Document Type : Research article
Authors
1 Dept. of Virology, Animal Health Research Institute, Dokki, Giza
2 Dept. of Virology, Animal Health Research Institute, Dokki, Giza.
3 Dept. of Biotechnology, Animal Health Research Institute, Dokki, Giza.
4 Animal Reproduction Institute
Abstract
Keywords
Dept. of Virology,
Animal Health Research Institute, Dokki, Giza.
ANTIGENIC AND MOLECULAR IDENTIFICATION OF SOME VIRUSES CAUSING RESPIRATORY DISORDER IN CALVES
(With 4 Tables and 4 Photos)
By
Nahed A. Mahmoud; Omayma A. Shemies; Jehan A. Gafer*and Hanaa A.M. Ghoniem**
* Dept. of Biotechnology, Animal Health Research Institute, Dokki, Giza.
** Animal Reproduction Institute.
(Received at 12/3/2009)
التعريف الأنجينى والجزيئى لبعض الفيروسات المسببة للاعراض التنفسية
فى العجول
ناهد أحمد محمود ، أميمة عبد العزيز شميس ، جيهان عبد الله جعفر ،
هناء عبد العزيز غنيم
يعتبر فيروس البارا-انفلونزا-3 البقرى والفيروس التنفسى المتضخم البقرى من الفيروسات المنتشرة انتشارا کبيرا بين الابقار وتتسبب فى احداث مشاکل تنفسية جسيمة ونظرا لان تلک الفيروسات تکون دائما متشابهة الاعراض فان الحاجة الى التشخيص المعملى الدقيق والسريع اصبحت ملحة. لذلک تم تجميع عدد 18 عينة من عجول عليها اعراض تنفسية (عدد 11 عينة مسحات انفية وعدد 7 عينات من نسيج رئوى) من احدى المزارع بمحافظة کفر الشيخ. تم فحص هذه العينات للکشف عن فيروس البارا-انفلونزا-3 باستخدام اختبار ادمصاص الدم واختبار الفلورسنت المناعى المشع وايضا تم الکشف عن الفيروس التنفسى المتضخم فى نفس العينات باستخدام اختبار الفلورسنت المناعى المشع واختبار الاليزا. تم استخدام اختبار الاستنساخ العکسى لاختبار تفاعل انزيم البلمرة المتسلسل للتاکد من وجود کل من الفيروسين فى العينات. اظهلرت النتائج وجود فيروس البارا-انفلونزا-3 فى 17 عينة بنسبة 94,4% باستخدام اختبار الاستنساخ العکسى لاختبار تفاعل انزيم البلمرة المتسلسل مقابل13 عينة ايجابية بنسبة 72,2% باستخدام اختبار الفلورسنت المناعى. وکذلک بالنسبة للفيروس التنفسى المتضخم تم التاکد من وجوده باستخدام اختبار الاستنساخ العکسى لاختبار تفاعل انزيم البلمرة المتسلسل فى 16 عينة بنسبة 88,9% مقابل 14 عينة بنسبة 77,8% باستخدام اختبار الاليزا. ونظرا للحساسية العالية لاختبار الاستنساخ العکسى لاختبار تفاعل انزيم البلمرة المتسلسل التى اثبتت من النتائج السابقة يوصى باستخدام ذلک الاختبار کطريقة مثلى لتشخيص فيروسى البارا-انفلونزا-3 والفيروس التنفسى المتضخم.
SUMMARY
Bovine parainfluenza virus Type 3 (BPI3) and bovine respiratory syncytial virus (BRSV), are ubiquitous respiratory pathogens of cattle, which contribute to causation of bovine respiratory disease complex. As these respiratory viral pathogens cause very similar clinical signs, laboratory diagnosis of these pathogens becomes important. A total of 18 respiratory samples (11 nasal swab samples collected from diseased calves and 7 lung tissue specimens from dead calves) were collected from a farm in Kafer El-Sheikh Governorate. All specimens were analyzed for BPI-3 by heamadsorption and direct immunofluorescent techniques. The same samples were investigated for the presence of BRSV using indirect fluorescent antibody technique and ELISA. RT-PCR technique was used to confirm the presence of both viruses. BPI-3 virus was detected by RT-PCR assay in 17 of 18 (94.4%) samples tested versus to 13 of 18 (72.2%) were detected by FAT. Also, BRSV was detected by RT-PCR in 16 of 18 (88.9%) specimens tested versus to 14 of 18 (77.8%) were detected by ELISA technique. Considering the higher sensitivity of RT-PCR assay that revealed from previous data, it can be recommended as the method of choice in diagnosis of both BPI-3 and BRSV.
Key words: Calves, bovine parainfluenza, respiratory diseases.
