Amplification and rearrangement in hepatoma cell DNA associated with integrated hepatitis B virus DNA.

DNA of hepatitis B virus is found to be integrated into the genome of infected human liver cells and may be related to the development of primary liver carcinoma. We have previously reported the cloning of cellular DNA with integrated HBV sequences from the PLC/PRF/5 cell line which derives from a human primary liver carcinoma. Two clones, designated as A-10.7 and A-10.5, and a third uncloned fragment are compared by restriction enzyme mapping, hybridization and nucleotide sequencing. The results indicate that amplification of integrated viral DNA and host flanking regions has occurred, followed by transposition and/or major deletions. The implications of these findings for the development of primary liver carcinoma are discussed.     

Rearrangement of a common cellular DNA domain on chromosome 4 in human primary liver tumors.

Hepatitis B virus (HBV) DNA integration has been shown to occur frequently in human hepatocellular carcinomas. We have investigated whether common cellular DNA domains might be rearranged, possibly by HBV integration, in human primary liver tumors. Unique cellular DNA sequences adjacent to an HBV integration site were isolated from a patient with hepatitis B surface antigen-positive hepatocellular carcinoma. These probes detected rearrangement of this cellular region of chromosomal DNA in 3 of 50 additional primary liver tumors studied. Of these three tumor samples, two contained HBV DNA, without an apparent link between the viral DNA and the rearranged allele; HBV DNA sequences were not detected in the third tumor sample. By use of a panel of somatic cell hybrids, these unique cellular DNA sequences were shown to be located on chromosome 4. Therefore, this region of chromosomal DNA might be implicated in the formation of different tumors at one step of liver cell transformation, possibly related to HBV integration.     

Integration of hepatitis B virus: analysis of unoccupied sites.

Hepatitis B virus (HBV) sequences integrated in the PLC/PRF/5 cell line (Alexander cells), which was derived from a human primary liver carcinoma, were previously extensively studied. Here we describe the analysis of the unoccupied sites of two linearly integrated forms of HBV DNA, AL-14 and AL-26, that were characterized previously. No major cellular DNA rearrangements were seen at the integration sites except for small deletions of host sequences: 2 kilobases of DNA in AL-14 and 17 base pairs (bp) in AL-26. The unoccupied site of AL-26 was found to be missing 182 bp, which previously mapped next to the right end of the integration sites of several independent clones. These were believed to be of cellular origin, but we show here that these 182 bp are in fact from unusual HBV sequences. Surprisingly, a region of this newly detected HBV DNA sequence is more homologous to that of woodchuck HBV DNA. Our analysis shows that the normal counterparts of both AL-14 and AL-26 contain minisatellite-like repetitive sequences. Based on the data presented here and our previous finding of HBV DNA integration at satellite sequences, we propose that genomic simple repetitive sequences are hot spots for HBV DNA integration.     

State of hepatitis B viral DNA in a human hepatoma cell line.

PLC/PRF/5, a tissue culture cell line isolated from a human hepatocellular carcinoma and producing hepatitis B surface antigen, was studied for the presence of hepatitis B virus (HBV)-specific DNA and RNA. PLC/PRF/5 cell DNA accelerated the rate of reassociation of HBV [32P]DNA, and quantitative experiments indicated that the cells contained approximately four copies of viral DNA per haploid, mammalian cell DNA equivalent. PLC/PRF/5 DNA accelerated the rate of reassociation of all individual restriction endonucleases HincII and HaeIII fragments of HBV [32P]DNA, indicating that DNA from all regions of the viral genome is present in the cells. This suggests that these cells contain at least most, and possibly all, of the viral genome. Digestion of PLC/PRF/5 cell DNA with restriction endonuclease HindIII (an enzyme found not to cleave the DNA of any HBV isolate so far examined) yielded only three fragments, all larger than virion DNA, which contained HBV DNA base sequences, suggesting that HBV DNA is integrated in high-molecular-weight DNA at three different sites in these cells and that there is no viral DNA in an episomal form. PLC/PRF/5 cell [32P]RNA was found to hybridize with all restriction fragments of HBV DNA adequately tested, indicating that at least most, and possibly all, of the viral DNA in these cells is transcribed.     

