DNA of a Human Hepatitis B Virus Candidate

Particles containing DNA polymerase (Dane particles) were purified from the plasma of chronic carriers of hepatitis B antigen. After a DNA polymerase reaction with purified Dane particle preparations treated with Nonidet P-40 detergent, Dane particle core structures containing radioactive DNA product were isolated by sedimentation in a sucrose density gradient. The radioactive DNA was extracted with sodium dodecyl sulfate and isolated by band sedimentation in a preformed CsCl gradient. Examination of the radioactive DNA band by electron microscopy revealed exclusively circular double-stranded DNA molecules approximately 0.78 mum in length. Identical circular molecules were observed when DNA was isolated by a similar procedure from particles that had not undergone a DNA polymerase reaction. The molecules were completely degraded by DNase 1. When Dane particle core structures were treated with DNase 1 before DNA extraction, only 0.78-mum circular DNA molecules were detected. Without DNase treatment of core structures, linear molecules with lengths between 0.5 and 12 mum, in addition to the 0.78-mum circles were found. These results suggest that the 0.78-mum circular molecules were in a protected position within Dane particle cores and the linear molecules were not within core structures. Length measurements on 225 circular molecules revealed a mean length of 0.78 +/- 0.09 mum which would correspond to a molecular weight of around 1.6 x 10(6). The circular molecules probably serve as primer-template for the DNA polymerase reaction carried out by Dane particle cores. Thermal denaturation and buoyant density measurements on the Dane particle DNA polymerase reaction product revealed a guanosine plus cytosine content of 48 to 49%.     

Structure of Hepatitis B Dane Particle DNA and Nature of the Endogenous DNA Polymerase Reaction

The circular DNA of hepatitis B Dane particles, which serves as the primer/template for an endogenous DNA polymerase, was analyzed by electrophoresis before and after a polymerase reaction and after digestion by restriction endonuclease or single-strand-specific endonuclease S1. The unreacted molecules extracted from the particles were electrophoretically heterogeneous, and treatment with S1 nuclease produced double-stranded linear DNA ranging in length from 1,700 to 2,800 base pairs (bp). After an endogenous DNA polymerase reaction, two discrete species of DNA molecules were found: a circular form and a linear form 3,200 bp long. The reaction resulted in a population of molecules with an elongated and more homogeneous double-stranded region. These results suggest that the circular molecules in Dane particles have single-stranded regions of varying lengths that are made double stranded during the DNA polymerase reaction. The endogenous DNA polymerase was found to initiate apparently at random in a region spanning more than a third of the molecule. Analysis of restriction endonuclease cleavage fragments of the fully elongated DNA revealed that although the molecules were of a uniform length, they were somewhat heterogeneous in sequence. The sum of the sizes of the 10 major endonuclease Hae III-generated fragments, detected by ethidium bromide, was 3,880 bp. Two additional fragments (B and G) detected by autoradiography after an endogenous DNA polymerase reaction with (32)P-labeled deoxynucleoside triphosphates made the total 4,910 bp.     

DNA synthesized in the hepatitis B Dane particle DNA polymerase reaction.

Radioactive DNA was prepared in extensive (4 h) Dane particle DNA polymerase reactions. In different experiments the amount of new DNA, determined by the amount of nucleotide incorporation into an acid-insoluble form, was between 29 and 45% of the total circular DNA isolated from Dane particle preparations after the reaction. DNA reassociation kinetics were used to determine the complexity of the newly synthesized DNA. In different experiments COt1/2 values, corresponding to between 625 and 1,250 nucleotide pairs, were obtained for the radioactive Dane particle DNA. These results suggest that a unique region (or regions), corresponsing to approximately one-fourth to one-half of the circular Dane particle DNA template, was copied one time during the reaction. DNA and RNA extracted from hepatitis B virus-infected liver but not from uninfected liver accelerated the rate of reassociation of radioactive DNA from Dane particles. These Dane particle DNA base sequences were found in alkali-stable, rapidly sedimenting DNA from infected liver as well as in DNA sedimenting at a rate similar to the DNA extracted from Dane particles. These findings are consistent with Dane particle DNA being hepatitis B virus DNA that is integrated into high-molecular-weight cellular DNA and transcribed into RNA in infected liver.     

Mechanism of DNA degradation by the ATP-dependent DNase from Hemophilus influenzae Rd.

