Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0019163 (hepatitis B)
38,309 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The hepatitis B virus X gene encodes a transcription activator which stimulates the synthesis of RNAs from a variety of class II and III promoter elements. In this report, we present a mutational analysis which genetically demonstrates that the X gene actually encodes two, and possibly three, related polypeptides from a single mRNA using alternate translation initiation from any of three in-frame AUG codons. Genetic analysis shows that translation initiates at the 5' proximal AUG of X mRNA and produces a full-length 17-kDa X protein but in addition also likely initiates at either of two conserved, in-frame AUG codons, producing two amino-terminally truncated X proteins presumably of 8 and 6.6 kDa. Expression of mRNAs capable of encoding only one of each X protein all individually transactivate class III (RNA polymerase III)-transcribed promoters. However, class II (RNA polymerase II)-transcribed promoters displayed various requirements for the different X proteins. Expression of two X proteins, the 17- and 6.6-kDa species, was required to activate transcription of the simian virus 40 enhancer/early promoter. In contrast, activation of an NF-kappa B-dependent promoter was carried out only by mRNAs encoding the full-length 17-kDa X protein. These results indicate that the X gene encodes several related proteins that possess different transcriptional regulatory activities.
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PMID:Alternate translation initiation on hepatitis B virus X mRNA produces multiple polypeptides that differentially transactivate class II and III promoters. 131 8

In vitro transcription of hepatitis B virus DNA (HBV DNA) was studied using nuclear extracts of human hepatoma cell lines. RNA polymerase II-dependent run-off transcription of pre-S mRNA under the control of pre-S1 promoter was observed in nuclear extracts obtained from HepG2 and PLC/PRF/5 cells, and the efficiencies in these extracts were significantly higher than those in nuclear extracts of non-liver cells such as HeLa, Molt-4, and Ehrlich. Analysis of run-off transcripts by the pre-S1 promoter, using deletion mutants of HBV DNA as templates and synthetic oligonucleotides as competitors, showed that hepatocyte nuclear factor 1 was necessary for initiation of in vitro transcription of pre-S mRNA. The run-off transcript of pregenome RNA was also detected and its initiation site was determined. Nuclear extracts of not only hepatoma cells but non-liver cells were active in transcription of pregenome RNA in vitro. However, run-off transcripts of S mRNA and X mRNA were not observed in this system. These results suggest that there were some differences between the mechanisms of HBV DNA transcription in vitro and in vivo. This in vitro transcription system will be useful for clarifying the mechanism regulating transcription of HBV DNA since the biochemical and functional characteristics of the nuclear factors can readily be analyzed.
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PMID:In vitro transcription of the hepatitis B virus gene by nuclear extracts of human hepatoma cells. 185 Sep 18

We employed an in vitro cell-free transcription system to locate RNA polymerase II promoters on the hepatitis B virus genome. The strongest promoter precedes the surface antigen (HBsAg) gene, which is comprised of a long (500 base pairs) presurface region as well as the mature HBsAg coding sequence. The origin of this transcript was localized by using truncated templates and S1 endonuclease mapping. The activity of the promoter was confirmed in transfection experiments in which the complete HBsAg gene was introduced into monkey kidney cells via a simian virus 40 expression vector. A second RNA polymerase II promoter preceding the HBcAg gene was also active in the cell-free system. The presence of multiple promoters in the hepatitis B virus genome suggests that the relative levels of viral-specific proteins detected in liver and serum may reflect differential or regulated promoter efficiency.
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PMID:Transcription of hepatitis B virus by RNA polymerase II. 664 22

