Pre-Flight Calibration of the Mars 2020 Rover Mastcam Zoom (Mastcam-Z) Multispectral, Stereoscopic Imager

The NASA Perseverance rover Mast Camera Zoom (Mastcam-Z) system is a pair of zoomable, focusable, multi-spectral, and color charge-coupled device (CCD) cameras mounted on top of a 1.7 m Remote Sensing Mast, along with associated electronics and two calibration targets. The cameras contain identical optical assemblies that can range in focal length from 26 mm ( 25.5 ∘ × 19.1 ∘ FOV ) to 110 mm ( 6.2 ∘ × 4.2 ∘ FOV ) and will acquire data at pixel scales of 148-540 μm at a range of 2 m and 7.4-27 cm at 1 km. The cameras are mounted on the rover's mast with a stereo baseline of 24.3 ± 0.1  cm and a toe-in angle of 1.17 ± 0.03 ∘ (per camera). Each camera uses a Kodak KAI-2020 CCD with 1600 × 1200 active pixels and an 8 position filter wheel that contains an IR-cutoff filter for color imaging through the detectors' Bayer-pattern filters, a neutral density (ND) solar filter for imaging the sun, and 6 narrow-band geology filters (16 total filters). An associated Digital Electronics Assembly provides command data interfaces to the rover, 11-to-8 bit companding, and JPEG compression capabilities. Herein, we describe pre-flight calibration of the Mastcam-Z instrument and characterize its radiometric and geometric behavior. Between April 26 t h and May 9 t h , 2019, ∼45,000 images were acquired during stand-alone calibration at Malin Space Science Systems (MSSS) in San Diego, CA. Additional data were acquired during Assembly Test and Launch Operations (ATLO) at the Jet Propulsion Laboratory and Kennedy Space Center. Results of the radiometric calibration validate a 5% absolute radiometric accuracy when using camera state parameters investigated during testing. When observing using camera state parameters not interrogated during calibration (e.g., non-canonical zoom positions), we conservatively estimate the absolute uncertainty to be < 10 % . Image quality, measured via the amplitude of the Modulation Transfer Function (MTF) at Nyquist sampling (0.35 line pairs per pixel), shows MTF Nyquist = 0.26 - 0.50 across all zoom, focus, and filter positions, exceeding the > 0.2 design requirement. We discuss lessons learned from calibration and suggest tactical strategies that will optimize the quality of science data acquired during operation at Mars. While most results matched expectations, some surprises were discovered, such as a strong wavelength and temperature dependence on the radiometric coefficients and a scene-dependent dynamic component to the zero-exposure bias frames. Calibration results and derived accuracies were validated using a Geoboard target consisting of well-characterized geologic samples.

SUPPLEMENTARY INFORMATION

The online version contains supplementary material available at 10.1007/s11214-021-00795-x.

Effect of alpha interferon on the hepatitis C virus replicon

Chronic hepatitis C virus (HCV) infections can be cured only in a fraction of patients treated with alpha interferon (IFN-alpha) and ribavirin combination therapy. The mechanism of the IFN-alpha response against HCV is not understood, but evidence for a role for viral nonstructural protein 5A (NS5A) in IFN resistance has been provided. To elucidate the mechanism by which NS5A and possibly other viral proteins inhibit the cellular antiviral program, we have constructed a subgenomic replicon from a known infectious HCV clone and demonstrated that it has an approximately 1,000-fold-higher transduction efficiency than previously used subgenomes. We found that IFN-alpha reduced replication of HCV subgenomic replicons approximately 10-fold. The estimated half-life of viral RNA in the presence of the cytokine was about 12 h. HCV replication was sensitive to IFN-alpha independently of whether the replicon expressed an NS5A protein associated with sensitivity or resistance to the cytokine. Furthermore, our results indicated that HCV replicons can persist in Huh7 cells in the presence of high concentrations of IFN-alpha. Finally, under our conditions, selection for IFN-alpha-resistant variants did not occur.

Does a cdc2 kinase-like recognition motif on the core protein of hepadnaviruses regulate assembly and disintegration of capsids?

