Document Type : Research article
Author
Department of Microbiology and Parasitology, College of Veterinary Medicine, Alhufuf, Al-Ahsa, King Faisal University, Saudi Arabia
Abstract
Keywords
Main Subjects
Assiut University web-site: www.aun.edu.eg
Received: 21 May 2018; Accepted: 8 July 2018
ABSTRACT
Infectious bronchitis virus (IBV) still to pose great economic losses among chickens of all ages in many parts in the world. Despite the massive application of IBV vaccines in many countries including Saudi Arabia, several outbreaks are still frequently reported. One of the important challenges that hampered the selection of the right vaccine candidates is the identification of the local circulating strain in a certain area. IBV is recently reported in many chickens flocks in the Eastern region of the Kingdom. The major goals of our study were to evaluate the immune status of some chicken farms in Al-Ahsa to IBV. To achieve this goal, total of (368) serum samples- from chicken farms from Al-Ahsa region were collected. Our results showing high seroprevelance of IBV in the non-IBV vaccinated chicken farms suggesting their exposure to the natural IBV infection. Meanwhile, we were able to detect a high IBV antibody titers in vaccinated chicken farms suggesting the used vaccines induced detectable IBV antibodies. This suggesting the circulation of novel IBV strains in these chicken farms. The overall results confirm the circulating of novel IBV strains in chicken farms in Al-Ahsa region. Further studies are needed to do molecular characterization of these IBV strains
Key words: Infectious bronchitis virus, ELISA, Al-Ahsa, broiler, baladi chickens |
A total of 368 sera from broilers (184) and layers (184) were collected from seven chicken farms (Table 1). Blood samples were collected randomly prior to each exposure. Specimens were placed for 12 hours at room temperature and centrifuged at 5000 RPM for 10 min. The serum was aspirated by micropipettes. Heat inactivation of sera at 56C for 30 min was done in a water bath to inactivate the non-specific inhibitors. The separated sera were and stored at - 80°C for further testing (Praveen & Narasimha, 2016, Hemida et al., 2017).
Evaluation of the IBV antibody titters from birds was done by using commercial available total antibody ELISA (IDVet Screen Infectious Bronchitis Virus Competition, insert 0913, lot 555). ELISA procedures were done as per the kits instructions with minor modifications. Simply, each sample was tested in triplicate. Specimen-to-positive ratios (S/P ratios) was calculated as the percent inhibition as per the following formula.
(PI%) = x100 (NC: Negative Control, OD: optical density).
The optical density of samples presenting a PI% greater than 40% were considered positive while the OD of samples between 30-40% were considered doubtful, However, the OD of samples less than 30% were considered negative. Individual serum titres were calculated from these S/P ratios, evaluated as positive or negative, and expressed as OD 450 nm values according to the manufacturer’s instructions. Allow all reagents to come to room temperature before use.
Table 1: Summary of the collected specimens and their geographical distribution 2014-2016.
Farm No. |
Organs |
No. of serum |
Type of vaccine |
Clinical signs |
Collection age |
Type |
No. |
Date |
|||||||
1 |
NA |
92 |
-IBV (H120) & NDV, at 0 days -NDV at 10 days -IBV at 16 days |
APN |
35 days |
B |
1 |
11/2014 |
|||||||
2 |
NA |
92 |
-IBV (H120) &ND at 0 days -NDV at 10 days -IBV at 16 days |
APN |
38 days |
B |
2 |
11/2014 |
|||||||
6 |
NA |
92 |
-IBV (H120) and ND at 7 days -IBDV at 15 days -NDV (LaSota strain) & IBDV at 19 days -NDV (LaSota strain) at 30 days -AI and NDV at 38 days -IBV (H120) at 42 days -Fowlpox at 52 days - AI & NDV at70 days -IBV (H120) and NDV at 100 days -NDV at 120 days |
APN |
150 days |
L |
3 |
11/2014
|
|||||||
7 |
Trachea, lung and kidney |
13 |
NV |
RS |
180-210 days |
L |
4 |
1/2015 |
|||||||
5 |
Trachea, lung and kidney |
41 |
NV |
RS |
210-240 days |
L |
5 |
1/2015 |
|||||||
3 |
Trachea, lung and kidney |
24 |
NV |
RS |
180-210 days |
L |
6 |
1/2015 |
|||||||
6 |
Trachea, lung and kidney |
14 |
NV |
APN |
270-300 days |
L |
7 |
2/2015 |
|||||||
6 |
276 |
368 |
Total |
B= broilers, L= layers, APN= apparently normal, RS= respiratory signs, IBV=infectious bronchitis virus, AI=avian influenza, IBDV= infectious bursal diseases virus, NDV= newcastle disease virus, VTC= veterinary training centre, NV= non vaccinated (did not receive any vaccine for viral diseases).
