Woodchuck hepatocytes remain permissive for hepadnavirus infection and mouse liver repopulation after cryopreservation.

Isolated hepatocytes represent a relevant model of the liver and are highly required both for research and therapeutic applications. However, sources of primary liver cells from human beings and from some animal species are limited. Therefore, cryopreservation of hepatocytes could greatly facilitate advances in various research areas. The aim of this study was to evaluate whether cryopreserved primary woodchuck hepatocytes could be used for woodchuck hepatitis B virus (WHV) infection studies, and whether they could maintain their regenerative potential in vivo after thawing. Critical steps for good quality of cryopreserved hepatocytes included the use of University of Wisconsin (UW) solution as a main component of the freezing medium, stepwise reduction of dimethylsulfoxide (DMSO) to avoid osmotic shock, and maintenance of low concentrations of DMSO in the culture medium. After cryopreservation, cell viability was still high (70% to 80%), and 50% to 60% of thawed cells attached to the plates. The appearance of covalently closed circular (ccc)DNA and of WHV-replicative forms a few days after in vitro infection demonstrated that thawed woodchuck hepatocytes were still susceptible to viral infection, thus proving maintenance of a very high hepatocyte-specific differentiation status. Furthermore, transplantation of woodchuck hepatocytes into the liver of urokinase-type plasminogen activator (uPA)/recombination activation gene-2 (RAG-2) mice, a model of liver regeneration, demonstrated that cryopreserved cells retained the ability to divide and to extensively repopulate a xenogenic liver. Notably, in vivo susceptibility to infection with WHV and proliferative capacity of frozen/thawed woodchuck hepatocytes in recipient mice were identical to those observed by transplanting fresh hepatocytes.

Repopulation of mouse liver with human hepatocytes and in vivo infection with hepatitis B virus.

Mice containing livers repopulated with human hepatocytes would provide excellent in vivo models for studies on human liver diseases and hepatotropic viruses, for which no permissive cell lines exist. Here, we report partial repopulation of the liver of immunodeficient urokinase-type plasminogen activator (uPA)/recombinant activation gene-2 (RAG-2) mice with normal human hepatocytes isolated from the adult liver. In the transplanted mice, the production of human albumin was demonstrated, indicating that human hepatocytes remained functional in the mouse liver for at least 2 months after transplantation. Inoculation of transplanted mice with human hepatitis B virus (HBV) led to the establishment of productive HBV infection. According to human-specific genomic DNA analysis and immunostaining of cryostat liver sections, human hepatocytes were estimated to constitute up to 15% of the uPA/RAG-2 mouse liver. This is proof that normal human hepatocytes can integrate into the mouse hepatic parenchyma, undergo multiple cell divisions, and remain permissive for a human hepatotropic virus in a xenogenic liver. This system will provide new opportunities for studies on etiology and therapy of viral and nonviral human liver diseases, as well as on hepatocyte biology and hepatocellular transplantation.

Duck hepatitis B virus DNA integration induced by oxidative radicals and its transmission from parent cells to offspring ones.

OBJECTIVE: To investigate the role of oxidative radicals in duck hepatitis B virus DNA (DHBV DNA) integration and the transmission of integrated DHBV DNA from parent cells to their offspring cells. METHODS: TUNEL assay and Southern blot hybridization were used to detect the cellular DNA strand breaks and the incidence of new type of DHBV DNA integration into cellular DNA of LMHD(21-6) cell line after the cells treated by low dose of hydrogen peroxide (10.0 micromol/L) during its growth from one cell to 3 +/- 10(7) to 5 +/- 10(7) cells. RESULTS: The rate of cell death induced by low dose of H(2)O(2) (10.0 micromol/L) was 32.0%, but that induced by high dose (>10.0 micromol/L) was more than 50.0%. At the same time, the incidence of new DHBV DNA integration into cellular DNA induced by 10.0 micromol/L of H(2)O(2) was 50.0% (6/12) and that in control group was 8.33% (1/12). There was a significant difference between the two groups (P<0.05). Besides, the new integrated DHBV-DNA in the parent cells could be found in the DNA of their offspring cells with the same size of base pair. CONCLUSION: Oxidative radicals is one of the important inducing factors in DHBV-DNA integration into cellular DNA and the integrated DHBV-DNA is able to transmit from the parent cells to their offspring cells stably.

