Your search keyword '"Picard-Meyer E"' showing total 8 results

1. Epidemiology of rabid bats in France, 1989 to 2002.

Author

Picard-Meyer, E., Barrat, J., Wasniewski, M., Wandeler, A., Nadin-Davis, S., Lowings, J.P., Fooks, A.R., McElhinney, L., Bruyère, V., and Cliquet, F.

Subjects

*EPIDEMIOLOGY, *BATS, *RABIES, *RABIES virus, *NUCLEOPROTEINS

Abstract

Studies the epidemiology of bats in France from 1989 to 2002. Virus strains causing bat rabies; Genetic characterization of all the French bat rabies isolates using reverse-transcriptase polymerase chain reaction and phylogenetic analysis; Amplification of the nucleoprotein sequences of all rabies virus genotypes; Characteristics of the French strains isolated from serotine bats.

Published

2004

2. Genetic analysis of European bat lyssavirus type 1 isolates from France.

Author

Picard-Meyer, E., Barrat, J., Tissot, E., Barrat, M.J., Bruyère, V., and Cliquet, F.

Subjects

*VIRAL genetics, *BAT diseases, *RABIES in animals, *GENETICS, *VIRUSES

Abstract

European bat lyssavirus type 1a (EBLV-1a) was first identified in central France from a serotine bat (Eptesicus serotinus) collected at the end of 2002. Rabies was diagnosed by reference rabies diagnosis methods and molecular tools. Phylogenetic analysis of 14 viral isolates obtained from French bats infected with EBLV-1 between 1989 and the end of 2002 against 47 nucleoprotein sequences showed a north-west to east distribution of EBLV-1a virus and a south to north distribution of EBLV-1b virus, isolates of which could be divided into two groups: group 1 in north-eastern France and group 2 in central and north-western France. [ABSTRACT FROM AUTHOR]

Published

2004

3. Assessment of virus and Leptospira carriage in bats in France.

Author

Arnaout Y, Picard-Meyer E, Robardet E, Cappelle J, Cliquet F, Touzalin F, Jimenez G, and Djelouadji Z

Subjects

Animals, RNA, Ribosomal, 16S, France, DNA, Bacterial, Phylogeny, Chiroptera, Leptospira genetics, Lyssavirus

Abstract

With over 1,400 species worldwide, bats represent the second largest order of mammals after rodents, and are known to host major zoonotic pathogens. Here, we estimate the presence of pathogens in autochthonous bat populations. First, we set out to check our samples for PCR amplification efficiency by assessing the occurrence of inhibited PCR reactions from different types of bat samples with amplifying the housekeeping gene β-actin. Second, we investigated the presence of five targeted pathogens in a French bat population using PCR. We targeted viral RNA of Canine distemper virus, Alphacoronavirus, Lyssavirus, Rotavirus and bacterial Leptospira DNA. To do so, we screened for these viruses in bat faecal samples as well as in oropharyngeal swab samples. The presence of Leptospira was assessed in urine, kidney, lung and faecal samples. Results showed a frequency of inhibited reactions ranging from 5 to 60% of samples, varying according to the sample itself and also suspected to vary according to sampling method and the storage buffer solution used, demonstrating the importance of the sampling and storage on the probability of obtaining negative PCR results. For pathogen assessment, rotavirus and alphacoronavirus RNA were detected in Myotis myotis, Myotis daubentonii, Myotis emarginatus and Rhinolophus ferrumequinum bats. Rotaviruses were also detected in Barbastella barbastellus. The presence of alphacoronavirus also varied seasonally, with higher frequencies in late summer and October, suggesting that juveniles potentially play an important role in the dynamics of these viruses. Leptospira DNA was detected in M. myotis and M. daubentonii colonies. The 16S rRNA sequences obtained from Leptospira positive samples showed 100% genetic identity with L. borgpetersenii. Neither canine distemper virus nor lyssavirus RNA were detected in any of the tested samples. This study is the first to show the presence of Leptospira in autochthonous French bats in addition to coronavirus and rotavirus RNA previously reported in European autochthonous bats., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2023 Arnaout et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2023

4. Investigations into SARS-CoV-2 and other coronaviruses on mink farms in France late in the first year of the COVID-19 pandemic.

