Deletion of open reading frames 9, 10 and 11 from the avian adenovirus CELO genome: effect on biodistribution and humoral responses

Downregulation of Cell Surface Major Histocompatibility Complex Class I Expression Is Mediated by the Left-End Transcription Unit of Fowl Adenovirus 9

Major histocompatibility complex class I (MHC-I) molecules play a critical role in the host’s antiviral response by presenting virus-derived antigenic peptides to cytotoxic T lymphocytes (CTLs), enabling the clearance of virus-infected cells. Human adenoviruses evade CTL-mediated cell lysis, in part, by interfering directly with the MHC-I antigen presentation pathway through the expression of E3-19K, which binds both MHC-I and the transporter associated with antigen processing protein and sequestering MHC-I within the endoplasmic reticulum. Fowl adenoviruses have no homologues of E3-19K. Here, we show that representative virus isolates of the species Fowl aviadenovirus C, Fowl aviadenovirus D, and Fowl aviadenovirus E downregulate the cell surface expression of MHC-I in chicken hepatoma cells, resulting in 71%, 11%, and 14% of the baseline expression level, respectively, at 12 h post-infection. Furthermore, this work reports that FAdV-9 downregulates cell surface MHC-I through a minimum of two separate mechanisms—a lysosomal-independent mechanism that requires the presence of the fowl adenovirus early 1 (FE1) transcription unit located within the left terminal genomic region between nts 1 and 6131 and a lysosomal-dependent mechanism that does not require the presence of FE1. These results establish a new functional role for the FE1 transcription unit in immune evasion. These studies provide important new information about the immune evasion of FAdVs and will enhance our understanding of the pathogenesis of inclusion body hepatitis and advance the progress made in next-generation FAdV-based vectors.

Generation and characterization of a fowl adenovirus 9 dual-site expression vector

Fowl adenoviruses (FAdVs) are widely considered as excellent platforms for vaccine development and gene therapy. We improved on our right-end partial TR-2 deleted or a left-end 2.3 kb deleted vectors by developing a single, dual-site delivery vector. We demonstrated that, in addition to ORF11, the right end ORF17 is also dispensable. To further improve the capacity and flexibility of the FAdV-9 based vector system, we generated an infectious recombinant FAdV-9 dual-site expression clone lacking 1.9 kb of the left end and replaced with mCherry under the control of a native promoter, and 3.6 kb of the right-end replaced with an EGFP expression cassette. Five intermediate FAdmid clones were successfully constructed: a) pFAdV-9Δ0-2RED (mCherry replacing the left end 2.2 kb ORF0 to 2); b) pFAdV-9RED (mCherry replacing the left end 1.9 kb ORF1 to 2); c) pFAdV-9Δ17 (deletion of ORF17 and 393 bp downstream untranslated region); d) pFAdV-9GFP (EGFP expression cassette replacing the right end 3.6 kb) and e) pFAdV-9Dual (both mCherry in the left end and the EGFP expression cassette in the right end of our vector). Our novel FAdV-9 dual-site vaccine vector, produced infectious virus and expressed either one or both mCherry and EGFP.

Chronological analysis of gross and histological lesions induced by field strains of fowl adenovirus serotypes 1, 8b and 11 in one-day-old chickens

Fowl adenoviruses (FAdVs) cause diseases in domestic chickens, including inclusion body hepatitis (IBH), with immunosuppression believed to play a role in their pathogenesis. To gain a better understanding of the pathogenesis and chronology of disease caused by FAdVs, the gross pathology, histopathology and dissemination of virus were examined at several different time points, after inoculation of one-day-old specific pathogen-free chickens with FAdV-1, FAdV-8b or FAdV-11 via the ocular route. FAdV-8b had a slightly greater virulence than FAdV-11, but both were primary pathogens. The presence and severity of hepatic lesions were used to define the three stages of the disease: incubation (1-3 days post-inoculation, PI), degeneration (4-7 days PI) and convalescence (14 days PI). Both viruses were detected in the liver, kidney, bursa, thymus and gizzard of most birds during the degenerative stage, and persisted in the gizzard into convalescence. The FAdV-1 isolate was found to be apathogenic, but virus was detected in the bursa and/or gizzard of several birds between 2 and 7 days PI. This is the first study examining the chronology of gross and microscopic lesions of pathogenic and apathogenic FAdVs in association with viral presence in multiple tissues. It was concluded that both FAdV-8b and FAdV-11 are primary pathogens, and that these strains may play a role in immunosuppression.

