Adenovirus type 5 packaging domain is composed of a repeated element that is functionally redundant

System for efficient helper-dependent minimal adenovirus construction and rescue

Helper-dependent minimal adenoviral vectors deleted for all viral coding sequences are promising vectors for gene therapy. They retain only the adenovirus cis elements for replication and packaging, can accommodate up to 36 kb of foreign DNA, and exhibit prolonged transgene expression and reduced tissue toxicity as compared with first-generation adenoviral vectors. We have developed a system consisting of a set of cosmid cloning vectors (pMV and pMVX) for simple routine construction and efficient rescue of minimal adenoviral vectors. In the cloning vectors the inverted terminal repeats (ITRs) are flanked by recognition sites for the super rare-cutting endonuclease I-SceI. This allows the release of linear minimal adenovirus genomes for rescue of minimal adenovirus regardless of the sequence of the insert DNA. pMV contains a multiple cloning site for the insertion of 26 to 36 kb of therapeutic DNA. pMVX contains a noncoding human X-chromosomal DNA fragment as a vector backbone, which provides endonuclease restriction sites that allow for complete or partial replacement of the vector backbone by 1 to 26 kb of therapeutic DNA sequences, while retaining a packageable final minimal adenovirus genome size between 27 and 37.5 kb. Both vectors exist in two forms, with or without an Escherichia coli lacZ reporter gene cassette. Several minimal adenoviral vectors with insert sizes ranging from 1.5 to 16 kb were constructed with these cloning vectors. Minimal adenoviruses were efficiently rescued and amplified to high titers, using a Cre/lox-based helper system. Vectors containing the X-chromosomal backbone were stable during amplification. This simple and efficient system facilitates the construction of minimal adenoviruses and should be useful for further improvement of these new vectors.

Characterization of cis-acting sequences involved in canine adenovirus packaging

The cis-acting packaging domain in adenovirus serotype 5 (Ad5) is a series of redundant, albeit not functionally equivalent, "A-repeats" made up of the consensus sequence 5'-TTTGN(8)CG-3'. A-repeats may bind trans-acting factors that direct packaging of the adenovirus genome into the preformed capsid. To try to understand this basic mechanism, we examined the packaging domain from a nonhuman adenovirus. We delimited the canine adenovirus type 2 (CAV-2) packaging domain to within 156 bp via a conditional mutation based on the Cre/loxP excision. Using an insertion, deletion, and substitution strategy, we generated packaging-defective CAV-2 vectors. Our results demonstrate that, like Ad5, CAV-2 cis-acting packaging sequences are located near the left inverted terminal repeat and are redundant, but not functionally equivalent. However, the bipartite motif found in Ad5 is present only once in CAV-2 and deletion of it caused only a minor variation in the packaging efficiency. We have identified at least four functional cis-acting packaging sequences in CAV-2. The CAV-2 vectors that we generated were not replication-defective in an E1-transcomplementing cell line and as heat stable as the parental vectors that did not contain mutations.

Interaction of the adenovirus IVa2 protein with viral packaging sequences

We have demonstrated previously that the adenovirus L1 52/55-kDa protein binds to the viral IVa2 protein in infected cells. The significance of this interaction was unclear, however, based on the known functions of these two proteins: the 52/55-kDa protein is required for viral DNA packaging, while the IVa2 protein is a transactivator of the major late promoter (MLP). In this report, we have attempted to elucidate a role for each of the two proteins in the other's known function. There is no apparent effect of the 52/55-kDa protein on the interaction of the IVa2 protein with the MLP. Surprisingly, however, we found that the IVa2 protein can interact with the adenoviral packaging signal and that this interaction involves DNA sequences that have previously been demonstrated to be required for packaging.

High-capacity adenoviral vectors for gene transfer and somatic gene therapy

The availability of efficient and nontoxic gene delivery technologies is fundamental to the translation of therapeutic concepts into clinical practice by gene transfer. High-capacity adenoviral (HC-Ad) vectors are characterized by the ability to transduce cells in vitro and in vivo with more than 30 kb of nonviral DNA. This quality allows simultaneous gene transfer of several expression cassettes, large promoters, and some genes in their natural genomic context. Because all viral coding sequences are removed from these vectors, safety is considerably improved compared with previous-generation adenoviral vectors.