The rate of production of acid-soluble material during degradation of duplex DNA by Hemophilus influenzae ATP-dependent DNAse (Hind exonuclease V) has been shown to be directly dependent upon the Mg2+ concentration in the reaction mixture. At high concentrations of Mg2+ (5 to 20 mM), DNA degradation to acid-soluble products is rapid and the rate of ATP hydrolysis is slightly depressed. At low concentrations of Mg2+ (0.1 to 0.5 mM), the enzyme rapidly hydrolyzes ATP and converts up to 35% of linear duplex DNA to single-stranded material while degrading less than 0.2% of the DNA to acid-soluble products. We refer to this enzymatic production of single-stranded DNA as the "melting" activity. Under the conditions of our assay, the initial melting reaction is processive, lasting about 70s on phage T7 DNA. Using DNAs with several different lengths, we have established that the duration of the initial reaction is dependent upon DNA length, requiring approximately 1 s per 0.18 mum. The products of the initial reaction on phage T7 DNA are somewhat heterogeneous, consisting of short duplex fragments approximately 0.5 mum long, purely single-stranded products up to 7 mum long, and longer duplex fragments 3 to 11 mum in length, some of which have single-stranded tails. Nearly half of the single-stranded material remains linked to a duplex segment of DNA after the inital processive reaction. We propose that Hind exo V initiates attack at the DNA termini and then acts in a processive manner, migrating along the DNA molecule, converting some regions to single-stranded material by the combined action of the melting activity and limited phosphodiester cleavage, while leaving other regions double-stranded. At the completion of its processive movement through a single DNA molecule, it is released and then recycles onto either intact molecules or the partially degraded products, continuing in this manner until the DNA is finally reduced to oligonucleotides.     

Evidence for supercoiled hepatitis B virus DNA in chimpanzee liver and serum Dane particles: possible implications in persistent HBV infection

In chimpanzee hepatitis B virus (HBV) carriers, the mechanism of viral persistence has been examined by analyzing viral DNA molecules in liver and serum. Chimpanzee liver DNA contained two extrachromosomal HBV DNA molecules migrating on hybridization blots at 4.0 kb and 2.3 kb. There was no evidence for integration of HBV DNA into the host genome. The extrachromosomal molecules were distinct from Dane particle DNA and were converted to linear 3.25 kb full-length double-stranded HBV DNA on digestion with Eco RI. Nucleases S1 and Bal 31 converted "2.3 kb" HBV DNA to 3.25 kb via an intermediate of "4.0 kb" apparent length. The HBV DNA molecule that migrated at 2.3 kb represents a supercoiled form I of the HBV genome, and the molecule that migrated at 4.0 kb represents a full-length "nicked," relaxed circular form II. Evidence for supercoiled HBV DNA in serum Dane particles was obtained by production of form II molecules upon digestion with nuclease S1 or Bal 31. It is proposed that most Dane particles represent interfering noninfectious virus containing partially double-stranded DNA circles and that particles containing supercoiled HBV DNA may represent infectious hepatitis B virus.     

Inhibition of hepatitis B Dane particle DNA polymerase activity by pyrophosphate analogs

A DNA polymerase is associated with the core of the so-called Dane particles. The probability that this is the hepatitis B viral DNA polymerase offers the possibility of preventing hepatitis B multiplication by selective inhibition of this enzyme. We have previously reported that trisodium phosphonoformate (PFA) inhibits Dane particle DNA polymerase. Fifteen compounds with structural similarity to PFA and pyrophosphate have now been tested for inhibition of hepatitis B virus DNA polymerase in an attempt to define the structural requirement for the inhibition. Active structures have two acid groups at close proximity of which at least one is a phosphono group. Phosphonoformate and hypophosphare were the two most active inhibitors. The Ki value for PFA was 7.2 microM when dTTP was used as variable substrate, and the mechanism of inhibition was non-competitive. Phosphonoformate caused rapid shut-off of the polymerase reaction, indicating that it might inhibit elongation. The efficient inhibition of hepatitis B virus DNA polymerase by PFA and its low toxicity suggest that it could be used to inhibit hepatitis B virus multiplication in vivo.     

Structure of the hepatitis B virus genome.

The extent and position of the single-stranded gap in DNA molecules from Dane particles isolated from two donors of the adw serotype were determined by molecular hybridization and electron microscopic methods. The results showed that in each preparation more than 99% of the circular molecules are of uniform length and contain both single- and double-stranded regions. They confirmed that one end of the short strand is fixed with respect to the single EcoRI site within the molecule and to the nick in the long strand, but they also showed that although the position of the other end is variable, there is a preferred minimum length of about 650 to 700 nucleotides for the single-stranded region.     

