Juliane Schatz

Bat Rabies Surveillance in Europe

Rabies is the oldest known zoonotic disease and was also the first recognized bat associated infection in humans. To date, four different lyssavirus species are the causative agents of rabies in European bats: the European Bat Lyssaviruses type 1 and 2 (EBLV‐1, EBLV‐2), the recently discovered putative new lyssavirus species Bokeloh Bat Lyssavirus (BBLV) and the West Caucasian Bat Virus (WCBV). Unlike in the new world, bat rabies cases in Europe are comparatively less frequent, possibly as a result of varying intensity of surveillance. Thus, the objective was to provide an assessment of the bat rabies surveillance data in Europe, taking both reported data to the WHO Rabies Bulletin Europe and published results into account. In Europe, 959 bat rabies cases were reported to the RBE in the time period 1977–2010 with the vast majority characterized as EBLV‐1, frequently isolated in the Netherlands, North Germany, Denmark, Poland and also in parts of France and Spain. Most EBLV‐2 isolates originated from the United Kingdom (UK) and the Netherlands, and EBLV‐2 was also detected in Germany, Finland and Switzerland. Thus far, only one isolate of BBLV was found in Germany. Published passive bat rabies surveillance comprised testing of 28 of the 52 different European bat species for rabies. EBLV‐1 was isolated exclusively from Serotine bats (Eptesicus serotinus and Eptesicus isabellinus), while EBLV‐2 was detected in 14 Daubenton′s bats (Myotis daubentonii) and 5 Pond bats (Myotis dasycneme). A virus from a single Natterer’s bat (Myotis nattereri) was characterized as BBLV. During active surveillance, only oral swabs from 2 Daubenton′s bats (EBLV‐2) and from several Eptesicus bats (EBLV‐1) yielded virus positive RNA. Virus neutralizing antibodies against lyssaviruses were detected in various European bat species from different countries, and its value and implications are discussed.

Twenty years of active bat rabies surveillance in Germany: a detailed analysis and future perspectives

SUMMARY In Germany, active bat rabies surveillance was conducted between 1993 and 2012. A total of 4546 oropharyngeal swab samples from 18 bat species were screened for the presence of EBLV-1- , EBLV-2- and BBLV-specific RNA. Overall, 0·15% of oropharyngeal swab samples tested EBLV-1 positive, with the majority originating from Eptesicus serotinus. Interestingly, out of seven RT-PCR-positive oropharyngeal swabs subjected to virus isolation, viable virus was isolated from a single serotine bat (E. serotinus). Additionally, about 1226 blood samples were tested serologically, and varying virus neutralizing antibody titres were found in at least eight different bat species. The detection of viral RNA and seroconversion in repeatedly sampled serotine bats indicates long-term circulation of the virus in a particular bat colony. The limitations of random-based active bat rabies surveillance over passive bat rabies surveillance and its possible application of targeted approaches for future research activities on bat lyssavirus dynamics and maintenance are discussed.

Molecular diagnostics for the detection of Bokeloh bat lyssavirus in a bat from Bavaria, Germany

A brain sample of a Natterers bat tested positive for rabies with classical virological techniques. Molecular techniques confirmed the presence of Bokeloh bat lyssavirus (BBLV) in Germany for the second time. Sequence analysis revealed a close genetic relationship to the initial German BBLV case. Using a TaqMan RT-PCR specific for BBLV viral RNA was detected in various other organs albeit with differences in the relative viral load.

Anti-Lyssaviral Activity of Interferons κ and ω from the Serotine Bat, Eptesicus serotinus

ABSTRACT Interferons (IFNs) are cytokines produced by host cells in response to the infection with pathogens. By binding to the corresponding receptors, IFNs trigger different pathways to block intracellular replication and growth of pathogens and to impede the infection of surrounding cells. Due to their key role in host defense against viral infections, as well as for clinical therapies, the IFN responses and regulation mechanisms are well studied. However, studies of type I IFNs have mainly focused on alpha interferon (IFN-α) and IFN-β subtypes. Knowledge of IFN-κ and IFN-ω is limited. Moreover, most studies are performed in humans or mouse models but not in the original host of zoonotic pathogens. Bats are important reservoirs and transmitters of zoonotic viruses such as lyssaviruses. A few studies have shown an antiviral activity of IFNs in fruit bats. However, the function of type I IFNs against lyssaviruses in bats has not been studied yet. Here, IFN-κ and IFN-ω genes from the European serotine bat, Eptesicus serotinus, were cloned and functionally characterized. E. serotinus IFN-κ and IFN-ω genes are intronless and well conserved between microchiropteran species. The promoter regions of both genes contain essential regulatory elements for transcription factors. In vitro studies indicated a strong activation of IFN signaling by recombinant IFN-ω, whereas IFN-κ displayed weaker activation. Noticeably, both IFNs inhibit to different extents the replication of different lyssaviruses in susceptible bat cell lines. The present study provides functional data on the innate host defense against lyssaviruses in endangered European bats. IMPORTANCE We describe here for the first time the molecular and functional characterization of two type I interferons (IFN-κ and -ω) from European serotine bat (Eptesicus serotinus). The importance of this study is mainly based on the fact that very limited information about the early innate immune response against bat lyssaviruses in their natural host serotine bats is yet available. Generally, whereas the antiviral activity of other type I interferons is well studied, the functional involvement of IFN-κ and -ω has not yet been investigated.

