Document Type : Research article
Authors
1 Virology Research Unit, Animal Reproduction Research Institute (ARRI), Giza, Egypt.
2 Department of Animal Medicine, Faculty of Veterinary Medicine, Beni-Suef University
Abstract
Keywords
Virology Research Unit,
Animal Reproduction Research Institute (ARRI), Giza, Egypt.
Epidemiological aspect of bovine viral diarrhea virus- II infection
in dairy cattle
(With 2 Figures)
By
Y.G.M. Abd El-Hafeiz; A.M. El-Sherif*
and K.N. Metias*
* Department of Animal Medicine, Faculty of Veterinary Medicine,
Beni-SuefUniversity.
(Received at 11/6/2011)
السمة الوبائية لفيروس اﻹسهال البقرى -2 فى الأبقار الحلوب
ياسر جميل محمود عبد الحفيظ ، أحمد ممدوح الشريف ، کميل نجيب متياس
تهدف هذه الدراسة إلى توصيف الخواص اﻹکلينيکية والفيرولوجية ﻹصابة الأغشية المخاطية والثرمبوسيتوبنک للأبقار الحلوب بفيروس اﻹسهال البقرى. تشتمل خطوات الدراسة على فحص الحيوانات المصابة إکلينيکيا، تجميع عدد 31 عينة سيرم تشمل جميع الأبقار المصابة، 8 عينات لبن من الأبقار المصابة، 8 مسحات مهبلية من الأبقار التى تعانى من نزيف ومن الأبقار المجهضة. تم إستخدام العترة المرجعية العالمية NADL کعترة ممثلة للنوع الوراثى الأول والعترة المحلية Behera-CP 58/99 والتى سبق عزلها وتوصيفها جينيا وأنتيجينيا ممثلة للنوع الوراثى الثانى. تم عزل فيروس اﻹسهال البقرى من جميع المسحات المهبلية (8) ، ومن (5/8 ) من عينات اللبن. جميع المعزولات من النوع الغير سيتوباثولوجى حيث لا يوجد أى تأثير سيتوباثولوجى للفيروس على الخلايا النسيجية المحقونة. بإستخدام الأجسام المناعية الآحادية الخاصة بالنوع الوراثى الثانى والتى تعمل على الجليکوبروتين 53 ، تم الکشف على الفيروس داخل السيتوبلازم بإستخدام إختبار الصبغة الفلورسنتى والأمينوبيروکسيداز. بإستخدام إختبار اﻹليزا، تم الکشف عن الأجسام المناعية المضادة للفيـروس فى جميـع عينـات السيـرم حيث کانت العيارية تتراوح ما بين ≥ 1/128 إلى ≥ 1/512. من ذلک نخلص إلى أن فيروس اﻹسهال البقرى النوع الوراثى الثانى موجود ويصيب العديد من قطعان الأبقار مسببا أعراض مرضية متعددة لذا فمعرفة السمة الوبائية للفيروس على المستوى الجزيئى له أولوية. تحسين الخطط اﻹستراتيجية فى التشخيص والتحکم فى المرض لازمة لتقليل الخسائر الناتجة عن الإصابة بالفيروس.
Summary
The purpose of this study was to characterize the clinical and virologic features of the mucosal and thrombocytopenic BVDV infection in infected dairy cattle. Strategy of examination included clinical examination of diseased animals, serum samples (n=31) represented all diseased cattle, milk samples (n=8) represented clinically diseased cattle and vaginal swabs (n=8) from the hemorrhagic diseased and aborted cattle were tested. An international reference strain (NADL: National Animal Disease Laboratory) and local cytopathic BVDV genotype-II strain (Behera-CP 58/99) were used as positive controls. The virus was isolated from the 8 vaginal swabs and 5 out of the 8 milk samples. All the isolates were ncp that no CPEs were noticed over the 3 passages. By specific BVDV genotype -II monoclonal antibodies (MAbs) against gp53, the viral antigen was identified using Fluorescence isothiocyanate (FITC)-conjugated anti-bovine IgG (specific intra cytoplasmic fluoresce granules) and horseradish peroxidase (HRP)-conjugated anti-bovine IgG (specific intra cytoplasmic brown granules) were detected. By enzyme linked immunosorbant assay (ELISA) technique, all serum samples were positive against the BVDV that had neutralizing antibodies titer ranges from ≥ 1/128 to ≥ 1/512. In conclusion, BVDV type -II do exist in cattle population and the understanding the molecular epidemiology is fundamental. Improved diagnostic and control strategies are essential to reduce losses inflected by BVDVs infection.
