Interaction of the adenovirus IVa2 protein with viral packaging sequences

A 40 kDa isoform of the type 5 adenovirus IVa2 protein is sufficient for virus viability

The multifunctional IVa2 protein is essential for adenovirus replication [J. Virol. 77 (2003) 3586], but the relative importance of the transcriptional and encapsidation functions is unknown. As part of a study of IVa2 function, we created a set of mutations in the IVa2 gene in the correct location in the viral genome. Unexpectedly, an opal stop codon at position 6 was recovered in virus twice. Isolate #2 showed defective viral replication, but produced late proteins at almost wild-type levels. Analysis of IVa2 mRNA showed an additional species, larger and more abundant than the equivalent wild-type species. It was a hybrid of the 5' UTR of L3 23 kDa attached to the IVa2 second exon, so that M75 is the 5' proximal methionine. This mRNA arises from a corresponding hybrid DNA, present in the virus stock. A protein of approximately 40 kDa, consistent with translation from the hybrid mRNA, was detected. It is able to bind to the packaging sequence and to the MLP downstream elements (DE1/2). Isolate #8 was more defective in replication than #2. No hybrid mRNA or DNA was detected, but it also produces a 40 kDa isoform, which is present in wild-type-infected cells. Mutational analysis of M75 and M101 revealed that the 40 kDa isoform is produced by initiation at Met75. This might be the origin of the previously unidentified 40 kDa factor present in the heterodimer DEF-A, which binds to DE1 and DE2a.

Identification of cis-acting sequences required for selective packaging of bovine adenovirus type 3 DNA

The assembly of adenovirus particles is a multistep process, in which viral genomic DNA is selected and subsequently inserted into preformed empty capsids. The selective encapsidation of the adenovirus genome is directed by cis-acting packaging motifs, termed A repeats due to their AT-rich character in DNA sequence. A repeats are usually located at the left end of the viral genome. In this report, the construction and analysis of bovine adenovirus type 3 (BAdV-3) mutants containing deletion mutations introduced into the AT-rich regions are described. The main cis-acting packaging domains of BAdV-3 were localized between nt 224 and 540 relative to the left end of the viral genome. They displayed a functional redundancy and followed a hierarchy of importance. In addition, the results demonstrated that not all of the AT-rich units functioned as cis-acting packaging motifs.

DNA synthesis-dependent relief of repression of transcription from the adenovirus type 2 IVa(2) promoter by a cellular protein

The promoter of the human adenovirus type 2 IVa(2) gene, which becomes active only during the late phase of infection, is built largely from sequences spanning, and downstream of, the sites of initiation of transcription. These sequences comprise an initiator, an intragenic sequence necessary for efficient transcription from the promoter by RNA polymerase II, and an intragenic binding site for a cellular repressor of IVa(2) transcription. The properties of the latter protein, which is termed IVa(2)-RF, suggested that it might account for the viral DNA synthesis-dependent activation of IVa(2) transcription during the adenoviral productive cycle. Here we report the results of experiments to assess the contributions of DNA template concentration and IVa(2)-RF binding to the activity of the IVa(2) promoter using a transient expression system. When a IVa(2)-EGFP reporter gene was introduced into HeLa cells, in which IVa(2)-RF was identified, no EFGP synthesis could be detected. In contrast, in IVa(2)-RF-containing cells in which the plasmid carrying the chimeric gene replicated, synthesis of both the EGFP protein and the IVa(2)-EGFP mRNA was readily detected. A vector mutation that blocked plasmid replication reduced IVa(2) promoter activity to undetectable levels. In contrast, a IVa(2) promoter substitution that impaired binding of IVa(2)-RF increased IVa(2) promoter activity under all conditions examined. Furthermore, introduction of DNA containing the IV-RF binding site with the chimeric reporter genes resulted in increased transcription from the IVa(2) promoter in the absence of plasmid replication. These properties are consistent with the hypothesis that the relative concentration of the IVa(2) promoter and of the cellular repressor that binds to it governs transcription from this adenoviral promoter.

