Genetic analysis of the vaccinia virus I6 telomere-binding protein uncovers a key role in genome encapsidation

The linear, double-stranded DNA genome of vaccinia virus contains covalently closed hairpin termini. These hairpin termini comprise a terminal loop and an A+T-rich duplex stem that has 12 extrahelical bases. DeMasi et al. have shown previously that proteins present in infected cells and in virions form distinct complexes with the telomeric hairpins and that these interactions require the extrahelical bases. The vaccinia virus I6 protein was identified as the protein showing the greatest specificity and affinity for interaction with the viral hairpins (J. DeMasi, S. Du, D. Lennon, and P. Traktman, J. Virol. 75:10090-10105, 2001). To gain insight into the role of I6 in vivo, we generated eight recombinant viruses bearing altered alleles of I6 in which clusters of charged amino acids were changed to alanine residues. One allele (temperature-sensitive I6-12 [tsI6-12]) conferred a tight ts phenotype and was used to examine the stage(s) of the viral life cycle that was affected at the nonpermissive temperature. Gene expression, DNA replication, and genome resolution proceeded normally in this mutant. However, proteolytic processing of structural proteins, which accompanies virus maturation, was incomplete. Electron microscopic studies confirmed a severe block in morphogenesis in which immature, but no mature, virions were observed. Instead, aberrant spherical virions and large crystalloids were seen. When purified, these aberrant virions were found to have normal protein content but to be devoid of viral DNA. We propose that the binding of I6 to viral telomeres directs genome encapsidation into the virus particle.     

Replication and resolution of cloned poxvirus telomeres in vivo generates linear minichromosomes with intact viral hairpin termini.

The covalently closed terminal hairpins of the linear duplex-DNA genomes of the orthopoxvirus vaccinia and the leporipoxvirus Shope fibroma virus (SFV) have been cloned as imperfect palindromes within circular plasmids in yeast cells and recombination-deficient Escherichia coli. The viral telomeres inserted within these recombinant plasmids are equivalent to the inverted-repeat structures detected as telomeric replicative intermediates during poxvirus replication in vivo. Although the telomeres of vaccinia and SFV show little sequence homology, the termini from both viral genomes exist as AT-rich terminal hairpins with extrahelical bases and alternate "flip-flop" configurations. Using an in vivo replication assay in which circular plasmid DNA was transfected into poxvirus-infected cells, we demonstrated the efficient replication and resolution of the cloned imperfect palindromes to bona fide hairpin termini. The resulting linear minichromosomes, which were readily purified from transfected cells, were shown by restriction enzyme mapping and by electron microscopy to have intact covalently closed hairpin termini at both ends. In addition, staggered unidirectional deletion derivatives of both the cloned vaccinia and SFV telomeric palindromes localized an approximately 200-base-pair DNA region in which the sequence organization was highly conserved and which was necessary for the resolution event. These data suggest a conserved mechanism of the resolution of poxvirus telomeres.     

Cloning of the vaccinia virus telomere in a yeast plasmid vector

The vaccinia virus DNA telomere, which contains a covalently closed hairpin structure, has been cloned in a yeast plasmid vector. Restriction mapping indicates that the cloned vaccinia telomere is maintained in yeast not in its native hairpin configuration but as an inverted repeat structure, within a circular plasmid, with the sequences of the viral hairpin now at the axis of symmetry of an imperfect palindrome. As such, the cloned telomere resembles the telomeric replicative intermediate observed during vaccinia virus DNA replication. Small deletions and duplications in the viral inverted repeats of different clones suggest a model in which the observed circular plasmids were generated in yeast by the replication of hybrid linear DNA molecules consisting of the linearized yeast vector flanked by two hairpin-containing vaccinia termini.     

Efficient resolution of replicated poxvirus telomeres to native hairpin structures requires two inverted symmetrical copies of a core target DNA sequence.