Genome sequence of a waterfowl aviadenovirus, goose adenovirus 4

We present, to our knowledge, the first complete genome sequence of a waterfowl aviadenovirus, goose adenovirus (GoAdV) strain P29, and an analysis of its genetic content in comparison with five published aviadenovirus genome sequences. Of the 35 genes predicted to encode functional proteins, the central region of the genome contains 19 (IVa2 to fiber-2) that were inherited from the ancestor of all known adenoviruses. Of the remaining genes, nine have orthologues only in aviadenoviruses and seven lack orthologues in any adenovirus. We also obtained limited sequence data for a pathogenic GoAdV strain D1036/08. Phylogenetic analyses placed the two GoAdV strains monophyletically in the genus Aviadenovirus. We propose designating strains P29 and D1036/08 as GoAdV-4 and GoAdV-5, respectively.

Antibody fragments, expressed by a fowl adenovirus vector, are able to neutralize infectious bursal disease virus

Single-chain variable fragments (scFv) contain the heavy and light chain variable domains of immunoglobulin, joined by a short peptide linker. Previously, our laboratory has produced neutralizing scFv to epitopes of infectious bursal disease virus (IBDV). The in vitro delivery and expression of one of these scFv with and without the C(H)2-C(H)4 Fc domain of chicken IgY attached (scFv-Fc) by a serotype 8 fowl adenovirus (FAdV-8) vector was investigated in the present study. A panel of FAdV-8 vectors was constructed, each containing a different transgene (scFv or scFv-Fc), a different promoter to drive scFv and scFv-Fc transcription (CMVie or the fowl adenovirus major late promoter), and a different sized, right-hand end genomic deletion (52 bp or 2.3 kb). This panel was used to establish what effect these variables had on protein production, viral replication and scFv transcription, as measured by enzyme-linked imunosorbent assay and real-time polymerase chain reaction. Our results showed that, using a FAdV-8 vector containing the optimal CMVie promoter/2.3 kb deletion combination, we successfully expressed a secreted form of both scFv and scFv-Fc that were able to neutralize IBDV both in vitro and in ovo. These studies indicate that the FAdV-8 vector may be a promising candidate to deliver and express therapeutic molecules such as scFv and scFv-Fc in vivo in poultry.

The non-essential left end region of the fowl adenovirus 9 genome is suitable for foreign gene insertion/replacement

The goals of this study were to demonstrate that a non-essential region at the left end of the fowl adenovirus 9 (FAdV-9) genome could be used to generate recombinant viruses, examine their in vitro growth characteristics and determine their ability to transduce non-avian cells. Three FAdV-9 vectors (rFAdV-9s) were generated carrying the enhanced-green fluorescent protein (EGFP) gene: FAdV-9inEGFP, FAdV-9 Delta 1-EGFP and FAdV-9 Delta 4-EGFP. FAdV-9inEGFP carried the EGFP cassette inserted into the non-essential region without deletion resulting in an increase of the genome size to 103.7% of the wild-type. FAdV-9 Delta 1-EGFP and FAdV-9 Delta 4-EGFP (rFAdV-9 Delta s) carried the EGFP cassette replacing the non-essential sequences at nucleotides 1194-2342 and 491-2782, respectively. All rFAdV-9s had wild-type growth kinetics and plaque morphology. The rFAdV-9 Delta s replicated in CH-SAH cells with the same titers as the wild-type virus. The FAdV-9inEGFP titers were approximately 1 log lower than those of rFAdV-9 Delta s and wt FAdV-9 at 36 and 48 h post-infection (h.p.i.). EGFP was expressed in avian and mammalian cells infected with rFAdV-9s. EGFP expression, based on spectrofluorometry, was significantly higher in chicken hepatoma cells infected with FAdV-9inEGFP than in those with rFAdV-9 Delta s at 18 and 24h.p.i, suggesting a functional role of some or all non-essential ORFs on foreign gene expression. This study demonstrated the suitability of the non-essential region as an insertion/replacement site for foreign genes to generate FAdV-9-based vectors that can be applied as recombinant vaccines for poultry or gene delivery vehicles for mammalian systems.

First step in characterization of cis-acting sequences involved in fowl adenovirus 1 (CELO) packaging and its effect on the development of a helper-dependent vector strategy

Adenovirus-based vectors are widely developed for potential utilization as vectors in vaccine and gene therapy strategies. We focused on developing a helper-dependent adenoviral (HD-Ad) vector for the potential use of CELO, a member of the Aviadenovirus genus, in avian species vaccination. Our aim was to localize sequences which could play an essential role in CELO genome encapsidation and, when deleted, was unable to produce viruses to develop a helper CELO virus. A panel of 6 mutants with deletions between nt 80 and 350 of the CELO genome was constructed and characterized for its ability to produce viable virus. To develop a helper-dependent adenoviral vector derived from CELO, a helper virus was developed by inserting loxP sequences around the region containing the identified putative packaging sequences. A LMH (Leghorn Male Hepatocarcinoma) cell line expressing Cre recombinase was developed to allow the excision of this region. We demonstrated that the region from nt 200 to 250 was important and the region from nt 250 to 300 at the left end of the CELO genome was essential for virus encapsidation. We also showed that the loxP-flanked region was efficiently removed in a Cre expressing cell line to produce a candidate helper virus.