Porcine Adenovirus Type 3 E3 Encodes a Structural Protein Essential for Capsid Stability and Production of Infectious Progeny Virions.

The adenovirus E3 region encodes proteins that are not essential for viral replication in vitro The porcine adenovirus type 3 (PAdV-3) E3 region encodes three proteins, including 13.7K. Here, we report that 13.7K is expressed as an early protein, which localizes to the nucleus of infected cells. The 13.7K protein is a structural protein, as it is incorporated in CsCl-purified virions. The 13.7K protein appears to be essential for PAdV-3 replication, as mutant PAV13.73A expressing a mutated 13.7K could be isolated only in VIDO AS2 cells expressing the 13.7K protein. Analysis of PAV13.73A suggested that even in the presence of reduced levels of some late viral proteins, there appeared to be no effect on virus assembly and production of mature virions. Further analysis of CsCl-purified PAV13.73A by transmission electron microscopy revealed the presence of disrupted/broken capsids, suggesting that inactivation of 13.7K protein expression may produce fragile capsids. Our results suggest that the PAdV-3 E3 region-encoded 13.7K protein is a capsid protein, which appears to be essential for the formation of stable capsids and production of infectious progeny virions.IMPORTANCE Although E3 region-encoded proteins are involved in the modulation of leukocyte functions (N. Arnberg, Proc Natl Acad Sci U S A 110:19976-19977, 2013) and inducing a lytic infection of lymphocytes (V. K. Murali, D. A. Ornelles, L. R. Gooding, H. T. Wilms, W. Huang, A. E. Tollefson, W. S. Wold, and C. Garnett-Benson, J Virol 88:903-912, 2014), none of the E3 proteins appear to be a component of virion capsid or required for replication of adenovirus. Here, we demonstrate that the 13.7K protein encoded by the E3 region of porcine adenovirus type 3 is a component of progeny virion capsids and appears to be essential for maintaining the integrity of virion capsid and production of infectious progeny virions. To our knowledge, this is the first report to suggest that an adenovirus E3-encoded protein is an essential structural protein.

Cleavage of bovine adenovirus type 3 non-structural 100K protein by protease is required for nuclear localization in infected cells but is not essential for virus replication.

The L6 region of bovine adenovirus type 3 (BAdV-3) encodes a non-structural protein named 100K. Rabbit antiserum raised against BAdV-3 100K recognized a protein of 130 kDa at 12-24 h and proteins of 130, 100, 95 and 15 kDa at 36-48 h after BAdV-3 infection. The 100K species localized to the nucleus and the cytoplasm of BAdV-3-infected cells. In contrast, 100K localized predominantly to the cytoplasm of the transfected cells. However, BAdV-3 infection of cells transfected with 100K-enhanced yellow fluorescent protein-expressing plasmid detected fluorescent protein in the nucleus of the cells, suggesting that other viral proteins may be required for the nuclear localization of 100K. Interaction of BAdV-3 100K with BAdV-3 33K protein did not alter the cytoplasmic localization of 100K. However, co-expression of BAdV-3 100K and BAdV-3 protease localized 100K to the nucleolus of the transfected cells. Subsequent analysis suggested that BAdV-3 protease cleaves 100K at two identified potential protease cleavage sites (aa 740-745 and 781-786) in transfected or BAdV-3-infected cells. The cleaved C terminus (107 aa) was localized to the nucleolus of the transfected cells. Further analysis suggested that the cleaved C terminus contains a bipartite nuclear localization signal and utilizes import receptor importin-α3 of the classical importin-α/ß transport pathway for nuclear transport. Successful isolation of recombinant BAdV-3 expressing mutant 100K (substitution of alanine for glycine in the potential protease cleavage site) suggested that cytoplasmic cleavage of BAdV-3 100K by adenoviral protease is not essential for virus replication.

Persistence and the state of bovine and porcine adenoviral vector genomes in human and nonhuman cell lines.

The state of vector genome in transduced cells influences the duration of transgene expression and can be a safety concern if it gets integrated randomly into the host genome. Although human adenovirus (Ad) serotype 5 (HAd5) mainly persists in a linear episomal form, information regarding the state of bovine Ad serotype 3 (BAd3) and porcine Ad serotype 3 (PAd3) vector genomes in human and nonhuman cells is currently unknown. To address this issue, MDA-MB-231 (human), MDBK (bovine), PK-15 (porcine), MT1A2 (mouse) and NIH-3T3 (mouse) cell lines were infected with replication-defective BAd3, PAd3 or HAd5 vectors carrying the green fluorescent protein (GFP) gene. The persistence and the state of vector genome were assessed by quantitative real-time PCR and Southern blot hybridization, respectively. Levels of transgene and Ad gene expressions were quantified using real-time RT-PCR. Persistence of BAd3 or PAd3 vectors was comparable to that of HAd5 vector. Only the linear episomal form of the vector genome was observed with each vector. In addition, expression levels of transgene as well as viral genes by all three vectors were comparable and correlated with their transduction levels in each cell type. These results indicate comparable biologic behavior of BAd3, PAd3 and HAd5 vectors in cell culture.

