Mechanism of Rep-Mediated Adeno-Associated Virus Origin Nicking

doi:10.1128/JVI.74.17.7762-7771.2000

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Journal of Virology, September 2000, p. 7762-7771, Vol. 74, No. 17
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

Mechanism of Rep-Mediated Adeno-Associated Virus Origin Nicking

J. Rodney Brister and Nicholas Muzyczka^*

Department of Molecular Genetics and Microbiology and Powell Gene Therapy Center, College of Medicine, University of Florida, Gainesville, Florida 32610

Received 18 January 2000/Accepted 7 June 2000

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

The single-stranded adeno-associated virus type 2 (AAV) genome is flanked by terminal repeats (TRs) that fold back on themselvesto form hairpinned structures. During AAV DNA replication, theTRs are nicked by the virus-encoded Rep proteins at the terminalresolution site (trs). This origin function apparently requiresthree sequence elements, the Rep binding element (RBE), a smallpalindrome that comprises a single tip of an internal hairpinwithin the TR (RBE'), and the trs. Previously, we determined thesequences at the trs required for Rep-mediated cleavage and demonstratedthat 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 secondstep, Rep transesterification activity cleaves the trs. Here weinvestigate the contribution of the RBE and RBE' during this process.Our data indicate that Rep is tethered to the RBE in a specificorientation during trs nicking. This orientation appears to alignRep on the AAV TR, allowing specific nucleotide contacts withthe RBE' and directing nicking to the trs. Accordingly, alterationsin the polarity or position of the RBE relative to the trs greatlyinhibit Rep nicking. Substitutions within the RBE' also reduceRep specific activity, but to a lesser extent. Interestingly,Rep interactions with the RBE and RBE' during nicking seem tobe functionally distinct. Rep contacts with the RBE appear necessaryfor both the DNA helicase and trs cleavage steps of the endonucleasereaction. On the other hand, RBE' contacts seem to be requiredprimarily for TR unwinding and formation of the trs stem-loopstructure, not cleavage. Together, these results suggest a modelof Rep interaction with the AAV TR during origin nicking througha tripartite cleavage signal comprised of the RBE, the RBE', andthe trs.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

The single-stranded DNA, adeno-associated virus (AAV) genome is flanked by terminal repeats (TRs). Internal palindromes alloweach TR to fold back on itself, forming terminal hairpinned structuresthat function as origins for AAV DNA replication, as well as integrationand packaging signals (12, 21, 28). During infection, synthesisof the AAV genome is initiated by an unidentified host cell DNApolymerase using the 3'-hydroxyl primer of the hairpinned TR.This second-strand synthesis results in the replication of internalgenes, allowing production of viral proteins (Fig. 1). Yet, continuedAAV DNA synthesis requires the introduction of a site-specific,single-stranded nick into the TRs by the virus-encoded, nonstructuralRep proteins, Rep78 and Rep68 (14, 22, 33, 35). In ourcurrent model of AAV DNA replication, Rep origin nicking and subsequentRep-mediated unwinding of the TR generate a 3'-hydroxyl primerfor repair synthesis of the TR. During this process of terminalresolution, Rep induces a single-stranded nick at the terminalresolution site (trs), forming a 5'-phosphotyrosyl linkage betweenRep and the nicking site (Fig. 1) (14, 31, 33). Currentevidence suggests that this Rep origin nicking activity requiresthree functional elements within the AAV TR, the canonical Repbinding element (RBE), a portion of the small internal palindromeswithin the terminal hairpin (RBE'), and the trs (see Fig. 2A)(8, 19, 20, 27, 32, 36). The secondary structureof the internal palindromes may also play a role (17).

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FIG. 1. Model of AAV DNA replication. The boxed region illustrates the steps involved in the terminal resolution of AAV viral ends. In vitro, Rep68 is necessary and sufficient for both the site-specific endonuclease and helicase activities required for terminal resolution. The viral 3' end is indicated with an arrow. Circles depict Rep covalently attached to the viral 5' end at the terminal resolution site (trs).

Previously, we identified the core trs sequence necessary for efficient Rep-catalyzed nicking, 3'-CCGGT/TG-5' (6). Thiscore sequence is strand specific in that it is required only onthe nicked strand. Interestingly, the sequences flanking the trscontain an inverted repeat conserved among various AAV serotypes(6). Similar to rolling circle origins of DNA replication (23,24), these inverted repeats appear to form a nicking site stem-loopstructure. In the case of AAV, extrusion of this structure requiresATP-dependent, Rep helicase activity, but once this structureis formed, the actual endonuclease reaction is not dependent onATP (6). Since the nicking site is within the single-strandedregion of this origin stem-loop, it appears that the nicking intermediateis a single-stranded trs (6).

In addition to a specific sequence and structure at the trs, efficient Rep nicking requires two additional sequence recognitionelements within the AAV TR, the RBE and RBE'. Mutational analysishas identified a core 22-bp sequence required for stable Rep bindingto linear TR substrates (27). This RBE includes the tetramericGAGC repeat identified by several groups as necessary for stableRep binding to both linear and hairpinned TR substrates (4,8, 19, 20, 32, 36). Moreover, chemical interferenceassays indicate that all major Rep contacts within the linearportion of the hairpinned TR fall within the RBE (1, 25,27). Thus, the 22-bp RBE appears to be the primary sequenceelement promoting Rep binding to the AAV TR. Homologues of thisRBE are present at the AAV p5 promoter, the preferential proviralintegration site on human chromosome 19, and within several viraland cellular promoters (3, 13, 15, 16, 18, 26, 36-38).

Although the contribution of the RBE to Rep-catalyzed trs nicking has not been determined, mutant AAV genomes containing multipletransversions in the RBE replicate at much lower levels than dowild-type (wt) genomes (4). This observation has led to theconclusion that stable Rep binding to the AAV TR is necessaryfor efficient origin nicking and subsequent viral replication.There is one report of a Rep mutant that fails to bind the AAVTR and yet nicks TR substrates in vitro, albeit at lower levelsthan those of the wt. However, this Rep mutant does not cleavethese substrates at the trs but 11 or 12 nucleotides downstreamof the correct nicking site (2). Thus, our current model predictsthat the RBE establishes the polarity of Rep interaction withthe AAV TR, correctly aligning Rep over the trs, culminating innicking of the correct strand at the correct site. This alignmentover the trs is thought to be quite precise since the correctstrand of the trs is nicked even when both strands contain thesame sequence (32).

Rep interaction with the AAV TR is enhanced by sequences within the internal palindromes of the terminal hairpin. Rep bindsthe complete TR with 125- to 170-fold-greater affinity than linearTR substrates lacking the internal palindromes (20, 27). Moreover,Rep trs nicking on similar linear TR substrates is reduced 4-to 50-fold compared to hairpinned TR substrates (7, 19, 34,39). Previously, it was thought that Rep made no specific contactswith the terminal hairpin, but recently, Ryan et al. (27) identifiedRep sequence contacts with the CTTTG motif at one tip of the secondarystructure element. Curiously, this short sequence, referred tohere as the RBE', has a constant position with respect to thetrs regardless of the orientation of the TR (flip or flop). Deletionof the RBE' and adjacent sequences reduces both Rep nicking invitro and viral DNA replication in vivo (5, 32, 39).

