Role for the adenovirus IVa2 protein in packaging of viral DNA

Although it has been demonstrated that the adenovirus IVa2 protein binds to the packaging domains on the viral chromosome and interacts with the viral L1 52/55-kDa protein, which is required for viral DNA packaging, there has been no direct evidence demonstrating that the IVa2 protein is involved in DNA packaging. To understand in greater detail the DNA packaging mechanisms of adenovirus, we have asked whether DNA packaging is serotype or subgroup specific. We found that Ad7 (subgroup B), Ad12 (subgroup A), and Ad17 (subgroup D) cannot complement the defect of an Ad5 (subgroup C) mutant, pm8001, which does not package its DNA due to a mutation in the L1 52/55-kDa gene. This indicates that the DNA packaging systems of different serotypes cannot interact productively with Ad5 DNA. Based on this, a chimeric virus containing the Ad7 genome except for the inverted terminal repeats and packaging sequence from Ad5 was constructed. This chimeric virus replicates its DNA and synthesizes Ad7 proteins, but it cannot package its DNA in 293 cells or 293 cells expressing the Ad5 L1 52/55-kDa protein. However, this chimeric virus packages its DNA in 293 cells expressing the Ad5 IVa2 protein. These results indicate that the IVa2 protein plays a role in viral DNA packaging and that its function is serotype specific. Since this chimeric virus cannot package its own DNA, but produces all the components for packaging Ad7 DNA, it may be a more suitable helper virus for the growth of Ad7 gutted vectors for gene transfer.     

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.     

Gutted adenoviral vector growth using E1/E2b/E3-deleted helper viruses

Background

Helper‐dependent, or gutted, adenoviruses (Ad) lack viral coding sequences, resulting in reduced immunotoxicity compared with conventional Ad vectors. Gutted Ad growth requires a conventional Ad to supply replication and packaging functions in trans. Methods that allow high‐titer growth of gutted vectors while reducing helper contamination, and which use safer helper viruses, will facilitate the use of gutted Ad vectors in vivo.

Methods

Replication‐defective helper viruses were generated that are deleted for Ad E1, E2b and E3 genes, but which contain loxP sites flanking the packaging signal. Complementing Ad packaging cell lines (C7‐cre cells) were also generated by transfecting 293 cells with the Ad E2b genes encoding DNA polymerase and pre‐terminal protein, and with a cre‐recombinase plasmid.

Results

We show that C7‐cre cells allow efficient production of gutted Ad using ΔE1 + ΔE2b + ΔE3 helper viruses whose growth can be limited by cre‐loxP‐mediated excision of the packaging signal. Gutted Ad vectors carrying ～28 kb cassettes expressing full‐length dystrophin were prepared at high titers, similar to those obtained with E2b+ helpers, with a resulting helper contamination of <1%.

Conclusions

These new packaging cell lines and helper viruses offer several significant advantages for gutted Ad vector production. They allow gutted virus amplification using a reduced number of passages, which should reduce the chances of selecting rearranged products. Furthermore, the residual helper contamination in gutted vector preparations should be less able to elicit immunological reactions upon delivery to tissues, since E2b‐deleted vectors display a profound reduction in viral gene expression. Copyright © 2002 John Wiley & Sons, Ltd.

     

表达超抗原SEA基因的溶瘤腺病毒载体的构建与鉴定

目的:构建表达超抗原SEA基因的溶瘤腺病毒载体并鉴定.方法:采用PCR技术,从产SEA的葡萄球菌标准菌株ATCC13565基因组DNA中获得SEA全长基因序列,酶切后克隆入pCA13质粒,构建重组病毒质粒pCA13-SEA.将鉴定正确的pCA13-SEA与含有腺病毒右臂的质粒pBHGE3通过Lipofectamine2000共转染HEK293细胞,经同源重组产生重组腺病毒Ad-SEA.Ad-SEA在293细胞中大量扩增并通过氯化铯密度梯度离心法纯化、测定其滴度.结果:经PCR扩增、酶切鉴定、序列测定证实,SEA基因成功克隆到溶瘤腺病毒载体中,可实现SEA基因的表达.结论:成功构建了表达超抗原SEA基因的溶瘤腺病毒载体,为进一步研究该病毒对膀胱肿瘤靶向治疗的作用奠定了基础.     

