In vitro resolution of adeno-associated virus DNA hairpin termini by wild-type Rep protein is inhibited by a dominant-negative mutant of rep.

An adeno-associated virus (AAV) genome with a Lys-to-His (K340H) mutation in the consensus nucleotide triphosphate binding site of the rep gene has a dominant-negative DNA replication phenotype in vivo. We expressed both wild-type (Rep78) and mutant (Rep78NTP) proteins in two helper-free expression systems consisting of either recombinant baculoviruses in insect cells or the human immunodeficiency virus type 1 long terminal repeat promoter in human 293 cell transient transfections. We analyzed nuclear extracts from both expression systems for the ability to complement uninfected HeLa cell cytoplasmic extracts in an in vitro terminal resolution assay in which a covalently closed AAV terminal hairpin structure is converted to an extended linear duplex. Although both Rep78 and Rep78NTP bound to AAV terminal hairpin DNA in vitro, Rep78 but not Rep78NTP complemented the terminal resolution assay. Furthermore, Rep78NTP was trans dominant for AAV terminal resolution in vitro. We propose that the dominant-negative replication phenotype of AAV genomes carrying the K340H mutation is mediated by mutant Rep proteins binding to the terminal repeat hairpin.     

A novel terminal resolution-like site in the adeno-associated virus type 2 genome.

The adeno-associated virus 2 (AAV) contains a single-stranded DNA genome of which the terminal 145 nucleotides are palindromic and form T-shaped hairpin structures. These inverted terminal repeats (ITRs) play an important role in AAV DNA replication and resolution, since each of the ITRs contains a terminal resolution site (trs) that is the target site for the AAV rep gene products (Rep). However, the Rep proteins also interact with the AAV DNA sequences that lie outside the ITRs, and the ITRs also play a crucial role in excision of the proviral genome from latently infected cells or from recombinant AAV plasmids. To distinguish between Rep-mediated excision of the viral genome during rescue from recombinant AAV plasmids and the Rep-mediated resolution of the ITRs during AAV DNA replication, we constructed recombinant AAV genomes that lacked either the left or the right ITR sequence and one of the Rep-binding sites (RBSs). No rescue and replication of the AAV genome occurred from these plasmids following transfection into adenovirus type 2-infected human KB cells, as expected. However, excision and abundant replication of the vector sequences was clearly detected from the plasmid that lacked the AAV left ITR, suggesting the existence of an additional putative excision site in the left end of the AAV genome. This site was precisely mapped to one of the AAV promoters at map unit 5 (AAV p5) that also contains an RBS. Furthermore, deletion of this RBS abolished the rescue and replication of the vector sequences. These studies suggest that the Rep-mediated cleavage at the RBS during viral DNA replication may, in part, account for the generation of the AAV defective interfering particles.     

Partial purification of adeno-associated virus Rep78, Rep52, and Rep40 and their biochemical characterization.

We have used differential cell extraction and conventional chromatography to separate and partially purify the four adeno-associated virus (AAV) nonstructural proteins Rep78, Rep68, Rep52, and Rep40. In the cytoplasmic extracts Rep52 and Rep40 were present in greater abundance than Rep68 and Rep78, with Rep78 being the least abundant. In nuclear extracts the four Rep proteins were approximately equal in abundance. Regardless of the subcellular fraction examined, three of the Rep proteins (Rep78, Rep68, and Rep40) consisted of two protein species with slightly different mobilities during polyacrylamide gel electrophoresis. In contrast, Rep52 consisted of only one protein species. Both Rep78 and Rep68 were capable of binding efficiently to AAV terminal hairpin DNA substrates, but we could not detect site-specific DNA binding by Rep52 and Rep40. Like Rep68, Rep78 had both an ATP-dependent trs endonuclease and a DNA helicase activity. Both Rep78 and Rep68 cut the terminal AAV sequence at the same site (nucleotide 124). The binding, trs endonuclease, and DNA helicase activities comigrated during sucrose density gradient centrifugation with a mobility expected for a monomer of the protein, suggesting that the three biochemical activities were intrinsic properties of the larger Rep proteins. The chromatographic behavior and the DNA-binding properties of the four Rep proteins identified at least two domains within the rep coding region, an exposed hydrophobic domain within the C-terminal end (amino acids 578 to 621) and a region within the N terminus (amino acids 1 to 214) which was necessary for binding to the terminal repeat sequence. No site-specific nuclease activity was seen in the presence of nucleotide analogs ATP-gamma-S or AMP-PNP, suggesting that ATP hydrolysis was required for the endonuclease reaction. Furthermore, although ATP was the only cofactor which would support the trs endonuclease activity of Rep78, Rep68 nuclease activity was seen in the presence of several other nucleotide cofactors, including CTP, GTP, and UTP.     