Structural rearrangement of integrated hepatitis B virus DNA as well as cellular flanking DNA is present in chronically infected hepatic tissues.

Cellular DNAs from human livers chronically infected with hepatitis B virus (HBV) were analyzed by Southern blot hybridization for the presence of integrated HBV DNA. In 15 of 16 chronically infected hepatic tissues, random HBV DNA integration was evident. By molecular cloning and structural analyses of 19 integrants from three chronically infected hepatic tissues, deletion of cellular flanking DNA in all cases and rearrangement of HBV DNA with inverted duplication or translocation of cellular flanking DNA at the virus-cell junction in some cases were noted. Thus, the rearrangement of HBV DNA or cellular flanking DNA is not a specific incident of hepatocellular carcinoma formation. Detailed analyses of various integrants bearing rearranged viral DNA failed to indicate any gross structural alteration in cellular DNA, except for a small deletion at the integration site, indicating that viral DNA rearrangement with inverted duplication possibly occurs before integration of HBV DNA. Based on nucleotide sequencing analyses of virus-virus junctions, a one- to three-nucleotide identity was found. A mechanism for this inverted duplication of HBV DNA is proposed in which illegitimate recombination between two complementary viral strands may take place by means of a nucleotide identity at the junction site in a weakly homologous region (patchy homology) on one side of adjoining viral sequences. For virus-cell junctions, the mechanism may be basically similar to that for virus-virus junctions.     

Free and integrated forms of hepatitis B virus DNA in human hepatocellular carcinoma cells (PLC/342) propagated in nude mice.

Primary hepatocellular carcinoma cells (PLC/342) propagated in nude mice produce hepatitis B surface antigen of subtype adr, as well as core particles containing viral DNA and DNA polymerase. Free and integrated forms of hepatitis B virus (HBV) DNA in the tumor were isolated by molecular cloning, and their nucleotide sequences were determined. Both of the two representative clones of free HBV DNA had the same genomic length (3,158 base pairs) and had two stop codons as well as two deletions in the envelope gene. None of the seven distinct clones of integrated HBV DNA possessed the entire viral genome. The integrated clone sequences had deletions and rearrangements, and only two clones possessed the envelope gene including the promoter and enhancer sequences. The C gene, which codes for core protein, was preserved in the two free clones and one of the integrated clones. The P gene, which codes for DNA polymerase, had deletions at two positions of 21 and 36 base pairs in both free clones, but was carried in toto by one of the integrated clones. The nucleotide sequences of the S genes of two free and four integrated clones, as well as their two inverted repeats, were compared. All of the eight sequences of the S gene possessed two nucleotide substitutions in common that were not displayed by any of the reported HBV genomes. The sequences differed from one another by only 1.2%. They differed, however, from 11 reported HBV genomes of subtype adr by 2.4%, from an ayr genome by 1.9%, from 2 adw genomes by 6.9%, and from 2 ayw genomes by 5.9%. These results indicate that all free and integrated HBV DNA species in the PLC/342 tumor cell evolved from a common progenitor. The free HBV DNA underwent nucleotide substitutions during several integration events, resulting in integrated HBV DNA copies that were similar in sequence but distinct from the reported HBV genomes.     

