Rotaviruses in Wild Ungulates from Germany, 2019-2022.

Rotavirus A (RVA) is an important cause of diarrhea in humans and animals. However, RVA in wild animals has only scarcely been investigated so far. Here, the presence of RVA in wild ungulates hunted between 2019 and 2022 in Brandenburg, Germany, was investigated using real-time RT-PCR and sequencing of RT-PCR products. By analyzing intestinal contents, RVA-RNA was detected in 1.0% (2/197) of wild boar (Sus scrofa), 1.3% (2/152) of roe deer (Capreolus capreolus), and 2.1% (2/95) of fallow deer (Dama dama) but not in 28 red deer (Cervus elaphus) samples. Genotyping identified G3P[13] strains in wild boar, which were closely related to previously described pig and wild boar strains. Genotype G10P[15] strains, closely related to strains from roe deer, sheep, or cattle, were found in roe deer. The strains of fallow deer represented genotype G3P[3], clustering in a group containing different strains from several hosts. The results indicated a low prevalence of RVA in wild ungulates in Germany. Associations of specific genotypes with certain ungulate species seem to exist but should be confirmed by analyses of more samples in the future.

Interlaboratory Validation of a Detection Method for Hepatitis E Virus RNA in Pig Liver.

BACKGROUND: In the last years, the number of notified hepatitis E cases in humans has continuously increased in Europe. Foodborne infection with the zoonotic hepatitis E virus (HEV) genotype 3 is considered the major cause of this disease. Undercooked liver and raw sausages containing the liver of pigs and wild boar are at high risk of containing HEV. However, so far, no standardized method for the detection of HEV-RNA in pig liver is available. METHODS: An international collaborative study on method reproducibility involving 11 laboratories was performed for an HEV-RNA detection method, which consists of steps of sample homogenization, RNA extraction and real-time RT-PCR detection, including a process control. Naturally contaminated pork liver samples containing two different amounts of HEV and a HEV-negative pork liver sample were tested by all laboratories using the method. RESULTS: Valid results were retrieved from 10 laboratories. A specificity of 100% and a sensitivity of 79% were calculated for the method. False negative results were only retrieved from the sample containing very low HEV amounts near the detection limit. CONCLUSIONS: The results show that the method is highly specific, sufficiently sensitive and robust for use in different laboratories. The method can, therefore, be applied to routine food control as well as in monitoring studies.

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.

No Evidence of Hepatitis E Virus Infection in Farmed Deer in Germany.

Hepatitis E virus (HEV) is a zoonotic agent, which is mainly transmitted by consumption of undercooked meat products originating from infected animals. Domestic pigs and wild boars are the major animal reservoirs, but HEV infections have been also repeatedly described in wild deer species. However, farmed deer has been only sparsely investigated so far. Here, 108 blood and 106 liver samples from fallow deer, red deer, and sika deer strictly hold in game enclosures from 11 farms in Germany were analyzed for markers of HEV infection. Using a commercial double antigen sandwich ELISA, 3/108 (2.7%) serum samples were scored borderline for HEV-specific antibodies, whereas the remaining samples were negative. No HEV-RNA (0%) was detected in the 106 liver samples. The results suggest a low risk of HEV infection in farmed deer in Germany.

Interlaboratory Validation of a Method for Hepatitis E Virus RNA Detection in Meat and Meat Products.

Increasing numbers of hepatitis E cases are currently recognized in many European countries. The zoonotic hepatitis E virus (HEV) genotype 3 mainly circulates in domestic pigs and wild boars, and can be transmitted to humans via consumption of insufficiently heated meat or meat products produced from those animals. Here, a detailed protocol for detection of HEV RNA in meat products is provided, which is based on the method originally described by Szabo et al. (Intl J Food Microbiol 215:149-156, 2015). It consists of a TRI Reagent®/chloroform-based food matrix homogenization, a silica bead-based RNA extraction and a real-time RT-PCR-based RNA detection. The method was further validated in a ring trial with nine independent laboratories using pork liver sausage samples artificially contaminated with different amounts of HEV. The results indicate sufficient sensitivity, specificity, and accuracy of the method for its broad future use in survey studies, routine food control or outbreak investigations.

Enhanced Replication of Hepatitis E Virus Strain 47832c in an A549-Derived Subclonal Cell Line.

Hepatitis E virus (HEV) is a human pathogen with increasing importance. The lack of efficient cell culture systems hampers systematic studies on its replication cycle, virus neutralization and inactivation. Here, several cell lines were inoculated with the HEV genotype 3c strain 47832c, previously isolated from a chronically infected transplant patient. At 14 days after inoculation the highest HEV genome copy numbers were found in A549 cells, followed by PLC/PRF/5 cells, whereas HepG2/C3A, Huh-7 Lunet BLR and MRC-5 cells only weakly supported virus replication. Inoculation of A549-derived subclone cell lines resulted in most cases in reduced HEV replication. However, the subclone A549/D3 was susceptible to lower virus concentrations and resulted in higher virus yields as compared to parental A549 cells. Transcriptome analysis indicated a downregulation of genes for carcinoembryonic antigen-related cell adhesion molecules (CEACAM) 5 and 6, and an upregulation of the syndecan 2 (SDC2) gene in A549/D3 cells compared to A549 cells. However, treatment of A549/D3 cells or A549 cells with CEACAM- or syndecan 2-specific antisera did not influence HEV replication. The results show that cells supporting more efficient HEV replication can be selected from the A549 cell line. The specific mechanisms responsible for the enhanced replication remain unknown.

