Production of hepatitis delta virus and suppression of helper hepatitis B virus in a human hepatoma cell line.

The hepatitis delta virus (HDV) is a defective virus with a coat composing of the surface antigen of its helper virus, hepatitis B virus (HBV). Replication of HDV in the absence of HBV has been shown in cell cultures by transient transfection of the HDV plasmid. However, the formation and release of HDV virions have not been observed. In this report, a human hepatoma cell line HuH-7 was transiently cotransfected with HDV and HBV plasmids. The production of monomeric and multimeric antigenomic RNAs of HDV in the transfected cells indicated replication of the HDV genome. The major 3.5- and 2.1-kb RNAs of HBV were also expressed. Virions of both HDV and HBV were released from the cotransfected cells, as shown by the detection of monomeric genomic HDV RNA and partially double-stranded HBV DNA in the culture medium. Thus, this is the first report that describes the assembly and the release of HDV viral particles in an in vitro cell culture. The HDV virions released possessed physicochemical properties identical to those of the HDV virions found in infected human serum. Furthermore, expression of both the 3.5- and 2.1-kb RNAs of HBV was shown to be dramatically decreased by the presence of HDV, indicating suppression of the expression of HBV genes by HDV. The amount of HBV virions released was similarly suppressed by HDV. Cotransfection of HBV with an expression plasmid of the HDV delta antigen remarkably reduced the levels of the 3.5- and 2.1-kb HBV RNAs, indicating that suppression of the expression of HBV RNAs by HDV occurs via the action of the delta antigen. This HBV- and HDV-cotransfected human hepatoma cell line should provide an excellent system for the study of the function of the delta antigen and the interaction between HDV and its helper, HBV.     

In vitro inhibition of hemopoietic cell line growth by hepatitis B virus.

The effects of hepatitis B virus (HBV) on established human cell lines of various tissue origins were evaluated by clonal or colorimetric assays in methylcellulose culture. HBV exposure inhibited the growth of six hemopoietic cell lines, while similar incubation did not affect the growth of seven nonhemopoietic carcinoma cell lines of breast, colon, liver, and stomach origin. The inhibition of hemopoietic cell line colony formation was dependent on the presence of intact viral (Dane) particles and the ratio of exposure of virions to cells and was reversible with antibodies to pre-S1, pre-S2, and S envelope protein epitopes. Purified HBV DNA, surface antigen pre-S antigens, and core antigen did not inhibit cell line growth. These results further demonstrate the tropism of HBV for cells of hemopoietic origin, confirming our previous findings on the effects of HBV on the growth of normal bone marrow progenitor cells in vitro. Established human tissue culture cell lines may be used to study the interactions of hemopoietic cells with HBV.     

Production of hepatitis B virus by a differentiated human hepatoma cell line after transfection with cloned circular HBV DNA

Closed-circular HBV DNA was introduced into cells of the established human hepatoma culture HepG2. The culture medium of one of 40 single-cell clones contained HBV surface antigen (HBsAg), core-related antigens (HBc/eAg), and HBV DNA sequences. HBV DNA and DNA polymerase activity were detected in particles resembling both nucleocapsids and complete virions (Dane particles). Intracellular integrated and extrachromosomal HBV DNA sequences were detected. Relaxed-circular and single-stranded forms of viral DNA were identified as likely replicative intermediates of the HBV genome. In conclusion, in vitro production of Dane-like particles by transformed human hepatocytes has been achieved. This model should be valuable as a cell culture system for studying virus replication and virus-host cell interactions.     

Protease-induced infectivity of hepatitis B virus for a human hepatoblastoma cell line.

