sia, D., Villanueva, A., Friedman, S. L. & Llovet, J. M. Liver cancer cell of origin, molecular class, and effects on patient prognosis. Gastroenterology 152, 745–761 (2017).
Llovet, J. M. et al. A molecular signature to discriminate dysplastic nodules from early hepatocellular carcinoma in HCV cirrhosis. Gastroenterology 131, 1758–1767 (2006).
Wurmbach, E. et al. Genome-wide molecular profiles of HCV-induced dysplasia and hepatocellular carcinoma. Hepatology 45, 938–947 (2007).
Schneider, J. L. & Cuervo, A. M. Autophagy and human disease: emerging themes. Curr. Opin. Genet. Dev. 26, 16–23 (2014).
Ueno, T. & Komatsu, M. Autophagy in the liver: functions in health and disease. Nat. Rev. Gastroenterol. Hepatol. 14, 170–184 (2017).
Czaja, M. J. et al. Functions of autophagy in normal and diseased liver. Autophagy 9, 1131–1158 (2013).
Llovet, J. M. et al. Hepatocellular carcinoma. Nat. Rev. Dis. Prim. 2, 16018 (2016).
Zucman-Rossi, J., Villanueva, A., Nault, J. C. & Llovet, J. M. Genetic landscape and biomarkers of hepatocellular carcinoma. Gastroenterology 149, 1226–1239.e4 (2015).
Lim, J. et al. Proteotoxic stress induces phosphorylation of p62/SQSTM1 by ULK1 to regulate selective autophagic clearance of protein aggregates. PLoS. Genet. 11, e1004987 (2015).
Schneider, J. L. & Cuervo, A. M. Liver autophagy: much more than just taking out the trash. Nat. Rev. Gastroenterol. Hepatol. 11, 187–200 (2014).
Deretic, V. Autophagy: an emerging immunological paradigm. J. Immunol. 189, 15–20 (2012).
Amaravadi, R. K. et al. Autophagy inhibition enhances therapy-induced apoptosis in a Myc-induced model of lymphoma. J. Clin. Invest. 117, 326–336 (2007).
Yang, Z. J., Chee, C. E., Huang, S. & Sinicrope, F. A. The role of autophagy in cancer: therapeutic implications. Mol. Cancer Ther. 10, 1533–1541 (2011).
Ni, H. M. et al. Nrf2 promotes the development of fibrosis and tumorigenesis in mice with defective hepatic autophagy. J. Hepatol. 61, 617–625 (2014).
Inami, Y. et al. Persistent activation of Nrf2 through p62 in hepatocellular carcinoma cells. J. Cell. Biol. 193, 275–284 (2011).
Takamura, A. et al. Autophagy-deficient mice develop multiple liver tumors. Genes Dev. 25, 795–800 (2011).
Komatsu, M. et al. Impairment of starvation-induced and constitutive autophagy in Atg7-deficient mice. J. Cell Biol. 169, 425–434 (2005).
Komatsu, M. et al. Homeostatic levels of p62 control cytoplasmic inclusion body formation in autophagy-deficient mice. Cell 131, 1149–1163 (2007).
Komatsu, M. et al. The selective autophagy substrate p62 activates the stress responsive transcription factor Nrf2 through inactivation of Keap1. Nat. Cell Biol. 12, 213–223 (2010).
Saito, T. et al. p62/Sqstm1 promotes malignancy of HCV-positive hepatocellular carcinoma through Nrf2-dependent metabolic reprogramming. Nat. Comms 7, 12030 (2016).
Basu, S., Totty, N. F., Irwin, M. S., Sudol, M. & Downward, J. Akt phosphorylates the Yes-associated protein, YAP, to induce interaction with 14-3-3 and attenuation of p73-mediated apoptosis. Mol. Cell 11, 11–23 (2003).
Wu, H. et al. Integration of Hippo signalling and the unfolded protein response to restrain liver overgrowth and tumorigenesis. Nat. Commun. 6, 6239 (2015).
Zhong, W. et al. Mesenchymal stem cell and chondrocyte fates in a multishear microdevice are regulated by Yes-associated protein. Stem. Cells Dev. 22, 2083–2093 (2013).
Zhao, B., Tumaneng, K. & Guan, K. L. The Hippo pathway in organ size control, tissue regeneration and stem cell self-renewal. Nat. Cell Biol. 13, 877–883 (2011).
Morikawa, Y., Heallen, T., Leach, J., Xiao, Y. & Martin, J. F. Dystrophin glycoprotein complex sequesters Yap to inhibit cardiomyocyte proliferation. Nature 547, 227–231 (2017).
Zhao, B. et al. Angiomotin is a novel Hippo pathway component that inhibits YAP oncoprotein. Genes Dev. 25, 51–63 (2011).
Moleirinho, S. et al. Regulation of localization and function of the transcriptional co-activator YAP by angiomotin. eLife 6, e23966 (2017).
