Cirrhosis of the liver is characterized by diffuse fibrosis, disruption of the normal lobular architecture of the liver with formation of regenerative nodules, and severe disruption of the vascular organization of the liver that can also result in portal hypertension. These profound structural and vascular changes can be accompanied by hepatocellular failure and the inability of hepatocytes to perform their normal synthetic and metabolic functions. The causes of cirrhosis include hepatitis B virus infection, hepatitis C virus infection, alcohol‐mediated Laennec's cirrhosis, and nonalcoholic steatohepatitis (NASH)/metabolic syndrome, among others. When advanced liver cirrhosis progresses to terminal liver failure, the only definitive therapy is orthotopic liver transplantation. The worldwide prevalence of liver cirrhosis is roughly 25 to 400 per 100,000 subjects. In 2015, liver disease represented the eleventh leading cause of death, with an estimated 15.8 deaths per 100,000 globally. From 2000 to 2015, mortality increased nearly 30%, with the majority of cases occurring during the most productive years of life, between 25 and 64 years of age.

Although the etiologic agents and events that lead to cirrhosis may be known, the mechanisms responsible for deterioration of hepatocyte function and ultimately hepatic failure are largely unknown. Chronic injury to the liver is characterized by a decrease in hepatocyte mass, ongoing oxidative stress, impaired mitochondrial function, and limited regenerative capacity. We have previously investigated the abnormal microenvironment associated with cirrhosis and the hepatocytes that reside within the cirrhotic liver in an experimental animal model of irreversible cirrhosis and fatal chronic liver failure that greatly resembles human disease. We found that hepatocytes early in the development of cirrhosis suffer an adaptive metabolic and energy shift that involves a conversion from using oxidative phosphorylation to glycolysis and that dysfunctional hepatocytes during the terminal stages of chronic liver disease are unable to sustain the needed high levels of energy produced from glycolysis. Interestingly, we found that liver‐enriched transcription factors (LETFs) are stably down‐regulated in hepatocytes from animals with end‐stage cirrhosis and terminal hepatic failure. We showed that forced re‐expression of hepatocyte nuclear factor 4 alpha (HNF4α) can reprogram dysfunctional hepatocytes from terminally cirrhotic livers to function again, both in culture and in vivo, through expansion of new hepatocytes or stem cells and without the need for regeneration.

While available animal models have been extremely useful for elucidating many aspects of hepatocyte dysfunction within the cirrhotic microenvironment, the relative expression of LETF pathways and downstream genes have yet to be examined in human degenerative liver disease and correlated with clinical hepatic function. Here, we examine expression of these LETF genes from explanted human liver specimens and correlate the results with clinical parameters of liver function and stage of liver decompensation. We demonstrate that the transcription factor HNF4α is significantly down‐regulated in association with the extent of hepatic dysfunction, in concert with select related genes. We thus corroborate previous findings from an animal model of irreversible cirrhosis with terminal liver failure.

Materials and Methods

STATISTICAL ANALYSIS

The statistical software JMP 10J (SAS Institute, Cary, NC) was used for all analyses. Data are expressed as mean ± SEM. Continuous variables were compared using the Wilcoxon test and one‐way analysis of variance between two groups and among four groups, respectively. Additionally, the messenger RNA (mRNA) expression values in Fig. were compared individually against control values using the Student t test. Regression analyses were performed to detect correlations between gene expression and clinical parameters and between relative expression of HNF4α and the other genes expressed. Values of P < 0.05 were considered statistically significant.

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Expression levels of liver‐enriched transcription factors, grouped by the Child‐Pugh classification. Gene expression levels were analyzed according to the Ct method with the amount of target normalized to β‐actin and relative to a control sample. The relative expression of (A) HNF4α, (B) FOXA2, (C) HNF1α, (D) CEBPα, and (E) CEBPβ were analyzed using real‐time reverse‐transcription polymerase chain reaction. The expression values were compared using one‐way analysis of variance among four groups. To compare the mRNA expression values from each experimental group against controls, the Student t test was used. (F) HNF4α and FOXA2 expression in liver samples (normal livers [n = 5], Child‐Pugh A [n = 5], Child‐Pugh B [n = 5], and Child‐Pugh C [n = 13]) were analyzed by immunohistochemistry, and immunoreactivity was quantified in hepatocyte nuclei (magnification ×40). Abbreviations: HBV, hepatitis B virus; HCV, hepatitis C virus. Data are expressed as mean ± SEM.

