key: cord-0002242-mcxkifh6 authors: Müller, Marcel A.; Devignot, Stéphanie; Lattwein, Erik; Corman, Victor Max; Maganga, Gaël D.; Gloza-Rausch, Florian; Binger, Tabea; Vallo, Peter; Emmerich, Petra; Cottontail, Veronika M.; Tschapka, Marco; Oppong, Samuel; Drexler, Jan Felix; Weber, Friedemann; Leroy, Eric M.; Drosten, Christian title: Evidence for widespread infection of African bats with Crimean-Congo hemorrhagic fever-like viruses date: 2016-05-24 journal: Sci Rep DOI: 10.1038/srep26637 sha: 59d3f98d78f2ff993174b173807435e75df8bc3a doc_id: 2242 cord_uid: mcxkifh6 Crimean Congo hemorrhagic fever virus (CCHFV) is a highly virulent tick-borne pathogen that causes hemorrhagic fever in humans. The geographic range of human CCHF cases largely reflects the presence of ticks. However, highly similar CCHFV lineages occur in geographically distant regions. Tick-infested migratory birds have been suggested, but not confirmed, to contribute to the dispersal. Bats have recently been shown to carry nairoviruses distinct from CCHFV. In order to assess the presence of CCHFV in a wide range of bat species over a wide geographic range, we analyzed 1,135 sera from 16 different bat species collected in Congo, Gabon, Ghana, Germany, and Panama. Using a CCHFV glycoprotein-based indirect immunofluorescence test (IIFT), we identified reactive antibodies in 10.0% (114/1,135) of tested bats, pertaining to 12/16 tested species. Depending on the species, 3.6%–42.9% of cave-dwelling bats and 0.6%–7.1% of foliage-living bats were seropositive (two-tailed t-test, p = 0.0447 cave versus foliage). 11/30 IIFT-reactive sera from 10 different African bat species had neutralizing activity in a virus-like particle assay. Neutralization of full CCHFV was confirmed in 5 of 7 sera. Widespread infection of cave-dwelling bats may indicate a role for bats in the life cycle and geographic dispersal of CCHFV. Bats (Order: Chiroptera) represent the only migratory flying mammals. Bats are commonly infested with soft and hard ticks 12, 13 , and were recently shown to carry nairoviruses 7, 14, 15 . Phylogenetic analyses as well as serological studies based on cross-reactivity in complement fixation tests suggest that all identified bat-associated nairoviruses belong to two novel serogroups that are distantly related to CCHFV 7 . One representative, termed Leopards Hill virus (LPHV), was successfully isolated from samples of the African bat species Hipposideros gigas (H. gigas). Phenotypic characterization revealed that LPHV causes hemorrhagic disease in mice 15 . Whether LPHV may be pathogenic for other mammals including humans is unknown. The large diversity of viruses in bats [16] [17] [18] [19] [20] together with previous findings of bat nairoviruses 7,14,15 encourage a wider and more systematic assessment of the endemicity of nairoviruses in bats. Previous studies were predominantly based on nucleic acid detection and virus isolation, which can only detect viraemic animals. While we do not know the expected frequency of nairovirus viraemia in free-ranging bats, field studies on other RNA viruses with a viraemic infection pattern, including hepadnaviruses 19 , hepaciviruses 17 , filoviruses [21] [22] [23] , and bunyaviruses 24, 25 , indicate very low virus detection rates. Unless very large sample collections are studied, virus detection by PCR lacks the power to reflect the host species range of a given virus, in particular because of a lack of negative predictive value 17, 18 . Serological techniques are better suited for host range studies because seroprevalence is less sensitive to temporal and spatial variation of infection activity 26 . Serology is also more suitable for the limited sample size that can be achieved in bat-related studies, as most bat species are too small to be bled without destruction. In the present study we screened 1,135 bat serum samples comprising 16 bat species (migratory and non-migratory) from five different countries for the presence of CCHF-like viruses. The sample was focused on African bat species as nairoviruses have been predominantly detected in the Old World bats [14] [15] [16] . We applied a staged set of serological assays including a recombinant glycoprotein (GP)-based indirect immunofluorescence test (IIFT), a novel pseudotype neutralization assay 27 as well as full virus neutralization tests conducted under biosafety level 4 conditions. Additional molecular screening involved two modified generic nairovirus RT-PCRs based on previously established protocols [28] [29] [30] . Bats carry CCHFV GP-reactive antibodies. From 2003 through 2011 bats were sampled in Congo, Gabon, Ghana, Germany and Panama. The sample included 1,135 blood or serum specimens from 16 bat species pertaining to six different bat families with variable habitat preference and diet. To assess if bats