Adeno-associated virus proteins: origin of the capsid components

Combined 100 keV Cryo-Electron Microscopy and Image Analysis Methods to Characterize the Wider Adeno-Associated Viral Products

Adeno-associated viruses (AAVs) are effective vectors for gene therapy. However, AAV drug products are inevitably contaminated with empty particles (EP), which lack a genome, owing to limitations of the purification steps. EP contamination can reduce the transduction efficiency and induce immunogenicity. Therefore, it is important to remove EPs and to determine the ratio of full genome-containing AAV particles to empty particles (F/E ratio). However, most of the existing methods fail to reliably evaluate F/E ratios that are greater than 90 %. In this study, we developed two approaches based on the image analysis of cryo-electron micrographs to determine the F/E ratios of various AAV products. Using our developed convolutional neural network (CNN) and morphological analysis, we successfully calculated the F/E ratios of various AAV products and determined the slight differences in the F/E ratios of highly purified AAV products (purity > 95 %). In addition, the F/E ratios calculated by analyzing more than 1000 AAV particles had good correlations with theoretical F/E ratios. Furthermore, the CNN reliably determined the F/E ratio with a smaller number of AAV particles than morphological analysis. Therefore, combining 100 keV cryo-EM with the developed image analysis methods enables the assessment of a wide range of AAV products.

High throughput screening of novel AAV capsids identifies variants for transduction of adult NSCs within the subventricular zone

The adult mammalian brain entails a reservoir of neural stem cells (NSCs) generating glial cells and neurons. However, NSCs become increasingly quiescent with age, which hampers their regenerative capacity. New means are therefore required to genetically modify adult NSCs for re-enabling endogenous brain repair. Recombinant adeno-associated viruses (AAVs) are ideal gene-therapy vectors due to an excellent safety profile and high transduction efficiency. We thus conducted a high-throughput screening of 177 intraventricularly injected barcoded AAV variants profiled by RNA sequencing. Quantification of barcoded AAV mRNAs identified two synthetic capsids, peptide-modified derivative of wild-type AAV9 (AAV9_A2) and peptide-modified derivative of wild-type AAV1 (AAV1_P5), both of which transduce active and quiescent NSCs. Further optimization of AAV1_P5 by judicious selection of the promoter and dose of injected viral genomes enabled labeling of 30%–60% of the NSC compartment, which was validated by fluorescence-activated cell sorting (FACS) analyses and single-cell RNA sequencing. Importantly, transduced NSCs readily produced neurons. The present study identifies AAV variants with a high regional tropism toward the ventricular-subventricular zone (v-SVZ) with high efficiency in targeting adult NSCs, thereby paving the way for preclinical testing of regenerative gene therapy.

Recent Advances in Molecular Biology of Human Bocavirus 1 and Its Applications

Human bocavirus 1 (HBoV1) was discovered in human nasopharyngeal specimens in 2005. It is an autonomous human parvovirus and causes acute respiratory tract infections in young children. HBoV1 infects well differentiated or polarized human airway epithelial cells in vitro. Unique among all parvoviruses, HBoV1 expresses 6 non-structural proteins, NS1, NS1-70, NS2, NS3, NS4, and NP1, and a viral non-coding RNA (BocaSR), and three structural proteins VP1, VP2, and VP3. The BocaSR is the first identified RNA polymerase III (Pol III) transcribed viral non-coding RNA in small DNA viruses. It plays an important role in regulation of viral gene expression and a direct role in viral DNA replication in the nucleus. HBoV1 genome replication in the polarized/non-dividing airway epithelial cells depends on the DNA damage and DNA repair pathways and involves error-free Y-family DNA repair DNA polymerase (Pol) η and Pol κ. Importantly, HBoV1 is a helper virus for the replication of dependoparvovirus, adeno-associated virus (AAV), in polarized human airway epithelial cells, and HBoV1 gene products support wild-type AAV replication and recombinant AAV (rAAV) production in human embryonic kidney (HEK) 293 cells. More importantly, the HBoV1 capsid is able to pseudopackage an rAAV2 or rHBoV1 genome, producing the rAAV2/HBoV1 or rHBoV1 vector. The HBoV1 capsid based rAAV vector has a high tropism for human airway epithelia. A deeper understanding in HBoV1 replication and gene expression will help find a better way to produce the rAAV vector and to increase the efficacy of gene delivery using the rAAV2/HBoV1 or rHBoV1 vector, in particular, to human airways. This review summarizes the recent advances in gene expression and replication of HBoV1, as well as the use of HBoV1 as a parvoviral vector for gene delivery.

Custom adeno-associated virus capsids: the next generation of recombinant vectors with novel tropism

Recombinant gene delivery vehicles based on adeno-associated virus (rAAV) have emerged as promising vectors for the correction of genetic and acquired human disease states. These vectors possess many characteristics, including low pathogenicity and immunogenicity, and long-term gene expression after a single administered dose, that make them leading candidates for clinical gene therapy applications. Yet, the broad tissue tropism of the available AAV serotypes remains a disadvantage for the safest, most effective in vivo delivery of transgenes to target tissues. In addition, clinically relevant cell types exist that are poorly transduced by current rAAV vectors. As a result, increased efforts are now being made to tailor the tropism of rAAV to improve their transduction and selectivity profiles. Flexible, diverse methodologies have emerged that allow more control over the cell surface receptors rAAV employs for cell entry. These novel rAAV production strategies have resulted in unique vectors characterized by unique capsid protein sequences that employ alternative receptors, and have provided a better understanding of many basic aspects of the rAAV life cycle. This review aims to summarize the genetic methods currently being employed to customize rAAV capsids.