A newly identified interaction between IVa2 and pVIII proteins during porcine adenovirus type 3 infection.

The adenovirus IVa2 is an intermediate viral gene product that appears to perform multiple essential roles in viral infection. Using IVa2 as bait in the yeast two-hybrid system, we screened selected open reading frames (ORFs) of porcine adenovirus (PAdV)-3 for potential interaction with IVa2. Interestingly, pVIII showed specific interaction with IVa2. The yeast two-hybrid findings were validated by GST pull-down assays, in vitro binding studies employing cell-free coupled transcription-translation products and in vitro co-immunoprecipitations using protein-specific antibodies. Finally, we demonstrated that IVa2 specifically interacts with pVIII during PAdV-3 infection.

Promoter activity of left inverted terminal repeat and downstream sequences of porcine adenovirus type 3.

Early region 1 (E1) of porcine adenovirus type 3 (PAdV-3) consists of E1A and E1B transcription units. The authentic promoter region of E1A contains a TATA box at nucleotide position (nt) 449 and a bifunctional regulatory element between nt 374 and 431, which enhances the transcription of E1A, but represses that of E1B. Here, we investigated the role of the left inverted terminal repeat (ITR) and its downstream sequences (between nt 151 and 312) in the transcription of early viral genes, and viral replication. Mutant PAdV-3s without the authentic E1A promoter region could be rescued by transfection of mutant genomic DNA into fetal porcine retina cells. Moreover, the mutant PAdV-3s produced E1A-specific mRNA and remained viable in swine testis (ST) cells suggesting that the left-terminal 151 bp including the ITR, can serve as a promoter for E1A expression. However, mutant PAdV-3s containing deletion including authentic E1A promoter region, displayed both reduced steady-state levels of early gene mRNAs (E1A, E1B, E2A, E3, and E4) and decreased rate of viral replication in ST cells. Interestingly, mutant PAdV-3s containing the left-terminal 312 bp displayed increased transcription of early genes including E1A. Our results suggest that the left ITR of PAdV-3 contain the promoter like elements and the sequences (between nt 151 and 312) downstream of left ITR can enhance its promoter activity.

Porcine adenovirus serotype 3 internalization is independent of CAR and alphavbeta3 or alphavbeta5 integrin.

Nonhuman adenoviruses including porcine adenovirus serotype 3 (PAd3) are emerging vectors for gene delivery. PAd3 efficiently transduces human and murine cells in culture, and circumvents preexisting humoral immunity in humans. The coxsackievirus-adenovirus receptor (CAR) serves as a primary receptor and alphavbeta3 or alphavbeta5 integrin as a secondary receptor for several human adenovirus (HAd) subtypes including HAd5. In this study, we deduced the role of CAR, alphavbeta3 or alphavbeta5 integrin in PAd3 internalization. Transduction experiments were conducted in human mammary epithelial (MCF-10A) cells using replication-defective PAd-GFP (PAd3 vector expressing green fluorescent protein [GFP]) and HAd-GFP (HAd5 vector expressing GFP). MCF-10A cells were treated with or without anti-human CAR, or anti-alphavbeta3 or anti-alphavbeta5 integrin antibodies prior to infection with HAd-GFP or PAd-GFP. Significant (P <0.05) inhibition in transduction by HAd-GFP was observed in antibody-treated cells as compared to untreated cells, whereas transduction by PAd-GFP remained to similar levels irrespective of the treatment. To study the adenoviral fiber knob-mediated virus interference, MCF-10A cells were treated with or without the recombinant HAd5 or PAd3 knob followed by infection with HAd-GFP or PAd-GFP. Significant (P <0.05) inhibition was observed only in transduction of the homologous vector. These results suggested that PAd3 internalization was CAR- as well as alphavbeta3 or alphavbeta5 integrin-independent and the primary receptor for HAd5 and PAd3 were distinct. CAR- and alphavbeta3 or alphavbeta5 integrin-independent entry of PAd3 vectors may have implications in targeting cell types that are not efficiently transduced by other adenoviral vectors.

Porcine adenoviral vectors evade preexisting humoral immunity to adenoviruses and efficiently infect both human and murine cells in culture.