Li, Z. et al. Structural insights into the YAP and TEAD complex. Genes Dev. 24, 235–240 (2010).
Benhamouche, S. et al. Nf2/Merlin controls progenitor homeostasis and tumorigenesis in the liver. Genes Dev. 24, 1718–1730 (2010).
Dong, J. et al. Elucidation of a universal size-control mechanism in Drosophila and mammals. Cell 130, 1120–1133 (2007).
Lu, L. et al. Hippo signaling is a potent in vivo growth and tumor suppressor pathway in the mammalian liver. Proc. Natl Acad. Sci. USA 107, 1437–1442 (2010).
Camargo, F. D. et al. YAP1 increases organ size and expands undifferentiated progenitor cells. Curr. Biol. 17, 2054–2060 (2007).
Yimlamai, D. et al. Hippo pathway activity influences liver cell fate. Cell 157, 1324–1338 (2014).
Perra, A. et al. YAP activation is an early event and a potential therapeutic target in liver cancer development. J. Hepatol. 61, 1088–1096 (2014).
Sohn, B. H. et al. Inactivation of Hippo Pathway Is Significantly Associated with Poor Prognosis in Hepatocellular Carcinoma. Clin. Cancer Res. 22, 1256–1264 (2016).
Zhao, B. et al. Inactivation of YAP oncoprotein by the Hippo pathway is involved in cell contact inhibition and tissue growth control. Genes Dev. 21, 2747–2761 (2007).
Network, C. G. A. R. Comprehensive and Integrative Genomic Characterization of Hepatocellular Carcinoma. Cell 169, 1327–1341.e23 (2017).
Madrigal-Matute, J. & Cuervo, A. M. Regulation of liver metabolism by autophagy. Gastroenterology 150, 328–339 (2016).
Singh, R. et al. Autophagy regulates lipid metabolism. Nature 458, 1131–1135 (2009).
Shafizadeh, N. & Kakar, S. Diagnosis of well-differentiated hepatocellular lesions: role of immunohistochemistry and other ancillary techniques. Adv. Anat. Pathol. 18, 438–445 (2011).
Song, H. et al. Mammalian Mst1 and Mst2 kinases play essential roles in organ size control and tumor suppression. Proc. Natl Acad. Sci. USA 107, 1431–1436 (2010).
Mohseni, M. et al. A genetic screen identifies an LKB1-MARK signalling axis controlling the Hippo-YAP pathway. Nat. Cell Biol. 16, 108–117 (2014).
Cordenonsi, M. et al. The Hippo transducer TAZ confers cancer stem cell-related traits on breast cancer cells. Cell 147, 759–772 (2011).
Schuler, M., Dierich, A., Chambon, P. & Metzger, D. Efficient temporally controlled targeted somatic mutagenesis in hepatocytes of the mouse. Genesis 39, 167–172 (2004).
Sekiya, S. & Suzuki, A. Hepatocytes, rather than cholangiocytes, can be the major source of primitive ductules in the chronically injured mouse liver. Am. J. Pathol. 184, 1468–1478 (2014).
Oka, T., Mazack, V. & Sudol, M. Mst2 and Lats kinases regulate apoptotic function of Yes kinase-associated protein (YAP). J. Biol. Chem. 283, 27534–27546 (2008).
Komatsu, M. et al. Loss of autophagy in the central nervous system causes neurodegeneration in mice. Nature 441, 880–884 (2006).
Singh, R. et al. Autophagy regulates adipose mass and differentiation in mice. J. Clin. Invest. 119, 3329–3339 (2009).
Davis, L. I. & Blobel, G. Identification and characterization of a nuclear pore complex protein. Cell 45, 699–709 (1986).
Chakraborty, P. et al. Nucleoporin levels regulate cell cycle progression and phase-specific gene expression. Dev. Cell 15, 657–667 (2008).
Pfeifer, A. M. et al. Simian virus 40 large tumor antigen-immortalized normal human liver epithelial cells express hepatocyte characteristics and metabolize chemical carcinogens. Proc. Natl Acad. Sci. USA 90, 5123–5127 (1993).
Zhang, N. et al. The Merlin/NF2 tumor suppressor functions through the YAP oncoprotein to regulate tissue homeostasis in mammals. Dev. Cell 19, 27–38 (2010).
Fitamant, J. et al. YAP inhibition restores hepatocyte differentiation in advanced HCC, leading to tumor regression. Cell Rep. 10, 1692–1707 (2015).
Umemura, A. et al. p62, Upregulated during Preneoplasia, Induces Hepatocellular Carcinogenesis by Maintaining Survival of Stressed HCC-Initiating Cells. Cancer Cell 29, 935–948 (2016).
Itoh, K. et al. An Nrf2/small Maf heterodimer mediates the induction of phase II detoxifying enzyme genes through antioxidant response elements. Biochem. Biophys. Res. Commun. 236, 313–322 (1997).
Plouffe, S. W. et al. The Hippo pathway effector proteins YAP and TAZ have both distinct and overlapping functions in the cell. J. Biol. Chem. 293, 11230–11240 (2018).