harbor CCHF-like viruses, we screened bat serum samples for CCHFV GP-reactive antibodies by IIFT. In total, 114 of 1,135 (10.0%) sera from 12 of 16 bat species sampled between 2005 and 2009 in 4/5 countries reacted with recombinant CCHFV GP antigen (range 1.0-57.6%, Table 1 , Fig. 1 ). An example of a reactive bat serum sample is shown in Fig. 2A . IIFT-positive detections were predominantly identified in cave-dwelling, migratory bats including the frugivorous species Rousettus aegyptiacus (24.4%; 48/197) as well as the insectivorous species Coleura afra (42.9%; 6/14), Hipposideros cf. caffer (6.3%; 3/48), Miniopterus inflatus (17.6%; 9/51) and Hipposideros gigas (24.8%; 32/129) from Congo and Gabon (Fig. 1) . CCHFV seropositivity was significantly elevated for bat species that roost in caves versus those that roost in trees ( Fig. 1 Figure) . Age (p = 0.7434), dietary (p = 0.4622), gender (p = 0.4613), migration (p = 0.4788) and seasonality (p = 0.1605) were not associated with differences in seroprevalence (Supplementary Table 1 ). No antibodies were found in (n = 43) sera from New World bats, corresponding to the notion that CCHFV is an Old World virus 2 . Detection of CCHFV neutralizing antibodies in African bat species. As antibody cross-reactivity between CCHFV and viruses from the related NSDV serogroup cannot be completely ruled out by IIFT 31 , specific virus neutralization tests (NT) were done. NT can prove previous infection with CCHFV because there is no cross-neutralization between serogroups 31 . Because NTs require relatively large volumes of serum that cannot be obtained from most bat species, only for 30 of the 114 IIFT-positive sera covering 10/12 bat species, NT assays could be performed. In addition, 10 CCHFV IIFT-negative samples with sufficient volume, representing all 10 assessed bat species, were tested. Sera were tested at a 1:100 dilution in a 96-well format using a recently established CCHF virus-like particle (VLP)-based NT 27 . Out of 30 IIFT-positive sera, 11 showed significant neutralizing activity defined as 80% reduction of luciferase luminescence signal (Fig. 2B, Supplementary Table 2 ). None of the 10 IIFT-negative control sera had neutralizing activity (Fig. 2B) . In parallel, all 40 (30 IIFT-positive, 10 IIFT-negative) bat sera were tested in a Rift Valley fever (RVF) VLP-based NT 32 , all with negative results, ruling out nonspecific neutralization activity in bat sera (Fig. 3, Supplementary Table 2 ). For 7 of 11 CCHF VLP-positive sera, enough material was available to conduct additional neutralization tests by a full virus CCHFV neutralization test under biosafety level 4 conditions. Endpoint titration by IIFT in these samples revealed high reciprocal titers between 160 and 1,280 ( Table 2 , Fig. 2A ). Sera were thus titrated in 2-fold serial dilutions in a range of 1:40-1:1,280. The test confirmed full virus neutralizing activity in 5 of 7 sera, with reciprocal titers ranging between 40 (lowest testing dilution due to lack of serum) and 160 ( Table 2 ). Lack of evidence for CCHFV-related nucleotide sequences in bat serum samples. To identify CCHFV-related nucleotide sequences in serum samples, we combined three previously established generic RT-PCR protocols that were shown to detect all known nairoviruses [28] [29] [30] . Modifications were made to increase the sensitivity for the detection of CCHFV-related nucleotide sequences by applying low annealing temperatures and degenerated oligonucleotides. Viral RNA of CCHFV strain IbAr was used to test oligonucleotides from Lambert et al. 29 in combination with primers from Wölfel and colleagues 30 . The endpoint RT-PCR detection limit of an RT-PCR formulation that used the best combination of primers was between 8 and 80 copies per reaction. An additional RT-PCR assay was developed based on a hemi-nested formulation using primers described in Honig et al. 28 followed by a 2 nd round RT-PCR step with novel primers. The sensitivity limit of this assay also ranged between 8 and 80 copies per reaction. Serum samples from Artibeus jamaicensis (n = 28), A. lituratus (n = 15, both from Panama) as well as Myotis dasycneme (n = 26, Germany) were not available for RT-PCR testing due to sample volume limitations (< 25 μ l). In the remaining 1,067 of 1,135 serologically-tested sera, no CCHFV RNA was found by both RT-PCR formulations. In parallel, these same bat serum sample-derived RNA extracts had successfully been used for the detection of novel paramyxo 18 -, hepe 20 -, hepadna 19 -and flaviviruses 17 , confirming that the material was appropriate for RNA virus testing. In this assessment of the potential host species range of CCHFV in bats we obtained strong serological evidence for bats constituting a putative host for CCHFV or a closely related virus belonging to the CCHFV serotype. Our