Surgical resection and radiofrequency ablation initiate cancer in cytokeratin-19⁺- liver cells deficient for p53 and Rb

INTRODUCTION

Liver cancer is one of the deadliest forms of cancer with approximately 700,000 deaths per year worldwide [1]. Hepatic resection and radiofrequency ablation (RFA) are the treatment of choice, especially for patients with tumors associated with early and severe cirrhosis respectively [2, 3]. However, long-term prognosis after resection or RFA of liver cancer remains unsatisfactory, because of the high recurrence rate [4, 5]. A retrospective study revealed that the 5-year recurrence rates after surgery (n=138) and RFA (n=236) were 53.7% and 69.5% respectively [6].

Many risk factors have been associated with liver cancer including chronic hepatitis B and C viral infection, and basically all cirrhosis-inducing conditions [7]. These etiological exposures are believed to interfere with the cell cycle machinery through inactivating tumor suppressor pathways [8]. Among the pathways that are often disrupted in concert are those regulated by the tumor suppressors p53 and Rb [9–11]. For example, viral proteins derived from Hepatitis B and C viruses have been shown to inactivate p53 as well as Rb in liver cells [12, 13]. Interestingly, liver specific deletion of the Rb gene in mice does not result in spontaneous tumor development [14], whereas deletion of all three pocket proteins (Rb, p107, p130) led to spontaneous liver cancer, indicating compensatory tumor suppressor mechanisms within the pocket protein family [15]. Deletion of p53 in mice is sufficient to cause spontaneous liver cancer [16, 17]. Intriguingly, liver-specific deletion of both p53 and Rb did not result in spontaneous liver cancer in mice aged to one year. However, in response to diethylnitrosamine (DEN), tumors started to develop at the age of three months [17, 18].

Previous studies in humans demonstrated that events that lead to the inhibition of the p53/Rb pathways occurred at early stages of the disease, indicating that these tumor suppressor pathways might play a critical role in preventing liver cancer initiation [19].

Hepatocytes, cholangiocytes and liver progenitor cells could function as candidates for the cell of origin in liver cancer [20]. However, identifying the cell of origin is currently not feasible in human patients. In addition, the lack of appropriate markers to clearly distinguish the differentiation stages of the different hepatic lineages has hindered the characterization of the cell of origin in human liver cancer patients [21]. In this study, we show that liver-specific inactivation of Rb and p53 in mice leads to the spontaneous formation of liver tumors at the age of 13 months with histological similarities to human liver cancers. Moreover, we show that surgical resection and RFA accelerate tumor genesis in p53/Rb deficient livers as a result of migration, expansion and transformation of Cytokeratin19- (CK19) positive - cells at the injury site.

RESULTS

Loss of p53 and Rb in liver results in spontaneous cancer

We used homologous recombination techniques and Cre-loxP technology to disrupt p53 and Rb function in the liver by crossing Alb-cre to p53^f/f;Rb^f/f mice (Supplementary Figure S1A and S1B).

Homozygous deletion of p53 and Rb in the liver led to spontaneous tumor formation in 13-26 month-old mice with an incidence of 63% (n=19) (Figure 1A; Table 1 ). No liver tumors were observed in age-matched control mice (n=17). Analysis of tumors discovered different phenotypes including well-differentiated hepatocellular carcinoma (HCC, Figure 1B), cholangiocarcinomas (CC, Figure 1C) and undifferentiated hepatocholangiocellular carcinomas HCC/CC (Figure 1D). Importantly undifferentiated carcinomas contained multiple areas with coagulation necrosis (Figure 1E) accompanied by infiltration of inflammatory cells (Figure 1D, Supplementary Figure S1C). The degree of necrosis and inflammation was more severe in undifferentiated HCC/CC compared to differentiated HCC/CC (Figure 1E). Notably the liver surrounding undifferentiated tumors displayed also more infiltration of inflammatory cells compared to well-differentiated tumors (Figure 1F). These findings suggest that loss of epithelial differentiation is a consequence of tissue injury and its associated inflammatory response. Alternatively, since undifferentiated carcinomas exhibited more necrosis this might trigger an enhanced immune response.

Hepatic resection leads to cancer at the ligation site in p53^Δ/Δ;Rb^Δ/Δ livers.