Author

Wasniewski M, Boué F, Richomme C, Simon-Lorière E, der Werf SV, Donati F, Enouf V, Blanchard Y, Beven V, Leperchois E, Leterrier B, Corbet S, Le Gouil M, Monchatre-Leroy E, and Picard-Meyer E

Subjects

Animals, Humans, SARS-CoV-2 genetics, Mink, Farms, Pandemics, France, Asymptomatic Infections, COVID-19 epidemiology, COVID-19 veterinary, Alphacoronavirus

Abstract

Soon after the beginning of the COVID-19 pandemic in early 2020, the Betacoronavirus SARS-CoV-2 infection of several mink farms breeding American minks (Neovison vison) for fur was detected in various European countries. The risk of a new reservoir being formed and of a reverse zoonosis from minks quickly became a major concern. The aim of this study was to investigate the four French mink farms to see whether SARS-CoV-2 was circulating there in late 2020. The investigations took place during the slaughtering period, thus facilitating different types of sampling (swabs and blood). On one of the four mink farms, 96.6% of serum samples were positive when tested with a SARS-CoV-2 ELISA coated with purified N protein recombinant antigen, and 54 out of 162 (33%) pharyngo-tracheal swabs were positive by RT-qPCR. The genetic variability among 12 SARS-CoV-2 genomes sequenced from this farm indicated the co-circulation of several lineages at the time of sampling. All the SARS-CoV-2 genomes detected were nested within the 20A clade (Nextclade), together with SARS-CoV-2 genomes from humans sampled during the same period. The percentage of SARS-CoV-2 seropositivity by ELISA varied between 0.3 and 1.1% on the other three farms. Interestingly, among these three farms, 11 pharyngo-tracheal swabs and 3 fecal pools from two farms were positive by end-point RT-PCR for an Alphacoronavirus very similar to a mink coronavirus sequence observed on Danish farms in 2015. In addition, a mink Caliciviridae was identified on one of the two farms positive for Alphacoronavirus. The clinical impact of these inapparent viral infections is not known. The co-infection of SARS-CoV-2 with other viruses on mink farms could help explain the diversity of clinical symptoms noted on different infected farms in Europe. In addition, the co-circulation of an Alphacoronavirus and SARS-CoV-2 on a mink farm would potentially increase the risk of viral recombination between alpha and betacoronaviruses as already suggested in wild and domestic animals, as well as in humans., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2023 Wasniewski et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2023

5. Genetic identification of bat species for pathogen surveillance across France.

Author

Arnaout Y, Djelouadji Z, Robardet E, Cappelle J, Cliquet F, Touzalin F, Jimenez G, Hurstel S, Borel C, and Picard-Meyer E

Subjects

Animals, Epidemiological Monitoring, Feces chemistry, France, Rabies veterinary, Wings, Animal chemistry, Zoonoses, Chiroptera classification, Chiroptera genetics, DNA, Mitochondrial analysis

Abstract

With more than 1400 chiropteran species identified to date, bats comprise one-fifth of all mammalian species worldwide. Many studies have associated viral zoonoses with 45 different species of bats in the EU, which cluster within 5 families of bats. For example, the Serotine bats are infected by European Bat 1 Lyssavirus throughout Europe while Myotis bats are shown infected by coronavirus, herpesvirus and paramyxovirus. Correct host species identification is important to increase our knowledge of the ecology and evolutionary pattern of bat viruses in the EU. Bat species identification is commonly determined using morphological keys. Morphological determination of bat species from bat carcasses can be limited in some cases, due to the state of decomposition or nearly indistinguishable morphological features in juvenile bats and can lead to misidentifications. The overall objective of our study was to identify insectivorous bat species using molecular biology tools with the amplification of the partial cytochrome b gene of mitochondrial DNA. Two types of samples were tested in this study, bat wing punches and bat faeces. A total of 163 bat wing punches representing 22 species, and 31 faecal pellets representing 7 species were included in the study. From the 163 bat wing punches tested, a total of 159 were genetically identified from amplification of the partial cyt b gene. All 31 faecal pellets were genetically identified based on the cyt b gene. A comparison between morphological and genetic determination showed 21 misidentifications from the 163 wing punches, representing ~12.5% of misidentifications of morphological determination compared with the genetic method, across 11 species. In addition, genetic determination allowed the identification of 24 out of 25 morphologically non-determined bat samples. Our findings demonstrate the importance of a genetic approach as an efficient and reliable method to identify bat species precisely., Competing Interests: No authors have competing interests.

