West Nile virus infection in crocodiles. (Letters).To the Editor: Recently West Nile virus (WNV) infection has been reported in three alligators (Alligator sp.) from central Florida (1) and one captive crocodile monitor (Varanus salvadori) with neurologic signs from the District of Columbia and Maryland area (2). These first reports of the virus in American reptiles highlight the possible role of this group of vertebrates in the WNV life cycle. To our knowledge, WNV in a reptile was reported only once before in a serosurvey conducted in Israel from 1965 to 1966, in which 22 reptiles and 96 amphibians were tested for hemagglutination-inhibiting antibodies against several viruses, including WNV; one turtle (Clemmys caspica) was seropositive (3). Experimental infection of the lake frog (Rana ridibunda) with a Russian strain of WNV resulted in high levels of viremia (4). At present, the role of reptiles and amphibians in the life cycle and epidemiology of WNV is not known. We report, for the first time, WNV infection in crocodiles (Crocodylus niloticus). To assess the potential role of crocodiles in the life cycle of WNV in Israel, serum specimens were collected from 20 healthy crocodiles on a commercial farm in the Negev Desert, in southern Israel (31[degrees]14'N, 34[degrees]19'E). The crocodiles came from two separate breeding farms (32[degrees]03'N, 35[degrees]26'E and 30[degrees]18'N, 35[degrees]07'E) in the Syrian-African Rift Valley, which is on the main route of bird migration from Africa to Europe. Five males and 15 females, 1-2.5 years of age, were examined. Blood was withdrawn from the crocodiles' ventral caudal 1. pertaining to a cauda. 2. situated more toward the cauda, or tail, than some specified reference point; toward the inferior (in humans) or posterior (in animals) end of the body. cau·dal (kôd vein, separated by centrifugation centrifugation /cen·trif·u·ga·tion/ (sen-trif?u-ga´shun) the process of separating lighter portions of a solution, mixture, or suspension from the heavier portions by centrifugal force., and kept at -20[degrees]C until analyzed. Neutralizing antibody titers were determined against WN-goose-98 (5) and attempts to isolate the virus were performed by using Vero cell culture (6) and by using direct reverse transcription-polymerase chain reaction (RT-PCR) on the serum specimens. To eliminate the possibilities of nonspecific reaction, all serum samples were concurrently tested for the only other flavivirus known to be present in Israel; Israeli turkey meningoencephalitis virus (ITV) (7). Because ITV does not produce cytopathic cytopathic /cy·to·path·ic/ (-path´ik) pertaining to or characterized by pathologic changes in cells. cy·to·path·ic (s  effects (CPE) in Vero cells, virus neutralization was conducted on BHK BHK - Baby Hamster KidneyBHK - Bachelor of Human Kinetics (degree) BHK - Biblia Hebraica Kittel (biblical studies) BHK - Blonde-Haired Kid (Kingdom Hearts gaming) BHK - Blue Honor Key (International Order of DeMolay) BHK - Brouwer-Heyting-Kolmogorov BHK - Bukhara, Uzbekistan (Airport Code) cells for both WNV and ITV by using WN-goose-98 and ITV (vaccine strain). In this case, the virus stocks ([10.sup.-4.2] 50% tissue culture infective dose) were diluted 1:400, and virus neutralization titers were checked 3 days later. Viral RNA was extracted from serum samples with the QIAamp RNA blood kit (QIAGEN, Valencia, CA), according to the manufacturer's protocol and resuspended in 30 [micro]l of RNase-free water. The primer pair WN240-Kun848 (respective genome positions 5': 848 and 1,645) was used to synthesize an 800-bp product in the E gene region (8,9). The resulting DNA fragment was visualized on 1.5% agarose gel stained with ethidium bromide. The seroprevalence rate in the first set of virus neutralization assays in Vero cells was 14/20 (70%, with titers ranging from 1:20 to 1:320 [3x1:20, 3x1:40, 3x1:80, 2x1:160, 3x1:320]). No differences were discernible in either the seroprevalence rate or in the average titers of crocodiles from two different breeding farms. In BHK cells, a similar seroprevalence rate was observed, with titers ranging from 1:40 to 1:1,280 (3x1:40, 2x1:80, 1x1:160, 4x1:320, 3x1:640, 1x1:1280). All serum samples, except one, were <1:10 against ITV virus, which had a titer of 1:640 against WNV and 1:10 against ITV. Viremia was not detected in any of the 20 samples in Vero cell culture or by RT-PCR. These results demonstrate a high rate of infection with WNV in crocodiles in Israel. The crocodiles may have been exposed to the virus during the summer at their present location, since no difference in prevalence was seen between the two groups (which differed only in the farm of origin) and since the younger crocodiles had been hatched in the spring of 2002. Furthermore, a cross-reaction with the other prevalent flavivirus in Israel, ITV, was ruled out. Preliminary results from an equine 1. Of, relating to, or characteristic of a horse. 