Survival analysis demonstrated that the mean life span of Alb-cre^+/-;p53^Δ/Δ;Rb^Δ/Δ mice that developed spontaneous liver tumors (527 days; n=12) was significantly shorter than control Alb-cre^-/-;p53^f/f;Rb^f/f mice (730 days; n=17; P=<0.05) (Figure 2A; Table 1 ). Although deletion of p53 and Rb is already induced during fetal development [22], tumor formation occurred relatively late in life, indicating that additional events are required to initiate cancer. To investigate whether tumor development could be accelerated in p53^Δ/Δ;Rb^Δ/Δ liver, we performed two subsequent partial hepatectomies (PH). Surgical resection resulted in early formation of large liver tumors with an incidence of 66% (Table 1). The mean survival time of Alb-cre^+/-;p53^Δ/Δ;Rb^Δ/Δ mice that underwent surgery and developed liver tumors was significantly shorter compared to tumor mice without surgery (Figure 2A; Table 1 ). We expected that liver tumors would be located in the regenerating lobes, because these lobes underwent multiple rounds of cell division, which would likely increase the risk of gaining additional mutations. Surprisingly, in all p53^Δ/Δ;Rb^Δ/Δ livers a large tumor was found at the stump of the resected lobes (Figure 2B), whereas in the regenerating lobes hardly any liver tumors were detected. Histological examination revealed that all tumors located at surgical sites were undifferentiated HCC/CC accompanied with multifocal necrosis and infiltration of inflammatory cells (Figure 2C, Table 1). Tumors that developed occasionally in a regenerated lobe away from the injury site were more well-differentiated HCC or CC (Figure 2D, 2E; Table 1 ). PH on control mice did not cause liver cancer (Supplementary Figure S2).

RFA initiates cancer at the necrotic injury site of p53^Δ/Δ;Rb^Δ/Δ livers

We evaluated whether RFA, a different therapy approach to remove tumors from the liver, had any effects on p53^Δ/Δ;Rb^Δ/Δ and control p53^f/f;Rb^f/f livers. Mice were euthanized weekly for post RFA analysis from 1-10 weeks (Supplementary Figure S3A). Examination of the injured liver lobes revealed that distinct neoplastic foci were detectable within the necrotic regions of p53^Δ/Δ;Rb^Δ/Δ and not in control livers from 5 weeks after RFA (Figure 3, Table 1 ). Tumors that developed upon RFA treatment were similar to tumor induced by PH and were classified as undifferentiated HCC/CC (Figure 3 and 2B, 2C; Table 1 ). In Alb-cre^+/-;p53^Δ/Δ , 4/5 mice developed tumors within 6 months, whereas no tumor was observed in Alb-cre^+/-;Rb^Δ/Δ mice within 12 months after RFA treatment. Morphologically, tumors observed in p53^Δ/Δ liver were identical to p53^Δ/Δ;Rb^Δ/Δ tumors (data not shown).

CK19⁺ cells migrate, expand and transform within necrotic regions of p53^Δ/Δ;Rb^Δ/Δ livers

Next we investigated which cell types invaded into the necrotic region before distinct neoplastic foci were recognizable. One week after RFA, we observed in p53^Δ/Δ;Rb^Δ/Δ and in control livers that multiple well differentiated bile ducts were present within the necrotic region (Figure 3). These bile ducts were surrounded by myofibroblasts, inflammatory cells and endothelial cells and localized adjacent to the border between dead and viable liver tissue. Intriguingly, at 3 weeks these bile ducts and the surrounding cells had migrated and expanded deeper into the necrotic liver regions in p53^Δ/Δ;Rb^Δ/Δ and not in control liver. Notably, viable well-differentiated hepatocytes had never been detected within necrotic regions (Supplementary Figure S3B). Presence and expansion of bile ducts within the necrotic region was confirmed by immunostaining for CK19, a marker for cholangiocytes and liver progenitor cells (LPC) (Figure 4A). Number of bile ducts (Figure 4B) and proliferation index of cholangiocytes (Figure 4C & 4D) in p53^Δ/Δ;Rb^Δ/Δ liver were increased 3 weeks after RFA. These findings suggest that liver-specific loss of p53 and Rb results in enhanced migration and proliferation of bile ducts into the area of tissue injury. Remarkably, 5-6 weeks post RFA and at later time points, bile duct structures were still present within the neoplastic foci surrounded by inflammatory cells, but were smaller in size (Figure 3).