A helper virus-free packaging system for recombinant adeno-associated virus vectors

Adeno-associated virus (AAV) is a human parvovirus that is currently receiving widespread attention for its potential use as a gene therapy vector. Construction of the recombinant AAV vector (rAAV) involves replacing most of the viral genome with a transgene of interest and then packaging this recombinant genome into an infectious virion. Most current protocols for generating rAAV entail the co-transfection of a vector plasmid and a packaging plasmid that expresses the viral replication and structural genes onto adenovirus (Ad) infected cells growing in culture. Limitations of this procedure include (1) contamination of rAAV with the Ad helper virus, (2) low yields of rAAV and (3) production of replication-competent AAV. In this report we describe new helper plasmids (pSH3 and pSH5) that eliminate the Ad co-infection requirement. The helper plasmids express the AAV rep and cap genes and the Ad E2A, VAI and E4 genes. When the helper plasmids are co-transfected onto human 293 cells with a vector plasmid in the absence of Ad infection, the rAAV vector yield is up to 80-fold greater than those obtained with the pAAV/Ad packaging plasmid. Moreover, replication competent AAV in the rAAV preparations is less than 0.00125%. The major advantages of this system are (1) the absence of infectious adenovirus and (2) the use of only two plasmids, which enhances transfection efficiencies and hence vector production. We believe that this two-plasmid transfection system will allow for more widespread use of the AAV vector system because of its simplicity and high yields. This system will be especially useful for preclinical analyses of multiple rAAV vectors.     

Construction of adenoviral vectors

Recombinant adenovirus vectors have proven to be useful tools in facilitating gene transfer. Construction of such vectors requires a knowledge of the adenovirus genome structure and its life cycle. A commonly used recombinant adenovirus involves deletion of the E1 region; such a recombinant is traditionally produced by overlap recombination after contransfection of 293 cells with a plasmid shuttle vector and a large right-end restriction fragment of viral DNA. The shuttle vector contains a cassette for a transgene placed in region E1 and flanking sequences from adenovirus for recombination. Normally, a high background of parental virus results because of the difficulty in separating right-end restriction fragment length DNA from uncut DNA. This paper describes a negative selection based on the traditional cotransfection method using viral DNA from an E1-deleted adenoviral recombinant that expresses green fluorescent protein (GFP). In situ fluorescent microscopy is used to distinguish the recombinant plaques (white or nonfluorescent) from the parental virus plaques (green or fluorescent). In addition, this system allows for the detection of contaminating parental virus at later stages when production lots of the recombinant vector are being made.     

Adenovirus type 5 precursor terminal protein-expressing 293 and HeLa cell lines.

HeLa and 293 cell lines that express biologically active adenovirus type 5 precursor terminal protein (pTP) have been made. The amount of pTP synthesized in these cell lines ranges from barely detectable to greater than that observed in cells infected with the wild-type virus. The pTP-expressing cell lines permit the growth of a temperature-sensitive terminal protein mutant virus sub100r at the nonpermissive temperature. A higher percentage of the stably transfected 293 cell lines expressed terminal protein, and generally at considerably higher levels, than did the HeLa cell lines. While 293 cells appeared to tolerate pTP better than did HeLa cells, high-level pTP expression in 293 cells led to a significantly reduced growth rate. The 293-pTP cell lines produce infectious virus after transfection with purified viral DNA and form plaques when overlaid with Noble agar after infection at low multiplicity. These cell lines offer promise for the production of adenoviruses lacking pTP expression and therefore completely defective for replication.     

