Viral DNA Strand Research Articles

Foscarnet decreases serum and liver duck hepatitis B virus DNA in chronically infected ducks

Foscarnet (trisodium phosphonoformate) is a new antiviral compound with in vitro inhibitory effects against the DNA polymerases of hepadna viruses. To study the effects of the drug in chronic hepadna virus infection, we treated ducks chronically infected with duck hepatitis B virus for 10 days with either low-dose foscarnet (50 mg/kg i.p. b.i.d.), high-dose foscarnet (250 mg/kg i.p. b.i.d.), or sterile water injections. Serum duck hepatitis B virus DNA and intrahepatic replicative forms of the virus were measured using molecular biological techniques with both a double-stranded radiolabeled DNA probe and a plus-strand (noncoding) specific RNA probe. We found a dose-related decrease in serum and intrahepatic duck hepatitis B virus DNA during treatment, with a rapid return toward baseline values after the cessation of treatment. There was a disproportionate decrease in the plus strand of viral DNA with treatment. We conclude that foscarnet exerts its effect in hepadna virus infection through inhibition of viral DNA polymerase. Further study is necessary to determine whether foscarnet, by itself or in combination with other treatment modalities, has a role to play in the treatment of chronic hepatitis B infections in humans.

Nuclease mechanism of the avian retrovirus pp32 endonuclease.

In vivo, the inferred circular retrovirus DNA precursor to the provirus contains two long terminal repeats (LTRs) in tandem. We studied the site-specific nicking of supercoiled DNA that contains tandem copies of avian retrovirus LTR DNA in vitro by using purified avian myeloblastosis virus pp32 endonuclease, Mg2+, and viral DNA substrates containing different LTR circle junction sequences. The results confirmed our previous observation that the pp32 protein generates two nicks, one in either viral DNA strand, each 2 nucleotides from the circle junction site. The specificity of nicking by pp32 was unchanged over an eight-fold range of protein concentration and with different avian retrovirus LTR circle junction substrates. These data are consistent with models which propose a role for the endonuclease in removal of two nucleotides from the LTR termini on integration of viral DNA in vivo.

Gene X of bacteriophage f1 is required for phage DNA synthesis: Mutagenesis of in-frame overlapping genes

The gene II protein of bacteriophage f1 is a site-specific endonuclease required for initiation of phage viral strand DNA synthesis. Within gene II is another gene, X, encoding a protein of unknown function identical to the C-terminal 27% of the gene II protein, and separately translated from codon 300 (AUG) of gene II. By oligonucleotide mutagenesis, we constructed phage mutants in which this codon has been changed to UAG (amber) or UUG (leucine), and propagated them on cells carrying a cloned copy of gene X on a plasmid. The amber mutant makes no gene X protein, and cannot grow in the absence of the complementing plasmid; the leucine-inserting mutant can make gene X protein, and grows normally without the plasmid. Without gene X protein, phage DNA synthesis (particularly viral strand synthesis) is impaired. We discuss this finding in the context of other known in-frame overlapping genes (particularly genes A and A ∗ of phage φX174), many of which are also involved in the specific initiation of DNA synthesis, and suggest applications for the mutagenic strategy we employed.

The bond in the bacteriophage øX174 gene A protein-DNA complex is a tyrosyl-5'-phosphate ester

The bacteriophage øX174 gene A protein cleaves the viral strand of the double-stranded replicative form (RF) DNA of the phage at a specific site, the origin. It leaves a free 3'-OH at nucleotide 4305 (G) of the øx DNA sequence and binds covalently to the DNA. The nature and position of the covalent bond have been determined using the octadecadesoxyribonucleotide CAACTTG[ 32P]ATATTAATAAC. This octadecamer, which corresponds to nucleotides 4299–4316 of øX viral DNA, is cleaved by gene A protein. Gene A protein is bound to the labelled phosphate via a tyrosyl residue, indicating that binding occurs to the nucleotide corresponding to 4306 (A) of the øX viral DNA strand. Bacteriophage øX174 Gene A protein DNA replication Protein-DNA complex Synthetic oligonucleotide Tyrosyl-5'-phosphate ester

DNA sequences required for the in vitro replication of adenovirus DNA.

