Sustained survival of human hepatocytes in mice: A model for in vivo infection with human hepatitis B and hepatitis delta viruses.

Persistence of hepatocytes transplanted into the same or related species has been established. The long-term engraftment of human hepatocytes into rodents would be useful for the study of human viral hepatitis, where it might allow the species, technical and size limitations of the current animal models to be overcome. Although transgenic mice expressing the hepatitis B virus (HBV) genome produce infectious virus in their serum, the viral life cycle is not complete, in that the early stages of viral binding and entry into hepatocytes and production of an episomal transcriptional DNA template do not occur. As for hepatitis delta virus (HDV), another cause of liver disease, no effective therapy exists to eradicate infection, and it remains resistant even to recent regimens that have considerably changed the treatment of HBV (ref. 13). Here, we demonstrate long-term engraftment of primary human hepatocytes transplanted in a matrix under the kidney capsule of mice with administration of an agonistic antibody against c-Met. These mice were susceptible to HBV infection and completion of the viral life cycle. In addition, we demonstrate super-infection of the HBV-infected mice with HDV. Our results describe a new xenotransplant model that allows study of multiple aspects of human hepatitis viral infections, and may enhance studies of human liver diseases.

State of the p53 gene in hepatocellular carcinomas of ground squirrels and woodchucks with past and ongoing infection with hepadnaviruses.

Infection with hepadnaviruses and exposure to dietary aflatoxin are considered major risk factors in the development of hepatocellular carcinoma (HCC) both in humans and in animals. Recently, a broad range of mutations in the p53 tumor suppressor gene has been reported in human HCCs, predominantly from hepatitis B virus carriers in areas with either high or low levels of exposure to dietary aflatoxin. To determine whether p53 mutations are common to HCCs of hosts infected with related hepadnaviruses with and without treatment with aflatoxin, we studied the occurrence of mutations in the p53 gene in HCCs of ground squirrels and woodchucks with history of infection with ground squirrel hepatitis virus (GSHV) and woodchuck hepatitis virus, respectively. Sequencing of wild type p53 genes from ground squirrels and woodchucks revealed remarkable homology between the two species with only a few amino acid differences in exons 4, 8, and 9. Using direct polymerase chain reaction sequencing, we analyzed the state of the p53 gene (exons 4-9) in 20 HCCs from ground squirrels (2 uninfected, 7 with past, and 11 with ongoing infection with GSHV) and in 11 HCCs from woodchucks persistently infected with woodchuck hepatitis virus. Five GSHV carrier and two uninfected ground squirrels received i.p. administration of aflatoxin B1. We detected only one mutation in the p53 gene of the tested animals. This mutation was located in codon 176 of exon 5 in the HCC of a GSHV-positive ground squirrel treated with aflatoxin. Mutation was caused by a G to T transversion in the second position of the codon, resulting in the replacement of cysteine with phenylalanine, and was accompanied by a tumor-specific loss of heterozygosity. p53 allelic amino acid variation with sequences coding for aspartic acid or asparagine was present in codon 61 in the variable region of exon 4 in both HCCs and nonneoplastic tissues of ground squirrels. In view of the considerably lower apparent rate of mutations in comparison to human HCCs, we suggest a less important role for aflatoxin in the induction of p53 mutations in HCCs of ground squirrels. Alternatively, etiological factors other than p53 mutations may be of greater significance in the development of HCC in ground squirrels and woodchucks.

Hepatic neoplasms in aflatoxin B1-treated, congenital duck hepatitis B virus-infected, and virus-free pekin ducks.

To assess the effects of the combination of persistent hepadnavirus infection and chemical carcinogen exposure, aflatoxin B1 (AFB) was administered p.o. for 60 days to congenitally duck hepatitis B virus (DHBV)-infected and virus-free Pekin ducks, starting at 3 days of age, during a 28-month study. Hepatic neoplasia occurred only in AFB-dosed ducks. Hepatocellular carcinomas or biliary carcinomas occurred in 4 of 8 DHBV-infected and 3 of 4 DHBV-free ducks, and hepatocellular adenomas developed in 2 DHBV-infected AFB-dosed ducks that survived 20 months or longer. Altered foci of hepatocytes similar to those observed in chemical carcinogen-dosed rodents, characterized by enlarged eosinophilic hepatocytes or vacuolated cytoplasm, occurred in AFB-dosed ducks. Cells in foci or hepatic neoplasms did not contain histochemically detectable gamma-glutamyltranspeptidase but were distinguished from uninvolved parenchyma by altered glycogen content. Immunohistochemical staining indicated that DHBV core antigen persisted in liver, spleen, pancreas, and, to a lesser extent, kidney of most congenitally infected ducks up to 28 months of age. Hepatic neoplasms contained only patches of hepatocytes were detectable viral antigen. Southern blot analysis of restriction endonuclease-digested neoplastic and normal liver DNA revealed high molecular weight forms of DHBV DNA consistent with integration of viral DNA into the genome of hepatic neoplasms from 3 of 4 DHBV-infected ducks but not nontumorous liver. These findings indicate that AFB is a potent hepatic carcinogen in ducks and that persistent congenital DHBV infection did not contribute significantly to the emergence of hepatic neoplasia in ducks under these conditions.

