Sequence and transcriptional analysis of terminal regions of the fowl adenovirus type 8 genome

An insertion and deletion mutant of adenovirus in Muscovy ducks

Duck adenovirus 3 (DuAdV-3; strain HB) was isolated and sequenced. The genome of the Muscovy-duck-origin virus contains a 54-bp insertion in pVIII, a 3-bp deletion in the overlap region of 100K, 22K, and 33K, a 42-bp deletion at the junction of ORF64 and ORF67, and a 715-bp deletion in right noncoding region of the genome. Notably, HB has a strikingly shorter right inverted terminal repeat (ITR) of 50 bp, whereas all other DuAdV-3 isolates have a 721-bp ITR. These findings demonstrate that HB is an insertion and deletion mutant of DuAdV-3.

In vitro growth kinetics and gene expression analysis of the turkey adenovirus 3, a siadenovirus

Turkey adenovirus 3 (TAdV-3) belongs to the genus Siadenovirus, family Adenoviridae. Previously, nucleotide sequencing and annotation of the Virginia avirulent strain (VAS) of TAdV-3 genome, isolated in our laboratory, indicated the presence of a total of 23 genes and open reading frames (ORFs). The goals of this study were 1) to delineate the growth kinetics of the virus using a qPCR-based infectivity assay, and 2) to determine the virus gene expression profile during the early and late phases of infection in target B lymphocytes. The one-step growth curve experiment demonstrated 3 phases of virus replication cycle: a lag phase lasted for 12-18 h post-infection (h.p.i.), in which the virus titer declined; a log phase from 18 to 120 h.p.i., in which the number of infectious virus particles increased over 20,000 folds, and a brief decline phase thereafter. Southern blot analysis indicated that the synthesis of new viral DNA started by 8 h.p.i. Gene-specific RT-PCR analysis revealed the expression of mRNAs from the 23 TAdV-3 genes/ORFs. According to the temporal transcriptional profiling of TAdV-3 genome, genes could be divided into 3 groups based on the time of transcription initiation: group 1 showed detectable levels of transcription at 2 h.p.i and included 7 genes, i.e., hyd, III, pX, pVI, II, 100 K, and 33 K; group 2 included 12 genes whose mRNAs were detected for the first time at 4 h.p.i., i.e., ORF1, IVa2, pol, pTP, pIIIa, EP, DBP, E3, U exon, IV, ORF7, and ORF8; group 3 of transcripts were detectable starting 8 h.p.i. and included only 4 genes, i.e., 52 K, 22 K, pVII, and pVIII. Our data suggest that the transcriptional kinetics of genus Siadenovirus differ from that observed in other adenoviral genera; however, a few TAdV-3 genes showed similar expression patterns to their adenoviral homologs.

Identification of a novel aviadenovirus, designated pigeon adenovirus 2 in domestic pigeons (Columba livia)

The young pigeon disease syndrome (YPDS) affects mainly young pigeons of less than one year of age and leads to crop stasis, vomitus, diarrhea, anorexia and occasionally death. This disease is internationally a major health problem because of its seasonal appearance during competitions such as homing pigeon races or exhibitions of ornamental birds. While the etiology of YPDS is still unclear, adenoviruses are frequently discussed as potential causative agents. Electron microscopy of feces from a YPDS outbreak revealed massive shedding of adenovirus-like particles. Whole genome sequencing of this sample identified a novel adenovirus tentatively named pigeon adenovirus 2 (PiAdV-2). Phylogenetic and comparative genome analysis suggest PiAdV-2 to belong to a new species within the genus Aviadenovirus, for which we propose the name Pigeon aviadenovirus B. The PiAdV-2 genome shares 54.9% nucleotide sequence identity with pigeon adenovirus 1 (PiAdV-1). In a screening of further YPDS-affected flocks two variants of PiAdV-2 (variant A and B) were detected which shared 97.6% nucleotide identity of partial polymerase sequences, but only 79.7% nucleotide identity of partial hexon sequences. The distribution of both PiAdV-2 variants was further investigated in fecal samples collected between 2008 and 2015 from healthy or YPDS-affected racing pigeons of different lofts. Independent of their health status, approximately 20% of young and 13% of adult pigeon flocks harbored PiAdV-2 variants. Birds were free of PiAdV-1 or other aviadenoviruses as determined by PCRs targeting the aviadenovirus polymerase or the PiAdV-1 fiber gene, respectively. In conclusion, there is no indication of a correlation between YPDS outbreaks and the presence of PiAdV-2 or other aviadenoviruses, arguing against an causative role in this disease complex.