Though many functions have been attributed to the interaction of Rep with the AAV TRs, the mechanics and architecture of thisinteraction remain undetermined. Here we investigate the functionalroles of the RBE and RBE' in an attempt to better characterizethe mechanism of Rep-catalyzed trs nicking in vitro. We determinethe contribution of the RBE by altering the polarity and distanceof the RBE relative to the trs within mutant TR substrates. Increasedspacing between the RBE and trs or a change in the polarity ofthe RBE dramatically reduces Rep specific activity, and only thewt orientation of the RBE is able to support efficient Rep nicking.These data indicate that association with the RBE is criticalto the correct alignment of the Rep active site over the trs forefficient cleavage. Additionally, we characterize the contributionof the RBE' to Rep-mediated trs nicking using a panel of substitutionmutants. The mutants indicate that specific nucleotides withinthe RBE' are required for efficient, Rep-mediated cleavage. TheseRBE' contacts apparently contribute to Rep-mediated unwindingof sequences near the trs and formation of the correct nickingintermediate. Together, these results suggest a model for Repinteraction with the AAV TR during trsnicking.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Purification of baculovirus-expressed Rep68. Rep68 was purified to homogeneity from baculovirus-infected Sf9 cells as previously described (40). Rep68 was purified bysequential chromatography on phenyl-Sepharose, single-strandedDNA-cellulose, and DEAE-cellulose. Preparations were more than99% pure as judged by sodium dodecyl sulfate-acrylamide gel electrophoresisfollowed by silver staining (40).

DNA substrates. The TR substrates used in this study were constructed from gel-purified, synthetic oligonucleotides (Genosys) as previouslydescribed (6). However, construction methods were scaled upto increase yields. Accordingly, 200 pmol of two annealed oligonucleotidescontaining the RBE and the trs sequences were ligated to 1,000pmol of a third oligonucleotide containing the terminal hairpin.Oligonucleotides were ligated together at 32°C for 2 h in a 100-µlreaction volume containing 50 mM Tris-HCl (pH 7.5), 10 mM MgCl₂,10 mM dithiothreitol, 1 mM ATP, 25 µg of bovine serum albuminper ml, and 1,600 U of T4 DNA ligase (New England Biolabs). Complete163-nucleotide TR constructs were purified from ethidium bromide-stained,10% denaturing polyacrylamide gels containing 50% urea. DNA concentrationsof purified substrates were determined using the Pico Green fluorometricreagent (Molecular Probes). Each panel of mutant and wt constructswas assayed together to ensure accurate relative DNA concentrations.TR substrates were 5' end labeled at 37°C in a 10-µl reactionmixture containing 200 fmol of substrate, 70 mM Tris-HCl (pH 7.6),10 mM MgCl₂, 5 mM dithiothreitol, 20 µCi of [ $gamma$ -³²P]ATP, and 20 U of T4 polynucleotide kinase (New England Biolabs).Final concentrations of labeled substrates were determined onthe basis of specific activity and confirmed with the Pico Greenfluorometric reagent (MolecularProbes).

trs endonuclease assay. The trs endonuclease reactions were performed as described previously (6, 14). The 20-µl reaction mixtures contained25 mM HEPES-KOH (pH 7.5), 20 mM NaCl, 5.5 mM MgCl₂, 10 ng of bovineserum albumin per ml, 0.25 pM 5'-end-labeled TR substrate (10⁴ cpm/fmol), and 0.5 mM ATP, unless otherwise indicated. The reactionmixtures were incubated at 37°C for 1 h. Proteinase K-digestedreaction products were phenol-chloroform extracted, ethanol precipitated,washed in 70% ethanol, and fractionated on 10% denaturing polyacrylamidegels containing 50% urea. The amount of product formed was determinedwith a phosphorimager (Fuji). To confirm that we were in the linearrange of the phosphorimager, we experimentally compared radioactivestandards by phosphorimager and scintillationcounting.

Unless otherwise indicated, each mutant was assayed at three or four Rep concentrations, giving several data points for eachsubstrate. Since the kinetics of Rep nicking are sigmoidal withrespect to enzyme concentration (40), this approach providedthe opportunity to measure Rep activity within a linear rangefor nicking and to repeat the nicking assay multiple times foreach substrate. Only the correct-sized product resulting fromRep cleavage at the trs was counted for analysis. Minor cuts atless favored sites or nicks present in the starting substratewere not included in phosphorimageranalysis.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Spacing between the RBE and trs is critical during Rep nicking. Previously, we determined that Rep makes sequence-specific contacts at the trs and that sequences flanking the trs includea conserved inverted repeat which apparently forms a nicking sitestem-loop structure (6). Substrates in which this stem-loopwas extruded (NOSTEM) abolished the ATP requirement for Rep68-mediatedtrs nicking in vitro, indicating that the actual Rep endonucleasereaction did not require ATP. Moreover, Rep nicked the NOSTEMsubstrate with a two- to threefold-greater specific activity thanthat for wt. Since the specific activity of Rep nicking on thissubstrate was essentially the same in the presence and in theabsence of ATP, we concluded that the DNA helicase activity ofRep was not required once the trs stem-loop was formed (6).Although these observations helped to clarify the nature of Repinteraction with the trs, the functional contribution of Rep interactionwith the RBE during trs nicking remainedunclear.

To assess the importance of spacing between the RBE and the trs during Rep nicking, a panel of insertion mutants was constructed.These mutant TRs contained 3, 5, 7, or 10 bp of heterologous sequenceinserted directly between the RBE and the trs stem-loop structure(Fig. 2A) in a region that does not overlap with either element.TRs were constructed from three synthetic oligonucleotides thatwere ligated together as described in Materials and Methods. CompleteTR constructs were then purified from ethidium bromide-stained,10% denaturing polyacrylamide gels and 5' end labeled with [ $gamma$ -³²P]ATP and T4 polynucleotide kinase. Rep trs cleavage was assayedon mutant and wt substrates in vitro using homogeneously pureRep68 as described in Materials and Methods.

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FIG. 2. Rep nicking activity on RBE insertion mutants. (A) The wt AAV TR is depicted after extrusion of trs stem-loop structure. The RBE is indicated with a box, the RBE' is indicated with a dashed oval, the minimal trs is indicated with small circles, and the actual nicking site is indicated with a small arrow. The position of insertions is indicated with a large arrow. The inserted sequences are given next to the mutant identifier. (B) Rep68 endonuclease reactions were performed on wt and insertion substrates in the presence of 0.5 mM ATP as described in Materials and Methods. Products were resolved on a 10% denaturing polyacrylamide gel. A representative gel is shown. Numbers above lanes indicate the total amount of Rep68 in the reactions expressed in femtomoles. The positions of substrates and products are indicated. (C) Nicking data were obtained from two independent trials. The relative Rep specific activity for each mutant was expressed as the fraction of mutant substrate nicked divided by the fraction of wt substrate nicked at the same Rep concentration. Ratios obtained at different Rep concentrations in the two trials were then averaged and graphed for each mutant (n = 4 for all substrates except WT+10, where n = 7). Bars indicate the standard deviations from means.