Herpes simplex virus co-infection facilitates rolling circle replication of the adeno-associated virus genome

Adeno-associated virus (AAV) genome replication only occurs in the presence of a co-infecting helper virus such as adenovirus type 5 (AdV5) or herpes simplex virus type 1 (HSV-1). AdV5-supported replication of the AAV genome has been described to occur in a strand-displacement rolling hairpin replication (RHR) mechanism initiated at the AAV 3’ inverted terminal repeat (ITR) end. It has been assumed that the same mechanism applies to HSV-1-supported AAV genome replication. Using Southern analysis and nanopore sequencing as a novel, high-throughput approach to study viral genome replication we demonstrate the formation of double-stranded head-to-tail concatemers of AAV genomes in the presence of HSV-1, thus providing evidence for an unequivocal rolling circle replication (RCR) mechanism. This stands in contrast to the textbook model of AAV genome replication when HSV-1 is the helper virus.     

Rescue of the adeno-associated virus genome from a plasmid vector: evidence for rescue by replication

In cultured cells, adeno-associated virus (AAV) replication requires coinfection with a helper virus, either adenovirus or herpesvirus. In the absence of helper virus coinfection AAV can integrate its genome site specifically into the AAVS1 region of chromosome 19. Upon subsequent infection with a helper virus, the AAV genome is released from chromosome 19 by a process termed rescue, and productive replication ensues. The AAV genome cloned into a plasmid vector can also serve to initiate productive AAV replication. When such constructs are transfected into cells and those cells are simultaneously or subsequently infected with a helper virus, the AAV genome is released from the plasmid. This process is thought to serve as a model for rescue from the human genomic site. In this report we present a model for rescue of AAV genomes by replication. A hallmark of this model is the production of a partially single-stranded and partially double-stranded molecule. We show that the AAV2 Rep 68 protein, together with the UL30/UL42 herpes simplex virus type 1 DNA polymerase and the UL29 single-strand DNA binding protein ICP8, is sufficient to efficiently and precisely rescue AAV from a plasmid in a way that is dependent on the AAV inverted terminal repeat sequence.     

Biologically active Rep proteins of adeno-associated virus type 2 produced as fusion proteins in Escherichia coli.

Four Rep proteins are encoded by the human parvovirus adeno-associated virus type 2 (AAV). The two largest proteins, Rep68 and Rep78, have been shown in vitro to perform several activities related to AAV DNA replication. The Rep78 and Rep68 proteins are likely to be involved in the targeted integration of the AAV DNA into human chromosome 19, and the full characterization of these proteins is important for exploiting this phenomenon for the use of AAV as a vector for gene therapy. To obtain sufficient quantities for facilitating the characterization of the biochemical properties of the Rep proteins, the AAV rep open reading frame was cloned and expressed in Escherichia coli as a fusion protein with maltose-binding protein (MBP). Recombinant MBP-Rep68 and MBP-Rep78 proteins displayed the following activities reported for wild-type Rep proteins when assayed in vitro: (i) binding to the AAV inverted terminal repeat (ITR), (ii) helicase activity, (iii) site-specific (terminal resolution site) endonuclease activity, (iv) binding to a sequence within the integration locus for AAV DNA on human chromosome 19, and (v) stimulation of radiolabeling of DNA containing the AAV ITR in a cell extract. These five activities have been described for wild-type Rep produced from mammalian cell extracts. Furthermore, we recharacterized the sequence requirements for Rep binding to the ITR and found that only the A and A' regions are necessary, not the hairpin form of the ITR.     