Encapsidated adenovirus mini-chromosome-mediated delivery of genes to the retina: application to the rescue of photoreceptor degeneration

First (DeltaE1/E3) and second (DeltaE1+DeltaE2/E3/E4) generation adenovirus (Ad) vectors have been shown previously to be of limited use in the treatment of human genetic diseases due to the induction of a host cytotoxic T-cell mediated immune response against virally expressed genes. In addition, a limited cloning capacity of approximately 8 kb does not cater for the incorporation of large upstream sequences essential for regulated tissue-specific expression or inclusion of multiple gene-expression cassettes. In this study we have exploited our recently developed Ad-based vector, the encapsidated adenovirus mini-chromosome (EAM) from which all of the viral genes have been deleted. EAMs contain only the inverted terminal repeats required for replication and five cis -acting Ad encapsidation signals necessary for packaging. We have shown previously that EAMs can efficiently transduce a variety of cell types in vitro. In this study we demonstrate that EAMs can transduce and rescue cells from the neurosensory retina in vivo. EAM-mediated delivery of the beta subunit of cyclic GMP phosphodiesterase (PDE) cDNA to mice affected with retinal degeneration (rd) allows prolonged transgene expression and rescue of rod photoreceptor cells. RT-PCR analysis from the injected retina indicates that transgene products are present for at least 18 weeks post-injection. Both the alpha and beta subunits of PDE could be detected up to 90 days postnatal in EAM-injected rd retina by western analysis. A maximal PDE activity of 150 nm/min/mg was detected at 33 days postnatal. Examination of outer nuclear thickness showed significant differences up to 12 weeks post-injection. These results demonstrate an improved level of rescue over first-generation adenoviral vectors and suggest the possibility of successful EAM-mediated treatment of some retinal diseases in humans.

Virus assembly and disassembly: the adenovirus cysteine protease as a trigger factor

Viruses are efficient carriers of genetic material between cells. They specifically recognise a target cell and utilise host functions for genome delivery to the replication site. A mature viral capsid emerging from an infected cell serves at least three distinct functions. It enables virus egress from the infected cell, protects the extracellular genome against chemical and physical stress and mediates virus entry into a non-infected cell. How can a virus particle be stably assembled in an infected cell and moments later-after passing through the extracellular milieu-be disintegrated by a non-infected cell? In this review I discuss how adenovirus, a DNA virus, recruits cellular and viral factors and makes use of its own cysteine protease to regulate capsid assembly and disassembly. Copyright 1998 John Wiley & Sons, Ltd.

Cellular components interact with adenovirus type 5 minimal DNA packaging domains

Adenovirus type 5 DNA packaging is initiated from the left end of the viral genome and depends on the presence of a cis-acting packaging domain located between nucleotides 194 and 380. Multiple redundant packaging elements (termed A repeats I through VII [AI through AVII]) are contained within this domain and display differential abilities to support DNA packaging in vivo. The functionally most important repeats, AI, AII, AV, and AVI, follow a bipartite consensus motif exhibiting AT-rich and CG-rich core sequences. Results from previous mutational analyses defined a fragment containing AV, AVI, and AVII as a minimal packaging domain in vivo, which supports a functional independence of the respective cis-acting sequences. Here we describe multimeric versions of individual packaging elements as minimal packaging domains that can confer viability and packaging activity to viruses carrying gross truncations within their left end. These mutant viruses directly rate the functional role that different packaging elements play relative to each other. The A repeats are likely to be binding sites for limiting, trans-acting packaging factors of cellular and/or viral origin. We report here the characterization of two cellular binding activities interacting with all of the minimal packaging domains in vitro, an unknown binding activity termed P-complex, and the transcription factor chicken ovalbumin upstream promoter transcription factor. The binding of both activities is dependent on the integrity of the AT-rich, but not the CG-rich, consensus half site. In the case of P-complex, binding affinity for different minimal packaging domains in vitro correlates well with their abilities to support DNA packaging in vivo. Interestingly, P-complex interacts not only with packaging elements but also with the left terminus of the viral genome, the core origin of replication. Our data implicate cellular factors as components of the viral packaging machinery. The dual binding specificity of P-complex for packaging and replication sequences may further suggest a direct involvement of left-end replication sequences in viral DNA encapsidation.