The Alb-cre transgene is known to specifically express Cre in hepatocytes. To verify that homologous recombination of conditional alleles had also occurred in cholangiocytes/LPC and not in hepatocytes only, we crossed Alb-cre^+/-;p53^Δ/Δ;Rb^Δ/Δ mice with mice carrying the LacZ-Cre-reporter (LSLR26R^f/f) [23]. As expected LacZ expression was detected in viable hepatocytes of Alb-cre^+/™; LSLR26R^Δ/Δ mice (Figure 4E). Importantly, bile ducts in non-injured livers (Supplementary Figure S1B) and bile ducts invading early into the necrotic regions of Alb-cre^+/-;p53^Δ/Δ;Rb^Δ/Δ;LSLR26R^Δ/Δ mice showed strong LacZ expression (Figure 4E), indicating that p53 and Rb has not only been deleted in hepatocytes but also in cholangiocytes/LPC. LacZ expression was also observed in liver tumors 10 weeks after RFA, and we found that undifferentiated carcinomas cells and cholangiocytes/LPC expressed LacZ, supporting that undifferentiated neoplastic cells originate from epithelial liver cells (Figure 4F). Deletion of p53 and Rb in liver tumors was confirmed by PCR analysis (Supplementary Figure S1A).

p53^Δ/Δ;Rb^Δ/Δ CK19⁺ cells are resistant to TGFβ and hypoxia mediated growth inhibition

Since the proliferation rate of wild type cholangiocytes within the RFA zone decreased from 1 to 3 weeks (Figure 4C, 4D) while p53/Rb deficient cholangiocytes continue to proliferate at high rate, we hypothesize that p53^Δ/Δ; Rb^Δ/Δ cholangiocytes might be less responsive towards inhibitory proliferation signals, such as the transforming growth factor beta (TGFβ). TGFβ is a secreted protein and a known inhibitor of cellular proliferation [24, 25]. We found that TGFβ is highly expressed by cells surrounding the migrating cholangiocytes at the RFA site 3 weeks after surgery (Figure 5A). To test our hypothesis, we isolated and cultured cholangiocytes/LPC from p53^Δ/Δ;Rb^Δ/Δ and wild type livers using organoid technology (Figure 5B) [26]. Administration of TGFβ to the culture medium of wild type organoids strongly reduced the DNA replication rate, quantified by EdU incorporation (Figure 5C). In contrast, TGFβ addition to p53^Δ/Δ;Rb^Δ/Δ organoids resulted in less inhibition of DNA replication (Figure 5C). Time course analysis with daily measurements of DNA replication further supported that p53^Δ/Δ;Rb^Δ/Δ organoids were less sensitive to inhibitory effects and displayed a higher proliferation rate in response to TGFβ (Figure 5D). Similar responses were observed when CK-19⁺ organoids were cultured under hypoxic conditions. Hypoxia decreased the proliferation rate and viability of wild type liver organoids, whereas p53^Δ/Δ;Rb^Δ/Δ organoids show no reduction in proliferation and viability (Figure 5E, 5F). To investigate whether oxidative stress contributes to the positive selection of CK19⁺ cells after RFA [27], we exposed organoids to hydrogen peroxide or we removed the anti-oxidant N-Acetyl-Cysteine (NAC) from the organoid medium. In contrast to hypoxia and TGFβ, wild type and p53^Δ/Δ;Rb^Δ/Δ organoids did not differ significantly in response to oxidative stress (Supplementary Figure S9A-S9D). Next, we evaluated the angiogenesis response towards the injury. However the number of blood vessels at the transition zone two weeks after RFA did not differ between control and p53/Rb deficient livers (Supplementary Figure S10A-S10B). Furthermore, the analysis of the polyploidy status of isolated wild type and p53/Rb deficient CK19⁺ cells from livers, revealed no difference in polyploidy between the two genetic groups (Supplementary Figure S11).

Tissue destruction leads to epithelial-mesenchymal transition (EMT) of p53^Δ/Δ;Rb^Δ/Δ neoplastic liver cells