Key words: Bovine viral diarrhea virus- II,Epidemiological aspect, isolation, immunohistochemistry.
Introduction
Bovine viral diarrhea virus (BVDV) is a complex pathogen of ruminants. The high prevalence of BVDV in combination with its negative effects on reproduction and the general health condition in affected herds result in significant economic losses to the cattle industry globally (Houe, 2003). The viral pathogenicity is related to its broad tissue tropism in the infected animal, its capacity to elicit damaging host responses, and most probably, an as yet incompletely defined direct mechanism of virulence (Potgieter, 1997; Brock, 2004).
According to the eighth report of the International Committee on Taxonomy of Virus (ICTV), there are two BVDV genotypes, BVDV-1 and BVDV-2, together with border disease (BD) virus, classical swine fever (CSF) virus and Giraffe virus, constituting the genus Pestivirus of the family Flaviviridae (Fauquet, et al., 2005). Bovine viral diarrhea virus strains are recognized as either cytopathic (cp) or noncytopathic (ncp), according to their effect in cell culture (Harding et al., 2002). As the overwhelming majority of BVDV isolates are noncytopathic (90%), infections can easily go unnoticed (Bezek et al., 1994). Cattle persistently infected (PI) with the ncp-BVDV are the main reservoir within the herds and play the most important role in spreading of the disease (Bolin, 1990). There is a predominance of studies showing that the prevalence of PI animals ranges from 0.5% to 2% (Houe, 1999).
Based on genetic and pathogenic properties, the low virulent classical BVDV strains, is present in either genotype and the hyper virulent strains, responsible for the hemorrhagic syndrome, are belong to genotype II (Pellerin et al., 1994; Ridpath and Bolin, 1995). The mechanism of increased virulence with some isolates of BVDV genotype II is currently unknown. However, the ability of BVDV genotype II to cause severe clinical disease and death is due, at least in part, to thrombocytopenia and the resulting hemorrhagic syndrome (Sandvik, 2005).
In Egypt, the sero-prevalence of BVDV infection in the rural localities is 51.8% (Abd El-Hafeiz, et al. 2010). Both genotypes were isolated from the different clinical samples and were characterized genetically and antigenically (Abd El-Hafeiz, 2002, 2005; Abd El-Hafeiz et al. 2009).
The purpose of this study was to characterize the clinical and virologic features of the mucosal and thrombocytopenic BVDV infection in infected cattle.
MaterialS and Methods
BVDV-infection herd-status:
Herd-statuses concerning BVDV-infection were defined based on the physical examination of the herds. Strategy of examination included clinical examination of diseased animals and a possible carry-over effect of BVDV-infection. Pyrexia (rectal temperature 39.4 ºC) was observed in the infected cows with bloody diarrhea for 48 hrs and hemorrhage on the mucosal membrane, reduction of the milk production and abortion within the first 3 months of gestation.
