Characterization of the mitochondrial association of hepatitis B virus X protein, HBx

Chronic infection with hepatitis B virus (HBV) is strongly associated with the development of hepatocellular carcinoma (HCC). HBx, a protein encoded by HBV is believed to contribute to the development of HCC. HBx was recently shown to associate with mitochondria. In this study, we mapped region(s) of HBx necessary for mitochondrial targeting and showed that a putative transmembrane region (aa 54-70) is required for mitochondrial association. In addition, amino acids in the putative alpha helical regions (aa 75-88 and aa 109-131) seem to aid in the mitochondrial targeting of this protein. We further show that the majority of HBx localizes to the outer mitochondrial membrane based on its sensitivity to trypsin and resistance to alkaline treatment. These studies suggest that the association of HBx with the outer mitochondrial membrane is its intrinsic property. These characterizations define transmembrane and alpha-helical regions of this viral protein as domains of mitochondrial targeting. These studies are further useful in the investigations concerning the physiological significance of the HBx's association with mitochondria and its impact on liver disease pathogenesis.     

Hepatitis B virus x protein induces perinuclear mitochondrial clustering in microtubule- and Dynein-dependent manners

The hepatitis B virus (HBV) X protein (HBx) is thought to play a key role in HBV replication and the development of liver cancer. It became apparent that HBx induces mitochondrial clustering at the nuclear periphery, but the molecular basis for mitochondrial clustering is not understood. Since mitochondria move along the cytoskeleton as a cargo of motor proteins, we hypothesized that mitochondrial clustering induced by HBx occurs by an altered intracellular motility. Here, we demonstrated that the treatment of HBx-expressing cells with a microtubule-disrupting drug (nocodazole) abrogated mitochondrial clustering, while the removal of nocodazole restored clustering within 30 to 60 min, indicating that mitochondrial transport is occurring in a microtubule-dependent manner. The addition of a cytochalasin D-disrupting actin filament, however, did not measurably affect mitochondrial clustering. Mitochondrial clustering was further studied by observations of HBV-related hepatoma cells and HBV-replicating cells. Importantly, the abrogation of the dynein activity in HBx-expressing cells by microinjection of a neutralizing anti-dynein intermediate-chain antibody, dynamitin overexpression, or the addition of a dynein ATPase inhibitor significantly suppressed the mitochondrial clustering. In addition, HBx induced the activation of the p38 mitogen-activated protein kinase (MAPK) and inhibition of the p38 kinase activity by SB203580-attenuated HBx-induced mitochondrial clustering. Taken together, HBx activation of the p38 MAPK contributed to the increase in the microtubule-dependent dynein activity. The data suggest that HBx plays a novel regulatory role in subcellular transport systems, perhaps facilitating the process of maturation and/or assembly of progeny particles during HBV replication. Furthermore, mitochondrion aggregation induced by HBx may represent a cellular process that underlies disease progression during chronic viral infection.     

Hepatitis B virus HBx protein localizes to mitochondria in primary rat hepatocytes and modulates mitochondrial membrane potential

Over 350 million people are chronically infected with hepatitis B virus (HBV), and a significant number of chronically infected individuals develop primary liver cancer. HBV encodes seven viral proteins, including the nonstructural X (HBx) protein. The results of studies with immortalized or transformed cells and with HBx-transgenic mice demonstrated that HBx can interact with mitochondria. However, no studies with normal hepatocytes have characterized the precise mitochondrial localization of HBx or the effect of HBx on mitochondrial physiology. We have used cultured primary rat hepatocytes as a model system to characterize the mitochondrial localization of HBx and the effect of HBx expression on mitochondrial physiology. We now show that a fraction of HBx colocalizes with density-gradient-purified mitochondria and associates with the outer mitochondrial membrane. We also demonstrate that HBx regulates mitochondrial membrane potential in hepatocytes and that this function of HBx varies depending on the status of NF-kappaB activity. In primary rat hepatocytes, HBx activation of NF-kappaB prevented mitochondrial membrane depolarization; however, when NF-kappaB activity was inhibited, HBx induced membrane depolarization through modulation of the mitochondrial permeability transition pore. Collectively, these results define potential pathways through which HBx may act in order to modulate mitochondrial physiology, thereby altering many cellular activities and ultimately contributing to the development of HBV-associated liver cancer.     