Adeno-associated virus type 2 VP2 capsid protein is nonessential and can tolerate large peptide insertions at its N terminus

Direct insertion of amino acid sequences into the adeno-associated virus type 2 (AAV) capsid open reading frame (cap ORF) is one strategy currently being developed for retargeting this prototypical gene therapy vector. While this approach has successfully resulted in the formation of AAV particles that have expanded or retargeted viral tropism, the inserted sequences have been relatively short, linear receptor binding ligands. Since many receptor-ligand interactions involve nonlinear, conformation-dependent binding domains, we investigated the insertion of full-length peptides into the AAV cap ORF. To minimize disruption of critical VP3 structural domains, we confined the insertions to residue 138 within the VP1-VP2 overlap, which has been shown to be on the surface of the particle following insertion of smaller epitopes. The insertion of coding sequences for the 8-kDa chemokine binding domain of rat fractalkine (CX3CL1), the 18-kDa human hormone leptin, and the 30-kDa green fluorescent protein (GFP) after residue 138 failed to lead to formation of particles due to the loss of VP3 expression. To test the ability to complement these insertions with the missing capsid proteins in trans, we designed a system for producing AAV vectors in which expression of one capsid protein is isolated and combined with the remaining two capsid proteins expressed separately. Such an approach allows for genetic modification of a specific capsid protein across its entire coding sequence leaving the remaining capsid proteins unaffected. An examination of particle formation from the individual components of the system revealed that genome-containing particles formed as long as the VP3 capsid protein was present and demonstrated that the VP2 capsid protein is nonessential for viral infectivity. Viable particles composed of all three capsid proteins were obtained from the capsid complementation groups regardless of which capsid proteins were supplied separately in trans. Significant overexpression of VP2 resulted in the formation of particles with altered capsid protein stoichiometry. The key finding was that by using this system we successfully obtained nearly wild-type levels of recombinant AAV-like particles with large ligands inserted after residue 138 in VP1 and VP2 or in VP2 exclusively. While insertions at residue 138 in VP1 significantly decreased infectivity, insertions at residue 138 that were exclusively in VP2 had a minimal effect on viral assembly or infectivity. Finally, insertion of GFP into VP1 and VP2 resulted in a particle whose trafficking could be temporally monitored by using confocal microscopy. Thus, we have demonstrated a method that can be used to insert large (up to 30-kDa) peptide ligands into the AAV particle. This system allows greater flexibility than current approaches in genetically manipulating the composition of the AAV particle and, in particular, may allow vector retargeting to alternative receptors requiring interaction with full-length conformation-dependent peptide ligands.

Insertional mutagenesis of the adeno-associated virus type 2 (AAV2) capsid gene and generation of AAV2 vectors targeted to alternative cell-surface receptors

Recombinant adeno-associated virus (AAV) vectors are of interest in the context of gene therapy because of their ability to mediate efficient transfer and stable expression of therapeutic genes in a wide variety of tissues. However, AAV-mediated gene delivery to specific cell populations is often precluded by the widespread distribution of heparan sulfate proteoglycan (HSPG), the primary cellular receptor for the virus. Conversely, an increasing number of cell types are being identified that do not express HSPG and are therefore poor targets for AAV-mediated gene transfer. To address these issues, we have developed strategies to physically modify AAV vectors and allow efficient, HSPG-independent, receptor-targeted infection. We began by generating a series of 38 virus capsid mutants containing peptide insertions at 25 unique sites within the AAV capsid protein. The mutant viruses were characterized on the basis of their phenotypes and grouped into three classes: class I mutants (4 of 38) did not assemble particles; class II mutants (14 of 38) assembled noninfectious particles; and class III mutants (20 of 38) assembled fully infectious particles. We examined the HSPG-binding characteristics of the class II mutants and showed that a defect in receptor binding was a common reason for their lack of infectivity. The display of foreign peptide epitopes on the surface of the mutant AAV particles was found to be highly dependent on the inclusion of appropriate scaffolding sequences. Optimal scaffolding sequences and five preferred sites for the insertion of targeting peptide epitopes were identified. These sites are located within each of the three AAV capsid proteins, and thus display inserted epitopes 3, 6, or 60 times per vector particle. Modified AAV vectors displaying a 15-amino acid peptide, which binds to the human luteinizing hormone receptor (LH-R), were generated and assessed for their ability to target gene delivery to receptor-bearing cell lines. Titers of these mutant vectors were essentially the same as wild-type vector. The LH-R-targeted vector was able to transduce ovarian cancer cells (OVCAR-3) in an HSPG-independent manner. Furthermore, transduction was shown to proceed via the LH-R and therefore treatment of OVCAR-3 cells with progesterone, to increase LH-R expression, accordingly increased LH mutant-mediated gene transfer. This technology may have a significant impact on the use of AAV vectors for human gene therapy.

Induction of circular episomes during rescue and replication of adeno-associated virus in experimental models of virus latency

The synthesis of linear duplex replicative structures (monomers, head-to-head, and tail-to-tail dimers) is an important hallmark of the productive phase of the adeno-associated virus (AAV) life cycle. These structures are generated by a strand-displacement replication mechanism and believed to be a reservoir for single-stranded DNA genomes. During the course of studies with recombinant versions of AAV (rAAV), we discovered the assembly of circular duplex provirus derivatives in latently infected cell lines under conditions permissive for replication (i.e., helper virus dependent). These novel structures were cloned by bacterial trapping revealing a markedly homogeneous structure that included a single copy of the rAAV genome joined head-to-tail about the inverted terminal repeats (ITR). Restriction and sequence analysis of the point of circularization revealed a so-called "TRT" domain, consisting of a single ITR hairpin palindrome flanked by 5' and 3' D sequence elements. The circular conformation was additionally characterized by Southern blotting and confirmed by purification on an ethidium bromide-CsCl gradient where the buoyant density was consistent with circular supercoiled DNA. These findings suggest that AAV replication is accompanied by the assembly of circular duplex structures.

Insertional mutagenesis of AAV2 capsid and the production of recombinant virus

The structural genes of adeno-associated virus serotype 2 (AAV2) have been altered by linker insertional mutagenesis in order to define critical components of virion assembly and infectivity. An in-frame restriction site linker was inserted across the capsid coding domain of a recombinant plasmid. After complementation in vivo, recombinant AAV2 viruses were generated and assayed for capsid production, packaging, transduction, heparin agarose binding, and morphology. Three classes of capsid mutants where identified. Class I mutants expressed structural proteins but were defective in virion assembly. Class II mutants generated intact virions that protected the viral genome from DNase, but failed to infect target cells. The majority of these mutants bound the heparin affinity matrix, suggesting that attachment to the AAV primary receptor was not rate limiting. One class II mutant, H2634, assembled virions and bound heparin using only Vp3, indicating that this subunit is responsible for mediating AAV receptor attachment. Finally, class III mutants assembled virions, encapsidated DNA, and infected target cells. Infectivity of these mutants ranged from 5 to 100% of that of the wild-type, demonstrating for the first time the ability to alter capsid proteins without interfering with infectivity. These AAV virions with altered capsid subunits will provide critical templates for manipulating AAV vectors for cell-specific gene delivery in vivo. In summary, the AAV capsid variants described here will facilitate further study of virus assembly, entry, and infection, as well as advance the development of this versatile vector system.

