SERO-PREVALENCE OF VIRAL RESPIRATORY DISEASES IN BUFFALOES AT ASSIUT GOVERNORATE المسح السيرولوجي للأمراض التنفسيه الفيروسيه في الجاموس في محافظة أسيوط

Document Type : Original Article

Abstract

ABSTRACT:
Respiratory disorders are major concern for Bovidae. Viruses and bacteria in combination with stress play a key role in triggering acute respiratory infections. It is generally accepted that viruses are the first pathogens to intervene, whereas bacteria act as the second invaders to worsen the ill-animal’s condition.  The most important viral agents are bovine herpes virus type 1 (BoHV-1), bovine respiratory syncytial virus (BRSV), parainfluenza virus type 3 (BPIV-3), bovine viral diarrhea virus (BVDV) and bovine adenoviruses (BAdVs). This study was conducted to evaluate the serological status of BoHV-1, BVDV, BRSV, BPIV-3 and BAdV-3 in buffaloes, Assiut governorate, Egypt. The samples were tested by commercial indirect ELISA kits. All samples were negative for BoHV-1, BVDV and BRSV; antibodies while detected against BPIV-3 and BAdV-3 in 0.05 and 10.55% of serum samples, respectively. According to the present study, presence of antibody against BAdV-3 were higher than BPIV-3 in buffaloes at Assiut Governorate, Egypt.
الملخص العربي :
الاضطرابات التنفسية تمثل خطراً کبيراً علي صحة الجاموس حيث تلعب الفيروسات والبکتيريا تحت تآثير عوامل الضغط والإجهاد دوراً أساسياً في حدوث العدوى التنفسية الحادة. من المقبول بشکل عام أن الفيروسات هي أول مسببات الأمراض ، في حين أن البکتيريا تعمل کمسبب ثانوي للعدوي يؤدي إلي سوء حالة الحيوان. ومن أهم المسببات الفيروسية فيروس الإسهال الفيروسي البقري (BVDV) ، وفيروس الهربس البقري من النوع الأول (BoHV-1) ، والفيروس المخلوي التنفسي البقري (BRSV) ، وفيروس نوع الإنفلونزا البقري 3 (BPIV-3) ، والفيروس الغدي البقري (BAdVs). أجريت هذه الدراسة لتقييم الحالة المصلية لـ BoHV-1 ، BVDV ، BRSV ، BPIV-3 و BAdV-3 في الجاموس، في محافظة أسيوط ، مصر. لهذا الغرض، تم اختبار العينات من خلال مجموعات الإليزا غير المباشرة التجارية. وکانت جميع العينات سلبية بالنسبة لـ BoHV-1 و BVDV و BRSV ؛ تم الکشف عن الأجسام المضادة ضد BPIV-3  وBAdV-3 في 0.05 و 10.55 ٪ من عينات المصل ، على التوالي. وفقا للدراسة الحالية ، کان وجود الأجسام المضادة ضد BAdV-3 أعلى من BPIV-3 في الجاموس في محافظة أسيوط ، مصر.

Sero-prevalence of viral respiratory diseases

 in Buffaloes at Assiut Governorate

Ghaly1, E.S., Mohamed2, A.E.A., Mottelib3, A.A. and Shaheen4, M.E.

1Animal Health Research Institute, Assiut, Egypt.

2Faculty of Veterinary Medicine, South Valley University, Egypt.

3Faculty of Veterinary Medicine, Assiut University, Egypt.

4Animal Health Research Institute, Dokki, Giza, Egypt.

ABSTRACT:

Respiratory disorders are major concern for Bovidae. Viruses and bacteria in combination with stress play a key role in triggering acute respiratory infections. It is generally accepted that viruses are the first pathogens to intervene, whereas bacteria act as the second invaders to worsen the ill-animal’s condition.  The most important viral agents are bovine herpes virus type 1 (BoHV-1), bovine respiratory syncytial virus (BRSV), parainfluenza virus type 3 (BPIV-3), bovine viral diarrhea virus (BVDV) and bovine adenoviruses (BAdVs). This study was conducted to evaluate the serological status of BoHV-1, BVDV, BRSV, BPIV-3 and BAdV-3 in buffaloes, Assiut governorate, Egypt. The samples were tested by commercial indirect ELISA kits. All samples were negative for BoHV-1, BVDV and BRSV; antibodies while detected against BPIV-3 and BAdV-3 in 0.05 and 10.55% of serum samples, respectively. According to the present study, presence of antibody against BAdV-3 were higher than BPIV-3 in buffaloes at Assiut Governorate, Egypt.


INTRODUCTION:

Water buffaloes in different regions have an economic value that is specific to their own regions. Especially, the unique quality of their milk and dairy products increase their value. Italian Mozzarella cheese, which is famous throughout the world, is made from water buffalo milk. Also, water buffalo farming has the advantages related to their resistance for various environmental conditions and diseases, their ability to benefit feed and to turn poor feed into meat and milk, as well as, their low cost compared with cows (Canbolat, 2012).

Respiratory disorders are major concern for Bovidae. They occur in all countries that practice intensive livestock farming. Viruses and bacteria in combination

 

 

with stress play a key role in triggering acute respiratory infections. It is generally accepted that viruses were the first pathogens to intervene, whereas bacteria act as the second invaders to worsen the ill-animal’s condition (Valarcher and Hägglund, 2006 and Solis-Calderón et al., 2007). The most important viral agents were bovine herpes virus type 1(BoHV-1), bovine viral diarrhea virus (BVDV), bovine respiratory syncytial virus (BRSV), bovine parainfluenza virus type 3 (BPIV-3) and bovine adenoviruses (BAdVs) (Hägglund et al., 2007).