用大肠杆菌同源重组获得克隆化重组腺病毒基因组

利用大肠杆菌细胞内质粒间同源重组获得克隆化重组腺病毒基因组 DNA,高效构建携带有外源基因的均一重组腺病毒 .将带有狂犬病毒糖蛋白 (GP)基因和加强型 GFP(enhanced GFP,EGFP)表达盒的重组穿梭质粒 p Ad- Track- CMV/ GP与腺病毒骨架载体质粒 p Ad Easy- 1一起同时电击共转化大肠杆菌 BJ51 83.在 BJ51 83细胞内 ,带有同源序列的重组穿梭质粒与骨架载体可进行同源重组 ,得到以质粒形式存在的克隆化重组腺病毒基因组 p Ad- GP’.以 p Ad- GP’为模板 ,经DNA测序确认 GP基因成功整合入此质粒中的腺病毒基因组 E1区外源基因表达盒中 .线形化的p Ad- GP’转染 2 93细胞后可得到基因组结构均一、在 E1区插入有 GP和 EGFP表达盒的重组腺病毒 ,病毒滴度可达 1× 1 0 8pfu/ ml.电镜下此重组病毒颗粒直径约为 70 nm,略呈球形 ,用荧光显微镜观察感染细胞有很强的 EGFP表达 .实验表明 :利用大肠杆菌同源重组获得克隆化的重组腺病毒基因组 DNA,可高效制备高滴度的均一重组腺病毒     

HAX1和EGFP共表达重组腺病毒载体的构建、鉴定

目的构建和鉴定HAX1和EGFP双基因共表达重组腺病毒载体。方法采用DNA重组技术,将目的基因HAX1克隆至含有报告基因EGFP的穿梭质粒pAdTrack—CMV中,并转化于大肠埃希菌DH5a;筛选出重组质粒pAdTrack—CMV—HAX1,并在BJ5183细菌中与pAdEasy-1质粒进行同源重组,产生重组腺病毒载体;用lipofectamine将其转染HEK293细胞,包装携带全长HAX1的重组复制缺陷型腺病毒pad—HAX1-EGFP,酶切和序列测定鉴定;用制备好的Ad—HAX1-EGFP感染HEK293细胞,流式细胞术检测其感染效率,RT—PCR、Western印迹鉴定外源基因HAX1的表达。BrdU检测感染了Ad—HAX1-EGFP的HEK293细胞增殖情况。结果pAdTrack—CMV—HAX1重组质粒构建成功。pAdTrack—CMV—HAX1质粒与pAdEasy-1质粒同源重组后与预期结果相符。构建好的Ad—HAX1-EGFP能有效感染HEK293细胞;外源基因能在239细胞中有效表达。HAX1高表达的HEK293细胞其增殖率得以提高。结论成功构建了表达HAX1和EGFP共表达的重组腺病毒载体,HAX1能够促进结肠癌细胞HEK293细胞的增殖。     

Cloning of infectious adeno-associated virus genomes in bacterial plasmids

We describe the construction of two Escherichia coli hybrid plasmids, each of which contains the entire 4.7-kb DNA genome of the human parvovirus, adeno-associated virus (AAV) type 2. Because the AAV genome was inserted into the plasmid DNA using BglII linkers the entire virus genome can be recovered by in vitro cleavage of the purified recombinant plasmid. Transfection of these recombinant DNAs into an adenovirus-transformed human cell line in the presence of helper adenovirus resulted in efficient rescue and replication of the AAV genome and production of fully infectious virus particles. These AAV-plasmid recombinant DNA molecules should be useful both for site-specific mutagenesis of the viral genome and to study the potential of AAV as a eukaryotic vector.     

Selective Modification of Adenovirus Replication Can Be Achieved through Rational Mutagenesis of the Adenovirus Type 5 DNA Polymerase