Efficient production of adeno-associated virus vectors using split-type helper plasmids

Adeno-associated virus (AAV) vectors are potentially useful vehicles for the delivery of therapeutic genes into human cells. To determine the optimal expression pattern of AAV proteins (Rep78, Rep68, Rep52, Rep40, and Cap proteins) for packaging the recombinant AAV genome, helper plasmids were split into two portions. In this study, two sets of split-type helper plasmids were prepared; i.e., 1) a Rep expression plasmid (pRep) and Cap expression plasmid (pCap), and 2) a large Rep expression plasmid (pR78/68) and small Rep plus Cap expression plasmid (pR52/40Cap). When AAV vectors were produced using these sets of split-type helper plasmids at various ratios, the optimal ratio of (large) Rep expression plasmid and Cap expression plasmid was 1 to 9 for both sets. More importantly, the titers were comparable to or even higher than that of a conventional helper plasmid (pIM45) (4.9+/-2.1x10(11) vector particles/10 cm dish for pRep and pCap; 2.9+/-1.6x10(11) vector particles/10 cm dish for pR78/68 and pR52/40Cap; and 1.8+/-0.16x10(11) particles/10 cm dish for pIM45). Western analysis of AAV proteins suggests that the expression of a relatively small amount of large Rep and a large amount of Cap is important for optimal vector production. The present study shows that the AAV helper plasmid can be split without losing the ability to package the recombinant AAV genome, and provides us with valuable basic information for the development of efficient AAV packaging cell lines.

The use of heterologous promoters for adeno-associated virus (AAV) protein expression in AAV vector production

Although adeno-associated virus (AAV) vectors are potentially useful gene transfer vehicles for gene therapy, the vector production system is currently at the developmental stage. We constructed AAV helper plasmids (Rep and Cap expression plasmids) by replacing a native AAV promoter, p5, with various heterologous promoters to examine whether the efficiency of AAV vector production was influenced by modulating the AAV protein expression pattern. The helper plasmids containing heterologous promoters (EF, CMV, SV40, B19p6, and CAG promoters, respectively) expressed Rep78/68 more efficiently than a conventional helper plasmid (pIM45), but the expression of Rep52/40 and Cap decreased, resulting in a significant reduction in AAV vector production. Furthermore, the efficiency of vector production never fully recovered even if the Cap proteins were supplied by an additional expression plasmid. A large amount of Rep78/68 and/or a reduced level of Rep52/40 may have deleterious effects on AAV vector production. The present findings will aid in the development of a more efficient AAV vector production system.

The adeno-associated virus type 2 p40 promoter requires a proximal Sp1 interaction and a p19 CArG-like element to facilitate Rep transactivation

We have identified the sequence elements that are required for adeno-associated virus type 2 p40 promoter activity. Mutation of specific promoter elements showed that two Sp1 sites at approximately -50 (Sp1-50) and -70 (GGT-70) bp upstream of the start of the p40 messages were necessary for maximal promoter activity. As expected, the TATA site at -30 was also essential. In vitro DNA binding experiments confirmed that the Sp1-50 and GGT-70 sites were bound by Sp1 or Sp1-like proteins. Two other transcription elements, the ATF-80 and AP1-40 sites, may play a role in p40 activity. Mutation of these elements resulted in a modest decrease in p40 transcription, but DNA binding experiments did not clearly demonstrate binding of transcription factors to these sites. In contrast, a major late transcription factor site at -110 was shown to bind the transcription factor, but mutation of this site had no effect on p40 activity. In a previous report, we have shown that transactivation of the p40 promoter by the viral Rep proteins required an upstream Rep binding element (in the terminal repeat or the p5 promoter), an unidentified p19 promoter element, and a p40 promoter element (D. J. Pereira and N. Muzyczka, J. Virol. 71:1747-1756, 1997). Here we demonstrate that the CArG-140 element in the p19 promoter and the Sp1-50 element in the p40 promoter are the specific p19 and p40 elements required for Rep induction of p40. As in the case of the p19 promoter, Sp1 facilitates interaction of Rep with the p40 promoter by interaction of the two proteins. Furthermore, electron microscopy experiments demonstrated that when Rep is bound to an upstream Rep binding element, it can interact with a proximal Sp1 site by protein contacts and create a loop in the intervening DNA. This finding suggests a common mechanism whereby the Rep binding element in the TR or the p5 promoter induces p19 and p40 activity by interaction with their respective Sp1 sites.

The cellular transcription factor SP1 and an unknown cellular protein are required to mediate Rep protein activation of the adeno-associated virus p19 promoter

Control of adeno-associated virus (AAV) transcription from the three AAV promoters (p5, p19, and p40) requires the adenovirus E1a protein and the AAV nonstructural (Rep) proteins. The Rep proteins have been shown to repress the AAV p5 promoter yet facilitate activation of the p19 and p40 promoters during a productive infection. To elucidate the mechanism of promoter regulation by the AAV Rep proteins, the cellular factors involved in mediating Rep activation of the p19 promoter were characterized. A series of protein-DNA binding experiments using extracts derived from uninfected HeLa cells was performed to identify cellular factors that bind to the p19 promoter. Electrophoretic mobility shift assays, DNase I protection analyses, and UV cross-linking experiments demonstrated specific interactions with the cellular factor SP1 (or an SP1-like protein) at positions -50 and -130 relative to the start of p19 transcription. Additionally, an unknown cellular protein (cellular AAV activating protein [cAAP]) with an approximate molecular mass of 34 kDa was found to interact with a CArG-like element at position -140. Mutational analysis of the p19 promoter suggested that the SP1 site at -50 and the cAAP site at -140 were necessary to mediate Rep activation of p19. Antibody precipitation experiments demonstrated that Rep-SP1 protein complexes can exist in vivo. Although Rep was demonstrated to interact with p19 DNA directly, the affinity of Rep binding was much lower than that seen for the Rep binding elements within the terminal repeat and the p5 promoter. Furthermore, the interaction of purified Rep68 with the p19 promoter in vitro was negligible unless purified SP1 was also added to the reaction. Thus, the ability of Rep to transactivate the p19 promoter is likely to involve SP1-Rep protein contacts that facilitate Rep interaction with p19 DNA.

