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.     

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.     

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.     

Charged-to-alanine scanning mutagenesis of the N-terminal half of adeno-associated virus type 2 Rep78 protein

The adeno-associated virus (AAV) Rep78 and Rep68 proteins are required for site-specific integration of the AAV genome into the AAVS1 locus (19q13.3-qter) as well as for viral DNA replication. Rep78 and Rep68 bind to the GAGC motif on the inverted terminal repeat (ITR) and cut at the trs (terminal resolution site). A similar reaction is believed to occur in AAVS1 harboring an analogous GAGC motif and a trs homolog, followed by integration of the AAV genome. To elucidate the functional domains of Rep proteins at the amino acid level, we performed charged-to-alanine scanning mutagenesis of the N terminus (residues 1 to 240) of Rep78, where DNA binding and nicking domains are thought to exist. Mutants were analyzed for their abilities to bind the GAGC motif, nick at the trs homolog, and integrate an ITR-containing plasmid into AAVS1 by electrophoretic mobility shift assay, trs endonuclease assay, and PCR-based integration assay. We identified the residues responsible for DNA binding: R107A, K136A, and R138A mutations completely abolished the binding activity. The H90A or H92A mutant, carrying a mutation in a putative metal binding site, lost nicking activity while retaining binding activity. Mutations affecting DNA binding or trs nicking also impaired the site-specific integration, except for E66A and E239A. These results provide important information on the structure-function relationship of Rep proteins. We also describe an aberrant nicking of Rep78. We found that Rep78 cuts predominantly at the trs homolog not only between the T residues (GGT/TGG), but also between the G and T residues (GG/TTGG), which may be influenced by the sequence surrounding the GAGC motif.     

Mutational analysis of the adeno-associated virus Rep68 protein: identification of critical residues necessary for site-specific endonuclease activity.

The Rep68 and Rep78 proteins of adeno-associated virus type 2 (AAV) are multifunctional proteins which contain overlapping amino acid sequences. They are required for viral replication and preferential integration of the AAV genome into a region of human chromosome 19. During the terminal resolution process of AAV DNA replication, these proteins make a site-specific and strand-specific endonuclease cut within the AAV inverted terminal repeat DNA. The Rep68 and Rep78 proteins also have helicase and DNA-binding activities. The endonuclease activity is believed to involve the covalent attachment of Rep68 or Rep78 at the cut site via a phosphotyrosine linkage. In an attempt to identify the active-site tyrosine residue of Rep78 and Rep68, tyrosine residues were site specifically mutated to phenylalanines by overlap extension PCR, and the resulting PCR fragments were cloned into a maltose binding protein-Rep68 fusion (MBP-Rep68delta) expression vector. The mutant MBP-Rep68delta proteins were expressed in Escherichia coli cells, purified with amylose resin, and assayed in vitro for Rep68-specific activities. Although several of the mutations disrupted the endonuclease activity, only the mutation of tyrosine 152 abrogated the endonuclease activity with no discernible effect on the helicase or DNA-binding activities. Our data therefore suggest that there are distinct active sites for the helicase and endonuclease activities.     

Analysis of the terminal repeat binding abilities of mutant adeno-associated virus replication proteins.

The adeno-associated virus (AAV) Rep78 and Rep68 proteins play essential roles in viral DNA replication, trans activation of viral gene expression, and suppression of oncogene-mediated cellular transformation. By using an extensive set of linker insertion and deletion mutations in the replication gene, we mapped the regions of the Rep78 protein that mediate binding to the AAV origin of replication in vitro. Deletions that removed amino acid codons 25 to 62, 88 to 113, 125 to 256, and 346 to 400 abolished binding. Alterations in several other regions of the protein affected the binding affinity of the mutant proteins. All of the mutant proteins that support AAV DNA replication or p40 trans activation bound to the terminal repeat sequence, thus verifying the importance of binding for these functions. Several mutant rep genes that failed to suppress oncogene-mediated cellular transformation produced proteins that were capable of binding to the AAV terminal repeat sequences.     