Mutations that reduce the efficiency of deoxynucleoside (dN) triphosphate (dNTP) substrate utilization by the HIV-1 DNA polymerase prevent viral replication in resting cells, which contain low dNTP concentrations, but not in rapidly dividing cells such as cancer cells, which contain high levels of dNTPs. We therefore tested whether mutations in regions of the adenovirus type 5 (Ad5) DNA polymerase that interact with the dNTP substrate or DNA template could alter virus replication. The majority of the mutations created, including conservative substitutions, were incompatible with virus replication. Five replication-competent mutants were recovered from 293 cells, but four of these mutants failed to replicate in A549 lung carcinoma cells and Wi38 normal lung cells. Purified polymerase proteins from these viruses exhibited only a 2- to 4-fold reduction in their dNTP utilization efficiency but nonetheless could not be rescued, even when intracellular dNTP concentrations were artificially raised by the addition of exogenous dNs to virus-infected A549 cells. The fifth mutation (I664V) reduced biochemical dNTP utilization by the viral polymerase by 2.5-fold. The corresponding virus replicated to wild-type levels in three different cancer cell lines but was significantly impaired in all normal cell lines in which it was tested. Efficient replication and virus-mediated cell killing were rescued by the addition of exogenous dNs to normal lung fibroblasts (MRC5 cells), confirming the dNTP-dependent nature of the polymerase defect. Collectively, these data provide proof-of-concept support for the notion that conditionally replicating, tumor-selective adenovirus vectors can be created by modifying the efficiency with which the viral DNA polymerase utilizes dNTP substrates.     

A deletion in the simian virus 40 large T antigen impairs lytic replication in monkey cells in vivo but enhances DNA replication in vitro: new complementation function of T antigen.

We describe a new complementation function within the simian virus 40 (SV40) A gene. This function is required for viral DNA replication and virus production in vivo but, surprisingly, does not affect any of the intrinsic enzymatic functions of T antigen directly required for in vitro DNA replication. Other well-characterized SV40 T-antigen mutants, whether expressed stably from integrated genomes or in cotransfection experiments, complement these mutants for in vivo DNA replication and plaque formation. These new SV40 mutants were isolated and cloned from human cells which stably carry the viral DNA. The alteration in the large-T-antigen gene was shown by marker rescue and nucleotide sequence analysis to be a deletion of 322 bp spanning the splice-donor site of the first exon, creating a 14-amino-acid deletion in the large T antigen. The mutant gene was expressed in H293 human cells from an adenovirus vector, and the protein was purified by immunoaffinity chromatography. The mutant protein directs greater levels of DNA replication in vitro than does the wild-type protein. Moreover, the mutant protein reduces the lag time for in vitro DNA synthesis and can be diluted to lower levels than wild-type T antigen and still promote good replication, which is in clear contrast to the in vivo situation. These biochemical features of the protein are independent of the source of the cellular replication factors (i.e., HeLa, H293, COS 7, or CV1 cells) and the cells from which the T antigens were purified. The mutant T antigen does not transform Rat-2 cells. Several different models which might reconcile the differences observed in vivo and in vitro are outlined. We propose that the function of T antigen affected prepares cells for SV40 replication by activation of a limiting cellular replication factor. Furthermore, a link between the induction of a cellular replication factor and transformation by SV40 is discussed.     

脂肪储存小滴蛋白5重组腺病毒的制备

目的：利用AdEasy腺病毒表达系统构建含有小鼠脂肪储存小滴蛋白5（LSDP5）基因的重组腺病毒。方法：从小鼠肝脏cDNA克隆出LSDP5基因全长,克隆至pMD18-T载体中,酶切测序。回收酶切产物,连接到腺病毒穿梭载体pShuttle-CMV,构建pShuttle-CMV-LSDP5重组质粒,经PmeI酶切线性化后转化至含有腺病毒骨架质粒pAdEasy-1的BJ5183中。筛选阳性克隆,提取重组质粒,PacI酶切线性化并转染AD293细胞进行包装,提取病毒DNA,鉴定重组病毒并检测病毒滴度。结果：LSDP5基因克隆经测序证实与Genebank公布一致,双酶切重组pMD18-T载体得到1400 bp左右的片段。重组穿梭载体经Kpn I和Sal I双酶切后得到预期片段。PacI酶切得到30 Kb大片段和4.5 Kb小片段。转染AD293细胞后收集病毒,经PCR鉴定,获得理想的目的片段。取病毒上清反复感染AD293细胞以扩增病毒,最后所得病毒滴度为2.5×109pfu/ml。结论：成功构建了携带脂肪储存小滴蛋白5基因的重组腺病毒载体,为进一步研究LSDP5基因功能奠定基础。     

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.     