Hepadnaviruses are enveloped viruses, each with a DNA genome packaged in an icosahedral nucleocapsid, which is the site of viral DNA synthesis. In the presence of envelope proteins, DNA-containing nucleocapsids are assembled into virions and secreted, but in the absence of these proteins, nucleocapsids deliver viral DNA into the cell nucleus. Presumably, this step is identical to the delivery of viral DNA during the initiation of an infection. Unfortunately, the mechanisms triggering the disintegration of subviral core particles and delivery of viral DNA into the nucleus are not yet understood. We now report the identification of a sequence motif resembling a serine- or threonine-proline kinase recognition site in the core protein at a location that is required for the assembly of core polypeptides into capsids. Using duck hepatitis B virus, we demonstrated that mutations at this sequence motif can have profound consequences for RNA packaging, DNA replication, and core protein stability. Furthermore, we found a mutant with a conditional phenotype that depended on the cell type used for virus replication. Our results support the hypothesis predicting that this motif plays a role in assembly and disassembly of viral capsids.

Combination therapy with lamivudine and adenovirus causes transient suppression of chronic woodchuck hepatitis virus infections

Treatment of hepatitis B virus carriers with the nucleoside analog lamivudine suppresses virus replication. However, rather than completely eliminating the virus, long-term treatment often ends in the outgrowth of drug-resistant variants. Using woodchucks chronically infected with woodchuck hepatitis virus (WHV), we investigated the consequences of combining lamivudine treatment with immunotherapy mediated by an adenovirus superinfection. Eight infected woodchucks were treated with lamivudine and four were infected with approximately 10(13) particles of an adenovirus type 5 vector expressing beta-galactosidase. Serum samples and liver biopsies collected following the combination therapy revealed a 10- to 20-fold reduction in DNA replication intermediates in three of four woodchucks at 2 weeks after adenovirus infection. At the same time, covalently closed circular DNA (cccDNA) and viral mRNA levels both declined about two- to threefold in those woodchucks, while mRNA levels for gamma interferon and tumor necrosis factor alpha as well as for the T-cell markers CD4 and CD8 were elevated about twofold. Recovery from adenovirus infection was marked by elevation of sorbitol dehydrogenase, a marker for hepatocyte necrosis, as well as an 8- to 10-fold increase in expression of proliferating cell nuclear antigen, a marker for DNA synthesis, indicating significant hepatocyte turnover. The fact that replicative DNA levels declined more than cccDNA and mRNA levels following adenovirus infection suggests that the former decline either was cytokine induced or reflects instability of replicative DNA in regenerating hepatocytes. Virus titers in all four woodchucks were only transiently suppressed, suggesting that the effect of combination therapy is transient and, at least under the conditions used, does not cure chronic WHV infections.

Hepatitis B virus biology

Hepadnaviruses (hepatitis B viruses) cause transient and chronic infections of the liver. Transient infections run a course of several months, and chronic infections are often lifelong. Chronic infections can lead to liver failure with cirrhosis and hepatocellular carcinoma. The replication strategy of these viruses has been described in great detail, but virus-host interactions leading to acute and chronic disease are still poorly understood. Studies on how the virus evades the immune response to cause prolonged transient infections with high-titer viremia and lifelong infections with an ongoing inflammation of the liver are still at an early stage, and the role of the virus in liver cancer is still elusive. The state of knowledge in this very active field is therefore reviewed with an emphasis on past accomplishments as well as goals for the future.

Apoptosis and regeneration of hepatocytes during recovery from transient hepadnavirus infections

It is well known that hepatitis B virus infections can be transient or chronic, but the basis for this dichotomy is not known. To gain insight into the mechanism responsible for the clearance of hepadnavirus infections, we have performed a molecular and histologic analysis of liver tissues obtained from transiently infected woodchucks during the critical phase of the recovery period. We found as expected that clearance from transient infections occurred subsequent to the appearance of CD4(+) and CD8(+) T cells and the production of interferon gamma and tumor necrosis factor alpha in the infected liver. These events were accompanied by a significant increase in apoptosis and regeneration of hepatocytes. Surprisingly, however, accumulation of virus-free hepatocytes was delayed for several weeks following this initial influx of lymphocytes. In addition, we observed that chronically infected animals can exhibit levels of T-cell accumulation, cytokine expression, and apoptosis that are comparable with those observed during the initial phase of transient infections. Our results are most consistent with a model for recovery predicting replacement of infected hepatocytes with regenerated cells, which by unknown mechanisms remain protected from reinfection in animals that can be cured.

Why are hepadnaviruses DNA and not RNA viruses?

Virion assembly in hepadnaviruses is a two-step process leading to (1) the packaging of viral pregenomic RNA and reverse transcriptase into nucleocapsids and (2) the assembly of nucleocapsids with envelope components, which results in the formation of mature virus particles. Characteristically, both steps are intimately coupled to viral DNA synthesis. While assembly of nucleocapsids is coupled to the protein priming of reverse transcription, virion formation is linked to genome maturation.