Initiation of adenovirus (Ad) DNA replication occurs on viral DNA containing a 55-kilodalton (kDa) protein at the 5' terminus of each viral DNA strand and on plasmid DNAs containing the origin of Ad replication but lacking the 55-kDa terminal protein (TP). Initiation of replication proceeds via the synthesis of a covalent complex between an 80-kDa precursor to the TP (pTP) and the 5'-terminal deoxynucleotide, dCMP. Formation of the covalent pTP-dCMP initiation complex with Ad DNA as the template requires the viral-encoded pTP and DNA polymerase and, in the presence of the Ad DNA binding protein, is dependent upon a 47-kDa host protein, nuclear factor I. Initiation of replication with recombinant plasmid templates requires the aforementioned proteins and an additional host protein, factor pL. Deletion mutants of the Ad DNA replication origin contained within the 6.6-kilobase plasmid pLA1 were used to analyze the nucleotide sequences required for the formation and subsequent elongation of the pTP-dCMP initiation complex. The existence of two domains within the first 50 base pairs of the Ad genome, both of which are required for the efficient use of recombinant DNA molecules as templates in an in vitro DNA replication system, was demonstrated. The first domain, consisting of a 10-base-pair "core" sequence located at nucleotide positions 9-18, has been identified tentatively as a binding site for the pTP [ Rijinders , A. W. M., van Bergen, B. G. M., van der Vliet , P. C. & Sussenbach , J. S. (1983) Nucleic Acids Res. 11, 8777-8789]. The second domain, consisting of a 32-base-pair region spanning nucleotides 17-48, was shown to be essential for the binding of nuclear factor I.

Enzymatic techniques for the isolation of random single-base substitutions in vitro at high frequency.

A general and efficient method has been developed to generate large numbers of single-base substitution mutations simply and rapidly. A unique f1 phage recombinant DNA cloning vector is described, which contains the phi X174 origin of viral strand DNA synthesis and allows one to direct mutagenesis to any specific segment of DNA. Gapped circular DNA is constructed by annealing viral single-stranded circular DNA [ss(c) DNA] with a mixture of linear duplex DNAs that have had their 3'-OH termini processively digested with Escherichia coli exonuclease III under conditions in which the resulting, newly generated 3'-OH termini present in the various hybrid molecules span the region of interest. Base changes are induced by misincorporation of an alpha-thiodeoxynucleoside triphosphate analog onto this primer-template, followed by DNA repair synthesis. The asymmetric segregation of mutants from wild-type sequences is accomplished by double-stranded replicative form DNA----ss(c) DNA synthesis in vitro, initiated from the phi X174 viral strand origin sequence present on the vector DNA. Mutated ss(c) DNA is screened by the dideoxy chain termination method. In one mutagenesis experiment, 21 independent single-base substitutions were isolated in a 72-nucleotide-long target region. DNA sequence analysis showed that all possible base transversions and transitions were represented.

Selective cloning of a DNA single-strand initiation determinant from phi X174 replicative-form DNA.

An M13 phage deletion mutant, M13 delta E101, developed as a vector for selecting DNA sequences that direct DNA strand initiation on a single-stranded template, has been used for cloning restriction enzyme digests of phi X174 replicative-form DNA. Initiation determinants, detected on the basis of clear-plaque formation by the chimeric phage, were found only in restriction fragments containing the unique effector site in phi X174 DNA for the Escherichia coli protein n' dATPase (ATPase). Furthermore, these sequences were functional only when cloned in the orientation in which the phi X174 viral strand was joined to the M13 viral strand. A 181-nucleotide viral strand fragment containing this initiation determinant confers a phi X174-type complementary-strand replication mechanism on M13 chimeras. The chimeric phage is converted to the parental replicative form in vivo by a mechanism resistant to rifampin, a specific inhibitor of the normal RNA polymerase-dependent mechanism of M13. In vitro, the chimeric single-stranded DNA promotes the assembly of a functional multiprotein priming complex, or primosome, identical to that utilized by intact phi X174 viral strand DNA. Chimeric phage containing the sequence complementary to the 181-nucleotide viral strand sequence shows no initiation capability, either in vivo or in vitro.