Demodex sp. in California ground squirrels.

An undescribed species of Demodex (Acari: Demodecidae) was observed in hair follicles and ducts of sebaceous glands in the ear canals of seven California ground squirrels (Spermophilus beecheyi) from Santa Clara County, California (USA). The animals had died of unrelated causes and were submitted for necropsy between September 1994 and February 1996. Similar mites were observed in the lumens of hair follicles and ducts of Meibomian glands in the eyelids of two of these squirrels. Microscopic changes in the epithelium and surrounding dermis, when present, were minimal. No associated clinical signs of disease or macroscopic lesions were observed. To our knowledge, this is the first report of Demodex sp. in a ground squirrel.

Harderian gland neoplasms in captive, wild-caught Beechey ground squirrels (Spermophilus beecheyi).

Harderian gland neoplasms were identified in 18 aged, adult Beechey ground squirrels (Spermophilus beecheyi) from the records of 167 wild-caught captive animals that were necropsied. All but one animal had tumors that were classified as carcinomas, with infiltrative growth and frequent metastases. This is the first detailed report of Harderian gland neoplasia in wild Sciuridae, although this neoplasm has been described in other rodent species. Clinically, affected ground squirrels typically were inappetent and presented with weight loss and exophthalmos. The biologic behavior of Harderian gland neoplasia is variable among rodent species; in Beechey ground squirrels there was a high incidence of malignant behavior. Eleven of 17 tumor-bearing animals for which the gender was known were male, and 6 were female. Nine of 16 for which data were available were uninfected, and 7 had evidence of current or prior infection with ground squirrel hepatitis virus. Tumor development occurred in older animals; all but 2 were 5.5 years of age or older. The presence of metastasis was not related to gender or chronic ground squirrel hepatitis virus infection.

Non-neoplastic liver disease associated with chronic ground squirrel hepatitis virus infection.

We examined 95 ground squirrels to compare the histological appearance of liver sections from animals that were chronically infected with ground squirrel hepatitis virus (GSHV) (n = 29), uninfected (n = 42), or had recovered from infection (n = 24). We studied the effects of long-term infection because these animals had been infected with GSHV for up to 10 years. Chronic infection generally produced a mild, persistent hepatitis characterized by light lymphocytic and plasmacytic portal infiltrates with occasional individual necrotic hepatocytes and small aggregates of Kupffer cells or mononuclear inflammatory cells in the parenchyma. In a few of the portal tracts from each of the more inflamed livers (grade 2), the inflammatory infiltrate penetrated the limiting plate and extended into the adjacent parenchyma. Hepatitis (grades 1 or 2) was detected more often in chronically infected animals (17 of 29) than in recovered (4 of 24) or uninfected ground squirrels (7 of 42). Fibrosis was generally not increased, but fine strands of collagen extended from the portal tracts and central veins into the parenchyma of about one quarter of the infected and recovered animals. Cytoplasmic pigment accumulation and variation in the size of hepatocyte nuclei appeared to be related to aging, not infection. Serum levels of aspartate and alanine transaminases (AST and ALT) were mildly elevated in samples from seven infected animals compared with seven control animals. Despite many years of chronic infection, liver injury was similar to that reported in previous studies on animals infected for shorter intervals, indicating that liver injury is not progressive in GSHV-infected ground squirrels.

Amino acids essential for RNase H activity of hepadnaviruses are also required for efficient elongation of minus-strand viral DNA.