Integration of HBV-DNA into liver and hepatocellular carcinoma cells during persistent HBV infection

The hepatitis B virus carrier state (persistent HBV infection) is characterized by the presence of viral surface antigen (HBsAg) and virion particles (Dane particles) in the blood. From 1% to 10% of carriers develop chronic liver disease and/or hepatocellular carcinoma. Recent studies have demonstrated integrated HBV-DNA in hepatocellular carcinomas and in several human hepatoma cell lines. In hepatoma patients, integrated HBV-DNA has been found in all HBsAg carriers. Nontumorous liver also revealed integrated HBV-DNA with the same or a different hybridization pattern from that observed in the tumor. To explore when integration occurs, carriers of short-term (less than 2 years) or long-term (greater than 8-10 years) were evaluated. DNA extracts from percutaneous (needle) liver biopsies showed free viral DNA with no specific integration bands in short-term carriers. In long-term carriers, HBV-DNA was integrated into the host genome with either a diffuse or a unique hybridization pattern. HBV-DNA integration correlated with the duration of the carrier state and absence of virions in the serum but did not correlate with histologic evidence of chronic hepatitis. These studies suggest that integration of HBV-DNA occurs during persistent HBV infection irrespective of liver disease and precedes development of hepatocellular carcinoma.     

Characterization of viral genomes in the liver and serum of chimpanzee long-term hepatitis B virus carriers: a possible role for supercoiled HBV-DNA in persistent HBV infection

In chimpanzee hepatitis B virus (HBV) carriers, the molecular mechanism for viral persistence has been examined by analyzing the properties of viral DNA molecules in liver and serum. Two extrachromosomal HBV-DNA molecules migrating on Southern blots at 4.0 kb and 2.3 kb were observed in chimpanzee liver DNA. There was no evidence for integration of HBV sequences into the host genome. The HBV-DNA molecule which migrated at 4.0 kb position represents a full-length "nicked," relaxed circular form, and the DNA molecules migrating at 2.3 kb position represents a supercoiled form of the HBV genome. Evidence for supercoiled HBV-DNA in serum was obtained by production of the relaxed circular intermediate upon digestion of Dane particle DNA with specific nucleases S1 and Bal 31. A possible role of these two extrachromosomal HBV-DNA molecules in the biology of hepatitis B virus infection and the mechanism for viral persistence are discussed.     

Organization and expression of hepatitis B sequences cloned from hepatocellular carcinoma tissue DNA

We have constructed a phage lambda library of liver DNA fragments from West African patient who died of liver failure due to advanced hepatocellular carcinoma. Four hepatitis B virus (HBV) DNA-carrying recombinants have been isolated, one clone (lambda IA22) being analyzed in greatest detail. It contains approximately 3.8 kb of HBV DNA without detectable deletions or rearrangements. One site of integration lies close to the nick in free viral DNA. The restriction map of the HBV sequences is close to those published for the ay subtype. Coconvection of mouse Ltk- cells with lambda IA22 and cloned thymidine kinase gene results in the expression of gene S and the excretion of hepatitis B surface antigen (HBsAg) particles into the culture supernatant.     

Integration pattern of hepatitis B virus DNA sequences in human hepatoma cell lines.

Four human hepatoma cell lines established from primary hepatocellular carcinomas were examined for the presence of hepatitis B virus DNA sequences. Reassociation kinetic analysis indicated that the cell lines HEp-3B 217, HEp-3B 14, HEp-3B F1, and PLC/PRF/5 contained two, one, one, and four genome equivalents per cell, respectively. Southern blot hybridization analysis demonstrated that hepatitis B virus DNA was integrated into the cellular DNAs of these cell lines. Further liquid hybridization studies with 32P-labeled HincII restriction fragments of hepatitis B virus DNA established that DNA sequences from all regions of the HBV genome were represented in the integrated viral sequences. Although the three HEp-3B cell lines were derived from the same tumor, they differed significantly in their patterns of integration of hepatitis B virus DNA, the number of copies of viral DNA per cell, and their ability to produce the virus-coded surface antigen.     

Naturally occurring missense mutation in the polymerase gene terminating hepatitis B virus replication.