The terminal hairpin sequences of the linear double-stranded DNA genome of the leporipoxvirus Shope fibroma virus (SFV) has been cloned in Saccharomyces cerevisiae and in recombination-deficient Escherichia coli as a palindromic insert within circular plasmid vectors. This sequence configuration is equivalent to the inverted repeat structure detected as a telomeric replicative intermediate during poxvirus replication in vivo. Previously, it has been shown that when circular plasmids containing this palindromic insert were transfected into SFV-infected cells, efficient replication and resolution generated linear minichromosomes with bona fide viral hairpin termini (A. M. DeLange, M. Reddy, D. Scraba, C. Upton, and G. McFadden, J. Virol. 59:249-259, 1986). To localize the minimal target DNA sequence required for efficient resolution, a series of staggered unidirectional deletions were constructed at both ends of the inverted repeat. Analyses of the resolution efficiencies of the various clones indicate that up to 240 base pairs (bp) centered at the symmetry axis were required for maximal resolution to minichromosomes. To investigate the role of the AT-rich central axis sequences, which in SFV include 8 nonpalindromic bp, a unique AflII site at the symmetry axis was exploited. Bidirectional deletions extending from this AflII site and insertions of synthetic oligonucleotides into one of the deletion derivatives were constructed and tested in vivo. The efficiency with which these plasmids resolved to linear minichromosomes with hairpin termini has enabled us to define the minimal target DNA sequence as two inverted copies of an identical DNA sequence between 58 and 76 bp in length. The nonpalindromic nucleotides, which, after resolution, constitute the extrahelical residues characteristic of native poxviral telomeres, were not required for resolution. The close resemblance of the SFV core target sequence to the analogous region from the orthopoxvirus vaccinia virus is consistent with a conserved mechanism for poxviral telomere resolution.     

Resolution of linear minichromosomes with hairpin ends from circular plasmids containing vaccinia virus concatemer junctions

The junctions, separating unit-length genomes in intracellular concatemeric forms of vaccinia virus DNA, are duplex copies of the hairpin loops that form the ends of mature DNA molecules present in infectious virus particles. Circular E. coli plasmids with palindromic junction fragments were replicated in vaccinia virus-infected cells and resolved into linear minichromosomes with vector DNA in the center and vaccinia virus DNA hairpins at the two ends. Resolution did not occur when the concatemer joint was less than 250 bp or when plasmids were transfected into uninfected cells, indicating requirements for a specific DNA structure and viral trans-acting factors. These studies indicate that concatemers can serve as replicative intermediates and account for the generation of flip-flop sequence variation of the hairpins at the ends of the mature vaccinia virus genome.     

The mismatched nucleotides encoded in vaccinia virus flip-and-flop hairpin telomeres serve an essential role in virion maturation

Poxvirus genomes consist of a linear duplex DNA that ends in short inverted and complementary hairpin structures. These elements also encode loops and mismatches that likely serve a role in genome packaging and perhaps replication. We constructed mutant vaccinia viruses (VACV) where the native hairpins were replaced by altered forms and tested effects on replication, assembly, and virulence. Our studies showed that structure, not sequence, likely determines function as one can replace an Orthopoxvirus (VACV) hairpin with one copied from a Leporipoxvirus with no effect on growth. Some loops can be deleted from VACV hairpins with little effect, but VACV bearing too few mismatches grew poorly and we couldn’t recover viruses lacking all mismatches. Further studies were conducted using a mutant bearing only one of six mismatches found in wild-type hairpins (SΔ1Δ3–6). This virus grew to ~20-fold lower titers, but neither DNA synthesis nor telomere resolution was affected. However, the mutant exhibited a particle-to-PFU ratio 10-20-fold higher than wild-type viruses and p4b/4b core protein processing was compromised, indicating an assembly defect. Electron microscopy showed that SΔ1Δ3–6 mutant development was blocked at the immature virus (IV) stage, which phenocopies known effects of I1L mutants. Competitive DNA binding assays showed that recombinant I1 protein had less affinity for the SΔ1Δ3–6 hairpin than the wild-type hairpin. The SΔ1Δ3–6 mutant was also attenuated when administered to SCID-NCR mice by tail scarification. Mice inoculated with viruses bearing wild-type hairpins exhibited a median survival of 30–37 days, while mice infected with SΔ1Δ3–6 virus survived >70 days. Persistent infections favor genetic reversion and genome sequencing detected one example where a small duplication near the hairpin tip likely created a new loop. These observations show that mismatches serve a critical role in genome packaging and provide new insights into how VACV “flip and flop” telomeres are arranged.     

