Access the full text.
Sign up today, get DeepDyve free for 14 days.
S. Workenhe, M. Rise, M. Kibenge, F. Kibenge (2010)
The fight between the teleost fish immune response and aquatic viruses.Molecular immunology, 47 16
A. Duffus, B. Pauli, K. Wozney, C. Brunetti, M. Berrill (2008)
FROG VIRUS 3-LIKE INFECTIONS IN AQUATIC AMPHIBIAN COMMUNITIES, 44
(2009)
Ranavirus phylogeny and differentiation
J. Langdon, J. Humphrey, L. Williams (1988)
Outbreaks of an EHNV‐like iridovirus in cultured rainbow trout, Salmo gairdneri Richardson, in AustraliaJournal of Fish Diseases, 11
J. Langdon, J. Humphrey, L. Williams, A. Hyatt, H. Westbury (1986)
First virus isolation from Australian fish: an iridovirus-like pathogen from redfin perch, Perca fluviatilis L.Journal of Fish Diseases, 9
B. Jensen, A. Ersbøll, E. Ariel (2009)
Susceptibility of pike Esox lucius to a panel of Ranavirus isolates.Diseases of aquatic organisms, 83 3
D. Willis, A. Granoff (1980)
Frog virus 3 DNA is heavily methylated at CpG sequences.Virology, 107 1
Hoverman (2010)
Anuran susceptibilities to ranaviruses: role of species identity, exposure route, and a novel virus isolateDis. Aquat. Org., 89
Chih-tung Tsai, J. Ting, Ming-Hsien Wu, Mingsong Wu, I. Guo, Chi-Yao Chang (2005)
Complete Genome Sequence of the Grouper Iridovirus and Comparison of Genomic Organization with Those of Other IridovirusesJournal of Virology, 79
R. Goorha, K. Murti (1982)
The genome of frog virus 3, an animal DNA virus, is circularly permuted and terminally redundant.Proceedings of the National Academy of Sciences of the United States of America, 79 2
J. Jancovich, M. Brémont, J. Touchman, B. Jacobs (2009)
Evidence for Multiple Recent Host Species Shifts among the Ranaviruses (Family Iridoviridae)Journal of Virology, 84
V. Chinchar, A. Hyatt, T. Miyazaki, Trevor Williams (2009)
Family Iridoviridae: poor viral relations no longer.Current topics in microbiology and immunology, 328
B. Jensen, R. Holopainen, H. Tapiovaara, E. Ariel (2011)
Susceptibility of pike-perch Sander lucioperca to a panel of ranavirus isolatesAquaculture, 313
(2009)
Susceptibility of pike
R. Mazzoni, Albenones Mesquita, L.F.F. Fleury, W. Brito, I. Nunes, J. Robert, H. Morales, A. Coelho, Denise Barthasson, L. Galli, M. Catroxo (2009)
Mass mortality associated with a frog virus 3-like Ranavirus infection in farmed tadpoles Rana catesbeiana from Brazil.Diseases of aquatic organisms, 86 3
Jianguo He, Ling Lü, M. Deng, H. He, S. Weng, X. Wang, Song Zhou, Q. Long, Xunzhang Wang, Siu Chan (2002)
Sequence analysis of the complete genome of an iridovirus isolated from the tiger frog.Virology, 292 2
K. Rafferty (1965)
THE CULTIVATION OF INÇLUSION‐ASSOCIATED VIRUSES FROM LUCKE TUMOR FROGS *Annals of the New York Academy of Sciences, 126
Kai Xu, D. Zhu, Ying Wei, L. Schloegel, Xiao-Feng Chen, Xiao-long Wang (2010)
Broad Distribution of Ranavirus in Free-Ranging Rana dybowskii in Heilongjiang, ChinaEcoHealth, 7
R. Whittington, J. Becker, M. Dennis (2010)
Iridovirus infections in finfish - critical review with emphasis on ranaviruses.Journal of fish diseases, 33 2
J. Jancovich, J. Mao, V. Chinchar, C. Wyatt, S. Case, Sudhir Kumar, G. Valente, Sankar Subramanian, E. Davidson, J. Collins, B. Jacobs (2003)
Genomic sequence of a ranavirus (family Iridoviridae) associated with salamander mortalities in North America.Virology, 316 1
Wen Song, Q. Qin, J. Qiu, C. Huang, Fan Wang, C. Hew (2004)
Functional Genomics Analysis of Singapore Grouper Iridovirus: Complete Sequence Determination and Proteomic AnalysisJournal of Virology, 78