Analysis of all spontaneous tumors arising in p53^Δ/Δ;Rb^Δ/Δ livers revealed that approximately 30% of tumors were well differentiated HCC or CC, while the remaining tumors were either poorly differentiated or undifferentiated (Figure 6A). Reduced differentiation of spontaneous tumors was associated with the presence of prominent necrotic foci and strong invasion of inflammatory cells (Figure 1E). Consistent with these observations, 100% of the liver tumors that developed after PH or RFA were undifferentiated HCC/CC (Figure 6A; Table 1 ). These findings prompt us to hypothesize that tissue destruction induced EMT of neoplastic liver cells. Selected markers were used to investigate the differentiation degree of the liver tumors in more detail. Hepatocyte nuclear factor 4 alpha (HNF4α), a nuclear marker for mature hepatocytes [28], was strongly expressed in normal hepatocytes and well differentiated HCC, whereas undifferentiated carcinomas showed almost no expression (Figure 6B). We observed that bile ducts located within undifferentiated carcinoma showed weak expression of HNF4α, which is in line with previous studies describing HNF4α expression in activated bile ducts (Figure 6B) [28]. CK19 staining displayed strong expression in normal bile ducts, in well differentiated CC, and in large and small ductular structures within undifferentiated carcinomas (Figure 4F, 6B, data not shown). Undifferentiated carcinoma cells showed infrequent low expression of CK19 (Figure 4F, 6B). Next, we investigated the expression of E-cadherin, a general marker for epithelial cells. Strong membranous E-cadherin expression was observed in normal hepatocytes and cholangiocytes, in well differentiated HCC and CC, and in ducts of undifferentiated carcinomas. Consistent with the expression pattern of the other epithelial marker HNF4α and CK19, undifferentiated carcinoma cells lacked E-cadherin expression (Figure 6B and Supplementary Figure S4). To determine whether these carcinomas cells had gained a mesenchymal phenotype, we performed S100A4 staining. Undifferentiated carcinomas cells show strong S100A4 expression, whereas bile ducts and hepatocytes lacked S100A4 expression (Figure 6B and Supplementary Figure S4). We also observed co-localization of CK19 and S100A4 as well as CK19 and vimentin in early tumor lesions (Supplementary Figure S5A, S5B). Other regions of advanced tumor lesions and normal liver tissues did not show co-expression of epithelial and mesenchymal markers (Supplementary Figure S6A, S6B).

Finally, Ki67 staining demonstrated enhanced Ki67 expression in undifferentiated carcinomas (Supplementary Figure S6C). Together these data suggest that tissue destruction by surgical resection or RFA leads to epithelial-mesenchymal transition and enhanced proliferation of p53^Δ/Δ; Rb^Δ/Δ neoplastic cholangiocytes/LPC.

Anti-inflammatory drugs could not prevent tumor development at the RFA injury site

Because the initiation of liver tumors at the injury site is associated with infiltration of inflammatory cells (Figure 3), we investigated whether inflammation contributes to tumor development. One group of Alb-cre^+/-;p53^Δ/Δ;Rb^Δ/Δ mice received Sulindac in drinking water and control group received plain water. A second cohort group received Dexamethasone or saline a day before RFA and continued treatment for 9 weeks. The Sulindac treated group (n=6) did not differ from the control group. Dexamethasone treated mice revealed reduced inflammation and bile ducts migration into necrotic region, three weeks after RFA (Supplementary Figure S7). Surprisingly only one mouse of the dexamethasone treated group did not develop tumors at RFA site, 75% (6/8) developed smaller tumors compared to control and one mouse developed a tumor larger than the control mice. As expected, all saline treated mice developed tumors at RFA site. Treatment with high dose of Dexamethasone (4mg/kg) alone did not induce any pathological change in the liver (data not shown). These findings suggest that reducing the inflammatory response at the injury site does not significantly contribute to the development of liver tumors after RFA.

CK19-specific deletion of p53 and Rb leads to liver cancer after RFA

Given the migration and expansion of cholangiocytes into early necrotic lesions of p53^Δ/Δ;Rb^Δ/Δ livers (Figure 3), we examined whether the bile duct cell/LPC could represent the cell-of-origin in this injury-induced mouse model of liver cancer. To delete p53 and Rb specifically in cholangiocytes/LPC, we bred mice transgenic for Cre under the control of the tamoxifen-inducible CK19 promoter (CK19-creERT) [29] with p53^f/f;Rb^f/f mice. To monitor Cre-specific expression, mice were also crossed with the R26LSL-lacZ reporter mice. 5-bromo-4-4chloro-3-indolyl-D-galacto-pyrmoside (X-gal) staining on liver sections from CK19-cre^+/-;p53^Δ/Δ;Rb^Δ/Δ;LSLR26R^Δ/Δ mice injected with tamoxifen demonstrated LacZ expression in cholangiocytes, not in hepatocytes or stromal cells (Figure 7A). To further ensure that CK19-cre expression is limited to cholangiocytes/LPC, we exposed tamoxifen-injected CK19-cre^+/-;p53^Δ/Δ;Rb^Δ/Δ;LSLR26R^Δ/Δ mice to a 3,5-diethoxycarbonyl-1,4-dihydrocollidine (DDC) diet for three weeks to induce proliferation of cholangiocytes/LPC [30]. We observed LacZ expression only in cholangiocytes/LPC during DDC exposure and after switching back to a normal diet (Supplementary Figure S8A). These findings are in line with previously published findings which demonstrate that CK19-cre expressing cells are not able to generate hepatocytes even under stress conditions [31]

Importantly, RFA resulted in the formation of liver tumors at the site of tissue destruction in 42% of CK19-cre^+/-;p53^Δ/Δ;Rb^Δ/Δ (Figure 7A; Table 1 ). Distinct neoplastic foci were detectable at first 9 weeks after RFA treatment and tumors showed strong LacZ expression and PCR analysis confirmed deletion of p53 and Rb within these tumors (Figure 7A and Supplementary Figure S1A). Comparative histological analysis revealed that the tumors had the same morphology and expression pattern of epithelial and mesenchymal markers similar to tumors that developed in Alb-cre^+/-;p53^Δ/Δ;Rb^Δ/Δ mice after PH or RFA (Figure 7B, and Supplementary Figure S8B). These findings provide strong evidence that the bile duct cell/LPC is the cell-of-origin of p53^Δ/Δ;Rb^Δ/Δ liver tumors induced by tissue destruction.