Characterization of cis-acting sequences involved in packaging porcine adenovirus type 311Published as VIDO Journal article no. 340

Encapsidation of adenovirus DNA involves specific interactions between cis-acting genomic DNA sequences and trans-acting proteins. The cis-acting packaging domain located near the left inverted terminal repeat is composed of a series of redundant but not functionally equivalent motifs. Such motifs are made up of the consensus sequence 5'-TTTGN(8)CG-3' and 5'-TTTG/A-3' in human adenovirus 5 (HAV-5) and canine adenovirus-2 (CAV-2), respectively. To gain comparative insight into adenovirus encapsidation, we examined the packaging domain of porcine adenovirus-3 (PAV-3). Using deletion mutants, we localized the PAV-3 packaging domain to 319 bp (nt 212 to 531), which contains six cis-acting elements. However, this domain does not contain the consensus motifs identified in HAV-5. In addition, consensus motif found in CAV-2 is present only once in PAV-3. Instead, PAV-3 packaging domain appears to contain AT/GC-rich sequences. The packaging motifs of PAV-3, which are functionally redundant but not equivalent, are located at the left end of the genome.

Nuclear perturbations following adenovirus infection

Adenoviruses are processed and assembled in the nuclei of infected cells and thereby produce significant perturbations to their structure and function. As the complex interactions that occur in the nuclei of uninfected cells are not yet fully understood many of the changes seen on infection have been described mainly in morphological terms. This chapter attempts to place more recent findings into this context and demonstrates that adenoviruses are able to hijack many cellular processes and enzymes to their advantage. In particular, modifications to nuclear PODs and nucleoli have more recently been explored in greater detail.

Regulation of adenovirus packaging

The application of fundamental concepts about the packaging of the adenovirus genome has contributed significantly to the development of therapeutic viral vectors for gene therapy. The packaging of adenovirus DNA into virus particles requires a cis-acting domain at the left end of the genome. This region contains a series of repeated sequences, termed A repeats due to their AT-rich character, that direct the packaging process. A repeats are believed to represent the binding sites for viral and cellular factors that mediate viral DNA packaging. This review will focus on fundamental aspects of adenovirus DNA packaging as well as how this information has been used and may be used to augment the selectivity of viral DNA packaging in applications pertaining to gene therapy vectors.

The structure and function of the adenovirus major late promoter

The adenovirus major late promoter (MLP) has played a pre-eminent role in the analysis of transcription initiation in mammalian cells, and is an outstanding example of the ways in which the study of adenovirus has led to fundamental insights into general cellular processes. The aim of this chapter is to give a comprehensive review of the structure and function of this model mammalian promoter. After a brief description of late transcription in the adenovirus replication cycle, the experimental evidence for the current consensus on the genetic structure of the MLP, including a consideration of non-primate adenovirus MLPs, will be reviewed. Next, the functions of the MLP in the viral life cycle will be examined, and some of the problems that remain to be resolved will be addressed. The review ends with some ideas on how the knowledge of the structure and function of the MLP can be used in designing virus vectors for specific experimental purposes.

Binding of CCAAT displacement protein CDP to adenovirus packaging sequences

Adenovirus (Ad) type 5 DNA packaging is initiated in a polar fashion from the left end of the genome. The packaging process is dependent upon the cis-acting packaging domain located between nucleotides 194 and 380. Seven A/T-rich repeats have been identified within this domain that direct packaging. A1, A2, A5, and A6 are the most important repeats functionally and share a bipartite sequence motif. Several lines of evidence suggest that there is a limiting trans-acting factor(s) that plays a role in packaging. Two cellular activities that bind to minimal packaging domains in vitro have been previously identified. These binding activities are P complex, an uncharacterized protein(s), and chicken ovalbumin upstream promoter transcription factor (COUP-TF). In this work, we report that a third cellular protein, octamer-1 protein (Oct-1), binds to minimal packaging domains. In vitro binding analyses and in vivo packaging assays were used to examine the relevance of these DNA binding activities to Ad DNA packaging. The results of these experiments reveal that COUP-TF and Oct-1 binding does not play a functional role in Ad packaging, whereas P-complex binding directly correlates with packaging function. We demonstrate that P complex contains the cellular protein CCAAT displacement protein (CDP) and that full-length CDP is found in purified virus particles. In addition to cellular factors, previous evidence indicates that viral factors play a role in the initiation of viral DNA packaging. We propose that CDP, in conjunction with one or more viral proteins, binds to the packaging sequences of Ad to initiate the encapsidation process.