Adeno-associated virus (AAV) type 5 Rep protein cleaves a unique terminal resolution site compared with other AAV serotypes

Adeno-associated virus (AAV) replication depends on two viral components for replication: the AAV nonstructural proteins (Rep) in trans, and inverted terminal repeat (ITR) sequences in cis. AAV type 5 (AAV5) is a distinct virus compared to the other cloned AAV serotypes. Whereas the Rep proteins and ITRs of other serotypes are interchangeable and can be used to produce recombinant viral particles of a different serotype, AAV5 Rep proteins cannot cross-complement in the packaging of a genome with an AAV2 ITR. In vitro replication assays indicated that the block occurs at the level of replication instead of at viral assembly. AAV2 and AAV5 Rep binding activities demonstrate similar affinities for either an AAV2 or AAV5 ITR; however, comparison of terminal resolution site (TRS) endonuclease activities showed a difference in specificity for the two DNA sequences. AAV2 Rep78 cleaved only a type 2 ITR DNA sequence, and AAV5 Rep78 cleaved only a type 5 probe efficiently. Mapping of the AAV5 ITR TRS identified a distinct cleavage site (AGTG TGGC) which is absent from the ITRs of other AAV serotypes. Comparison of the TRSs in the AAV2 ITR, the AAV5 ITR, and the AAV chromosome 19 integration locus identified some conserved nucleotides downstream of the cleavage site but little homology upstream.     

Analysis of the Effects of Charge Cluster Mutations in Adeno-Associated Virus Rep68 Protein In Vitro

The Rep78 and Rep68 proteins of adeno-associated virus type 2 (AAV) are multifunctional proteins which are required for viral replication, regulation of AAV promoters, and preferential integration of the AAV genome into a region of human chromosome 19. These proteins bind the hairpin structures formed by the AAV inverted terminal repeat (ITR) origins of replication, make site- and strand-specific endonuclease cuts within the AAV ITRs, and display nucleoside triphosphate-dependent helicase activities. Additionally, several mutant Rep proteins display negative dominance in helicase and/or endonuclease assays when they are mixed with wild-type Rep78 or Rep68, suggesting that multimerization may be required for the helicase and endonuclease functions. Using overlap extension PCR mutagenesis, we introduced mutations within clusters of charged residues throughout the Rep68 moiety of a maltose binding protein-Rep68 fusion protein (MBP-Rep68Δ) expressed in Escherichia coli cells. Several mutations disrupted the endonuclease and helicase activities; however, only one amino-terminal-charge cluster mutant protein (D40A-D42A-D44A) completely lost AAV hairpin DNA binding activity. Charge cluster mutations within two other regions abolished both endonuclease and helicase activities. One region contains a predicted alpha-helical structure (amino acids 371 to 393), and the other contains a putative 3,4 heptad repeat (coiled-coil) structure (amino acids 441 to 483). The defects displayed by these mutant proteins correlated with a weaker association with wild-type Rep68 protein, as measured in coimmunoprecipitation assays. These experiments suggest that these regions of the Rep molecule are involved in Rep oligomerization events critical for both helicase and endonuclease activities.     

Factors that bind to adeno-associated virus terminal repeats.