Field samples:
Milk samples (n=8) represented clinically diseased cattle were tested against the BVDV. Milk somatic cells from each milk sample were prepared and purified as described by Radwan et al. (1995). Briefly, 25 ml of each sample was centrifuged at 1000 xg, 4ºC for 15 minutes to pellet the somatic cells. The cell pellet was re-suspended in 15 ml phosphate buffered saline (PBS) and centrifuged at 200 xg, 4ºC for 15 minutes. Second washing of cell pellet was applied in 5 ml PBS and centrifuged at 200 xg, 4ºC for 15 minutes. The supernatant was removed and the purified milk somatic cells (PMSC) were re-suspended in 0.5 ml of PBS and storied at –70 ºC till inoculated on the tissue culture (TC).
Vaginal swabs (n=8) from the hemorrhagic diseased and aborted cattle were collected and transport in transport medium and inoculated on the TC as the standard method.
Serum samples (n=31) were tested against BVDV-antibodies with indirect solid-phase enzyme linked immunosorbant assay (ELISA) techniques.
Virus strain:
An international reference strain (NADL: National Animal Diseases Laboratory) as genotype I was used as positive control on TC. Also, local cytopathic BVDV genotype-II strain (Behera-CP 58/99) that was isolated from the PMSC and identified genetically and antigenically previously (Abd El-Hafeiz, 2002) was used as coating antigen in ELISA technique.
Virus isolation:
The samples were prepared and cultured in Madin Darby bovine kidney (MDBK) cells (tested against latent infection with BVDV and mycoplasma). The inoculated MDBK was cultured with minimum essential medium (MEM; Life Technologies, Grand Island, NY), supplemented with 2% fetal bovine serum (FBS, Biowest, France), penicillin–streptomycin-fungizone as 100 IU, 100 µg and 25 µg per mlmedium respectively (Sigma–Aldrich, St. Louis, MO) and incubated under the standard culture conditions (37 ◦C, 5% CO2 and 85% RH). The inoculated MDBK was daily examined for the cytopathic effects (CPEs) development along 5-7 days for 3 passages (Schweizer and Peterhans,1999).
Immunofluorescence antibody (IFA) technique:
From the 3rd passage and after 48 hrs post inoculation (Po.I.) of the 4th passage, the viral agent was identified using immunofluorescence antibody (IFA) technique as outlined by (Bolin et al., 1991). A specific BVDV type-II monoclonal antibodies (MAbs) against gp53 and Fluorescence isothiocyanate (FITC) conjugated anti bovine IgG (VMRD, INC. Pullman, WA, USA) were used to identify the positive samples that examined by an inverted epifluorescence phase-contrast trinuclear microscope (Nikon ECLIPSE-TS100, Japan) with 20X plan a chromatic lens and a digital camera DS-U2 with NIS elements software.
Immunoperoxidase technique:
As discussed briefly in (Abd El-Hafeiz et al., 2011), cultured MDBK cells on coverslips and 48 hrs Po.I. of samples from the 3rd passage, the inoculated samples were tested against the viral antigen using the specific BVDV type -II MAbs against gp53 (VMRD, INC. Pullman, WA, USA) and horseradish peroxidase (HRP) conjugated anti-bovine IgG (Bethyl laboratories, INC, Germany) at the recommended concentration (1/103)in PBS pH 7.2. The chromogen, Diaminobenzidine tetrahydrocloride (DAB), was prepared as 5 mg of DAB in 10 ml of 0.05 M Tris-HCl pH 7.4 (6.1 gm Tris-base, 50 ml deionized water and 37 ml of 1N HCl) and filtered through filter paper before addition of 150 µl of freshly prepared 3% H2O2. To each well, 100 µl of chromogen was added and incubated at room temperature for 5 minutes before washing the coverslips thoroughly by distilled water and examined using an inverted epifluorescence phase-contrast trinuclear microscope (Nikon ECLIPSE-TS100, Japan) with 10 X plan a chromatic lens and a digital camera DS-U2 with NIS elements software.
Indirect enzyme linked immunosorbant assay (ELISA):
By using the concentrated and purified local cytopathic BVDV genotype-II strain (Behera-CP 58/99) as described by Chu and Zee (1984); Kelling et al. (1990) and at antigen concentration 11.2 µg per well, the ELISA test was done that described briefly by Crowther, (2001).
