Literature DB >> 26689887

Surveillance for Coronaviruses in Bats, Lebanon and Egypt, 2013-2015.

Mahmoud M Shehata, Daniel K W Chu, Mokhtar R Gomaa, Mounir AbiSaid, Rabeh El Shesheny, Ahmed Kandeil, Ola Bagato, Samuel M S Chan, Elie K Barbour, Houssam S Shaib, Pamela P McKenzie, Richard J Webby, Mohamed A Ali, Malik Peiris, Ghazi Kayali.

Abstract

Entities: Disease Gene Species

Keywords: Coronavirus; Egypt; Lebanon; Middle East; bats; surveillance; viruses; zoonoses

Mesh：

Year: 2016 PMID： 26689887 PMCID： PMC4696718 DOI： 10.3201/eid2201.151397

Source DB: PubMed Journal: Emerg Infect Dis ISSN： 1080-6040 Impact factor: 6.883

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To the Editor: Coronaviruses (CoVs) in bats are genetically diverse, and evidence suggests they are ancestors of Middle East respiratory virus CoV (MERS-CoV), severe acute respiratory syndrome CoV, and human CoVs 229E and NL63 (–). We tested several bat species in Lebanon and Egypt to understand the diversity of bat CoVs there. Samples were collected during February 2013–April 2015. A total of 821 bats were captured live in their caves; sampled (oral swab, rectal swab, serum); and released, except for 72 bats that died or were euthanized upon capture. Lungs and livers of euthanized bats were harvested and homogenized. Caves were in proximity to human-inhabited area but not in proximity to camels. In Egypt, we sampled 3 bat species (Technical Appendix 1). Eighty-two Egyptian tomb bats (Taphozous perforatus) tested negative for CoV. We also sampled 31 desert pipistrelle bats (Pipistrellus deserti) and detected an HKU9-like betacoronavirus (β-CoV) in the liver of 1 bat (prevalence 3.2%). From 257 specimens from Egyptian fruit bats (Rousettus aegyptiacus), we detected β-CoV in 18 samples from 18 different bats (prevalence 7%). A murine hepatitis virus–like CoV was detected in the lung of 1 bat. HKU9-like viruses were detected in 5 oral, 2 lung, 5 liver, and 5 rectal samples. Overall, 5.1% of the bats tested positive. In Lebanon, we sampled 4 bat species. Four Rhinolophus hipposideros bats and 6 Miniopterus schribersii bats tested negative. One of 3 Rhinolophus ferrumequinum bats sampled was positive. We sampled 438 Rousettus aegyptiacus bats from 10 different locations and detected HKU9-like viruses in 24 rectal swab specimens (prevalence 5.5%). Overall, 5.5% of the bats tested positive. A subset of the samples (696 samples: 516 from Egypt, 180 from Lebanon) were tested for MERS-CoV by using the specific upstream of E quantitative reverse transcription PCR; all tested negative. Serum samples from 814 bats tested negative for MERS-CoV antibodies. Phylogenetic analysis revealed that the RNA-dependent RNA polymerase (RdRp) genes of viruses detected in R. aegyptiacus bats in Lebanon and Egypt were closely related to the RdRp gene of HKU9 CoV (Figure). Our viruses clustered in 3 groups: A, B, and C. Group A viruses were closely related to HKU9-10-2 virus and included viruses from Egypt. Group B included viruses from both countries and were closely related to HKU9-1 and HKU9-4 viruses. Group C also included viruses from both countries that were related to HKU9-3 and HKU9-5 viruses. The RdRp fragments sequenced had <90% nt similarity among groups A, B, and C. Within-group nucleotide similarity was >90%, and amino acid variability was 2%–4% (Technical Appendix 2). The phylogenetic tree of the N gene also showed proximity of the viruses detected in our study to HKU9 viruses (Technical Appendix 1). Viruses from Lebanon clustered together as did the viruses from Egypt.