Microinjected simian virus 40 cRNA is spliced, as evidenced by electron microscopy.

Simian virus 40 cRNA was transcribed in vitro from the early viral DNA strand. The RNA was injected through glass capillaries into the nuclei of monkey cells. After a 2-h incubation, the RNAs were extracted and hybridized to single-stranded simian virus 40 DNA sequences contained in a bacteriophage M13 vector. Electron microscopy revealed processed cRNAs with splice loops in the region of the intron of large T antigen.

DNA sequences which support activities of the bacteriophage phi X174 gene A protein.

The DNA sequence of 30 nucleotides which surrounds the origin of viral strand DNA replication is highly conserved amongst the icosahedral single-stranded DNA bacteriophages. The A gene of these phages encodes a protein which is required for initiation and termination of viral strand DNA synthesis and acts as a nicking-closing activity specifically within this 30-nucleotide sequence. A system of purified Escherichia coli host proteins and phi X174 gene A protein has been developed which specifically replicates in vitro the viral strand of phi X174 from RF (replicative form) I template DNA and yields single-stranded circular DNA products (RF leads to SS(c) DNA replication system). Recombinant plasmids carrying inserts derived from phage phi X174 or G4 DNA which range in length from 49 to 1175 base pairs and contain the 30-nucleotide conserved sequence have been shown to support phi X A protein-dependent DNA synthesis in vitro in this replication system. We report here that insertion of the 30-nucleotide sequence alone into pBR322 allows the resulting recombinant plasmids to support phi X A protein-dependent in vitro DNA synthesis as efficiently as phi X174 template DNA in the RF leads to SS(c) replication system. The 30-nucleotide sequence functions as a fully wild type DNA replication origin as determined by the rate of DNA synthesis and the structure of resulting DNA products. Furthermore, the DNA sequence requirements for nicking of RF I DNA by the phi X A protein and for supporting replication origin function have been partially separated. Homology to positions 1, 29, and 30 of the 30-nucleotide conserved sequence are not required for cleavage of RF I DNA by the A protein; homology to position 1 but not 29 or 30 is required for efficient DNA replication.

Structure and Replication of Minute Virus of Mice DNA

Minute virus of mice (MVM) is a member of the Parvoviridae, a family of viral agents that contain linear, single-stranded DNA genomes of only 1.2 × 106 daltons to 2.2 × 106 daltons (Berns and Hauswirth 1978). Parvoviruses that infect vertebrate hosts are divided into two subgroups on the basis of their requirement for helper viruses. Members of the adeno-associated-virus (AAV) subgroup are defective and entirely dependent on adenovirus (Atchison et al. 1965) or herpes simplex virus (Buller et al. 1981) coinfection for their replication; they also package equal numbers of plus and minus strands of DNA in separate virions (Berns and Hauswirth 1978). In contrast, members of the Parvovirus genus, to which MVM belongs, are capable of productive replication without the aid of a helper virus, and they normally package a unique (V or minus) strand of viral DNA. Replication of the autonomous parvoviruses is, however, dependent on cellular...

Virion DNA of ground squirrel hepatitis virus: structural analysis and molecular cloning.

The structure of the encapsidated DNA genome of ground squirrel hepatitis virus (GSHV) has been examined by restriction endonuclease cleavage, nucleic acid hybridization, and molecular cloning. GSHV virion DNA is a relaxed circular molecule of approximately 3,200 bases in length; most molecules harbor an extensive single-stranded region which is largely confined to one-half of the genome. The full-length viral DNA strand is covalently bound to protein. The single-stranded region can be repaired in vitro by the action of the endogenous virion polymerase, exogenously added DNA polymerase from avian myeloblastosis virus, or both. Restriction enzyme cleavage of viral DNA from different isolates demonstrated that multiple variants of GSHV exist in nature. The genomes of two such strains have been cloned in Escherichia coli, and their physical maps have been determined. Nucleic acid hybridization studies revealed that the strains share sequence homology with the DNA of human hepatitis B virus. Regions homologous to the coding regions for the surface and core antigens of human hepatitis B virus have been localized on the GSHV chromosome. Molecular cloning experiments have also led to the identification of a region of the viral genome which is altered in a procaryotic host.