The human hepatoblastoma cell line HepG2 produces and secretes hepatitis B virus (HBV) after transfection of cloned HBV DNA. Intact virions do not infect these cells, although they attach to the surface of the HepG2 cell through binding sites in the pre-S1 domain. Entry of enveloped virions into the cell often requires proteolytic cleavage of a viral surface protein that is involved in fusion between the cell membrane and the viral envelope. Recently, we observed pre-S-independent, nonspecific binding between hepatitis B surface (HBs) particles and HepG2 cells after treatment of HBs antigen particles with V8 protease, which cleaves next to a putative fusion sequence. Chymotrypsin removed this fusion sequence and did not induce binding. In this study, we postulate that lack of a suitable fusion-activating protease was the reason why the HepG2 cells were not susceptible to HBV. To test this hypothesis, virions were partially purified from the plasma of HBV carriers and treated with either staphylococcal V8 or porcine chymotrypsin protease. Protease-digested virus lost reactivity with pre-S2-specific antibody but remained morphologically intact as determined by electron microscopy. After separation from the proteases, virions were incubated with HepG2 cells at pH 5.5. Cultures inoculated with either intact or chymotrypsin-digested virus did not contain detectable levels of intracellular HBV DNA at any time following infection. However, in cultures inoculated with V8-digested virions, HBV-specific products, including covalently closed circular DNA, viral RNA, and viral pre-S2 antigen, could be detected in a time-dependent manner following infection. Immunofluorescence analysis revealed that 10 to 30% of the infected HepG2 cells produced HBV antigen. Persistent secretion of virus by the infected HepG2 cells lasted at least 14 days and was maintained during several reseeding steps. The results show that V8-digested HBV can productively infect tissue cultures of HepG2 cells. It is suggested that proteolysis-dependent exposure of a fusion domain within the envelope protein of HBV is necessary during natural infection.     

Replication of hepatitis B virus which carries foreign DNA in vitro.

Targeting a specific DNA sequence to the desired tissues is an important step in gene therapy. The hepatitis B virus (HBV) is the only DNA virus that has hepatocyte specificity. We attempted to construct an HBV-based vector for targeting the liver. We observed the replication and secretion of virus particles in an HBV construct that lacks X gene and carries an extra 63 bp DNA fragment in vitro. Replication was observed in the cell line HuH-7 but not HepG2. From this construct, we designed an HBV-based vector that could carry foreign DNA. HBV based vectors provide for the possibilities of generating therapeutic agents for individual patients. Our host vector system may be used to clear out the HBV from the HBV carrier or chronic hepatitis B patients by introducing a genetically engineered HBV into these patients.     

Two mammalian cell systems for propagation of the hepatitis B virus genome in extrachromosomal and chromosomally integrated states: production of the surface and e antigens

A recombinant plasmid consisting of (i) the entire genome of hepatitis B virus (HBV) DNA, (ii) the replication origin of SV40 virus, and (iii) a deletion derivative of pBR322 was introduced either into COS cells of monkey origin which constitutively express SV40 large T antigen, or into thymidine kinase(TK)-deficient mouse L cells together with the TK DNA of Herpes simplex virus. In the COS cell system, the transfecting recombinant DNA replicates via SV40 origin and is maintained in an autonomously replicating state. The cells carrying these extrachromosomal elements express the hepatitis B surface antigen gene at moderate rate, and release the products into the culture medium. However, neither core antigen nor e antigen expression was detected in this system. In the L cell system, the transformed L cells carry the recombinant DNA in a chromosomally integrated state. Such cells express the surface antigen gene at high rate, and release the products into the culture medium. This system also excretes the e antigen into the culture medium. The core antigen was not detected.     

Enhanced production of hepatitis B surface antigen in NIH 3T3 mouse fibroblasts by using extrachromosomally replicating bovine papillomavirus vector.

We have constructed a recombinant pBR322 plasmid composed of a subgenomic transforming fragment of bovine papillomavirus DNA and the hepatitis B surface antigen gene from cloned hepatitis B virus DNA and used it for transfection of NIH 3T3 mouse fibroblasts. The transformed cells retain the plasmids in extrachromosomal form with a copy number of about 50 to 100 per cell. Expression of the hepatitis B surface antigen gene linked to bovine papillomavirus DNA is independent of its orientation relative to the bovine papillomavirus vector. Cell lines continuously secreting high amounts of hepatitis B surface antigen into the medium could be established. The antigen is released into the culture medium as 22-nm particles, having the same physical properties and constituent polypeptides as those found in the serum of hepatitis B virus-infected patients.     

A molecularly cloned hepatitis B virus produced in vitro is infectious in a chimpanzee.

The infectivity of hepatitis B virus (HBV) produced in vitro by HepG2 cells transfected with HBV DNA (HepG2T14) has been assayed in a chimpanzee. Following inoculation, the chimpanzee underwent a typical course of type B hepatitis infection, characterized by elevation of serum aminotransferases and by histological identification of hepatic damage. Hepatitis B surface antigen and core-related antigen appeared in the serum at weeks 5 and 7, respectively, after infection. HBV DNA was detected in serum samples, and replicative forms of the HBV genome were identified in liver biopsies. Subtype identification of hepatitis B surface antigen and restriction enzyme analysis of HBV DNA in both the inoculum and the serum of the infected chimpanzee confirmed that the hepatitis B infection observed in this animal was caused by viral particles produced by HepG2T14 cells. These findings indicate that, although HepG2 cells do not seem to be susceptible to infection by HBV in vitro, they can produce biologically active infectious virions after transfection with cloned HBV DNA.     