Hepatitis B virus X protein inhibits autophagic degradation by impairing lysosomal maturation

Deficiency in autophagy, a lysosome-dependent cell degradation pathway, has been associated with a variety of diseases especially cancer. Recently, the activation of autophagy by hepatitis B virus X (HBx) protein, which is implicated in hepatitis B virus (HBV)-associated hepatocellular carcinoma (HCC), has been identified in hepatic cells. However, the underlying mechanism and the relevance of HBx-activated autophagy to the carcinogenesis caused by HBV remain elusive. Here, by transfection of HBV genomic DNA and HBx in hepatic and hepatoma cells, we showed that HBV- or HBx-induced autophagosome formation was accompanied by unchanged MTOR (mechanistic target of rapamycin) activity and decreased degradation of LC3 and SQSTM1/p62, the typical autophagic cargo proteins. Further functional and morphological analysis indicated that HBx dramatically impaired lysosomal acidification leading to a drop in lysosomal degradative capacity and the accumulation of immature lysosomes possibly through interaction with V-ATPase affecting its lysosome targeting. Moreover, clinical specimen test showed increased SQSTM1 and immature lysosomal hydrolase CTSD (cathepsin D) in human liver tissues with chronic HBV infection and HBV-associated liver cancer. These data suggest that a repressive effect of HBx on lysosomal function is responsible for the inhibition of autophagic degradation, and this may be critical to the development of HBV-associated HCC.     

COX-2在乙肝病毒X蛋白（HBx）促进肝癌细胞和肝细胞增殖中的作用

乙型肝炎病毒（hepatitis B virus, HBV）X蛋白（HBx）对肝癌的发生发展具有十分重要的作用．大量研究结果表明,与花生四烯酸代谢相关的磷脂酶COX-2与肿瘤细胞的增殖密切相关．为了阐明COX-2在HBx促进肝细胞增殖中的作用,在前期应用基因芯片方法检测发现稳定转染HBx 基因的肝癌细胞H7402-X中COX-2基因表达明显上调的基础上,本研究应用免疫印迹技术在蛋白表达水平上获得了相同的结果．进而,应用COX-2的特异性抑制剂Indo分别作用H7402-X细胞和L-O2-X细胞（稳定转染HBx 基因的人永生化L-O2肝细胞）,观察HBx蛋白是否通过COX-2促进肝癌细胞或肝细胞增殖．BrdU掺入实验和流式细胞仪检测结果显示,50 μmol/L的Indo可明显抑制H7402-X细胞和L-O2-X细胞的增殖．本研究结果提示,HBx可通过COX-2所介导的花生四烯酸代谢促进肝癌细胞和肝细胞增殖．     

Hepatitis B virus X protein stimulates the mitochondrial translocation of Raf-1 via oxidative stress

The human hepatitis B virus (HBV) X protein (HBx) plays a crucial role(s) in the viral life cycle and contributes to the onset of hepatocellular carcinoma (HCC). HBx caused the mitochondrial translocation of Raf-1 kinase either alone or in the context of whole-viral-genome transfections. Mitochondrial translocation of Raf-1 is mediated by HBx-induced oxidative stress and was dependent upon the phosphorylation of Raf-1 at the serine338/339 and Y340/341 residues by p21-activated protein kinase 1 and Src kinase, respectively. These studies provide an insight into the mechanisms by which HBV induces intracellular events relevant to liver disease pathogenesis, including HCC.     

乙肝病毒感染对细胞基本自噬的影响

【目的】慢性乙肝病毒(Hepatitis B virus,HBV)感染在肝硬化和肝癌的发生过程中起着重要的作用,通过研究HBV感染对细胞基本自噬的影响,为HBV感染诱发肝癌以及HBV的免疫逃逸机理研究提供新的思路。【方法】本研究利用乙肝病毒表达质粒瞬时或稳定转染不同肝细胞,通过计数绿色荧光蛋白(greenfluorescent protein,GFP)聚集数目检测自噬小体形成,western blot检测LC3(microtubule-associated proteinlight chain 3,微管相关蛋白质轻链3)脂酰化和p62的降解,通过构建HBV B型和C型X蛋白(HBx)的表达质粒并瞬时转染肝癌细胞和正常肝细胞,对不同基因型X蛋白对细胞自噬的影响进行了分析。【结果】乙肝病毒感染后促进了LC3的脂酰化和p62的降解,增加了自噬小体的形成,增强了细胞的基本自噬。进一步研究发现,HBV感染增强的细胞基本自噬水平由HBx所引发,且C型HBx比B型对细胞基本自噬的增加更加显著。【结论】HBV通过HBx增强细胞的基本自噬,且不同基因型HBx对细胞基本自噬的增强程度不同,为进一步阐明HBV感染机理奠定了基础。     

Hepatitis B virus core protein stimulates the proteasome-mediated degradation of viral X protein

Hepatitis B virus (HBV) X protein (HBx) plays an essential role in viral replication and in the development of hepatocellular carcinoma. HBx has the ability to transactivate the expression of all HBV proteins, including the viral core protein HBc. Consistent with its regulatory role, HBx is relatively unstable and is present at low levels in the cell. We report here that the level of HBx was significantly reduced by the coexpression of HBc in cultured human hepatoma cells, whereas the level of HBx mRNA was unaffected. The repression of HBx by HBc was relieved by treating cells with the proteasome inhibitor MG132, indicating that HBc acts by stimulating the proteasome-mediated degradation of HBx. Moreover, the inhibitory effect of HBc was specific to HBx and did not affect other proteins, including p53, a known target of the proteasome. Although no direct physical interaction between HBc and HBx could be demonstrated, mutational analysis indicated that the C-terminal half of HBc is responsible for its inhibitory effect. These results suggest that HBc functions as a novel regulator of the HBV life cycle and of hepatocellular carcinogenesis through control of the HBx level via an inhibitory feedback type of mechanism.     