Nucleotide sequence, genome organization, and transcription map of bovine adenovirus type 3

The complete DNA sequence of bovine adenovirus type 3 is reported here. The size of the genome is 34,446 bp in length with a G+C content of 54%. All the genes of the early and late regions are present in the expected locations of the genome. However, the late-region genes are organized into seven families, instead of five as they are in human adenovirus type 2. The deduced amino acid sequences of open reading frames (ORFs) in the late regions and early region 2 (E2) and for IVa2 show higher degrees of homology, whereas the predicted amino acid sequences of ORFs in the E1, E3, and E4 regions and the pIX, fiber, and 33,000-molecular-weight nonstructural proteins show little or no homology with the corresponding proteins of other adenoviruses. In addition, the penton base protein lacks the integrin binding motif, RGD, but has an LDV motif instead of an MDV motif. Interestingly, as in other animal adenoviruses, the virus-associated RNA genes appear to be absent from their usual location. Sequence analysis of cDNA clones representing the early- and late-region genes identified splice acceptor and splice donor sites, polyadenylation signals and polyadenylation sites, and tripartite leader sequences.

Bipartite structure and functional independence of adenovirus type 5 packaging elements

Selectivity and polarity of adenovirus type 5 DNA packaging are believed to be directed by an interaction of putative packaging factors with the cis-acting adenovirus packaging domain located within the genomic left end (nucleotides 194 to 380). In previous studies, this packaging domain was mutationally dissected into at least seven functional elements called A repeats. These elements, albeit redundant in function, exhibit differences in the ability to support viral packaging, with elements I, II, V, and VI as the most critical repeats. Viral packaging was shown to be sensitive to spatial changes between individual A repeats. To study the importance of spatial constraints in more detail, we performed site-directed mutagenesis of the 21-bp linker regions separating A repeats I and II, as well as A repeats V and VI. The results of our mutational analysis reveal previously unrecognized sequences that are critical for DNA encapsidation in vivo. On the basis of these results, we present a more complex consensus motif for the adenovirus packaging elements which is bipartite in structure. DNA encapsidation is compromised by changes in spacing between the two conserved parts of the consensus motif, rather than between different A repeats. Genetic evidence implicating packaging elements as independent units in viral DNA packaging is derived from the selection of revertants from a packaging-deficient adenovirus: multimerization of packaging repeats is sufficient for the evolution of packaging-competent viruses. Finally, we identify minimally sized segments of the adenovirus packaging domain that can confer viability and packaging activity to viruses carrying gross truncations within their left-end sequences. Coinfection experiments using the revertant as well as the minimal-packaging-domain mutant viruses strengthen existing arguments for the involvement of limiting, trans-acting components in viral DNA packaging.

Construction of adenovirus vectors through Cre-lox recombination

Two barriers prevent adenovirus-based vectors from having wide application. One is the difficulty of making new adenoviruses, and the second is the strong immunological reaction to viral proteins. Here we describe uses of Cre-lox recombination to overcome these problems. First, we demonstrate a simple method for constructing E1-substituted adenoviruses. Second, we demonstrate a method to construct adenovirus vectors carrying recombinant genes in place of all of the viral genes, so-called gutless adenovirus vectors. The pivotal feature in each method is the use of a negatively selected adenovirus named psi5. We engineered a cis-acting selection into psi5 by flanking its packaging site with loxP sites. When psi5 was grown in cells making a high level of Cre recombinase, the packaging site was deleted by recombination and the yield of psi5 was reduced to 5% of the wild-type level. To make a new E1-substituted virus, we used psi5 as a donor virus and recombined it with a shuttle vector via a loxP site. The resulting recombinant virus has a single loxP site next to the packaging site and therefore outgrows psi5 in the presence of Cre recombinase. To make a gutless virus, we used psi5 as a helper virus. The only viral sequences included in the gutless vector are those needed in cis for its replication and packaging. We found that a loxP site next to the packaging site of the gutless virus was necessary to neutralize homologous recombination between psi5 and the gutless viruses within their packaging domains.

A new adenoviral vector: Replacement of all viral coding sequences with 28 kb of DNA independently expressing both full-length dystrophin and beta-galactosidase

Adenoviral vector-mediated gene transfer offers significant potential for gene therapy of many human diseases. However, progress has been slowed by several limitations. First, the insert capacity of currently available adenoviral vectors is limited to 8 kb of foreign DNA. Second, the expression of viral proteins in infected cells is believed to trigger a cellular immune response that results in inflammation and in only transient expression of the transferred gene. We report the development of a new adenoviral vector that has all viral coding sequences removed. Thus, large inserts are accommodated and expression of all viral proteins is eliminated. The first application of this vector system carries a dual expression cassette comprising 28.2 kb of nonviral DNA that includes the full-length murine dystrophin cDNA under control of a large muscle-specific promoter and a lacZ reporter construct. Using this vector, we demonstrate independent expression of both genes in primary mdx (dystrophin-deficient) muscle cells.