Rep68 nicking was reduced on all of the insertion mutants compared to wt and decreased as the spacing between the RBE andthe trs increased (Fig. 2B and C). Furthermore, no significantimprovement was seen in the WT+10 mutant, in which the trs sitewas expected to be on approximately the same side of the DNA helixas the wt substrate. This trend suggests that the actual spacingbetween the RBE and trs is important during Rep nicking and notjust the relative position of the trs on the surface of the DNAhelix. Although most of the Rep68-mediated cleavage on the mutantsubstrates occurred at the trs, some non-trs Rep68 nicking wasobserved on the 7- and 10-bp insertion mutants. This secondarysite nicking occurred on the correct strand but internally withrespect to the trs, suggesting that the increased spacing betweenthe RBE and trs was changing the specificity of Rep68 nicking.Together, these observations indicate that the spacing betweenthe RBE and the nicking site is critical for both accurate andefficient Rep68 trscleavage.

Rep remains bound to the RBE during trs nicking. Although the spacing between the RBE and trs appeared important, the reason for the spacing requirement was unclear. One possibilitywas that the increased distance of our spacer mutants preventedformation of the nicking site stem-loop structure by endogenousRep DNA helicase activity. To investigate this possibility, weconstructed a 10-bp insertion mutant that included a preferentiallyextruded trs stem-loop structure (Fig. 3A, NOSTEM+10 substrate).Rep nicking on this substrate and its wt counterpart, NOSTEM,should no longer require ATP or DNA helicase activity (6).Thus, we reasoned that if increased spacing inhibited trs stem-loopformation, then preferentially extruding this structure shouldresult in efficient Rep68 trs nicking of the 10-bp insertion mutantin the absence of ATP.

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FIG. 3. Rep nicking activity on RBE insertion mutants in the NOSTEM background. (A) The two TR substrates containing preferentially extruded trs stem-loop structure are illustrated. NOSTEM and NOSTEM+10 TRs are depicted after formation of trs stem-loop structure. The RBE is indicated with a box, the RBE' is indicated with a dashed oval, the minimal trs is indicated with small circles, and the actual nicking site is indicated with a small arrow. The position and sequence of the NOSTEM+10 insertion are indicated with boldface italics. (B) Rep68 endonuclease reactions were performed on wt and the WT+10 insertion substrates in the presence of 0.5 mM ATP as described in Materials and Methods. Rep68 endonuclease reactions were performed on NOSTEM and NOSTEM+10 insertion substrates in the absence of ATP. Products were resolved on a 10% denaturing polyacrylamide gel. Numbers above lanes indicate the total amount of Rep68 in the reactions expressed in femtomoles. (C) The gel from panel B was phosphorimaged, and the amounts of substrate and product were determined. The fraction of nicked substrate for wt and mutant TRs was then calculated at each Rep concentration and plotted. Closed squares, wt; closed triangles, NOSTEM; open squares, WT+10; open triangles, NOSTEM+10.

In fact, preferential extrusion of the nicking site stem-loop structure in the 10-bp insertion mutant did not result in efficienttrs nicking. Rep68 nicking on this substrate was barely detectable(Fig. 3B and C, NOSTEM+10 substrate). In contrast, preferentialextrusion of the trs stem-loop structure in the wt backgroundincreased Rep68 specific activity as previously reported (Fig.3, NOSTEM substrate) (6). This result indicated that Rep68is unable to make functional contacts with the trs, in the absenceof ATP, when the spacing between the RBE and trs has been increased.Since our previous study indicated that Rep helicase activityis not required for cleavage once the trs stem-loop is formed,these data strongly suggested that Rep is unable to recognizeand nick the trs efficiently unless Rep is also physically interactingwith theRBE.

The RBE aligns Rep over the trs. If Rep must maintain contact with the RBE during nicking, then the polarity of the RBE within the TR should have a strongeffect on nicking efficiency. To test this prediction, we constructedthree additional mutants in which the 22-bp RBE was replaced withits complement, inverse, or inverse complement (Fig. 4A). If anyof these polarity changes still supported Rep trs nicking, thenthis would suggest a possible model of Rep interaction with theAAV TR.

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FIG. 4. Rep endonuclease activity on RBE polarity mutants. (A) The wt AAV TR is depicted after extrusion of the trs stem-loop structure. The RBE is indicated with a box, the RBE' is indicated with a dashed oval, the minimal trs is indicated with small circles, and the actual nicking site is indicated with a small arrow. The wt RBE was replaced with alternative orientations of this sequence. The sequences of the various RBE orientations are given next to the mutant identifier. Note that the integrity of the RBE base composition is maintained. Only the polarity of the nucleic acid sequence has been altered. (B) Rep68 endonuclease reactions were performed on wt and insertion substrates in the presence of 0.5 mM ATP as described in Materials and Methods. Products were resolved on a 10% denaturing polyacrylamide gel. A representative gel is shown. Numbers above lanes indicate the total amount of Rep68 in the reactions expressed in femtomoles. The positions of substrates and products are indicated. (C) The gels from two independent trials were phosphorimaged, and the amounts of substrate and product were determined. The fractions of nicked substrate for wt and mutant TRs were calculated at each Rep concentration, averaged between trials, and plotted. Closed squares, wt; closed circles, complement; closed triangles, inverse; closed inverted triangles, inverse complement (n = 2 for all data points). Bars indicate the range at each data point in the two independent trials. (D) Rep binding to wt and mutant TRs was assayed under endonuclease conditions in the absence of ATP (see Materials and Methods). Reactions were resolved on a 4% native polyacrylamide gel to separate substrate from protein-bound DNA complexes (PDCs). The positions of substrate and protein-bound DNA complexes are indicated.

Initially, we asked if the RBE polarity mutations prevented Rep binding to the AAV TR. Although the inverse complement RBEwas expected to bind with approximately the same efficiency asthat of wt, it was not clear whether the more severe alterationsin strand polarity in the inverse and complement mutants wouldaffect binding. To assess Rep binding to these mutants, steady-statebinding assays were done under the same reaction conditions asfor the nicking assays. However, to prevent nicking and the subsequentaccumulation of covalent complexes between Rep and the TR substrates,ATP was omitted from the binding reactions. These reaction mixtureswere then resolved on a native polyacrylamide gel to separatethe Rep-bound TR complexes from the starting substrates. As shownin Fig. 4D, all of the RBE polarity mutants were bound by Repat the enzyme concentrations used in the nicking assays (Fig.4B and C). This result indicates that the strand polarity of theRBE sequence does not significantly affect Repbinding.

In contrast, the results from Rep68 nicking assays on the three polarity mutants indicated that only the wt RBE was capableof directing efficient Rep trs nicking (Fig. 4B and C). Thus,changes in the polarity of the RBE dramatically inhibited theassociation of the Rep endonuclease active site with the trs.This is consistent with the notion that the RBE aligns Rep ora Rep complex in an orientation that is favorable for subsequenttrscleavage.

