Adenovirus DNA replication in vitro: duplication of single-stranded DNA containing a panhandle structure

Human Adenovirus Gene Expression and Replication Is Regulated through Dynamic Changes in Nucleoprotein Structure throughout Infection

Human adenovirus (HAdV) is extremely common and can rapidly spread in confined populations such as daycare centers, hospitals, and retirement homes. Although HAdV usually causes only minor illness in otherwise healthy patients, HAdV can cause significant morbidity and mortality in certain populations, such as the very young, very old, or immunocompromised individuals. During infection, the viral DNA undergoes dramatic changes in nucleoprotein structure that promote the rapid expression of viral genes, replication of the DNA, and generation of thousands of new infectious virions-each process requiring a distinct complement of virus and host-encoded proteins. In this review, we summarize our current understanding of the nucleoprotein structure of HAdV DNA during the various phases of infection, the cellular proteins implicated in mediating these changes, and the role of epigenetics in HAdV gene expression and replication.

Clinical features and treatment of adenovirus infections

Adenoviruses (Ads) are common opportunistic pathogens that are rarely associated with severe clinical symptoms in healthy individuals. In contrast, in patients with compromised immunity, Ad infections often result in disseminated and potentially life-threatening disease. Among these are AIDS patients, individuals with hereditary immunodeficiencies and recipients of solid organ or haematopoietic stem cell transplants (HSCT) who receive immunosuppressive therapy. The latter account for the largest number of severe Ad infections. There is currently no formally approved antiviral therapy for the treatment of severe Ad keratoconjunctivitis and life-threatening Ad infections in immunocompromised patients. Here we update current knowledge on Ad biology, the clinical features observed in different patient groups and specific immune responses towards Ad infections. In addition, we review current and future treatment options, including: (i) the antiviral drugs cidofovir, ribavirin and new investigational compounds, as evaluated in the clinic or in relevant animal models, as well as (ii) novel immunotherapeutic strategies.

Restoration of a functional open reading frame by homologous recombination between two adenoviral vectors

In this study, we examined the ability of adenoviral (Ad) vectors to undergo homologous recombination. The lacZ gene was divided between two parental, first-generation vectors such that neither encoded a functional product but both shared 494 bp in common. The open reading frame could only be restored by homologous recombination. We observed beta-galactosidase activity only upon co-infection of both parental vectors and after the onset of viral DNA replication, creating a delay in expression of 24-36 hours in HeLa cells. At peak efficiency, this recombination vector system resulted in beta-galactosidase activity levels 100x above background and just 18x less than a conventional, first-generation vector in HeLa cells. After recombination, the resultant progeny vector genomes containing reconstituted expression cassettes were devoid of all viral genes and contained two packaging signals. These progeny genomes were efficiently packaged, could be separated from their parental vectors based on their lighter buoyant densities in CsCl gradients, and were subsequently used as functional gene transfer vectors. This novel recombination vector system should be useful for transferring large transgenes (because the carrying capacity of two Ad vectors can be exploited) or expressing any cytotoxic or Ad replication inhibitory protein (because the parental vectors exhibit no background expression).

Generation of adenovirus vectors devoid of all viral genes by recombination between inverted repeats

Direct or inverse repeated sequences are important functional features of prokaryotic and eukaryotic genomes. Considering the unique mechanism, involving single-stranded genomic intermediates, by which adenovirus (Ad) replicates its genome, we investigated whether repetitive homologous sequences inserted into E1-deleted adenoviral vectors would affect replication of viral DNA. In these studies we found that inverted repeats (IRs) inserted into the E1 region could mediate predictable genomic rearrangements, resulting in vector genomes devoid of all viral genes. These genomes (termed DeltaAd.IR) contained only the transgene cassette flanked on both sides by precisely duplicated IRs, Ad packaging signals, and Ad inverted terminal repeat sequences. Generation of DeltaAd.IR genomes could also be achieved by coinfecting two viruses, each providing one inverse homology element. The formation of DeltaAd.IR genomes required Ad DNA replication and appeared to involve recombination between the homologous inverted sequences. The formation of DeltaAd. IR genomes did not depend on the sequence within or adjacent to the inverted repeat elements. The small DeltaAd.IR vector genomes were efficiently packaged into functional Ad particles. All functions for DeltaAd.IR replication and packaging were provided by the full-length genome amplified in the same cell. DeltaAd.IR vectors were produced at a yield of approximately 10(4) particles per cell, which could be separated from virions with full-length genomes based on their lighter buoyant density. DeltaAd.IR vectors infected cultured cells with the same efficiency as first-generation vectors; however, transgene expression was only transient due to the instability of deleted genomes within transduced cells. The finding that IRs present within Ad vector genomes can mediate precise genetic rearrangements has important implications for the development of new vectors for gene therapy approaches.

Mechanism of DNA replication in eukaryotic cells: cellular host factors stimulating adenovirus DNA replication

Replication of adenovirus (Ad) DNA depends on interactions between three viral and three cellular proteins. Human transcription factors NFI and Oct-1 recruit the Ad DNA polymerase to the origin of DNA replication as a complex with the Ad protein primer pTP. High affinity and specificity DNA binding to recognition sites in this origin by the transcription factors stimulate and stabilize pre-initiation complex formation to compensate for the low binding specificity of the pTP/pol complex. In this review, we discuss the properties of NFI and Oct-1 and the mechanism by which they enhance initiation of DNA replication. We propose a model that describes the dynamics of initiation and elongation as well as the assembly and disassembly of the pre-initiation complex.