BoHV-1 was a member of the genus Varicellovirus in the subfamily Alpha herpesvirinae, which belongs to the Herpesviridae family (Nandi et al., 2009).

These agents (BoHV-1) might represent risks to livestock and even human population (Teshome et al., 2003). Infectious bovine rhinotracheitis (IBR) is one of the most economically important emerging contagious diseases of cattle and buffalo caused by Bovine herpes virus 1 (BoHV-1) (Saravanajayam et al., 2017).

BVDV belongs to genus Pestivirus within the Flaviviridae family (Radostits et al., 2007). It was previously reported that BVDV causing persistent infection in bovines and other ruminant species (Carman et al., 2005 and Uttenthal et al., 2005). Infection of water buffaloes with BVDVs has been confirmed in several studies by serological and molecular techniques (Craig et al., 2015).

BRSV is a pneumovirus in the family Paramyxoviridae. It is a major cause of respiratory disease in young calves. BRSV genomes consisted of a single stranded, negative-sense RNA containing ten genes encoding eleven proteins. Clinical signs of BRSV vary from none to severe, with most outbreaks occurring during the winter season (Valarcher and Taylor, 2007).

BPIV-3 is a member of respirovirus genus in the family Paramyxoviridae (Adams et al., 2016). BPIV-3 is one of most important viral respiratory pathogens of young and adult cattle associated with BRDC (Dong et al., 2012). BPIV-3 could be present and cause economic losses in both cattle and buffalo population. Little was known about epizootic character of BPIV-3 in buffalo population (Akca et al., 2004).

BAdVs are DNA non-enveloped viruses, members of Adenoviridae family (Shirvani et al., 2012). BAdV-3 is one of the most important causes of respiratory manifestation in cattle especially newborn calves (Zhu et al., 2011). The occurrence and seroprevalence of BAdV-3 infections were detected in buffalo’s in Turkey (Akca et al., 2004).

MATERIAL AND METHODS:
1-Animals:

199 randomly selected Egyptian buffaloes with varying sexes and ages including 173 females classified according to puberty to 36 calves & heifers and 137 adult females classified according to pregnancy, 20 pregnant females and 117 non pregnant females and 26 males classified according to puberty, 11 calves and 15 adult males, ages varying from 15 days to 12 years old. Also vaccinated and non-vaccinated animals by master cattle vaccine were used in this study.

2-Samples:

Blood samples (5 ml) were collected aseptically from jugular vein of each animal using plain vacutainer tubes without anticoagulant and transported in ice-box to the laboratory. 

Serum was separated by centrifugation of blood at 3000 r.p.m. for 10 minutes at room temperature; the aliquots were transferred into 1.5 ml sterile micro tube (Eppendorf).

These samples were stored at -20 ᵒC until tested.

The samples were collected from 25 July 2016 to 15 January 2018 from different districts at Assiut Governorate.

3- Serological test, Enzyme linked immunosorbant assay (ELISA)according to (Saravanajayam et al., 2017).

3.1. MULTISCREEN ELISA (Bovine respiratory): (Yousef et al., 2013 and Al-Hammadi and Hemida, 2014)

Serum samples were divided to 40 pools each pool contains 5 serum samples except one pool had 4 serum samples. Testing of the serum's groups by using 3 plates of  ELISA kit for serodiagnosis of BoHV-1, BVDV, BRSV, BPIV-3 and BAdV-3 (indirect test for blood serum), used in accordance with the manufacturer’s instructions (Bio-X Diagnostics, Belgium).

3.2. Select the highest three groups in results for each virus and make analysis for each sample in these groups by using MULTISCREEN ELISA (Bovine respiratory) to confirm the results. 

3.3. MONOSCREEN ELISA (Bovine adenovirus 3): (Sinbat et al., 2016)

Make analysis for each sample in the positive groups for BAdV-3 by using ELISA kit for serodiagnosis of BAdV-3, indirect test for blood sera to differentiate the positive samples from the negative ones and to detect the degree of positivity for each positive sample, used in accordance with the manufacturer’s instructions (Bio-X Diagnostics, Belgium). 

ELISA plates were coated with monoclonal antibodies and inactivated viruses. Tested sera were diluted at a ratio of 1:100 in the dilution buffer. Samples were added to corresponding wells, incubated at 37 ̊C for 1 hr. plates then washed three times with the washing buffer by using graduated automatic multichannel pipettes. The conjugate was diluted 1:50 in 1X dilution buffer and added to each wells. Plates were then lidded, incubated at room temperature for one hour and washed as stated above. Undiluted chromogen was added to each well. Plates were then incubated in dark at room temperature for 10 minutes. The reaction was stopped by adding 50 μl per well of the undiluted stop solution followed by reading Optical Density (OD) in the microwells using a plate reader and a 450 nm filter.

4. Interpretation of test results:

4.1 . Interpretation of MULTISCREEN ELISA test results:

Subtract from each value recorded in 1, 2, 3, 4, 5, the signal of the corresponding negative control well 6 and write down the result. In performing this calculation, allow for any negative values that may exist. Carry out the same operations for the column corresponding to the positive and negative controls.

The test can be validated  only if the positive control serum yields a difference in optical density at 10 minutes that is greater for each valence than: BoHV-1 > 0.700, BVDV > 1.000, BRSV > 0.800, BPIV-3 > 0.800 and BAdV-3 > 0.600 and the negative control yields a difference in optical density at 10 minutes that is lower than 0,300.