Comparison of fiber gene sequences of inclusion body hepatitis (IBH) and non-IBH strains of serotype 8 and 11 fowl adenoviruses

Fowl adenoviruses (FAdVs) are common in broiler operations, and the most frequently isolated FAdVs belong to serotypes 1, 8, and 11. Serotype 1 viruses are considered nonpathogenic. While some serotype 8 and 11 viruses cause inclusion body hepatitis (IBH), these virus serotypes can also be isolated from non-IBH cases. The fiber protein is one of the major constituents of the adenoviral capsid, involved in virus entry, and it has been implicated in the variation of virulence of FAdVs. The fiber gene sequences of four FAdV-8 and four FAdV-11 isolates from both IBH and non-IBH cases were determined and analyzed for a possible association of the fiber gene sequence in virulence. The fiber protein can be divided into tail, shaft, and head domains comprising some specific features. The conserved "RKRP" sequence motif (aa 17-aa 20) fit the consensus sequence predicted for the nuclear localization signal, while the "VYPF" motif (aa 53-aa 56), involved in the penton base interaction, was also found. Similar to mammalian adenoviruses, 17 pseudo-repeats with an average length of 16 aa were detected in the FAdV-8 fiber shaft region, while 20 pseudo-repeats with an average length of 18 aa were found in FAdV-11 fibers. There was a 144-147 nt difference between the fiber genes of the two FAdV serotypes. In the shaft region, the TLWT motif that marks the beginning of the fiber head domain of the mastadenovirus was not evident among examined FAdVs. The FAdV-11 isolates had 99.1 % aa sequence identity and 99.3 % similarity to each other, and there was no conserved aa substitution within the fibers. The FAdV-8 fiber proteins showed an overall lower, 89 % aa sequence identity and 93.4 % similarity, to each other and 22 nonsynonymous mutations were detected. Virulence markers were not detected in the analyzed fiber gene sequences of the different pathotypes of the two FAdV serotypes.

Polymerase chain reaction combined with restriction enzyme analysis for detection and differentiation of fowl adenoviruses

A polymerase chain reaction combined with restriction enzyme analysis was developed for detection and differentiation of all 12 fowl adenovirus (FAdV) serotypes representing the five fowl adenovirus (A to E) species. For primer design, the published sequences of the hexon proteins of FAdV1, FAdV8 and FAdV9 were aligned and conserved regions in the two pedestal regions adjacent to the L1 loop region were determined. A primer pair (hexon A/hexon B) was constructed and was shown to amplify approximately 900 bp of the hexon gene including the L1 loop region. An amplification product was detected using supernatant of infected cell cultures from all FAdV1 to FAdV12 reference strains used in our study. The sequence and the restriction patterns of the hexon A/B fragments of the 12 FAdV strains were determined and compared. The successive use of four different endonucleases allowed the complete differentiation of the reference FAdV strains. Twenty-six fowl adenoviruses isolated during our routine virological diagnosis activities could all be amplified using hexon A/hexon B primers. Restriction analysis results showed that 8/26 adenovirus strains contained two different FAdV types. FAdV4, FAdV12, FAdV1, FAdV5 and FAdV6 were the most frequently isolated.