We have identified and characterized a DNA-protein complex that forms with the adeno-associated virus (AAV) terminal repeats. The complex formed only if the terminal palindrome was in the covalently closed or hairpin configuration; little if any binding was detected with the open duplex form of the terminal repeat. This fact suggested that both secondary structure and primary sequence are essential elements of recognition. DNase I protection studies indicated that virtually all of the A-A' palindrome and significant portions of the B-B' and C-C' palindromes are protected. The postulated terminal resolution site of AAV also is protected. Restriction mapping of the sequences necessary for binding indicated that almost all of the terminal palindrome must be present for binding to occur. Hairpins which are similar in size and shape to the AAV termini did not exhibit competition for binding, and the complex formed only if AAV-infected extracts were used. Thus, the binding reaction is specific for AAV sequences. The viral-coded nonstructural proteins Rep78 and Rep68 comigrated with the DNA-protein complex on neutral acrylamide gels, suggesting that one or both of these proteins are components of the complex. The characteristics of the complex suggested that it has a role in AAV DNA replication.     

Recognition site of nuclear factor I, a sequence-specific DNA-binding protein from HeLa cells that stimulates adenovirus DNA replication.

Nuclear factor I is a 47-kd protein, isolated from nuclei of HeLa cells, that binds specifically to the inverted terminal repeat of the adenovirus (Ad) DNA and enhances Ad DNA replication in vitro. We have studied the DNA sequence specificity of nuclear factor I binding using cloned terminal fragments of the Ad2 genome and a set of deletion mutants. Binding of nuclear factor I protects nucleotides 19-42 of Ad2 DNA against DNase I digestion. Filter binding assays show that deletion of the first 23 nucleotides does not impair binding while a deletion of 24 nucleotides reduces binding severely. However, binding studies on Ad12 DNA indicate that nucleotide 24 can be mutated. Fragments containing the first 40 bp are bound normally while the first 38 bp are insufficient to sustain binding. Taken together, these results indicate that the minimal recognition site of nuclear factor I contains 15 or 16 nucleotides, located from nucleotide 25 to nucleotide 39 or 40 of the Ad2 DNA. This site contains two of the four conserved nucleotide sequences in this region. Sequences flanking the minimal recognition site may reduce the binding affinity of nuclear factor I. In accordance with these binding studies, DNA replication of a fragment that carries the sequence of the terminal 40 nucleotides of Ad2 at one molecular end is enhanced by nuclear factor I in an in vitro replication system.     

In vitro replication of adeno-associated virus DNA: enhancement by extracts from adenovirus-infected HeLa cells.

Previously we have described an in vitro assay for the replication of adeno-associated virus type 2 (AAV2) DNA. Addition of the AAV2 nonstructural protein Rep68 to an extract from uninfected cells supports the replication of linear duplex AAV DNA. In this report, we examine replication of linear duplex AAV DNA in extracts from either uninfected or adenovirus (Ad)-infected HeLa cells. The incorporation of radiolabeled nucleotides into full-length linear AAV DNA is 50-fold greater in extracts from Ad-infected cells than in extracts from uninfected cells. In addition, the majority of the labeled full-length AAV DNA molecules synthesized in the Ad-infected extract have two newly replicated strands, whereas the majority of labeled full-length AAV DNA molecules synthesized in the uninfected extract have only one newly replicated strand. The numbers of replication initiations on original templates in the two assays are approximately the same; however, replication in the case of the Ad-infected cell extract is much more likely to result in the synthesis of a full-length AAV DNA molecule. Most of the newly replicated molecules in the assay using uninfected cell extracts are in the form of stem-loop structures. We hypothesize that Ad infection provides a helper function related to elongation during replication by a single-strand displacement mechanism. In the assay using the uninfected HeLa cell extract, replication frequently stalls before reaching the end of the genome, causing the newly synthesized strand to be displaced from the template, with a consequent folding on itself and replication back through the inverted terminal repeat, using itself as a template. In support of this conjecture, replication in the uninfected cell extract of shorter substrate molecules is more efficient, as measured by incorporation of radiolabeled nucleotides into full-length substrate DNA. In addition, when shorter substrate molecules are used as the template in the uninfected HeLa cell assay, a greater proportion of the labeled full-length substrate molecules contain two newly replicated strands. Shorter substrate molecules have no replicative advantage over full-length substrate molecules in the assay using an extract from Ad-infected cells.     

Interaction of wild-type and mutant adeno-associated virus (AAV) Rep proteins on AAV hairpin DNA.