Divide the signal read for each sample well by the corresponding positive control serum signal and multiply this result by 100 to express it as a percentage.

 

 

 

 

 

Using the following table, determine each serum's degree of positivity.

+++++

 

++++

 

+++

 

++

 

+

 

0

 

Val >

178%

=>Val>

141%

=>Val>

104%

=>Val>

67%

=>Val>

30%

=>Val

BoHV-1

Val >

100%

=>Val>

80%

=>Val>

60%

=>Val>

40%

=>Val>

20%

=>Val

BVDV

Val >

100%

=>Val>

80%

=>Val>

60%

=>Val>

40%

=>Val>

20%

=>Val

BRSV

Val >

100%

=>Val>

80%

=>Val>

60%

=>Val>

40%

=>Val>

20%

=>Val

BPIV-3

Val >

102%

=>Val>

79%

=>Val>

56%

=>Val>

33%

=>Val>

10%

=>Val

BAdV-3

 

            A sample must be considered positive if it yields a result is greater than or equal to one plus sign (+).

 

 


4.2 . Interpretation of MONOSCREEN ELISA test results:

Subtract from each value recorded for the odd columns the signal of the corresponding negative control well and write down the result. In performing this calculation, allow for any negative values that may exist. Carry out the same operations for the column corresponding to the positive control. 

The test can be validated only if the positive serum yields a difference in optical density at 10 minutes that is greater than 0.600 and the negative serum yields a difference in optical density that is lower than 0.200.

Divide the signal read for each sample well by corresponding positive control serum signal and multiply this result by 100 to express it as a percentage.

 

 

 

Using the following table, determine each serum's degree of positive.

+++++

 

++++

 

+++

 

++

 

+

 

0

Val >

102%

=>Val>

79%

=>Val>

56%

=>Val>

33%

=>Val>

10%

=>Val

 

A sample must be considered positive if it yields a result is greater than or equal to one plus sign (+).

 


RESULTS

A-   According to the clinical examination all samples were divided to two main groups. First group contained 99 samples were collected from apparently health animals and second group contained 100 samples were collected from 30 animals with respiratory signs such as high temperature (39-40.5 ℃), high pules (65-85), high respiration rate (35-45), cough, congested eyes with lacrimation and nasal discharge, 40 animals with digestive troubles such as off food, tympany and enteritis, 20 animals with reproductive disorders such as repeat breeding and abortions with high temperature and 10 animals appear other clinical signs, 5 animals of them appear udder affections (suspects mastitis) and another 5 animals appear urinary system affections

B-   The laboratory and epidemiological findings of the present work were arranged in tables: 1-8. Also, the results were supported by photos of Multiscreen and Monoscreen ELISA plates (1-3).


Table 1; Results of Multiscreen ELISA kit for serodiagnosis of BoHV-1, BVDV, BRSV, BPIV-3 and BAdV-3 in buffalo’s sera samples collected from Assiut governorate.

Serial number

District

No. of samples

Results

BoHV-1

BVDV

BRSV

BPIV-3

BAdV-3

+ve

-ve

+ve

-ve

+ve

-ve

+ve

-ve

+ve

-ve

1

Sidfa

12

-----

12

-----

12

-----

12

-----

12

-----

12

2

Abu Tig

8

-----

8

-----

8

-----

8

-----

8

-----

8

3

El Ghanayem

88

-----

88

-----

88

-----

88

1

87

17

71

4

Dayrout

9

-----

9

-----

9

-----

9

-----

9

-----

9

5

Al Qusiyyah

3

-----

3

-----

3

-----

3

-----

3

-----

3

6

Manfalut

14

-----

14

-----

14

-----

14

-----

14

1

13

7

Assiut

24

-----

24

-----

24

-----

24

-----

24

1

23

8

El Fath

11

-----

11

-----

11

-----

11

-----

11

-----

11

9

Al Badari

6

-----

6

-----

6

-----

6

-----

6

-----

6

10

Abnub

22

-----

22

-----

22

-----

22

-----

22

2

20

11

Sahil Salim

2

-----

2

-----

2

-----

2

-----

2

-----

2

 

Total

199

-----

199

-----

199

-----

199

1

198

21

178

 

 

Table 2; Relationship between districts and results of Monoscreen ELISA Kit used for serodiagnosis of BAdV-3 in buffalo’s sera samples from Assiut governorate

Serial No.

district

No. of samples

Results of BAdV-3

-ve

+ve

++ve

1

Sidfa

12

12

-----

-----

2

Abu Tig

8

8

-----

-----

3

El Ghanayem

88

71

12

5

4

Dayrout

9

9

-----

-----

5

Al Qusiyyah

3

3

-----

-----

6

Manfalut

14

13

1

-----

7

Assiut

24

23

1

-----

8

El Fath

11

11

-----

-----

9

Al Badari

6

6

-----

-----

10

Abnub

22

20

2

-----

11

Sahil Salim

2

2

-----

-----

 

Total

199

178

16

5

 

 

 

 

 

Table 3; Relationship between seasons and results of Monoscreen ELISA Kit used for serodiagnosis of BAdV-3 in buffalo’s sera samples from Assiut governorate.

Serial No.

Seasons

No. of Samples

Results of BAdV 3

 

-ve

+ve

++ve

1

Winter

53

48

3

2

2

Spring

64

50

11

3

3

Summer

78

76

2

-----

4

Autumn

4

4

-----

-----

 

Total

199

178

16

5

 

Table 4; Relationship between ages and results of Monoscreen ELISA Kit used for serodiagnosis of BAdV-3 in buffalo’s sera samples from Assiut governorate

Serial No.