Minimal cis-acting elements required for adenovirus genome packaging

The design of drugs for treatment of virus infections and the exploitation of viruses as drugs for treatment of diseases could be made more successful by understanding the molecular mechanisms of virus-specific events. The process of assembly, and more specifically packaging of the genome into a capsid, is an obligatory step leading to future infections. To enhance our understanding of the molecular mechanism of packaging, it is necessary to characterize the viral components necessary for the event. In the case of adenovirus, sequences between nucleotides 200 and 400 at the left end of the genome are essential for packaging. This region contains a series of redundant bipartite sequences, termed A repeats, that function in packaging. Synthetic packaging sequences made of multimers of a single A repeat substitute for the authentic adenovirus packaging domain. A repeats are binding sites for the CCAAT displacement protein and the viral protein IVa2. Several lines of evidence implicate these proteins in the packaging process. It was not known, however, whether other cis-acting elements play a role in the packaging process as well. We utilized an in vivo approach to address the role of the inverted terminal repeats and the covalently linked terminal proteins in packaging of the adenovirus genome. Our results show that these elements are not necessary for efficient packaging of the viral genome. A significant implication of these results applicable to gene therapy vector design is that the linkage of the adenovirus packaging domain to heterologous DNA sequences should suffice for targeting to the viral capsid.

Requirement of the adenovirus IVa2 protein for virus assembly

The adenovirus L1 52/55-kDa protein is required for viral DNA packaging and interacts with the viral IVa2 protein, which binds to the viral packaging sequence. Previous reports suggest that the IVa2 protein plays a role in viral DNA packaging and that this function of the IVa2 protein is serotype specific. To further examine the function of the IVa2 protein in viral DNA packaging, a mutant virus that does not express the IVa2 protein was constructed by introducing two stop codons at the beginning of the IVa2 open reading frame in a full-length bacterial clone of adenovirus type 5. The mutant virus, pm8002, was defective for growth in 293 cells, although it replicated its DNA and produced early and late viral proteins. Electron microscopic and gradient analyses revealed that the mutant virus did not assemble any viral particles in 293 cells. In 293-IVa2 cells, which express the IVa2 protein, infectious viruses were produced, although the titer of the mutant virus was lower than that of the wild-type virus, indicating that these cells may not fully complement the mutation. The mutant viral particles produced in 293-IVa2 cells were heterogeneous in size and shape, less stable, and did not traffic efficiently to the nucleus. Marker rescue experiments with a wild-type IVa2 DNA fragment confirmed that the only mutations present in pm8002 were in the IVa2 gene. The results indicate that the IVa2 protein is required for adenovirus assembly and suggest that virus particles may be assembled around the DNA rather than DNA being packaged into preformed capsids.

Analysis of the adenovirus E1B-55K-anchored proteome reveals its link to ubiquitination machinery

During the early phase of infection, the E1B-55K protein of adenovirus type 5 (Ad5) counters the E1A-induced stabilization of p53, whereas in the late phase, E1B-55K modulates the preferential nucleocytoplasmic transport and translation of the late viral mRNAs. The mechanism(s) by which E1B-55K performs these functions has not yet been clearly elucidated. In this study, we have taken a proteomics-based approach to identify and characterize novel E1B-55K-associated proteins. A multiprotein E1B-55K-containing complex was immunopurified from Ad5-infected HeLa cells and found to contain E4-orf6, as well as several cellular factors previously implicated in the ubiquitin-proteasome-mediated destruction of proteins, including Cullin-5, Rbx1/ROC1/Hrt1, and Elongins B and C. We further demonstrate that a complex containing these as well as other proteins is capable of directing the polyubiquitination of p53 in vitro. These ubiquitin ligase components were found in a high-molecular-mass complex of 800 to 900 kDa. We propose that these newly identified binding partners (Cullin-5, Elongins B and C, and Rbx1) complex with E1B-55K and E4-orf6 during Ad infection to form part of an E3 ubiquitin ligase that targets specific protein substrates for degradation. We further suggest that E1B-55K functions as the principal substrate recognition component of this SCF-type ubiquitin ligase, whereas E4-orf6 may serve to nucleate the assembly of the complex. Lastly, we describe the identification and characterization of two novel E1B-55K interacting factors, importin-alpha 1 and pp32, that may also participate in the functions previously ascribed to E1B-55K and E4-orf6.

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.