The hepadnavirus P gene contains amino acid sequences which share homology with all known RNases H. In this study, we made four mutants in which single amino acids of the duck hepatitis B virus (DHBV) RNase H region were altered. In two of them, amino acids at locations comprising the putative catalytic site were changed, while the remaining mutants had alterations at amino acids conserved among hepadnaviruses. Transfection of these mutant genomes into permissive cells resulted in synthesis of several discrete viral nucleic acid species, ranging in apparent sizes from approximately 500 to 3,000 bp, numbered I, II, III, IV, and V. While the locations of the species were similar in all mutants, the proportions of the species varied among the mutants. Analysis of the nucleic acid species revealed that they were hybrid molecules of RNA and minus-strand DNA, indicating that the RNase H activity was missing or greatly reduced in these mutants. Primer extension experiments showed that the mutant viruses initiated minus-strand viral DNA synthesis normally. The 3' termini of minus-strand DNA in species II, III, and IV were mapped just downstream of nucleotides 1659, 1220, and 721, respectively. Species V contained essentially full-length minus-strand viral DNA. A parallel amino acid change in the putative catalytic site of the HBV RNase H domain resulted in accumulation of low-molecular-weight hybrid molecules consisting of RNA and minus-strand DNA and similar in size and pattern to those seen with DHBV. These studies demonstrate experimentally the involvement of the C-terminal portion of the P gene in RNase H activity in both DHBV and human hepatitis B virus and indicate that the amino acids essential for RNase H activity of hepadnavirus P protein are also important for the efficient elongation of minus-strand viral DNA.

Selected mutations of the duck hepatitis B virus P gene RNase H domain affect both RNA packaging and priming of minus-strand DNA synthesis.

The genome of all hepadnaviruses has an open reading frame called the P gene, which encodes a polypeptide of 90 to 97 kDa. The product or products of this P gene are involved in multiple functions of the viral life cycle. These functions include a priming activity which initiates minus-strand DNA synthesis, a polymerase activity which synthesizes DNA by using either RNA or DNA templates (reverse transcriptase), a nuclease activity which degrades the RNA strand of RNA-DNA hybrids (RNase H), and involvement in packaging the RNA pregenome into nucleocapsids. In a previous study, we found that a single point mutation at position 711 in the duck hepatitis B virus (DHBV) P gene product RNase H domain prevented viral RNA packaging. In the present experiments, we have mutated additional conserved amino acids in the DHBV RNase H domain and examined the ability of viral genomes containing these mutations to package RNA and replicate viral DNA. Charged and sulfur group amino acids adjacent to Cys-711 were mutated. None of these mutants was defective in either RNA packaging or viral replication. We also tested a number of mutations on the basis of common elements in the crystal structures of Escherichia coli and human immunodeficiency virus reverse transcriptase RNase H enzymes and on the basis of the similarities of their amino acid sequences to those of the RNase H domains of DHBV and HBV. Our results revealed that the entire beta 4 strand and amino acids Leu-712, Leu-697, and Val-719 in the putative hydrophobic cores of the beta 4, alpha A, and alpha B regions, respectively, are involved in pregenomic RNA encapsidation. This suggests that the basic structure of the RNase H domain in the DHBV P gene product is required for viral RNA packaging. We used the in vitro DHBV minus-strand DNA priming system developed by Wang and Seeger (G.-H. Wang and C. Seeger, Cell 71:663-670, 1992) to test the effect of RNase H packaging mutations on P gene product enzymatic activity. While all packaging-defective mutants tested maintained DNA priming activity, levels were decreased 5- to 20-fold compared with that of the wild-type genome. This observation suggests that the hepadnavirus RNase H domain plays a role in optimizing priming of minus-strand DNA synthesis.

Duck hepatitis B virus replicates in the yolk sac of developing embryos.

Duck hepatitis B virus (DHBV) is the only member of the hepadnavirus family in which nearly 100% vertical transmission from carrier mother to embryo has been reported. Large quantities of maternally transmitted virus particles are present in the yolk prior to incubation of the eggs, and replicative forms of DHBV DNA are detectable in the liver at 6 days of incubation. Since the yolk sac is similar to the liver in its production of serum proteins, we examined the yolk sacs of developing embryos for signs of viral replication. We detected the supercoiled form of DHBV DNA, DHBV RNA transcripts similar to those in the virus-replicating liver, and DNA polymerase activity and viral DNA in corelike particles in extracts of yolk sac tissue of naturally infected eggs. DHBV core antigen was strongly stained in only the endodermal layer of the yolk sac by immunofluorescence. DHBV RNA was detectable in the yolk sac from 4 days of incubation until hatching, and a larger quantity of DHBV RNA was present in the yolk sac than in the liver during all the stages of embryogenesis. Our data indicate that DHBV replicates actively in the yolk sac from an earlier stage than that previously reported in studies of embryonic liver and that replication is limited to the endodermal cell layer, which is ontogenetically and functionally related to the liver. The yolk sac may support the vertical transmission of DHBV.