The complete DNA sequence and genomic organization of the avian adenovirus CELO

The complete DNA sequence of the avian adenovirus chicken embryo lethal orphan (CELO) virus (FAV-1) is reported here. The genome was found to be 43,804 bp in length, approximately 8 kb longer than those of the human subgenus C adenoviruses (Ad2 and Ad5). This length is supported by pulsed-field gel electrophoresis analysis of genomes isolated from several related FAV-1 isolates (Indiana C and OTE). The genes for major viral structural proteins (Illa, penton base, hexon, pVI, and pVIII), as well as the 52,000-molecular-weight (52K) and 100K proteins and the early-region 2 genes and IVa2, are present in the expected locations in the genome. CELO virus encodes two fiber proteins and a different set of the DNA-packaging core proteins, which may be important in condensing the longer CELO virus genome. No pV or pIX genes are present. Most surprisingly, CELO virus possesses no identifiable E1, E3, and E4 regions. There is 5 kb at the left end of the CELO virus genome and 15 kb at the right end with no homology to Ad2. The sequences are rich in open reading frames, and it is likely that these encode functions that replace the missing El, E3, and E4 functions.

Efficient selection of recombinant adenoviruses by vectors that express beta-galactosidase

Adenovirus serotype 5 vectors which contain the Excherichia coli beta-galactosidase gene driven by the cytomegalovirus immediate-early promoter as a screenable marker have been made and successfully used in the construction of recombinant adenoviruses. The beta-galactosidase gene has been introduced into viruses in which the E3 region is maintained or deleted and in which the cis-acting packaging sequence has been reiterated at the right end of the chromosome. A unique BstBI site has been introduced 3' of the beta-galactosidase gene. Cotransfection of BstBI-digested vector DNA and a plasmid containing the left end of the viral chromosome followed by staining with X-Gal (5-bromo-4-chloro-3-indolyl-beta-D-galactopyranoside) results in clear plaques when overlap recombination has occurred and blue plaques when ligation of the viral arms has occurred within the host cell. The beta-galactosidase-expressing viruses grow to lower titers than do the parental viruses, leading to a relative growth advantage for viruses resulting from overlap recombination. Combined with color selection based on the beta-galactosidase gene, this system permits efficient production and selection of recombinant viruses after cotransfection of BstBI-digested viral DNA with a plasmid including left-end viral sequences and the gene of interest. The beta-galactosidase-expressing viral DNAs were used to construct viruses containing BstBI sites on either side of the cis-acting packaging element as a means of testing their utility.

Trans-complementation of E1-deleted adenovirus: a new vector to reduce the possibility of codissemination of wild-type and recombinant adenoviruses

Treatment of cystic fibrosis by gene therapy will require the development of vectors capable of efficient and safe transfer of a functional cystic fibrosis transmembrane conductance regulator (CFTR) cDNA to airway epithelia. To achieve this goal, replication-deficient (E1-) adenoviruses (Ad) are promising vectors. We have previously demonstrated efficient CFTR gene delivery to the airways of cotton rats and rhesus monkeys using a replication-deficient adenovirus, Ad-CFTR. Here, we have investigated an important safety issue, the interaction between the vector and wild-type virus which can provide the missing E1 function in trans. We show that Ad5 can mobilize the defective Ad-CFTR genome in vitro and in cotton rats. However, the extent of the complementation in vivo by wild-type virus is limited because no additional spreading or shedding of Ad-CFTR to trachea, lungs, and stools is elicited. To attenuate Ad-CFTR further, a mutation was introduced in the cis-acting regulatory sequences that control the encapsidation of the viral genome. We demonstrate that when cells are coinfected with wild-type virus and the new attenuated vector, the viral DNA containing the natural encapsidation sequences is preferentially packaged, leading to a rapid dilution of the recombinant virus.