Published

2022

6. Bat rabies in France: a 24-year retrospective epidemiological study.

Author

Picard-Meyer E, Robardet E, Arthur L, Larcher G, Harbusch C, Servat A, and Cliquet F

Subjects

Animals, Female, France, Humans, Male, Phylogeny, RNA, Viral genetics, Rabies virus classification, Rabies virus pathogenicity, Retrospective Studies, Chiroptera virology, Rabies epidemiology

Abstract

Since bat rabies surveillance was first implemented in France in 1989, 48 autochthonous rabies cases without human contamination have been reported using routine diagnosis methods. In this retrospective study, data on bats submitted for rabies testing were analysed in order to better understand the epidemiology of EBLV-1 in bats in France and to investigate some epidemiological trends. Of the 3176 bats submitted for rabies diagnosis from 1989 to 2013, 1.96% (48/2447 analysed) were diagnosed positive. Among the twelve recognised virus species within the Lyssavirus genus, two species were isolated in France. 47 positive bats were morphologically identified as Eptesicus serotinus and were shown to be infected by both the EBLV-1a and the EBLV-1b lineages. Isolation of BBLV in Myotis nattereri was reported once in the north-east of France in 2012. The phylogenetic characterisation of all 47 French EBLV-1 isolates sampled between 1989 and 2013 and the French BBLV sample against 21 referenced partial nucleoprotein sequences confirmed the low genetic diversity of EBLV-1 despite its extensive geographical range. Statistical analysis performed on the serotine bat data collected from 1989 to 2013 showed seasonal variation of rabies occurrence with a significantly higher proportion of positive samples detected during the autumn compared to the spring and the summer period (34% of positive bats detected in autumn, 15% in summer, 13% in spring and 12% in winter). In this study, we have provided the details of the geographical distribution of EBLV-1a in the south-west of France and the north-south division of EBLV-1b with its subdivisions into three phylogenetic groups: group B1 in the north-west, group B2 in the centre and group B3 in the north-east of France.

Published

2014

7. Isolation of Bokeloh bat lyssavirus in Myotis nattereri in France.

Author

Picard-Meyer E, Servat A, Robardet E, Moinet M, Borel C, and Cliquet F

Subjects

Animals, Brain virology, France, Lyssavirus genetics, Phylogeny, RNA, Viral genetics, RNA, Viral isolation & purification, Rabies virology, Salivary Glands virology, Sequence Analysis, DNA, Chiroptera classification, Chiroptera virology, Lyssavirus isolation & purification, Rabies veterinary

Abstract

Bokeloh bat lyssavirus (BBLV) was found in Myotis nattereri for the first time in northeastern France in July 2012. The complete genome sequence of the virus from the infected Natterer's bat was determined by whole-genome sequencing and compared to that of the first BBLV strain isolated in 2010 in Germany and with those of all currently identified lyssaviruses. The French isolate [KC169985] showed 98.7 % nucleotide sequence identity to the German BBLV strain [JF311903]. Several organs of the infected French bat were examined by classical rabies diagnostic methods: fluorescent antibody test, cell culture inoculation test and RT-qPCR. Antigen, infectious virus and high viral RNA levels were found in both the brain and salivary glands. Traces of genomic RNA were detected in the bladder, kidney and lung tissue. The results of an investigation of the distribution of lyssaviruses with the detection of infectious virus in the salivary glands suggest a possible mode of transmission of the virus.

Published

2013

8. Bat rabies surveillance in France, from 1989 through May 2005.

Author

Picard-Meyer E, Barrat J, Tissot E, Verdot A, Patron C, Barrat MJ, and Cliquet F

Subjects

Animals, France, History, 20th Century, History, 21st Century, Humans, Mice, Chiroptera virology, Lyssavirus, Rabies diagnosis, Rabies epidemiology, Rabies history, Rabies virology

Abstract

In France, the passive surveillance of lyssaviruses in bats started in 1989, with the first positive case found in the East of the country. In 2000, the French bat rabies surveillance network in France was improved on the basis of the one used for the surveillance of fox rabies. The objectives of this network are to improve bat rabies surveillance by increasing the number of specimens and to provide an estimation of rabies incidence in bat populations across the country. The surveillance network is principally constituted by the network of local Veterinary Services and by the National Bat Conservationists Network (French Society for the Study and Protection of Mammals). From 1989 to through 2004, 21 autochtonous rabies cases were diagnosed out of the 934 French bat cadavers found. The laboratory techniques used for diagnosis, recommended by WHO and OIE, were fluorescent antibody test (FAT), rabies tissue culture infection test (RTCIT) on murine neuroblastoma cells, and the mouse inoculation test (MIT). All 21 cases were diagnosed in serotine bats (Eptesicus serotinus) and were due to European bat lyssavirus type 1 (EBLV-1), genotype 5, infection.

Published

2006