First report of the whole-genome sequence analysis of avian rotavirus A from Japanese chickens.

Rotavirus A infects many mammalian species, including humans and causes diarrhea and gastrointestinal diseases. The virus also infects various bird species, including chickens, although information of avian rotavirus A (ARVA) infection in chicken populations in Japan is scarce. In this study, we report for the first time the whole-genome sequences of ARVA strains from Japanese chicken populations. The virus strains were inoculated to MA104 cells and cultured viruses were used to obtain the sequences with the MiSeq system, and genetic analysis demonstrated the genotype constellation of G19-P[30]-I11-R6-C6-M7-A16-N6-T8-E10-H8 of the Japanese chicken ARVA isolates. Phylogenetic analyses demonstrated that the VP1, VP2, VP3, VP4, VP7, NSP2, and NSP4 coding gene sequences of the Japanese strains were closer to those of Korean than the European ARVA strains, although such relationship was not clear for other genes. The data suggest that the Japanese ARVA strains and the ones in Korea have genetically close relationship, although the origin is not clear at this point. Further information including the whole-genome sequences of the Korean strains and sequences of other Japanese chicken ARVA strains will be necessary for elucidation of their origin.

Establishment of a reverse genetics system for avian rotavirus A strain PO-13.

Avian rotavirus A (RVA) is one of major enteric pathogens that cause diarrhoea in young avian individuals. Importantly, some of the avian RVA strains of G18P[17] genotype are naturally transmitted to and cause clinical diseases in mammalian species, indicating their potential risks to animal health. Although molecular information on the pathogenesis by avian RVA strains will be useful for estimating their risks, the absence of a reverse genetics (RG) system for these strains has hindered the elucidation of their pathogenic mechanisms. In this study, we aimed to establish an RG system for the avian G18P[17] prototype strain PO-13, which was isolated from a pigeon in Japan in 1983 and was experimentally shown to be pathogenic in suckling mice. Transfection with plasmids expressing 11 genomic RNA segments of the strain resulted in rescue of the infectious virus with an artificially introduced genetic marker on its genome, indicating that an RG system for the PO-13 strain was successfully established. The rescued recombinant strain rPO-13 had biological properties almost identical to those of its wild-type strain (wtPO-13). Notably, both rPO-13 and wtPO-13 induced diarrhoea in suckling mice with similar efficiencies. It was thus demonstrated that the RG system will be useful for elucidating the pathogenic mechanisms of the PO-13 strain at the molecular level. This is the first report of the establishment of an RG system for an avian RVA strain.

Potential of avian and mammalian species A rotaviruses to reassort as explored by plasmid only-based reverse genetics.

Species A rotavirus (RVA) is an important gastrointestinal pathogen that is widely distributed in humans, mammalian animals and birds. The RVA genome consists of eleven double-stranded RNA segments, enabling the generation of novel strains with new pathogenic or antigenic features by genetic reassortment. While reassortants between human and mammalian animal RVAs have been repeatedly described, data on the reassortment potential of avian RVA strains are rare. To investigate genome segment exchanges between avian and mammalian RVA strains, a plasmid-based reverse genetics strategy originally developed for the simian RVA strain SA11 was used here. All eleven genome segments of the chicken RVA strain 02V0002G3 were cloned into similar plasmids as in the SA11 system. However, in contrast to SA11, no infectious virus could be generated by transfection of the eleven 02V0002G3 plasmids into cell culture under the same conditions. In another series of experiments, each of the genome segments of 02V0002G3 was transfected together with the remaining ten genome segments of SA11. Viable mono-reassortants were only retrieved for the avian VP3 and VP4 genes. The reassortant viruses were structurally indistinguishable from their parental viruses, but grew to slightly lower titers in cell culture. The results indicate that the VP3 and VP4 genes, but not the other genes of avian RVA, can functionally substitute their mammalian homologs and create viable reassortants. Further research should focus on the reasons behind the reassortment incompatibility and on the optimization of the system for the generation of viable avian RVA rescued entirely from cloned avian RVA genome segments.

Whole genome sequence analysis of cell culture-adapted rotavirus A strains from chicken.