Curiously, none of our polarity mutations completely prevented Rep68 trs nicking. The small amount of cleavage observed onthese mutants may arise from at least two possibilities. First,Rep may be capable of recognizing and cleaving the trs in thepresence of ATP, outside the context of other elements. It shouldbe noted, however, that the amount of Rep trs cleavage observedon these mutant substrates is quite small (5- to 10-fold lessthan that wt) and similar to levels observed on nicking site mutantsthat we previously reported (6). Second, the low level of cleavagewith the polarity mutants may indicate that other sequence elements,like the RBE', are also contributing to the alignment of Rep alongthe AAV TR and directing nicking to the trs (see below). In eithercase, the RBE appears to align Rep along the TR and direct nickingto the trs.

The RBE' is required for efficient Rep-mediated nicking. Despite the importance of the RBE in Rep-catalyzed nicking, previous binding assays have detected Rep contacts with a singletip of the internal palindromes of the AAV TR (27). This sequence,referred to as the RBE', has a constant position with respectto the trs regardless of the orientation of the TR (flip or flop)(see Fig. 6). The functional importance of RBE' sequences duringRep trs nicking was recently confirmed by Wu et al. (39). Thisgroup observed a three- to eightfold reduction in Rep nickingactivity on TR substrates in which the RBE' had beendeleted.

The data from Rep68 nicking assays conducted on these RBE' substitution substrates were consistent with those from previousbinding and nicking assays (27, 39). Rep68 cleavage was reducedon all substrates containing substitutions in the CTTTG motifby two- to threefold [Fig. 5B and C, compare AAA, AAAAT, or SWITCHwith WT (FLIP)]. Furthermore, substitutions in the complementarysequence that comprises the other tip of the internal palindromeshad no effect on nicking [Fig. 5B and C; compare TTT with WT (FLIP)or AAA with SWITCH]. To determine whether other sequences withinthe internal palindromes affected nicking, we made a mutant inwhich all of the internal palindromic sequence was deleted inthe context of a covalently closed end (Fig. 5A and C, LINEAR).Rep specific activity on the LINEAR substrate was only moderatelyreduced compared to the specific activity observed on the RBE'substitution mutants (Fig. 5, compare AAA, SWITCH, and AAAAT toLINEAR). Together, these nicking results supported the hypothesisthat Rep makes specific nucleotide contacts with the RBE' duringtrs nicking and the most important contacts within the internalpalindromes are within RBE'. If internal palindrome sequencesoutside the RBE' contributed significantly to Rep nicking, thenwe would have expected a greater reduction in Rep68 nicking onthe LINEAR substrate.

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FIG. 5. Rep endonuclease activity on RBE' substitution mutants. (A) The wt AAV TR is depicted after extrusion of trs stem-loop structure. The RBE is indicated with a box, the RBE' is indicated with a dashed oval, the minimal trs is indicated with small circles, and the actual nicking site is indicated with a small arrow. Additionally, the position of the SmaI endonuclease site is indicated with a line. The terminal hairpins of flop and RBE' substitution mutants are also depicted. Mutated sequences are indicated in boldface. (B) Rep68 endonuclease reactions were performed on wt and substitution substrates in the presence of 0.5 mM ATP as described in Materials and Methods. Products were resolved on a 10% denaturing polyacrylamide gel. Numbers above lanes indicate the total amount of Rep68 in the reactions expressed in femtomoles. The positions of substrates and products are indicated. (C) The gel from panel B and a second gel containing reaction products from wt and LINEAR substrates were phosphorimaged, and the amounts of substrate and product were determined. The relative Rep specific activity for each mutant was expressed as the fraction of mutant substrate nicked divided by the fraction of wt substrate nicked at the same Rep concentration. Ratios obtained at different Rep concentrations were then averaged and graphed for each mutant (n = 2 for all mutants except for LINEAR, where n = 4). Bars indicate ranges between the different Rep concentrations.

To confirm the importance of the RBE' to nicking, we also tested Rep68 nicking on the wt flop substrate. We expected thissubstrate to nick at approximately wt levels because all threecomponents of the TR (trs, RBE, and RBE') had the correct sequenceand orientation. However, Rep68 nicked the flop substrate withabout half the efficiency for the flip substrate, suggesting thatother factors influenced Rep trs nicking activity. Since boththe flip and flop orientations of the AAV TR maintain the RBEand the RBE' in the same position relative to the trs, the differencein Rep nicking activity must be due to the dissimilar sequencesflanking the RBE' in these two substrates [Fig. 5A; compare WT(FLIP) with WT (FLOP)]. Indeed, our previous analysis indicatedthat Rep made additional base contacts within the terminal hairpinsequences flanking the RBE' when bound to the flop substratescompared to when it was bound to flip substrates (27).

RBE' facilitates DNA helicase activity and trs cruciform extrusion. Although it was clear that Rep contacts with RBE' were important for efficient nicking, it was not clear whether they affectedthe DNA helicase or endonuclease activity of Rep. We reasonedthat, if contacts with RBE' were important for trs transesterificationactivity, then RBE' mutations should inhibit Rep nicking, evenafter extrusion of the trs stem-loop structure. To clarify thisissue, a panel of RBE' substitution mutants was constructed inthe NOSTEM background (Fig. 6A). As discussed earlier, the NOSTEMsubstrate contains a preformed trs stem-loop structure and nickingof this substrate does not require ATP-dependent Rep helicaseactivity, allowing nicking assays to be done in the absence ofATP. Interestingly, both of our NOSTEM RBE' mutants were nickedat nearly wt levels in the absence of ATP (Fig. 6B). Moreover,Rep nicked these NOSTEM RBE' substitutions about twofold moreefficiently than the same RBE' mutations in the wt TR background(compare Fig. 5C, AAA and AAAAT, with Fig. 6B, NOSTEM AAA andNOSTEM AAAAT). This result indicates that Rep interaction withRBE' is not necessary for the Rep transesterification reaction.Rather, it appears that RBE' is required primarily for efficient,Rep-mediated unwinding of the AAV TR and formation of the nickingintermediate.

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FIG. 6. Rep endonuclease activity on RBE' substitution mutants in the NOSTEM background. (A) The NOSTEM substrate is depicted. The RBE is indicated with a box, the RBE' is indicated with a dashed oval, the minimal trs is indicated with small circles, and the actual nicking site is indicated with a small arrow. The terminal hairpins of the RBE' substitution mutants are also depicted. Mutated sequences are indicated in boldface. (B) Rep68 endonuclease reactions were performed on NOSTEM and NOSTEM RBE' substitution substrates in the absence of ATP as described in Materials and Methods. Products were resolved on a 10% denaturing polyacrylamide gel. The gel was phosphorimaged, and the amounts of substrate and product were determined. The relative Rep specific activity for each mutant was expressed as the fraction of mutant substrate nicked divided by the fraction of wt substrate nicked at the same Rep concentration. Ratios obtained at different Rep concentrations were then averaged and graphed for each mutant (n = 4 for all mutants). Bars indicate standard deviations from the means.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

Previous binding and chemical interference studies in the absence of ATP have determined that Rep makes contact with two distinctelements within the AAV TR, the linear RBE and the CTTTG motifat one tip of one of the internal palindromes, the RBE' (8,19, 20, 27). In the presence of ATP, Rep makes additionalcontacts with the trs that lead to transesterification (6,14, 32, 33). Regardless of the orientation of the internalpalindromes, flip or flop, these three elements are maintainedin a constant position relative to the trs during viral DNA replication.During the course of this study, we have analyzed the contributionof Rep binding contacts along the AAV TR to Rep-mediated trs nicking.Using synthetic AAV TR substrates, we have altered the positionand polarity of the RBE relative to the trs and mutated the primarysequence of the RBE'. In vitro Rep trs nicking assays on thesemutant substrates indicate that both the RBE and RBE' are requiredfor efficient Rep-catalyzed trsnicking.