Comparison and optimization of detection methods for noroviruses in frozen strawberries containing different amounts of RT-PCR inhibitors.

Frozen berries have been repeatedly identified as vehicles for norovirus (NoV) transmission causing large gastroenteritis outbreaks. However, virus detection in berries is often hampered by the presence of RT-PCR-inhibiting substances. Here, several virus extraction methods for subsequent real-time RT-PCR-based NoV-RNA detection in strawberries were compared and optimized. NoV recovery rates (RRs) between 0.21 ± 0.13% and 10.29 ± 6.03% were found when five different artificially contaminated strawberry batches were analyzed by the ISO/TS15216-2 method indicating the presence of different amounts of RT-PCR inhibitors. A comparison of five different virus extraction methods using artificially contaminated strawberries containing high amounts of RT-PCR inhibitors revealed the best NoV RRs for the ISO/TS15216 method. Further improvement of NoV RRs from 2.83 ± 2.92% to 15.28 ± 9.73% was achieved by the additional use of Sephacryl(®)-based columns for RNA purification. Testing of 22 frozen strawberry samples from a batch involved in a gastroenteritis outbreak resulted in 5 vs. 13 NoV GI-positive and in 9 vs. 20 NoV GII-positive samples using the original ISO/TS15216 method vs. the extended protocol, respectively. It can be concluded that the inclusion of an additional RNA purification step can increase NoV detection by the ISO/TS15216-2 method in frozen berries containing high amounts of RT-PCR inhibitors.

Thermal Stability of Hepatitis E Virus as Estimated by a Cell Culture Method.

UNLABELLED: Hepatitis E virus (HEV) is an increasingly recognized zoonotic pathogen. Transmission is suspected to occur from infected pigs or wild boars to humans through direct contact, environmental pathways, or contaminated food. However, the physical and chemical stability of HEV is largely unknown, because suitable cell culture methods for infectivity measurement are missing. Here, we developed a titration method using infection of the cell line A549/D3 with HEV genotype 3 strain 47832c and subsequent counting of focus-forming units by immunofluorescence, which allowed HEV infectivity measurements within a 4-log-dilution range. Long-term storage of HEV in cell culture medium at different temperatures indicated a phase of rapid virus inactivation, followed by a slower progression of virus inactivation. Infective HEV was detected up to 21 days at 37°C, up to 28 days at room temperature, and until the end of the experiment (56 days) with a 2.7-log decrease of infectious virus at 4°C. Heat treatment for 1 min resulted in moderate decreases of infectivity up to 60°C, 2- to 3.5-log decreases between 65°C and 75°C, and no remaining virus was detected at temperatures of ≥80°C. Heating for 70°C resulted in a 3.6-log decrease after 1.5 min and the absence of detectable virus (>3.9-log decrease) after 2 min. The data were used to calculate predictive heat inactivation models for HEV. The results may help estimate HEV stability in the environment or food. The established method may be used to study other aspects of HEV stability in the future. IMPORTANCE: In this study, a cell culture method was developed which allows the measurement of hepatitis E virus (HEV) infectivity. Using this system, the stability of HEV at different time-temperature combinations was assessed, and a predictive model was established. The obtained data may help estimate HEV stability in the environment or food, thus enabling an assessment of the relative risks of HEV infection through distinct routes and by distinct types of food in the future.

Generation of an Avian-Mammalian Rotavirus Reassortant by Using a Helper Virus-Dependent Reverse Genetics System.

UNLABELLED: The genetic diversity of rotavirus A (RVA) strains is facilitated in part by genetic reassortment. Although this process of genome segment exchange has been reported frequently among mammalian RVAs, it remained unknown if mammalian RVAs also could package genome segments from avian RVA strains. We generated a simian RVA strain SA11 reassortant containing the VP4 gene of chicken RVA strain 02V0002G3. To achieve this, we transfected BSR5/T7 cells with a T7 polymerase-driven VP4-encoding plasmid, infected the cells with a temperature-sensitive SA11 VP4 mutant, and selected the recombinant virus by increasing the temperature. The reassortant virus could be stably passaged and exhibited cytopathic effects in MA-104 cells, but it replicated less efficiently than both parental viruses. Our results show that avian and mammalian rotaviruses can exchange genome segments, resulting in replication-competent reassortants with new genomic and antigenic features. IMPORTANCE: This study shows that rotaviruses of mammals can package genome segments from rotaviruses of birds. The genetic diversity of rotaviruses could be broadened by this process, which might be important for their antigenic variability. The reverse genetics system applied in the study could be useful for targeted generation and subsequent characterization of distinct rotavirus reassortant strains.