Late transient expression of human hepatitis B virus genes in monkey cells

The expression of human hepatitis B virus (HBV) surface (HBS) and e (HBe) antigens has been studied comparatively in monkey and mouse cell lines co-transfected with HBV DNA and the dominant selective marker aminoglycoside 3'-phosphotransferase gene. We have found that the kinetics and stability of expression of the HBS gene varies with the cell lines used. Only a late transient expression of both HBS and HBe is observed between 1 and 5 weeks after transfection in monkey kidney Vero cells transfected with the complete HBV genome, while a permanent expression of HBS and HBe is obtained in mouse cells. HBS and HBe are excreted into the cell culture medium. HBe is expressed in cells transfected with the complete HBV genome, but not with isolated HBS gene. In clones of Vero cells transformed with the HBS gene, HBV sequences were rearranged or lost.     

Small-form hepatitis B surface antigen is sufficient to help in the assembly of hepatitis delta virus-like particles.

Hepatitis delta virus (HDV) has an envelope composed of large-, middle-, and small-form hepatitis B surface antigens (HBsAgs) provided by the helper hepatitis B virus (HBV). In order to examine the roles of individual HBsAgs in HDV assembly, we constructed plasmids containing each specific HBsAg gene and then cotransfected each plasmid with HDV cDNA into a permissive human hepatoma cell line (HuH-7) to examine the effects on HDV production. Results indicated that the plasmids containing only the HBsAg genes were able to complement HDV cDNA as efficiently as the plasmid containing the complete HBV genome in generating HDV-like particles. Moreover, the small-form HBsAg alone was sufficient for HDV packaging. The particles produced from the cotransfection experiments have density and protein composition characteristics similar to those of naturally occurring HDV. With the electron microscope, they were identified as 36- to 38-nm-diameter particles. It was concluded that only the HBsAgs were able to help in the assembly of HDV-like particles.     

Lipid composition of hepatitis B virus surface antigen particles and the particle-producing human hepatoma cell lines

More than 90% of lipids of hepatitis B virus surface antigen (HBsAg) particles produced by two human hepatoma cell lines (huGK-14 and PLC/PRF/5) were composed of phospholipids, with phosphatidylcholine being the dominant component, accounting for more than 80% of total membrane lipids. Analysis of subclass compositions of phospholipids of HBsAg particles and the host cell lines revealed that 1,2-diacyl glycerophosphocholine was preferentially incorporated into the membrane of the HBsAg particles, although both host cell lines contained extremely high concentrations (more than 60% of total phospholipids) of ether-linked phospholipids. Phospholipids of other hepatoma cell lines (HuH-7, Hep-G2, and huL-1) which were not associated with hepatitis B virus (HBV) infection, were composed mostly of 1,2-diacylglycerophospholipids. Activities of dihydroxyacetone-phosphate acyltransferase, which is known to be an obligatory enzyme in ether lipid biosynthesis, were found to be elevated by three- to fourfold in both huGK-14 and PLC/PRF/5 cells compared to those of other hepatoma cell lines. The results suggest a possible relationship between HBV-induced hepatocellular carcinogenesis and the drastic change in the metabolism of membrane phospholipids.     

Interferon inhibits hepatitis B virus replication in a stable expression system of transfected viral DNA.

The effect of interferon (IFN) on hepatitis B virus (HBV) replication was investigated in a stable expression system, using HepG2 cells transfected with recombinant HBV DNA. IFN was found to cause a marked reduction in the levels of both minus and plus strands of HBV DNA from core particles in the cytoplasm. Neither HBV DNA from virus particles nor the HBV surface antigen in the culture medium primarily underwent change in quantity by treatment with IFN, as was also found for HBV mRNAs and the HBV core antigen/HBV e antigen in the cytoplasm. IFN exerted no influence on HBV DNA synthesis by endogenous DNA polymerase in the core particle fraction. From these findings, it would appear that IFN inhibits HBV replication by blocking some step in the pregenome RNA-primed assembly of core particles.     

A chronic carrierlike state is established in nude mice injected with cloned hepatitis B virus DNA.