PNA-mediated purification of PCR amplifiable human genomic DNA from whole blood

A simple and rapid procedure whereby human genomic DNA can be purified in a PCR amplifiable form from whole blood is described. In a first step, human genomic DNA is hybridized in solution to a biotinylated peptide nucleic acid (PNA), which forms a high-affinity triplex with A7 sequence motifs in the target DNA. The complex is then captured onto paramagnetic streptavidin-coated particles, which are subsequently transferred directly into the PCR. The purification method effectively removes inhibitors of the PCR from as much as 500 microL of whole blood.

Inducible expression of human hepatitis B virus (HBV) in stably transfected hepatoblastoma cells: a novel system for screening potential inhibitors of HBV replication

We report the development and isolation of a cell line, termed HepAD38, that replicates human hepatitis B virus (HBV) under conditions that can be regulated with tetracycline. In the presence of the antibiotic, this cell line is free of virus due to the repression of pregenomic (pg) RNA synthesis. Upon removal of tetracycline from the culture medium, the cells express viral pg RNA, accumulate subviral particles in the cytoplasm that contain DNA intermediates characteristic of viral replication, and secrete virus-like particles into the supernatant. Since the HepAD38 cell line can produce high levels of HBV DNA, it should be useful for analyses of the viral replication cycle that depend upon viral DNA synthesis in a synchronized fashion. In addition, this cell line has been formatted into a high-throughput, cell-based assay that permits the large-scale screening of diverse compound libraries for new classes of inhibitors of HBV replication.

The hepatitis B virus X protein: the quest for a role in viral replication and pathogenesis

Although the biological importance of hepatitis B virus X protein (HBX) in the life cycle of hepatitis B virus has been well established, the cellular and molecular basis of its function remains largely undefined. Despite the association of multiple activities with HBX, none of them appear to provide a unifying hypothesis regarding the true biological function of HBX. Identification and characterization of cellular targets of HBX remain an essential goal in the elucidation of the molecular mechanisms of HBX. Using the Saccharomyces cerevisiae two-hybrid system, we have identified and characterized a novel subunit of the proteasome complex (XAPC7) that interacts specifically with HBX. We also showed that HBX binds specifically to XAPC7 in vitro. Mutagenesis studies have defined the domains of interaction to be critical for the function of HBX. Furthermore, overexpression of XAPC7 appeared to activate transcription by itself and antisense expression of XAPC7 was able to block transactivation by HBX. Therefore, the proteasome complex is possibly a functional target of HBX in cells.

Hepadnavirus assembly and reverse transcription require a multi-component chaperone complex which is incorporated into nucleocapsids

Assembly of hepadnaviruses depends on the formation of a ribonucleoprotein (RNP) complex comprising the viral polymerase polypeptide and an RNA segment, epsilon, present on pregenomic RNA. This interaction, in turn, activates the reverse transcription reaction, which is primed by a tyrosine residue on the polymerase. We have shown recently that the formation of this RNP complex in an avian hepadnavirus, the duck hepatitis B virus, depends on cellular factors that include the heat shock protein 90 (Hsp90). We now report that RNP formation also requires ATP hydrolysis and the function of p23, a recently identified chaperone partner for Hsp90. Furthermore, we also provide evidence that the chaperone complex is incorporated into the viral nucleocapsids in a polymerase-dependent reaction. Based on these findings, we propose a model for hepadnavirus assembly and priming of viral DNA synthesis where a dynamic, energy-driven process, mediated by a multi-component chaperone complex consisting of Hsp90, p23 and, potentially, additional factors, maintains the reverse transcriptase in a specific conformation that is competent for RNA packaging and protein priming of viral DNA synthesis.

Mutagenesis of a hepatitis B virus reverse transcriptase yields temperature-sensitive virus

Replication of the hepadnavirus genome is catalyzed by a multifunctional reverse transcriptase (the pol protein) that exhibits DNA polymerase and DNA priming activities and has the ability to transfer RNA and DNA strands across the viral genome. A salient feature of this enzyme is the ability to prime RNA-directed DNA synthesis with protein rather than with RNA. This is reflected in its unique physical make up, which includes an amino-terminal (TP) domain that is separated by a spacer from the reverse transcriptase (RT) domain. To establish a structure function relationship for the pol protein, we examined 52 mutants for their ability to replicate viral DNA in vitro and in cultured cells. We demonstrated that the role of the TP domain is limited to the early steps of viral DNA synthesis including RNA packaging and protein priming. Both the TP and the RT domains are required for the interaction with epsilon RNA, which is the template for the protein-priming reaction and serves as the RNA packaging signal. In addition, we report the isolation of a thermosensitive variant of a hepadnavirus that will permit investigations of individual steps of the viral replication cycle under synchronized conditions.