The RBE is required both for origin unwinding and for trs nicking. Rep nicking activity decreased dramatically when the spacing between the RBE and the trs was altered, indicating that theposition of the RBE relative to the trs is critical for efficientcleavage. This observation is consistent with previous in vivostudies of AAV DNA replication, in which AAV genomes harboringmutant RBEs replicated at lower levels than those of wt genomes(4), and in vitro studies, which indicated that the RBE wasnecessary for Rep binding (8, 19, 20, 27). Recently,we showed that the trs endonuclease reaction occurs in two steps,an initial unwinding of the TR by the Rep-associated DNA helicasethat leads to the extrusion of the trs stem-loop structure andthe subsequent transesterification reaction that leads to cleavageof the trs (6). We also demonstrated that Rep has a site-specificDNA helicase activity that unwinds DNA containing an RBE (40).Our data from the RBE polarity and spacing mutants in this reportindicate that Rep must maintain contact with the RBE during boththe TR unwinding and the trs cleavage steps of the endonucleasereaction.

At least two models could describe Rep interaction with the TR during trs transesterification. For example, it is possiblethat Rep initially binds the RBE and then translocates along thenicked strand to the downstream nicking site, in a manner similarto the restriction endonuclease EcoKI (9-11). Once at the trs,Rep would recognize the nicking site and initiate the transesterificationreaction. In this model, the trs stem-loop structure may functionas a helicase pause site, allowing prolonged contact between Repand the nicking site. Alternatively, Rep may be tethered to theRBE during nicking. Endogenous Rep helicase activity would allowdownstream contact with the trs, melting of the duplex nickingsite, and formation of the nicking site stem-loop structure. Inthis second model (illustrated in Fig. 7), the nicking site stem-loopstructure would effectively reposition the trs closer to the RBE-boundRep, allowing efficient cleavage.

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FIG. 7. Model of Rep interaction with the AAV TR during trs nicking. The various steps involved in Rep-catalyzed trs nicking are illustrated. The gray ovals each depict separate Rep molecules. The black circles represent the Rep catalytic site. The trs is indicated with an arrow. See the text for details.

Rep nicking data from our insertion mutants are not consistent with a translocation model of Rep-mediated trs nicking. Repis a fairly strong helicase capable of unwinding 345 bp per min(40). If Rep was initially binding the AAV TR through the RBEand then actively being translocated downstream analogous to EcoKI,then we would not expect small increases in spacing between theRBE and the trs to affect the specific activity of Rep nicking.Yet, Rep had a lowered specific activity on all spacer mutantscompared to that of wt (Fig. 2). Moreover, the specific activityof Rep nicking decreased rapidly as spacing between the RBE andthe trs increased. Since it is unlikely that 5, 7, or 10 bp ofintervening sequence would prevent translocation of Rep from theRBE toward the trs, it appears that the mechanism of Rep-mediatedtrs cleavage does not include helicase-stimulated translocation.Furthermore, artificially fixing the trs stem-loop structure inthe extruded configuration should remove the need for Rep DNAhelicase activity and thus contact with the RBE. However, Repnicking on our 10-bp insertion mutant was barely detectable evenafter extrusion of the trs stem-loop structure (Fig. 3). Thus,it appears that Rep maintains contact with the RBE during bothDNA helicase and trs cleavageactivities.

We note that none of our RBE spacer or polarity mutations completely prevented Rep-mediated trs nicking. Apparently, Rep isable to recognize and nick the trs regardless of RBE position,albeit at much decreased levels. Thus, other elements within theAAV TR such as the RBE' and trs must also contribute to Rep nicking.In the case of the trs, this is not surprising, because our previousstudy indicated that Rep makes sequence specific contacts at thetrs during nicking. Mutation of sequences within the 7-base coretrs sequence site reduced Rep cleavage 6- to 10-fold comparedto wt substrates, suggesting that Rep specificity for the trsis quite stringent (6). Indeed, Smith and Kotin (29) recentlyshowed directly that Rep can cleave a single-stranded, trs-containingoligonucleotide in the absence of RBE or RBE'sequences.

Contribution of the RBE' to Rep trs nicking. The importance of the RBE' to Rep-mediated nicking was anticipated by viral DNA replication assays as well as Rep bindingand nicking assays (5, 8, 17, 19, 27, 39). PreviousAAV DNA replication assays demonstrated that the internal palindromesof the TR are necessary for efficient viral DNA replication. AAVplasmid constructs with deletions of the RBE' and adjacent sequencesreplicated at lower levels than did wt AAV constructs (5, 17).Furthermore, in vitro studies indicated that Rep requires theinternal palindromes for efficient TR binding and nicking (8,19, 27, 32). During TR binding, Rep appears to make limitedsequence contacts with the internal palindromes, and the mostprominent of these contacts occur within RBE' (27).

Our data confirmed that Rep is making sequence-specific contacts with the CTTTG motif of the RBE'. Substitutions within thissequence significantly reduced Rep nicking activity (Fig. 5).However, when we examined these same RBE' mutations in the contextof the NOSTEM background, the reduction in Rep nicking activitywas very small (Fig. 6). This suggested that Rep no longer requirescontact with the RBE' once the stem-loop has been formed and impliedthat interaction with the RBE' was important primarily for RepTR unwinding activity, rather than the transesterificationreaction.

The RBE' sequences appear to be the most significant Rep contacts with the internal palindromes during trs nicking. Rep nickingactivity on our LINEAR substrate was only slightly reduced comparedto our RBE' substitution mutants, supporting this conclusion.However, the slight reduction in Rep specific activity observedon our LINEAR substrate does imply that either sequences flankingthe CTTTG motif or the internal palindrome structure itself contributesto efficient Rep cleavage. Additionally, Rep nicking activitywas reduced on our flop substrate compared to that on the flipsubstrate. Although this alternative orientation of the AAV TRmaintains the CTTTG motif in the same position relative to thetrs, the sequences flanking this motif are different from theflip orientation. Indeed, Ryan et al. (27) observed differencesin Rep binding contacts between the flip and flop orientationswithin these flanking internal palindrome sequences. Perhaps thisindicates that Rep association with the flop orientation is fundamentallydifferent from that with the flip orientation. This concept issupported by chemical interference assays that reveal differencesbetween Rep contacts within the RBEs of the two substrates. AlthoughRep makes many discrete contacts within the RBEs of both flipand flop, the strength of individual base contacts is differentin the two TR orientations (27). Finally, the reduction in nickingactivity seen with our RBE' substitution mutants and the LINEARmutant (about threefold) was less than we and others had previouslyseen on substrates that were missing portions of the internalpalindromes (5- to 100-fold) (8, 19, 32, 39). This wasmost likely due to the fact that the substrates used in this studywere covalently closed at one end, whereas previous studies hadused SmaI-cut or linear oligonucleotide substrates. Thus, previouslyused substrates would likely be unwound by the Rep helicase activityto generate single-stranded DNA molecules. In contrast, the substratesused in this study would rapidly reanneal to duplexmolecules.