The adeno-associated virus (AAV) Rep protein acts as both a repressor and an activator to regulate AAV transcription during a productive infection

Adeno-associated virus (AAV) uses three promoters, p5, p19, and p40, to regulate viral gene expression. The p5 and p19 promoters direct the synthesis of the viral regulatory proteins, Rep78 and -68 and Rep52 and -40, respectively. The p5 Rep proteins bind a linear 22-bp sequence, the Rep binding element (RBE), that is within both the terminal repeat (TR) and the p5 promoter. In the absence of helper virus, all four Rep proteins have been shown to reduce transcription from the viral p5 and p19 promoters. In this report, we focus on the roles of these proteins and the RBEs in controlling transcription during a productive infection, that is, in the presence of adenovirus. We find that in the presence of adenovirus, the p5 RBE represses p5 transcription while the RBE in the TR activates p5. However, both the TR RBE and the p5 RBE transactivate the p19 and p40 promoters. The fact that the p5 RBE-Rep complex can transactivate p19 and p40 while repressing p5 suggests that Rep78/68 is both a repressor and a transactivator. Rep repression of p5 is specific for the p5 RBE, as other p5 promoter elements do not support this activity. We also demonstrate that in the presence of adenovirus, the p19 Rep proteins, which do not bind to the RBE, can eliminate repression of the p5 promoter by Rep78 and Rep68. This may occur by the association of Rep52 with Rep78 or Rep68 to produce a Rep78/68-Rep52 protein complex which can be detected in vivo by immunoprecipitation. Finally, two Rep mutants that were deficient in RBE binding and transactivation but positive for p5 repression were identified. These mutants may define interaction domains involved in making contacts with other proteins that facilitate repression. These observations suggest a mechanism for controlling the p5 and p19 mRNA levels during a productive AAV infection.

Site-directed mutagenesis of adeno-associated virus type 2 structural protein initiation codons: effects on regulation of synthesis and biological activity

It has been shown that two of the three adeno-associated virus type 2 capsid proteins, B and C, are synthesized from a single spliced transcript. Protein C arises from an AUG codon at nucleotide 2810, whereas protein B is initiated by a unique eucaryotic initiation codon (ACG) that lies 65 triplets upstream from the C origin. The third capsid component, protein A, is synthesized from a second spliced transcript which uses an alternative 3' acceptor site. In this study we used oligonucleotide-directed mutagenesis to confirm the positions of the B initiation codon and the 3' acceptor sites for the alternatively spliced B/C and A protein messages. We also located definitively the protein A initiation codon, an AUG triplet mapping to nucleotide 2203. Mutagenesis of the B initiator permitted a direct test of the effect of increased B initiator strength on the translational efficiencies of the B and C proteins. It was found that conversion of the relatively inefficient protein B initiator (ACG) to an AUG enhanced the level of B synthesis while abolishing the synthesis of C from its downstream AUG initiator. Protein C synthesis thus depends on the strength of the B initiator, i.e., the relatively higher levels of C (approximately 20-fold greater than B) must result from frequent readthrough of the weak B initiator. Finally, we examined the abilities of mutants deficient in the synthesis of A, B, or C to produce infectious virions. We found that at least two of the structural proteins, B and C, are required for the production of infectious virions and that sequestration of single-stranded adeno-associated virus genomes from the pool of replicating DNA molecules does not occur in the absence of either of these proteins.

Replication of adeno-associated virus type 2 in human lymphocytic cells and interaction with HIV-1

Adeno-associated virus (AAV) is a nonpathogenic parvovirus which normally requires helper adenovirus or herpes-virus for replication. We examined the growth of AAV type 2 in human lymphocytes and its possible interaction with HIV-1. Three B cell lines (CK-B, HS-2, and UC729) and four T cell lines (Molt-4, Jurkat, HUT78, and HUT78+HIV, which is persistently infected with HIV-1) were infected with AAV either in the presence or in the absence of adenovirus. AAV DNA was found in cells of all the lines following incubation with the virus, indicating absorption. AAV DNA replication occurred in most cell lines without particular preference for B or T cells, but only in the presence of helper virus, either adenovirus or Epstein-Barr virus. Expression of AAV proteins was examined by immunoblotting and ELISA, using sera specific for AAV Rep or capsid proteins. The level of AAV protein synthesis correlated with the efficiency of AAV DNA replication, and both varied between cell lines. The yield of infectious AAV was low in most cases, except in one T4 line (Jurkat), where AAV replication and protein synthesis in the presence of adenovirus were very extensive. In HUT78+HIV cells both adenovirus and AAV (in the presence of Ad2) replicated efficiently. The effects of adenovirus plus AAV coinfections on HIV-1 replication, measured by reverse-transcriptase (RT) activity, were mild. Infection with adenovirus or AAV alone resulted in a 60-70% increase in RT activity, while infection with AAV plus adenovirus resulted in a 20% decrease in RT activity. The yield of infectious AAV in this cell line was very low.

Topographical analysis of the G virion of Aleutian mink disease parvovirus with monoclonal antibodies

The topography of the Aleutian mink disease parvovirus (ADV) G virion was analyzed with monoclonal antibodies and polyclonal antiserum. There was homology between the two major structural proteins as others have previously reported. Trypsin treatment of the virion with subsequent immunoblotting revealed that VP2 represents the main peptide on the exterior of virion and that VP1 is probably embedded within the capsid. Additional analyses of the trypsin-treated virions showed that VP2 is responsible for binding complement and that it also represents the structural part of the virion that binds to cellular receptors. A third protein, p34, was detected that might represent a third structural polypeptide because of its many unique epitopes relative to the other peptides detected.