Hsp90 is required for the activity of a hepatitis B virus reverse transcriptase

The heat shock protein Hsp90 is known as an essential component of several signal transduction pathways and has now been identified as an essential host factor for hepatitis B virus replication. Hsp90 interacts with the viral reverse transcriptase to facilitate the formation of a ribonucleoprotein (RNP) complex between the polymerase and an RNA ligand. This RNP complex is required early in replication for viral assembly and initiation of DNA synthesis through a protein-priming mechanism. These results thus invoke a role for the Hsp90 pathway in the formation of an RNP.

Identification and characterization of genes (xapA, xapB, and xapR) involved in xanthosine catabolism in Escherichia coli

We have characterized four genes from the 52-min region on the Escherichia coli linkage map. Three of these genes are directly involved in the metabolism of xanthosine, whereas the function of the fourth gene is unknown. One of the genes (xapA) encodes xanthosine phosphorylase. The second gene, named xapB, encodes a polypeptide that shows strong similarity to the nucleoside transport protein NupG. The genes xapA and xapB are located clockwise of a gene identified as xapR, which encodes a positive regulator belonging to the LysR family and is required for the expression of xapA and xapB. The genes xapA and xapB form an operon, and their expression was strictly dependent on the presence of both the XapR protein and the inducer xanthosine. Expression of the xapR gene is constitutive and not autoregulated, unlike the case for many other LysR family proteins. In minicells, the XapB polypeptide was found primarily in the membrane fraction, indicating that XapB is a transport protein like NupG and is involved in the transport of xanthosine.

Role of RNA in enzymatic activity of the reverse transcriptase of hepatitis B viruses

The hepadnavirus reverse transcriptase is a multifunction enzyme. In addition to its role in DNA synthesis, the polymerase is required for RNA packaging and also functions as the primer for minus-strand DNA synthesis. Previously, we demonstrated that the protein-priming activity of the polymerase requires a viral RNA segment, termed epsilon, which serves as a template for the synthesis of a short DNA oligomer that is covalently attached to the reverse transcriptase (G.-H. Wang and C. Seeger, J. Virol. 67:6507-6512, 1993). We now report that epsilon is sufficient for activation of the reverse transcriptase to prime DNA synthesis through the formation of a stable RNA-protein (RNP) complex. We also demonstrate that the binding reaction depends on sequence-specific determinants on epsilon. Moreover, our results indicate that two genetically separated domains of the reverse transcriptase are required for formation of the RNP complex. Finally, we show that the polymerase has a DNA polymerase activity in the absence of epsilon which does not depend on the protein-priming mechanism.

Woodchuck hepatitis virus X protein is required for viral infection in vivo

The X gene of the mammalian hepadnaviruses is believed to encode a protein of 17 kDa which has been shown to transactivate a wide range of viral and cellular promoters. The necessity for X gene expression during the viral life cycle in vivo has recently been suggested (H.-S. Chen, S. Kaneko, R. Girones, R. W. Anderson, W. E. Hornbuckle, B. C. Tennant, P. J. Cote, J. L. Gerin, R. H. Purcell, and R. H. Miller, J. Virol. 67:1218-1226, 1993). We have independently constructed two variants of woodchuck hepatitis virus (WHV) with mutations in the X coding region. Transient transfection of two different hepatoma cell lines showed that these WHV X gene mutants were competent for virus replication in vitro. To determine whether X expression was required for viral replication in vivo, we injected mutant and wild-type genomes into the livers of susceptible woodchucks. While the wild-type WHV genomes were infectious in all animals examined, the mutant genomes did not initiate a WHV infection in woodchucks. These results indicate that the X gene of the hepadnaviruses plays a major role in viral replication in vivo.

Reverse transcription in hepatitis B viruses is primed by a tyrosine residue of the polymerase

All known DNA polymerases require primers for the initiation of DNA synthesis. While cellular polymerases and reverse transcriptases use free hydroxyl groups of RNA or DNA, the DNA polymerases of certain animal viruses and bacteriophages depend upon hydroxyl groups of amino acid residues within proteins as primers for DNA synthesis. Recently, the reverse transcriptase of a hepadnavirus has been shown to prime RNA-directed DNA synthesis from an internal site of the polypeptide (G.H. Wang and C. Seeger, Cell 71:663-670, 1992). In this report we demonstrate that a tyrosine residue of the polymerase polypeptide is the site of a phosphodiester linkage with the first nucleotide of minus-strand DNA. This tyrosine residue is located within an amino-terminal domain of the polymerase polypeptide and is indispensable for the priming of reverse transcription. Our results demonstrate that the hepatitis B virus reverse transcriptase can initiate DNA synthesis without the requirement for tRNA as a primer.