Truncation of the human adenovirus type 5 L4 33-kDa protein: evidence for an essential role of the carboxy-terminus in the viral infectious cycle

The subgroup C human adenovirus L4 33-kDa protein is a nuclear phosphoprotein that plays a direct, but dispensable, role in virion assembly. The r-strand open reading frame (ORF) for this protein lies opposite to the 5' end of the l-strand E2 early (E2E) transcription units. To facilitate studies of regulation of E2E transcription, we wished to construct a mutant virus in which the 33-kDa ORF was truncated to serve as a background into which specific E2E mutations could be introduced without also altering the 33-kDa protein. We constructed viral DNA (vDNA) containing within the 33-kDa ORF two tandem, premature stop codons that should prevent translation of the C-terminal 47 amino acids of the protein (Delta47). We report here the unanticipated lethality of such truncation of the L4 33-kDa protein. Viral DNA harboring the Delta47 mutations did not produce infectious virus when transfected into cultured cells. In contrast, infectious virus was recovered upon transfection of revertant vDNA, indicating that the Delta47 mutations were responsible for the observed phenotype. The Delta47 mutations did not affect E2E transcription or production of the E2 DNA-binding protein. Transfected Delta47 vDNA was replicated and directed the production of early and late viral proteins, including hexon protein in the trimer conformation. However, no virus particles of any kind were produced. We propose that truncation of the adenovirus 33-kDa protein results in a lethal, late block in the infectious cycle during the assembly of progeny virions and discuss the implications of this phenotype for the mechanism of virion assembly.

Functional analysis of adenovirus protein IX identifies domains involved in capsid stability, transcriptional activity, and nuclear reorganization

The product of adenovirus (Ad) type 5 gene IX (pIX) is known to actively participate in the stability of the viral icosahedron, acting as a capsid cement. We have previously demonstrated that pIX is also a transcriptional activator of several viral and cellular TATA-containing promoters, likely contributing to the transactivation of the Ad expression program. By extensive mutagenesis, we have now delineated the functional domains involved in each of the pIX properties: residues 22 to 26 of the highly conserved N-terminal domain are crucial for incorporation of the protein into the virion; specific residues of the C-terminal leucine repeat are responsible for pIX interactions with itself and possibly other proteins, a property that is critical for pIX transcriptional activity. We also show that pIX takes part in the virus-induced nuclear reorganization of late infected cells: the protein induces, most likely through self-assembly, the formation of specific nuclear structures which appear as dispersed nuclear globules by immunofluorescence staining and as clear amorphous spherical inclusions by electron microscopy. The integrity of the leucine repeat appears to be essential for the formation and nuclear retention of these inclusions. Together, our results demonstrate the multifunctional nature of pIX and provide new insights into Ad biology.

Adenovirus protein V induces redistribution of nucleolin and B23 from nucleolus to cytoplasm

Adenovirus infection inhibits synthesis and processing of rRNA and redistributes nucleolar antigens. Adenovirus protein V associates with nucleoli in infected cells. This study delineates regions of protein V independently capable of nucleolar targeting. Also, evidence is presented that protein V has the unique property of relocating nucleolin and B23 to the cytoplasm when transiently expressed on its own in uninfected cells. Point mutation analysis indicates a role for the C terminus of protein V in the redirection of nucleolin and B23 to the cytoplasm. This is the first time an adenovirus protein has been shown to have a direct effect on nucleolar antigens in isolation from viral infection. Moreover, adenovirus protein V is the first protein demonstrated to be capable of redirecting nucleolin and B23 to the cytoplasm.

Identification of a cellular repressor of transcription of the adenoviral late IVa(2) gene that is unaltered in activity in infected cells

The gene encoding the adenovirus type 2 IVa(2) protein, a sequence-specific activator of transcription from the viral major late promoter, is itself transcribed only during the late phase of infection. We previously identified a cellular protein (IVa(2)-RF) that binds specifically to an intragenic sequence of the IVa(2) transcription unit. We now report that precise substitutions within the IVa(2)-RF-binding site that decreased binding affinity increased the efficiency of IVa(2) transcription in in vitro reactions containing IVa(2)-RF. Consistent with the conclusion that this cellular protein represses IVa(2) transcription, mutations that led to more efficient transcription in the presence of IVa(2)-RF were without effect in reactions lacking this cellular protein. No change in the concentration or activity of IVa(2)-RF could be detected in adenovirus-infected cells during the period in which the IVa(2) gene is transcribed. We therefore propose that restriction of IVa(2) transcription to the late phase is the result of titration of this cellular repressor as the number of copies of the IVa(2) promoter increases upon replication of the viral genome.