Ages

No. of Samples

Results of BAdV-3

-ve

+ve

++ve

1

0-12 Months

30

30

-----

-----

2

1-3 Years

60

58

2

-----

3

3-5 Years

27

26

1

-----

4

>5-12 Years

82

64

13

5

 

Total

199

178

16

5

 

Table 5; Occurance of BAdV-3 infection in diseased and clinically healthy animals according to Monoscreen ELISA Kit.

Serial No.

Case History

No. of Samples

Results of BAdV-3

-ve

+ve

++ve

1

Apparently health

99

81

13

5

2

Diseased animals

100

97

3

-----

 

Total

199

178

16

5

 

Table 6; Relationship between sexes and results of Monoscreen ELISA Kit used for serodiagnosis of BAdV-3 in buffalo’s sera samples from Assiut governorate

Serial No.

Sexes

No. of Samples

Results of BAdV-3

-ve

+ve

++ve

1

Male

26

26

------

------

2

Female

173

152

16

5

 

Total

199

178

16

5

 


 

Table 7; Relationship between pregnancy and results of Monoscreen ELISA Kit used for serodiagnosis of BAdV-3 in buffalo’s sera samples from Assiut governorate

Serial No.

Pregnancy

No. of Samples

Results of BAdV-3

-ve

+ve

++ve

1

Pregnant

20

19

1

-----

2

Non-pregnant

117

97

15

5

 

Total

137

116

16

5

 

Table 8; Relationship between vaccination and results of Monoscreen ELISA Kit used for serodiagnosis of BAdV-3 in buffalo’s sera samples from Assiut governorate.

Serial No.

Vaccination

No. of Samples

Results of BAdV-3

-ve

+ve

++ve

1

Vaccinated animals

13

12

1

-----

2

Non-vaccinated animals

186

166

15

5

 

Total

199

178

16

5

 

 

Photo 1; Show the results of plate (1) in MULTISCREEN ELISA (ELISA kit for serodiagnosis of BoHV-1, BVDV, BRSV, BPI3 and Bovine Adenovirus 3 in Buffalo’s serum samples) after dividing of serum samples to 40 groups, each group contains 5 serum samples.

 

Photo 2; Show the results of plate (2) in MULTISCREEN ELISA (ELISA kit for serodiagnosis of BoHV-1, BVDV, BRSV, BPI3 and Bovine Adenovirus 3 in buffalo’s serum samples) after dividing of serum samples to 40 groups, each group contains 5 serum samples.

 

 

Photo 3; Show the results of MONOSCREEN ELISA (ELISA kit for serodiagnosis of Bovine Adenovirus 3 in buffalo’s serum samples).


DISCUSSION

According to results of Multiscreen and Monoscreen ELISA kits, Table (1) showed that, one positive sample for BPIV-3 1/88 (1.14%) was reported at El Ghanaym and no positive results for BPIV-3 were detected in other districts in this study. The summation of all positive samples for BPIV-3 was 1 sample from totally 199 samples (0.05%). This result was lower than that reported by Akca et al. (2004) who detected that seropositivity rate for BPIV-3 was 11% in buffaloes in Turkey. In this study; also 17 positive samples for BAdV-3 were reported at El Ghanayem 17/88 (19.32%), one positive sample for BAdV-3 was reported at Manfalut 1/14 (7.14%), one positive sample for BAdV-3 was reported at Assiut 1/24 (4.17%) and two positive samples for BAdV-3 were reported at Abnub 2/22 (9.09%). The summations of all positive samples for BAdV-3 were 21 samples from 199 samples (10.55%) these results were lower than that reported by Akca et al. (2004) who detected that seropositivity rates for BAdV-3 were 55% in buffaloes in Turkey.  All samples in this study were negative for BoHV-1; this result is similar to that recorded by Anonymous (2000) who reported that Finland was free from IBR and contrast to that reported by Soares et al. (2017) who detected that the occurrence of anti-BoHV-1 antibodies in buffaloes was 56.1% in Pernambuco state - Brazil. All samples were negative for BVDV this result is contrast to that reported by Soares et al. (2017) who detected that the occurrence of anti-BVDV antibodies in buffaloes was 97.9% in Pernambuco state – Brazil and 4.5% of water buffaloes samples were positive for BVDV antibodies in Australia (Evans et al., 2016). These different results of BVDV in different countries were agreement with Hemmatzadeh et al. (2001) who reported that the prevalence of BVDV infection varies between different countries and even between different provinces within a single country; that may be related to the differences in management, environmental variation, size of herds and existence of Persistent Infection (PI) of animals in these herds. All samples in this study were negative for BRSV, this result was contrast to that reported by Akca et al. (2004) who detected that seropositivity rates for BRSV were 28% in buffaloes in Turkey and Shalaby et al. (2002) who reported that seroprevalence of BRSV infection detected by ELISA was 37.5 % in buffaloes in Giza, Egypt. Finally these total results were similar to that reported by Akca et al. (2004) who detected that the presence of antibody against BAdV-3 was higher than the other viruses and all these low percent may be due to decrease in direct contact with source of infection according to that detected by Soares et al. (2017) who mentioned that the high number of positive animal properties may be related to the absence of biosecurity measures and introduction of infected animals.