Rotavirus A (RVA) is a major cause of gastroenteritis in humans and mammalian animals, and has also been abundantly detected in avian species. Avian RVA infection is associated with diarrhea, reduced growth and increased mortality, leading to economic losses in the poultry industry. Avian RVA forms a unique genetic clade within the whole RVA species. However, up to now, only a few full-length avian RVA genomes have been published and only a small number of avian RVA strains have been adapted to grow in cell culture for subsequent studies. Here, the four cell culture-adapted chicken RVA strains 02V0002G3, 04V0027G6, 05V0500F6 and 06V0661G1 were characterized in more detail. Transmission electron microscopy of the viruses derived from culture supernatant showed a typical triple-layered morphology of rotavirus particles; in addition, strain 06V0661G1 showed a high proportion of double-layered particles. The (nearly) complete genome sequences of the viruses were determined using next-generation sequencing (NGS). The resulting sequences were compared to full-length or partial sequences of the strains previously determined using Sanger sequencing; and a few nucleotide mismatches, some of them resulting in amino acid substitutions, were identified. The genomes of strains 02V0002G3, 04V0027G6 and 05V0500F6 were closely related to each other showing a G19-P[30]-I11-R6-C6-M7-A16-N6-T8-E10-H8 genotype constellation. Strain 06V0661G1 carries the VP4 genotype P[31] in the same genetic backbone like the other strains. However, further sequence analysis showed that the genes of this strain, especially that encoding NSP3, clustered more separately from the other strains in phylogenetic trees. The characterized cell culture-adapted chicken RVA strains may be useful for future studies investigating genetic diversity and replication of avian rotaviruses, as well as for the development of vaccines and diagnostic tools.

Sensitive SYBR Green-Real Time PCR for the Detection and Quantitation of Avian Rotavirus A.

Avian rotavirus A (ARtV-A) is a virus that affects young birds, causing acute diarrhea and economic losses in the poultry industry worldwide. The techniques used for the diagnosis of ARtV-A include electron microscopy, isolation in cell culture, and serology, as well as molecular techniques, such as the reverse transcription-polymerase chain reaction (RT-PCR). The objective of this work was to standardize a real-time RT-polymerase chain reaction (RT-qPCR) using SYBR Green chemistry for the rapid detection and quantification of ARtV-A from bird tissues and materials fixed on FTA cards on the basis of the nucleotide sequence of segment 6 (S6), which codes for the structural VP6 protein of ARtV-A. The results show the efficient amplification of the proposed target, with a limit of detection (LoD) of one copy gene (CG) per microliter of cDNA and a limit of quantification (LoQ) of 10 CGs per microliter. The efficiency of the primers was determined to be 95.66% using a standard curve, with an R² value of 0.999 and a slope of -3.43. The specificity was determined using samples coinfected with ARtV-A, the chicken parvovirus, the chicken astrovirus, and the avian nephritis virus as positive controls and commercially available vaccines of the infectious bronchitis virus, infectious bursa disease virus, avian reovirus and healthy organs as negative controls. This technique, which lacks nonspecific PCR products and dimers, demonstrated greater sensitivity and specificity than conventional RT-PCR, and it reduced the analysis time by more than 50%.

Design and evaluation of primer pairs for efficient detection of avian rotavirus.

The use of molecular methods for rotavirus characterisation provides increased sensitivity for typing and allows the identification of putative reassortant strains. Reagents and methods for genotyping the virus need constant modification because of the reassortant nature of the virus. This study was aimed at designing and evaluating new oligonucleotide degenerate primer pairs that provide increased sensitivity and specificity for detecting avian rotavirus. Gene-specific primer pairs were designed by analysing different rotavirus strains isolated during the last decade by downloading them from the GenBank. The alignments were generated using clustal analysis from the BioEdit program. Degenerate nucleotides were included due to the reassortant nature of rotavirus. The consensus sequences were aligned using the BioEdit program and then treated with the Fast PCR software to derive the primers. The derived primer sequences were submitted for a BLAST search to ensure alignment was exclusive to the desired target genes. The designed primers had specific bands and were efficient in detecting rotavirus in faecal samples than previously published primers. Thus, a successful surveillance of rotaviruses requires that primer pairs be updated regularly in order to detect the emergence of novel or "unusual types", which have occurred by genetic drift causing nucleotide changes at the primer binding sites that result in typing failures. We recommend the use of the proposed primers in molecular surveillance studies for efficient detection of avian rotavirus.

Prevalence of histopathological intestinal lesions and enteric pathogens in Dutch commercial broilers with time.