Hepadnaviruses and retroviruses share genome homology and features of replication.

The hepadnavirus family includes hepatitis B virus (HBV), woodchuck hepatitis virus (WHV), ground squirrel hepatitis virus (GSHV) and duck hepatitis B virus (DHBV). These viruses share unique ultrastructural, molecular and biological features. HBV has great medical importance in many parts of the world. More important numerically than acute hepatitis B in high prevalence geographic regions is the liver disease associated with chronic infection. There appear to be more than 200 million chronically infected humans in the world, and these HBV infections appear to be the single most common cause of chronic liver disease and liver cancer in man. All hepadnaviruses share the propensity for silent infection in early life leading to persistence of the virus, and hepatocellular carcinoma (HCC) is clearly associated with long-standing persistent infection in man, woodchucks and ground squirrels. Although the viral DNA has been found to be integrated in cellular DNA of many HCC in man, woodchucks and ground squirrels, the precise role of the virus in tumor formation has not been defined. Hepadna viruses have an interesting molecular structure and mechanisms of replication, and they appear to share certain important features with retroviruses as reviewed here. It is of interest to define similarities and differences between hepadnaviruses and retroviruses in order to understand their evolutionary relationship and to determine whether they share a common oncogenic mechanism, since infection with members of both virus families is associated with neoplastic disease.

A sequential histologic and immunohistochemical study of duck hepatitis B virus infection in Pekin ducks.

Twenty-nine Pekin ducks were inoculated with duck hepatitis B virus (DHBV), DHBV-free serum, or saline at 1 day of age. Congenitally DHBV-infected ducks were also studied. Ducks were killed periodically during a 92-week study and examined histologically and immunohistochemically to assess liver and extrahepatic inflammation and to detect and characterize DHBV core antigen tissue distribution. DHBV infection produced an asymptomatic but persistent DHBV viremia in all ducks associated with a mild to moderate transient hepatic inflammation apparent at 3 to 6 weeks post-inoculation and waning afterwards. DHBV core antigen was detected in hepatocyte cytoplasm at 1 week post-inoculation, and by 3 weeks post-inoculation scattered pancreatic acinar and islet cells also contained viral antigen. Small numbers of mononuclear cells in the splenic white pulp also contained viral antigen. Viral antigen persisted in all of these tissues throughout the duration of the experiment. No inflammation or tissue injury was detected in any of the extrahepatic tissues during the course of DHBV infection. One DHBV-injected duck developed a hepatocellular carcinoma at 88 weeks of age. Isolated patches of neoplastic hepatocytes contained cytoplasmic DHBV core antigen. The results of this study indicate that DHBV, like mammalian hepadnavirus, is capable of producing a persistent infection of the liver and several extrahepatic tissues and suggest that persistent infection may be associated with the development of hepatocellular carcinoma.

Naturally occurring point mutation in the C terminus of the polymerase gene prevents duck hepatitis B virus RNA packaging.

A duck hepatitis B virus (DHBV) genome cloned from a domestic duck from the People's Republic of China has been sequenced and exhibits no variation in sequences known to be important in viral replication or generation of gene products. Intrahepatic transfection of a dimer of this viral genome into ducklings did not result in viremia or any sign of virus infection, indicating that the genome was defective. Functional analysis of this mutant genome, performed by transfecting the DNA into a chicken hepatoma cell line capable of replicating wild-type virus, indicated that viral RNA is not encapsidated. However, virus core protein is made and can assemble into particles in the absence of encapsidation of viral nucleic acid. Using genetic approaches, it was determined that a change of cysteine to tyrosine in position 711 in the polymerase (P) gene C terminus led to this RNA-packaging defect. By site-directed mutagenesis, it was found that while substitution of Cys-711 with tryptophan also abolished packaging, substitution with methionine did not affect packaging or viral replication. Therefore, Cys-711, which is conserved in all published sequences of DHBV, may not be involved in a disulfide bridge structure essential to viral RNA packaging or replication. Our results, showing that a missense mutation in the region of the DHBV polymerase protein thought to be primarily the RNase H domain results in packaging deficiency, support the previous findings that multiple regions of the complex hepadnaviral polymerase protein may be required for viral RNA packaging.

The nature of polypeptides larger in size than the major surface antigen components of hepatitis b and like viruses in ground squirrels, woodchucks, and ducks.