A. Granoff, P. Came, David Breeze (1966)
Viruses and renal carcinoma of Rana pipiens. I. The isolation and properties of virus from normal and tumor tissue.Virology, 29 1
M. Gray, Debra Miller, J. Hoverman (2009)
Ecology and pathology of amphibian ranaviruses.Diseases of aquatic organisms, 87 3
J. Hoverman, M. Gray, Debra Miller
Diseases of Aquatic Organisms Dis Aquat Org Anuran Susceptibilities to Ranaviruses: Role of Species Identity, Exposure Route, and a Novel Virus Isolate
Stefanie Ohlemeyer, R. Holopainen, H. Tapiovaara, Sven Bergmann, Heike Schütze (2011)
Major capsid protein gene sequence analysis of the Santee-Cooper ranaviruses DFV, GV6, and LMBV.Diseases of aquatic organisms, 96 3
F. Gobbo, E. Cappellozza, M. Pastore, G. Bovo (2010)
Susceptibility of black bullhead Ameiurus melas to a panel of ranavirus isolates.Diseases of aquatic organisms, 90 3
Ellen Ariel, Ellen Ariel, B. Jensen, B. Jensen (2009)
Challenge studies of European stocks of redfin perch, Perca fluviatilis L., and rainbow trout, Oncorhynchus mykiss (Walbaum), with epizootic haematopoietic necrosis virus.Journal of fish diseases, 32 12
(1999)
Isolation of an iridovirus-like agent from New Zealand eel
W. Ahne, H. Schlotfeldt, I. Thomsen (1989)
Fish viruses: isolation of an icosahedral cytoplasmic deoxyribovirus from sheatfish (Silurus glanis).Zentralblatt fur Veterinarmedizin. Reihe B. Journal of veterinary medicine. Series B, 36 5
A. Hyatt, A. Gould, Ž. Županović, A. Cunningham, S. Hengstberger, R. Whittington, J. Kattenbelt, B. Coupar (2000)
Comparative studies of piscine and amphibian iridovirusesArchives of Virology, 145
(1993)
Isolamento di un agente virale irido-like da pesce gatto (Ictalurus melas) dallevamento
R. Holopainen, Stefanie Ohlemeyer, Heike Schütze, Sven Bergmann, H. Tapiovaara (2009)
Ranavirus phylogeny and differentiation based on major capsid protein, DNA polymerase and neurofilament triplet H1-like protein genes.Diseases of aquatic organisms, 85 2
Pozet (1992)
Isolation and preliminary characterization of a pathogenic icosahedral deoxyribovirus from the catfish (Ictalurus melas)Dis. Aquat. Org., 14
J. Langdon, J. Humphrey (1987)
Epizootic haematopoietic necrosis, a new viral disease in redfin perch, Perca fluviatilis L., in Australia.Journal of Fish Diseases, 10
(1965)
The cultivation of inclusion-associated
(2003)
Genomic sequence of a rana
V. Chinchar (2002)
Ranaviruses (family Iridoviridae): emerging cold-blooded killersArchives of Virology, 147
R. Speare, J. Smith (1992)
An iridovirus-like agent isolated from the ornate burrowing frog Limnodynastes ornatus in northern Australia
(2011)
Family Iridoviridae. In: Virus taxonomy
R. Hedrick, T. McDowell (1995)
Properties of iridoviruses from ornamental fish.Veterinary research, 26 5-6
I. Marsh, R. Whittington, B. O’Rourke, A. Hyatt, O. Chisholm (2002)
Rapid differentiation of Australian, European and American ranaviruses based on variation in major capsid protein gene sequence.Molecular and cellular probes, 16 2
S. Torrence, D. Green, C. Benson, H. Ip, Loren Smith, S. Mcmurry (2010)
A new ranavirus isolated from Pseudacris clarkii tadpoles in playa wetlands in the southern High Plains, Texas.Journal of aquatic animal health, 22 2
A. Hyatt, M. Williamson, B. Coupar, Deborah Middleton, S. Hengstberger, Allan Gould, P. Selleck, Terry Wise, J. Kattenbelt, Andrew Cunningham, J. Lee (2002)
FIRST IDENTIFICATION OF A RANAVIRUS FROM GREEN PYTHONS (CHONDROPYTHON VIRIDIS), 38