DISCUSSION

An important question, which is difficult to address in human patients, is whether liver cancers originate from hepatocytes, liver progenitor cells or cholangiocytes. We used genetically modified mice that lack the expression of tumor suppressors in different liver cell lineages to identify the cell of origin in an injury-induced model of liver cancer. Albumin-cre activation in p53/Rb conditional knockout mice resulted in the expansion of structures with characteristics of bile ducts. We showed that Albumin-cre transgenic mice expresses cre not only in hepatocytes, but also in cholangiocytes/LPC. It is also possible that liver tumors originated from dedifferentiated hepatocytes in Albumin-cre transgenic mice, as it has been shown previously [32]. To genetically delete Rb and p53 exclusively in cholangiocytes/LPC we used the Ck19-creERT transgenic mice [29] and found that the same type of tumors developed at the same location. We and others have never observed any Ck19-cre expression in hepatocytes not even after DDC exposure (Supplementary Figure S8A, [31], indicating that CK19-cre expressing cells in this transgenic mouse line do not generate hepatocytes and also do not originate from dedifferentiated hepatocytes. These observations strongly suggest that p53/Rb deficient liver tumors in CK19-cre expressing mice originate from cholangiocytes/LPC at the injury site.

This study provides insights into the pathogenesis of the development of liver tumors after surgical resection or RFA treatment, a scenario that is often observed in human liver cancer patients that underwent surgical or RFA therapy [6]. We provide now strong evidence that the necrotic injury site induced by these therapeutic modalities could serves as an optimal microenvironment for the initiation of liver tumors. Notably, surgical resection and RFA caused liver cancer only in p53 and Rb deficient livers, while wild type mice that underwent similar procedure were tumor-free. Nevertheless, p53 and Rb are commonly inactivated in human liver cells for example through infection with hepatitis B and C virus [33–35], raising the risk to develop liver tumors after surgical interventions. In fact, a recent study showed that liver cancer patients (n=266) infected with Hepatitis B virus had a 2-year recurrence rate of 54.3% after RFA [36]. Furthermore a study with 72 HCC patients revealed that a high hepatitis B virus load (>2000IU/ml) at the time of tumor resection was the most important risk factor for HCC recurrence after 19 months (p=0.001) [34] . Moreover antiviral treatment after resection was associated with significantly lower cumulative risk of recurrence [36, 37].

We show that thermal destruction leads to massive coagulation necrosis, followed by a wound healing response characterized by the migration of activated cholangiocytes/LPC, inflammatory cells, myofibroblasts, and deposition of extracellular matrix (fibrosis) into the necrotic regions. In wild type livers this dynamic wound healing process slows down and results in sequestration of the necrotic regions. In contrast, the chronic inflammatory response continues in p53/Rb deficient livers and leads to further expansion and enhanced proliferation of cholangiocytes. Remarkably, within 5 weeks after injury, cholangiocytes/LPC transform and initiate tumor formation within the necrotic regions. These migrating and expanding bile ducts were surrounded by cells that expressed high levels of TGFβ. Based on the morphology and the presence of brown pigment in the cytoplasm, the TGFβ-expressing cells represent most likely macrophages that were possibly recruited to injury site to phagocytize the necrotic debris (Figure 5A). Previous studies have shown that an increased TGFβ gradient promotes differentiation towards biliary lineage [16, 17, 25, 38] which is consistent with our finding that we only observed migration and expansion of cholangiocytes, and never observed any hepatocytes in the necrotic region. When we exposed isolated cholangiocytes/LPC to different dosages of TGFβ, we observed that Rb/p53 deficient cells proliferate more efficiently than wild type cells. These findings are also in line with the observation that the TGFβ-receptor contributes to the development of liver tumors in p53 deficient livers [16]. In addition, TGFβ is well known for inducing EMT in cancer cells [39], a phenotype that we clearly observed in the tumors that developed at necrotic injury where many cells express high levels of TGFβ. Together, our studies provide strong evidence for a model in which the increased TGF-β gradient generated by macrophages at the necrotic injury site promotes the migration, expansion, transformation and EMT of p53 and Rb deficient cholangiocytes/LPC.