Novel mechanism for reverse transcription in hepatitis B viruses

Reverse transcription of all retroviruses and most retroid elements requires tRNA as a primer for DNA synthesis. However, in hepatitis B viruses the viral polymerase itself acts as a primer for reverse transcription (G.-H. Wang and C. Seeger, Cell 71:663-670, 1992). We have now demonstrated that in order to prime DNA synthesis, the polymerase binds to an RNA hairpin, which then serves as a template for the formation of a short DNA primer that is covalently linked to protein. Following its synthesis, the nascent DNA strand apparently dissociates from its template and reanneals with complementary sequences at the 3' end of the RNA genome, where DNA synthesis continues. Since this RNA hairpin also functions as a packaging signal for viral RNA, hepadnaviruses have adopted a replication strategy that relies on the same signal for two biochemically distinct events, RNA packaging and reverse transcription. This mechanism is without precedent among all known retroid elements and among other viruses and bacteriophages that use protein as a primer for RNA or DNA synthesis. It could provide an effective target for antiviral therapy, which is required for the treatment of more than 300 million carriers of hepatitis B virus.

Differential activation of myc gene family members in hepatic carcinogenesis by closely related hepatitis B viruses

Woodchucks infected with woodchuck hepatitis virus (WHV) and ground squirrels infected with ground squirrel hepatitis virus (GSHV) both develop hepatocellular carcinoma (HCC), but WHV-associated tumors arise more frequently and much earlier in life. These differences are preserved when the oncogenic potentials of the two viruses are examined in the same host (woodchucks). We examined RNA and genomic DNA from tumors arising from WHV- and GSHV-infected woodchucks to determine whether these viruses use the same oncogenic pathway. N-myc RNA was not expressed in normal liver but was expressed in 10 of 13 WHV-associated HCCs examined. Southern blot analysis showed that 7 of 17 WHV-induced tumors (41%) contained rearrangements at N-myc loci due to viral genomic integration. Six of these seven inserts affected N-myc2, and most of these were at the 5' end of the gene. In contrast, only two of seven GSHV-induced woodchuck HCCs expressed N-myc RNA, and only 1 of the 16 tumors (6%) contained a rearranged N-myc allele. The GSHV-associated HCCs all contained numerous viral insertions, so the low frequency of integration into N-myc loci by GSHV was not due to a general block to integration. Four of sixteen GSHV-induced tumors harbored amplified c-myc alleles, and five of seven GSHV tumors tested contained elevated c-myc RNA levels. By contrast, enhanced c-myc RNA levels were observed in only 2 of 13 WHV-induced HCC. We conclude that N-myc overexpression is a regular feature of WHV- but not GSHV-associated hepatocarcinogenesis in a common host. In contrast, c-myc transcriptional deregulation is rarely encountered in WHV-induced HCC but is frequent in GSHV-induced HCC.

The reverse transcriptase of hepatitis B virus acts as a protein primer for viral DNA synthesis

Hepatitis B viruses (hepadnaviruses) replicate their DNA genomes by reverse transcription of an RNA intermediate. Efforts to examine the biochemical mechanism for viral DNA synthesis have been hampered by the failure to solubilize the reverse transcriptase from virions and to express the polymerase in heterologous systems in an enzymatically active form. Here, we demonstrate that the polymerase of a hepadnavirus synthesized in an in vitro translation reaction exhibits reverse transcriptase activity. Furthermore, our results show that the polymerase acts as a primer for DNA synthesis and remains covalently linked to nascent DNA, a feature that is not known to exist in any other RNA-directed DNA polymerases. Priming of DNA synthesis requires viral RNA but occurs independently of other viral components. The ability to express the hepadnavirus reverse transcriptase in an enzymatically active form will allow detailed biochemical and functional analyses of this complex enzyme, and may facilitate the identification of inhibitors required for antiviral therapy.