Replication of hepadnaviruses requires a persistent population of covalently closed circular (CCC) DNA molecules in the nucleus of the infected cell. It is widely accepted that the vital role of this molecule is to be the sole DNA template for the synthesis by RNA polymerase II of all viral transcripts throughout the infection process. Since the transcriptional activity of eukaryotic nuclear DNA is considered to be determined in part by its specific organization as chromatin, the nucleoprotein disposition of the hepadnavirus CCC DNA was investigated. These studies were undertaken on the duck hepatitis B virus (DHBV) CCC DNA present in the liver cell nuclei of DHBV-infected ducks. The organization and protein associations of the DHBV CCC DNA in situ were inferred from sedimentation, micrococcal nuclease digestion, and DNA superhelicity analyses. These three lines of investigation demonstrate that the DHBV CCC DNA is stably associated with proteins in the nuclei of infected liver cells. Moreover, they provide compelling evidence that the viral nucleoprotein complex is indeed a minichromosome composed of classical nucleosomes but in arrays that are atypical for chromatin. When the DHBV chromatin is digested with micrococcal nuclease, a ladder of viral DNA fragments that exhibits a 150-bp repeat is produced. This profile for the viral chromatin is obtained from the same nuclei in which the duck chromatin shows the standard 200-bp ladder. The superhelicity of the DHBV CCC DNA ranges from 0 to 20 negative supertwists per molecule, with all possible 21 topoisomers present in each DNA preparation. The 21 topoisomers of DHBV CCC DNA are inferred to derive from an identically diverse array of viral minichromosomes. In the DHBV minichromosomes composed of 20 nucleosomes, 96.7% of the viral DNA is calculated to be compacted into these chromatin subunits spaced on average by 5 bp of linker DNA; other minichromosomes contain fewer nucleosomes and proportionately more linker DNA. Two major subpopulations of DHBV minichromosomes are detected with comparable prevalence. The two groups correspond to minichromosomes which contain essentially a full or half complement of nucleosomes. The functional significance of this minichromosome diversity is unknown but is suggestive of transcriptional regulation of the viral DNA template.
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PMID:The covalently closed duplex form of the hepadnavirus genome exists in situ as a heterogeneous population of viral minichromosomes. 774 82

Transcription of the core (C) gene of hepatitis B virus DNA (HBV-DNA) was studied by an in vitro transcription system using nuclear extracts of human liver cell (HepG2) and non-liver cell (HeLa) origins. RNA polymerase II-dependent run-off transcription of 3.5-kb (C) mRNA was observed in both nuclear extracts; but the efficiency was much higher in the HepG2 nuclear extract. Analysis of run-off transcripts using upstream deletion mutants of HBV-DNA demonstrated that there are two transcription start sites located at approximately nucleotide numbers (nt) 1,797 +/- 5 and 1,815 +/- 5. This analysis also suggested that the minimum core promoter sequence and a cis-acting and liver-specific element for C mRNA transcription are located in the downstream region from -80 and -110 (HincII site) of transcription start sites, respectively. DNA-binding protein assays using synthetic double-stranded oligonucleotide probes corresponding to three regions in the upstream region (nt from 1,401 to 1,760) of transcription start sites revealed that there are some liver cell-specific and non-specific DNA-binding proteins in both nuclear extracts. The amount of those proteins was generally higher in the HepG2 nuclear extract. However, no obvious correlation was observed in the present study between the presence of DNA-binding proteins and transcription activity of nuclear extracts in our system. The possible causes of this discrepancy are discussed.
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PMID:Analysis of upstream region of hepatitis B virus core gene using in vitro transcription system. 796 51

Lack of an in vitro culture system for human hepatitis B virus has hampered the ability to address fundamental questions regarding the viral life cycle and the effect of viral gene products during productive infection. To study the activity of HBV X protein (HBx) in the context of a viral infectious cycle, we provided HBx in trans during adenovirus infection of liver-derived cells. In hepatoma cells infected with adenovirus mutants deficient in expression of various E1A products, HBx was able to partially substitute for the transcriptional activation function of E1A. HBx also activated adenovirus replication, but to a lesser extent than the activation of transcription. Adenovirus genes transcribed by either RNA polymerase II or RNA polymerase III were activated by HBx during infection. These results suggest that HBx and E1A activate transcription by a similar mechanism and that this viral infection system will be useful for characterization of the functional activities of HBx.
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PMID:Hepatitis B virus X protein partially substitutes for E1A transcriptional function during adenovirus infection. 860 73