Figure

Phylogenetic tree of the coronavirus RNA-dependent RNA polymerase gene. This tree was constructed on the basis of a sequence alignment of 330 bp using the neighbor-joining method. Bold text indicates sequences found in this study. Scale bar indicates nucleotide substitutions per site. Most of the positive samples were detected in Egyptian fruit bats. These are cave-dwelling species that inhabit regions of East Africa, Egypt, the Eastern Mediterranean, Cyprus, and Turkey (). This species is a reservoir for several viruses, including Marburg, Kasokero, and Sosuga viruses (–). The β-CoVs HKU9 and HKU10 were detected in Chinese fruit bats (). All but 1 of the detected viruses were HKU9-like. However, there was enough genetic variability within the sequenced RdRp fragments to suggest the circulation of at least 3 diverse groups comprising 3 different CoV species. Our detection of CoVs in oral, rectal, lung, and liver samples suggests that CoV infection in those bats was systemic, although the bats were apparently healthy. One bat had a murine hepatitis virus–like infection. This bat was captured from a brood that inhabited the windowsills of a historic building in urban Cairo. This infection might have been a cross-species infection from mice to bats in the same habitat. Although bats rarely come in direct contact with humans, humans can come into more frequent contact with bat urine and feces and, in the case of fruit bats, bat saliva through partially eaten fruits. Bats in the Middle East are not eaten for food but are occasionally hunted. In this study, HKU9-related viruses were detected in apparently healthy fruit bat species from Egypt and Lebanon and appear to cause systemic infection. HKU9-related viruses are not known to cause human disease. MERS-CoV was not detected in bats sampled in this study. More surveillance for bat CoVs in the Middle East is needed, and the zoonotic potential for bat-CoVs requires further study.

Technical Appendix 1

Laboratory methods.

Technical Appendix 2

Nucleotide and amino acid pairwise distances of coronaviruses found in bats, Egypt and Lebanon, 2013–2015.

9 in total

1. Environmental margin and island evolution in Middle Eastern populations of the Egyptian fruit bat.

Authors: P Hulva; T Marešová; H Dundarova; R Bilgin; P Benda; T Bartonička; I Horáček
Journal: Mol Ecol Date: 2012-10-24 Impact factor: 6.185

2. Kasokero virus: a new human pathogen from bats (Rousettus aegyptiacus) in Uganda.

Authors: M Kalunda; L G Mukwaya; A Mukuye; M Lule; E Sekyalo; J Wright; J Casals
Journal: Am J Trop Med Hyg Date: 1986-03 Impact factor: 2.345

3. Comparative analysis of twelve genomes of three novel group 2c and group 2d coronaviruses reveals unique group and subgroup features.

Authors: Patrick C Y Woo; Ming Wang; Susanna K P Lau; Huifang Xu; Rosana W S Poon; Rongtong Guo; Beatrice H L Wong; Kai Gao; Hoi-Wah Tsoi; Yi Huang; Kenneth S M Li; Carol S F Lam; Kwok-Hung Chan; Bo-Jian Zheng; Kwok-Yung Yuen
Journal: J Virol Date: 2006-11-22 Impact factor: 5.103

4. A Recently Discovered Pathogenic Paramyxovirus, Sosuga Virus, is Present in Rousettus aegyptiacus Fruit Bats at Multiple Locations in Uganda.

Authors: Brian R Amman; Cesar G Albariño; Brian H Bird; Luke Nyakarahuka; Tara K Sealy; Stephen Balinandi; Amy J Schuh; Shelly M Campbell; Ute Ströher; Megan E B Jones; Megan E Vodzack; DeeAnn M Reeder; Winyi Kaboyo; Stuart T Nichol; Jonathan S Towner
Journal: J Wildl Dis Date: 2015-04-28 Impact factor: 1.535