New evidence for an extra-hepatic role of N-acetylglucosaminyltransferase III in the progression of diethylnitrosamine-induced liver tumors in mice.

N-acetylglucosaminyltransferase III (GlcNAc-TIII) is encoded by the Mgat3 gene and catalyzes the addition of the bisecting GlcNAc to the core of N-glycans. Mice lacking GlcNAc-TIII due to the insertion mutation Mgat3tmlPst (termed Mgat3neo), exhibit retarded progression of liver tumors induced by diethylnitrosamine (DEN; M. Bhaumik et al, Cancer Res., 58: 2881-2887, 1998). This phenotype seemed to be due to a reduction, in activity or amount, of a circulating glycoprotein(s) that enhances DEN-induced liver tumor progression. Here, we provide new evidence to support this hypothesis. First, we show that mice with a deletion mutation of the Mgat3 gene coding exon (Mgat3tmlJxm, termed Mgat3delta) also exhibit retarded progression of DEN-induced liver tumors. At 7 months there was a significant decrease in liver weight (approximately 27%; P < 0.01), reflecting reduced tumor burden in Mgat3delta/delta mice. In addition, tumors were generally fewer and smaller, and histological changes were less severe in Mgat3delta/delta livers. Therefore, tumor progression is retarded in mice with two different null mutations in the Mgat3 gene. Second, we show that the development of DEN-induced tumors is unaltered by high levels of GlcNAc-TIII in the liver of transgenic mice. The Mgat3 gene coding exon under the control of the major urinary protein (MUP) promoter was used to generate transgenic mice that express GlcNAc-TIII in liver. Following DEN injection and phenobarbitol treatment, however, no significant differences were observed between MUP/Mgat3 transgenic and control mice in either tumor numbers or liver weight. The combined data provide strong evidence that retarded progression of tumors in mice lacking GlcNAc-TIII is due to the absence of the bisecting GlcNAc residue on N-glycans of a circulating glycoprotein(s) from a tissue other than liver.

Lessons From Genetically Engineered Animal Models VI. Liver repopulation systems and study of pathophysiological mechanisms in animals.

The ability to localize transplanted hepatocytes in the liver offers exciting new opportunities. Transplanted hepatocytes enter liver plates, form hybrid plasma membrane structures with adjacent hepatocytes, express liver genes correctly, and survive indefinitely. The transplanted cell mass is regulated, such that cell proliferation is limited in the normal adult liver, whereas the liver is repopulated extensively when proliferation rates in transplanted and host hepatocytes become dissociated or host hepatocytes are ablated selectively. Transplanted hepatocytes are susceptible to hepatitis viruses. These aspects of transplanted hepatocyte biology indicate that liver repopulation systems can help address questions concerning pathophysiological mechanisms.

Human DNA topoisomerase I-mediated cleavage and recombination of duck hepatitis B virus DNA in vitro.

In this study, we report that eukaryotic topoisomerase I (top1) can linearize the open circular DNA of duck hepatitis B virus (DHBV). Using synthetic oligonucleotides mimicking the three-strand flap DR1 region of the DHBV genome, we found that top1 cleaves the DNA plus strand in a suicidal manner, which mimics the linearization of the virion DNA. We also report that top1 can cleave the DNA minus strand at specific sites and can linearize the minus strand via a non-homologous recombination reaction. These results are consistent with the possibility that top1 can act as a DNA endo-nuclease and strand transferase and play a role in the circularization, linearization and possibly integration of viral replication intermediates.

Double-stranded linear duck hepatitis B virus (DHBV) stably integrates at a higher frequency than wild-type DHBV in LMH chicken hepatoma cells.