Results

CLINICAL LIVER FUNCTION AND LETF EXPRESSION

Previous observations in animals with terminal chronic hepatic failure indicated that disruption of the transcription factor network and cellular dedifferentiation likely mediate hepatocyte decompensation. This observation led us to assess the relationship between LETF expression (HNF4α, FOXA2, HNF1α, CEBPα, and CEBPβ) and clinical evidence of liver dysfunction in human cirrhotic livers where gene expression was correlated with the Child‐Pugh score. There was a significant difference in expression of HNF4α among specimens from patients with normal liver and those with Child‐Pugh A, Child‐Pugh B, and Child‐Pugh C liver disease (3.0 ± 1.5 versus 7.8 ± 0.8 versus 4.5 ± 1.5 versus 2.6 ± 0.8; P < 0.001) using one‐way analysis of variance to determine differences among groups (Fig. A). Additionally, we performed individual comparisons of each group versus the normal liver control group. This analysis revealed that only mRNA expression of HNF4α in the Child‐Pugh A group was significantly higher than that in the normal liver group (7.8 ± 0.8 versus 3.0 ± 1.5; P = 0.008). However, the mRNA expression of HNF4A in the Child‐Pugh B or Child‐Pugh C group did not differ from that in normal liver (4.5 ± 1.5 or 2.6 ± 0.8 versus 3.0 ± 0.9; P = 0.32 or 0.65, respectively) (Fig. A). Moreover, HNF4α expression correlated significantly with serum total bilirubin level (r = –0.35, P = 0.009), serum albumin levels (r = 0.52, P < 0.001), and prothrombin time activity (r = 0.41, P = 0.002) among the patients analyzed (Fig. ). In fact, HNF4α mRNA values correlated inversely and significantly with the Model for End‐Stage Liver Disease (MELD) score of disease severity (r = 0.42, P = 0.002). However, gene expression levels of FOXA2, HNF1α, CEBPα, and CEBPβ showed no significant difference in the livers among patients with Child‐Pugh A, B, and C scores (FOXA2, 2.4 ± 0.6 versus 2.9 ± 0.5 versus 3.9 ± 0.9 versus 2.4 ± 0.5, P = 0.40; HNF1α, 20 ± 14 versus 34 ± 13 versus 33 ± 23 versus 12 ± 11, P = 0.56; CEBPα, 1.9 ± 0.5 versus 1.5 ± 0.3 versus 2.5 ± 0.6 versus 0.88 ± 0.3, P = 0.237; CEBPβ, 1.4 ± 0.9 versus 2.5 ± 07 versus 4.1 ± 1.3 versus 1.8 ± 0.6, P = 0.26) (Fig. B‐E). In addition, FOXA2, HNF1α, CEBPα, and CEBPβ had no significant correlation with serum total bilirubin level, serum albumin levels, prothrombin time activity, or MELD score (Supporting Figs. S2‐S3). These facts indicate that only loss of HNF4α expression is associated with the progression to terminal chronic hepatic failure in humans.

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Regression analyses between HNF4α expression and clinical parameters. Gene expression levels in Child‐Pugh A, B, and C patients' samples were analyzed according to the Ct method with the amount of target normalized to β‐actin and relative to a control sample. Scatterplots are shown depicting the correlation between the expression of (A) HNF4α and total bilirubin level, (B) serum albumin, (C) prothrombin time activity, and (D) MELD score.

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Comparison of liver‐enriched transcription factors and histologic cirrhosis. Livers were stained with Masson Trichrome and evaluated for fibrosis using the New Inuyama and Ishak classification. Data were analyzed according to the Ct method with the amount of target normalized to β‐actin and relative to a control sample. The relative expression of (A) HNF4α, (B) FOXA2, (C) HNF1α, (D) CEBPα, and (E) CEBPβ was compared between histologic liver cirrhosis and non‐liver cirrhosis. (F) Liver fibrosis in each Child‐Pugh classification (A, B, and C) and etiology was evaluated using Masson Trichrome staining and scored by Ishak scoring for histologic fibrosis (magnification ×10). Abbreviations: ETOH, ethanol; HBV, hepatitis B virus; HCV, hepatitis C virus.