Introduction
Respiratory diseases have had a major impact on the overall health of cattle and continue to be of great importance even today. Many of the diseases that have been shown to impact the respiratory tract of cattle have been grouped into an overall category known as bovine respiratory disease (BRD) complex. This includes shipping fever syndrome, enzootic calf pneumonia, acute respiratory distress syndrome, and atypical interstitial pneumonia (Baker 1995; Ames 1997; Apley 2006; Bolte, et al., 2009).These diseases are considered the major cause of economic losses in cattle, sheep and goat industry (Zaki, et al., 2000; Ellis, 2001). Pathogens that have been implicated in the causation of this complex include microbial and viral pathogens. In terms of microbial pathogens, the most common are Pasteurella species (Apley, 2006). Studies have shown that the major viral pathogens that contribute to BRD are: bovine parainfluenza – 3 virus (BPI-3), and bovine respiratory syncytial virus (BRSV) (Lehmkuhl and Gough, 1977; Gagea, et al., 2006). These pathogens, along with stress and other environmental factors, have been shown to have a synergistic effect on each other so that the severity of the disease is worse with concurrent infections than with an individual pathogen (Brodersen and Kelling 1998; Godinho, et al., 2007).In addition, viral pathogens have been show to weaken the host’s immune response making the host more susceptible to opportunistic pathogens (Potgieter, 1995). BPI-3 is one of the most important agents associated with upper respiratory disease of cattle allover the world. The uncomplicated respiratory infection caused by PI-3 virus run a benign clinical course of 3-4 days with complete recovery. However, the true importance of the infection in cattle drives from its role in endemic pneumonia.
The term parainfluenza virus was originally coined because some of disease symptoms are influenza-like and because the virus particle, like that of influenza in having haemagglutination and neuraminidase activities (Field, et al., 1996). BPI-3 was originally isolated from cattle with shipping fever (SF) and designated as SF4 (Reisinger, et al., 1959). Since then BPI-3 virus was incriminated in many respiratory disorders, in calves and other animal species (Kite, et al., 1994; Steinhagen and Hubent, 1995).In Egypt BPI-3 virus was recorded by Hamdy, 1966; Atta and Singh 1967; Baz, et al., 1986).
Parainfluenza-3 virusbelongs to genus Respirovirus in the family Paramyxoviridea of order Mononegavirals, the non segmented negative single stranded RNA viruses(Pringle, 1991). The genomic RNA has approximately 15,462 nucleotides and composed of six genes (Field, et al.., 1996).
Bovine respiratory syncytial virus (BRSV) can cause severe lower respiratory tract infection in cattle. Clinical disease occur most often in young calves but adult cattle can develop severe disease as well (Schrijver, et al., 1997).
RSV was named for the characteristic merging of cells it causes, which forms multinucleated masses of protoplasm called syncytial (Baker and Frey, 1985; Zeidan, et al., 2000). BRSV was 1st isolated from cattle with respiratory disease in Switzerland in 1970 by Paccaud and Jacquier, 1970and was reported in 1974 from cattle in United States (LeBlanc, et al., 1991).The first isolation in Egypt from cattle was conducted by Saber, et al., 1996.Seroepidemiologic surveys forantibodies to BRSV have indicated that the virus is wide spread, seropositivity up to 80% (Collins, et al., 1988; Bastawecy, et al., 2002). BRSV is a single- stranded negative-sense RNA virus which belongs to the Pneumovirus genus, a member of the paramyxoviridae family. Its genome has approximately 15,140 nucleotides. The viral genome is transcribed into 10 subgenomic mRNAs which encode for 11 different proteins(Huang and Wertez, 1982; Arns, et al., 2003).
Although there is a large list of pathogens that contribute to BRD, the clinical signs of infection are very similar. Typical signs include rapid respiration, anorexia, nasal and /or ocular discharge, depression, fever, interstitial pneumonia and reproductive failure (Brock 2004; Solis-Calderon, et al., 2005; Apley 2006). Because of the similarities in clinical presentation, so the aim of the current study is to develop methods for quick and accurate diagnosis of the cause of infection.
Materials and Methods
Samples:
A total of 11 nasal swab samples were collected from diseased calves suffering from respiratory manifestation and 7 lung tissues were collected from dead calves on a farm in Kafer El-Sheikh Governorate.
Cells: MDBK cell (Madien Derby Bovine kidney) obtained from Virology Department, Animal Health Research Institute, Dokki Cairo used for blind passages of the samples
Viruses:
- Local Egyptian BPI-3 virus strain45 of a titer 106.2 TCID50/ml was kindly supplied from Rinder Pest like disease Department at Veterinary Serum and Vaccine Production Institute, Abbassia, Cairo
- Local Egyptian strain of BRSV was supplied by Animal Health Research Institute Dokki, Cairo. The virus titer 105.8 TCID50/ml. Each virus was calculated according to Reed and Muench (1938).
Antisera:
Locally prepared in rabbit in Virology Department Animal Health Research Institute according to Grist (1979).