Three envelope proteins of hepatitis B virus: large S, middle S, and major S proteins needed for the formation of Dane particles.

The infectious particles of hepatitis B virus are called Dane particles and consist of viral nucleic acid encapsulated within a core particle that is enveloped by virus-coded surface proteins. The major S protein constitutes a significant fraction of these surface proteins. In addition, there are two other related proteins (large S and middle S), but their role in envelope formation has not yet been elucidated. We modified the translation initiation codon ATG of each of the envelope proteins by site-directed mutagenesis and found that mutant genomes that did not produce one or two of these proteins were unable to form Dane particles. The particles released into the culture medium by such mutants did not carry DNA. Synthesis of virus-coded RNA still occurred normally, and core particles carrying DNA accumulated intracellularly. The DNA in such core particles was mostly in the double-stranded open circular form, in contrast to the normal situation in which the particles contain mostly RNA and its complementary single-stranded DNA or else contain linear DNA that is partially single stranded and otherwise duplex. The role of the large S and middle S proteins in the formation of Dane particles is discussed.     

Characterisation of DNA forms associated with cassava latent virus infection.

In addition to the major encapsidated DNA species found in preparations of cassava latent virus (genomic DNAs 1 and 2) there are minor DNA populations of twice (dimeric) and approximately half genome length. Both minor species resemble the genomic DNAs in that they are composed of predominantly circular single-stranded DNA. All of these size groups have a corresponding covalently-closed circular double-stranded DNA form in infected tissue. Infectivity studies using cloned DNAs 1 and 2 show that dimeric DNA routinely appears, suggesting it to be an intermediate in the DNA replicative cycle that can be encapsidated at low efficiency. In contrast, half unit length DNA has not yet been detected after multiple passaging of virus derived from the cloned DNA inoculum. Half unit length DNAs appear to be derived exclusively from DNA 2 and consist of a population of molecules exhibiting a relatively specific deletion. As they have an inhibitory effect on virus multiplication, their encapsidated forms are analogous to defective interfering particles associated with other eukaryotic DNA containing viruses. Small primer molecules associated with the genomic single-stranded DNAs, as reported for another geminivirus, have not been detected in CLV.     

Homologous pairing in duplex DNA regions and the formation of four-stranded paranemic joints promoted by RecA protein. Effects of gap length and negative superhelicity

RecA protein catalyzes homologous pairing of partially single-stranded duplex DNA and fully duplex DNA to form stable joint molecules. We constructed circular duplex DNA with various defined gap lengths and studied the pairing reaction between the gapped substrate with fully double-stranded DNA. The reaction required a stoichiometric amount of RecA protein, and the optimal reaction was achieved at a ratio of 1 RecA monomer per 4 base pairs. The length of the gap, ranging from 141 to 1158 nucleotides, had little effect on the efficiency of homologous pairing. By using a circular gapped duplex DNA prepared from the chimeric phage M13Gori1, we were able to show the formation of nonintertwined or paranemic joints in duplex regions between the gapped and fully duplex molecules. The formation of such paranemic joints occurred efficiently and included nearly all of the DNA in the reaction mixture. The reaction required negative superhelicity, and pairing was greatly reduced with linear or nicked circular DNA. We conclude that one functional role of the single-stranded gap is for facilitating the binding of RecA protein to the duplex region of the gapped DNA. Once the nucleoprotein filament is formed, homologous pairing between the gapped and fully duplex DNA can take place anywhere along the length of the nucleoprotein complex.     

Topological linkage of circular DNA molecules promoted by Ustilago rec 1 protein and topoisomerase

We studied the formation of linked circular DNA molecules promoted by the combined action of rec 1 protein and type I topoisomerase of Ustilago maydis. When ATP was added as cofactor to reactions containing rec 1 protein, pairs of homologous circular DNA molecules became linked after addition of topoisomerase. Closed circular duplex molecules could be joined at homologous sites with circular single-stranded molecules or with other circular duplex molecules, provided that homologous single-stranded DNA fragments or RNA polymerase and nucleoside triphosphates were also added. Complexes formed were topologically linked through regions of heteroduplex DNA. When the analog adenylyl-imidodiphosphate was substituted for ATP, nonhomologous pairs of circular DNA molecules became linked.     