According to results of Monoscreen ELISA kit, for serodiagnosis of BAdV-3 Table (2) showed that, out of 21 positive samples, 16 samples (8.04%) with one degree of positivity, 12 samples of them were reported at El Ghanayem 12/88 (13.63), 1 sample was reported at Manfalut 1/14 (7.14%), 1 sample was reported at Assiut 1/24 (4.16%) and 2 samples were reported at Abnub 2/22 (9.09). out of 21 positive samples, 5 samples (2.51%) with two degree of positivity, all these 5 samples recorded at El Ghanayem (5.68%). These results agreed with Hemmatzadeh et al. (2001) who mentioned that the prevalence of infection differs between different countries and even between different provinces within a single country; this may be related to the differences in management, environmental variation and size of these herds.

According to results of Monoscreen ELISA kit, Table (3) showed that, 3 samples with one degree of positivity (5.66%) and two samples with two degrees of positivity (3.77%) were reported in Winter, 11 samples with one degree of positivity (17.18%) and 3 samples with two degrees of positivity (4.68%) were reported in Spring, 2 samples with one degree of positivity (2.56%) were reported in Summer and no positive samples were reported in Autumn. These results were in contrast to that reported by NADIS (2014) about outbreaks of respiratory disease in UK which occurred within one month of housing in the autumn/early winter and agreed with Henrickson (2003) about high percentage of infected animals with BPIV-3 in cold weather (December-March). According to results of Monoscreen ELISA kits, Table (4) showed that, no positive samples were reported at the age from 0-12 months, 2 samples with one degree of positivity 2/60 (3.33%) were reported at the age from 1-3 years, 1 sample with one degree of positivity 1/27 (3.7%) was reported at the age from 3-5 years and 13 samples with one degree of positivity 13/82 (15.85%) and 5 samples with two degrees of positivity 5/82 (6.11%) were reported at the age >5 years, these results agreed with Also Shirvani et al. (2012) who detected that the infection in adults was usually asymptomatic and recurrent. When sings were present such as respiratory distress, nasal and ocular discharges in addition to hyperthermia may be complicated by secondary bacterial infections.

According to results of Monoscreen ELISA kit, Table (5) showed that, 13 samples with one degree of positivity (13.13%) and 5 samples with two degrees of positivity (5.05%) were reported in apparently health animals. 3 samples with one degree of positivity (3%) were reported in diseased animals (one from animal with high temperature, another one from animal suffering from mastitis and last one from animal suffering from off food for 2 weeks). The result of presence of BAdV-3 in apparently health animals was agreement with Gras et al. (2017) who mentioned that presence of BAdV-3 in cattle related to subclinical infections, in the absence of clinical cases and high levels of their immunity in Brazil.

According to results of Monoscreen ELISA kit, Table (6) showed that, no positive samples were reported in males and 16 samples with one degree of positivity (9.24%) and 5 samples with two degrees of positivity (2.89%) were reported in females animals. This significant difference in this study between males and females may be agreed with Hemmatzadeh et al. (2001) who found significant difference between males and females in infection. The higher susceptibility of female buffaloes may be due to the fact that females are presented for slaughter at older age than males after the end of their breeding and milking period, while, males are fattened for a short period indoors and are fed mainly on dry ration until their slaughter which reduce the chance of contracting the infection (Dorny, 2002).

According to results of Monoscreen ELISA kit, Table (7) showed that, 1 sample with one degree of positivity (5%) was reported in pregnant animals, 15 samples with one degree of positivity (12.82%) and 5 samples with two degrees of positivity (4.27%) were reported in non-pregnant animals. These results may be due to reproductive disorders caused by BAdV-3 (Kahrs, 1981 and Gras et al., 2017).

According to results of Monoscreen ELISA kit, Table (8) showed that, 1 sample with one degree of positivity (7.69%) was reported in vaccinated animals by master cattle vaccine (vaccine against BoHV-1, BVDV, BRSV and BPI3), 15 samples with one degree of positivity (8.06%) and 5 samples with two degrees of positivity (2.68%) were reported in non-vaccinated animals by master cattle vaccine. This high seropositivity in non-vaccinated animals by master cattle vaccine may be due to that co-infection in BAdV-3 was prevalent according to Gras et al. (2017) and absence of biosecurity measures and introduction of infected animals (Soares et al., 2017).

CONCLUSION

In this study all samples were negative for BoHV-1, BVDV and BRSV; antibodies were detected against BPIV-3 and BAdV-3 in 0.05 and 10.55% in serum samples. Antibodies against BAdV-3 were higher than BPIV-3 in buffaloes at Assiut governorate. Also, it could be concluded that the various well known environmental factors plays an important role in spreading of these viral agents.

On the other side, and on the benefit of animal welfare, we surely need to pay attention for the continuous control of the environmental factors. From the obtained results further studies are needed to investigate the prevalence and role of different respiratory viruses especially BAdV-3 in Egyptian buffalo species.

 

REFERENCES

Adams, M.J.; Lefkowitz, E.J.; King, A.M.Q.; Harrach, B.; Harrison, R.L. and Knowles, N.J. (2016): Ratification vote on Taxonomic proposals to the International Committee on Taxonomy of Viruses. Arch. Virol. 161: 2921-49.

Akca, Y.; Burgu, I.; Gur, S. and Dagalp, S.B. (2004): A study on investigation of occurrence of some virus infection in Buffaloes in Turkey. Rev. Méd. Vét. 156(5): 268-271.

Al-Hammadi, M.A. and Hemida, M.G. (2014): Sero-prevalence of common respiratory viral diseases in Saudi Arabia. Assuit Vet. Med. J. 140: 76-81.