Conjugates:
Anti rabbit FITC conjugate was supplied by Sigma immunochemical used in indirect FAT.
- Rabbit antibovine Horse raddish peroxidase diluted at 1:1000 in diluting buffer used in ELISA.
- Standard anti bovine PI-3 serum conjugated with FITC used in direct FAT.
Identification of BPI-3 virus using heamadsorption: The test was applied according to Elizabeth, et al. (1997)on infected MDBK cell and examined under inverted microscope.
Fluorescent antibody technique for detection of BPI-3 & BRSV: The test was conducted according to Coons (1956)using frozen cryostat section from the seven diseased lung tissue samples at 5-8u and for samples inoculated on MDBK in order to detect viral antigen of BPI-3by direct FAT according to Vander Hide (1971)and indirect FAT used for detection of the BRSV was applied according to Vilcek, et al. (1994).
Solid phase ELISA for detection of BRSV: The test was conducted according to Voller, et al. (1979)the calculation and determination of cut off value were according to Peterfy, et al. (1983).
Reverse transcriptase polymerase chain reaction (RT-PCR):
Nine positive BPI-3 and BRSV nasal swab samples as well as the 5 positive BPI-3 and 4 positive BRSV of lung tissue samples were pooled independently for each virus to be identified using RT-PCR. The negative specimens (5 samples for BPI-3 & 4 samples for RSV) were also investigated independently by RT-PCR technique for confirmation.
RNA extraction:
The viral RNAs were extracted according to Chomczynski and Sacchi (1987)using acid guanidinium thiocyanate-phenol-chloroform extraction. The RNAs were precipitated in isopropanol and the pellet washed in cold ethanol and centrifuged, then the pellet was air dried and redissolved in 50ul diethylpyrocarbonated-treated water (DEPC) (Sigma). The samples (1ul) of these total RNAs were reverse transcribed and the resulting cDNA were used as templets for PCR reactions using specific oligonucleotide primers listed in Table (1). The oligonucleotide primers were designed according to the published sequence of BPI-3 by Lyon, et al. (1997)and the published sequence of BRSV by Van der poel, et al. (1997). The primers define a 400bp and 204bp segments of BPI-3 and BRSV genomes respectively in the regions encoding the fusion (F)-protein.
Table 1: Primers used in RT- PCR reactions of BPI-3 and BRSV
Target |
Name (strand) |
Primer sequence |
BPI-3 |
PS1873 (F) PAS2273 (R) |
5'-CATTGAATTCATACTCAGCAC-3' 5'-AGATTGTCGCATTT(AG)CCTC-3' |
BRSV |
(P751) (F) (P752) (R) |
5'-GTGCATTAAGAACTGGATGG-3' 5'-GCAAAAAGAGGGATACCAGAGT-3' |
PCR amplification:
Briefly, the templates and primers were mixed with Taq polymerase in a volume of 50ul of amplification buffer. The RT-PCR reaction was performed in a programmable DNA thermal cycler according to the cycling protocols listed in Table (2).
Table 2: Cycling protocols for amplification of F gene of both BPI-3 and BRSV
Target |
Amplicon size |
Cycling condition |
No. of cycle |
||
BPI-3 F gene |
400 bp |
Step |
Temp. |
Time |
|
Initial denaturation |
94˚C |
2 min. |
1 cycle |
||
Denaturation |
94˚C |
45 sec. |
35 cycles |
||
Annealing |
51˚C |
45 sec. |
|||
Extension |
72˚C |
1 min. |
|||
RSV F gene |
204 bp |
Denaturation |
94˚C |
1 min. |
38 cycles |
Annealing |
58˚C |
1 min. |
|||
Extension |
72˚C |
1 min. |
Analysis of PCR products using agar gel electrophoresis:
The analysis were carried out according to Sambrook, et al. (1989).Briefly 10ul of each PCR product was loaded on agarose gel (1.5% for PI-3 and 1% for RSV), containing 1ul/ml ethidium bromide in Tris-acetate buffer. Positive control viruses as well as DNA-Marker Ladder were also included.
Results
The collected samples propagated on MDBK cell. Results of heamadsorption are shown in Photo (1-A). It demonstrates number of G. pig RBCs adsorbed on the surface of monolayer of infected MDBK cell while there is no RBCs adsorbed on the sheet of normal non infected cells Photo (1-B). The results were positive in 12 of 18 (66.7%) specimens tested as shown in Table (3).
Direct FAT used for detection of BPI-3 virus revealed observed intracytoplasmic fluorescence in 13 out of 18 (72.2%) tested slides of infected MDBK cell as shown in Photo (2-A).Also the indirect FAT used for detection of BRSV revealed positive fluorescence in 11 of 18 (61.1%) tested slides as shown in Photo (2-B). The ELISA technique detected a higher percentage of BRSV positive samples (77.8%) than the FAT did. The detailed data are shown in Tables (3&4).