Hepatocystin/80K-H inhibits replication of hepatitis B virus through interaction with HBx protein in hepatoma cell

Hepatitis B virus (HBV) X protein (HBx) is a key player in HBV replication as well as HBV-induced hepatocellular carcinoma (HCC). However, the pathogenesis of HBV infection and the mechanisms of host–virus interactions are still elusive. In this study, a combination of affinity purification and mass spectrometry was applied to identify the host factors interacting with HBx in hepatoma cells. Thirteen proteins were identified as HBx binding partners. Among them, we first focused on determining the functional significance of the interaction between HBx and hepatocystin. A physical interaction between HBx and hepatocystin was confirmed by co-immunoprecipitation and Western blotting. Immunocytochemistry demonstrated that HBx and hepatocystin colocalized in the hepatoma cells. Domain mapping of both proteins revealed that the HBx C-terminus (amino acids 110–154) was responsible for binding to the mannose 6-phosphate receptor homology domain (amino acids, 419–525) of hepatocystin. Using translation and proteasome inhibitors, we found that hepatocystin overexpression accelerated HBx degradation via a ubiquitin-independent proteasome pathway. We demonstrated that this effect was mediated by an interaction between both proteins using a HBx deletion mutant. Hepatocystin overexpression significantly inhibited HBV DNA replication and expression of HBs antigen concomitant with HBx degradation. Using the hepatocystin mutant constructs that bind HBx, we also confirmed that hepatocystin inhibited HBx-dependent HBV replication. In conclusion, we demonstrated for the first time that hepatocystin functions as a chaperon-like molecule by accelerating HBx degradation, and thereby inhibits HBV replication. Our results suggest that inducing hepatocystin may provide a novel therapeutic approach to control HBV infection.     

Protein profile in HBx transfected cells: A comparative iTRAQ-coupled 2D LC-MS/MS analysis

The x protein of HBV (HBx) has been involved in the development of hepatocellular carcinoma (HCC), with a possible link to individual genotypes. Nevertheless, the underlying mechanism remains obscure. In this study, we aim to identify the HBx-induced protein profile in HepG2 cells by LC-MS/MS proteomics analysis. Our results indicated that proteins were differentially expressed in HepG2 cells transfected by HBx of various genotypes. Proteins associated with cytoskeleton were found to be either up-regulated (MACF1, HMGB1, Annexin A2) or down-regulated (Lamin A/C). These may in turn result in the decrease of focal adhesion and increase of cell migration in response to HBx. Levels of other cellular proteins with reported impact on the function of extracellular matrix (ECM) proteins and cell migration, including Ca²⁺-binding proteins (S100A11, S100A6, and S100A4) and proteasome protein (PSMA3), were affected by HBx. The differential protein profile identified in this study was also supported by our functional assay which indicated that cell migration was enhanced by HBx. Our preliminary study provided a new platform to establish a comprehensive cellular protein profile by LC-MS/MS proteomics analysis. Further downstream functional assays, including our reported cell migration assay, should provide new insights in the association between HCC and HBx.     

HBx combined with AFB1 triggers hepatic steatosis via COX‐2‐mediated necrosome formation and mitochondrial dynamics disorder

Hepatitis B virus (HBV) infection and aflatoxin B1 (AFB1) exposure have been recognized as independent risk factors for the occurrence and exacerbation of hepatic steatosis but their combined impacts and the potential mechanisms remain to be further elucidated. Here, we showed that exposure to AFB1 impaired mitochondrial dynamics and increased intracellular lipid droplets (LDs) in the liver of HBV‐transgenic mice in vivo and the hepatitis B virus X protein (HBx)‐expressing human hepatocytes both ex vivo and in vitro. HBx combined with AFB1 exposure also up‐regulated receptor interaction protein 1 (RIP1), receptor interaction protein 3 (RIP3) and activated mixed lineage kinase domain like protein (MLKL), providing evidence of necrosome formation in the hepatocytes. The shift of the mitochondrial dynamics towards imbalance of fission and fusion was rescued when MLKL was inhibited in the HBx and AFB1 co‐treated hepatocytes. Most importantly, based on siRNA or CRISPR/Cas9 system, we found that the combination of HBx and AFB1 exposure increased cyclooxygenase‐2 (COX‐2) to mediate up‐regulation of RIP3 and dynamin‐related protein 1 (Drp1), which in turn promoted location of RIP3‐MLKL necrosome on mitochondria, subsequently exacerbated steatosis in hepatocytes. Taken together, these findings advance the understanding of mechanism associated with HBx and AFB1‐induced hepatic necrosome formation, mitochondrial dysfunction and steatosis and make COX‐2 a good candidate for treatment.