The herpes simplex virus amplicon: a new eucaryotic defective-virus cloning-amplifying vector

We have employed repeat units of herpes simplex virus (HSV) defective genomes to derive a cloning-amplifying vector (amplicon) that can replicate in eucaryotic cells in the presence of standard HSV helper virus. The design of the HSV amplicon system is based on the previous observation that cotransfection of cells with helper virus DNA and seed monomeric repeat units of HSV defective genomes results in the regeneration of concatemeric defective genomes composed of multiple reiterations of the seed repeats. Cotransfection of cells with helper virus DNA and chimeric repeat units containing bacterial plasmid pKC7 DNA resulted in the generation of defective genomes composed of reiterations of the seed HSV-pKC7 repeats. These chimeric defective genomes were packaged into virus particles and could be propagated in virus stocks, with the most enriched passages containing more than 90% chimeric defective genomes. Furthermore, monomeric chimeric repeat units could be transferred back and forth between bacteria and eucaryotic cells. A derivative vector constructed so as to contain several unique restriction enzyme sites could be potentially employed in the introduction of additional viral or eucaryotic DNA sequences into eucaryotic cells.     

Transposase-mediated construction of an integrated adeno-associated virus type 5 helper plasmid

Adeno-associated viruses (AAVs) are replication-defective parvoviruses that require helper virusfunctionsfor efficient productive replication. The AAVs are currently premier candidates as vectors for human gene therapy applications. In particular; much recent interest has been expressed concerning recombinant AAV serotype 5 (rAAV-5) vectors, as they appear to utilize cellular receptors distinctfrom those of the prototypical AAV serotype (AAV-2) and have been reported to have transduction properties in vivo that differ significantly from those of the prototype. One of the most popular current methodsfor the production of rAAVs involves co-transfection of human 293 cells with three plasmids: (i) an adenovirus (Ad)-derived helper plasmid containing Ad genes required for AAV replication, (ii) an AAV-derived plasmid encoding complementing AAV genes (ie., the viral rep and cap genes), and (iii) a target plasmid containing a transgene of interestflanked by AAV inverted terminal repeats (ITRs) that confer packaging and replication capabilities upon the ITR-flanked heterologous DNA. Here we describe novel plasmid reagents designed for convenient and efficient production of rAAV-S. An integrated helper plasmid containing all Ad genes requiredfor the efficient production of recombinant AAV as well as the complementing AAV genes on the same plasmid backbone, was constructed via transposase-mediated insertion into an Ad helper plasmid of a transposable element containing the AAV-5 rep and cap genes linked to a selectable marker This simple strategy can be used in the rapid and efficient construction of integrated helper plasmids derived from any reported AAV serotype for which a molecular clone exists.     

Role of the Adenovirus DNA-Binding Protein in In Vitro Adeno-Associated Virus DNA Replication

A basic question in adeno-associated virus (AAV) biology has been whether adenovirus (Ad) infection provided any function which directly promoted replication of AAV DNA. Previously in vitro assays for AAV DNA replication, using linear duplex AAV DNA as the template, uninfected or Ad-infected HeLa cell extracts, and exogenous AAV Rep protein, demonstrated that Ad infection provides a direct helper effect for AAV DNA replication. It was shown that the nature of this helper effect was to increase the processivity of AAV DNA replication. Left unanswered was the question of whether this effect was the result of cellular factors whose activity was enhanced by Ad infection or was the result of direct participation of Ad proteins in AAV DNA replication. In this report, we show that in the in vitro assay, enhancement of processivity occurs with the addition of either the Ad DNA-binding protein (Ad-DBP) or the human single-stranded DNA-binding protein (replication protein A [RPA]). Clearly Ad-DBP is present after Ad infection but not before, whereas the cellular level of RPA is not apparently affected by Ad infection. However, we have not measured possible modifications of RPA which might occur after Ad infection and affect AAV DNA replication. When the substrate for replication was an AAV genome inserted into a plasmid vector, RPA was not an effective substitute for Ad-DBP. Extracts supplemented with Ad-DBP preferentially replicated AAV sequences rather than adjacent vector sequences; in contrast, extracts supplemented with RPA preferentially replicated vector sequences.     

