Horst Schirrmeier

Novel orthobunyavirus in Cattle, Europe, 2011.

In 2011, an unidentified disease in cattle was reported in Germany and the Netherlands. Clinical signs included fever, decreased milk production, and diarrhea. Metagenomic analysis identified a novel orthobunyavirus, which subsequently was isolated from blood of affected animals. Surveillance was initiated to test malformed newborn animals in the affected region.

Schmallenberg virus as possible ancestor of Shamonda virus.

Schmallenberg virus (SBV), an orthobunyavirus of the Simbu serogroup, recently emerged in Europe and has been suggested to be a Shamonda/Sathuperi virus reassortant. Results of full-genome and serologic investigations indicate that SBV belongs to the species Sathuperi virus and is a possible ancestor of the reassortant Shamonda virus.

Pathogenic, antigenic and molecular properties of rabbit haemorrhagic disease virus (RHDV) isolated from vaccinated rabbits: detection and characterization of antigenic variants

SummaryRabbit haemorrhagic disease virus (RHDV) isolates were obtained from several animals previously vaccinated with an inactivated vaccine. Seven isolates were analyzed by immunological and molecular biological methods and compared to reference strains. Antigenic characterization with monoclonal antibodies as well as haemagglutination assays demonstrated considerable differences between individual isolates. However, sequencing of the capsid protein genes revealed a high degree of homology between five of these isolates and the reference strain FRG. In contrast, two isolates specified remarkably different capsid proteins with a degree of variation not observed so far in RHDV. Amino acid alterations were found clustered between residues 301 and 328 (region C), 344 and 434 (region E) and also in the 3′ region of the capsid protein gene. Interestingly, experimental vaccination of rabbits followed by challenge with the heterologous variant strains showed restricted cross-protection against one of the strains. In summary, we found a level of antigenic variation not detected in RHDV so far, and describe two distinct new antigenic variants.

Comparison of Porcine Epidemic Diarrhea Viruses from Germany and the United States, 2014

Since 2013, highly virulent porcine epidemic diarrhea virus has caused considerable economic losses in the United States. To determine the relation of US strains to those recently causing disease in Germany, we compared genomes and found that the strain from Germany is closely related to variants in the United States.

Epizootic spread of Schmallenberg virus among wild cervids, Belgium, Fall 2011.

Schmallenberg virus was detected in cattle and sheep in northwestern Europe in 2011. To determine whether wild ruminants are also susceptible, we measured antibody seroprevalence in cervids (roe deer and red deer) in Belgium in 2010 and 2011. Findings indicated rapid spread among these deer since virus emergence ≈250 km away.

Oral exposure, reinfection and cellular immunity to Schmallenberg virus in cattle

Schmallenberg virus (SBV), a novel orthobunyavirus, was discovered in Germany in 2011. In adult ruminants SBV causes mild transient disease, but foetal infection can lead to severe malformations. Owing to its recent discovery, the knowledge about the pathogenesis is limited. In this study, two heifers seroconverted after a previous SBV infection and five SBV antibody-negative calves were subcutaneously inoculated, another two animals received SBV orally and three were kept as controls. In naïve cattle infected subcutaneously viral RNA was detected in serum and blood samples for several days. Seropositive or orally inoculated animals as well as the uninfected controls remained negative throughout the study. Seroconversion was observed only after subcutaneous exposure of the naïve animals to SBV. In lymphocytes from peripheral blood SBV genome was not detected, but the lymphocyte homeostasis in blood was influenced.

Recombination in rabbit haemorrhagic disease virus: Possible impact on evolution and epidemiology ☆

Rabbit haemorrhagic disease (RHD) was first recognised in 1984 following the introduction of apparently healthy rabbits into China from Germany. The aetiological agent Rabbit haemorrhagic disease virus (RHDV) has subsequently killed hundreds of millions of domestic and wild rabbits particularly in Europe, China and Australia. Previously, using phylogenetic analysis we have attempted to understand the underlying factors that determine why this virus emerged, and why it has such an unpredictable epidemiology. Here we report the use of tree congruency supported by bootscanning analysis to detect recombination amongst both closely related, and widely divergent strains of RHDV. We show that recombination occurs commonly and in several different regions of the RHDV genome. Moreover, the first identified strain of RHDV, i.e. from China in 1984, showed evidence of recombination in the capsid gene, with a virus or viruses containing lineages in German strains. These observations imply that recombination may play a significant role in the evolution, epidemiology and diversity of RHDV.

Schmallenberg virus-two years of experiences.

In autumn 2011, a novel species of the genus Orthobunyavirus of the Simbu serogroup was discovered close to the German/Dutch border and named Schmallenberg virus (SBV). Since then, SBV has caused a large epidemic in European livestock. Like other viruses of the Simbu serogroup, SBV is transmitted by insect vectors. Adult ruminants may show a mild transient disease, while an infection during a critical period of pregnancy can lead to severe congenital malformation, premature birth or stillbirth. The current knowledge about the virus, its diagnosis, the spread of the epidemic, the impact and the possibilities for preventing infections with SBV is described and discussed.

Generation of recombinant pestiviruses using a full-genome amplification strategy

Complete genome amplification of viral RNA provides a new tool for the generation of modified viruses. We have recently reported a full-genome amplification strategy for recovery of pestiviruses (Rasmussen et al., 2008). A full-length cDNA amplicon corresponding to the Border disease virus-Gifhorn genome was generated by long RT-PCR and then RNA transcripts derived from this amplicon were used to rescue infectious virus. Here, we have now used this full-genome amplification strategy for efficient and robust amplification of three additional pestivirus strains: the vaccine strain C and the virulent Paderborn strain of Classical swine fever virus plus the CP7 strain of Bovine viral diarrhoea virus. The amplicons were cloned directly into a stable single-copy bacterial artificial chromosome generating full-length pestivirus DNAs from which infectious RNA transcripts could be also derived.

Detection and Typing of Highly Pathogenic Porcine Reproductive and Respiratory Syndrome Virus by Multiplex Real-Time RT-PCR

Porcine reproductive and respiratory syndrome (PRRS) causes economic losses in the pig industry worldwide, and PRRS viruses (PRRSV) are classified into the two distinct genotypes “North American (NA, type 2)” and “European (EU, type 1)”. In 2006, a highly pathogenic NA strain of PRRSV (HP-PRRSV), characterized by high fever as well as high morbidity and mortality, emerged in swine farms in China. Therefore, a real-time reverse transcription polymerase chain reaction (RT-qPCR) assay specific for HP-PRRSV was developed and combined with type 1- and type 2-specific RT-qPCR systems. Furthermore, an internal control, based on a heterologous RNA, was successfully introduced. This final multiplex PRRSV RT-qPCR, detecting and typing PRRSV, had an analytical sensitivity of less than 200 copies per µl for the type 1-assay and 20 copies per µl for the type 2- and HP assays and a high diagnostic sensitivity. A panel of reference strains and field isolates was reliably detected and samples from an animal trial with a Chinese HP-PRRS strain were used for test validation. The new multiplex PRRSV RT-qPCR system allows for the first time the highly sensitive detection and rapid differentiation of PRRSV of both genotypes as well as the direct detection of HP-PRRSV.