Mutational analysis of adeno-associated virus type 2 Rep68 protein endonuclease activity on partially single-stranded substrates

The endonuclease activity of the Rep68 and Rep78 proteins (Rep68/78) of adeno-associated virus type 2 (AAV) cuts at the terminal resolution site (trs) within the hairpin structure formed by the AAV inverted terminal repeats. Recent studies suggest that a DNA unwinding function of Rep68/78 may be required for endonuclease activity. We demonstrate that several mutant proteins which are endonuclease negative on a fully duplex hairpin substrate are endonuclease positive on a partially single-stranded hairpin substrate. Truncation analysis revealed that the endonuclease function is contained within the first 200 amino acids of Rep68/78. This endonucleolytic cleavage is believed to involve the covalent attachment of Rep68/78 to the trs via a phosphate-tyrosine linkage. A previous report (S. L. Walker, R. S. Wonderling, and R. A. Owens, J. Virol. 71:2722-2730, 1997) suggested that tyrosine 152 was part of the active site. We individually mutated each tyrosine within the first 200 amino acids of the Rep68 moiety of a maltose binding protein-Rep68/78 fusion protein to phenylalanine. Only mutation of tyrosine 156 resulted in a protein incapable of covalent attachment to a partially single-stranded hairpin substrate, suggesting that tyrosine 156 is part of the endonuclease active site.     

Features of the adeno-associated virus origin involved in substrate recognition by the viral Rep protein.

We previously demonstrated that the adeno-associated virus (AAV) Rep68 and Rep78 proteins are able to nick the AAV origin of DNA replication at the terminal resolution site (trs) in an ATP-dependent manner. Using four types of modified or mutant substrates, we now have investigated the substrate requirements of Rep68 in the trs endonuclease reaction. In the first kind of substrate, portions of the hairpinned AAV terminal repeat were deleted. Only deletions that retained virtually all of the small internal palindromes of the AAV terminal repeat were active in the endonuclease reaction. This result confirmed previous genetic and biochemical evidence that the secondary structure of the terminal repeat was an important feature for substrate recognition. In the second type of substrate, the trs was moved eight bases further away from the end of the genome. The mutant was nicked at a 50-fold-lower frequency relative to a wild-type origin, and the nick occurred at the correct trs sequence despite its new position. This finding indicated that the endonuclease reaction required a specific sequence at the trs in addition to the correct secondary structure. It also suggested that the minimum trs recognition sequence extended three bases from the cut site in the 3' direction. The third type of substrate harbored mismatched base pairs at the trs. The mismatch substrates contained a wild-type sequence on the strand normally cut but an incorrect sequence on the complementary strand. All of the mismatch mutants were capable of being nicked in the presence of ATP. However, there was substantial variation in the level of activity, suggesting that the sequence on the opposite strand may also be recognized during nicking. Analysis of the mismatch mutants also suggested that a single-stranded trs was a viable substrate for the enzyme. This interpretation was confirmed by analysis of the fourth type of substrate tested, which contained a single-stranded trs. This substrate was also cleaved efficiently by the enzyme provided that the correct strand was present in the substrate. In addition, the single-stranded substrate no longer required ATP as a cofactor for nicking. Finally, all of the substrates with mutant trss bound the Rep protein as efficiently as the wild-type did. This finding indicated that the sequence at the cut site was not involved in recognition of the terminal repeat for specific binding by the enzyme. We concluded that substrate recognition by the AAV Rep protein involves at least two and possibly as many as four features of the AAV terminal repeat.(ABSTRACT TRUNCATED AT 400 WORDS)     