Maximal limits of the Escherichia coli replication factor Y effector site sequences in pBR322 DNA.

pBR322 DNA contains two separate regions on opposite strands and close to the origin of replication which, when in single-stranded form, can act as effectors for the ATPase activity of Escherichia coli replication factor Y. Small fragments of DNA containing these sites when cloned into an fl phage vector act as origins of DNA replication allowing the formation of complementary double-stranded DNA in a rifampicin-resistant, dnaB-, dnaG-, and dnaC-dependent fashion in vitro. We report here the maximal limits of the E. coli replication factor Y effector sites of pBR322 DNA. The site on the H strand of pBR322 DNA can form a structure resistant to digestion by E. coli exonuclease VII, the site on the L strand cannot. The H and L strand sites lie within nucleotides 2144-2185 and 2353-2416, respectively, of pBR322 DNA. A deletion of 34 nucleotides (nucleotides 2121-2154) within the H strand site renders it totally inactive as an effector for factor Y ATPase activity. No extensive homology could be detected between the three known factor Y effector sites, the two reported here and the one previously identified on the phi X174 viral DNA strand (Shlomai, J., and Kornberg, A. (1980) Proc. Natl. Acad. Sci. U. S. A. 77, 799-803).

Mechanism of replication of bacteriophage phi X174 XX. Sensitivity of nascent DNA to single-strand-specific nucleases.

We reported earlier that dephosphorylated nascent phi X174 viral strand DNA molecules were less extensively degraded from the 5' end by spleen exonuclease than were non-nascent molecules. Experiments described here revealed that the insensitivity to the 5'-OH end-specific nuclease was more evident among the longer molecules in the population than among the shorter, all of the molecules being less than unit length in size. The smallest molecules in the population were about as sensitive to the enzyme as the control molecules and hence must possess unblocked 5'-terminal nucleotides. Degradation of the nascent DNA with the 3' end-specific snake venom phosphodiesterase revealed only a small enrichment for [3H]thymidine near the 3' end, seemingly insufficient to account completely for the apparent insensitivity of the longer molecules to spleen exonuclease. When the nascent molecules were isolated without the use of proteolytic enzymes, some pronase-sensitive material was found associated with the DNA, particularly the longer molecules. We suggest that the resistance of the longer nascent (pronase-treated) molecules to spleen exonuclease occurs because they have remnants of the viral gene A or A* protein covalently bound to the 5' end.

Mechanism of replication of bacteriophage phi X174 XIX. Initiation of phi X174 viral strand DNA synthesis at internal sites on the genome.

Bacteriophage phi X174 viral strand DNA molecules shorter than genome length found late in the infectious cycle in Escherichia coli were 5' end labeled with 32P. Hybridization of the 32P-labeled molecules to restriction enzyme fragments of phi X replicative form DNA revealed an excess of phi X molecules whose 5' ends mapped in HaeIII fragments Z3 and Z4 in comparison with fragments Z1 and Z2. This suggests that initiation of phi X174 viral strand DNA synthesis may occur at internal sites on the complementary strand. There are several appropriately located sequences that might serve as n' (factor Y) recognition sequences and thereby facilitate discontinuous synthesis of the viral strand.

Structure and 5′-termini of the large and 19 S RNA transcripts encoded by the cauliflower mosaic virus genome

Cauliflower mosaic virus-infected leaves accumulate two major RNA species late in infection—a 19 S RNA and a large RNA transcript. We have found that the large transcript is approximately full genome length. The 3′-end of the large transcript is located at or near a site corresponding to the 3′-end of the 19 S RNA. The 5′-end of the large transcript maps near its own 3′-end and only about 100 bp downstream from the terminator codon for coding region VI. The 5′-end of the large transcropt is situated at the beginning of the large intergenic region, about 600 bp upstream from the single-strand break in the transcribed viral DNA strand. The location of this site is of particular interest because it suggests that synthesis of the large transcript proceeds across the DNA break site. The 5′-end of the 19 S RNA maps in the small intergenic region between coding regions V and VI about 20–30 bp upstream from the initiation codon for coding region VI. By comparing the transcription initiation sites to DNA sequences for the CaMV genome, it can be shown that TATATAA sequences lie 20–30 bp upstream from the 5′-ends of both the 19 S and large transcripts.