The densovirus of Junonia coenia (Jc DNV) as an insect cell expression vector

An infectious genome of the Junonia coenia densovirus (Jc DNV) has been recently cloned and sequenced. We investigated the ability of this cloned genome to be used as expression vector by inserting the lacZ gene of Escherichia coli as fusion gene in the major open reading frame (ORF 1) of the viral sequence. The resulting recombinant plasmid designated pBRJlac Z was transfected into insect SPC-SL 52 cells and the expression of beta-galactosidase (beta-gal) was detected qualitatively or quantitatively by using Xgal or ONPG as chromogenic substrates. Western blot analysis revealed that beta-gal was expressed as chimeric capsid-beta-gal polypeptides. This provided evidence that ORF1 codes for structural polypeptides which share a common C-terminal sequence. Construction of plasmids with alterations or deletions in ORF2, 3 or 4, allowed us to implicate nonstructural (NS) functions in viral DNA replication. Deletions in inverted terminal repeats or in NS functions did not abolish expression of capsid polypeptides but reduced it dramatically. Encapsidation of Jlac Z recombinant genome was achieved by trans-complementation with plasmids bearing intact structural and nonstructural functions. Detection of a beta-gal activity in SPC-SL 52 cells following several subcultures post-transfection suggests that Jlac Z recombinant genome could be maintained in an integrative or episomal state.

Adeno-associated viruses having nonsense mutations in the capsid genes: growth in mammalian cells containing an inducible amber suppressor

When an adeno-associated virus (AAV) genome contained in a recombinant plasmid is transfected into adenovirus-infected cells, infectious AAV particles are efficiently generated. We previously described the construction of a conditional lethal mutant of AAV having an amber termination codon inserted in the rep gene. This mutant was propagated on a monkey kidney cell line (SupD12) having an inducible amber suppressor tRNAser. We now describe the construction and propagation of two additional conditional lethal mutants of AAV having amber codons affecting all three capsid proteins (AAV Capam) or only the VP1 capsid protein (AAV VP1am). Suppression of the amber mutations in the capsid proteins was demonstrated directly by immunoblot analysis. The efficiency of amber suppression on the SupD12 cell was about 6 to 10% for AAV VP1am and 4 to 5% for AAV Capam. The reversion frequency of either mutant was apparently less than 10(-5). On nonsuppressing cells AAV VP1am exhibited an Lip (Inf) phenotype, whereas AAV Capam exhibited a Cap phenotype.

Sequences required for coordinate induction of adeno-associated virus p19 and p40 promoters by Rep protein

A series of contiguous 30-bp deletions were introduced into the regions upstream of the p19 and p40 promoters of adeno-associated virus (AAV), and the effects of these deletions on induction of AAV transcription by the rep gene products was evaluated. A novel complementation system was devised for supplying wild-type Rep protein when mutations disrupted the trans activation activity of the Rep protein. Transcription from the p40 promoter was eliminated upon deletion of the TATA sequence located between -4 and -33 from the cap site. Deletions which removed sequences from -34 to -123 bp from the p40 mRNA start site substantially reduced Rep induction of p40 transcription. p19 transcription was also undetectable when the p19 TATA sequence between -4 and -33 was deleted. In contrast to the p40 region, two types of cis-active sequences were found associated with the p19 promoter. Sequences between -4 and -63 bp relative to the p19 cap site were essential for Rep induction only from the p19 promoter. Deletions between -94 and -153 bp relative to the p19 cap site reduced Rep induction of both the p19 and p40 promoters coordinately. These two noncontiguous regions were separated by a 30-bp sequence that was not essential for transcription control. Further deletion analysis delineated a second cis-active element, associated with the p5 promoter (AAV nucleotides 191 to 320), which was also necessary for coordinate Rep activation of both the p19 and p40 promoters. Finally, the dependence of p40 transcription on the Rep-responsive elements within the p5 and p19 regions could be overcome by the presence of the AAV terminal repeats, suggesting that the terminal repeats contained redundant Rep-responsive elements. These results implied an interdependence in cis between the three AAV promoters and suggested a novel mechanism for coordinate regulation of gene expression in response to the trans-activating Rep protein. Coordinate induction appeared to be the result of a simultaneous interaction between the Rep protein and sequence elements associated with two or all three of the AAV promoters.

Efficient synthesis of adeno-associated virus structural proteins requires both adenovirus DNA binding protein and VA I RNA

We have shown previously that replication of defective parvoviruses [adeno-associated viruses (AAV)] requires several early adenovirus (Ad) gene products [J. E. Janik, M. M. Huston, and J. A. Rose (1981) Proc. Natl. Acad. Sci. USA 78, 1925-1929]. To examine their possible roles in the transcription and translation of AAV mRNA, 293-31 cells, a human embryonic kidney cell line that constitutively expresses the Ad early region IA and IB gene products, were transfected with a pBR325 plasmid (pLH1) that contains a duplex AAV2 DNA segment (0.03-0.97 map units) which encompasses the promoters and coding sequences necessary for expression of all AAV polypeptides. When cells were transfected with pLH1 alone, both spliced and unspliced AAV-specific cytoplasmic RNAs accumulated. These transcripts were capable of directing synthesis of the three AAV capsid polypeptides in vitro, whereas in vivo synthesis of AAV protein was not detected by immunofluorescence or immunoprecipitation. When cells were cotransfected with pLH1 and intact Ad DNA, the level of cytoplasmic AAV RNA was enhanced and AAV protein was synthesized in vivo. Additional experiments demonstrated that in vivo AAV protein synthesis also could be induced when pLH1 was cotransfected with plasmids that contain the Ad DNA-binding protein (pDBP) and VA I RNA (p2BalM) genes; however, a low level of in vivo AAV capsid protein was occasionally detected in cotransfections with pLH1 and a plasmid that contains both VA I and VA II RNA coding sequences (p2SalC). Cotransfection of pLH1 and pDBP or pLH1 and p2SalC showed complex alterations in the steady-state patterns of AAV cytoplasmic transcripts. In both cases, increased levels of transcripts, particularly the 2.3-kb spliced species, were detected in comparison to levels seen in cells transfected with pLH1 alone. Despite these increases, however, there was little, if any, induction of AAV protein synthesis unless both the DNA-binding protein (DBP) and VA I RNA coding sequences were present in cotransfection with pLH1. We conclude that, in 293-31 cells, the Ad VA I RNA and DBP gene products regulate AAV capsid protein synthesis at least at two levels: (i) by increasing the steady-state levels of structural protein transcripts in the cytoplasm, especially the spliced species, and (ii) by enhancing the translation of these messages.