Lyssavirus distribution in naturally infected bats from Germany.

In Germany, to date three different lyssavirus species are responsible for bat rabies in indigenous bats: the European Bat Lyssaviruses type 1 and 2 (EBLV-1, EBLV-2) and the Bokeloh Bat Lyssavirus (BBLV) for which Eptesicus serotinus, Myotis daubentonii and Myotis nattereri, respectively, are primary hosts. Lyssavirus maintenance, evolution, and epidemiology are still insufficiently explored. Moreover, the small number of bats infected, the nocturnal habits of bats and the limited experimental data still hamper attempts to understand the distribution, prevalence, and in particular transmission of the virus. In an experimental study in E. serotinus a heterogeneous dissemination of EBLV-1 in tissues was detected. However, it is not clear whether the EBLV-1 distribution is similar in naturally infected animals. In an attempt to further analyze virus dissemination and viral loads within naturally infected hosts we investigated tissues of 57 EBLV-1 positive individuals of E. serotinus from Germany by RT-qPCR and compared the results with those obtained experimentally. Additionally, tissue samples were investigated with immunohistochemistry to detect lyssavirus antigen in defined structures. While in individual animals virus RNA was present only in the brain, in the majority of E. serotinus viral RNA was found in various tissues with highest relative viral loads detected in the brain. Interestingly, viral antigen was confirmed in various tissues in the tongue including deep intralingual glands, nerves, muscle cells and lingual papillae. So, the tongue appears to be a prominent site for virus replication and possibly shedding.

Detection of European bat lyssavirus 2 (EBLV-2) in a Daubenton's bat (Myotis daubentonii) from Magdeburg, Germany.

In Europe bat rabies in Daubentons bats (Myotisdaubentonii) and in Pond bats (Myotis dasycneme) caused by the European bat lyssavirus 2 (EBLV-2) has been confirmed in less than 20 cases to date. Here we report the second encounter of this virus species in Germany. A Daubentons bat found grounded in the zoological garden in Magdeburg died shortly after. In the frame of a retrospective study the bat carcass was eventually transferred to the national reference laboratory for rabies at the Friedrich-Loeffler-Institute for rabies diagnosis. Lyssavirus was isolated and characterized as EBLV-2.

Lagos bat virus transmission in an Eidolon helvum bat colony, Ghana.

A brain sample of a straw-coloured fruit bat (Eidolon helvum) from Ghana without evident signs of disease tested positive by generic Lyssavirus RT-PCR and direct antigen staining. Sequence analysis confirmed the presence of a Lagos bat virus belonging to phylogenetic lineage A. Virus neutralization tests using the isolate with sera from the same group of bats yielded neutralizing antibodies in 74% of 567 animals. No cross-neutralization was observed against a different Lagos bat virus (lineage B).

No virological evidence for an influenza A - like virus in European bats.

New members of the influenza A virus genus have been detected recently in bats from South America. By molecular investigations, using a generic real‐time RT‐PCR (RT‐qPCR) that detects all previously known influenza A virus subtypes (H1‐H16) and a newly developed RT‐qPCR specific for the South American bat influenza‐like virus of subtype H17, a total of 1571 samples obtained from 1369 individual bats of 26 species from Central Europe were examined. No evidence for the occurrence of such influenza viruses was found. Further attempts towards a more comprehensive evaluation of the role of bats in the ecology and epidemiology of influenza viruses should be based on more intense monitoring efforts. However, given the protected status of bats, not only in Europe, such activities need to be embedded into existing pathogen‐monitoring programs.

New insights into the genetics of EBLV-1 from Germany.

Previous epidemiological studies on EBLVs indicated a distinct geographical distribution of EBLV-1 in Germany. In this study, 48 isolates were selected to further investigate the spatial and temporal distribution of EBLV-1 variants in Germany. The nucleoprotein-gene (N), the nucleoprotein-phosphoprotein spanning untranslated region (NP-UTR) and the UTR between G- and L-gene of each isolate were sequenced using direct cycle sequencing. Results of the subsequent phylogenetic analysis of the N-gene confirmed previous studies on EBLVs, showing a high sequence identity among German EBLV-1a isolates, and a correlation between genetic and temporal and spatial distance, respectively, was shown. Our results indicate that the GL-UTR is not suitable for phylogenetic analyses. Interestingly, 6 nt insertions in two isolates as well as a single nucleotide insertion in a different isolate were detected in the N-P UTR. Within the UTR between G- and L-gene one isolate showed a 35 nt deletion. The effect of those changes on viral properties remains elusive as such mutations have not been described for lyssaviruses before.

Identification of rhabdoviral sequences in oropharyngeal swabs from German and Danish bats

BackgroundIn the frame of active lyssavirus surveillance in bats, oropharyngeal swabs from German (N = 2297) and Danish (N = 134) insectivorous bats were investigated using a newly developed generic pan-lyssavirus real-time reverse transcriptase PCR (RT-qPCR).FindingsIn total, 15 RT-qPCR positive swabs were detected. Remarkably, sequencing of positive samples did not confirm the presence of bat associated lyssaviruses but revealed nine distinct novel rhabdovirus-related sequences.ConclusionsSeveral novel rhabdovirus-related sequences were detected both in German and Danish insectivorous bats. The results also prove that the novel generic pan-lyssavirus RT-qPCR offers a very broad detection range that allows the collection of further valuable data concerning the broad and complex diversity within the family Rhabdoviridae.