Results
Physical finding:
Nine of the cattle met the criteria for euthanasia during the study period. In the infected herds, appetite remained normal, but diarrhea, characterized by blood and mucosal casts, was a consistent finding in all infected cases. Pyrexia (rectal temperature 39.4 ºC), hemorrhage with erosion on mucosal membrane and abortions within the first 3 months of gestation were finding. In post mortem of dead cattle, severe hemorrhage on the internal organs specially the digestive tract with depletion of the lymph nodes.
Virologic and serological findings:
BVDV was isolated from the 8 vaginal swabs and 5 out of the 8 milk samples. All the isolates were ncp that no CPEs were noticed over the 3 passages. By specific BVDV type -II MAbs against gp53, the viral antigen was identified using FITC-conjugated anti-bovine IgG (specific intra cytoplasmic fluoresce granules, Figure 1) and HRP-conjugated anti-bovine IgG (specific intra cytoplasmic brown granules, Figure 2) were detected.
By ELISA technique, all serum samples were positive against the BVDV that had neutralizing antibodies titer ranges from ≥ 1/128 to ≥ 1/512.
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Discussion
Infections with BVDV are endemic in cattle populations in most parts of the world. BVDV-seropositive cattle are allegedly virus free (Houe, 1995). Although bovine viral diarrhea (BVD) can be suspected from the clinical signs, the wide range in both diversity and severity makes them at best unreliable for diagnostic investigations.
Outbreaks of severe, peracute disease in adult cattle and calves were reported in 1993 and 1995, for the first time in the United States and Canada, respectively (Pellerin et al., 1994; Drake et al., 1994; Carman et al., 1998). These outbreaks, which involved beef, dairy and veal operations, were characterized by fever, diarrhea, abortion, leukopenia, thrombocytopenia, and death. Thrombocytopenia, regardless of the underlying etiology, results from only 3 basic mechanisms: decreased production, accelerated destruction, or abnormal sequestration of platelets (Warkentin and Kelton, 1994). The underlying mechanisms are complex, multifactorial, and incompletely understood.
Diagnostic assays that can be scaled up for testing of large number of samples are needed. They need to be as sensitive and specific as possible, but since no test is able to operate at 100% for both parameters, a choice of a deliberate trade-off in either sensitivity or specificity is a more realistic option, and then combined with a different set of back-up assays (Sandvik, 2005).
Except for in special cases, infectious virus is investigated by inoculation of bovine cell cultures. Several virus isolation (VI) protocols have been developed, using different cell culture formats, periods of incubation and serial passage of the inoculum, to meet the demands for different purposes. Virus isolation is an essential back-up and reference test for other indirect methods for identification of BVDV, and should be available to all laboratories using other tests to detect the BVDV indirectly (Sandvik, 2005). Since most field isolates of BVDV are ncp, the inoculated cells are routinely fixed after 3–5 days of the 2-3rd passage on TC and examined for presence of BVDV antigens either by immunofluorescence or immunoperoxidase staining (Anonymous, 2004). Here, BVDV was isolated from the 8 vaginal swabs and 5 out of the 8 milk samples. All the isolates were ncp that no CPEs were noticed over the 3 passages. By specific BVDV type -II MAbs against gp53, the viral antigen was identified using FITC-conjugated anti-bovine IgG (specific intra cytoplasmic fluoresce granules, Figure 1) and HRP-conjugated anti-bovine IgG (specific intra cytoplasmic brown granules, Figure 2) were detected.