Adeno-associated virus rep protein synthesis during productive infection

Adeno-associated virus (AAV) Rep proteins mediate viral DNA replication and can regulate expression from AAV genes. We studied the kinetics of synthesis of the four Rep proteins, Rep78, Rep68, Rep52, and Rep40, during infection of human 293 or KB cells with AAV and helper adenovirus by in vivo labeling with [35S]methionine, immunoprecipitation, and immunoblotting analyses. Rep78 and Rep52 were readily detected concomitantly with detection of viral monomer duplex DNA replicating about 10 to 12 h after infection, and Rep68 and Rep40 were detected 2 h later. Rep78 and Rep52 were more abundant than Rep68 and Rep40 owing to a higher synthesis rate throughout the infectious cycle. In some experiments, very low levels of Rep78 could be detected as early as 4 h after infection. The synthesis rates of Rep proteins were maximal between 14 and 24 h and then decreased later after infection. Isotopic pulse-chase experiments showed that each of the Rep proteins was synthesized independently and was stable for at least 15 h. A slower-migrating, modified form of Rep78 was identified late after infection. AAV capsid protein synthesis was detected at 10 to 12 h after infection and also exhibited synthesis kinetics similar to those of the Rep proteins. AAV DNA replication showed at least two clearly defined stages. Bulk duplex replicating DNA accumulation began around 10 to 12 h and reached a maximum level at about 20 h when Rep and capsid protein synthesis was maximal. Progeny single-stranded DNA accumulation began about 12 to 13 h, but most of this DNA accumulated after 24 h when Rep and capsid protein synthesis had decreased.

Alternate mRNA splicing is required for synthesis of adeno-associated virus VP1 capsid protein

Fine-structure mapping of the capsid-specific mRNAs from adeno-associated virus (AAV) revealed an alternate splicing pattern in these RNAs. S1 nuclease and primer extension analyses showed that splicing of these mRNAs occurs at acceptor sites at nucleotide 2228 (major splice) or 2201 (minor splice). Both splice acceptors were ligated to the same 55-nucleotide leader in mature mRNAs. Both species were present in equal amounts in mRNA derived from AAV plasmid-transfected cells. However, when adenovirus infection accompanied the DNA transfection, the major splice predominated over the minor splice. Using cDNA clones of both the major and minor spliced mRNAs, we demonstrated that the largest AAV capsid protein, VP1, was derived from the minor spliced mRNA. The other capsid proteins, VP2 and VP3, came predominantly from the major spliced mRNA. These results, which describe the previously undetected minor splice, provide a mechanism for the production of all three AAV virion proteins.

Synthesis of adeno-associated virus structural proteins requires both alternative mRNA splicing and alternative initiations from a single transcript

The three adeno-associated virus type 2 (AAV2) structural proteins (A, B, and C) are specified by transcripts generated from the most-rightward promoter (p40). Protein C (60 kilodaltons [kDa]), the most abundantly produced, is entirely contained within B (72 kDa) which, in turn, is contained within A (90 kDa). Although neither of the known structures of p40 transcripts, an unspliced 2.6-kilobase (kb) RNA and a spliced 2.3-kb RNA, possesses an AUG-initiated open reading frame that accounts for the synthesis of proteins A and B, recent evidence indicates that B is initiated by a unique eucaryotic initiation codon (ACG) (S.P. Becerra, J.A. Rose, M. Hardy, B. Baroudy, and C.W. Anderson, Proc. Natl. Acad. Sci. USA 82:7919-7923, 1985). In the present study, we analyzed the in vitro translation of AAV capsid proteins from synthetic transcripts and the in vivo expression of AAV mRNA and capsid proteins in 293 cells transfected with AAV DNA constructs. The results demonstrated that AAV transcripts contain only one functional 5' splice donor site, that synthesis of capsid proteins from the unspliced 2.6-kb transcript is very inefficient, that transcripts without the intervening sequence (IVS) (i.e., the 2.3-kb RNA) do not produce protein A but effectively synthesize proteins B and C, and that protein A is actively synthesized from transcripts which contain the last 34 bases of the IVS. Protein A initiates within this 34-base segment in reading frame 1, apparently with the AUG codon at nucleotide 2203, and then elongates into the B and C open reading frame. Because A is inefficiently synthesized from the 2.6-kb transcript, we conclude that an effective A transcript is generated by alternative splicing and that the alternative 3' acceptor site may lie at nucleotide 2200 within a context of...CAG]GTA. The levels of B and C produced by a synthetic transcript devoid of the IVS suggest that the known 2.3-kb RNA is the main source of these proteins and indicate that this single RNA species expresses both proteins by alternative use of their respective initiation codons.

Adeno-associated virus general transduction vectors: analysis of proviral structures

We used two kinds of adeno-associated virus (AAV) vectors to transduce the neomycin resistance gene into human cells. The first of these (dl52-91) retains the AAV rep genes; the second (dl3-94) retains only the AAV terminal repeats and the AAV polyadenylation signal (428 base pairs). Both vectors could be packaged into AAV virions and produced proviral structures that were essentially the same. Thus, the AAV sequences that are required in cis for packaging (pac), integration (int), rescue (res), and replication (ori) of viral DNA are located within a 284-base-pair sequence that includes the terminal repeat. Most of the G418r cell lines (73%) contained proviruses which could be rescued (Res+) when the cells were superinfected with the appropriate helper viruses. Some produced high yields of viral DNA; other rescued at a 50-fold lower level. Most of the lines that were Res+ (79%) contained a tandem repeat of the AAV genome (2 to 20 copies) which was integrated randomly with respect to cellular DNA. Junctions between two consecutive AAV copies in a tandem array contained either one or two copies of the AAV terminal palindrome. Junctions between AAV and cellular sequences occurred predominantly at or within the AAV terminal repeat, but in some cases at internal AAV sequences. Two lines were seen that contained free episomal copies of AAV DNA. Res+ clones contained deleted proviruses or tandem repeats of a deleted genome. Occasionally, flanking cellular DNA was also amplified. There was no superinfection inhibition of AAV DNA integration. Our results suggest that AAV sequences are amplified by DNA replication either before or after integration and that the mechanism of replication is different from the one used during AAV lytic infections. In addition, we have described a new AAV general transduction vector, dl3-94, which provides the maximum amount of room for insertion of foreign DNA and integrates at a high frequency (80%).