The immunofluorescence test performed on sections of the lung tissue of seven dead animals revealed 4 positive lung tissue samples of either BPI-3 or BRSV.
Detection of BPI-3 and BRSV using RT-PCR are shown in photo 3 and 4 respectively.
The detection of BPI-3 or BRSV by different used methods are presented in Tables (3 & 4)
Table 3: The detection of BPI-3 by different used methods
Type of sample |
No. of sample |
Diagnostic method of used |
|||||
Heamadsorption |
FAT |
RT-PCR |
|||||
No. of +ve |
No. of -ve |
No. of +ve |
No. of -ve |
No. of +ve |
No. of -ve |
||
Nasal swabs |
11 |
8 |
3 |
9 |
2 |
10 |
1 |
Lung tissues |
7 |
4 |
3 |
4 |
3 |
7 |
0 |
Total |
18 |
12 |
6 |
13 |
5 |
17 |
1 |
% |
|
66.7% |
33.3% |
72.2% |
27.8% |
94.4% |
5.6% |
Table 4: The detection of BRSV by different used methods
Type of samples |
No. of samples |
Diagnostic method of used |
|||||
FAT |
ELISA |
RT-PCR |
|||||
No. of +ve |
No. of -ve |
No. of +ve |
No. of -ve |
No. of +ve |
No. of -ve |
||
Nasal swabs |
11 |
7 |
4 |
9 |
2 |
9 |
2 |
Lung tissues |
7 |
4 |
3 |
5 |
2 |
7 |
0 |
Total |
18 |
11 |
7 |
14 |
4 |
16 |
2 |
% |
|
61.1% |
38.9% |
77.8% |
22.2% |
88.9% |
11.1% |
|
||
Photo (1-A) +ve heamadsorption |
Photo (1-B) normal MDBK cell |
Photo (2-A) Shows observed intracytoplasmic fluorescence of PI-3V |
Photo (2-B) Shows intracytoplasmic fluorescence with some syncytia of BRSV |
Photo 3: Shows ethidium bromide stained 1.5% agarose gel electrophoresis of PCR product of BPI-3 virus. Lane M: 1KB DNA ladder. Lane 1: control +ve. Lane 2&3: +ve samples from N.S & lung tissue Lane 4 to 8: five –ve samples that even could not detected by FAT.
Photo 4: Shows ethidium bromide stained 1% agarose gel electrophoresis of PCR product of BRSV. Lane M: 100bp DNA ladder. Lane 1: control +ve. Lane 2 &3: +ve samples from N.S & lung tissue Lane 4 to 7: the four –ve samples that even could not detected by ELISA.
Discussion
World wide, many preceeding studies have demonstrated a negative impact of bovine respiratory disease complex on cattle industry. Recently, BRSV has been reported to be responsible for 14 to 71% of the respiratory diseases (Ames, 1997). This virus is responsible for a high morbidity (60 to 80%) and a mortality that can reach 20%. However, BPI-3 infections cause less serious disease than BRSV (Verhoeff and van Nieuwstadt, 1984)which has a worldwide distribution and high serum antibody prevalence in adult animals (Bryson, 1990).Althoughthe role of PIV-3 remains ambiguous as it seems, in some cases, responsible of respiratory signs but in other it is clinically unapparent or causes only mild disease (Graham et al., 1999) it nevertheless significantly correlated with respiratory diseases in cattle (Stott et al., 1980). The virus is thought to have a predisposing role in shipping fever and enzootic pneumonia. The predisposing role of BPIV-3 in bovine respiratory diseases is probably correlated to its immunosuppressive effects. (Adair et al., 2000).
Because of the similarities in clinical presentation, it is important to develop methods for quickly and accurately differentiation of the cause of infection. Therefore, our article planed to fulfill towards the application of some of antigenic and molecular methods with special reference to RT-PCR technique for identification of these two viruses.
Immunoflurescence (IF) test Performed in this work on sections of lung provide a rapid diagnosis for both BPI-3 virus and BRSV, but its limitation are obvious when dealing with epizootics of respiratory disease with low mortality (Kimman, et al., 1986).As well the specimen integrity and the number of intact cells present in sample may be crucial for a reliable direct immunofluorescent assay (Reina, et al., 1995). Also this direct antigen testing often lacks sensitivity and require confirmation by indirect antigen testing following specimen culture (Fan and Henrickson, 1996) for this reason we propagated all samples on tissue culture for three blind passages and detected by FAT the results revealed that the percentages of positive samples were (61.1%) and (72.2%)for BRSV and PI-3 virus, respectively. These results agree with previous results of (Vilcek, et al., 1994).