Construction of viable and lethal mutations in the origin of bacteriophage φX174 using synthetic oligodeoxyribonucleotides

Six different synthetic deoxyhexadecamers complementary to the origin of bacteriophage φX174, corresponding to nucleotides 4299 to 4314, except for one preselected nucleotide change were used as primers for DNA synthesis on wild-type φX † † Abbreviations used: φX, bacteriophage φX174; RF DNA, replicative form DNA; RFI, replicative form DNA with both strands closed, containing superhelical turns; RFII, replicative form DNA with one or more discontinuities in either strand; RFIV, replicatiye form DNA with both strands closed, containing no superhelical turns; p.f.u., plaque-forming units; u.v., ultraviolet light; v, viral strand DNA; c, complementary strand DNA; wt φX, wild-type φX. DNA as a template. DNA synthesis was performed with Escherichia coli DNA polymerase I (Klenow fragment) in the presence of DNA ligase. Heteroduplex RFIV DNA was isolated and, after limited digestion with DNAase I, complementary strands containing the mutant primers were isolated. The biological activity of these complementary strands was assayed in spheroplasts. Spheroplasts were made from E. coli K58 ung − (uracil N-glycosylase) to prevent degradation of the complementary strands caused by uracil incorporation (Baas et al., 1980 a). Using (5′- 32P) end-labeled primers, it was shown that all tested DNA polymerase preparations, including phage T4 DNA polymerase, contained variable amounts of 5′ → 3′ exonuclease activity. This nick translation activity may result in removal of the mutation in the primers, and therefore in isolation of wild-type complementary DNA instead of mutant complementary DNA. Restriction enzyme analysis of completed RFIV DNA showed that the primers can initiate DNA synthesis at more than one place on the φX174 genome. These complications result in a mixed population of complementary strand DNAs synthesized in vitro. Nevertheless, the desired mutants were picked up with high frequency using a selection test that is based on the difference in ultraviolet light sensitivity of homoduplex and heteroduplex φX174 RF DNA. Heteroduplex φX174 RF DNA is two to three times more sensitive to ultraviolet light irradiation than is homoduplex φX174 RF DNA (Baas & Jansz, 1971,1972). Phage DNA derived from single plaque lysates of two of the six mutant complementary strand DNA preparations yielded, after annealing with wild-type complementary strand DNA, heteroduplex DNA with high frequency. DNA sequence analysis in the origin region of RF DNA obtained from these two phage preparations revealed the presence of the expected mutation. RFI DNA of these two origin mutants was nicked by φX174 gene A protein in the same way as wild-type φX174 RFI DNA. Phage DNA derived from single plaque lysates of the other four mutant complementary strand DNA preparations yielded exclusively homoduplex DNA after annealing with wild-type complementary strand DNA. It is concluded that priming with these deoxyhexadecamers resulted in the synthesis of complementary φX174 DNA with lethal mutations. The implications of these results, the construction of two silent, viable φX174 origin mutants and the failure to detect four others, for the initiation mechanism of φX174 RF DNA replication are discussed.

