Transcriptional trans-activating function of hepatitis B virus

The ability of hepatitis B virus (HBV) to stimulate the expression of a cellular gene was investigated by using a transient-expression system. A plasmid in which the expression of the bacterial chloramphenicol acetyltransferase (cat) gene had been placed under the control of the DNA sequences that regulate the expression of the human beta-interferon gene was constructed. In Vero cells, cotransfection of the 2.7-kilobase BglII DNA fragment of HBV together with the test plasmid containing the cat gene resulted in stimulation of the expression of the cat gene. This HBV DNA fragment was specific in its trans-activation; no significant stimulation of CAT activity was observed in constructs when the promoter and enhancer elements were derived from the murine sarcoma viral long terminal repeat, Rous sarcoma virus, BK virus, or simian virus 40. Results of subcloning of the HBV DNA fragment indicate that the trans-activating function resides in a 944-base-pair EcoRV-BglII DNA fragment of the HBV genome that contains the X structural gene and its promoter element. Removal of the promoter from the X structural gene resulted in loss of the trans-activating function. A frameshift mutation within the X gene region also eliminated the trans-activating activity. These results suggest that the X antigen could play a role in HBV infections by activating the expression of cellular genes.     

Identification of protein-binding sites in the hepatitis B virus enhancer and core promoter domains.

We have investigated the role of liver-specific trans-acting factor(s) in the regulation of hepatitis B virus (HBV) gene expression. A recorder plasmid (pEcoAluCAT; HBV nucleotides 1 through 1878) was constructed containing the HBV enhancer and the promoter region of the pregenomic RNA, which was ligated to the bacterial chloramphenicol acetyltransferase (CAT) gene. Upon transfecting this plasmid into various cell lines, the CAT gene was expressed only in cells of liver origin. Moreover, competition cotransfections with pEcoAluCAT and plasmids containing HBV enhancer sequences in human hepatoblastoma-derived HepG2 cells indicated the presence of titratable trans-acting factor(s) in these cells. Gel mobility shift assays using HBV enhancer and core promoter domains confirmed the existence of sequence-specific DNA-binding proteins in liver cell nuclear extract which bound to these regions. These binding sites encompass 17- and 12-nucleotide palindromes in the HBV enhancer and core promoter domains, respectively, when mapped by the methylation interference assay.     

Functional interaction of nuclear factors EF-C, HNF-4, and RXR alpha with hepatitis B virus enhancer I.

Hepatitis B virus (HBV) enhancer I contains cis-acting elements that are both sufficient and essential for liver-specific enhancer function. The EF-C binding site was previously shown to be a key element in enhancer I. EF-C binding activity is evident in hepatic and nonhepatic cells. Although the EF-C binding site is required for efficient HBV enhancer I function, the EF-C site does not possess intrinsic enhancer activity when assayed in the absence of flanking elements. We have defined a novel region in HBV enhancer I, termed the GB element, that is adjacent to and functions in conjunction with the EF-C binding site. The GB element and EF-C site confer interdependent liver-specific enhancer activity in the absence of flanking HBV enhancer sequences. The nucleotide sequence of the GB element is similar to sequences of the DNA binding sites for members of the steroid receptor superfamily. Among these proteins, we demonstrate that HNF-4, RXR (retinoid X receptor), and COUP-TF bind to the GB element in vitro. HNF-4 transactivates a promoter linked to a multimerized GB/EF-C domain via the GB element in vivo in a manner that is dependent on the integrity of the adjacent EF-C binding site. RXR alpha also transactivates promoter expression via the GB element in vivo in response to retinoic acid but in a largely EF-C-independent manner. Finally, we show that COUP-TF antagonizes the activity of the GB element in human liver cells.     

乙型肝炎病毒变异与肝细胞癌发生关系

乙型肝炎病毒（hepatitisBvirus,HBV）基因组复制时,以病毒前基因组RNA作为模板合成子代病毒DNA,催化该过程的逆转录酶缺乏校对功能,所以HBV易出现变异。近年来,各国学者通过比较肝细胞癌（hepatocellular carcinoma,HCC）患者和非HCC患者的HBV基因序列,发现HBV基本核心启动子区的A1762T／G1764A变异或T1753V变异、增强子Ⅰ区的G1053A或G1229A变异、前S蛋白的F141L变异、前s2区基因缺失变异和x基因的截短变异,分别是HCC的易患因素,而前c区常见的G1896A变异,与HCC的发生无关。增强子Ⅱ区的C1653T变异在c基因HBV感染中可能与发生HCC有关,而在A基因型可能无关。     

Hepatitis B virus (HBV) promoters are regulated by the HBV enhancer in a tissue-specific manner.

The activities of the individual hepatitis B virus (HBV) promoters and the effects of the HBV enhancer on these promoters in several human cell types have been compared by measuring the activity and RNA levels of the linked reporter function chloramphenicol acetyltransferase. The relative promoter activities in the human HepG2 (liver), HeLa, and HS27 (fibroblast) cell lines are in the order precore greater than X greater than preS2 greater than preS1; thus, the promoters of the gene producing the largest quantity of viral proteins have relatively low activity. The juxtaposition of the HBV enhancer in either orientation increased the promoter activities only modestly (2- to 5-fold) in the nonliver cell lines, whereas it dramatically increased (20- to 100-fold) the promoter activities in the liver cell line. Thus, the HBV enhancer is especially active in liver cells. This may be one of the causes of hepatotrophicity of the virus.     

Molecular cloning and characterization of the promoter region of the mouse regulatory subunit RII beta of type II cAMP-dependent protein kinase

The promoter and exon 1 of the regulatory subunit (RII beta) of type II cAMP-dependent protein kinase were isolated from a mouse genomic library. The 5'-flanking DNA lacked TATA and CAAT sites but contained GC rich regions typically found in constitutively expressed house keeping genes. Fusion gene constructs, containing RII beta 5'-flanking sequences and the bacterial CAT structural gene, were transfected into NB2a neuroblastoma cells and CHO cells. The NB2a cells expressed high levels of CAT activity. CHO cells expressed CAT activity at 5% of the level seen in the NB2a cells. Transfection of deletion constructs into both cell lines was used to define the core promoter and enhancer elements. The core promoter was situated between bp -291/-121. An enhancer element was located between bp -1426/-1018.