2. Of or belonging to the family Equidae, which includes the horses, asses, and zebras. WNV has been endemic in Israel since the early 1950s (12). More recently, in the summer of 2000, an extensive outbreak occurred, affecting hundreds of people (11), dozens of horses (6), and several flocks of geese (5). However, no deaths of crocodiles were reported. This contrasts with the report from Florida (1), where WNV was isolated from dead alligators, and where hundreds of cases of sudden death had been reported in previous years; these deaths are now suspected to result, at least in part, from WNV disease. The role of various reptile species in the epidemiology of other arboviruses ar·bor·vi·rus (är  b r-)n. such as western equine encephalitis, eastern equine encephalitis, and Venezuelan equine encephalitis is well documented (13-15). At present, the role of reptiles and amphibians in the life cycle and epidemiology of WNV is not known, and further research is necessary. Acknowledgments We thank Kubbi Ofer for assistance in the collection of serum samples from the crocodiles. References (1.) ProMED-mail. Florida: West Nile virus identified in alligators for the first time. ProMED-mail 2002; 14 Nov: 20021114.5797. Available from: URL: http://www.promedmail.org (2.) Travis D, McNamara T, Glaser A, Campbell R. A national surveillance system for WNV in zoological institutions. Available from: URL: http://www.cdc.gov/ncidod/dvbid/westnile/conf/ppt/1a-travis.ppt (3.) Nir Y, Lasowski Y, Avivi A, Goldwasser R. Survey for antibodies to arboviruses in the serum of various animals in Israel during 1965-1966. Am J Trop Med Hyg 1969;18:416-22. (4.) Kostiukov MA, Gordeeva ZE, Bulychev VP, Nemova NV, Daniiarov OA. The lake frog (Rana ridibunda)--one of the food hosts of blood-sucking mosquitoes in Tadzhikistan--a reservoir of the West Nile fever virus. Med Parazitol (Mosk) 1985;3:49-50. (5.) Malkinson M, Banet C, Weisman Y, Pokamunski S, King R, Drouet MT, et al. Introduction of West Nile virus in the Middle East by migrating white storks. Emerg Infect Dis 2002;8:392-7. (6.) Steinman A, Banet C, Sutton GA, Yadin H, Hadar S, Brill A. Clinical description of equine West Nile encephalomyelitis acute disseminated encephalomyelitis inflammation of the brain and spinal cord after infection (especially measles) or, formerly, rabies vaccination. acute necrotizing hemorrhagic encephalomyelitis a rare, fatal postinfection or allergic demyelinating disease of the central nervous system, having a fulminating course; characterized by liquefactive destruction of the white matter and widespread necrosis of blood vessel during the outbreak of 2000 in Israel. Vet Rec 2002; 151:47-9. (7.) Ianconescu M. Turkey meningoencephalitis: a general review. Avian Dis 1976;20:135-8. (8.) Berthet FX, Zeller HG, Drouet MT, Rauzier J, Digoutte JP, Deubel V. Extensive nucleotide changes and deletions within the envelope glycoprotein gene of Euro-African West Nile viruses. J Gen Virol 1997;78:2293-7. (9.) Savage HM, Ceianu C, Nicolescu G, Karabatsos N, Lanciotti RS, Vladimirescu A, et al. Entomologic and avian investigations of an epidemic of West Nile fever in Romania in 1996, with serologic and molecular characterization of a virus isolate from mosquitoes. Am J Trop Med Hyg 1999;61:600-11. (10.) Ministry of the Environment, State of Israel. Available from: URL: http://www.sviva.gov.il (11.) Weinberger M, Pitlik SD, Gandacu D, Lang R, Nassar F, Ben David D, et al. West Nile fever outbreak, Israel, 2000: epidemiologic aspects. Emerg Infect Dis 2001;7:686-91. (12.) Bernkopf H, Levine S, Nerson R. Isolation of West Nile virus in Israel. J Infect Dis 1953;93:207-18. (13.) Bowen G.S. Prolonged western equine encephalitis viremia in the Texas tortoise (Gopherus berlandieri). Am J Trop Med Hyg 1977;26:171-5. (14.) Thomas LA, Eklund CM, Rush WA. Susceptibility of garter snakes (Thamnophis spp.) to western equine encephalomyelitis virus. Proc Soc Exper Biol Med 1958;99:698-700. (15.) Walder R, Suarez OM, Calisher CH. Arbovirus studies in the Guajira region of Venezuela: activities of Eastern equine encephalitis and Venezuelan equine encephalitis viruses during an interepizootic period. Am J Trop Med Hyg 1984;33:699-707. Address for correspondence: Amir Steinman, Koret School of Veterinary Medicine, Hebrew University of Jerusalem, P.O.B. 12, Rehovot 76100, Israel; fax: 972-3-9688539; email: Steinman@agri.huji.ac.il Amir Steinman, * Caroline Banet-Noach, ([dagger]) Shlomit Tal, ([double dagger]) Ohad Levi, * Lubov Simanov, ([dagger]) Shimon Perk, ([dagger]) Mertyn Malkinson, ([double dagger]) and Nahum Shpigel * * Hebrew University of Jerusalem Koret School of Veterinary Medicine, Rehovot, Israel; ([dagger]) Kimron Veterinary Institute, Bet Dagan, Israel; and ([double dagger]) Tel Aviv University Sackler Faculty of Medicine, Tel Aviv, Israel |
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