April Johnson, A. Pessier, J. Wellehan, A. Childress, T. Norton, N. Stedman, D. Bloom, W. Belzer, Valorie Titus, R. Wagner, J. Brooks, J. Spratt, E. Jacobson (2008)
RANAVIRUS INFECTION OF FREE-RANGING AND CAPTIVE BOX TURTLES AND TORTOISES IN THE UNITED STATES, 44
D. Willis, R. Goorha, A. Granoff (1984)
DNA methyltransferase induced by frog virus 3Journal of Virology, 49
T. Williams, V. Barbosa-Solomieu, V. Chinchar (2005)
A decade of advances in iridovirus research.Advances in virus research, 65
K. Murti, R. Goorha, A. Granoff (1985)
An unusual replication strategy of an animal iridovirus.Advances in virus research, 30
Wen-Hsiung Chen, Lian-Tien Sun, C. Tsai, Yen-Lin Song, Ching-Fong Chang (2002)
Cold-stress induced the modulation of catecholamines, cortisol, immunoglobulin M, and leukocyte phagocytosis in tilapia.General and comparative endocrinology, 126 1
The current study was undertaken in order to assess the risk that different ranaviruses might impose on European sheatfish aquaculture. As the European sheatfish virus (ESV) is a known pathogen causing losses in European sheatfish aquaculture, it was assumed that closely related exotic ranaviruses might also be able to infect European sheatfish and probably cause disease and mortality in this species. The differential susceptibility of European sheatfish (Silurus glanis) to various ranavirus isolates was assessed at two different temperatures (15°C and 25°C) in a recirculation system. Fish were infected experimentally with a panel of ranavirus isolates including ESV, European catfish virus (ECV), European catfish virus isolate 24 (ECV‐24), Epizootic haematopoietic necrosis virus (EHNV), Rana esculenta virus isolate Italy 282/ I02 (REV), short‐finned eel virus (SERV), Bohle iridovirus (BIV), guppy virus 6 (GV6), doctor fish virus (DFV) and Frog virus 3 (FV3). Significant mortalities were observed, as expected, in fish infected with ESV at 15°C (100%) as well as at 25°C (86/83%). Fish infected with ECV at 15°C showed no clinical signs of disease (8% mortality), whereas those fish infected at 25°C exhibited a cumulative mortality of 54%. Fatal disease was also induced by Italian isolate ECV‐24 at 25°C (81%). Virus isolates ESV, ECV and ECV‐24, generally the most genetically closely related viruses, were successfully isolated from dead fish by cell culture with subsequent identification by polymerase chain reaction (PCR) and sequence analysis. However, no mortality or clinical signs of disease were observed in the groups of sheatfish infected with the other ranaviruses investigated in the study, and none of those viruses were re‐isolated in cell culture or identified by PCR. It was concluded that European sheatfish are susceptible to infection with ESV, ECV and ECV‐24 under laboratory conditions, but not to infection with EHNV, REV, SERV, BIV, GV6, DFV or FV3. For ESV, the incubation period was shorter at 25°C compared to 15°C water temperature, but whereas all fish died after ESV infection at 15°C, some fish survived the infection at 25°C. Futhermore, the very young sheatfish were susceptible to ECV and ECV‐24 at 25°C, whereas there was no significant mortality in the group of older sheatfish challenged with ECV at 15°C. Therefore, the clinical characteristics of the disease seem to depend on the age of the fish as well as on the water temperature.
Journal of Applied Ichthyology – Wiley
Published: Jan 1, 2014
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.