Surprisingly, the use of anti-inflammatory agents showed that the overall tumor incidence after RFA was not significantly reduced, suggesting that other mechanism such as hypoxia may contribute to peri-necrotic tumor formation. Our in vitro study with CK19+ isolated cells (Figure 5E and Supplementary Figure S9A, S9B) as well as our previous studies utilizing an in vivo colon carcinoma cancer model [40] provide strong evidence that hypoxia could contribute to the positive selection cancer cells at the injury site.

In summary, our findings show that deletion of p53 or Rb leads to the expansion, transformation, and EMT of bile duct cells/LPC within an inflammatory, hypoxic and necrotic environment induced by surgery/RFA. We conclude that the combination of loss of tumor suppressors, creation of hypoxia/necrosis and the accompanied activation of TGFβ signaling causes cancer and EMT at the surgery site.

Finally, we provide the field with a novel mouse model, in which surgical resection and RFA treatment leads to formation of highly aggressive, fast growing and undifferentiated carcinomas. This model could represent a tool to test the efficacy of anti-cancer drugs that are aimed to use in human patients that developed liver tumors after hepatic resection or RFA.

MATERIALS AND METHODS

Animals and histology

All experiments were approved by the Utrecht University Animal Ethics Committee and performed according to institutional and national guidelines. Albumin-cre and R26R-LacZ^f/f mice were derived from Jackson laboratory [22, 23]. Rb^f/f and p53^f/f mice were provided by Dr. A. Berns (Netherlands Cancer Institute, Amsterdam, The Netherlands). Ck19-cre-ERT mice were generated as described previously [22]. Partial hepatectomy (PH) and RFA experiments were performed on mice aged for 10-14 weeks. First PH was done as described previously [41]. The second PH, removing the right lateral lobe, was performed 10 weeks after the first PH [42]. RFA was performed as described previously [40]. X-gal and immunostaining on liver sections were performed as described previously [43].

Additional description of materials and methods is provided as supplementary information .

GRANT SUPPORT

This work was supported in part by funding from Nuffic (NFP grant : R.B.M., DU.282001.1.3.), Netherlands Organization for Scientific Research (A.d.B., NWO-ALW-IN/11-28; 834.11.002.) the Dutch Cancer Society (K.M.G. KWF; A.d.B. KWF UU 2013-5777).

CONFLICT OF INTERESTS

No conflict of interests to disclose.

REFERENCES

1. Jemal A, Bray F, Center MM, Ferlay J, Ward E, Forman D. Global cancer statistics. CA Cancer J Clin. 2011; 61: 69-90.

2. Poon RT. Prevention of recurrence after resection of hepatocellular carcinoma: a daunting challenge. Hepatology (Baltimore, Md.). 2011; 54: 757-759.

3. Ng KK, Poon RT. Radiofrequency ablation for malignant liver tumor. Surgical oncology. 2005; 14: 41-52.

4. Poon RT, Fan ST, Ng IO, Wong J. Significance of resection margin in hepatectomy for hepatocellular carcinoma: A critical reappraisal. Annals of Surgery. 2000; 231: 544-551.

5. Ng KK, Poon RT, Lo CM, Yuen J, Tso WK, Fan ST. Analysis of recurrence pattern and its influence on survival outcome after radiofrequency ablation of hepatocellular carcinoma. Journal of gastrointestinal surgery. 2008; 12: 183-191.

6. Ikeda K, Kobayashi M, Kawamura Y, Imai N, Seko Y, Hirakawa M, Hosaka T, Sezaki H, Akuta N, Saitoh S, Suzuki F, Suzuki Y, Arase Y, et al. Stage progression of small hepatocellular carcinoma after radical therapy: comparisons of radiofrequency ablation and surgery using the Markov model. Liver international. 2011; 31: 692-699.

7. El-Serag HB. Hepatocellular carcinoma. The New England journal of medicine. 2011; 365: 1118-1127.

8. McGivern DR, Lemon SM. Tumor suppressors, chromosomal instability, and hepatitis C virus-associated liver cancer. Annual review of pathology. 2009; 4: 399-415.

9. Iakova P, Timchenko L, Timchenko NA. Intracellular signaling and hepatocellular carcinoma. Seminars in cancer biology. 2011; 21: 28-34.

10. Knudsen ES, Knudsen KE. Tailoring to RB: tumour suppressor status and therapeutic response. Nature reviews cancer. 2008; 8: 714-724.