HNF4α and FOXA2 expressions were then examined by immunohistochemistry. HNF4α immunoreactivity was observed in almost all nuclei from normal (n = 5) and Child‐Pugh A liver samples (n = 5), as expected. However, HNF4α was not observed in hepatocytes from Child‐Pugh B (n = 5) and C liver samples (n = 13) (Fig. F) independent of etiology (hepatitis B virus, hepatitis C virus, alcohol‐mediated Laennec's cirrhosis, and NASH). FOXA2, a LETF normally related to biliary epithelial cell specification in human adult normal livers but observed in hepatocytes of diseased human livers, was strongly expressed in duct structures from normal liver samples as expected, and Child‐Pugh A and B liver samples showed FOXA2 was confined mainly to duct‐like structures. However, weak expression was also observed in the majority of hepatocytes, and there was strong expression in a minority of hepatocytes. In Child‐Pugh C liver samples, FOXA2 was more variable and weak in hepatocytes; notably, NASH–Child‐Pugh C liver samples showed weak expression in a minority of hepatocytes (Fig. F). The findings related to specific transcription factor expression relate to nuclear localization (the nucleus is the site in which transcription factors exert their effects on gene expression); however, weak cytoplasmic staining was often observed, especially in patient samples with Child‐Pugh B and C.

REGULATION OF HNF4α AND DOWNSTREAM EFFECTORS OF LIVER FUNCTION

To determine the extent to which HNF4α serves as a master regulator of liver function, HNF4α expression was correlated with the expression of three genes that are important indicators of hepatic function and known to be regulated by HNF4α: OTC, CYP3A4, and F7 (Fig. A‐D). The expression of HNF4α correlated with the expression of OTC (r = 0.37, P = 0.0064), CYP3A4 (r = 0.28, P = 0.040), and F7 (r = 0.29, P = 0.036). However, the expression of other LETFs did not correlate significantly with these hepatocyte‐specific genes (Supporting Fig. S4A‐C). Indeed, these three hepatocyte‐specific genes were severely down‐regulated in association with low expression of HNF4α, indicating that HNF4α definitely affects the expression of many liver‐specific target genes involved in protein secretion, amino acid production, and xenobiotic and drug metabolism. However, the molecular changes that promote the loss of HNF4α in cirrhotic livers in chronic hepatic failure remain undefined. Thus, we evaluated the role of cell–cell and cell–matrix mechanotransduction cascade‐related pathways in this process. As fibrosis is a dominant feature in the cirrhotic liver and the scarring causes cell membrane changes, we evaluated the expression of cadherin 1 (CDH1), a gene that encodes the cell–cell adhesion protein E‐cadherin. Linear regression analysis showed that E‐cadherin significantly correlated with HNF4α expression (r = 0.41, P = 0.0024) (Fig. D). We further examined the activity of Rho/Rho‐associated protein kinase (ROCK), a known mechanotransducer, and its downstream target p‐ERM (Fig. A), using immunohistochemistry, and found no activity in hepatocytes from the Child‐Pugh A and Child‐Pugh B specimens. However, p‐ERM immunoreactivity was present in the cytoplasm of hepatocytes from Child‐Pugh C specimens. Moreover, we confirmed ROCK activation by examining the expression of phospho‐myosin light chain and found that immunoreactivity was present in the cytoplasm of hepatocytes from Child‐Pugh B and Child‐Pugh C specimens (Fig. B). Finally, as the loss of LRP1, a marker of mature hepatocytes that regulates surface urokinase receptor and integrins, also reportedly leads to increased RhoA/ROCK function, we examined the staining pattern of LRP1 in relation to Child‐Pugh status. LRP1 staining inversely correlated with that of p‐ERM as would be expected if LRP1 regulated RhoA/ROCK (Fig. F).

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HNF4α expression and liver function genes. Gene expression levels in Child‐Pugh A, B, and C patients' samples were analyzed according to the Ct method with the amount of target normalized to β‐actin and relative to a control sample. Scatterplots are shown depicting the correlation between the expression of (A) HNF4α and OTC, (B) CYP3A4, (C) F7, and (D) E‐cadherin.