Mechanism of Rep-mediated adeno-associated virus origin nicking

The single-stranded adeno-associated virus type 2 (AAV) genome is flanked by terminal repeats (TRs) that fold back on themselves to form hairpinned structures. During AAV DNA replication, the TRs are nicked by the virus-encoded Rep proteins at the terminal resolution site (trs). This origin function apparently requires three sequence elements, the Rep binding element (RBE), a small palindrome that comprises a single tip of an internal hairpin within the TR (RBE'), and the trs. Previously, we determined the sequences at the trs required for Rep-mediated cleavage and demonstrated that the trs endonuclease reaction occurs in two discrete steps. In the first step, the Rep DNA helicase activity unwinds the TR, thereby extruding a stem-loop structure at the trs. In the second step, Rep transesterification activity cleaves the trs. Here we investigate the contribution of the RBE and RBE' during this process. Our data indicate that Rep is tethered to the RBE in a specific orientation during trs nicking. This orientation appears to align Rep on the AAV TR, allowing specific nucleotide contacts with the RBE' and directing nicking to the trs. Accordingly, alterations in the polarity or position of the RBE relative to the trs greatly inhibit Rep nicking. Substitutions within the RBE' also reduce Rep specific activity, but to a lesser extent. Interestingly, Rep interactions with the RBE and RBE' during nicking seem to be functionally distinct. Rep contacts with the RBE appear necessary for both the DNA helicase and trs cleavage steps of the endonuclease reaction. On the other hand, RBE' contacts seem to be required primarily for TR unwinding and formation of the trs stem-loop structure, not cleavage. Together, these results suggest a model of Rep interaction with the AAV TR during origin nicking through a tripartite cleavage signal comprised of the RBE, the RBE', and the trs.     

DNA-binding activity of adeno-associated virus Rep is required for inverted terminal repeat-dependent complex formation with herpes simplex virus ICP8

Herpes simplex virus (HSV) helper functions for (AAV) replication comprise HSV ICP8 and helicase-primase UL5/UL52/UL8. Here we show that N-terminal amino acids of AAV Rep78 that contact the Rep-binding site within the AAV inverted terminal repeat (ITR) are required for ternary-complex formation with infected-cell protein 8 (ICP8) on AAV single-strand DNA (ssDNA) in vitro and for colocalization in nuclear replication domains in vivo. Our data suggest that HSV-dependent AAV replication is initiated by Rep contacting the AAV ITR and by cooperative binding of ICP8 on AAV ssDNA.     

Charge-to-Alanine Mutagenesis of the Adeno-Associated Virus Type 2 Rep78/68 Proteins Yields Temperature-Sensitive and Magnesium-Dependent Variants

The adeno-associated virus type 2 (AAV) replication (Rep) proteins Rep78 and 68 (Rep78/68) exhibit a number of biochemical activities required for AAV replication, including specific binding to a 22-bp region of the terminal repeat, site-specific endonuclease activity, and helicase activity. Individual and clusters of charged amino acids were converted to alanines in an effort to generate a collection of conditionally defective Rep78/68 proteins. Rep78 variants were expressed in human 293 cells and analyzed for their ability to mediate replication of recombinant AAV vectors at various temperatures. The biochemical activities of Rep variants were further characterized in vitro by using Rep68 His-tagged proteins purified from bacteria. The results of these analyses identified a temperature-sensitive (ts) Rep protein (D40,42,44A-78) that exhibited a delayed replication phenotype at 32 degrees C, which exceeded wild-type activity by 48 h. Replication activity was reduced by more than threefold at 37 degrees C and was undetectable at 39 degrees C. Stability of the Rep78 protein paralleled replication levels at each temperature, further supporting a ts phenotype. Replication differences resulted in a 3-log-unit difference in virus yields between the permissive and nonpermissive temperatures (2.2 x 10(6) and 3 x 10(3), respectively), demonstrating that this is a relatively tight mutant. In addition to the ts Rep mutant, we identified a nonconditional mutant with a reduced ability to support viral replication in vivo. Additional characterization of this mutant demonstrated an Mg(2+)-dependent phenotype that was specific to Rep endonuclease activity and did not affect helicase activity. The two mutants described here are unique, in that Rep ts mutants have not previously been described and the D412A Rep mutant represents the first mutant in which the helicase and endonuclease functions can be distinguished biochemically. Further understanding of these mutants should facilitate our understanding of AAV replication and integration, as well as provide novel strategies for production of viral vectors.     

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.     