Anonymous (2000): Contagious animal disease in 2000. National Veterinary and Food Research institute EELA, Annual report, 2000: 29-30.

Canbolat, Ö. (2012): Buffalo breeding and current situation in Turkey. Tarim Türk J. 30: 176-180.

Carman, S.; Carr, N.; Delay, J.; Baxi, M.; Deregt, D. and Hazlett, M. (2005): Bovine viral diarrhea virus in alpaca: abortion and persistent infection. Vet. Diagn. Invest. J. 17: 589-93.

Craig, M.I.; Konig, G.A.; Benitez, D.F. and Draghi, M.G. (2015): Molecular analyses detect natural coinfection of water buffaloes (Bubalus bubalis) with bovine viral diarrhea viruses (BVDV) in serologically negative animals. Rev. Argent. Microbiol. 47(2): 148-151.

Dong, X.; Zhu, Y.; Cai, H.; Lv, C.; Gao,Y. and Yu, Z. (2012): Studies on the pathogenesis of a Chinese strain of bovine parainfluenza virus type 3 infection in Balb/c mice. Vet. Microbiol. 158: 199-204.

Dorny, P. (2002): A sero-epidemiological study of bovine cysticercosis in Zambia. Vet. Parasitol. 104(3):211-215.

Evans, C.A.; Cockcroft, P.D. and Reichel, M.P. (2016): Antibodies to bovine viral diarrhoea virus (BVDV) in water buffalo (Bubalus bubalis) and cattle from the Northern Territory of Australia. Australian Veterinary Journal 94(11): 423:426.

Gras, C.K.; Demoliner, M.; Eisen, A.K.A.; Spilki, F.R. and Henzel, A. (2017): Seroprevalence of Bovine Adenovirus and Enterovirus Antibodies Reveals Different Infection Dynamics in Cattle Herds. Acta Scientiae Veterinariae 45: 1463.

Hägglund, S.; Hjort, M.; Graham, D.A.; Ohagen, P.; Tornquist, M. and Alenius, S. (2007): A six year study on respiratory viral infections in a bull testing facility. Vet. J. 173: 585-593.

Hemmatzadeh, F.; Kojouri, G.H.; Karegar, P. and Rovhani, M. (2001): A serological survey on bovine viral diarrhea virus infection in Chahar Mahal Bakhtiary province, Iran. Fac. Vet. Med. J. the University of Tehran 56: 85-92.

Henrickson, K.J. (2003): Parainfluenza viruses. Clin. Microbiol. Rev., 16: 242-64.

Kahrs, R.F. (1981): Viral diseases of cattle, Ames, Iowa, Iowa State University Press: 61-70.

NADIS (2014): Respiratory Disease in Dairy and Beef Rearer Units. Available at: http://www.nadis.org.uk/bulletins/respiratory-disease-in-dairy-and-beef-rearer-units.aspx. Accessed at: 22 Feb., 2016.

Nandi, S.; Kumar, M.; Manohar, M. and Chauhan, R.S. (2009): Bovine herpesvirus infections in cattle. Anim. Health Res. Rev., 10: 85-98.

Radostits, O.M.; Gay, C.C.; Hinchcliff, K.W. and Constable, P.D. (2007): Veterinary Medicine. 10 editions, W.B. Saunders, London, pp: 1248-1276.

Saravanajayam, M.; Kumanan, K.; Balasubramaniam, A. and Palanivel, K.M. (2017): Comparison of Three Immunological Assays to Detect Infectious Bovine Rhinotracheitis (IBR) Antibodies in Buffaloes. Animal Research Journal 7 (5): 837-840.

Shalaby, M.A.; Saleh, A.A.; Hussein, H.A.; Baker, M.E.A. and Samy, A.M. (2002): Detection and isolation of bovine respiratory syncytial virus in buffaloes. Vet. Med. J. Giza, 50 (3): 339-404.

Shirvani, E.; Lotfi, M.; Kamalzadeh, M.; Noaman, V.; Bahriari, M.; Morovati, H. and Hatami, A. (2012): Seroepidemiological study of bovine respiratory viruses (BRSV, BoHV-1, PI-3V, BVDV, and BAV-3) in dairy cattle in central region of Iran (Esfahan province). Tropical animal health and production 44(1): 191-195.

Sinbat, S.A.; Al-Rodhan, A.M. and Othman, R.M. (2016): Molecular and serological detection of Bovine adenovirus type-3 in Basra province. Basra Veterinary Research J. 15: 3.

Soares, L.B.F.; Silva, B.P.; Borges, J.M.; Oliveira, J.M.B.; Macêdo, A.A.; Aragão, B.B.; Nascimento, S.A. and Junior, J.W.P. (2017): Occurrence of Bovine Viral Diarrhea (BVDV) and Bovine Infectious Rhinotracheitis (IBR) Virus Infections in Buffaloes in Pernambuco state – Brazil. Acta Scientiae Veterinariae 45: 1459.

 

Solis-Calderon, J.J.; Segura-Correa, J.C.; Aguilar-Romero, F. and Segura-correa, V.M. (2007): Detection of antibodies and risk factors for infection with bovine respiratory syncytial virus and Para-influenza virus-3 in beef cattle of Yucatan, Mexico. Prev. Vet. Med. 82: 102-10.

Teshome, H.; Molla, B. and Tibbo, M. (2003): A seroprevalence study of camel brucellosis in three camel-rearing regions of Ethiopia. Trop. Anim. Health prod. 35: 381-90.