The X protein of hepatitis B virus (HBV) coactivates activators bearing potent (mostly acidic) activation domains. Here, we investigated the molecular mechanisms of this coactivation. We show that pX interacts with general transcription factors TFIIB and TFIIH, as well as with the potent activation domain of VP16. TFIIB interacts with both pX and VP16 simultaneously. In addition, the RNA polymerase II enzyme itself binds to pX. By reducing the activity of cellular coactivators, through squelching, we intensify the dependence of the activator on pX-mediated coactivation. Squelching is essentially diminished in the presence of pX, both in vivo and in vitro. The target of pX in this activity is the template-bound activator, and not the squelcher. Furthermore, by following transcription in a TAF-deprived reaction, we demonstrate absolute dependence of the activator on the activity of pX. We propose that pX coactivates transcription by substituting cellular coactivators in activator-preinitiation complex interactions.
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PMID:pX, the HBV-encoded coactivator, interacts with components of the transcription machinery and stimulates transcription in a TAF-independent manner. 867 Aug 43

Hepatitis B viral X protein (HBx) and small X proteins (HBSx) are known to transactivate promoters for RNA polymerase II and RNA polymerase III. Small X promoter has been mapped in the 5'-distal half of the X open reading frame. A 5'-serial deletion analysis showed that there was a positive regulatory sequence for the efficient transcription of the small X promoter. Two cellular proteins of 110 kDa (p110) and 33 kDa (p33) bound at the 3' and 5' regions of the regulatory sequence, respectively. Mutation of p33-binding and p110-binding sites led to diminution and elevation, respectively, of activation properties of the positive element, suggesting that p33 participates in the transactivation and that p110 has an inhibitory effect on the function of p33. This possibility was further supported by the result demonstrating that in vitro phosphorylation of p110 reduced its target DNA-binding capability.
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PMID:A positive regulatory sequence of hepatitis B viral small X promoter. 877

Hepatitis delta virus (HDV) is a unique viroid-like human pathogen that is always associated with hepatitis B infection. Replication of HDV involves the transcription of genomic RNA, probably by the host RNA polymerase II, by a rolling circle mechanism followed by self-cleavage and self-ligation. Editing of antigenomic RNA, possibly involving the enzyme adenosine deaminase, generates two functionally distinct forms of delta antigen. The molecular basis for HDV pathogenicity remains uncertain.
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PMID:Replication of hepatitis delta virus. 887 76

pX, the hepatitis B virus (HBV)-encoded regulator, coactivates transcription through an unknown mechanism. pX interacts with several components of the transcription machinery, including certain activators, TFIIB, TFIIH, and the RNA polymerase II (POLII) enzyme. We show that pX localizes in the nucleus and coimmunoprecipitates with TFIIB from nuclear extracts. We used TFIIB mutants inactive in binding either POLII or TATA binding protein to study the role of TFIIB-pX interaction in transcription coactivation. pX was able to bind the former type of TFIIB mutant and not the latter. Neither of these sets of TFIIB mutants supports transcription. Remarkably, the latter TFIIB mutants fully block pX activity, suggesting the role of TFIIB in pX-mediated coactivation. By contrast, in the presence of pX, TFIIB mutants with disrupted POLII binding acquire the wild-type phenotype, both in vivo and in vitro. These results suggest that pX may establish the otherwise inefficient TFIIB mutant-POLII interaction, by acting as a molecular bridge. Collectively, our results demonstrate that TFIIB is the in vivo target of pX.
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PMID:Hepatitis B virus pX targets TFIIB in transcription coactivation. 948 73


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