Bacteriophage P2 DNA replication. Characterization of the requirement of the gene B protein in vivo

Replicative intermediates isolated from Escherichia coli cells infected with P2 gene B mutants were circular DNA molecules with single-stranded DNA tails, as opposed to the double-stranded DNA tails of wild-type replicative intermediates. The results show that the mutant replicative intermediates arose from aberrant DNA replication, aberrant due to a lack of lagging strand DNA synthesis, but with normal leading strand synthesis, so that only one circular duplex daughter DNA molecule was made from each duplex parent molecule. The single-stranded tails were shown to correspond to the nicked (and therefore displaced) parental DNA "l" strands. By partial denaturation mapping, the ends of the single-stranded tails tended to map close to the replication origin, but not all at a unique position, probably due to partial degradation or breakage in vivo, or during cell lysis or DNA isolation. By hybridization to separated strands of P2 DNA on nitrocellulose filters, DNA synthesis was shown to be asymmetric, and consistent with more leading strand than lagging strand synthesis having occurred. We concluded that the gene B protein is required for lagging strand DNA synthesis, but not for initiation, elongation or termination of the leading strand.     

Genetic transformation of Saccharomyces cerevisiae with single-stranded circular DNA vectors

We asked if single-stranded vector DNA molecules could be used to reintroduce cloned DNA sequences into a eukaryotic cell and cause genetic transformation typical of that observed using double-stranded DNA vectors. DNA was presented to Saccharomyces cerevisiae following a standard transformation protocol, genetic transformants were isolated, and the physical state of the transforming DNA sequence was determined. We found that single-stranded DNA molecules transformed yeast cells 10- to 30-fold more efficiently than double-stranded molecules of identical sequence. More cells were competent for transformation by the single-stranded molecules. Single-stranded circular (ssc) DNA molecules carrying the yeast 2 μ plasmid-replicator sequence were converted to autonomously replicating double-stranded circular (dsc) molecules, suggesting their efficient utilization as templates for DNA synthesis in the cell. Single-stranded DNA molecules carrying 2 μ plasmid non-replicator sequences recombined with the endogenous multicopy 2 μ plasmid DNA. This recombination yielded either the simple molecular adduct expected from homologous recombination (40% of the transformants examined) or aberrant recombination products carrying incomplete transforming DNA sequences, endogenous 2 μ plasmid DNA sequences, or both (60% of the transformants examined). These aberrant recombination products suggest the frequent use of a recombination pathway that trims one or both of the substrate DNA molecules. Similar aberrant recombination products were detected in 30% of the transformants in cotransformation experiments employing single-stranded and double-stranded DNA molecules, one carrying the 2 μ plasmid replicator sequence and the other the selectable genetic marker. We conclude that single-stranded DNA molecules are useful vectors for the genetic transformation of a eukaryotic cell. They offer the advantage of high transformation efficiency, and yield the same intracellular DNA species obtained upon transformation with double-stranded DNA molecules. In addition, single-stranded DNA molecules can participate in a recombination pathway that trims one or both DNA recombination substrates, a pathway not detected, at least at the same frequency, when transforming with double-stranded DNA molecules     

Single strand-containing replicating molecules of circular mitochondrial DNA

Mitochondrial DNAs (mtDNAs) from Chang rat solid hepatomas and Novikoff rat ascites hepatomas were examined in the electron microscope after preparation by the aqueous and by the formamide protein monolayer techniques. MtDNAs from both tumors were found to include double-forked circular molecules with a form and size suggesting they were replicative intermediates. These molecules were of two classes. In molecules of one class, all three segments were apparently totally double stranded. Molecules of the second class were distinguished by the fact that one of the segments spanning the region between the forks in which replication had occurred (the daughter segments) was either totally single stranded, or contained a single-stranded region associated with one of the forks. Daughter segments of both totally double-stranded and single strand-containing replicating molecules varied in length from about 3 to about 80% of the circular contour length of the molecule. Similar classes of replicating molecules were found in mtDNA from regenerating rat liver and chick embryos, indicating them to be normal intermediates in the replication of mtDNA All of the mtDNAs examined included partially single-stranded simple (nonforked) circular molecules. A possible scheme for the replication of mtDNA is presented, based on the different molecular forms observed     

Complete enzymatic synthesis of DNA containing the SV40 origin of replication

The replication of simian virus 40 origin-containing DNA has been reconstituted in vitro with SV40 large T antigen and purified proteins isolated from HeLa cells. Covalently closed circular DNA (RF I') daughter molecules are formed in the presence of T antigen, a single-stranded DNA binding protein and DNA polymerase alpha-primase complex, together with ribonuclease H, DNA ligase, topoisomerase II, and a double-stranded specific exonuclease that has been purified to homogeneity. The 44-kDa exonuclease-digested oligo(rA) annealed to poly(dT) in the 5'----3' direction. DNA ligase and the 5'----3' exonuclease were essential for RF I' formation. Covalently closed circular duplex DNA and full length linear single-stranded DNA were detected by alkaline gel electrophoresis as products of the complete system. DNA replication in the absence of either DNA ligase or the 5'----3' exonuclease yielded DNA products that were half length (approximately 1500 nucleotides) and smaller Okazaki-like fragments (approximately 200 nucleotides). Hybridization experiments showed that the longer chains were synthesized from the leading strand template, while the small products were synthesized from the lagging strand template. These results suggest that the RNA primers attached to 5' ends of replicated DNA are completely removed by the 5'----3' exonuclease, with the assistance of RNase H.     