Virus isolation was not attempted, since it is not considered to be a practical diagnostic method of choice (Vilcek, et al., 1994)as the viral isolation is complicated by the high sensitivity of the agent and the fact that several passages are necessary before CPE develops (Valentova and kovarcik, 2003).Alsothe isolation is a laborious procedure with unpredictable results because animal that develop the disease are not the best of choice as in most cases of BRSV or BPI-3 is obtained during isolation procedures for other viral pathogens rather than procedure specifically carried out for those viruses (Arns, et al., 2003). Moreover, tissue samples containing high concentrations of those viral antigens frequently do not reproduce the virus in cell cultures (Dubovi, 1993).
BPI-3 virus was detected in 12 of 18 (66.7%) samples tested by haemadsorption technique on infected MDBK cell culture. The test considered good indicator system for the presence of BPI-3 virus beside it proved to be more rapid and sensitive than waiting till the cytopathic change appearance. This finding is similar to that described previously by St.George, (1969).Also, this, agreed with the results of Toth and Jankura (1990)who diagnosed BPI-3 by both heamadsorption technique and immunofluorescence where both techniques match with each other for demonstration of PI-3 virus in cell culture however the haemadsorption offers several advantages over fluorescent antibody technique as it is more easy to read and does not require especial equipment for observation.
BRSV was detected in 14 out of 18 (77.8%) total specimens' analyzed using ELISA technique this results agreed with previous results of West, et al. (1998) Graham, et al. (1999) Hazari, et al. (2002). They concluded that ELISA techniquehas been shown to be an invaluable test for determining the presence of BRSV in clinical samples. ELISA has been shown to be highly sensitive, specific, rapid, Alternative methods such as virus isolation and immunohistochemistry are time-consuming and laborious and results may be difficult to interpret whereas ELISA technology lends itself to large-scale testing of a greater number of samples (Hill, et al., 2007). However, it requires use of viral protein specific antibodies for detection.
Molecular methods for the diagnosis of viral infection are now well established in routine virology laboratory and have replaced conventional techniques, such as viral isolation by cell culturing or detection of a virus-specific antibody response, approaches which, in comparison, are slow or lack sensitivity.(Kalvatchev, et al., 2004). The wide spread use of PCR has improved the laboratory diagnosis and understanding of viral etiology of different clinical syndromes.
RT-PCR assays that performed in our study were standardized to amplify fragments of 400bp and 204bp corresponding to parts of (F) gene of both BPI-3 and BRSV genomes respectively. The (F) gene was chosen as the target for the RT-PCR assay to become of wide detection range because it is one of the most conservative genes in the family Paramyxoviridae and consequently, represent a good alternative to be used for virus detection in calves with unknown history about those viruses (Renata, et al., 2004) therefore, this gene is a good choice for our study.
Our result of BPI-3 (F) gene RT-PCR assay (PCR-F) revealed the detection of viral RNA in 17 of 18 (94.4%) samples tested comparing with 72.2% detected by FAT. Also respiratory syncytial viral RNA was detected in 16 of 18 (88.9%) sample tested comparing with 77.8% detected by ELISA technique indicating with no doubt that (PCR-F) assay is more sensitive than the conventional methods in diagnosis of both BPI-3 and BRSV. This result agreed with the published data of Vilček, et al. (1994) West, et al. (1998) and Renata, et al. (2004)who indicated that RT-PCR technique is much more sensitive than the conventional virological methods.
Many of previous studies employed successfully fusion protein gene of BPI-3 virus in RT-PCR assays (Karron, et al., 1993; Lyon, et al., 1997; Maria et al., 1998).
Several RT-PCR for RSVdetection based on the fusion (F) gene (Vilček, et al., 1994; Van der poel, et al., 1997 and Valentova, et al., 2003) have been developed and evaluatedin studies involving numerous field specimens. Therefore RT-PCR is potentially useful for improving the sensitivity of RSV detection.
In conclusion the respiratory disease-complex considers one of the most important causes of economic impact in livestock especially in calves so the rapid and accurate diagnosis of the viruses causing this disease is important. The use of sensitive and rapid techniques as FAT and ELISA was beneficial but the use of RT-PCR technique proved to be much more reliable, quick, sensitive and easy method of detection of virus. So it is considered a gold standard test for diagnosis of bovine parainfluenza-3 and bovine respiratory syncytial virus.
References
Adair, B.M. and Bradford, H.E. et al. (2000):Effect of parainfluenza-3 virus challenge on cell-mediated immune function in parainfluenza-3 vaccinated and non-vaccinated calves. Res. Vet. Sci; 68:197-199.SitedinWorld Buiatrics Congress 2006- Nice, France.
Ames, T.R. (1997): "Dairy calf pneumonia. The disease and its impact." Vet. Clin. North Am Food Anim. Pract. 13(3): 379-391.
Anthony, E.C. and Werner, P.H.E. (1992):Veterinary diagnostic virology: A practitioness guide, Mosby, ST. Louis, Missouri.