Both the Rep68 and Rep78 proteins of adeno-associated virus type 2 (AAV) bind to AAV terminal repeat hairpin DNA and can mediate site-specific nicking in vitro at the terminal resolution site (trs) within the terminal repeats. To define the regions of the Rep proteins required for these functions, a series of truncated Rep78 derivatives was created. Wild-type and mutant proteins were synthesized by in vitro translation and analyzed for AAV hairpin DNA binding, trs endonuclease activity, and interaction on hairpin DNA. Amino-terminal deletion mutants which lacked the first 29 or 79 amino acid residues of Rep78 did not bind hairpin DNA, which is consistent with our previous identification of a DNA-binding domain in this region. Progressive truncation of the carboxyl-terminal region of Rep78 did not eliminate hairpin DNA binding until the deletion reached amino acid 443. The electrophoretic mobility of the Rep-specific protein-DNA complexes was inversely related to the molecular weight of the Rep derivative. Analysis of the C-terminal deletion mutants by the trs endonuclease assay identified a region (amino acids 467 to 476) that is essential for nicking but is not necessary for DNA binding. When endonuclease-positive, truncated Rep proteins that bound hairpin DNA were mixed with full-length Rep78 or Rep68 protein in electrophoretic mobility shift assays, a smear of protein-DNA complexes was observed. This smear migrated at an intermediate position with respect to the bands generated by the proteins individually. An antibody recognizing only the full-length protein produced a novel supershift band when included in a mixed binding assay containing Rep68 and a truncated Rep mutant. These experiments suggest that the Rep proteins can form hetero-oligomers on the AAV hairpin DNA.     

In vitro rescue of an integrated hybrid adeno-associated virus/simian virus 40 genome.

In an in vitro simian virus 40 (SV40) DNA replication assay, we have observed excision of a hybrid adeno-associated virus (AAV)/SV40 insert from a plasmid construct. The excision was dependent on the presence of the palindromic AAV terminal repeat and greatly enhanced by the addition of the SV40 T antigen to the reaction. Analysis of the excision product supports a model in which the palindromic terminal sequences of AAV form a cruciform structure (equivalent to a Holliday recombination intermediate), which is cleaved and resealed so that the excision products are linear duplex pBR322 and linear duplex AAV/SV40 insert. Both the excised linear duplex pBR322 and the excised linear duplex AAV/SV40 insert have each terminus covalently crosslinked by one copy of the palindromic region of the AAV terminal repeat region folded on itself. The excision process may be a model system for cellular homologous recombination. The process as observed was either concomitant with or subsequent to DNA replication.     

Evidence for two nucleotide sequence orientations within the terminal repetition of adeno-associated virus DNA.

Duplex adeno-associated virus (AAV) DNA, produced by annealing plus and minus virion single strands, has been digested with several bacterial restriction endonucleases. These studies reveal the existence of alternate secondary structures at the termini of duplex AAV DNA. Analysis of the sites of endo R-Hpa II cleavage, the products of complete endo R-Hpa II digestion, and the multiple terminal secondary structures leads to the conclusion that there are two possible nucleotide sequences at each end of AAV DNA. A model that attributes the terminal nucleotide sequence heterogeneity to two possible orientations of the first 120 nucleotides at each end of the DNA is proposed; in one case the sequence is 1 to 120; in the other case the sequence is inverted. An origin of the inversion is suggested based on previously described intermediates in AAV DNA replication.     

Sequence and hairpin structure of an inverted repeat series at termini of the Physarum extrachromosomal rDNA molecule

The termini of the 61 kb palindromic rDNA molecules of Physarum polycephalum possess a series of multiple inverted repeats in which are located specific single-strand gaps and tightly attached protein. After treating rDNA with S1 nuclease, we have cloned several 5 kb Eco RI terminal restriction fragments. Sequencing of more than 800 nucleotides from the end of one such clone reveals the presence of six to ten tandemly repeated units averaging 140 +/- 4 bp in length and flanked by Hae III sites. Each 140 nucleotide repeat unit can form thermodynamically stable hairpin structures based on complex internal palindromic components. When the specific gap sequence CCCTA is present, it is located near the apex of a hairpin component. These secondary structures are formed in growing plasmodia, as seen in electron micrographs of native rDNA molecules, which also reveal apparent recombination forms involving rDNA ends and noncontiguous DNA segments. Recombination initiated at terminal single-strand hairpin loops can result in genetic exchange of ribosomal gene sequences and can lead to completion of 5' nucleotide sequences at ends of newly replicated rDNA molecules.     