Sizing of single-stranded regions in double-stranded DNA by preparative benzoylated DEAE-cellulose chromatography

The concentration of caffeine required to elute wholly single-stranded DNA from benzoylated DEAE-cellulose is proportional to the polynucleotide length. The use of benzoylated DEAE-cellulose chromatography for isolating and sizing single-stranded regions in double-stranded DNA has been examined using a series of hybrid molecules. Restriction fragments of the replicating form of bacteriophage luminal diameter X174 were hybridized to the intact 'plus' strand, thereby forming hybrids having single- and/or double-stranded regions in the kilobase range. A series of such hybrid preparations were subject to caffeine concentration gradient elution from benzoylated DEAE-cellulose. After logarithmic transformation, a linear relationship (R = 0.94) could be demonstrated between eluting caffeine concentration and single-stranded length, irrespective of the length of associated double-stranded regions or the location, within a given fragment, of unpaired nucleotides. Benzoylated DEAE-cellulose chromatography may therefore be used to separate and characterize, on a preparative scale, double-stranded DNA containing single-stranded regions.     

The mechanism of action of an accessory protein for DNA polymerase alpha/primase

A previous paper reported the purification (from mouse cell extracts) and some of the properties of a protein, alpha accessory factor (AAF), that specifically stimulates DNA polymerase alpha/primase (1). We describe here studies on the mechanism of action of AAF. In the presence of AAF and a large excess of single-stranded circular DNA template, a molecule of DNA polymerase alpha/primase interacts with a single template DNA molecule priming and synthesizing multiple short DNA fragments covering thousands of nucleotides without detaching from the template, and, by many-fold repetition of the process, accomplishes serial replication of the population of DNA molecules. In contrast, without AAF the reaction involves the whole population of DNA molecules in parallel and with a very large number of binding events between DNA polymerase alpha/primase and DNA [corrected] template. The profound [corrected] increase in affinity of DNA polymerase alpha/primase for the DNA template that characterizes the mechanism suggests a functional identification of AAF as a template affinity protein. The resulting greater efficiency accounts for the ability of AAF to stimulate both the primase and polymerase activities of DNA polymerase alpha/primase. AAF also increases the processivity of DNA polymerase alpha/primase from approximately 15 to approximately 115 nucleotides, a size similar to that of mammalian Okazaki fragments, and it appears to allow DNA polymerase alpha/primase to traverse double-stranded regions of a DNA template. These features of the mechanism of AAF suggest that it may have a role in assisting DNA polymerase alpha/primase in synthesis of the lagging strand of a replication fork.     

On the mechanism of pairing of single- and double-stranded DNA molecules by the recA and single-stranded DNA-binding proteins of Escherichia coli

The pairing of single- and double-stranded DNA molecules at homologous sequences promoted by recA and single-stranded DNA-binding proteins of Escherichia coli follows apparent first-order kinetics. The initial rate and first-order rate constant for the reaction are maximal at approximately 1 recA protein/3 and 1 single-stranded DNA-binding protein/8 nucleotides of single-stranded DNA. The initial rate increases with the concentration of duplex DNA; however, the rate constant is independent of duplex DNA concentration. Both the rate constant and extent of reaction increase linearly with increasing length of duplex DNA over the range 366 to 8623 base pairs. In contrast, the rate constant is independent of the size of the circular single-stranded DNA between 6,400 and 10,100 nucleotides. No significant effect on reaction rate is observed when a single-stranded DNA is paired with 477 base pairs of homologous duplex DNA joined to increasing lengths of heterologous DNA (627-2,367 base pairs). Similarly, heterologous T7 DNA has no effect on the rate of pairing. These findings support a mechanism in which a recA protein-single-stranded DNA complex interacts with the duplex DNA to produce an intermediate in which the two DNA molecules are aligned at homologous sequences. Conversion of the intermediate to a paranemic joint then occurs in a rate-determining unimolecular process.