11. Teufel A, Staib F, Kanzler S, Weinmann A, Schulze-Bergkamen H, Galle PR. Genetics of hepatocellular carcinoma. World journal of gastroenterology. 2007; 13: 2271-2282.

12. Munakata T, Liang Y, Kim S, McGivern DR, Huibregtse J, Nomoto A, Lemon SM. Hepatitis C virus induces E6AP-dependent degradation of the retinoblastoma protein. PLoS pathogens. 2007; 3: 1335-1347.

13. Majumder M, Ghosh AK, Steele R, Ray R, Ray RB. Hepatitis C virus NS5A physically associates with p53 and regulates p21/waf1 gene expression in a p53-dependent manner. Journal of virology. 2001; 75: 1401-1407.

14. Mayhew CN, Carter SL, Fox SR, Sexton CR, Reed CA, Srinivasan SV, Liu X, Wikenheiser-Brokamp K, Boivin GP, Lee JS, Aronow BJ, Thorgeirsson SS, Knudsen ES. RB loss abrogates cell cycle control and genome integrity to promote liver tumorigenesis. Gastroenterology. 2007; 133: 976-984.

15. Viatour P, Ehmer U, Saddic LA, Dorrell C, Andersen JB, Lin C, Zmoos AF, Mazur PK, Schaffer BE, Ostermeier A, Vogel H, Sylvester KG, Thorgeirsson SS, et al. Notch signaling inhibits hepatocellular carcinoma following inactivation of the RB pathway. The Journal of experimental medicine. 2011; 208: 1963-1976.

16. Morris SM, Baek JY, Koszarek A, Kanngurn S, Knoblaugh SE, Grady WM. Transforming growth factor-beta signaling promotes hepatocarcinogenesis induced by p53 loss. Hepatology. 2012; 55: 121-131.

17. Katz SF, Lechel A, Obenauf AC, Begus-Nahrmann Y, Kraus JM, Hoffmann EM, Duda J, Eshraghi P, Hartmann D, Liss B, Schirmacher P, Kestler HA, Speicher MR, et al. Disruption of Trp53 in livers of mice induces formation of carcinomas with bilineal differentiation. Gastroenterology. 2012; 142: 1229-1239.

18. McClendon AK, Dean JL, Ertel A, Fu Z, Rivadeneira DB, Reed CA, Bourgo RJ, Witkiewicz A, Addya S, Mayhew CN, Grimes HL, Fortina P, Knudsen ES. RB and p53 cooperate to prevent liver tumorigenesis in response to tissue damage. Gastroenterology. 2011; 141: 1439-1450.

19. Zhang YJ, Rossner P,Jr, Chen Y, Agrawal M, Wang Q, Wang L, Ahsan H, Yu MW, Lee PH, Santella RM. Aflatoxin B1 and polycyclic aromatic hydrocarbon adducts, p53 mutations and p16 methylation in liver tissue and plasma of hepatocellular carcinoma patients. International journal of cancer. 2006; 119: 985-991.

20. Duncan AW, Dorrell C, Grompe M. Stem cells and liver regeneration. Gastroenterology. 2009; 137: 466-481.

21. Zhang L, Theise N, Chua M, Reid LM. The stem cell niche of human livers: symmetry between development and regeneration. Hepatology. 2008; 48: 1598-1607.

22. Postic C, Magnuson MA. DNA excision in liver by an albumin-Cre transgene occurs progressively with age. Genesis. 2000; 26: 149-150.

23. Soriano P. Generalized lacZ expression with the ROSA26 Cre reporter strain. Nature genetics. 1999; 21: 70-71.

24. Sanchez A, Fabregat I. Growth factor- and cytokine-driven pathways governing liver stemness and differentiation. World journal of gastroenterology. 2010; 16: 5148-5161.

25. Clotman F, Jacquemin P, Plumb-Rudewiez N, Pierreux CE, Van der Smissen P, Dietz HC, Courtoy PJ, Rousseau GG, and Lemaigre FP. Control of liver cell fate decision by a gradient of TGF beta signaling modulated by Onecut transcription factors. Genes Dev. 2005; 19: 1849-1854.

26. Huch M, Dorrell C, Boj SF, van Es JH, Li VS, van de Wetering M, Sato T, Hamer K, Sasaki N, Finegold MJ, Haft A, Vries RG, Grompe M, et al. In vitro expansion of single Lgr5+ liver stem cells induced by Wnt-driven regeneration. Nature. 2013; 494: 247-250.

27. Ma J, Cheng G, Xu G, Weng S, Lu X. Effect of radiofrequency catheter ablation on endothelial function and oxidative stress. Acta Cardiologica. 2006; 61: 339-342.

