Investigation on susceptibility of the Caspian kutum (Rutilus kutum ) primary caudal fin cells to spring viremia of carp virus

Document Type : Research Paper

Authors

1 M.Sc. Student in Fisheries, Department of Fisheries, Bandar Anzali Branch, Islamic Azad University, Bandar Anzali, Iran

2 Assistant Professor in Department of Fisheries, Bandar Anzali Branch, Islamic Azad University, Bandar Anzali, Iran

3 Assistant Professor in Inland Waters Aquaculture Research Center, Iranian Fisheries Science Research Institute (IFSRI), Agriculture Research, Education and Extension Organization (AREEO), Bandar Anzali, Iran

10.22124/japb.2022.21587.1456

Abstract

In this in vitro study the susceptibility of primary caudal fin cells of Caspian Whitefish (Rutilus kutum)- as the mast commercial endemic fish in the southern Caspian Sea- was examined to the spring viremia of carp virus (SVCV), the acute infectious, hemorrhagic and contagious agent. For this purpose, the primary cell culture was established from the caudal fin of fingerlings, using tissue explant technique and trypsinization of minced tissues. After the propagation of SVCV’s standard strain, the different dilutions of virus, in six replicates, were inoculated to 96-well plates which was contained primary caudal fin monolayer of cells after 5 passages, and the EPC cell line. In order to evaluation of virus characterization, an indirect immunofluorescent antibody test was hired. The clearly observable cytopathic effects and emergence of SVCV antigens as light fluorescence spots in both primary culture of caudal fin cells and the EPC cell line, highly confirmed the susceptibility of caudal fin primary cells to the SVCV.