Apley, M. (2006): "Bovine respiratory disease: pathogenesis, clinical signs, and treatment in lightweight calves." Vet. Clin. North. Am Food Anim Pract 22(2): 399-411.
Arns, C.W.; Campalans, J.; Costa, S.C.B. and Domingues, H.C.; et al. (2003): Characterization of bovine respiratory syncytial virus isolated in Brazil. Brazilian J. Medical & Biological Res. (36): 213-218.
Atta, F.A. and Singh, F.V. (1967):Isolation and experimental infection of calves with parainfluenza-3 virus. J. Vet. Sci. UAR, 4 (1): 1-12.
Baker, J.C. (1995): "The clinical manifestations of bovine viral diarrhea infection." Vet Clin North Am Food Anim Pract 11(3): 425-45.
Baker, J.C. and Frey, M.L. (1985): "Bovine respiratory syncytial virus." Vet. Clin. North Am Food Anim Pract 1(2): 259-275.
Bastawecy, M. Iman; Abd EL-Samee, A.A. and Fayed, A.A. (2002): Serodiagnosis of the main bovine viral respiratory infection by using ELISA Pantakit. J. of the Egyptian Vet. Med. Association, 62 (6): 231-240.
Baz, T.I.; Taha, M.M.; Zahran, M.H. and El-Dobeigy, Aida, I. (1986):Major respiratory viruses and multiple infection in pneumoenteritis of new born calves in Egypt. J. Vet. Sci, 23 (2): 235-248.
Bolte, J.W.; Olson, K.C.; Jaeger, J.R.; Schmidt, T.B.; Thomson, D.U.; White, B.J.; Larson, R.L.; Sproul, N.A.; Pacheco, L.A. and Thomas, M.D. (2009):Length the Weaning Period Affects Postweaning Growth, Health, and Carcass Merit of Ranch-Direct Beef Calves Weaned During the Fall. Beef cattle Research: pp 1-10. Kansas State University Agricultural Experiment Station and Cooperative Extension Service.
Brock, K.V. (2004): "The many faces of bovine viral diarrhea virus." Vet. Clin. North Am Food Anim Pract 20(1): 1-3.
Brodersen, B.W. and Kelling, C.L. (1998): "Effect of concurrent experimentally induced bovine respiratory syncytial virus and bovine viral diarrhea virus infection on respiratory tract and enteric diseases in calves." Am J Vet Res 59(11): 1423-1430.
Bryson, D.G. (1990): Parainfluenza-3 virus in cattle. In: Virus infections in ruminants. Eds. Z. Dinter & B. Morein, Elsevier, Amsterdam: 319-333.
Carn, V.M. and Kitching, R.P. (1995):The clinical response of cattle experimentally infected with lumpy skin disease (Neethling) virus "Arch. Virol., 140: 503-513.
Chomczynski, P. and Sacchi, N. (1987):Single-stepmethod of RNA isolation by acid guanidinum thiocyanate-phenol-chloroform extraction. Annal. Biochem. 162, 156-159.
Collins, J.K.; Teegarden, R.M.; MacVean, D.W.; Smith, G.H.; Frank, G.R. and Salman (1988):Prevalence and specificity of antibodies to bovine respiratory syncytial virus sera from feed lot and range cattle. Am. J. Vet. Res., 49 (8): 1316-1319.
Coons (1956):histochemistry with labeled antibody. Int. Rev. Cytol., 5,1.
Dubovi, E.J. (1993):Diagnosing BRS infection: A laboratory perspective. Vet. Med. 88: 888-893.
Elisabeth, J.; Haanes, Paul Guimond and Richard Wardly (1997): The bovine parainfluenza virus type-3 heamagglutination, neuraminidase, glycoprotein expressed in baculovirus protect against experimental BPI-3 challenge. Vaccine, 15 (6/7): 730-738.
Ellis, J.A. (2001):The immunology of the bovine respiratory disease complex. Vet. Clinics of North America: Food Animal Practice, 17: 535-550.
Fan, J. and Henrickson, K.J. (1996):Rabid diagnosis of human parainfluenza virus type 1 infection by quantitative reverse transcription-PCR-enzyme by hybridization assay. J.Clin. Microbiol; 34: 1914-1917.
Field, B.N.; Knipe, D.M. and Howley, P.M. et al. (1996):Parainfluenza-3 viruses Field Virology third edition 1205-1241.
Gagea, M.I. and Bateman, K.G. et al. (2006): "Diseases and pathogens associated with mortality in Ontario beef feedlots." J Vet. Diagn. Invest 18(1): 18-28. sited in an abstract of the thesis submitted to Oregon State University Presented June 14, 2007.