Integration of hepadnavirus DNAs into host chromosomes can have oncogenic consequences. Analysis of host-viral DNA junctions of DHBV identified the terminally duplicated r region of the viral genome as a hotspot for integration. Since the r region is present on the 5' and 3' ends of double-stranded linear (DSL) hepadnavirus DNAs, these molecules have been implicated as integration precursors. We have produced a LMH chicken hepatoma cell line (LMH 66-1 DSL) which replicates exclusively DSL duck hepatitis B virus (DHBV) DNA. To test whether linear DHBV DNAs integrate more frequently than the wild type open circular DHBV DNAs, we have characterized the integration frequency in LMH 66-1 DSL cells by using a subcloning approach. This approach revealed that 83% of the LMH 66-1 DSL subclones contained new integrations, compared to only 16% of subclones from LMH-D2 cells replicating wild-type open circular DHBV DNA. Also, a higher percentage of the LMH 66-1 DSL subclones contained two or more new integrations. Mathematical analysis suggests that the DSL DHBV DNAs integrated stably once every three generations during subcloning whereas wild-type DHBV integrated only once every four to five generations. Cloning and sequencing of new integrations confirmed the r region as a preferred integration site for linear DHBV DNA molecules. One DHBV integrant was associated with a small deletion of chromosomal DNA, and another DHBV integrant occurred in a telomeric repeat sequence.

Metabolic labeling of woodchuck hepatitis B virus X protein in naturally infected hepatocytes reveals a bimodal half-life and association with the nuclear framework.

In order to identify potential sites of hepadnavirus X protein action, we have investigated the subcellular distribution and the stability of woodchuck hepatitis virus (WHV) X protein (WHx) in primary hepatocytes isolated from woodchucks with persistent WHV infection. In vivo cell labeling and cell fractionation studies showed that the majority of WHx is a soluble cytoplasmic protein while a minor part of newly synthesized WHx is associated with a nuclear framework fraction (20%) and with cytoskeletal components (5 to 10%). Pulse-chase experiments revealed that cytoplasmic WHx has a short half-life and decays with bimodal kinetics (approximately 20 min and 3 h). The rates of association and turnover of nucleus-associated WHx suggest that compartmentalization may be responsible for the bimodal turnover observed in the cytoplasm.

Antisense downregulation of N-myc1 in woodchuck hepatoma cells reverses the malignant phenotype.

Cell line WH44KA is a highly malignant woodchuck hepatoma cell line. WH44KA cells contain a single woodchuck hepatitis virus (WHV) DNA integration in the 3' untranslated region of exon 3 of the woodchuck N-myc1 gene. The highly rearranged WHV DNA contains WHV enhancers which activate the N-myc promoter, and a hybrid N-myc1-WHV mRNA is produced, which leads to a high steady-state level of N-myc1 protein. To investigate whether continuous N-myc1 expression is required to maintain the tumor phenotype, we knocked out N-myc expression using a WHV-N-myc1 antisense vector. We identified two WH44KA antisense cell lines, designated 4-5 and 4-11, in which steady-state N-mycl protein levels were reduced by 95 and 80%, respectively. The growth rates of both antisense cell lines were reduced in comparison to those of wild-type and vector controls. The phenotype of 4-5 and 4-11 cells changed to a flattened appearance, and the cells exhibited contact inhibition. Colony-forming ability in soft agar was reduced by 92% for 4-5 cells and by 88% for 4-11 cells. Cell line 4-11 formed only small, slow-growing tumors in nude mice, consistent with a low level of N-myc1 remaining in the cells. In contrast, 4-5 cells, in which N-myc protein was reduced by greater than 95%, failed to form tumors in nude mice. The integrated WHV DNA contained the complete WHV X gene (WHx) and its promoter; however, we did not detect any WHx protein in the cells by using a sensitive assay. These data demonstrate that N-myc overexpression is required to maintain the malignant phenotype of WH44KA woodchuck hepatoma cells and provide a direct function for integrated WHV DNA in hepatocarcinogenesis.

Reactivation of the maternally imprinted IGF2 allele in TGFalpha induced hepatocellular carcinomas in mice.

