1.Screening of cellular proteins binding to the core region of hepatitis C virus RNA by ultraviolet cross-linking assay.
Hai-xia SU ; Jing-xia ZHANG ; Xiao-ning ZHAO ; Juan LU ; Yong-ping YAN
Chinese Journal of Hepatology 2005;13(9):656-659
OBJECTIVETo screen cellular proteins binding to the core region of hepatitis C virus (HCV) from human hepatoma cells.
METHODSUnlabeled and labeled RNA transcripts were prepared by in vitro transcription. Cytoplasmic extracts were prepared from human hepatoma cells HepG2. Ultraviolet (UV) cross-linking was used to screen the cellular proteins that would bind to the core region of HCV. Competition experiment was performed to confirm the specificity of the binding in which excess unlabeled RNA of HCV core region and plasmid RNA were used as competitors.
RESULTSTwo cellular proteins of 6.6 x 10(4) and 5.5 x 10(4) were found binding to the core region of HCV RNA by UV cross-linking assay. The unlabeled core region of HCV RNA could compete out this binding whereas the unlabeled plasmid RNA could not.
CONCLUSIONThe cellular proteins from HepG2 cells could bind to the core region of HCV RNA.
Binding Sites ; Cross-Linking Reagents ; chemistry ; Hepacivirus ; genetics ; metabolism ; RNA, Viral ; genetics ; metabolism ; Ultraviolet Rays ; Viral Core Proteins ; genetics ; metabolism
2.The biological function of auto-induced expression of the hepatitis C virus soluble core protein.
Xu-yang GONG ; Qi-huan MA ; Xi DU ; Jie-li HU ; Xue-fei CAI ; Ai-long HUANG
Chinese Journal of Hepatology 2013;21(8):565-569
OBJECTIVETo investigate the biological role of auto-induced expression of hepatitis C virus (HCV) core protein (protein C) using a recombinant protein in an in vitro cell-based system.
METHODSThe PCR-amplified full-length HCV protein C gene (573 bp) was inserted into the pET28a prokaryotic expression vector. The recombinant plasmid was transformed into BL21(DE3)pLysS E. coli to achieve high-concentration expression of the recombinant C protein by auto-induction. The recombinant protein C was purified by Ni-NTA affinity chromatography, and tested in a protein binding assay for its ability to bind the HCV NS3 protein.
RESULTSThe transformed E. coli produced a large amount of recombinant protein C, as detected in the sonicated supernatant of the bacteria culture. The antigenic reactivity of the recombinant protein C was confirmed by western blotting. However, the recombinant protein C could not be purified by Ni-NTA affinity chromatography, but co-precipitated with the HCV NS3 protein.
CONCLUSIONSoluble recombinant protein C was successfully expressed by auto-induction, and shown to interact with the HCV NS3 protein, which provides a novel insight into the putative biological activity of this factor in HCV-related molecular processes. Future studies of this recombinant HCV protein C's crystal structure and antigenicity may provide further clues to its biological function(s) and potential for clinical applications.
Escherichia coli ; metabolism ; Genetic Vectors ; Hepacivirus ; Recombinant Proteins ; genetics ; metabolism ; Viral Core Proteins ; biosynthesis ; genetics ; metabolism ; Viral Nonstructural Proteins ; metabolism
3.Effects of HCV NS3 protein on apoptosis of QSG7701 cells induced by serum starvation.
Shu-yan SUN ; Hui GUO ; Bo LI ; Qiong-qiong HE ; De-yun FENG
Chinese Journal of Hepatology 2007;15(7):540-541
Apoptosis
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Cell Line
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Hepacivirus
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genetics
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Humans
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Serum
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metabolism
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Viral Nonstructural Proteins
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genetics
4.Hepatitis C virus and hepatocarcinogenesis.
Soung Won JEONG ; Jae Young JANG ; Raymond T CHUNG
Clinical and Molecular Hepatology 2012;18(4):347-356
Hepatitis C virus (HCV) is an RNA virus that is unable to integrate into the host genome. However, its proteins interact with various host proteins and induce host responses. The oncogenic process of HCV infection is slow and insidious and probably requires multiple steps of genetic and epigenetic alterations, the activation of cellular oncogenes, the inactivation of tumor suppressor genes, and dysregulation of multiple signal transduction pathways. Stellate cells may transdifferentiate into progenitor cells and possibly be linked to the development of hepatocellular carcinoma (HCC). Viral proteins also have been implicated in several cellular signal transduction pathways that affect cell survival, proliferation, migration and transformation. Current advances in gene expression profile and selective messenger RNA analysis have improved approach to the pathogenesis of HCC. The heterogeneity of genetic events observed in HCV-related HCCs has suggested that complex mechanisms underlie malignant transformation induced by HCV infection. Considering the complexity and heterogeneity of HCCs of both etiological and genetic aspects, further molecular classification is required and an understanding of these molecular complexities may provide the opportunity for effective chemoprevention and personalized therapy for HCV-related HCC patients in the future. In this review, we summarize the current knowledge of the mechanisms of hepatocarcinogenesis induced by HCV infection.