5. Middle East respiratory syndrome coronavirus in bats, Saudi Arabia.

Authors: Ziad A Memish; Nischay Mishra; Kevin J Olival; Shamsudeen F Fagbo; Vishal Kapoor; Jonathan H Epstein; Rafat Alhakeem; Abdulkareem Durosinloun; Mushabab Al Asmari; Ariful Islam; Amit Kapoor; Thomas Briese; Peter Daszak; Abdullah A Al Rabeeah; W Ian Lipkin
Journal: Emerg Infect Dis Date: 2013-11 Impact factor: 6.883

6. Close relative of human Middle East respiratory syndrome coronavirus in bat, South Africa.

Authors: Ndapewa Laudika Ithete; Samantha Stoffberg; Victor Max Corman; Veronika M Cottontail; Leigh Rosanne Richards; M Corrie Schoeman; Christian Drosten; Jan Felix Drexler; Wolfgang Preiser
Journal: Emerg Infect Dis Date: 2013-10 Impact factor: 6.883

7. Isolation of genetically diverse Marburg viruses from Egyptian fruit bats.

Authors: Jonathan S Towner; Brian R Amman; Tara K Sealy; Serena A Reeder Carroll; James A Comer; Alan Kemp; Robert Swanepoel; Christopher D Paddock; Stephen Balinandi; Marina L Khristova; Pierre B H Formenty; Cesar G Albarino; David M Miller; Zachary D Reed; John T Kayiwa; James N Mills; Deborah L Cannon; Patricia W Greer; Emmanuel Byaruhanga; Eileen C Farnon; Patrick Atimnedi; Samuel Okware; Edward Katongole-Mbidde; Robert Downing; Jordan W Tappero; Sherif R Zaki; Thomas G Ksiazek; Stuart T Nichol; Pierre E Rollin
Journal: PLoS Pathog Date: 2009-07-31 Impact factor: 6.823

8. MERS-related betacoronavirus in Vespertilio superans bats, China.

Authors: Li Yang; Zhiqiang Wu; Xianwen Ren; Fan Yang; Junpeng Zhang; Guimei He; Jie Dong; Lilian Sun; Yafang Zhu; Shuyi Zhang; Qi Jin
Journal: Emerg Infect Dis Date: 2014-07 Impact factor: 6.883

Review 9. Ecology, evolution and classification of bat coronaviruses in the aftermath of SARS.

Authors: Jan Felix Drexler; Victor Max Corman; Christian Drosten
Journal: Antiviral Res Date: 2013-10-31 Impact factor: 5.970

9 in total

6 in total

1. MERS-CoV at the Animal-Human Interface: Inputs on Exposure Pathways from an Expert-Opinion Elicitation.

Authors: Anna L Funk; Flavie Luce Goutard; Eve Miguel; Mathieu Bourgarel; Veronique Chevalier; Bernard Faye; J S Malik Peiris; Maria D Van Kerkhove; Francois Louis Roger
Journal: Front Vet Sci Date: 2016-10-05

Review 2. Bat Research Networks and Viral Surveillance: Gaps and Opportunities in Western Asia.

Authors: Kendra L Phelps; Luke Hamel; Nisreen Alhmoud; Shahzad Ali; Rasit Bilgin; Ketevan Sidamonidze; Lela Urushadze; William Karesh; Kevin J Olival
Journal: Viruses Date: 2019-03-10 Impact factor: 5.048

3. Middle East respiratory syndrome coronavirus infection in non-camelid domestic mammals.

Authors: Ahmed Kandeil; Mokhtar Gomaa; Mahmoud Shehata; Ahmed El-Taweel; Ahmed E Kayed; Awatef Abiadh; Jamel Jrijer; Yassmin Moatasim; Omnia Kutkat; Ola Bagato; Sara Mahmoud; Ahmed Mostafa; Rabeh El-Shesheny; Ranawaka Apm Perera; Ronald Lw Ko; Nagla Hassan; Basma Elsokary; Lotfi Allal; Ahmed Saad; Heba Sobhy; Pamela P McKenzie; Richard J Webby; Malik Peiris; Mohamed A Ali; Ghazi Kayali
Journal: Emerg Microbes Infect Date: 2019 Impact factor: 7.163