Godinho, K.S. and Sarasola, P. et al. (2007): "Use of deep nasopharyngeal swabs as a predictive diagnostic method for natural respiratory infections in calves." Vet. Rec. 160(1): 22-5. Sited in an abstract of the thesis submitted to Oregon State University Presented June 14, 2007.
Graham, D.A.; Foster, J.C. and Mawhinney, K.A. et al. (1999): "Detection of IgM responses to bovine respiratory syncytial virus by indirect ELISA following experimental infection and reinfection of calves: abolition of false positive and false negative results by pre-treatment of sera with protein-G agarose." Vet Immunol Immunopathol 71(1): 41-51.
Grist, N.R.; Bell, E.J. and Urquhart, G.E. (1979):Diagnostic method in clinical virology 3rd Edition 49-51.
Hamdy, A.H. (1966):Association of myxovirus parainfluenza-3 with pneumoenteritis of calves: Virus isolation. Am. J Vet. Res. 27, 981-986.
Hazari, S. and Panda, H.K. et al. (2002):"Comparative evaluation of indirect andsandwich ELISA for the detection of antibodies to bovine respiratory syncytial virus(BRSV) in dairy cattle." Comp Immunol Microbiol Infect Dis. 25(1): 59-68. Sited in an abstract of the thesis submitted to Oregon State University Presented June 14, 2007.
Hill, F.I. and Reichel, M.P. et al. (2007): "Evaluation of two commercial enzymelinked immunosorbent assays for detection of bovine viral diarrhoea virus in serum and skin biopsies of cattle." N Z Vet J 55(1): 45-8. Sited in an abstract of the thesis submitted to Oregon State University Presented June 14, 2007.
Huang, Y. and Wertz, G. (1982): The genome of respiratory syncytial virus is a negative-stranded RNA that codes for at least seven mRNA species. J. Virol. 43, pp 150-157.
Kalvatchev, Z.; Draganov, P. and Kalvatchev, N. (2004):Efficiency of multiplex polymerase chain reaction (M-PCR) for detection and molecular analysis of human viruses. Biotechnol. & Biotechnol. Eq. pp 3-11.
Karron, R.A.O.; Brien, K.L.; Froehlich, J.L. and Brown, V.A. (1993):Molecular epidemiology of parainfluenza-3 virus outbreak on pediatric ward. J. Infect. Dis. 167 (6): 1441-1445.
Kimman, T.G.; Zimmer, G.M.; Straver, P.J. and DeLeeuw, P.W. (1986):Diagnosis of bovine respiratory syncytial virus detection in lung lavage samples. American J. of Vet. Res. 47 (1): 143-147.
Kite, J.; Ochmanska-Hecold, M. and Pery, T. (1994):Mixed viral infection in calves in bronchopneumonia outbreaks. Meyleyna Veterynaryina, 50 (1): 608-609.
LeBlance, P.H.; Baker, J.C.; Gray, P.R.; Robinson, N.E. and DerKSEN, F.J. (1991):Effect of bovine respiratory syncytial virus on airway function in neonatal calves. Am. J. Vet. Res., 52 (9): 1401-1406.
Lehmkuhl, H.D. and Gough, P.M. (1977): "Investigation of causative agents of bovine respiratory tract disease in a beef cow-calf herd with an early weaning program." Am. J. Vet. Res. 38(11): 1717-1720.
Lyon, M.; Leroux, C.; Greenland, T.; Chastang, J.; Patet, J. and Monrex, J-F. (1997):Presence of unique parainfluenza-3 strain identified by RT-PCR in visna-maedi virus infected sheep. Vet. Microbiol, 51:95-104.
Maria, Z.; Tim, B.; Carol, J.S.; John, M.G. and Katherine, N.W. (1998):Molecular epidemiology of conequtive outbreaks of parainfluenza-3 in Bone Marrow Transplant Unit. J. Clin. Microbiol. 36 (36):2289-2293.
Paccaud, M.F. and Jacquier, C. (1970):A respiratory syncytial virus of bovine origin. Archiv für die Gesamtte Virusforschung, 30: 327-342.
Peterfy, F.; Kuuseia, P. and Makela, O. (1983): Affinity requirements for antibody assay mapped by monoclonal antibodies. J. Immunol., 230: 1809-1813.
Potgieter, L.N. (1995): "Immunology of bovine viral diarrhea virus." Vet. Clin. North Am. Food Anim. Pract. 11(3): 501-20.
Pringle, C.R. (1991):The order mononegavirales. Arch. Virol. 117: 137-140.
Reed, L.M. and Muench, H. (1938):A simple method of estimating 50 percent end points. Am. J., 27: 493-495.
Reina, J.; Ros, M.J.; DelValle, J.M.; Blanco, I. and Munan, M. (1995): Evaluation of direct immunofluorescence, dot-blot enzyme immuno assay and shell-vial culture for detection of respiratory syncytial virus in patients with bronchiolitis. Eur.J.Clin. Microbiol. Infec. Dis. 14: 1018-1020.
