Isolation and propagation of the animal rotaviruses in MA-104 cells--30 years of practical experience.

A total of 136 rotavirus positive samples from diarrhoeic animals of different species were submitted for isolation and cultural propagation of rotavirus on MA-104 cells. The samples were collected from animals with diarrhoea, between 1980 and 2010, originating from herds or farms located in several parts of Germany. Rotaviruses of species A were isolated from 102 faecal samples in cultures of MA-104 cells under the following conditions: pre-treatment of virus with trypsin, incorporation of trypsin into culture medium, use of roller cultures, and centrifugation of the samples on the cells. The cell culture adapted viruses produced a cytopathic effect, accompanied by the release of cells from the glass surface of the cultivation vessels. After 10 passages the virus isolates yielded titres between 10(5.5) and 10(7.5)ml(-1) TCID50. Isolation and serial propagation of the virus in MA-104 cells was confirmed by immunofluorescence assay, transmission electron microscopy, and polyacrylamide-gel electrophoresis of viral dsRNA. Eight (5.9%) of the electrophoretic profiles were characteristic of species B or D rotaviruses, which were not replicated in MA-104 cells.

Detection of rotavirus species A, B and C in domestic mammalian animals with diarrhoea and genotyping of bovine species A rotavirus strains.

Rotaviruses (RVs) are a major cause of neonatal diarrhoea in humans and animals worldwide. In this study, 425 faecal samples were collected between 1999 and 2013 from diarrhoeic livestock and companion animals at different locations in Germany and tested for RVs. A previously published real-time RT-PCR assay was optimized for detection of a larger variety of RV species A (RVA) strains, and real-time RT-PCR assays for detection of RV species B (RVB) and C (RVC) were newly developed. The detection limits of the assays were 1.54×10(2), 3.95×10(2) and 3.60×10(3) genome copies for RVA, RVB and RVC, respectively. RVA was identified in 85.2% of bovine samples, 51.2% of porcine samples, 50.0% of feline samples, 43.2% of equine samples and 39.7% of canine samples. RVB was found in 3.0% of bovine samples, 2.7% of equine samples and 1.6% of porcine samples. RVC was detected in 31.0% of porcine samples, 21.7% of feline samples, 9.0% of canine samples and 6.0% of bovine samples. For genotyping, 101 RVA-positive bovine samples were further analysed by semi-nested RT-PCR. Genotype combination G6P[5] was most frequently detected (67.3% of samples), followed by G6P[11] (13.9%), G10P[5] (4.0%), G8P[11] (3.0%), G6P[1] (1.0%), and G10P[11] (1.0%). Mixed RVA infections were detected in 5.9% of samples; no or incomplete typing was possible in 4.0% of the samples. This first overview on RV species and RVA genotypes in diarrhoeic livestock and companion animals from Germany indicates a broad circulation of a large variety of RVs.

Identification of an avian group A rotavirus containing a novel VP4 gene with a close relationship to those of mammalian rotaviruses.

Group A rotaviruses (RVAs) are an important cause of diarrhoeal illness in humans, as well as in mammalian and avian animal species. Previous sequence analyses indicated that avian RVAs are related only distantly to mammalian RVAs. Here, the complete genomes of RVA strain 03V0002E10 from turkey (Meleagris gallopavo) and RVA strain 10V0112H5 from pheasant (Phasianus colchicus) were analysed using a combination of 454 deep sequencing and Sanger sequencing technologies. An adenine-rich insertion similar to that found in the chicken RVA strain 02V0002G3, but considerably shorter, was found in the 3' NCR of the NSP1 gene of the pheasant strain. Most genome segments of both strains were related closely to those of avian RVAs. The novel genotype N10 was assigned to the NSP2 gene of the pheasant RVA, which is related most closely to genotype N6 found in avian RVAs. However, this virus contains a VP4 gene of the novel genotype P[37], which is related most closely to RVAs from pigs, dogs and humans. This strain either may represent an avian/mammalian rotavirus reassortant, or it carries an unusual avian rotavirus VP4 gene, thereby broadening the potential genetic and antigenic variability among RVAs.

Analysis of rotavirus species diversity and evolution including the newly determined full-length genome sequences of rotavirus F and G.

Rotaviruses are a leading cause of viral acute gastroenteritis in humans and animals. Eight different rotavirus species (A-H) have been defined based on antigenicity and nucleotide sequence identities of the VP6 gene. Here, the first complete genome sequences of rotavirus F (strain 03V0568) and G (strain 03V0567) with lengths of 18,341 and 18,186bp, respectively, are described. Both viruses have open reading frames for rotavirus proteins VP1 to VP7 and NSP1 to NSP5 located at the 11 genome segments. Nucleotide sequence identities to other rotaviruses ranged between 29.8% (NSP1 gene) and 61.7% (VP1 gene) for rotavirus F and between 29.3% (NSP1-2 gene) and 65.9% (NSP2 gene) for rotavirus G, thus confirming their classification as separate virus species. Encoded proteins revealed remarkable sequence differences among the rotavirus species. In contrast, the non-coding 5'-terminal sequences of the genome segments are highly conserved among all rotavirus species. Different 3'-terminal consensus sequences are found between rotavirus A/D/F, rotavirus C and rotavirus B/G/H. Phylogenetic analyses indicated a separation of rotaviruses in two major clades consisting of rotavirus A/C/D/F and rotavirus B/G/H. Within these clades, rotavirus F mainly clustered with rotavirus D and rotavirus G with rotavirus B. In addition, differentiation among mammalian and avian rotavirus A strains, host-specific evolution of rotavirus B and C as well as an ancient reassortment event between avian rotavirus A and D are indicated by the phylogenetic data. These results underline the high diversity of rotaviruses as a result of a complex evolutionary history.