Replication of DHBV genomes with mutations at the sites of initiation of minus- and plus-strand DNA synthesis

We have examined the consequences on duck hepatitis B virus DNA synthesis of deleting the 5' and 3' copies of the 12 base sequence, DR1, from the viral pregenome. With the wild-type virus, reverse transcription initiates at nt 2537 within the 3' copy of DR1. When this sequence was deleted, initiation of reverse transcription was found at two other sites located closer to the 3' end of the pregenome (nt 2576 and nt 2644). The 3-base motif UUA was the only sequence common to these sites as well as the wild-type initiation site in DR1. Deletion of the 5' copy of DR1 did not alter minus strand synthesis, but led to aberrant priming of plus strand synthesis to generate predominantly linear rather than relaxed circular, double-stranded viral DNA, in agreement with the recent report by Loeb et al. (EMBO J. 10, 3533-3540, 1991). A mutant lacking only the 3' copy of DR1 rapidly converted to wild type in transfected cells. This apparently occurred as a consequence of conversion of newly synthesized relaxed circular to covalently closed circular (CCC) DNA, which might then serve as a template for the synthesis of wild-type viral RNAs. A mutant lacking only the 5' copy of DR1 did not exhibit this behavior. These results support the conclusion that amplified CCC DNA serves as transcriptional template.

Beat-to-beat variation of heart rate in diabetic patients with autonomic neuropathy and in completely cardiac denervated patients following orthotopic heart transplantation

Dysfunction of the vagal nerve, an early symptom in the development of autonomic neuropathy, can be assessed reliably by the beat-to-beat variation in heart rate. Patients after a cardiac transplantation are a unique model to investigate the beat-to-beat variation of a completely denervated heart. Heart rate and the beat-to-beat variation during normal and deep respiration were investigated in diabetic subjects with an autonomic neuropathy (n = 10), age and sex matched healthy controls (n = 10) and cardiac transplanted patients (n = 10). Further studies during pharmacological blockade of the parasympathetic nervous system with atropine were performed. In the denervated heart the coefficient of variation of the beat-to-beat interval was 0.38 +/- 0.02% during normal respiration, compared to 1.32 +/- 0.13% (P less than 0.0001) and 2.56 +/- 0.13% (P less than 0.0001) in the diabetic and control subjects, respectively. Administration of atropine (2 mg intravenously) decreased the coefficient of variation of the RR-interval to 0.73 +/- 0.09% in the diabetic patients (P less than 0.0005) and to 0.67 +/- 0.07% in the controls (P less than 0.0001), whereas the coefficient of variation remained unaffected in the cardiac denervated patients (0.39 +/- 0.02%). In the three groups an almost parallel increase of the RR-variation was observed during deep respiration at a rate of 6 breaths/min (from 0.38 +/- 0.02% to 1.99 +/- 0.38% in cardiac transplanted patients, P less than 0.0025; from 1.32 +/- 0.13% to 3.10 +/- 0.43% in diabetic patients, P less than 0.0025; from 2.56 +/- 0.13% to 5.42 +/- 0.94% in healthy controls, P less than 0.005). We conclude that a beat-to-beat variation of heart rate is present in the completely denervated heart. This RR-variation can not be influenced by a pharmacological blockade of the parasympathetic nervous system with atropine. The beat-to-beat variation increases during deep respiration not only in healthy controls but also in diabetic patients with autonomic neuropathy (partially denervated hearts) and cardiac transplanted patients (completely denervated hearts). This indicates an intracardiac mechanism in the modulation of heart rate.

Identification of a signal necessary for initiation of reverse transcription of the hepadnavirus genome

Reverse transcription of the hepadnavirus genome initiates near the 3' end of the RNA template and has previously been shown to depend on sequences flanking the initiation site for DNA synthesis (C. Seeger and J. Maragos, J. Virol. 64:16-23, 1990). DNA synthesis leads to the covalent attachment of a protein to the 5' end of minus-strand DNA, and it is generally believed that this protein serves as the primer for reverse transcription. To examine priming in more detail, we have carried out a detailed genetic analysis of the nucleotide sequences at the origin of minus-strand DNA synthesis characterized in our earlier study. This mutational analysis has led to the identification of a short, four-nucleotide-long sequence as the signal for initiation of reverse transcription. This signal is a UUUC sequence motif flanking the position of the 5' end of minus-strand DNA, which alone is not sufficient for DNA synthesis, indicating that positional effects are also important to specify the origin of DNA synthesis.