Intestinal disease has a major impact on the broiler industry due to economic and welfare reasons. Intestinal disease might occur due to a large number of reasons varying from well-defined pathogens to non-specific enteritis and complex syndromes. However, knowledge about the nature of intestinal disease and presence of enteric viruses in the Dutch broiler industry is largely absent. Therefore, a large-scale field study, in which 98 broiler flocks from 86 farms were sampled weekly, was started to assess the prevalence of histopathological lesions in the jejunum, a number of enterotropic viruses by real-time quantitative reverse transcriptase PCR (RT-qPCR) and coccidia by lesion scoring. Histopathological lesions indicative of intestinal disease were found in all flocks examined. The pathogens investigated were chicken astrovirus (99% of flocks positive), avian nephritis virus 3 (100%), rotavirus A (95%), rotavirus D (52%), reovirus (100%), Eimeria acervulina (94%), E. maxima (49%) and E. tenella (40%). The enteric viruses were more prevalent in the first weeks of the growing period, while coccidiosis was more frequently found at 4 and 5 weeks of age. The abundant presence of the enteric viruses and enteric disorders stresses the need to elucidate the role of these viruses in intestinal disease. Furthermore, the high prevalence of coccidiosis despite the use of anticoccidials shows that the current coccidial management programmes might be insufficient in controlling this disease.

Relationship between different enteric viral infections and the occurrence of diarrhea in broiler flocks in Jordan.

The aim of this study is to determine if enteric viruses are the cause of diarrhea in broiler flocks in Jordan. Intestinal content samples were collected from 101 broiler flocks from several regions of Jordan to detect the presence of astrovirus, coronavirus, reovirus, and rotavirus, by using reverse transcriptase polymerase chain reaction (RT-PCR). Forty-six of these flocks were clinically healthy with no enteric disease, and the other 55 flocks were clinically suffering from diarrhea. The samples were collected between 5 and 16 d of age. The results show that 79% of total 101 flocks tested were infected with one or more of the above enteric viruses. Coronavirus was the most common virus, detected in 56.4% of these flocks, with astrovirus in 29.7% of the flocks, and rotavirus (9.9%) and reovirus (5.6%) being the least common. None of these flocks were found to be infected with all four viruses, but one of the flocks was found to be infected with astrovirus, coronavirus, and rotavirus simultaneously. Individual infection was noted with astrovirus, coronavirus and rotavirus but not with reovirus, whereas all flocks infected with reovirus were also infected with coronavirus. There was no statistical evidence to link these viruses as the main cause of diarrhea in the flocks tested. This is the first study in Jordan to detect all of these viruses and to correlate their presence with diarrhea in chicken flocks.

Analysis of codon usage pattern evolution in avian rotaviruses and their preferred host.

Rotavirus infection is a worldwide problem, with occurrence of highly divergent viruses classified in 8 species (A-H). We report here the evolution assessment of codon usage patterns in virus-host system in avian rotavirus (AvRV) of species RVA, RVD, RVF and RVG (preferentially affecting birds). The nucleotide contents, codon usage bias (CUB), relative synonymous codon usage (RSCU), and effective number of codons (ENCs) values were investigated targeting overexpressing major inner capsid viral protein (VP6) of these AvRV species. The results confirm that the evolutionary characteristics influences the rotavirus (RV) genetic diversity and impact of host's natural selection on the AvRVs codons. Synonymous codon usage patterns were evaluated following multivariate statistical procedures on all available AvRV coding gene sequences. RSCU trees accommodated all AvRV species and preferred host sequences in one topology confirming greater imminence of AvRVs with the host chicken cell genes. Similarly, the codon adaptation index (CAI) results also displayed a higher adaptation of AvRVs to its chicken host. The codon preference analysis of RVs revealed that VP6 gene express more proficiently in the yeast system, whereas, codon optimization might be required for the effectual expression in Escherichia coli and Homo sapiens. The findings provide basic evidence on the dynamics of AvRV evolution and its host adaptation, which could be exploited for additional research on avian species in future.

An unusual case of concomitant infection with chicken astrovirus and group A avian rotavirus in broilers with a history of severe clinical signs.