Detection of hepatitis E virus RNA in raw sausages and liver sausages from retail in Germany using an optimized method.

Hepatitis E virus (HEV) is a pathogen of increasing importance, which can be zoonotically transmitted from domestic pigs, wild boar, and deer to humans. Foodborne transmission by consumption of raw and undercooked liver, meat, or sausages prepared from infected animals has been documented. The aim of this study was to investigate the distribution of HEV in different types of sausages sold in Germany. As no standardized methods for HEV detection in food exist, several techniques of sample homogenization, virus concentration and nucleic acid extraction followed by real-time RT-PCR were compared using artificially contaminated sausages. A method using TRI Reagent® Solution showed the best efficacy of matrix disruption and a treatment with chloroform followed by a silica-based RNA extraction method resulted in the highest HEV detection rates. The detection limit of the method was 2.9 × 10(3) and 5.3 × 10(4) genome equivalents per 5 g raw sausage and 2 g liver sausage, respectively. Application of the method to raw and liver sausages from retail in Germany resulted in the HEV genome detection in 14 out of 70 (20%) raw sausages and in 11 out of 50 (22%) liver sausages. The detected HEV sequences showed a high diversity and belonged to different subtypes of HEV genotype 3. The results indicate a broad distribution of HEV-RNA in meat products sold in Germany; however, the infectivity of the detected virus remains to be assessed in future.

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.

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.

Sequence analysis of the VP6-encoding genome segment of avian group F and G rotaviruses.

Rotavirus groups A to E are mainly defined by antibody reactivity to the capsid protein VP6. Additionally, two putative rotavirus groups (F and G) have been identified in birds. Here, the first nucleotide sequences of the VP6-encoding genome segment of group F (strain 03V0568) and group G (strain 03V0567) rotaviruses, both derived from chickens, are presented. The group F rotavirus is most closely related to avian group A and D rotaviruses, with 49.9-52.3% nucleotide and 36.5-39.0% amino acid sequence identity. The group G rotavirus is most closely related to mammalian group B rotaviruses, with 55.3-57.5% nucleotide and 48.2-49-9% amino acid sequence identity. The terminal sequences of the genome segment were similar in groups A, D and F, and in groups B and G. The findings indicate a long-term evolution of rotavirus groups in two separated clades and support the development of a sequence-based classification system for rotavirus groups.

The genome segments of a group D rotavirus possess group A-like conserved termini but encode group-specific proteins.

Rotaviruses are a leading cause of viral acute gastroenteritis in humans and animals. They are grouped according to gene composition and antigenicity of VP6. Whereas group A, B, and C rotaviruses are found in humans and animals, group D rotaviruses have been exclusively detected in birds. Despite their broad distribution among chickens, no nucleotide sequence data exist so far. Here, the first complete genome sequence of a group D rotavirus (strain 05V0049) is presented, which was amplified using sequence-independent amplification strategies and degenerate primers. Open reading frames encoding homologues of rotavirus proteins VP1 to VP4, VP6, VP7, and NSP1 to NSP5 were identified. Amino acid sequence identities between the group D rotavirus and the group A, B, and C rotaviruses varied between 12.3% and 51.7%, 11.0% and 23.1%, and 9.5% and 46.9%, respectively. Segment 10 of the group D rotavirus has an additional open reading frame. Generally, phylogenetic analysis indicated a common evolution of group A, C, and D rotaviruses, separate from that of group B. However, the NSP4 sequence of group C has only very low identities in comparison with cogent sequences of all other groups. The avian group A NSP1 sequences are more closely related to those of group D than those of mammalian group A rotaviruses. Most interestingly, the nucleotide sequences at the termini of the 11 genome segments are identical between group D and group A rotaviruses. Further investigations should clarify whether these conserved structures allow an exchange of genome segments between group A and group D rotaviruses.

The first complete genome sequence of a chicken group A rotavirus indicates independent evolution of mammalian and avian strains.

Group A rotaviruses are a leading cause of gastroenteritis in humans and animals. Transmission between mammalian species and humans has been demonstrated repeatedly. Here, the first entire genome sequence (19,064 bp) of a chicken rotavirus, strain Ch-02V0002G3, is presented. A low degree of nucleotide sequence identity with the mammalian group A rotaviruses is evident for all 11 genome segments, whereas a closer relationship to available rotavirus sequences from avian species has been determined. According to a novel rotavirus classification system, new genotypes were proposed and ratified by the Rotavirus Classification Working Group for eight of the Ch-02V0002G3 genome segments, resulting in the genotype constellation G19-P[30]-I11-R6-C6-M7-A16-N6-T8-E10-H8. Due to the low percentages of genome sequence identity, the different genome segment sizes and the marked sequence differences of non-structural proteins, an independent evolution without exchange of genetic material between mammalian and avian group A rotavirus strains is likely.