Uttenthal, A.; Grondahl, C.; Hoyer, M.J.; Houe, H.; Van Maanen, C.; Rasmussen, T.B. and Larsen, L.E. (2005): Persistent BVDV infection in mousedeer infects calves. Do we know the reservoirs for BVDV? Prev. Vet. Med. 72: 87-91.

Valarcher, J. F. and Hӓgglund, S. (2006): Viral respiratory infections in cattle. In: Proceedings of the 24th World Buiatrics Congress. Nice, France.

Valarcher, J.F. and Taylor, G. (2007): Bovine respiratory syncytial virus infection. Vet. Res. 38: 153-180.

Yousef, M.R.; Mahmoud, M.A.; Ali, S.M. and Al-Blowi, M.H. (2013): Seroprevalence of some bovine viral respiratory diseases among non- vaccinated cattle in Saudi Arabia, Vet. World 6 (1): 1-4.

Zhu, Y.M.; Yu, Z.; Cai, H.; Gao, Y.R.; Dong, X.M.; Li, Z.L.; Shi, H.F.;  Meng, Q.F.; Lu, C. and Xue, F. (2011): Isolation, identification, and complete genome sequence of a bovine adenovirus type 3 from cattle in China. Virol J. 8: 557.


 


 

المسح السیرولوجی للأمراض التنفسیه الفیروسیه فی الجاموس فی محافظة أسیوط                                             

ط.ب/ إیناس شکری غالی 1, أ.د/ عادل السید أحمدمحمد 2, أ.د/عبد الرحیم عبد المطلب عبد الرحیم 3, أ.د/ممتاز عبد الهادی شاهین 4 .

1-       معهد بحوث الصحة الحیوانیة أسیوط، مصر.   2-  کلیة الطب البیطرى، جامعة جنوب الوادی، مصر.

3- کلیة الطب البیطرى، جامعة أسیوط،، مصر.    4- معهد بحوث الصحة الحیوانیة الدقی، الجیزة، مصر.

الملخص العربی :

الاضطرابات التنفسیة تمثل خطراً کبیراً علی صحة الجاموس حیث تلعب الفیروسات والبکتیریا تحت تآثیر عوامل الضغط والإجهاد دوراً أساسیاً فی حدوث العدوى التنفسیة الحادة. من المقبول بشکل عام أن الفیروسات هی أول مسببات الأمراض ، فی حین أن البکتیریا تعمل کمسبب ثانوی للعدوی یؤدی إلی سوء حالة الحیوان. ومن أهم المسببات الفیروسیة فیروس الإسهال الفیروسی البقری (BVDV) ، وفیروس الهربس البقری من النوع الأول (BoHV-1) ، والفیروس المخلوی التنفسی البقری (BRSV) ، وفیروس نوع الإنفلونزا البقری 3 (BPIV-3) ، والفیروس الغدی البقری (BAdVs). أجریت هذه الدراسة لتقییم الحالة المصلیة لـ BoHV-1 ، BVDV ، BRSV ، BPIV-3 و BAdV-3 فی الجاموس، فی محافظة أسیوط ، مصر. لهذا الغرض، تم اختبار العینات من خلال مجموعات الإلیزا غیر المباشرة التجاریة. وکانت جمیع العینات سلبیة بالنسبة لـ BoHV-1 و BVDV و BRSV ؛ تم الکشف عن الأجسام المضادة ضد BPIV-3  وBAdV-3 فی 0.05 و 10.55 ٪ من عینات المصل ، على التوالی. وفقا للدراسة الحالیة ، کان وجود الأجسام المضادة ضد BAdV-3 أعلى من BPIV-3 فی الجاموس فی محافظة أسیوط ، مصر.