Reisinger, R.C.; Heddleston, K.L. and Manthei, C.A. (1959): Myxovirus (SF4) associated with shipping fever of cattle. J. Am. Vet. Med. Assoc., 135: 147-152.
Renata, S.A.; Helena, G.D. and Lia, T.C. et. Al. (2004): Detection of respiratory syncytial virus in experimentally infected balb/c mice. Vet. Res. 35 189-197.
Saber, M.S.; Hana Abdel Aziz; Salem, S.A.H; Mohmmed, H.H.; Hadia, M.; Nawal, M. and Fathia, M. (1996):Isolation identification and sero conversion of BRSV. Vet. Med. J. 44 (4): 735-747.
Sambrook, J.E.; Fritsch, E.F. and Maiates, T. (1989):Molecular coloning laboratory Manual. 2nd Edition.
Schrijver, R.S.; Hensen, E.J. and Langedijk, J.P.M. et al. (1997): Antibody response against epitopes on the protein of bovine respiratory syncytial virus differ in infected orvaccinated cattle. Arch. Virol 142: 2195-2210
Solis-Calderon, J.J. and Segura-Correa, V.M. et al. (2005): "Bovine viral diarrhoea virus in beef cattle herds of Yucatan, Mexico: seroprevalence and risk factors." Prev. Vet. Med. 72(3-4): 253-62. SitedinWorld Buiatrics Congress 2006 - Nice, France
Stein-Hagen, P. and Hubent, T.P. (1995): Epidemiologic of viral disease of cattle in Schlesving-Hastein (1986-1993). Tierdztiche Umschan 50 (4): 264-271.
St.George, T.D. (1969):[I] a bovine strain of myxovirus parainfluenza type 3. [II] The isolation of myxovirus parainfluenza type 3 from sheep in. Australian Vet. J. (8): 370-374.
Stott, E.J. and Thomas, L.H. et al. (1980): A survey of virus infections of the respiratory tract of cattle and their association with disease. J. Hygiene. 85:257-270. SitedinWorld Buiatrics Congress 2006 - Nice, France.
Swierkosz, E.M.; Erdman, D.D.; Bonnot, T.; Schneiderheinze, C. and Waner, J.L. (1995):Isolation and characterization of a naturally occurring parainfluenza3 virus variant. J. Clin. Microbiol. 33: 1839-1841.
Toth, T.E. and Jankura, D. (1990):Analysis of bovine parainfluenza-3 replication in bovine embryonic lung cell by indirect fluorescent antibody and heamadsorption assay. J. Virological Methods, 27 (1): 113-119.
Valentova, V.; Kovarcik, K. and Psikal, I. (2003): Detection of bovine respiratory syncytial virus in cell culture by nested RT-PCR and use of the method for virus identification in clinical samples. Acta. Vet. Brno, 72: 115-122.
Vander Heide, L. (1971):The fluorescent antibody technique in the diagnosis of bovine respiratory disease. Proceeding 14th Animal Meteeing of the Virus United States, Animal Health Association. 584-588.
Van der Poel, W.H.M.; Langedjk, J.P.M. and Kramp, J.A. et al. (1997):Serological identification for persistence of bovine respiratory syncytial virus in cattle and attempts to detect the virus Arch. Virol. 142: 1681-1696.
Verhoeff, J. and Van Nieuwstadt, A.P. (1984): BRS virus, PI3 virus and BHV1 infections of young stock on self-contained dairy farms: epidemiological and clinical findings. Vet Rec, 114: 288-293.
Vilek, S.M.; Elvander, A.; Ballagi-Pordány, and Belák, S. (1994):Development of nested PCR assays for detection of bovine respiratory syncytial virus in clinical samples. J. Clin. Microbiol. 32: 2225-2231.
Voller, A.; Bedwell, D.E. and Bartlett, A. (1979):The enzyme linked immunosorbent assay (ELISA) A Cide with abstracts of microplate application. Dynatec (MedaA/S).
West, K.; Bogdan, K.; Hamel, J.; Nayar, A.; Morley, G.; Haines, P.S. and Ellis, J.A. (1998):A comparison of diagnostic methods for the detection of bovine respiratory syncytial virus in experimental specimens Can. J. Vet. Res. 62: 245-250.
Zaki, F.F.; Wassel, M.S.; Zeidan, S.M. and Samy, A.M. (2000): Evaluation of locally prepared inactivated respiratory syncytial virus vaccine in sheep. J. Egypt.Vet. Med. Ass. 60(5): 187-195.
Zeidan, S.M.; Iman, K.A.; Kassem, and Baker, A.A. (2000): Preparation and evaluation of inactivated respiratory syncytial vaccine. Egypt. J. Agric. Res., 78(5), 2155- 2167.