A hepatitis B virus (HBV) genome was cloned from human liver. Numerous mutations in all viral genes define this HBV DNA as a mutant, divergent from all known HBV DNA sequences. Functional analyses of this mutant demonstrated a defect blocking viral DNA synthesis. The genetic basis of this defect was identified as a single missense mutation in the 5' region of the viral polymerase gene, resulting in the inability to package pregenomic RNA into core particles. The replication defect could be trans-complemented by a full-length wild-type, but not by a full-length mutant or 3'-truncated wild-type, polymerase gene construct. Our findings indicate a critical role of the 5' polymerase gene region in the life cycle of the virus and suggest that introducing missense mutations in this region can be a strategy to terminate viral replication in vivo.     

Genomic localization of hepatitis B virus in a human hepatoma cell line.

The integration of hepatitis B viral sequences in the human hepatoma Alexander cell line has been investigated after fractionation of the cell line DNA by centrifugation in a Cs2SO4/BAMD (3,6-(bis-acetato mercurimethyl) dioxane) density gradient. Eight out of nine integrated viral sequences were localized in DNA component H3, which only represents 4% of the human genome and matches the base composition of HBV sequences. These results indicate a targeting and/or a higher stability of the latter in a specific, small compartment of the host genome.     

Multiple integration site of hepatitis B virus DNA in hepatocellular carcinoma and chronic active hepatitis tissues from children.

Attention was directed to hepatitis B virus (HBV) integration in tissues obtained from an hepatocellular carcinoma (HCC) of an 11-year-old boy and from the liver of his 6-year-old brother, who had chronic active hepatitis. Multiple HBV DNA integration sites were demonstrated in both tissues. Cell population(s) in the HCC and liver from the patient with chronic active hepatitis were assumed to be heterogeneous with regard to HBV integration. The integrated forms in the two tissues showed similar genetic organization without gross rearrangement. The location of one of the virus-chromosomal junctions was restricted to the 5'-end region of the minus-strand DNA of HBV. The experimental results support our previous model for the mechanism of HBV integration, in which minus-strand replicative intermediates integrate into chromosomal DNA. The integrated HBV DNAs were conserved in the same region of the viral genome, spanning from the C gene through the S gene to the X gene, which contains intrinsic promoter-enhancer sequences.     

Rearrangement of the surface antigen gene of hepatitis B virus integrated in the human hepatoma cell lines.

The rearrangement of integrated HBV DNA sequences in three different hepatoma cell lines, huH-1, huH-2, KG-55-T from Japanese patients, were studied by blot hybridization using whole HBV genome or a HBsAg or HBcAg DNA as a probe. The characteristic existence of multiple integration sites of HBV DNA sequences in each HindIII-restricted hepatoma cell DNA was revealed by the HBV genome probe. Detection of the isolated HBsAg gene in the HindIII fragment indicates that the integration of HBV DNA was not always related to the maintenance of the whole viral genome, and that movement of the HBsAg gene to another location occurred by rearrangement. On the other hand, the presence of the HBV DNA sequence without the intact HBcAg gene was shown in some of the HindIII fragments, when the HBcAg gene, probe was used, but a HindIII fragment, containing only the HBcAg gene, was not detected so far. The absence of the intact HBcAg gene suggests that the viral genome may lose a part of the HBcAg gene in the process of integration. This is consistent with recent findings of Ogston et al. (1982) that in Woodchuck hepatocellular carcinoma viral sequences are extensively rearranged.     

Hepatitis B virus DNA integration and expression of an erb B-like gene in human hepatocellular carcinoma.

Southern blot studies on Hepatitis B Virus (HBV) DNA integration in 13 human hepatocellular carcinomas (HCCs) patients revealed the presence of several distinct HBV integration sites in different human liver disease patients. In one HCC patient the DNA fragment containing the HBV integration also hybridized to an erb B probe. The erb B/HBV co-migrating DNA fragment was cloned and sequenced, and showed that HBV DNA is integrated next to a cellular DNA fragment which is homologous to the tyrosine protein kinase domain of the human epidermal growth factor receptor gene and other cell surface receptor genes. The virus-integrated cellular DNA sequence is expressed in this HCC patient, suggesting a possible role for this gene in hepatocarcinogenesis.