The Insulin like growth factor 2 (IGF2) gene is expressed in several types of tumors in humans and mice and has been implicated as an important growth factor in tumor progression. IGF2 expression in the TGF alpha transgenic mice was analysed in liver and tumors from animals which also contained one or two functional IGF2 alleles. In a two by two mating experiment using transgenic mice containing either a TGF alpha transgene or a IGF2 gene knockout, we have investigated whether IGF2 imprinting is reversed during hepatocarcinogenesis and the consequences of IGF2 expression for tumor growth. We observed that: (1) 100% of the hepatocellular carcinomas expressed IGF2 (2) the normally imprinted maternal allele is active in the tumors in which the paternal allele is knocked out and (3) all three of the murine IGF2 promoters upstream of the reactivated maternal alleles are transcriptionally active in tumors. We also observed that the total tumor burden of animals with two wild type IGF-2 alleles (paternal and maternal) was the same as the tumor burden in animals which contained only a single reactivated maternal allele. The 100% incidence of reactivation of the imprinted maternal allele suggests that IGF2 expression is selected during murine hepatocarcinogenesis and can substitute for the paternal allele when it is inactivated.

Liver repopulation with xenogenic hepatocytes in B and T cell-deficient mice leads to chronic hepadnavirus infection and clonal growth of hepatocellular carcinoma.

To investigate host and viral mechanisms determining hepadnaviral persistence and hepatocarcinogenesis, we developed a mouse model by transplanting woodchuck hepatocytes into the liver of mice that contain the urokinase-type plasminogen activator transgene (uPA) and lack mature B and T lymphocytes due to a recombination activation gene 2 (RAG-2) gene knockout. The woodchuck hepatocytes were transplanted via intrasplenic injection and were found to integrate into the recipient mouse liver cord structure. Normal adult woodchuck hepatocytes proliferated and reconstituted up to 90% of the uPA/RAG-2 mouse liver. uPA/RAG-2 mice containing woodchuck hepatocytes were infectable with woodchuck hepatitis virus (WHV) and showed WHV replication for at least 10 months with titers up to 1 x 10(11) virions per ml in the peripheral blood. WHV-infected hepatocytes from chronic carrier woodchucks also established a persistent infection in uPA/RAG-2 mice after an 8- to 12-week lag period of viremia. Although WHV envelope, core, and X proteins were produced in the uPA/RAG-2 mice, no inflammatory host immune response was observed in the liver of WHV-replicating mice. A first antiviral test demonstrated a greater than four orders of magnitude drop in WHV titer in response to interferon alpha treatment. WHV replication was up-regulated by dexamethasone treatment. Comparison of precancerous lesions in donor woodchucks versus recipient uPA/RAG-2 mice revealed an enrichment of dysplastic precancerous hepatocytes in transplanted mice. Clonal amplification of hepatocytes from a woodchuck with hepatocellular carcinomas was demonstrated by the detection of unique WHV DNA integration patterns in hepatocellular carcinomas that arose in uPA/RAG-2 mice. In the absence of B or T cell-mediated immune responses, WHV establishes a persistent noncytotoxic infection of woodchuck hepatocytes in uPA/RAG-2 chimeric mouse livers. Further studies of the kinetics of hepadnavirus infection and replication in quiescent and proliferating hepatocytes should increase our understanding of hepadnavirus spread and aid in the design of therapies to block or cure persistent infection.

Increase in the frequency of hepadnavirus DNA integrations by oxidative DNA damage and inhibition of DNA repair.