failure to directly detect viral RNA may be caused by an overall low infection prevalence that precludes detection in spite of using sensitive RT-PCR assays on a rather large collection of serum samples from bats. We applied two generic pan-nairovirus RT-PCR assays that made use of low stringency amplification conditions to enable the detection of unknown CCHF-related viruses. These conditions led to a maximal 10-fold higher limit of detection (LOD: 8-80 copies/reaction) compared to previously established diagnostic CCHFV real time PCRs with LODs of 5-16 copies per reaction [33] [34] [35] [36] . However, as CCHFV-infected viraemic humans, for example, have viral loads up to 10 9 viral RNA copies per ml 37 , we assume that viraemic animals would have been identified if present. Nonetheless, we cannot rule out that bats may not experience a pronounced viraemia as observed for birds 38, 39 . In addition, sampling time point and/or type of sample may have prevented amplification. In humans it was shown that viremia can be very short (6 days) 37 . Although there is, to our knowledge, no data on nairovirus viraemia in bats, we think that the chances to detect CCHFV RNA in bat samples may be very limited. Previous studies conducted by us and others have already shown that the detection frequency of viral RNA is generally very low (< 3%) 17, 19 . As shown by Ishii et al. the bat-related nairovirus LPHV was primarily detected in lung samples 15 . Therefore, destructive sampling involving the collection of organ tissue of designated bat species may be more promising for nairovirus detection as virus might persist for prolonged periods in parenchymatous organs such as the lung or liver 14, 15 . In the context of this retrospective study we did not test different organs from bats because most species are protected and were sampled without destruction or samples were exhausted from previous experiments 40, 41 . In spite of this limitation we consider the serological results from our study to be indicative of the presence of members of the CCHFV serogroup in bats. The current demarcation criteria for nairovirus taxa have to rely on the definition of serogroups as long as formal species definitions are not in place. Serogroups based on cross-reactivity in antibody affinity assays reflect phylogeny and can be used to classify novel nairoviruses as they are identified 42, 43 . For example, complement fixation assays (CFA) and IIFT were applied to discriminate shrew nairoviruses from CCHFV and classify them into a separate serogroup termed Thiafora 44 . Phylogenetically, all members of the Thiafora serogroup form a monophyletic clade in sister relation to a clade containing all members of the CCHFV and NSDV serogroups 7 (overview shown in Fig. 4) . The NSDV serogroup contains NSDV (also named Ganjam virus), and Dugbe virus whose serological classification in one serogroup was again based on cross-reactivity in CFA and IIFT 31 . NT enables further serological discrimination between taxa in serogroups, exemplified by the presence of cross-reactivity but absence of cross-neutralization between Dugbe and NSDV 31 . These taxa might be referred to as two different serotypes within the NSDV serogroup (Fig. 4) . The whole NSDV serogroup is discriminated from the CCHFV serogroup, its monophyletic sister taxon, based on absence of cross-reactivity in CFA and decreased IIFT endpoint titers 31, 43, 45 . Further sub-differentiation into serotypes based on NT has not been observed within the CCHFV serogroup 42, 46 . Consequently, the combined reactivity in IIFT and NT suggests that bat species, tested in the present study, carry viruses which are less distinct from CCHFV than Dugbe virus is from NSDV. Also the height of IIFT titers observed in our study, up to 1:1,280, corresponds to CCHFV-specific titers in experimentally infected wild mammals that reached endpoint titers of 128-1,024 by IIFT 47 . We conclude that African bat species have been infected with CCHFV or a closely related nairovirus in the same serogroup and probably the same species. The identification of high neutralizing antibody titers (up to 1:160 based on full virus neutralization) indicates that bats experience infections followed by seroconversion, which in case of humans is correlated with clearance of the virus and survival of infection 48 . CCHFV might thus exemplify another highly pathogenic agent that is effectively controlled in bats. As several cave-dwelling bat species migrate over various distances, bats might contribute to the geographic dispersal of CCHFV in similar ways as hypothesized for birds [9] [10] [11] . Future studies should aim to clarify whether the CCHFV strains carried by bats or bat ticks are identical or distinct from strains associated with birds or bird ticks. Interestingly, we found a predominance