Identification of temperature-sensitive mutants of vaccinia virus that are defective in conversion of concatemeric replicative intermediates to the mature linear DNA genome

Pulsed-field gel electrophoresis was used to screen temperature-sensitive mutants of vaccinia virus for the ability to convert replicated viral DNA into mature linear 185-kilobase hairpin-terminated genomes. Of 30 mutually noncomplementing mutants tested, 5 displayed a temperature-sensitive defect in the resolution of the telomere fusion configuration within concatemeric replicative intermediates, resulting in a failure to convert such intermediates to the linear monomeric genome. Adjacent genomic units in the concatemeric arrays generated in these mutants were arranged in both tandem and inverted orientations. The observation that four of the five mutants had a severe general defect in the synthesis of the late class of viral proteins suggests that at least one late protein is directly required to resolve the telomere fusion intermediate to hairpin termini. The identification of such telomere resolution proteins should be facilitated by genetic and molecular characterization of resolution-defective mutants, such as C63, in which late protein synthesis is not severely affected.     

The N-terminal domain of the Agrobacterium tumefaciens telomere resolvase,TelA, regulates its DNA cleavage and rejoining activities

Linear replicons can be found in a minority of prokaryotic organisms, including Borrelia species and Agrobacterium tumefaciens. The problem with replicating the lagging strand end of linear DNAs is circumvented in these organisms by the presence of covalently closed DNA hairpin telomeres at the DNA termini. Telomere resolvases are enzymes responsible for generating these hairpin telomeres from a dimeric replication intermediate through a two-step DNA cleavage and rejoining reaction referred to as telomere resolution. It was previously shown that the agrobacterial telomere resolvase, TelA, possesses ssDNA annealing activity in addition to telomere resolution activity. The annealing activity derives, chiefly, from the N-terminal domain. This domain is dispensable for telomere resolution. In this study, we used activity analyses of an N-terminal domain deletion mutant, domain add back experiments, and protein–protein interaction studies and we report that the N-terminal domain of TelA is involved in inhibitory interactions with the remainder of TelA that are relieved by the binding of divalent metal ions. We also found that the regulation of telomere resolution by the N-terminal domain of TelA extends to suppression of inappropriate enzymatic activity, including hairpin telomere fusion (reaction reversal) and recombination between replicated telomeres to form a Holliday junction.     

Molecular cloning of the terminal hairpin of vaccinia virus DNA as an imperfect palindrome in an Escherichia coli plasmid

The genome of vaccinia virus is a linear duplex molecule of approximately 185 kb with hairpins at each end that link the complementary strands. The hairpins, which exist in two forms that are inverted and complementary in sequence, were isolated as XbaI restriction fragments and converted to a linear intermolecular duplex structure by denaturation and reannealing. The latter was then stably cloned as a 142-bp imperfect palindrome in an Escherichia coli plasmid. The insert was excised from the plasmid and the palindrome was extended on both sides by ligating it to the adjacent vaccinia virus DNA segment. The resulting fragment was cloned as a 278-bp imperfect palindrome. Restriction endonuclease analysis and DNA sequencing indicated the absence of any deletions or rearrangements. After excision from the plasmid, the palindrome was converted by heating and rapid cooling to the original two hairpin forms. In this manner, large quantities of vaccinia virus telomeres may be obtained for physical and biochemical studies.     