Regulation of adeno-associated virus gene expression in 293 cells: control of mRNA abundance and translation

We studied the effects of the adeno-associated virus (AAV) rep gene on the control of gene expression from the AAV p40 promoter in 293 cells in the absence of an adenovirus coinfection. AAV vectors containing the chloramphenicol acetyltransferase (cat) gene were used to measure the levels of cat expression and steady-state mRNA from p40. When the rep gene was present in cis or in trans, cat expression from p40 was decreased 3- to 10-fold, but there was a 2- to 4-fold increase in the level of p40 mRNA. Conversely, cat expression increased and the p40 mRNA level decreased in the absence of the rep gene. Both wild-type and carboxyl-terminal truncated Rep proteins were capable of eliciting both effects. These data suggest two roles for the pleiotropic AAV rep gene: as a translational inhibitor and as a positive regulator of p40 mRNA levels. We also provide additional evidence for a cis-acting negative regulatory region which decreases RNA from the AAV p5 promoter in a fashion independent of rep.

Gene expression in adeno-associated virus vectors: the effects of chimeric mRNA structure, helper virus, and adenovirus VA1 RNA

We used a recombinant plasmid containing an adeno-associated virus (AAV) genome to construct several vectors which express the gene for chloramphenicol acetyltransferase (CAT). We transfected four different AAV-CAT vectors into human 293 (adenovirus-transformed) cells and analyzed CAT activity. We show that, for vectors using the AAV p40 and p19 promoter, the chimeric AAV-CAT transcripts began from the correct 5' position but the basal level of CAT expression depended in part on the structure of the transcript. We also examined the effects of coinfection of the cells with the helper adenovirus or cotransfection with a plasmid which expressed the adenovirus translational control RNA, VA1 RNA. Cotransfection with plasmids containing the gene for VA1 RNA resulted in elevated levels of CAT activity. VA1 RNA stimulated translation of the chimeric mRNA. However, in two cases, the VA1 RNA apparently decreased the level of mRNA. These results suggest that in addition to its function in translation, VA1 RNA acts at a second site to alter cytoplasmic accumulation of some mRNAs. Infection with adenovirus increased CAT activity several-fold by increasing the cytoplasmic levels of the chimeric AAV-CAT transcript. When the CAT gene is inserted down stream of the AAV intron, adenovirus and not VA1 RNA alone increased CAT activity by promoting accumulation of a spliced transcript.

Adeno-associated virus gene expression inhibits cellular transformation by heterologous genes

In this paper we report that adeno-associated virus (AAV) genomes inhibit stable transformation by several dominant selectable marker genes upon cotransfection into mouse tissue culture cells. Cotransfection of AAV genomes also inhibited the expression of pSV2cat in transient assays. In both cases, the inhibitory effect was independent of AAV DNA replication but required the AAV p5 and p19 genes, which encode proteins required for AAV DNA replication and regulation of AAV gene expression. Finally, addition of a cloned E4 gene in the transfection experiments partially blocked the AAV-mediated inhibitory activities.

Adeno-associated virus gene expression inhibits cellular transformation by heterologous genes

In this paper we report that adeno-associated virus (AAV) genomes inhibit stable transformation by several dominant selectable marker genes upon cotransfection into mouse tissue culture cells. Cotransfection of AAV genomes also inhibited the expression of pSV2cat in transient assays. In both cases, the inhibitory effect was independent of AAV DNA replication but required the AAV p5 and p19 genes, which encode proteins required for AAV DNA replication and regulation of AAV gene expression. Finally, addition of a cloned E4 gene in the transfection experiments partially blocked the AAV-mediated inhibitory activities.

Identification of the trans-acting Rep proteins of adeno-associated virus by antibodies to a synthetic oligopeptide

Prior genetic analysis provided evidence for trans-acting regulatory proteins (Rep) coded by the left-hand open reading frame (orf-1) of adeno-associated virus (AAV). We have used immunoblotting analysis to identify four protein products of orf-1. Antibodies elicited against an oligopeptide encoded by orf-1 were reacted with extracts of cells that were infected with AAV or transfected with AAV recombinant vectors in the presence or absence of helper adenovirus. The antibody recognized four polypeptides with apparent molecular weights of 78,000, 68,000, 52,000, and 40,000. The 78,000-dalton (78K) (Rep78) and 68K (Rep68) proteins appear to be encoded by the unspliced 4.2-kilobase (kb) and spliced 3.9-kb mRNAs, respectively, transcribed from the p5 promoter. The 52K (Rep52) and 40K (Rep40) proteins appear to be the products of the unspliced 3.6-kb and the spliced 3.3-kb mRNAs, respectively, transcribed from the p19 promoter. Rigorous identification of Rep68 as an AAV-coded protein is compromised by a cross-reacting cellular protein of similar size. All four proteins were expressed in the human cell lines 293, HeLa, HT29, and A549 infected with AAV together with adenovirus. Rep78 and Rep52 were detected at lower levels in cells infected with AAV at high multiplicity in the absence of adenovirus. Human 293 cells transfected with a recombinant AAV vector (pAV2) also expressed Rep proteins in the presence or absence of adenovirus. Mutations introduced into the Rep region of pAV2 further identified the Rep proteins. The amount of each Rep protein varied between nuclear and cytoplasmic extracts, but all four proteins accumulated during the lytic cycle of the viral infection. Other studies have indicated that the Rep proteins have independent trans-acting functions in viral DNA replication and negative and positive regulation of gene expression. Correlation of each trans-acting function with individual Rep proteins will be facilitated with the antibodies described herein.