Identification and characterization of the woodchuck hepatitis virus origin of DNA replication

Replication of the woodchuck hepatitis virus (WHV) genome requires the synthesis of minus-strand DNA from an RNA template, the pregenome, by reverse transcription. During this reaction, the 5' end of minus-strand DNA becomes covalently linked to a protein. The position of the 5' end of minus-strand DNA was identified previously, but the initiation site for DNA synthesis on pregenomic RNA remained ambiguous because of a sequence repetition at the termini of the RNA template for reverse transcription. Employing a recently designed expression vector for the production of infectious WHV, we localized the origin of minus-strand DNA synthesis to the 3' end of pregenomic RNA. In addition, we identified the nucleotide sequences on pregenomic RNA that provide the signal for the initiation of reverse transcription. Removal of this signal sequence from pregenomic RNA abolished minus-strand DNA synthesis. Insertion of a DNA oligomer bearing this signal sequence at the 3' end of pregenomic RNA restored the production of minus-strand DNA joined to protein. Our results support a model in which protein is the primer for reverse transcription of minus-strand DNA of WHV.

Expression of infectious woodchuck hepatitis virus in murine and avian fibroblasts

The liver is the primary site for replication of the hepadnavirus genome. We asked whether the posttranscriptional phase of the viral replication cycle would depend on hepatocyte-specific functions. For this purpose, we assayed a previously constructed chimera between sequences of the cytomegalovirus immediate-early promoter-enhancer region and woodchuck hepatitis virus (WHV) (C. Seeger and J. Maragos, J. Virol. 63:1907-1915, 1989) for its ability to direct the synthesis of infectious WHV in hepatoma cells and in murine and avian fibroblast cells. Viruslike particles containing WHV DNA were produced transiently in transfected hepatoma cells and in fibroblasts. Inoculation of woodchucks with culture medium from hepatoma cells or fibroblasts transfected with viral DNA led to productive WHV infection, as observed following infection of woodchucks with serum from WHV-infected animals. These results demonstrate that posttranscriptional events of the hepadnavirus replication cycle are not dependent on hepatocyte-specific functions.

In vitro infection of woodchuck hepatocytes with woodchuck hepatitis virus and ground squirrel hepatitis virus

Primary cultures of woodchuck hepatocytes were demonstrated to be susceptible to in vitro infection by both woodchuck hepatitis virus and ground squirrel hepatitis virus, as evidenced by the appearance of DNA species characteristic of hepadnavirus replication. Initiation of infection by woodchuck hepatitis virus was blocked by the presence of suramin, polybrene, or dideoxycytidine. Viral CCC DNA, the putative template for viral RNA transcription, was detected at 2 days postinfection. Accumulation of intracellular intermediates in virion DNA synthesis was negligible until 7-10 days postinfection, but these DNA intermediates then increased dramatically in amount over the next few weeks. Results were obtained which suggested that the prolonged accumulation of intermediates in virion DNA synthesis was an intrinsic property of the infection of individual cells, and not the result of a slow spread of virus through the cultures.

Molecular analysis of the function of direct repeats and a polypurine tract for plus-strand DNA priming in woodchuck hepatitis virus

The replication of the hepadnavirus DNA genome is initiated by reverse transcription of pregenome RNA into minus-strand DNA followed by plus-strand DNA synthesis. The priming of plus-strand DNA requires the transfer of an RNA primer from pregenome RNA to the primer-binding site on minus-strand DNA. Annealing of the primer to the primer-binding site is facilitated by short direct repeats, DR1 and DR2. To investigate the mechanism of plus-strand primer formation, we have introduced specific mutations into DR1 and DR2 and measured the effect of these mutants on initiation of plus-strand DNA synthesis. To facilitate such an analysis, we have constructed a vector for the efficient expression of woodchuck hepatitis virus in cultured cells. Our results suggest that the 3' end of the RNA primer is determined prior to its transfer to the primer-binding site and that the determination of the 3' end of the primer does not depend on a specific sequence motif at the cleavage site. In addition, we have identified an alternative initiation site for plus-strand DNA synthesis at a purine-rich sequence between DR1 and DR2. Initiation at this site occurs by a mechanism that is independent of the direct repeats and does not require the transfer of an RNA primer to the primer-binding site.

In vitro recombinants of ground squirrel and woodchuck hepatitis viral DNAs produce infectious virus in squirrels

Hepatitis B viruses of humans, woodchucks, ground squirrels, and ducks are similar biochemically but differ with respect to host range and pathogenicity. To pursue the genetic basis of these properties in the absence of a cell culture system for virus growth, we exploited the demonstrated infectivity of cloned hepatitis B virus DNA in whole animals. We constructed several recombinant molecules in vitro between cloned infectious genomes of woodchuck hepatitis virus (WHV) and ground squirrel hepatitis virus (GSHV) and assayed the recombinants for infectivity after intrahepatic injection in ground squirrels, which support growth of GSHV but not WHV. Two of the recombinants molecules initiated productive infection; in one recombinant genome, 76% of the coding region for the major surface glycoprotein of GSHV and for the overlapping portion of the presumptive gene for DNA polymerase was replaced by WHV DNA; in the other, 29% of the same coding domain was replaced by WHV DNA. These findings demonstrate the feasibility of generating viable recombinants of hepatitis B viruses from different animal species and suggest that the major host range determinants are not encoded within the surface antigen gene of these viruses.