Preexisting immunity against human adenoviruses (HAd) limits the efficiency of transduction of HAd vectors in humans. In addition, development of a vector-specific immune response after the first inoculation with a HAd vector further lowers vector uptake following readministration. We investigated the usefulness of porcine adenovirus serotype 3 (PAd3)-based vectors as a supplement to HAd vectors. Here we demonstrate that preexisting HAd-specific neutralizing antibodies in humans do not cross-neutralize PAd3. In order to generate E1A-deleted PAd3 vectors, an E1-complementing cell line of porcine origin was produced. E1A-deleted PAd3 vector expressing green fluorescent protein; GFP (PAd-GFP) and E1-deleted HAd5 vector expressing GFP (HAd-GFP) transduced human cell lines with comparable efficiencies. Both of these vectors efficiently transduced murine MT1A2 breast cancer cell line, while PAd-GFP transduced murine NIH 3T3 fibroblast cell line significantly better (P < 0.05) than HAd-GFP. These results suggest that PAd3 vectors would be promising supplement to HAd vectors as a delivery vehicle for recombinant vaccines and gene therapy applications.

Analysis of early region 4 of porcine adenovirus type 3.

The early region 4 (E4) of porcine adenovirus (PAdV)-3, located at the right-hand end of the genome is transcribed in a leftward direction and has the potential to encode seven (p1-p7) open reading frames (ORFs). To determine the role of each protein in viral replication, we constructed full-length PAdV-3 genomic clones containing deletions of individual E4 ORF or combined deletions of the neighboring ORFs. Transfection of swine testicular (ST) cells with individual E4 mutant plasmid DNAs generated PAdV-3 E4 mutant viruses except with plasmids containing a deletion of ORF p3, ORF p2+ p3 or ORF p3+ p4. Each of the mutants was further analyzed for growth kinetics, and early/late protein synthesis. Mutant viruses carrying deletions in ORF p1, ORF p2 or ORF p4 showed growth characteristics similar to that of wild-type PAdV-3. Early/late protein synthesis was also indistinguishable from that of wild-type PAdV-3. However, mutant viruses carrying deletions in ORF p5, ORF p6 or ORF p7 showed a modest effect in their ability to grow in porcine cells and express early proteins. These results suggest that the E4 ORF p3 (showing low homology with non-essential human adenovirus (HAdV)-9-E4 ORF1 encoded proteins) is essential for the replication of PAdV-3 in vitro. In contrast, the E4 ORF p7 (showing homology to essential HAdV-2 34 kDa protein) is not essential for replication of PAdV-3 in vitro. Moreover, successful deletion of 1.957 kb fragment in E4 region increased the available capacity of replication-competent PAdV-3 (E3 + E4 deleted) to approximately 4.3 kb and that of replication-defective PAdV-3 (E1 + E3 + E4 deleted) to approximately 7 kb. This is extremely useful for the construction of PAdV-3 vectors that express multiple genes and/or regulatory elements for gene therapy and vaccination.

cis-Acting packaging motifs of porcine adenovirus type 3.

The cis-acting packaging domain is required for selective encapsidation of adenovirus DNA into preformed empty capsids late in the viral life cycle. Earlier, it was demonstrated that the cis-acting packaging domain of porcine adenovirus type (PAdV)-3 is located between nucleotide position (nt) 212 and 531 at the left end genome which contains six AT/GC rich motifs. Removal of packaging domain from left end to the right end of the genome produced a viable mutant virus suggesting that the identified cis-acting packaging domain represents the DNA sequences required for selective packaging of PAdV-3 DNA, whose position and orientation appear to be flexible. Here, by constructing and analyzing a panel of virus mutants carrying deletions or linker scanning mutations in AT/GC rich sequences, we examined the significance of the continuous A/T or G/C sequences individually in the viral packaging process. In contrast to consensus bipartite structure (5'-TTTGN8CG-3') described for most of packaging motifs of human adenovirus type 5 (HAdV-5), the packaging motifs I, II, III, and IV of PAdV-3 displayed a tripartite structure in which the continuous A/T nucleotides were flanked by G/C-rich sequences. Mutations in both continuous A/T nucleotides and its flanking GC-rich sequences reduced the packaging efficiency of mutants to varying degrees. In addition, although the continuous A/T sequences were present in all of the packaging motifs, their significance in the packaging process appears to vary within each packaging motif.

Porcine adenovirus type 3 E1 transcriptional control region contains a bifunctional regulatory element.

We identified a bifunctional regulatory element located between nt 374 and 431 upstream of TATA box of porcine adenovirus (PAV) 3 E1A promoter. Deletion of the element dramatically reduced the steady-state level of E1A mRNA, but increased that of E1B, which lies immediately downstream of E1A. The mutant virus displayed defective replication at early times of infection, but replicated nearly as efficiently as wild-type PAV-3 at late times of infection. This defect was complemented with coinfecting wild-type virus in a mixed infection. The results indicated that the upstream activation sequences (UAS) of E1A overlap the upstream repression sequences (URS) of E1B, although both transcription units are transcribed from different promoters.