Capsid Proteins/metabolism
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Carcinoma, Hepatocellular/genetics/*metabolism/pathology
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Cell Transformation, Neoplastic
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Genome, Viral
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Genome-Wide Association Study
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Hepacivirus/genetics/*metabolism
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Humans
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Liver Neoplasms/genetics/*metabolism/pathology
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MicroRNAs/metabolism
5.Characterization of Serial Passage of 1b/2a Chimera Hepatitis C Virus Cell Culture System Carrying Envelope E1E2 Coding Gene from Hebei Strain of China.
Sha LU ; Ling ZHANG ; Gesi TAO ; Min CAI ; Bao LILI ; Lian LI ; Yao DENG ; Xiaoling SHEN ; Wenjie TAN
Chinese Journal of Virology 2015;31(6):647-652
To character a novel chimera(1b/2a) hepatitis C virus cell culture (HCVcc) system carrying envelope E1E2 coding gene from Hebei strain of China, chimera HCVcc (cHCVcc) was developed from Huh7.5-CD81 cells after transfection with in vitro transcribed full-length 1b/2a chimera RNA, which carrying envelope E1E2 coding gene from Hebei strain of China. Then the replication, expression and infectious titer of serial passage HCVcc were assessed by Real Time RT-PCR, indirect immunofluorescence assay (IFA) and Western blotting (WB). In addition, chimeric envelope gene from HCVcc was sequenced after serial passage. We found that the number of HCV positive focus increased gradually in cell post-transfection with chimera HCVcc (1b/2a) RNA and reach a peak platform (80% to 90%) at 41 days post-transfection; the expression of HCV protein was also confirmed by WAB during serial passage. At meantime, HCV RNA copy number in the supernatant peaked at 10(4)-10(7) copies/mL and the highest infectious titer of this 1b/2a cHCVcc reinfection were tested as 10(4) ffu/mL. Sequence analysis indicated 6 of adaptive amino acid substitutes occur among chimeric envelope E1E2 during serial passages. We con:luded that a novel 1b/2a chimera HCVcc carrying envelope E1E2 coding gene from Hebei strain of China was developed and its infectious titer increased after serial passage of HCVcc. This novel cHCVcc will be an effective tool for further evaluation of anti-virus drugs and immune effects against the major genotype from Chinese.
Cell Line
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China
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Hepacivirus
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genetics
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growth & development
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metabolism
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Hepatitis C
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virology
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Humans
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Serial Passage
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Viral Envelope Proteins
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genetics
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metabolism
6.RNA binding protein 24 regulates the translation and replication of hepatitis C virus.
Huang CAO ; Kaitao ZHAO ; Yongxuan YAO ; Jing GUO ; Xiaoxiao GAO ; Qi YANG ; Min GUO ; Wandi ZHU ; Yun WANG ; Chunchen WU ; Jizheng CHEN ; Yuan ZHOU ; Xue HU ; Mengji LU ; Xinwen CHEN ; Rongjuan PEI
Protein & Cell 2018;9(11):930-944
The secondary structures of hepatitis C virus (HCV) RNA and the cellular proteins that bind to them are important for modulating both translation and RNA replication. However, the sets of RNA-binding proteins involved in the regulation of HCV translation, replication and encapsidation remain unknown. Here, we identified RNA binding motif protein 24 (RBM24) as a host factor participated in HCV translation and replication. Knockdown of RBM24 reduced HCV propagation in Huh7.5.1 cells. An enhanced translation and delayed RNA synthesis during the early phase of infection was observed in RBM24 silencing cells. However, both overexpression of RBM24 and recombinant human RBM24 protein suppressed HCV IRES-mediated translation. Further analysis revealed that the assembly of the 80S ribosome on the HCV IRES was interrupted by RBM24 protein through binding to the 5'-UTR. RBM24 could also interact with HCV Core and enhance the interaction of Core and 5'-UTR, which suppresses the expression of HCV. Moreover, RBM24 enhanced the interaction between the 5'- and 3'-UTRs in the HCV genome, which probably explained its requirement in HCV genome replication. Therefore, RBM24 is a novel host factor involved in HCV replication and may function at the switch from translation to replication.
Cells, Cultured
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Hepacivirus
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genetics
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growth & development
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metabolism
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Humans
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Protein Biosynthesis
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RNA-Binding Proteins
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metabolism
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Virus Replication
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genetics
8.Proapoptotic and pronecrosis effect of different truncated hepatitis C virus core proteins.
Xue-bing YAN ; Zhi CHEN ; Dong-hui LUO ; Xiao-yan XU ; Wei WU ; Lin-fu ZHOU
Journal of Zhejiang University. Science. B 2005;6(4):295-300
OBJECTIVETo study the roles of different truncated hepatitis C virus (HCV) core proteins (CORE) in the pathogenesis of HCV persistent infection and hepatocellular carcinoma (HCC) and to assess intracellular localization in transiently transfected cells.