REFERENCES
Adams, M.J.; Lefkowitz, E.J.; King, A.M.Q.; Harrach, B.; Harrison, R.L. and Knowles, N.J. (2016): Ratification vote on Taxonomic proposals to the International Committee on Taxonomy of Viruses. Arch. Virol. 161: 2921-49.
Akca, Y.; Burgu, I.; Gur, S. and Dagalp, S.B. (2004): A study on investigation of occurrence of some virus infection in Buffaloes in Turkey. Rev. Méd. Vét. 156(5): 268-271.
Al-Hammadi, M.A. and Hemida, M.G. (2014): Sero-prevalence of common respiratory viral diseases in Saudi Arabia. Assuit Vet. Med. J. 140: 76-81.
Anonymous (2000): Contagious animal disease in 2000. National Veterinary and Food Research institute EELA, Annual report, 2000: 29-30.
Canbolat, Ö. (2012): Buffalo breeding and current situation in Turkey. Tarim Türk J. 30: 176-180.
Carman, S.; Carr, N.; Delay, J.; Baxi, M.; Deregt, D. and Hazlett, M. (2005): Bovine viral diarrhea virus in alpaca: abortion and persistent infection. Vet. Diagn. Invest. J. 17: 589-93.
Craig, M.I.; Konig, G.A.; Benitez, D.F. and Draghi, M.G. (2015): Molecular analyses detect natural coinfection of water buffaloes (Bubalus bubalis) with bovine viral diarrhea viruses (BVDV) in serologically negative animals. Rev. Argent. Microbiol. 47(2): 148-151.
Dong, X.; Zhu, Y.; Cai, H.; Lv, C.; Gao,Y. and Yu, Z. (2012): Studies on the pathogenesis of a Chinese strain of bovine parainfluenza virus type 3 infection in Balb/c mice. Vet. Microbiol. 158: 199-204.
Dorny, P. (2002): A sero-epidemiological study of bovine cysticercosis in Zambia. Vet. Parasitol. 104(3):211-215.
Evans, C.A.; Cockcroft, P.D. and Reichel, M.P. (2016): Antibodies to bovine viral diarrhoea virus (BVDV) in water buffalo (Bubalus bubalis) and cattle from the Northern Territory of Australia. Australian Veterinary Journal 94(11): 423:426.
Gras, C.K.; Demoliner, M.; Eisen, A.K.A.; Spilki, F.R. and Henzel, A. (2017): Seroprevalence of Bovine Adenovirus and Enterovirus Antibodies Reveals Different Infection Dynamics in Cattle Herds. Acta Scientiae Veterinariae 45: 1463.
Hägglund, S.; Hjort, M.; Graham, D.A.; Ohagen, P.; Tornquist, M. and Alenius, S. (2007): A six year study on respiratory viral infections in a bull testing facility. Vet. J. 173: 585-593.
Hemmatzadeh, F.; Kojouri, G.H.; Karegar, P. and Rovhani, M. (2001): A serological survey on bovine viral diarrhea virus infection in Chahar Mahal Bakhtiary province, Iran. Fac. Vet. Med. J. the University of Tehran 56: 85-92.
Henrickson, K.J. (2003): Parainfluenza viruses. Clin. Microbiol. Rev., 16: 242-64.
Kahrs, R.F. (1981): Viral diseases of cattle, Ames, Iowa, Iowa State University Press: 61-70.
NADIS (2014): Respiratory Disease in Dairy and Beef Rearer Units. Available at: http://www.nadis.org.uk/bulletins/respiratory-disease-in-dairy-and-beef-rearer-units.aspx. Accessed at: 22 Feb., 2016.
Nandi, S.; Kumar, M.; Manohar, M. and Chauhan, R.S. (2009): Bovine herpesvirus infections in cattle. Anim. Health Res. Rev., 10: 85-98.
Radostits, O.M.; Gay, C.C.; Hinchcliff, K.W. and Constable, P.D. (2007): Veterinary Medicine. 10 editions, W.B. Saunders, London, pp: 1248-1276.
Saravanajayam, M.; Kumanan, K.; Balasubramaniam, A. and Palanivel, K.M. (2017): Comparison of Three Immunological Assays to Detect Infectious Bovine Rhinotracheitis (IBR) Antibodies in Buffaloes. Animal Research Journal 7 (5): 837-840.
Shalaby, M.A.; Saleh, A.A.; Hussein, H.A.; Baker, M.E.A. and Samy, A.M. (2002): Detection and isolation of bovine respiratory syncytial virus in buffaloes. Vet. Med. J. Giza, 50 (3): 339-404.
Shirvani, E.; Lotfi, M.; Kamalzadeh, M.; Noaman, V.; Bahriari, M.; Morovati, H. and Hatami, A. (2012): Seroepidemiological study of bovine respiratory viruses (BRSV, BoHV-1, PI-3V, BVDV, and BAV-3) in dairy cattle in central region of Iran (Esfahan province). Tropical animal health and production 44(1): 191-195.
Sinbat, S.A.; Al-Rodhan, A.M. and Othman, R.M. (2016): Molecular and serological detection of Bovine adenovirus type-3 in Basra province. Basra Veterinary Research J. 15: 3.
Soares, L.B.F.; Silva, B.P.; Borges, J.M.; Oliveira, J.M.B.; Macêdo, A.A.; Aragão, B.B.; Nascimento, S.A. and Junior, J.W.P. (2017): Occurrence of Bovine Viral Diarrhea (BVDV) and Bovine Infectious Rhinotracheitis (IBR) Virus Infections in Buffaloes in Pernambuco state – Brazil. Acta Scientiae Veterinariae 45: 1459.
 
Solis-Calderon, J.J.; Segura-Correa, J.C.; Aguilar-Romero, F. and Segura-correa, V.M. (2007): Detection of antibodies and risk factors for infection with bovine respiratory syncytial virus and Para-influenza virus-3 in beef cattle of Yucatan, Mexico. Prev. Vet. Med. 82: 102-10.
Teshome, H.; Molla, B. and Tibbo, M. (2003): A seroprevalence study of camel brucellosis in three camel-rearing regions of Ethiopia. Trop. Anim. Health prod. 35: 381-90.
Uttenthal, A.; Grondahl, C.; Hoyer, M.J.; Houe, H.; Van Maanen, C.; Rasmussen, T.B. and Larsen, L.E. (2005): Persistent BVDV infection in mousedeer infects calves. Do we know the reservoirs for BVDV? Prev. Vet. Med. 72: 87-91.
Valarcher, J. F. and Hӓgglund, S. (2006): Viral respiratory infections in cattle. In: Proceedings of the 24th World Buiatrics Congress. Nice, France.
Valarcher, J.F. and Taylor, G. (2007): Bovine respiratory syncytial virus infection. Vet. Res. 38: 153-180.
Yousef, M.R.; Mahmoud, M.A.; Ali, S.M. and Al-Blowi, M.H. (2013): Seroprevalence of some bovine viral respiratory diseases among non- vaccinated cattle in Saudi Arabia, Vet. World 6 (1): 1-4.
Zhu, Y.M.; Yu, Z.; Cai, H.; Gao, Y.R.; Dong, X.M.; Li, Z.L.; Shi, H.F.;  Meng, Q.F.; Lu, C. and Xue, F. (2011): Isolation, identification, and complete genome sequence of a bovine adenovirus type 3 from cattle in China. Virol J. 8: 557.