An efficient and flexible system for construction of adenovirus vectors with insertions or deletions in early regions 1 and 3

Human adenoviruses (Ads) are attracting considerable attention because of their potential utility for gene transfer and gene therapy, for development of live viral vectored vaccines, and for protein expression in mammalian cells. Engineering Ad vectors for these applications requires a variety of reagents in the form of Ads and bacterial plasmids containing viral DNA sequences and requires different strategies for construction of vectors for different purposes. To simplify Ad vector construction and develop a procedure with maximum flexibility, efficiency, and cloning capacity, we have developed a vector system based on use of Ad5 DNA sequences cloned in bacterial plasmids. Expanded deletions in early region 1 (3180 bp) and early region 3 (2690 or 3132 bp) can be combined in a single vector that should have a capacity for inserts of up to 8.3 kb, enough to accommodate the majority of cDNAs encoding proteins with regulatory elements. Genes can be inserted into either early region 1 or 3 or both and mutations or deletions can be readily introduced elsewhere in the viral genome. To illustrate the flexibility of the system, we have introduced a wild-type early region 3 into the vectors, and to illustrate the high capacity for inserts, we have isolated a vector with two genes totaling 7.8 kb.

The NFIII/OCT-1 binding site stimulates adenovirus DNA replication in vivo and is functionally redundant with adjacent sequences

The inverted terminal repeat (ITR) of adenovirus type 5 (Ad5) is 103 bp in length and contains the origin of DNA replication. Cellular transcription factors NFI/CTF and NFIII/OCT-1 bind to sites within the ITR and participate in the initiation of viral DNA replication in vitro. The ITR also contains multiple copies of two conserved sequence motifs that bind the cellular transcription factors SP1 and ATF. We have analyzed a series of viruses that carry deletions at the left terminus of Ad5. A virus carrying a deletion of the NFIII/OCT-1, SP1, and ATF sites within the ITR (mutant dl309-44/107) was wild type for virus growth. However, the deletion of these elements in addition to sequences immediately flanking the ITR (mutant dl309-44/195) resulted in a virus that grew poorly. The analysis of growth parameters of these and other mutants demonstrate that the NFIII/OCT-1 and adjacent SP1 sites augment the accumulation of viral DNA following infection. The function of these elements was most evident in coinfections with a wild-type virus, suggesting that these sites enhance the ability of a limiting trans-acting factor(s), that stimulates viral DNA replication, to interact with the ITR. The results of these analyses indicate functional redundancy between different transcription elements at the left terminus of the Ad5 genome and demonstrate that the NFIII/OCT-1 site and adjacent SP1 site, previously thought to be nonessential for adenovirus growth, play a role in viral DNA replication in vivo.

cis and trans requirements for the selective packaging of adenovirus type 5 DNA

Polar packaging of adenovirus DNA into virions is dependent on the presence of cis-acting sequences at the left end of the viral genome. Our previous analyses demonstrated that the adenovirus type 5 (Ad5) packaging domain (nucleotides 194 to 358) is composed of at least five elements that are functionally redundant. A repeated sequence, termed the A repeat, was associated with packaging function. Here we report a more detailed analysis of the requirements for the selective packaging of Ad5 DNA. By introducing site-directed point mutations into specific A repeat sequences, we demonstrate that the A repeats represent cis-acting functional components of the packaging signal. Additional elements, located outside the originally defined packaging domain boundaries and that resemble the A repeat consensus sequence, also are capable of promoting the packaging of viral DNA. The cis-acting components of the packaging signal appear to be subject to certain spatial constraints for function, possibly reflecting a necessity for the coordinate binding of packaging proteins to these sites. In agreement with this idea, we present evidence that the interaction of a limiting trans-acting factor(s) with the packaging domain in vivo is required for efficient encapsidation of the Ad5 genome.

Redundant elements in the adenovirus type 5 inverted terminal repeat promote bidirectional transcription in vitro and are important for virus growth in vivo

The adenovirus inverted terminal repeat (ITR) contains a number of cis-acting elements that are involved in the initiation of viral DNA replication, as well as multiple binding motifs for the cellular transcription factors SP1 and ATF. In this study, we utilized a Hela cell transcription extract to demonstrate that the adenovirus type 5 ITR promotes bidirectional transcription in vitro. Primer extension analyses demonstrated that the ITR directed transcription at initiation sites both within the terminal repeat and at fixed distances outside of the ITR. The ITR also strongly stimulated transcription at the early region 1A (E1A) initiation site when it was situated immediately upstream of the E1A TATA box region. Deletion and point mutational analyses demonstrated that two distinct cis-acting elements were involved in these ITR-dependent transcriptional activities in vitro. Cellular transcription factors SP1 and ATF were previously shown to bind to these two regions. Analysis of viral mutants in vivo demonstrated that the NFIII/OCT-1 binding site and a conserved ATF motif were important for efficient viral growth. Regulatory elements in the ITR flanking region were found to functionally substitute for these sites.