METHODSSeven truncated GFP (green fluorescent protein)-CORE fusion protein expression plasmids were constructed, which contained HCV CORE sequences derived from tumor tissues (BT) and non-tumor tissues (BNT) from one patient infected with HCV. Amino acid (aa) lengths were BT: 1-172 aa, 1-126 aa, 1-58 aa, 59-126 aa, 127-172 aa; BNT: 1-172 aa and C191: 1-172 aa respectively. Subcellular localization of CORE-GFP was analyzed by con-focal laser scanning microscope. Apoptosis and necrosis were quantified by flow cytometry.
RESULTSDifferent truncated CORE-GFP localized mainly in the cytoplasm, but nuclear staining was also observed. HCV CORE could induce apoptosis and necrosis, and different truncated COREs could induce cell apoptosis and necrosis at different levels. Among the same length 1-172 aa of BT, BNT and C191, the cell apoptosis and necrosis percentage of BT is highest, and C191 is the lowest (BT>BNT>C191). To the different fragment COREs of BT, N-terminal of CORE induced apoptosis and necrosis higher, compared with that of C-terminal (1-172 aa>1-126 aa>1-58 aa>127-172 aa>59-126 aa).
CONCLUSIONThese results suggest HCV CORE could induce apoptosis and necrosis of cells, which might play an important role in the pathogenesis of HCV persistent infection and HCC and the different CORE domains of different HCV quasi-species might have some difference in their pathogenesis.
Apoptosis ; Cell Line, Tumor ; Hepacivirus ; genetics ; pathogenicity ; physiology ; Humans ; Necrosis ; virology ; Sequence Deletion ; genetics ; Viral Core Proteins ; chemistry ; genetics ; metabolism
9.Screening and cloning of hepatitis C virus non-structural protein 4A interacting protein gene in hepatocytes.
Yan LIU ; Gui-qin BAI ; Jun CHENG ; Shun-hua WU ; Lin WANG ; Fu-ming YAN ; Ling-xia ZHANG ; Yu-fang CUI
Chinese Journal of Hepatology 2005;13(10):738-740
OBJECTIVETo investigate biological functions of hepatitis C virus (HCV) non-structural protein 4A (NS4A).
METHODSYeast-two hybrid technique was performed to seek proteins in hepatocytes interacting with HCV NS4A. HCV NS4A bait plasmid was constructed by ligating the NS4A gene with carrier plasmid pGBKT7, then it was transformed into yeast AH109 (alpha type). The transformed yeast cells were amplified and mated with yeast cells Y187 (alpha type) containing liver cDNA library plasmid pACT2 in 2 x YPDA medium. Diploid yeast cells were plated on synthetic dropout nutrient medium (SD/-Trp-Leu-His-Ade) and synthetic dropout nutrient medium (SD/-Trp-Leu-His-Ade) containing X-alpha-gal for selection two times. After extracting plasmid from blue colonies, plasmid DNA was transformed into competent E.coli and analyzed by DNA sequencing and bioinformatics methods.
RESULTSAmong twenty-two positive colonies there were eleven positive for metallothionein 2A, three for eukaryotic translation elongation factor 1 alpha 1, two for albumin, two for RNA binding motif protein 21, two for myomesin, one for cytochrome C oxidase II, and one for ATPase.
CONCLUSIONSGenes of HCV NS4A interacting proteins in hepatocytes were successfully cloned and the results pave the way for studying the biological functions of NS4A and associated proteins.
Carrier Proteins ; genetics ; Cloning, Molecular ; Hepacivirus ; genetics ; Hepatocytes ; metabolism ; Humans ; Two-Hybrid System Techniques ; Viral Nonstructural Proteins ; Viral Proteins ; genetics
10.Identification of HCV core protein binding proteins by yeast two-hybrid.
Jin-qian ZHANG ; Chen-yu ZHANG ; Shu-ling WU ; Qi WANG ; Jun CHENG
Chinese Journal of Hepatology 2009;17(7):501-504
OBJECTIVETo identify HCV core protein binding proteins.
METHODSThe library was amplified, purified, and then were transformed into yeast strain Y187. The reconstructed plasmid pGBKT7-core was transformed into yeast strain AH109 and screened on the nutrient deficiency medium SD/-Trp. The transformed AH109 mated with Y187 containing the library plasmid. The diploid yeast cells were plated on nutrient deficiency medium SD/-Trp/-Leu/-His/-Ade and SD/-Trp/-Leu/-His/-Ade containing X-alpha-gal for selecting. The plasmids in diploid yeast cells were extracted and electrotransformed into E.coli DH5alpha. The plasmids in DH5alpha were extracted and sequenced.
RESULTSEleven proteins, including chymotrypsinogen B1 precursor, carboxypeptidase A1, trypsinogen 2, chymotryptic peptide C, trypsin 1, carboxypeptidase B1, kinesin superfamily proteins 3B, trypsin 2, mitochondria protein gene, elastase 3A and colipase were found to be able to bind to HCV core protein.
CONCLUSIONSProteins related with metabolism of glucose and lipid may bind to HCV core protein.
Gene Library ; Hepacivirus ; genetics ; Plasmids ; genetics ; Polymerase Chain Reaction ; Transformation, Genetic ; Two-Hybrid System Techniques ; Viral Core Proteins ; genetics ; metabolism