Coding potential and transcript analysis of fowl adenovirus 4: insight into upstream ORFs as common sequence features in adenoviral transcripts

Recombinant fowl adenoviruses (FAdVs) have been successfully used as veterinary vaccine vectors. However, insufficient definitions of the protein-coding and non-coding regions and an incomplete understanding of virus-host interactions limit the progress of next-generation vectors. FAdVs are known to cause several diseases of poultry. Certain isolates of species FAdV-C are the aetiological agent of inclusion body hepatitis/hydropericardium syndrome (IBH/HPS). In this study, we report the complete 45667 bp genome sequence of FAdV-4 of species FAdV-C. Assessment of the protein-coding potential of FAdV-4 was carried out with the Bio-Dictionary-based Gene Finder together with an evaluation of sequence conservation among species FAdV-A and FAdV-D. On this basis, 46 potentially protein-coding ORFs were identified. Of these, 33 and 13 ORFs were assigned high and low protein-coding potential, respectively. Homologues of the ancestral adenoviral genes were, with few exceptions, assigned high protein-coding potential. ORFs that were unique to the FAdVs were differentiated into high and low protein-coding potential groups. Notable putative genes with high protein-coding capacity included the previously unreported fiber 1, hypothetical 10.3K and hypothetical 10.5K genes. Transcript analysis revealed that several of the small ORFs less than 300 nt in length that were assigned low coding potential contributed to upstream ORFs (uORFs) in important mRNAs, including the ORF22 mRNA. Subsequent analysis of the previously reported transcripts of FAdV-1, FAdV-9, human adenovirus 2 and bovine adenovirus 3 identified widespread uORFs in AdV mRNAs that have the potential to act as important translational regulatory elements.

Pathogenicity and complete genome sequence of a fowl adenovirus serotype 8 isolate

In this study we determined and analyzed the complete nucleotide sequence of the genome of a fowl adenovirus serotype 8 (FAdV-8) isolate and examined its pathogenicity in chickens. The full genome of FAdV-8 was 44,055 nucleotides in length with a similar organization to that of FAdV-1 and FAdV-9 genomes. No regions homologous to early regions E1, E3 and E4 of mastadenoviruses were recognized. Along with FAdV-9, FAdV-8 has only one fiber gene and with regard to sequence composition and genome organization, FAdV-8 is closer to FAdV-9 than to FAdV-1. Moreover, our findings suggest that FAdV-1 of species Fowl adenovirus A as the current type species despite its historical priority is not representative of the genus Aviadenovirus, and that FAdV-8 or FAdV-9 in species Fowl adenovirus E and Fowl adenovirus D, respectively, would be more suitable for that designation. Additionally, pathogenicity of FAdV-8 was studied in specific pathogen free chickens following oral and intramuscular inoculations. Despite lack of clinical signs and pathological changes virus was found in tissues and cloacal swabs of all birds with the highest viral copy numbers present in the cecal tonsils. The highest virus titers in the feces for orally and intramuscularly inoculated chickens were recorded at days 10 and 3 post-infection, respectively.

Sequence Analysis of the Left End of Fowl Adenovirus Genomes

Nucleotide sequence analysis of the left end of the genome of fowl adenoviruses (FAdV) representing species group C (FAdV-4 and -10), D (FAdV-2) and E (FAdV-8) were carried out, and the sequence data was compared to those of FAdV-1 (FAdV-A) and FAdV-9 (FAdV-D). The viruses were propagated in chicken hepatoma cell line for viral DNA isolation. Restriction endonuclease analysis was performed followed by hybridization with two DNA probes representing the left end of FAdV-9. The identified fragments were sequenced, and the generated data were compared with the GenBank database. Nucleotide sequence homology and amino acid sequence identities were high between members of the same species group, FAdV-2 and -9, and FAdV-4 and -10, whereas different degrees of variations were observed among all FAdVs. Gene arrangement and position of ORFs at the left end of FAdV genomes were largely conserved suggesting similar gene functions. All previously characterized left end ORFs in CELO virus and FAdV-9 were found in all analyzed FAdVs. However, ORF 1C was absent in FAdV-4 and -10, but additional ORFs, most likely corresponding to duplicates of ORF 14, were observed in these viruses.