Persistent hepadnavirus infection leads to oxidative stress and DNA damage through increased production of toxic oxygen radicals. In addition, hepadnaviral DNA integrations into chromosomal DNA can promote the process of hepatocarcinogenesis (M. Feitelson, Clin. Microbiol. Rev. 5:275-301, 1992). While previous studies have identified preferred integration sites in hepadnaviral genomes and suggested integration mechanisms (M. A. Buendia, Adv. Cancer Res. 59:167-226, 1992; C. E. Rogler, Curr. Top. Microbiol. Immunol. 168:103-141, 1991; C. Shih et al., J. Virol. 61:3491-3498, 1987), very little is known about the effects of agents which damage chromosomal DNA on the frequency of hepadnaviral DNA integrations. Using a recently developed subcloning approach to detect stable new integrations of duck hepatitis B virus (DHBV) (S. S. Gong, A. D. Jensen, and C. E. Rogler, J. Virol. 70:2000-2007, 1996), we tested the effects of increased chromosomal DNA damage induced by H2O2, or of the disturbance in DNA repair due to the inhibition of poly(ADP-ribose) polymerase (PARP), on the frequency of DHBV DNA integrations. Subclones of LMH-D21-6 cells, which replicate DHBV, were grown in the presence of various H2O2 concentrations and exhibited up to a threefold increase in viral DNA integration frequency in a dose-dependent manner. Moreover, inhibition of PARP, which plays a role in cellular responses to DNA breakage, by 3-aminobenzamide (3-AB) resulted in a sevenfold increase in the total number of new DHBV DNA integrations into host chromosomal DNA. Removal of either H2O2 or 3-AB from the culture medium in a subsequent cycle of subcloning was accompanied by a reversion back towards the original lower frequency of stable DHBV DNA integrations for LMH-D21-6 cells. These data support the hypothesis that DNA damage sites can serve as sites for hepadnaviral DNA integration, and that increasing the number of DNA damage sites dramatically increases viral integration frequency.

The hepatitis B virus (HBV) precore protein inhibits HBV replication in transgenic mice.

In this study, we examined the ability of the hepatitis B virus (HBV) precore, envelope, and X gene products to modulate HBV replication in the livers of transgenic mice that replicate the virus. Hepatic HBV replication was not affected by overexpression of the envelope or X gene products when these animals were crossed with transgenic mice that express the corresponding viral genes in the hepatocyte. Overexpression of the precore protein, however, eliminated nucleocapsid particles from the cytoplasm of the hepatocytes and abolished HBV replication without affecting the hepatic steady-state content of pregenomic HBV RNA. These observations suggest that the precore protein can exert a dominant negative effect on HBV replication, presumably at the level of nucleocapsid particle maturation or stability, suggesting an important role for this enigmatic viral protein in the HBV life cycle.

Insulin-like growth factor II blocks apoptosis of N-myc2-expressing woodchuck liver epithelial cells.

N-myc2 and insulin-like growth factor II (IGF-II) are coordinately overexpressed in the great majority of altered hepatic foci, which are the earliest precancerous lesions observed in the liver of woodchuck hepatitis virus carrier woodchucks, and these genes continue to be overexpressed in hepatocellular carcinomas (HCCs). We have investigated the function of these genes in woodchuck hepatocarcinogenesis by using a woodchuck liver epithelial cell line (WC-3). WC-3 cells react positively with a monoclonal antibody (12.8.5) against woodchuck oval cells, suggesting a lineage relationship with oval cells. Overexpression of N-myc2 in three WC-3 cell lines caused their morphological transformation and increased their growth rate and saturation density in medium containing 10% serum. Removal of serum from the medium increased cell death of the N-myc2-expressing lines, whereas cell death in control lines was minimal. The death of N-myc2-expressing WC-3 cells was accompanied by nucleosomal fragmentation of cellular DNA, and DAPI (4',6-diamidino-2-phenylindole) staining revealed condensation and fragmentation of the nuclei, suggesting that N-myc2-expressing WC-3 cells undergo apoptosis in the absence of serum. In colony regression assays, conducted in the absence of serum, control colonies were stable, while N-myc2-expressing colonies regressed to various degrees. Addition of recombinant human IGF-II to the serum-free medium blocked both cell death and colony regression in all the N-myc2-expressing lines. Therefore, coordinate overexpression of N-myc2 and IGF-II in woodchuck altered hepatic foci may allow cells which otherwise might die to survive and progress to hepatocellular carcinoma.