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Immunohistochemistry of mechanosignaling molecules in human livers grouped by the Child‐Pugh classification. The expressions of (A) p‐ERM, (B) phospho‐MLT, and (C) LRP1 were analyzed by immunohistochemistry (magnification ×40). Abbreviations: HBV, hepatitis B virus; HCV, hepatitis C virus.

Discussion

Hepatic transcription factors are key regulators of normal liver function. Hepatocyte‐specific gene transcription is stimulated by the concerted action of HNF 1, CEBPα, CEBPβ (formerly called HNF2), FOXA (previously known as HNF3), HNF4, and HNF6. Current literature indicates that HNF4α is the master hepatic regulator and controls numerous functions that include maintenance of the hepatic epithelium and morphogenesis, glucose and fatty acid metabolism, synthesis of blood coagulation factors, detoxification (CYPP450 activity), preservation of hepatocyte polarity, and maintenance of differentiation. HNF4α even controls the expression of other liver‐enriched factors, such as HNF1α, and can reestablish liver function and differentiated hepatocyte‐specific characteristics when reintroduced in models of liver cirrhosis and hepatocellular carcinoma.

We now show levels of HNF4α, HNF1α, CEBPα, CEBPβ, and FOXA2 expression in human livers with and without cirrhosis and with varying degrees of liver failure as defined by the Child‐Pugh score. We previously demonstrated that levels of HNF4α decreased in end‐stage hepatocytes from animals with cirrhosis and terminal hepatic failure and showed that forced re‐expression of HNF4α can immediately convert senescent and irreversibly dysfunctional hepatocytes derived from terminal livers to reestablish normal function. In the present study, we show that patients with cirrhosis of the liver express significantly lower levels of HNF4α in their livers than those without cirrhosis.

In addition, we showed significant mRNA down‐regulation of HNF4α in Child‐Pugh C decompensated livers compared to mRNA expression in Child‐Pugh A compensated livers. Importantly, HNF4α mRNA expression in Child‐Pugh C decompensated livers was not significantly different when compared to normal liver samples. However, HNF4α localization to the nucleus was significantly reduced in Child‐Pugh B and Child‐Pugh C livers. These findings might indicate an essential role for HNF4α in preserving normal liver function. Its expression is significantly up‐regulated at the onset of injury (Child‐Pugh A) to potentially maintain liver homeostasis; however, as liver disease progresses, HNF4α protein expression is diminished in the nuclei of hepatocytes and/or rendered ineffective, leading to impaired regulation and hepatic function. Although several LETFs were down‐regulated in severe liver disease (Child‐Pugh C), only HNF4α expression directly correlated with liver function and disease progression. For instance, protein expression of FOXA2 in biliary endothelial cells remained consistent in all liver samples examined in this study. However, in liver samples from patients with Child‐Pugh A, B, and C, a substantial number of hepatocytes became positive for FOXA2, supporting that reprogramming of biliary endothelial cells to hepatocytes or vice versa is also operative in human liver.

Our findings indicate that failure of the hepatic transcription system appears to be a pathologic finding in liver disease progression. These findings suggest that any correlation between chronic liver failure in cirrhosis in humans and HNF4α‐dependent hepatic functions is not regulated at the level of HNF4α transcription but rather at the level of protein expression and/or nuclear localization.

To confirm the role of LETFs in liver disease progression, we examined the possible correlation of HNF4α and other LETFs with clinical measures of hepatic function. We chose serum albumin, total bilirubin, and prothrombin time activity as indicators of overall hepatic function, although this only partially covers the many functions of the liver. These clinical markers, however, affect bile metabolism and indicate the capacity of the hepatocyte to synthesize proteins. Significant correlations were found between the levels of serum albumin and total bilirubin with expression of HNF4α.

Regulation of serum albumin has previously been noted to be associated with HNF4α as well as with the expression of HNF1α and the FOXA family of transcription factors. Biliary metabolism has also been linked to HNF4α expression as some enzymes involved in bile acid synthesis, such as 7α‐hydroxylase and 12α‐hydroxylase, have promoters that are bound directly by HNF4α and the expression of bile acid transporter proteins, such as organic anion transporting polypeptide‐C and Na⁺‐taurocholate cotransporting polypeptide, is indirectly regulated by HNF4α‐mediated transactivation of HNF1α. Unfortunately, regulation of the LETFs is complex and has not been completely delineated in humans, although LETF regulatory networks that control the expression of liver function genes have been published based on microarray data.