Transient gene expression control: effects of transfected DNA stability and trans-activation by viral early proteins.

The effects of trans-acting factors and transfected DNA stability on promoter activity were examined with chloramphenicol acetyl transferase (CAT) transient expression analysis. With cotransfection into CV-1P and HeLa cells, simian virus 40 T antigen, adenovirus E1a, and herpes-virus IE proteins were compared for their ability to trans-activate a variety of eucaryotic promoters constructed into CAT plasmids. T antigen and the IE protein were promiscuous activators of all the promoters tested [the simian virus 40 late promoter, the adenovirus E3 promoter, the alpha 2(I) collagen promoter, and the promoter of the Rous sarcoma virus long terminal repeat]. Conversely the E1a protein was specific, activating only the adenovirus E3 promoter and suppressing the basal activity of the other promoters. This specificity of activation by E1a contrasted with the high activity generated by all of the promoter-CAT plasmids when transfected into 293 cells, which endogenously produce E1a protein. Examination of transfected 293 cells determined that they stabilized much greater amounts of plasmid DNA than any other cells tested (CV-1P, COS, NIH-3T3, KB). Thus the high activity of nonadenovirus promoter-CAT plasmids in 293 cells results from the cumulative effect of basal promoter activity from a very large number of gene copies, not from E1a activation. This conclusion was supported by similar transfection analysis of KB cell lines which endogenously produce E1a protein. These cells stabilize plasmid DNA at a level comparable to that of CV-1P cells and, in agreement with the CV-1P cotransfection results, did not activate a nonadenovirus promoter-CAT plasmid. These results indicate that the stability of plasmid DNA must be considered when transient gene expression is being compared between cell lines. The use of relative plasmid copy numbers for the standardization of transient expression results is discussed.     

Rescue and Autonomous Replication of Adeno-Associated Virus Type 2 Genomes Containing Rep-Binding Site Mutations in the Viral p5 Promoter

The Rep proteins encoded by the adeno-associated virus type 2 (AAV) play a crucial role in the rescue, replication, and integration of the viral genome. In the absence of a helper virus, little expression of the AAV Rep proteins occurs, and the AAV genome fails to undergo DNA replication. Since previous studies have established that expression of the Rep78 and Rep68 proteins from the viral p5 promoter is controlled by the Rep-binding site (RBS) and the YY1 factor-binding site (YBS), we constructed a number of recombinant AAV plasmids containing mutations and/or deletions of the RBS and the YBS in the p5 promoter. These plasmids were transfected in HeLa or 293 cells and analyzed for the potential to undergo AAV DNA rescue and replication. Our studies revealed that (i) a low-level rescue and autonomous replication of the wild-type AAV genome occurred in 293 but not in HeLa cells; (ii) mutations in the RBS resulted in augmented expression from the p5 promoter, leading to more efficient rescue and/or replication of the AAV genome in 293 but not in HeLa cells; (iii) little rescue and/or replication occurred from plasmids containing mutations in the YBS alone in the absence of coinfection with adenovirus; (iv) expression of the adenovirus E1A gene products was insufficient to mediate rescue and/or replication of the AAV genome in HeLa cells; (v) autonomously replicated AAV genomes in 293 cells were successfully encapsidated in mature progeny virions that were biologically active in secondary infection of HeLa cells in the presence of adenovirus; and (vi) stable transfection of recombinant AAV plasmids containing a gene for resistance to neomycin significantly affected stable integration only in 293 cells, presumably because rescue and autonomous replication of the AAV genome from these plasmids occurred in 293 cells but not in HeLa or KB cells. These data suggest that in the absence of adenovirus, the AAV Rep protein-RBS interaction plays a dominant role in down-regulating viral gene expression from the p5 promoter and that perturbation in this interaction is sufficient to confer autonomous replication competence to AAV in 293 cells.