Woodchuck hepatitis virus X protein is present in chronically infected woodchuck liver and woodchuck hepatocellular carcinomas which are permissive for viral replication.

The woodchuck hepatitis virus (WHV) X gene (WHx) is required for infectivity of WHV in woodchucks, and the gene encodes a broadly acting transcription factor. Several lines of evidence from cell culture and transgenic mice suggest that X proteins can promote hepatocarcinogenesis. To determine whether WHx-encoded proteins are present during persistent infection and hepatocellular carcinoma (HCC) in woodchucks, we surveyed livers and HCCs from a panel of WHV carrier woodchucks for the presence of WHx by utilizing an immunoprecipitation-Western blot (immunoblot) procedure. We detected a single 15.5-kDa WHx gene product in 100% of the persistently infected livers but not in livers from animals which had recovered from acute infection or in those of uninfected woodchucks. Analysis of HCCs revealed that all of the tumors which contained WHV replication intermediates were also positive for WHx. In contrast, WHx was undetectable in HCCs which did not contain replicative intermediates. Subcellular localization studies detected WHx in the cytoplasm but not in the nuclei of primary woodchuck hepatocytes. Comparative immunoprecipitation experiments revealed that there were 4 X 10(4) to 8 X 10(4) molecules of WHx per primary woodchuck hepatocyte. Four lines of WHx transgenic mice did not develop HCC spontaneously. However, when one line was treated with diethylnitrosamine, the occurrence of precancerous lesions was enhanced compared with that in diethylnitrosamine-treated nontransgenic controls. The apparent absence of WHx in some woodchuck HCCs indicates that WHx may not be required to maintain the tumor phenotype, whereas its presence in all persistently infected livers leaves open the possibility that it plays a role in hepatocarcinogenesis.

Loss and acquisition of duck hepatitis B virus integrations in lineages of LMH-D2 chicken hepatoma cells.

Hepatocellular carcinoma is the culmination of a series of genetic events which progressively alter the phenotype of a hepatocyte toward malignancy. Hepadnaviral DNA integrations are agents of genetic change which can promote the process of hepatocarcinogenesis. We previously characterized episomally derived duck hepatitis B virus (DHBV) integrations in LMH-D2 cells that replicate wild-type DHBV. In an effort to understand how integrations function as agents of progressive genetic change, we have studied integrations of DHBV DNA in three lineages of LMH-D2 cells through three generations of subclones. Our data have established several features of the integration process. First, single and multiple integrations occur continuously through successive cell generations. Second, the integration frequency can vary dramatically in subclones of the same cell line. Third, integrations can be lost from successive generations of cells and loss of an integration can be accompanied by loss of cellular DNA associated with the integration. Finally, certain subclones which acquire greater plating efficiency have been distinguished by unique new integration patterns. These results provide a basis for DHBV integrations to function as activators of protooncogenes, as well as agents of the loss of tumor suppressor genes during hepatocellular carcinogenesis.

Hepatic overexpression of insulin-like growth factor-II in adulthood increases basal and insulin-stimulated glucose disposal in conscious mice.

The physiological role of circulating insulin-like growth factor-II (IGF-II) in adult humans is poorly understood. We recently generated an IGF-II transgenic murine model of persistent IGF-II production (plasma IGF-II approximately 30-fold increased above normal) through over-expression of the transgene driven by the major urinary protein promoter (Rinderknecht, E., and Humbel, R. E. (1978) J. Biol. Chem. 269, 13779-13784). To determine whether in vivo insulin action is improved in these transgenic mice, we performed euglycemic insulin (18 milliunits/kg.min) clamp studies in conscious IGF-II transgenic and in age- and weight-matched control mice. Plasma glucose and insulin concentrations were significantly lower in the IGF-II transgenic compared with both control grouoff Despite decreased plasma glucose concentration, basal hepatic glucose production (HGP) and glucose clearance were increased. During the insulin clamp studies in IGF-II transgenic mice compared with control mice (a) the rates of glucose infusion and glucose uptake were increased by approximately by 65 and approximately 55%, respectively; (b) glycolysis was increased by approximately 12% while glycogen synthesis was approximately 2-fold higher; (c) while the suppression of plasma free fatty acid was similar, the increment in plasma lactate concentration was significantly higher; (d) although HGP was similarly inhibited by insulin, phosphoenolpyruvate gluconeogenesis was enhanced and accounted for a larger portion of HGP (64% versus approximately 40% in control mice). Our data suggest that the persistence of circulating IGF-II in adult mice to levels commonly observed in adult humans (50-70 nM) causes a marked improvement in peripheral (skeletal muscle) insulin action, which is not due to changes in body composition. These results suggest that circulating IGF-II may exert a regulatory role on insulin sensitivity and body composition in humans.