Discovery and genetic characterization of novel caliciviruses in German and Dutch poultry.

Caliciviruses (CV) were identified in the intestinal contents of five chickens and one turkey from various regions in Germany between 2009 and 2011 by degenerate reverse transcription PCR. The full 7,656-nt-long genomic sequence of the turkey CV L11043 was determined. Partial nucleotide sequences were determined for nine chicken strains. Phylogenetic analysis based on partial deduced amino acid sequences of the protease and RNA polymerase and the complete VP1 capsid sequence identified two distinct clusters of avian CVs, the first of which contained chicken CVs that were closely related to strains found in German chickens in Bavaria and that had been proposed to form a novel CV genus (proposed name: Bavovirus). In contrast, the turkey CV strain L11043 and three chicken CV strains formed a genetically distinct second cluster. Distance analysis suggested that the strains of the second cluster may represent members of two distinct genogroups of another novel CV genus (proposed name: Nacovirus). Based on the newly obtained sequence information, two real-time RT-PCR assays were developed and used to identify bavovirus and nacovirus in pooled intestinal contents from 24 chicken farms in Germany and the Netherlands. Of these, 20 (83 %) were positive for bavovirus, 11 (46 %) were positive for nacovirus, and nine (38 %) were positive for both bavovirus and nacovirus. Attempts were made to propagate chicken and turkey CVs from both the bavovirus and nacovirus clusters in primary chicken cecal cells, embryonal liver cells and fibroblast cells, but these attempts were not successful.

VP6-sequence-based cutoff values as a criterion for rotavirus species demarcation.

Indirect immunofluorescence techniques targeting the rotavirus (RV) protein VP6 are used to differentiate RV species. The ICTV recognizes RV species A to E and two tentative species, F and G. A potential new RV species, ADRV-N, has been described. Phylogenetic trees and pairwise identity frequency graphs were constructed with more than 400 available VP6 sequences and seven newly determined VP6 sequences of RVD strains. All RV species were separated into distinct phylogenetic clusters. An amino acid sequence cutoff value of 53% firmly permitted differentiation of RV species, and ADRV-N was tentatively assigned to a novel RV species H (RVH).

Detection of avian rotaviruses of groups A, D, F and G in diseased chickens and turkeys from Europe and Bangladesh.

Avian rotaviruses (AvRVs) represent a diverse group of intestinal viruses, which are suspected as the cause of several diseases in poultry with symptoms of diarrhoea, growth retardation or runting and stunting syndrome (RSS). To assess the distribution of AvRVs in chickens and turkeys, we have developed specific PCR protocols. These protocols were applied in two field studies investigating faecal samples or intestinal contents of diseased birds derived from several European countries and Bangladesh. In the first study, samples of 166 chickens and 33 turkeys collected between 2005 and 2008 were tested by PAGE and conventional RT-PCR and AvRVs were detected in 46.2%. In detail, 16.1% and 39.2% were positive for AvRVs of groups A or D, respectively. 11.1% of the samples contained both of them and only four samples (2.0%) contained rotaviruses showing a PAGE pattern typical for groups F and G. In the second study, samples from 375 chickens and 18 turkeys collected between 2009 and 2010 were analyzed using a more sensitive group A-specific and a new group D-specific real-time RT-PCR. In this survey, 85.0% were AvRV-positive, 58.8% for group A AvRVs, 65.9% for group D AvRVs and 38.9% for both of them. Although geographical differences exist, the results generally indicate a very high prevalence of group A and D rotaviruses in chicken and turkey flocks with cases of diarrhoea, growth retardation or RSS. The newly developed diagnostic tools will help to investigate the epidemiology and clinical significance of AvRV infections in poultry.

Infection of calves with bovine norovirus GIII.1 strain Jena virus: an experimental model to study the pathogenesis of norovirus infection.

The experimental infection of newborn calves with bovine norovirus was used as a homologous large animal model to study the pathogenesis of norovirus infection and to determine target cells for viral replication. Six newborn calves were inoculated orally with Jena virus (JV), a bovine norovirus GIII.1 strain, and six calves served as mock-inoculated controls. Following infection, calves were euthanized before the onset of diarrhea (12 h postinoculation [hpi]), shortly after the onset of diarrhea (18 to 21 hpi), and postconvalescence (4 days pi [dpi]). Calves inoculated with JV developed severe watery diarrhea at 14 to 16 hpi, and this symptom lasted for 53.5 to 67.0 h. Intestinal lesions were characterized by severe villus atrophy together with loss and attenuation of villus epithelium. Viral capsid antigen (JV antigen) was detected by immunohistochemistry in the cytoplasm of epithelial cells on villi. In addition, granular material positive for JV antigen was detected in the lamina propria of villi. Lesions first appeared at 12 hpi and were most extensive at 18 to 19 hpi, extending from midjejunum to ileum. The intestinal mucosa had completely recovered at 4 dpi. There was no indication of systemic infection as described for norovirus infection in mice. JV was found in intestinal contents by reverse transcription-PCR (RT-PCR) and enzyme-linked immunosorbent assay (ELISA) as early as 12 hpi. Fecal shedding of the virus started at 13 hpi and stopped at 23 hpi or at necropsy (4 dpi), respectively. Throughout the trial, none of the control calves tested positive for JV by ELISA or RT-PCR.