vLIP, a viral lipase homologue, is a virulence factor of Marek's disease virus

The genome of Marek's disease virus (MDV) has been predicted to encode a secreted glycoprotein, vLIP, which bears significant homology to the alpha/beta hydrolase fold of pancreatic lipases. Here it is demonstrated that MDV vLIP mRNA is produced via splicing and that vLIP is a late gene, due to its sensitivity to inhibition of DNA replication. While vLIP was found to conserve several residues essential to hydrolase activity, an unfavorable asparagine substitution is present at the lipase catalytic triad acid position. Consistent with structural predictions, purified recombinant vLIP did not show detectable activity on traditional phospholipid or triacylglyceride substrates. Two different vLIP mutant viruses, one bearing a 173-amino-acid deletion in the lipase homologous domain, the other having an alanine point mutant at the serine nucleophile position, caused a significantly lower incidence of Marek's disease in chickens and resulted in enhanced survival relative to two independently produced vLIP revertants or parental virus. These data provide the first evidence that vLIP enhances the replication and pathogenic potential of MDV. Furthermore, while vLIP may not serve as a traditional lipase enzyme, the data indicate that the serine nucleophile position is nonetheless essential in vivo for the viral functions of vLIP. Therefore, it is suggested that this particular example of lipase homology may represent the repurposing of an alpha/beta hydrolase fold toward a nonenzymatic role, possibly in lipid bonding.

Complete genome sequence of simian adenovirus 1: an Old World monkey adenovirus with two fiber genes

Simian adenovirus 1 (SAdV-1) is one of many adenovirus strains that were isolated from Old World monkey cells during poliomyelitis vaccine production several decades ago. Despite the availability of these viruses, knowledge of their genetic content and phylogeny is rudimentary. In the present study, the genome sequence of SAdV-1 (34 450 bp) was determined and analysed. In regions where genetic content varies between primate adenoviruses, SAdV-1 has a single virus-associated RNA gene, six genes in each of the E3 and E4 regions and two fiber genes. SAdV-1 clusters phylogenetically with HAdV-40, a member of human adenovirus species HAdV-F, which also has two fiber genes. However, based on phylogenetic distances and other taxonomic criteria, SAdV-1 is proposed to represent a novel adenovirus species.

Antibody response and virus tissue distribution in chickens inoculated with wild-type and recombinant fowl adenoviruses

We demonstrated that the long tandemly repeated region (TR-2) is dispensable for in vitro replication of fowl adenovirus 9 (FAdV-9). The TR-2-deleted recombinant FAdV-9 expressing the enhanced green fluorescence protein was further characterized for in vivo effects. Groups of chickens were exposed to recombinant or wild-type FAdV-9 by intramuscular injection, through the feed or drinking water and one group served as a negative control. The antibody (Ab) response, evaluated by ELISA and a plaque reduction test depended on the virus, dosage and the route of inoculation. Although the highest levels of anti-viral Ab were detected in chickens inoculated intramuscularly (i.m.) with wild-type FAdV-9, the deletion of TR-2 did not have a significant effect on the immune response. The tissue distribution of the virus was examined by the polymerase chain reaction (PCR) and was similar for both wild-type and recombinant viruses. Based on these results the TR-2 was dispensable for viral replication in vivo and did not influence virus distribution, and the recombinant FAdV-9 induced the same immune response as the wild-type virus.

Reannotation of the CELO genome characterizes a set of previously unassigned open reading frames and points to novel modes of host interaction in avian adenoviruses

BACKGROUND

The genome of the avian adenovirus Chicken Embryo Lethal Orphan (CELO) has two terminal regions without detectable homology in mammalian adenoviruses that are left without annotation in the initial analysis. Since adenoviruses have been a rich source of new insights into molecular cell biology and practical applications of CELO as gene a delivery vector are being considered, this genome appeared worth revisiting. We conducted a systematic reannotation and in-depth sequence analysis of the CELO genome.