Complete nucleotide sequence and genome organization of bovine parvovirus

We determined the complete nucleotide sequence of bovine parvovirus (BPV), an autonomous parvovirus. The sequence is 5,491 nucleotides long. The terminal regions contain nonidentical imperfect palindromic sequences of 150 and 121 nucleotides. In the plus strand, there are three large open reading frames (left ORF, mid ORF, and right ORF) with coding capacities of 729, 255, and 685 amino acids, respectively. As with all parvoviruses studied to date, the left ORF of BPV codes for the nonstructural protein NS-1 and the right ORF codes for the major parts of the three capsid proteins. The mid ORF probably encodes the major part of the nonstructural protein NP-1. There are promoterlike sequences at map units 4.5, 12.8, and 38.7 and polyadenylation signals at map units 61.6, 64.6, and 98.5. BPV has little DNA homology with the defective parvovirus AAV, with the human autonomous parvovirus B19, or with the other autonomous parvoviruses sequenced (canine parvovirus, feline panleukopenia virus, H-1, and minute virus of mice). Even though the overall DNA homology of BPV with other parvoviruses is low, several small regions of high homology are observed when the amino acid sequences encoded by the left and right ORFs are compared. From these comparisons, it can be shown that the evolutionary relationship among the parvoviruses is B19 in equilibrium with AAV in equilibrium with BPV in equilibrium with MVM. The highly conserved amino acid sequences observed among all parvoviruses may be useful in the identification and detection of parvoviruses and in the design of a general parvovirus vaccine.

Positive and negative autoregulation of the adeno-associated virus type 2 genome

The defective human parvovirus, adeno-associated virus (AAV), requires multiple functions provided by a coinfecting helper virus for viral replication. In addition, it has recently been shown that at least one AAV gene is also required for AAV DNA replication. In this paper, we investigate the autoregulation of the AAV genome by analyzing the expression of mutant AAV genomes upon transfection into adenovirus-infected human cells. Evidence is presented which indicates that the AAV genome regulates its own gene expression in at least two ways. First, either the AAV p5 gene or both the p5 and p19 genes appear to encode a trans activator of AAV transcription. Frameshift mutations within the p5 or p19 gene severely inhibited the synthesis and accumulation of all AAV transcripts. The defective accumulation of transcripts could be complemented in trans, in a manner independent of DNA replication, by cotransfection with a capsid deletion mutant. Second, evidence is presented which suggests that the p5 and p19 genes contain negative cis-active regulatory elements. Deletion of sequences within the p5 and p19 genes enhanced the accumulation of the p5 transcript in cis upon complementation with an AAV capsid deletion mutant, whereas certain deletions enhanced p40 RNA accumulation in the absence of trans activation by the p5 gene.

Nucleotide sequence and genome organization of human parvovirus B19 isolated from the serum of a child during aplastic crisis

The nucleotide sequence of an almost-full-length clone of human parvovirus B19 was determined. Whereas the extreme left and right ends of this genomic clone are incomplete, the sequence clearly indicates that the two ends of viral DNA are related by inverted terminal repeats similar to those of the Dependovirus genus. The coding regions are complete in the cloned DNA, and the two large open reading frames which span almost the entire genome are restricted to one strand, as has been found for all other parvoviruses characterized to date. From the DNA sequence we conclude that the organization of the B19 transcription units is similar although not identical to those of other parvoviruses. In particular, we predict that the B19 genome may utilize a fourth promoter to transcribe mRNA encoding the major structural polypeptide, VP2. Analysis of the putative polypeptides confirms that B19 is only distantly related to the other parvoviruses but reveals that there is a small region in the gene probably encoding the major nonstructural protein of B19, which is closely conserved between all of the parvovirus genomes for which sequence information is currently available.

The minute virus of mice P39 transcription unit can encode both capsid proteins

The right-hand 80% of the genome of minute virus of mice (MVM) was cloned into the bovine papillomavirus type I shuttle vector and used to transfect mouse C127 cells. Transformed lines were isolated that efficiently produce both authentic MVM capsid proteins at a ratio similar to that seen in a normal viral infection, and these proteins assemble into intact empty virions. The only transcription of MVM sequences detected in these lines was representative of the viral P39 transcription unit, which therefore contains sufficient information to encode both authentic capsid proteins at the same regulated ratio seen in an infected cell.

Regulation of protein synthesis in virus-infected animal cells

This chapter summarizes the structural features that govern the translation of viral mRNAs: where the synthesis of a protein starts and ends, how many proteins can be produced from one mRNA, and how efficiently. It focuses on the interplay between viral and cellular mRNAs and the translational machinery. That interplay, together with the intrinsic structure of viral mRNAs, determines the patterns of translation in infected cells. It also points out some possibilities for translational regulation that can only be glimpsed at present, but are likely to come into focus in the future. The mechanism of selecting the initiation site for protein synthesis appears to follow a single formula. The translational machinery displays a certain flexibility that is exploited more frequently by viral than by cellular mRNAs. Although some of the parameters that determine efficiency have been identified, how efficiently a given mRNA will be translated cannot be predicted by summing the known parameters.

Direct mapping of adeno-associated virus capsid proteins B and C: a possible ACG initiation codon

The three major capsid proteins of adeno-associated virus type 2 (AAV2) virions are designated A, B, and C and have molecular sizes of 90, 72, and 60 kDa, respectively. These proteins are related, and genetic studies have shown they are encoded by a long open reading frame located in the right half of the genome. The coding capacity distal to the first ATG in this reading frame is only 503 amino acids (i.e., a protein about the size of protein C), but an open frame sequence devoid of ATG codons extends upstream for an additional 184 codons. Although the amino terminus of the C capsid protein is blocked, partial amino acid sequence analyses of peptides from C have confirmed that it is encoded within the portion of the reading frame distal to the first ATG at nucleotide (nt) location 2810. The amino terminus of the B capsid protein is not blocked, and its sequence begins with alanine. The triplet encoding this alanine lies 64 codons upstream from the initiation site for protein C and is immediately preceded by the threonine codon, ACG, at nt 2615. This ACG codon lies in the most favorable sequence context for protein synthesis initiation. All three AAV2 capsid proteins are labeled in vitro with formyl[35S]methionyl-tRNAf, indicating that synthesis of each protein is initiated independently. Our data suggest that the nt 2615 ACG codon directs the methionyl-tRNA-dependent initiation of the AAV2 B capsid protein. Proteins B and C may be synthesized from the same mRNA species and their relative abundance could be determined by the efficiencies of their respective initiation codons.