Integration of the adeno-associated virus genome into cellular DNA in latently infected human Detroit 6 cells.

A clone of human cells (Detroit 6) latently infected by adeno-associated virus (AAV) has been characterized with regard to the status of the viral DNA. In both early (9 to 10) and late (118) passages of the clone, AAV-DNA was recombined with host DNA, at least in some cases as a head-to-tail tandem repeat, via the terminal sequences of the viral genome. However, it was not possible to distinguish between integration into chromosomal DNA and very large plasmids (< 20 x 10(6) molecular weight) which contain both viral and cellular DNA sequences. Although evidence for some modifications of the viral sequence was obtained, most of the integrated sequences appeared to be intact. In some cases sequences of undetermined origin separated adjacent copies of the viral genome. Free copies of the AAV genome were detectable in late passage cells, but not in early passage cells. The orientation of nucleotide sequences present in the free AAV DNA from late passage cells was indistinguishable from that of virion DNA. With the notable exception, the organization of the integrated AAV sequences as determined by restriction enzyme digestion remained constant with continued passage. Digestion with SmaI, which cleaves within the palindromic region of the terminal repetition in AAV DNA, produced reproducibly different patterns when early and late passage DNAs were compared. Several models for rescue of free copies of the genome from the integrated DNA are possible, all of which involve the terminal repetition.     

Characterization of Wild-Type Adeno-Associated Virus Type 2-Like Particles Generated during Recombinant Viral Vector Production and Strategies for Their Elimination

The pSub201-pAAV/Ad plasmid cotransfection system was developed to eliminate homologous recombination which leads to generation of the wild-type (wt) adeno-associated virus type 2 (AAV) during recombinant vector production. The extent of contamination with wt AAV has been documented to range between 0.01 and 10%. However, the precise mechanism of generation of the contaminating wt AAV remains unclear. To characterize the wt AAV genomes, recombinant viral stocks were used to infect human 293 cells in the presence of adenovirus. Southern blot analyses of viral replicative DNA intermediates revealed that the contaminating AAV genomes were not authentic wt but rather wt AAV-like sequences derived from recombination between (i) AAV inverted terminal repeats (ITRs) in the recombinant plasmid and (ii) AAV sequences in the helper plasmid. Replicative AAV DNA fragments, isolated following amplification through four successive rounds of amplification in adenovirus-infected 293 cells, were molecularly cloned and subjected to nucleotide sequencing to identify the recombinant junctions. Following sequence analyses of 31 different ends of AAV-like genomes derived from two different recombinant vector stocks, we observed that all recombination events involved 10 nucleotides in the AAV D sequence distal to viral hairpin structures. We have recently documented that the first 10 nucleotides in the D sequence proximal to the AAV hairpin structures are essential for successful replication and encapsidation of the viral genome (X.-S. Wang et al., J. Virol. 71:3077–3082, 1997), and it was noteworthy that in each recombinant junction sequenced, the same 10 nucleotides were retained. We also observed that adenovirus ITRs in the helper plasmid were involved in illegitimate recombination with AAV ITRs, deletions of which significantly reduced the extent of wt AAV-like particles. Furthermore, the combined use of recombinant AAV plasmids lacking the distal 10 nucleotides in the D sequence and helper plasmids lacking the adenovirus ITRs led to complete elimination of replication-competent wt AAV-like particles in recombinant vector stocks. These strategies should be useful in producing clinical-grade AAV vectors suitable for human gene therapy.