The RBE appears to align Rep asymmetrically on the TR. When we examined all three possible polarity changes of the RBE sequence (Fig. 4, INVERSE, COMPLEMENT, and INVERSE COMPLEMENT),only the wt polarity retained significant nicking activity. Yet,all of these polarity mutants bound Rep with affinities that werecomparable to the wt substrate. This suggested that RBE bindingis not particularly sensitive to strand polarity. It also suggestedthat Rep interaction with the RBE during nicking is inherentlyasymmetric and serves to align the Rep nicking complex in theappropriate orientation on the TR for the subsequent helicaseand transesterificationreactions.

Although the RBE appears to play a central role in orienting Rep along the AAV TR during nicking, the architecture of thisinteraction is undefined. It is not yet clear what an active Repcomplex looks like when it is bound to the TR. The kinetics oftrs nicking are second order with respect to Rep and ATP concentration,suggesting that a dimer of Rep is sufficient for nicking activity(40). In contrast, Rep DNA helicase activity appears to be firstorder with respect to enzyme concentration. Furthermore, bindingstudies detect at least six different bound species, suggestingthat Rep complexes can contain as many as six Rep molecules (20,30). If a Rep dimer is the active nicking complex as impliedby the kinetic data, then our data suggest that individual Repmonomers do not associate along a twofold axis of symmetry similarto the type II restriction endonucleases. Presumably such an arrangementof Rep molecules would be active on both our wt and inverse complementsubstrates. Indeed, our data imply that the Rep nicking complexis arranged asymmetrically along the RBE. This asymmetry may arisefrom the arrangement of Rep monomers within the homodimer or mayreflect the involvement of higher-order complexes in the nickingreaction.

In conclusion, it appears that at least three discrete steps are involved in Rep-mediated AAV origin nicking (Fig. 7). First,Rep binds the TR through the RBE. The RBE aligns the Rep complexalong the TR, allowing specific contacts with RBE'. These RBE'contacts appear to stabilize the Rep complex and facilitate Rep-mediatedDNA helicase activity. It is unclear if Rep maintains its originalcontacts and pulls unwound downstream sequences toward the RBE,allowing them to self-anneal into the trs stem-loop, or if stem-loopformation is more passive in nature. In either case, the net resultof Rep helicase activity is the formation of the trs stem-loop.Once formed, this structure presents the single-stranded trs tothe Rep transesterification active site in the proper positionfornicking.

	ACKNOWLEDGMENTS

This work was supported by grants from the National Institutes of Health: RO1 GM35723, P01 HL51811, and P01 NS36302.

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Molecular Genetics and Microbiology, College of Medicine, Universityof Florida, P.O. Box 100266 JHMHSC, Gainesville, FL 32610. Phone:(352) 392-5913. Fax: (352) 392-5914. E-mail: muzyczka{at}ufl.edu.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

1. Ashktorab, H., and A. Srivastava. 1989. Identification of nuclear proteins that specifically interact with adeno-associated virus type 2 inverted terminal repeat hairpin DNA. J. Virol. 63:3034-3039[Abstract/Free Full Text].

2. Batchu, R. B., and P. L. Hermonat. 1995. Dissociation of conventional DNA binding and endonuclease activities by an adeno-associated virus Rep78 mutant. Biochem. Biophys. Res. Commun. 210:717-725[CrossRef][Medline].

3. Batchu, R. B., R. M. Kotin, and P. L. Hermonat. 1994. The regulatory rep protein of adeno-associated virus binds to sequences within the c-H-ras promoter. Cancer Lett. 86:23-31[CrossRef][Medline].

4. Bishop, B. M., A. D. Santin, J. G. Quirk, and P. L. Hermonat. 1996. Role of the terminal repeat GAGC trimer, the major Rep78 binding site, in adeno-associated virus DNA replication. FEBS Lett. 397:97-100[CrossRef][Medline].

5. Bohenzky, R. A., R. B. LeFebvre, and K. I. Berns. 1988. Sequence and symmetry requirements within the internal palindromic sequences of the adeno-associated virus terminal repeat. Virology 166:316-327[CrossRef][Medline].

6. Brister, J. R., and N. Muzyczka. 1999. Rep-mediated nicking of the adeno-associated virus origin requires two biochemical activities, DNA helicase activity and transesterification. J. Virol. 73:9325-9336[Abstract/Free Full Text].

7. Chiorini, J. A., M. D. Weitzman, R. A. Owens, E. Urcelay, B. Safer, and R. M. Kotin. 1994. Biologically active Rep proteins of adeno-associated virus type 2 produced as fusion proteins in Escherichia coli. J. Virol. 68:797-804[Abstract/Free Full Text].

8. Chiorini, J. A., S. M. Wiener, R. A. Owens, S. R. Kyostio, R. M. Kotin, and B. Safer. 1994. Sequence requirements for stable binding and function of Rep68 on the adeno-associated virus type 2 inverted terminal repeats. J. Virol. 68:7448-7457[Abstract/Free Full Text].

9. Davies, G. P., P. Kemp, I. J. Molineux, and N. E. Murray. 1999. The DNA translocation and ATPase activities of restriction-deficient mutants of Eco KI. J. Mol. Biol. 292:787-796[CrossRef][Medline].

10. Ellis, D. J., D. T. Dryden, T. Berge, J. M. Edwardson, and R. M. Henderson. 1999. Direct observation of DNA translocation and cleavage by the EcoKI endonuclease using atomic force microscopy. Nat. Struct. Biol. 6:15-17[CrossRef][Medline].

11. Garcia, L. R., and I. J. Molineux. 1999. Translocation and specific cleavage of bacteriophage T7 DNA in vivo by EcoKI. Proc. Natl. Acad. Sci. USA 96:12430-12435[Abstract/Free Full Text].

12. Hauswirth, W. W., and K. I. Berns. 1977. Origin and termination of adeno-associated virus DNA replication. Virology 78:488-499[CrossRef][Medline].

13. Horer, M., S. Weger, K. Butz, F. Hoppe Seyler, C. Geisen, and J. A. Kleinschmidt. 1995. Mutational analysis of adeno-associated virus Rep protein-mediated inhibition of heterologous and homologous promoters. J. Virol. 69:5485-5496[Abstract].

14. Im, D. S., and N. Muzyczka. 1990. The AAV origin binding protein Rep68 is an ATP-dependent site-specific endonuclease with DNA helicase activity. Cell 61:447-457[CrossRef][Medline].

15. Kokorina, N. A., A. D. Santin, C. Li, and P. L. Hermonat. 1998. Involvement of protein-DNA interaction in adeno-associated virus Rep78-mediated inhibition of HIV-1. J. Hum. Virol. 1:441-450[Medline].