A molecular study of intestinal samples from 21 broiler flocks with a history of enteritis revealed that 23.8% and 14.3% were positive for chicken astrovirus (CAstV) and avian rotavirus (ARV), respectively. CAstV and group A ARV were simultaneously detected in only one broiler flock. Birds in this group developed the significant intestinal lesions characterized by frothy contents, paleness, and thin intestinal walls. In this report we present an unusual case of runting stunting syndrome (RSS) with a history of high mortality and growth retardation in broiler chickens. We also make the first identification of CAstV and group A ARV in broiler chickens in Korea.

An unusual case of concomitant infection with chicken astrovirus and group A avian rotavirus in broilers with a history of severe clinical signs

A molecular study of intestinal samples from 21 broiler flocks with a history of enteritis revealed that 23.8% and 14.3% were positive for chicken astrovirus (CAstV) and avian rotavirus (ARV), respectively. CAstV and group A ARV were simultaneously detected in only one broiler flock. Birds in this group developed the significant intestinal lesions characterized by frothy contents, paleness, and thin intestinal walls. In this report we present an unusual case of runting stunting syndrome (RSS) with a history of high mortality and growth retardation in broiler chickens. We also make the first identification of CAstV and group A ARV in broiler chickens in Korea.

The occurrence of orthoreovirus, rotavirus and chicken anemia virus in chickens of the poultry industry in Minas Gerais, Brazil / Ocorrência de orthoreovirus, rotavirus e vírus da anemia das galinhas em frangos de corte da indústria avícola de Minas Gerais

Fifty-four fecal samples taken from broiler chickens from 1 to 45 days of age, and of pullets from 10 to 13 weeks of age, original from eight different poultry regions in the state of Minas Gerais, Brazil, were collected from March 2008 to January 2010 for avian Orthoreovirus (ARV) and avian Rotavirus (AvRV) analyses. For the assay of ARV, RNA was immediately extracted (Trizolâ) and transcribed into cDNA for assaying in a nested-PCR with ARV-specific primers. For AvRV, polyacrylamide gel electrophoresis (PAGE) was performed with RNA extracts obtained by phenol-chloroform extraction. CAV was additionally investigated through a nested-PCR of thymus and spleen. Results found 5.55% positive for ARV and 9.25% for AvRV. Also, CAV and ARV genomes were detected in co-infection, in a highly prostrated and claudicating chicken flock. No ARV or AvRV infections were detected in pullets. Material of a clinically affected flock was inoculated into SPF embryos, resulting in embryonic hemorrhage, whitish foci in the chorio-allantoic membrane and death. Sequencing of ARV amplicons and isolate cDNA grouped local strains with the ARV S1133 strain, historically used in live vaccines, suggesting the continued circulation of this vaccine virus strain in intensive poultry regions. Detection rates for ARV and AvRV, as well as the presence of CAV, were additionally indicative of failing biosecurity strategies for the intensive poultry regions examined.

Avaliou-se a ocorrência de Orthoreovirus (ARV) e Rotavirus (AvRV) aviários na avicultura industrial de Minas Gerais. Foram colhidas cinquenta e quatro amostras de fezes de frangos de corte entre um e 45 dias e de frangas de postura de 10 a 13 semanas de idade. Para análise de ARV, o RNA foi imediatamente extraído (Trizol), transcrito em cDNA e avaliado em uma PCR com oligonucleotídeos iniciadores específicos para ARV. Para a investigação de AvRV, os extratos de RNA foram obtidos por fenol-clorofórmio e submetidos à eletroforese em gel de poliacrilamida. Todas as amostras foram também avaliadas para o DNA do vírus da anemia das galinhas (CAV) em uma nested-PCR específica. Em frangos de corte, a positividade encontrada para ARV foi de 5,55% e para AvRV de 9,25%. CAV foi detectado em coinfecção em um plantel com refugagem, claudicação e prostração. Nenhuma amostra de poedeiras foi positiva para ARV ou AvRV. Material de plantel com sinais clínicos foi purificado e inoculado em ovos SPF embrionados, sendo obtidas lesões hemorrágicas e focos brancos na membrana cório-alantóide. O sequenciamento dos produtos de PCR e de embrião agrupou os isolados de ARV com a estirpe S1133, historicamente usada como vacina viva. Os resultados sugerem a continuada circulação da infecção por estirpes assemelhadas a ARV S1133 nas regiões de avicultura industrial. Os índices de detecção de ARV, AvRV e CAV indicam que a intensificação nas regiões produtoras tem resultado em falhas de biosseguridade.