BALB/c nude mice were injected intrahepatically with hepatitis B virus (HBV) DNA prepared from recombinant plasmids. Hepatitis B surface antigen appeared in the circulation in 19 of 23 mice (82%) 3 to 20 weeks postinjection and persisted for more than 6 months in most animals. Hepatitis B e antigen appeared transiently in the circulation in 12 of the 23 mice (52%) within a few weeks after the appearance of hepatitis B surface antigen. Antibodies to the core, X, and/or polymerase gene products of HBV have also been observed in 14 (61%) of the mice. Histopathological examination of the livers at 7 months postinjection demonstrated that nearly half had characteristics consistent with chronic hepatitis. HBV DNA appeared to be integrated into host liver DNA. No evidence of viral replication was observed in sera or livers from these mice at 7 months postinjection. These results demonstrate that an HBV chronic carrierlike state can be established in mice and that such a model could be used to study host and virus factors important in the establishment and maintenance of HBV-associated chronic liver disease.     

Overexpression of hepatitis B virus surface antigens including the preS1 region in a serum-free Chinese hamster ovary cell line

Current hepatitis B virus (HBV) vaccines consist of preparations of recombinant HBV major surface antigen (sAg) and are protective in about 90-95% of vaccinated subjects. In improved vaccines, the frequency of nonresponders to the classical vaccine could be reduced by including additional epitopes from the preS-domains of the middle and large surface antigens. In this report, the development and characterization of a CHO cell line for HBsAg, expressing major, middle, and large antigens are described. Despite the previously reported retention of secreted proteins by the preS1 domain, cell lines could be amplified that secreted large amounts of the complete set of antigens. A producer line was established that expressed 1mg HBsAg per 100ml suspension culture per week during exponential growth. The productivity per cell increased further by at least threefold when the culture reached the stationary phase at high cell densities. In the production cell line, several hundred copies of the HBV vector were integrated at two adjacent sites into chromosome 2. The cell line was adapted to growth in a defined protein-free medium minimizing the risk of adventitious agents introduced by animal derived supplements. The cell line stably produced antigen over several months. In the candidate vaccine, both preS2 and preS1 domains were present at ratios similar to HBsAg from human sera. In summary, a production cell line for an improved HBV vaccine is presented with properties such as high productivity, long term stability of expression, and growth in protein-free media.     

Intracellular expression of a cloned antibody fragment interferes with hepatitis B virus surface antigen secretion

We evaluated the potential of an intracellularly expressed antibody fragment to interfere with hepatitis B virus (HBV). Sequences coding for the immunoglobulin variable regions of the HBV surface antigen (HBsAg) specific monoclonal antibody 5C3 were isolated and characterized. A secretory pathway-targeted, 5C3 derived single chain Fv (sFv) fragment was expressed in HuH-7 hepatocellular carcinoma cells together with HBsAg. Quantification of extracellular HBsAg levels in the cell culture supernatant demonstrated that the presence of the 5C3 sFv equipped with a secretory pathway retention signal SEKDEL reduced extracellular HBsAg levels by a mean of 85%. Co-immunoprecipitation studies revealed that the 5C3 sFv targeted to the secretory pathway physically interacted with its target antigen, HBsAg. Confocal microscopy studies confirmed the intracellular expression and colocalization of the 5C3 sFv and HBsAg. We conclude that certain intracellularly expressed antibody fragments will substantially interfere with HBV antigen secretion from the cell.     

Specific inhibition of hepatitis B viral gene expression in vitro by targeted antisense oligonucleotides.

A 21-mer oligodeoxynucleotide complementary to the polyadenylation signal for human hepatitis B virus (HBV) was complexed to a soluble DNA-carrier system that is targetable to hepatocytes via asialoglycoprotein receptors present on those cells. A cell line, HepG2 (2.2.15) that possesses asialoglycoprotein receptors and is permanently transfected with hepatitis B virus (ayw subtype) was exposed to complexed antisense DNA or controls. In the presence of complexed antisense DNA, the concentration of hepatitis B surface antigen in medium was 80% lower than controls after 24 h. Furthermore, during the next 6 days, there was no significant increase in surface antigen concentration in the presence of complexed antisense DNA. The inhibition could be effectively blocked by competition with an excess of free asialoglycoprotein. Total protein synthesis remained unchanged by exposure to complexed antisense sequences under identical conditions. In addition, HBV DNA in the medium and cell layers after 24-h exposure to complexed antisense sequences was 80% lower than in controls. The data indicate that antisense oligonucleotides complexed by a soluble DNA-carrier system can be targeted to cells via asialoglycoprotein receptors resulting in specific inhibition of hepatitis B viral gene expression and replication.