For testing of large series of serum samples, ELISAs have many advantages. They are independent of cell cultures and challenge viruses, give a test result within a few hours, are relatively inexpensive both to establish and run, and are suitable for automation. In principle, three kinds of antigen can be used, which each influence the diagnostic properties of the assay. In the indirect ELISAs, BVDV harvested from infected cell cultures is used, which allows viral nonstructural proteins to be included. Thus, the antibodies assayed will be against the full spectrum of immunogenic proteins encoded by the virus (Beaudeau et al., 2001). In this format, viral antigen is immobilized on the solid phase, onto which specific antibodies and subsequently detecting enzyme-conjugated antiglobulins bind. A positive reaction is recognized by color development in the substrate solution, which is read optically and reported as optical density (OD) values (Tijssen, 1985; Schrijver and Kramps, 1998). In this study, all serum samples were positive against the BVDV that had neutralizing antibodies titer ranges from ≥ 1/128 to ≥ 1/512.
In conclusion, BVDV type -II do exist in cattle population and the understanding the molecular epidemiology is fundamental. Improved diagnostic and control strategies are essential to reduce losses inflected by BVDVs infection.
References
Abd El-Hafeiz, Y.G.M. (2002): Bovine viral diarrhea virus (BVDV): Molecular-based diagnostic approach and isolation of cytopathic and non cytopathic strains genotype 11 from cow milk.” Thesis (Ph.D.), Vet. Virol., Fac.Vet. Med., CairoUniv.
Abd El-Hafeiz, Y.G.M. (2005): Genotyping the Egyptian isolates of bovine viral diarrhea virus from milk using restriction endonuclease enzyme-Pst1. Assiut Vet. Med. J. 51 (105): 336-345.
Abd El-Hafeiz, Y.G.M.; Abd El Hafez, S.M. and Hassan, H.M. (2009): Molecular characterization of the isolated strains of bovine viral diarrhea virus. Global Veterinaria, 3 (5): 383-389.
Abd El-Hafeiz, Y.G.M.; Abou Gazia, K.A.A. and Ibrahim, I.G.A. (2010): Sero-prevalence of bovine herpesvirus-1 and bovine viral diarrhea virus infection in Egypt and their relation to brucellosis. Global Veterinaria, 4 (1): 1-5.
Abd El-Hafeiz, Y.G.M.; Badr, M.R. and Azab, A.S. (2011): Immunohistochemical detection of anti-BVDV in follicular fluid of she camel with respect the effect of infection on in vitro embryos production and pathological structure of the ovary. Internat. J. Microbiol. Res. 2 (1): 61-68.
Anonymous, (2004): Manual of Diagnostic Tests and Vaccines for Terrestrial Animals, fifth ed. Office International des Epizooties, Paris. Available at
Beaudeau, F.; Belloc, C.; Seegers, H.; Assie, S.; Sellal, E. and Joly, A. (2001): Evaluation of a blocking ELISA for the detection of bovine viral diarrhea virus (BVDV) antibodies in serum and milk, Vet. Microbiol. 80: 329–337.
Bezek, D.M.; Grohn, Y.T. and Dubovi, E.J. (1994): Effect of acute infection with noncytopathic or cytopathic bovine viral diarrhea virus isolates on bovine platelets, Am. J. Vet. Res. 55: 1115–1119.
Bolin, S.R. (1990): Control of bovine virus diarrhea virus, Rev. Sci. Technol. 9: 163–171.
Bolin, S.R.; Matthews, P.J. and Ridpath, J.F. (1991): Methods for detection and frequency of contamination of fetal calf serum with bovine viral diarrhea virus and antibodies against bovine viral diarrhea virus. J. Vet. Diagn. Invest. 3: 199-203.
Brock, K.V. (2004): Strategies for the control and prevention of bovine viral diarrhea virus. Vet. Clin. North Am. Food Anim. Pract. 20 (1): 171–180.
Chu, H.-J. and Zee, Y.C. (1984): Morphology of bovine viral diarrhea virus. Am. J. Vet. Res. 45: 845-850.
Crowther, J.R. (2001): The ELISA Guidebook, series II. In: Walker, J.M (ed), methods in molecular biology (Totowa, NJ); V. 149. ISBN 0-89603-728-2, USA.