RESULTS

We describe a strongly diverged paralogous cluster including ORF-2, ORF-12, ORF-13, and ORF-14 with an ATPase/helicase domain most likely acquired from adeno-associated parvoviruses. None of these ORFs appear to have retained ATPase/helicase function and alternative functions (e.g. modulation of gene expression during the early life-cycle) must be considered in an adenoviral context. Further, we identified a cluster of three putative type-1-transmembrane glycoproteins with IG-like domains (ORF-9, ORF-10, ORF-11) which are good candidates to substitute for the missing immunomodulatory functions of mammalian adenoviruses. ORF-16 (located directly adjacent) displays distant homology to vertebrate mono-ADP-ribosyltransferases. Members of this family are known to be involved in immuno-regulation and similiar functions during CELO life cycle can be considered for this ORF. Finally, we describe a putative triglyceride lipase (merged ORF-18/19) with additional domains, which can be expected to have specific roles during the infection of birds, since they are unique to avian adenoviruses and Marek's disease-like viruses, a group of pathogenic avian herpesviruses.

CONCLUSIONS

We could characterize most of the previously unassigned ORFs pointing to functions in host-virus interaction. The results provide new directives for rationally designed experiments.

Unique features of fowl adenovirus 9 gene transcription

We examined the transcriptional organization of fowl adenovirus 9 (FAdV-9) and analyzed temporal transcription profiles of its early and late mRNAs. At least six early and six late transcriptional regions were identified for FAdV-9. Extensive splicing was observed in all FAdV-9 early transcripts examined. Sequence analysis of the cDNAs representing the early proteins identified untranslated leader sequences, precise locations of splice donor and acceptor sites, as well as polyadenylation signals and polyadenylation sites. A unique characteristic, compared to other adenoviruses, was the detection by RT-PCR of multiple transcripts specific for each of five late genes (protein III, pVII, pX, 100K, and fiber), suggesting that FAdV-9 late transcripts undergo more extensive splicing than reported for other adenoviruses.

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.

Construction of avian adenovirus CELO recombinants in cosmids

The avian adenovirus CELO is a promising vector for gene transfer applications. In order to study this potentiality, we developed an improved method for construction of adenovirus vectors in cosmids that was used to engineer the CELO genome. For all the recombinant viruses constructed by this method, the ability to produce infectious particles and the stability of the genome were evaluated in a chicken hepatocarcinoma cell line (LMH cell line). Our aim was to develop a replication-competent vector for vaccination of chickens, so we first generated knockout point mutations into 16 of the 22 unassigned CELO open reading frames (ORFs) to determine if they were essential for virus replication. As the 16 independent mutant viruses replicated in our cellular system, we constructed CELO genomes with various deletions in the regions of these nonessential ORFs. An expression cassette coding for the enhanced green fluorescent protein (eGFP) was inserted in place of these deletions to easily follow expression of the transgene and propagation of the vector in cell monolayers. Height-distinct GFP-expressing CELO vectors were produced that were all replication competent in our system. We then retained the vector backbone with the largest deletion (i.e., 3.6 kb) for the construction of vectors carrying cDNA encoding infectious bursal disease virus proteins. These CELO vectors could be useful for vaccination in the chicken species.

The long repeat region is dispensable for fowl adenovirus replication in vitro

Two regions containing tandemly repeated sequences are present in the fowl adenovirus 9 (FAdV-9) genome. The longer repeat region (TR-2) is composed of 13 contiguous 135-bp-long direct repeats, the function of which is unknown. An infectious FAdV-9 genomic clone, constructed by homologous recombination in Escherichia coli, was used for engineering of recombinant viruses. The enhanced green fluorescence protein (EGFP) coding sequence was cloned in both rightward and leftward orientations so as to replace TR-2. Replication-competent recombinant FAdVs were recovered, demonstrating that TR-2 was dispensable for FAdV-9 propagation in vitro. The expression of EGFP in infected cells was demonstrated by fluorescence microscopy, immunoprecipitation, and RT-PCR.