16. Kyostio, S. R., R. S. Wonderling, and R. A. Owens. 1995. Negative regulation of the adeno-associated virus (AAV) P5 promoter involves both the P5 rep binding site and the consensus ATP-binding motif of the AAV Rep68 protein. J. Virol. 69:6787-6796[Abstract].

17. LeFebvre, R. B., S. Riva, and K. I. Berns. 1984. Conformation takes precedence over sequence in adeno-associated virus DNA replication. Mol. Cell. Biol. 4:1416-1419[Abstract/Free Full Text].

18. McCarty, D. M., M. Christensen, and N. Muzyczka. 1991. Sequences required for coordinate induction of adeno-associated virus p19 and p40 promoters by Rep protein. J. Virol. 65:2936-2945[Abstract/Free Full Text].

19. McCarty, D. M., D. J. Pereira, I. Zolotukhin, X. Zhou, J. H. Ryan, and N. Muzyczka. 1994. Identification of linear DNA sequences that specifically bind the adeno-associated virus Rep protein. J. Virol. 68:4988-4997[Abstract/Free Full Text].

20. McCarty, D. M., J. H. Ryan, S. Zolotukhin, X. Zhou, and N. Muzyczka. 1994. Interaction of the adeno-associated virus Rep protein with a sequence within the A palindrome of the viral terminal repeat. J. Virol. 68:4998-5006[Abstract/Free Full Text].

21. McLaughlin, S. K., P. Collis, P. L. Hermonat, and N. Muzyczka. 1988. Adeno-associated virus general transduction vectors: analysis of proviral structures. J. Virol. 62:1963-1973[Abstract/Free Full Text].

22. Ni, T. H., X. Zhou, D. M. McCarty, I. Zolotukhin, and N. Muzyczka. 1994. In vitro replication of adeno-associated virus DNA. J. Virol. 68:1128-1138[Abstract/Free Full Text].

23. Noirot, P., J. Bargonetti, and R. P. Novick. 1990. Initiation of rolling-circle replication in pT181 plasmid: initiator protein enhances cruciform extrusion at the origin. Proc. Natl. Acad. Sci. USA 87:8560-8564[Abstract/Free Full Text].

24. Orozco, B. M., and L. Hanley-Bowdoin. 1996. A DNA structure is required for geminivirus replication origin function. J. Virol. 70:148-158[Abstract].

25. Owens, R. A., M. D. Weitzman, S. R. Kyostio, and B. J. Carter. 1993. Identification of a DNA-binding domain in the amino terminus of adeno-associated virus Rep proteins. J. Virol. 67:997-1005[Abstract/Free Full Text].

26. Pereira, D. J., D. M. McCarty, and N. Muzyczka. 1997. The adeno-associated virus (AAV) Rep protein acts as both a repressor and an activator to regulate AAV transcription during a productive infection. J. Virol. 71:1079-1088[Abstract].

27. Ryan, J. H., S. Zolotukhin, and N. Muzyczka. 1996. Sequence requirements for binding of Rep68 to the adeno-associated virus terminal repeats. J. Virol. 70:1542-1553[Abstract].

28. Samulski, R. J., A. Srivastava, K. I. Berns, and N. Muzyczka. 1983. Rescue of adeno-associated virus from recombinant plasmids: gene correction within the terminal repeats of AAV. Cell 33:135-143[CrossRef][Medline].

29. Smith, R. H., and R. M. Kotin. 2000. An adeno-associated virus (AAV) initiator protein, Rep78, catalyzes the cleavage and ligation of single-stranded AAV ori DNA. J. Virol. 74:3122-3129[Abstract/Free Full Text].

30. Smith, R. H., A. J. Spano, and R. M. Kotin. 1997. The Rep78 gene product of adeno-associated virus (AAV) self-associates to form a hexameric complex in the presence of AAV ori sequences. J. Virol. 71:4461-4471[Abstract].

31. Snyder, R. O., D. S. Im, and N. Muzyczka. 1990. Evidence for covalent attachment of the adeno-associated virus (AAV) Rep protein to the ends of the AAV genome. J. Virol. 64:6204-6213[Abstract/Free Full Text].

32. Snyder, R. O., D. S. Im, T. Ni, X. Xiao, R. J. Samulski, and N. Muzyczka. 1993. Features of the adeno-associated virus origin involved in substrate recognition by the viral Rep protein. J. Virol. 67:6096-6104[Abstract/Free Full Text].

33. Snyder, R. O., R. J. Samulski, and N. Muzyczka. 1990. In vitro resolution of covalently joined AAV chromosome ends. Cell 60:105-113[CrossRef][Medline].

34. Urcelay, E., P. Ward, S. M. Wiener, B. Safer, and R. M. Kotin. 1995. Asymmetric replication in vitro from a human sequence element is dependent on adeno-associated virus Rep protein. J. Virol. 69:2038-2046[Abstract].

35. Ward, P., E. Urcelay, R. Kotin, B. Safer, and K. I. Berns. 1994. Adeno-associated virus DNA replication in vitro: activation by a maltose binding protein/Rep 68 fusion protein. J. Virol. 68:6029-6037[Abstract/Free Full Text].

36. Weitzman, M. D., S. R. Kyostio, R. M. Kotin, and R. A. Owens. 1994. Adeno-associated virus (AAV) Rep proteins mediate complex formation between AAV DNA and its integration site in human DNA. Proc. Natl. Acad. Sci. USA 91:5808-5812[Abstract/Free Full Text].

37. Wonderling, R. S., and R. A. Owens. 1997. Binding sites for adeno-associated virus Rep proteins within the human genome. J. Virol. 71:2528-2534[Abstract].

38. Wonderling, R. S., and R. A. Owens. 1996. The Rep68 protein of adeno-associated virus type 2 stimulates expression of the platelet-derived growth factor B c-sis proto-oncogene. J. Virol. 70:4783-4786[Abstract]. (Erratum, 70:9084.)

39. Wu, J., M. D. Davis, and R. A. Owens. 1999. Factors affecting the terminal resolution site endonuclease, helicase, and ATPase activities of adeno-associated virus type 2 Rep proteins. J. Virol. 73:8235-8244[Abstract/Free Full Text].

40. Zhou, X., I. Zolotukhin, D. S. Im, and N. Muzyczka. 1999. Biochemical characterization of adeno-associated virus Rep68 DNA helicase and ATPase activities. J. Virol. 73:1580-1590[Abstract/Free Full Text].