28. Limaye PB, Alarcon G, Walls AL, Nalesnik MA, Michalopoulos GK, Demetris AJ, Ochoa ER. Expression of specific hepatocyte and cholangiocyte transcription factors in human liver disease and embryonic development. Laboratory investigation. 2008; 88: 865-872.

29. Means AL, Xu Y, Zhao A, Ray KC, Gu G. A CK19(CreERT) knockin mouse line allows for conditional DNA recombination in epithelial cells in multiple endodermal organs. Genesis. 2008; 46: 318-323.

30. Preisegger KH, Factor VM, Fuchsbichler A, Stumptner C, Denk H, Thorgeirsson SS. Atypical ductular proliferation and its inhibition by transforming growth factor beta1 in the 3,5-diethoxycarbonyl-1,4-dihydrocollidine mouse model for chronic alcoholic liver disease. Laboratory investigation. 1999; 79: 103-109.

31. Jors S, Jeliazkova P, Ringelhan M, Thalhammer J, Durl S, Ferrer J, Sander M, Heikenwalder M, Schmid RM, Siveke JT, Geisler F. Lineage fate of ductular reactions in liver injury and carcinogenesis. The Journal of clinical investigation. 2015; 125: 2445-2457.

32. Mu X, Espanol-Suner R, Mederacke I, Affo S, Manco R, Sempoux C, Lemaigre FP, Adili A, Yuan D, Weber A, Unger K, Heikenwalder M, Leclercq IA, et al. Hepatocellular carcinoma originates from hepatocytes and not from the progenitor/biliary compartment. The Journal of clinical investigation. 2015; 125: 3891-3903.

33. Staib F, Perwez Hussain S, Hofseth LJ, Wang XW, Harris CC. TP53 and liver carcinogenesis. Human mutation. 2003; 21: 201-216.

34. Hung IF, Poon RT, Lai CL, Fung J, Fan ST, Yuen MF. Recurrence of hepatitis B-related hepatocellular carcinoma is associated with high viral load at the time of resection. The American Journal of Gastroenterology. 2008; 103: 1663-1673.

35. Qu LS, Jin F, Huang XW, Shen XZ. High hepatitis B viral load predicts recurrence of small hepatocellular carcinoma after curative resection. Journal of gastrointestinal surgery. 2010; 14: 1111-1120.

36. Lee T, Lin J, Zeng Y, Chen Y, Wu M, Wu C. Association between nucleos(t)ide analog and tumor recurrence in hepatitis B virus–related hepatocellular carcinoma after radiofrequency ablation. Hepatology. 2016; 63: 1517-1527.

37. Chan AC, Chok KS, Yuen WK, Chan SC, Poon RT, Lo CM, Fan ST. Impact of antiviral therapy on the survival of patients after major hepatectomy for hepatitis B virus-related hepatocellular carcinoma. Archives of surgery. 2011; 146: 675-681.

38. Fan Q, Jing YY, Yu G, Kou X, Ye F, Gao L, Li R, Zhao Q, Yang Y, Lu Z, and Wei L. Tumor-associated macrophages promote cancer stem cell-like properties via transforming growth factor-beta1-induced epithelial-mesenchymal transition in hepatocellular carcinoma. Cancer Lett. 2014; 352: 160-168.

39. Sheahan S, Bellamy CO, Harland SN, Harrison DJ, Prost S. TGFbeta induces apoptosis and EMT in primary mouse hepatocytes independently of p53, p21Cip1 or Rb status. BMC Cancer. 2008; 8.

40. Nijkamp MW, van der Bilt JD, de Bruijn MT, Molenaar IQ, Voest EE, van Diest PJ, Kranenburg O, Borel Rinkes IH. Accelerated perinecrotic outgrowth of colorectal liver metastases following radiofrequency ablation is a hypoxia-driven phenomenon. Annals of Surgery. 2009; 249: 814-823.

41. Kester MH, Toussaint MJ, Punt CA, Matondo R, Aarnio AM, Darras VM, Everts ME, de Bruin A, Visser TJ. Large induction of type III deiodinase expression after partial hepatectomy in the regenerating mouse and rat liver. Endocrinology. 2009; 150: 540-545.

42. Martins PNA, Theruvath TP, Neuhaus P. Rodent models of partial hepatectomies*. Liver International. 2008; 28: 3-11.

43. Pandit SK, Westendorp B, Nantasanti S, van Liere E, Tooten PC, Cornelissen PW, Toussaint MJ, Lamers WH, de Bruin A. E2F8 is essential for polyploidization in mammalian cells. Nature cell biology. 2012; 14: 1181-1191.