RESULTS
Seroprevalence of IBV in some chicken farms in Al-Hasa
A total of 368 chicken serum samples were tested for the presence of IBV antibodies. Specimens were collected from chicken farms on six regions in Al-Hasa. Our results are showing that 23/92 (25%) non-vaccinated chicken sera and 257/276 (93.12%) (Figure. 5), the vaccinated sera were positive for IBV antibodies (Figure. 6). However, seven samples out of 13 tested from non-vaccinated chicken in Farm No.7 were positive (53, 85%).Our results are showing that 8/41 (19.51%) in farm No.5 and test 6/24 (25%) in Farm No.3 sera were positive. However, two samples from chickens in Veterinary Training Centre was IBV antibodies positive out of 14 tested samples (14.29%) non-vaccinated. In contrast, the antibody IBV ELISA reported much higher 90/92 (93,83%) in farm No.1 and same in farm No.2 result was 86/92 (93.48%) chicken vaccinated. We test 81/92 (88.04%) chicken vaccinated were positive from the Veterinary Training Centre (Table 2).
Table 2: Summary of the seroprevalence of IBV in some chicken farms in Al-Hasa.
Farm No. |
No. of |
No. of |
No. of serum |
Type of vaccine |
Collection of age |
Type of chicken |
No. |
||
% |
- |
% |
+ |
||||||
1
|
2.17 % |
2 |
97.83 % |
90 |
92 |
-IBV (H120) & NDV, at 0 days -NDV at 10 days -IBV at 16 days |
35 days |
B |
1 |
2
|
6.52 % |
6 |
93.48 % |
86 |
92 |
-IBV (H120) &ND at 0 days -NDV at 10 days -IBV at 16 days |
38 days |
B |
2 |
6 |
11.96 % |
11 |
88.04 % |
81 |
92 |
-IBV (H120) and ND at 7 days -IBDV at 15 days -NDV (LaSota strain) & IBDV at 19 days -NDV (LaSota strain) at 30 days -AI and NDV at 38 days -IBV (H120) at 42 days -Fowlpox at 52 days - AI & NDV at70 days -IBV (H120) and NDV at 100 days -NDV at 120 days |
150 days |
L |
3 |
7 |
46.15 % |
6 |
53.85 % |
7 |
13 |
NV |
180-210 days |
L |
4 |
5 |
80.49 % |
33 |
19.51 % |
8 |
41 |
NV |
210-240 days |
L |
5 |
3 |
75 % |
18 |
25 % |
6 |
24 |
NV |
180-210 days |
L |
6 |
6 |
85.71 % |
12 |
14.29 % |
2 |
14 |
NV |
270-300 days |
L |
7 |
6 |
23.91 % |
88 |
76.09 % |
280 |
368 |
Total |
B= broilers, L= layers, APN= apparently normal, RS= respiratory signs, IBV=infectious bronchitis virus, AI=avian influenza, IBDV= infectious bursal diseases virus, NDV= Newcastle disease virus, VTC= veterinary training centre, NV= non vaccinated (did not receive any vaccine for viral diseases).
Figure 1: ELISA results of some vaccinated chicken farms in Al-Hasa.
Figure 2: ELISA results of some non-vaccinated chicken farms in Al-Hasa.
DISCUSSION
Infectious bronchitis virus (IBV) is one of the major viral threats of poultry industry worldwide. There are large number of IBV genotypes identified in many parts around the globe (Khataby et al., 2016, Fellahi et al., 2016). IBV is one of the family Coronaviridae. The IBV viral genome is believed to mutate at a high frequency due to the poor proof reading capabilities of its viral RNA polymerases. Both mutations and recombinations provides ample genetic diversity among the IBV population throughout the world (Jackwood et al., 1992, Najafi et al., 2015, Xu et al., 2016a). Although IBV vaccination is a common practice throughout most poultry farms across the globe, many IBV outbreaks still reported in commercial poultry farms. This resulted in high economic losses to poultry raisers and industry (Mohajer Shojai et al., 2016, Sun & Liu, 2016). Isolation of many IBV strains and antigenic variants from vaccinated commercial chickens was reported in many cases frequently (Xu et al., 2016b). Recombination occurs among different IBV genes and was reported so frequently especially within the S gene (Promkuntod et al., 2015, Makhija & Kumar, 2015). The N protein plays important roles in the pathogenesis and replication cycle of most coronaviruses. The N protein has many conserved motifs showing similarity of more than 94% among different coronaviruses (Sapats et al., 1996). The N protein is an important diagnostic marker which have been used for diagnostic purposes of many coronaviruses including IBV for long time by the RT-PCR technique. Meanwhile, it is most frequently used to study the evolution of IBV strains and genotypes (Chang et al., 2016). The live IBV attenuated vaccines are effective tools for controlling IBV when used properly. Improper IBV vaccine distribution within chicken flocks and insufficient vaccine dosage favors the reversion of IBV vaccines to virulence. In some cases using the IBV live vaccine in chickens may increase the susceptibility of birds to be infected with the virus rather than protected from its field infection as planned. (Lim et al., 2015, Reddy et al., 2016, Seger et al., 2016).A serosurveillance study was conducted among some IBV vaccinated and non- vaccinated chickens in some chicken farms across Al-Ahsa region. A total of 368 including 276 IBV vaccinated and 92 non-IBV vaccinated chicken sera were collected. Sera were tested for the presence of IBV antibodies by the commercial available ELISA kits. Our date is showing that 257/276 (93.12%) (Figure.1) vaccinated chicken were positive while 23/92 (25%) non-vaccinated sera were positive for IBV (Figure.2). Presence of IBV antibodies in vaccinated chicken sera indicating the IBV vaccines were able to induce antibodies against the IBV antigen. In contrast to the detection of IBV antibodies in non-vaccinated chicken sera indicating that, those birds were exposed to a recent IBV natural infection.