Molecular cloning and sequence of the concatemer junction from vaccinia virus replicative DNA. Viral nuclease cleavage sites in cruciform structures

The concatemer junction from replicative forms of vaccinia virus DNA was cloned into plasmid vectors and shown to be a precise duplex copy of the viral terminal hairpin structure, with each strand corresponding to one of the alternative sequence isomers. The plasmids were relaxed circles with extruded cruciforms representing two copies of the vaccinia telomere hairpin structure. Head-to-head dimers containing two copies of the vaccinia virus concatemer junction were observed to contain only one set of stem-loop structures per molecule, suggesting that the initial formation of a small cruciform, and not branch migration, was the rate-limiting step in cruciform formation. The plasmids containing the concatemer junction were converted into nicked circular, linear and cross-linked linear molecules by a nuclease isolated from vaccinia virions. The region-specific cleavage near the border of the hairpin loop and the formation of DNA cross-links in some of the molecules is consistent with the nuclease acting as a nicking-closing enzyme that participates in the resolution of mature termini from replicative concatemer intermediates.     

Telomere resolution by Borrelia burgdorferi ResT through the collaborative efforts of tethered DNA binding domains

Borrelia burgdorferi, a causative agent of Lyme disease, has a highly unusual segmented genome composed of both circular molecules and linear DNA replicons terminated by covalently closed hairpin ends or telomeres. Replication intermediates of the linear molecules are processed into hairpin telomeres via the activity of ResT, a telomere resolvase. We report here the results of limited proteolysis and mass spectroscopy to identify two main structural domains in ResT, separated by a chymotrypsin cleavage site between residues 163 and 164 of the 449 amino acid protein. The two domains have been overexpressed and purified. DNA electrophoretic mobility shift assays revealed that the C-terminal domain (ResT(164-449)) displays sequence-specific DNA binding to the box 3,4,5 region of the telomere, while the N-terminal domain (ResT(1-163)) exhibits sequence-independent DNA binding activity. Further analysis by DNase I footprinting supports a model for telomere resolution in which the hairpin binding module of the N-terminal domain is delivered to the box 1,2 region of the telomere through its tethering to ResT(164-449). Conversely, ResT(1-164) may play an important regulatory role by modulating both sequence-specific DNA binding activity and catalysis by the C-terminal domain.     

ResT, a telomere resolvase encoded by the Lyme disease spirochete.

The genus Borrelia includes the causative agents of Lyme disease and relapsing fever. An unusual feature of these bacteria is a segmented genome consisting mostly of a number of linear DNA molecules with covalently closed hairpin ends or telomeres. In this study we show that the BBB03 locus encodes the B. burgdorferi telomere resolvase, ResT. The purified protein catalyzes telomere resolution in vitro through a unique reaction: breakage of two phosphodiester bonds in a single DNA duplex (one on each strand) and joining of each end with the opposite DNA strand to form covalently closed hairpin telomeres. Telomere resolution by ResT occurs through a two-step transesterification reaction involving the formation of a covalent protein-DNA intermediate at a position three nucleotides from the axis of symmetry in each strand of the substrate.     

Tumorigenic poxviruses: construction of the composite physical map of the Shope fibroma virus genome.

The sites for the restriction enzymes BamHI, Bg/I, HindIII, PstI, PvuII, and SstI on the linear DNA genome of Shope fibroma virus, a tumorigenic poxvirus of rabbits, have been determined by digestions of the cloned BamHI and HindIII restriction fragments and by hybridization of 32P-labeled cloned fragments to Southern blots of Shope fibroma virus DNA cleaved partially or completely with the various enzymes. The linear genome is shown to be 160 kilobases in length and to possess terminal inverted repeat sequences of between 12.2 and 12.5 kilobases extending inwards from the cross-linked DNA telomeres. The fine map of the Shope fibroma virus terminal inverted repeats has been constructed and shown to be distinctly different from that of members of the orthopoxvirus group, such as vaccinia, by the absence of detectable tandemly repeated sequences near the termini and by the lack of detectable sequence homology with vaccinia termini.     