Carman, S.; Van Dreumel, T.; Ridpath, J.; et al. (1998): Severe acute bovine viral diarrhea in Ontario, 1993–1995. J. Vet. Diagn. Invest. 10: 27–35.
Drake, T.R.; Moore, D.A.; Whitlock, R.H.; et al. (1994): An outbreak of peracute BVD in Pennsylvania cattle. 37th Annu. Meet. Am. Assoc. Vet. Lab. Diagn. 37: 20.
Fauquet, M.; Mayo, A.; Maniloff, J.; Desselberger, U. and Ball, L.A. (2005): 8th Report of the international committee on taxonomy of viruses. Elsevier. In: Virus taxonomy classification and nomenclature of viruses. pp. 1259.
Harding, M.J.; Cao, X.; Shams, H.; Johnson, A.F.; Vassilev, V.B.; Gil, L.H.; Wheeler, D.W.; Haines, D.; Sibert, G.J.; Nelson, L.D.; Campos, M. and Donis, R.O. (2002): Role of bovine viral diarrhea virus biotype in the establishment of fetal infections, Am. J. Vet. Res. 63: 1455–1463.
Houe, H. (1995): Epidemiology of bovine viral diarrhea virus. Vet. Clin. North Am. Food Anim. Pract. 11: 521–547.
Houe, H. (1999): Epidemiological features and economical importance of bovine virus diarrhea virus (BVDV) infections. Vet. Microbiol. 64: 89–107.
Houe, H. (2003): Economic impact of BVDV infection in dairies. Biological, 31: 137–143.
Kelling, C.L.; Kennedy, J.E.; Stine, L.C.; Rump, K.K.; Paul, P.S. and Partridge, J.E. (1990): Genetic comparison of ovine and bovine pestiviruses. Am. J. Vet. Res. 51: 2019-2024.
Pellerin, C.; Van den Hurk, J.; Lecomte, J. and Tijssen, P. (1994): Identification of a new group of bovine viral diarrhea virus strains associated with severe outbreaks and high mortalities. Virol. 203: 260–268.
Potgieter, L.N. (1997): Bovine respiratory tract disease caused by bovine viral diarrhea virus, Vet. Clin. North Am. Food Anim. Pract. 13 (3): 471–481.
Radwan, G.S.; Brock, K.V.; Hogan, J.S. and Smith, K.L. (1995): Development of a PCR amplification assay as a screening test using bulk milk samples for identifying dairy herds infected with bovine viral diarrhea virus. Vet. Microbiol. 44: 77-92.
Ridpath, J.C. and Bolin, S.R. (1995): The genomic sequence of a virulent bovine viral diarrhea virus (BVDV) from the genotype 2: detection of a large genomic insertion in a noncytopathic BVDV. Virol. 212: 39-46.
Sandvik, T. (2005): Selection and use of laboratory diagnostic assays in BVD control programs. Prev. Vet. Med. 72 (1-2): 3-16.
Schrijver, R.S. and Kramps, J.A. (1998): Critical factors affecting the diagnostic reliability of enzyme-linked immunosorbent assay formats, Rev. Sci. Tech. 17: 550–561.
Schweizer, M. and Peterhans, E. (1999): Oxidative stress in cells infected with bovine viral diarrhea virus: a crucial step in the induction of apoptosis. J. Gen. Virol. 80: 1147 -1155.
Tijssen, P. (1985): Laboratory techniques in biochemistry and molecular biology: Practice and theory of enzyme immunoassay, Elsevier, Amsterdam. ISBN 0-444-80633-4.
Warkentin, T.E. and Kelton, J.G. (1994): Management of thrombocytopenia. In:Thrombosis and hemostasis: basic principles and clinical practice, (ed). Colman, R.W.; Hirsh, J.; Marder, V.J. and Salzman, E.W., 3rd ed., p. 469. J. B. Lippincott Co., Philadelphia, PA.
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