Duck hepatitis B virus integrations in LMH chicken hepatoma cells: identification and characterization of new episomally derived integrations.

While the cytoplasmic phase of the hepadnavirus replication cycle is well understood, very little is known about the nuclear phase. In contrast to retroviruses, proviral integration is not required for hepadnavirus replication; however, some of the viral DNAs in the nucleus are diverted into an integration pathway. Under certain conditions these integrations function as carcinogenic agents. In order to study the integration process, we have utilized LMH-D2 cells, which replicate wild-type duck hepatitis B virus (DHBV), to develop the first protocol to detect and characterize integrations of DHBV originating from episomal viral DNAs. Contrary to expectations, our results showed that stable new integrations are readily detectable in subclones of LMH-D2 cells. Complete characterization of one integration revealed a single-genome-length integrant with the structure of double-stranded linear (DSL) DHBV DNAs which are produced by in situ priming during viral replication. The integration contained a terminal redundancy of 6 bp from the r region of the virus DNA minus strand as well as a direct repeat of 70 bp of cellular DNA. On the basis of the structure of the integrant and the cellular DNA target site, we propose a molecular model for the integration mechanism that has some similarities to that of retroviruses. Identification of DSL hepadnavirus DNA integration suggests the possibility that modified DSL viral DNAs may be the precursors to a class of simple, unrearranged hepadnavirus integrations.

Sequences and structures at hepadnaviral integration: recombination sites implicate topoisomerase I in hepadnaviral DNA rearrangements and integration.

We have previously shown that eukaryotic topoisomerase I (topo I) can mediate hepadnaviral integration in vitro. To investigate further the possible in vivo significance of topo I in hepadnaviral integration and to detect additional important factors, we have generated an extensive compilation of hepadnaviral recombination sites from chronically infected liver tissues and hepatocellular carcinomas. These sequences were subjected to various established sequence and structural analyses. Our investigation provides evidence that topo I can mediate hepadnaviral integration and rearrangement in vivo. During integration, free ends can be exposed to other nuclear enzymes, resulting in the addition of 'filler DNA'. In other cases, junctional homologies between viral and cellular DNA may facilitate integration. Structural analysis suggests that torsional stress may act on the cellular target sites, possibly promoting the integration process. A mechanism is proposed by which hepadnavirus integration into the host chromosomes is primarily mediated by topo I.

Hepatitis B virus nucleocapsid particles do not cross the hepatocyte nuclear membrane in transgenic mice.

Transgenic mice that express the hepatitis B virus core protein were used to examine factors that influence the intracellular localization of nucleocapsid particles in the primary hepatocyte in vivo. In this model, viral nucleocapsid particles are strictly localized to the nucleus of the hepatocyte except when the nuclear membrane dissolves during cell division, at which time they enter the cytoplasm. The cytoplasmic nucleocapsid particles do not reenter the nucleus, however, when the nuclear membrane re-forms after cell division. The data support the notion that nucleocapsid particles can form de novo within the nucleus, and they suggest that performed nucleocapsid particles cannot be transported across the intact nuclear membrane in either direction. The results imply that nucleocapsid disassembly is probably required for entry of the hepadnaviral genome into the nucleus, and they question the role of the intranuclear viral nucleocapsid particle during the viral life cycle.