CONCLUSIONS
Our results confirmed the detection of specific antibodies against IBV in non-vaccinated chickens in Al-Ahsa province. This suggesting those chickens were exposed to an IBV natural infection.
ACKNOWLEDGMENT
I thank Mr. Musaed Alsultan for his technical assistance with ELISA technique
COMPETING OF INTEREST
The author declare there is no competing of interest exist
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تقييم الاستجابة المناعية لفيروس التهاب الشعب الهوائية في بعض قطعان الدواجن
بمحافظة الاحساء بالمملکة العربية السعودية
محمد علي عبد اللطيف الحمادى
Email: malhammadi@kfu.edu.sa Assiut University web-site: www.aun.edu.eg
يصنف فيروس التهاب الشعب الهوائية من أهم مسببات الأمراض المعدية والذي يصيب الجهاز التنفسي في مختلف الاعمار في الدواجن. کما يسبب هذا الفيروس إصابات شديدة للجهاز التناسلي للدجاج البياض مما يؤدى الى انخفاض شديد في معدلات إنتاج البيض بين القطعان المصابة. بالإضافة الى أن بعض العترات من الفيروس تسبب إصابات بالغة للکليتين في الدواجن المصابة مما قد يؤدي الى نفوق العديد من الطيور المصابة بهذه العترات. ينتمي فيروس التهاب الشعب الهوائية الى عائلة الفيروسات التاجية (کورونا) وقد أثبتت أکثر من دراسة سابقة وجود إصابات بفيروس التهاب الشعب الهوائية في قطعان الدواجن بالمملکة العربية السعودية. على الرغم من وجود العديد من اللقاحات ضد هذا الفيروس الا أنه مازال متفشي في العديد من مزارع الدواجن في مناطق مختلفة من المملکة وخاصة في الأحساء. تم تصميم هذه الدراسة لتقييم الاستجابة المناعية لبعض قطعان الدواجن بالأحساء لهذا الفيروس ولتحقيق هذه الاهداف، تم اختبار عدد ٤٦٨ عينة من بعض مزارع الدواجن بالأحساء من نوفمبر ٢٠١٤ إلى أبريل ٢٠١٦. وقد شملت هذه العينات عدد ٣٦٨ سيرمات اختبر منها عدد ٢٧٦ عينة من السيرم لبعض الدواجن المحصنة ضد فيروس التهاب الشعب الهوائية وکذلک عدد ٩٢ عينة لدواجن غير محصنة ضد الفيروس والتي تم جمعها من ستة مزارع للکشف عن الأجسام المضادة للفيروس باستخدام اختبار الاليزا. وقد کانت النتيجة على النحو التالي لعينات السيرم وجدت اجسام مضادة للفيروس في ٢٥٧/٢٧٦ (٩٣.١٢٪) في الدواجن المحصنة بينما کانت النتيجة للدواجن الغير محصنة ٢٣/٩٢ (٢٥٪). توصى الدراسة الحالية بضرورة إجراء المزيد من الدراسات المستقبلية لعمل المزيد من التوصيف البيولوجي الجزيئي الکامل لعترات هذا الفيروس مع استمرار إجراء المزيد من المسوحات التي تعتمد على البيولوجيا الجزيئية للفيروس. کما توصي بالاعتماد على التقنيات البيولوجية والسيرولوجية الحديثة في إجراء التحصينات الدورية لمزارع الدواجن ضد فيروس التهاب الشعب الهوائي.