The relationships of various polypeptides associated with hepatitis B surface antigen (HBsAg), ground squirrel hepatitis surface antigen (GSHsAg), woodchuck hepatitis surface antigen (WHsAg), and duck hepatitis B surface antigen (DHBsAg) were studied by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and tryptic peptide mapping. Analysis of independent antigen isolates by SDS-PAGE resulted in bands consistently observed at 24,000, 28,000, 32,000, 43,000, and 50,000 Da with HBsAg; at 22,000, 25,000, 35,000, 37,000, 39,000, and 42,000 Da with GSHsAg and WHsAg; and at 18,500, 30,000, and 38,500, Da with DHBsAg. Comparison of the major polypeptide pair from the mammalian viruses by tryptic peptide mapping suggests more than a single point of glycosylation or other post-translational modification(s) in some paired comparisons and/or heterogeneity in glycosylation in others. Comparison of the major component of each mammalian virus (HBsAg p24, GSHsAg p22, or WHsAg p22), or the major polypeptide of DHBsAg (p18.5), with their respective larger polypeptides by peptide mapping indicated that one or more of the larger components in each virus shares extensive homology with the appropriate major component. Further, these larger components possess additional spots, interpreted as additional primary sequences, which were not found in the map of the appropriate major component. Collectively, the results suggest that a number of surface antigen-associated polypeptides may be partially encoded for by the pre-S gene region known to exist in hepatitis B virus (HBV) and woodchuck hepatitis virus (WHV), and likely to exist in ground squirrel hepatitis virus (GSHV) and duck hepatitis B virus (DHBV) DNA.

Hepatitis B viral DNA-RNA hybrid molecules in particles from infected liver are converted to viral DNA molecules during an endogenous DNA polymerase reaction.

Particles purified from the liver of hepatitis B virus-infected patients were previously shown by us to incorporate 32P-deoxynucleotides into viral DNA and DNA-RNA hybrid molecules when incubated in a DNA polymerase reaction mixture. In this investigation, similar particles from duck and ground squirrel livers infected with viruses closely related to HBV were also shown to incorporate 32P-deoxynucleotides into viral-specific DNA and DNA-RNA hybrid molecules when incubated in vitro in a DNA polymerase reaction mixture. The particles from duck hepatitis B virus-infected liver contained a heterogeneous population of hybrid molecules, while those from ground squirrel hepatitis virus-infected liver contained hybrid molecules with densities similar to those found in HBV particles including a distinct population of molecules with an average density of 1.57 g/cm3. Brief endogenous DNA polymerase reactions with particles from all three livers, resulted in incorporation of 32P-deoxynucleotides into viral DNA of DNA-RNA hybrid as well as viral DNA molecules. When the reaction was continued in the presence of a 1000-fold molar excess of unlabeled deoxynucleotides, a decrease in [32P]DNA in the DNA-RNA hybrid region of the Cs2SO4 density gradient and a proportional increase in [32P]DNA in the DNA region of the gradient was observed. This effect was seen most dramatically with particles isolated from freshly obtained ground squirrel hepatitis virus-infected livers in which 90% of the pulse labeled DNA in the hybrid species at the buoyant density of 1.57 g/cm3 appeared to be converted to a form with the buoyant density of pure DNA (1.42 g/cm3). Storage of virus particles at 4 degrees, or prior freezing of infected ground squirrel liver almost completely abolished the ability of the endogenous DNA polymerase activity to incorporate 32P-deoxynucleotides into hybrid molecules, while incorporation into DNA molecules was apparently unaffected. These results suggest that different enzymatic activities catalyze synthesis of the viral DNA in DNA-RNA hybrids and in molecules with buoyant density of pure DNA. Thus particles from infected liver synthesize DNA of DNA-RNA hybrid molecules which can be converted in the particles into molecules with the buoyant density of pure DNA. This indicates that DNA-RNA hybrids may be intermediates in viral DNA replication and that the mechanism of hepatitis B virus (and closely related viruses of ground squirrels and ducks) DNA replication differs from that known for other DNA viruses.

Core particles of hepatitis B virus and ground squirrel hepatitis virus. I. Relationship between hepatitis B core antigen- and ground squirrel hepatitis core antigen-associated polypeptides by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and tryptic peptide mapping.