Factors Affecting the Terminal Resolution Site Endonuclease, Helicase, and ATPase Activities of Adeno-Associated Virus Type 2 Rep Proteins

The Rep68 and Rep78 proteins (Rep68/78) of adeno-associated virus type 2 (AAV) are critical for AAV replication and site-specific integration. They bind specifically to the AAV inverted terminal repeats (ITRs) and possess ATPase, helicase, and strand-specific/site-specific endonuclease activities. In the present study, we further characterized the AAV Rep68/78 helicase, ATPase, and endonuclease activities by using a maltose binding protein-Rep68 fusion (MBP-Rep68Delta) produced in Escherichia coli cells and Rep78 produced in vitro in a rabbit reticulocyte lysate system. We found that the minimal length of single-stranded DNA capable of stimulating the ATPase activity of MBP-Rep68Delta is 100 to 200 bases. The degree of stimulation correlated positively with the length of single-stranded DNA added to the reaction mixture. We then determined the ATP concentration needed for optimal MBP-Rep68Delta helicase activity and showed that the helicase is active over a wide range of ATP concentrations. We determined the directionality of MBP-Rep68Delta helicase activity and found that it appears to move in a 3' to 5' direction, which is consistent with a model in which AAV Rep68/78 participates in AAV DNA replication by unwinding DNA ahead of a cellular DNA polymerase. In this report, we also demonstrate that single-stranded DNA is capable of inhibiting the MBP-Rep68Delta or Rep78 endonuclease activity greater than 10-fold. In addition, we show that removal of the secondary Rep68/78 binding site, which is found only in the hairpin form of the AAV ITR, causes a three- to eightfold reduction in the ability of the ITR to be used as a substrate for the Rep78 or MBP-Rep68Delta endonuclease activity. This suggests that contact between Rep68/78 and this secondary element may play an important role in the Rep-mediated endonuclease activity.     

The nuclease domain of adeno-associated virus rep coordinates replication initiation using two distinct DNA recognition interfaces

Integration into a particular location in human chromosomes is a unique property of the adeno-associated virus (AAV). This reaction requires the viral Rep protein and AAV origin sequences. To understand how Rep recognizes DNA, we have determined the structures of the Rep endonuclease domain separately complexed with two DNA substrates: the Rep binding site within the viral inverted terminal repeat and one of the terminal hairpin arms. At the Rep binding site, five Rep monomers bind five tetranucleotide direct repeats; each repeat is recognized by two Rep monomers from opposing faces of the DNA. Stem-loop binding involves a protein interface on the opposite side of the molecule from the active site where ssDNA is cleaved. Rep therefore has three distinct binding sites within its endonuclease domain for its different DNA substrates. Use of these different interfaces generates the structural asymmetry necessary to regulate later events in viral replication and integration.     

The AAV origin binding protein Rep68 is an ATP-dependent site-specific endonuclease with DNA helicase activity

Genetic studies of adeno-associated virus (AAV) indicate that two AAV genes are required for viral DNA replication: the palindromic terminal repeat, which is the origin for DNA replication, and the rep gene, which codes for a family of at least four viral nonstructural proteins. To determine the biochemical function of the Rep proteins, we have purified the AAV Rep68 protein to apparent homogeneity. We find that it contains a site-specific and strand-specific endonuclease activity that specifically cuts the AAV origin at the terminal resolution site (TRS). The TRS endonuclease requires the presence of ATP for activity and becomes covalently attached to the 5' end at the cut site. In addition to the specific endonuclease activity, Rep68 also contains a DNA helicase activity. These results demonstrate that the large AAV Rep proteins have a direct role in AAV DNA replication; namely, they provide the activities required for the resolution of covalently joined AAV termini.     

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.     

Activation of the ATPase activity of adeno-associated virus Rep68 and Rep78

Rep68 and Rep78 DNA helicases, encoded by adeno-associated virus 2 (AAV2), are required for replication of AAV viral DNA in infected cells. They bind to imperfect palindromic elements in the inverted terminal repeat structures at the 3'- and 5'-ends of virion DNA. The ATPase activity of Rep68 and Rep78 is stimulated up to 10-fold by DNA containing the target sequence derived from the inverted terminal repeat; nontarget DNA stimulates ATPase activity at 50-fold higher concentrations. Activation of ATPase activity of Rep68 by DNA is cooperative with a Hill coefficient of 1.8 +/- 0.2. When examined by gel filtration at 0.5 M NaCl in the absence of DNA, Rep68 self-associates in a concentration-dependent manner. In the presence of DNA containing the binding element, Rep68 (and Rep78) forms protein-DNA complexes that exhibit concentration-dependent self-association in gel filtration analysis. The ATPase activity of the isolated Rep68-DNA and Rep78-DNA complexes is not activated by additional target DNA. Results of sedimentation velocity experiments in the presence of saturating target DNA are consistent with Rep68 forming a hexamer of the protein with two copies of the DNA element. Activation of the ATPase activity of Rep68 is associated with the formation of a protein-DNA oligomer.     