Biochemical and genetic evidence for the hepatitis B virus replication strategy

Hepatitis B viruses synthesize their open circular DNA genomes by reverse transcription of an RNA intermediate. The details of this process have been examined with the use of mammalian hepatitis B viruses to map the sites for initiation and termination of DNA synthesis and to explore the consequences of mutations introduced at short, separated direct repeats (DR1 and DR2) implicated in the mechanisms of initiation. The first DNA strand to be synthesized is initiated within DR1, apparently by a protein primer, and the completed strand has a short terminal redundancy. In contrast, the second DNA strand begins with the sequence adjacent to DR2, but its 5' end is joined to an oligoribonucleotide that contains DR1; thus the putative RNA primer has been transposed to the position of DR2. It is now possible to propose a detailed strategy for reverse transcription by hepatitis B viruses that can be instructively compared with that used by retroviruses.

The cloned genome of ground squirrel hepatitis virus is infectious in the animal

The lack of an in vitro infectivity assay for hepatitis B viruses has impeded the analysis of their genetic organization. To examine the feasibility of generating mutant and recombinant viruses after manipulation of cloned viral DNA in vitro, we have tested the infectivity of the cloned genome of ground squirrel hepatitis virus (GSHV) in virus-free Beechey ground squirrels. We demonstrate that cloned GSHV DNA is infectious when injected directly into the liver in the form of trimeric, head-to-tail recombinant clones and recircularized monomeric molecules but not when injected into the portal vein. Infections established in all four recipients of intrahepatic injections of cloned GSHV DNA exhibited the characteristics observed after administration of virus: GSHV surface antigen and viral DNA appeared in the serum 14-22 weeks after inoculation, and both circular and heterogeneous protein-linked forms of viral DNA were found in liver biopsy samples. Furthermore, virus present in the sera of these animals can be transmitted to other ground squirrels. These findings imply that any function of virion proteins in the initiation of infection by hepatitis B viruses can be bypassed with the use of cloned viral DNA and that this animal model is suitable for testing mutant genomes.

Nucleotide sequence of an infectious molecularly cloned genome of ground squirrel hepatitis virus

We have determined the complete nucleotide sequence of an infectious cloned genome of ground squirrel hepatitis virus (GSHV), a nonpathogenic member of the hepadnavirus group. The genome is 3,311 base pairs long and contains the major open reading frames described for the related human and woodchuck hepatitis B viruses (HBV and WHV, respectively). These reading frames include genes for the major structural proteins (the surface and core antigens), unassigned open reading frames (A and B), the longer of which is presumed to encode the viral DNA polymerase, and an open reading frame preceding and continuous with the surface antigen gene. The arrangement of these open reading frames is similar to that encountered in the genomes of HBV and WHV: all of the reading frames are encoded on the same strand, they are positioned in the same fashion with respect to each other, and a large portion (at least 51%) of the genome can be translated in two reading frames. Comparisons of the predicted translational products of the three mammalian hepadnaviruses reveal 78% amino acid homology between the proteins of GSHV and WHV and 43% homology between those of GSHV and HBV. In addition, a perfect direct repeat of 10 to 11 base pairs, separated by ca. 46 to 223 base pairs, is present in the three mammalian viruses and in duck hepatitis B virus; the position of the repeats near the 5' termini of the two strands of virion DNA suggests a role in viral replication.

Closed circular viral DNA and asymmetrical heterogeneous forms in livers from animals infected with ground squirrel hepatitis virus

To identify possible intermediates in the replication of ground squirrel hepatitis virus, we characterized the major forms of intracellular virus-specific DNA in the livers of infected ground squirrels. A variety of DNA species were found: covalently closed circular molecules, relaxed circular molecules, and a heterogeneous collection of molecules that migrated ahead of closed circular DNA during agarose gel electrophoresis. The heterogeneous DNA was at least partly single stranded, consisted of minus strands in a greater than eight-fold mass excess of plus strands, and was tightly associated with protein.