In our study, we evaluated hepatic function directly through expression of OTC, CYP3A4, and F7, which are three genes that loosely reflect metabolic, detoxification, and synthetic capacities of the liver. Interestingly, all three are downstream targets of HNF4α and their expression correlated strongly with HNF4α expression, although statistical significance was obtained only with OTC and CYP3A4. These findings emphasize the role of HNF4α in maintaining essential liver functions and, as described previously regarding its down‐regulation in decompensated liver disease, may explain the mechanism responsible for progression of cirrhosis to organ failure.

While the mechanism by which HNF4α and other LETFs are down‐regulated in cirrhosis has not yet been delineated, there are several possible candidate factors and pathways. For instance, there is evidence that nuclear localization of HNF4α can be regulated at the posttranslational level by phosphorylation and acetylation, while SUMOylation can regulate HNF4α protein degradation and stability. At the transcriptional level, Desai et al. recently showed that hepatic HNF4α expression and its target genes are regulated by extracellular matrix rigidity; they found a threshold level of stiffness beyond which expression of HNF4α and liver function genes are lost. The extracellular matrix signals through a mechanotransduction cascade in which cells sense the stiffness of their environment through integrin clustering, activation of focal adhesion kinase, and further activation of intracellular signaling pathways involving the ROCK pathway. Activation of the ROCK pathway by mechanical cues leads to phosphorylation and activation of effector proteins, such as the ERM proteins, which induces actin stabilization, smooth muscle contraction, and transcriptional regulation. Our study shows a significant increase in the phosphorylated ERM proteins, indicative of ROCK activation, coincident with loss of E‐cadherin, HNF4α, and other LETFs in more severe liver failure. Although it is not clear how Rho/ROCK signaling affects gene expression, it has been found to interact with YAP/TAZ transcriptional regulators. Importantly, it was previously shown that loss of LRP1, a protein essential for normal hepatic development, a regulator of lipid metabolism in mature livers, and a known regulator of other mechanotransducers, also activates the Rho/ROCK pathway in Schwann Cells. In this paper, we similarly show an inverse correlation between LRP1 levels and Rho/ROCK activation in hepatocytes. Interestingly, while little is known regarding the transcriptional regulation of LRP1, the harmonizome ENCODE transcription factor database indicates that LRP1 is a potential downstream transcriptional target of HNF4α. This suggests there may be a biological loop involving HNF4α, LRP1 expression, and suppression of Rho/ROCK that is disrupted in high‐grade liver failure.

E‐cadherin is a cell–cell junction protein that has many signaling partners in common with the integrin–focal adhesion kinase signaling pathway; it is involved in mechanical transduction and is greatly affected by fibrosis. Molecules involved in the genesis of liver fibrosis, such as transforming growth factor beta, are also implicated in the loss of E‐cadherin, and knockout of CDH1, the gene encoding E‐cadherin, has been shown to induce an inflammatory response and periductal fibrosis. Furthermore, fibrocystin‐deficiency diseases, such as congenital hepatic fibrosis, down‐regulate E‐cadherin expression. Interestingly, E‐cadherin is a direct transcriptional target of HNF4α and loss of HNF4α results in loss of E‐cadherin expression. While there is no known link between mechanical transduction signaling and regulation of LETFs in fibrosis, two intracellular kinases involved in integrin‐ and E‐cadherin‐mediated signaling, e.g., proto‐oncogene tyrosine‐protein kinase Src (c‐Src) and protein kinase C, can phosphorylate HNF4α and other nuclear receptors, and their activation can lead to a decrease in stability and a loss of nuclear localization and transactivation functions.

In summary, gene and protein expression analysis of liver samples from patients with cirrhosis and worsening liver function demonstrate that liver disease disrupts the normal expression and activity of LETFs, especially HNF4α. Clinical data and MELD score correlations point to the loss of hepatic transcriptome expression with liver decompensation and suggest a possible mechanism responsible for disease progression in cirrhosis and terminal liver failure. Further studies are needed to more fully characterize how each LETF might affect liver function and to delineate molecules that directly regulate their expression levels.

Author names in bold designate shared co‐first authorship.