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1.	Ashktorab, H., and A. Srivastava. 1989. Identification of nuclear proteins that specifically interact with adeno-associated virus type 2 inverted terminal repeat hairpin DNA. J. Virol. 63:3034-3039[Abstract/Free Full Text].
2.	Batchu, R. B., and P. L. Hermonat. 1995. Dissociation of conventional DNA binding and endonuclease activities by an adeno-associated virus Rep78 mutant. Biochem. Biophys. Res. Commun. 210:717-725[CrossRef][Medline].
3.	Batchu, R. B., R. M. Kotin, and P. L. Hermonat. 1994. The regulatory rep protein of adeno-associated virus binds to sequences within the c-H-ras promoter. Cancer Lett. 86:23-31[CrossRef][Medline].
4.	Bishop, B. M., A. D. Santin, J. G. Quirk, and P. L. Hermonat. 1996. Role of the terminal repeat GAGC trimer, the major Rep78 binding site, in adeno-associated virus DNA replication. FEBS Lett. 397:97-100[CrossRef][Medline].
5.	Bohenzky, R. A., R. B. LeFebvre, and K. I. Berns. 1988. Sequence and symmetry requirements within the internal palindromic sequences of the adeno-associated virus terminal repeat. Virology 166:316-327[CrossRef][Medline].
6.	Brister, J. R., and N. Muzyczka. 1999. Rep-mediated nicking of the adeno-associated virus origin requires two biochemical activities, DNA helicase activity and transesterification. J. Virol. 73:9325-9336[Abstract/Free Full Text].
7.	Chiorini, J. A., M. D. Weitzman, R. A. Owens, E. Urcelay, B. Safer, and R. M. Kotin. 1994. Biologically active Rep proteins of adeno-associated virus type 2 produced as fusion proteins in Escherichia coli. J. Virol. 68:797-804[Abstract/Free Full Text].
8.	Chiorini, J. A., S. M. Wiener, R. A. Owens, S. R. Kyostio, R. M. Kotin, and B. Safer. 1994. Sequence requirements for stable binding and function of Rep68 on the adeno-associated virus type 2 inverted terminal repeats. J. Virol. 68:7448-7457[Abstract/Free Full Text].
9.	Davies, G. P., P. Kemp, I. J. Molineux, and N. E. Murray. 1999. The DNA translocation and ATPase activities of restriction-deficient mutants of Eco KI. J. Mol. Biol. 292:787-796[CrossRef][Medline].
10.	Ellis, D. J., D. T. Dryden, T. Berge, J. M. Edwardson, and R. M. Henderson. 1999. Direct observation of DNA translocation and cleavage by the EcoKI endonuclease using atomic force microscopy. Nat. Struct. Biol. 6:15-17[CrossRef][Medline].
11.	Garcia, L. R., and I. J. Molineux. 1999. Translocation and specific cleavage of bacteriophage T7 DNA in vivo by EcoKI. Proc. Natl. Acad. Sci. USA 96:12430-12435[Abstract/Free Full Text].
12.	Hauswirth, W. W., and K. I. Berns. 1977. Origin and termination of adeno-associated virus DNA replication. Virology 78:488-499[CrossRef][Medline].
13.	Horer, M., S. Weger, K. Butz, F. Hoppe Seyler, C. Geisen, and J. A. Kleinschmidt. 1995. Mutational analysis of adeno-associated virus Rep protein-mediated inhibition of heterologous and homologous promoters. J. Virol. 69:5485-5496[Abstract].
14.	Im, D. S., and N. Muzyczka. 1990. The AAV origin binding protein Rep68 is an ATP-dependent site-specific endonuclease with DNA helicase activity. Cell 61:447-457[CrossRef][Medline].
15.	Kokorina, N. A., A. D. Santin, C. Li, and P. L. Hermonat. 1998. Involvement of protein-DNA interaction in adeno-associated virus Rep78-mediated inhibition of HIV-1. J. Hum. Virol. 1:441-450[Medline].
16.	Kyostio, S. R., R. S. Wonderling, and R. A. Owens. 1995. Negative regulation of the adeno-associated virus (AAV) P5 promoter involves both the P5 rep binding site and the consensus ATP-binding motif of the AAV Rep68 protein. J. Virol. 69:6787-6796[Abstract].
17.	LeFebvre, R. B., S. Riva, and K. I. Berns. 1984. Conformation takes precedence over sequence in adeno-associated virus DNA replication. Mol. Cell. Biol. 4:1416-1419[Abstract/Free Full Text].
18.	McCarty, D. M., M. Christensen, and N. Muzyczka. 1991. Sequences required for coordinate induction of adeno-associated virus p19 and p40 promoters by Rep protein. J. Virol. 65:2936-2945[Abstract/Free Full Text].
19.	McCarty, D. M., D. J. Pereira, I. Zolotukhin, X. Zhou, J. H. Ryan, and N. Muzyczka. 1994. Identification of linear DNA sequences that specifically bind the adeno-associated virus Rep protein. J. Virol. 68:4988-4997[Abstract/Free Full Text].
20.	McCarty, D. M., J. H. Ryan, S. Zolotukhin, X. Zhou, and N. Muzyczka. 1994. Interaction of the adeno-associated virus Rep protein with a sequence within the A palindrome of the viral terminal repeat. J. Virol. 68:4998-5006[Abstract/Free Full Text].
21.	McLaughlin, S. K., P. Collis, P. L. Hermonat, and N. Muzyczka. 1988. Adeno-associated virus general transduction vectors: analysis of proviral structures. J. Virol. 62:1963-1973[Abstract/Free Full Text].
22.	Ni, T. H., X. Zhou, D. M. McCarty, I. Zolotukhin, and N. Muzyczka. 1994. In vitro replication of adeno-associated virus DNA. J. Virol. 68:1128-1138[Abstract/Free Full Text].
23.	Noirot, P., J. Bargonetti, and R. P. Novick. 1990. Initiation of rolling-circle replication in pT181 plasmid: initiator protein enhances cruciform extrusion at the origin. Proc. Natl. Acad. Sci. USA 87:8560-8564[Abstract/Free Full Text].
24.	Orozco, B. M., and L. Hanley-Bowdoin. 1996. A DNA structure is required for geminivirus replication origin function. J. Virol. 70:148-158[Abstract].
25.	Owens, R. A., M. D. Weitzman, S. R. Kyostio, and B. J. Carter. 1993. Identification of a DNA-binding domain in the amino terminus of adeno-associated virus Rep proteins. J. Virol. 67:997-1005[Abstract/Free Full Text].
26.	Pereira, D. J., D. M. McCarty, and N. Muzyczka. 1997. The adeno-associated virus (AAV) Rep protein acts as both a repressor and an activator to regulate AAV transcription during a productive infection. J. Virol. 71:1079-1088[Abstract].
27.	Ryan, J. H., S. Zolotukhin, and N. Muzyczka. 1996. Sequence requirements for binding of Rep68 to the adeno-associated virus terminal repeats. J. Virol. 70:1542-1553[Abstract].
28.	Samulski, R. J., A. Srivastava, K. I. Berns, and N. Muzyczka. 1983. Rescue of adeno-associated virus from recombinant plasmids: gene correction within the terminal repeats of AAV. Cell 33:135-143[CrossRef][Medline].
29.	Smith, R. H., and R. M. Kotin. 2000. An adeno-associated virus (AAV) initiator protein, Rep78, catalyzes the cleavage and ligation of single-stranded AAV ori DNA. J. Virol. 74:3122-3129[Abstract/Free Full Text].
30.	Smith, R. H., A. J. Spano, and R. M. Kotin. 1997. The Rep78 gene product of adeno-associated virus (AAV) self-associates to form a hexameric complex in the presence of AAV ori sequences. J. Virol. 71:4461-4471[Abstract].
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