The relationships among the core antigen polypeptides of hepatitis B virus (HBV) and ground squirrel hepatitis virus (GSHV) were studied using sodium dodecyl sulfate-polyacrylamide gel electrophoresis and tryptic peptide mapping. The major core antigen polypeptides of liver-derived HBV (p22) and GSHV (p20.5) shared 56% of the spots in their peptide maps. Comparison of hepatitis B core antigen (HBcAg) p19 or ground squirrel hepatitis core antigen (GSHcAg) p16.5 with their respective major polypeptides indicated that these components probably resulted from cleavage of the major polypeptide of each virus. Other polypeptides smaller than the major component of each virus were often faint on polyacrylamide gels and probably resulted from the cleavage or degradation of components larger than p22 of HBcAg or p20.5 of GSHcAg, since their peptide maps contained spots unique to these high-molecular-weight components. p26 of GSHcAg and p27.5 of HBcAg shared approximately two-thirds of the spots on their peptide maps with those of their respective major core polypeptides. Furthermore, p37.5 of GSHcAg and p40 of HBcAg shared about 60% homology with their respective major polypeptides, and also shared many of the spots that were unique to p26 of GSHcAg or p27.5 of HBcAg but were not found in the peptide map of their respective core antigen polypeptides. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis bands larger than 40,000 daltons were variably present, and peptide mapping indicated that these were aggregates of various smaller core antigen-associated polypeptides. The results suggest that p40 of HBcAg and p37.5 of GSHcAg are the largest unique polypeptides in these core particles, and that they are encoded for by the genome of each virus. That a subset of the spots unique to p40 or p37.5 was also found in p27.5 of HBcAg or p26 of GSHcAg, respectively, as compared to the major core polypeptides, also suggests that p27.5 and p26 are unique proteins encoded by the genome of each virus. It is proposed that the core antigen gene of each virus is larger than that which would encode the major polypeptide of each virus, and that the genetic organizations of the core genes of HBV and GSHV are very similar.

Core particles of hepatitis B virus and ground squirrel hepatitis virus. II. Characterization of the protein kinase reaction associated with ground squirrel hepatitis virus and hepatitis B virus.

The recently described protein kinase activity in hepatitis B virus core antigen particles (Albin and Robinson, J. Virol. 34:297-302, 1980) has been demonstrated here in the liver-derived core particles of ground squirrel hepatitis virus. Both protein kinase activities were initially associated with DNA polymerase-positive heavy core particles in CsCl density equilibrium gradients and shifted to polymerase-negative cores during the course of purification. The major core-associated polypeptide of each virus was the dominant species labeled. A variable number of other polypeptide species were also labeled by this reaction. Tryptic peptide mapping of both major and minor phosphorylated polypeptides of each virus resulted in similar patterns, suggesting that many of the sites of phosphorylation were the same in the components of each core particle. Hydrolysis of these phosphorylated core particles revealed a major phosphoamino acid as serine and a minor phosphoamino acid as threonine. The products of the protein kinase reaction in both human hepatitis B and ground squirrel hepatitis virus core particles, then, share many characteristics. The possible function(s) of this protein kinase activity is discussed in the light of similarly characterized activities in other animal viruses.

Ground squirrel hepatitis virus DNA: molecular cloning and comparison with hepatitis B virus DNA.

Ground squirrel hepatitis virus (GSHV) shares many ultrastructural antigenic, molecular, and biological features with hepatitis B virus (HBV) of humans, indicating that they are members of the same virus group. Both viruses contain small circular DNA molecules which are partially single stranded. Here, we ligated an endonuclease EcoRI digest of GSHV DNA with EcoRI-cleaved plasmid vector pBR322 and cloned recombinant plasmids in Escherichia coli C600. Two cloned recombinants were characterized. One (pGS2) was found to contain only part of the GSHV genome, and the other (pGS11) was found to contain the entire viral DNA. A restriction endonuclease cleavage map of the GSHV insert in pGS11 and the locations of certain physical features of the virion DNA were determined. The relative positions of the single-stranded region, the unique 5' end of the short DNA strand, and the unique nick in the long DNA strand in GSHV DNA were found to be the same as those previously described for HBV DNA. Hybridization with an HBV [32P]DNA probe containing the apparent coding sequence for the major polypeptide of HBV surface antigen and a probe containing the putative coding sequence for the major polypeptide of the HBV core revealed specific homology with different restriction fragments of GSHV DNA. The two homologous regions had approximately the same locations relative to the single-stranded region, the 5' end of the short strand, and the nick in the long strand in the two viral DNAs. These results suggest that in both viruses the genes for the major HBV surface antigen and core polypeptides have the same locations relative to unique physical features of the viral DNAs.