of CCHFV antibody-positive bats among cave-dwelling species in particular in the Batouala cave in Gabon. The specific habitat conditions in caves (high population density, host availability, humidity, moderate temperature variations) could potentially enable a virus amplification cycle between bats and ticks 12,13,49 . Caves harbor many different arthropods including soft and hard ticks. Cave-dwelling animals like ruminants, bird and bats are highly exposed to blood-sucking parasites. Whereas in case of humans and ruminants it is known that CCHFV is predominantly transmitted by hard ticks 2,6,8 the role of soft ticks in the CCHFV transmission cycle is less clear. However, soft ticks have been found to carry bunyaviruses 50 and evidence from CCHFV-endemic countries suggests that certain soft tick species (Ornithodoros lahorensis, Argas reflexus) may as well serve as vectors for CCHFV 51, 52 . Soft ticks are long-lived and blood meals of soft ticks often take only a short period of time (minutes to hours) 53 . Consequently, bats may not be infested by soft ticks during sampling. The low rate of viremia in bats points to a persistence of the virus in ticks rather than bats, encouraging targeted investigations into the pathogen ecology of CCHFV based on cave-associated ticks that can be studied in proximity to bat roosts. Table 3 . All animals were handled according to national and European legislation for the protection of animals (EU council directive 86/609/EEC). For all individual sampling sites, study protocols including trapping, sampling and testing of animals were approved by the responsible animal ethics committees as detailed below. Maximum efforts were made to leave animals unharmed or to minimize suffering of animals. All bats were caught with mist nets and blood was taken by vein or heart punctures by trained personnel in accordance with the approved guidelines of the respective authorities. Any surgical procedure was performed under sodium pentobarbital/ketamine anesthesia. Sampling, capturing and sample transport were done as described before [17] [18] [19] [20] 29 were used in multiple combinations with primers described by Wölfel and colleagues 30 . Tenfold dilution series of viral RNA of CCHFV strain IbAr were used to determine the sensitivity of the PCR assays. Optimal amplification of CCHFV RNA was identified using the oligonucleotide combinations Nairo-F (ATG ATT GC5 AAY AG5 AAY TTY AA) and Nairo-R (ACA GCA RTG 5AT 5GG 5CC CCA YTT, 1 st round) and cc1a-c-F (GTG CCA CTG ATG ATG CAC AAA AGG ATT CCA TCT) and Nairo-R (2 nd round) in a hemi-nested PCR protocol. The use of the nucleoside inosine is indicated by the number 5. In a second PCR assay, which was based on the Honig et al. 28 protocol, the published 1 st round of PCR amplification by oligonucleotides Nairo-F and Nairo-R was followed by a newly introduced 2 nd round PCR using oligonucleotides Nairo-Fnest (CCA AGA AGY GT5 AGR AGY AAR GT) and Nairo-Rnest (TTG GGC CCC ACT T5G TRT TRT C5C C). 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The Journal of veterinary medical science/the A survey of Crimean-Congo haemorrhagic fever in livestock and ticks in Ardabil Province, Iran during Molecular epidemiology of Crimean-Congo hemorrhagic fever virus genome isolated from ticks of Hamadan province of Iran Biological and ecological characteristics of soft ticks (Ixodida: Argasidae) and their impact for predicting tick and associated disease distribution Coronavirus antibodies in African bat species We thank Stephan Kallies, Monika Eschbach-Bludau, Tobias Bleicker, Sebastian Brünink and Anette Klein for excellent technical assistance, Gudrun Wibbelt and Kristin Mühldorfer (IZW, Berlin) for providing bat serum samples, Antje Seebens (Noctalis) for field work in Ghana, and Eric Bergeron and Stuart Nichol for donating the original minireplicon plasmids. We thank Tasnim Suliman (Stellenbosch University) for critically reading the manuscript and Dennis Bente (UTMB, Galveston) for helpful comments. The CCHFV N antibody and CCHFV strain IbAr10200 were kindly provided by Ali Mirazimi, SMI, Sweden. The CCHFV positive serum was provided by Gülay Korukluoglu (Refik Saydam National Public Health Agency, Ankara, Turkey), and the negative human serum by Andreas Kaufmann (Philipps Universität Marburg, Germany). This work was supported by European Commission projects Antigone (contract no. 278976 to CD) and CCHFever Network (contract no. 260427 to FW). Samples and essential reagents were contributed by earlier projects funded by the Deutsche Forschungsgemeinschaft, including grants DR772/3-1, DR772/12-1, DR722/10-1 to CD, We 2616/7-1 to FW, MU 3564/1-1 to MAM, KA 1241/18-1 to E. Kalko and MT). The funders had no role in study design, data collection and analysis, decision to publish or preparation of the manuscript.