Liu-Chittenden, Y. et al. Genetic and pharmacological disruption of the TEAD-YAP complex suppresses the oncogenic activity of YAP. Genes Dev. 26, 1300–1305 (2012).
Huggett, M. T. et al. Phase I/II study of verteporfin photodynamic therapy in locally advanced pancreatic cancer. Br. J. Cancer 110, 1698–1704 (2014).
Hoshida, Y. et al. Integrative transcriptome analysis reveals common molecular subclasses of human hepatocellular carcinoma. Cancer Res. 69, 7385–7392 (2009).
Salomao, M., Yu, W. M., Brown, R. S. J., Emond, J. C. & Lefkowitch, J. H. Steatohepatitic hepatocellular carcinoma (SH-HCC): a distinctive histological variant of HCC in hepatitis C virus-related cirrhosis with associated NAFLD/NASH. Am. J. Surg. Pathol. 34, 1630–1636 (2010).
Tan, P. S. et al. Clinicopathological indices to predict hepatocellular carcinoma molecular classification. Liver Int. 36, 108–118 (2015).
Llovet, J. M., Montal, R., Sia, D. & Finn, R. S. Molecular therapies and precision medicine for hepatocellular carcinoma. Nat. Rev. Clin. Oncol. 15, 599–616 (2018).
Hoshida, Y. et al. Molecular classification and novel targets in hepatocellular carcinoma: recent advancements. Semin. Liver Dis. 30, 35–51 (2010).
Sia, D. et al. Identification of an immune-specific class of hepatocellular carcinoma, based on molecular features. Gastroenterology 153, 812–826 (2017).
Hidvegi, T. et al. An autophagy-enhancing drug promotes degradation of mutant a1-antitrypsin Z and reduces hepatic fibrosis. Science 329, 229–232 (2010).
Macé, K. et al. Aflatoxin B1-induced DNA adduct formation and p53 mutations in CYP450-expressing human liver cell lines. Carcinogenesis 18, 1291–1297 (1997).
Hoshida, Y. Nearest template prediction: a single-sample-based flexible class prediction with confidence assessment. PLoS ONE 5, e15543 (2010).
Nakagawa, S. et al. Molecular liver cancer prevention in cirrhosis by organ transcriptome analysis and lysophosphatidic acid pathway inhibition. Cancer Cell 30, 879–890 (2016).
We thank Dr. Dean Yimlamai for critical discussion of the manuscript. Dr. Manjeet Desmukh for HPLC analysis of verteporfin and Jenny Wong for excellent technical assistance. Funding was provided by NIH (RO1DK56621, RO1 AA020709, the US Department of Defense CA150272 and 1P30 CA 196521-01 (S.L.F.) and the German Research Foundation LE 2794/1-1 (Y.A.L), Y.A.L. was also supported in part by grant # UL1TR001866 from the National Center for Advancing Translational Sciences (NCATS), National Institutes of Health (NIH) Clinical and Translational Science Award (CTSA) program. Y.H. received funding from US NIH/NIDDK R01 DK099558, European Union ERC-2014-AdG-671231 HEPCIR, Irma T. Hirschl Trust, U.S. Department of Defense W81XWH-16-1-0363, and Cancer Prevention and Research Institute of Texas RR180016. Funding was provided by the European Union Seventh Framework Program (FP7/2007–2013) grant agreement no. 267248 (L.A.N.), NIH/NIDDK R01 DK103022 (K.N.C.). Fernando Camargo and Dean Yimlamai kindly shared Tead4-Luciferase and renilla constructs. Microscopy was performed at the Microscopy CoRE at the Icahn School of Medicine at Mount Sinai. We thank the Center for Comparative Medicine and Surgery for excellent animal care and Dr. Kevin Kelley for support in vitro rederivation of mice lines.
The authors declare the following competing interests: A.M.C. is co-founder of Selphagy Therapeutics (Boston) and consults for Neuropore (San Diego, CA). S.L.F. was consultant to Vivace Therapeutics. The remaining authors declare no competing interests.
Publisher’s note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
About this article
Cite this article
Lee, Y.A., Noon, L.A., Akat, K.M. et al. Autophagy is a gatekeeper of hepatic differentiation and carcinogenesis by controlling the degradation of Yap. Nat Commun 9, 4962 (2018). https://doi.org/10.1038/s41467-018-07338-z
A Comprehensive Review of Autophagy and Its Various Roles in Infectious, Non-Infectious, and Lifestyle Diseases: Current Knowledge and Prospects for Disease Prevention, Novel Drug Design, and Therapy
International Journal of Molecular Sciences (2019)
Activation of tumor-promoting pathways implicated in hepatocellular adenoma/carcinoma, a long-term complication of glycogen storage disease type Ia
Biochemical and Biophysical Research Communications (2019)
Biomedicine & Pharmacotherapy (2019)
Journal of Hepatology (2019)