Four new inverted terminal repeat sequences from bovine adenoviruses reveal striking differences in the length and content of the ITRs

The inverted terminal repeat (ITR) of the genome of four bovine adenovirus (BAdV) types have been sequenced, analysed and compared to the ITRs of other adenoviruses. The length of ITRs of the examined BAdVs ranged between 59 and 368 base pairs, thus the presently known longest adenovirus ITR sequence is from BAdV-10. The conserved motifs and characteristic sequence elements of the ITRs providing different binding sites for replicative proteins of viral and cellular origin seemed to be distributed according to the proposed genus classification of BAdVs. The ITRs of BAdV-10 share similarity with the members of the genus Mastadenovirus, while the ITRs of the other three sequenced serotypes (BAdV-4, 5 and strain Rus) which are candidate members of the genus Atadenovirus are very short and contain NFI and Sp1 binding sites only. The analysis of the new ITRs implied that the nucleotide sequence of the so-called core origin is highly preserved within the mastadenovirus genus only.

The ORF RTL1 transcript of fowl adenovirus type-8 is spliced and truncated at late stages of the virus replication cycle

Two transcription products were found for the open reading frame (ORF) RTL1 located near the right terminus of the fowl adenovirus type-8 genome. The larger transcript, which was transcribed mostly during the early stage of the virus infection, contains the complete sequence (933 nucleotides) of the predicted ORF from the genomic DNA sequence encoding a 311 amino acid (aa) polypeptide. In contrast, the shorter transcript, which was more predominant at the late stage of the infection, was missing 580 nucleotides (from nucleotide 117 to 696). A premature stop codon was introduced at 210 nucleotides downstream from the start codon and the shorter transcript would encode a 70 aa polypeptide. This observation indicates that the ORF RTL1 may produce two different proteins, which function differently at different stages of the virus infection. Another possibility is that the virus may use alternative splicing as a mechanism to control the expression of the ORF, since the spliced transcript was prematurely terminated at the late stage of the infection.

The complete nucleotide sequence of fowl adenovirus type 8

The fowl adenovirus type 8 (FAdV-8) genome was sequenced and found to be 45063 nucleotides in length, the longest adenovirus (AdV) genome for which the complete nucleotide sequence has been determined so far. No regions homologous to early regions 1, 3 and 4 (E1, E3 and E4) of mastadenoviruses were recognized. Gene homologues for early region 2 (E2) proteins, intermediate protein IVa2 and late proteins were found by their similarities to protein sequences from other AdVs. However, sequences homologous to intermediate protein IX and late protein V could not be identified. Sequences for virus-associated RNA could also not be recognized. Two regions of repeated sequences were found on the FAdV-8 genome. The shorter repeat region contained five identical and contiguous direct repeats that were each 33 bp long, while the longer repeat region was made of 13 identical and contiguous, 135 bp long repeated subunits.

Growth characteristics of fowl adenovirus type 8 in a chicken hepatoma cell line

Fowl adenoviruses, many of which appear to be non-pathogenic, are ubiquitous in birds. In addition, the genome of these viruses is large, making them ideal candidates for construction as vectors for foreign genes. Current methods to cultivate fowl adenoviruses use primary cell cultures derived from embryonated chicken eggs. In order to provide a more suitable culture method, the growth of fowl adenovirus type 8 (FAdV-8) was investigated in CH-SAH, a continuous hepatoma cell line. A one step growth curve demonstrated release of extracellular virus beginning by 18 h p.i. and with a final yield about 100 fold higher than that in chicken embryo liver cells. Viral DNA synthesis was first detected 8 h prior to this. The CH-SAH cell line supported the production of progeny viruses similar to the wild-type virus after being transfected with purified FAdV-8 DNA. This study demonstrated that the continuous hepatoma cell line is an appropriate in vitro host for FAdV-8.