The role of DNA-PKcs and artemis in opening viral DNA hairpin termini in various tissues in mice

A subset of cellular DNA hairpins at double-strand breaks is processed by DNA-dependent protein kinase catalytic subunit (DNA-PKcs)- and Artemis-associated endonuclease. DNA hairpin termini of adeno-associated virus (AAV) are processed by DNA repair machinery; however, how and what cellular factors are involved in the process remain elusive. Here, we show that DNA-PKcs and Artemis open AAV inverted terminal repeat (ITR) hairpin loops in a tissue-dependent manner. We investigated recombinant AAV (rAAV) genome metabolism in various tissues of DNA-PKcs- or Artemis-proficient or -deficient mice. In the absence of either factor, ITR hairpin opening was impaired, resulting in accumulation of double-stranded linear rAAV genomes capped with covalently closed hairpins at termini. The 5' end of 3-base hairpin loops of the ITR was the primary target for DNA-PKcs- and Artemis-mediated cleavage. In the muscle, heart, and kidney, DNA-PKcs- and Artemis-dependent hairpin opening constituted a significant pathway, while in the liver, undefined alternative pathways effectively processed hairpins. In addition, our study revealed a Holliday junction resolvase-like activity in the liver that cleaved T-shaped ITR hairpin shoulders by making nicks at diametrically opposed sites. Thus, our approach furthers our understanding of not only rAAV biology but also fundamental DNA repair systems in various tissues of living animals.     

DNA replication in the autonomous parvoviruses

Both ends of the linear single-stranded parvoviral DNA genome contain short palindromic sequences which form duplex hairpins containingcis-acting information required for replication and encapsidation. DNA synthesis is primed directly by the 3′ end, and genomes are replicated through multimeric duplex intermediates by unidirectional, leading-strand synthesis. Unit-length genomes are excised from these concatemers, and their telomeres replicated, by the viral NS1 protein, which introduces a single-strand nick into specific origin sequences, becoming covalently attached to the 5′ end at the nick and providing a 3′ hydroxyl which primes synthesis of a new copy of the telomere. Progeny DNA synthesis requires ongoing replication and is dependent upon packaging.     

Molecular genetic and biochemical characterization of the vaccinia virus I3 protein, the replicative single-stranded DNA binding protein

Vaccinia virus, the prototypic poxvirus, efficiently and faithfully replicates its ～200-kb DNA genome within the cytoplasm of infected cells. This intracellular localization dictates that vaccinia virus encodes most, if not all, of its own DNA replication machinery. Included in the repertoire of viral replication proteins is the I3 protein, which binds to single-stranded DNA (ssDNA) with great specificity and stability and has been presumed to be the replicative ssDNA binding protein (SSB). We substantiate here that I3 colocalizes with bromodeoxyuridine (BrdU)-labeled nascent viral genomes and that these genomes accumulate in cytoplasmic factories that are delimited by membranes derived from the endoplasmic reticulum. Moreover, we report on a structure/function analysis of I3 involving the isolation and characterization of 10 clustered charge-to-alanine mutants. These mutants were analyzed for their biochemical properties (self-interaction and DNA binding) and biological competence. Three of the mutant proteins, encoded by the I3 alleles I3-4, -5, and -7, were deficient in self-interaction and unable to support virus viability, strongly suggesting that the multimerization of I3 is biologically significant. Mutant I3-5 was also deficient in DNA binding. Additionally, we demonstrate that small interfering RNA (siRNA)-mediated depletion of I3 causes a significant decrease in the accumulation of progeny genomes and that this reduction diminishes the yield of infectious virus.     

Telomere resolution in the Lyme disease spirochete.

The genus Borrelia includes the causative agents of Lyme disease and relapsing fever. An unusual feature of these bacteria is a genome that includes linear DNA molecules with covalently closed hairpin ends referred to as telomeres. We have investigated the mechanism by which the hairpin telomeres are processed during replication. A synthetic 140 bp sequence having the predicted structure of a replicated telomere was shown to function as a viable substrate for telomere resolution in vivo, and was sufficient to convert a circular replicon to a linear form. Our results suggest that the final step in the replication of linear Borrelia replicons is a site-specific DNA breakage and reunion event to regenerate covalently closed hairpin ends. The telomere substrate described here will be valuable both for in vivo manipulation of linear DNA in Borrelia and for in vitro studies to identify and characterize the telomere resolvase.