Orientation of the DNA in the filamentous bacteriophage f1

The filamentous bacteriophage f1 consists of a molecule of circular single-stranded DNA coated along its length by about 2700 molecules of the B protein. Five molecules of the A protein and five molecules of the D protein are located near or at one end of the virion, while ten molecules of the C protein are located near or at the opposite end. The two ends of the phage can be separated by reacting phage fragments, which have been generated by passage of intact phage through a French press, with antibody directed against the A protein (Grant et al., 1981 a). By hybridizing the DNA isolated from either end of 32P-labeled phage to specific restriction fragments of fl replicative form I DNA, we have determined that the single-stranded DNA of the filamentous bacteriophage f1 is oriented within the virion. For wild-type phage, the DNA that codes for the gene III protein is located at the A and D protein end and that which corresponds to the intergenic region is located close to the C protein end of the particle. The intergenic region codes for no protein but contains the origins for both viral and complementary strand DNA synthesis. Analysis of the DNA orientation in phage in which the plasmid pBR322 has been inserted into different positions within the intergenic region of fl shows that the C protein end of all sizes of filamentous phage particles appears to contain a common sequence of phage DNA. This sequence is located near the junction of gene IV and the intergenic region, and probably is important for normal packaging of phage DNA into infectious particles. There appears to be no specific requirement for the origins of viral and complementary strand DNA synthesis to be at the end of a phage particle.

Properties of the A and A proteins of bacteriophage G4. The origin of G4 replicative-form DNA replication.

The A and A proteins of the bacteriophage G4 have been purified. The proteins have been analysed for their enzymatic activities on single-stranded and double-stranded DNA. The A protein introduces a single-stranded break at a specific place in the G4 replicative form I DNA. This cleavage site has been localized between nucleotides 506 and 507 in the viral (+) strand. The A protein binds covalently to the 5' end of the cleavage site. The A protein initiates the replication of the viral (+) DNA [Borrias, et al. (1979) Virology, 31, 288-298]; the cleavage site therefore identifies the origin of replication. The A protein cleaves viral (+) strand DNA at many different sites and also binds covalently to the 5' ends of the nick sites. The properties of both proteins strongly resemble the properties of the A and A proteins of the related and much butter analysed phage phi X174. These results indicate that the G4 and phi X174A and A proteins have comparable functions and also that both phages initiate the replicative form DNA in a similar way.

Conservation of the primosome in successive stages of phi X174 DNA replication.

Synthesis of a complementary strand to match the single-stranded, circular, viral (+) DNA strand of phage phi X174 creates a parental duplex circle (replicative form, RF). This synthesis is initiated by the assembly and action of a priming system, called the primosome [Arai, K. & Kornberg, A (1981) Proc. Natl. Acad. Sci. USA 78, 69-73; Arai, K., Low, R. L. & Kornberg, A. (1981) Proc. Natl. Acad. Sci. USA 78, 707-711]. Of the seven proteins that participate in the assembly and function of the primosome, most all of the components remain even after the DNA duplex is completed and covalently sealed. Remarkably, the primosome in the isolated RF obviates the need for supercoiling of RF by DNA gyrase, an action previously considered essential for the site-specific cleavage by gene A protein that starts viral strand synthesis in the second stage of phi X174 DNA replication. Finally, priming of the synthesis of complementary strands on the nascent viral strands to produce many copies of progeny RF utilizes the same primosome, requiring the addition only of prepriming protein i. thus a single primosome, which becomes associated with the incoming viral DNA in the initial stage of replication, may function repeatedly in the initiation of complementary strands at the subsequent stage of RF multiplication. These patterns of phi X174 DNA replication suggest that a conserved primosome also functions in the progress of the replicating fork of the Escherichia coli chromosome, particularly in initiating the synthesis of nascent (Okazaki) fragments.

Cytoplasmic viral DNA synthesis in exogenous infection of murine leukemia virus: effect of interferon and cycloheximide.

Cytoplasmic viral DNA synthesis can be followed efficiently by [3H]thymidine labeling of cells exogenously infected with Moloney murine leukemia virus. Both the negative and the positive strands of viral DNA reached their maximal level in the cytoplasm at 3.5 h postinfection. Interferon treatment before infection markedly reduced the amount of viral DNA formed during the first 3.5 h, but led to a second major wave of viral DNA synthesis, peaking at 7.5 h postinfection. No such late cytoplasmic DNA synthesis occurred in the untreated control. Inhibition of protein synthesis by cycloheximide, on the other hand, stimulated cytoplasmic viral DNA synthesis during the first 3.5 h.