Selective cleavage of AAVS1 substrates by the adeno-associated virus type 2 rep68 protein is dependent on topological and sequence constraints

The adeno-associated virus type 2 (AAV-2) Rep78 and Rep68 proteins are required for replication of the virus as well as its site-specific integration into a unique site, called AAVS1, of human chromosome 19. Rep78 and Rep68 initiate replication by binding to a Rep binding site (RBS) contained in the AAV-2 inverted terminal repeats (ITRs) and then specifically nicking at a nearby site called the terminal resolution site (trs). Similarly, Rep78 and Rep68 are postulated to trigger the integration process by binding and nicking RBS and trs homologues present in AAVS1. However, Rep78 and Rep68 cleave in vitro AAVS1 duplex-linear substrates much less efficiently than hairpinned ITRs. In this study, we show that the AAV-2 Rep68 endonuclease activity is affected by the topology of the substrates in that it efficiently cleaves in vitro in a site- and strand-specific manner the AAVS1 trs only if this sequence is in a supercoiled (SC) conformation. DNA sequence mutagenesis in the context of SC templates allowed us to elucidate for the first time the AAVS1 trs sequence and position requirements for Rep68-mediated cleavage. Interestingly, Rep68 did not cleave SC templates containing RBS from other sites of the human genome. These findings have intriguing implications for AAV-2 site-specific integration in vivo.     

Identification of active site residues of the adeno-associated virus type 2 Rep endonuclease

Adeno-associated virus type 2 Rep endonuclease activity is necessary for both viral DNA replication and site-specific integration of the viral genome into human chromosome 19. The biochemical activities required for site-specific endonuclease activity (namely specific DNA binding and transesterification activity) have been mapped to the amino-terminal domain of the AAV2 Rep protein. The amino-terminal 208 amino acids are alone sufficient for site-specific endonuclease activity, and nicking by this domain is metal-dependent. To identify this metal-binding site, we have employed a cysteine mutagenesis approach that targets conserved acidic amino acids. By using this technique, we provide functional biochemical data supporting a role for glutamate 83 in the coordination of metal ions in the context of Rep endonuclease activity. In addition, our biochemical data suggest that glutamate 164, although not involved in the coordination of metal ions, is closely associated with the active site. Thus, in lieu of a crystal structure for the AAV type 2 amino-terminal domain, our data corroborate the recently published structural studies of the AAV type 5 endonuclease and suggest that although the two enzymes are not highly conserved with respect to the AAV family, their active sites are highly conserved.     

Rep-Mediated Nicking of the Adeno-Associated Virus Origin Requires Two Biochemical Activities, DNA Helicase Activity and Transesterification

The single-stranded adeno-associated virus (AAV) genome is flanked by terminal hairpinned origins of DNA replication (terminal repeats [TRs]) that are nicked at the terminal resolution site (trs) by the AAV Rep protein in an ATP-dependent, site-specific manner. Here we determine the minimal trs sequence necessary for Rep cleavage, 3'-CCGGT/TG-5', and show that this 7-base core sequence is required only on the nicked strand. We also identify a potential stem-loop structure at the trs. Interestingly, Rep nicking on a TR substrate that fixes this trs stem-loop in the extruded form no longer requires ATP. This suggests that ATP-dependent Rep helicase activity is necessary to unwind the duplex trs and extrude the stem-loop structure, prior to the ATP-independent Rep transesterification reaction. The extrusion of origin stem-loop structures prior to nicking appears to be a general mechanism shared by plant and animal viruses and bacterial plasmids. In the case of AAV, this mechanism of TR nicking would provide a possible regulatory function.