Helix-destabilizing properties of the adenovirus DNA-binding protein

The adenovirus DNA-binding protein (DBP) is a multifunctional protein that is essential for viral DNA replication. DBP binds both single-stranded and double-stranded DNA as well as RNA in a sequence-independent manner. Previous studies showed that DBP does not promote melting of duplex poly(dA-dT) in contrast to prokaryotic single-strand-binding proteins. However, here we show that DBP can displace oligonucleotides annealed to single-stranded M13 DNA. Depending upon the DBP concentration, strands of at least 200 nucleotides can be unwound. Although unwinding of short (17-bp), fully duplex DNA is facilitated by DBP, unwinding of larger (28-bp) duplexes is only possible if single-stranded protruding ends are present. These protruding ends must be at least 4 nucleotides long for optimal unwinding, and both 5' and 3' single-stranded overhangs suffice. DBP-promoted strand displacement is sensitive to MgCl2 and NaCl and not dependent upon ATP. Our results suggest that DBP, through formation of a protein chain on the displaced strand, may destabilize duplex DNA ahead of the replication fork, thereby assisting in strand displacement during replication.

The adenovirus DNA binding protein enhances intermolecular DNA renaturation but inhibits intramolecular DNA renaturation

The Adenovirus DNA binding protein (DBP) imposes a regular, rigid and extended conformation on single stranded DNA (ssDNA) and removes secondary structure. Here we show that DBP promotes renaturation of complementary single DNA strands. Enhancement of intermolecular renaturation is sequence independent, can be observed over a broad range of ionic conditions and occurs only when the DNA strands are completely covered with DBP. When one strand of DNA is covered with DBP and its complementary strand with T4 gene 32 protein, renaturation is still enhanced compared to protein-free DNA, indicating that the structures of both protein-DNA complexes are compatible for renaturation. In contrast to promoting intermolecular renaturation, DBP strongly inhibits intramolecular renaturation required for the formation of a panhandle from an ssDNA molecule with an inverted terminal repeat. We explain this by the rigidity of an ssDNA-DBP complex. These results will be discussed in view of the crystal structure of DBP that has recently been determined.

A deletion derivative of the kalilo senescence plasmid forms hairpin and duplex DNA structures in the mitochondria of Neurospora

A novel deletion derivative, delta kal, of the kalilo senescence plasmid from Neurospora intermedia, was recovered from a culture treated with chloramphenicol. The deletion derivative exists in mitochondria as two different, equally abundant forms: a 2.8 kb duplex DNA molecule (delta kal-2.8) and a 1.4 kb hairpin form (delta kal-1.4). The delta kal-2.8 plasmid contains the 1366 bp terminal inverted repeats and a partially duplicated 102 bp segment of the unique sequence of the 8.6 kb kalilo plasmid. In contrast, the delta kal-1.4 hairpin plasmid appears to result from the folding of single strands that are generated during the replication of delta kal-2.8. Both forms of delta kal have covalently linked terminal proteins. Sequence analysis suggests that delta kal was generated either by slippage of the tip of a growing strand during the replication of kalilo, or by illegitimate recombination between two copies of the plasmid at non-homologous palindromic sequences that might form cruciform structures. In either case, the deletion process was mediated at least in part by an inverted repeat of 5 bp in the unique region of kalilo. Since the terminal segments of kalilo DNA that are implicated in plasmid integration might also form cruciform structures, it is possible, but improbable, that the process that generated the first delta kal molecule is related to that which mediates integration of the plasmid into mitochondrial DNA.

Symmetrical adenovirus minichromosomes have hairpin replication intermediates

A special class of panhandles (hairpin or foldback structures) arising from the replication of symmetrical adenovirus (Ad) minichromosome dimers and oligomers have been identified by two-dimensional gel electrophoresis. Hairpins provide evidence for replicative intermediates in the pathway for Ad complementary-strand synthesis. Furthermore, larger inverted sequences give Ad minichromosomes a replicative advantage.

Analysis of replicative intermediates produced during bacteriophage phi 29 DNA replication in vitro

Replication of bacteriophage phi 29 DNA initiates at either end of its linear double-stranded DNA molecule and proceeds by a strand-displacement mechanism. In the present paper we have used an in vitro phi 29 DNA replication system to analyse by electron microscopy the replicative intermediates produced at different reaction times. Two types of replicative intermediates were observed: type I (full-length double-stranded phi 29 DNA molecules with one or more single-stranded DNA branches) and type II (full-length phi 29 DNA molecules formed by a double-stranded DNA portion of variable length from one end plus a single-stranded DNA portion spanning to the other end). Thus, the types of replicative intermediates produced in vivo were also formed in the in vitro phi 29 DNA replication system. Analysis of type I intermediates indicated that initiation of DNA replication occurs preferentially at both ends of the same DNA template, in a non-simultaneous manner. Type II intermediates appeared as early as two minutes after the reaction started, well before unit-length single-stranded phi 29 DNA molecules were synthesized. In addition, replication of recombinant phi 29 DNA templates lacking terminal protein at one end did not produce type II intermediates and led to an accumulation of full-length single-stranded phi 29 DNA molecules. These two observations strongly suggest that type II intermediates appear when two growing DNA chains, running from opposite ends, merge.