Keywords

Main Subjects


عبدلی ا. و  نادری م. 1387. تنوع زیستی ماهیان حوضه جنوبی دریای خزر. انتشارات علمی آبزیان. 244ص.
نیک‌قربان س.، حقیقی کارسیدانی س. و قاسمی م. 1398. بررسی شرایط بهینه تهیه کشت سلولی اولیه از کلیه ماهی سفید  (Rutilus kutum) به روش کاشتن. زیست‌شناسی دریا، 11: 90-79.
Abadi Z.T.R., Abtahi B., Grossart H.P. and Khodabandeh S. 2021. Microplastic content of kutum fish, Rutilus frisii kutum in the southern Caspian Sea. Science of The Total Environment, 752: 1–15 (141542).
Agol V.I. 2012. Cytopathic effects: Virus-modulated manifestations of innate immunity? Trends in Microbiology, 20: 570–576.
Ahne W., Bjorklund H., Essbauer S., Fijan N., Kurath G. and Winton J. 2002. Spring viremia of carp (SVC). Diseases of Aquatic Organisms, 52: 261–272.
Ashraf U., Lu Y., Lin L., Yuan J., Wang M. and Liu X. 2016. Spring viraemia of carp virus: Recent advances. Journal of General Virology, 97: 1037–1051.
Avella M., Berhaut J. and Payan P. 1994. Primary culture of gill epithelial cells from the sea bass Dicentrarchus labrax. In Vitro Cellular and Developmental Biology-Animal, 30: 41–49.
Emadi H. 1979. The State of the Fishing and Reproduction of the Kutum, Rutilus frisii kutum, in the Caspian Sea of Iran. Journal of Ichthyology, 19(4): 151–154.
Fazli H. and Parafkandeh Haghighy F. 2016. Spatiotemporal abundance and diversity of bonyfishes in beach seines in Iranian waters of the Caspian Sea. Fisheries Science and Technology, 5: 109–120.
Fazli H., Daryanabard G., Pourgholam R., Abdolmalaki S., Bandani A., Pourgholami A. and Safavi S. 2012. Qualitative assessment of Caspian kutum (Rutilus frisii kutum Kamensky 1901) stocks in Iranian waters of the Caspian Sea (1991-2011). Iranian Scientific Fisheries Journal, 21: 53–64.
Freshney R.I. and Freshney M.G. 2004. Culture of Epithelial Cells. John Wiley and Sons, USA. 441P.
Gardell A.M., Qin Q., Rice R.H., Li J. and Kultz D. 2014. Derivation and osmotolerance characterization of three immortalized tilapia (Oreochromis mossambicus) cell lines. PLoS One, 9: 1–14 (e95919).
Ghasemi M., Zamani H., Hosseini S., Karsidani S.H. and Bergmann S. 2014. Caspian white fish (Rutilus frisii kutum) as a host for spring viraemia of carp virus. Veterinary Microbiology, 170: 408–413.
Hadifar M., Haghighi Karsidani S. and Ghasemi M. 2019. The Primary cell culture from caudal fin tissue of Caspian Kutum (Rutilus frisii kutum). Iranian Scientific Fisheries Journal, 28: 95–104.
Iranian Fisheries Organization, 2019. Annually Statistical Report, Iranian Fisheries Organization, Iran. 64P.
Kennedy M. 2005. Methodology in diagnostic virology. Veterinary Clinics: Exotic Animal Practice, 8: 7–26.
Lakra W., Swaminathan T.R. and Joy K. 2011. Development, characterization, conservation and storage of fish cell lines: A review. Fish Physiology and Biochemistry, 37: 1–20.
Lei C., Yang J., Hu J. and Sun X. 2021. On the calculation of TCID 50 for quantitation of virus infectivity. Virologica Sinica, 36: 141–144.
Lei X.Y., Chen Z.Y., He L.B., Pei C., Yuan X.P. and Zhang Q.Y. 2012. Characterization and virus susceptibility of a skin cell line from red-spotted grouper (Epinephelus akaara). Fish Physiology and Biochemistry, 38: 1175–1182.
Leibovitz A. 1963. The growth and maintenance of tissue-cell cultures in free gas exchange with the atmosphere. American Journal of Hygiene, 78: 173–180.
Pereira H. 1962. The cytopathic effect of animal viruses. Advances in virus research, 8: 245–285.
Petty B.D., Riggs A.C., Klinger R., Yanong R. and Francis-Floyd R. 2002. Spring Viremia of Carp. Fact Sheet VM-142, University of Florida Cooperative Extension Institute of Food and Agricultural Sciences. 4P.
Sobhana K., George K., Venkat Ravi G., Ittoop G. and Paulraj R. 2009. Development of a cell culture system from gill explants of the grouper, Epinephelus malabaricus (Bloch and Shneider). Asian Fisheries Science, 22: 541–547.
Stone  D.M.,  Ahne  W.,  Denham K.L., Dixon P.F., Liu C.T.Y., Sheppard A.M., Taylor G.R. and Way K. 2003. Nucleotide sequence analysis of the glycoprotein gene of putative spring viraemia of carp virus and pike fry rhabdovirus isolates reveals four genogroups. Diseases of Aquatic Organisms, 53(3): 203–210.
Volpato G.L., Goncalves-De-Freitas E. and Fernandes-De-Castilho M. 2007. Insights into the concept of fish welfare. Diseases of Aquatic Organisms, 75: 165–171.
Wang Y., Zhang H., Lu Y., Wang F., Liu L., Liu J. and Liu X. 2017. Comparative transcriptome analysis of zebrafish (Danio rerio) brain and spleen infected with spring viremia of carp virus (SVCV). Fish and Shellfish Immunology, 69: 35–45.
Wolf K. and Ahne W. 1982. Fish cell Culture. Advances in Cell Culture, 2: 305–328.
Yan W., Nie P. and Lu Y. 2011. Establishment, characterization and viral susceptibility of a new cell line derived from goldfish, Carassius auratus (L.), tail fin. Journal of Fish Diseases, 34: 757–768.
Zamani H., Ghasemi M., Hosseini S. and Karsidani S.H. 2014. Experimental susceptibility of Caspian white fish, Rutilus frisii kutum to Spring viraemia of carp virus. Virus Disease, 25: 57–62.
Zeng W., Dong H., Chen X., Bergmann S.M., Yang Y., Wei X., Tong G., Li H., Yu H. and Chen Y. 2022. Establishment and characterization of a permanent heart cell line from largemouth bass Micropterus salmoides and its application to fish virology and immunology. Aquaculture, 547: 1–12 (737427).